LB11868VGEVB

Ordering number : ENA1915A LB11868V Monolithic Digital IC For Fan Motor http://onsemi.com Variable Speed Single-phase Full-wave Pre-driver Overview LB11868V is a single-phase bipolar driving motor pre-driver with the variable speed function compatible with external PWM signal. With a few external parts, a highly-efficient and highly-silent variable drive fan motor with low power consumption can be achieved. This product is best suited for driving of the server requiring large air flow and large current and the fan motor of consumer appliances. Features • Single-phase full-wave driving pre-driver • Variable speed control possible with external PWM input • Current limiting circuit incorporated • Reactive current cut circuit incorporated • Minimum speed setting pin • Soft start setting pin • Start setting pin of on time • Pch-FET kickback absorption setting pin • Lock protection and automatic reset circuits incorporated • FG (rotational speed detection) output, RD (lock detection) output • Thermal shutdown circuit incorporated Semiconductor Components Industries, LLC, 2013 February, 2018 – Rev. 1 51311 SY/11911 SY 20101217-S00010 No.A1915-1/11 LB11868V Specifications Absolute Maximum Ratings at Ta = 25°C Parameter Symbol VCC pin maximum supply voltage VCC max 18 V IOUTN max VOUTN max 30 mA 18 V IOUTP max IOUTP off max 30 mA DUTY8% under 10 mA *1 19 V 7 V OUTN pin maximum current OUTN pin output withstand voltage OUTP pin maximum Sink current Maximum inflow current at OUTP Conditions Ratings Unit pin OFF OUTP pin output withstand voltage VTH/RMI pins withstand voltage VOUTP max VVTH/VRMI max S-S pin withstand voltage VS-S max 7 V OTS pin withstand voltage VOTS max 7 V KBSET pin withstand voltage VKBSET max 7 V FG/RD pin withstand voltage VFG/RD max 19 V FG/RD pin maximum Sink current IFG/RD max IREG max 10 mA 10 mA IHB max Pd max 10 mA 800 mW REG pin maximum output current HB pin maximum output current Allowable power dissipation Operating temperature Topr Storage temperature Tstg with specified substrate *2 *3 -30 to 95 °C -55 to 150 °C *1 The direct input from the power supply is improper. There must be resistance between OUTP and the power side power supply. *2 Specified substrate: 114.3mm×76.1mm×1.6mm, glass epoxy board. *3 Tj max=150°C must not be exceeded. Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability. Recommended Operating Conditions at Ta = 25°C Parameter VCC Supply voltage VTH/RMI input voltage range Hall input voltage range Symbol VCC Conditions Ratings VTH/RMI VICM Unit 4.0 to 16 V 0 to 4.0 V 0.2 to 1.8 V Electrical Characteristics at Ta = 25°C, VCC = 12V Parameter Circuit current REG voltage Symbol Conditions Ratings min typ Unit max ICC1 ICC2 During drive 7.5 9.0 10.5 mA During lock protection 6.0 7.6 9.0 mA VREG IREG = 5mA IHB = 5mA 3.65 3.80 3.95 V 1.14 1.24 1.34 V HB voltage VHB Current limiting voltage VLIM 195 215 235 mV CPWM pin “H” level voltage VCPWMH 2.35 2.50 2.65 V CPWM pin “L” level voltage VCPWML 0.65 0.80 0.95 V CPWM pin charge current VCPWM = 0.5V 19 24 29 µA CPWM pin discharge current ICPWM1 ICPWM2 24.5 29.5 FPWM VCPWM = 2.8V C = 220PF 19.5 CPWM Oscillation frequency CT pin “H” level voltage VCTH 2.35 2.50 2.65 V CT pin “L” level voltage VCTL 0.65 0.80 0.95 V CT pin charge current ICT1 ICT2 VCT = 0.5V 1.6 2.0 2.4 μA CT pin discharge current VCT = 2.8V 0.16 0.20 0.24 CT pin charge/discharge ratio RCT ICT1/ICT2 VS-S = 1V 8 10 12 0.35 0.45 0.55 VOTS=0.5V 0.65 0.85 1.05 µA VOTS=0.5V 50 58 66 µA S-S pin discharge current OTS pin charge current OTS pin discharge current OTS pin threshold voltage OUTN output H-level voltage IS-S IOTS1 IOTS2 VOTS VONH 32 1.2 IO = 1mA IO = 10mA µA kHz μA times µA 1.3 1.4 V VCC-0.9 VCC-1.0 V VCC-1.9 VCC-2.1 V Continued on next page. No.A1915-2/11 LB11868V Continued from preceding page. Ratings Parameter Symbol Conditions Unit min typ max OUTN output L-level voltage VONL IO = 10mA 0.9 1.05 OUTP output L-level voltage VOPL IO = 10mA 0.4 0.55 V V Hall input sensitivity VHN IN+, IN- differential voltage (including offset and hysteresis) ±10 ±20 mV 0.2 FG/RD output L-level voltage VFGL/RDL IFG/RD = 5mA 0.3 V FG/RD pin leakage current IFGL/RDL VFG/RD = 19V 10 µA VTH/RMI pin bias current IVTH/IRMI CPWM = 2V, VTH/RMI = 1V 0.3 µA Truth table (1) Drive lock CPWM=H VTH, RMI, S-S=L IN- IN+ H L L OUT1P OUT1N OUT2P OUT2N FG RD Mode L L OFF H L L OUT1 → 2 drive H OFF H L L OFF L OUT2 → 1 drive H L OFF L OFF H L OFF L H OFF H OFF L OFF OFF IN- IN+ OUT1P OUT1N OUT2P OUT2N Mode H L L L OFF H OUT1 → 2 drive OUT2 → 1 drive CT L H Lock protection (2) Speed