Page 1 Series Integrated Servo Motor User Manual...
Page 2 User Manual of iSV2-CAN Integrated Servo Foreword Thank you for purchasing Leadshine iSV2-CAN series Integrated Servo Motors. This manual will provide information on the iSV2-CAN series Integrated Servo products regarding product safety & specifications, installations & wiring, tuning & problem diagnostics.
Page 3 User Manual of iSV2-CAN Integrated Servo Transportation Caution Caution  Please provide storage and transportation under protected conditions.  Do not stack the products too high up to prevent toppling.  The product should be packaged properly during transportation,  Do not hold the product by the cable, motor shaft or encoder while transporting it. ...
Page 4 User Manual of iSV2-CAN Integrated Servo Tuning and running Caution Caution  Make sure the wirings of servo drive and servo motor are installed and fixed properly before powering on.  On the first time tuning of the product, it is recommended to run unloaded until all the parameter settings are confirmed to prevent any damage to the product or machine.
Page 5 If available, please send product back in original packaging or make sure it is well packaged to prevent any damage to the product during shipping. Leadshine Technology Co.,Ltd. and its certified sales channel reserved the final right of the interpretation of the warranty information.
Page 6: Table Of Contents
User Manual of iSV2-CAN Integrated Servo TABLE OF CONTENT CHAPTER 1 INTRODUCTION ........................... 9 ........................... 9 1.1 P RODUCT NTRODUCTION 1.2 M ........................... 10 ODEL UMBER TRUCTURE 1.3 S ........................11 ERVO RIVE ECHNICAL PECIFICATION 1.4 I ......................12 NTEGRATED OTOR ORTS AND ONNECTORS...
Page 7 User Manual of iSV2-CAN Integrated Servo CHAPTER 4 CONTROL MODE ..........................81 4.1 P ............................81 ROFILE OSITION 4.1.1 Pulse ................................81 4.1.2 Motion settings ............................81 4.1.3 Monitoring settings ............................ 82 4.1.4 Applications example ..........................82 4.2 P ............................83 ROFILE ELOCITY 4.2.1 Motion Settings ............................
Page 8 User Manual of iSV2-CAN Integrated Servo 6.5.4 Access attribute ............................134 6.6 N (NMT) ........................... 135 ETWORK ANAGEMENT 6.6.1 NMT module control ..........................135 6.6.2 NMT node guarding ..........................135 6.6.3 NMT Boot-up ............................136 6.6.4 NMT communication status machine ...................... 136 6.7 P (PDO) ..........................
Page 9: Chapter 1 Introduction
Chapter 1 Introduction 1.1 Product Introduction iSV2-CAN Series DC Servo Drive is our latest generation DC servo drive that is based on CANopen DSP402 protocol. It can be easily matched to any controller that supports this protocol. Using the latest signal processing chip from Texas Instrument, the drive is compact with small volume and good reliability.
Page 10: Model Number Structure
User Manual of iSV2-CAN Integrated Servo 1.2 Model Number Structure iSV2 – CAN 60 40 V48 G Motor Series Motor Brake Without brake iSV2 Series Integrated iSV2 Servo Motor With brake Rated Voltage Communication Protocol 24VDC Modbus RTU/Pulse+Direction 48VDC CANopen Rated Power Motor Flange Size 200W...
Page 11: Servo Drive Technical Specification
User Manual of iSV2-CAN Integrated Servo 1.3 Servo Drive Technical Specification iSV2-CAN series CAN6020V24 CAN6020V48 CAN6040V48 CAN8075V48 Rated Current (Arms) Peak Current (Arms) Flange size (mm) Main power supply 24/48VDC Drive mode SVPWM sinusoidal wave drive Velocity regulation ratio 5000:1 Electronic gear ratio 1～32767/1～32767...
Page 12: Integrated Motor Ports And Connectors
User Manual of iSV2-CAN Integrated Servo 1.4 Integrated Motor Ports and Connectors iSV2-CAN Series Integrated Servo Motor (6020/6040/8075) CANopen Communication Port Baud Rate/Terminal Resistor Switch Main Power Supply (DC+, DC-) Regenerative Resistor I/O Port (RB+, RB-) ID Spin Dial (RSC)
Page 13: Chapter 2 Installation & Wiring
User Manual of iSV2-CAN Integrated Servo Chapter 2 Installation & Wiring 2.1 Servo Drive Installation 2.1.1 Servo drive installation environment Storage: -20~+65℃ (Condensation free); Temperature Installation: -20~+45℃ ( Please allow air circulation if >45℃) Humidity Under 90%RH (Condensation free) Altitude Up to 1000m above sea level Atmospheric 86 ~ 106kPa...
Page 14: Integrated Servo Motor Basic Information
User Manual of iSV2-CAN Integrated Servo 2.2 Integrated Servo Motor basic information 2.2.1 Speed-torque curves 200W Motors (iSV2-**20*) 400W Motors (iSV2-**40*)
Page 15 User Manual of iSV2-CAN Integrated Servo 750W Motors (iSV2-**75*)
Page 16: Integrated Servo Motor Dimension
User Manual of iSV2-CAN Integrated Servo 2.2.2 Integrated Servo Motor Dimension iSV2 Series 95.7 CAN6020V24H 124.7 CAN6020V24G 95.7 CAN6020V48H Ø70 Ø5.5 124.7 CAN6020V48G 112.7 CAN6040V48H 124.7 CAN6040V48G 128.8 CAN8075V48H 100 Ø90 Ø6.6 21.5 160.3 CAN8075V48G...
Page 17: Isv2-Can Wiring Diagram
2.3 iSV2-CAN Wiring Diagram iSV2-CAN Wiring Diagram  iSV2-CAN series integrated servo motor doesn’t have pulse or analogue input.  Make sure data transferring cables are as short as possible. Keep CN1 cable under 3m and CN2 cable under 10m. Use shielded double winding cables to cut down on electromagnetic interference.
Page 18: Integrated Servo Motor Ports
User Manual of iSV2-CAN Integrated Servo 2.4 Integrated Servo Motor Ports iSV2-CAN 6020/6040/8075 CN5 CANopen Baud Rate/Terminal Communication Resistor Switch Port ID Spin Dial (RSC) CN1 I/O Port CN3 Main Power Supply (DC+, DC-) CN4 Regenerative Resistor (RB+, RB-) Cooling Vent CN7 RS232 Indicator LED Tuning Port...
Page 19: Cn1 I/O Signal Port
User Manual of iSV2-CAN Integrated Servo 2.4.1 CN1 I/O Signal Port Diagram Signal Description COM_IN Common DI Emergency stop Homing switch Positive limit Negative limit Alarm output, current output <100mA Servo ready, current output <100mA COM_OUT Common output I/O Signal Wiring Diagram 1.
Page 20: Cn3/Cn4 Power Supply & Regenerative Resistor Port
User Manual of iSV2-CAN Integrated Servo CN1 control signal cable selection To ensure I/O signal to not be affected by electromagnetic interference, a shielded cable is recommended for this application. Foil shield Cables for different analogue signals should be using isolated shielded cable while cables for digital signals should be shielded twisted pair cable.
Page 21: Cn7 Rs232 Tuning Port
User Manual of iSV2-CAN Integrated Servo 2.4.4 CN7 RS232 Tuning Port Port Diagram Signal ISV2-CAN Series Integrated Servo Motor can be connected to Motion Studio 2 for parameters tuning and data monitoring using CABLE-PC-1. 2.4.5 ID spin dial RSC Diagram CAN address CAN address Pr0.23...
