JP2562469B2 - Vehicle rear wheel steering system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention
A vehicle rear wheel steering device for steering the rear wheels together with the front wheels,
In particular, the present invention relates to a rear wheel steering system for a vehicle capable of changing and controlling the turning ratio of the rear wheels according to the vehicle speed.

[Prior Art] Conventionally, as a four-wheel steering system including a rear-wheel steering system of a vehicle, for example, as disclosed in Japanese Patent Publication No. 60-44185, front and rear wheels are operated in accordance with the operation of the steering wheel. It is known that the wheels are steered and the steering ratios of the front and rear wheels are changed according to the vehicle speed based on a predetermined steering ratio characteristic set in advance. Then, in this case, the above-described turning ratio characteristic is basically
At low vehicle speeds lower than the predetermined vehicle speed (35 km / h), the front and rear wheels are in opposite phases to enhance turning (turning) of the vehicle, and at the predetermined vehicle speed, the rear wheels are not steered so-called 2WS.
When the vehicle speed is higher than the predetermined vehicle speed, the front and rear wheels are in phase and the vehicle running stability (lane change stability)
Each is set to increase.

In such a conventional rear wheel steering device, when traveling on a curved road with a vehicle speed higher than a predetermined vehicle speed, the front and rear wheels are steered in the same phase, so that the so-called high-speed cornering characteristics are favorably maintained. Will be. Here, at the time of such high-speed cornering, for example, if an obstacle or the like is found ahead and a sudden break is stepped on, the vehicle rapidly decelerates,
As a result, the steering ratio suddenly changes in the opposite phase. For this reason, originally, in order to maintain a stable posture of the vehicle during cornering and to perform stable running,
Despite the fact that the front and rear wheels must step on the same phase, the same phase decreases, and consequently the vehicle is steered to the opposite phase, acting in the direction that causes yaw rate, thereby increasing the turning performance of the vehicle become. Such a phenomenon appears as a scooping phenomenon.

In particular, when the rear wheels lock and slip due to breaking, the vehicle speed sensor used to control the steering ratio of the front and rear wheels is the wheel speed, even though the vehicle body is actually traveling at a certain speed. Since it is for detecting, it instantly becomes zero. For this reason, the steering ratio is instantaneously changed to the maximum value of the opposite phase, and there is a possibility that the running state may fall into an unstable state due to the decrease in the grip force of the tire due to the locking. Yes.

Therefore, conventionally, for example, as shown in Japanese Utility Model Publication No. Sho 62-5974, when the vehicle speed-sensitive rear wheel steering device detects a sudden deceleration of the vehicle, the steering ratio of the front and rear wheels is changed. There is known a technique in which a steering angle (an angle in a direction in which a sliding angle is increased) corresponding to a traveling condition of a vehicle is obtained by setting the steering angle in the same phase range to prevent so-called tack-in.

Further, as disclosed in JP-A-59-81275, in a vehicle speed-sensitive rear wheel steering system of a vehicle, when a sudden deceleration of the vehicle is detected, a change in the steering ratio of the front and rear wheels is delayed. Therefore, a technique for preventing the above-mentioned scooping phenomenon is known.

Here, as means for detecting sudden deceleration of the vehicle, a vehicle speed sensor is used, and when the output of the vehicle speed sensor drops sharply, sudden deceleration is determined. It is known that sudden deceleration of the output of the vehicle speed sensor after the vehicle is depressed determines that rapid deceleration has occurred.

Further, as disclosed in Japanese Patent Laid-Open No. 59-81274, other means for replacing the technique of delaying the change of the steering ratio at the time of sudden deceleration, such as fixing the steering ratio or 2WS. It is known that the steering ratio is set to 0 so that

[Problems to be Solved by the Invention] However, in these related arts, after detecting a sudden deceleration of the vehicle, control of a turning ratio for preventing rake is executed. For this reason, the following problems occur.

That is, first, in the case of detecting the rapid deceleration of the vehicle, the time during which such rapid deceleration occurs is a very short time, for example, on the order of several hundred msec. on the other hand,
The sampling time of the vehicle speed sensor for controlling the steering ratio of the rear wheels is, for example, 131 msec at present. Therefore, in actual deceleration detection, the detection result obtained every 131 msec is 2 to 3 points, and the deceleration per unit time is calculated from such a small amount of information to accurately determine the current deceleration. It is impossible to determine whether or not to fall into the category of deceleration. As described above, in the related art, at present, only extremely inaccurate deceleration determination can be performed.

If the control for changing the turning ratio is performed based on the extremely inaccurate sudden deceleration determination, for example, the actual deceleration may not be a sudden deceleration but may be determined to be a sudden deceleration due to an erroneous determination. In the case of such a misjudgment,
Although the steering ratios of the front and rear wheels have to be set in opposite phases as the vehicle speed decreases, the same phase state is still maintained. Also, due to the actual sudden deceleration of the vehicle, the steering ratio of the front and rear wheels must be fixed, for example, to keep the running state safe. Therefore, there is a possibility that the steering ratio is not fixed and the phase is changed to the opposite phase. In this way, the running performance is significantly impaired due to the inaccuracy of the current vehicle speed sensor.

Further, in this vehicle speed sensor, since a contact type is conventionally used, so-called chattering may occur. When such chattering occurs in the vehicle speed sensor, the control mechanism determines sudden acceleration with a temporary increase in the input signal. On the other hand, when this chattering is completed, the original number of input signals is restored thereafter. Therefore, as a reaction to the previous sudden acceleration determination, the control mechanism determines the sudden deceleration.