control CT, S-S=L VTH, RMI L CPWM OTS H L H OFF H L L H L OFF L OFF H L H OFF H OFF L L H H L L Regeneration mode H L OFF L OFF L L H OFF L OFF L H Standby mode For VTH, RMI, and S-S pins, refer to the timing chart. Pin Assignment No.A1915-3/11 LB11868V Package Dimensions unit : mm (typ) 3360 5.2 0.5 4.4 6.4 20 12 0.5 0.15 0.22 1.5 MAX 0.1 (1.3) (0.35) SANYO : SSOP20J(225mil) Block Diagram No.A1915-4/11 LB11868V Application Circuit Example *1. Power stabilization capacitor For the power stabilization capacitor on the signal side, use the capacitance of 1μF or more. Connect VCC and SGND with a thick and shortest pattern. *2. Power stabilization capacitor on the power side For the power stabilization capacitor on the power side, use the capacitance of 1μF or more. Connect the power supply on the power side and GND with a thick and shortest pattern. When the IC is used for a fan with a high current level, insert a zener diode between the power supply on the power side and GND. *3. REG pin 3.8V constant-voltage output pin. For the REG oscillation prevention and stabilization, use a capacitor with capacitance of 1µF or more. Connect the REG pin and SGND with a thick and shortest pattern. *4. HB pin Used for Hall device bias purposes. *5. IN+, IN- pins Hall signal input pin. Wiring should be short to prevent carrying of noise. If noise is carried, insert the capacitor between IN+ and IN- pins. The Hall input circuit functions as a comparator with hysteresis (15mV). This also has a soft switch section with ±30mV (input signal differential voltage). It is also recommended that the Hall input level is minimum 100mV (p-p). No.A1915-5/11 LB11868V *6. CPWM pin Pin to connect the capacitor for generation of the PWM basic frequency The use of CP = 220pF causes oscillation at f = 30kHz (typical), which is the basic frequency of PWM. As this is used also for the current limiting canceling signal, ON-time start function and Soft start function, be sure to connect the capacitor even when the speed control is not made. *7. RMI pin Minimum speed setting pin. Perform pull-up with REG when this pin is not to be used. If the IC power supply is likely to be turned OFF first when the pin is used with external power supply, be sure to insert the current limiting resistor to prevent inflow of large current. (The same applies to the VTH pin.) *8. VTH pin Speed control pin. Connect this pin to GND when it is not used (at full speed). For the control method, refer to the timing chart. For control with pulse input, insert the current limiting resistor and use the pin with the frequency of 20kHz to 100kHz (20kHz to 50kHz recommended). *9. SENSE pin Current limiting detection pin. When the pin voltage exceeds VLIM, the current is limited and the operation enters the lower regeneration mode. Connect this pin to GND when it is not to be used. *10. FG pin Rotational speed detection pin. Open collector output that can detect rotational speeds by the FG output in response to the phase switching signal. Keep this pin open when it is not to be used. It is recommended that a current-limiting resistor with a resistance of 1kΩ or more be inserted in order to protect the pin during unplugging and plugging the connector or when mistakes are made in connection. *11. RD pin Lock detection pin In open collector output, L upon rotation and H when locked (using pull-up resistance). Keep this pin open when it is not to be used. *12. CT pin Pin to connect the lock detection capacitor. The constant-current charge and discharge circuits incorporated cause locking when the pin voltage becomes VCTH and unlocking when it is VCTL. Connect the pin to GND when it is not to be used (locking not necessary). *13. S-S pin Pin to connect the soft-start setting capacitor. Connect the capacitor between REG and S-S pin. This pin enables setting of the soft start time according to the capacity of the capacitor. See the timing char. Connect the pin to GND when it is not to be used. *14. OTS pin Pin to connect the ON-time start setting capacitor. A constant-current charging circuit and a discharging circuit based on the control duty ratio are incorporated, and when the pin voltage exceeds VOTS, the CT pin is discharged and the S-S pin is charged. Connect the pin to GND when it is not to be used (when the lowest speed setting is used). No.A1915-6/11 LB11868V *15. KBSET pin Pch kickback absorption circuit setting pin. Open: The kickback absorption circuit is activated at a VCC voltage of 7.4V (typ) or above. Pull-down to GND: Always OFF Pull-up to REG: Always ON (but when the IC power is