Page 22: Baud Rate/Terminal Resistor Switch Sw
User Manual of iSV2-CAN Integrated Servo 2.4.6 Baud rate/Terminal resistor switch SW CAN_ID Terminal Diagram Baud rate (High Bit) resistor Pr0.24 Default: 1MHz Disconnected (CAN) 500kHz 250kHz Connected (CAN) 125kHz...
Page 23: Cable Selection
User Manual of iSV2-CAN Integrated Servo 2.5 Cable Selection 2.5.1 Communication Cable CABLE-TX*M*-iSV2 CABLE-TX*M*-iSV2-LD2 - For CANopen and Modbus RS485 - For CANopen and Modbus RS485 communication between iSV2 devices. communication between iSV2 devices and ELD2/2ELD2 drives. 2.5.2 Tuning Cable CABLE-PC-1 - To connect to Motion Studio 2 PC tuning software.
Page 24: Regenerative Resistor Selection
User Manual of iSV2-CAN Integrated Servo 2.6 Regenerative Resistor Selection The use of regenerative resistor When the motor opposes the direction of rotation as in deceleration or vertical axis escalation, part of the regenerative energy will be delivered back to the driver. This energy will first be stored in internal capacitors of the driver.
Page 25 User Manual of iSV2-CAN Integrated Servo Theoretical selection of regenerative resistor Without external loading torque, the need for an external regenerative resistor can be determined as the flow chart below Start T is the time for velocity to reach Determine the max.
Page 26 User Manual of iSV2-CAN Integrated Servo Diagram below shows the acceleration and deceleration cycle periods and the regenerative torque that occurs during the process. V:Motor rotational velocity Rotational velocity :Deceleration time Motor Torque : Load torque Regenerative torque Steps to calculate capacity of regenerative resistor Steps Calculation Symbol...
Page 27 User Manual of iSV2-CAN Integrated Servo Recommended regenerative resistor specification for each drives Motors Power rating(W) Resistance (Ω) Min. Resistance(Ω) ISV2-CAN6020 ISV2-CAN6040 ISV2-CAN8075 Note: 1. Use 10 /100W resistor for test operation and make sure: Drive temperature d33<60 , dynamic Ω...
Page 28: Chapter 3 Parameter
User Manual of iSV2-CAN Integrated Servo Chapter 3 Parameter 3.1 Parameter List Panel Display as follows:  Parameter Valid mode Description  HM: Valid in homing mode PP: Valid in profile position mode PV: Valid in profile velocity mode PT: Valid in profile torque mode F: Valid in all modes 3.1.1 Servo drive parameter CANopen...
Page 29 User Manual of iSV2-CAN Integrated Servo CANopen Label Class Parameter Activation Valid Mode Address position loop gain 2100h PR_100 Immediate velocity loop gain 2101h PR_101 Immediate Integral Time Constant 2102h PR_102 Immediate of Velocity Loop velocity detection filter 2103h PR_103 Immediate Torque Filter Time 2104h...
Page 30 User Manual of iSV2-CAN Integrated Servo CANopen Label Class Parameter Activation Valid Mode Address Adaptive filtering mode 2200h PR_200 Immediate settings notch frequency 2201h PR_201 Immediate notch bandwidth 2202h PR_202 Immediate selection notch depth selection 2203h PR_203 Immediate notch frequency 2204h PR_204 Immediate...
Page 31 User Manual of iSV2-CAN Integrated Servo CANopen Label Class Parameter Activation Valid Mode Address Zero speed clamp level 2316h PR_316 Immediate Internal/External 2317h PR_317 Immediate settings of torque Torque command 2320h PR_320 Immediate direction selection Velocity limit value in 2321h PR_321 Immediate torque mode...
Page 32 User Manual of iSV2-CAN Integrated Servo CANopen Label Class Parameter Activation Valid Mode Address threshold Negative torque warning 2524h PR_524 Immediate threshold Torque warning threshold alarm delay 2537h PR_537 After restart time Torque limit 2539h PR_539 Immediate JOG trial run velocity 2604h PR_604 Immediate...
Page 33 User Manual of iSV2-CAN Integrated Servo CANopen Label Class Parameter Activation Valid Mode Address Current loop gain 2700h PR_700 Immediate Current loop integral Immediate time 2701h PR_701 Motor rotor initial angle Immediate compensation 2702h PR_702 Current differential Immediate coefficient 2703h PR_703 Death zone...
Page 34: Motion Parameter Starting With Object Dictionary 6000
User Manual of iSV2-CAN Integrated Servo 3.1.2 Motion parameter starting with object dictionary 6000 Index Sub-index Label Unit Default Mode Error code 0xFFFF 603F Control word 0xFFFF 6040 Status word 0xFFFF 6041 605A Quick stop option code Shutdown option code 605B Disable operation...
Page 35 User Manual of iSV2-CAN Integrated Servo Command 2147483 Max. software limit 2147483 unit Polarity 607E 0xFF Command 214748 2147483 PP/HM Max Profile Velocity 607F unit /s 3647 2147483 Max Motor Speed 6080 r/min 6000 Command 2147483 Profile Velocity 10000 6081 unit /s Command 2147483...
Page 36: Parameter Function
User Manual of iSV2-CAN Integrated Servo unit /s 2147483 Position Demand Internal Encoder 2147483 60FC 2147483 PP/HM Value unit 0x7FFFF Digital Inputs 60FD Number of Entries 0x7FFFF 60FE Physical Outputs 0x7FFFF Bit Mask Command 2147483 60FF Target velocity 2147483 unit /s 0x7FFFF 6502 Supported drive modes...
Page 37 User Manual of iSV2-CAN Integrated Servo Label Control Mode Settings Valid Mode Pr0.01 Range Unit — Default Index 2001h Activation After restart Set value to use following control modes： Value Content Details Only for internal position Position Only for internal velocity Velocity Reserved PP/PV/PT/HM...
Page 38 User Manual of iSV2-CAN Integrated Servo Label Inertia ratio Mode Pr0.04 Range 0~1 0000 Unit Default Index 2004h Activation Immediate Pr0.04=( load inertia/motor rotational inertia)×100% Notice: Set inertia ratio according to actual load inertia. When both are uniform, actual motor velocity loop responsiveness and gain settings will be consistent.
Page 39 User Manual of iSV2-CAN Integrated Servo Label Absolute Encoder settings Mode Pr0.15 Range 0~32767 Unit Default Index 2015h Activation Immediate 0: Incremental mode: Used as an incremental encoder. Doesn’t retain position data on power off. Unlimited travel distance. 1: Multiturn linear mode: Used as a multiturn absolute encoder.
Page 40: Class 1】Gain Adjustments
User Manual of iSV2-CAN Integrated Servo 3.2.2【Class 1】Gain Adjustments Label position loop gain Mode 0~3000 Range Unit 0.1/s Default Index 2100h Pr1.00 Activation Immediate Higher position loop gain value improves the responsiveness of the servo driver and lessens the positioning time. Position loop gain value shouldn’t exceed responsiveness of the mechanical system and take in consideration velocity loop gain, if not it might cause vibration, mechanical noise and overtravel.
Page 41 User Manual of iSV2-CAN Integrated Servo Label velocity detection filter Mode Range 0~10000 Unit — Default Index 2103h Pr1.03 Activation Immediate This filter is a low pass filter. It blocks high frequencies which cause system instability from velocity feedback data. The higher the set value, lower frequencies will be blocked and velocity responsiveness will also be lowered.
