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80141013

80141013

  • 厂商:

    CROUZET(高诺斯)

  • 封装:

    -

  • 描述:

    MOTORDC66W12-48VDCSMI2110-2

  • 详情介绍
  • 数据手册
  • 价格&库存
80141013 数据手册
W W W.C ROUZET-MOTOR S.COM SMi21 DCMIND BRUSHLESS MOTORS USER AND SAFETY MANUAL SMi21 SMi21 DCmind Brushless Motors User Manual and Safety Notice Important Notes        This manual is part of the product. Read and follow the instructions in this manual. Keep this manual in a safe place. Give this manual and any other documents relating to the product to anyone that uses the product. Read and be sure to comply with all the safety instructions and the section "Before you Begin Safety-Related Information". Please consult the latest catalogue to find out about the product's technical specifications. We reserve the right to make modifications without prior notification. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 1/224 SMi21 Table of Contents 1. 2. 3. Introduction ................................................................................................................................................6 1.1. Motor Family .....................................................................................................................................6 1.2. Characteristics ..................................................................................................................................6 1.3. Options ..............................................................................................................................................6 1.4. Identification Label ............................................................................................................................6 1.5. Product Coding .................................................................................................................................7 Before you Begin - Safety-Related Information .........................................................................................8 2.1. Personnel Qualifications ...................................................................................................................8 2.2. Use in Compliance with Industry Practice .........................................................................................8 2.3. Basic Information ..............................................................................................................................9 2.4. Standards and concepts .................................................................................................................10 Precautions for use concerning the mechanics .......................................................................................11 3.1. 3.1.1. Press-fit force .........................................................................................................................11 3.1.2. Radial load on the shaft ..........................................................................................................11 3.2. 4. Options ............................................................................................................................................12 3.2.1. Holding brake .........................................................................................................................12 3.2.2. Gearboxes ..............................................................................................................................12 3.2.3. Other .......................................................................................................................................12 Accessories ..............................................................................................................................................12 4.1. 5. Data specific to the motor shaft ......................................................................................................11 Starter Kit ........................................................................................................................................12 Installation ................................................................................................................................................13 5.1. Overview of the Installation Procedure ...........................................................................................15 5.2. Electromagnetic Compatibility (EMC) .............................................................................................15 5.3. Prior to Mounting .............................................................................................................................16 5.4. Mounting the Motor .........................................................................................................................17 5.5. Electrical Installation .......................................................................................................................18 5.5.1. 5.6. 6. 8. USB Connector ...............................................................................................................................21 operation ..................................................................................................................................................22 6.1. 7. Connecting the Holding Brake (Optional) ...............................................................................20 Preparation for Operating ................................................................................................................22 Product overview .....................................................................................................................................24 7.1. Description of the Product ...............................................................................................................24 7.2. SMi21 Control Electronics ...............................................................................................................24 7.3. "DCmind-Soft" PC Parameter-Definition Software ..........................................................................25 Technical Specifications ..........................................................................................................................26 8.1. Electrical Data .................................................................................................................................26 8.2. Generic Data ...................................................................................................................................26 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 2/224 SMi21 8.3. Control Logic Bundle .......................................................................................................................27 8.4. Power Supply Cable ........................................................................................................................28 9. Motor electrical connection ......................................................................................................................29 9.1. Power Connection ...........................................................................................................................29 9.1.1. Ballast Circuit ..........................................................................................................................29 9.1.2. EMC Protection ......................................................................................................................31 9.2. Protection ........................................................................................................................................32 9.2.1. Voltage Protection ..................................................................................................................32 9.2.2. Temperature Protection ..........................................................................................................32 9.2.3. Current Limiting ......................................................................................................................32 9.3. USB Connection ..............................................................................................................................33 9.4. Input/Output Connection .................................................................................................................35 9.4.1. Equivalent Input Diagram .......................................................................................................35 9.4.2. Equivalent Output Diagram ....................................................................................................36 10. Installation of the DCmind-Soft HMI ....................................................................................................37 10.1. Introduction......................................................................................................................................37 10.2. System Required .............................................................................................................................37 10.3. Installation of the USB Drivers ........................................................................................................37 10.4. Installation of the Crouzet DCmind-Soft HMI ..................................................................................38 10.5. Description of the Main Window .....................................................................................................41 10.6. Motor Connection ............................................................................................................................43 10.7. Updating the Firmware ....................................................................................................................44 11. Application programs ...........................................................................................................................46 11.1. Description ......................................................................................................................................46 11.2. Description of the Monitoring Part ...................................................................................................48 11.3. "Valve" Group ..................................................................................................................................49 11.3.1. "Valve 4 positions" Application Program ................................................................................49 11.3.2. "Valve 30 positions" Application Program with 1 Mechanical Stop ........................................51 11.4. "Conveyor Belt" Group ....................................................................................................................54 11.4.1. "Conveyor Belt 0-10V" Application Program ..........................................................................54 11.4.2. "Conveyor Belt PWM" Application Program ...........................................................................56 11.4.3. « Conveyor with stop on detection » Application program .....................................................58 11.5. "Machine" Group .............................................................................................................................60 11.5.1. "Worm Gear" Application Program .........................................................................................60 11.5.2. "Worm Gear (Proportional)" Application Program .................................................................63 11.5.3. "Clamp" Application Program .................................................................................................66 11.6. « Dosing » group .............................................................................................................................68 11.6.1. 12. Application program « Peristaltic pump » ...............................................................................68 Expert programs ..................................................................................................................................70 12.1. Speed Programs .............................................................................................................................70 12.1.1. Types of Inputs in V100 Programs .........................................................................................70 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 3/224 SMi21 12.1.2. Types of Inputs in V200 Programs .........................................................................................70 12.1.3. Types of Outputs in V100 Programs ......................................................................................71 12.1.4. Type of outputs in V200 programs .........................................................................................71 12.1.5. Description of the Various V100 and V200 Tabs ...................................................................71 12.1.6. Expert Program V101 .............................................................................................................77 12.1.7. Expert Program V102 .............................................................................................................87 12.1.8. Expert Program V103 .............................................................................................................96 12.1.9. Expert Program V104 ...........................................................................................................106 12.1.10. Expert program V201 ...........................................................................................................116 12.1.11. Expert program V202 ...........................................................................................................124 12.2. Position Programs .........................................................................................................................132 12.2.1. Types of Inputs in P100 Programs .......................................................................................132 12.2.2. Types of Inputs in P200 Programs .......................................................................................133 12.2.3. Types of Outputs in P100 and P200 Programs ....................................................................134 12.2.4. Description of the Different Types of Homing ......................................................................135 12.2.5. Description of the P100 Various Tabs ..................................................................................141 12.2.6. Expert Program P101 ...........................................................................................................147 12.2.7. Expert Program P111 ...........................................................................................................160 12.2.8. Description of the P200 Various Tabs ..................................................................................172 12.2.9. Expert Program P201 ...........................................................................................................178 12.2.10. Expert Program P202 ...........................................................................................................192 12.3. Torque Programs ..........................................................................................................................206 12.3.1. Types of Inputs in C100 Programs .......................................................................................206 12.3.2. Types of Outputs in C100 Programs ....................................................................................206 12.3.3. Description of the Various Tabs ...........................................................................................207 12.3.4. Expert Program C101 ...........................................................................................................211 13. Saving Parameters ............................................................................................................................218 14. Diagnostics and Troubleshooting ......................................................................................................221 14.1. Mechanical Failures ......................................................................................................................221 14.2. Electrical Failures ..........................................................................................................................221 15. Service, maintenance and disposal ...................................................................................................222 15.1. Addresses of After-Sales Service Outlets .....................................................................................222 15.2. Storage ..........................................................................................................................................222 15.3. Maintenance ..................................................................................................................................222 15.4. Replacing the Motor ......................................................................................................................223 15.5. Dispatch, Storage, Disposal ..........................................................................................................223 15.6. Terminology and Abbreviations.....................................................................................................224 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 4/224 SMi21 About This Manual This manual applies to SMi21 DCmind brushless products:  801400SMI21, 801495SMI21, 801496SMI21, 801410SMI21  801800SMI21, 801896SMI21, 801897SMI21, 801810SMI21  802800SMI21, 802896SMI21, 802897SMI21, 802810SMI21 Reference source for manuals The manuals can be downloaded from our website at the following address: http://www.crouzet.com/ Units SI units are the default values. Risk Categories In this manual, safety instructions are identified by warning symbols. Depending on how serious the situation is, the safety instructions are split into 3 risk categories. DANGER DANGER indicates a directly dangerous situation which, if the instructions are not followed, will inevitably lead to a serious or fatal accident. WARNING WARNING indicates a possibly dangerous situation which, if the instructions are not followed, will in some cases lead to a serious or fatal accident or cause damage to equipment. CAUTION CAUTION indicates a potentially dangerous situation which, if the instructions are not followed, will in some cases lead to an accident or cause damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 5/224 SMi21 1. INTRODUCTION 1.1. Motor Family SMi21 DCmind brushless motors are brushless DC motors, with a control circuit board integrated in the motor. 1.2. Characteristics SMi21 DCmind brushless motors are intelligent servomotors for speed, position and torque control applications. They can be configured via a Human-Machine Interface (HMI). They are equipped with 2 unshielded cables as standard, 1 for the power, 1 for the control signals. 1.3. Options The motors can be supplied with options, such as:  Different gearboxes  A failsafe holding brake  Different motor output shaft versions 1.4. Identification Label The label contains the following data: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. Product family code. Product part number. Reserved zone. Zone reserved for specific customer marking. Week/year manufacturing date. Operating voltage. Nominal motor speed at 24 V. Nominal motor current. Reduction ratio (for geared motor versions). Maximum nominal torque applicable to the gearbox (for geared motor versions). Motor approvals. Insulation system temperature class. Product degree of protection (sealing) during operation (excluding output shaft). Country of origin. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 6/224 SMi21 1.5. Product Coding 80 XX XX SMi21: Product family on SMi21 electronic base PRODUCT REFERENCE 8 0 X X X X X X Motor Type of stator: 14: 30mm brushless stator 18: 50 mm brushless stator 28: 50 mm brushless stator high torque Gearbox adaptation 00: no gearbox 10: RAD10 gearbox 95: P52 gearbox 96: P62 gearbox 97: P81 gearbox Increment numbers C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 7/224 SMi21 2. BEFORE YOU BEGIN - SAFETY-RELATED INFORMATION 2.1. Personnel Qualifications Only qualified personnel who are familiar with and fully understand the contents of this manual are authorized to work on and with this product. Qualified personnel must be familiar with current standards, regulations and requirements concerning prevention of accidents during work undertaken on and with this product. These qualified personnel must have undergone safety training in order to be able to detect and avoid related hazards. Their professional training, knowledge and experience renders such qualified personnel capable of preventing and recognizing potential hazards that might be generated through use of the product, modifying settings and the mechanical, electrical and electronic equipment in the whole installation. 2.2. Use in Compliance with Industry Practice As demonstrated in these instructions, this product is a component designed for use in industrial environments. The current safety instructions, specified conditions and technical specifications must be complied with at all times. Before starting to use the product, undertake a risk analysis using actual examples. Depending on the result, the necessary safety measures must be implemented. Since the product is used as a component in an overall system, it is the user's responsibility to guarantee people's safety through the concept of the overall system (e.g. concept of a machine). Only use original manufacturer accessories and spare parts. The product must not be used in explosive atmospheres (Ex zone). All other types of use are deemed to be non-compliant and can be dangerous. Only qualified personnel are authorized to install, operate, maintain and repair electrical equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 8/224 SMi21 2.3. Basic Information DANGER DANGEROUS PHENOMENON LINKED TO ELECTRIC SHOCK, EXPLOSION OR EXPLOSION DUE TO AN ELECTRIC ARC • Only qualified personnel who are familiar with and fully understand the contents of this manual are authorized to work on this product. Only qualified personnel are authorized to undertake installation, setting, repair and maintenance. • The installation manufacturer is responsible for complying with all the applicable requirements and regulations with regard to grounding the drive system. • It is the user's responsibility to define whether it is necessary to ground the motor, depending on its intended use. • Do not touch unprotected live parts. • Only use electrically-isolated tools. • AC voltages can be connected to unused conductors in the motor cable. Isolate unused conductors at both ends of the motor cable. • The motor produces a voltage when the shaft turns. Protect the motor shaft from any external drive operation before working on the drive system: – De-energize all connections. – Attach a notice saying "DO NOT START UP" on all the switches. – Protect all the switches from switching on. – Wait for the internal motor capacitors to discharge. Measure the voltage on the power cable and check that it is less than 12 VDC. • Install protective covers and ensure they are closed before energization. Failure to comply with these precautions will result in death or serious injury. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 9/224 SMi21 WARNING LOSS OF COMMAND CONTROL • When perfecting the command concept, the installation manufacturer must take account of the possibilities for potential failure of command paths and provide, for certain critical functions, the means of returning to safe states during and after the failure of a command path. Examples of critical command functions are: EMERGENCY STOP, end position limiting, network outage and restarting. • Separate or redundant command paths must be available for critical functions. • Comply with the accident prevention instructions and all current safety directives. • Any installation in which the product described in this manual has a central role must be carefully and meticulously checked prior to commissioning to ensure it is working properly. Failure to comply with these precautions can result in death or serious injury. WARNING UNBRAKED MOVEMENT In the event of a power outage and errors resulting in disconnection of the power stage, the motor is no longer braked in a controlled way and can cause damage. • Prevent access to the hazardous zone. • If necessary, use a damped mechanical stop or a service brake. Failure to comply with these precautions can result in death, serious injury or damage to equipment. 2.4. Standards and concepts The product is ROHS confirmed following European Directive 2011/65/CE. Following this confirmation, the product is CE marked. The electrical design follows the IEC 60335-1 and IEC 60950-1 standards. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 10/224 SMi21 3. PRECAUTIONS FOR USE CONCERNING THE MECHANICS 3.1. Data specific to the motor shaft 3.1.1. Press-fit force WARNING MOTOR MECHANISM Exceeding the maximum permissible forces on the shaft leads to rapid bearing wear, a broken shaft or damage to any accessories (encoder, brake, etc.) • Never exceed the maximum axial and radial forces. • Protect the shaft from any impact. • When press-fitting components, do not exceed the maximum permissible axial force. Failure to comply with these precautions can result in death, serious injury or damage to equipment. The maximum press-fit force is limited by the maximum permissible axial force on the ball bearings. This maximum axial force is stated in the motor technical data sheet. Alternatively, the component to be fixed in position can be clamped, glued or shrunk-fit. 3.1.2. Radial load on the shaft The application point X of the radial force F depends on the motor size. This information appears in the motor technical data sheet. The maximum axial and radial loads must not be applied simultaneously. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 11/224 SMi21 3.2. Options 3.2.1. Holding brake SMi21 DCmind brushless motors can be equipped as standard with a failsafe electromechanical brake. The holding brake is designed to lock the motor shaft in a de-energized state. The holding brake is not a safety function. How it is controlled is described in the "Connecting the Holding Brake" section. 3.2.2. Gearboxes SMi21 DCmind brushless motors can be equipped with different types of gearbox. The gearboxes offered as standard in the catalogue are planetary gearboxes which combine compact size and robust design, and worm gearboxes that allow a shaft output at right-angles to the motor shaft. 3.2.3. Other Other types of adaptation are possible on request, please contact the sales department. 4. ACCESSORIES 4.1. Starter Kit This kit consists of a 2-meter long micro USB B to USB A (MOLEX 68784-0003) connecting cable and a USB stick containing the "Crouzet Interface" parameter-definition software and installation drivers for this HMI. This starter kit can be obtained by ordering part number 79 298 008. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 12/224 SMi21 5. INSTALLATION Installation must, as a general rule, be performed in accordance with good practice. WARNING HEAVY WEIGHT AND FALLING PARTS The motor can be extremely heavy. • When mounting, take the weight of the motor into account. • Mounting (screw tightening torque) must be performed in such a way that the motor cannot become detached, even if subjected to strong accelerations or constant jolting. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING STRONG ELECTROMAGNETIC FIELDS Motors can generate locally powerful electrical and magnetic fields. These can cause sensitive equipment to fail. • Keep people with implants such as pacemakers away from the motor. • Do not place sensitive equipment in the immediate vicinity of the motor. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING UNEXPECTED BEHAVIOR CAUSED BY DAMAGE OR FOREIGN BODIES Following damage to the product or the presence of foreign bodies, deposits or penetration of fluid, unexpected behavior can occur. • Do not use damaged products. • Make sure that no foreign body has been able to penetrate the product. • Check that the power supply lead seals and cable entries have been positioned correctly. • Check that the stopper protecting the USB B to USB A micro connector has been positioned correctly. Failure to comply with these precautions can result in death, serious injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 13/224 SMi21 WARNING HOT SURFACES The product's metal surface can heat up to more than 70°C in certain types of use. • Avoid all contact with the metal surface. • Do not place flammable or heat-sensitive components in the immediate vicinity. • Assemble components in the best way for heat dissipation. Failure to comply with these precautions can result in injury or damage to equipment. WARNING DAMAGE AND DESTRUCTION OF THE MOTOR CAUSED BY STRESS The motor is not designed to carry loads. If subjected to stress, the motor can be damaged, or even fall. • Do not use the motor as a step. • Prevent the motor from being used in any way other than its intended purpose by installing guards or displaying safety instructions. Failure to comply with these precautions can result in injury or damage to equipment. CAUTION VOLTAGE SURGES During braking phases, the motor generates voltage surges. • Check that these voltage surges are acceptable to other devices connected on the same power supply. • If possible, use an external circuit to limit voltage surges. if the brake is used intensively. Failure to comply with these precautions can result in injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 14/224 SMi21 5.1. Overview of the Installation Procedure The installation procedure is described in the following sections:      Electromagnetic Compatibility (EMC) Prior to Mounting Mounting the Motor Electrical Installation Connecting the USB cable to Set the Motor Parameters Check that these sections have been read and understood, and that installation has subsequently been executed correctly. 5.2. Electromagnetic Compatibility (EMC) DANGER INTERFERENCE AFFECTING SIGNALS AND EQUIPMENT Disturbed signals can cause equipment to behave unpredictably. • Wire up products in compliance with the specific EMC recommendations for each device. • Make sure that these EMC recommendations are executed correctly. Failure to comply with these precautions can result in death, serious injury or damage to equipment. Recommendations in terms of EMC: Installing the motor power supply leads When planning the wiring, take account of the fact that the motor power supply leads must be kept separate from line supplies or cables carrying signals. Comply with the following measures as concerns EMC. Measures relating to EMC Effect Keep the cables as short as possible. Do not install unnecessary cable loops. Reduces stray couplings, both capacitive and inductive. Ground the product. Reduces emissions, improves immunity to interference. Reduces emissions. If using shielded cables, install the cable shielding so that it is in contact with the widest possible surface area, use cable grips and ground strips. Keep the motor power supply leads separate from cables carrying signals or use shielding plates. If using shielded cables, install the cables without any disconnection points. 1) Reduces stray cross-couplings. Reduces stray radiation. 1) When a cable is disconnected for installation, the cables must be connected at the disconnection point via a shelding connection and a metal box. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 15/224 SMi21 Equipotential bonding conductors If using shielded cables, differences in potential can generate unauthorized currents on the cable shielding. Use equipotential bonding conductors to minimize currents on the cable shielding. 5.3. Prior to Mounting Look for any damage Damaged drive systems must neither be mounted nor used.  Check the drive system prior to mounting, looking out for any visible signs of damage. Clean the shaft On leaving the factory, the motor shaft extensions are coated with a film of oil. If transmission devices are to be glued on, it may be necessary to remove the film of oil and clean the shaft. If necessary, use degreasing products in accordance with the glue manufacturer's instructions.  Avoid any direct contact between the skin or sealing materials and the cleaning product used. Flange mounting surface The mounting surface must be stable, flat and clean.  In regards to installation, make sure that all dimensions and tolerances are respected. Specification of power supply leads The power supply leads for the motor and its accessories must be selected carefully on the basis of their length, the motor supply voltage, the ambient temperature, the current level circulating therein, and their environment. WARNING DAMAGE AND FIRE DUE TO INCORRECT INSTALLATION Repeated force and movement around the grommets can damage the cables. • Comply with the stated bend radius. • Avoid subjecting the grommets to repeated force or movement. • Attach the power supply cables close to the grommets using a strain relief. Failure to comply with these precautions can result in injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 16/224 SMi21 5.4. Mounting the Motor DANGER HOT SURFACES The motor's surface can heat up to more than 70°C in certain types of use. • Avoid contact with hot surfaces. • Do not place flammable or heat-sensitive components in the immediate vicinity. • Assemble components in the best way for heat dissipation. • Check the temperature when performing a test. Failure to comply with these precautions can result in injury or damage to equipment. WARNING UNEXPECTED MOVEMENT DUE TO ELECTROSTATIC DISCHARGES Electrostatic discharges (ESD) on the shaft can, in rare cases, lead to encoder system failures and generate unexpected motor movements. • Use conductive parts (e.g. antistatic straps) or other appropriate measures to avoid a static charge due to movement. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING UNINTENDED BEHAVIOR CAUSED BY MECHANICAL DAMAGE TO THE MOTOR Exceeding the maximum permissible forces leads to rapid bearing wear, a broken shaft or damage to the internal encoder. • Never exceed the maximum axial and radial forces. • Protect the shaft from any impact. • When press-fitting components, do not exceed the maximum permissible axial force. Failure to comply with these precautions can result in death, serious injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 17/224 SMi21 Mounting position The motor can be mounted in any position. Mounting When mounting the motor on the flange, the motor must be aligned precisely in both the axial and radial directions. All the fixing screws must be tightened to the tightening torque stipulated by the application, taking care not to generate any warping. Install the transmission devices If the transmission device is installed incorrectly, this can damage the motor. Transmission devices such as pulleys and gears must be mounted in compliance with the maximum axial and radial loads defined in each motor's technical data sheet. Follow the transmission device manufacturer's assembly instructions. The motor and the transmission device must be aligned precisely both axially and radially. If this is not done, it will result in abnormal operation, damage to the bearings and significant wear. 5.5. Electrical Installation These motors are not designed to be connected directly to the line supply. It is the installer's responsibility to define the electrical protection devices to be implemented according to the regulations applicable to the end product range of application. For the power supply to the power part we recommend using a double-insulated stabilized power supply. The motor is not protected against polarity reversals on the power part. The motor is regenerative, in other words it can feed back energy to the power supply during braking phases. Voltage surges created in this way can reach levels that risk destroying the motor itself or devices placed on the same power supply. DANGER ELECTRIC SHOCK High voltages can appear unexpectedly on the motor connection. • The motor produces a voltage when the shaft turns. Protect the motor shaft from any external drive operation before working on the drive system. • The system manufacturer is responsible for complying with all applicable regulations with regard to grounding the drive system. Failure to comply with these precautions will result in death or serious injury. WARNING UNEXPECTED MOVEMENT As a result of incorrect wiring or other error, the drives can execute unexpected movements. • Do not start up the installation if there is anybody or any obstacle in the danger zone. • Execute the initial test movements without loads connected. • Do not touch the motor shaft or related drive elements. Failure to comply with these precautions can result in death, serious injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 18/224 SMi21 WARNING VOLTAGE SURGES During braking phases, the motor generates voltage surges. • Check that these voltage surges are acceptable to other devices connected on the same power supply. • If possible, use an external circuit to limit voltage surges. if the brake is used intensively. Failure to comply with these precautions can result in death, serious injury or damage to equipment. CAUTION FIRE CAUSED BY BAD CONTACTS If the connector is not properly inserted the motor connector can overheat, causing the contacts to melt due to an electric arc. • Incorrect connection can cause overheating due to an electric arc. Failure to comply with these precautions can result in injury or damage to equipment. CAUTION IRREPARABLE PRODUCT DAMAGE CAUSED BY REVERSED POLARITY Incorrect connection of the power can result in reversed polarity, resulting in destruction of the circuit board inside the motor. • Check the conformity of the power connections. • Place a slow-blow fuse on the power supply that is appropriately sized for the current the motor needs to absorb in the application. Failure to comply with these precautions can result in injury or damage to equipment. Connecting the protection conductor It is the installer's responsibility to define whether the motor needs to be grounded. The mounting flange should be used for this purpose. Never connect or disconnect the product power supply leads while the voltage is applied. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 19/224 SMi21 5.5.1. Connecting the Holding Brake (Optional) WARNING LOSS OF BRAKING FORCE DUE TO WEAR OR HIGH TEMPERATURE Engaging the holding brake while the motor is running leads to rapid wear and loss of braking force. • Do not use the brake as a service brake. • Note that "emergency stops" can also cause wear. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING UNEXPECTED MOVEMENT Releasing the holding brake can result in unexpected movement on the installation. • Make sure this cannot cause any damage. • Do not continue with the test if there is anybody or any obstacle in the danger zone. Failure to comply with these precautions can result in death, serious injury or damage to equipment. CAUTION MALFUNCTION OF THE HOLDING BRAKE DUE TO INAPPROPRIATE VOLTAGE • If the voltage is too low, the holding brake cannot release, resulting in wear. • In the event of voltages higher than the specified value, the holding brake will be subject to significant overheating. Failure to comply with these precautions can result in injury or damage to equipment. A motor with a holding brake needs a corresponding control logic which releases the holding brake at the start of the rotation movement, locking the motor shaft in time when the motor stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 20/224 SMi21 5.6. USB Connector Stopper Housing The motor is equipped with a USB B to USB A micro connector, which can be accessed by removing the stopper from the housing. The stopper prevents penetration of foreign bodies or fluids inside the motor. The stopper prevents fingers or any inappropriate object making contact with the USB B to USB A micro connector. It must be replaced carefully after use, in order to keep the motor sealed. WARNING UNEXPECTED MOVEMENT DUE TO ELECTROSTATIC DISCHARGES Electrostatic discharges (ESD) on the USB B to USB A micro connector can, in some cases, lead to deterioration or destruction of some system components and generate unexpected motor operation. • Never touch the connector with your fingers or any inappropriate object. Failure to comply with these precautions can result in death, serious injury or damage to equipment. CAUTION LOSS OF SEALING The stopper ensures the motor is sealed. • Replace it after completing parameter definition. • Make a visual check to ensure it is in place. Failure to comply with these precautions can result in injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 21/224 SMi21 6. OPERATION 6.1. Preparation for Operating Prior to operating:  Check that the mechanical installation is correct.  Check that the electrical installation has been carried out professionally: pay special attention to the protective conductor connections and the grounding connections. Check that all the junctions are correct, properly connected and that the screws are fully tightened.  Check the ambient conditions and operating conditions: make sure that the stipulated ambient conditions are adhered to and that the drive solution conforms to the expected operating conditions.  Check that any transmission devices that are already mounted are balanced and aligned precisely.  Check that the operating conditions do not generate abnormal voltage surges for the product or the application.  Check that the holding brake can withstand the maximum load. After applying the braking voltage, make sure that the holding brake is fully released. Make sure that the holding brake is fully released before initiating a movement.  Check that the USB micro connector's protective stopper has been replaced correctly. WARNING UNEXPECTED MOVEMENT As a result of incorrect wiring or other error, the drives can execute unexpected movements. • Check the wiring. • Do not start up the installation if there is anybody or any obstacle in the danger zone. • Execute the initial test movements without loads connected. • Do not touch the motor shaft or related drive elements. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING ROTATING PARTS Rotating parts can cause injuries, trap clothing or hair. Separate parts or unbalanced parts can be ejected. • Check that all rotating parts are fitted properly. • Use a protective cover for rotating parts. Failure to comply with these precautions can result in death, serious injury or damage to equipment. WARNING FALLING PARTS The motor can move due to the reaction torque; it can topple over and fall. • Fix the motor firmly in place so that it cannot become detached during rapid acceleration. Failure to comply with these precautions can result in death, serious injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 22/224 SMi21 CAUTION HOT SURFACES The motor's surface can heat up to more than 70°C in certain types of use. • Avoid contact with hot surfaces. • Do not place flammable or heat-sensitive components in the immediate vicinity. • Assemble components in the best way for heat dissipation. • Check the temperature when performing a test. Failure to comply with these precautions can result in injury or damage to equipment. CAUTION VOLTAGE SURGES During braking phases, the motor generates voltage surges. • Check that these voltage surges are acceptable to other devices connected on the same power supply. • If possible, use an external circuit to limit voltage surges. if the brake is used intensively. Failure to comply with these precautions can result in injury or damage to equipment. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 23/224 SMi21 7. PRODUCT OVERVIEW 7.1. Description of the Product 12-pin logic connector (Inputs/Outputs) Label Failsafe rear brake (Optional) Power supply (Power and Logic) Integrated optical encoder (4096 points) Output shaft USB-B micro-connector (Parameter definition via HMI) SMi21 integrated electronics Figure 1 7.2. SMi21 Control Electronics The SMi21 electronic control card contains the control electronics for a brushless motor, integrated in the motor body. This electronics is used for: • • • • • • Power switching of the motor in sine mode (field-oriented control (FOC)). Position-Speed-Torque and Current control algorithms. Use of preconfigured programs which can perform numerous routine applications. Management of different types of operation: o "Stand-alone" motor without external PLC. o Use with other motors incorporating SMi21 or TNI21 or Motomate electronics. o Use with a programmable controller, with the SMi21 simplifying motor management. The interface with parameter-definition software installed on the PC: o Easy to use, even by a layman, thanks to simplified application programs that are quick to get up and running. o Wide choice of expert programs covering a wide range of applications. o USB connection via a commercially-available standard cable (can be supplied on request). Management of 6 inputs and 4 outputs to control the motor: o 2 inputs that can be configured for 0-10 V 10-bit analog or PWM or digital control o 4 digital inputs o 1 output that can be configured as PWM or frequency or digital o 1 output that can be configured as PWM or digital o 2 digital outputs As standard, the motors have an internal encoder with 4096 points per revolution that can reach high positioning and control resolutions. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 24/224 SMi21 7.3. "DCmind-Soft" PC Parameter-Definition Software This software can be downloaded from the Internet at the following address: http://www.crouzet.com/. It can also be supplied as a kit, see "Programming Kit" section. This "DCmind-Soft" software is needed the first time the motor is used and for debugging. It is used for: • Selecting the motor operating program: o Position o Speed o Torque o Quick and easy starting using preprogrammed applications. o Use of "expert" programs that provide access to all settings. • • The various settings needed for the application to work correctly. Updating the "firmware" motor program using the bootloader function. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 25/224 SMi21 8. TECHNICAL SPECIFICATIONS 8.1. Electrical Data Maximum Product Specifications Parameters Supply voltage VDC_MAX Maximum current IDC_MAX Maximum input voltage VIN_MAX Maximum output voltage VOUT_MAX Maximum output current IOUT_MAX Operating Specifications Parameters Supply voltage VDC Current IDC Motor consumption when stopped without holding W0 Input Specifications Parameters Input impedance In1 to In4 RIN_DIG Input impedance I5 to I6 RIN_ANA/PWM Low logic level on inputs In1 to In4 VIL_DIG High logic level on inputs In1 to In4 VIH_DIG Low logic level on inputs I5 to I6 VIL_PWM High logic level on inputs I5 to I6 VIH_PWM Output Specifications Parameters Low logic level on outputs Out1 to Out4 VOL RL = 4 K7Ω, VDC = 24 V High logic level on outputs Out1 to Out4 VOL RL = 4 K7Ω, VDC = 24 V PNP open collector type Value 60 20 50 60 50 Unit V A V V mA Min 9 - Typical 12 / 24 / 48 10 Max 56 17 Unit V A - 1 - W Min 0 4 0 7.5 Typical 57 69 - Max 2 50 2 50 Unit Ω Ω V V V V Min Typical Max Unit 0 - 0.2 V VDC – 0.5 V - VDC V 8.2. Generic Data General Specifications Parameters Ambient motor temperature Insulation class (compliant with directive IEC 60085) Ingress protection (excluding output shaft) C.MO.SAV.00006.FR_V5 January 12th, 2016 Value -30 to +70 E IP65M Unit °C / / Page 26/224 SMi21 8.3. Control Logic Bundle This consists of a UL approved cable Style 2464 80°C 300 V, 500 mm long as standard, fitted with a 12-pin MOLEX connector part number 43025-1200: Figure 2 Pin 1 2 3 4 5 6 7 8 9 10 11 12 Type Input no. 1 – Digital Input no. 2 – Digital Input no. 3 – Digital Input no. 4 – Digital Input no. 5 – Analog setpoint or PWM (or Digital) Input no. 6 – Analog setpoint or PWM (or Digital) Logic ground - 0 VDC Logic ground - 0 VDC Output no. 1 – Digital or PWM Output no. 2 – Digital or PWM Output no. 3 – Digital Output no. 4 – Digital Wire Color (AWG24) Green Yellow White White/Brown Blue Orange Black White/Black Brown Purple Red Gray A label attached to the motor summarizes this information: Figure 3 Connector part numbers to be used for connection: On a card: MOLEX series 43045 On a cable: MOLEX series 43020 With cables more than 3 m long, tests must be performed in situ. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 27/224 SMi21 8.4. Power Supply Cable Type Power supply: 12 VDC → 48 VDC Power ground: 0 VDC Wire Color (AWG16) Brown Blue The power supply cable is UL approved Style 2517 105°C 300 V, 500 mm long as standard. When a cable extension is used, the cable cross-section size should depend on the current drawn and the cable length. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 28/224 SMi21 9. MOTOR ELECTRICAL CONNECTION 9.1. Power Connection We recommend grounding the motor housing. Power connection diagram. Figure 4 (1) (2) Include capacitors to smooth out inrush currents. Recommended value 1000 µF/A drawn. Optional. The ballast circuit eliminates voltage surges produced when braking. See next section. The product is not protected against polarity reversals on the power cable. A polarity reversal can damage the product irreversibly. 9.1.1. Ballast Circuit When the motor brakes, the kinetic energy stored in the inertias during rotation is returned to the power supply and generates a voltage surge. This voltage surge can be destructive for the motor or for devices connected to the power supply. In the event of frequent braking, an external ballast circuit must be used. It is always necessary to conduct tests to check what size it should be. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 29/224 SMi21 9.1.1.1. Proposed Ballast Circuit Diagram The diagram below allows the braking energy to be dissipated into a resistor, thus limiting voltage surges at the motor terminals. Figure 5 9.1.1.2. Determining the Size of the R12 Resistor (RBallast) The higher the braking current, the lower the resistor value. Typical values are around several Ohms. With V the rotation speed in revolutions per minute and J the inertia in Kg.m², the energy E in Joules stored in the inertia is given by: 𝐸= 𝜋² × 𝐽 × 𝑉² 1800 If t is the braking duration in seconds, the power P1 dissipated during this time will be: 𝑃1 = 𝐸 𝑡 Note: The time t is set via the value of the deceleration ramps in the HMI. If T is the time interval between 2 braking operations in seconds, the dissipated power P2 will be: 𝑃2 = 𝑃1 𝑇 The resistor should be large enough to dissipate the power P2 while tolerating peaks at P1. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 30/224 SMi21 It should be noted however that this is a simplified and somewhat pessimistic calculation since it does not take account of the energy stored in the capacitors, nor that lost during friction, the gearbox, etc. 9.1.1.3. Voltage Breaking Capacity Selection The voltage breaking capacity should be selected: - Depending on the power supply - Depending on the other devices connected to this power supply If your power supply does not tolerate current feedback, place a diode in series upstream of the ballast circuit to protect it. The voltage breaking capacity usually selected is between +10% and +20% of the supply voltage. E.g.: For 24 VDC the voltage breaking capacity would be 28 VDC. List of components for the usual operating voltages: Nominal voltage Voltage breaking capacity D1 R13 R5 12V 14V 24V 28V 32V 36V 48V 52V SMBJ14A 0R 15K 1% SMBJ28A 560R 0.5W 4K32 1% SMBJ36A 1K 1W 3K09 1% SMBJ54A 2K2 2W 1K95 1% 9.1.2. EMC Protection In order to ensure that the product is compatible with EMC standards IEC 61000-6-1, IEC 61000-6-2, IEC 61000-6-3, IEC 61000-6-4, we recommend: - Connecting the motor to ground while limiting length of the grounding strip, - Adding capacitors on the main power supply. We recommend 1000 µF per amp drawn. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 31/224 SMi21 9.2. Protection DANGER PROTECTION The product has internal protection devices that switch off the motor power supply when activated. As the motor is no longer controlled, driving loads can decrease. • The system manufacturer is responsible for complying with all the applicable safety rules in the event of product failure. Failure to comply with these precautions will result in death or serious injury. 9.2.1. Voltage Protection The product incorporates protection against voltage surges and undervoltages. Protection against voltage surges: The voltage surge threshold can be set in the HMI between 12 and 57 V (set at 57 V by default). When the supply voltage exceeds the threshold, the product automatically switches to ERROR mode. In ERROR mode the motor is no longer controlled. To reset the motor: - The supply voltage must be at least 1 V below the threshold value. - The motor inputs must be set to STOP mode. Protection against undervoltages: When the supply voltage falls below 8 V, the product automatically switches to ERROR mode. In ERROR mode the motor is no longer controlled. To reset the motor: - The supply voltage must be higher than 9 V. - The motor inputs must be set to STOP mode. 9.2.2. Temperature Protection The product incorporates temperature protection in the form of a temperature sensor on the motor pilot control card. Temperature protection: When the internal temperature exceeds 110°C, the product automatically switches to ERROR mode. In ERROR mode the motor is no longer controlled. To reset the motor: - The temperature must be less than 90°C. - The motor inputs must be set to STOP mode. 9.2.3. Current Limiting The product incorporates internal current limiting. This limiting directly affects the motor in terms of hardware. This limiting automatically restricts the current to 17 A in the motor phases. If this limit is reached, it results in a loss of motor performance. This product is not designed to operate continuously with this limiting (see the "Electrical Data" section). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 32/224 SMi21 9.3. USB Connection USB connection requires a type B micro-USB socket on the motor. The cable must be less than 3 m long. Possible cable part number: MOLEX 68784-0003. Connection procedure  Carefully remove the black stopper from the motor to reveal the Micro USB-B connector. The stopper has a retainer to keep it attached to the motor. Figure 6  Figure 7 Insert the USB cable and install the drivers as instructed. Take care never to touch the connector or contacts inside the motor with your fingers or any inappropriate object. Once finished, it is essential to replace the stopper carefully, to maintain the motor seal and protect the connector from any contact. Simply pressing your finger in the middle of the stopper will close it properly. Figure 8 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 33/224 SMi21 Incorrect stopper fitting Figure 9 Figure 10 Correct stopper fitting Figure 11 C.MO.SAV.00006.FR_V5 January 12th, 2016 Figure 12 Page 34/224 SMi21 9.4. Input/Output Connection 9.4.1. Equivalent Input Diagram NPN digital inputs Figure 13 Analog/PWM/digital inputs Figure 14 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 35/224 SMi21 9.4.2. Equivalent Output Diagram PNP outputs with max. 50 mA open collector. Include a pull down resistor (recommended value 4.7 kΩ). Figure 15 Caution: The output level is the same as the motor supply voltage: if V DC = 48V then Out1/Out2/Out3/Out4 = 48 V. In the event of rejection, this voltage increases accordingly, and can rise up to 57 V maximum (voltage threshold value). If your application necessitates limiting the voltage value of these outputs, implement the diagram below. Customer output (24 V) C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 36/224 SMi21 10. INSTALLATION OF THE DCMIND-SOFT HMI 10.1. Introduction To configure motors in the SMi21 DCmind Brushless range, Crouzet provides a user-friendly HMI that is easy to use. By means of a communication interface, the HMI establishes the connection between the PC and the motor and can be used to configure the motor and adapt its operation to the application. 10.2. System Required The HMI is compatible with the following operating systems: - Windows XP Family & Professional (with Framework version 3.5 minimum: supplied on USB stick) Windows Vista Windows 7 (32 & 64-bit) The HMI installation files are supplied on the USB stick in the programming kit and are available for download from the Internet at the following address: http://www.crouzet.com/ 10.3. Installation of the USB Drivers Run the "Driver Motor.exe" file in the "Driver" folder: Figure 16 Figure 17 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 37/224 SMi21 10.4. Installation of the Crouzet DCmind-Soft HMI Run the "Setup_DCmind_Soft_Vxxx.msi" file and follow the instructions: N.B.: - When installing the "DCmind-Soft" HMI, check that Bluetooth is disabled on the PC. - The USB drivers must always be installed upstream. Figure 18: Steps 1 and 2 Figure 19: Steps 3 and 4 Once installation is complete, the PC software can be launched directly via the "DCmind-Soft" icon on the desktop. Note: To uninstall the "DCmind-Soft" application, follow the standard Windows procedure: - "Start" "Control Panel" "Add or Remove Programs" "DCmind-Soft" "Remove" C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 38/224 SMi21 Note: For PCs running Windows XP, the version of Framework may not be recent enough to be able to install the "DCmind-Soft" HMI. On launching the setup, the HMI automatically informs the user of this problem by displaying the following window: Figure 20 We recommend that you download the latest available version of Framework from the Microsoft website. Should no internet connection be available, a minimum version of Framework is supplied on the USB stick in the programming kit. To install version 3.5 of Framework supplied on the USB stick, run the "dotnetfx35.exe" file and follow the instructions: Figure 21 Tick the box "I have read and accept the license terms", then press the "Install >" button. Figure 22 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 39/224 SMi21 During installation, Windows tries to connect to the server to download the Framework multi-language package (this may take several minutes as 5 attempts are made to connect to the server). After 5 attempts, the software is installed directly via the setup supplied on the USB stick: Figure 23 Figure 24 Once installation of Framework 3.5 is complete, try again to install the "DCmind-Soft" HMI, referring to the "Installation of the Crouzet DCmind-Soft HMI" section in this document. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 40/224 SMi21 10.5. Description of the Main Window Once all the installations are complete (drivers + HMI), connect the motor to the PC and launch the HMI by double-clicking on the icon below: Figure 25 The HMI home page appears: Main menu bar Contextual help window Displays the various application programs in the form of icons Application Program selection Displays the various expert programs in the form of icons Expert Program selection Figure 26 Application programs:  The application programs are grouped together with similar applications (valve, conveyor belt, machine, etc.).  They enable quick start-up with completion of just a few key application values.  Each application program is based on a preconfigured expert program. After testing the motor a few times in the application, the user can refine the motor operation by accessing all the adjustment parameters via the expert program linked to the application program and changing the pre-filled values. Expert programs:  The expert programs are grouped together with similar programs (P1xx, P2xx, etc position control, V1xx, V2xx speed control, C1xx, C2xx torque control).  These are generic programs, not specific to any application. They can be used to access all the options and settings. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 41/224 SMi21  They can be used directly, without going via the "application program" step and they offer a wider choice of uses. The contextual help window gives a description of the selected application when you hover over it with the mouse cursor. Note: DCmind-Soft is constantly being improved. The latest available update can be downloaded from our website http://www.crouzet.com/ Description of the tabs on the main menu bar: Bootloader: Board firmware update Language: HMI language selection Motor Information: Can be used to find out information about the motor when it is connected Open: Loads a parameter file Save As: Saves a parameter file Exit: Closes the HMI Figure 27 "Motor Information" window Figure 28 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 42/224 SMi21 The "Help" tab contains the SMi21 DCmind Brushless motors user manual in .pdf format. 10.6. Motor Connection To connect the motor, link the motor and the PC using the USB B to USB A micro cable (supplied in the programming kit), power up the motor and click on "Motor Connection" in the main menu bar. The following window appears: Figure 29 Click the "Autodetect button to start the automatic motor search. If a motor is connected to the PC, it is automatically detected and the following window appears: COM port on which the motor has been detected Link baud rate Figure 30 Figure 31 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 43/224 SMi21 Click "OK", the motor is now connected and ready to be used. If "Motor not detected" appears in the information window, check that the motor is correctly supplied with power, the micro USB B to USB A cable is plugged in correctly and repeat the procedure. 10.7. Updating the Firmware To update the version of the software embedded in the motor, a bootloader is used via USB communication. This operation can only be performed by advanced users, as if done incorrectly this could result in the product not working. Power up the motor and click "Bootloader" in the main menu bar (entire memory completely rewritten), the following window appears: Click this completely program. button rewrite to the Figure 32 A warning message appears asking to confirm the firmware update request and to avoid any incorrect action: Figure 33 To start the update, click "Yes" and select the .hex program supplied by CROUZET: C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 44/224 SMi21 .hex program supplied by CROUZET Figure 34 Click the "Open" button, updating begins: Location of the .hex file being loaded. Loading progress bar. Figure 35 When the update is complete, the following window appears, meaning that loading has been successful: C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 45/224 SMi21 Figure 36 11. APPLICATION PROGRAMS 11.1. Description Select an application group from the list of application programs, then one of the icons corresponding to your application. Figure 37 Figure 38 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 46/224 SMi21 Figure 39 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 47/224 SMi21 11.2. Description of the Monitoring Part The monitoring part of the HMI is common to all the expert and application program tabs. This zone uses graphic icons to indicate the type of program I/O used (in this case 4 digital inputs, 2 analog setpoint inputs, 2 PWM outputs and 2 digital outputs). This zone describes the status of the connection between the HMI and the motor (green for connected and red for not connected).It gives in real time (once a second) the value of the various measurements taken on the motor (voltage, temperature, speed, position and torque). States of the various program digital I/O (green for active and blue for inactive). For the analog setpoints, the user can display their value (rpm, rpm/sec, mN.m, etc.) on the IN5 and IN6 dial faces. The type of error detected can be viewed on this tab. PWM/Pulse or Frequency type outputs are not included in this tab. Figure 40 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 48/224 SMi21 11.3. "Valve" Group 11.3.1. "Valve 4 positions" Application Program Input connections Output connections Figure 41 The "Valve 4 positions" application program invokes the P101 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. Note: Each time you power ON the power supply or a program is loaded, it is necessary to perform the homing sequence. 11.3.1.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:       IN1: If 0 → No position setpoint, IN2: If 0 → No position setpoint, IN3: If 0 → No position setpoint, IN4: If 0 → No position setpoint, IN5: If 0 → No action, IN6: If 0 → Stop, if 1 → Setpoint = "Position 1" Parameter if 1 → Setpoint = "Position 2" Parameter if 1 → Setpoint = "Position 3" Parameter if 1 → Setpoint = "Position 4" Parameter if 1 → Launch homing phase if 1 → Run N.B.: if more than 1 input IN1 to IN4 is activated at the same time, the motor switches to stop mode. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 49/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.   OUT1: If 0 → setpoint position not reached, OUT2: If 0 → homing phase complete,   OUT3: If 0 → motor stopped, OUT4: If 0 → no error, 11.3.1.2. if 1 → setpoint position reached. if 1 → homing phase in progress or not performed. if 1 → motor running. if 1 → error detected. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  The "Number of rotation(s) to close the valve" and "Mechanical ratio between the motor and the valve" parameters are used to calculate the application total stroke in number of motor revolutions: 𝑇𝑜𝑡𝑎𝑙 𝑐𝑜𝑢𝑟𝑠𝑒 [𝑅𝑜𝑡𝑎𝑡𝑖𝑜𝑛 𝑚𝑜𝑡𝑜𝑟] = 𝑁𝑏 𝑜𝑓 𝑟𝑜𝑡𝑎𝑡𝑖𝑜𝑛𝑟𝐶𝑙𝑜𝑠𝑖𝑛𝑔 𝑣𝑎𝑙𝑣𝑒 × 𝜂 𝑉𝑎𝑣𝑒𝑠 𝑣𝑠 𝑀𝑜𝑡𝑜𝑟  The "Time to realize the total stroke" parameter is used to calculate the motor speed of rotation during the positioning phases: 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝑇𝑜𝑡𝑎𝑙 𝑐𝑜𝑢𝑟𝑠𝑒 [𝑅𝑜𝑡𝑎𝑡𝑖𝑜𝑛𝑚𝑜𝑡𝑜𝑟 ] × 60 𝑇𝑖𝑚𝑒𝑠𝑡𝑜𝑡𝑎𝑙 𝑐𝑜𝑢𝑟𝑠𝑒 [𝑠𝑒𝑐] The calculated value is given for information in the grayed-out box.  The motor speed of rotation during the mechanical stop search phase (homing) is determined as follows: 𝐻𝑜𝑚𝑖𝑛𝑔 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 11.3.1.3. 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] 5 Motor Configuration  Used to configure the mechanical stop search phase (homing) by setting the "Homing torque" and the direction of valve closing.  The nominal and maximum torques in the motor are determined from the "Homing torque" value as follows: 𝑁𝑜𝑚𝑖𝑛𝑎𝑙 𝑡𝑜𝑟𝑞𝑢𝑒 = 𝐻𝑜𝑚𝑖𝑛𝑔 𝑡𝑜𝑟𝑞𝑢𝑒 𝑇𝑜𝑟𝑞𝑢𝑒 𝑀𝑎𝑥𝑖 = 2 × 𝐻𝑜𝑚𝑖𝑛𝑔 𝑡𝑜𝑟𝑞𝑢𝑒  For information, the maximum torque value seen by the valve during operation is given in the grayed-out box. 11.3.1.4. Valve Positioning  The user has the option of setting 4 setpoint position parameters as a percentage of valve opening.  By default, position 1 corresponds to detection of the mechanical stop (valve closed). If the user wishes to add an offset to avoid mechanical shocks during valve closing, he should change the "Position 1" parameter accordingly.  By default, position 4 corresponds to the application total stroke (valve open).  For information, all 4 positions are given in number of pulses (4096 pulses per motor revolution) in the grayed-out boxes. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 50/224 SMi21 11.3.2. "Valve 30 positions" Application Program with 1 Mechanical Stop Input connections Output connections Figure 42 The "Valve 30 positions" application program invokes the P111 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. Note: Each time you power ON the power supply or a program is loaded, it is necessary to perform the homing sequence. 11.3.2.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:   IN1 to IN5: 32 possible combinations: - IN1 = IN2 = IN3 = IN4 = IN5 = 0 → Stop. - IN1 = 1, all 4 others = 0 → Launch homing phase. - The other 30 combinations correspond to the 30 position setpoints. IN6: Not used. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 51/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.   OUT1: If 0 → setpoint position not reached, OUT2: If 0 → homing phase complete,   OUT3: If 0 → motor stopped, OUT4: If 0 → no error, 11.3.2.2. if 1 → setpoint position reached. if 1 → homing phase in progress or not performed. if 1 → motor running. if 1 → error detected. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  The "Number of rotation(s) to close the valve" and "Mechanical ratio between the motor and the valve" parameters are used to calculate the application total stroke in number of motor revolutions: 𝑇𝑜𝑡𝑎𝑙𝑒 𝑐𝑜𝑢𝑟𝑠𝑒 [𝑅𝑜𝑡𝑎𝑡𝑖𝑜𝑛𝑚𝑜𝑡𝑜𝑟 ] = 𝑁𝑏 𝑟𝑜𝑡𝑎𝑡𝑖𝑜𝑛 𝑐𝑙𝑜𝑠𝑖𝑛𝑔 𝑣𝑎𝑙𝑣𝑒 × 𝜂 𝑉𝑎𝑙𝑣𝑒 𝑣𝑠 𝑀𝑜𝑡𝑜𝑟  The "Time to realize the total stroke" parameter is used to calculate the motor speed of rotation during the positioning phases: 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝑇𝑜𝑡𝑎𝑙𝑒 𝑐𝑜𝑢𝑟𝑠𝑒[𝑟𝑜𝑡𝑎𝑡𝑖𝑜𝑛 𝑚𝑜𝑡𝑜𝑟 ] × 60 𝑇𝑖𝑚𝑒𝑠𝑇𝑜𝑡𝑎𝑙𝑒 𝑐𝑜𝑢𝑟𝑠𝑒 [𝑠𝑒𝑐] The calculated value is given for information in the grayed-out box.  The motor speed of rotation during the mechanical stop search phase (homing) is determined as follows: 𝐻𝑜𝑚𝑖𝑛𝑔 𝑠𝑝𝑒𝑒𝑑[𝑅𝑃𝑀] = 11.3.2.3. 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] 5 Motor Configuration  Used to configure the mechanical stop search phase (homing) by setting the "Homing torque" and the direction of valve closing.  