OFF, the kickback absorption circuit is OFF) If the Pch load is to be reduced due to the large fan current, short the KBSET pin to GND, and use a zener diode between the power supply on the power side and GND. Kickback absorption circuit ON: At OUTPOFF, the OUTP voltage is clamped at VCC + 0.85V (at room temperature and inflow current 5mA (typ)). Kickback absorption circuit OFF: At OUTPOFF, the OUTP voltage is clamped at 18V or so (at room temperature and inflow current 5mA (typ)) in order to protect the pin. At OUTPOFF, the maximum inflow current must not be exceeded. *16. Pch FET If the Pch kickback absorption circuit is activated and a zener diode between the power supply and GND is not used, the kickback during phase switching is absorbed by Pch. Since the circuit is activated with a high voltage difference between the drain and source, select a FET with sufficiently high capability. *17. Nch FET If the Nch gate voltage fluctuates significantly due to the effects of switching, insert a capacitor between the gate and GND. Since an Nch diode is used during coil current regeneration, select a FET with sufficiently high capability. No.A1915-7/11 LB11868V Control timing chart (Speed control) (1) Minimum speed setting (standby) mode The low-speed fan rotation occurs at the minimum speed set with the RMI pin. When the minimum speed is not set (RMI pin pulled up to REG), the motor stops. If the VHT voltage rises when the lowest speed is not set (RMI pin is pulled up to REG), the fan stops running, and if the OTS pin capacitor is used, the standby mode is established. Details of the standby mode are given in the section “Control timing chart (ON-time start, Lock protection). (2) Low speed⇔high speed PMW control is made by comparing the CPWM oscillation voltage (VCPWML⇔VCPEMH) and VTH voltage. The drive mode is established when the VTH voltage is low. Both upper and lower output FET are turned ON when the VTH voltage is low. When the VTH voltage is high, Pch is turned off, and the coil current is regenerated inside the lower FET. Therefore, as the VTH voltage decreases, the output ON-DUTY increases, causing an increase in the coil current and raising the motor rotation speed. The upper output Pch is turned OFF when the VTH voltage is high, regenerating the coil current in the lower TR. Therefore, as the VTH voltage decreases, the output ON-DUTY increases, causing increase in the coil current, raising the motor rotation speed. The rotational speed can be monitored using the FG output. (3) Full speed mode The full speed mode becomes effective when the VTH voltage is VCPWML or less. (Set VTH = GND when the speed control is not to be made.) No.A1915-8/11 LB11868V Control timing chart (Soft start) (1)At VTH < RMI voltage (2) At VTH > RMI voltage Adjust the S-S pin voltage gradient by means of the capacitance of the capacitor between the S-S pin and REG.. Recommended capacitor: 0.1µ to 1µF No.A1915-9/11 LB11868V Control timing chart (ON-time start, Lock protection) (1) When a stop signal based on the VTH voltage has been input during normal rotation When the output duty ratio based on the VTH/RMI input drops to below 1% or so, the OTS voltage rises, and when it reaches VOTS, the standby mode is established, the CT pin discharges, and the S-S pin is charged. In the standby mode, if the drive mode has been established again by the VTH/RMI input, the rotation is started immediately with soft start. The CT pin discharges at the same time as the switching of FG. For details on lock protection, refer to (2). (2) When a stop signal based on the VTH voltage has been input while the fan is constrained When the fan is constrained, the CT pin voltage rises, and when it reaches VCTH, the lock protection mode is established, and OUTP is set to OFF and RD is set to OFF. When the lock protection mode is established, the CT pin discharges, and when VCTL is reached, restart (soft start) is initiated. When rotation is started and the FG signal is switched, RD is set to low. Note: RD is also set to low when the standby mode is established when locked. No.A1915-10/11 LB11868V ORDERING INFORMATION Device LB11868V-TLM-H LB11868V-W-AH Package SSOP20J(225mil) (Pb-Free/ Halogen Free) SSOP20J(225mil) (Pb-Free/ Halogen Free) Wire bond Au-wire Shipping (Qty / Packing) 2000 / Tape & Reel Cu-wire 2000 / Tape & Reel ON Semiconductor and the ON logo are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent-Marking.pdf. SCILLC reserves the right to make changes without further notice to any products herein. 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