Allen Bradley Kinetix 5700 Servo Drive

Allen Bradley Kinetix 5700 Servo Drive Fault Codes:

Fault Code and Meaning	Cause and Remedy
FLT S02 – MTR COMMUTATION Motor Commutation Fault	Cause: An illegal state transition of the motor hall-commutation feedback signals has been detected. Remedy: Verify the motor hall feedback wiring is not open/shorted/missing. Use shielded cables, route feedback away from potential noise sources. Check system grounds. Replace the motor.
FLT S03 – MTR OVERSPEED FL – 0 Motor Overspeed Factory Limit Fault	Cause: Motor speed has exceeded 125% of its maximum speed. Remedy: Check control loop tuning.
FLT S03 – MTR OVERSPEED FL – 1 Motor Overspeed Factory Limit Fault	Cause: The output frequency has exceeded 590 Hz. Remedy: Check control loop tuning. Reduce the velocity command.
FLT S04 – MTR OVERSPEED UL Motor Overspeed User Limit Fault	Cause: Motor speed has exceeded motor overspeed user limit. Remedy: Check control loop tuning. Increase the Motor Overspeed UL attribute value.
FLT S05 – MTR OVERTEMP FL nn Motor Overtemperature Factory Limit Fault	Cause: Calculations based on the motor thermistor indicate that the motor factory temperature limit has been exceeded. Sub-code (nn): 01: Motor Thermostat or Thermistor 02: Encoder Temperature Sensor Remedy: Operate motor within continuous torque rating. Reduce motor ambient temperature. Add motor cooling. (Available only on Kinetix VP and MP-Series™ motors. Not supported on induction motors).
FLT S07 – MTR OVERLOAD FL Motor Thermal Overload Factory Limit Fault	Cause: The motor thermal model has exceeded its factory set thermal capacity limit. Remedy: Modify the command profile to reduce speed or increase time.
FLT S08 – MTR OVERLOAD UL Motor Thermal Overload User Limit Fault	Cause: The motor thermal model has exceeded the thermal capacity limit given by Motor Thermal Overload User Limit. Remedy: Modify the command profile. Increase the Motor Thermal Overload UL attribute value.
FLT S09 – MTR PHASE LOSS Motor Phase Loss	Cause: Torque Prove function detected motor current below a limit set by Torque Prove Current Limit. Remedy: Check motor connections.
FLT S10 – INV OVERCURRENT Inverter Overcurrent Fault	Cause: Inverter current has exceeded the instantaneous current limit (determined by hardware). Remedy: Check motor power cable for shorts. Verify motor windings are not shorted. Verify motor power wire gauge. Operate within the continuous power rating. Reduce acceleration times. Verify iTRAK power supply cable wiring.
FLT S11 – INV OVERTEMP FL Inverter Overtemperature Factory Limit Fault	Cause: The measured inverter temperature has exceeded the factory set temperature limit. Remedy: Modify the command profile to reduce speed or increase time. Reduce drive ambient temperature. Verify airflow through drive is not obstructed.
FLT S13 – INV OVERLOAD FL Inverter Thermal Overload Factory Limit Fault	Cause: The thermal capacity of the inverter has exceeded the factory set limit. Remedy: Modify the command profile to reduce speed or increase time.
FLT S14 – INV OVERLOAD UL Inverter Thermal Overload User Limit Fault	Cause: The thermal capacity of the inverter has exceeded the user set limit given by the inverter Thermal Overload User Limit. Remedy: Modify the command profile to reduce speed or increase time. Increase the Inverter Thermal Overload UL attribute value.
FLT S15 – CONV OVERCURRENT Converter Overcurrent Fault	Cause: The measured converter current has exceeded the factory set current limit. Remedy: Reduce the number of drives in the same bus group. Reduce number of capacitor modules. Verify iTRAK power supply requirements.
FLT S16 – GROUND CURRENT Ground Current Factory Limit Fault	Cause: The sensing circuitry in the power stage has detected excessive ground current. Remedy: Check motor power wiring; check power cable for shorts. Replace motor if the fault persists. Check DC bus wiring if using a capacitor module.
FLT S18 – CONV OVERTEMP FL Converter OverTemp Factory Limit Fault	Cause: The measured converter temperature has exceeded the factory set temperature limit. Remedy: Reduce the number of drives in the same bus group. Modify the command profile of inverters in the same bus group to reduce speed or increase time. Reduce drive ambient temperature. Verify airflow through drive is not obstructed. Verify iTRAK power supply requirements.