In this way, the erroneous determination of sudden deceleration may cause a problem in running performance by fixing the steering ratio of the front and rear wheels to the same phase without having to fix the steering ratio to the same phase. .

As described above, in the vehicle speed-sensitive rear wheel steering device using the current vehicle speed sensor, inaccuracy of the vehicle speed sensor sometimes impairs the traveling performance and focuses only on sudden deceleration. It has been pointed out that an unnecessary turning ratio fixing operation or an erroneous turning ratio fixing operation is performed, which causes a problem in running performance.

On the other hand, when detecting sudden deceleration of the vehicle, even when the vehicle speed sensor and the brake sensor are used together, the following problems are pointed out in addition to the above-described problems of the vehicle speed sensor.

That is, when the vehicle is running on a rough road and the wheel tries to get over the bumpy part of the road surface while the brake is being stepped on, the rotation of the wheel momentarily drops and the above-mentioned sudden deceleration occurs. In some cases, the detection result of the vehicle speed sensor may fall into this category. In this case, if the running state is during cornering, conventionally, the steering ratio of the front and rear wheels is fixed to the same phase,
Originally, even if an attempt is made to perform cornering with good turning performance due to the opposite phase, it becomes impossible to turn well and the running performance is significantly impaired, which is a problem.

As described above, conventionally, during high-speed cornering, in order to avoid danger, when a sudden brake is applied, control for fixing the steering ratio of the front and rear wheels to the same phase is performed only by sudden deceleration by the vehicle speed sensor. Because of the attention, an unnecessary turning ratio fixing operation or an incorrect turning ratio fixing operation is performed, which causes a problem in running performance, which is a problem.

Here, in order to solve the above-described problem, the lock state of the wheel is detected, and from the time when the lock state is detected, the normal steering ratio control is stopped, and the lock for setting the steering ratio to the stable side is set. It is conceivable to execute the control.

In this case, the period for executing such lock control is
If it is continued unnecessarily even after the wheels are unlocked, the running property in normal running is impaired and the commercial property is deteriorated, which is a problem.

The present invention has been made in view of the above problems,
An object of the present invention is to detect the lock state of the wheel and perform the lock control in order to maintain a good traveling property in conformity with the running state during cornering, and the lock of the wheel is released. After that, the lock control is quickly released to return to the normal steering ratio control state to ensure the running stability in normal running and to improve the merchandise's rear wheel steering system. It is to provide.

[Means for Solving Problems] In order to solve the above problems and achieve the object, a rear wheel steering system for a vehicle according to the present invention detects a vehicle speed,
In a vehicle rear wheel steering device for steering rear wheels according to the detected vehicle speed and front wheel steering, a vehicle speed detecting means for detecting a vehicle speed, a lock detecting means for detecting a locked state of the wheels, and Setting means for setting the lock control state by changing the steering characteristic of the rear wheel from the normal first characteristic to the stable second characteristic when the locked state is detected by the detection means; The releasing means for releasing the lock control state by changing the steering characteristic in the setting means from the second characteristic to the first characteristic when a predetermined time has elapsed from the time when the wheel lock state was detected by the detecting means. And is provided.

[Operation] In the vehicle rear wheel steering system configured as described above, the lock control is configured to be released when a predetermined time has elapsed after the wheel lock was detected. In this way, when the predetermined time elapses,
The vehicle speed detected by the vehicle speed detecting means coincides with the actual vehicle speed when the vehicle speed is zero. In this way, by determining the release of the lock of the wheels, after the lock of the wheels is actually released, the lock control state is surely released, and the control state of the normal steering characteristic is returned to the normal state. The traveling stability in traveling is secured and the commercialability is improved.

[Embodiment] An embodiment of a rear wheel steering system for a vehicle according to the present invention will be described in detail below with reference to the accompanying drawings.

FIGS. 1 and 2 show a four-wheel steering mechanism 12 having a rear wheel steering device 10 according to one embodiment of the present invention.
In the figure, reference numerals FL, FR, RL, and RR indicate the four-wheel steering mechanism 12.
The left and right front wheels FL, FR are shown by the front wheel steering device 14 and the left and right rear wheels.
RL and RR are connected so as to be steered by the rear wheel steering device 10, respectively.

The front wheel steering device 14 described above is composed of a pair of left and right knuckle arms 16L and 16R and tie rods 18L and 18R, and a relay rod 20 that connects these left and right tie rods 18L and 18R. A steering wheel 24 is connected to the front wheel steering device 14 via a rack and pinion type steering mechanism 22. The steering mechanism 22 includes a first rack 28 formed on the relay rod 20.
And a first pinion 30 which is connected to a steering wheel 24 at the upper end and meshes with the first rack 28 at the lower end.
And a steering shaft 32 to which is attached. In this way, the left and right front wheels FL and FR can be steered according to the operation (rotation) of the steering wheel 24.

On the other hand, the above-described rear wheel steering device 10 has left and right knuckle arms 34L and 34R and tie rods 36L and 36R, and relay rods 38 that connect these tie rods 36L and 36R to each other, similarly to the front wheel steering device 14. A hydraulic power steering mechanism 26 is provided. The power steering mechanism 26 is fixed to the vehicle body and has a relay rod.
A power cylinder 40 having a piston rod 38 is provided.

In the power cylinder 40, a piston 40a is disposed so as to be movable in the axial direction so as to slide on the inner peripheral surface thereof. The piston 40a is integrally attached to the relay rod 38. The piston 40a allows the internal space of the power cylinder 40 to have two hydraulic chambers.
It is divided into 40b and 40c. These hydraulic chambers 40b, 40c
Are connected to a control valve 46 via pipes 42 and 44, respectively. The control valve 46 has an oil supply pipe 50 and an oil discharge pipe leading to a reserve tank 48.
52 two pipes are connected. The oil discharge pipe 52 has a hydraulic pump 54 driven by an engine (not shown).
Is interposed.

