JP4156878B2 - Electric power steering device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electric power steering apparatus, and more particularly, to an electric power steering apparatus that reduces the burden on a driver's steering force by applying motor power to a steering system in an automobile steering apparatus.
[0002]
[Prior art]
The electric power steering device performs driving control of the motor by the motor control unit to reduce the steering force based on signals output from the steering torque detection unit that detects the steering torque and the vehicle speed detection unit that detects the vehicle speed. Yes. An electric power steering apparatus using a brushless motor as the motor is known. Further, in addition to the steering torque detection unit and the vehicle speed detection unit, there is a motor control unit that controls the motor to reduce the steering force based on the output of the steering angle sensor that detects the steering angle.
[0003]
Since the electric power steering apparatus using the brushless motor does not have a decrease or fluctuation in the motor output due to a voltage drop between the brush and the commutator, a stable steering assist force can be obtained. Further, since the moment of inertia of the motor is smaller than that of a motor with a brush, a good steering feeling can be obtained when the vehicle goes straight at a high speed or when the steering wheel is turned back.
[0004]
However, when a brushless motor is used as the motor, it is necessary to control the amount of motor current applied according to the rotation angle of the motor instead of the brush and the commutator. A motor rotation angle detection unit and a motor current detection unit for detection are provided, and PWM drive control of the brushless motor is performed based on output signals of the motor rotation angle detection unit and the motor current detection unit. Here, the electrical angle is an angle obtained from the position of the magnet of the rotor, and when there are four pairs of magnets around the rotor so that N poles and S poles are alternately arranged along the rotational direction. The mechanical angle of the rotor is 90 °, that is, a quarter rotation of the rotor corresponds to an electrical angle of 360 °. The motor rotation angle detection unit is formed by, for example, a resolver and an RD conversion unit. A signal from the resolver is continuously supplied to an RD (resolver digital) converter. The RD conversion unit calculates an angle (rotation angle) θ of the rotor with respect to the stator in the brushless motor, and outputs a signal corresponding to the calculated angle θ. Further, the RD conversion unit calculates a rotational angular velocity ω of the rotor of the brushless motor with respect to the stator, and outputs a signal corresponding to the calculated rotational angular velocity ω.
[0005]
FIG. 15 is a block diagram of the electric power steering apparatus. The outputs of the steering torque detector 300 and the vehicle speed detector 301 are input to the motor controller 302. A resolver 304 for detecting the rotation angle of the brushless motor 303 is attached to the brushless motor 303 controlled by the motor control unit 302.
[0006]
FIG. 16 is a block diagram of another electric power steering apparatus. In this case, in addition to the configuration shown in FIG. 15, the output of the steering angle sensor 305 is also input to the motor control unit 302. It has become.
[0007]
[Problems to be solved by the invention]
However, in the conventional electric power steering apparatus, although the rotor angle and the rotational angular velocity at which the steering angle can be detected by the RD converter based on the output from the resolver are output, the steering angle is controlled by the motor. Otherwise, as shown in FIG. 16, a steering angle sensor is provided separately, and the steering angle from the steering angle sensor is detected and used for motor control. Also, no means for detecting a failure of the rudder angle sensor has been provided. Therefore, there is a problem that when the rudder angle sensor fails, it cannot be determined that the failure has occurred.
[0008]
In order to solve the above problem, an object of the present invention is to detect the steering angle using the rotational angular velocity of the rotor obtained based on the output signal from the resolver, and to detect the failure of the steering angle sensor based on the steering angle. It is another object of the present invention to provide an electric power steering device that detects and controls a brushless motor according to a steering angle obtained based on an output signal from a resolver.
[0009]
[Means and Actions for Solving the Problems]
The electric power steering apparatus according to the present invention is configured as follows to achieve the above object.