Page 42 User Manual of iSV2-CAN Integrated Servo Label Position Loop Gain Mode Range 0~30000 Unit 0.1/s Default Index 2105h Pr1.05 Activation Immediate Label velocity loop gain Mode Range 1~32767 Unit 0.1Hz Default Index 2106h Pr1.06 Activation Immediate Integral Time Constant of Velocity Label Mode Loop...
Page 43 User Manual of iSV2-CAN Integrated Servo Velocity feed forward Label Mode filter time constant Pr1.11 Range 0~6400 Unit 0.01ms Default Index 2111h Activation Immediate Set velocity feed forward low pass filter to eliminate high or abnormal frequencies in velocity feed forward command.
Page 44 User Manual of iSV2-CAN Integrated Servo Position control gain Label Mode switching mode Pr1.15 Range 0~11 Unit — Default Index 2115h Activation Immediate Condition Gain switching condition Value gain fixed Fixed on using 1 gain(Pr1.00-Pr1.04) gain fixed Fixed on using 2 gain (Pr1.05-Pr1.09) Reserved Switch to 2...
Page 45 User Manual of iSV2-CAN Integrated Servo Valid for position control. Switch to 2 gain when position deviation absolute value larger than (level + hysteresis)[pulse] Switch to 1 gain when position deviation absolute value smaller than (level-hysteresis)[pulse] Large position deviation Velocity Level Hysteresis Position...
Page 46 User Manual of iSV2-CAN Integrated Servo Hysteresis Level Velocity Feedback Valid for position control. Switch to 2 gain if position command ≠ 0 Switch to 1 gain if positional command = 0 throughout the duration of delay time and absolute value of actual velocity remains smaller than (level - hysteresis) (r/min) Pending position command...
Page 47 User Manual of iSV2-CAN Integrated Servo Hysteresis at position Label Mode control switching Mode Pr1.18 Range 0~20000 Unit Default Index 2118h dependent Activation Immediate To eliminate the instability of gain switching. Used in combination with Pr1.17 the same unit. If level< hysteresis, drive will set internally hysteresis = level. Position gain switching Label Mode...
Page 48: Class 2】Vibration Suppression
User Manual of iSV2-CAN Integrated Servo Special function Label Mode Register Pr1.37 Range 0~10000 Unit 0.1ms Default Index 2119h Activation Immediate Description Description Positioning done signal for Status Word 0: 6062 Reserved 1：INP input signal Reserved Reserved Virtual I/O homing 0：Disable Reserved 1：Enable...
Page 49 User Manual of iSV2-CAN Integrated Servo Label notch frequency Mode Range 50~4000 Unit Hz Default 4000 Index 2201h Pr2.01 Activation Immediate Set center frequency of 1 torque command notch filter. Set Pr2.01 to 4000 to deactivate notch filter notch bandwidth Label Mode selection...
Page 50 User Manual of iSV2-CAN Integrated Servo Label notch depth selection Mode Range 0~99 Unit Default Index 2206h Pr2.06 Activation Immediate Set notch depth for 1 resonant notch filter. When Pr2.06 value is higher, notch depth becomes shallow, phase lag reduces. Under normal circumstances, please use factory default settings.
Page 51 User Manual of iSV2-CAN Integrated Servo Position command Label Mode smoothing filter Pr2.22 Range 0~32767 Unit 0.1ms Default Index 2222h Activation Stop axis To set time constant of 1 time delay filter of position command. To set time constant of 1 time delay filter, according to target velocity Vc square wave command as show below.
Page 52 User Manual of iSV2-CAN Integrated Servo Position command Label Mode filter Pr2.23 Range 0~10000 Unit 0.1ms Default Index 2223h Activation Disable axis As shown below, when target velocity Vc square wave command reaches Vc, it becomes trapezoidal wave after filtering. Position Position command Velocity...
Page 53: Class 3】Velocity/ Torque Control
User Manual of iSV2-CAN Integrated Servo 3.2.4【Class 3】Velocity/ Torque Control Internal/External settings Label Mode of velocity settings Pr3.00 Range Unit Default Index 2300h Activation Immediate Internal settings can be achieved by connecting to driver’s input interface. velocity Set value Velocity settings Analog velocity command (SPR) Internal velocity command: 1 to 4...
Page 54 User Manual of iSV2-CAN Integrated Servo Label Mode speed of velocity setting Range -10000~10000 Unit r/min Default Index 2308h Pr3.08 Activation Immediate Label Mode speed of velocity setting Range -10000~10000 Unit r/min Default Index 2309h Pr3.09 Activation Immediate Label Mode speed of velocity setting Range -10000~10000...
Page 55: Class 4】I/O Interface Setting
User Manual of iSV2-CAN Integrated Servo Sigmoid Label acceleration/deceleration Mode settings Pr3.14 Range 0~1000 Unit Default Index 2314h Activation Axis disable To set sigmoid acceleration and deceleration turning point in accordance to Pr3.12 and Pr3.13. Velocity (RPM) Target velocity ta=Vc/1000 PA3.12 1ms td=Vc/1000 PA3.13 1ms ts=Pr3.14 1ms Please set according to...
Page 56 User Manual of iSV2-CAN Integrated Servo Label Input selection DI4 Mode Range 0x0~0xFF Unit — Default Index 0x16 2403h Pr4.03 Activation Immediate Digital input DI allocation using hexadecimal system Set value Input Symbol Normally Normally 0x60FD (bit) open close Invalid —...
Page 57 User Manual of iSV2-CAN Integrated Servo Velocity coincidence V-COIN Servo status SRV-ST Position command ON/OFF P-CMD Velocity limit signal V-LIMIT Velocity command ON/OFF V-CMD Homing done HOME-OK · Please don’t set any other than the outputs listed in the table above. ·...
Page 58 User Manual of iSV2-CAN Integrated Servo positioning delay Label Mode time Pr4.33 Range 0~15000 Unit Default Index 2433h Activation Immediate To set delay time when Pr 4.32 = 3 Set value Positioning completed signal Indefinite delay time, signal ON until next position command OFF within the time set;...
Page 59 User Manual of iSV2-CAN Integrated Servo Velocity coincidence Label Mode range Pr4.35 Range 10~2000 Unit Default Index 2435h Activation Immediate If the difference between velocity command and motor actual speed is below Pr4.35, Velocity coincidence (V-COIN) output signal valid. Due to 10RPM hysteresis: Velocity coincidence output OFF ->...
Page 60 User Manual of iSV2-CAN Integrated Servo Label Mode Motor power-off delay time Range 0~3000 Unit Default Index 2437h Pr4.37 Activation Immediate To set delay time for holding brake to be activated after motor power off to prevent axis from sliding. Delay time for holding brake Label Mode...
Page 61: Class 5】Extension Settings
User Manual of iSV2-CAN Integrated Servo Label Holding brake activation speed Mode Range 30~3000 Unit Default Index 2439h Pr4.39 Activation Immediate To set the activation speed for which holding brake will be activated. When SRV-OFF signal is given, motor decelerates, after it reaches below Pr4.39 and Pr6.14 is not yet reached, BRK_OFF is given.
Page 62 User Manual of iSV2-CAN Integrated Servo Label Servo-off mode Mode Range Unit — Default Index 2506h Pr5.06 Activation After restart To set action for deceleration and stopping of motor Value Description Disable only after velocity dropped below set value in Pr4.39 Disable immediately.
Page 63 User Manual of iSV2-CAN Integrated Servo Overload level Label Mode setting Pr5.12 Range 0~115 Unit Default Index 2512h Activation Immediate If Pr5.12 = 0, overload level = 115% Use only when overload level degradation is needed. Label Overspeed level settings Mode Range 0~10000...
