JP3613691B2 - Vehicle steering system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle steering apparatus for steering a vehicle according to a driver's operation.
[0002]
[Prior art]
Steering of the vehicle is performed outside the vehicle compartment by operating a steering means arranged inside the vehicle compartment, for example, rotating the steering wheel to steer a steering wheel (generally, the front wheel). To the steering mechanism.
In recent years, a steering assist actuator such as a hydraulic cylinder or an electric motor is arranged in the middle of the steering mechanism, and this actuator is driven based on the detection result of the operation force applied to the steering wheel for steering. Power steering devices (power steering devices) that are configured to assist the operation of the steering mechanism according to the rotation of the steering wheel with the generated force of the actuator and reduce the labor burden on the driver for steering are widely used. ing.
[0003]
However, in such a conventional vehicle steering apparatus, it is necessary to mechanically connect the steering wheel, which is a steering means, and the steering mechanism, and the position of the steering wheel in the vehicle interior is outside the vehicle interior. There is a problem that it is limited to a position where it can be connected to the steering mechanism, and even if a steering wheel is arranged so that it can be connected, a complicated connecting structure is required to realize the connection. However, this is a factor that hinders weight reduction of the vehicle and simplification of the assembly process.
[0004]
For example, Japanese Utility Model Publication No. 2-29017 discloses a steering apparatus for a vehicle which is a linkless power steering for the purpose of solving such a problem. In this vehicle steering device, the steering wheel is separated from the steering mechanism, and an electric motor as a steering actuator is provided in the middle of the steering mechanism in the same manner as the steering assist actuator in the power steering device. The electric motor is driven on the basis of the detection result of the operation direction and the operation amount of the steering wheel, so that steering according to the operation of the steering wheel is performed.
[0005]
A reaction force actuator provided with a motor is attached to a steering wheel that is not mechanically connected to the steering mechanism. The reaction force actuator applies a reaction force toward the neutral position to the steering wheel by driving the motor based on the detection result of the vehicle speed and the steering angle of the steering wheel. This reaction force has a characteristic of increasing or decreasing depending on the vehicle speed and the steering angle.
The vehicle steering device detects torque applied to the steering wheel against the reaction force, and increases or decreases the motor current of the steering electric motor in accordance with the detection result, and the steering force generated by the electric motor. Increase or decrease. As a result, steering can be performed with a sense similar to that of a general vehicle steering device (connected steering device) in which the steering wheel and the steering mechanism are mechanically connected.
[0006]
The separation type vehicle steering apparatus configured as described above is a new steering that replaces the steering wheel such as a lever, a pedal, etc., in addition to the above-described purposes such as an increase in the degree of freedom of arrangement of the steering wheel and weight reduction of the vehicle. It is useful for the development of automobile technology in the future, such as realization of means, detection of guidance signs on the road surface, realization of an automatic driving system according to traveling information such as reception of satellite information.
[0007]
[Problems to be solved by the invention]
In the above-described vehicle steering device and the like, in order to perform the steering, the steering angle of the steering wheel, the steering torque applied to the steering wheel, the vehicle speed, the motor current of the steering electric motor, the current flowing through the reaction force actuator, the steering It is equipped with various sensors that detect various physical quantities, such as the steering angle of the mechanism, but if these sensors fail, the driver will continue to operate without noticing abnormalities unless he notices the failure, Even if you notice, you may not be able to immediately determine what went wrong. There is also a problem that the output signal of the sensor cannot be distinguished from sudden noise.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a vehicle steering apparatus that can immediately recognize a failure of a steering torque sensor.
[0008]
[Means for Solving the Problems]
Vehicle steering apparatus according to the first invention comprises a steering unit which is not mechanically connected to the steering mechanism for changing the orientation of the vehicle wheel, a reaction force toward the neutral position in the steering unit, the reaction force instruction instructed And a steering torque detecting means for detecting a steering torque applied to the steering means against the reaction force, and depending on a steering angle of the steering means. An upper limit value for determining whether or not the difference between the steering torque detected by the steering torque detecting means and the upper limit value of the reaction force instruction torque is greater than or equal to a predetermined value in the vehicle steering apparatus that controls increase and decrease of the steering angle of the mechanism. Determining means, a lower limit determining means for determining whether or not a difference between a lower limit value of the reaction force instruction torque and the steering torque is a predetermined value or more, and the upper limit determining means or the lower limit determining means is a predetermined value. When it is determined that the above is true, Steering torque, and out of range detection means that detect that the out of range of possible, when 該範囲外detecting means, which detects the presence of the range where the steering torque can be taken, the steering torque detected And determining means for determining that the means has failed.