Here, the above-described control valve 46 is configured by a known spool valve type. The control valve 46 includes a tubular valve casing 46a integrally attached to the relay rod 38 via a connecting member 56,
A spool valve (not shown) fitted in the valve casing 46a is provided. In the control valve 46 configured as described above, one of the hydraulic chambers 40b (4
0c), the compressed oil is supplied from the hydraulic pump 54, and as a result, the driving force for the relay rod 38 is assisted.

Incidentally, the respective hydraulic chambers 40b, 40
c, set the relay rod 38 in the neutral position (rear wheel R
L, return spring 40d of the steering angle theta _R of RR is biased to a position) to be respectively zero, they are respectively mounted.

A second rack 58 is formed on the relay rod 26 of the front wheel steering device 14 at a position different from the first rack 28 constituting the steering mechanism 22. A second pinion 62 attached to the front end of a rear steering shaft 60 extending along the front-rear direction of the vehicle body is meshed with the second rack 58. This rear steering shaft 60
The rear end of the rear wheel steering device 10 is controlled by the steering ratio control mechanism 64.
Is joined to.

As shown in FIG. 2, the steering ratio control mechanism 64 has a control rod 66 slidably held along a movement axis defined along the vehicle width direction.
One end of the control rod 66 is connected to a spool valve inside the control valve 46.

The turning ratio control mechanism 64 includes a holder 68 having a base end formed in a U-shape. Support pins 70 are rotatably supported at both ends of the U-shape of the holder 68. A swing arm 72 is fixed to the center of the support pin 70 in a state perpendicular to the center. That is, the swing arm 72 is swingably supported by the holder 68 via the support pin 70. A support shaft 74 is fixed to the center of the holder 68. The support shaft 74 is rotatable in a casing (not shown) of the steering ratio control mechanism 64 fixed to the vehicle body about a rotation axis set to be orthogonal to the above-mentioned movement axis of the control rod 66. Supported by.

In other words, the support pin 70 of the swing arm 72 is positioned at the intersection of the above-described two axes (that is, the movement axis of the control rod 66 and the rotation axis of the support shaft 74), and Is set so as to extend in a direction orthogonal to. By rotating the holder 68 about the rotation axis together with the support shaft 74, the inclination angle between the support pin 70 at the tip thereof and the movement axis of the control rod 66 changes. That is, the swing arm 72 centered on the support pin 70
Is configured such that the inclination angle formed by the swing locus plane with respect to a plane orthogonal to the movement axis (hereinafter referred to as a reference plane) changes.

Further, one end of a connect glove 78 is connected to a tip end of the swing arm 72 via a ball joint 76. The other end of the connect rod 78 is connected to the control rod via the ball joint 80.
It is connected to the other end of 66. In this manner, the control rod 66 is displaced along the vehicle width direction according to the swing of the tip of the swing arm 72.

The above-described connect grove 78 has a disk-shaped rotating force applying member at a portion near the ball joint 76.
Insert the through hole formed in the eccentric part of 82 into the ball joint 84
Through so that it can swing. This rotational force applying member
82 is provided integrally with a large-diameter bevel gear 88 rotatably supported via a support shaft 86 which is coaxial with the movement axis of the control rod 66. The large bevel gear 88 meshes with a small-diameter bevel gear 90 attached to the rear end of the rear steering shaft 60 described above. In this way, the turning force of the steering wheel 24 is transmitted to the turning force imparting member 82.

Therefore, the turning force applying member 82 rotates by an amount corresponding to the turning angle of the steering wheel 24, and as a result, the connecting rod 78 pivots around the movement axis of the control rod 66. As a result, the swing arm 72
When the support pin 70 is swung about the center 70 and the axis of the support pin 70 is coincident with the movement axis of the control rod 66 (in the neutral position), the ball joint 76 at the tip of the swing arm 72 is used. Only swings in the above-described reference plane, and the control rod 66 does not move along the movement axis, and is kept stationary.

On the other hand, when the axis of the support pin 70 is inclined with respect to the movement axis and the swing locus surface of the swing arm 72 is displaced from the reference plane, the swing arm 72 around the support pin 70 is swung. Accordingly, the ball joint 76 is displaced in the vehicle width direction. As a result, this displacement is
Is transmitted to the control rod 66 via the. And
The control rod 66 moves along the movement axis, and the spool valve of the control valve 46 is operated.

That is, even if the swing angle of the swing arm 72 about the axis of the support pin 70 is the same, the displacement of the control rod 66 in the left-right direction is the inclination angle of the support pin 70, in other words, the holder 68. Will change with the change of the turning angle of.

In detail, the axis of the support pin 70 is
When the angle is formed so as to be deviated clockwise from the movement axis of the arm (when in the opposite phase position), the swing arm 72
The ball joint 76 at the tip swings so as to obliquely intersect the above-described reference plane, and the control rod 66 is biased rightward in the drawing in accordance with the right steering of the steering wheel 24. Then, due to the rightward deviation of the control rod 66, the rear wheels RL and RR are steered to the left as described later. In other words, in this reverse phase state, the rear wheels are steered in the direction opposite to the steered direction of the front wheels.