Page 64 User Manual of iSV2-CAN Integrated Servo Label Torque limit selection Mode Range Unit — Default Index 2521h Pr5.21 Activation Immediate Set value Positive limit Negative limit value value Pr0.13 Pr0.13 Pr0.13 Pr5.22 60E0 60E1 Between max. torque 6072 and Pr5.21, actual torque limit will take smaller value. Label torque limit Mode...
Page 65: Class 6 】 Other Settings
User Manual of iSV2-CAN Integrated Servo 3.2.7【Class 6】Other settings trial velocity Label Mode command Pr6.04 Range 0~10000 Unit r/min Default Index 2604h Activation Immediate To set velocity for JOG trial run command. Label Position 3 gain valid time Mode Range 0~10000 Unit 0.1ms Default...
Page 66 User Manual of iSV2-CAN Integrated Servo Label Torque command additional Mode value Range -100~100 Unit Default Index 2607h Pr6.07 Activation Immediate To set torque forward feed additional value of vertical axis. Applicable for loaded vertical axis, compensate constant torque. Application: When load move along vertical axis, pick any point from the whole motion and stop the load at that particular point with motor enabled but not rotating.
Page 67 User Manual of iSV2-CAN Integrated Servo BRK_ON given time is determined by Pr6.14 or when motor speed goes below Pr4.39, whichever comes first. Applications: 1. After disabling axis, if motor speed is still higher than Pr4.39 but the time set in Pr6.14 is reached, BRK_ON given and holding brake activated.
Page 68 User Manual of iSV2-CAN Integrated Servo To set delay time for blocked rotor alarm to trigger Label Homing position (16-bit high) Mode -2147483647~ Range Unit Default Index 2658h Pr6.58 2147483647 Activation Immediate Homing position 16-bit high Homing position (16-bit Label Mode low) -2147483647~...
Page 69: Parameters Function
User Manual of iSV2-CAN Integrated Servo 3.3 402 Parameters Function Panel Display as follows:  Parameter Valid mode Description  HM: Valid in homing mode PP: Valid in profile position mode PV: Valid in profile velocity mode PT: Valid in profile torque mode F: Valid in all modes Label Error code...
Page 70 User Manual of iSV2-CAN Integrated Servo Label Status word Unit Structure Type Uint 16 Index 0x0~ 6041h Access Mapping TPDO Mode Range 0xFF Default Label Description Servo ready 1 - valid, 0 - invalid Start 1 - valid, 0 - invalid Servo running 1 - valid, 0 - invalid Fault...
Page 71 User Manual of iSV2-CAN Integrated Servo Label Shutdown option code Mode Index 605Bh Range Unit Range Default PP, PV 0 ：To stop motor through Pr5.06, 5.06 = 0(Emergency stop), 5.06=1(Free stop) 1 ：Motor decelerates and stops through 6084 0 ：To stop motor through Pr5.06, 5.06 = 0(Emergency stop), 5.06=1(Free stop) 1 ：Motor decelerates and stops through 609A Label Disable operation option code...
Page 72 User Manual of iSV2-CAN Integrated Servo Label Mode of Operation Unit Structure Type Int 8 Index 6060h Access Mapping RPDO Mode Range -2~6 Default Mode Abbr. Profile position mode Profile velocity mode profile Torque mode Homing mode Mode Operation Label Unit Structure Type...
Page 73 User Manual of iSV2-CAN Integrated Servo Position Actual Comman Label Unit Structure Type Int 32 Value d unit Index 6064h 214748364 Access Mapping TPDO Mode Range Default 8~2147483 Reflects user’s real time absolute position 6064h*Gear ratio = 6063h Velocity Demand Comman Label Unit...
Page 74 User Manual of iSV2-CAN Integrated Servo Label Torque Demand Unit 0.1% Structure Type Int 16 Index 6074h Access Mapping TPDO Mode Range 32768~3 Default 2767 Internal command torque Label Motor Rated Current Unit Structure Type Int 32 Index 0~21474 6075h Access Mapping TPDO...
Page 75 User Manual of iSV2-CAN Integrated Servo Homing position Command Label Unit Structure Type offset unit Index 607Ch 214748364 Access TPDO Mode Range Default Mapping 7~2147483 To set position offset to compensate for the deviation of mechanical origin from motor origin under homing Command Label...
Page 76 User Manual of iSV2-CAN Integrated Servo Command Label Max Profile Velocity Unit Structure Type UInt 32 unit/s Index 0~214 607Fh PP/HM/P 21474836 Access Mapping RPDO Mode Range 74836 Default To set maximum allowable velocity. Limited by 6080. Label Max Motor Speed Unit R/min Structure...
Page 77 User Manual of iSV2-CAN Integrated Servo Label Encoder Increments Unit Encoder unit Structure Type UInt 32 Index 1~2147 608Fh-01 Access TPDO Mode Range 48364 Default Mapping To set encoder resolution Label Motor Revolutions Unit Structure VAR Type Dint 32 Index Defaul 6091h-01 Access...
Page 78 User Manual of iSV2-CAN Integrated Servo homing switch Negative Homing switch Motor Z-signal Rising edge on same side of homing switch Positive Homing switch Motor Z-signal Falling edge on same side of homing switch Positive Homing switch Motor Z-signal Rising edge on same side of homing switch Positive Homing switch...
Page 79 User Manual of iSV2-CAN Integrated Servo Comman Label Max Acceleration Unit Structure Type UInt 32 Index d unit/s² 60C5h 1~21474836 1000000 Access Mapping RPDO Mode Range Default To set upper limit of acceleration. Command Label Max Deceleration Unit Structure Type UInt 32 unit/s²...
Page 80 User Manual of iSV2-CAN Integrated Servo Label Digital Inputs Unit Structure Type UINT 32 Index CSP/PP/H 214748364 60FDh Access TPDO Mode Range Default Mapping 8~2147483 The bits of 60FDh object are functionally defined as follow: Bit31 Bit30 Bit29 Bit28 Bit27 Bit26 Bit25 Bit24...
Page 81: Chapter 4 Control Mode
User Manual of iSV2-CAN Integrated Servo Chapter 4 Control Mode 4.1 Profile Position Mode 4.1.1 Pulse Pulse uses 6091H or 6092H parameters in object dictionary. Electronic gear ratio has a range of 1/1000 ~ 8000, if not Er A00 will appear. Error disappear after the parameter is set to be within the range but 402 state machine error status might still exist, please write 0x80 into control word (6040h) to deactivate the error status.
Page 82: Monitoring Settings
User Manual of iSV2-CAN Integrated Servo 607Ah Target position pulse 6081h Profile velocity pulse/s 6083h Profile acceleration pulse/s 6084h Profile deceleration pulse/s 6092h Pulse count per rev 4.1.3 Monitoring settings To monitor 6041h for motion status  To monitor 6064h for real time update of position during operation ...
Page 83: Profile Velocity Mode
User Manual of iSV2-CAN Integrated Servo 4.2 Profile Velocity Mode 4.2.1 Motion Settings Set 6060h = 3 for Profile Velocity mode.  Set target velocity to 60FFh (Unit: pulse/s)  Set profile acceleration and deceleration to 6083h and 6084h (Unit: pulse/s ...
Page 84: Profile Torque Mode
User Manual of iSV2-CAN Integrated Servo 4.3 Profile Torque Mode 4.3.1 Motion Settings Set 6060h = 4 for Profile Torque mode.  Set torque limit to 6071h (Unit: 0.1%)  Set profile torque change rate to 6087h (Unit: 0.1%/s)  Set velocity limit to 6080h (Unit: rpm) ...
