Cat. No.
I51E-EN-04
Trajexia motion control system
hardware reference manual
TJ1-MC04, TJ1-MC16, TJ1-ML04, TJ1-ML16, TJ1-PRT, TJ1-DRT, TJ1-CORT, TJ1-FL02
GRT1-ML2
Trajexia motion control system
Cat. No.
I51E-EN-05
hardware reference manual
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Note:
Although we do strive for perfection, Omron Europe BV and/or its subsidiary and affiliated companies do not warrant or make any representations regarding the correctness or completeness
of information described in this catalogue. Product information in this catalogue is provided ‚as is‘ without warranty of any kind, either express or implied, including, but not limited to, the
implied warranties of merchantability, fitness for a particular purpose, or non-infringement. In a jurisdiction where the exclusion of implied warranties is not valid, the exclusion shall be
deemed to be replaced by such valid exclusion, which most closely matches the intent and purpose of the original exclusion. Omron Europe BV and/or its subsidiary and affiliated companies
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Cat. No. I51E-EN-04
Notice
/i
OMRON products are manufactured for use according to proper procedures
by a qualified operator and only for the purposes described in this manual.
The following conventions are used to indicate and classify precautions in
this manual. Always heed the information provided with them. Failure to
heed precautions can result in injury to people or damage to property.
Definition of precautionary information
WARNING
Indicates a potentially hazardous situation, which, if not avoided,
could result in death or serious injury.
Caution
Indicates a potentially hazardous situation, which, if not avoided,
may result in minor or moderate injury, or property damage.
Trademarks and Copyrights
PROFIBUS is a registered trademark of PROFIBUS International.
MECHATROLINK is a registered trademark of Yaskawa Corporation.
DeviceNet is a registered trademark of Open DeviceNet Vendor Assoc INC.
CIP is a registered trademark of Open DeviceNet Vendor Assoc INC.
CANopen is a registered trademark of CAN in Automation (CiA).
ModbusTCP is a registered trademark of Modbus IDA.
Trajexia is a registered trademark of OMRON.
Motion Perfect is a registered trademark of Trio Motion Technology Ltd.
All other product names, company names, logos or other designations
mentioned herein are trademarks of their respective owners.
Revision 5.0
HARDWARE REFERENCE MANUAL
© OMRON, 2010
All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form, or by any means, mechanical, electronic, photocopying,
recording, or otherwise, without the prior written permission of OMRON.
No patent liability is assumed with respect to the use of the information contained herein.
Moreover, because OMRON is constantly striving to improve its high-quality products, the
information contained in this manual is subject to change without notice. Every precaution
has been taken in the preparation of this manual. Nevertheless, OMRON assumes no
responsibility for errors or omissions. Neither is any liability assumed for damages resulting
from the use of the information contained in this publication.
I
About this manual
This manual describes the installation and operation of the Trajexia Motion
Control System.
Please read this manual and the related manuals listed in the following table
carefully and be sure you understand the information provided before
attempting to install or operate the Trajexia Motion Control units. Be sure to
read the precautions provided in the following section.
/i
Revision 5.0
Name
Cat. No.
Contents
Trajexia motion control system
QUICK START
GUIDE
I50E
Describes how to get quickly familiar
with Trajexia, moving a single axis using
MECHATROLINK-II, in a test set-up.
Trajexia motion control system HARDWARE
REFERENCE MANUAL
I51E
Describes the installation and hardware
specification of the Trajexia units, and
explains the Trajexia system philosophy.
Trajexia motion control system
PROGRAMMING
MANUAL
I52E
Sigma-II Servo
Driver manual
SIEP S800000 15
Describes the installation and operation
of Sigma-II Servo Drivers
Sigma-III with
MECHATROLINK
interface manual
SIEP S800000 11
Describes the installation and operation
of Sigma-III Servo Drivers with MECHATROLINK-II interface
Sigma-V Servo
Driver manual
SIEP S800000-44-O-OY
SIEP S800000-46-O-OY
SIEP S800000-48-O-OY
Describes the installation and operation
of Sigma-V Servo Drivers
JUNMA series servo
drive manual
TOEP-C71080603 01-OY Describes the installation and operation
of JUNMA Servo Drivers
HARDWARE REFERENCE MANUAL
Describes the BASIC commands to be
used for programming Trajexia, communication protocols and Trajexia Studio
software, gives practical examples and
troubleshooting information.
Name
Cat. No.
Contents
V7 Inverter
TOEP C71060605 02-OY Describes the installation and operation
of V7 Inverters
F7Z Inverter
TOE S616-55 1-OY
Describes the installation and operation
of F7Z Inverters
G7 Inverter
TOE S616-60
Describes the installation and operation
of G7 Inverters
JUSP-NS115 manual
SIEP C71080001
Describes the installation and operation
of the MECHATROLINK-II application
module
SI-T MECHATROLINK interface for
the G7 & F7
SIBP-C730600-08
Describes the installation and operation
of MECHATROLINK-II interfaces for G7
and F7 Inverters
ST-T/V7 MECHATROLINK interface
for the V7
SIBP-C730600-03
Describes the installation and operation
of MECHATROLINK-II interfaces for V7
Inverters
MECHATROLINK IO
Modules
SIE C887-5
Describes the installation and operation
of MECHATROLINK-II input and output
modules and the MECHATROLINK-II
repeater
SYSMAC CS/CJ
Series Communications Commands
W342
Describes FINS communications protocol and FINS commands
Omron Smartslice
GRT1-Series, slice I/
O units, Operation
manual
W455-E1
Describes the installation and operation
of Omron slice I/O units
Omron G-series
user’s manual
I566-E1
Describes the installation and operation
of G-series Servo Drivers
Omron Accurax G5
user’s manual
I572-E1
Describes the installation and operation
of Accurax G5 Servo Drivers
Trajexia Studio user
manual
I56E-EN
Describes the use of Trajexia Studio
programming software
II
WARNING
Failure to read and understand the information provided in this
manual may result in personal injury or death, damage to the product, or product failure. Please read each section in its entirety and
be sure you understand the information provided in the section and
related sections before attempting any of the procedures or operations given.
Connect the TJ1-MC__ to Trajexia Studio software. Refer to the
Programming Manual.
Open the terminal window and type the following commands:
Type PRINT VERSION in the terminal window. The version parameter returns
the current firmware version number of the motion controller.
Type PRINT FPGA_VERSION SLOT(-1) in the terminal window. The
parameter returns the current FPGA version number of the TJ1-MC__.
Functions supported by unit versions
During the development of Trajexia new functionality was added to the
controller unit after market release.
This functionality is implemented in the firmware, and/or the FPGA of the
controller unit.
In the table below, the overview of the applicable functionality is shown
related to the firmware and FPGA version of the TJ1-MC__.
/i
Revision 5.0
Functionality
TJ1-MC__ Firmware
version
TJ1-MC__ FPGA
version
Full support TJ1-FL02
V1.6509
21 and higher
Support BASIC commands FINS_COMMS
V1.6509
All versions
Support TJ1-DRT
V1.6509
All versions
Support TJ1-MC04 andTJ1-ML04
V1.6607
21 and higher
Support TJ1-CORT, GRT1-ML2, ModbusTCP, Sigma-V series Servo Drivers
(except DATUM and REGIST BASIC commands) and allow Inverters to be controlled
as servo axes
V1.6652
21 and higher
Support for G-series Drivers, full support for
Sigma-V series Servo Drivers
V1.6714
21 and higher
Support for Accurax G5 Drivers
V1.6720
21 and higher
Verify the firmware and FPGA versions of the TJ1-MC__
HARDWARE REFERENCE MANUAL
III
Contents
1
Safety warnings and precautions................................................................................................................................................................ 1
1.1
1.2
1.3
1.4
1.5
1.6
1.7
2
System philosophy ....................................................................................................................................................................................... 7
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
3
Introduction .......................................................................................................................................................................................................................................7
Motion control concepts ....................................................................................................................................................................................................................8
Servo system principles ..................................................................................................................................................................................................................19
Trajexia system architecture .........................................................................................................................................................................................................22
Cycle time ......................................................................................................................................................................................................................................23
Program control and multi-tasking ..................................................................................................................................................................................................29
Motion sequence and axes.............................................................................................................................................................................................................30
Motion buffers ...............................................................................................................................................................................................................................40
Mechanical system .........................................................................................................................................................................................................................42
Hardware reference .................................................................................................................................................................................... 43
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10
A
Intended audience ............................................................................................................................................................................................................................1
General precautions .........................................................................................................................................................................................................................1
Safety precautions ............................................................................................................................................................................................................................1
Operating environment precautions..................................................................................................................................................................................................2
Application precautions.....................................................................................................................................................................................................................3
Unit assembly precautions................................................................................................................................................................................................................5
Conformance to EC Directives Conformance ...................................................................................................................................................................................6
Introduction .....................................................................................................................................................................................................................................43
All units ..........................................................................................................................................................................................................................................46
Power Supply Unit (PSU) ...............................................................................................................................................................................................................57
TJ1-MC__ .....................................................................................................................................................................................................................................59
TJ1-ML__........................................................................................................................................................................................................................................70
GRT1-ML2 ....................................................................................................................................................................................................................................143
TJ1-PRT .......................................................................................................................................................................................................................................158
TJ1-DRT .......................................................................................................................................................................................................................................162
TJ1-CORT ....................................................................................................................................................................................................................................166
TJ1-FL02 ......................................................................................................................................................................................................................................170
Differences between Sigma-II and Junma .............................................................................................................................................. 188
Revision history .............................................................................................................................................................................................. 189
Revision 5.0
HARDWARE REFERENCE MANUAL
IV
Safety warnings and precautions
1
1.1
Safety warnings and precautions
Intended audience
This manual is intended for personnel with knowledge of electrical systems
(electrical engineers or the equivalent) who are responsible for the design,
installation and management of factory automation systems and facilities.
1.2
General precautions
The user must operate the product according to the performance
specifications described in this manual.
Before using the product under conditions which are not described in the
manual or applying the product to nuclear control systems, railroad systems,
aviation systems, vehicles, safety equipment, petrochemical plants, and
other systems, machines and equipment that can have a serious influence
on lives and property if used improperly, consult your OMRON
representative.
1.3
Safety precautions
WARNING
Do not attempt to take the Unit apart and do not touch any of the
internal parts while power is being supplied.
Doing so may result in electrical shock.
WARNING
Do not touch any of the terminals or terminal blocks while power is
being supplied.
Doing so may result in electric shock.
Revision 5.0
HARDWARE REFERENCE MANUAL
WARNING
Never short-circuit the positive and negative terminals of the batteries, charge the batteries, disassemble them, deform them by
applying pressure, or throw them into a fire.
The batteries may explode, combust or leak liquid.
WARNING
Fail-safe measures must be taken by the customer to ensure
safety in the event of incorrect, missing, or abnormal signals
caused by broken signal lines, momentary power interruptions, or
other causes.
Not doing so may result in serious accidents.
WARNING
Emergency stop circuits, interlock circuits, limit circuits, and similar
safety measures must be provided by the customer as external circuits, i.e., not in the Trajexia motion controller.
Not doing so may result in serious accidents.
WARNING
When the 24 VDC output (I/O power supply to the TJ1) is overloaded or short-circuited, the voltage may drop and result in the
outputs being turned off.As a countermeasure for such problems,
external safety measures must be provided to ensure safety in the
system.
WARNING
The TJ1 outputs will go off due to overload of the output transistors
(protection).As a countermeasure for such problems, external
safety measures must be provided to ensure safety in the system.
1
Safety warnings and precautions
WARNING
The TJ1 will turn off the WDOG when its self-diagnosis function
detects any error.As a countermeasure for such errors, external
safety measures must be provided to ensure safety in the system.
WARNING
Provide safety measures in external circuits, i.e., not in the Trajexia Motion Controller (referred to as "TJ1"), in order to ensure
safety in the system if an abnormality occurs due to malfunction of
the TJ1 or another external factor affecting the TJ1 operation.
Not doing so may result in serious accidents.
WARNING
Do not attempt to disassemble, repair, or modify any Units.
Any attempt to do so may result in malfunction, fire, or electric
shock.
Caution
Confirm safety at the destination unit before transferring a program
to another unit or editing the memory.
Doing either of these without confirming safety may result in injury.
Caution
User programs written to the Motion Control Unit will not be automatically backed up in the TJ1 flash memory (flash memory function).
Caution
Tighten the screws on the terminal block of the Power Supply Unit
to the torque specified in this manual.
Loose screws may result in burning or malfunction.
1.4
Operating environment precautions
Caution
Do not operate the Unit in any of the following locations.
Doing so may result in malfunction, electric shock, or burning.
- Locations subject to direct sunlight.
- Locations subject to temperatures or humidity outside the
range specified in the specifications.
- Locations subject to condensation as the result of severe
changes in temperature.
- Locations subject to corrosive or flammable gases.
- Locations subject to dust (especially iron dust) or salts.
- Locations subject to exposure to water, oil, or chemicals.
- Locations subject to shock or vibration.
Caution
Take appropriate and sufficient countermeasures when installing
systems in the following locations.
Inappropriate and insufficient measures may result in malfunction.
- Locations subject to static electricity or other forms of noise.
- Locations subject to strong electromagnetic fields.
- Locations subject to possible exposure to radioactivity.
- Locations close to power supplies.
Revision 5.0
Caution
Pay careful attention to the polarity (+/-) when wiring the DC power
supply.A wrong connection may cause malfunction of the system.
HARDWARE REFERENCE MANUAL
2
Safety warnings and precautions
Caution
The operating environment of the TJ1 System can have a large
effect on the longevity and reliability of the system.
Improper operating environments can lead to malfunction, failure,
and other unforeseeable problems with the TJ1 System.
Make sure that the operating environment is within the specified
conditions at installation and remains within the specified conditions during the life of the system.
1.5
Caution
Take appropriate measures to ensure that the specified power with
the rated voltage and frequency is supplied. Be particularly careful
in places where the power supply is unstable.
An incorrect power supply may result in malfunction.
Application precautions
Caution
Install external breakers and take other safety measures against
short-circuiting in external wiring.
Insufficient safety measures against short-circuiting may result in
burning.
WARNING
Do not start the system until you check that the axes are present
and of the correct type.
The numbers of the Flexible axes will change if MECHATROLINKII network errors occur during start-up or if the MECHATROLINK-II
network configuration changes.
Not doing so may result in unexpected operation.
Caution
Do not apply voltage to the Input Units in excess of the rated input
voltage.
Excess voltage may result in burning.
WARNING
Check the user program for proper execution before actually running it in the Unit.
Not checking the program may result in an unexpected operation.
Caution
Always use the power supply voltage specified in this manual.
An incorrect voltage may result in malfunction or burning.
Caution
Do not apply voltage or connect loads to the Output Units in
excess of the maximum switching capacity.
Excess voltage or loads may result in burning.
Caution
Disconnect the functional ground terminal when performing withstand voltage tests.
Not disconnecting the functional ground terminal may result in
burning.
Revision 5.0
Caution
Always connect to a class-3 ground (to 100Ω or less) when installing the Units.
Not connecting to a class-3 ground may result in electric shock.
HARDWARE REFERENCE MANUAL
3
Safety warnings and precautions
Caution
Always turn off the power supply to the system before attempting
any of the following.
Not turning off the power supply may result in malfunction or electric shock.
- Mounting or dismounting expansion Units, CPU Units, or any
other Units.
- Assembling the Units.
- Setting dipswitches or rotary switches.
- Connecting or wiring the cables.
- Connecting or disconnecting the connectors.
Caution
Be sure that all mounting screws, terminal screws, and cable connector screws are tightened to the torque specified in this manual.
Incorrect tightening torque may result in malfunction.
Caution
Leave the dust protective label attached to the Unit when wiring.
Removing the dust protective label may result in malfunction.
Caution
Remove the dust protective label after the completion of wiring to
ensure proper heat dissipation.
Leaving the dust protective label attached may result in malfunction.
Revision 5.0
Caution
Use crimp terminals for wiring. Do not connect bare stranded wires
directly to terminals.
Connection of bare stranded wires may result in burning.
HARDWARE REFERENCE MANUAL
Caution
Double-check all the wiring before turning on the power supply.
Incorrect wiring may result in burning.
Caution
Wire correctly.
Incorrect wiring may result in burning.
Caution
Mount the Unit only after checking the terminal block completely.
Caution
Be sure that the terminal blocks, expansion cables, and other
items with locking devices are properly locked into place.
Improper locking may result in malfunction.
Caution
Confirm that no adverse effect will occur in the system before
changing the operating mode of the system.
Not doing so may result in an unexpected operation.
Caution
Resume operation only after transferring to the new CPU Unit the
contents of the VR and table memory required for operation.
Not doing so may result in an unexpected operation.
Caution
When replacing parts, be sure to confirm that the rating of a new
part is correct.
Not doing so may result in malfunction or burning.
4
Safety warnings and precautions
Caution
Do not pull on the cables or bend the cables beyond their natural
limit. Doing so may break the cables.
Caution
The TJ1 will start operating in RUN mode when the power is
turned on and if a BASIC program is set to Auto Run mode.
Caution
Before touching the system, be sure to first touch a grounded
metallic object in order to discharge any static build-up.
Otherwise it might result in a malfunction or damage.
Caution
Always check the “Status-Words” of each GRT1-ML2 coupler.
Not doing so can lead to missing or incorrect I/O data.
Caution
Always check the status of the connected MECHATROLINK-II
devices in a BASIC program.
Not doing so may result in an unexpected operation.
Caution
UTP cables are not shielded. In environments that are subject to
noise use a system with shielded twisted-pair (STP) cable and
hubs suitable for an FA environment.
Do not install twisted-pair cables with high-voltage lines.
Do not install twisted-pair cables near devices that generate noise.
Do not install twisted-pair cables in locations that are subject to
high humidity.
Do not install twisted-pair cables in locations subject to excessive
dirt and dust or to oil mist or other contaminants.
Caution
Use the dedicated connecting cables specified in operation manuals to connect the Units.
Using commercially available RS-232C computer cables may
cause failures in external devices or the Motion Control Unit.
Revision 5.0
Caution
Outputs may remain on due to a malfunction in the built-in transistor outputs or other internal circuits.
As a countermeasure for such problems, external safety measures
must be provided to ensure the safety of the system.
HARDWARE REFERENCE MANUAL
Caution
The TJ1-CORT unit is developed to exchange I/O data between
the Trajexia system and a CANopen network.
The TJ1-CORT is not able to exchange motion commands.
Using the TJ1-CORT to exchange motion commands may result in
unexpected operation.
1.6
Unit assembly precautions
Caution
Install the unit properly.
Improper installation of the unit may result in malfunction.
Caution
Be sure to mount the TJ1-TER supplied with the TJ1-MC__ to the
right most Unit.
Unless the TJ1-TER is properly mounted, the TJ1 will not function
properly.
5
Safety warnings and precautions
1.7
Conformance to EC Directives Conformance
1.7.1
Concepts
The concepts for the directives EMC and Low Voltage are as follows:
EMC Directives
OMRON devices that comply with EC Directives also conform to the related
EMC standards so that they can be more easily built into other devices or
machines. The actual products have been checked for conformity to EMC
standards. Whether the products conform to the standards in the system
used by the customer, however, must be checked by the customer.
EMC-related performance of the OMRON devices that comply with EC
Directives will vary depending on the configuration, wiring, and other
conditions of the equipment or control panel in which the OMRON devices
are installed. The customer must, therefore, perform final checks to confirm
that devices and the over-all machine conform to EMC standards.
Low Voltage Directive
Always ensure that devices operating at voltages of 50 to 1,000 VAC or 75 to
1,500 VDC meet the required safety standards.
1.7.2
Conformance to EC Directives
The Trajexia Motion Controllers comply with EC Directives.
To ensure that the machine or device in which a system is used complies
with EC directives, the system must be installed as follows:
1. The system must be installed within a control panel.
2. Reinforced insulation or double insulation must be used for the DC
power supplies used for the communications and I/O power supplies.
Revision 5.0
HARDWARE REFERENCE MANUAL
6
System philosophy
2
System philosophy
2.1
Introduction
The system philosophy is centred around the relationship between:
• System architecture
• Cycle time
• Program control and multi-tasking
• Motion sequence and axes
• Motion buffers
fig. 1
AXIS CONTROL LOOP
TJ1-MC__
Buffer &
profile
gererator
Program Buffer
A clear understanding of the relationship between these concepts is
necessary to obtain the best results for the Trajexia system.
AXIS TYPE
Position
Loop
TJ1-ML__
ENC
BASIC PROGRAMS
2.1.1
Glossary
All other
Servo
Drivers
Process 1
Servo Driver
Process 2
Process 3
Motion sequence
…
The Motion Sequence is responsible for controlling the position of the axes.
Comms
Position
Loop
Speed Loop
Process 14
Servo period
Defines the frequency at which the Motion Sequence is executed. The servo
period must be set according to the configuration of the physical axes. The
available settings are 0.5ms, 1ms or 2ms.
MOTOR
Torque
Loop
TJ1-FL02
MC I/O
ENC
Servo Driver
Ethernet
FINS
TJ1-PRT
Ethernet
Profibus
Speed Loop
Torque
Loop
MOTOR
Cycle time
Is the time needed to execute one complete cycle of operations in the TJ1MC__. The cycle time is divided in 4 time slices of equal time length, called
"CPU Tasks". The cycle time is 1ms if SERVO_PERIOD=0.5ms or
SERVO_PERIOD=1ms and 2ms if the SERVO_PERIOD=2ms.
BUILT-IN
Via
TJ1-ML16
CPU tasks
The operations executed in each CPU task are:
Revision 5.0
CPU task
Operation
First CPU task
Motion Sequence
Low priority process
HARDWARE REFERENCE MANUAL
7
System philosophy
CPU task
Operation
Second CPU task
High priority process
Third CPU task
Motion Sequence (only if SERVO_PERIOD=0.5ms)
LED Update
High priority process
Fourth CPU task
External Communications
Program
A program is a piece of BASIC code.
Process
Is a program in execution with a certain priority assigned. Process 0 to 12
are Low priority processes and Process 13 and 14 are High priority
processes. First the process priority, High or Low, and then the process
number, from high to low, will define to which CPU task the process will be
assigned.
2.2
Motion control concepts
The TJ1-MC__ offers these types of positioning control operations:
1. Point-to-Point (PTP) control
2. Continuous Path (CP) control
3. Electronic Gearing (EG) control.
This section introduces some of the commands and parameters used in the
BASIC programming of the motion control application.
Coordinate system
Positioning operations performed by the TJ1-MC__ are based on an axis
coordinate system. The TJ1-MC__ converts the position data from either the
connected Servo Driver or the connected encoder into an internal absolute
coordinate system.
Revision 5.0
The engineering unit that specifies the distances of travelling can be freely
defined for each axis separately. The conversion is performed through the
use of the unit conversion factor, which is defined by the UNITS axis
HARDWARE REFERENCE MANUAL
8
System philosophy
parameter. The origin point of the coordinate system can be determined
using the DEFPOS command. This command re-defines the current position
to zero or any other value.
A move is defined in either absolute or relative terms. An absolute move
takes the axis (A) to a specific predefined position with respect to the origin
point. A relative move takes the axis from the current position to a position
that is defined relative to this current position. The figure shows an example
of relative (command MOVE) and absolute (command MOVEABS) linear
moves.
fig. 2
MOVEABS(30)
MOVE(60)
MOVEABS(50)
MOVE(50)
MOVE(30)
0
2.2.1
50
100
A
PTP control
In point-to-point positioning, each axis is moved independently of the other
axis. The TJ1-MC__ supports the following operations:
• Relative move
• Absolute move
• Continuous move forward
• Continuous move reverse.
Revision 5.0
HARDWARE REFERENCE MANUAL
9
System philosophy
Relative and absolute moves
To move a single axis either the command MOVE for a relative move or the
command MOVEABS for an absolute move is used. Each axis has its own
move characteristics, which are defined by the axis parameters.
Suppose a control program is executed to move from the origin to an axis
no. 0 (A) coordinate of 100 and axis no. 1 (B) coordinate of 50. If the speed
parameter is set to be the same for both axes and the acceleration and
deceleration rate are set sufficiently high, the movements for axis 0 and axis
1 will be as shown in the figure.
At start, both the axis 0 and axis 1 moves to a coordinate of 50 over the
same duration of time. At this point, axis 1 stops and axis 0 continues to
move to a coordinate of 100.
fig. 3
B
MOVEABS(100) AXIS(0)
MOVEABS(50) AXIS(1)
50
0
50
A
100
The move of a certain axis is determined by the axis parameters. Some
relevant parameters are:
/i
Parameter
Description
UNITS
Unit conversion factor
ACCEL
Acceleration rate of an axis in units/s2
DECEL
Deceleration rate of an axis in units/s2
SPEED
Demand speed of an axis in units/s2
Defining moves
The speed profile in this figure shows a simple MOVE operation. Axis A is
the time, axis B is the speed. The UNITS parameter for this axis has been
defined for example as meters. The required maximum speed has been set
to 10 m/s. In order to reach this speed in one second and also to decelerate
to zero speed again in one second, both the acceleration as the deceleration
rate have been set to 10 m/s2. The total distance travelled is the sum of
distances travelled during the acceleration, constant speed and deceleration
segments. Suppose the distance moved by the MOVE command is 40 m,
the speed profile is given by the figure.
fig. 4
B
ACCEL=10
DECEL=10
SPEED=10
MOVE(40)
10
Revision 5.0
0
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1
2
3
4
5
6
A
10
System philosophy
The two speed profiles in these figures show the same movement with an
acceleration time respectively a deceleration time of 2 seconds. Again, Axis
A is the time, axis B is the speed.
fig. 5
B
ACCEL=5
DECEL=10
SPEED=10
MOVE(40)
10
0
1
2
3
4
5
6
A
fig. 6
B
ACCEL=10
DECEL=5
SPEED=10
MOVE(40)
10
0
1
2
3
4
5
6
A
Move calculations
The following equations are used to calculate the total time for the motion of
the axes.
• The moved distance for the MOVE command is D.
• The demand speed is V.
• The acceleration rate is a.
• The deceleration rate is d.
/i
Revision 5.0
Acceleration time
=
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System philosophy
Acceleration distance
=
Deceleration time
=
Deceleration distance
=
Constant speed distance
=
Total time
=
Continuous moves
The FORWARD and REVERSE commands can be used to start a
continuous movement with constant speed on a certain axis. The
FORWARD command moves the axis in positive direction and the
REVERSE command in negative direction. For these commands also the
axis parameters ACCEL and SPEED apply to specify the acceleration rate
and demand speed.
Both movements can be cancelled by using either the CANCEL or
RAPIDSTOP command. The CANCEL command cancels the move for one
axis and RAPIDSTOP cancels moves on all axes. The deceleration rate is
set by DECEL.
2.2.2
CP control
Revision 5.0
Continuous Path control enables to control a specified path between the
start and end position of a movement for one or multiple axes. The TJ1MC__ supports the following operations:
• Linear interpolation
• Circular interpolation
• CAM control.
HARDWARE REFERENCE MANUAL
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System philosophy
Linear interpolation
In applications it can be required for a set of motors to perform a move
operation from one position to another in a straight line. Linearly interpolated
moves can take place among several axes. The commands MOVE and
MOVEABS are also used for the linear interpolation. In this case the
commands will have multiple arguments to specify the relative or absolute
move for each axis.
Consider the three axis move in a 3-dimensional plane in the figure. It
corresponds to the MOVE(50,50,50) command. The speed profile of the
motion along the path is given in the diagram. The three parameters
SPEED, ACCEL and DECEL that determine the multi axis movement are
taken from the corresponding parameters of the base axis. The MOVE
command computes the various components of speed demand per axis.
A is the time axis, B is the speed axis.
fig. 7
2
1
3
B
A
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System philosophy
Circular interpolation
It may be required that a tool travels from the starting point to the end point
in an arc of a circle. In this instance the motion of two axes is related via a
circular interpolated move using the MOVECIRC command.
Consider the diagram in the figure. It corresponds to the MOVECIRC(100,0,-50,0,0) command. The centre point and desired end point of the
trajectory relative to the start point and the direction of movement are
specified. The MOVECIRC command computes the radius and the angle of
rotation. Like the linearly interpolated MOVE command, the ACCEL, DECEL
and SPEED variables associated with the base axis determine the speed
profile along the circular move.
CAM control
Additional to the standard move profiles the TJ1-MC__ also provides a way
to define a position profile for the axis to move. The CAM command moves
an axis according to position values stored in the TJ1-MC__ Table array.
