JP5023833B2 - Electric power steering apparatus and abnormality detection method - Google Patents

Description

  The present invention relates to an electric power steering apparatus and an abnormality detection method.

  Conventionally, many electric power steering devices (EPS) supply drive power to a motor that is a drive source, such as disconnection of a power supply line, occurrence of an overcurrent due to a contact failure of a drive circuit, or failure of a torque sensor or a current sensor. When an abnormality of the control system occurs, abnormality detection means for detecting the occurrence of the abnormality is provided. And when generation | occurrence | production of the said abnormality is detected, the structure which stops motor control rapidly and aims at fail safe is common (for example, refer patent document 1).

  However, when the motor control is stopped as described above, the steering characteristic changes greatly. Further, since a large steering force is required for the steering operation, there is a problem that the burden on the driver increases.

In consideration of this point, for example, in the EPS described in Patent Document 2, the detected abnormality is an energization failure for only one of the three-phase (U, V, W) motor coils. The motor control is continued with the two phases other than the current-carrying failure occurrence phase as current-carrying phases. As a result, the application of assist force to the steering system is continued to avoid an increase in the driver's burden associated with fail-safe control.
JP 2000-177610 A JP 200326020 A

  By the way, there is a failure mode in which the provisional assist force can be continued, that is, so-called life extension control can be executed in addition to the above-described failure of energization. For example, when a failure occurs in any of the current sensors, if the failed sensor can be identified, the application of the assist force can be continued without causing a decrease in stability or steering feeling. it can. However, on the other hand, it is actually difficult to add a new configuration for abnormality detection or to strengthen arithmetic processing from the viewpoint of manufacturing cost reduction, and it is simple to realize advanced life extension control. Therefore, there is a need for an abnormality detection method that can detect an abnormality of the current sensor with higher accuracy and more accurately.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide an electric power steering apparatus and an abnormality detection method capable of accurately detecting an abnormality of a current sensor with a simpler configuration. It is to provide.

In order to solve the above-described problems, the invention according to claim 1 is directed to a steering force assisting device that applies an assisting force for assisting a steering operation to a steering system using a motor as a driving source, and a driving power for the motor. Control means for controlling the operation of the steering force assisting device through supply, and the control means outputs motor control signal output means for outputting a motor control signal and three-phase drive power based on the motor control signal. A drive circuit for outputting, and an abnormality detection means capable of detecting an abnormality of the control system relating to the supply of the drive power, wherein the drive circuit is formed by connecting a pair of switching elements connected in series in parallel. When each of the switching elements is turned on / off based on the signal, the energization pattern for the motor is switched, and each of the switches connected in parallel is switched. The low potential side of the quenching element pair, a current sensor for detecting a current value of each phase corresponding to respective switching element pairs are provided, the switching element is low the drain is disposed on a high potential side An electric power steering device which is an N-channel FET having a source arranged on the potential side, and wherein the motor control signal output means generates the motor control signal based on each phase current value detected by each current sensor When the occurrence of a failure in any of the current sensors is detected, the abnormality detecting means turns on the high-potential side switching element and turns off the low-potential side switching element. Each phase current value is acquired at the timing of, and the current sensor is compared for each phase by comparing the acquired phase current value with a predetermined threshold value. The failure to identify the phase generated, and the gist.

That is, the phase current value detected by the current sensor provided on the low potential side of each switching element pair constituting the drive circuit is obtained when the high potential side switching element is turned on and the low potential side switching element As long as it is off, it should basically be “0”. Therefore, when the occurrence of a failure in any of the current sensors is detected, the high potential side switching element is turned on and the low potential side switching element is turned off for each phase as in the above configuration. By comparing the acquired phase current value with the threshold value, it is possible to identify the current sensor failure occurrence phase easily and accurately with an extremely simple configuration without causing the addition of a new configuration. . As a result, more advanced life extension control can be executed, and the application of the assist force can be continued without deteriorating stability and steering feeling.

The gist of the invention described in claim 2 is that the abnormality detecting means identifies a phase in which a failure of the current sensor has occurred when occurrence of an overcurrent is not detected .