Page 85: Homing Mode
User Manual of iSV2-CAN Integrated Servo Write Control word = 06h, machine status changes 40 60 00 06 00 00 00 Ready to Switch On-> Switched On Drive internal relay closes Note: Step 1 and step 2 frame ID = 0x0000, the rest = SDO address (0x0600+node no.) 4.4 Homing mode 4.4.1 Motion Settings Set 6060h = 6 for Homing mode.
Page 86: Homing Mode
User Manual of iSV2-CAN Integrated Servo 60 60 00 06 00 00 00 Write Operation Mode = 6h, homing mode 99 60 01 30 75 00 00 Write homing high velocity = 7530h (180rpm, default 10000ppr) Write homing low velocity = 4e20h (120rpm, default 10000ppr) 99 60 02 20 4e 00 00 Write homing acceleration = 7530h (Accelerates to 180rpm in...
Page 87 User Manual of iSV2-CAN Integrated Servo Low velocity Start Stop 6099h-02h Mode -4：Search for homing point in negative direction at high velocity. Move in positive direction after torque reaches the value set in Pr5.39, stops when torque is gone. Homing done signal delivers after the time value set in Pr5.37 High velocity Low velocity...
Page 88 User Manual of iSV2-CAN Integrated Servo Mode -2：Search for homing point in negative direction at low velocity. Move in positive direction after torque reaches the value set in Pr5.39, stops when torque is gone with the first Z-signal. High velocity Low velocity Start Stop...
Page 89 User Manual of iSV2-CAN Integrated Servo Mode 1: Negative limit switch = OFF Diagram A: 1. Move in negative direction at high velocity until negative limit switch valid. 2. Move in positive direction at low velocity and stops after negative limit switch and first encoder Z-signal valid Negative limit switch = ON Diagram B:...
Page 90 User Manual of iSV2-CAN Integrated Servo Mode 2: Positive limit switch = OFF Diagram A: 1. Move in positive direction at high velocity until positive limit switch valid. 2. Move in negative direction at low velocity and stops after positive limit switch and first encoder Z-signal valid Positive limit switch = ON Diagram B:...
Page 91 User Manual of iSV2-CAN Integrated Servo Mode 3: Homing switch = OFF Diagram A: 1. Move in positive direction at high velocity until homing switch valid. 2. Move in negative direction at low velocity and stops after homing switch and first encoder Z- signal valid Homing switch = ON Diagram B:...
Page 92 User Manual of iSV2-CAN Integrated Servo Mode 4: Homing switch = OFF Diagram A: 1. Move in positive direction at high velocity until homing switch valid. 2. Move in negative direction at high velocity until homing switch invalid. 3. Move in positive direction at low velocity and stops after homing switch valid and first encoder Z-signal valid Homing switch = ON Diagram B:...
Page 93 User Manual of iSV2-CAN Integrated Servo Mode 5: Homing switch = OFF Diagram A: 1. Move in negative direction at high velocity until homing switch valid. 2. Move in positive direction at low velocity and stops after homing switch and first encoder Z- signal valid Homing switch = ON Diagram B:...
Page 94 User Manual of iSV2-CAN Integrated Servo Mode 6: Homing switch = OFF Diagram A: 1. Move in negative direction at high velocity until homing switch valid. 2. Move in positive direction at high velocity until homing switch invalid. 3. Move in negative direction at low velocity and stops after homing switch valid and first encoder Z-signal valid Homing switch = ON Diagram B:...
Page 95 User Manual of iSV2-CAN Integrated Servo Mode 7 Homing switch & positive limit switch = OFF Diagram A: 1. Move in positive direction at high velocity until homing switch valid. 2. Move in negative direction at low velocity and stops after homing switch and first encoder Z- signal valid.
Page 96 User Manual of iSV2-CAN Integrated Servo Mode 8 Homing switch & positive limit switch = OFF Diagram A: 1. Move in positive direction at high velocity until homing switch valid. 2. Move in negative direction at high velocity until after homing switch. 3.
Page 97 User Manual of iSV2-CAN Integrated Servo Mode 9 Homing switch & positive limit switch = OFF Diagram A: 1. Move in positive direction at high velocity until after homing switch. 2. Move in negative direction at low velocity and stops after homing switch valid and first encoder Z-signal valid.
Page 98 User Manual of iSV2-CAN Integrated Servo Mode 10 Homing switch & positive limit switch = OFF Diagram A: 1. Move in positive direction at high velocity until after homing switch. 2. Move in negative direction at high velocity until homing switch valid. 3.
Page 99 User Manual of iSV2-CAN Integrated Servo Mode 11 Homing switch & negative limit switch = OFF Diagram A: 1. Move in negative direction at high velocity until homing switch valid. 2. Move in positive direction at low velocity and stops after homing switch and first encoder Z- signal valid Homing switch = ON, negative limit switch = OFF Diagram B:...
Page 100 User Manual of iSV2-CAN Integrated Servo Mode 12 Homing switch & negative limit switch = OFF Diagram A: 1. Move in negative direction at high velocity until homing switch valid. 2. Move in positive direction at high velocity until after homing switch. 3.
Page 101 User Manual of iSV2-CAN Integrated Servo Mode 13 Homing switch & negative limit switch = OFF Diagram A: 1. Move in negative direction at high velocity until after homing switch. 2. Move in positive direction at low velocity and stops after homing switch valid and first encoder Z-signal valid.
Page 102 User Manual of iSV2-CAN Integrated Servo Mode 14 Homing switch & negative limit switch = OFF Diagram A: 1. Move in negative direction at high velocity until after homing switch. 2. Move in positive direction at high velocity until homing switch valid. 3.
Page 103 User Manual of iSV2-CAN Integrated Servo Mode 17： This mode is similar to mode 1. Only difference is that homing point detection is not through Z- signal but through triggering of negative limit switch signal Low velocity High velocity Start Stop 6099h-02h 6099h-01h...
Page 104 User Manual of iSV2-CAN Integrated Servo Mode 19： This mode is similar to mode 3. Only difference is that homing point detection is not through Z- signal but through triggering of homing switch signal High velocity Low velocity Start Stop 6099h-01h 6099h-02h Z-signal...
Page 105 User Manual of iSV2-CAN Integrated Servo Mode 21： This mode is similar to mode 5. Only difference is that homing point detection is not through Z- signal but through triggering of homing switch signal. High Velocity Low Velocity Start Stop 6099h-01h 6099h-02h Z-Signal...
Page 106 User Manual of iSV2-CAN Integrated Servo Mode 23： This mode is similar to mode 7. Only difference is that homing point detection is not through Z- signal but through triggering of homing switch signal. High velocity Low velocity Start Stop 6099h-01h 6099h-02h Z-Signal...
Page 107 User Manual of iSV2-CAN Integrated Servo Mode 25： This mode is similar to mode 9. Only difference is that homing point detection is not through Z- signal but through triggering of homing switch signal High Velocity Low Velocity Start Stop 6099h-01h 6099h-02h Z-Signal...
Page 108 User Manual of iSV2-CAN Integrated Servo Mode 27： This mode is similar to mode 11. Only difference is that homing point detection is not through Z- signal but through triggering of homing switch signal High Velocity Low Velocity Start Stop 6099h-01h 6099h-02h Z-Signal...
Page 109 User Manual of iSV2-CAN Integrated Servo Mode 29： This mode is similar to mode 13. Only difference is that homing point detection is not through Z-signal but through triggering of homing switch signal High velocity Low velocity Start Stop 6099h-01h 6099h-02h Z-Signal HOMING SWITCH...