The speed of travelling through the profile is determined by the axis
parameters of the axis.
The figure corresponds to the command CAM(0,99,100,20). A is the time
axis, B is the position axis.
fig. 8
50
-50
0
50
fig. 9
B
A
2.2.3
EG control
Revision 5.0
Electronic Gearing control allows you to create a direct gearbox link or a
linked move between two axes. The MC Unit supports the following
operations.
• Electronic gearbox
• Linked CAM
• Linked move
• Adding axes
HARDWARE REFERENCE MANUAL
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System philosophy
Electronic gearbox
The TJ1-MC__ is able to have a gearbox link from one axis to another as if
there is a physical gearbox connecting them. This can be done using the
CONNECT command in the program. In the command the ratio and the axis
to link to are specified.
In the figure, A is the Master axis, and B is the CONNECT axis.
/i
Axes
0
Ratio
CONNECT command
1:1
CONNECT(1,0) AXIS(1)
fig. 10
B
2:1
1:1
1:2
1
A
2:1
CONNECT(2,0) AXIS(1)
1:2
CONNECT(0.5,0) AXIS(1)
Revision 5.0
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System philosophy
Linked CAM control
Next to the standard CAM profiling tool the TJ1-MC__ also provides a tool to
link the CAM profile to another axis. The command to create the link is called
CAMBOX. The travelling speed through the profile is not determined by the
axis parameters of the axis but by the position of the linked axis. This is like
connecting two axes through a cam.
In the figure, A is the Master axis (0) position, and B is the CAMBOX Axis (1)
position.
fig. 11
B
A
Linked move
The MOVELINK command provides a way to link a specified move to a
master axis. The move is divided into an acceleration, deceleration and
constant speed part and they are specified in master link distances. This can
be particularly useful for synchronizing two axes for a fixed period.
The labels in the figure are:
A. Time axis.
B. Speed axis.
C. Master axis (1).
D. Synchronized.
E. MOVELINK axis (0).
fig. 12
B
C
D
E
A
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System philosophy
Adding axes
It is very useful to be able to add all movements of one axis to another. One
possible application is for instance changing the offset between two axes
linked by an electronic gearbox. The TJ1-MC__ provides this possibility by
using the ADDAX command. The movements of the linked axis will consists
of all movements of the actual axis plus the additional movements of the
master axis.
In the figure, A is the time axis and B is the speed axis.
fig. 13
B
BASE(0)
ADDAX(2)
FORWARD
MOVE(100) AXIS(2)
MOVE(-60) AXIS(2)
A
B
A
B
A
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System philosophy
2.2.4
Other operations
Cancelling moves
In normal operation or in case of emergency it can be necessary to cancel
the current movement from the buffers. When the CANCEL or RAPIDSTOP
commands are given, the selected axis respectively all axes will cancel their
current move.
Origin search
The encoder feedback for controlling the position of the motor is
incremental. This means that all movement must be defined with respect to
an origin point. The DATUM command is used to set up a procedure
whereby the TJ1-MC__ goes through a sequence and searches for the
origin based on digital inputs and/or Z-marker from the encoder signal.
Print registration
The TJ1-MC__ can capture the position of an axis in a register when an
event occurs. The event is referred to as the print registration input. On the
rising or falling edge of an input signal, which is either the Z-marker or an
input, the TJ1-MC__ captures the position of an axis in hardware. This
position can then be used to correct possible error between the actual
position and the desired position. The print registration is set up by using the
REGIST command.
The position is captured in hardware, and therefore there is no software
overhead and no interrupt service routines, eliminating the need to deal with
the associated timing issues.
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System philosophy
Merging moves
If the MERGE axis parameter is set to 1, a movement is always followed by
a subsequent movement without stopping. The figures show the transitions
of two moves with MERGE value 0 and value 1.
In the figure, A is the time axis and B is the speed axis.
fig. 14
B
MERGE=0
Jogging
Jogging moves the axes at a constant speed forward or reverse by manual
operation of the digital inputs. Different speeds are also selectable by input.
Refer to the FWD_JOG, REV_JOG and FAST_JOG axis parameters.
A
B
MERGE=1
A
2.3
Servo system principles
The servo system used by and the internal operation of the TJ1-MC__ are
briefly described in this section.
2.3.1
Semi-closed loop system
The servo system of the TJ1-MC__ uses a semi-closed or inferred closed
loop system. This system detects actual machine movements by the rotation
of the motor in relation to a target value. It calculates the error between the
target value and actual movement, and reduces the error through feedback.
Revision 5.0
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System philosophy
2.3.2
Internal operation of the TJ1-MC__
Inferred closed loop systems occupy the mainstream in modern servo
systems applied to positioning devices for industrial applications. The figure
shows the basic principle of the servo system as used in the TJ1-MC__.
1. The TJ1-MC__ performs actual position control. The main input of the
controller is the Following Error, which is the calculated difference
between the demand position and the actual measured position.
2. The Position Controller calculates the required speed reference output
determined by the Following Error and possibly the demanded position
and the measured position. The speed reference is provided to the
Servo Driver.
3. The Servo Driver controls the rotational speed of the servo motor
corresponding to the speed reference. The rotational speed is
proportional to the speed reference.
4. The rotary encoder generates the feedback pulses for both the speed
feedback within the Servo Driver speed loop and the position feedback
within the TJ1-MC__ position loop.
fig. 15
A
B
2
3
C
1
D
E
F
G
I
4
H
J
The labels in the figure are:
A. TJ1-MC__.
B. Servo system.
C. Demand position.
D. Position control.
E. Speed reference.
F. Speed control.
G. Motor.
H. Encoder.
I. Measured speed.
J. Measured position.
2.3.3
Motion control algorithm
Revision 5.0
The servo system controls the motor by continuously adjusting the speed
reference to the Servo Driver. The speed reference is calculated by the
motion control algorithm of the TJ1-MC__, which is explained in this section.
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System philosophy
The motion control algorithm uses the demand position (A), the measured
position (D) and the Following Error (B) to determine the speed reference.
The Following Error is the difference between the demanded and measured
position. The demand position, the measured position and the Following
Error are represented by the axis parameters MPOS, DPOS and FE. Five
gain values have been implemented for the user to be able to configure the
correct control operation for each application.
C is the output signal.
• Proportional gain
The proportional gain Kp creates an output Op that is proportional to the
Following Error E.
Op = Kp · E
All practical systems use proportional gain. For many just using this gain
parameter alone is sufficient. The proportional gain axis parameter is
called P_GAIN.
• Integral gain
The integral gain Ki creates an output Oi that is proportional to the sum
of the Following Errors that have occurred during the system operation.
Oi = Ki · ΣE
Integral gain can cause overshoot and so is usually used only on
systems working at constant speed or with slow accelerations. The
integral gain axis parameter is called I_GAIN.
• Derivative gain
The derivative gain Kd produces an output Od that is proportional to the
change in the Following Error E and speeds up the response to changes
in error while maintaining the same relative stability.
Od = Kd · ∆E
Derivative gain may create a smoother response. High values may lead
to oscillation. The derivative gain axis parameter is called D_GAIN.
• Output speed gain
The output speed gain Kov produces an output Oov that is proportional to
the change in the measured position Pm and increases system damping.
Oov = Kov · ∆Pm
fig. 16
Kvff ∑
Kp
A
B
C
Ki ∑
Kd ∆
Kov ∆
D
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System philosophy
•
The output speed gain can be useful for smoothing motions but will
generate high Following Errors. The output speed gain axis parameter is
called OV_GAIN.
Speed feed forward gain
The speed feedforward gain Kvff produces an output Ovff that is
proportional to the change in demand position Pd and minimizes the
Following Error at high speed.
Ovff = Kvff · ∆Pd
The parameter can be set to minimise the Following Error at a constant
machine speed after other gains have been set. The speed feed forward
gain axis parameter is called VFF_GAIN.
The default settings are given in the table along with the resulting profiles.
Fractional values are allowed for gain settings.
/i
Gain
Default value
Proportional gain
0.1
Integral gain
0.0
Derivative gain
0.0
Output speed gain
0.0
Speed feedforward gain
0.0
2.4
Trajexia system architecture
The system architecture of the Trajexia is dependant upon these
concepts:
• Program control
• Motion Sequence
• Motion buffers
• Communication
• Peripherals
Revision 5.0
These concepts depend upon the value set in the SERVO_PERIOD
parameter. The relationship between the value of SERVO_PERIOD and the
different concepts of the system architecture are describes as follows.
HARDWARE REFERENCE MANUAL
2.4.1
Program control
Programs make the system work in a defined way. The programs are written
in a language similar to BASIC and control the application of the axes and
modules. 14 Programs can be executed in parallel. The programs can be set
to run at system power-up, started and stopped from other programs and
executed from Trajexia Tools.
Programs execute commands to move the axes, control inputs and outputs
and make communication via BASIC commands.
2.4.2
Motion sequence
The motion sequence controls the position of all 16 axes with the actions as
follows:
• Reading the Motion buffer
• Reading the current Measured Position (MPOS)
• Calculating the next Demanded Position (DPOS)
• Executing the Position loop
• Sending the Axis reference
• Error handling
2.4.3
Motion buffers
Motion buffers are the link between the BASIC commands and the Axis
control loop. When a BASIC motion command is executed, the command is
stored in one of the buffers. During the next motion sequence, the profile
generator executes the movement according to the information in the buffer.
When the movement is finished, the motion command is removed from the
buffer.
2.4.4
Communication
All communication is carried out in the forth CPU task. A set of BASIC
communication commands are used to configure the communications.
When the Trajexia is a communication slave (as in the PROFIBUS
communication) it is only necessary to configure the communication in an
22
System philosophy
initial task. The values are exchanged from the configured global variables in
a transparent way. When the Trajexia is a communications master, the
BASIC communication commands are used to write and read.
2.4.5
Peripherals
All inputs and outputs are used with the set of parameters (IN, OP, AIN,
AOUT). The inputs and outputs are automatically detected and mapped in
Trajexia. Inverters are considered a peripheral device and have a set of
BASIC commands to control them. Various MECHATROLINK-II input and
output modules can be connected to a TJ1-ML__ unit.
2.5
Cycle time
All processes in the Trajexia system are based on the cycle time. The cycle
time is divided into four CPU tasks:
• 250µs time intervals for a SERVO_PERIOD of 0.5 and 1.0ms
• 500µs time intervals for a SERVO_PERIOD of 2.0ms
The processes that can be carried out in each time interval depends on the
SERVO_PERIOD that is set.
The operations executed in each CPU task are:
CPU task
Operation
First CPU task
Motion Sequence
Low priority process
Second CPU task
High priority process
Third CPU task
1
Fourth CPU task
External Communications
Motion Sequence (only if SERVO_PERIOD=0.5ms)
LED Update.
High priority process
fig. 17
250µs
1
3
2
4
Cycle time = 1ms
fig. 18
500 µs
1
2
3
4
Cycle time = 2 ms
Revision 5.0
Note
The Motion sequence execution depends on setting of the
SERVO_PERIOD parameter.
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System philosophy
2.5.1
Servo period
The SERVO_PERIOD can be set at 0.5, 1 or 2ms. The processes that take
place within the cycle time depend on the setting of the SERVO_PERIOD
parameter. The SERVO_PERIOD parameter is a Trajexia parameter that
must be set according to the system configuration.
The factory setting is 1ms (SERVO_PERIOD=1000). A change is set only
after a restart of the TJ1-MC__.
Note
Only the Sigma-III Servo Driver and the Sigma-V Servo Driver
support the 0.5 ms transmission cycle.
Example 1
The SERVO_PERIOD has a value of 0.5ms and the motion sequence is
executed every 0.5ms.
fig. 19
CPU task 1
Motion sequence
Low priority task (0,1,2,3...)
CPU task 2
High priority task (13,14)
CPU task 3
Motion sequence
LED refresh
High priority task (13,14)
CPU task 4
Communication
1ms
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System philosophy
Example 2
The SERVO_PERIOD has a value of 1ms and the motion sequence is
executed every 1ms. As the motion sequence is not executed during CPU
task 3, there is more time for the program execution. High priority programs
run faster.
fig. 20
CPU task 1
Motion sequence
Low priority task (0,1,2,3...)
CPU task 2
High priority task (13,14)
CPU task 3
LED refresh
High priority task (13,14)
CPU task 4
Communication
1ms
Example 3
The SERVO_PERIOD has a value of 2ms and the motion sequence is
executed every 2.0ms.
Servo period rules
The number of axes and MECHATROLINK-II devices in the Trajexia system
determines the value of the SERVO_PERIOD system parameter.
There are 3 types of MECHATROLINK-II devices that are supported by the
TJ1-MC__ units:
• Servo Drivers
The TJ1-MC__ considers Servo Drivers as axes.
• Inverters
The TJ1-MC__ does not consider Inverters as axes.
• I/O units and slice bus couplers
The TJ1-MC__ does not consider I/O units (analog and digital, counter
and pulse) and slice bus couplers as axes.
fig. 21
CPU task 1
Motion sequence
Low priority task (0,1,2,3...)
CPU task 2
High priority task (13,14)
CPU task 3
LED refresh
High priority task (13,14)
CPU task 4
Communication
2ms
Revision 5.0
You must obey the most restrictive rules when you set the SERVO_PERIOD
parameter. An incorrect value of the SERVO_PERIOD parameter results in
an incorrect detection of the MECHATROLINK-II devices.
The most restrictive rules are given in the tables below. For each unit the
table lists the maximum number of devices the unit can control at the given
SERVO_PERIOD setting.
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System philosophy
/i
SERVO_PERIOD
TJ1-MC16
TJ1-MC04
TJ1-ML16
TJ1-ML04
0.5 ms
8 axes
5 axes
4 devices
4 devices
4 non-axis
devices
4 non-axis
devices
16 axes
5 axes
8 devices
4 devices
8 non-axis
devices
8 non-axis
devices
16 axes
5 axes
16 devices
4 devices
8 non-axis
devices
8 non-axis
devices
1.0 ms
2.0 ms
Configuration examples
Example 1
•
•
•
•
1x TJ1-MC__
1x TJ1-ML__
3x Sigma-II Servo Driver
SERVO_PERIOD = 1ms
fig. 22
Servo Driver
TJ1-MC__ Supports 0.5ms SERVO_PERIOD with 3 axes.
TJ1-MC__ Supports 0.5ms SERVO_PERIOD with 3 devices.
Sigma-II supports 1ms SERVO_PERIOD. This is the limiting factor.
Address
43
Address
44
Address
45
Terminator
Revision 5.0
Axis 2
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Axis 3
Axis 4
26
System philosophy
Example 2
•
•
•
•
1x TJ1-MC16
2x TJ1-ML16
16x Sigma-II Servo Driver
SERVO_PERIOD = 1ms
fig. 23
Servo Drive
TJ1-MC16 supports 1ms SERVO_PERIOD with 16 axes.
TJ1-ML16 supports 1ms SERVO_PERIOD with 8 devices.
Sigma-II supports 1ms SERVO_PERIOD.
Address Address Address Address Address Address Address Address
41
42
43
44
45
46
47
48
Terminator
Axis 0
Axis 1
Axis 2
Axis 3
Axis 4
Axis 5
Axis 6
Axis 7
Address Address Address Address Address Address Address Address
49
4A
4B
4C
4D
4E
4F
50
Terminator
Axis 8
Axis 9
Axis 10
Axis 11
Axis 12
Axis 13
Axis 14
Axis 15
Revision 5.0
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System philosophy
Example 3
•
•
•
•
•
•
1x TJ1-MC16
1x TJ1-ML16
8x Sigma-II Servo Driver
1x F7Z Inverter with SI-T interface
3x MECHATROLINK-II I/Os
SERVO_PERIOD = 2.0ms
TJ1-ML16 supports 2.0ms SERVO_PERIOD with 12 devices. This is the
limiting factor.
Sigma-II supports 1.0ms SERVO_PERIOD.
SI-T supports 1ms.
MECHATROLINK-II I/Os support 1.0ms.
fig. 24
Address
21
Address Address Address
61
62
63
Address Address Address Address Address Address Address Address
41
42
43
44
45
46
47
48
0
31 32
95 96
159 160
Example 4
I/O Memory Allocations
•
•
•
•
•
•
1x TJ1-MC16
1x TJ1-ML16
2x TJ1-FL02
1x TJ1-PRT (does not influence in the SERVO_PERIOD)
5x Sigma-II Servo Driver
SERVO_PERIOD = 1.0ms
TJ1-MC16 supports 1.0ms SERVO_PERIOD with 9 axes (5
MECHATROLINK-II servo axes and 4 TJ1-FL02 axes)
TJ1-ML16 supports 1.0ms SERVO_PERIOD with 5 devices
TJ1-FL02 supports 0.5ms SERVO_PERIOD (2 axes each module)
Sigma-II supports 1.0ms SERVO_PERIOD.
Revision 5.0
HARDWARE REFERENCE MANUAL
fig. 25
Axis 7
Axis 8
Axis 0
Axis 1
Address
43
Address
44
Address
45
Address
46
Address
47
Axis 2
Axis 3
Axis 4
Axis 5
Axis 6
28
System philosophy
2.6
Program control and multi-tasking
The Trajexia system has program, processes and multi tasking control.
2.6.1
Program control
The Trajexia system can control 14 processes that are written as BASIC
programs. When the program is set to run, the program is executed.
Processes 1 to 12 are low priority, 13 and 14 are high priority.
2.6.2
Processes
The low-priority process 0 is reserved for the "Terminal Window" of Trajexia
Tools. This terminal window is used to write direct BASIC commands to the
TJ1-MC__ independent to other programs. These commands are executed
after you press the Enter button.
2.6.3
Multi-tasking
Each cycle time is divided into 4 time slices called CPU tasks. Processes run
in the first 3 CPU tasks according to the priority of the process.
Motion sequence and low-priority processes (A) are executed in the Low
Task (LT) period.
High priority processes (B) are executed in the high Task (HT) periods.
fig. 26
LT
HT #1
HT #2
COMS.
Cycle time
External communication that are not related to the motion network are
updated in the communications (COMS) period in the fourth CPU task.
Trajexia can control up to 14 programs at the same time.
In contrast to low priority processes, a high priority process is always
available for execution during two of the four CPU tasks. The high-priority
tasks are executed faster than the low-priority tasks, it is that they have more
time available for their execution. All the low-priority tasks must share one
slot of time and the high-priority task have their own two slots of time.
fig. 27
A
B
LT
HT #1
HT #2
COMS.
Revision 5.0
Cycle time
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System philosophy
2.6.4
Multi-tasking example
In the example 1, there are two high-priority processes, 13 and 14. The two
HT periods are reserved for these processes, one for processes 13 and one
for processes 14. The low-priority processes 3, 2, 1 and 0 are executed in
the LT period, one process per Cycle time here set to 1.0ms.
1
In the middle example, there is only one high-priority process, 14. Both HT
3
periods are reserved for this process. The low-priority processes, 3, 2, 1 and
0 are executed in the LT period, one process per cycle time.
In the lower example, there are no high-priority processes. Therefore, the
2
HT periods can be used for the low-priority processes. The LT period is also
3
used for the low-priority processes.
fig. 28
1ms
COMS.
2
COMS.
2
13
14
1ms
2
1
COMS.
1
COMS.
0 (c/l)
3
13
14
COMS.
0 (c/l) 14
COMS.
0 (c/l)
14
1ms
2
COMS.
1
0 (c/l)
13
COMS.
1ms
14
1ms
1
1ms
1ms
14
1ms
3
COMS.
1ms
14
3
2.7
13
14
1ms
1ms
COMS.
1ms
3
COMS.
2
1
0 (c/l)
COMS.
Motion sequence and axes
Motion sequence is the part of the TJ1-MC__ that controls the axes. The
actual way that the motion sequence operates depends on the axis type.
The axis type can be set and read by the parameter ATYPE. At start-up the
Trajexia system automatically detects the configuration of the axes.
• The default value for the parameter ATYPE for MECHATROLINK-II axes
is 41 (MECHATROLINK-II speed).
• The default value for the parameter ATYPE for the TJ1-FL02 axes is 44
(Servo axis with an incremental encoder).
All non allocated axes are set as a virtual axis. The value for the parameter
ATYPE is 0.
Every axis has the general structure as shown in fig. 29.
Revision 5.0
The motion sequence which will be executed at the beginning of each servo
period will contain the following elements:
HARDWARE REFERENCE MANUAL
fig. 29
•
block
•
Servo Drive
AXIS PARAMETER
OFF
Position loop
Speed loop
+
Profile generator
ON
Demanded
position
Measured
position
Following
error
Torque
loop
M
Speed
command
E
30
System philosophy
1. Transfer any moves from BASIC process buffers to motion buffers (see
section 2.8).
2. Read digital inputs.
3. Load moves. (See note.)
4. Calculate speed profile. (See note.)
5. Calculate axis positions. (See note.)
6. Execute position servo. For axis 0 this also includes the Servo Driver
communications. (See note.)
7. Update outputs.
Note
Each of these items will be performed for each axis in turn before
moving on to the next item.
2.7.1
Profile generator
The profile generator is the algorithm that calculates the demanded position
for each axis. The calculation is made every motion sequence.
The profile is generated according to the motion instructions from the BASIC
programs.
fig. 30
Basic Program
.........
.........
MOVE(1000)
.........
.........
Profile generator
Demand Position
2.7.2
Position loop
The position loop is the algorithm that makes sure that there is a minimal
deviation between the measured position (MPOS) and the demand position
(DPOS) of the same axis.
2.7.3
•
Axis sequence
Revision 5.0
The motion controller applies motion commands to an axis array that is
defined with the BASE command. If the motion command concerns one
axis, it is applied to the first axis in the BASE array. If the motion
command concerns more than one axis, and makes an orthogonal
HARDWARE REFERENCE MANUAL
31
System philosophy
•
•
move, the axes are taken from the array in the order defined by the
BASE command. For more information on the BASE command and the
definition of the axis sequence in an axis array, refer to the Trajexia
Programming Manual, chapter 3 (BASIC commands).
If SERVO=OFF for one axis, the motion commands for that axis are
ignored.
If the Following Error (FE) in one axis exceeds the parameter value
FELIMIT, the next action occurs:
- WDOG is set to OFF and all axes stop.
- SERVO for the axis that causes the error goes to OFF.
- The current move is cancelled and removed from the buffer.
2.7.4
Type of axis
/i
ATYPE Applicable to
Name
Description
0
All axes
Virtual axis
Internal axis with no physical output. It is the
only valid setting for non-allocated axes. That
is, those that are not MECHATROLINK-II servos or a flexible axis.
40
MECHATROLINK-II Servo
Drivers connected to a TJ1ML__
MECHATROLINK-II Position
Position loop in the Servo Driver. TJ1-MC__
sends position reference to the Servo Driver
via MECHATROLINK-II.
41
42
MECHATRO- Position loop in the Trajexia. TJ1-MC__ sends
LINK-II Speed speed reference to the Servo Driver via
MECHATROLINK-II.
(Default)
MECHATRO- Position loop in the Trajexia. TJ1-MC__ sends
LINK-II Torque torque reference to the Servo Driver via
MECHATROLINK-II.
Revision 5.0
HARDWARE REFERENCE MANUAL
32
System philosophy
ATYPE Applicable to
Name
43
Stepper output Pulse and direction outputs. Position loop is in
the driver. TJ1-FL02 sends pulses and receives
no feed back.
External driver
connected to a
TJ1-FL02
Description
44
Servo axis
(Default)
Encoder
Analogue servo. Position loop is in the TJ1MC__. The TJ1-FL02 sends speed reference
and receives position from an incremental
encoder.
45
Encoder output
The same as stepper, but with the phase differential outputs emulating an incremental
encoder.
46
Absolute Tam- The same as servo axis but the feed back is
agawa
received from a Tamagawa absolute encoder.
47
Absolute
EnDat
The same as servo axis but the feed back is
received from an EnDat absolute encoder.
48
Absolute SSI
The same as servo axis but the feed back is
received from an SSI absolute encoder.
Inverter as
axis
Inverters (with built-in encoder interface) are
controlled on the MECHATROLINK-II bus as
servo axes.
49
ML__
Virtual axis ATYPE=0
You can split a complex profile into two or more simple movements, each
assigned to a virtual axis. These movements can be added together with the
BASIC command ADDAX then assigned to a real axis.
fig. 31
Profile generator
MEASURED
POSITION
=
DEMAND
POSITION
Revision 5.0
HARDWARE REFERENCE MANUAL
33
System philosophy
MECHATROLINK-II position ATYPE=40
With SERVO = ON, the position loop is closed in the Servo Driver. Gain
settings in the TJ1-MC__ have no effect. The position reference is sent to
the Servo Driver.
Note
Although MPOS and FE are updated, the real value is the value in
the Servo Driver. The real Following Error can be monitored by the
DRIVE_MONITOR parameter by setting DRIVE_CONTROL = 2.
fig. 32
TJ1-MC__
TJ1-ML__
SERVO = OFF
SERVO
SERVO = OFF
ML-II
Position
command
Profile generator
Position Loop
Speed Loop
Torque Loop
Position loop
Note
The MECHATROLINK-II position ATYPE = 40 is the recommended setting to obtain a higher performance of the servo motor.
Trajexia
Position Loop is
deactivated
(Gains are not
used!)
+
_
Demanded
position
Following
error
Speed
command
Measured
position
M
E
MECHATROLINK-II speed ATYPE=41
With SERVO = ON, the speed loop is closed in the TJ1-MC__.
Speed reference is sent to the Servo Driver. This setting is not
recommended, since there is one cycle delay in the loop (DPOS(n) is
compared with MPOS(n-1)).
With SERVO = OFF, the speed reference is sent via S_REF command.
0x40000000 means maximum speed of the servomotor. This is the
recommended setting.
fig. 33
TJ1-ML__
TJ1-MC__
SERVO = OFF
Position loop
SERVO = OFF
ML-II
Speed
command
+
_
Profile generator
Demanded
position
Following
error
SERVO
Speed Loop
Torque Loop
Speed
command
Measured
position
Revision 5.0
E
HARDWARE REFERENCE MANUAL
M
34
System philosophy
MECHATROLINK-II torque ATYPE=42
With SERVO = ON, the torque loop is closed in the TJ1-MC__. The torque
reference in the Servo Driver depends on the FE and the gain.
With SERVO = OFF, the torque reference is sent directly via the T_REF
command. 0x40000000 is the maximum torque of the servomotor.
Note
To monitor the torque in the servo in DRIVE_MONITOR, set
DRIVE_CONTROL=11.
fig. 34
TJ1-MC__
SERVO = OFF
TJ1-ML__
Position loop
SERVO = OFF
ML-II
Torque
command
+
Profile generator
_
Demanded
position
Following
error
SERVO
Torque Loop
Torque
command
Measured
position
E
M
Stepper output ATYPE=43
The position profile is generated and the output from the system is a pulse
train and direction signal. This is useful to control a motor via pulses or as a
position reference for another motion controller.
Revision 5.0
HARDWARE REFERENCE MANUAL
35
System philosophy
Servo axis ATYPE=44
With SERVO = ON this is an axis with an analogue speed reference output
and incremental encoder feedback input. The position loop is closed in the
TJ1-MC__ which sends the resulting speed reference to the axis.
fig. 35
TJ1-MC__
TJ1-FL02
DRIVE
_ 10V
+
SERVO = OFF
Position loop
SERVO = OFF
+
_
Profile generator
Demanded
Position
Following
Error
Speed
Command
Measured
Position
Encoder Signal
E
With SERVO = OFF, the position of the external incremental encoder is
read. The analogue output can be set with BASIC commands only and can
be used for general purposes.
M
fig. 36
TJ1-FL02
TJ1-MC__
Measured
Position
Revision 5.0
HARDWARE REFERENCE MANUAL
36
System philosophy
Encoder output ATYPE=45
The position profile is generated and the output from the system is an
incremental encoder pulse. This is useful to control a motor via pulses or as
a position reference for another motion controller.
fig. 37
TJ1-FL02
Profile generator
AXIS 1
ATYPE = 45
Demanded
position
Absolute Tamagawa encoder ATYPE=46
With SERVO = ON, this is an axis with analogue speed reference output and
absolute Tamagawa encoder feedback. The position loop is closed in the
TJ1-MC__ and the resulting speed reference is sent to the axis.
With SERVO = OFF, the position of the external absolute Tamagawa
encoder is read. The analogue output can be set with BASIC commands
only and can be used for general purposes.
See fig. 35 for reference.