請 Motomeko invention described in 3, a drive circuit energizing pattern based on the on / off of it respective switching elements a pair of switching elements connected in series and parallel connection is switched, each said parallel connected A current sensor provided on the low potential side of the pair of switching elements; and a control signal output means for outputting a control signal for turning on / off each of the switching elements based on a current value detected by each of the current sensors. An abnormality detection method for a control system provided, wherein the switching element is an N-channel FET in which a drain is disposed on a high potential side and a source is disposed on a low potential side. If the occurrence of the failure has been detected in pressure, the low-potential side switching element o the switching elements of the high potential side is turned on Each phase current value is acquired at the timing of, and for each phase, the phase current value acquired is compared with a predetermined threshold value to identify the phase in which the current sensor has failed. The gist.

According to the above configuration, the current sensor failure occurrence phase can be identified easily and with high accuracy with an extremely simple configuration without causing the addition of a new configuration.
The gist of the invention described in claim 4 is to identify the phase in which the failure of the current sensor has occurred when the occurrence of overcurrent is not detected .

  ADVANTAGE OF THE INVENTION According to this invention, the electric power steering apparatus and abnormality detection method which can detect abnormality of a current sensor accurately with a simpler structure can be provided.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment of the invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram of the EPS 1 of the present embodiment. As shown in the figure, a steering shaft 3 to which a steering wheel (steering) 2 is fixed is connected to a rack 5 via a rack and pinion mechanism 4. It is converted into a reciprocating linear motion of the rack 5 by the and pinion mechanism 4. The rudder angle of the steered wheels 6 is changed by the reciprocating linear motion of the rack 5.

  Further, the EPS 1 includes an EPS actuator 10 as a steering force assisting device that applies an assist force for assisting a steering operation to the steering system, and an ECU 11 as a control unit that controls the operation of the EPS actuator 10. .

  The EPS actuator 10 of the present embodiment is a so-called rack-type EPS actuator in which a motor 12 that is a driving source thereof is arranged coaxially with the rack 5, and an assist torque generated by the motor 12 is a ball screw mechanism (not shown). Is transmitted to the rack 5 via. In addition, the motor 12 of this embodiment is a brushless motor, and rotates by receiving supply of three-phase (U, V, W) driving power from the ECU 11. And ECU11 as a motor control apparatus controls the assist force given to a steering system by controlling the assist torque which this motor 12 generate | occur | produces (power assist control).

  In the present embodiment, a torque sensor 14 and a vehicle speed sensor 15 are connected to the ECU 11. Then, the ECU 11 executes the operation of the EPS actuator 10, that is, power assist control, based on the steering torque τ and the vehicle speed V detected by the torque sensor 14 and the vehicle speed sensor 15, respectively.

Next, the electrical configuration of the EPS of this embodiment will be described.
FIG. 2 is a control block diagram of the EPS of this embodiment. As shown in the figure, the ECU 11 supplies three-phase drive power to the motor 12 based on the microcomputer 17 serving as motor control signal output means for outputting a motor control signal and the motor control signal output from the microcomputer 17. And a drive circuit 18.

  The drive circuit 18 of this embodiment is formed by connecting a plurality of FETs 18a to 18f as switching elements. Specifically, the drive circuit 18 includes FETs 18a and 18d, FETs 18b and 18e, and FETs 18c and 18f connected in series, and each connection point of the FETs 18a and 18d, FETs 18b and 18e, and FETs 18c and 18f. 19u, 19v, and 19w are connected to the motor coils 12u, 12v, and 12w of the motor 12, respectively.

  That is, the drive circuit 18 of the present embodiment is a well-known PWM inverter in which three arms corresponding to each phase are connected in parallel with a pair of switching elements connected in series as a basic unit (arm). The motor control signal output by 17 defines the on-duty ratio of each of the FETs 18 a to 18 f constituting the drive circuit 18. Then, each FET 18a to 18f is turned on / off in response to a motor control signal applied to each gate terminal, and the energization pattern to each phase motor coil 12u, 12v, 12w is switched, so that an in-vehicle power source (battery) The 20 DC voltages are converted into three-phase (U, V, W) driving power and output to the motor 12.