[0009]
In this vehicle steering apparatus, out of range detecting means, the steering torque steering torque detecting means detects detects that lies outside the steering torque can be taken. Then, out of range detecting means, when it is detected that a range outside the steering torque can be taken, the determination means determines that the steering torque detecting means fails.
As a result, the driver can immediately notice a failure of the steering torque detecting means by a failure display, an alarm, etc., and can take appropriate measures such as driving stop and repair.
[0014]
In the vehicle steering apparatus according to the second aspect of the present invention, when the determination means continues to detect that the out-of-range detection means is outside the range that the steering torque can take, for a predetermined time, the steering torque detection means It is characterized by determining that a failure has occurred.
[0015]
In this vehicle steering apparatus, the determination means determines that the steering torque detection means has failed when the out-of-range detection means continues to detect that the steering torque is outside the range that the steering torque can take, for a predetermined time. Misjudgment due to sudden noise can be prevented.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings illustrating embodiments thereof.
FIG. 1 is a block diagram showing the overall configuration of an embodiment of a vehicle steering apparatus according to the present invention. This vehicle steering device is arranged separately from the steering mechanism 1 for causing the pair of steering wheels 10, 10 arranged on the left and right of the vehicle body (not shown) to steer, and the steering mechanism 1. A steering wheel 4 that is a steering means, a reaction force actuator 3 that applies a reaction force to the steering wheel 2, and a steering control unit 4 that uses a microprocessor are provided, and a steering control unit 4 that responds to the operation of the steering wheel 2 Thus, the steering motor 5 disposed in the middle of the steering mechanism 1 is driven to operate the steering mechanism 1.
[0017]
As is well known, the steering mechanism 1 includes both ends of a steering shaft 11 that extends in the left-right direction of the vehicle body and slides in the axial length direction, and knuckle arms 12 and 12 that support the wheels 10 and 10. The tie rods 13 and 13 are connected to each other, and the knuckle arms 12 and 12 are pushed and pulled through the tie rods 13 and 13 by sliding the steering shaft 11 in both directions to steer the wheels 10 and 10 left and right. The steering is performed by converting the rotation of the steering motor 5 coaxially configured in the middle portion of the steering shaft 11 into sliding of the steering shaft 11 by an appropriate motion conversion mechanism.
[0018]
The steering shaft 11 is constrained from rotating about a shaft by a rotation restricting means (not shown) interposed between the steering shaft housing 14 and the rotation of the steering motor 5 in the axial length direction of the steering shaft 11. And steering (steering of the steering wheels 10 and 10) according to the rotation of the steering motor 5 is performed.
The steering angle of the wheels 10 and 10 steered in this way is a steering angle sensor 16 which is a steering angle detection means, with the relative sliding position between the steering shaft housing 14 on one side of the steering motor 5 and the steering shaft 11 as a medium. The output of the steering angle sensor 16 is given to the steering control unit 4 together with the output of the rotary encoder 15 that detects the rotational position of the steering motor 5.
[0019]
A reaction force actuator 3 which is a reaction force applying means for applying a reaction force to the steering wheel 2 is an electric motor (for example, a three-phase brushless motor), and in relation to the rotating shaft 30, its casing is not shown as an appropriate part of the vehicle body. It is fixed and attached to. The steering wheel 2 is coaxially fixed to a protruding end on one side of the rotating shaft 30, and the protruding end on the other side is connected to an appropriate part of a vehicle body (not shown) by a twisted spring 31 having a predetermined elasticity. Yes.
[0020]
The reaction force actuator 3 is driven in both forward and reverse directions by energization from the drive circuit 3 a according to the reaction force instruction torque signal given from the steering control unit 4, and is operated on the steering wheel 2 attached to one end of the rotating shaft 30. Performs the action of applying force (reaction force) in the opposite direction to the direction. Therefore, it is necessary to apply a steering torque against the reaction force generated by the reaction force actuator 3 to rotate the steering wheel 2. The steering torque applied to the steering wheel 2 in this way is applied to the reaction force actuator 3. It is detected by an attached torque sensor 32 (steering torque detecting means). Further, the operation amount (steering angle) of the steering wheel 2 is detected including the operation direction by a rotary encoder 33 which is a steering angle detecting means attached to the reaction force actuator 3. It is given to the control unit 4.