Absolute EnDat encoder ATYPE=47
With SERVO = ON, this is an axis with analogue speed reference output and
absolute EnDat encoder feedback. The position loop is closed in the TJ1MC__ and the resulting speed reference is sent to the axis.
With SERVO = OFF, the position of the external absolute EnDat encoder is
read. The analogue output can be set with BASIC commands only and can
be used for general purposes.
See fig. 35 for reference.
Revision 5.0
HARDWARE REFERENCE MANUAL
37
System philosophy
Absolute SSI encoder ATYPE=48
With SERVO = ON, this is an axis with analogue speed reference output and
absolute SSI encoder feedback. The position loop is closed in the TJ1-MC__
and the resulting speed reference is sent to the axis.
With SERVO = OFF, the position of the external absolute SSI encoder is
read. The analogue output can be set with BASIC commands only and can
be used for general purposes.
See fig. 35 for reference.
Inverter axis ATYPE=49
This type allows Inverters (with built-in encoder interface) to be controlled on
the MECHATROLINK-II bus as servo axes.
From the controller point of view, Inverter axes are handled the same as
servo axes in MECHATROLINK-II Speed Mode (ATYPE=44).
Unlike the other axis types, this Inverter axis must be defined
programmatically with function 8 of the command INVERTER_COMMAND.
fig. 38
TJ1-ML__
TJ1-MC__
SERVO = OFF
Position loop
SERVO = OFF
ML-II
Speed
command
+
The Speed command to the Inverter and the feedback from the encoder is
refreshed in the Inverter every 5 ms. This is a DPRAM limitation. This means
that the use of the Inverter is similar to the use of a Servo Driver, but the
performance is lower.
Summary of axis types and control modes
_
Profile generator
Demanded
position
Following
error
INVERTER
Speed Loop
Speed
command
Measured
position
DPRAM
REFRESH
EVERY 5ms
The following table lists the axis types and their recommended modes for
speed control, position control and torque control.
/i
E
ATYPE SERVO Mode
Comment
Revision 5.0
40
OFF
Position
The position loop is closed in the Servo Driver.
(MECHATROLINK-II) No new motion command is allowed.
40
ON
Position
Recommended mode for position control with
(MECHATROLINK-II) MECHATROLINK-II axes.
41
OFF
Speed
Recommended mode for speed control with
(MECHATROLINK-II) MECHATROLINK-II axes. Set the speed with
S_REF.
HARDWARE REFERENCE MANUAL
M
38
System philosophy
ATYPE SERVO Mode
Comment
41
ON
Position
The position loop is closed in Trajexia. This
(MECHATROLINK-II) gives lower performance than closing the position loop in the Servo Driver.
42
OFF
Torque
Recommended mode for torque control with
(MECHATROLINK-II) MECHATROLINK-II axes. Set the torque with
T_REF.
42
ON
Position via torque
The position loop is closed in Trajexia. The out(MECHATROLINK-II) put of the position loop is sent as the torque reference to the Servo Driver.
44, 46,
47, 48
OFF
Speed
(Flexible Axis)
Recommended mode for speed control with
Flexible Axis.
44, 46,
47, 48
ON
Position
(Flexible Axis)
The position loop is closed in Trajexia. Recommended mode for position control with Flexible
Axis.
49
OFF
Speed
Inverter (with built-in encoder interface) controlled on the MECHATROLINK-II bus as a servo
axis. Set the speed with S_REF.
49
ON
Position
Inverter (with built-in encoder interface) controlled on the MECHATROLINK-II bus as a servo
axis. The position loop is closed in Trajexia.
Revision 5.0
HARDWARE REFERENCE MANUAL
39
System philosophy
2.8
Motion buffers
The motion buffer is a temporary store of the motion instruction from the
BASIC program to the profile generator.
The BASIC program continues while the instruction waits in the buffer.
There are three types of buffer:
• MTYPE. The current movement that is being executed. MTYPE relates
to the axis and not to the process.
• NTYPE. The new movement that waits for execution. NTYPE relates to
the axis and not to the process.
• Process Buffer. The third buffered movement cannot be monitored. The
process buffer relates to the process and not to the axis.
It is possible to check if the process buffer is full by checking the PMOVE
process parameter.
fig. 39
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
CONNECT(1,1)
AXIS BUFFER
(one per axis)
CONNECT(1,1) AXIS(2)
NTYPE
Waiting to be executed
MOTION COMMAND
MTYPE
Currently executed
MOTION COMMAND
PROCESS BUFFER
.......
DEMAND
POSITION
Profile generator
When a motion instruction is executed in the BASIC program, the instruction
is loaded into the process buffer and distributed to the corresponding axis
buffer in the next motion sequence.
If a fourth motion instruction is executed and the three buffers are full, the
BASIC program stops execution until a process buffer is free for use.
Example of buffered instructions:
fig. 40
Process 1
Process Buffer
Process 2
Process Buffer
Axis 0
Process 3
Process Buffer
Axis 1
Process 4
Process Buffer
Axis 2
Process 5
Process Buffer
Process 6
Process Buffer
Process 7
Process Buffer
Process 14
Program
Axis 3
WAITING
EXECUTING
NTYPE
MTYPE
NTYPE
MTYPE
NTYPE
MTYPE
NTYPE
MTYPE
NTYPE
MTYPE
Axis 15
Buffer
Each process has its own
“Process Buffer”
Each Axis has its own
2 buffers: NTYPE & MTYPE
Revision 5.0
HARDWARE REFERENCE MANUAL
40
System philosophy
fig. 41
EXAMPLE:
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DATUM(3)
.......
MOVE(200)
.......
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DATUM(3)
.......
MOVE(200)
.......
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DATUM(3)
.......
MOVE(200)
.......
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DATUM(3)
.......
MOVE(200)
.......
BUFFER
--------------------------------NTYPE IDLE
--------------------------------MTYPE MOVE(-500)
----
1.- All buffers are empty
and a movement is
loaded. The movement
starts to execute
.
MOVE -500
BUFFER
-----------------------------------NTYPE MOVE(1000)
--------------------------------MTY PE MOVE(-500)
2.- A second movement is
loaded while the first one
is not finished.
The new movement waits in the
second buffer.
MOVE -500
BUFFER
DATUM(3)
--------------------------------NTYPE MOVE(1000)
--------------------------------MTYPE MOVE(-500)
3.- A third movement can
still be stored in the process bu
If the basic program reaches
‘MOVE(200)’ it will wait.
MOVE -500
BUFFER
MOVE(200)
--------------------------------NTYPE DATUM(3)
--------------------------------MTYPE MOVE(1000)
4.- The first movement has
finished. The buffer moves
by one position .
The next movement starts to
execute.
MOVE -500
MOVE 1000
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DATUM(3)
.......
MOVE(200)
.......
BUFFER
-------------------------------------NTYPE MOVE(200)
--------------------------------MTYPE DATUM(3)
DATUM (3)
MOVE -500
5.- As the sent
movements are finished,
the buffer empties.
MOVE 1000
BASIC PROGRAM
.......
MOVE(-500)
.......
MOVE(1000)
.......
DAT UM(3)
.......
MOVE(200)
.......
BUFFER
-------------------------------------NT YPE IDLE
--------------------------------MT YPE MOVE(200)
DAT UM (3) MOVE 200
MOVE -500
MOVE 1000
6.- If no new movements
are executed,finally, the
buffer will become empty
and the profile generator
becomes inactive.
Revision 5.0
HARDWARE REFERENCE MANUAL
41
System philosophy
2.9
Mechanical system
2.9.1
Inertia ratio
The inertia ratio is a stability criterion. The higher the intertia of the load in
relation to the intertia of the motor, the lower the gains you can set in your
system before you reach oscillation, and the lower the performance you can
reach.
With a ratio of 1:30 for small Servo Drivers and a ratio of 1:5 for big Servo
Drivers you can reach the maximum dynamic of the motor-driver
combination.
2.9.2
Rigidity
If a machine is more rigid and less elastic, you can set higher gains without
vibration, and you can reach higher dynamic and lower Following Error.
2.9.3
Resonant frequency
A mechanical system has at least one resonant frequency. If you excite your
mechanical system to the resonant frequency, it starts oscillating. For motion
systems, it is best to have mechanical systems with a very high resonant
frequency, that is, with low inertia and high rigidity.
The resonant frequency of the mechanical system is the limit for the gain
settings.
Revision 5.0
HARDWARE REFERENCE MANUAL
42
Hardware reference
3
Hardware reference
3.1
Introduction
Trajexia is OMRON's motion platform that offers you the performance and
the ease of use of a dedicated motion system.
fig. 1
CJ-series PLC
Trajexia is a stand-alone modular system that allows maximum flexibility and
scalability. At the heart of Trajexia lies the TJ1 multi-tasking motion
coordinator. Powered by a 32-bit DSP, it can do motion tasks such as e-cam,
e-gearbox, registration control and interpolation, all via simple motion
commands.
Trajexia offers control of up to 16 axes over a MECHATROLINK-II motion
bus or traditional analogue or pulse control with independent position, speed
or torque control for every axis. And its powerful motion instruction set
makes programming intuitive and easy.
You can select from a wide choice of best-in-class rotary, linear and directdriver servos as well as Inverters. The system is scalable up to 16 axes and
8 Inverters & I/O modules.
3.1.1
NS-series HMI
CX-one
Trajexia Tools
PROFIBUS-DP
Master
DEVICENET
Master
CANopen
Master
Ethernet
Digital I/O
Hostlink
MECHATROLINK-II
Trajexia High-Lights
The main high-lights of the trajexia system are as follows:
Direct connectivity via Ethernet
Trajexia's Ethernet built-in connector provides direct and fast connectivity to
PCs, PLCs, HMIs and other devices while providing full access to the drivers
over a MECHATROLINK-II motion bus. It allows explicit messaging over
Ethernet and through MECHATROLINK-II to provide full transparency down
to the actuator level, and making remote access possible.
Revision 5.0
Keep your know-how safe
Trajexia's encryption method guarantees complete protection and
confidentiality for your valuable know-how.
HARDWARE REFERENCE MANUAL
43
Hardware reference
Serial Port and Local I/Os
A serial connector provides direct connectivity with any OMRON PLC, HMIs
or any other field device. 16 Inputs and 8 outputs are freely configurable
embedded I/Os in the controller to enable you to tailor Trajexia to your
machine design.
MECHATROLINK-II Master
The MECHATROLINK-II master performs control of up to 16 servos,
Inverters or I/Os while allowing complete transparency across the whole
system.MECHATROLINK-II offers the communication speed and time
accuracy essential to guarantee perfect motion control of servos. The
motion cycle time is selectable between 0.5 ms, 1 ms or 2 ms.
TJ1-FL02 (Flexible Axis Unit)
The TJ1-FL02 allows full control of two actuators via an analogue output or
pulse train. The module supports the main absolute encoder protocols
allowing the connection of an external encoder to the system.
Drives and Inverters
A wide choice of rotary, linear and direct-driver servos as well as Inverters
are available to fit your needs in compactness, performance and reliability.
The Inverters connected to the MECHATROLINK-II are driven at the same
update cycle time as the Servo Drivers.
Remote I/Os
The I/Os on the MECHATROLINK-II motion bus provide for system
expansion while keeping the devices under one motion bus.
PROFIBUS-DP
The PROFIBUS-DP slave allows connectivity to the PROFIBUS network in
your machine.
DeviceNet
Revision 5.0
The DeviceNet slave allows connectivity to the DeviceNet network in your
machine.
HARDWARE REFERENCE MANUAL
44
Hardware reference
CANopen
The CANopen master allows connectivity to the CANopen network in your
machine.
3.1.2
Trajexia Studio
One software
fig. 2
Trajexia's intuitive and easy programming tool, based on the Motion BASIC
instruction set, includes dedicated commands for linking axes, e-cams, egearboxes etc. Multi-tasking provides flexibility in application design. The
motion commands are "buffered" so the BASIC programs are executed
while motion movements are executed.
One connection
The parameters and functions inside the drivers on the MECHATROLINK-II
are fully accessible from the Ethernet connection.
One minute
Trajexia Studio includes advanced debugging tools, including trace and
oscilloscope functions, to ensure efficient operation and minimum downtime.
The servos, Inverters and I/Os connected to the MECHATROLINK-II motion
bus are automatically identified and configured, allowing you to set up your
system in minutes.
3.1.3
This manual
This Hardware Reference Manual gives the dedicated information for:
• The description, connections and use of the Trajexia units
• The description, connections and use of the MECHATROLINK-II slaves
• A detailed philosophy of the system design to obtain the best results for
Trajexia
Revision 5.0
HARDWARE REFERENCE MANUAL
45
Hardware reference
3.2
All units
3.2.1
System installation
A Trajexia system consists of these units:
• A Power Supply Unit.
• A TJ1-MC__ (Motion Controller Unit). This can be one of these:
- TJ1-MC16. It supports 16 real or virtual axes, and 16 axes in total.
- TJ1-MC04. It supports 5 real and up to 16 virtual axes, 16 axes in
total.
• Up to 7 expansion units.
• A TJ1-TER (Terminator Unit).
fig. 3
The expansion units (unit numbers 0-6) can be arranged in any order. The
TJ1-MC__ autodetects all units.
A Trajexia system with a TJ1-MC16 can include:
• 0 to 4 TJ1-ML__ units (MECHATROLINK-II Master Unit).
• 0 to 7 TJ1-FL02 units.
• 0 or 1 TJ1-PRT (PROFIBUS-DP Slave Unit) or TJ1-DRT units
(DeviceNet Slave Unit)1.
• 0 or 1 TJ1-CORT units (CANopen Master Unit).
Unit number: -1
0
1
2
3
4
5
6
A Trajexia system with a TJ1-MC04 can include:
• 0 to 4 TJ1-ML__ units.
• 0 to 3 TJ1-FL02 units.
• 0 or 1 TJ1-PRT or TJ1-DRT units1.
• 0 or 1 TJ1-CORT units.
Revision 5.0
1. Trajexia does not support both a TJ1-PRT and a TJ1-DRT unit in the same
system.
HARDWARE REFERENCE MANUAL
46
Hardware reference
The figure is an example of a simple configuration.
A. Power supply
B. TJ1-MC__.
C. TJ1-ML__.
D. Sigma-II Servo Driver
E. NS115 MECHATROLINK-II Interface Unit.
F. Sigma-II servo motor
G. TJ1-TER.
fig. 4
A
B
C
G
MC
16
OMRON
MOT
ION CON
TROLLE
R
0
1
2
3
4
5
6
7
ML16
RUN
CN3
8F
CN1
TER
M
ON/OF
F
CN1
WIR
E
2/4
CN2
F
D
E
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HARDWARE REFERENCE MANUAL
47
Hardware reference
1. Remove all the units from the packaging. Make sure all units are
complete.
2. Do not remove the protection labels from the units.
3. To disconnect the TJ1-MC__ and the TJ1-TER, push the clips (A) on top
and bottom of the TJ1-TER to the front.
4. Disconnect the TJ1-TER from the TJ1-MC__.
fig. 5
A
MC
16
OMRO
MOTIO N
N CON
TROLLE
R
0
1
2
3
4
5
6
7
CN3
CN1
TERM
ON/OF
F
WIR
E
2/4
CN2
5. Push the clips (A) on top and bottom of all the units to the front.
fig. 6
A
MC1
6
OMRO
MOTIO N
N CO
NTRO
LLER
0
1
2
3
4
5
6
7
CN3
CN1
TERM
ON/O
FF
WIRE
2/4
CN2
Revision 5.0
HARDWARE REFERENCE MANUAL
48
Hardware reference
6. Attach the TJ1-MC__ (C) to the Power Supply Unit (B).
fig. 7
B
MC1
C
6
OMRO
MOTIO N
N CO
NTRO
LLER
0
1
2
3
4
5
6
7
CN3
CN1
TERM
ON/O
FF
WIRE
2/4
CN2
7. Push the clips (A) on top and bottom to the rear.
fig. 8
A
MC
16
OMRO
MOTIO N
N CO
NTROLL
ER
0
1
2
3
4
5
6
7
CN3
CN1
TERM
ON/OF
F
WIRE
2/4
CN2
Revision 5.0
HARDWARE REFERENCE MANUAL
49
Hardware reference
8. Repeat the previous two steps for all other units.
9. Make sure the last unit is the TJ1-TER.
fig. 9
A
MC
16
OMRO
MOTIO N
N CON
TROLLE
R
0
1
2
3
4
5
6
7
ML16
RUN
CN3
8F
CN1
TER
M
ON/OF
CN1
F
WIR
E
2/4
CN2
10. Pull down all the clips (D) on all units.
11. Attach the Trajexia system to the DIN rail in an upright position to
provide proper cooling. The recommended DIN rail is of type PFP100N2, PFP-100N or PFP-50N.
12. Push all the clips (D) up on all units.
13. After you complete the wiring of the units, remove the protection labels
from the units.
fig. 10
D
MC
16
OMRON
MOT
ION CON
TROLLE
R
0
1
2
3
4
5
6
7
ML16
RUN
CN3
8F
CN1
TER
M
ON/OF
F
CN1
WIR
E
2/4
CN2
Revision 5.0
HARDWARE REFERENCE MANUAL
50
Hardware reference
fig. 11
CN2
WIRE
2/4
TERM
ON/OFF
14. Do not install the Trajexia units in one of these positions:
•
Upside down.
•
With the top side forward.
•
With the bottom forward.
•
Vertically.
CN1
CN3
CN1
MOTION CONTROLLER
OMRON
0
1
2
3
4
5
6
7
8F
RUN
ML16
8F
WIRE
2/4
CN3
MOTION CONTROLLER
OMRON
MC16
0
1
2
3
4
5
6
7
CN1
TERM
ON/OFF
CN2
ML16
RUN
CN1
MC16
Revision 5.0
HARDWARE REFERENCE MANUAL
51
Hardware reference
15. When you design a cabinet for the units, make sure that the cabinet
allows at least 20 mm of space around the units to provide sufficient
airflow. We advise to allow at least 100 mm of space around the units.
3.2.2
fig. 12
Environmental and storage for all units
/i
Revision 5.0
Item
Specification
Ambient operating temperature
0 to 55°C
Ambient operating humidity
10 to 90% RH. (with no condensation)
Ambient storage temperature
-20 to 70°C (excluding battery)
Ambient storage humidity
90% max. (with no condensation)
Atmosphere
No corrosive gases
Vibration resistance
10 to 57 Hz: (0.075 mm amplitude): 57 to 100 Hz:
Acceleration: 9,8 m/s2, in X, Y and Z directions for
80 minutes
Shock resistance
147 m/s2, 3 times each X, Y and Z directions
Insulation resistance
20 MΩ
Dielectric strength
500 VAC
Protective structure
IP20
International standards
CE, EN 61131-2, cULus, Lloyds
RoHS compliant
HARDWARE REFERENCE MANUAL
52
Hardware reference
3.2.3
Unit dimensions
The dimensions for the units of the Trajexia system are as follows:
Trajexia motion controller
All measurements are in mm.
90
94
fig. 13
70.3
65
62
71
Revision 5.0
HARDWARE REFERENCE MANUAL
53
Hardware reference
Trajexia units
All measurements are in mm.
94
90
fig. 14
70.3
31
39.9
Revision 5.0
HARDWARE REFERENCE MANUAL
54
Hardware reference
Trajexia system
All measurements are in mm.
fig. 15
65
90
94
PA202
31
29.7
fig. 16
94
The installation depth of the Trajexia system is up to 90 mm, depending on
the modules that are mounted. Allow sufficient depth in the control cabinet.
62
90
45
70.30
81.60 to 89.0 mm
3.2.4
Wire the I/O connectors
Revision 5.0
To wire the I/O connectors of the TJ1-MC__ and the TJ1-FL02 units, do
these steps:
HARDWARE REFERENCE MANUAL
55
Hardware reference
1. Strip the wires.
2. To make it easier to insert the wires, twist them.
3. If necessary, crimp the plain (top) ferrules or the collared (bottom)
ferrules.
4. Insert the screwdriver into the inner (square) hole. Push firmly.
5. Insert the wire into the outer (circular) hole.
6. Remove the screwdriver.
7. Make sure that there are no loose strands.
fig. 17
Wiring specifications
/i
Item
Specification
Wire types
0.14−1.0 mm2
Solid, stranded or stranded with ferrule:
•
Crimp ferrules according to DIN46228/1
•
Crimp ferrules wit plastic collar according to DIN46228/4
•
With recommended tool Weidmüller PZ6
Insertion tool
2.5 mm flat-bladed screwdriver
Recommended
ferrule types
Weidmüller
AEH H0,14/12
AEH H0,25/12
AEH H0,34/12
Stripping length
7 mm without ferrules (tolerance: +1 mm, −0 mm)
10 mm with ferrules (tolerance: +1 mm, −0 mm)
Conductor size
/i
Revision 5.0
Item
Specification
Clamping range
0.08−1.0 mm2
Wires without ferrule
0.5−1.0 mm2
Wires with ferrule
AEH H0,14/12, 0.13 mm2
AEH H0,25/12, 0.25 mm2
AEH H0,34/12, 0.34 mm2
HARDWARE REFERENCE MANUAL
56
Hardware reference
3.3
Power Supply Unit (PSU)
3.3.1
Introduction
The PSU supplies power to the other units in the Trajexia system. You can
use three different types of Power Supply Unit with the Trajexia system:
•
•
•
CJ1W-PA202
CJ1W-PA205R
CJ1W-PD025.
3.3.2
PSU Connections
Each Power Supply Unit has six terminals:
fig. 18
/i
Item
CJ1W-PA202
CJ1W-PA205R
CJ1W-PD025
A
110 - 240 VAC input
110 - 240 VAC input
24 VDC input
B
110 - 240 VAC input
110 - 240 VAC input
0 V input
C
Line earth
Line earth
Line earth
D
Earth
Earth
Earth
E
N/C
1Wdog
F
N/C
Wdog relay contact
relay contact
G
XXXXX
POWER
A
L1
AC100
-240V
INPUT
L2/N
N/C
C
D
N/C
1. Terminals E and F for the CJ1W-PA205R are relay contacts that close
when Wdog is enabled. Refer to the BASIC Commands in the Programming manual.
B
NC
NC
E
F
Caution
Always connect to a class-3 ground (to 100Ω or less) when installing the Units.
Not connecting to a class-3 ground may result in electric shock.
Revision 5.0
HARDWARE REFERENCE MANUAL
57
Hardware reference
Caution
A ground of 100Ω or less must be installed when shorting the GR
and LG terminals on the Power Supply Unit.
Not connecting a ground of 100Ω or less may result in electric
shock.
Each Power Supply Unit has one green LED (G). This LED comes on when
you connect the Power Supply Unit to the power source.
Caution
Tighten the screws of the power supply terminal block to the
torque of 1.2 N·m. Loose screws can result in short-circuit, malfunction or fire.
3.3.3
PSU Specifications
/i
Power
Supply
Unit
Input
voltage
Maximum current consumption
Output
power
5 V group
24 V group
CJ1W-PA202
110 - 240 VAC
2.8 A
0.4 A
14 W
CJ1W-PA205R
110 - 240 VAC
5.0 A
0.8 A
25 W
CJ1W-PD025
24 VDC
5.0 A
0.8 A
25 W
Revision 5.0
Caution
The amount of current and power that can be supplied to the system is limited by the capacity of the Power Supply Unit. Refer to
this table when designing your system so that the total current
consumption of the units in the system does not exceed the maximum current for each voltage group.
The total power consumption must not exceed the maximum for
the Power Supply Unit.
HARDWARE REFERENCE MANUAL
58
Hardware reference
3.3.4
•
•
•
PSU box contents
Safety sheet.
Power Supply Unit.
Protection label attached to the top surface of the unit.
3.4
TJ1-MC__
3.4.1
Introduction
The TJ1-MC__ is the heart of the Trajexia system. You can program the
TJ1-MC__ with the BASIC programming language to control the expansion
units and the servo motors attached to the expansion units. Refer to the
Programming Manual.
There are two versions of the TJ1-MC__:
The TJ1-MC04 supports 5 axes (up to 4 axis on MECHATROLINK-II)
The TJ1-MC16 supports 16 axes.
The TJ1-MC__ has these visible parts:
fig. 19
/i
Part
Description
A
LED display
B
I/O LEDs 0 - 7
C
Battery
D
Ethernet connector
E
TERM ON/OFF switch
F
WIRE 2/4 switch
G
Serial connector
H
28-pin I/O connector
A
B
C
D
E
F
G
H
Revision 5.0
HARDWARE REFERENCE MANUAL
59
Hardware reference
3.4.2
LED Display
The LED display shows the following information:
/i
Information
fig. 20
When
IP address and sub- Shows 3 times when you connect the Trajexia system to the power
net mask
supply.
IP address
Shows 4 times when you connect an Ethernet cable to the Ethernet
connector of the TJ1-MC__ and to a PC.
RUN
When the TJ1-MC__ operates a Servo Driver.
OFF
When the TJ1-MC__ does not operate a Servo Driver.
ERR + code
When an error occurs in the Trajexia system.
The code is the error code. Refer to troubleshooting chapter in the
Programming Manual.
Revision 5.0
HARDWARE REFERENCE MANUAL
60
Hardware reference
3.4.3
TJ1-MC__ Connections
The TJ1-MC__ comes with these connectors:
• One Ethernet connector, to connect to a PC or Ethernet network (D)
• One serial connector (G).
• One 28-pin I/O connector (H).
The parts for the serial connector and the 28-pin connector are supplied.
Ethernet connector
The Ethernet connector is used to connect the TJ1-MC__ to a PC or
Ethernet network. The Ethernet connector is the only connection that can be
used to program the system. Use either a crossover or a Ethernet patch
cable for this connection. If you connect the PC directly to the TJ1-MC__,
and not via a hub or any other network device, the PC must have a fixed IP
address.
The TJ1-MC__ automatically detects when a cable is connected to the
Ethernet connector.
fig. 21
A
B
C
D
E
F
G
H
BASIC installation precautions
Make sure that the Ethernet system is to the IEEE Std 802.3 standard.
Do not install the Ethernet system near a source of noise.
Environmental precautions
UTP cables are not shielded. In environments that are subject to noise use a
system with shielded twisted-pair (STP) cable and hubs suitable for an FA
environment.
Install twisted-pair cables away from high-voltage lines and devices that
generate noise.
Install twisted-pair cables in locations that are free of high humidity and
excessive dust and contaminates.
Revision 5.0
HARDWARE REFERENCE MANUAL
61
Hardware reference
Serial connector
The serial connector allows for three communication standards:
• RS232.
• RS422.
• RS485.
fig. 22
/i
Pin
Communication
Connection
1
RS422/RS485
/Tx
2
RS232
Tx
3
RS232
Rx
4
N/C
N/C
5
N/C
N/C
6
RS422/RS485
/Rx
7
RS422/RS485
Tx
8
RS422/RS485
Rx
9
RS232
0V
9
8
7
6
5
4
3
2
1
TERM ON/OFF Switch
Sets the termination on/off of the RS422 / 485 serial connection. The setting
of the TERM ON/OFF switch depends on the communication standard of the
serial connection and the position of the TJ1-MC__ in the network:
/i
Communication
standard
Position of the TJ1-MC__
Setting of the TERM ON/OFF
switch
RS422 or RS485
First or last
Left (on)
RS422 or RS485
Not the first and not the last
Right (off)
Revision 5.0
HARDWARE REFERENCE MANUAL
62
Hardware reference
WIRE 2/4 Switch
The WIRE 2/4 switch sets the communication standard for the RS422/485
serial connection. To use one of the communication standards, do this:
/i
Communication standard
How to select it
RS422
Set the WIRE 2/4 switch right
RS485
Set the WIRE 2/4 switch left
fig. 23
A
B
C
Note
In RS485 mode, the transmit pair is connected to the receive pair.
D
E
F
G
H
Revision 5.0
HARDWARE REFERENCE MANUAL
63
Hardware reference
28-Pin I/O connector
The 28 pin connector is a Weidmuller connector designation:
B2L 3.5/28 LH.
/i
fig. 24
Pin
Connection
Pin
Connection
1
0 V input common
2
0 V input common
3
Input 0
4
Input 1
5
Input 2
6
Input 3
7
Input 4
8
Input 5
9
Input 6
10
Input 7
11
Input 8
12
Input 9
13
Input 10
14
Input 11
15
Input 12
16
Input 13
17
Input 14
18
Input 15
19
Output 8
20
Output 9
21
Output 10
22
Output 11
23
Output 12
24
Output 13
25
Output 14
26
Output 15
27
0 V output common
28
24V Power supply Input for
the Outputs.