Page 110 User Manual of iSV2-CAN Integrated Servo Mode 33： The motor starts to move in negative direction and stops when the Z-signal is valid. If the positive/negative limit switch signal or homing switch is valid during the homing process, the status word (6041h) bit 13 will be valid, indicating homing error and the motor will stop immediately.
Page 111: Emergency Stop
User Manual of iSV2-CAN Integrated Servo 4.5 Emergency Stop 4.5.1 Motion Settings Set 6060h = 3 for Profile Velocity mode.  Set 6040h to corresponding value to machine status and start motion.  Object Dictionary Label Set Value Unit Emergency stop 6085h pulse/s deceleration...
Page 112: Chapter 5 Applications
User Manual of iSV2-CAN Integrated Servo Chapter 5 Applications 5.1 Trial Run Not released yet. Trial Run To test run servo products after successfully connected to Motion Studio and initial setup is done. Main power supply and motor/encoder cable need to be connected to use this function.
Page 113: Inertia Ratio Measuring
User Manual of iSV2-CAN Integrated Servo 5.2 Inertia Ratio measuring Inertia measuring using Motion Studio 1. Start Motion Studio and maneuver to inertia ratio identification page under performance tuning. Set trial run velocity Pr6.04 and acc-/deceleration time Pr6.25, click on ‘Upload’ to upload parameters to servo driver.
Page 114 User Manual of iSV2-CAN Integrated Servo 6. Click on “Parameter List” to enter parameters management to check or modify Pr0.04. Then, click on “Save” to save parameters to driver. Please take note: 1. Trial run velocity and distance should be optimal to prevent any axis from bumping into objects. 2.
Page 115: Notch Filter (Vibration Suppression)
User Manual of iSV2-CAN Integrated Servo 5.3 Notch Filter (Vibration Suppression) To use notch filter Automatic notch filter Set Pr2.00 = 1 for auto notch filter adjustment If Pr0.03 stiffness increases, 3 group of notch filter (Pr2.07/Pr2.08/Pr2.09) updates automatically when driver is enabled. Pr2.00 = 0, auto adjustments stop. If resonance is suppressed, it means self-adjusting notch filter is working.
Page 116 User Manual of iSV2-CAN Integrated Servo notch bandwidth Label Mode selection Pr2.02 Range 0~20 Unit Default Index 2202h Activation Immediate Set notch bandwidth for 1 resonant notch filter. Under normal circumstances, please use factory default settings. If resonance is under control, in combination with Pr2.01 and Pr2.03, Pr2.02 can be reduced to improve current loop responsiveness which allows higher mechanical stiffness settings.
Page 117: Auto Gain Adjustment
User Manual of iSV2-CAN Integrated Servo Label notch frequency Mode 50~400 Range Unit Default 4000 Index 2207h Pr2.07 Activation Immediate Set center frequency of 3 torque command notch filter. Set Pr2.07 to 4000 to deactivate notch filter notch bandwidth Label Mode selection Pr2.08...
Page 118 User Manual of iSV2-CAN Integrated Servo ・Acc-/deceleration to 2000r/min within 1s. 。・Acc-/deceleration torque lower than eccentric load, frictional torque. ・Velocity < 100r/min, acc-/deceleration to 2000r/min within 1s but not longer than 50ms To enable automatic gain adjustment: 1. Disable the servo driver. 2.
Page 119: Rd Gain Switching
User Manual of iSV2-CAN Integrated Servo Pr1.03 velocity detection filter Pr1.04 torque filter Pr1.05 position loop gain Pr1.06 velocity loop gain Pr1.07 velocity integral time constant Pr1.08 velocity detection filter Pr1.09 torque filter If auto gain adjustment is valid, the parameters listed above can’t be manually modified. Only when Pr0.02 = 0, can the gain related parameters be modified manually.
Page 120 User Manual of iSV2-CAN Integrated Servo Set up the 3 gain by multiplying factor of the 1 gain Position command velocity (RPM) Effective time Pr6.05 x 0.1ms gain gain gain Pr1.05~Pr1.09 Pr1.00~Pr1.04 Position loop gain = Pr1.00 x Pr6.06/100 Velocity loop gain = Pr1.01 x Pr6.06/100 Velocity loop integral time constant，Velocity detection filter，Torque filter time constant still uses 1 gain...
Page 121: Friction Compensation Function
User Manual of iSV2-CAN Integrated Servo 5.6 Friction compensation function This function is to compensation for changes in load to reduce the effect of friction in motion. The compensation value is directional. Velocity command Pr6.08 Pr6.07 Time Pr6.09 Velocity command Motor off Motor on Motor off...
Page 122: Regenerative Resistor Settings
User Manual of iSV2-CAN Integrated Servo Label Negative direction torque Mode compensation value Range -100~100 Unit Default Index 2609h Pr6.09 Activation Immediate To reduce the effect of mechanical friction in the movement(s) of the axis. Compensation values can be set according to needs for both rotational directions. Applications: 1.
Page 123: Safety Functions
User Manual of iSV2-CAN Integrated Servo 5.8 Safety Functions 5.8.1 Max. motor rotational speed limitation Maximum motor rotational Label Mode velocity Pr3.24 Range 0~10000 Unit r/min Default Index 2324h Activation Immediate Maximum motor rotational as accordance to technical specification if set to 0 5.8.2 Max.
Page 124: External Brake Deactivation Output Signal Brk-Off
User Manual of iSV2-CAN Integrated Servo 5.8.3 External brake deactivation output signal BRK-OFF Please refer to Pr4.11 to set up the I/O output function parameters. When enabled and timing conditions are fulfilled, the set I/O output will deliver ON signal. Label Mode Motor power-off delay time...
Page 125: Servo Stopping Mode
User Manual of iSV2-CAN Integrated Servo Holding brake activation Label Mode speed Pr4.39 Range 30~3000 Unit Default Index 2439h Activation Immediate To set the activation speed for which holding brake will be activated. When SRV-OFF signal is given, motor decelerates, after it reaches below Pr4.39 and Pr6.14 is not yet reached, BRK_OFF is given.
Page 126: Emergency Stop Function
User Manual of iSV2-CAN Integrated Servo 5.8.5 Emergency stop function Emergency stop is used when an alarm occurs or a servo prohibition signal is received when servo driver is enabled. Method 1: Set up Pr4.43 to enable the function Label Emergency stop function Mode Range...
Page 127: Multiturn Absolute Encoder
User Manual of iSV2-CAN Integrated Servo 5.9 Multiturn Absolute encoder Multiturn absolute encoder records the position and the revolution counts of the motor. When driver is powered-off, multiturn absolute encoder will backed up the data using battery and after powering on, the data will be used to calculated absolute mechanical position and there is no need for a mechanical homing process.
Page 128: Read Absolute Position
User Manual of iSV2-CAN Integrated Servo 5.9.2 Read absolute position 1、Steps： 1) First, select a motor with multiturn absolute encoder, install battery and confirm whether the driver version supports the specific motor; 2) Set Pr0.15 = 1. If it is the first time of installation, Err153 will occur because battery is newly Please home the axis and initialize the absolute position of the installed and position data is invalid.
Page 129 User Manual of iSV2-CAN Integrated Servo 2、Read absolute position When the rotor turns in clockwise direction, the revolution count will be negative; turns in counter clockwise direction, the count will be positive. No. of revolutions will be from -32767 to +32767.
Page 130: Absolute Encoder Related Alarm
User Manual of iSV2-CAN Integrated Servo 5.9.3 Absolute Encoder Related Alarm The alarm can determine if absolute value encoder is valid. If battery power is low, not a motor with absolute encoder, encoder error etc. occurs, user can find out about the error from alarm output or on the front panel.