FLT S20 – CONV OVERLOAD FL Converter Thermal Overload Factory Limit Fault	Cause: The converter thermal model indicates that the temperature has exceeded the factory set capacity rating of 110%. Remedy: Reduce the number of drives in the same bus group. Reduce duty-cycle of commanded motion. Verify iTRAK power supply requirements.
FLT S21 – CONV OVERLOAD UL Converter Thermal Overload User Limit Fault	Cause: The converter thermal model indicates that the temperature has exceeded the limit given by the Converter Thermal Overload User Limit. Remedy: Reduce the number of drives in the same bus group. Reduce duty-cycle of commanded motion. Increase the Converter Thermal Overload UL attribute value. Verify iTRAK power supply requirements.
FLT S22 – AC POWER LOSS AC Power Loss Fault	Cause: All three AC input phases are detected as absent when any one of the inverters connected to a converter is in the enabled state. Remedy: Check AC input voltage on all phases.
FLT S23 – AC PHASE LOSS AC Single Phase Loss Fault	Cause: A single AC input phase was lost. Remedy: Check AC input voltage on all phases.
FLT S25 – CONV PRECHARGE FAILURE Precharge Failure Fault	Cause: The pre-charge circuit monitoring algorithm detected that the DC bus did not reach a factory set voltage level after charging for a period of time. Remedy: Check AC input voltage on all phases. Check input power wiring. Replace power supply or drive module if fault persists. Verify iTRAK power supply cable wiring.
FLT S27 – BUS REG OVERTEMP FL Bus Regulator Overtemperature Factory Limit Fault	Cause: The digital input assigned to the shunt thermal switch OK is asserted LOW. Remedy: Check the digital input wiring. Check the digital input assignments. Check the shunt power configuration in Logix Designer. Reduce regenerative energy dissipation of the application. Add a larger external shunt resistor or active brake module.
FLT S29 – BUS REG OVERLOAD FL Bus Regulator Thermal Overload Factory Limit Fault	Cause: The shunt thermal model has exceeded its factory set thermal capacity limit. Remedy: Modify the duty cycle of the application. Add external shunt for additional capacity. Add capacitor module.
FLT S30 – BUS REG OVERLOAD UL Bus Regulator Thermal Overload User Limit Fault	Cause: The shunt thermal model has exceeded the thermal capacity limit given by Bus Regulator Thermal Overload User Limit. Remedy: Modify the duty cycle of the application. Add external shunt for additional capacity. Increase the Bus Regulator Thermal Overload UL attribute value. Add capacitor module.
FLT S31 – BUS REG FAILURE Bus Regulator Failure	Cause: The shunt circuit has detected that the shunt resistor is shorted. Remedy: Check for shorts in the shunt connector. Unplug the shunt connector and measure the resistance of the shunt. Replace power supply if shunt resistor is shorted.
FLT S32 – BUS CAPACITOR MODULE FAILURE Bus Capacitor Module Failure	Cause: The digital input assigned to capacitor module OK is asserted LOW. Remedy: Check the digital input wiring. Check the digital input assignments. Replace the capacitor module, if necessary.
FLT S33 – BUS UNDERVOLT FL Bus Undervoltage Factory Limit Fault	Cause: DC Bus voltage level is below the factory set limit. Remedy: Verify voltage level of the incoming AC. Monitor AC power source for glitches or line droop. Install UPS on AC input.
FLT S34 – BUS UNDERVOLT UL Bus Undervoltage User Limit Fault	Cause: DC Bus voltage level is below the user set limit as given by Bus Undervoltage User Limit. For iTRAK power supply, this refers to the output (IDC) power busses. Remedy: Verify voltage level of the incoming AC. Monitor AC power source for glitches or line droop. Install UPS on AC input. Increase Bus Undervoltage UL attribute value. Verify iTRAK power supply cable wiring.
FLT S35 – BUS OVERVOLT FL Bus Overvoltage Factory Limit Fault	Cause: DC Bus voltage level is above the factory set limit. For iTRAK power supply, this refers to the input or output iTRAK power busses. Remedy: Change the deceleration or motion profile of some or all of the drives connected to the DC bus. Unplug the shunt connector and measure the resistance of the shunt. Add an external shunt resistor or an active brake module. Replace DC-bus power supply if shunt resistor is open. Verify iTRAK power supply cable wiring.
FLT S37 – BUS POWER LOSS Bus Power Loss Fault	Cause: The DC-bus voltage level is below the bus power loss threshold for more than 50 ms. Remedy: Verify voltage level of the incoming AC. Increase the Power Loss Threshold Attribute. Monitor AC power source for glitches or line droop. Install UPS on AC input.