[0012]
According to the present invention Electric power steering device (Claims) 1 Corresponds to the electric angle of the brushless motor in an electric power steering device using a three-phase brushless motor. Detect Resolver When , Resolver output Integration means that integrates the signal and outputs the integration value, the difference between the integration value output from the integration means and the integral value at neutral, and the right maximum integral value for right steering or the left maximum for left steering The rudder angle estimation means for estimating the rudder angle by the ratio of the difference between the integral value and the integral value at neutral, and the rudder angle estimation means Rudder angle It becomes more than predetermined value Near the maximum rudder angle Place Together In Is 3 phase Reduce the current flowing to the brushless motor Motor current control means It is characterized by that.
[0013]
the above According to the electric power steering apparatus, in the electric power steering apparatus using a three-phase brushless motor, Resolver Electric angle of brushless motor Inspect Know, Integration means Resolver output The signal is integrated and the integrated value is output.The difference between the integrated value output from the integrating means and the neutral value is calculated by the rudder angle estimating means, and in the case of right steering, the maximum right integrated value or in the case of left steering. Estimate the rudder angle by the ratio of the difference between the left maximum integral value and the neutral integral value And The motor current control means was estimated by the rudder angle estimation means Rudder angle It becomes more than predetermined value Near the maximum rudder angle Place Together In Is 3 phase Since the current flowing through the brushless motor is reduced, heat generation in the motor control unit can be suppressed, and good control of the electric power steering apparatus can be performed.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings.
[0015]
The overall configuration of the electric power steering apparatus according to the present invention, the main configuration of the mechanical mechanism, and the layout of the electronic circuit unit will be described with reference to FIGS.
[0016]
FIG. 1 is an overall configuration diagram of an electric power steering apparatus according to a first embodiment of the present invention. The electric power steering device 10 is configured to give auxiliary steering force (steering torque) to the steering shaft 12 and the like connected to the steering wheel 11. An upper end of the steering shaft 12 is connected to the steering wheel 11, and a pinion gear 13 is attached to the lower end. A rack shaft 14 provided with a rack gear 14a meshing with the pinion gear 13 is disposed. A rack and pinion mechanism 15 is formed by the pinion gear 13 and the rack gear 14a. Tie rods 16 are provided at both ends of the rack shaft 14, and front wheels 17 are attached to the outer ends of the tie rods 16. A brushless motor 19 is provided on the steering shaft 12 via a power transmission mechanism 18. The brushless motor 19 outputs a rotational force (torque) that assists the steering torque, and applies this rotational force to the steering shaft 12 via the power transmission mechanism 18. The steering shaft 12 is provided with a steering torque detector 20. The steering torque detector 20 detects the steering torque applied to the steering shaft 12 when the steering torque generated by the driver operating the steering wheel 11 is applied to the steering shaft 12. Reference numeral 20b denotes a rudder angle sensor that detects a rudder angle, 21 denotes a vehicle speed detection unit that detects the vehicle speed of the vehicle, and 22 denotes a control device configured by a computer. The control device 22 takes in the steering torque signal T output from the steering torque detection unit 20, the steering angle signal output from the steering angle sensor 20d, and the vehicle speed signal V output from the vehicle speed detection unit 21, and information related to the steering torque. Based on the information related to the steering angle and the information related to the vehicle speed, a drive control signal SG1 for controlling the rotational operation of the brushless motor 19 is output. Further, the brushless motor 19 is provided with a motor rotation angle detector 23 constituted by a resolver or the like. The rotation angle signal SG2 of the motor rotation angle detector 23 is fed back to the control device 22. The rack and pinion mechanism 15 and the like are housed in a gear box 24 not shown in FIG.
[0017]
In the above, the electric power steering device 10 adds a steering torque detection unit 20, a steering angle sensor 20d, a vehicle speed detection unit 21, a control device 22, a brushless motor 19, and a power transmission mechanism 18 to a normal steering system configuration. Is made up of.