In addition, the current that is supplied from the drive circuit 3 a to the reaction force actuator 3 is detected by the current sensor 3 b and is given to the steering control unit 4.
[0021]
Note that the torsion spring 31 interposed between the other end of the rotating shaft 30 and a part of the vehicle body rotates the rotating shaft 30 by its elasticity when the rotation operation performed as described above is stopped, thereby steering. The wheel 2 is returned to a predetermined neutral position. This return is necessary for returning the steering wheel 2 in accordance with the return operation of the wheels 10 and 10 in the straight traveling direction that occurs on the steering mechanism 1 side that is not mechanically connected.
[0022]
As described above, the steering state actually generated on the steering mechanism 1 side is given to the steering control unit 4 as input from the rotary encoder 15 and the steering angle sensor 16, and steering as a steering means is provided. The operation state of the wheel 2 is given as an input from the torque sensor 32 and the rotary encoder 33, respectively. In addition, on the input side of the steering control unit 4, a vehicle speed sensor 6 for detecting the traveling speed of the vehicle is provided. Output is given.
[0023]
On the other hand, as described above, the output of the steering control unit 4 is divided into the reaction force actuator 3 that applies a reaction force to the steering wheel 2 and the steering motor 5 that causes the steering mechanism 1 to perform a steering operation. The reaction force actuator 3 and the steering motor 5 perform different operations in response to an instruction signal from the steering control unit 4.
The current that is supplied to the steering motor 5 from the drive circuit 5 a is detected by the current sensor 7 and is given to the steering control unit 4.
[0024]
The steering control unit 4 determines a reaction force to be applied to the steering wheel 2 and performs a reaction force control for generating a reaction force instruction torque signal to the reaction force actuator 3 to generate the reaction force.
The reaction force to be applied to the steering wheel 2 becomes large or small according to the level of the vehicle speed given as an input from the vehicle speed sensor 6 and the magnitude of the steering angle.
[0025]
Further, the steering control unit 4 recognizes an operation angle including an operation direction of the steering wheel 2 by an input from the rotary encoder 33 and recognizes an actual rudder recognized by an input of a rudder angle sensor 16 attached to the steering mechanism 1. The rudder angle deviation from the angle is obtained, and the rudder angle deviation is corrected so as to become larger or smaller according to the slow speed of the vehicle speed given as an input from the vehicle speed sensor 6 to obtain the target rudder angle, and this target rudder angle is obtained The steering control operation for driving the steering motor 5 is performed. At this time, the input from the rotary encoder 15 is used as a feedback signal for checking whether or not the steering motor 5 has reached a desired rotational position.
[0026]
Hereinafter, the operation of the vehicle steering apparatus according to the present invention having such a configuration will be described with reference to a flowchart showing the operation.
FIG. 2 is a flowchart showing the operation of the vehicle steering apparatus according to the present invention. When detecting a failure of the torque sensor 32, the steering control unit 4 first detects and reads the steering torque T _S by the torque sensor 32 (S2). Next, the reaction force instruction torque upper limit value T _U related to the upper limit of the value that can be taken by the steering torque T _S stored in the memory is read (S4), and the steering torque T _S and the reaction force instruction torque upper limit value T are read. calculating a difference ΔT = T _S -T _U and _U (S6).
[0027]
Next, the steering control unit 4, when the steering torque T _S and the difference ΔT between the reaction force instruction torque upper limit value T _U is a predetermined value or more (S8), the steering torque T _S is possible steering torque T _S is It is determined that the torque sensor 32 is out of the range of values (S16).
The steering control unit 4, when ΔT is less than a predetermined value, reads a reaction force instruction torque lower limit T _L associated with the lower limit of the steering torque T _S possible values (S10), the reaction force instruction torque limit value T _L and calculates the difference [Delta] T ₌ T L -T _S between the steering torque _{T S} (S12).
[0028]
Next, the steering control unit 4, when the difference ΔT between the reaction force instruction torque limit value T _L and the steering torque T _S is a predetermined value or more (S14), the steering torque T _S is possible steering torque T _S is It is determined that the torque sensor 32 is out of the range of values (S16).