FLT S38 – FUSE BLOWN nn Bus Power Fuse Blown Fault	Cause: The internal DC-bus power fuse is blown. Sub-code (nn): 00: Non user-replaceable fuse 01: User replaceable fuse (iTRAK power supply only) Remedy: 00: Return drive for repair if fault continues; Verify output power wiring (iTRAK). 01: Verify output power wiring; Replace fuse.
FLT S40 – BUS POWER SHARING FAULT Bus Power Sharing Fault	Cause: A power supply or RPS sharing DC-bus power with this module (power supply or drive) has requested that this module stop consuming power from the DC-bus. Remedy: Check the fault condition on the DC-bus power supply. Install UPS on AC input.
FLT S41 – MTR AQB STATE FL Feedback Signal Noise FL	Cause: The number of illegal state transitions of the motor AQB encoder feedback signals has exceeded a factory limit. Remedy: Verify the motor feedback wiring is not open/shorted/missing. Use shielded cables, route feedback away from potential noise sources. Check system grounds, replace motor/encoder.
FLT S43 – FDBK LOSS FL Feedback Signal Loss FL	Cause: The detected voltage levels of the A/B channel signals from the feedback device are below the Feedback Signal Loss factory limit. Remedy: Verify the motor feedback wiring is not open/shorted/missing. Use shielded cables, route feedback away from potential noise sources. Check system grounds, replace motor/encoder.
FLT S44 – FDBK LOSS UL Feedback Signal Loss UL	Cause: The associated fault/alarm sub-code indicates which of the supported feedback channels is reporting this fault/alarm. Remedy: Verify the motor feedback wiring is not open/shorted/missing. Use shielded cables, route feedback away from potential noise sources. Check system grounds, replace motor/encoder.
FLT S45 – FDBK COMM FL Motor Feedback Data Loss Factory Limit Fault	Cause: The number of consecutive missed or corrupted serial data packets, or invalid position feedback values from the intelligent feedback device has exceeded a factory set limit. Remedy: Check motor feedback cable and connector. Check motor power cable and feedback wire shields are secured correctly. Check motor frame is grounded correctly.
FLT S46 – FDBK COMM UL Motor Feedback Data Loss User Limit Fault	Cause: The number of consecutive missed or corrupted serial data packets from the intelligent feedback device has exceeded a user set limit. Remedy: Consult Possible Solutions for FLT S47.
FLT S47 – FDBK DEVICE FAILURE nn Motor Feedback Device Failure Fault (DSL or Hiperface feedback)	Cause: The feedback device has detected an internal error (DSL or Hiperface). (Refer to manual for specific nn sub-code definitions including Acceleration Overflow, Tracking Filter Error, Counter Error, Sync Error, etc.) Remedy: Check motor feedback cable for proper connectivity and continuity. Check motor phasing (U, V, W) and feedback wire connections at the drive. Review Electrical Noise Reduction (see bonding painted panels and wire-braid bonding). Cycle control power. Check feedback shield connection. Reduce shock and vibration to motor. Replace motor if fault continues.
FLT S49 – BRAKE SLIP FLT Brake Slip Exception	Cause: Motor displacement exceeded the brake slip tolerance while the mechanical brake was engaged. Remedy: Check motor brake.
FLT S50 – POS HW OTRAVEL Hardware Overtravel – Positive	Cause: The axis has moved beyond the digital input travel limit in the positive direction. Remedy: Check digital input and axis position.
FLT S51 – NEG HW OTRAVEL Hardware Overtravel – Negative	Cause: The axis has moved beyond the digital input travel limit in the negative direction. Remedy: Check digital input and axis position.
FLT S54 – POSN ERROR Excessive Position Error Fault	Cause: The position error of the position control loop has exceeded the value given by Position Error Tolerance for a time period given by Position Error Tolerance Time. Remedy: Check position loop tuning. Increase the feedforward gain. Verify sizing of the drive and motor. Check motor power wiring. Increase Position Error Tolerance and/or Position Error Tolerance Time attribute values.