1
3
5
7
9
11
13
15
17
19
21
23
25
27
2
4
6
8
10
12
14
16
18
20
22
24
26
28
LEDs 0 - 7
The I/O LEDs reflect the activity of the input and outputs. You can use the
BASIC DISPLAY=n command to set the LEDs.
The table below lists the configuration for LEDs 0 - 7 and the DISPLAY=n
command where n ranges from 0 to 7.
/i
Revision 5.0
LED
label
n=0
n=1
n=2
n=3
n=4
n=5
n=6
n=7
0
IN 0
IN 8
IN 16
IN 24
OUT 0
OUT 8
OUT 16
OUT 24
1
IN 1
IN 9
IN 17
IN 25
OUT 1
OUT 9
OUT 17
OUT 25
HARDWARE REFERENCE MANUAL
64
Hardware reference
LED
label
n=0
n=1
n=2
n=3
n=4
n=5
n=6
n=7
2
IN 2
IN 10
IN 18
IN 26
OUT 2
OUT 10
OUT 18
OUT 26
3
IN 3
IN 11
IN 19
IN 27
OUT 3
OUT 11
OUT 19
OUT 27
4
IN 4
IN 12
IN 20
IN 28
OUT 4
OUT 12
OUT 20
OUT 28
5
IN 5
IN 13
IN 21
IN 29
OUT 5
OUT 13
OUT 21
OUT 29
6
IN 6
IN 14
IN 22
IN 30
OUT 6
OUT 14
OUT 22
OUT 30
7
IN 7
IN 15
IN 23
IN 31
OUT 7
OUT 15
OUT 23
OUT 31
For example, if you use the DISPLAY=1 command, LED 5 reflects the
activity of the input in 13 (pin16) of the 28-pin I/O connector.
Digital inputs
The following table and illustration details the digital input (Input 0 to Input
15) specifications for the I/O:
fig. 25
/i
Item
Specification
Type
PNP/NPN
Maximum voltage
24 VDC + 10%
Input current
5 mA at 24 VDC
ON voltage
14.4 VDC
OFF voltage
5.0 VDC max.
The timings are dependant upon the MC16’s servo period, and include
physical delays in the input circuit.
Maximum response times of 1250 µs (for servo periods of 0.5 ms or 1.0 ms)
or 2500 µs (for a servo period of 2.0 ms) are achieved between a change in
the input voltage and a corresponding change in the IN Parameter.
TJ 1-MC 16
Input 3
External power
supply 24V
0V Input 1
0V common for Input circuits
Revision 5.0
HARDWARE REFERENCE MANUAL
65
Hardware reference
Digital outputs
The following table and illustration details the digital output (O8 to O15)
specifications:
fig. 26
Specification
Type
PNP
Maximum voltage
24 VDC + 10%
Current capacity
100 mA each output (800 mA for a group of 8)
Max. Voltage
24 VDC + 10%
Protection
Over current, Over temperature and 2A fuse on
Common
TJ 1-MC 16
2A Fuse
28 24V output supply
19 O8
Equivalent
circuit
27
0Vout
Load
Item
Internal circuits (galvanically
isolated from the system)
/i
External
power
supply
24V
To other output circuits
The timings are dependant upon the MC16’s servo period, and include
physical delays in the output circuit.
Maximum response times of 250 µs on and 350 µs off (for servo periods of
0.5 ms or 1.0 ms) or 500 µs on and 600 µs off (for a servo period of 2.0 ms)
are achieved between a change in the OP parameter and a corresponding
change in the digital output circuit.
Revision 5.0
HARDWARE REFERENCE MANUAL
66
Hardware reference
3.4.4
Battery
The backup battery provides power to the RAM, where programs and global
variables are stored, and real Time Clock when the power supply is off. You
must replace it every five years. The part number of the backup battery is
CJ1W-BAT01.
To replace the battery the power must not be off for more than five minutes
to ensure no backup memory loss. If the TJ1-MC__ has not been on, set the
unit to on for at least five minutes before you replace the battery else the
capacitor that gives backup power to the memory is not fully changed and
backup memory may be lost before the new battery is inserted.
fig. 27
A
B
C
D
E
F
G
H
3.4.5
TJ1-MC__ Specification
/i
Item
Specification
TJ1-MC04
TJ1-MC16
Revision 5.0
Power supply
5 VDC and 24 VDC (supplied by a Power Supply Unit)
Total power consumption
3.3 W
Current consumption
650 mA at 5 VDC
Approximate weight
230 g
Number of axes
5 (up to 4 axis on MECHATROLINK-II)
Number of Inverters and I/Os
Up to 8 on MECHATROLINK-II, depending on the type of
TJ1-ML__ in the system.
Number of TJ1-ML__ units
Up to 4
Real Time Clock
Yes
HARDWARE REFERENCE MANUAL
16
67
Hardware reference
Item
Specification
TJ1-MC04
TJ1-MC16
Servo period
0.5 ms, 1 ms or 2 ms
Programming language
BASIC-like motion language
Multi-tasking
Up to 14 tasks
Digital I/O
16 digital inputs and 8 digital outputs, freely configurable
Measurement units
User-definable
Available memory for user programs
500 kB
Data storage capacity
Up to 2 MB flash data storage
Saving program data on the
TJ1-MC__
•
•
Saving program data on the PC
Trajexia Tools software manages backups on the harddisk of the PC
Communication connectors
•
•
Firmware update
Via Trajexia Tools software
Electrical characteristics of the
Ethernet connector
Conforms to IEEE 802.3 (100BaseT)
Ethernet connector
RJ45
RAM and flash memory backup
Battery backup
1 Ethernet connection
2 serial connections
Serial connectors 1 and 2
/i
Revision 5.0
Item
Specification
Electrical characteristics
•
•
Connector
SUB-D9 connector
Baud rate
1200, 2400, 4800, 9600, 19200 and 38400 bps
Transmission format, databit length
7 or 8 bit
Transmission format, stop bit
1 or 2 bit
HARDWARE REFERENCE MANUAL
PORT1: RS232C, non-isolated
PORT2: RS485/RS422A, isolated
68
Hardware reference
Item
Specification
Transmission format, parity bit
Even/odd/none
Transmission mode
•
•
RS232C: Point-to-point (1:1)
RS422/485: Point-to-multipoint (1:N)
Transmission protocol
•
•
•
Host link master protocol
Host link slave protocol
ASCII general purpose
Galvanic isolation
RS422/485 connector only
Communication buffers
254 bytes
Flow control
None
Terminator
Yes, selected by switch
Maximum cable length
•
•
3.4.6
RS232C: 15 m
RS422/485: 100 m
TJ1-TER
The TJ1-TER makes sure that the internal data bus of the Trajexia system
functions correctly. A Trajexia system must always contain a TJ1-TER as the
last unit.
fig. 28
Revision 5.0
HARDWARE REFERENCE MANUAL
69
Hardware reference
3.4.7
•
•
•
•
•
•
•
TJ1-MC__ box contents
Safety sheet.
TJ1-MC__ (battery included).
Protection label attached to the top surface of the TJ1-MC__.
TJ1-TER, attached to the TJ1-MC__.
Parts for a serial connector.
Parts for an I/O connector.
Two metal DIN-rail clips, to prevent the Trajexia system from sliding off
the rail.
White clip, to replace the yellow clip of the Power Supply Unit.
•
3.5
TJ1-ML__
3.5.1
Introduction
The TJ1-ML__ controls MECHATROLINK-II devices in a cyclic and
deterministic way. MECHATROLINK-II devices can be:
• Servo Drivers.
• Inverters.
• I/Os.
fig. 29
ML16
RUN
A
BF
The TJ1-ML__ has these visible parts:
/i
Part
Description
A
LED indicators
B
CN1 MECHATROLINK-II bus connector
CN1
B
Together the TJ1-ML__ and its devices form a serial network. The first unit in
the network is the TJ1-ML__.
• One TJ1-ML16 can control 16 devices.
• One TJ1-ML04 can control 4 devices.
Revision 5.0
HARDWARE REFERENCE MANUAL
70
Hardware reference
3.5.2
LEDs description
/i
Label
Status
Description
run
off
Start-up test failed. Unit not operational
Operation stopped. Fatal error
on
Start-up test successful. Normal operation
off
Normal operation
on
A fault in the MECHATROLINK-II bus
BF
-
3.5.3
Reserved
TJ1-ML__ connection
The MECHATROLINK-II bus connector (A) fits a MECHATROLINK-II
connector. Use this connector to connect the TJ1-ML__ to a
MECHATROLINK-II network.
fig. 30
ML16
RUN
8F
The MECHATROLINK-II network must always be closed by the
MECHATROLINK-II terminator.
CN1
A
Revision 5.0
HARDWARE REFERENCE MANUAL
71
Hardware reference
Example connections
Example 1
• 1 x TJ1-MC__
• 1 x TJ1-ML__
• 3 x Sigma-II Servo Driver
• 1 x MECHATROLINK-II terminator
fig. 31
Servo Driver
Address
43
Address
44
Address
45
Terminator
Axis 2
Axis 3
Axis 4
Revision 5.0
HARDWARE REFERENCE MANUAL
72
Hardware reference
Example 2
• 1 x TJ1-MC16
• 2 x TJ1-ML16
• 16 x Sigma-II Servo Driver
• 2 x MECHATROLINK-II terminator
fig. 32
Servo Drive
Address Address Address Address Address Address Address Address
41
42
43
44
45
46
47
48
Terminator
Axis 0
Axis 1
Axis 2
Axis 3
Axis 4
Axis 5
Axis 6
Axis 7
Address Address Address Address Address Address Address Address
49
4A
4B
4C
4D
4E
4F
50
Terminator
Axis 8
Axis 9
Axis 10
Axis 11
Axis 12
Axis 13
Axis 14
Axis 15
Revision 5.0
HARDWARE REFERENCE MANUAL
73
Hardware reference
The MECHATROLINK-II Units can control different combinations of axes,
Inverters and I/O units.
Example 3
• 1 x TJ1-MC__
• 1 x TJ1-ML16
• 1 x Sigma-II Servo Driver
• 1 x Inverter
• 3 x I/O units
• 1 x MECHATROLINK-II terminator
fig. 33
INVERTERS
All Inverter Addresses
are numbered 2x
(valid range 20 to 2F)
Address
41
Address
21
I/O UNITS
I/O Addresses are numbered 6x
(valid range 60 to 6F)
I/O Address selected on DIP Switches
Address
61
Address
62
Address
63
Terminator
I/O Memory Allocations
0
31 32
95 96
159 160
223 224
Axis 0
3.5.4
TJ1-ML__ specifications
/i
Item
Specification
TJ1-ML04
TJ1-ML16
Revision 5.0
Power supply
5 VDC (supplied by the TJ1-MC__)
Total power consumption
1.0 W
Current consumption
200 mA at 5 VDC
HARDWARE REFERENCE MANUAL
74
Hardware reference
Item
Specification
TJ1-ML04
Name
TJ1-ML16
Remarks
Model
5 meters
FNY-W6003-05
10 meters
FNY-W6003-10
Approximate weight
75 g
Number of controlled devices
4
16
20 meters
FNY-W6003-20
Controlled devices
•
•
•
•
•
Omron G-Series Servo Drivers
Omron Accurax G5 Servo Drivers
Sigma-II, Sigma-V and Junma-ML Servo Drivers
I/Os
V7, F7 and G7 Inverters
30 meters
FNY-W6003-30
MECHATROLINK-II
terminator
Terminating resistor
FNY-W6022
MECHATROLINK-II
interface unit
For Sigma-II series Servo Drivers
(firmware version 39 or later)
JUSP-NS115
For Varispeed V7 Inverter (For the supported version details of the Inverter, contact your OMRON sales office).
SI-T/V7
For Varispeed F7, G7 Inverter (For the
supported version details of the Inverter,
contact your OMRON sales office).
SI-T
Electrical characteristics
Conforms to MECHATROLINK-II standard
Communication connection
1 MECHATROLINK-II master connector
Transmission speed
10 Mbps
Servo period
0.5 ms, 1 ms or 2 ms
Transmission distance without a
repeater
Up to 50 m
3.5.5
TJ1-ML__ related devices
/i
Name
Remarks
Distributed I/O mod- MECHATROLINK-II Smartslice coupler
ules
64-point digital input and 64-point digital
output (24 VDC sinking)
Revision 5.0
MECHATROLINK-II
cables
Model
GRT1-ML2
JEPMC-IO2310
JEPMC-IO2330
Analogue input: -10V to +10 V,
4 channels
JEPMC-AN2900
Analogue output: -10 V to +10 V,
2 channels
JEPMC-AN2910
0.5 meter
FNY-W6003-A5
1 meters
FNY-W6003-01
3 meters
FNY-W6003-03
HARDWARE REFERENCE MANUAL
MECHATROLINK-II Interface Unit box:
• Safety sheet.
• TJ1-ML__.
• Protection label attached to the top surface of the unit.
3.5.6
64-point digital input and 64-point digital
output (24 VDC sourcing)
TJ1-ML__ box contents
Related BASIC commands
The following BASIC commands are related to the TJ1-ML__:
• ATYPE
• MECHATROLINK
For more information, refer to the Trajexia Programming Manual.
75
Hardware reference
3.5.7
MECHATROLINK-II Servo Drivers
A MECHATROLINK-II Servo Driver is designed to do position control in
Trajexia. In every MECHATROLINK-II cycle, the TJ1-MC__ receives the
position feedback from the Servo Driver via the TJ1-ML__. The TJ1-MC__
sends either the target position, speed or torque to the receiver, depending
on the axis type.
Other functionality of the Servo Driver is available but refreshed at slower
rate.
A Servo Driver is considered an axis by the TJ1-MC__.
When you connect a servo to the Trajexia, the parameter does not change
automatically so, depending on the application, you may have to change
values.
3.5.8
MECHATROLINK-II Servo Drivers Sigma-II series
To connect a Sigma-II Servo Driver to a Trajexia system, a JUSP-NS115
MECHATROLINK-II interface must be connected to the Servo Driver.
For details about the Sigma-II connections refer to the manual.
fig. 34
Revision 5.0
HARDWARE REFERENCE MANUAL
76
Hardware reference
LED indicators on the NS115
/i
fig. 35
LED
Color
Description
Alarm
Red
Lit: an alarm occurred
Not lit: no alarm active
Ready
Green
Lit: communication active
Not lit: no communication in progress
A
B
C
Address settings (SW1 & SW2)
C
The dipswitches (B) on the NS115 configure the communication settings.
fig. 36
Dipswitch
Function
Setting
Description
1
Baud rate
on
10 Mbps
2
Data length
on
32-byte data transmission
3
Address range
off
Addresses 40-4F
on
Addresses 50-5F
off
Must always be set to off. on is not used
4
Maintenance
(Reserved)
1 2 3 4
/i
ON
OFF
Revision 5.0
HARDWARE REFERENCE MANUAL
77
Hardware reference
Set the address selector (A, fig 35) of the NS115 to n (where n ranges from 0
to F) to assign the following address to the NS115:
fig. 37
/i
Rotary
switch
number
Dipswitch 3 Station address
Axis in motion controller
1
off
41
0
2
off
42
1
3
off
43
2
4
off
44
3
5
off
45
4
6
off
46
5
7
off
47
6
8
off
48
7
9
off
49
8
A
off
4A
9
B
off
4B
10
C
off
4C
11
D
off
4D
12
E
off
4E
13
F
off
4F
14
0
on
50
15
Do not use the addresses 40 and 51-5F. Use only the addresses 41-50.
Revision 5.0
HARDWARE REFERENCE MANUAL
78
Hardware reference
MECHATROLINK-II connectors (CN1A & CN1B)
Connect to the MECHATROLINK-II network as in the figure using a suitable
MECHATROLINK-II cable. Both connectors are parallelled so you can
connect both cables to both connectors. Connect a MECHATROLINK-II
terminator resistor in one of the connectors if the Servo Driver is the last
device in the network.
fig. 38
CN4 Full-closed encoder connector
CN4 is for connecting a full-closed encoder, that is, the position is controlled
based in one external encoder, and the speed and torque loop based in the
motor encoder. This is used when you install the motor in machines where
you have to measure directly on the load because either:
• There is slip or backlash in the mechanical transmission.
• The precision required is very high.
The supported encoder is line driver and the pinout is shown in the figure.
The table shows the CN4 connector terminal layout and connector
specifications.
Revision 5.0
HARDWARE REFERENCE MANUAL
79
Hardware reference
/i
fig. 39
1
PG0V
Signal ground
2
PG0V
Signal ground
3
PG0V
Signal ground
4
-
-
5
-
-
6
-
-
7
-
-
8
-
-
9
-
-
10
-
-
11
-
-
12
-
-
13
-
-
14
FC
Phase-C input +
15
/FC
Phase-C input -
16
FA
Phase-A input +
17
/FA
Phase-A input -
18
FB
Phase-B input +
19
/FB
Phase-B input -
20
-
-
NS115
CN4
1,2,3
16
17
18
19
14
15
PG0V
FA
/FA
FB
/FB
FC
/FC
GND
A
/A
B
/B
Z
/Z
External PG
External
power supply
Note
Make sure that shielded cable is used and that the shield is connected to the connector shell.
Revision 5.0
Relevant servo parameters related with the use of Trajexia:
HARDWARE REFERENCE MANUAL
80
Hardware reference
Encoder gear ratio resolution
These two parameters define the units of the system in combination with
UNITS.
• Pn202: Gear ratio numerator. Default is 4, set to 1 to obtain the
maximum encoder resolution.
• Pn203: Gear ratio denominator. Default=1.
Absolute encoder
•
Pn205= Number of multiturn limit. Default 65535. Set to suitable value in
combination with the encoder gear ratio and UNITS.
Full close encoder
•
•
Pn002.3: 0=Disabled, 1=uses without Z, 2=uses with Z, 3=uses without
Z reverse rotation, 4= uses with Z reverse rotation.
Pn206: Number of full-closed encoder pulses per revolution. Default
16384
Using the Servo Driver digital inputs with Trajexia
•
•
•
•
Pn50A: Mapping of the forward limit switch (P_OT).
Pn50B: Mapping of the reverse limit switch (N_OT).
Pn511: Mapping of the registration inputs and zero point return
declaration.
Pn81E: Mapping of the normal inputs.
For the overview of all possible settings and parameter values to map the
input signals from the Servo Driver to Trajexia, refer to the Trajexia
Programming manual, chapter “Mapping Servo Driver inputs and outputs”.
For the rest of the parameters and connections refer to the Sigma-II manual.
Related BASIC commands
Revision 5.0
The following BASIC commands are related to the MECHATROLINK-II
Servo Drivers Sigma-II series:
• ATYPE
• AXIS
• AXIS_ENABLE
• AXISSTATUS
HARDWARE REFERENCE MANUAL
81
Hardware reference
•
•
•
•
•
•
•
•
•
DRIVE_ALARM
DRIVE_CLEAR
DRIVE_CONTROL
DRIVE_INPUTS
DRIVE_MONITOR
DRIVE_READ
DRIVE_RESET
DRIVE_STATUS
DRIVE_WRITE
For more information, refer to the Trajexia Programming Manual.
3.5.9
MECHATROLINK-II Servo Drivers Sigma-V series
You can also connect a Sigma-V Servo Driver to a Trajexia system.
fig. 40
/i
A
CHARGE
Charge indicator
B
L1, L2, L3
Main circuit power supply terminals
C
L1, L2
Control power supply terminals
D
B1, B2
Regenerative resistor connecting terminals
E
1, 2
DC reactor terminals for harmonic suppression
F
U, V, W
Servo motor terminals
G
+
Ground terminal
A
CHARGE
L2
CN6A/B
MECHATROLINK-II bus connectors
I
CN3
Connector for digital operator
J
CN7
PC connector
K
CN1
I/O signal connector
L
CN8
Connector for safety function devices
M
CN2
Encoder connector
N
SW1
Rotary switch for MECHATROLINK-II address settings
O
SW2
Dipswitches for MECHATROLINK-II communication settings
Revision 5.0
P
Panel display
Q
MECHATROLINK-II communication LED
HARDWARE REFERENCE MANUAL
C
L1
D
B1
L2
E
I
C
N
7
J
F0 12
ON
1
N
O P
C
N
1
K
1
2
U
V
W
G
C
N
3
B2
B3
F
R
Q
H
L1
B
L3
H
C
N
6
A/B
BCDE
Description
7 8 9A
Terminal/LED
3 4 56
Label
C
N
8
C
N
2
L
M
82
Hardware reference
Label
Terminal/LED
R
Description
Power LED
Communication settings (SW2)
The 4 dipswitches configure the communication settings.
fig. 41
/i
Dipswitch
Function
Setting
Description
Factory
setting
1
Baud rate
on
10 Mbps
on
2
Data length
on
32-byte data transmission
on
3
Address
range
off
Addresses 40-4F
off
on
Addresses 50-5F
off
Must always be set to off. on is not
used
4
Reserved
off
1
Revision 5.0
HARDWARE REFERENCE MANUAL
83
Hardware reference
Address settings (SW1)
Set the address selector of the Sigma-V Servo Driver to n (where n ranges
from 0 to F) to assign the following station address to it:
fig. 42
/i
Rotary
switch
number
Dipswitch 3 Station address
Axis in motion controller
1
off
41
0
2
off
42
1
3
off
43
2
4
off
44
3
5
off
45
4
6
off
46
5
7
off
47
6
8
off
48
7
9
off
49
8
A
off
4A
9
B
off
4B
10
C
off
4C
11
D
off
4D
12
E
off
4E
13
F
off
4F
14
0
on
50
15
Do not use the addresses 40 and 51-5F. Use only the addresses 41-50.
Revision 5.0
HARDWARE REFERENCE MANUAL
84
Hardware reference
LEDs
/i
LED
Color
Description
Charge indicator
Orange
Lit: main circuit power supply is on or internal
capacitor is charged
Not lit: no power supply and internal capacitor
is not charged
Power LED
Green
Lit: control power is supplied
Not lit: no control power
MECHATROLINK-II communication LED
Green
Lit: communication active
Not lit: no communication
Panel display
The panel display is a 7-segment LED display. It indicates the status of the
Servo Driver.
The panel display has 3 display modes:
• Status display
The display shows the statuses listed in the table below.
/i
Display
Description
Remark
Baseblock
Comes on when the motor current is shut off. Does not
come on when the Servo Driver is on
Rotation detection
(/TGON)
Comes on when the motor speed is greater than the
value set in Pn502
Reference input
Comes on when a reference is being input
CONNECT
Comes on during connection
Revision 5.0
HARDWARE REFERENCE MANUAL
85
Hardware reference
•
Alarm/warning
If an alarm or a warning occurs, the display shows the alarm code or the
warning code.
The figure shows an example of displaying alarm code A.E60.
•
Test without motor
The display shows the sequence given in the figure if a test is executed
without a motor.
MECHATROLINK-II connectors (CN6A & CN6B)
fig. 43
Status
Display
Unlit
Unlit
Unlit
Unlit
Unlit
Unlit
Unlit
fig. 44
Status
Display
Unlit
Unlit
Unlit
Connect the Sigma-V Servo Driver to the MECHATROLINK-II network using
the CN6A and CN6B connectors. Use one of the MECHATROLINK-II
connectors to connect to the previous MECHATROLINK-II device or the
TJ1-ML__. Use the other MECHATROLINK-II connector to connect to the
next MECHATROLINK-II device, or to connect a MECHATROLINK-II
terminator.
CN1 I/O Signal connector
The table below shows the pin layout for the I/O signal connector (CN1).
/i
Revision 5.0
Pin
I/O
Signal
Signal name
1
Output
/BK+ (/SO1+)
Brake interlock signal
2
Output
/BK- (/SO1-)
Brake interlock signal
3
Output
ALM+
Servo alarm output signal
4
Output
ALM-
Servo alarm output signal
5
N/A
N/A
Not used
6
Input
+24 V IN
Control power supply for sequence signal
7
Input
P-OT
Forward run prohibited
8
Input
N-OT
Reverse run prohibited
9
Input
/DEC
Homing deceleration limit switch
10
Input
/EXT1
External latch signal 11
11
Input
/EXT2
External latch signal 21
HARDWARE REFERENCE MANUAL
86
Hardware reference
Pin
I/O
Signal
Signal name
31
Pin
Signal
Description
6
/PS
PG serial signal input (-)
Shell
Shield
-
12
Input
/EXT3
External latch signal
13
Input
/SIO
General-purpose input signal
14
N/A
N/A
Not used
Related BASIC commands
15
N/A
N/A
Not used
16
Output
FG
Signal ground
17
N/A
N/A
Not used
18
N/A
N/A
Not used
19
N/A
N/A
Not used
20
N/A
N/A
Not used
21
Input
BAT (+)
Battery (+) input signal
22
Input
BAT (-)
Battery (-) input signal
23
Output
/SO2+
General-purpose output signal
24
Output
/SO2-
General-purpose output signal
25
Output
/SO3+
General-purpose output signal
26
Output
/SO3-
General-purpose output signal
The following BASIC commands are related to the MECHATROLINK-II
Servo Drivers Sigma-V series:
• ATYPE
• AXIS
• AXIS_ENABLE
• AXISSTATUS
• DRIVE_ALARM
• DRIVE_CLEAR
• DRIVE_CONTROL
• DRIVE_INPUTS
• DRIVE_MONITOR
• DRIVE_READ
• DRIVE_RESET
• DRIVE_STATUS
• DRIVE_WRITE
1. NPN only.
For more information, refer to the Trajexia Programming Manual.
For more information, refer to the Sigma-V Series SERVOPACKs manual.
CN2 encoder connector
The tables below shows the pin layout for the Sigma-V encoder connector.
/i
Revision 5.0
Pin
Signal
Description
1
PG 5 V
PG power supply +5 V
2
PG 0 V
PG power supply 0 V
3
BAT (+)
Battery (+)
(For an absolute encoder)
4
BAT (-)
Battery (-)
(For an absolute encoder)
5
PS
PG serial signal input (+)
HARDWARE REFERENCE MANUAL
87
Hardware reference
3.5.10 MECHATROLINK-II Servo Drivers Junma series
You can also connect a Junma Servo Driver to a Trajexia system.
fig. 45
/i
FIL
Rotary switch for reference filter setting
B
CN6A & CN6B
MECHATROLINK-II bus connectors
C
CN1
I/O signal connector
A
COM ALM RDY
FIL
3456
B CDE
CN2
Encoder input connector
E
SW1
Rotary switch for MECHATROLINK-II address settings
F
SW2
Dipswitches for MECHATROLINK-II communication settings
G
RDY
Servo status indicator
H
ALM
Alarm indicator
I
COM
MECHATROLINK-II communication status indicator
J
CNA
Connector for power supply
K
CNB
Connector for servo motor
CN6
ON
E
F
1
A/B
C
I H G
CN1
D
3 4 56
BCDE
D
B
F0 12
A
7 8 9A
Description
7 8 9A
Terminal/LED
F012
Label
CN2
PWR
J
L1
U
L2
V
W
CNA
K
CNB
LED indicators
/i
LED
Description
COM
Lit: MECHATROLINK-II communication in progress
Not lit: No MECHATROLINK-II communication
ALM
Lit: An alarm occurred
Not lit: no alarm
RDY
Lit: Power is on, standby for establishment of communication
Blinking: Servo ON status
Revision 5.0
HARDWARE REFERENCE MANUAL
88
Hardware reference
Communication settings (SW2)
The 4 dipswitches configure the communication settings.
fig. 46
/i
Dipswitch
Function
Setting
Description
1
Reserved
ON
Must always be set to ON. OFF is not used
2
Data
length
ON
32 bytes
3
Address
range
OFF
Addresses 40-4F
ON
Addresses 50-5F
Filter
setting
OFF
Set the filter with the FIL rotary switch
ON
Set the filter with Pn00A
4
1
Revision 5.0
HARDWARE REFERENCE MANUAL
89
Hardware reference
Address settings (SW1)
Set the address selector of the Junma Servo Driver to n (where n ranges
from 0 to F) to assign the following station address to it:
fig. 47
/i
Rotary
switch
number
Dipswitch 3 Station address
Axis in motion controller
1
off
41
0
2
off
42
1
3
off
43
2
4
off
44
3
5
off
45
4
6
off
46
5
7
off
47
6
8
off
48
7
9
off
49
8
A
off
4A
9
B
off
4B
10
C
off
4C
11
D
off
4D
12
E
off
4E
13
F
off
4F
14
0
on
50
15
Do not use the addresses 40 and 51-5F. Use only the addresses 41-50.