  Further, the ECU 11 is provided with current sensors 21u, 21v, and 21w for detecting respective phase current values Iu, Iv, and Iw that are energized to the motor 12. In the present embodiment, each of the current sensors 21u, 21v, and 21w is connected to the drive circuit 18, more specifically, a switching element pair that constitutes the three arms corresponding to each phase of the motor 12 by being connected in parallel, that is, an FET 18a. , 18d, FETs 18b, 18e, and FETs 18c, 18f are provided on the low potential side (ground side, lower side in FIG. 2).

  Specifically, each of the current sensors 21u, 21v, and 21w of the present embodiment has a known configuration that performs current detection based on a voltage across terminals of a resistor (shunt resistor) connected in series to the circuit. . In the present embodiment, each resistor has a switching element pair corresponding to each phase, that is, among the connection points 19H and 19L that connect the FETs 18a and 18d, the FETs 18b and 18e, and the FETs 18c and 18f in parallel. Is connected in series to the circuit between the ground-side connection point 19L and the ground-side FETs 18d, 18e, and 18f.

  The phase current values Iu, Iv, Iw detected by the current sensors 21u, 21v, 21w are provided in the steering torque τ and the vehicle speed V detected by the torque sensor 14 and the vehicle speed sensor 15, respectively, and the motor 12. The rotation angle (electrical angle) θ of the motor 12 detected by the rotation angle sensor 22 is input to the microcomputer 17. The microcomputer 17 outputs a motor control signal to the drive circuit 18 based on the phase current values Iu, Iv, Iw, the rotation angle θ, the steering torque τ, and the vehicle speed V.

  More specifically, the microcomputer 17 according to the present embodiment determines an assist force (target assist force) to be applied to the steering system based on the steering torque τ and the vehicle speed V, and causes the motor 12 to generate the assist force. The motor control signal is generated by executing current control based on the detected phase current values Iu, Iv, Iw and the rotation angle θ.

  Specifically, the microcomputer 17 of this embodiment includes an assist command applied to the steering system, that is, a current command value calculation unit 23 as a current command value calculation unit that calculates a current command value as a control target value of the motor torque, A motor control signal generator 24 is provided as a motor control signal generator that generates a motor control signal based on the current command value calculated by the current command value calculator 23.

  The current command value calculator 23 calculates a target assist force to be generated by the EPS actuator 10 based on the steering torque τ and the vehicle speed V detected by the torque sensor 14 and the vehicle speed sensor 15, and the motor torque corresponding thereto is calculated. The current command value Iq * is calculated as the control target value. Specifically, the current command value calculation unit 23 calculates a larger target assist force as the input steering torque τ is larger and the vehicle speed V is smaller. Then, the current command value calculator 23 outputs a current command value Iq * corresponding to the target assist force to the motor control signal generator 24.

  On the other hand, the motor control signal generation unit 24 includes the current command value Iq * output from the current command value calculation unit 23 and the phase current values Iu, Iv, Iw detected by the current sensors 21u, 21v, 21w, and The rotation angle θ detected by the rotation angle sensor 22 is input. Then, the motor control signal generation unit 24 executes current feedback control in the d / q coordinate system based on the phase current values Iu, Iv, Iw and the rotation angle θ (electrical angle), thereby performing the motor control signal. Is generated.

  That is, in the microcomputer 17 of the present embodiment, the current command value Iq * output from the current command value calculation unit 23 is input to the motor control signal generation unit 24 as a q-axis current command value, and the motor is generated together with the current command value Iq *. The phase current values Iu, Iv, Iw input to the control signal generator 24 are converted into d-axis current values and q-axis current values in the d / q coordinate system. Then, the motor control signal generation unit 24 adds the q-axis current value that is an actual current to the input current command value Iq * (and d-axis current command value (Id * = 0)) as the q-axis current command value. Feedback control is executed so as to follow (and d-axis current value).

  Then, the microcomputer 17 outputs the motor control signal generated by the motor control signal generation unit 24 to each switching element (the gate terminal thereof) constituting the drive circuit 18, thereby operating the drive circuit 18. It is configured to control the supply of drive power to the motor 12.