When ΔT is less than the predetermined value (S14), the steering control unit 4 determines that the torque sensor 32 is normal and returns.
[0029]
FIG. 3 is a flowchart showing the operation of the vehicle steering apparatus according to the present invention. Since the configuration of the present embodiment of the vehicle steering device according to the present invention is the same as the configuration of the embodiment of the vehicle steering device according to the present invention described above, the description thereof will be omitted. The steering control unit 4, when detecting the failure of the torque sensor 32 is first read a reaction force instruction torque T _M at that time (S20). Next, the steering torque T _S is detected and read by the torque sensor 32 (S22), and a deviation ΔT = T _M −T _S between the reaction force instruction torque T _M and the steering torque T _S is calculated (S24).
[0030]
Next, the steering control unit 4, when the absolute value of the deviation ΔT of the reaction force instruction torque T _M and the steering torque T _S is a predetermined value or more (S26), the steering torque T _S takes the steering torque T _S is The time parameter t = t + 1 is calculated assuming that it is out of the range of values to be obtained.
Next, the steering control unit 4, the time parameter t is a predetermined value when reached (predetermined time) (S30), the state is out of the range of the steering torque T _S possible value, it continues for a predetermined time Then, it is determined that the torque sensor 32 has failed (S32). If the time parameter t has not reached the predetermined value (predetermined time) (S30), the process returns.
[0031]
The steering control unit 4, when the absolute value of the deviation ΔT of the reaction force instruction torque T _M and the steering torque T _S is less than a predetermined value (S26), the steering torque T _S is the possible values steering torque T _S is Assuming that it is within the range, the torque sensor 32 is assumed to be normal, and the process returns with a time parameter t = 0.
In each of the embodiments described above, the case of the torque sensor 32 has been described. However, the present invention is not limited to the torque sensor 32. The same can be applied to the sensor (detection means).
[0032]
【The invention's effect】
With the vehicle steering apparatus according to the first aspect of the present invention, the driver can immediately notice a failure of the steering torque detection means, and can take appropriate measures such as driving stop and repair.
[0035]
According to the vehicle steering apparatus of the second aspect of the invention, the driver can immediately notice a failure of the steering torque detection means, and can take appropriate measures such as driving stop and repair. Further, it is possible to prevent erroneous determination due to sudden noise with respect to the failure of the steering torque detecting means.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of a vehicle steering apparatus according to the present invention.
FIG. 2 is a flowchart showing the operation of the vehicle steering apparatus according to the present invention.
FIG. 3 is a flowchart showing the operation of the vehicle steering apparatus according to the present invention.
[Explanation of symbols]
1 Steering mechanism 2 Steering wheel (steering means)
3 Reaction force actuator (Reaction force applying means)
3a, 5a Drive circuit 3b, 7 Current sensor 4 Steering control section (out-of-range detection means, determination means)
5 Steering motor 6 Vehicle speed sensor 32 Torque sensor (steering torque detection means)
33 Rotary encoder (steering angle detection means)

Claims (2)

A steering means which are not mechanically connected to the steering mechanism for changing the orientation of the vehicle wheel, a reaction force toward the neutral position in the steering unit, the reaction force applying means for applying on the basis of the reaction force instruction torque is instructed, Steering for a vehicle which includes a steering torque detecting means for detecting a steering torque applied to the steering means against the reaction force, and controls increase / decrease of the steering angle of the steering mechanism according to the steering angle of the steering means. In the device
Upper limit determination means for determining whether or not the difference between the steering torque detected by the steering torque detection means and the upper limit value of the reaction force instruction torque is greater than or equal to a predetermined value; the lower limit value of the reaction force instruction torque; When the difference between the steering torque and the lower limit value determining means for determining whether or not the difference is greater than or equal to a predetermined value, and the upper limit value determining means or the lower limit value determining means determines that the difference is greater than or equal to a predetermined value, the steering torque is: and out of range detection means that detect that it is in the range of possible, 該範囲外detecting means, when it is detected that a range outside the steering torque can be taken, the steering torque detecting means fails A vehicle steering apparatus comprising: a determination unit configured to determine 2. The vehicle according to claim 1, wherein the determination unit determines that the steering torque detection unit has failed when the out-of-range detection unit continues to detect that the steering torque is out of a possible range for a predetermined time. Steering device.

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