On the other hand, when the axis of the support pin 70 forms an angle that deviates in the counterclockwise direction from the axis of movement of the control rod 66 (when in the same phase position), the ball joint at the tip of the swing arm 72 is The int 76 oscillates so as to cross the reference plane obliquely on the side opposite to the opposite phase, and in response to the right steering of the steering wheel 24, the control rod 66
Is shifted to the left in the figure. The rearward bias of the control rod 66 causes the rear wheels RL and RR to be steered to the right as described later. In other words, in this in-phase state, the rear wheels RL, RR are steered in the same direction as the steering direction of the front wheels FL, FR.

On the other hand, the inclination angle of the support pin 70 with respect to the moving axis, that is,
In order to change the inclination angle of the holder 68 with respect to the reference plane,
A sector gear 92 as a worm wheel is integrally attached to the support shaft 74 of the holder 68. This sector gear
A worm gear 96 that rotates integrally with the rotation shaft 94 is meshed with 92. A bevel gear 98 is integrally attached to the rotating shaft 94. The bevel gear 98 meshes with a bevel gear 102 mounted coaxially with an output shaft 100a of a stepping motor 100 as a control motor.

In this way, by operating the stepping motor 100, the sector gear 92 rotates and the inclination angle of the holder 68 with respect to the reference plane is changed. In other words,
In accordance with the rotation drive amount of the scan Tetsu ping motor 100, the rear wheels RL, the front wheels FL steered angle theta _R of RR, same phase with respect to FR, opposite phase, so that the neutral state is changed controlled.

The sector gear 92 is centered on the worm gear.
The neutral position is defined at a position perpendicular to the center line of the rotation axis 94 of the 96. When the vehicle is turned clockwise as viewed from above the vehicle body from the neutral position, the steering ratio is changed to the rear wheel R.
L and RR are controlled to have opposite phases in the opposite directions to the front wheels FL and FR. On the other hand, when the wheel is turned counterclockwise, the steering ratio is controlled so that the rear wheels RL and RR face the same direction as the front wheels FL and FR.

Further, in the casing (not shown) of the steering ratio control mechanism 64 described above, in a state where it is located on the left and right sides of the sector gear 92, the opposite phase side and the same phase side formed of pins for regulating the rotation range of the sector gear 92 are provided. Stopper members 104 and 106 are attached. In this way, when the sector gear 92 rotates in the opposite phase image, when the rotation angle from the neutral position becomes, for example, −17.5 °, the sector gear 92 abuts on the opposite phase side stopper member 104 and further Rotation will be restricted.

When the sector gear 92 rotates in the same phase, if the rotation angle from the neutral position becomes, for example, 20 °, the sector gear 92 rotates.
Is in contact with the stopper member 106 on the same phase side, and further movement is restricted. Then, the sector gear 92 takes the position on the opposite phase side as the initial position,
The control position of the stepping motor 100 is defined.

In addition, rod stoppers 108 are provided on both sides of the connecting member 25 in order to restrict the maximum movement range of the relay rod 38 in the rear wheel steering device 10.

As shown in FIG. 1, an oil filter 110 is provided in the middle of the oil supply pipe 50 described above. Then, from the oil filter 110, a failsafe oil branch pipe 112 is branched separately from the oil supply pipe 50. The oil branch pipe 112 is bifurcated at the distal end, and the input ports of the fail-safe solenoid valves 114 and 116 are connected to the respective distal ends 112a and 112b. On the other hand, the output ports of these two sets of solenoid valves 114 and 116 are connected to return oil branch pipes 118a and 118b. These return oil branch pipes 118a and 118b are connected to the reserve tank 48 in a state where they are combined into one return oil pipe 118.

Here, each solenoid valve 114, 116 is energized with the turning-on operation of the ignition key of the vehicle, and the corresponding oil branch pipe is energized.
112a and 112b are configured to be closed, and to be opened in a state where they are not energized. As a result, both solenoid valves 114, 11
As long as 6 is closed, the hydraulic pressure from the hydraulic pump 54 will act on the control valve 46.
On the other hand, when a later-described fail detection is performed during the rear wheel steering operation, a fail-safe operation in which the energization state of both the solenoid valves 114 and 116 is cut off by the later-described control unit 132 is executed.

As a result, when one of the solenoid valves 114 and 116 is opened, the hydraulic pressure from the hydraulic pump 54 escapes to the reserve tank 48 without acting on the control valve 46. Therefore, the hydraulic pressure does not act on the power cylinder 40, and the relay rod 38 is pressed from both sides by the pair of return springs 40d and mechanically urged to the neutral position. That is, the fail-safe operates, and the rear wheels are mechanically fixed in the neutral position, in other words, the vehicle is in the two-wheel drive state (2WS).

Here, as described above, the turning ratio is defined at the rotational position of the sector gear 92. Therefore, the sector gear 92 is provided with a turning ratio sensor to detect a set turning ratio by detecting a turning angle of the sector gear 92.
120 is installed. Note that this steering ratio sensor 120
Are configured to output a zero value in the neutral position, a positive value in the same phase, and a negative value in the opposite phase.

On the other hand, as shown in FIG. 3, in this embodiment, in order to achieve a vehicle speed-sensitive four-wheel steering system,
It has first and second two vehicle speed sensors 122 and 124. The first vehicle speed sensor 122 includes a transaxle 126
A second vehicle speed sensor 124, mounted at the junction of the speedometer shaft 128 to, is mounted within the speedometer 130. As each of the vehicle speed sensors 122 and 124, a lead switch type is adopted, and the speedometer shafts are respectively provided.
It is configured to output an output signal of 4 pulses per one rotation of 128.