(Abnormality detection and control mode when abnormality occurs)
Next, an abnormality detection in EPS and a control mode when an abnormality occurs in the present embodiment will be described.

  As shown in FIG. 2, in the ECU 11 of the present embodiment, the microcomputer 17 is provided with an abnormality determination unit 31 for identifying the form of the abnormality that has occurred (failure mode) when any abnormality occurs in the EPS 1. It has been.

  In the present embodiment, an abnormality signal S_tr for detecting an abnormality in the mechanical system of the EPS actuator 10 is input to the abnormality determination unit 31, and the abnormality determination unit 31 receives this input. Based on the abnormality signal S_tr, an abnormality of the mechanical system in the EPS 1 is detected.

  In addition to the abnormality signal S_tr, a plurality of state quantities and control signals are input to the abnormality determination unit 31 of the present embodiment. Based on the amount and the control signal, an abnormality occurring in the control system relating to the supply of driving power to the motor 12 as described above is detected.

  Specifically, in the present embodiment, a current sensor 34 is provided in the power supply line 33 that connects the drive circuit 18 and the in-vehicle power supply 20, and the abnormality determination unit 31 is provided with the current sensor 34. The detected power supply current value Ib is input. Then, the abnormality determination unit 31 detects excessive energization of the motor 12, that is, occurrence of overcurrent, based on a comparison between the detected power supply current value Ib and a predetermined threshold value.

  The abnormality determination unit 31 is supplied with the phase current values Iu, Iv, Iw detected by the current sensors 21u, 21v, 21w. And the abnormality determination part 31 detects generation | occurrence | production of the failure in each said current sensor 21u, 21v, 21w based on each phase current value Iu, Iv, Iw.

  The microcomputer 17 according to this embodiment switches the control mode of the motor 12 based on the result of abnormality detection in the abnormality determination unit 31. Specifically, the abnormality determination unit 31 outputs the abnormality detection result as the abnormality detection signal S_tm to the current command value calculation unit 23 and the motor control signal generation unit 24, and the current command value calculation unit 23 and the motor control signal. The generation unit 24 calculates a current command value according to the input abnormality detection signal S_tm and generates a motor control signal. As a result, power assist control is executed in accordance with the result of the abnormality detection, that is, the failure mode.

  More specifically, as shown in the flowchart of FIG. 3, when the microcomputer 17 determines that some abnormality has occurred (step 101: YES), it first determines whether or not the abnormality is an overcurrent. (Step 102). If it is determined that the generated abnormality is the occurrence of an overcurrent (step 102: YES), the motor control, that is, the control for stopping the application of assist force to the steering system is executed (step 103). .

  On the other hand, when it is determined in step 102 that the abnormality that has occurred is not the occurrence of an overcurrent (step 102: NO), the microcomputer 17 subsequently determines whether or not the abnormality is a failure of the current sensor. Determination is made (step 104).

  Here, the microcomputer 17 (abnormality determination unit 31) of the present embodiment monitors the total value of the phase current values Iu, Iv, and Iw detected by the current sensors 21u, 21v, and 21w. Then, based on a comparison between the total value (absolute value thereof, | Iu + Iv + Iw |) and a predetermined threshold value I1, occurrence of a failure in any one of these current sensors 21u, 21v, 21w is detected.

  That is, according to Kirchhoff's law, the total value of the phase current values Iu, Iv, and Iw is theoretically “0”. And as a case where the total value does not become “0”, in addition to “when the current sensor is broken”, there is “when leakage current occurs” due to contact of the power line, etc. Since the execution of the assist force stop control is determined by detection of the generated overcurrent (step 102: YES), the determination in step 104 is not performed.

  That is, when the occurrence of overcurrent is not detected (step 102: NO), the total value of the phase current values Iu, Iv, Iw exceeds a predetermined threshold value I1 set to a value close to “0” ( In | Iu + Iv + Iw |> I1), there is a high possibility that one of the current sensors 21u, 21v, 21w has failed. And the abnormality determination part 31 of this embodiment is each current sensor 21u, 21v, 21w, when the total value of such each phase current value Iu, Iv, Iw is a state which continuously exceeds the predetermined threshold value I1. It is determined that a failure has occurred in any of the above.