Revision 5.0
HARDWARE REFERENCE MANUAL
90
Hardware reference
CN1 I/O Signal connector
The table below shows the pin layout for the I/O signal connector (CN1).
fig. 48
/i
Pin
I/O
Code
Signal name
1
Input
/EXT1
External latch
2
Input
/DEC
Homing deceleration
3
Input
N_OT
Reverse run prohibit
4
Input
P_OT
Forward run prohibit
5
Input
+24VIN
External input power supply
6
Input
E-STP
Emergency stop
7
Output
SG-COM
Output signal ground
8
N/C
9
N/C
10
N/C
11
N/C
12
Output
ALM
Servo alarm
13
Output
/BK
Brake
14
N/C
Shell
-
-
FG
8 9 10 11 12 13 14
1 2 3 4 5 6 7
MECHATROLINK-II connectors (CN6A & CN6B)
Connect the Junma Servo Driver to the MECHATROLINK-II network using
the CN6A and CN6B connectors. Use one of the MECHATROLINK-II
connectors to connect to the previous MECHATROLINK-II device or the
TJ1-ML__. Use the other MECHATROLINK-II connector to connect to the
next MECHATROLINK-II device, or to connect a MECHATROLINK-II
terminator.
Revision 5.0
HARDWARE REFERENCE MANUAL
91
Hardware reference
CN2 encoder input connector
The tables below shows the pin layout for the Junma Servo Driver encoder
connector.
fig. 49
/i
Pin
Signal
1
PG5V
2
PG0V (GND)
3
Phase A (+)
4
Phase A (-)
5
Phase B (+)
6
Phase B (-)
7
Phase /Z
8
Phase U
9
Phase V
10
Phase W
Shell
-
9 7 5 3 1
10 8 6 4 2
CNA power supply connector
The tables below shows the pin layout for the CNA power supply connector.
fig. 50
/i
Power supply terminal
L2
Power supply terminal
3
+
Regenerative unit connection terminal
4
-
Regenerative unit connection terminal
1
N
A
L1
2
2
3
4
1
3
Name
2
Signal
1
Pin
4
Revision 5.0
HARDWARE REFERENCE MANUAL
92
Hardware reference
CNB servo motor connector
The tables below shows the pin layout for the CNB servo motor connector.
fig. 51
/i
Phase V
3
W
Phase W
4
N/C
A
Phase U
V
1
N
U
2
2
3
4
1
3
Name
2
Signal
1
Pin
4
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
Servo Drivers Junma series:
• ATYPE
• AXIS
• AXIS_ENABLE
• AXISSTATUS
• DRIVE_ALARM
• DRIVE_CLEAR
• DRIVE_CONTROL
• DRIVE_INPUTS
• DRIVE_MONITOR
• DRIVE_READ
• DRIVE_RESET
• DRIVE_STATUS
• DRIVE_WRITE
Revision 5.0
For more information, refer to the Trajexia Programming Manual.
HARDWARE REFERENCE MANUAL
93
Hardware reference
3.5.11 MECHATROLINK-II Servo Drivers G-series
You can also connect a G-Series Servo Driver to a Trajexia system.
fig. 52
/i
G
Description
A
SP, IM, G
Analog monitor check pins
B
L1, L2, L3
Main-circuit power terminals
C
L1C, L2C
Control-circuit power terminals
D
B1, B2, B3
External Regeneration Resistor connection terminals
E
U, V, W
Servomotor connection terminals
F
CN2
Protective ground terminals
G
---
Display area
H
---
Rotary switches
H
AC SERVO DRIVE
ADR
0 1
MECHATROLINK-II communications status LED indicator
CN3
RS-232 communications connector
K
CN6A, CN6B
MECHATROLINK-II communications connector
L
CN1
Control I/O connector
M
CN2
Encoder connector
4 5 6
COM
J
2 3
I
9 0 1
7 8
Terminal/LED
2 3
Label
X10
X1
I
COM
J
SP
A
IM
G
K
B
C
LED indicators
/i
LED
Description
COM
Lit: MECHATROLINK-II communication in progress
Not lit: No MECHATROLINK-II communication
D
L
E
F
M
Revision 5.0
HARDWARE REFERENCE MANUAL
94
Hardware reference
Address settings (SW1)
fig. 53
Rotary switches for
setting a node
address
7-segment LED (2 digits)
AC SERVO DRIVER
ADR
9 01
2 3
7 8
01
2 3
Set the address selector of the G-series Servo Driver to the required node
address by using the X1 (right) and X10 (left) rotary switches.
The setting range for the node address setting rotary switch is 1 to 31. The
actual station address used on the network will be the sum of the rotary
switch setting and the offset value of 40h. These node addresses
correspond to axis numbers 0 (node address = 1) to 15 (node address = 16).
4 5 6
Note
The node address is only loaded once when the control power
supply is turned ON. Changes made after turning the power ON
will not be applied until the power is turned ON next time. Do not
change the rotary switch setting after turning the power ON
Note
If the rotary switch setting is not between 1 and 31, a node
address setting error (alarm code 82) will occur.
X10
Analog monitor pins
SP: Speed monitor
IM: Torque monitor
G: Signal ground
X1
COM
SP
IM
MECHATROLINK-II
communications
status LED
indicator (COM)
G
Revision 5.0
HARDWARE REFERENCE MANUAL
95
Hardware reference
7-segment LED
The display of the 7-segment LED on the front panel is shown below.
fig. 54
Turn ON Control Power Supply
When the power is turned ON, the node address set with the rotary switch is
displayed, followed by the display content set by the Default Display (Pn001)
parameter. When an alarm occurs, the alarm code will be displayed. When a
warning occurs, the warning code will be displayed.
All OFF
8.8.
All ON
(approx. 0.6 s)
nkak
[nA] (Node Address)
(approx. 0.6 s)
k3k
Rotary switch setting (for MSD = 0, LSD = 3)
(Time set by the Power ON Address Display
Duration Setting (Pn006))
Main Power Supply ON
and Network Established
-k-k
-k-.
Servo ON
[- -]
Main Power Supply OFF
or Network Not Established
[- -] + right dot ON
Servo OFF
0k0.
Alarm Issued
Alarm Cleared
Alarm code flashes in decimal display
(Below is an example for overload)
Revision 5.0
1k6k
[00] + right dot ON
Warning Issued
Alternates between warning code (hex)
and normal display
(Below is an example for overload)
9k0.
Warning code (2 s)
HARDWARE REFERENCE MANUAL
Warning Cleared
0k0.
Normal Display
(approx. 4 s)
96
Hardware reference
CN1 I/O Signal connector
The table below shows the pin layout for the I/O signal connector (CN1).
fig. 55
/i
1
Pin
I/O
Code
Signal name
1
Input
+24VIN
12 to 24-VDC Power Supply Input
2
Input
STOP
Emergency Stop Input
3
Input
EXT3
External Latch Signal 3
4
Input
EXT2
External Latch Signal 2
5
Input
EXT1
External Latch Signal 1
6
Input
IN1
2
4
6
8
STOP
EXT2
IN1
NCL
Input
PCL
Input
NCL
Reverse Torque Limit Input
19 to 20
Input
POT
Forward Drive Prohibit Input
NOT
Reverse Drive Prohibit Input
Revision 5.0
21
Input
DEC
Origin Proximity Input
22
Input
IN0
External general-purpose Input 0
23
Input
IN2
External general-purpose Input 2
11 to 14
Input
---
Spare inputs. Do not connect anything to
these inputs.
9 to 10
Input
---
Spare inputs. Do not connect anything to
these inputs.
27 to 28
Input
---
Spare inputs. Do not connect anything to
these inputs.
34
Input
BAT
33
Input
BATCOM
Backup
Battery Input
17 to 18
Input
---
Spare inputs. Do not connect anything to
these inputs.
24 to 26
Input
---
Spare inputs. Do not connect anything to
these inputs.
HARDWARE REFERENCE MANUAL
5
EXT1
External Latch
Signal 1
7
PCL
Forward Torque
Limit Input
22
28
*
32 OUTM3COM
15
/ALM
*
DEC
Origin Proximity
Input
23
IN2
External
General-purpose
Input2
25
*
27
*
29
OUTM2
General-purpose
Output 2
31
OUTM3
General-purpose
Output 3
33
BATCOM
Backup Battery
Input
General-purpose
Output 3
Alarm Output
Alarm Output
34
17
18
21
General-purpose
30 OUTM2COM
Output 2
*
ALMCOM
Forward Drive
Prohibit Input
*
*
13
16
POT
*
*
*
14
19
*
26
11
12
IN0
External
General-purpose
Input 0
24
*
Forward Torque Limit Input
NOT
Reverse Drive
Prohibit Input
External Latch
Signal 3
3
Reverse Torque
Limit Input
External general-purpose Input 1
8
20
External Latch
Signal 2
External
General-purpose
Input 1
12 to 24-VDC
Power Supply
Input
EXT3
9
10
7
+24VIN
Emergency
Stop Input
BAT
Backup Battery
Input
OUTM1
General-purpose
Output 1
35 OUTM1COM
*
36
General-purpose
Output1
97
Hardware reference
Pin
I/O
Code
Signal name
15
Output
/ALM
Alarm Output
16
Output
ALMCOM
29
Output
OUTM2
30
Output
OUTM2COM
31
Output
OUTM3
32
Output
OUTM3COM
36
Output
OUTM1
35
Output
OUTM1COM
Shell
---
---
General-purpose
Output 2 (READY)
General-purpose
Output 3 (CLIM)
General-purpose
Output 1 (BKIR)
FG
MECHATROLINK-II connectors (CN6A & CN6B)
fig. 56
MC Unit
789A
D
BC E
F 012
3456
Connect the G-series Servo Driver to the MECHATROLINK-II network using
the CN6A and CN6B connectors. Use one of the MECHATROLINK-II
connectors to connect to the previous MECHATROLINK-II device or the
TJ1-ML__. Use the other MECHATROLINK-II connector to connect to the
next MECHATROLINK-II device, or to connect a MECHATROLINK-II
terminator.
L1
L2
Ln
Note
Cable length between nodes (L1, L2, ... Ln) should be 0.5 m or
longer.
Total cable length should be L1 + L2 + ... + Ln = 50 m max.
Termination
resistor
Revision 5.0
HARDWARE REFERENCE MANUAL
98
Hardware reference
CN2 encoder input connector
The table below shows the pin layout for the encoder connector.
/i
Pin
Signal
Name
1
E5V
Encoder power supply +5 V
2
E0V
Encoder power supply GND
3
BAT+
Battery +
4
BAT-
Battery -
5
PS+
Encoder +phase S input
6
PS-
Encoder -phase S input
Shell
FG
Shield ground
CNA power supply connector
The table below shows the pin layout for the CNA power supply connector.
/i
Pin
Signal
Name
1
L1
2
L2
Main circuit
power supply input
3
L3
4
L1C
5
L2C
Control circuit
power supply input
Revision 5.0
HARDWARE REFERENCE MANUAL
99
Hardware reference
CNB servo motor connector
The table below shows the pin layout for the CNB servo motor connector.
/i
Pin
Signal
Name
External Regeneration Resistor
connection terminals
1
B1
2
B2
3
B3
4
U
5
V
6
W
Servomotor
connection
terminals
7
8
Frame ground
Revision 5.0
HARDWARE REFERENCE MANUAL
100
Hardware reference
3.5.12 MECHATROLINK-II Servo Drivers Accurax G5
You can also connect an Accurax G5 Servo Driver to a Trajexia system.
fig. 57
/i
+
Label
Terminal/LED
Description
A
---
Display area
B
CN5
Analog monitor check pins
C
L1, L2, L3
Main-circuit power terminals
D
L1C, L2C
Control-circuit power terminals
E
CHARGE
Charge lamp
F
B1, B2, B3
External Regeneration Resistor connection terminals
G
U, V, W
Servomotor connection terminals
H
---
Protective ground terminals
I
COMM
MECHATROLINK-II communications status LED indicator
J
---
Rotary switches
K
CN6A, CN6B
MECHATROLINK-II communications connector
L
CN7
USB connector
M
CN8
Connector for safety function devices
N
CN1
Control I/O connector
O
CN4
Full-closed encoder connector
P
CN2
Encoder connector
#
$
,
-
.
%
/
&
'
0
(
)
1
Revision 5.0
*
HARDWARE REFERENCE MANUAL
2
101
Hardware reference
MECHATROLINK-II Communications Status LED Indicator
The table below shows the LED indication status and the corresponding
conditions of the communications.
/i
LED status
Communications status
Not lit
No communication is established.
Green Flash
Asynchronous communications is established.
Green Light
Synchronous communications is established.
Red Flash
A clearable error occurred in MECHATROLINK-II communications.
•
Communications error (Err83.0)
•
Transmission cycle error (Err84.0)
•
SSYNC_SET error (Err84.4)
•
Watchdog data error (Err86.0)
•
Transmission cycle setting error (Err90.0)
•
CONNECT error (Err90.1)
•
SYNC command error (Err91.0)
Red Light
A non-clearable error occurred in MECHATROLINK-II communications.
•
Node address setting error (Err82.0)
•
SYNC process error (Err84.3)
Note
If any of communication related error occurs while an error that is
not related to MECHATROLINK-II communications happens, the
MECHATROLINK-II Communications Status LED Indicator follows
the corresponding communications status as shown above.
Revision 5.0
HARDWARE REFERENCE MANUAL
102
Hardware reference
Address settings (SW1)
Set the address selector of the Accurax G5 Servo Driver to the required
node address by using the X1 (right) and X10 (left) rotary switches.
The setting range for the node address setting rotary switch is 1 to 31. The
actual station address used on the network will be the sum of the rotary
switch setting and the offset value of 40h. These node addresses
correspond to axis numbers 0 (node address = 1) to 15 (node address = 16).
Note
The node address set by the rotary switch is read only once when
the control power is turned on. Any changes made by the rotary
switches after the power-on are not reflected to the Controller.
Such changes become effective only after the subsequent poweron following to a power-off. Do not change the rotary switch setting
after the power-on.
fig. 58
MECHATROLINK-II communications
status LED indicator (COMM)
Rotary switches for
node address setting
7-segment LED
indicator (2-digit)
COMM
ADR
Connector for
Analog Monitor
Note
The settable range for a node address is between 1 and 31. The
node address used over the network is the value obtained by adding the offset 40h to the rotary switch set value. If any value over or
under the range is set, the Node address setting error (Err82.0)
occurs.
Revision 5.0
HARDWARE REFERENCE MANUAL
103
Hardware reference
7-segment LED
The 7-segment LED indicator is on the front panel.
When the power is turned on, it shows the node address that is set by the
rotary switches. Then the indication changes in accordance with the setting
on the Default Display (Pn700). If any alarming error occurs, it indicates the
error number (Errxxx) as the alarm code. If any warning situation occurs, it
indicates the warning number as the warning code.
fig. 59
Turn ON Control Power Supply
All OFF
8.8.
All ON
(approx. 0.6 s)
nkak
[nA] (Node Address)
(approx. 0.6 s)
k3k
Rotary switch setting (for MSD = 0, LSD = 3)
(Time set by the Power ON Address Display
Duration Setting (Pn006))
Main Power Supply ON
and Network Established
-k-k
-k-.
Servo ON
[- -]
Main Power Supply OFF
or Network Not Established
[- -] + right dot ON
Servo OFF
0k0.
Alarm Issued
Alarm Cleared
Alarm code flashes in decimal display
(Below is an example for overload)
Revision 5.0
1k6k
[00] + right dot ON
Warning Issued
Alternates between warning code (hex)
and normal display
(Below is an example for overload)
9k0.
Warning code (2 s)
HARDWARE REFERENCE MANUAL
Warning Cleared
0k0.
Normal Display
(approx. 4 s)
104
Hardware reference
CN1 I/O Signal connector
The table below shows the pin layout for the I/O signal connector (CN1).
fig. 60
/i
1
Pin
I/O
Code
Signal name
6
Input
+24 VIN
12 to 24-VDC Power Supply Input
5
7
Input
Input
IN1
IN2
OUTM1
8
Input
IN3
General-purpose Input 3
9
Input
IN4
General-purpose Input 4
10
Input
IN5
General-purpose Input 5
11
Input
IN6
General-purpose Input 6
12
Input
IN7
General-purpose Input 7
13
Input
IN8
General-purpose Input 8
3
Output
/ALM
Alarm output
4
Output
ALMCOM
1
Output
OUTM1
2
Output
OUTM1COM
25
Output
OUTM2
26
Output
OUTM2COM
14
---
BAT
15
---
BATGND
16
---
GND
Signal ground
17 to 24
Input
---
Spare inputs. Do not connect anything to
these inputs.
Shell
---
---
FG
14
2 OUTM1COM
3
/ALM
5
IN1
General-purpose
Input 1
6
7
IN2
General-purpose
Input 2
IN4
General-purpose
Input 4
10
11
IN6
General-purpose
Input 6
IN8
General-purpose
Input 8
12
13
IN3
IN5
IN7
GND
12 to 24-VDC
power
supply input
18
General-purpose
Input 3
Absolute
encoder backup
battery input
17
*
19
*
21
*
23
*
*
*
22
*
24
*
General-purpose
nput 5
General-purpose
Input 7
BATGND
Signal Ground
Alarm Output
Common
20
8
9
+24 VIN
Absolute
encoder backup
battery input
15
16
ALMCOM
BAT
General-purpose
Output 1 Common
Alarm Output
4
General-purpose Input 1
General-purpose Input 2
General-purpose
Output 1
25
General-purpose
26 OUTM2COM
Output 2 Common
OUTM2
General-purpose
Output 2
General-purpose
Output 1
General-purpose
Output 2
Backup
Battery Input
Revision 5.0
HARDWARE REFERENCE MANUAL
105
Hardware reference
MECHATROLINK-II connectors (CN6A & CN6B)
fig. 61
MC Unit
78 9 A
D
BC E
F 01 2
34 5 6
Connect the G-series Servo Driver to the MECHATROLINK-II network using
the CN6A and CN6B connectors. Use one of the MECHATROLINK-II
connectors to connect to the previous MECHATROLINK-II device or the
TJ1-ML__. Use the other MECHATROLINK-II connector to connect to the
next MECHATROLINK-II device, or to connect a MECHATROLINK-II
terminator.
L1
L2
Ln
Note
Cable length between nodes (L1, L2, ... Ln) should be 0.5 m or
longer.
Total cable length should be L1 + L2 + ... + Ln = 50 m max.
Termination
resistor
Revision 5.0
HARDWARE REFERENCE MANUAL
106
Hardware reference
CN2 Encoder input connector
The table below shows the pin layout for the encoder connector.
/i
Pin
Signal
Name
1
E5V
Encoder power supply +5 V
2
E0V
Encoder power supply GND
3
BAT+
Battery +
4
BAT-
Battery -
5
PS+
Encoder +phase S input
6
PS-
Encoder -phase S input
Shell
FG
Shield ground
CN4 External encoder connector
The table below shows the pin layout for the external encoder connector.
/i
Pin
Signal
Name
1
E5V
Encoder power supply +5 V
2
E0V
Encoder power supply GND
3
PS+
Encoder +phase S input
4
PS-
Encoder -phase S input
5
EXA+
Encoder +phase A input
6
EXA-
Encoder -phase A input
7
EXB+
Encoder +phase B input
8
EXB-
Encoder -phase B input
9
EXZ+
Encoder +phase Z input
10
EXZ-
Encoder -phase Z input
Shell
FG
Shield ground
Revision 5.0
HARDWARE REFERENCE MANUAL
107
Hardware reference
CN5 Monitor connector
The table below shows the pin layout for the CN5 monitor connector.
/i
Pin
Signal
Name
1
AM1
Analog monitor output 1
2
AM2
Analog monitor output 2
3
GND
Analog monitor ground
4
---
Reserved: do not connect.
5
---
Reserved: do not connect.
6
---
Reserved: do not connect.
CN7 USB Connector
The table below shows the pin layout for the CN7 USB connector.
/i
Pin
Signal
Name
1
VBUS
2
D+
3
D-
4
---
Reserved: do not connect.
5
SENGND
Signal ground
USB signal terminal
CN8 Safety connector
The table below shows the pin layout for the CN8 safety connector.
/i
Revision 5.0
Pin
Signal
Name
1
---
Reserved: do not connect.
2
---
Reserved: do not connect.
3
SF1-
Safety input 1
4
SF1+
5
SF2-
6
SF2+
7
EDM-
8
EDM+
Safety input 2
EDM output
HARDWARE REFERENCE MANUAL
108
Hardware reference
Pin
Signal
Name
Shell
FG
Shield ground
CNA Power supply connector
The table below shows the pin layout for the CNA power supply connector.
/i
Pin
Signal
Name
1
L1
2
L2
Main circuit
power supply input
3
L3
4
L1C
5
L2C
Control circuit
power supply input
CNB Servo motor connector
The table below shows the pin layout for the CNB servo motor connector.
/i
Pin
Signal
Name
1
B1
2
B2
External Regeneration Resistor
connection terminals
3
B3
4
U
5
V
6
W
Servomotor
connection
terminals
7
8
Frame ground
Related BASIC commands
Revision 5.0
The following BASIC commands are related to the MECHATROLINK-II
Servo Drivers Accurax G5:
• ATYPE
• AXIS
• AXIS_ENABLE
• AXISSTATUS
• DRIVE_ALARM
HARDWARE REFERENCE MANUAL
109
Hardware reference
•
•
•
•
•
•
•
•
DRIVE_CLEAR
DRIVE_CONTROL
DRIVE_INPUTS
DRIVE_MONITOR
DRIVE_READ
DRIVE_RESET
DRIVE_STATUS
DRIVE_WRITE
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
HARDWARE REFERENCE MANUAL
110
Hardware reference
3.5.13 MECHATROLINK-II Inverter V7
A V7 Inverter with a MECHATROLINK-II interface is designed to make
speed and torque control (if the Inverter supports this feature) of an AC
induction motor. No position control is supported via MECHATROLINK-II.
fig. 62
A
B
C
By default an Inverter is not considered an axis by the TJ1-MC__. To control
an Inverter as a servo axis, this axis must be defined with function 8 of the
command INVERTER_COMMAND. Refer to section 2.7.4 for more
information.
The illustration shows the external appearance of the SI-T/V7 Unit.
A. LED
B. Modular plug (CN10)
C. Optional connector (CN1)
D. Communications connector (CN2)
E. Dipswitch
F. Rotary switch
G. Ground terminal
H. Communications connector (CN2)
H
G
F
E
D
Revision 5.0
HARDWARE REFERENCE MANUAL
111
Hardware reference
LED indicators
The LED indicators indicate the status of the communications of the
MECHATROLINK-II and the SI-T/V7 Unit.
A. Run
B. TX
C. RX
D. ERR
fig. 63
A
B
C
D
/i
Name
RUN
ERR
TX
RX
Display
Explanation
Color
Status
Green
Lit
Normal operation
-
Not lit
Communications CPU stopped, resetting hardware,
RAM check error, DPRAM check error, station address
setting error or Inverter model code error
Red
Lit
Watchdog timeout error, communications error or resetting hardware
Red
Flashing
ROM check error (once)*, RAM check error (twice)*,
DPRAM check error (3 times)*, communications ASIC
self-diagnosis error (4 times)*, ASIC RAM check error
(5 times)*, station address setting error (6 times)*,
Inverter model code error (7 times)*
*: indicates the number of flashes
-
Not lit
No communication error or self-diagnosis error
Green
Lit
Sending data
-
Not lit
Sending of data stopped, hardware reset
Green
Lit
Searching for receiving carrier
-
Not lit
No receiving carrier found, hardware reset
Revision 5.0
HARDWARE REFERENCE MANUAL
112
Hardware reference
Dipswitch
The following table shows the dipswitch settings of the SI-T/V7 Unit.
/i
fig. 64
Name
Label
Status
Function
Baud rate
S1-1
on
10 Mbps (MECHATROLINK-II)
Data length
S1-2
on
32-byte data transmission
(MECHATROLINK-II)
Station
address
S1-3
off
Set the 10th digit of the station number to 2.
Invalid if the maximum number of units including
the S2 of the rotary switch is 20.
on
Set the 10th digit of the station number to 3.
Invalid if the maximum number of units including
the S2 of the rotary switch is 3F.
off
Normally off1
on
Not used
Maintenance
S1-4
1
2
3
4
OFF
1. For maintenance. Always leave this switch off.
Rotary switch
The following table shows the rotary switch settings of the SI-T/V7 Unit.
/i
fig. 65
Factory setting
S2
0 to F
Set the 1st digit of the station number. Invalid if 1
the maximum number of units including the S13 is 20 or 3F.
Revision 5.0
S1-3
S2
Station number
S1-3
S2
Station number
off
0
Fault
on
0
30
off
1
21
on
1
31
off
2
22
on
2
32
HARDWARE REFERENCE MANUAL
3 4 5 6
/i
F 0 1
B CDE
A
Function
7 8 9
Status
2
Label
113
Hardware reference
S1-3
S2
Station number
S1-3
S2
Station number
off
3
23
on
3
33
off
4
24
on
4
34
off
5
25
on
5
35
off
6
26
on
6
36
off
7
27
on
7
37
off
8
28
on
8
38
off
9
29
on
9
39
off
A
2A
on
A
3A
off
B
2B
on
B
3B
off
C
2C
on
C
3C
off
D
2D
on
D
3D
off
E
2E
on
E
3E
off
F
2F
on
F
Fault
To use the V7 Inverter with the MECHATROLINK-II interface it is necessary
to make the following settings in the Inverter:
• N3=3 Sequence via MECHATROLINK-II
• N4=9 Reference via MECHATROLINK-II
Check the manual for details about the V7 Inverter.
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
Inverters V7 series:
• ATYPE (ATYPE=49)
• INVERTER_COMMAND
• INVERTER_READ
• INVERTER_WRITE
Revision 5.0
For more information, refer to the Trajexia Programming Manual.
HARDWARE REFERENCE MANUAL
114
Hardware reference
3.5.14 MECHATROLINK-II Inverter F7 and G7
The F7 and G7 Inverters with a MECHATROLINK-II interface are designed
to make speed and torque control (if the Inverter supports this feature) of an
AC induction motor. No position control is supported via MECHATROLINKII.
By default an Inverter is not considered an axis by the TJ1-MC__. To control
an Inverter as a servo axis, this axis must be defined with function 8 of the
command INVERTER_COMMAND. Refer to section 2.7.4 for more
information
The illustration shows the installation of the SI-T card.
A. SI-T Card
B. Control terminal
C. 3CN: Option D connector
D. Option CN (To secure option C or D)
E. 2CN: Option C connector
F. 4CN: Option A connector
fig. 66
A
F
E
D
C
B
Revision 5.0
HARDWARE REFERENCE MANUAL
115
Hardware reference
The illustration shows the external appearance of the SI-T Card.
A. LED
B. Rotary switch
C. Dipswitch
D. Communications connector
E. Code No.
F. Type
fig. 67
A
B
C
F
E
D
LED indicators
The LED indicators indicate the status of the communications of the
MECHATROLINK-II and the SI-T Card.
/i
Name
RUN
Display
Explanation
Color
Status
Green
Lit
Normal operation
-
Not lit
Communication CPU stopped, resetting hardware, RAM
check error, DPRAM check error, station address setting
error or Inverter model code error
Revision 5.0
HARDWARE REFERENCE MANUAL
116
Hardware reference
Name
ERR
TX
RX
Display
Explanation
Color
Status
Red
Lit
Watchdog timeout error, communication error, diagnosis
error or resetting hardware
Red
Flashing
ROM check error (once)*, RAM check error (twice)*,
DPRAM check error (3 times)*, communications ASIC
self-diagnosis error (4 times)*, ASIC RAM check error (5
times)*, station address setting error (6 times)*, Inverter
model code error (7 times)*
*: indicates the number of flashes
-
Not lit
No communication error or self-diagnosis error
Green
Lit
Sending data
-
Not lit
Sending of data stopped, hardware reset
Green
Lit
Searching for receiving carrier
-
Not lit
No receiving carrier found, hardware reset
Dipswitch
The following table shows the dipswitch settings of the SI-T/V7 Unit.
fig. 68
/i
Name
Label
Status
Function
Baud rate
S1-1
on
10 Mbps (MECHATROLINK-II)
Data length
S1-2
on
32-byte data transmission
(MECHATROLINK-II)
Station
address
S1-3
off
Set the 10th digit of the station number to 2. Invalid
if the maximum number of units including the S2 of
the rotary switch is 20.
on
Set the 10th digit of the station number to 3. Invalid
if the maximum number of units including the S2 of
the rotary switch is 3F.
off
Normally off1
on
Not used
Maintenance
S1-4
1
2
3
4
OFF
Revision 5.0
1. For maintenance. Always leave this switch off.
HARDWARE REFERENCE MANUAL
117
Hardware reference
Rotary switch
The following table shows the rotary switch settings of the SI-T/V7 Unit.