[0018]
In the above configuration, when the driver operates the steering wheel 11 to steer in the traveling direction during the traveling operation of the automobile, the rotational force based on the steering torque applied to the steering shaft 12 is transmitted via the rack and pinion mechanism 15. It is converted into a linear motion in the axial direction of the rack shaft 14, and further, the traveling direction of the front wheel 17 is changed via the tie rod 16. At this time, at the same time, the steering torque detector 20 attached to the steering shaft 12 detects the steering torque corresponding to the steering by the driver at the steering wheel 11 and converts it into an electrical steering torque signal T. A steering torque signal T is output to the control device 22. The steering angle sensor 20 d detects the steering angle and outputs a steering angle signal to the control device 22. Further, the vehicle speed detection unit 21 detects the vehicle speed of the vehicle, converts it into a vehicle speed signal V, and outputs this vehicle speed signal V to the control device 22. The control device 22 generates a motor current for driving the brushless motor 19 based on the steering torque signal T, the steering angle signal, and the vehicle speed signal V. The brushless motor 19 driven by the motor current causes an auxiliary steering force to act on the steering shaft 12 via the power transmission mechanism 18. By driving the brushless motor 19 as described above, the steering force applied by the driver to the steering wheel 11 is reduced.
[0019]
FIG. 2 shows a specific configuration of the main part of the mechanical mechanism of the electric power steering apparatus 10 and the electric system. A part of the left end portion and the right end portion of the rack shaft 14 is shown in cross section. The rack shaft 14 is housed in a cylindrical housing 31 arranged in the vehicle width direction (left-right direction in FIG. 2) so as to be slidable in the axial direction. Ball joints 32 are screwed to both ends of the rack shaft 14 protruding from the housing 31, and left and right tie rods 16 are connected to these ball joints 32. The housing 31 includes a bracket 33 for attaching to a vehicle body (not shown), and includes stoppers 34 at both ends.
[0020]
In FIG. 2, 35 is an ignition switch, 36 is an in-vehicle battery, and 37 is an AC generator (ACG) attached to the vehicle engine. The AC generator 37 starts power generation by the operation of the vehicle engine. Necessary electric power is supplied from the battery 36 or the AC generator 37 to the control device 22. The control device 22 is attached to the brushless motor 19. Reference numeral 38 denotes a rack end that hits the stopper 34 when the rack shaft is moved. Reference numeral 39 denotes a dust seal boot for protecting the inside of the gear box from water, mud, dust and the like.
[0021]
FIG. 3 is a cross-sectional view taken along line AA in FIG. In FIG. 3, the specific structure of the support structure of the steering shaft 12, the steering torque detector 20, the power transmission mechanism 18, the rack and pinion mechanism 15, and the layout of the brushless motor 19 and the control device 22 are clearly shown.
[0022]
In FIG. 3, the steering shaft 13 is rotatably supported by two bearing portions 41 and 42 in a housing 24 a forming the gear box 24. A rack and pinion mechanism 15 and a power transmission mechanism 18 are housed inside the housing 24a, and a steering torque detector 20 is additionally provided at the top. The upper opening of the housing 24 a is closed with a lid 43, and the lid 43 is fixed with bolts 44. The pinion 13 provided at the lower end portion of the steering shaft 13 is located between the bearing portions 41 and 42. The rack shaft 14 is pressed against the pinion 13 side by a contact member 47 guided by a rack guide 45 and biased by a compressed spring 46. The power transmission mechanism 18 is formed by a worm gear 49 fixed to a transmission shaft 48 coupled to an output shaft of the brushless motor 19 and a worm wheel 50 fixed to the steering shaft 12. The steering torque detection unit 20 includes an electronic circuit unit 20b that electrically processes a detection signal output from a steering torque detection sensor 20a disposed around the steering shaft 12. The steering torque detection sensor 20 a is attached to the lid 43.
[0023]
4 is a cross-sectional view taken along line BB in FIG. In FIG. 4, specific configurations of the brushless motor 19 and the control device 22 are clearly shown.