The above-described stepping motor 100 functions as a turning ratio changing means, and is configured such that its operation is controlled by an output from a control unit 132 having a built-in microcomputer as shown in FIG. The control unit 132 is configured to execute a fail-safe operation when a predetermined fail state occurs in the four-wheel steering state, as will be described in detail later. In this configuration, the steering ratio of the front and rear wheels is fixed to a steering ratio corresponding to the vehicle speed immediately before the detection of the lock, different from a normal characteristic set in advance.

Here, as shown in FIG. 4, the control unit 132 is supplied with a power supply voltage from a battery (indicated by + B in the drawing) via a relay type circuit 134. On the other hand, the above-described first and second solenoid valves 114, 116
The power supply voltage from the battery is also supplied to the stepping motor 100 via the relay / timer circuit 134. Further, the voltage from the relay / timer circuit 134 is supplied to the control unit 132 via an oil level switch 136 described later.

Further, an ignition switch (indicated by IG in the figure) is connected to the relay / timer circuit 134,
The power supply voltage from the battery is supplied to each part connected to the battery after a predetermined time elapses with the ON operation of the ignition switch. The L terminal of the alternator 138 is connected to the relay / timer circuit 134 for detecting a failure described later. When the input voltage at the L terminal is equal to or lower than a predetermined voltage, the control unit 132 disconnects the relay, stops supplying the voltage to each part, and interrupts the four-wheel steering control.

The control unit 132 detects the generated voltage value of the alternator 138, and is set so that the generated voltage value is equal to or higher than a predetermined voltage and a driving state of the engine at a predetermined rotation speed is detected.

Further, the relay / timer circuit 134 is configured to output a fail signal to the control unit 132 when the ignition voltage input accompanying the ON operation of the ignition switch described above is not 9 V or higher.

Here, as shown in FIG. 4, the control unit
First and second vehicle speed sensors 122 and 124, a break sensor 140 that is turned on when a break pedal is depressed, and an inhibitor switch 142 attached to a select lever are connected to 132.

The control unit 132 is configured to execute the following two types of file detection and the following file detection from various sensors connected to the control unit 132. That is, when the first and second vehicle speed sensors 122 and 124 output the vehicle speed sudden change signal, when the output values of the first and second vehicle speed sensors 122 and 124 are different,
When both output values are lost during traveling, when the calculated value of the rotation angle of the sector gear 92 due to the operation of the stepping motor 100 and the output value of the steering ratio sensor 120 are different, the output to both solenoid valves 114, 116 When the circuit is broken, disconnected or shorted, when the output circuit of the stepping motor 100 is broken, broken or shorted, or when the output of the steering ratio sensor 120 is out of the setting range, the reference output signal of the steering ratio sensor is If it cannot be read, the oil level switch in the tank of the hydraulic pump 54
When, for example, the 136 is turned on, a fail signal is set to be output to the control unit 132.

The control unit 132 receives the above-mentioned fail signal and drives the stepping motor 100 to forcibly shift to the 2WS mode or cut off the power supply to both the solenoid valves 114 and 116 according to the contents of the fail signal. The hydraulic pressure does not act on the control valve 46 and the pair of springs 40
Mechanically fixed by the urging force of d, or the rear wheel steering device 10
To interrupt the control operation by shutting off the voltage supply to the
It is configured to execute three types of fail-safe operations.

Here, in this embodiment, the rotation speed is 2,200 r.
At pm or more, when the OFF signal from the inhibitor switch 142, that is, when the select lever is brought to the travel setting position other than the N level (neutral position) or the P range (parking position), it is determined that the vehicle is in the actual traveling state. are doing. In this state, if the vehicle speed information is not output from the first and second vehicle speed sensors 122 and 124, as described above, it is determined in the control unit 132 that the vehicle speed sensor is determined to be abnormal and the fail detection is executed. I have.

The fail detecting operation itself is a control content without error. However, if the fail detecting operation is always executed to cause the fail safe operation, inconvenience occurs in the case described below. Therefore, in this embodiment, the fail detection operation based on the abnormality of the vehicle speed sensor is set to be prohibited.

That is, at the time of inspection of a vehicle at a repair shop or the like, in order to inspect whether or not the engine output is properly output, depress the accelerator pedal with the brake pedal depressed to forcibly stop the vehicle. There are tests to increase the engine speed. In this test, if the engine is normal, the engine speed will increase to the speed at which the maximum torque is exhibited. In such a test, if no restriction is placed on the fail detection, no vehicle speed information is output from both vehicle speed sensors 122 and 124 even though the traveling state is detected. Will be executed.

However, in this embodiment, when the brake pedal is depressed and the brake switch 140 is turned on, the above-described failure generation state is defined as a test, and in such a case, the failure detection is performed. Is set to be executed.

In this way, in this embodiment, the use of the break switch prohibits the useless failure detection operation during the test of the vehicle, thereby improving the workability of the test operation.

On the other hand, in the normal running state, the control unit 132 responds to the current running state, that is, the detected vehicle speed, in accordance with the normal first steering ratio characteristic shown by the solid line I in FIG. The steering ratio is set. Here, in the control unit 132, the first vehicle speed sensor 122 on the transaxle side and the second vehicle speed sensor 122 on the speedometer side
A step is performed to steer the rear wheels RL and RR based on a steering ratio determined according to the vehicle speed detected by the higher value of the two vehicle speeds detected by the vehicle speed sensor 124 of the vehicle. The driving of the ping motor 100 is controlled.

Note that this vehicle speed detection is executed by each vehicle speed sensor 122, 124 taking a moving average from the latest six vehicle speed information sampled every 131 msec.

Here, in the control unit 132, as a separate control independent of the above-described fail-safe operation, a lock control operation when a wheel is locked during running of the vehicle is set.