/i
fig. 69
S2
0 to F
Set the 1st digit of the station number X0H-XFH.
Invalid if the maximum number of units including the
S1-3 is 20 or 3F.
1
Switch Setting and Station Number:
/i
Revision 5.0
S1-3
S2
Station number
S1-3
S2
Station number
off
0
Fault
on
0
30
off
1
21
on
1
31
off
2
22
on
2
32
off
3
23
on
3
33
off
4
24
on
4
34
off
5
25
on
5
35
off
6
26
on
6
36
off
7
27
on
7
37
off
8
28
on
8
38
off
9
29
on
9
39
off
A
2A
on
A
3A
off
B
2B
on
B
3B
off
C
2C
on
C
3C
off
D
2D
on
D
3D
off
E
2E
on
E
3E
off
F
2F
on
F
Fault
HARDWARE REFERENCE MANUAL
F 0 1
B CDE
A
Factory setting
7 8 9
Function
3 4 5 6
Status
2
Label
118
Hardware reference
To use the F7 or G7 Inverter with the MECHATROLINK-II interface it is
necessary to make the following settings in the Inverter:
• B1-01=3 Sequence via MECHATROLINK-II
• B1-02=3 Reference via MECHATROLINK-II
Check the corresponding manual for details about the F7 or G7 Inverter.
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
Inverters F7 and G7 series:
• ATYPE (ATYPE=49)
• INVERTER_COMMAND
• INVERTER_READ
• INVERTER_WRITE
For more information, refer to the Trajexia Programming Manual.
3.5.15 MECHATROLINK-II digital I/O slaves
An I/O device allows to integrate in the system remote digital and analogue
inputs and outputs. Those are autodetected and automatically allocated by
the Trajexia system.
Digital I/O module: JEPMC IO2310/IO2330
Revision 5.0
This is a 64 channel Digital Input and 64 channel Digital Output
MECHATROLINK-II slave unit. The digital inputs and outputs are
automatically allocated by the Trajexia system according to the unit number
and can be read and set by Trajexia starting from IN(32) and OP(32).
Trajexia Inputs and outputs are automatically mapped starting from IN(32)
and OP(32), according to the MECHATROLINK-II node number. In the case
of existing several IO2310 units, the unit with lowest node number
corresponds to IN(32) to IN(95) and OP(32) to OP(95), the next lower to
IN(156) to IN(219) and OP(156) to OP(219).
The value is refreshed every servo period.
A. Input signal connector 1
B. Output signal connector 1
C. Input signal connector 2
HARDWARE REFERENCE MANUAL
fig. 70
J
I
H
A
B
C
D
G
F
E
119
Hardware reference
D.
E.
F.
G.
H.
I.
J.
Output signal connector 2
Power supply terminals
I/O indicator switch
Station number switch
Dipswitch for setting
MECHATROLINK-II connector
I/O indicators
Connector description
I/O and Status Indicators:
fig. 71
/i
R Active F
Indicator
Name
Indicator Color
Meaning when lit
R
Yellow
Not used, stays lit
ACTIVE
Yellow
Sending data through MECHATROLINK-II
F
Red
Blown fuse
1 to 32
Yellow
Input signal and output signal monitors.
The meaning of these indicators depends on the I/O
indicator switch setting.
1
9 17 25
2 10 18 26
3 11 19 27
4 12 20 28
5 13 21 29
6 14 22 30
7 15 23 31
8 16 24 32
Indicator switch:
Selects which 32 I/O points are monitored by the I/O indicators.
• IN1: Input signals 1 to 32
• IN2: Input signals 33 to 64
• OUT1: Output signals 1 to 32
• OUT2: Output signals 33 to 64
MECHATROLINK-II Connector:
Connects through a MECHATROLINK-II cable.
fig. 72
IN2
SW2 IN1
OUT2
OUT1
fig. 73
Revision 5.0
HARDWARE REFERENCE MANUAL
120
Hardware reference
I/O Signal connector:
Connect the I/O Unit with external I/O signals through the I/O Cable.
Number of I/O points: 64 inputs and 64 outputs
fig. 74
IN 1
A1
OUT 1
B1 A1
IN 2
B1 A1
OUT 2
B1 A1
B1
Revision 5.0
HARDWARE REFERENCE MANUAL
121
Hardware reference
Digital I/O layout
The pin layout of the I/O connectors is the same for the IO2310, and IO2330
modules. The following table shows the pin layout of the IN1 connector.
/i
No.
Signal name
A1
(NC)
A2
+24V_2
A3
Remarks
No.
Signal name
B1
(NC)
24-V power supply 2
B2
+24V_2
24-V power supply 2
IN32
Input 32
B3
IN31
Input 31
A4
IN30
Input 30
B4
IN29
Input 29
A5
IN28
Input 28
B5
IN27
Input 27
A6
IN26
Input 26
B6
IN25
Input 25
A7
IN24
Input 24
B7
IN23
Input 23
A8
IN22
Input 22
B8
IN21
Input 21
A9
IN20
Input 20
B9
IN19
Input 19
A10
IN18
Input 18
B10
IN17
Input 17
A11
IN16
Input 16
B11
IN15
Input 15
A12
IN14
Input 14
B12
IN13
Input 13
A13
IN12
Input 12
B13
IN11
Input 11
A14
IN10
Input 10
B14
IN09
Input 9
A15
IN08
Input 8
B15
IN07
Input 7
A16
IN06
Input 6
B16
IN05
Input 5
A17
IN04
Input 4
B17
IN03
Input 3
A18
IN02
Input 2
B18
IN01
Input 1
A19
(NC)
B19
(NC)
A20
+24V_1
B20
+24V_1
24-V power supply 1
Remarks
24-V power supply 1
Note: The +24V_1 is used for IN01 to IN16; +24V_2 is used for IN17 to IN32.
Revision 5.0
HARDWARE REFERENCE MANUAL
122
Hardware reference
The following table shows the pin layout of the IN2 connector.
/i
No.
Signal name
A1
(NC)
A2
+24V_4
A3
Remarks
No.
Signal name
B1
(NC)
24-V power
supply 4
B2
+24V_4
24-V power supply 4
IN64
Input 64
B3
IN63
Input 63
A4
IN62
Input 62
B4
IN61
Input 61
A5
IN60
Input 60
B5
IN59
Input 59
A6
IN58
Input 58
B6
IN57
Input 57
A7
IN56
Input 56
B7
IN55
Input 55
A8
IN54
Input 54
B8
IN53
Input 53
A9
IN52
Input 52
B9
IN51
Input 51
A10
IN50
Input 50
B10
IN49
Input 49
A11
IN48
Input 48
B11
IN47
Input 47
A12
IN46
Input 46
B12
IN45
Input 45
A13
IN44
Input 44
B13
IN43
Input 43
A14
IN42
Input 42
B14
IN41
Input 41
A15
IN40
Input 40
B15
IN39
Input 39
A16
IN38
Input 38
B16
IN37
Input 37
A17
IN36
Input 36
B17
IN35
Input 35
A18
IN34
Input 34
B18
IN33
Input 33
A19
(NC)
B19
(NC)
A20
+24V_3
B20
+24V_3
24-V power
supply 3
Remarks
24-V power supply 3
Note: The +24V_3 is used for IN33 to IN48; +24V_4 is used for IN49 to IN64.
Revision 5.0
HARDWARE REFERENCE MANUAL
123
Hardware reference
The following table shows the pin layout of the OUT1 connector.
/i
No.
Signal name
Remarks
No.
Signal name
Remarks
A1
024V_6
Common
ground 6
B1
024V_6
Common ground
6
A2
+24V_6
24-V power
supply 6
B2
+24V_6
24-V power supply 6
A3
OUT32
Output 32
B3
OUT31
Output 31
A4
OUT30
Output 30
B4
OUT29
Output 29
A5
OUT28
Output 28
B5
OUT27
Output 27
A6
OUT26
Output 26
B6
OUT25
Output 25
A7
OUT24
Output 24
B7
OUT23
Output 23
A8
OUT22
Output 22
B8
OUT21
Output 21
A9
OUT20
Output 20
B9
OUT19
Output 19
A10
OUT18
Output 18
B10
OUT17
Output 17
A11
OUT16
Output 16
B11
OUT15
Output 15
A12
OUT14
Output 14
B12
OUT13
Output 13
A13
OUT12
Output 12
B13
OUT11
Output 11
A14
OUT10
Output 10
B14
OUT09
Output 9
A15
OUT08
Output 8
B15
OUT07
Output 7
A16
OUT06
Output 6
B16
OUT05
Output 5
A17
OUT04
Output 4
B17
OUT03
Output 3
A18
OUT02
Output 2
B18
OUT01
Output 1
A19
024V_5
Common
ground 5
B19
024V_5
Common ground
5
A20
+24V_5
24-V power
supply 5
B20
+24V_5
24-V power supply 5
Revision 5.0
Note: The +24V_5 and 024V_5 are used for OUT01 to OUT16;
+24V_5 and 024V_6 are used for OUT17 to OUT32.
HARDWARE REFERENCE MANUAL
124
Hardware reference
The following table shows the pin layout of the OUT2 connector.
/i
No.
Signal name
Remarks
No.
Signal name
Remarks
A1
024V_8
Common
ground 8
B1
024V_8
Common ground
8
A2
+24V_8
24-V power
supply 8
B2
+24V_8
24-V power supply 8
A3
OUT64
Output 64
B3
OUT63
Output 63
A4
OUT62
Output 62
B4
OUT61
Output 61
A5
OUT60
Output 60
B5
OUT59
Output 59
A6
OUT58
Output 58
B6
OUT57
Output 57
A7
OUT56
Output 56
B7
OUT55
Output 55
A8
OUT54
Output 54
B8
OUT53
Output 53
A9
OUT52
Output 52
B9
OUT51
Output 51
A10
OUT50
Output 50
B10
OUT49
Output 49
A11
OUT48
Output 48
B11
OUT47
Output 47
A12
OUT46
Output 46
B12
OUT45
Output 45
A13
OUT44
Output 44
B13
OUT43
Output 43
A14
OUT42
Output 42
B14
OUT41
Output 41
A15
OUT40
Output 40
B15
OUT39
Output 39
A16
OUT38
Output 38
B16
OUT37
Output 37
A17
OUT36
Output 36
B17
OUT35
Output 35
A18
OUT34
Output 34
B18
OUT33
Output 33
A19
024V_7
Common
ground 7
B19
024V_7
Common ground
7
A20
+24V_7
24-V power
supply 7
B20
+24V_7
24-V power supply 7
Revision 5.0
Note: The +24V_7 and 024V_7 are used for OUT33 to OUT48;
+24V_8 and 024V_8 are used for OUT49 to OUT64
HARDWARE REFERENCE MANUAL
125
Hardware reference
I/O Cable:
The following table shows the standard I/O cable models. The standard
cable is used for both IO2310 and IO2330 modules.
fig. 75
/i
Model
Length (m)
I/O Cable
JEPMC-W5410-05
0.5
JEPMC-W5410-10
1
JEPMC-W5410-30
3
fig. 76
BCD
E
6
F012
Station number and dipswitch settings
Station Number switch sets the station number of the module in the
MECHATROLINK-II system. The range is 0 to F.
Use a unique station number for each unit if two or more units are
connected.
7 8 9A
Name
345
Dipswitch settings:
The dipswitch sets the communication parameters.
fig. 77
/i
Display (Switch
no.)
Name
Status
Function
-
Reserved by system
-
Be sure to turn it off
3
MECHATROLINK-II upperplace
address setting
on
7xh
off
6xh
2
I/O byte setting
on
32-byte mode
1
Baud rate setting
on
10 Mbps
_
3
2
1
OFF ON
Revision 5.0
The data in the parentheses indicate the MECHATROLINK-II addresses.
HARDWARE REFERENCE MANUAL
126
Hardware reference
/i
Station
Address
Dipswitch 3
Station
number
switch
Station
Address
Dipswitch 3
Station
number
switch
1(61h)
off
1
16(70h)
on
0
2(62h)
off
2
17(71h)
on
1
3(63h)
off
3
18(72h)
on
2
4(64h)
off
4
19(73h)
on
3
5(65h)
off
5
20(74h)
on
4
6(66h)
off
6
21(75h)
on
5
7(67h)
off
7
22(76h)
on
6
8(68h)
off
8
23(77h)
on
7
9(69h)
off
9
24(78h)
on
8
10(6Ah)
off
A
25(79h)
on
9
11(6Bh)
off
B
26(7Ah)
on
A
12(6Ch)
off
C
27(7Bh)
on
B
13(6Dh)
off
D
28(7Ch)
on
C
14(6Eh)
off
E
29(7Dh)
on
D
15(6Fh)
off
F
Not used
on
E, F
Revision 5.0
HARDWARE REFERENCE MANUAL
127
Hardware reference
Power supply input
The external wiring terminal supplies 24 VDC to the I/O module.
fig. 78
/i
Terminal name
Function
DC24V
+24 VDC
DC0V
0 VDC
FG
Protective ground terminal
24 VDC
0 VDC
Specification
Input circuit:
The input circuit specifications are shown below. The input circuit is used
both for IO2310, and IO2330 modules.
fig. 79
+ 5V
/i
Item
Specifications
Number of input points
64 points (32 points x 2)
Input type
Sinking or sourcing
Isolation method
Photocoupler
Input voltage
24 VDC (20.4 to 28.8 VDC)
Input current
5 mA/point
on voltage/current
9V min./1.6 mA min.
off voltage/current
7V max./1.3 mA max.
on time / off time
on time: 2ms, off time: 3 ms
Output points per common
16 points per common (1 to 16, 17 to 32, 33 to 48, 49 to
64)
680 Ω
0.01 µF
4.7 kΩ
Revision 5.0
HARDWARE REFERENCE MANUAL
Input Circuit
128
Hardware reference
Output circuit:
The output specifications are shown below.
fig. 80
+ 24V
/i
+ 24V
Item
Specifications
Module
IO2310
Number of output points
64 points (32 point x 2)
Output type
Transistor, open collector or
sinking
Isolation method
Photocoupler
Output voltage
24 VDC (20.4 to 28.8 VDC)
Output current
50 mA/point
Leakage current when off
0.1 mA max.
on time / off time
on time: 2 ms max., off time: 4 ms max.
Output points per common
16 points per common (1 to 16, 17 to 32, 33 to 48, 49 to 64)
Fuses
A fuse for each common point to prevent fire caused by the
output short-circuit
Error detection
Blown fuse detection
IO2330
OUT
10 kΩ
Transistor, open collector or
sourcing
O24V
O24V
Output Circuit IO2310
+ 24V
+ 24V
15 kΩ
OUT
O24V
General specifications:
O24V
/i
Item
Specifications
Name
64-point I/O Module
Model description
IO2310/IO2330
Model number
JEPMC-IO2310/JEPMC-IO2330
External power supply
24 VDC (20.4 to 28. 8VDC)
Rated current
0.5 A
Inrush current
1A
Dimensions (mm)
120 x 130 x 105 (W x H x D)
Output Circuit IO2330
Revision 5.0
HARDWARE REFERENCE MANUAL
129
Hardware reference
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
digital I/O module:
• IN
• NIO
• OP
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
HARDWARE REFERENCE MANUAL
130
Hardware reference
3.5.16 MECHATROLINK-II 4-Channel analogue input
module
This is a 4-channel analogue input MECHATROLINK-II slave. The analogue
inputs are automatically allocated by the Trajexia system according to the
unit number and can be read by Trajexia starting from AIN(0).
The I/Os are automatically mapped in AIN(x) according to the
MECHATROLINK-II node number. In the case of existing several AN2900
units, the one with lowest node number corresponds to AIN(0) to AIN(3), the
next lowest one to AIN(4) to AIN(7).
The value is refreshed every servo_period.
A. LED indicators
B. Module description (AN2900)
C. Module mounting holes (for M4 screws) for back mounting
D. Module mounting holes (for M4 screws) for bottom mounting
E. Terminal cover
F. Detachable terminal
G. External connector terminals (M3, Phillips-head)
H. Signal label
I. Terminal block mounting screws (two M3.5 screws)
J. MECHATROLINK-II connector
K. Front cover
L. Dipswitch
fig. 81
A
L
K
B
J
C
D
I
H
F
G
E
Connector description
LED Indicators:
/i
fig. 82
Indicator
name
Indicator color
Meaning when lit or flashing
RDY
Green
Lit
The module is operating normally
Flashing
The transmission cable is disconnected or the module is waiting for
communication with the master
Revision 5.0
TX
Green
Lit
Sending data
RX
Green
Lit
Receiving data
HARDWARE REFERENCE MANUAL
RDY TX RX ERR FLT
CH1 CH2 Ch3 Ch4
131
Hardware reference
ERR
Red
Lit
A communication error occurred
FLT
Red
Lit
Offset/gain setting error
Flashing
Self-diagnostic error
Lit
Each LED indicates that the input is
out-of-range for that channel.
Out-of-range inputs are as follows:
+10.02 V < Channel input signal
Channel input signal < -10.02 V
CH1 to CH4
Green
Dipswitch functions:
The dipswitch consists of eight pins. The pins are numbered 1 to 8, as
shown in the illustration. Each pin is turned to on when it is moved to the
upper position.
The following table shows the function of each switch.
Any switches other than pin 7 become effective when each switch is
changed.
fig. 83
ON
Meaning when lit or flashing
1 2 3 4 5 6 7 8
ON
Indicator color
SW
Indicator
name
/i
Pin no.
Setting
Function
1 to 5
on
Set the slave address of pins 1 through 5. For details, refer to
the table below.
off
6
on
32-byte data transmission (MECHATROLINK-II).
7
on
Software filter (average is 5 times) is set to “Enabled“.
off
Software filter is set to “Disabled“.
on
Sets the baud rate to 10 Mbps.
8
Revision 5.0
Slave address settings:
Set the slave address with pins 1 to 5 on the dipswitch on the front of the
front of the distributed I/O module.
Refer to the following table, and set the slave addresses as required.
HARDWARE REFERENCE MANUAL
132
Hardware reference
/i
Pin No.
Slave address
Revision 5.0
1
2
3
4
5
0
0
0
0
0
Not used
1
0
0
0
0
1
0
1
0
0
0
2
1
1
0
0
0
3
0
0
1
0
0
4
1
0
1
0
0
5
0
1
1
0
0
6
1
1
1
0
0
7
0
0
0
1
0
8
1
0
0
1
0
9
0
1
0
1
0
10
1
1
0
1
0
11
0
0
1
1
0
12
1
0
1
1
0
13
0
1
1
1
0
14
1
1
1
1
0
15
0
0
0
0
1
16
1
0
0
0
1
17
0
1
0
0
1
18
1
1
0
0
1
19
0
0
1
0
1
20
1
0
1
0
1
21
0
1
1
0
1
22
1
1
1
0
1
23
0
0
0
1
1
24
HARDWARE REFERENCE MANUAL
133
Hardware reference
Pin No.
Slave address
1
2
3
4
5
1
0
0
1
1
25
0
1
0
1
1
26
1
1
0
1
1
27
0
0
1
1
1
28
1
0
1
1
1
29
0
1
1
1
1
30
1
1
1
1
1
Not used
Specification
The performance specifications of the analogue input module (±10 V, 4 CH)
are shown below.
/i
Revision 5.0
Item
Specifications
Name
Analog input module (-10 V to + 10 V, 4 CH)
Model description
AN2900
Model number
JEPMC-AN2900
Input signal range
-10 to 10V
Special inputs
None
Number of input channels
4 channels, isolated as a group
Input impedance
1 MΩ min.
Maximum allowable overload
-20 to 20 V
Digital resolution
16 bits
Data format
Binary (2s complement) -32,000 to 32,000
Error
±0.5% F.S. (at 25ºC)
±1.0% F.S. (at 0 to 60ºC)
Input delay time
4 ms max.
Sampling interval
Input data is refreshed every communication cycle
HARDWARE REFERENCE MANUAL
134
Hardware reference
Item
Specifications
Input filter characteristics
Software filter
Number of allocated words
5 words/module
Maintenance/diagnostic functions
Watchdog timer
External connections
Removable terminal block with 23 M3 screw terminals
/i
fig. 84
Item
Input circuit isolation
Specifications
Isolation
method
Photocoupler
(There is no isolation between input channels.)
Dielectric
strength
1,500 VAC for 1 minute between input terminals and
internal circuits
Insulation
resistance
100 MΩ min. at 500 VDC between input terminals and
internal circuits (at room temperature and humidity)
External power supply
Main external power supply:
24 VDC (20.4 to 26.4 VDC), 120 mA max.
Derating conditions
The maximum ambient operating temperature is limited
with some mounting directions.
Maximum heating value
2.88 W
Hot swapping
Terminal block: not permitted
Communication connector: permitted
weight
Approx. 300 g
Dimensions (mm)
161 x 44 x 79 (W x H x D)
The figure shows the circuit configuration for the analogue input module.
Related BASIC commands
Revision 5.0
The following BASIC commands are related to the MECHATROLINK-II
analogue input module:
• AIN
• NAIO
For more information, refer to the Trajexia Programming Manual.
HARDWARE REFERENCE MANUAL
135
Hardware reference
3.5.17 MECHATROLINK-II 2-Channel analogue output module
This is a 2-channel analogue output MECHATROLINK-II slave. The
analogue output is automatically allocated by the Trajexia system according
to the unit number and can be read by Trajexia starting from AOUT(0).
The I/Os are automatically mapped in AOUT(x) according to the
MECHATROLINK-II node number. In case of existing several AN2910 units,
the one with lower node number corresponds to AOUT(0) to AOUT(1), the
next one to AOUT(3) to AOUT(4).
The value is refreshed every SERVO_PERIOD.
A. LED indicators
B. Module description (AN2910)
C. Module mounting holes (for M4 screws) for back mounting
D. Module mounting holes (for M4 screws) for bottom mounting
E. Terminal cover
F. Detachable terminal
G. External connector terminals (M3, Phillips-head)
H. Signal label
I. Terminal block mounting screws (two M3.5 screws)
J. MECHATROLINK-II connector
K. Front cover
L. Dipswitch
fig. 85
A
L
K
B
J
C
D
I
H
G
F
E
Connector description
LED Indicators:
/i
fig. 86
Revision 5.0
Indicator
name
Indicator color
Meaning when lit or flashing
RDY
Green
Lit
The module is operating normally
Flashing
The transmission cable is disconnected or the module is waiting for
communication with the master
Lit
Sending data
TX
Green
HARDWARE REFERENCE MANUAL
RDY TX RX ERR FLT
136
Hardware reference
RX
Green
Lit
Receiving data
ERR
Red
Lit
A communication error occurred
FLT
Red
Lit
Offset/gain setting error
Flashing
Self-diagnostic error
Dipswitch functions:
The dipswitch consists of eight pins. The pins are numbered 1 to 8, as
shown in the following diagram. Each pin is turned to on when it is moved to
the upper position.
The setting of each pin becomes effective as soon as the dipswitch is
changed.
The following table shows the functions that correspond to the settings for
each pin.
fig. 87
ON
Meaning when lit or flashing
1 2 3 4 5 6 7 8
ON
Indicator color
SW
Indicator
name
/i
Pin no.
Setting
Function
1 to 5
on
Set the slave address of pins 1 through 5. For details, refer to
the table below:
off
6
on
32-byte data transmission (MECHATROLINK-II).
7
on
The output when communication stops is set to “data immediately before stop“.
off
The output when communication stops is set to “0“.
on
Sets the baud rate to 10 Mbps.
8
Slave address settings:
Set the slave address with pins 1 to 5 on the dipswitch on the front of the
distributed I/O module.
Refer to the following table, and set the slave addresses as required.
/i
Revision 5.0
HARDWARE REFERENCE MANUAL
137
Hardware reference
Pin No.
Slave address
Revision 5.0
1
2
3
4
5
0
0
0
0
0
Not used
1
0
0
0
0
1
0
1
0
0
0
2
1
1
0
0
0
3
0
0
1
0
0
4
1
0
1
0
0
5
0
1
1
0
0
6
1
1
1
0
0
7
0
0
0
1
0
8
1
0
0
1
0
9
0
1
0
1
0
10
1
1
0
1
0
11
0
0
1
1
0
12
1
0
1
1
0
13
0
1
1
1
0
14
1
1
1
1
0
15
0
0
0
0
1
16
1
0
0
0
1
17
0
1
0
0
1
18
1
1
0
0
1
19
0
0
1
0
1
20
1
0
1
0
1
21
0
1
1
0
1
22
1
1
1
0
1
23
0
0
0
1
1
24
HARDWARE REFERENCE MANUAL
138
Hardware reference
Pin No.
Slave address
1
2
3
4
5
1
0
0
1
1
25
0
1
0
1
1
26
1
1
0
1
1
27
0
0
1
1
1
28
1
0
1
1
1
29
0
1
1
1
1
30
1
1
1
1
1
Not used
Specification
The performance specifications of the analogue output module (±10 V, 2
CH) are shown below.
The illustration shows the circuit configuration for the analogue input
module.
/i
fig. 88
Specifications
Name
Analog output module (-10 V to +10 V, 2 CH)
Model description
AN2910
Model number
JEPMC-AN2910
Input signal range
-10 to 10V
Number of output channels
2 channels
Maximum allowable load current
±5 mA (2 kΩ)
Digital resolution
16 bits
Data format
Binary (2s complement) -32,000 to 32,000
Error
±0.2% F.S. (at 25ºC)
±0.5% F.S. (at 0 to 60ºC)
+5V
+12V
Internal Circuits
Item
From CPU
Status
display
Photocoupler
Isolation
amplifier
D/A
converter
Load
7
9
-12V
0V (analog)
8
Revision 5.0
1 ms
Number of allocated words
2 words/module
Maintenance/diagnostic functions
Watchdog timer
HARDWARE REFERENCE MANUAL
+
CH1-
-
Shield 1
Load
+12V
-12V
Insulating
DC/DC
converter
15
17
Output delay time
CH1+
0V (analog)
16
+5V
Insulating
DC/DC
converter
22
23
CH2+
+
CH2-
-
Shield 2
0V
24 VDC
+
-
24 VDC
0V
139
Hardware reference
Item
Specifications
Output status when master stops
Mode selected with the dipswitch (SW7):
SW7 off: clear outputs (output 0 V)
SW7 on: retain prior output status
External connections
Removable terminal block with M3 screw terminals
Output circuit
isolation
Isolation method Photocoupler
(There is no isolation between channels.)
Dielectric
strength
1,500 VAC for 1 minute between output terminals and
internal circuits
Insulation resist- 100 MΩ min. at 500 VDC between input terminals and
ance
internal circuits (at room temperature and humidity)
External power supply
Main external power supply:
24 VDC (20.4 to 26.4 VDC), 120 mA max.
Derating conditions
The maximum ambient operating temperature is limited with some mounting directions.
Maximum heating value
2.88 W
Hot swapping
Terminal block: not permitted
Communication connector: permitted
weight
Approx. 300 g
Dimensions (mm)
161 x 44 x 79 (W x H x D)
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
analogue output module:
• AOUT
For more information, refer to the Trajexia Programming Manual.
3.5.18 MECHATROLINK-II repeater
Revision 5.0
The JEPMC-REP2000 is a MECHATROLINK-II repeater. It extends the
range and the maximum number of MECHATROLINK-II devices in the
MECHATROLINK-II network.
HARDWARE REFERENCE MANUAL
140
Hardware reference
/i
fig. 89
Terminal/LED
Label
Description
A
TX1
CN1 communication indicator
B
TX2
CN2 communication indicator
C
POWER
Power indicator
D
SW
Dipswitch
E
CN1 & CN2
MECHATROLINK-II connectors
F
CN3
Power supply connector
LED indicators
B
A
F
E
D
C
/i
LED
Description
POWER
Lit: Power on
Not lit: No power
TX1
Lit: Communication via CN1
Not lit: No communication via CN1
TX2
Lit: Communication via CN2
Not lit: No communication via CN2
MECHATROLINK-II connectors
Use one MECHATROLINK-II connector (CN1 or CN2) to connect the
repeater to the master-side network, i.e. the part of the network that had the
TJ1-ML__. Use the other connector to connect the repeater to the network
extension.
Both connectors have a built-in terminator.