[0024]
The brushless motor 19 includes a rotor 52 made of a permanent magnet fixed to the rotation shaft 51 and a stator 54 disposed around the rotor 52. The stator 54 includes a stator winding 53. The rotating shaft 51 is rotatably supported by the two bearing portions 55 and 56. The tip of the rotating shaft 51 is an output shaft 19 a of the brushless motor 19. The output shaft 19a of the brushless motor 19 is coupled to the transmission shaft 48 through the torque limiter 57 so that rotational power is transmitted. As described above, the worm gear 49 is fixed to the transmission shaft 48, and the worm wheel 50 meshing with the worm gear 49 is disposed. At the rear end portion of the rotation shaft 51, the above-described motor rotation angle detection unit (position detection unit) 23 that detects the rotation angle (rotation position) of the rotor 52 of the brushless motor 19 is provided. The motor rotation angle detection unit 23 includes a rotor 23a fixed to the rotation shaft 51 and a detection element 23b that detects the rotation angle of the rotor 23a using a magnetic action. For example, a resolver is used for the motor rotation angle detector 23. A motor current is supplied to the stator winding 53 of the stator 54. The above components of the brushless motor 19 are arranged inside the motor case 58.
[0025]
FIG. 5 is a block diagram of the control device 22 described above. The control device 22 includes a motor control unit 100, an integration unit 101, and a failure detection unit 102. In addition, a failure display unit 103 is connected to the failure detection unit 102. The motor control unit 100 is basically the same as that described with reference to FIGS. The failure detection unit 102 outputs 1 as a signal when the failure of the steering angle sensor is determined, and zero as a signal when the failure is not determined, but the motor control unit 100 outputs a signal from the failure detection unit 102. When zero, the state is kept as it is, and when the input from the failure detection unit 102 is 1, the signal of the steering angle sensor 20d is cut off, the input signal from the vehicle speed detection unit 21 and the input from the steering torque detection unit 20 An input signal switching unit 104 that is switched so as to be controlled by a signal is provided.
[0026]
In FIG. 5, the integrating unit 101 integrates the rotational angular velocity signal obtained from the resolver 23 by the RD converting unit 23 d and inputs the integrated value to the failure detecting unit 102. The rotation angle of the rotor can be obtained by an integration value obtained by integrating the rotation angular velocities.
[0027]
FIG. 6 is a block configuration diagram illustrating the failure detection unit. The failure detection unit 102 includes an input unit 105, an output unit 106, a CPU 107, and a storage unit 108. In this failure detection unit 102, the steering wheel is opened in advance until the steering angle becomes maximum, the steering angle signal from the steering angle sensor 20d at each steering angle when the steering wheel is turned, and the integration unit at each corresponding steering angle. The integral value obtained from 101 is input, and the integral value corresponding to each steering angle is stored in the storage unit 108. That is, a steering angle map 109 corresponding to each integral value as shown in FIG. 7 is created in the storage area 109 in the storage unit 108. In the map 109 shown in FIG. 7, the horizontal axis represents the steering angle, the vertical axis represents the integral value, and the curve C10 is a steering angle map 109 corresponding to each integral value. If an integral value is obtained from this map, the steering angle corresponding to the integral value can be obtained. The failure detection unit 102 obtains the steering angle corresponding to the integral value according to the map 109 from the input of the integral value of the rotational angular velocity from the integration unit, compares the steering angle with the input from the steering angle sensor, for example, If the difference is smaller than a predetermined value, it is determined that the difference is normal, and a normal value signal, for example, zero is output to the motor control unit 100 and the failure display unit 103, and if the difference is larger than the predetermined value, It is determined that there is a failure, and a failure signal, for example, 1 is output to the motor control unit 100 and the failure display unit 103. The predetermined value here is stored in advance in the storage area 110 of the storage unit 108.
[0028]
The failure display unit 103 is a device that displays whether or not the rudder angle sensor 20d is in failure. For example, the failure display unit 103 is provided with a light emitting diode that blinks based on an input signal from the failure detection unit 102. The light-emitting diode may be kept off when the signal from the failure detection unit 103 is zero, and lit up when the input from the failure detection unit 103 is 1. Thereby, when the light emitting diode is turned on, it can be determined that the steering angle sensor is out of order.