FLT S55 – VEL ERROR Excessive Velocity Error Fault	Cause: The velocity error of the velocity control loop has exceeded the value given by Velocity Error Tolerance for a time period given by Velocity Error Tolerance Time. Remedy: Check velocity loop tuning Reduce acceleration Verify sizing of the drive and motor Check motor power wiring Increase Velocity Error Tolerance and/or Velocity Error Tolerance Time attribute values
FLT S56 – OVERTORQUE LIMIT Overtorque Limit Fault	Cause: Motor torque has risen above user defined maximum torque level given by Overtorque Limit for a time period given by Overtorque Limit Time. Remedy: Verify Torque Trim value Verify motion profile Verify sizing of the drive and motor Increase Overtorque Limit and/or Overtorque Limit Time attribute values
FLT S57 – UNDERTORQUE LIMIT Undertorque Limit Fault	Cause: Motor torque has dropped below user defined minimum torque level given by Undertorque Limit for a time period given by Undertorque Limit Time. Remedy: Verify motion profile Verify sizing of the drive and motor Decrease Undertorque Limit and/or Undertorque Limit Time attribute values
FLT S61 – ENABLE INPUT Enable Input Deactivated	Cause: The hardware enable input was deactivated while the drive was enabled. Remedy: Check drive enable input wiring Un-assign Enable as a digital input source
FLT M02 – MOTOR VOLTAGE Motor Voltage Mismatch Fault	Cause: The configured voltage of the drive is greater than the motor rated voltage. For example, a 400V-class drive with a 200V-class motor. Remedy: Set the drive voltage to a lower value or replace motor with voltage rating that matches the drive.
FLT M07 – FEEDBACK INCREMENTAL COUNT ERROR FAULT Feedback Incremental Count Error	Cause: The periodic check of the incremental encoder position against the absolute encoder position or Hall edges (when available) indicates they are out of tolerance. Remedy: Verify the motor feedback wiring is correct and not open/shorted/missing, use shielded cables, route feedback away from potential noise sources, check system grounds, replace motor/encoder.
FLT M12 – POWER CYCLE FL Converter Precharge Overload Factory Limit Fault	Cause: The thermal model for the precharge resistor detected that precharge capacity exceeded the factory limit. Remedy: Reduce the amount of modules in the same bus group Reduce the frequency of AC power cycling Remove capacitor modules
FLT M26 – RUNTIME ERROR Runtime Error	Cause: The drive firmware encountered an unrecoverable runtime error. Remedy: Cycle control power Reset the drive Return drive for repair if fault continues
FLT M28 – SAFETY COMM Safety Module Communication Error	Cause: Communication with the safety hardware within the drive has failed. Remedy: Cycle control power Reset the drive Return drive for repair if fault continues
INIT FLT M01 – ENCODER DATA Smart Encoder Data Corruption	Cause: The data stored in the encoder has a checksum error. Remedy: Cycle control power Return motor for repair if fault continues
INIT FLT M02 – MTR DATA RANGE nn Motor Data Range Error	Cause: A motor data attribute stored in the encoder is out of range (See sub-codes 01-16 in manual). Remedy: Cycle control power Return motor for repair if fault continues
INIT FLT M03 – MTR ENC STARTUP Motor Feedback Communication Startup	Cause: Communication with the encoder could not be established. Remedy: Cycle control power Check motor feedback connector Check motor power and feedback shield terminations on the drive Return motor for repair if fault continues
INIT FLT M06 – MOTOR ABSOLUTE STARTUP SPEED Feedback Absolute Startup Speed	Cause: The absolute encoder was not able to accurately determine the position after powerup due to speed greater than 100 rpm. Remedy: Make sure the motor shaft is not moving during power-up.
INIT FLT M14 – SAFETY FIRMWARE Invalid Safety Firmware	Cause: The loaded Safety firmware is not compatible with the drive firmware. Remedy: Cycle control power Update the drive firmware Return drive for repair if fault continues
INIT FLT M20 – UNKNOWN MODULE Unknown Module Fault	Cause: The product code of the power board is invalid. Remedy: Cycle control power Reset the drive Return drive for repair if fault continues
INIT FLT M21 – FACTORY CONFIG Factory Configuration Error	Cause: Factory configuration data is missing or invalid. Remedy: Cycle control power Reset the drive Return drive for repair if fault continues
INHIBIT S01 – ENABLE INPUT Axis Enable Input Fault – Start Inhibit	Cause: When Enable Input Checking is enabled, the drive displays Axis Enable Input start inhibit when it detects the enable input is inactive and while the axis is in Starting/Running/Testing/Hold sub-state of Stopped state. Remedy: Confirm that the digital input assigned to the Enable is active Check module enable input wiring Check digital input assignments Verify Gateway computer and Logix Designer application operation (applies to iTRAK power supply)
INHIBIT S02 – MOTOR NOT CONFIG Motor Not Configured	Cause: The associated motor has not been properly configured for use. Remedy: Verify motor configuration in the Logix Designer application.