  Specifically, as shown in the flowchart of FIG. 4, when the abnormality determination unit 31 acquires the phase current values Iu, Iv, and Iw (step 201), the total value (absolute value thereof) is a predetermined threshold value I1. It is determined whether or not (step 202). When the total value (absolute value thereof) exceeds a predetermined threshold value I1 (| Iu + Iv + Iw |> I1, Step 202: YES), the counter for measurement is incremented (ta = ta + 1, Step 203). If the total value (absolute value) is equal to or less than the predetermined threshold value I1 (| Iu + Iv + Iw | ≦ I1, step 202: NO), the counter for measurement is cleared (ta = 0, step 204). .

  Then, it is determined whether or not the counter value ta is equal to or greater than the predetermined value t1 (step 205). When the counter value ta is equal to or greater than the predetermined value t1 (ta ≧ t1, step 205: YES), It is determined that a failure has occurred in any of the current sensors 21u, 21v, 21w (step 206). When the counter value ta is less than the predetermined value t1 (ta <t1, step 205: NO), the process of step 206 is not executed.

  As described above, the microcomputer 17 (abnormality determination unit 31) executes failure determination of the current sensor at a predetermined cycle. If it is determined by the failure determination that the abnormality that has occurred is a failure of the current sensor (step 104: YES), a failure mode in which a failure occurs in any of the current sensors 21u, 21v, 21w. By executing the current sensor failure control corresponding to the above, the output of the motor control signal for applying the assist force is continued (step 105).

  If it is determined in step 101 that there is no abnormality (step 101: NO), the microcomputer 17 executes the normal power assist control as described above (normal control, step 106). If it is determined in step 105 that the abnormality that has occurred is not a failure of the current sensor (step 104: NO), the microcomputer 17 performs other failure mode determination and control corresponding to the detected failure mode. Execute (step 107).

(Control when current sensor fails)
Next, an aspect of the current sensor failure control in this embodiment will be described.
As the "current sensor failure control", the microcomputer 17 (abnormality determination unit 31) of the present embodiment first identifies the phase in which the current sensor has failed. Then, based on the phase current values of the two phases other than the current sensor failure occurrence phase, by calculating the phase current value of the current sensor failure occurrence phase by calculation, the same power assist control as in the above-described normal state is continued. To do.

  Specifically, the abnormality determination unit 31 of the present embodiment has a timing at which the lower FETs 18d, 18e, and 18f on the lower side among the FETs 18a to 18f constituting the drive circuit 18 are turned off. Each phase current value Iu, Iv, Iw is acquired. Then, for each phase, by comparing the acquired phase current value Ix (X = U, V, W) with a predetermined threshold value I2, the current sensor failure occurrence phase is specified.

  That is, each current sensor 21u, 21v, 21w is provided on the low potential side of each switching element pair constituting the drive circuit 18, that is, FETs 18a, 18d, FETs 18b, 18e, and FETs 18c, 18f. The phase current value Ix of the target phase (X phase) acquired at the timing when each FET on the side is turned off should be basically “0”. In the case where the phase current value Ix of the X phase does not become “0”, there is “on-fixation failure of the lower stage FET” in addition to “when the current sensor corresponding to the X phase fails”. Since the execution of the assist force stop control is determined due to the occurrence of an overcurrent associated therewith, the “current sensor failure control” itself is not executed in the first place (see FIG. 3).

  That is, the X-phase phase current value Ix (absolute value) acquired at the timing when the corresponding FETs 18d, 18e, and 18f on the low potential side are turned off is set to a value close to “0”. When the threshold value I2 is exceeded, there is a high possibility that a failure has occurred in the current sensor corresponding to the X phase. Then, the abnormality determination unit 31 of the present embodiment continuously obtains the phase current value Ix (absolute value) acquired at the timing when each of the low potential side FETs 18d, 18e, and 18f is turned off in a predetermined manner. When the threshold value I2 is exceeded, it is determined that a failure has occurred in the current sensor corresponding to the X phase.