[0029]
Next, the operation of this embodiment will be described with reference to the flowchart of FIG. The output from the resolver 23 is converted by the RD converter 23d, and the rotational angular velocity signal is output to the integrating unit 101 (step ST10). In the integration unit 101, an integral value of the rotation angular velocity is calculated based on the rotation angular velocity signal output from the RD conversion unit 23d (step ST11).
[0030]
The steering angle is obtained from the integral value based on the map stored in the storage unit, temporarily stored in the storage area A of the storage unit of the failure detection unit 102 (step ST12), and the output from the steering angle sensor 20d is stored in the storage area of the storage unit. Temporarily stored in B (step ST13). The CPU calculates a difference from the values in the storage areas A and B (step ST14), and stores the difference in the storage area C (step ST15). The CPU compares the difference with a predetermined value stored in the storage area 110 of the storage unit (step ST16). As a result, when the difference is smaller than the predetermined value, zero is output to the motor control unit 100 and the failure display unit 103 (step ST17). At that time, the motor control unit 100 maintains that state. Moreover, the failure display part 103 does not light a light emitting diode. And it returns to step ST10 again and processes.
[0031]
If the difference is equal to or greater than a predetermined value as a result of comparison by the CPU, signal 1 is output to motor control unit 100 and failure display unit 103 (step ST18). At that time, in the motor control unit 100, the input signal switching unit 104 is operated to cut off the signal from the steering angle sensor 20d, and at the same time, the control is switched to the control by the values in the steering torque detection unit 20 and the vehicle speed detection unit 21 (step). ST19). Moreover, in the failure display part 103, a light emitting diode lights (step ST20).
[0032]
Thereby, normal control can be performed even when the steering angle sensor 20d fails, and the operator can be notified of the failure of the steering angle sensor 20d.
[0033]
Next, an electric power steering apparatus according to a second embodiment of the present invention will be described. In the second embodiment, the electric power steering apparatus shown in FIG. 1 does not include the steering angle sensor 20d. Further, the control device 22 is partially changed as described below.
[0034]
As shown in FIG. 9, the control device 22 includes a motor control unit 200, an integration unit 201, a steering angle neutral position determination unit 202, and a steering angle estimation unit 203. 15 and 16, but includes a storage unit 204, a comparison unit 205, and a current limit instruction unit 206. The storage unit 204 stores the current limit region designated steering angle, and the comparison unit 205 compares the steering angle from the steering angle estimation unit 203 with the current limit region designated steering angle, and when the steering angle is equal to or greater than the designated steering angle. The current limit instruction unit 206 sends a signal for instructing to limit the motor current.
[0035]
In FIG. 9, the integration unit 201 integrates the rotational angular velocity signal obtained from the resolver 23 by the RD conversion unit 23 d and inputs the integrated value to the steering angle estimation unit 203. The rotation angle of the rotor can be obtained by an integration value obtained by integrating the rotation angular velocities.
[0036]
The rudder angle neutral position determination unit 202 determines a rudder angle neutral position. The determination unit 202 has two methods shown in the following two specific examples.
[0037]
First, a first specific example will be described with reference to FIG. The steering angle neutral position determination unit 202 receives signals from the left front wheel speed sensor 207 and the right front wheel speed sensor 208 as input to the input unit 209. The input wheel speed signals of the left and right front wheels are compared by the comparison unit 210. When the vehicle speed signals are different, a signal zero is output from the output unit 211, and when the vehicle speed signals match, 1 is output.
[0038]
FIG. 11 is a block diagram of the rudder angle estimation unit. The steering angle estimation unit 203 includes an input unit 212, an output unit 213, a CPU 214, and a storage unit 215. The rudder angle estimating unit 203 estimates the rudder angle based on the integrated value from the integrating unit 201 and the value from the rudder angle neutral position determining unit 202. The steering angle estimation unit 203 includes a neutral integration value storage unit 216 that stores a signal from the integration unit 201 when the signal from the steering angle neutral position determination unit 202 is 1. In addition, there is a left maximum integrated value storage unit 217 that stores an integral value when the maximum torque value is obtained when left steering is performed, and a left maximum steering angle storage unit 218 that stores a left maximum steering angle. Do . In addition, it has a right maximum integrated value storage unit 219 that stores an integral value when the maximum torque value is obtained when steering right, and a right maximum steering angle storage unit 220 that stores a right maximum steering angle. In the steering angle estimation, the difference between the integral value input from the integration unit and the integral value at neutral is obtained, and the steering angle is calculated based on the maximum steering angle by the ratio between the difference and the difference between the maximum integral value and the neutral integral value. Calculate and output the value to the motor controller.