That is, as discussed in detail in the prior art, in this embodiment, the front and rear wheels are steered in phase when traveling on a curved road at a vehicle speed higher than the predetermined vehicle speed of 35 km / h. Therefore, the so-called high-speed cornering characteristic is maintained well. Here, during such high-speed cornering, if an obstacle or the like is found ahead, for example, a sudden break will be performed. When the wheels are locked due to the sudden braking, the actual speed of the vehicle does not suddenly decrease, but the vehicle speed information output from the first and second vehicle speed sensors 122 and 124 becomes zero. Therefore, the detected vehicle speed becomes lower than the predetermined vehicle speed, and the front and rear wheels are steered in opposite phases.

That is, during the cornering, the rear wheels are steered from the same phase to the opposite phase. For this reason, in order to maintain a stable posture of the vehicle during cornering and to run stably, the front and rear wheels must be stepped on in phase, but the steering is reversed to the opposite phase, and the yaw rate is reduced. Acting in the direction in which it is generated, the turning performance of the vehicle is sharply increased, and a so-called scooping phenomenon occurs,
The vehicle will spin and fall into danger.

In order to avoid such a danger, in this embodiment, when the control unit 132 detects the lock of the wheel, the danger avoidance control (hereinafter referred to as the lock control) for setting the steering ratio to the stable side is performed. Is called).

Here, the control unit 132 executes lock detection as follows. (1) When the brake pedal is depressed, the brake sensor 140
Is on, and (2) the detection result of the vehicle speed from the first vehicle speed sensor 122 is
When the vehicle speed becomes substantially zero, and (3) the detected vehicle speed immediately before the vehicle speed is substantially zero is determined from the detection result of the first vehicle speed sensor 122 is 30 km / h, the wheels are locked. It is set to judge it as something.

Here, the first vehicle speed sensor 12 in the above (2) is used.
The detection content of 2 is set to "substantially zero" because the reed switch type vehicle speed sensor currently used has poor detection accuracy and the detected vehicle speed as described in the conventional example. This is because zero is determined in the range of about 10 km / h to zero.

In the above (3), the detected vehicle speed immediately before the vehicle speed is substantially determined to be zero is the last detected vehicle speed among the six detection results used when the vehicle speed is substantially determined to be zero. 6 immediately before the sampling time of
This is defined by the average value of the detection results.

When the three conditions are satisfied, a lock determination is made. Based on the lock determination, the control unit 132 is set to execute the lock control described below.

That is, in this lock control, in order to maintain the running state on the stable side, a fixed operation of fixing the steering ratio of the front and rear wheels to the value of the steering ratio at the time when the vehicle speed immediately before the rock determination is detected is performed. To be executed. That is, the broken line in FIG.
As shown by II, in the case where the wheels are locked by suddenly stepping on the vehicle from a vehicle speed of 35 km / h or more, even if the vehicle speed detected by the first vehicle speed sensor 122 is substantially zero, the detection is performed. The subsequent steering ratio is fixed to the steering ratio on the same phase side at the point in time. By this operation of fixing the steering ratio, the steering ratio is maintained on the stable side, and the rear wheels are no longer steered. In this manner, in this embodiment, the traveling performance in a state where the wheels are locked is safely ensured.

As is clear from the above discussion, when the vehicle speed immediately before locking is 30 km / h or more and less than 35 km / h, the steering ratio on the opposite phase side is fixed. However, as described above, the turning ratio when the vehicle speed is 30 km / h or more and less than 35 km / h is almost a value of zero, and no inconvenience occurs even if the turning ratio is fixed at this value. Things.

Here, as described above, in the normal rear wheel steering control and the failure detection, the first and second vehicle speed sensors 122 and 122 are used.
Although 124 is used as the detecting means, only the first vehicle speed sensor 122 on the trunk axle side is used as the vehicle speed detecting means in the lock detecting operation, and the second vehicle speed sensor 124 on the speedometer side is used. Absent. That is, the first and second vehicle speed sensors 122 and 124 are connected to each other via a speedometer shaft 28. Here, since the speedometer shaft 128 is rigid but long, the variation in the rotation of the driven gear in the transaxle due to variations in the torsional direction and inertia during rotation transmission, etc., can be accurately and immediately. Second on the far side
Is not transmitted to the vehicle speed sensor 124.

As described above, in this embodiment, the two vehicle speed sensors 12 are used for normal rear wheel steering control and fail detection.
Although 2,124 are used, only one vehicle speed sensor, in particular, the first vehicle speed sensor 122 on the transaxle side is used in the lock detection operation. In this manner, the vehicle speed is detected with good responsiveness in the lock detection operation.

In this embodiment, two vehicle speed sensors 12
The comparison / examination operation of adopting the higher detected value after comparing the values of 2,124 is not executed. Therefore, the operation time of the detection operation is extremely short, and the above-described good responsiveness is further ensured.

Here, in this embodiment, as the contents of the above-mentioned fail control that is executed separately from the vehicle speed detection operation in the above-described lock detection operation, the output values of the first and second vehicle speed sensors 122 and 124 are the same.・ A mismatch is detected. And as long as both output values match,
The first vehicle speed sensor 122 is employed as vehicle speed detection means without fail detection.

However, for some reason, the first vehicle speed sensor
If the output of the second vehicle speed sensor 122 suddenly changes to zero and is output only from the second vehicle speed sensor 124, the second vehicle speed sensor
Without using the detection result from 124,
Based on the mismatch between the detection outputs from the two vehicle speed sensors 122 and 124, fail detection is performed, and the above-described fail-safe operation is performed.