INHIBIT S03 – FEEDBACK NOT CONFIGURED Feedback Not Configured	Cause: The feedback has not been properly configured for use. Remedy: Verify feedback configuration in the Logix Designer application.
INHIBIT S04 – COMMUTATION NOT CONFIGURED Commutation Not Configured – Standard Start Inhibit	Cause: Associated permanent magnet motor commutation has not been configured for use. Remedy: Verify that the proper motor feedback commutation alignment has been selected.
INHIBIT M02 – MOTOR FEEDBACK REQURIED Motor Feedback Required	Cause: Selected Motor Control mode cannot run without a valid feedback selection. Remedy: Verify that the proper motor feedback type has been selected.
INHIBIT M04 – PROVING CONFIG Torque Prove Configuration – Mfg Specific Start Inhibit	Cause: When Torque Proving configuration is enabled, control mode, feedback mode, motor feedback type, and motor option configuration must be set properly. Remedy: Verify that the proper axis configuration has been selected. Verify that sufficient torque prove current has been configured.
INHIBIT M05 – SAFE TORQUE OFF Start Inhibit – Safe Torque Off	Cause: The safety function has disabled the power structure. Remedy: Check safety input wiring Check state of safety devices
NODE FLT 01 – LATE CTRL UPDATE Control Connection Update Fault	Cause: Several consecutive updates from the controller have been lost. Remedy: Remove unnecessary network devices from the motion network Change network topology so that fewer devices share common paths Use high performance network equipment Use shielded cables Separate signal wiring from power wiring
NODE FLT 02 – PROC WATCHDOG nn Processor Watchdog Fault	Cause: The processor on the power board or control board failed to update in a certain amount of time. Remedy: Cycle control power Update the drive firmware Return drive for repair if fault continues
NODE FLT 03 – HARDWARE 00 Hardware Fault -PwrIF	Cause: Communication with the power board could not be established. Remedy: Cycle control power Update the drive firmware Return drive for repair if fault continues
NODE FLT 03 – HARDWARE 02 Hardware Fault – DSL	Cause: Communication with the encoder could not be established. Remedy: DSL feedback wiring is incorrect (check against wiring diagram) DSL feedback wiring is shorted or open DSL feedback cable is defective Kinetix VP motor feedback device is defective Cycle power Return drive for repair if fault continues
NODE FLT 03 – HARDWARE 03 DSL Internal Hardware Fault	Cause: A DSL hardware error internal to the drive was detected. Remedy: Check DSL feedback device, wiring, and cable Cycle power Return drive for repair if fault continues
NODE FLT 03 – HARDWARE 04 Hardware Fault – Board Compatibility	Cause: The control and power boards are incompatible. Remedy: Return drive for repair if fault continues.
NODE FLT 05 – CLOCK SKEW FLT Clock Skew Fault	Cause: The controller time and the drive’s system time are not the same. Remedy: Cycle control power Check controller and Ethernet switch operation
NODE FLT 06 – LOST CTRL CONN Lost Controller Connection Fault	Cause: Communication with the controller has been lost. Remedy: Check Ethernet connection Check controller and Ethernet switch operation
NODE FLT 07 – CLOCK SYNC Clock Sync Fault	Cause: Drive’s local clock has lost synchronization with controller’s clock and was not able to resynchronize within allotted time. Remedy: Check Ethernet connection Check controller and Ethernet switch operation
NODE FLT 09 – DUPLICATE IP ADDRESS Duplicate IP Address Fault	Cause: Several consecutive updates from the controller have been lost (or IP conflict detected). Remedy: Select an IP address not already in use on the network.
NODE ALARM 01 – LATE CTRL UPDATE Control Connection Update Alarm	Cause: Updates from the controller have been late. Remedy: Remove unnecessary network devices from the motion network Change network topology so that fewer devices share common paths Use high performance network equipment Use shielded cables Separate signal wiring from power wiring
NODE ALARM 03 – CLOCK JITTER Clock Jitter Alarm	Cause: The sync variance has exceeded the sync threshold while the device is running in sync mode. Remedy: Route the network cable away from potential noise sources Reduce the number of devices on the EtherNet/IP network
NODE ALARM 04 – CLOCK SKEW ALARM Clock Skew Alarm	Cause: The controller time and the drive’s time are not the same. Remedy: Check the Ethernet connection Check controller and Ethernet switch operation
NODE ALARM 05 – CLOCK SYNC ALARM Clock Sync Alarm	Cause: Drive’s local clock has lost synchronization with controller’s clock for a short time during synchronous operation. Remedy: Check the Ethernet connection Check controller and Ethernet switch operation