The nominal and maximum torques in the motor should be determined from the "Homing torque" value as follows: 𝑁𝑜𝑚𝑖𝑛𝑎𝑙 𝑡𝑜𝑟𝑞𝑢𝑒 = 𝐻𝑜𝑚𝑖𝑛𝑔 𝑡𝑜𝑟𝑞𝑢𝑒 𝑀𝑎𝑥𝑖 𝑡𝑜𝑟𝑞𝑢𝑒 = 2 × 𝐻𝑜𝑚𝑖𝑛𝑔 𝑡𝑜𝑟𝑞𝑢𝑒  For information, the maximum torque value seen by the valve during operation is given in the grayed-out box. 11.3.2.4. Position Table  The user is not able to change the position setpoints, they will automatically be defined with between 2 and 30 equal positions, according to the defined total stroke and the "Number of positions" parameter. To change them, you need to change to "Expert Mode".  By default, position 1 corresponds to detection of the mechanical stop (valve closed).  By default, the last position corresponds to the application total stroke (valve open). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 52/224 SMi21  For information, the position setpoints are given in number of valve rotations and number of pulses (4096 pulses per motor revolution). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 53/224 SMi21 11.4. "Conveyor Belt" Group 11.4.1. "Conveyor Belt 0-10V" Application Program Input connections Output connections Figure 43 The "Conveyor Belt 0-10V" application program invokes the V101 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. 11.4.1.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:      IN1: If 0 → Stop, if 1 → Run IN2: If 0 → motor running in reverse (CCW), if 1 → motor running forward (CW) IN3: If IN3 = 1 and IN1 = 1 and IN6 = 0, application of a 150 mNm holding torque. IN4: If 0 → no action, if 1 → Quick start by short-circuiting the coils. This action takes priority over the other commands. IN5: 0-10 V control. Sets the motor acceleration and deceleration. 40,000 rpm/sec for 0 V (maximum acceleration) and 100 rpm/sec for 10 V. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 54/224 SMi21  IN6: 0-10 V control. Sets the speed setpoint. 0 V for 0 rpm and 10 V for the maximum motor speed defined by the user. Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1: Provides information on the motor speed value in PWM. Cyclical ratio = 0% → speed = 0 rpm Cyclical ratio = 100% → speed = maximum speed.  OUT2: Provides information on the real torque value in PWM. Cyclical ratio = 0% → torque = 0 mNm Cyclical ratio = 100% → torque = 1 Nm.   OUT3: If 0 → motor running, OUT4: If 0 → error detected, 11.4.1.2. if 1 → motor stopped. if 1 → no error. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  The maximum motor speed corresponding to a voltage of 10 V is calculated as follows: 𝑆𝑒𝑡𝑝𝑜𝑖𝑛𝑡 𝑚𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑10𝑉 [𝑅𝑃𝑀] = 𝑀𝑎𝑥 𝑠𝑝𝑒𝑒𝑑 𝑇𝑎𝑝𝑖𝑠 [𝑚. 𝑠 −1 ] × 60 𝑆𝑝𝑒𝑒𝑑 𝑠𝑡𝑒𝑝 [𝑚. 𝑡𝑟 −1 ] The calculated value is given for information in the grayed-out box. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 55/224 SMi21 11.4.2. "Conveyor Belt PWM" Application Program Input connections Output connections Figure 44 The "Conveyor Belt PWM" application program invokes the V101 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. 11.4.2.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:       IN1: If 0 → Stop, if 1 → Run IN2: If 0 → motor running in reverse (CCW), if 1 → motor running forward (CW) IN3: If IN3 = 1 and IN1 = 1 and IN6 = 0, application of a 150 mNm holding torque. IN4: If 0 → no action, if 1 → Quick start by short-circuiting the coils. This action takes priority over the other commands. IN5: PWM control. Sets the motor acceleration and deceleration. 40,000 rpm/sec for 0% PWM (maximum acceleration) and 100 rpm/sec for 100% PWM. IN6: PWM control. Sets the speed setpoint. 0% PWM for 0 rpm and 100% PWM for the maximum motor speed defined by the user. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 56/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1: Provides information on the motor speed value in PWM. Cyclical ratio = 0% → speed = 0 rpm Cyclical ratio = 100% → speed = maximum speed.  OUT2: Provides information on the real torque value in PWM. Cyclical ratio = 0% → torque = 0 mNm Cyclical ratio = 100% → torque = 1 Nm.   OUT3: If 0 → motor running, OUT4: If 0 → error detected, 11.4.2.2. if 1 → motor stopped. if 1 → no error. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  The maximum motor speed corresponding to a PWM signal with 100% cyclical ratio is calculated as follows: 𝑆𝑒𝑡𝑝𝑜𝑖𝑛𝑡 𝑚𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑100% 𝑃𝑊𝑀 [𝑅𝑃𝑀] = 𝑀𝑎𝑥 𝑠𝑝𝑒𝑒𝑑 [𝑚. 𝑠 −1 ] × 60 𝑆𝑝𝑒𝑒𝑑 𝑠𝑡𝑒𝑝 [𝑚. 𝑡𝑟 −1 ] The calculated value is given for information in the grayed-out box. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 57/224 SMi21 11.4.3. « Conveyor with stop on detection » Application program Output connecting Input connecting Figure 45 The « Conveyor belt with stop on detection » application program invokes the V202 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once settings are complete, press the "Load Program" button to configure the motor. 11.4.3.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs: (0 = no voltage applied; 1 = voltage applied on the input)       0 → Stop, 1 → Run 0 → Direction from program setting 1 → Direction inverted Note: this input is useful when a same program setting is needed for conveyors having to run in opposite directions. IN3 : « Reverse direction » 0 → No reverse 1 → Reverses and inhibits IN4 IN4 : « Sensor » 0 → Nothing detected 1 → Stop required (if IN3 = 0) IN5 : « Speed » Analog input (0/10V or PWM) → Speed setting IN6 : « Position » Analog input (0/10V or PWM) → Stop distance setting IN1 : « ON/OFF » IN2 : « Usual belt direction » C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 58/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1 : Target 0 : Stop position not reached 1 : Stop position reached OUT2 : Direction. 0 : Motor CCW (counter clock wise) 1 : Motor CW (clock wise)  OUT3 : Run 0 : No run 1 : Motor running  OUT4 : Error : 0: No error detected 1: Error detected.  11.4.3.2. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  Parameters « Max. belt speed » and « Mechanical ratio » allow to define the maximum motor speed at 10V input.  Maximum motor speed is calculated as following : 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑10𝑉 [𝑅𝑃𝑀] = 𝑀𝑎𝑥 𝑏𝑒𝑙𝑡 𝑠𝑝𝑒𝑒𝑑 [𝑚. 𝑠 −1 ] × 60 𝑀𝑒𝑐ℎ𝑎𝑛𝑖𝑐𝑎𝑙 𝑟𝑎𝑡𝑖𝑜 [𝑚. 𝑡𝑟 −1 ] This value is indicated in the grey box for information.  Belt conveyor stop distance is calculated as following : Parameters « Max. stop distance » and « Mechanical ratio » are used to calculate the maximum rotation of the motor in number of pulses (4096 pulses represent one motor turn). 𝑀𝑜𝑡𝑜𝑟 𝑝𝑢𝑙𝑠𝑒𝑠10𝑉 [𝑃𝑢𝑙𝑠𝑒𝑠] = 𝑀𝑎𝑥. 𝑠𝑡𝑜𝑝 𝑑𝑖𝑠𝑡𝑎𝑛𝑐𝑒 [𝑐𝑚] × 4096 100 ∗ 𝑀𝑒𝑐ℎ𝑎𝑛𝑖𝑐𝑎𝑙 𝑟𝑎𝑡𝑖𝑜 [𝑚. 𝑡𝑟 −1 ] This value is indicated in the grey box for information.  « Motor direction » area allows to define the motor direction by defect (when IN2 = 0). Conveyor belt manufacturers ask for good use, that conveyor’s motor pulls the belt which brings objects (not push).  « Command” area allows to define which signal type will be used for IN5 and IN6.  Option “Via PLC” allows to precise if the “sensor” input is driven by PLC (if selected) or directly by the object’s sensor (if not selected). When “Via PLC” is not selected, motor memorizes the “sensor” detections and goes to stop position even if the detected object exceeds the detector. To restart the conveyor in speed, an OFF/ON action on IN1 has to be done.  Parameter « minimum pulse duration » allows to filter IN4 sensor input signal. The signal has to exceed this time before to be taken in count. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 59/224 SMi21 11.5. "Machine" Group 11.5.1. "Worm Gear" Application Program Output connections Input connections Figure 46 The "Worm Gear" application program uses a preset P111 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. Note: Each time you power ON the power supply or a program is loaded, it is necessary to perform the homing sequence. 11.5.1.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:   IN1 to IN5: 32 possible combinations: - IN1 = IN2 = IN3 = IN4 = IN5 = 0 → Stop - IN1 = 1, all 4 others = 0 → Launch homing phase - The other 30 combinations correspond to the 30 position setpoints IN6: Switch limit input if « switch » is selected as “type of stop” C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 60/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.   OUT1: If 0 → setpoint position not reached, OUT2: If 0 → homing phase complete,   OUT3: If 0 → motor stopped, OUT4: If 0 → no error, 11.5.1.2. if 1 → setpoint position reached. if 1 → homing phase in progress or not performed. if 1 → motor running. if 1 → error detected. Initialization Phase  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  Select the type of stop, either "Mechanical" if the stop is achieved by detection of an obstacle on the application, or "Switch" if a limit switch is used in the application.  Define the motor direction of rotation used to reach the stop selected above (forward (CW) rotation by default).  To protect the application and prevent the mechanical stop being reached each time it returns to position zero, a position offset (in mm) can be set between the mechanical stop and position 1 corresponding to the application reference. 11.5.1.3. Application Settings  To determine the maximum operating speed during the positioning phases, the user should enter the maximum linear speed in mm/s and the "Step of the screw" and "Mechanical ratio between the motor and the screw" adjustment parameters are used to obtain a motor speed of rotation according to the formula below: 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝐿𝑖𝑛𝑒𝑎𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑚𝑚/𝑠] × 𝑠𝑡𝑒𝑝𝑅𝑒𝑑𝑢𝑐𝑡𝑖𝑜𝑛 × 60 𝑆𝑡𝑒𝑝𝑠𝑐𝑟𝑒𝑤 [𝑚𝑚/𝑟𝑜𝑡𝑎𝑡𝑖𝑜𝑛]  The motor speed of rotation during the mechanical stop search phase (homing) is determined as follows: 𝐻𝑜𝑚𝑖𝑛𝑔 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 11.5.1.4. 𝑀𝑜𝑡𝑜𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] 5 Motor Configuration  To determine the nominal torque during operation, the user should enter the maximum thrust for his application in Newtons and the "Step of the screw" and "Mechanical ratio between the motor and the screw" adjustment parameters are used to obtain a nominal motor torque using the following formula: 𝑀𝑜𝑡𝑜𝑟 𝑡𝑜𝑟𝑞𝑢𝑒 [𝑚𝑁. 𝑚] = 1 𝑃𝑢𝑠ℎ𝑖𝑛𝑔 [𝑁] × 𝑆𝑡𝑒𝑝𝑠𝑐𝑟𝑒𝑤 [𝑚𝑚/𝑡𝑜𝑢𝑟] × 2𝜋 𝑆𝑡𝑒𝑝𝑅𝑒𝑑𝑢𝑐𝑡𝑖𝑜𝑛  The homing and maximum torques for detecting the mechanical stop in the motor are determined from the "Motor Torque" value defined above as follows: 𝐻𝑜𝑚𝑖𝑛𝑔 𝑡𝑜𝑟𝑞𝑢𝑒 = 𝑀𝑜𝑡𝑜𝑟 𝑡𝑜𝑟𝑞𝑢𝑒 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 61/224 SMi21 𝑀𝑎𝑥𝑖 𝑡𝑜𝑟𝑞𝑢𝑒 = 2 × 𝑀𝑜𝑡𝑜𝑟 𝑡𝑜𝑟𝑞𝑢𝑒 11.5.1.5. Position Table  The user is not able to enter the 2 to 30 position setpoints himself, they are automatically defined with between 2 and 30 equidistant positions, according to the defined total stroke "Total stroke length" and the "Number of positions" parameter.  Position 1 corresponds to detection of the mechanical stop (as close as possible to the offset).  The last position corresponds to the application total stroke.  In the table, the position setpoints are given in mm. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 62/224 SMi21 11.5.2. "Worm Gear (Proportional)" Application Program Output connections Input connections Figure 47 The "Worm Gear (Proportional)" application program uses the P201 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. Note: Each time you power ON the power supply or a program is loaded, it is necessary to perform the homing sequence 11.5.2.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:  IN1 and IN2 : 4 possible combinations : - [IN1-IN2] = [00] → Stop and error reset - [IN1-IN2] = [10] → Homing phase - [IN1-IN2] = [01] → Maintain actual position - [IN1-IN2] = [11] → Go to required position  IN3 : Switch limit input if « switch » is selected as “type of stop”  IN4 : High speed (if 0) or low speed (if 1) selection  IN5 : Proportional position setting – Coarse tuning  IN6 : Proportional position setting – Thin tuning  C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 63/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1: Provides information on the motor speed value in PWM. Cyclical ratio = 0% → speed = 0 rpm Cyclical ratio = 100% → speed = 4000 rpm.  OUT2: Provides information on the real torque value in PWM. Cyclical ratio = 0% → torque = 0 mNm Cyclical ratio = 100% → torque = maximum torque.   OUT3: If 0 → motor running, OUT4: If 0 → error detected, 11.5.2.2. if 1 → motor stopped. if 1 → no error. Initialization Phase  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  Select the type of stop, either "Mechanical" if the stop is achieved by detection of an obstacle on the application, or "Switch" if a limit switch is used in the application.  Define the motor direction of rotation used to reach the stop selected above (forward (CW) rotation by default).  To protect the application and prevent the mechanical stop being reached each time it returns to position zero, a position offset (in mm) can be set between the mechanical stop and position 1 corresponding to the application reference. 11.5.2.3. Application Settings  To determine the maximum operating speed during the positioning phases, the user should enter the maximum linear speed in mm/s and the "Step of the screw" and "Mechanical ratio between the motor and the screw" adjustment parameters are used to obtain a motor speed of rotation according to the formula below: 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑙𝑖𝑛𝑒𝑎𝑟 𝑠𝑝𝑒𝑒𝑑 [𝑚𝑚/𝑠] × 𝑠𝑡𝑒𝑝𝑅𝑒𝑑𝑢𝑐𝑡𝑖𝑜𝑛 × 60 𝑆𝑡𝑒𝑝𝑠𝑐𝑟𝑒𝑤 [𝑚𝑚/𝑟𝑜𝑡𝑎𝑡𝑖𝑜𝑛]  By activating the digital input 4 (IN4 = 1), the user selects the low speed profile : 𝐿𝑜𝑤 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] 5  The motor speed of rotation during the mechanical stop search phase (homing) is determined as follows: 𝐻𝑜𝑚𝑖𝑛𝑔 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] = 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑠𝑝𝑒𝑒𝑑 [𝑅𝑃𝑀] 5 NB: Motor speed is restricted to max. 4000rpm in this program. If this value is exceeded, the writing becomes red colored and the loading of the parameters becomes impossible. It is strongly advised to check motor specifications before to configuring the application. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 64/224 SMi21 11.5.2.4. Motor Configuration  To determine the maximum torque during operation, the user should enter the maximum thrust for his application in Newtons and the "Step of the screw" and "Mechanical ratio between the motor and the screw" and “Mechanical system efficiency” adjustment parameters are used to obtain a maximum motor torque using the following formula: 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑡𝑜𝑟𝑞𝑢𝑒 [𝑚𝑁. 𝑚] = 1 𝑃𝑢𝑠ℎ𝑖𝑛𝑔 [𝑁] × 𝑆𝑡𝑒𝑝𝑠𝑐𝑟𝑒𝑤 [𝑚𝑚/𝑡𝑜𝑢𝑟] × ×2 2𝜋 𝑆𝑡𝑒𝑝𝑅𝑒𝑑𝑢𝑐𝑡𝑖𝑜𝑛 𝑁𝑜𝑚𝑖𝑛𝑎𝑙 𝑡𝑜𝑟𝑞𝑢𝑒 = 𝑀𝑎𝑥𝑖𝑚𝑢𝑚 𝑡𝑜𝑟𝑞𝑢𝑒 2  To detect the mechanical end stop, the homing torque is automatically set to be equal to nominal torque. NB : The max. torque has to don’t be higher than 1000 mNm. If this value is exceeded, the writing becomes red colored and the loading of the parameters becomes impossible. The real maximum torque value is limited per motor characteristics. It is strongly advised to check motor specifications before to configuring the application. 11.5.2.5. Position setpoint  The user indicates the total stroke in mm of the application : parameter « Total stroke length ». The full stroke is achieved when both setpoints (IN5 and IN6) are at 10V. To travel this distance, the settings are distributed as follows: o o Coarse setting : Input IN5 allows to travel 63/64th of the « total stroke length » Thin setting : Input IN6 allows to travel 1/64th of the « total stroke length »  The resolution of each of the two inputs IN5 and IN6 is given as an indication in the gray boxes in the « Position table – Input 5 and input 6 scale » zone : o Distance equivalent to an applied voltage of 1V o Distance equivalent to an applied voltage of 0,01V (resolution of the system) Example : For a «Total stroke length » = 300 mm : → Input IN5 allows to travel: 𝑆𝑡𝑟𝑜𝑘𝑒𝐸5 = 63 64 × 300𝑚𝑚 = 295,3125𝑚𝑚 (for 10V applied) Meaning 29,53125 mm for 1V Meaning 0,2953125 mm for 0,01V → Input IN6 allows to travel: 𝑆𝑡𝑟𝑜𝑘𝑒𝐸6 = 1 64 × 300𝑚𝑚 = 4,6875𝑚𝑚 (for 10V applied) Meaning 0,46875 mm for 1V Meaning 0,0046875 mm for 0,01V C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 65/224 SMi21 11.5.3. "Clamp" Application Program Input connections Output connections Figure 48 The "Clamp" application program invokes the C101 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. 11.5.3.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:       IN1: If 0 → Stop, if 1 → Run IN2: If 0 → motor running in reverse (CCW), if 1 → motor running forward (CW) IN3: Not used. IN4: If 0 → no action, if 1 → Quick start by short-circuiting the coils. This action takes priority over the other commands. IN5: 0-10 V control. Sets the motor torque ramp. 20,000 mNm/sec for 0 V (maximum ramp) and 100 mNm/sec for 10 V. IN6: 0-10 V control. Sets the torque setpoint. 0V for 0 mNm and 10V for the maximum motor torque defined by the user (value in the grayed-out box). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 66/224 SMi21 Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1: Provides information on the motor speed value in PWM. Cyclical ratio = 0% → speed = 0 rpm Cyclical ratio = 100% → speed = 4000 rpm.  OUT2: Provides information on the real torque value in PWM. Cyclical ratio = 0% → torque = 0 mNm Cyclical ratio = 100% → torque = maximum torque.   OUT3: If 0 → motor running, OUT4: If 0 → error detected, 11.5.3.2. if 1 → motor stopped. if 1 → no error. Application Settings  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  The maximum motor torque corresponding to a voltage of 10 V is calculated as follows: 𝐶𝑜𝑛𝑠𝑖𝑔𝑛𝑒 𝐶𝑜𝑢𝑝𝑙𝑒 𝑀𝑜𝑡𝑒𝑢𝑟10𝑉 [𝑚𝑁𝑚] = 𝐹𝑜𝑟𝑐𝑒 𝑀𝑎𝑥𝑖 𝑆𝑒𝑟𝑟𝑎𝑔𝑒 [𝑁] 𝑅𝑎𝑝𝑝𝑜𝑟𝑡𝑃𝑖𝑛𝑐𝑒/𝑀𝑜𝑡𝑒𝑢𝑟 [𝑁/𝑚𝑁𝑚] The calculated value is given for information in the grayed-out box. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 67/224 SMi21 11.6. « Dosing » group 11.6.1. Application program « Peristaltic pump » Input connections Output connections The "Peristaltic pump" application program uses a preset V201 expert program. The user can switch to this expert mode at any time to access all the settings by clicking the "Expert Mode" button. The values preset in application mode will be loaded directly in expert mode. It is then impossible to return to this application program. The user can press the "STOP" button at any time to stop the application quickly. To restart the motor, the program needs to be reloaded. Once the settings are complete, press the "Load Program" button to configure the motor. 11.6.1.1. Inputs/Outputs Configuration Refer to the "I/O Connection" section. Inputs:  IN1 : ON/OFF 0 → Stop 1 → ON 0 → Dosing mode 1 → Flow mode (speed)  IN2 : Mode  IN3 : Direction / Go  In flow mode : 0 → Motor turns CCW 1 → Motor turns CW  In Dosing mode: 0 → No new dosing 1→ launches a new dose Note : When Dosing mode is selected, the IN3 signal has to be available during more than 15ms before to be taken in count.  IN4 + IN 5 : Coding  IN6 : Codes speed range or dose values depending on selected mode. Flow / Dose 0/10V analog input.  In Flow mode : Adjusts the flow value depending on the flow range selected (IN4 and I N5 coding). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 68/224 SMi21  In Dosing mode: Adjusts D4, the dose to deliver (IN4=IN5=1) Outputs: Don't forget to fit the pull-down resistors on each of the outputs.  OUT1 : Mode 0 : Dosing mode 1 : Flow mode  OUT2 : Direction of rotation 0 : CCW 1 : CW  OUT3 : Target  In Dosing mode :  In Flow mode:  0 → Dose not completely delivered, 0 → Motor is running 1→ Dose completed 1→ Motor doesn’t move OUT4 : Error 0 → No error detected 1 → Error detected 11.6.1.2. Application configuration  The user can give a 4-character name in "Project name" which is stored in the motor and appears in the "Motor Information" window.  If it has been saved on the PC by the user, this name is used by default. For more details, see the "Saving Parameters" paragraph.  « Dose », « Time » and « ratio » parameters allow to calculate the motor parameters for each dose (IN4 + IN5) the position to move, speed to deliver the dose. Calculation is as following: 𝑃𝑜𝑠𝑖𝑡𝑖𝑜𝑛 𝑠𝑒𝑡𝑡𝑖𝑛𝑔 [𝑃𝑢𝑙𝑠𝑒𝑠] = 𝑆𝑝𝑒𝑒𝑑 𝑠𝑒𝑡𝑡𝑖𝑛𝑔 [𝑅𝑃𝑀] = 𝐷𝑜𝑠𝑒 [𝑚𝑙] × 4096 × 𝑅𝑎𝑡𝑖𝑜 𝐹𝑙𝑜𝑤 [𝑚. 𝑡𝑟 −1 ] 𝐷𝑜𝑠𝑒 [𝑚𝑙] 60 × × 𝑅𝑎𝑡𝑖𝑜 −1 𝐹𝑙𝑜𝑤 [𝑚. 𝑡𝑟 ] 𝑇𝑖𝑚𝑒 [𝑠𝑒𝑐] For information, for each dose, the calculated speed is in grey boxes.  For this program, speed ranges are fixed. You could modify them in going in “Expert mode”. IN 4 0 1 0 1 C.MO.SAV.00006.FR_V5 January 12th, 2016 IN 5 0 0 1 1 Min. motor speed (rpm) 0 0 900 1800 Max. motor speed (rpm) 3000 1000 2000 3000 Page 69/224 SMi21 12. EXPERT PROGRAMS 12.1. Speed Programs 12.1.1. Types of Inputs in V100 Programs The table below defines the function associated with each of the inputs in the 4 V100 programs (the color associated with the input number corresponds to that of the I/O bundle): Inputs V101 V102 In1 ON/OFF ON/OFF In2 Direction Direction In3 Holding Holding In4 Fast stop Fast stop In5 Speed ramp Nominal torque In6 Speed Speed Key: Programs V103 V104 000 : "In6" setpoint speed 001 : Priority speed 1 010 : Priority speed 2 100 : Priority speed 3 00 : Fast stop 10 : CCW 01 : CW 11 : Stop, disable error Speed (if In1 = In2 = In3 = 0) 8 combinations: Coding 8 preprogrammed speeds 00 : Fast stop 10 : CCW 01 : CW 11 : Stop, disable error Nominal torque Digital type input Analog or PWM type input 12.1.2. Types of Inputs in V200 Programs The table below defines the function associated with each of the inputs in the 2 V200 programs (the color associated with the input number corresponds to that of the I/O bundle): Inputs V201 Speed Mode V201 Position Mode V202 E1 ON / OFF ON / OFF ON / OFF E2 Mode Mode Direction E3 Direction E4 E5 E6 00 = Speed Range 1 10 = Speed Range 2 01 = Speed Range 3 11 = Speed Range 4 Validation de Consigne 00 = Position 1 10 = Position 2 01 = Position 3 11 = Position 4 Analog Speed Setpoint Analog Position Setpoint Key: C.MO.SAV.00006.FR_V5 January 12th, 2016 Reverse Sensor Speed Setpoint Position Setpoint Digital type input Page 70/224 SMi21 Analog or PWM type input 12.1.3. Types of Outputs in V100 Programs For all expert speed programs, 4 configurable output configurations are available (the color associated with the output number corresponds to that of the I/O bundle): Type 1 Out1 Hall pulse pulse PWM Digital Digital Type 2 Real speed Real torque Motor running Error PWM PWM Digital Digital Type 3 Real speed Direction of rotation Motor running Error Frequency Digital Digital Digital Type 4 Out2 Real torque Real speed (centered on 50%) Real torque (centered on 50%) PWM PWM Key: Out3 Direction of rotation Out4 Error 00 : error detected 01 : motor running 10 : motor stopped in holding mode 11 : motor stopped and freewheeling Digital combinations Digital type output PWM/Pulse/Frequency type output 12.1.4. Type of outputs in V200 programs For V200 programs, configurable output configurations is as following (the color associated with the output number corresponds to that of the I/O bundle): Speed Mode V201 Program Position Mode V202 Program key : OUT1 Type mode OUT2 Direction OUT3 Motor runs OUT4 Error Digital Digital Digital Digital Type mode Direction Target reached Error Digital Digital Digital Digital Target reached Direction Motor runs Error Digital Digital Digital Digital Digital type output 12.1.5. Description of the Various V100 and V200 Tabs For the description of tabs, expert program V101 is used as an example (for detailed information about each speed expert program, see the "Expert Program V101" to "Expert Program V104" sections in this document). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 71/224 SMi21 12.1.5.1. Home Page This page is common to all the expert and application programs, whether in speed, position or torque mode. It can be used to choose between the various types of application and expert programs. In our example, we have chosen the "Speed V100" category in the "Expert Programs" group, so the icons for the various V100 expert programs appear in the bottom right-hand corner of the window, and you then need to click on the one corresponding to the "V101" expert program: Concise description of the V101 expert program Expert program category selection: V100 Expert program selection: V101 Figure 49 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 72/224 SMi21 12.1.5.2. "Description" Tab This is an information tab containing a concise description of the various speed profiles that are created using this expert mode: Option to name the project I/O Summary description of the profiles that can be created using this expert mode: speed control, acceleration ramps, etc. Figure 50 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 73/224 SMi21 12.1.5.3. "Inputs" Tab This tab is used to configure the various inputs in this expert mode (digital input polarity, value, control type, maximum and minimum control limit, etc.): Figure 51 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 74/224 SMi21 12.1.5.4. "Outputs" Tab This tab is used to select and configure the various outputs in this expert mode (speed type 1 to type 4): Output 1 type parameter settings Output 3 type parameter settings Output 2 type parameter settings Output 4 type parameter settings Figure 52 12.1.5.5. "Tuning" Tab This tab is used to represent some parameters (speed, torque, etc.) in graphic form and modify the speed control loop coefficients. It is common to all the speed expert programs. This tab is used to view the selected parameters in graphic form. This zone is used to: - Select the parameters to be viewed in graphic form - Set the speed correction factors - Set the display time - Export the data (.csv) Figure 53 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 75/224 SMi21 12.1.5.6. "Limits" Tab This tab is used to configure the various motor operating limits: nominal and maximum torque (torque peak authorization) and the power supply overvoltage threshold. Summary description of torque control. Setting the parameters associated with torque control. Overvoltage threshold settings: if this value is exceeded, an error will be generated. 12.1.5.7. "Errors" Tab This tab provides information about the type of error encountered (based on the error code) and the action to be taken by the motor following this error. Action for the over torque error can be configured. Setting the action to be taken when an overtorque error is encountered If an error is detected that could jeopardize motor safety, the motor is automatically turned off and left freewheeling. Procedure for restarting the motor following detection of an error: Eliminate the cause of the fault. Switch to stop mode and then back to run mode. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 76/224 SMi21 12.1.6. 12.1.6.1. Expert Program V101 Description Expert program V101 is used to: - Create speed profiles with analog or PWM control. - Set the acceleration/deceleration phases with analog or PWM control. - Set the nominal and maximum torque parameters for the application safety via the HMI. 12.1.6.2. "Inputs" Tab Parameters Digital input 1: Used to set the "On/Off" input polarity. Figure 54 Digital input 2: Used to set the "Direction of rotation" input polarity. Figure 55 Digital input 3: Used to set the "Holding at stop" input polarity and set the Holding Torque value. Figure 56 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 77/224 SMi21 Digital input 4: Used to set the "Fast stop" input polarity. This input is used to stop the motor as quickly as possible, ignoring the setpoints applied to the other inputs. Figure 57 Setpoint input 5: Used to select the control type for the acceleration/deceleration setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 58 Setpoint input 6: Used to select the control type for the speed setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 59 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 78/224 SMi21 12.1.6.3. Type 1 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 60 Setting the parameters of PWM output 2 "Real Torque": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 61 State of digital output 3 "Real direction": Used to find out the motor direction of rotation. Figure 62 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 63 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 79/224 SMi21 12.1.6.4. Type 2 "Outputs" Tab Parameters Setting the parameters of PWM output 1 "Real Speed": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 100% → Real speed = 0 rpm. → Real speed = maximum speed setpoint defined in In6. Figure 64 Setting the parameters of PWM output 2 "Real Torque": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 65 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 66 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 67 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 80/224 SMi21 12.1.6.5. Type 3 "Outputs" Tab Parameters Setting the parameters of frequency output 1 "Real speed": The parameters can be set for the signal frequency of this output for which the motor runs at 1000 RPM (200, 500 or 1000 Hz). Figure 68 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 69 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 70 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 71 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 81/224 SMi21 12.1.6.6. Type 4 "Outputs" Tab Parameters Setting the parameters of PWM output 1: "Real speed (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Motor running forward (CW) at maximum speed setpoint defined in In6. → Real speed = 0 rpm. → Motor running in reverse (CCW) at maximum speed setpoint defined in In6. Figure 72 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 73 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 74 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 82/224 SMi21 12.1.6.7. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2 or 3 parameters. The system speed response (measurement vs setpoint) can therefore be compared while displaying changes in the current. Figure 75 Set the PID controller factors in the speed control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 76 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 77 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 78 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 83/224 SMi21 Example: With a speed setpoint on input 6 at 3200 RPM and an acceleration setpoint on input 5 at 800 RPM/s, this gives us the following graphic representation (recording time of 10 seconds): Real speed Speed setpoint Figure 79 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 80 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 84/224 SMi21 12.1.6.8. "Limitations" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 81 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 85/224 SMi21 Figure 82 12.1.6.9. "Errors" Tab Parameters Setting the parameters for the action to be taken when an overtorque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX". Figure 83 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 84 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital input 1 "On/Off". Switch back to run mode: enable digital input 1 "On/Off". C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 86/224 SMi21 12.1.7. 12.1.7.1. Expert Program V102 Description Expert program V102 is used to: - Create speed profiles with analog or PWM control. - Set torque limiting with analog or PWM control. 12.1.7.2. "Inputs" Tab Parameters Digital input 1: Used to set the "On/Off" input polarity. Figure 85 Digital input 2: Used to set the "Direction of rotation" input polarity. Figure 86 Digital input 3: Used to set the "Holding at stop" input polarity and set the Holding Torque value. Figure 87 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 87/224 SMi21 Digital input 4: Used to set the "Fast stop" input polarity. This input is used to stop the motor as quickly as possible, ignoring the setpoints applied to the other inputs. Figure 88 Setpoint input 5: Used to select the control type for the torque limiting setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 89 Setpoint input 6: Used to select the control type for the speed setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 90 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 88/224 SMi21 12.1.7.3. Type 1 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 91 Setting the parameters of PWM output 2 "Real Torque": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 92 State of digital output 3 "Real direction": Used to find out the motor direction of rotation. Figure 93 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 94 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 89/224 SMi21 12.1.7.4. Type 2 "Outputs" Tab Parameters Setting the parameters of PWM output 1 "Real Speed": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 100% → Real speed = 0 rpm. → Real speed = maximum speed setpoint defined in In6. Figure 95 Setting the parameters of PWM output 2 "Real Torque": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 96 State of digital output 3 "Motor Running": Used to find out whether the motor is stopped or running. Figure 97 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 98 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 90/224 SMi21 12.1.7.5. Type 3 "Outputs" Tab Parameters Setting the parameters of frequency output 1 "Real speed": The parameters can be set for the signal frequency of this output for which the motor runs at 1000 RPM (200, 500 or 1000 Hz). Figure 99 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 100 State of digital output 3 "Motor Running": Used to find out whether the motor is stopped or running. Figure 101 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 102 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 91/224 SMi21 12.1.7.6. Type 4 "Outputs" Tab Parameters Setting the parameters of PWM output 1: "Real speed (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Motor running forward (CW) at maximum speed setpoint defined in In6. → Real speed = 0 rpm. → Motor running in reverse (CCW) at maximum speed setpoint defined in In6. Figure 103 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 104 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 105 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 92/224 SMi21 12.1.7.7. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2 or 3 parameters. The system speed response (measurement vs setpoint) can therefore be compared while displaying changes in the current. Figure 106 Set the PID controller factors in the speed control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 107 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 108 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 109 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 93/224 SMi21 Example: With a speed setpoint on input 6 at 2000 RPM and a torque limit on input 5 at 1000 mN.m, this gives us the following graphic representation (recording time of 5 seconds): Real speed Speed setpoint Figure 110 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 111 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 94/224 SMi21 12.1.7.8. "Limits" Tab Parameters WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). Figure 112 12.1.7.9. "Errors" Tab Parameters For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 113 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital input 1 "On/Off". Switch back to run mode: enable digital input 1 "On/Off". C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 95/224 SMi21 12.1.8. 12.1.8.1. Expert Program V103 Description Expert program V103 is used to: - Create speed profiles with analog or PWM control. - Force speed control to one of the 3 preprogrammed speeds. - Set the acceleration/deceleration phase parameters via the HMI. 12.1.8.2. "Inputs" Tab Parameters Combinations of digital inputs 1 to 3: Used to choose the type of speed setpoint applied at the motor input: - If no input is active, the setpoint will be that applied to input 6. - If one of these 3 inputs is active, the setpoint will be the priority speed associated with this input. N.B.: If more than 1 input In1 to In3 is active, the setpoint taken into account will be that for input 6. Figure 114 Combinations of digital inputs 4 and 5: Used to choose the motion to be performed from the 4 actions indicated below. Figure 115 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 96/224 SMi21 Setpoint input 6: Used to select the control type for the speed setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 116 Setting the acceleration and braking ramps: These values are fixed via the HMI and cannot be changed by inputs while the motor is running. By default, the rates are fixed at 40,000 RPM/sec. Figure 117 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 97/224 SMi21 12.1.8.3. Type 1 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 118 Setting the parameters of PWM output 2 "Real torque": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 119 State of digital output 3 "Real direction": Used to find out the motor direction of rotation. Figure 120 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 121 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 98/224 SMi21 12.1.8.4. Type 2 "Outputs" Tab Parameters Setting the parameters of PWM output 1 "Real speed": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 100% → Real speed = 0 rpm. → Real speed = maximum speed setpoint defined in In6. Figure 122 Setting the parameters of PWM output 2 "Real torque": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 123 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 124 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 125 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 99/224 SMi21 12.1.8.5. Type 3 "Outputs" Tab Parameters Setting the parameters of frequency output 1 "Real speed": The parameters can be set for the signal frequency of this output for which the motor runs at 1000 RPM (200, 500 or 1000 Hz). Figure 126 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 127 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 128 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 129 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 100/224 SMi21 12.1.8.6. Type 4 "Outputs" Tab Parameters Setting the parameters of PWM output 1: "Real speed (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Motor running forward (CW) at maximum speed setpoint defined in In6. → Real speed = 0 rpm. → Motor running in reverse (CCW) at maximum speed setpoint defined in In6. Figure 130 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 131 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 132 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 101/224 SMi21 12.1.8.7. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2 or 3 parameters. The system speed response (measurement vs setpoint) can therefore be compared while displaying changes in the current. Figure 133 Set the PID controller factors in the speed control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 134 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 135 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 136 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 102/224 SMi21 Example: With a priority speed on input 1 at 1000 RPM, a priority speed on input 2 at 2000 RPM and a priority speed on input 3 at 3000 RPM, this gives us the following graphic representation (recording time of 10 seconds): Real speed Speed setpoint Figure 137 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 138 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 103/224 SMi21 12.1.8.8. "Limits" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 139 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 104/224 SMi21 12.1.8.9. "Errors" Tab Parameters Setting the parameters for the action to be taken when an overtorque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX". Figure 140 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 141 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: enable digital inputs 4 and 5. Switch back to run mode: disable either digital input 4 or digital input 5. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 105/224 SMi21 12.1.9. 12.1.9.1. Expert Program V104 Description Expert program V104 is used to: - Create speed profiles with a choice of 8 preconfigured values. - Set torque limiting with analog or PWM control. - Set the acceleration/deceleration phase parameters via the HMI. 12.1.9.2. "Inputs" Tab Parameters Combinations of digital inputs 1 to 3: Used to select the type of speed setpoint applied at the motor input: 8 possible combinations: Figure 142 Combinations of digital inputs 4 and 5: Used to select the motion to be performed from the 4 actions indicated below. Figure 143 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 106/224 SMi21 Setpoint input 6: Used to select the control type for the torque limiting setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 144 Setting the acceleration and braking ramps: These values are fixed via the HMI and cannot be changed by inputs while the motor is running. By default, the rates are fixed at 40,000 RPM/sec. Figure 145 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 107/224 SMi21 12.1.9.3. Type 1 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 146 Setting the parameters of PWM output 2 "Real torque": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 147 State of digital output 3 "Real direction": Used to find out the motor direction of rotation. Figure 148 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 149 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 108/224 SMi21 12.1.9.4. Type 2 "Outputs" Tab Parameters Setting the parameters of PWM output 1 "Real speed": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 100% → Real speed = 0 rpm. → Real speed = 4000 rpm. Figure 150 Setting the parameters of PWM output 2 "Real torque": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 151 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 152 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 153 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 109/224 SMi21 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 110/224 SMi21 12.1.9.5. Type 3 "Outputs" Tab Parameters Setting the parameters of frequency output 1 "Real speed": The parameters can be set for the signal frequency of this output for which the motor runs at 1000 RPM (200, 500 or 1000 Hz). Figure 154 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 155 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 156 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 157 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 111/224 SMi21 12.1.9.6. Type 4 "Outputs" Tab Parameters Setting the parameters of PWM output 1: "Real speed (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Motor running forward (CW) at speed of 4000 rpm. → Real speed = 0 rpm. → Motor running in reverse (CCW) at speed of 4000 rpm. Figure 158 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 159 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 160 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 112/224 SMi21 12.1.9.7. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2 or 3 parameters. The system speed response (measurement vs setpoint) can therefore be compared while displaying changes in the current. Figure 161 Set the PID controller factors in the speed control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 162 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 163 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 164 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 113/224 SMi21 Example: With 8 preprogrammed speeds, this gives us the following graphic representation: (recording time of 30 seconds). Speed 1 is at 0 RPM. Real speed Speed setpoint Figure 165 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 166 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 114/224 SMi21 12.1.9.8. "Limits" Tab Parameters WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). Figure 167 12.1.9.9. "Errors" Tab Parameters For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 168 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: enable digital inputs 4 and 5. Switch back to run mode: disable either digital input 4 or digital input 5. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 115/224 SMi21 12.1.10. Expert program V201 12.1.10.1. Description V201 expert program allows to: - Set a speed using an analog input 0/10V or 0/5V or PWM. The speed regulation is based on the “moving target” principle which allows to reach very low speed (down to 1 rpm). - Or to set a relative position using the same analog input (0/10V or 0/5V or PWM). - Switch between speed mode and position mode. 12.1.10.2. “Inputs" Tab Parameters Digital input 1: « On/Off » This input is to start or stop the motor. The input polarity is adjustable. Figure 169 Digital input 2: « Mode » This input is to select the speed or position mode. The input polarity is adjustable. Figure 170 Digital input 3 (in speed mode): « Direction » This input is to select motor direction. The input polarity is adjustable. Figure 171 Digital input 3 (in position mode): « Go » This input gives the start to go to a new position. This input is taken in count only after that the last positioning was completed. The “Pulse time min.” works as a filter. The « Go » signal could not be taken in count if its duration is lower than the set value. Figure 172 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 116/224 SMi21 Digital inputs 4 and 5 (in speed mode) : « speed coding » They allow to select the speed range for the IN6 input. For each range, the min and max speed, the acceleration and deceleration can be set. Figure 173 Digital inputs 4 and 5 (in position mode) : “Position coding” They allow to select the relative position to reach (the step value to do). For each of the positions, the number of pulses (4096 pulses  1 motor turn), the max speed, the acceleration and deceleration can be set. The last position is adjustable by IN6 analog input (IN4 = IN5 =0). Figure 174 Analog input 6 (In speed mode) : « Speed » This input adjusts motor speed using an analog 0/10V or 0/5V or PWM signal. Speed range is given per IN4 + IN5 coding. The setting parameter is: o Analog signal type. Figure 175 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 117/224 SMi21 Analog input 6 (In position mode) : « Step » This input adjusts the value of the step to do (relative position) when IN4=IN5=0, using an analog 0/10V or 0/5V or PWM signal. The setting parameters are o o o Minimum of pulses (4096 pulses  1 motor turn) Maximum of pulses (4096 pulses  1 motor turn) Analog signal type. Figure 176 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 118/224 SMi21 12.1.10.3. "Outputs" Tab Parameters State of digital output 1: "Mode": Gives mode used. Figure 177 State of digital output 2: "Direction" Used to find out the motor direction of rotation. Figure 178 State of digital output 3 (speed mode): "Motor running": Used to find out whether the motor is stopped or running. Figure 179 State of digital output 3 (position mode): "Target": Used to find out if the position is reached. Figure 180 State of digital output 4: "Error": Used to find out whether an error has been detected. Figure 181 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 119/224 SMi21 12.1.10.4. Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 182 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 183 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 184 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 185 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 120/224 SMi21 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 121/224 SMi21 Example: With a speed setting at 2,000 rpm on IN6 and 5seconds measurement time, the following curves are obtained. Figure 186 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 187 12.1.10.5. "Limits" Tab Parameters WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 122/224 SMi21 Setting the overvoltage detection threshold parameter: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). Figure 188 12.1.10.6. “Errors" Tab Parameters For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor stops, and no holding torque is applied (freewheeling). Figure 189 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 123/224 SMi21 12.1.11. Expert program V202 12.1.11.1. Description The expert program V202 allows to: - To adjust a speed with an analog signal input 0/10V or 0/5V or PWM. The regulation is based on moving target principle and allows to reach very low speed values (down to 1rpm). - To adjust a relative position using an analog input 0/10V or 0/5V or PWM. - To switch from the speed mode (moving target) to the position mode (fix target) and reciprocally. 12.1.11.2. “Inputs" Tab Parameters Digital input 1: « On/OFF » This input is to start or stop the motor. The input polarity is adjustable. Figure 190 Digital input 2: « Direction » This input reverses motor direction. This input doesn’t inhibit IN4 (sensor input). The input polarity is adjustable. Figure 191 Digital input 3: « Reverse ». This input reverses motor direction and inhibits IN4 (sensor input). The input polarity is adjustable. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 124/224 SMi21 Figure 192 Digital input 4 : « Sensor » This input is to switch from the moving target position mode (speed mode) to the fix target position mode and reciprocally. The input polarity is adjustable. The parameter « minimum pulse duration » allows to filter IN4 “sensor” input signal. The signal has to exceed this time before to be taken in count. Option PLC: o If “Via PLC” is selected: motor switches to speed mode when “sensor” input IN4 is deactivated. o If “Via PLC” is not selected: Motor memorizes the “sensor” input IN4 activations. To return to speed mode, an OFF/ON action on IN1 is required. Figure 193² Analog input 5 : « Speed» This input adjusts motor speed using an analog signal 0/10V or 0/5V or PWM. The setting parameters are o o o o Speed range Acceleration (value for IN5 and IN6) Deceleration Analog signal type. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 125/224 SMi21 Figure 194 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 126/224 SMi21 Analog input 6 : « Position » This input adjusts the position set point using an analog signal 0/10V or 0/5V or PWM. When IN4 is activated, motor memorizes its position and fixes it as the zero position reference. The setting parameters are o o o o o Position range (max:0 to 2,000,000,000 pulses = 0 to 488,000 motor turns) Deceleration Analog signal type. Filter time (IN6 signal has to be constant during a time exceeding this value before to be taken in count) Memorization (not available when IN6 is a PWM signal) Take in count the IN6 signal changes when IN5 signal is lower than the set value.  If value is 10V, IN6 changes are taken in count all the time  If value is 0.2V, IN6 changes are taken in count only when IN5 setting is below this value. It can be used when analog signals are perturbed due to very long cabling and ground issues. Figure 195 12.1.11.3. "Outputs" Tab Parameters State of digital output 1 "Target Position Reached": Used to find out whether the position set point has been reached. Figure 196 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 197 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 127/224 SMi21 Figure 198 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 199 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 128/224 SMi21 12.1.11.4. “Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 200 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 201 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 202 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 203 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 129/224 SMi21 Example: With a speed setting at 2,000 rpm on IN5 and 5 seconds measurement time, the following curves are obtained. Figure 204 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 205 12.1.11.5. "Limits" Tab Parameters WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 130/224 SMi21 Setting the overvoltage detection threshold parameter: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). Figure 206 12.1.11.6. “Errors" Tab Parameters For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor stops, and no holding torque is applied (freewheeling). Figure 207 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital input 1 "On/Off". Switch back to run mode: enable digital input 1 "On/Off". C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 131/224 SMi21 12.2. Position Programs 12.2.1. Types of Inputs in P100 Programs The table below defines the function associated with each of the inputs in the 12 P100 programs (the color associated with the input number corresponds to that of the I/O bundle): Inputs P101 P102 P103 In1 Position 1 Validation Validation In2 Position 2 Programs P104 P105 P106 Validation Validation Validation 1 to 8 positions 1 to 6 positions + Homing + ON/OFF 1 to 6 positions + Homing + ON/OFF 1 to 6 positions + Homing + ON/OFF 1 to 6 proportional positions + Homing + ON/OFF In3 Position 3 In4 Position 4 In5 Homing Homing Speed ramps Switch 1: limit stop Switch 1: limit stop Switch 1: limit stop In6 ON/OFF ON/OFF Speed Speed Fast stop Switch 2: limit stop Inputs P107 P108 P109 P110 Validation Validation Validation In1 P111 P112 1 to 30 positions + Homing + ON/OFF 1 to 30 proportional positions + Homing + ON/OFF Switch 1: limit stop Switch 1: limit stop In2 In3 1 to 16 positions In4 In5 Homing In6 ON/OFF Key: 1 to 14 positions + Homing + ON/OFF 1 to 14 positions + Homing + ON/OFF 1 to 14 positions + Homing + ON/OFF Speed Switch 1: limit stop Fast stop Digital type input Analog or PWM type input Forthcoming programs C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 132/224 SMi21 12.2.2. Types of Inputs in P200 Programs The table below defines the function associated with each of the inputs in the 5 P200 programs (the color associated with the input number corresponds to that of the I/O bundle): Inputs E1 E2 Programs P202 P201 00 : Stop, erase error 10 : Homing 01 : Maintain actual position 11 : Live positioning P203 00 : Stop, erase error 10 : Homing 01 : Memorize new position setting 11 : Go to new memorized position ON / OFF Homing E3 Switch 1 : Limit stop Switch 1 : Limit stop Switch 1 : Limit stop E4 Speed profile selection Speed profile selection Validation E5 Position setting Coarse tuning Position setting Coarse tuning Analog max.speed setting E6 Position setting Thin tuning Position setting Thin tuning Analog position setting (1024) Programs P205 Inputs P204 E1 ON / OFF E2 Homing E3 Switch 1 : Limit stop Switch 1 : Limit stop Switch 1 : Limit stop E4 Switch 2 : Limit stop Switch 2 : Limit stop Switch 2 : Limit stop E5 Validation Analog max.speed setting Analog max.speed setting E6 Analog position setting (1024) Analog position setting (1024) Analog position setting (1024) Key : 00 : Stop, erase error 10 : Homing 01 : Memorize new position setting 11 : Go to new memorized position P206 00 : Stop, erase error 10 : Homing 01 : Maintain actual position 11 : Live positioning Digital type input Analog or PWM type input Forthcoming programs C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 133/224 SMi21 12.2.3. Types of Outputs in P100 and P200 Programs For all expert position programs, 5 configurable output configurations are available (the color associated with the output number corresponds to that of the I/O bundle): Type 5 Type 6 Type 7 Type 8 Out1 On stand-by, target reached (if 1) Out2 Homing phase complete (if 0) Out3 Motor running (if 1) Out4 Error (if 1) Digital Digital Digital Digital On stand-by, target reached (if 1) Homing phase complete (if 1) Motor running (if 0) Error (if 0) Digital Digital Digital Digital On stand-by, target reached (if 1) Real torque (centered on 50%) Digital PWM On stand-by, target reached (if 1) Real torque (centered on 50%) Digital PWM Hall pulse Direction of rotation pulse Digital Type 9 Key: 00 : error detected 01 : homing not performed OR not completed 10 : motor stopped AND homing completed 11 : motor running (positioning) Digital combinations 00 : error detected OR motor in stop mode AND homing not performed 01 : motor running (positioning) 10 : motor stopped AND homing completed 11 : not used Digital combinations 00 : error detected OR motor in stop mode 01 : not used 10 : motor stopped AND target reached 11 : motor running (positioning) Digital combinations Digital type output PWM/Pulse/Frequency type output C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 134/224 SMi21 12.2.4. Description of the Different Types of Homing The homing sequence is an initialization phase that helps the motor estimate the application total stroke by searching for mechanical stops. These stops can be detected in one of 2 ways: - With 1 limit switch by retrieving information from one of the inputs. - By detecting overtorque when the motor is at a mechanical stop. N.B.: The default motor direction of rotation is forward (CW). 12.2.4.1. Homing Phase Without a Switch a) Start from current position: Selection of homing type 0 No parameter accessible for this type of homing Figure 208 When the homing sequence starts, the current position is used as a reference (position 0). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 135/224 SMi21 b) 1 mechanical stop: Selection of homing type "mechanical zero" Accessible parameters "software zero" Figure 209 This homing phase is used to search for the system mechanical stop as follows: - Depending on the "END1" stop position (on the right or left), the user selects the appropriate "Direction of rotation" and sets a "Homing Speed". - When the application torque increases to more than the "Homing Torque", the "END1" mechanical stop is detected, the motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the "END1" mechanical stop each time it returns to the reference position, "Offset 1" can be set (in encoder pulses). - This new position should be considered as the reference position. The motor positions itself at "software zero": the homing phase is complete. - As a safety measure, if the homing phase is not complete after the "Max Homing Time", the motor detects a "Homing" type error and stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 136/224 SMi21 c) 2 mechanical stops: Selection of homing type "mechanical end" "mechanical zero" "total travel" "software zero" Accessible parameters Figure 210 This homing phase is used to search for the 2 system mechanical stops as follows: - Depending on the 1st "END1" stop position (on the right or left), the user selects the appropriate "Direction of rotation" and sets a "Homing Speed". - When the application torque increases to more than the "Homing Torque", the "END1" mechanical stop is detected, the motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the "END1" mechanical stop each time it returns to the reference position, "Offset 1" can be set (in encoder pulses) which gives us the difference in position between the "mechanical zero" and the "software zero". - The motor then travels in the opposite direction to find the 2nd mechanical stop "END2". The "END2" mechanical stop is detected in a similar way. The motor is in the "mechanical end" position. - To avoid the motor coming into contact with the "END2" mechanical stop each time it returns to the reference position, "Offset 2 " can be set (in encoder pulses) which gives us the difference in position between the "mechanical end" and the "total stroke". - After detecting both mechanical stops, the motor positions itself at (END2 – offset 2): the homing phase is complete. - As a safety measure, if the homing phase is not complete after the "Max Homing Time", the motor detects a "Homing" type error and stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 137/224 SMi21 12.2.4.2. Homing Phase With 1 Switch a) 1 switch: Selection of homing type "mechanical zero" "software zero" Accessible parameters Figure 211 This homing phase is used to search for the system "switch" type stop as follows: - First configure the switch polarity: « High state active " or "Low state active ". - Depending on the switch position (on the right or left), the user selects the appropriate "Direction of rotation" and sets a " Homing Speed". - When the switch changes state, the "Switch 1" stop is detected. The motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the switch each time it returns to the reference position, " Offset 1" can be set (in encoder pulses). - This new position should be considered as the reference position. The motor positions itself at "software zero": the homing phase is complete. - As a safety measure, if the homing phase is not complete after the "Max Homing Time", the motor detects a "Homing" type error and stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 138/224 SMi21 b) 1 switch then 1 end: with the zero defined by the switch Selection of homing type "mechanical end" "mechanical zero" "total travel" "software zero" Accessible parameters Figure 212 This homing phase is used to search initially for the system "switch" type stop, then for the system mechanical stop as follows: - First configure the switch polarity: « High state active " or "Low state active ". - Depending on the switch position (on the right or left), the user selects the appropriate "Direction of rotation" and sets a " Homing Speed". - When the switch changes state, the first stop "Switch 1" is detected. The motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the "Switch 1 " stop each time it returns to the reference position, " Offset 1" can be set (in encoder pulses) which gives us the difference in position between the "mechanical zero" and the "software zero". - The motor then travels in the opposite direction to find the 2nd mechanical stop "END2". - When the application torque increases to more than the "Homing Torque", the "END2" mechanical stop is detected, the motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the "END2" mechanical stop each time it returns to the reference position, "Offset 2 " can be set (in encoder pulses) which gives us the difference in position between the "mechanical end" and the "total stroke". - After detecting both stops, the motor positions itself at (END2 – offset 2): the homing phase is complete. - As a safety measure, if the homing phase is not complete after the "Max Homing Time", the motor detects a "Homing" type error and stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 139/224 SMi21 c) 1 end then 1 switch: with the zero defined by the mechanical switch Selection of homing type "mechanical zero" "total travel" "mechanical end" "software zero" Accessible parameters Figure 213 This homing phase is used to search initially for the system mechanical stop, then for the system "switch" type stop as follows: - First configure the switch polarity: « High state active " or "Low state active ". - Depending on the "END1" stop position (on the right or left), the user selects the appropriate "Direction of rotation» and sets a "Homing Speed". - When the application torque increases to more than the "Homing Torque", the "END1" mechanical stop is detected, the motor is in the "mechanical zero" position. - To avoid the motor coming into contact with the "END1" mechanical stop each time it returns to the reference position, "Offset 1" can be set (in encoder pulses) which gives us the difference in position between the "mechanical zero" and the "software zero". - The motor then travels in the opposite direction to find the 2nd stop "Switch 2". - When the switch changes state, the 2nd stop "Switch 2" is detected, the motor is in the "mechanical end" position. - To avoid the motor coming into contact with the "Switch 2" stop each time it returns to the reference position, " Offset 2" can be set (in encoder pulses) which gives us the difference in position between the "mechanical end" and the "total stroke". - After detecting both stops, the motor positions itself at (Switch 2 – offset 2): the homing phase is complete. - As a safety measure, if the homing phase is not complete after the "Max Homing Time", the motor detects a "Homing" type error and stops. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 140/224 SMi21 12.2.5. Description of the P100 Various Tabs For the description of tabs, expert program P101 is used as an example (for detailed information about each position expert program, see the "Expert Program P101" to "Expert Program P111" sections in this document). 12.2.5.1. Home Page This page is common to all the expert and application programs, whether in speed, position or torque mode. It can be used to choose between the various types of application and expert programs. In our example, we have chosen the "Position P100" category in the "Expert Programs" group, so the icons for the various P100 expert programs appear in the bottom right-hand corner of the window, and you then need to click on the one corresponding to the "P101" expert program: Concise description of the P101 expert program Expert program category selection: P100 Expert program selection: P101 Figure 214 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 141/224 SMi21 12.2.5.2. "Description" Tab This is an information tab containing a concise description of the various position profiles that are created using this expert mode: Option to name the project I/O Summary description of the profiles that can be created using this expert mode: positioning with 4 predefined targets, acceleration ramps, etc. C.MO.SAV.00006.FR_V5 January 12th, 2016 Figure 215 Page 142/224 SMi21 12.2.5.3. "Homing" Tab This tab is used to select and configure the type of homing to be performed: offset(s), speed, homing torque, maximum duration of the homing phase, motor direction of rotation to search for the 1st stop. Selection of the type of homing to be performed: 0, 1 or 2 mechanical stops Parameters associated with Figure the selected 216 homing type. 12.2.5.4. Summary description of the selected homing phase "Inputs" Tab This tab is used to configure the various inputs in this expert mode (digital input polarity, setting the parameters for the 4 target positions: position, maximum speed, acceleration and deceleration rates). Figure 217 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 143/224 SMi21 12.2.5.5. "Outputs" Tab This tab is used to select and configure the various outputs in this expert mode (position type 5 to type 9): Output 5 type parameter settings Output 6 type parameter settings Output 7 type parameter settings Output 8 type parameter settings Output 9 type parameter settings Figure 218 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 144/224 SMI21 12.2.5.6. "Tuning" Tab This tab is used to represent some parameters (speed, position, torque, etc.) in graphic form and modify the position control loop coefficients. It is common to all the position expert programs. This tab is used to view the selected parameters in graphic form. This zone is used to: - Select the parameters to be viewed in graphic form - Set the position correction factors - Set the display time - Export the data (.csv) Figure 219 12.2.5.7. "Limits" Tab This tab is used to configure the various motor operating limits: nominal and maximum torque (torque peak authorization) and the power supply overvoltage threshold. Summary description of torque control. Setting the parameters associated with torque control. Overvoltage threshold settings: if this value is exceeded, an error will be generated. C.MO.SAV.00006.FR_V5 January 12th, 2016 Figure 220 Page 145/224 SMi21 12.2.5.8. "Errors" Tab This tab provides information about the type of error encountered (based on the error code) and the action to be taken by the motor following this error. Action for the over-torque error can be configured. Setting the action to be taken when an overtorque error is encountered. If an error is detected that could jeopardize motor safety, the motor is automatically turned off and left freewheeling. Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode and then back to run mode. Figure 221 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 146/224 SMi21 12.2.6. 12.2.6.1. Expert Program P101 Description Expert program P101 is used to: - Perform a homing phase to initialize the system with detection of the stroke ends. - Perform various positionings using 4 preset setpoint positions, each corresponding to one of the digital inputs "In1" to "In4". - Set the acceleration/deceleration phases and the maximum speed that must not be exceeded between each point via the HMI. 12.2.6.2. "Homing" Tab Parameters Set the difference in position (in pulses) between the mechanical stops and the application total stroke limits: stop 1 (END1) represents the stroke start, stop 2 (END2) represents the stroke end. Note: Where there is only one mechanical stop, the "Offset 2" parameter is not available. Figure 222 Set the search speed for stops during the homing phase. Figure 223 Set the homing torque that allows the mechanical stop to be found by detection of overtorque. Figure 224 Set the maximum permitted time for the homing phase. If this value is exceeded, an error will be generated. Time limited to 300 seconds. Figure 225 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 147/224 SMi21 Set the direction of rotation for the first stop search (END1). N.B.: By default, the motor runs forward (CW). Figure 226 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 148/224 SMi21 12.2.6.3. "Inputs" Tab Parameters Digital input 1: Used to set the "Position 1" input polarity. Figure 227 Digital input 2: Used to set the "Position 2" input polarity. Figure 228 Digital input 3: Used to set the "Position 3" input polarity. Figure 229 Digital input 4: Used to set the "Position 4" input polarity. Figure 230 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 149/224 SMi21 Set the 4 position setpoints and the speed profiles to be followed (acceleration ramp, speed step and deceleration ramp: trapezoidal profile): Figure 231 Digital input 5: Used to set the "Start Homing" input polarity. Figure 232 Digital input 6: Used to set the "On/Off" input polarity. Figure 233 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 150/224 SMi21 12.2.6.4. Type 5 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 234 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 235 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 236 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 237 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 151/224 SMi21 12.2.6.5. Type 6 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 238 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 239 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 240 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 241 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 152/224 SMi21 12.2.6.6. Type 7 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 242 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 243 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 244 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 153/224 SMi21 12.2.6.7. Type 8 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 245 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 246 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 247 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 154/224 SMi21 12.2.6.8. Type 9 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 248 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 249 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 250 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 155/224 SMi21 12.2.6.9. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 251 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 252 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 253 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 254 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 156/224 SMi21 Example: - Position 1: 2,000,000 points, acceleration ramp 400 rpm/sec, speed step 1000 rpm, deceleration ramp 100 rpm/sec. Position 2: 0 points, acceleration ramp 400 rpm/sec, speed step 1000 rpm, deceleration ramp 100 rpm/sec. This gives us the following graphic representation: Position setpoint Real speed Real position Figure 255 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 256 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 157/224 SMi21 12.2.6.10. "Limits" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 257 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameter: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 158/224 SMi21 12.2.6.11. "Errors" Tab Parameters Setting the parameters for the action to be taken when an overtorque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX". Figure 258 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor stops, and no holding torque is applied (freewheeling). Figure 259 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital input 6 "On/Off". Switch back to run mode: enable digital input 6 "On/Off". C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 159/224 SMi21 12.2.7. 12.2.7.1. Expert Program P111 Description Expert program P111 is used to: - Perform a homing phase to initialize the system with detection of the limit switches (switch or mechanical type). A single switch type contact is managed in this program. - Perform various positionings using 1 to 30 preset setpoint positions, each corresponding to a specific combination of digital inputs "In1" to "In5". - Set the acceleration/deceleration phases and the maximum speed that must not be exceeded between each point via the HMI. 12.2.7.2. "Homing" Tab Parameters Set the polarity of the switch wired on digital input "In6": Figure 260 Set the difference in position (in pulses) between the mechanical stops and the application total stroke limits: stop 1 (END1) represents the stroke start, stop 2 (END2) represents the stroke end. Note: Where there is only one mechanical stop, the "Offset 2" parameter is not available. Figure 261 Set the search speed for stops during the homing phase. Figure 262 Set the homing torque that allows the mechanical stop to be found by detection of over-torque. Figure 263 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 160/224 SMi21 Set the maximum permitted time for the homing phase. If this value is exceeded, an error will be generated. Time limited to 300 s. Figure 264 Set the direction of rotation for the first stop search. N.B.: By default, the motor runs forward (CW). Figure 265 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 161/224 SMi21 12.2.7.3. "Inputs" Tab Parameters Information concerning the polarity of the switch wired on digital input 6. This polarity is selected in the "Homing" tab (see above). Figure 266 Select the number of position setpoints to be preset (see table below). Figure 267 Figure 268 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 162/224 SMi21 12.2.7.4. Type 5 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 269 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 270 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 271 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 272 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 163/224 SMi21 12.2.7.5. Type 6 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 273 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 274 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 275 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 276 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 164/224 SMi21 12.2.7.6. Type 7 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 277 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 278 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 279 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 165/224 SMi21 12.2.7.7. Type 8 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 280 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 281 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 282 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 166/224 SMi21 12.2.7.8. Type 9 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 283 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 284 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 285 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 167/224 SMi21 12.2.7.9. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 286 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 287 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 288 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 289 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 168/224 SMi21 Example: - Position 1: 2,000,000 points, acceleration ramp 400 rpm/sec, speed step 1000 rpm, deceleration ramp 100 rpm/sec. Position 2: 0 points, acceleration ramp 400 rpm/sec, speed step 1000 rpm, deceleration ramp 100 rpm/sec. This gives us the following graphic representation: Position setpoint Real speed Real position Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 290 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 169/224 SMi21 12.2.7.10. "Limits" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 291 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 170/224 SMi21 12.2.7.11. "Errors" Tab Parameters Setting the parameters for the action to be taken when an over-torque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX". Figure 292 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 293 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital inputs 1 to 5. Switch back to run mode: enable one of digital inputs 1 to 5. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 171/224 SMi21 12.2.8. Description of the P200 Various Tabs For the description of tabs, expert program P201 is used as an example (for detailed information about each position expert program, see the "Expert Program P201" and "Expert Program P202" sections in this document). 12.2.8.1. Home Page This page is common to all the expert and application programs, whether in speed, position or torque mode. It can be used to choose between the various types of application and expert programs. In our example, we have chosen the "Position P200" category in the "Expert Programs" group, so the icons for the various P200 expert programs appear in the bottom right-hand corner of the window, and you then need to click on the one corresponding to the "P201" expert program: Concise description of the P201 expert program Expert program category selection: P200 Expert program selection: P201 Figure 294 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 172/224 SMi21 12.2.8.2. "Description" Tab This is an information tab containing a concise description of the various position profiles that are created using this expert mode: Option to name the project I/O Summary description of the profiles that can be created using this expert mode: position follows in live the position settings, choice between 2 speed profiles… Figure 295 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 173/224 SMi21 12.2.8.3. “Homing” Tab This tab is used to select and configure the type of homing to be performed: offset(s), speed, homing torque, maximum duration of the homing phase, motor direction of rotation to search for the 1st stop. Selection of the type of homing to be performed: 0, 1 or 2 mechanical Parameters associated with the selected homing type. Summary description of the selected homing phase Figure 296 12.2.8.4. “Inputs” Tab This tab is used to configure the various inputs in this expert mode (speed profile : max speed, acceleration, deceleration ; application stroke…). Figure 297 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 174/224 SMi21 12.2.8.5. “Outputs” Tab This tab is used to select and configure the various outputs in this expert mode (position type 5 to type 9): Output 5 type parameter settings Output 6 type parameter settings Output 7 type parameter settings Output 8 type parameter settings Output 9 type parameter settings Figure 298 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 175/224 SMi21 12.2.8.6. "Tuning" Tab This tab is used to represent some parameters (speed, position, torque, etc.) in graphic form and modify the position control loop coefficients. It is common to all the position expert programs. This tab is used to view the selected parameters in graphic form. This zone is used to: - Select the parameters to be viewed in graphic form - Set the position correction factors - Set the display time - Export the data (.csv) Figure 299 12.2.8.7. "Limits" Tab This tab is used to configure the various motor operating limits: nominal and maximum torque (torque peak authorization), the power supply overvoltage threshold and the required accuracy for the positioning. Summary description of torque control. Setting the parameters associated with torque control. Setting of target’s tolerance for positioning Overvoltage threshold settings: if this value is exceeded, an error will be generated. C.MO.SAV.00006.FR_V5 January 12th, 2016 Figure 300 Page 176/224 SMi21 12.2.8.8. "Errors" Tab This tab provides information about the type of error encountered (based on the error code) and the action to be taken by the motor following this error. Motor actions can be set when Over torque error or Position target error are detected (*not available, optional only). Motor action selection when a target error is detected (*optional). Setting the action to be taken when an over torque error is encountered (*optional). If an error is detected that could jeopardize motor safety, the motor is automatically turned off and left freewheeling. Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode and then back to run mode. Figure 301 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 177/224 SMi21 12.2.9. 12.2.9.1. Expert Program P201 Description P201 expert program allows to: - Perform a homing phase to initialize the system with detection of the stroke ends (mechanical stop or switch limit). - Perform positioning in using two 0/10V analog inputs: One for coarse tuning and second for thin tuning. The total stroke (which has to be set per the user in this program) can be cut up to 65536 positions. The targeted position follows in live the 2 inputs. - Select a speed profile (choice between 2 profiles) to go from a position to another position. A speed profile contains acceleration, deceleration and maximum allowed speed values. 12.2.9.2. "Homing" Tab Parameters Set the polarity of the switch wired on digital input "In3": Figure 302 Set the difference in position (in pulses) between the mechanical stops and the application total stroke limits: stop 1 (END1) represents the stroke start, stop 2 (END2) represents the stroke end. Note: Where there is only one mechanical stop, the "Offset 2" parameter is not available. Figure 303 Set the search speed for stops during the homing phase. Figure 304 Set the homing torque that allows the mechanical stop to be found by detection of over-torque. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 178/224 SMi21 Figure 305 Set the maximum permitted time for the homing phase. If this value is exceeded, an error will be generated. Time limited to 300 s. Figure 306 Set the direction of rotation for the first stop search. N.B.: By default, the motor runs forward (CW). Figure 307 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 179/224 SMi21 12.2.9.3. "Inputs" Tab Parameters Combinations of digital inputs 1 and 2: Used to choose the motion to be performed from the 4 actions indicated below. Figure 308 Information concerning the polarity of the switch wired on digital input 3. This polarity is selected in the "Homing" tab (see above). Figure 309 Digital input 4 - IN4 : Used to select one of the two speed profile. To go from a position to a new position, motor follows a trapezoidal trajectory. This trajectory uses the maximum speed, acceleration and deceleration which are set in the « Digital speed profile selection » zone. Figure 310 NB : If the user needs to change its velocity profile during a positioning phase, it is strongly recommended to use the same deceleration slope for both velocity profiles to ovoid overruns targets. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 180/224 SMi21 Input IN5 and IN6 setpoints: To do the position setting using the two 0-10V analog inputs. Parameter « total stroke lenght » is the number of encoder pulses corresponding to the stroke when IN5 and IN6 are at 10V. Parameter “resolution coefficient” allows to cut the « total stroke length » in 2,048 or 4,096 or 8,192 or 16,384 or 32,768 or 65,536 positions. The distribution of the « Total stroke length » on the two analog setpoint inputs is carried out according to the rules below. - On IN5 : [0 − 10𝑉] ≡ [0 ; 𝑆𝑡𝑟𝑜𝑘𝑒𝑡𝑜𝑡𝑎𝑙_𝑎𝑝𝑝𝑙𝑖𝑐𝑎𝑡𝑖𝑜𝑛 × 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 −1 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 ] coded on 1024 points (coarse setting) - On IN6 : [0 − 10𝑉] ≡ [0 ; 𝐶𝑜𝑢𝑟𝑠𝑒𝑡𝑜𝑡𝑎𝑙𝑒_𝑎𝑝𝑝𝑙𝑖𝑐𝑎𝑡𝑖𝑜𝑛 × 1 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟é𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 ] coded on 1024 points (thin setting) Figure 311 Figure 312 The motor position setpoint is the addition of position setpoint of IN5 and of position setpoint of IN6. In above example : - On IN5 : [0 − 10𝑉] ≡ [0 ; 40960 × - On IN6 : [0 − 10𝑉] ≡ [0 ; 40960 × 16−1 16 1 16 ] = [0 ; 38400] coded on 1,024 points (coarse setting) ] = [0 ; 2560] coded on 1,024 points (thin setting) Note : The sign (-) at the 10V setpoint depends from the direction of rotation during the homing sequence. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 181/224 SMi21 12.2.9.4. Type 5 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 313 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 314 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 315 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 316 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 182/224 SMi21 12.2.9.5. Type 6 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 317 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 318 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 319 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 320 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 183/224 SMi21 12.2.9.6. Type 7 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 321 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 322 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 323 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 184/224 SMi21 12.2.9.7. Type 8 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 324 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 325 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 326 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 185/224 SMi21 12.2.9.8. Type 9 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 327 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 328 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 329 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 186/224 SMi21 12.2.9.9. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 330 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 331 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 332 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 333 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 187/224 SMi21 Example: - Application total stroke length = 2000000 pulses Speed profile: speed = 1000 rpm / acceleration = 400 rpm/sec / deceleration = 100 rpm/sec The following results were obtained : Position setpoint Real speed Real position NB: The display scales can be changed with the mouse wheel. Other functions are available by right-clicking the mouse. Figure 334 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 188/224 SMi21 12.2.9.10. "Limits" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 335 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 189/224 SMi21 Figure 336 Setting of the « Acceptable position accuracy » for the position to reach : This value gives the acceptable tolerance to consider that the target position is reached. The output « target reached » will become active when motor position will be at the position [targeted position +/- the « Acceptable position accuracy »]. Figure 337 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 190/224 SMi21 12.2.9.11. "Errors" Tab Parameters Setting the parameters for the action to be taken when an over-torque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX" (in option). Figure 338 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 339 Setting of the action to perform when a target error is detected : (not available, optional only) When motor is not able to achieve in the required time limit its position target +/- the “Acceptable position accuracy », the “Position target error” is activated and the selected action will occur. Figure 340 Procedure for restarting the motor following detection of an error: - - Eliminate the cause of the fault. Switch to stop mode: Inhibit inputs 1 and 2 (IN1 = IN2 = 0) to be in the « stop and erase error » mode. Go back to a running mode in activating input 1 or 2 or the both. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 191/224 SMi21 12.2.10. Expert Program P202 12.2.10.1. Description P202 expert program allows to: - Perform a homing phase to initialize the system with detection of the stroke ends (mechanical stop or switch limit). - Define a position setpoint in using two 0/10V analog inputs: One for coarse tuning and second for thin tuning. The total stroke (which has to be set per the user in this program) can be cut up to 65536 positions. - Memorize the new position setpoint - Go to the new position target - Select a speed profile (choice between 2 profiles) to go from a position to another position. A speed profile contains acceleration, deceleration and maximum allowed speed values. 12.2.10.2. "Homing" Tab Parameters Set the polarity of the switch wired on digital input "In3": Figure 341 Set the difference in position (in pulses) between the mechanical stops and the application total stroke limits: stop 1 (END1) represents the stroke start, stop 2 (END2) represents the stroke end. Note: Where there is only one mechanical stop, the "Offset 2" parameter is not available. Figure 342 Set the search speed for stops during the homing phase. Figure 343 Set the homing torque that allows the mechanical stop to be found by detection of overtorque. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 192/224 SMi21 Figure 344 Set the maximum permitted time for the homing phase. If this value is exceeded, an error will be generated. Time limited to 300 s. Figure 345 Set the direction of rotation for the first stop search. N.B.: By default, the motor runs forward (CW). Figure 346 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 193/224 SMi21 12.2.10.3. "Inputs" Tab Parameters Combinations of digital inputs 1 and 2: Used to choose the motion to be performed from the 4 actions indicated below. Figure 347 Information concerning the polarity of the switch wired on digital input 3. This polarity is selected in the "Homing" tab (see above). Figure 348 Digital input 4 - IN4 : Used to select one of the two speed profile. To go from a position to a new position, motor follows a trapezoidal trajectory. This trajectory uses the maximum speed, acceleration and deceleration which are set in the « Digital speed profile selection » zone. Figure 349 Note : If the user needs to change its velocity profile during a positioning phase, it is strongly recommended to use the same deceleration slope for both velocity profiles to ovoid overruns targets. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 194/224 SMi21 Input IN5 and IN6 setpoints: To do the position setting using the two 0-10V analog inputs. Parameter « total stroke lenght » is the number of encoder pulses corresponding to the stroke when IN5 and IN6 are at 10V. Parameter “resolution coefficient” allows to cut the « total stroke length » in 2,048 or 4,096 or 8,192 or 16,384 or 32,768 or 65,536 positions. The distribution of the « Total stroke length » on the two analog setpoint inputs is carried out according to the rules below. - On IN5 : [0 − 10𝑉] ≡ [0 ; 𝑆𝑡𝑟𝑜𝑘𝑒𝑒𝑡𝑜𝑡𝑎𝑙𝑒_𝑎𝑝𝑝𝑙𝑖𝑐𝑎𝑡𝑖𝑜𝑛 × 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 −1 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 ] coded on 1024 points (coarse setting) - On IN6 : [0 − 10𝑉] ≡ [0 ; 𝑆𝑡𝑟𝑜𝑘𝑒𝑡𝑜𝑡𝑎𝑙𝑒_𝑎𝑝𝑝𝑙𝑖𝑐𝑎𝑡𝑖𝑜𝑛 × 1 𝐶𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡_𝑟é𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 ] coded on 1024 points (thin setting) Figure 350 Figure 351 The motor position setpoint is the addition of position setpoint of IN5 and of position setpoint of IN6. In above example : - On IN5 : [0 − 10𝑉] ≡ [0 ; 40960 × - On IN6 : [0 − 10𝑉] ≡ [0 ; 40960 × 16−1 16 1 16 ] = [0 ; 38400] coded on 1,024 points (coarse setting) ] = [0 ; 2560] coded on 1,024 points (thin setting) Note : The sign (-) at the 10V setpoint depends from the direction of rotation during the homing sequence. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 195/224 SMi21 12.2.10.4. Type 5 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 352 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 353 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 354 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 355 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 196/224 SMi21 12.2.10.5. Type 6 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 356 State of digital output 2 "Homing Sequence Information": Used to find out how the homing phase is progressing: completed, in progress or not performed. Figure 357 State of digital output 3 "Motor running": Used to find out whether the motor is stopped or running. Figure 358 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 359 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 197/224 SMi21 12.2.10.6. Type 7 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 360 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 361 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 362 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 198/224 SMi21 12.2.10.7. Type 8 "Outputs" Tab Parameters State of digital output 1 "Target Reached Flag": Used to find out whether the position setpoint has been reached. Figure 363 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 364 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 365 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 199/224 SMi21 12.2.10.8. Type 9 "Outputs" Tab Parameters Setting the parameters of Pulse output 1 "Real speed": A Hall pulse with configurable width (100 to 800 µs) is generated each time one of the 3 motor Hall sensors changes state. 80140_SMi21 and 80180_SMi21 motors have 12 Hall pulses per revolution (2 pairs of poles). The 80280_SMi21 motor has 24 Hall pulses per revolution (4 pairs of poles). Figure 366 State of digital output 2 "Real direction": Used to find out the motor direction of rotation. Figure 367 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 368 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 200/224 SMi21 12.2.10.9. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2, 3 or 4 parameters. The system position response (measurement vs setpoint) can therefore be compared while displaying changes in the current and the speed. Figure 369 Set the PID controller factors in the position control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 370 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 371 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 372 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 201/224 SMi21 Example: - Application total stroke length = 2000000 pulses Speed profile: speed = 1000 rpm / acceleration = 400 rpm/sec / deceleration = 100 rpm/sec The following results were obtained : Position setpoint Real speed Real position Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 373 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 202/224 SMi21 12.2.10.10. "Limits" Tab Parameters WARNING UNEXPECTED MOVEMENT An inappropriate setting for the torque values can result in unexpected movements of the application and destruction of the motor. • Make sure this will not cause any damage. • Do not continue with the test if there is anyone or any obstacle in the hazardous zone. Failure to comply with these precautions will result in death, serious injury or equipment damage. This tab can be used to set the limit values for various parameters. Figure 374 Setting the various torque parameters: When the application torque exceeds the torque "CNOMINAL", the motor can provide torque up to the value "CMAX" for the maximum duration " tMAX". Thereafter, if the application torque is still higher than "CNOMINAL", the motor torque is limited to the value "CNOMINAL" until the application torque falls back below this value. WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 203/224 SMi21 Figure 375 Setting of the « Acceptable position accuracy » for the position to reach : This value gives the acceptable tolerance to consider that the target position is reached. The output « target reached » will become active when motor position will be at the position [targeted position +/- the « Acceptable position accuracy »]. Figure 376 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 204/224 SMi21 12.2.10.11. "Errors" Tab Parameters Setting the parameters for the action to be taken when an over-torque error is encountered: real torque higher than the nominal torque "CNOMINAL" for a time longer than "tMAX" (in option). Figure 377 For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 378 Setting of the action to perform when a target error is detected : (not available, optional only) When motor is not able to achieve in the required time limit its position target +/- the “Acceptable position accuracy », the “Position target error” is activated and the selected action will occur. Figure 379 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: Inhibit inputs 1 and 2 (IN1 = IN2 = 0) to be in the « stop and erase error » mode. Go back to a running mode in activating input 1 or 2 or the both. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 205/224 SMi21 12.3. Torque Programs 12.3.1. Types of Inputs in C100 Programs The table below defines the function associated with each of the inputs in the 2 C100 programs (the color associated with the input number corresponds to that of the I/O bundle): Programs Inputs C101 In1 ON/OFF C102 000 : "In6" torque setpoint 001 : Priority torque 1 010 : Priority torque 2 100 : Priority torque 3 In2 Direction In3 Not used In4 Fast stop In5 Torque ramp In6 Torque Key: 00 : Fast stop 10 : CCW 01 : CW 11 : Stop, disable error Torque (if In1 = In2 = In3 = 0) Digital type input Analog or PWM type input Forthcoming programs 12.3.2. Types of Outputs in C100 Programs For all expert torque programs, we have 2 configurable output configurations (the color associated with the output number corresponds to that of the I/O bundle): Type 2 Type 10 Out1 Real speed Out2 Real torque PWM PWM Out3 Motor running Out4 Error Digital Digital Real speed (centered on 50%) Real torque (centered on 50%) 00 : error detected 01 : motor running 10 : motor stopped, torque position reached and held 11 : motor stopped, no torque applied PWM PWM Digital combinations Key: Digital type output PWM/Pulse/Frequency type output C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 206/224 SMi21 12.3.3. Description of the Various Tabs For the description of tabs, expert program C101 is used as an example (for detailed information about each torque expert program, see the "Expert Program C101" section in this document). 12.3.3.1. Home Page This page is common to all the expert and application programs, whether in speed, position or torque mode. It can be used to choose between the various types of application and expert programs. In our example, we have chosen the "Torque C100" category in the "Expert Programs" group, so the icons for the various C100 expert programs appear in the bottom right-hand corner of the window, and you then need to click on the one corresponding to the "C101" expert program: Concise description of the C101 expert program Expert program category selection: C100 Expert program selection: C101 Figure 380 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 207/224 SMi21 12.3.3.2. "Description" Tab This is an information tab containing a concise description of the various torque profiles that are created using this expert mode: Option to name the project I/O Summary description of the profiles that can be created using this expert mode: torque control with ramp management, etc. Figure 381 12.3.3.3. "Inputs" Tab This tab is used to configure the various inputs in this expert mode (digital input polarity, value, control type, maximum and minimum control limit, etc.): Figure 382 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 208/224 SMi21 12.3.3.4. "Outputs" Tab This tab is used to select and configure the various outputs in this expert mode (torque type 2 and type 10): Output 2 type parameter settings Output 10 type parameter settings Figure 383 12.3.3.5. "Tuning" Tab This tab is used to represent some parameters (speed, torque, etc.) in graphic form and modify the torque control loop coefficients. It is common to all the torque expert programs. This tab is used to view the selected parameters in graphic form. This zone is used to: - Select the parameters to be viewed in graphic form - Set the torque correction factors - Set the display time - Export the data (.csv) Figure 384 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 209/224 SMi21 12.3.3.6. "Limits" Tab This tab can be used to set the power supply overvoltage threshold. Overvoltage threshold settings: if this value is exceeded, an error will be generated. Figure 385 12.3.3.7. "Errors" Tab This tab provides information about the type of error encountered (based on the error code) and the action to be taken by the motor following this error. If an error is detected that could jeopardize motor safety, the motor is automatically turned off and left freewheeling. Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode. Figure 386 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 210/224 SMi21 12.3.4. 12.3.4.1. Expert Program C101 Description Expert program C101 is used to: - Create torque profiles with analog or PWM control. - Set the torque up and down ramps with analog or PWM control. 12.3.4.2. "Inputs" Tab Parameters Digital input 1: Used to set the "On/Off" input polarity. Figure 387 Digital input 2: Used to set the "Direction of Rotation" input polarity. Figure 388 Digital input 3: Not used Digital input 4: Used to set the "Fast stop" input polarity. This input is used to stop the motor as quickly as possible, ignoring the setpoints applied to the other inputs. Figure 389 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 211/224 SMi21 Setpoint input 5: Used to select the control type for the torque ramp setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 390 Setpoint input 6: Used to select the control type for the torque setpoint and fix the maximum and minimum limits for this setpoint. An inverted scale can be used. Figure 391 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 212/224 SMi21 12.3.4.3. Type 2 "Outputs" Tab Parameters Setting the parameters of PWM output 1 "Real Speed": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 100% → Real speed = 0 rpm. → Real speed = maximum speed setpoint defined in In6. Figure 392 Setting the parameters of PWM output 2 "Real Torque": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 100% → Torque supplied = 0 mNm. → Torque supplied = "S2 torque". Figure 393 State of digital output 3 "Motor Running": Used to find out whether the motor is stopped or running. Figure 394 State of digital output 4 "Error": Used to find out whether an error has been detected. Figure 395 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 213/224 SMi21 12.3.4.4. Type 10 "Outputs" Tab Parameters Setting the parameters of PWM output 1: "Real speed (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 2). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Motor running forward (CW) at maximum speed setpoint defined in In6. → Real speed = 0 rpm. → Motor running in reverse (CCW) at maximum speed setpoint defined in In6. Figure 396 Setting the parameters of PWM output 2 "Real torque (centered on 50%)": The parameters can be set for the signal frequency of this output (must be identical to the one for PWM output 1) and the torque value corresponding to a cyclical ratio of 100% (scaling). If cyclical ratio = 0% If cyclical ratio = 50% If cyclical ratio = 100% → Braking torque supplied = "S2 torque". → Torque supplied = 0 mNm. → Motor torque supplied = "S2 torque". Figure 397 Combinations of digital outputs 3 & 4 "Motor status": Used to find out the motor status. Figure 398 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 214/224 SMi21 12.3.4.5. "Tuning" Tab Parameters Selection of the various parameters to be represented in graphic form: either 1, 2 or 3 parameters. The system torque response (measurement vs setpoint) can therefore be compared while displaying changes in the speed. Figure 399 Set the PID controller factors in the torque control loop (this function is reserved for advanced users). The values given in the example below ensure correct product operation in the majority of cases. Figure 400 It is possible to set the recording time you wish to view, from 1 to 300 seconds. The sampling interval is 10 ms. During data acquisition, the other HMI functions are not available. Figure 401 "Curve Drawing" button: used to start data acquisition. Curves are only displayed once acquisition is complete. "Export Data" button: used to retrieve data corresponding to the selected parameters in a text file (.txt). To make this file compatible with the Excel spreadsheet, change its extension to .csv. Figure 402 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 215/224 SMi21 Example: With a torque setpoint on input 6 at 200 mN.m and a torque ramp setpoint on input 5 at 50 mN.m/s, this gives us the following graphic representation (recording time of 20 seconds): Torque setpoint Real torque Figure 403 Note: The display scales can be changed with the mouse wheel. Other functions are available by rightclicking the mouse. Figure 404 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 216/224 SMi21 12.3.4.6. "Limits" Tab Parameters WARNING VOLTAGE SURGES During the braking phases, the motor generates voltage surges. • Check that its voltage surges can be tolerated by the other devices connected to the same power supply. • Use an external circuit to limit voltage surges if the brake is being used intensively. Failure to comply with these precautions will result in death, serious injury or equipment damage. Setting the overvoltage detection threshold parameters: If the voltage at the motor terminals exceeds this threshold, an error is generated, the motor is stopped and no holding torque is applied (freewheeling). Figure 405 12.3.4.7. "Errors" Tab Parameters For all errors affecting motor safety, the action to be taken cannot be configured: in the event of an error, the motor is stopped and no holding torque is applied (freewheeling). Figure 406 Procedure for restarting the motor following detection of an error: - Eliminate the cause of the fault. Switch to stop mode: disable digital input 1 "On/Off". Switch back to run mode: enable digital input 1 "On/Off". C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 217/224 SMi21 13. SAVING PARAMETERS In all the expert programs (speed, position and torque), the user can give a name to his project (4 alphanumerical characters maximum) using the "Project name" parameter in the program "Description" tab (expert program V101 will be used as an example): Figure 407 The "Project name" parameter can be accessed by clicking the "Motor Information" tab in the main menu bar: Updating the parameter "Project name" Figure 408 The project parameters can be saved in an .xml file by clicking on "Save As" in the "File" tab of the main menu. Figure 409 They can also be reused by clicking on "Open" in the "File" tab of the main menu, then selecting the appropriate "MOT1.xml" file. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 218/224 SMi21 Figure 410 Select the parameter backup file Figure 411 C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 219/224 SMi21 When the parameter file is uploaded, the HMI automatically launches the associated expert or application program (in our example expert program V101): Load saved parameters Figure 412 Press the "Load Program" button to load the "MOT1.xml" file parameters in the motor. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 220/224 SMi21 14. DIAGNOSTICS AND TROUBLESHOOTING 14.1. Mechanical Failures Error Significant temperature rise Whistling or knocking Friction noise Radial vibration Axial vibration 14.2. Cause Overload Holding brake not released Faulty bearings A rotary transmission device is catching Transmission device incorrectly aligned Transmission device unbalanced Twisted shaft Resonance in the fixing Transmission device incorrectly aligned Transmission device being knocked Resonance in the fixing Remedy Reduce the load Check control of the holding brake Contact the after-sales service Align the transmission device Align the transmission device Balance the transmission device Contact the after-sales service Check the rigidity of the motor fixing Align the transmission device Check the transmission device Check the rigidity of the motor fixing Electrical Failures Error The motor does not start or starts with difficulty Cause Overload Fault in the connection wires Significant temperature rise in the stator Temperature rise in the connection terminals Overload C.MO.SAV.00006.FR_V5 January 12th, 2016 Power supply wires disconnected or loose Remedy Reduce the load Check the connection wires Contact the after-sales service Reduce the load Tighten the screws Page 221/224 SMi21 15. SERVICE, MAINTENANCE AND DISPOSAL 15.1. Addresses of After-Sales Service Outlets Please contact your distributor. The list of distributors is accessible on the CROUZET Automatismes website www.crouzet.com 15.2. Storage The motors must only be transported and stored in dry, dust-free environments that are resistant to vibration. The ambient conditions are stated in the product technical data sheet and must be adhered to. The storage period is essentially dictated by the stability of the lubricants and should be less than 36 months. To keep the motor in working order, it is advisable to start up the drive solution occasionally. 15.3. Maintenance Only the manufacturer is authorized to undertake repairs. Any personal intervention voids any guarantee and precludes manufacturer liability. Repairs cannot be performed with the motor mounted. Prior to any intervention on the drive system, please refer to the Installation and Commissioning sections to find out what steps to take. We recommend that the following operations are done at regular intervals. Connections and fixing => Check the connection cables and connections regularly for signs of damage. Replace any damaged cables immediately. => Check that all the transmission devices are fully tightened. => Retighten all the mechanical and electrical bolted connections to the appropriate tightening torque. WARNING UNEXPECTED MOVEMENT Exceeding the permissible ambient conditions can allow foreign bodies from the surrounding area to get in and lead to unexpected motor movements or damage to equipment. • Check the ambient conditions. • It is vital to avoid fluid stagnation in the shaft bushing. Failure to comply with these precautions can result in death, serious injury or damage to equipment. Cleaning Clean the motor regularly to remove any dust and dirt. If heat cannot dissipate adequately into the ambient air, this can cause abnormally high temperatures. The motors are not designed to be cleaned with high-pressure washers. Jet washing can cause water to get inside the motor. When using cleaning products or solvents, take care not to damage the motor power supply leads and any options (brake), ball bearings and the motor coating. Check/run in the holding brake Occasional braking with a shifted load helps conserve the holding brake's holding torque. If the holding brake produces no mechanical work over a prolonged period (braking with a shifted load), some parts of the holding brake can corrode or other deposits can accumulate and thus reduce the holding torque. The holding brake has been run in on leaving the factory. If the holding brake produces no mechanical work over a prolonged period, some parts of the holding brake can corrode. If the holding brake should not demonstrate the holding torque specified in the technical specifications, it would need to be run in again: C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 222/224 SMi21 => The motor is not mounted. The holding brake is engaged. => Measure the brake holding torque using a torque wrench. => Compare the value with the holding torque indicated on the technical data sheet. => If the holding torque is markedly different from the stated values, turn the motor shaft by hand 25 turns in both directions. => Repeat the operation. If the holding torque has not been restored after 3 repeat operations, please contact your vendor. 15.4. Replacing the Motor => Disconnect all the supply voltages. Make sure that no other voltage is applied (safety instructions). => Mark all connections and demount the product. => Replace it with a motor with the same part number. => Install the new product as described in section 4 "Installation". => Commission the product as described in section 5 "Commissioning". 15.5. Dispatch, Storage, Disposal Comply with the ambient conditions described in the "TECHNICAL SPECIFICATIONS" section. Dispatch Protect the product against shocks during transport. Use the original packaging for this purpose. Storage Only store the product in the stated permissible ambient conditions in terms of temperature and air humidity. Protect the product against dust and dirt. Disposal The product is made up of various materials that can be reused or are suitable for separation and recycling. Dispose of the product in accordance with local regulations. C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 223/224 SMi21 15.6. Terminology and Abbreviations Encoder Mounted on the motor, the angular position sensor provides frequency pulses proportional to the motor speed. Degree of protection The degree of protection is a standard definition used for electrical equipment that aims to describe the protection against penetration of solids and liquids inside the motor casing (for example IP54M). The M indicates that the tests are conducted with the motor running. This value cannot take account of the seal around the output shaft, for which the installer must take responsibility. Axial forces Longitudinal traction or compression forces affecting the shaft. Radial forces Radial forces affecting the shaft. Direction of rotation Positive or negative direction of rotation of the motor shaft. The positive direction of rotation is clockwise rotation of the motor shaft, when looking at the motor from the output shaft. Nominal speed Motor speed of rotation when nominal torque is applied. Nominal current Current drawn by the motor when nominal torque is applied. Nominal torque Maximum applicable torque in continuous duty on the motor shaft. Firmware Control software embedded in the motor. Bootloader Function available in the HMI which can be used to update the firmware. Commonly used abbreviations: HMI: Human-Machine Interface SMi21: Trade name of the new CROUZET brushless range Homing: Initialization phase for finding the limits Type of digital inputs/outputs (All Or Nothing) AON: PWM: Pulse Width Modulation FWD: Forward REV: Reverse NO: Normally Open NC: Normally Closed Electromagnetic Compatibility EMC: C.MO.SAV.00006.FR_V5 January 12th, 2016 Page 224/224
80141013
1. 物料型号:文档中没有明确提及具体的物料型号,可能需要查看文档的其他部分或产品手册来获取这一信息。

2. 器件简介:文档提供了关于SMi21系列电机的详细描述,包括其功能和应用场景。例如,文档中提到了电机的图形化表示、速度设定、扭矩控制等。

3. 引脚分配:文档中提到了电机控制器的输入和输出配置,包括数字输入、模拟输入以及PWM输出等,但没有提供具体的引脚分配图。通常,这些信息可以在电机的技术手册或数据表中找到。

4. 参数特性:文档详细列出了电机的各种参数设置,如速度设定点、PID控制器参数、扭矩管理参数、过电压检测阈值等。

5. 功能详解:文档中对电机的多种功能进行了详细解释,包括速度控制、扭矩控制、位置控制、故障处理和重启程序等。

6. 应用信息:文档提供了电机在不同应用中的配置示例,如速度设定、位置设定、扭矩限制等,以及如何通过不同的输入来控制电机的行为。

7. 封装信息:文档中没有直接提供封装信息,但通常这类信息会在产品的技术规格书或数据表中详细描述。
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