Specifically, the fail-safe operation in this case is the first
Also, the state of energization to the second solenoid valves 114 and 116 is cut off, and the hydraulic circuit is cut off. By cutting the hydraulic circuit, the rear wheels RL and RR are fixed to a so-called 2WS state without being steered by the biasing force of the pair of coil springs 40d, even if the front wheels FL and FR are steered. Become. Further, the fail warning lamp 144 provided in the meter panel shown in FIG. 4 blinks once. Thus, the fail-safe operation is performed.

Here, in this control unit 132,
The failure detection based on the failure of the first vehicle speed sensor 122 as described above is not performed when the brake pedal is depressed and the brake switch 140 is turned on.
It is set so as to execute the lock control described above.
The failure detection based on the sudden change of the output of the first vehicle speed sensor 122 to zero is performed by the brake switch.
Set to run only when 140 is turned off.

That is, of the three conditions for the above-described lock determination, the state in which the detected vehicle speed from the first vehicle speed sensor 122 in (2) suddenly changes to substantially zero, and the first vehicle speed sensor 122 A state in which a failure occurs and information is not output rapidly is expressed as the same state. For this reason, in this embodiment, the control unit 132 uses the information that the output from the first vehicle speed sensor 122 when the brake switch 140 is turned on becomes zero for the lock determination, and the brake switch 140 The information that the output from the first vehicle speed sensor 122 in the off state is zero is
It is distinguished for use in file detection.

In this way, in this embodiment, even if the output of the first vehicle speed sensor 122 is reduced to zero when the wheel is locked due to the breaking operation while the vehicle is running, this is the case. Because it is based on
The lock detection operation is executed without detecting the file.

As a result, the output of the first vehicle speed sensor 122 becomes zero on the basis of the locking of the wheels during traveling, and thus the failure detection is performed, and the inconvenience occurs when the steering state is forcibly fixed to 2WS, that is, , For example, when the vehicle is running at a vehicle speed of 35 km / h or more and the wheel is locked due to a sudden break, the rear wheels must be fixed to the steering ratio of the same phase to maintain a stable running state. Nevertheless, since the operation of forcibly fixing to 2WS is executed based on the fail-safe, there is a problem that the rear wheels RL and RR are steered from the position steered in phase to the neutral position. Will be prevented.

On the other hand, in this embodiment, during traveling, the first vehicle speed sensor 122 is turned off while the brake switch 140 is off.
Means that the first vehicle speed sensor 122 detects a stopped state in a running state in which no breaking occurs.
Therefore, for the first time in this state, the first vehicle speed sensor 122
This means that the occurrence of an abnormal state such as a failure has been found, and the above-described failure detection is executed.

Further, in the control unit 132 described above, the following restriction conditions are imposed on the lock detection. That is, in the above-described lock detection operation, when the vehicle speed detection result from the first vehicle speed sensor 122 is accompanied by a sudden increase in the vehicle speed of a predetermined value abnormality, the lock detection is not executed,
In the first steering ratio characteristic shown by the solid line I in FIG.
Is set to steer.

More specifically, the control unit 132 detects the amount of change per second of the vehicle speed detection result from the first vehicle speed sensor 122. If it is determined that the amount of change in vehicle speed per second is a rapid increase exceeding the set predetermined value of 40 km / h, even if the lock detection state occurs immediately after that, in other words, For example, even if the three lock determination conditions described above are satisfied, the lock is not detected and the shift to the lock control is prohibited. Then, in such a lock control prohibited state, the rear wheels RL and RR are steered by the first steering ratio characteristic described above.

As described above, since the control unit 132 imposes a restriction condition on the rock detection, in this embodiment, when the traveling road surface has a low friction coefficient, in other words, the frozen road surface is In this case, when the so-called wheel spin state occurs by strongly depressing the accelerator pedal at the time of starting, the traveling performance of the vehicle body can be safely ensured.

That is, when wheel spin occurs at the time of starting, control of the vehicle body is lost, and the vehicle body may turn sideways. In this case, the driver operates the steering wheel 21 while trying to correct the posture of the vehicle body, and makes a sudden break to operate the vehicle body to stop the vehicle body. In this state,
When the wheel locks, the above-described three lock determination conditions are satisfied. However, in this embodiment, as described above, lock detection immediately after the determination of a sudden increase in vehicle speed is prohibited. Therefore, by executing the lock detection, the steering ratio is fixed to the steering ratio immediately before the lock detection, and the inconvenience caused by not returning to the normal steering ratio at the time of restart is reliably prevented.

Further, in this embodiment, since the restriction condition for the lock detection is imposed as described above, chattering in the vehicle speed sensor occurs as described in the related art, and although the actual vehicle speed does not change, the detection is not performed. The output alone will surely prevent the inconvenience caused by the sudden increase in vehicle speed.

That is, if the above-mentioned restriction conditions are not imposed, 40 km
When the brake pedal is depressed lightly at / h or more and this braking occurs, and this state of zero vehicle speed is detected even for a moment, the control unit 132 detects the wheel lock and detects the steering ratio. A fixed operation will be performed. However, the occurrence of chattering necessarily accompanies a sudden increase in vehicle speed. In this embodiment,
Since the lock detection operation is prohibited by the detection of the rapid increase in the vehicle speed, an unnecessary fixed operation of the steering ratio due to an erroneous operation of the vehicle speed sensor called chattering is prevented, and based on the first steering ratio characteristic described above, Normal steering ratio control is executed, and good stability is secured.

In the above description, the lock detection operation, the lock control operation in the control unit 132, and the various control operations associated therewith have been described.