Power supply connector
Connect an external 24 VDC power supply to the power supply connector
(CN3).
Revision 5.0
HARDWARE REFERENCE MANUAL
141
Hardware reference
The table below gives the pin layout for the power supply connector.
fig. 90
/i
Pin
Signal
Description
1
FG
Frame ground
2
0V
0 VDC input
3
+24 V
24 VDC input
3
2
1
Dipswitch settings (SW)
The dipswitch is for future use. Set all the pins to OFF.
System configuration
The maximum number of MECHATROLINK-II devices that you can connect
in the MECHATROLINK-II network with a repeater is set by the
MECHATROLINK-II cable length.
fig. 91
/i
TJ1-ML16
Network part
MECHATROLINK-II
cable length
Maximum number of
MECHATROLINK-II devices1
Master-side (B)
Max. 30 m
16
Max. 50 m
15
Max. 30 m
16
Max. 50 m
15
Extension (C)
REP2000
A
CN1 CN2
1
15
B
16
C
1. The repeater itself is included in the maximum number of MECHATROLINK-II devices.
The total number of MECHATROLINK-II devices is set by the TJ1-ML__:
• The TJ1-ML04 can have up to 4 MECHATROLINK-II devices.
• The TJ1-ML16 can have up to 16 MECHATROLINK-II devices.
Terminate the last MECHATROLINK-II device with a MECHATROLINK-II
terminator (A).
Revision 5.0
HARDWARE REFERENCE MANUAL
142
Hardware reference
3.6
GRT1-ML2
3.6.1
Introduction
The GRT1-ML2 SmartSlice Communication Unit controls data exchange
between a TJ1-MC__ Motion Controller Unit (via a connected TJ1-ML__
MECHATROLINK-II Master Unit) and SmartSlice I/O Units over a
MECHATROLINK-II network. For more information on SmartSlice I/O Units,
refer to the GRT1 Series SmartSlice I/O Units Operation Manual (W455).
/i
fig. 92
LED indicators
H
OMRON
GRT1-ML2
RUN
7 8 9
Unit dipswitches
C
Unit power supply terminals
D
I/O power supply terminals
E
MECHATROLINK-II connectors
F
Shielding terminal
G
Rotary switch
H
Communication dipswitches
G
B C D
B
A
3 4 5 6
A
F 0 1 2
Description
E
Label
SW1
1
2
3
4
A
UNIT PWR
ALARM
ML COM
SW2
TS
I/O PWR
CN2
F
ON
E
1 REGS
2 NC
CN1
A/B
B
3 ADR
4 BACK
UNIT
+V
C
-V
I/O
+V
D
-V
DC24V
INPUT
Unit dipswitches
/i
fig. 93
Dipswitch
Function
Setting
Description
REGS
Create/enable
registration table
ON
Registered table is enabled
OFF
Registered table is disabled
Revision 5.0
OFF to
ON to
NC
N/A
ON1
OFF1
OFF
HARDWARE REFERENCE MANUAL
ON
1 RE GS
2 NC
3 ADR
4 B ACK
Register I/O unit table
Clear registered I/O unit table
Not used, always set to OFF
143
Hardware reference
Dipswitch
Function
Setting
Description
ADR
Automatic
restore
OFF to ON
When the SmartSlice I/O Units are
replaced, the parameter data that was
backed up with the BACK dipswitch is
automatically restored2
OFF
Automatic restore disabled
ON to OFF to
ON in 3 s3
Parameter data of all connected SmartSlice I/O Units is backed up2
BACK
Backup trigger
1. When the unit power is on.
2. When dipswitch 1 is set to ON.
3. The setting of dipswitch 4 (BACK) is given in figure 94.
fig. 94
Caution
The Backup and Restore functionality is available in the GRT1ML2. However, the backed up and restored parameters cannot be
accessed via MECHATROLINK-II communication.
Note
•
•
1s
1s
1s
ON
OF F
ON
T he backup operation s tarts after DIP s witch 4 is
turned from ON to OF F to ON within 3 s econds .
It is recommended to do a registration of the SmartSlice I/O
Units (see the Trajexia Programming Manual).
It is recommended to set dipswitches 1, 3 and 4 on after this
registration.
The factory setting of all dipswitches is OFF.
Revision 5.0
HARDWARE REFERENCE MANUAL
144
Hardware reference
LED indicators
/i
fig. 95
LED
Description
Color
Status
Meaning
RUN
Unit status
Green
Not lit
•
•
ALARM
ML COM
Unit error
MECHATROLINK-II communication
Red
Green
Startup test failed, unit not operational
Operation stopped due to a fatal
error
Lit
Initialization successful, unit is in normal operation
Not lit
Unit is in normal operation
Flashing
A startup error has occurred
Lit
Unit is in alarm state, or a fatal error
has occurred
Not lit
No MECHATROLINK-II communication
Lit
MECHATROLINK-II communication
active
RUN
UNIT PWR
ALARM
ML COM
TS
I/O PWR
Revision 5.0
HARDWARE REFERENCE MANUAL
145
Hardware reference
LED
Description
Color
Status
Meaning
TS
SmartSlice I/O
system communication
status
N/A
Not Lit
•
•
•
Green
Red
UNIT
PWR
I/O PWR
Green
Green
Flashing
(every
second)
SmartSlice I/O Unit added to the system
Flashing
(every 0.5
second)
Backup/Restore function operating:
•
Restoring settings to SmartSlice I/
O Unit, backup function operating
•
Downloading SmartSlice I/O Unit
settings
Lit
Communication with SmartSlice I/O
Unit established
Flashing
Non-fatal communication error
occurred.
•
Communication timeout
•
Verification error occurred with
registered table
•
Different model unit detected after
SmartSlice I/O Unit replacement
Lit
Fatal communication error occurred.
Lit for 2 s
Failure occurred while restoring settings to I/O unit or downloading I/O unit
settings
Revision 5.0
Not Lit
No power supply to the unit
(All LEDs are off)
Lit
Power supply to the unit
Not Lit
No power supply to the SmartSlice I/O
(No output from the SmartSlice I/O
Units, even when they are in operation)
Lit
Power supply to the SmartSlice I/O
HARDWARE REFERENCE MANUAL
Note
No power supply
Communication with SmartSlice I/
O Unit has not started
Overcurrent detected
•
•
•
When the power of the Trajexia system is turned on, the TJ1MC__ executes its startup sequence before it initializes the
MECHATROLINK-II bus. During this startup sequence, the ML
COM LED is off.
When the TJ1-MC__ initializes the MECHATROLINK-II bus
with the command MECHATROLINK(unit,0), the ML COM
LED goes on.
When the GRT1-ML2 loses the MECHATROLINK-II communication with the master, or when the command
MECHATROLINK(unit,1) is executed, the ML COM LED goes
off.
Communication dipswitches
/i
Dipswitch
Function
Setting
Description
1
MECHATROLINK-II
address range
ON
70 hex − 7F hex
OFF
60 hex − 6F hex
2
MECHATROLINK-II
bus speed
OFF
10 Mbps1
3
Frame size
OFF
32 bytes2
4
HOLD/CLEAR
ON
HOLD: All outputs hold their values
when communication is lost
OFF
CLEAR: All outputs become 0 when
communication is lost
1. Trajexia only supports 10 Mbps bus speed. Therefore always set
dipswitch 2 to OFF.
2. Trajexia only supports 32-byte communication. Therefore always set
dipswitch 3 to OFF.
146
Hardware reference
Rotary switch
The rotary switch (SW1) sets the MECHATROLINK-II address that identifies
the GRT1-ML2 in the MECHATROLINK-II network. The settings range is
from 0 hex to F hex.
To set the MECHATROLINK-II address of the GRT1-ML2, do these steps:
1. Turn off the Unit power supply of the GRT1-ML2.
Note
The address of the GRT1-ML2 is read only at power on. Setting
the new address when the power is on has no effect.
2. To set the address of the unit, set communication dipswitch 1 and the
rotary switch as given in the table below.
/i
Revision 5.0
Dipswitch 1
Rotary
switch
Address
Dipswitch 1
Rotary
switch
Address
OFF
0
60 hex
ON
0
70
OFF
1
61 hex
ON
1
71
OFF
2
62 hex
ON
2
72
OFF
3
63 hex
ON
3
73
OFF
4
64 hex
ON
4
74
OFF
5
65 hex
ON
5
75
OFF
6
66 hex
ON
6
76
OFF
7
67 hex
ON
7
77
OFF
8
68 hex
ON
8
78
OFF
9
69 hex
ON
9
79
OFF
A
6A hex
ON
A
7A
OFF
B
6B hex
ON
B
7B
OFF
C
6C hex
ON
C
7C
OFF
D
6D hex
ON
D
7D
OFF
E
6E hex
ON
E
7E
HARDWARE REFERENCE MANUAL
147
Hardware reference
Dipswitch 1
Rotary
switch
Address
Dipswitch 1
Rotary
switch
Address
OFF
F
6F hex
ON
F
7F
Note
Make sure that the address is unique in the MECHATROLINK-II
network. If two or more units have the same MECHATROLINK-II
address, they cannot be initialized properly.
3. Turn the power on.
Note
To make the MECHATROLINK-II address of the unit valid, do one
of these steps:
• Restart the TJ1-MC__.
• Execute the command MECHATROLINK(unit,0).
Power supply connector
The GRT1-ML2 has 2 24 VDC power supply terminals:
fig. 96
/i
UNIT
Label Power supply terminal Description
A
B
Unit power supply
terminal
External I/O power
supply terminal
Power supply to the internal circuits of the GRT1-ML2
and to the internal circuits of the connected SmartSlice I/
O Units (through the SmartSlice bus)
Power supply to the external I/Os connected to the
SmartSlice I/O Units
+V
A
24 VDC
-V
I/O
+V
B
24 VDC
-V
DC24V
INPUT
Revision 5.0
Note
The unit power supply and the external I/O power supply are not
transferred through the GCN2-100 Turnback cable. The GRT1TBR units have the same power supply terminals as the GRT1ML2.
HARDWARE REFERENCE MANUAL
148
Hardware reference
3.6.2
Specifications
/i
Environment
Installation
Item
Specification
Unit type
SmartSlice GRT1 series
Model
GRT1-ML2
Installation position
On a DIN rail
Power supply
24 VDC +10% −15% (20.4 to 26.4 VDC)
Current consumption
110 mA typical at 24 VDC
Dimensions (W × H × D)
58 × 80 × 70 mm
Weight
130 g
Ambient operating temperature
−10 to 55°C (no icing or condensation)
Ambient operating
humidity
25% to 85% Relative humidity
Storage temperature
−20 to 65°C (no icing or condensation)
Vibration resistance
10 to 57 Hz, 0.7 mm amplitude
57 to 150 Hz, acceleration: 49 m/s2
Shock resistance
150 m/s2
Dielectric strength
500 VAC (between isolated circuits)
Conformance to EMC
and electrical safety
standards
EN61131-2:2003
Enclosure rating
IP20
Revision 5.0
HARDWARE REFERENCE MANUAL
149
Hardware reference
MECHATROLINK-II SmartSlice I/O
Item
Specification
Number of connectable
SmartSlice I/O Units
64 Units max.
Connected directly to the GRT1-ML2 or via Turnback extension units
Baud rate
3 Mbps
Communication signal
level
RS485
Communication distance
SmartSlice I/O Units: 64 Units coupled (about 2 m max.)
Turnback cable: 2 m max. (2 cables, 1 m each)
Turnback cable
Length 1 m max., up to 2 cables can be connected
SmartSlice I/O Unit connections
Building-block style configuration with slide connectors
(Units connect with Turnback cables).
Baseblock power supply Voltage: 24 VDC
Current: 4 A max.
Event messaging
Supported
Baud rate
10 Mbps (MECHATROLINK-II)
Data length
17-byte and 32-byte data transmission
Supported SmartSlice I/O Units
The GRT1-ML2, in combination with the Trajexia system, supports these
SmartSlice I/O Units.
/i
Revision 5.0
Function
Specification
Model
4 NPN inputs
24 VDC, 6 mA, 3-wire connection
GRT1-ID4
4 PNP inputs
24 VDC, 6 mA, 3-wire connection
GRT1-ID4-1
8 NPN inputs
24 VDC, 4 mA, 1-wire connection + 4xG
GRT1-ID8
8 PNP inputs
24 VDC, 4 mA, 1-wire connection + 4xV
GRT1-ID8-1
4 NPN outputs
24 VDC, 500 mA, 2-wire connection
GRT1-OD4
HARDWARE REFERENCE MANUAL
150
Hardware reference
Function
Specification
Model
4 PNP outputs
24 VDC, 500 mA, 2-wire connection
GRT1-OD4-1
4 PNP outputs with shortcircuit protection
24 VDC, 500 mA, 3-wire connection
GRT1-OD4G-1
8 NPN outputs
24 VDC, 500 mA, 1-wire connection +
4xV
GRT1-OD8
8 PNP outputs
24 VDC, 500 mA, 1-wire connection +
4xG
GRT1-OD8-1
8 PNP outputs with shortcircuit protection
24 VDC, 500 mA, 1-wire connection +
4xG
GRT1-OD8G-1
2 relay outputs
240 VAC, 2A, normally-open contacts
GRT1-ROS2
2 analog inputs, current/
voltage
10 V, 0-10 V, 0-5 V, 1-5 V, 0-20 mA, 4-20
mA
GRT1-AD2
2 analog outputs, voltage
10 V, 0-10 V, 0-5 V, 1-5 V
GRT1-DA2V
2 analog outputs, current
0-20 mA, 4-20 mA
GRT1-DA2C
Revision 5.0
HARDWARE REFERENCE MANUAL
151
Hardware reference
Dimensions
The external dimensions are in mm.
2.9
11.9
fig. 97
OMRON
GRT1-ML2
RUN
7 8 9
2
B CDE
3 4 5 6
A
F 0 1
SW1
1
2
3
4
UNIT PWR
ALARM
ML COM
SW2
TS
I/O PWR
CN2
ON
1 REGS
83.5
2 NC
CN1
A/B
3 ADR
54
4 BACK
UNIT
35.5
+V
-V
I/O
-V
DC24V
INPUT
16.2
+V
2.9
26.3
28.8
17.1
61.2
1.5
3.6.3
69.7
36.8
58
2.4
Installation
Revision 5.0
Follow these rules when installing the GRT1-ML2:
• Before installing the GRT1-ML2 or connect or disconnect cables, switch
off the power of the Trajexia system, the SmartSlice I/O Units and the
external I/Os.
• Make sure that the power supplies of the GRT1-ML2, the SmartSlice I/O
Units and the external I/Os are correctly connected.
HARDWARE REFERENCE MANUAL
152
Hardware reference
•
•
•
•
Provide separate conduits or ducts for the I/O lines to prevent noise from
high-tension lines or power lines.
It is possible to connect up to 64 SmartSlice I/O Units to 1 GRT1-ML2.
Install the GRT1-ML2 and the SmartSlice I/O Units on a DIN rail. To
install a GRT1-ML2 on the DIN rail, press it onto the DIN track from the
front, and press the unit firmly until it clicks. Check that all DIN rail sliders
of the unit are locked onto the DIN rail.
To remove the GRT1-ML2 from the DIN rail, release the sliders from the
DIN rail with a screwdriver, and pull the unit straight from the DIN rail.
Connections
Connect the first SmartSlice I/O Unit to the GRT1-ML2:
• Align the sides of the GRT1-ML2 and the SmartSlice I/O Unit.
• Slide the SmartSlice I/O Unit to the rear until it clicks onto the DIN rail.
Caution
Do not touch the connectors on the side of GRT1-ML2 and the
SmartSlice I/O Units.
fig. 98
-ML2
GRT1
SW1
CN2
SW2
UNIT
PWR
RUN
ALAR
M
M
ML CO
See the GRT1 Series SmartSlice I/O Units Operation Manual for more
information on connecting additional SmartSlice I/O Units, Turnback Units,
End Units and end plates.
I/O PW
R
TS
CN1
A/B
ON
GS
1 RE
2 NC
R
3 AD
CK
4 BA
UNIT
+V
Wiring
The GRT1-ML2 has 2 power supply terminals. Both power supply terminals
have screwless clamping-type connections.
To determine the power supply requirements, do the steps below.
The maximum power consumption for SmartSlice I/O Units is 80 W per
block.
-V
I/O
+V
-V
V
DC24T
INPU
Revision 5.0
HARDWARE REFERENCE MANUAL
153
Hardware reference
1. Calculate the power consumption of all SmartSlice I/O Units connected
to the GRT1-ML2. Refer to the GRT1 Series SmartSlice I/O Units
Operation Manual (W455) for the power value for each SmartSlice I/O
Unit.
2. If the power consumption exceeds 80 W, mount a Right Turnback Unit
(GRT1-TBR) on the SmartSlice I/O Unit at the point where the power
consumption is less than 80 W.
3. Connect the 24 VDC unit power supply to the Left Turnback Unit (GRT1TBL).
The maximum I/O current consumption is 4 A.
1. Calculate the total current consumption used by all external I/Os of the
connected SmartSlice I/O Units (including other units like Turnback
Units). Refer to the GRT1 Series SmartSlice I/O Units Operation Manual
(W455) for the current value for each SmartSlice I/O Unit.
2. If the current consumption exceeds 4 A or if you want to provide
separate systems for inputs and outputs, divide the SmartSlice I/O Units
at the desired point with a GRT1-PD_(-1) I/O Power Supply Unit and
provide a separate external I/O power supply.
Note
It is also possible to provide a separate external I/O power supply
at a Left Turnback Unit (GRT1-TBL).
Note
Make sure the power supply is isolated.
Note
The GCN2-100 Turnback cable does not supply power.
The figure gives a wiring example.
Revision 5.0
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154
Hardware reference
To supply power to the units and the I/O devices, connect the power supply
wires to the power supply terminals of the GRT1-ML2. If the wire ends have
pin terminals, just insert the pin terminals in the power supply terminals.
fig. 99
GRT 1-PD_(-1) I/O Power Supply Unit GRT 1-T B R Right T urnback Unit
I/O
(IN)
GRT 1 - ML2
I/O
(IN)
I/O
I/O
I/O
I/O
I/O
(OUT )
(OUT )
(OUT )
(OUT )
(OUT )
max. 80 W
I/O
power
s upply
I/O
power
s upply
I/O
(AD)
I/O
(AD)
I/O
(AD)
T urnback cable
I/O
(AD)
I/O
(AD)
E nd Unit
max. 80 W
Power s upply
(24 VDC)
I/O
power
s upply
GRT 1-T B L Left T urnback Unit
To remove the wires, press the release button above the terminal hole with a
precision screwdriver, and pull out the wire.
fig. 100
Precis ion s crewdriver
It is recommended to use a SELV (Safety Extra Low Voltage) power supply
with over-current protection. A SELV power supply has redundant or
increased insulation between the I/O, an output voltage of 30 V rms and a
42.4 V peak or maximum of 60 VDC.
Recommended power supplies are:
• S82K-01524 (OMRON)
• S8TS-06024 (OMRON).
Releas e button
Revision 5.0
It is recommended to use wires with a gauge of 20 AWG to 16 AWG (0.5 to
1.25 mm2).
Strip the wire between 7 and 10 mm of insulation at the ends of the wires
(stranded or solid wire), or use pin terminals with a pin (conductor) length of
8 to 10 mm.
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Hardware reference
Replace
Caution
The GRT1-ML2 is a unit that is part of a network. If the GRT1-ML2
is damaged, it effects the whole network. Make sure that a damaged GRT1-ML2 is repaired immediately.
To replace the unit, follow these rules:
• Turn off the power before replacing the unit. This includes the power to
all master and slave units in the network.
• Make sure that the new unit is not damaged.
• If a poor connection is the probable cause of any malfunctioning, do
these steps:
- Clean the connectors with a clean, soft cloth and industrial-grade
alcohol.
- Remove any lint or threads left from the cloth.
- Install the unit again.
• When returning a damaged unit to the OMRON dealer, include a detailed
damage report with the unit.
• Before reconnecting the new unit, do these steps:
- Set the MECHATROLINK-II station address to the same address as
the old unit.
- If the table registration function was used for the old unit, create a
new registration table for the new unit. See the Trajexia
Programming Manual.
3.6.4
Online replacement
Revision 5.0
It is possible to replace SmartSlice I/O Units connected to a GRT1-ML2
when the power is on. The I/O communication continues while a SmartSlice
I/O Unit is removed and replaced.
To replace a SmartSlice I/O Unit online, do these steps:
1. Turn off all power supplies of the SmartSlice I/O Unit. This is the I/O
power supply, plus possible external power supplies to the terminal block
(for example, a Relay Output Unit).
2. Release the locks on the front of the unit and remove the terminal block.
Do not remove the wiring.
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Hardware reference
3. Remove the main block of the unit. Replace it with a new SmartSlice I/O
Unit of the same type.
4. Attach the new unit to the system. Close the locks on the front of the unit.
5. Turn on the power supplies to the unit.
When replacing a SmartSlice I/O Unit online, note the following things:
• When a unit is removed from the I/O communication, the withdrawn flag
of the unit is set on and the TS LED on the GRT1-ML2 flashes red.
• If I/O power supply of the unit is not turned off, there can be false output
signals, false input signals and electrical shocks.
• Only replace one SmartSlice I/O Unit at a time.
• If a unit is replaced with a different type of unit, there can be unexpected
outputs and the restore operation can be incomplete.
• If the base block has faults or damage, turn off the power supply and
replace the entire unit.
When an online replacement is performed, the status word of the GRT1-ML2
reports an error (missing I/O Unit). When the I/O Unit is replaced or put
back, the status word changes to 8000 hex, but the error has already been
detected by the TJ1-MC__. To avoid this, it is necessary to mask the errors
before the online replacement is performed. To perform the online
replacement do the following:
1. Execute MECHATROLINK(unit,37,station_addr, 0). This masks all
bits, including errors, in the GRT1-ML2 status word.
2. Replace the I/O Unit.
3. Execute MECHATROLINK(unit,37,station_addr, $4000). This sets the
error mask to its default value.
3.6.5
Related BASIC commands
The following BASIC commands are related to the MECHATROLINK-II
GRT1-ML2 module:
• MECHATROLINK
Revision 5.0
For more information, refer to the Trajexia Programming Manual.
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Hardware reference
3.7
TJ1-PRT
3.7.1
Introduction
The TJ1-PRT is an interface between the Trajexia system and a PROFIBUS
network.
The TJ1-PRT has these visible parts.
fig. 101
H
B
/i
A
A
LEDs
B and C
Node number selectors
D
PROFIBUS connector
901
Description
78
Part
456
23
901
B
78
3.7.2
456
23
C
D
LEDs description
/i
Label
Status
Description
run
off
Start-up test failed. Unit not operational
Operation stopped. Fatal error
on
Start-up test successful. Normal operation
off
Normal operation
flashing
Start-up error
on
Fatal error in program
Error occurred while Reading or Writing error log
off
Normal operation
flashing
I/O-size not configured
on
Error detected in communication with controller
ERC
ERH
Revision 5.0
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Hardware reference
Label
Status
Description
COM
off
No PROFIBUS data exchange communication
on
I/O data exchange on PROFIBUS is active
off
No PROFIBUS bus communication errors
flashing
Parameter values sent by the PROFIBUS master unit are invalid.
I/O data exchange is not possible.
on
No PROFIBUS communication is detected by the unit
BF
3.7.3
Node number selectors
You can use the node number selectors to assign a node number to the TJ1PRT. This node number identifies the TJ1-PRT in the PROFIBUS network.
The upper node number selector sets the tens of the node number. The
lower node number selector sets the units of the node number. Both
selectors range from 0 to 9. To set a selector to n, turn the arrow to point to
the label n. Refer to the chapter, Communication Protocols in the
Programming Manual.
Revision 5.0
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Hardware reference
3.7.4
TJ1-PRT Connections
/i
fig. 102
Pin
Signal
Description
1
Shield
Connected to the metal shell
2
N/A
N/A
3
B-line
Data signal
4
RTS
Direction control signal for repeaters
5
DGND
Data 0 Volts
6
VP
Power output for the termination, 5 V, 10 mA
7
N/A
N/A
8
A-line
Data signal
9
N/A
N/A
3.7.5
9
8
7
6
5
4
3
2
1
TJ1-PRT Specifications
/i
Revision 5.0
Item
Specification
Power supply
5 VDC (supplied by the TJ1-MC__)
Power consumption
0.8 W
Current consumption
150 mA at 5 VDC
Approximate weight
100 g
Electrical characteristics
Conforms to PROFIBUS-DP standard EN50170 (DP-V0)
Communication connector
1 PROFIBUS-DP slave connector
Transmission speed
9.6, 19.2, 45.45, 93.75, 187.5, 500, 1500, 3000, 6000 and
12000 Kbps
Node numbers
0 to 99
I/O size
0 to 122 words (16-bit), configurable, for both directions
Galvanic isolation
Yes
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Hardware reference
3.7.6
TJ1-PRT unit box contents
TJ1-PRT box:
• Safety sheet.
• TJ1-PRT.
• Protection label attached to the top surface of the unit.
3.7.7
Applicable BASIC commands
The following BASIC commands are applicable for the TJ1-PRT:
• PROFIBUS
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
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Hardware reference
3.8
TJ1-DRT
3.8.1
Introduction
The TJ1-DRT is an interface between the Trajexia system and a DeviceNet
network.
fig. 103
/i
B and C
Node number selectors
D
DeviceNet connector
78
LEDs description
B
901
23
456
/i
Label
901
LEDs
456
23
A
3.8.2
A
Description
78
Part
C
V-
D
CAN L
DRAIN
Status
Description
off
Start-up test failed. Unit not operational
Operation stopped. Fatal error
on
Start-up test successful. Normal operation
off
Normal operation
flashing
Start-up error
on
Fatal error in program
Error occurred while Reading or Writing error log
off
Normal operation
flashing
I/O-size not configured
on
Error detected in communication with controller
off
Baud rate not detected or node address duplication check not
completed.
flashing
Slave not allocated to a DeviceNet master.
on
Slave is on-line and allocated to a DeviceNet master.
CAN H
V+
RUN
ERC
ERH
NOK
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Hardware reference
Label
Status
Description
NF
off
No network error detected.
flashing
Connection time-out detected for I/O connection with the DeviceNet master.
on
Other device detected with the same node number or severe network error detected.
3.8.3
Node number selectors
You can use the node number selectors to assign a node number to the TJ1DRT. This node number identifies the TJ1-DRT in the DeviceNet network.
The upper node number selector sets the tens of the node number. The
lower node number selector sets the units of the node number. Both
selectors range from 0 to 9. To set a selector to n, turn the arrow to point to
the label n. Refer to the chapter, Communication Protocols in the
Programming Manual.
The DeviceNet node numbers range from 0 to 63. If you select a node
number with the node number selectors that exceeds this range, you will
select the node number that is set by software. The nodes that enable
software settings are 64 to 99.
Revision 5.0
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Hardware reference
3.8.4
TJ1-DRT Connections
/i
fig. 104
Pin
Signal
Description
1
V-
Power supply input, negative voltage
2
CAN L
Communication line, low
3
DRAIN
Shield
4
CAN H
Communication line, high
5
V+
Power supply input, positive voltage
1
2
3
4
5
3.8.5
TJ1-DRT Specifications
/i
Revision 5.0
Item
Specification
Power supply
5 VDC (supplied by the TJ1-MC__)
Power consumption
120 mA at 5 VDC
Network power supply
24 VDC
Network current consumption
15 mA at 24 VDC
Power dissipation
0.6 W
Approximate weight
100 g
Electrical characteristics
Conforms to DeviceNet standard of CIP edition 1.
Communication connector
1 DeviceNet slave connector
Transmission speed
125, 250 and 500 Kbps, auto-detected
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Hardware reference
Item
Specification
Node numbers
0 to 63
I/O size
0 to 32 words (16-bit), configurable, for both directions
Galvanic isolation
Yes
3.8.6
TJ1-DRT unit box contents
TJ1-DRT box:
• Safety sheet.
• TJ1-DRT.
• DeviceNet connector.
• Protection label attached to the top surface of the unit.
3.8.7
Applicable BASIC commands
The following BASIC commands are applicable for the TJ1-DRT:
• DEVICENET
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
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Hardware reference
3.9
TJ1-CORT
3.9.1
Introduction
The CANopen Master Unit (TJ1-CORT) is an interface between the Trajexia
system and a CANopen network.