[0039]
Next, the operation of this embodiment will be described with reference to the flowchart of FIG. The output from the resolver 23 is converted by the RD converter 23d, and the angular velocity signal is output to the integrating unit 201 (step ST30). In the integration unit 201, the integral value of the angular velocity is calculated based on the angular velocity signal output from the RD conversion unit 23 (step ST31).
[0040]
The integral value is temporarily stored in the storage area F of the storage unit 215 of the steering angle estimation unit 203 (step ST32), and the integral value at the steering angle neutral position stored in the neutral integration value storage unit 216 of the storage unit 215 Is calculated and stored (step ST33). The ratio between the difference and the difference between the maximum integrated value stored in the left maximum integrated value storage unit 217 or the right maximum integrated value storage unit 219 and the integrated value at the steering angle neutral position is calculated, thereby estimating the steering angle. (Step ST34). The steering angle is compared with the current limit region steering angle (predetermined value) by the comparison unit of the motor control unit 200 (step ST35). As a result, when the steering angle is smaller than the predetermined value, the current limit instruction unit 206 remains unchanged. Keep state. At that time, the motor control unit 200 maintains that state.
[0041]
Further, as a result of comparison by the comparison unit, when the steering angle is equal to or greater than a predetermined value, a current limit command is output from the current limit instruction unit 206 (step ST36). At that time, the motor current is limited.
[0042]
FIG. 13 shows the change in the steering angle and the change in the target current at that time. Fig.13 (a) shows the change of a steering angle, FIG.13 (b) shows the change of the target electric current corresponding to the steering angle. In FIG. 13B, the target current changes as indicated by a curve C20 as the steering angle increases. In the electric power steering apparatus of the present embodiment, when the steering angle is increased, the target currents as indicated by the solid lines C21 and C22 are obtained in the range R10 and the range R11 in the figure, and the motor current is limited. Dotted lines C23 and C24 are changes in the target current in the conventional electric power steering apparatus.
[0043]
Thus, an excessive current at the time of maximum torque is reduced, and heat generation of the control device can be suppressed.
[0044]
Next, a second specific example will be described with reference to FIG. The steering angle neutral position determination unit 202 includes a torque determination unit 221 and an angular velocity determination unit 222, and a signal from the steering torque detection unit 20 and an angular velocity signal from the RD conversion unit 23d are input to the input unit 223. When the steering angle neutral position determination unit 202 is locked in the right direction, that is, when the input steering torque is the maximum torque in the right direction and the angular velocity is zero, the output unit 224 outputs the 2-bit signal 10 and the left When the angular velocity is zero with the maximum torque in the left direction, the 2-bit signal 01 is output, and when the steering torque is smaller than the maximum right torque and the maximum left torque and the angular velocity is not zero. , 00 from the output unit 224 is output.
[0045]
The steering angle estimation unit 203 is similar to the first specific example shown in FIG. 11, and estimates the steering angle based on the integrated value from the integration unit 201 and the value from the steering angle neutral position determination unit 202. When the signal from the steering angle neutral position determination unit 202 is 10, the steering angle estimation unit 203 has a right maximum integrated value storage unit 219 that stores a signal from the integration unit and a signal from the steering angle neutral position determination unit 202. Is 01, the left maximum integrated value storage unit 217 for storing the signal from the integration unit 201 is provided. The storage unit 215 stores a right maximum steering angle and a left maximum steering angle in advance. Furthermore, it has a neutral time integral value storage unit 216 that stores an average value of the right maximum integral value and the left maximum integral value as a neutral time integral value. In the steering angle estimation, the difference between the integral value input from the integration unit 201 and the neutral time integral value stored in the neutral time integral value storage unit 216 is obtained, and in the case of right steering, the right maximum integral value or the left In the case of steering, the steering angle is calculated based on the right maximum steering angle or the left maximum steering angle based on the ratio of the difference between the left maximum integral value and the neutral integral value, and the value is output to the motor control unit 200.