Page 131: Chapter 6 Canopen Communication
User Manual of iSV2-CAN Integrated Servo Chapter 6 CANopen Communication 6.1 CANopen Protocol CAN(Control Area Network) defines the physical and data layer but not the application layer. It needs a higher layer protocol to defined the specific function of each CAN telegram. CANopen is a higher level protocol based on CAN with CiA (CAN-in-Automation) defines the standard protocol.
Page 132: Canopen Communication Protocol For Isv2 Series
 CANopen standard protocol DS301 V4.02  CANopen standard protocol DSP402 V2.01  CANopen services supported on iSV2-CAN series NMTslave  Device monitoring services: Heartbeart, node guarding  PDO: every slave station can be configured with max. of 4 TxPDO and 4 RxPDO ...
Page 133: Object Dictionary
User Manual of iSV2-CAN Integrated Servo TXPDO3(Transmit) 0111 0x380+Node-ID 1802H RXPDO3(Receive) 1000 0x400+Node-ID 1402H TXPDO4(Transmit) 1001 0x480+Node-ID 1803H RXPDO4(Receive) 1010 0x500+Node-ID 1403H SDO(Server 1011 0x580+Node-ID 1200H Transmission) SDO(Client 1100 0x600+Node-ID 1200H Transmission) NMT error control 1110 0x700+Node-ID 1016H~1017H Note: 1. PDO/SDO Transmit/Receive is from the perspective of CAN slave node 2.
Page 134: Object Dictionary Structure
User Manual of iSV2-CAN Integrated Servo Device profile - describes functions, label, index/sub-index and data type of an object in object dictionary. The objects have to be write only, read only or read/write. Device profile determines if the object is selectable. If required object is more than is provided in device profile, enough room is left for manufacturer to define specific function object.
Page 135: Network Management (Nmt)
User Manual of iSV2-CAN Integrated Servo 6.6 Network Management (NMT) NMT provides network managing services which realized through master/slave communication mode. 6.6.1 NMT module control Only NMT master node can transmit NMT control module telegram, all slave nodes must support NMT module control service, NMT module control doesn’t have to answer.
Page 136: Nmt Boot-Up
User Manual of iSV2-CAN Integrated Servo Heartbeart is defined as a node that can be configured as operational duty cycle. Heartbeat producer Consumer COB-ID Byte 0 0x700+Node-ID Status Status code Status Boot-up Stop Operation Pre-Op 6.6.3 NMT Boot-up NMT sends Boot-up telegram from node to NMT master to inform that it has switched from initialization status to Pre-Op status.
Page 137: Process Data Object (Pdo)
User Manual of iSV2-CAN Integrated Servo (4)(7) Enter Pre-Operation mode (5)(8) Deactivate remote node (9)(10)(11) Reset node (12)(13)(14) Reset communication (15) Automatically enter reset application mode (16) Automatically enter reset communication mode Enter Pre-Operation after device initialization (Initialization, reset application and reset communication) is done.
Page 138 User Manual of iSV2-CAN Integrated Servo Diagram shows in a more detailed description of the relationship between PDO parameters (1400h) and PDO image (1600h), PDO data transmission (Node 2 as example). Arrow represents data flow direction from master device. Sub- Sub- Index Code...
Page 139 User Manual of iSV2-CAN Integrated Servo Master device receives data from slave station Diagram shows in a more detailed description of the relationship between PDO parameters (1800h) and PDO image (1A00h), PDO data transmission (Node 2 as example). Arrow represents data flow direction from slave station.
Page 140: Service Data Object
User Manual of iSV2-CAN Integrated Servo 6.8 Service Data Object SDO is used to access object dictionary of a device. Access side is referred to as client, CANopen device which provides required services with accessed object dictionary is referred to as server. Clients’ CAN telegram and servers’...
Page 141: Emergency Object
User Manual of iSV2-CAN Integrated Servo 6.9 Emergency Object Emergency object is triggered when there is an occurrence of severe error from device internal. This will be sent to other devices with highest priority. Applicable for alarms which interrupt and stop operation. An emergency telegram is made up of 8 bytes with format as below: Transmitting end Receiving end...
Page 142: Chapter 7 Warning And Alarm
User Manual of iSV2-CAN Integrated Servo Chapter 7 Warning and Alarm 7.1 Servo drive alarm overview Green LED: Power ON/Motor enable ON for once: Power ON Always ON: Motor Enable Blinking: Motor Disable OFF: Power OFF Red LED: Alarm indicator (Motor stops when alarm indicator is ON) Blink for 5s/cycle (Please refer to the table below) OFF: Alarm cleared Error...
Page 143 User Manual of iSV2-CAN Integrated Servo Mode not supported under synchronous 5202 mode 5441 IO emergency stop 5510 RAM full 5511 RAM over boundary 5530 EEPROM parameters saving error 5531 EEPROM hardware error 5532 Error saving alarm history record Error occurred when saving vendor 5533 parameters Error occurred when saving communication...
Page 144 User Manual of iSV2-CAN Integrated Servo Encoder initial position error 7323 Multiturn encoder error / Encoder 7324 parameter settings error 7325 153/154 Encoder data overflow 7326 Encoder overheated 7327 Encoder count error Encoder disconnected 7328 Position limit alarm, position limit valid 7329 during alarm 7701...
Page 145 User Manual of iSV2-CAN Integrated Servo 821C Invalid SyncManager type 821D Invalid output configuration 821E Invalid input configuration 821F Watchdog configuration invalid 8220 PDO length over limit 8224 TPDO mapping invalid 8225 RPDO mapping invalid 8226 Configuration non-consistent 8310 Motor overloaded 8311 Driver overloaded 8305...
Page 146 User Manual of iSV2-CAN Integrated Servo 8734 DC sync timeout 8735 Distribution Clock cycle time is invalid 8736 SYNC0 cycle time invalid 8737 SYNC1 cycle time invalid 873A SyncManager2 lost 873B SYNC0 lost 873C Excessive Distributed Clock error When error occurs, drive will take protection measures and stops the motor. Error code will be shown on tuning software or master device (controller) can read corresponding error code from object dictionary.
Page 147: Alarm Handling
User Manual of iSV2-CAN Integrated Servo 3222 Main power supply disconnected 4201 Temperature base sampling error 4210 Drive over-temperature 5201 Servo unable to enable under current mode 7.2 Alarm Handling **When error occurs, please solve accordingly. Then, restart. Main Display: “Er 090”...
Page 148 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 0A5” Error code Content: DC bus circuit error Cause Diagnosis Solution Driver fault Replace driver Main Display: “Er 0A6” Error code Content: Temperature detection circuit error Cause Diagnosis Solution Driver fault Replace driver Main Display:...
Page 149 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 0E0” Error code Content: Overcurrent Cause Diagnosis Solution Verify if there is short circuit 1. Make sure there is no circuit. Driver power output 2. Make sure motor is not between UVW terminals, or short circuit damaged shorted to PG.
Page 150: Cause
User Manual of iSV2-CAN Integrated Servo Display: “Er 0F0” Main Error code Content: Driver overheated Cause Diagnosis Solution Temperature of power Measure the temperature 1. Improve cooling condition. Please module exceeded upper of driver radiator. check installation guide; limit 2. Replace driver and motor with higher power rating;...