  More specifically, as shown in the flowchart of FIG. 5, first, the timing at which the low-potential side (lower stage) FET corresponding to the phase to be determined (phase X) is turned off (step 301: YES). Thus, the X-phase phase current value Ix is obtained (step 302), and it is determined whether or not the phase current value Ix (absolute value thereof) exceeds a predetermined threshold value I2 (step 303). When the phase current value Ix (absolute value thereof) exceeds a predetermined threshold value I2 (| Ix |> I2, step 303: YES), the measurement counter is incremented (tx = tx + 1, step 304). ). When the phase current value Ix (absolute value) is equal to or smaller than the predetermined threshold value I2 (| Ix | ≦ I2, step 303: NO), the measurement counter is cleared (tx = 0, Step 305).

  Then, it is determined whether or not the counter value tx is equal to or greater than the predetermined value t2 (step 306). If the counter value tx is equal to or greater than the predetermined value t2 (tx ≧ t2, step 306: YES), It is determined that a failure has occurred in the current sensor corresponding to the X phase (step 307).

  In the present embodiment, the abnormality determination unit 31 performs the above-described steps 301 to 307 at every predetermined period when the low potential side (lower side) FET corresponding to the phase to be determined (X phase) is turned off. The determination process shown in FIG. That is, when the low-potential side (lower stage) FET corresponding to the phase to be determined (phase X) is on (step 301: NO), the processing of step 302 to step 307 is not executed. In step 306, when the counter value tx is less than the predetermined value t2 (tx <t2, step 306: NO), the process of step 307 is not executed.

As described above, according to the present embodiment, the following operations and effects can be obtained.
(1) The microcomputer 17 (abnormality determination unit 31), when the occurrence of a failure in any of the current sensors 21u, 21v, 21w is detected, the timing at which each low potential (lower) FET is turned off (Step 301: YES), each phase current value is acquired (step 302). Then, for each phase, by comparing the acquired phase current value Ix with a predetermined threshold value I2 (step 303), the failure occurrence phase of the current sensor is specified.

  That is, the phase current value Ix detected by the current sensor provided on the low potential side of each switching element pair, that is, the FETs 18a and 18d, the FETs 18b and 18e, and the FETs 18c and 18f constituting the driving circuit 18 is obtained at the timing of acquisition. As long as the FET on the low potential side is OFF, it should be basically “0”. Therefore, when the occurrence of a failure is detected in any of the current sensors 21u, 21v, and 21w, a new configuration is obtained by executing such determination processing for each of the U, V, and W phases. Therefore, the current sensor failure occurrence phase can be identified easily and with high accuracy with an extremely simple configuration. As a result, more advanced life extension control can be executed, and the application of the assist force can be continued without deteriorating stability and steering feeling.

  (2) The microcomputer 17 (abnormality determination unit 31) monitors the total value of the phase current values Iu, Iv, Iw detected by the current sensors 21u, 21v, 21w. Then, based on a comparison between the total value (absolute value thereof, | Iu + Iv + Iw |) and a predetermined threshold value I1, occurrence of a failure in any one of these current sensors 21u, 21v, 21w is detected.

  That is, according to Kirchhoff's law, the total value of the phase current values Iu, Iv, and Iw is theoretically “0”. And in the case where the total value is not “0”, there is “leakage current occurrence” caused by contact of the power line, etc. in addition to “current sensor failure”. Since a high overcurrent is generated, the current sensor failure determination itself is not performed. Therefore, according to the above configuration, a failure occurring in any one of the current sensors 21u, 21v, and 21w can be easily detected with an extremely simple configuration without causing the addition of a new configuration. .

In addition, you may change this embodiment as follows.
In this embodiment, as the “current sensor failure control”, the phase in which the current sensor failure occurs is specified, and the current is calculated by calculation based on the phase current values of the two phases other than the current sensor failure occurrence phase. By calculating the phase current value of the sensor failure occurrence phase, the same power assist control as in the normal state is continued. However, the present invention is not limited to this, and “current sensor failure control” may be configured to perform two-phase driving with two phases other than the current sensor failure occurrence phase as energized phases, and each phase current value detected It may be embodied in a configuration that switches to open loop control that does not use Iu, Iv, and Iw.