[0046]
Since the operation of the motor control unit after estimating the rudder angle is the same as that of the first specific example, the description thereof is omitted.
[0047]
In this embodiment, the rotation angle is estimated by detecting the angular velocity of the output from the resolver by the RD conversion unit and integrating the angular velocity, but the rotor is driven by the electrical angle output from the RD conversion unit. A configuration may be adopted in which one pulse is generated for each rotation, and the rotation angle is estimated by counting the number of rotations of the rotor based on the number of pulses.
[0048]
【The invention's effect】
As is apparent from the above description, the present invention has the following effects.
[0049]
In an electric power steering apparatus using a three-phase brushless motor, the electrical angle of the brushless motor is detected by a resolver, and the failure of the steering angle sensor is detected based on the output of the resolver. be able to.
[0050]
In an electric power steering apparatus using a three-phase brushless motor, the electrical angle of the brushless motor is detected by a resolver, the rudder angle is detected based on the output of the resolver, and the rudder angle is estimated to be near the maximum rudder angle. In this case, since the current flowing through the brushless motor is reduced, heat generation in the motor control unit can be suppressed, and the electric power steering apparatus can be controlled satisfactorily.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of an electric power steering apparatus according to a first embodiment of the present invention.
FIG. 2 is a diagram showing a specific configuration of a main part and an electric system of a mechanical mechanism of the electric power steering apparatus.
FIG. 3 is a cross-sectional view taken along line AA in FIG.
4 is a cross-sectional view taken along line BB in FIG. 3. FIG.
FIG. 5 is a block configuration diagram of a control device.
FIG. 6 is a block configuration diagram showing a failure detection unit.
FIG. 7 is a graph showing a steering angle map corresponding to each integral value.
FIG. 8 is a flowchart illustrating the operation of the present embodiment.
FIG. 9 is a block configuration diagram of a control device.
FIG. 10 is a diagram illustrating a first specific example of a rudder angle neutral position determination unit.
FIG. 11 is a block configuration diagram of a rudder angle estimation unit.
FIG. 12 is a flowchart illustrating the operation of the present embodiment.
FIG. 13 is a graph showing a change in steering angle and a change in target current at that time.
FIG. 14 is a diagram illustrating a second specific example of the rudder angle neutral position determination unit.
FIG. 15 is a block diagram of a conventional electric power steering apparatus.
FIG. 16 is a block diagram of another conventional electric power steering apparatus.
[Explanation of symbols]
10 Electric power steering device
11 Steering wheel
12 Steering shaft
18 Power transmission mechanism
19 Brushless motor
20 Steering torque detector
20d Rudder angle sensor
22 Control device
23 Motor rotation angle detector (resolver)
100 Motor controller
101 Integration part
102 Failure detection unit
103 Failure indicator
104 Input signal switching section
200 Motor controller
201 Integration part
202 Rudder angle neutral position determination unit
203 Rudder angle estimation unit

Claims (1)

In an electric power steering device using a three-phase brushless motor,
A resolver for detecting the electrical angle of the brushless motor,
Integrating means for integrating the output signal of the resolver and outputting the integrated value;
The difference between the integral value output from the integrating means and the integral value at neutral time, and the ratio of the difference between the right maximum integral value in the case of right steering or the left maximum integral value in the case of left steering and the neutral time integral value Rudder angle estimating means for estimating the rudder angle by:
Wherein the steering angle estimated the steering angle is Ru maximum steering angle vicinity der equal to or larger than a predetermined value if the estimating means, and the motor current control means for reducing the current flowing in the three-phase brushless motor,
An electric power steering apparatus comprising: a.

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