Page 151: Replace Driver
User Manual of iSV2-CAN Integrated Servo Display: “Er 120” Main Error code Content: Regenerative resistor overvoltage Cause Diagnosis Solution Regenerative energy 1. Verify if velocity is too 1. Decrease motor rotational velocity; exceeded capacity of high 2. Decrease load inertia; regenerative resistor 2.
Page 152: Replace Driver
User Manual of iSV2-CAN Integrated Servo Display: “Er 151” Main Error code Content: Encoder communication error Cause Diagnosis Solution Encoder wire shielding Verify if encoder cable has Replace with standard encoder layer is missing shielding layer cable Encoder cable wiring Verify if encoder wiring is correct Reconnect encoder wiring error...
Page 153 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 154” Error code Content: Encoder parameter settings error Cause Diagnosis Solution Absolute encoder mode Verify if encoder has multi-turn Modify absolute encoder mode is incorrectly set. absolute value function. settings Main Display: “Er 155”...
Page 154 User Manual of iSV2-CAN Integrated Servo Display: “Er 171” Main Error code Content: Encoder parameter initialization error Cause Diagnosis Solution Driver and motor Replace with matching driver and Verify driver and motor models. not matched motor 1. Verify if encoder cable is standard. Use standard encoder cable, verify Error while getting 2.
Page 155 User Manual of iSV2-CAN Integrated Servo Display: “Er 1A0” Main Error code Content: Overspeed Cause Diagnosis Solution 1. Verify if velocity command is too high; 1. Adjust velocity input 2. Verify if simulated velocity command command; 2. Increase Pr3.21 Motor velocity voltage is too high;...
Page 156 User Manual of iSV2-CAN Integrated Servo Display: “Er 1c1” Main Error code Content: 1 STO failed Cause Diagnosis Solution Verify if STO power supply Verify 24V STO power supply and power is normal cable connection STO input signal valid Disconnect switch Close switch connected to STO Display:...
Page 157 User Manual of iSV2-CAN Integrated Servo Display: “Er 241” Main Error code Content: EEPROM hardware error Cause Diagnosis Solution Verify if multiple storages are Replace driver/Upgrade software EEPROM damaged the same Display: “Er 242” Main Error code Content: Error saving alarm history record Cause Diagnosis Solution...
Page 158 User Manual of iSV2-CAN Integrated Servo Display: “Er 260” Main Error Error description: Positive/Negative position limit triggered under code non-homing mode Cause Diagnosis Solution Positive/negative Verify position limit signal position limit triggered Display: “Er 280” Main Error code Error description: Output pulse frequency too high Cause Diagnosis Solution...
Page 159: Canopen Communication Alarm
User Manual of iSV2-CAN Integrated Servo Main Display: “Er 601” Error code Error description: Velocity loop interrupted timeout Cause Diagnosis Solution Verify if encoder connection is Replace encoder cable if necessary and that the encoder cable is Motor control loop too not long (more than 20 calculation time overflow...
Page 160 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 73b” Error code Error description: SYNC0 lost Cause Diagnosis Solution Poor master Increase threshold value performance limit Single-unit drive has Is it a single unit or multiple units together Switch drive problem in the network Check the grounding and network wiring...
Page 161 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 803” Error code Error description: RAM out of bound Cause CANopen state machine memory address access request from master device is out of bound The status of the All communication status error can be detected The result status Solution...
Page 162 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 813” Error code Error description: Protection request from boot state Cause Driver receives a transition request to boot state The status of the Initialize the conversion to a boot error can be detected The result status initialization Solution...
Page 163 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 818” Error code Error description: No valid input data Cause The input data is not updated for more than 1 second The status of the All ESM status error can be detected The current state is maintained below the safe operation, and the The result status operation state is switched to the safe operation state...
Page 164 User Manual of iSV2-CAN Integrated Servo Main Display: “Er 81c” Error code Error description: Invalid SyncManager type Synchronization Manager configuration types other than the following: Cause 1. Email output 2. Email input 3. Process data output 4. Process data input The status of the Pre-operation error can be detected...
Page 165 User Manual of iSV2-CAN Integrated Servo Display: “Er 822” Main Error code Error description: Waiting for the CANopen state machine Pre-Op state Cause Driver waiting for master device to send Pre-Op request The status of the Safe operation, operation error can be detected The result status Keeping the current state Solution...
Page 166 User Manual of iSV2-CAN Integrated Servo Main Error Display: “Er 82b” code Error description: Invalid inputs and outputs Cause No RxPDO and TxPDO updates for more than 1 second The status of the All ESM status error can be detected The current state is maintained below the safe operation, and the The result status operation state is switched to the safe operation state...
Page 167 User Manual of iSV2-CAN Integrated Servo Main Error Display: “Er 832” code Error description: Distribution Clock phase-locked loop failure Cause Distribution Clock phase-locked loop setting is invalid The status of the Safe operation, operation error can be detected The result status Safe operation Verify master device Distribution Clock settings and network Solution...
Page 168 User Manual of iSV2-CAN Integrated Servo Main Error Display: “Er 851” code Error description: EEPROM error Cause EEPROM operation of CANopen slave controller failed The status of the All ESM status error can be detected The result status Keeping the current state Solution Verify if master device released access Display:...
Page 169: Alarm Clearing
User Manual of iSV2-CAN Integrated Servo 7.4 Alarm clearing 7.4.1 Servo Drive Alarm Clearing Clearable Alarm Please clear alarm using Motion Studio after solving the error by clicking on the “Clear” button. Non-clearable Alarm Please restart drive to clear alarm...
Page 170: Appendixa
User Manual of iSV2-CAN Integrated Servo Appendix A Control word 6040H switching under different modes PP mode (6060h=1) 6040h 15:9 Absolute/ Error Operation Quick Output Enable Definition Null Stop Relative Immediate Reset allowed stop voltage Position point Control word 6040h under relative position: 0x06 0x07 0x0F...
Page 171 User Manual of iSV2-CAN Integrated Servo PV mode (6060h=3) 6040h 15:9 Error Operation Quick Output Definition Null Stop Null Enable Reset allowed stop voltage Control word 6040h under PV mode: 0x06 0x07 0x0F 0x10F 0x00F Execute Output voltage + Enable Operation Stop Quick stop...
Page 172: Appendixb
User Manual of iSV2-CAN Integrated Servo Appendix B PDO transmission type definition PDO transmission Transmission Non- Not- Remote code Cyclic Sync cyclic sync frame √ √ 1~240 √ √ 241~251 Reserved √ √ √ √ √ √ Transmission code 1~240: Number of SYNC info between 2 PDO transmissions. Transmission code 252: Data immediately updates after receiving SYNC info Transmission code 253: Data immediately updates after receiving RTR info Transmission code 254: Not supported...
Page 173: Appendixd
User Manual of iSV2-CAN Integrated Servo Appendix D SDO transmission termination code Termination Description code 0503 0000H No alternating changes on trigger point 0504 0000H SDO protocol timeout 0504 0001H Illegal/unknown command word 0504 0002H Invalid module size 0504 0003H Invalid sequence no.
Page 174: Appendixe
User Manual of iSV2-CAN Integrated Servo Appendix E Drive Function Object Object dictionary Description index 3000H IO signal status 3001H Status change 3002H Write EEPROM trigger 3003H Write EEPROM Status 3004H Output channel settings 3010H Servo alarm code 4000H Clear alarm Note 1: In PP mode: Send enable command (i.e.
Page 175: Contact Us
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Chapter 1 Introduction

Chapter 2 Installation & Wiring

Chapter 3 Parameter

Chapter 4 Control Mode

Chapter 5 Applications

Chapter 6 Canopen Communication

Chapter 7 Warning and Alarm

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