/i
fig. 105
B and C
Node number selectors
D
CANopen port
NWST
BF
A
23
901
LED indicators
B
456
23
901
A
CORT
78
Description
456
Part
78
C
V-
D
CAN L
DRAIN
CAN H
V+
3.9.2
LEDs description
/i
Label
Status
Description
RUN
off
Start-up test failed. Unit not operational.
Operation stopped. Fatal error.
on
Start-up test successful. Normal operation.
off
Normal operation
flashing
Start-up error
on
Fatal error in program.
Error occurred while Reading or Writing error log.
ERC
Revision 5.0
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Hardware reference
Label
Status
Description
ERH
off
Normal operation.
flashing
I/O size not configured.
on
Error detected in communication with controller.
off
Start-up error or fatal error detected.
single flash
TJ1-CORT in stopped state.
flashing
TJ1-CORT in pre-operational state.
on
TJ1-CORT in operational state.
NWST
BF
off
single
No network error detected.
flash1
Warning limit reached.
At least one of the error counters of the CAN controller has
reached or exceeded the warning level (too many errors).
double flash2
A remote error or a heartbeat event has occurred.
flashing3
Invalid configuration.
on
A duplicate node address has been detected, or
the unit is in Bus OFF state.
1. Single flash: one 200ms pulse, followed by 1 second off.
2. Double flash: two 200ms pulses, followed by 1 second off.
3. LED flashing frequency: 2.5 Hz.
3.9.3
Node number selectors
Revision 5.0
You can use the node number selectors to assign a node number to the TJ1CORT. This node number identifies the TJ1-CORT in the CANopen network.
The upper node number selector sets the tens of the node number. The
lower node number selector sets the units of the node number. Both
selectors range from 0 to 9. To set a selector to n, turn the arrow to point to
the label n.
The CANopen node number can range from 0 to 127. But the TJ1-CORT
only supports node numbers from 1 to 99. The default node number, 0, is
invalid. Therefore, the default node number must be changed before the
TJ1-CORT is used.
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Hardware reference
3.9.4
TJ1-CORT connections
/i
fig. 106
Pin
Signal
Description
1
V-
Power supply input, negative voltage
2
CAN L
Communication line, low
3
DRAIN
Shield
4
CAN H
Communication line, high
5
V+
Power supply input, positive voltage
1
2
3
4
5
3.9.5
TJ1-CORT specifications
/i
Revision 5.0
Item
Specification
Power supply
5 VDC (supplied by the TJ1-MC__)
Power consumption
120 mA at 5 VDC
Network power supply
24 VDC
Network current consumption
15 mA at 24 VDC
Power dissipation
0.6 W
Approximate weight
100 g
Electrical characteristics
Conforms to ISO 11898-1
HARDWARE REFERENCE MANUAL
168
Hardware reference
Item
Specification
Communication ports
1 CAN port
Transmission speed
20, 50, 125 and 500 Kbps
Node numbers
1 to 99
I/O size
8 RPDO and 8 TPDO
Galvanic isolation
Yes
Device profile
DS302: CANopen manager profile
Note:
This CANopen master does not support motion control features of
slaves with the DS401 profile
3.9.6
TJ1-CORT unit box contents
CANopen Master Unit box:
• Safety sheet.
• CANopen Master Unit.
• DeviceNet connector.
• Protection label attached to the top surface of the unit.
3.9.7
Applicable BASIC commands
The following BASIC commands are applicable for the TJ1-CORT:
• CAN_CORT
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
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Hardware reference
3.10
TJ1-FL02
3.10.1 Introduction
WARNING
Do not start the system until you check that the axes are present
and of the correct type.
The numbers of the Flexible axes will change if MECHATROLINKII network errors occur during start-up or if the MECHATROLINK-II
network configuration changes.
The TJ1-FL02 is an analogue control unit. It controls up to two axes A and B
in these modes:
• Analogue speed reference plus encoder feedback.
• Incremental or absolute encoder input.
• Pulse output.
At start up the TJ1-MC__ assigns the TJ1-FL02 to the first 2 free axes in
sequence. When multiple TJ1-FL02 units are connected they are assigned
in unit sequence 0..6. Any MECHATROLINK-II axes that are assigned
(using the driver switches) will not change. The TJ1-MC__ assigns the next
free axis.
The TJ1-FL02 has these visible parts:
fig. 107
FL02
A
B
C
/i
Part
Description
A
LEDs
B
15-pin connector
C
18-pin connector
3.10.2 LED description
Revision 5.0
The function of the LEDs is defined by the BASIC command
AXIS_DISPLAY. For more information, refer to the Programming Manual.
HARDWARE REFERENCE MANUAL
170
Hardware reference
/i
Axis
Label
Status
AXIS_DISPLAY parameter
0
1
2
3
All
run
on
The TJ1-MC__ recognises the TJ1-FL02
A
A EN
on
Axis enabled.
flashing
Axis error
off
Axis disabled
A0
on
REG 0
AUX
OUT 0
Encoder A
A1
on
REG 1
Encoder Z
OUT 1
Encoder B
B EN
on
Axis enabled
flashing
Axis error
off
Axis disabled
B0
on
REG 0
AUX
OUT 0
Encoder A
B1
on
REG 1
Encoder Z
OUT 1
Encoder B
B
3.10.3 TJ1-FL02 connections
The signals of the 15-pin connector depend on the type of interface
selected:
Revision 5.0
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171
Hardware reference
15-pin connector
/i
fig. 108
Pin
Axis
Encoder
input1
Encoder
output
Stepper
output
SSI/EnDat Tamagawa
1
A
A+
A+
Step+
Clock+
2
A
A-
A-
Step-
Clock-
3
A
B+
B+
Dir+
4
A
B-
B-
Dir-
GND
GND
GND
GND
GND
5
5
10
6
A
Z+
Enable+
Data+
SD+
7
A
Z-
Enable-
Data-
SD-
8
B
Z+
Enable+
Enable+
Data+
SD+
9
B
Z-
Enable-
Enable-
Data-
SD-
+5V out
Do not use
Do not use
Do not use Do not use
10
11
B
A+
A+
Step+
Clock+
12
B
A-
A-
Step-
Clock-
13
B
B+
B+
Dir+
14
B
B-
B-
Dir-
GND
GND
GND
15
GND
15
14
13
12
11
4
9
3
8
2
7
1
6
GND
1. With the VERIFY parameter the input type can be changed from phase
differential (VERIFY=ON, default) to Step (Channel A) and Direction
(Channel B) (VERIFY=OFF).
Revision 5.0
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Hardware reference
18-pin connector
/i
fig. 109
Pin
Axis
Signal
Pin
Axis
Signal
Description
1
A
Vout
2
B
Vout
Analog output
3
A
0V
4
B
0V
0V Reference for Vout
Wdog-
6
Wdog+
Enable relay contacts
5
7
A
Reg 0
8
B
Reg 0
24V registration inputs
9
A
Reg 1
10
B
Reg 1
24V registration inputs
11
A
AUX
12
B
AUX
24V auxiliary inputs
13
A
OUT 0
14
B
OUT 0
position switch outputs
(HW_PSWITCH)
15
A
OUT 1
16
B
OUT 1
OUT1 Auxiliary outputs
I/O 0V
Common
18
I/O +24 V
24V Power supply Input for
the Outputs.
17
1
3
5
7
9
11
13
15
17
2
4
6
8
10
12
14
16
18
Digital inputs
The following table and illustration details the digital input specifications:
fig. 110
/i
Item
Specification
Type
PNP
Maximum voltage
24 VDC + 10%
Input current
8 mA at 24 VDC
on voltage
18.5 VDC min
off voltage
5.0 VDC max
Input response time (registration):
• without noise filter: 0.5µs maximum.
• with noise filter 3.5µs maximum.
TJ 1-FL02
Reg A0 7
External power
supply 24V
0V I/O 17
0V common for Input circuits
Revision 5.0
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173
Hardware reference
Note
In the case of an incorrect registration due to slow edges or noise,
a digital noise filter can be enabled with the REGIST command.
Refer to the BASIC Commands in the Programming Manual.
Note
A maximum of 4 inputs on is allowed simultaneously.
Digital outputs
The following table and illustration details the digital output specifications:
fig. 111
Specification
Type
PNP
Maximum voltage
24 VDC + 10%
Current capacity
100 mA each output (400 mA for a group of 4)
Max. Voltage
24 VDC + 10%
Protection
Over current, Over temperature and 2A fuse on
Common
TJ 1-FL02
2A Fuse
18 24V output supply
13 Out 0
Equivalent
circuit
17
0V I/O
Load
Item
Internal circuitry (galvanically
isolated from system)
/i
External
power
supply
24V
To other output circuits
Output response time (PSwitch):
• 140 µs maximum
Revision 5.0
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Hardware reference
Analog outputs
The following table and illustration details the analog output specifications:
fig. 112
/i
Item
Specification
Output voltage
-10 to +10 V
Resolution
16 bit
Output impedance
100 Ω
Load impedance
10 k Ω min
TJ1-FL02
+15V
1 Vout 0
-15V
3
Isolated 0V
0V
Note
The analogue output of one flexible axis is always 0V unless both
axes in the TJ1-FL02, axis A & B are enabled, that is:
WDOG=ON
AXIS_ENABLE AXIS(A)=1
AXIS_ENABLE AXIS(B)=1
Wdog relay
The following table and illustration details the Wdog relay:
fig. 113
/i
Item
Specification
Type
Solid state relay
Current capacity
50 mA
on resistance
25 Ω max.
Maximum voltage
24 VDC + 10%
TJ1-FL02
5 WDOG+
6
WDOG-
Revision 5.0
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Hardware reference
Encoder interface
The following table and illustration details the encoder interface:
fig. 114
/i
Item
Specification
TJ1-FL02
Type
Phase differential incremental encoder
Signal level
EIA RS-422-A Standards (line-driver)
Input impedance
48 kΩ min
Load impedance
220 Ω min
Termination
None
A0+ /
STEP0+ /
...
A0- /
STEP0- /
...
B0+ /
DIR0+ /
...
B0- /
DIR0- /
...
Connection example
Z0+ /
ENA0+ /
...
Z0- /
ENA0- /
...
+5V
0V
The example shows the connections for the TJ1-FL02 to a F7 Inverter for
position control.
The encoder from the motor must be connected to the encoder interface
(PG-X2) in the Inverter (connector TA1). The encoder signal is forwarded in
the connector TA2 of the (PG-X2).
Make the connections for the 18 pin connector on the TJ1-FL02 to the
terminal board on the F7 Inverter as follows:
1
2
3
4
6
7
10
+5V
5,15
0V
fig. 115
/i
Revision 5.0
TJ1-FL02
pin number
F7 Inverter
TA1
Signal
Description
1
A1
Vout
Analog output
3
AC
0V
0V Reference for Vout
ENC
MOTOR
Encoder Feedback
5
S1
Wdog-
HARDWARE REFERENCE MANUAL
Enable relay contacts
176
Hardware reference
TJ1-FL02
pin number
F7 Inverter
TA1
Signal
Description
6
SP
Wdog+
Enable relay contacts
The cable for pins 1 and 3 must be shielded twisted pair.
The cables for pins 5 and 6 are two single strand cables.
Make the connections for the 15 pin connector on the TJ1-FL02 to the PGX2 option board on the F7 Inverter as follows:
/i
TJ1-FL02
pin number
F7 Inverter
TA2
Signal
Description
1
1
A+
Pulse monitor input phase A+
2
2
A-
Pulse monitor input phase A-
3
3
B+
Pulse monitor input phase B+
4
4
B-
Pulse monitor input phase B-
5
7
GND
Isolated controller circuit GND
Note
The cables are twisted pair (A+,A- and B+,B-) and shielded with
the shield connected to the shell of the TJ1-FL02 15 pin connector.
3.10.4 TJ1-FL02 specifications
/i
Revision 5.0
Item
Specification
Power supply
5 VDC and 24 VDC (supplied by the TJ1-MC__)
Total power consumption
3.35 W
Current consumption
190 mA at 5 VDC and 100 mA at 24 VDC
Approximate weight
110 g
Galvanic isolation
•
•
•
Output power supply
5 VDC, 150 mA Maximum
HARDWARE REFERENCE MANUAL
Encoder interface
Analogue outputs
Digital interface
177
Hardware reference
Item
Specification
Number of axes
2
Control method
•
•
Encoder position/speed feedback
Incremental and absolute
Absolute encoder standards supported
•
•
•
Encoder input maximum frequency
6 MHz
Encoder/pulse output maximum frequency
2 MHz
Maximum cable length:
•
•
•
•
•
SSI 200 kHz, 100 m
EnDat 1 MHz, 40 m
Tamagawa, 50 m
Encoder input, 100 m
Encoder/stepper output, 100 m
Auxiliary I/Os
•
•
•
•
•
Two fast registration inputs per axis
Two definable inputs
Two hardware position switch outputs
One enable output
Two definable outputs
+/- 10 V analogue output in Closed Loop
Pulse Train output in Open Loop
SSI 200 kHz
EnDat 1 MHz
Tamagawa
Note
The 5 VDC power supply can only be used when both axes are in
SERVO_AXIS mode (ATYPE=44).
3.10.5 Applicable BASIC commands
Revision 5.0
The following BASIC commands are applicable for the TJ1-FL02:
• ATYPE
• AXIS_DISPLAY
• DRIVE_CONTROL
• DRIVE_STATUS
HARDWARE REFERENCE MANUAL
178
Hardware reference
BASIC commands applicable for specific encoder types, are listed with the
corresponding explanations in the next chapters. For more information of
BASIC commands, refer to the Trajexia Programming Manual.
3.10.6 Incremental encoder
An incremental encoder has this phase definition:
• An advanced phase A for forward rotation.
• An advanced phase B for reverse rotation.
By monitoring the relative phase of the 2 signals, you can easily detect the
rotation direction. If signal A leads signal B, the movement is clockwise and
the counter increments. If channel B leads channel A, the movement is
counterclockwise and the counter decrements.
Most rotary encodes also provide an additional Z marker. This Z marker is a
reference pulse within each revolution. With these 3 signals, you can
determine the direction, the speed and the relative position.
Encoder input
The pulse ratio of the TJ1-MC__ is 1: every encoder edge (i.e., a pulse edge
for either phase A or B) is equal to one internal count.
The figure shows phase A (A), phase B (B) and the number of counts (C) for
forward or clockwise rotation (D) and reverse or counterclockwise rotation
(E).
The signals A, B and Z appear physically as A+ and A-, B+ and B- and Z+
and Z-. They appear as differential signals on twisted-pair wire inputs. This
makes sure that common mode noise is rejected.
When you use an encoder from other manufacturers, check the encoder
specification for the phase advancement carefully. If the phase definition is
different from the phase definition of the standard OMRON equipment,
reverse the B-phase wiring between the TJ1-MC__ and the encoder.
fig. 116
D
E
A
B
0
1 2
3
4
5 6
7
7
6 5 4
3
2 1
0
C
Revision 5.0
Note
The TJ1-FL02 does not have a termination inside. In case of long
distances or disturbed communication, add an external termination to the TJ1-FL02.
HARDWARE REFERENCE MANUAL
179
Hardware reference
The table below and the figure give an example of how to connect the
OMRON E6B2-CWZ1Z encoder to the TJ1-FL02.
fig. 117
TJ1-FL02
/i
Encoder
A+
AB+
BZ+
Z0 V (COM)
5 VDC
TJ1-FL02
Signal
Wire color
Pin
Signal
A+
Black
1
A+
A-
Black/red
2
A-
B+
White
3
B+
B-
White/red
4
B-
Z+
Orange
6
Z+
Z-
Orange/red
7
Z-
0 V (COM)
Blue
5
GND
5 VDC
Brown
10
+ 5V
1
2
3
4
6
7
5
10
Encoder output
The TJ1-FL02 can generate encoder type pulses. For each internal count
(C), the TJ1-FL02 produces one encoder edge for phase A (A) or phase B
(B).
fig. 118
A
Related BASIC commands
The following BASIC commands are related to incremental encoders:
• ATYPE (ATYPE=44 and ATYPE=45)
• ENCODER_RATIO
For more information, refer to the Trajexia Programming Manual.
B
C
0
1
2
3
4
5
6
7
Revision 5.0
HARDWARE REFERENCE MANUAL
180
Hardware reference
3.10.7 Absolute encoder
SSI
SSI (Synchronous Serial Interface) is a digital system for transferring data in
serial form. SSI is the most widely used serial interface between absolute
sensors and controllers. SSI uses a pulse train from the controller to clock
out the data from the sensor.
The SSI interface of the TJ1-FL02 accepts absolute values from an encoder
if the data is in Gray Code format or in binary format and if the resolution is
25 bits or less. The number of bits, and therefore the number of clock pulses
sent to the encoder in each frame, is programmable. You set this number
with the BASIC command ENCODER_BITS = n.
When you have initialized the TJ1-FL02 with the ENCODER_BITS
command, the TJ1-FL02 continuously sends clock pulses to the encoder.
These clock pulses are sent in frames of n+2 pulses, where n is the bit count
set. The clock rate is fixed at 200 kHz. The clock interval between frames is
32 µs. The resulting maximum cable length between the controller and the
sensor is 200 m.
The labels in the figure are:
A. Timing diagram.
B. Clock sequence.
C. Clock.
D. Data.
E. MSB (Most Significant Bit).
F. LSB (Least Significant Bit).
G. Clock frame.
fig. 119
C
A
E
D
B
F
32 µs
G
G
When the data is clocked into the TJ1-MC__, the position value is
interpreted. With this position value, it produces a value for MPOS and a
position error that is used to close the control loop.
The connections for SSI are:
Revision 5.0
HARDWARE REFERENCE MANUAL
181
Hardware reference
/i
Encoder signal
Axis A
Axis B
DATA+
6
8
DATA-
7
9
CLOCK+
1
11
CLOCK-
2
12
GND
5 / 15
5 / 15
Note
The TJ1-FL02 does not have a termination inside. In case of long
distances or disturbed communication, add an external termination to the TJ1-FL02.
The table below and the figure give an example of how to connect the
Stegmann ATM 60-A encoder to the TJ1-FL02.
fig. 120
TJ1-FL02
/i
Encoder
TJ1-FL02
Pin
Signal
Wire color
Pin
Signal
2
DATA+
White
6
DATA+
10
DATA-
Brown
7
DATA-
3
CLOCK+
Yellow
1
CLOCK+
11
CLOCK-
Lilac
2
CLOCK-
1
GND
Blue
5
8
Us
Red
See footnote
GND
1
2
10
3
11
1
6
7
1
2
5
8
24 V
0V
24 VDC Power Supply
1. Use an external power supply
Revision 5.0
Related BASIC commands
The following BASIC commands are related to SSI absolute encoders:
• ATYPE (ATYPE=48)
• ENCODER_BITS
For more information, refer to the Trajexia Programming Manual.
HARDWARE REFERENCE MANUAL
182
Hardware reference
EnDat
You can configure the TJ1-FL02 to
interface directly to EnDat absolute
encoders. EnDat absolute encoders
respond on a dedicated Clock and
Data 1 MHz RS485 serial interface
when their position is requested by
the controller. When you set the
encoder to the relevant encoder
mode, the axis transmits an
information request to the encoder
on a fixed 250 µs cycle.
The connections for EnDat are:
/i
Encoder signal
Axis A
Axis B
DATA
6
8
/DATA
7
9
CLOCK
1
11
/CLOCK
2
12
GND
5 / 15
5 / 15
Note
The TJ1-FL02 does not have a termination inside. In case of long
distances or disturbed communication, add an external termination
to the TJ1-FL02.
The table below and the figure give
an example of how to connect the
Heidenhain ROC 425 2048 5XS08C4 encoder to the TJ1-FL02.
Encoder
/i
fig. 121
TJ1-FL02
TJ1-FL02
Revision 5.0
Pin
Signal
Wire color
Pin
Signal
3
DATA
Grey
6
DATA
4
/DATA
Pink
7
/DATA
7
CLOCK
Violet
1
CLOCK
6
/CLOCK
Yellow
2
/CLOCK
5
GND
White/Green
5
GND
HARDWARE REFERENCE MANUAL
3
4
7
6
5
6
7
1
2
5
2
1
5V
0V
5 VDC Power Supply
183
Hardware reference
Encoder
TJ1-FL02
Pin
Signal
Wire color
Pin
Signal
2
0V
White
See footnote 1
1
Up
Blue
1. Use an external power supply
Related BASIC commands
The following BASIC commands are
related to EnDat absolute encoders:
• ATYPE (ATYPE=47)
• ENCODER_BITS
• ENCODER_CONTROL
• ENCODER_READ
• ENCODER_TURNS
• ENCODER_WRITE
For more information, refer to the
Trajexia Programming Manual.
Tamagawa
In the figure, A is the encoder side,
and B is the receiving side.
The TJ1-FL02 can interface directly
to Tamagawa “SmartAbs” absolute
encoders. Tamagawa encoders
respond on a dedicated 2.5 MHz
RS485 serial interface when their
position is requested by the
controller. When you set the
encoder to the relevant encoder
mode, the axis transmits an
information request to the encoder
on a fixed 250 µs cycle. The data
returned is available to BASIC and
you can use it to drive a servo
motor.
The connections for Tamagawa are:
fig. 122
/i
Encoder signal
Axis A
Axis B
SD
6
8
/SD
7
9
GND
5 / 15
5 / 15
A
B
TJ1-FL02
5V
ADM485
1 kΩ
220kΩ
Revision 5.0
Note
The TJ1-FL02 does not have a termination inside. In case of long
distances or disturbed communication, add an external termination
to the TJ1-FL02.
HARDWARE REFERENCE MANUAL
1 kΩ
DE
184
Hardware reference
The table below and the figure give an example of how to connect the
Tamagawa TS5667N420 encoder to the TJ1-FL02.
fig. 123
TJ1-FL02
/i
Encoder
TJ1-FL02
Signal
Wire color
Pin
Signal
SD
Blue
6
SD
/SD
Blue/Black
7
/SD
GND
Black
5
GND
Vcc
Red
Use an external power supply
Related BASIC commands
The following BASIC commands are related to Tamagawa absolute
encoders:
• ATYPE (ATYPE=46)
• ENCODER_ID
• ENCODER_STATUS
• ENCODER_TURNS
SD
/SD
GND
6
7
5
VCC
5V
0V
5 VDC Power Supply
For more information, refer to the Trajexia Programming Manual.
Revision 5.0
HARDWARE REFERENCE MANUAL
185
Hardware reference
3.10.8 Stepper
The TJ1-FL02 can generate pulses to drive an external stepper motor
amplifier. You can use single step, half step and micro-stepping drivers with
this interface. Applicable signals:
• Enable
• Step
• Direction.
Related BASIC commands
The following BASIC commands are related to stepper outputs:
• ATYPE (ATYPE=43)
• INVERT_STEP
fig. 124
ENABLE
STEP
DIRECTION
WDOG=ON MOVE(4)
MOVE(-4)
For more information, refer to the Trajexia Programming Manual.
3.10.9 Registration
The TJ1-FL02 can capture the position of an axis in a register when an
event occurs. The event is called the print registration input. On the rising or
falling edge of an input signal (either the Z marker or an input), the TJ1-FL02
captures the position of an axis in hardware. You can use this position to
correct possible errors between the actual position and the desired position.
You set up the print registration with the REGIST command.
The position is captured in hardware and therefore there is no software
overhead. This eliminates the need to deal with timing issues.
Because the registration inputs are very fast, they are susceptible to noise in
combination with slow rising and falling edges. To counter this problem, you
can use a digital noise filter. Use of the noise filter increases the response
time from 0.5 µs to 3.5 µs.
We refer to the REGIST command in the Trajexia Programming Manual for
more information on using the registration inputs.
Revision 5.0
HARDWARE REFERENCE MANUAL
186
Hardware reference
3.10.10 Hardware PSWITCH
The TJ1-FL02 has 2 outputs that you can use as hardware position
switches. These outputs go on when the measured position of the
predefined axis is reached. They go off when another measured position is
reached.
The outputs are driven by hardware only. This means that the response
times do not have software delays.
We refer to the HW_PSWITCH command in the Trajexia Programming
Manual for more information on using the position switches.
3.10.11 TJ1-FL02 box contents
•
•
•
•
•
Safety sheet.
TJ1-FL02.
Protection label attached to the top surface of the unit.
Parts for a 15-pin connector.
Parts for an 18-pin connector.
Revision 5.0
HARDWARE REFERENCE MANUAL
187
Differences between Sigma-II and Junma
A
Differences between Sigma-II and Junma
Revision 5.0
These are the differences between Sigma-II and Junma Servo Drivers and
motors.
1. Motor
• The Sigma-II Servo Driver can control a large range of servo motors.
These include rotary, DD and Linear motors with different encoders,
IP rates, inertias and other electrical and mechanical characteristics.
• The Junma can only control Junma motors with a 13-bit incremental
encoder. These motors have a low IP rate and medium inertia.
2. Power and voltage range
• The output power of Sigma-II Servo Drivers and motors range from
30 W to 15 kW. The input voltages of Sigma-II Servo Drivers and
motors are 200 V single phase and 400 V three phase.
• The output power of Junma Servo Drivers and motors range from
100W to 800W. The input voltage of Junma Servo Drivers and
motors is 200V single phase.
3. Power circuit
• Sigma-II always has a breaking chopper. Most models have internal
braking resistor too. The voltage supplies for power and control
circuits are separate.
• Junma has no breaking chopper or resistor. The same voltage
supply is used for both power and control circuits.
4. Motion control algorithm
• Sigma-II has a traditional PID control algorithm, which in most cases
needs adjustments and tuning of parameters. Sometimes adjusting
and tuning can be time consuming but the benefit is full coverage of
a very wide range of applications regarding mechanical
characteristics of the system, such as inertia ratio, rigidity etc.
• Junma supports a new and innovative self-tuning control algorithm,
which requires no adjustment and tuning from the user. The benefit
of this algorithm is that commissioning of the system is very fast and
easy. The drawback is a limited range of applications covered. This
particularly applies to inertia ratio. Junma Servo Drivers and motors
cannot serve applications where the inertia ratio is larger than 1:10
approximately.
5. Control modes
HARDWARE REFERENCE MANUAL
•
•
Sigma-II can work in all three control modes: position mode
(ATYPE=40), speed mode (ATYPE=41) and torque (force) mode
(ATYPE=42).
Junma can work only in position mode (ATYPE=40). Trying to set an
axis assigned to a Junma Servo Driver and motor to some other
control mode results in an alarm on the driver
6. I/O
• Sigma-II has 7 digital inputs and 4 digital outputs. Functionality of
these I/Os is very flexible and can be configured using drivers
parameters. Analog control is possible (with the TJ1-FL02). There is
an encoder output as well, and fully closed encoder configuration is
possible.
• Junma has 4 digital inputs and 2 digital outputs. They are not flexible,
but have fixed functionality. Fully closed encoder configuration is not
possible.
7. Operator interface and settings
• The Sigma-II Servo Driver has a full operator interface. It consists of
a 4-digits display and 4 buttons. The interface can be used to
monitor and change parameters, perform tuning etc. Changing
parameters by using the CX-Drive software or by sending
MECHATROLINK-II commands from Trajexia is also possible.
• The Junma Servo Driver has a limited operator interface. It consists
of a 1-digit display that shows the driver status and alarms.
Monitoring and changing of parameters is only possible by using a
separate operator panel, the CX-Drive software or by sending
MECHATROLINK-II commands from Trajexia.
For more detailed information on the differences between Sigma-II and
Junma Servo Drivers and motors, please see their respective manuals.
188
Revision history
Revision history
A manual revision code shows as a suffix to the catalogue number on the front cover of the manual.
/i
Revision code
Date
Revised content
01
August 2006
Original
02
October 2006
DeviceNet update
03
May 2007
Updated with TJ1-MC04, TJ1-ML04, JUNMA series Servo Drivers and the MECHATROLINK-II repeater.
Updated with motion control concepts, servo system principles and detailed encoder information.
04
June 2008
Updated with TJ1-CORT, GRT1-ML2, Sigma-V Servo Driver and MECHATROLINK-II functionality (Inverter as an axis)
05
January 2010
Updated with G-Series and Accurax G5 Servo Drivers
Revision 5.0
HARDWARE REFERENCE MANUAL
189
hardware reference manual
TJ1-MC04, TJ1-MC16, TJ1-ML04, TJ1-ML16, TJ1-PRT, TJ1-DRT, TJ1-CORT, TJ1-FL02
GRT1-ML2
Trajexia motion control system
Cat. No.
I51E-EN-04
Cat. No.
I51E-EN-04
Trajexia motion control system
hardware reference manual
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Cat. No. I51E-EN-05