  In the present embodiment, the predetermined threshold values I1 and I2 are set to values close to “0”. However, the present invention is not limited to this, and when the potential is offset in advance, it may be set to a value close to the offset value.

  -Moreover, about continuation conditions when exceeding each threshold value I1 and I2 (refer step 205 of FIG. 4 and step 306 of FIG. 5), you may measure time progress more directly instead of the frequency | count count.

  In the present embodiment, the abnormality determination unit 31 detects the occurrence of overcurrent based on the power supply current value Ib detected by the current sensor 34 provided in the power supply line 33. However, the present invention is not limited to this, and the present invention may be embodied in a configuration that detects the occurrence of overcurrent by estimation using other state quantities such as a power supply voltage.

The schematic block diagram of an electric power steering device (EPS). The block diagram which shows the electric constitution of EPS. The flowchart which shows the process sequence of abnormality determination and control switching. The flowchart which shows the process sequence of a current sensor failure detection. The flowchart which shows the process sequence of a current sensor failure phase identification.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Electric power steering apparatus (EPS), 10 ... EPS actuator, 11 ... ECU, 12 ... Motor, 12u, 12v, 12w ... Motor coil, 17 ... Microcomputer, 18 ... Drive circuit, 18a-18f ... FET, 21u, 21v , 21w, 34 ... current sensor, 23 ... current command value calculation unit, 24 ... motor control signal generation unit, 31 ... abnormality determination unit, Ix, Iu, Iv, Iw ... phase current value, Ib ... power supply current value, I1, I2 is a threshold value.

Claims (4)

A steering force assisting device for applying an assisting force for assisting a steering operation to a steering system using a motor as a driving source; and a control means for controlling the operation of the steering force assisting device through supply of driving power to the motor. ,
The control means can detect a motor control signal output means for outputting a motor control signal, a drive circuit for outputting three-phase drive power based on the motor control signal, and a control system abnormality relating to the supply of the drive power Anomaly detection means,
The drive circuit is formed by connecting a pair of switching elements connected in series in parallel, and turning on / off the switching elements based on the motor control signal to switch the energization pattern for the motor and the parallel connection. On the low potential side of each switching element pair, a current sensor for detecting the current value of each phase corresponding to each switching element pair is provided,
The switching element is an N-channel FET in which a drain is disposed on the high potential side and a source is disposed on the low potential side,
The motor control signal output means is an electric power steering device that generates the motor control signal based on each phase current value detected by each current sensor,
When the occurrence of a failure in any of the current sensors is detected, the abnormality detection means is configured to turn on the high-potential side switching element and turn off the low-potential side switching element. Electricity characterized in that each phase current value is acquired and, for each phase, the phase in which the failure of the current sensor has occurred is identified by comparing the acquired phase current value with a predetermined threshold value. Power steering device. The electric power steering apparatus according to claim 1, wherein
The abnormality detecting means specifies a phase in which a failure of the current sensor has occurred in a case where occurrence of an overcurrent is not detected ;
An electric power steering device. A drive circuit in which a pair of switching elements connected in series are connected in parallel and the energization pattern is switched based on on / off of each switching element, and provided on the low potential side of each of the pair of switching elements connected in parallel And a control signal output means for outputting a control signal for turning on / off each switching element based on a current value detected by each current sensor. And
The switching element is an N-channel FET in which a drain is disposed on the high potential side and a source is disposed on the low potential side,
When occurrence of a failure in any of the current sensors is detected, each phase current value is obtained at a timing when the high potential side switching element is turned on and the low potential side switching element is turned off, A method for detecting an abnormality, characterized in that, for each phase, the phase in which the failure of the current sensor occurs is identified by comparing the acquired phase current value with a predetermined threshold value. In the abnormality detection method according to claim 3,
An abnormality detection method comprising: identifying a phase in which a failure of the current sensor has occurred when occurrence of an overcurrent is not detected.

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