However, when the lock control is executed based on the lock detection, the steering ratio is fixed to the steering ratio corresponding to the vehicle speed immediately before the lock detection as described above. Such an operation is necessary from the viewpoint of ensuring the safety of the running state, but is an unnecessary operation after the wheels are unlocked. Therefore, after the lock of the wheels is released in this way, the lock control operation is released as soon as possible, and the state in which the steering ratio is fixed is removed.
A normal steering ratio control operation must be performed. Therefore, in this embodiment, as described below, the lock control operation is released, in other words,
A return operation from the lock control state to a normal steering ratio control operation is specified.

Hereinafter, the return operation (lock release operation) will be described.

This return operation (lock release operation) is basically performed when it is determined that it is safe to release the lock control operation after the lock detection operation. Actual vehicle speed and first vehicle speed sensor 122
The first mode in which the release operation is executed when the vehicle speed detected by the above-mentioned substantially coincides with the second mode in which the release operation is executed when the detected vehicle speed is lower than the actual vehicle speed. It is set in the unit 132.

That is, in the first embodiment, after such a lock detection operation, the case where the actual vehicle speed substantially coincides with the vehicle speed detected by the first vehicle speed sensor 122 means that the wheels are not on the road surface. Means a state in which the grip is completely gripped, and it is determined that the user has escaped the danger state without slip. Here, such a substantial match between the actual vehicle speed and the vehicle speed detected by the first vehicle speed sensor 122 is determined when any of the following three conditions is satisfied. It is.

First, the first condition is that a period in which the locked vehicle can be reliably stopped under any condition (running condition, road surface condition) elapses. After this time has elapsed, in the state where the vehicle speed is zero (stopped state), as described above, after the lock detection operation, the actual vehicle speed and the first
The vehicle speed detected by the vehicle speed sensor 122 substantially coincides, and at this timing, the lock control operation is released. In this way, the normal steering ratio control operation as shown by the solid line I in FIG. 5 is restored.

In detail, after the lock is detected by the above three conditions being met and the lock control operation is started, the release period T ₁ for releasing this lock control operation is at a speed x km immediately before the vehicle is locked. When traveling, the cancellation period T ₁ (sec) = xC where C; constant.

Here, in this embodiment, the constant C is 0.
It is given as 142. And the value of 0.142 is a vehicle running on a road with a road surface friction coefficient of 0.2 at 120 km / h, a sudden brake was applied, and the wheels were locked,
It is a value calculated from 17 seconds, which is the time that the vehicle can stop when it keeps gliding on the road. The value of the road surface friction coefficient of 0.2 occurs, for example, in a frozen state of the road surface in a severe winter season in Scandinavian countries, and is a sufficient setting condition.

In this way, as shown in Figure 6A, for example, during traveling vehicle is 50 km / h, even shall apply in the case where the wheel suddenly Bureiki is depressed has lock, release time T ₁ is, 50 × 0.142 = 7.1 (seconds), so after 7.1 seconds, it is surely stopped.

In FIG. 6A, the solid line represents the first vehicle speed sensor 122.
, And the dashed line indicates the actual vehicle speed of the vehicle. As is apparent from the alternate long and short dash line in FIG. 6A, the vehicle is actually stopped in 3.6 seconds after the wheels are locked in this embodiment. In addition, this setting is performed according to FIGS.
The same applies to the 6D diagram.

Thus, by setting the first condition,
When the release described above time T ₁ is passed, for example, by the driver continues depressing the Bureikipedaru, no matter Bureikisuitsuchi 140 is made ON, already vehicles are those stopped reliably. Therefore, after this release time T ₁ elapses,
There is no difference even if the lock control is released and the normal turning ratio control operation is set.

In this way, in this embodiment, when the driver notices the stop state of the vehicle and tries to start again, the steering ratio is not fixed to the steering ratio immediately before the lock, Since the normal steering ratio control is executed, the traveling performance of the vehicle is maintained satisfactorily.

Next, a second condition for releasing the lock control operation will be described. The second condition is that the detected vehicle speed at the present time exceeds the vehicle speed immediately before the lock is detected.
By satisfying the second condition, the actual vehicle speed substantially matches the vehicle speed detected by the first vehicle speed sensor 122 at the vehicle speed immediately before the lock detection, and at this timing, The lock control operation is released.
In this way, the normal steering ratio control operation as shown by the solid line I in FIG. 5 is restored.

In detail, as shown in FIG.
While the vehicle is traveling at / h, the wheel is suddenly stepped on and the wheel is locked, so that the lock is detected and the lock control operation is started. Here, the driver notices that the vehicle has completely stopped and lifts his foot off the brake pedal,
There is a case where the vehicle is accelerated by depressing the accelerator pedal. In such a case, the wheels are gripped,
As shown by the solid line in the figure, the output of the vehicle speed sensor 122 increases in accordance with the depression of the accelerator pedal. Then, when the detected vehicle speed at the present time exceeds the vehicle speed immediately before the lock detection, the running stability of the vehicle cannot be secured unless the steering ratio is further changed to the same phase side.
Therefore, from the standpoint of traveling safety, the lock control operation is naturally canceled and the rear wheels are steered at the turning ratio according to the current vehicle speed.

On the other hand, under the second condition, the driver releases the brake pedal at a relatively fast time when the wheels are locked, in other words, before the actual vehicle speed is significantly reduced, the driver performs the brake. There is a case where the operation is released and the accelerator pedal is depressed. In this case, when the wheels grip the road surface, the output of the vehicle speed sensor 122 increases in accordance with the depression of the accelerator pedal, as indicated by the solid line in the figure. Then, as described above, when the detected vehicle speed at the present time exceeds the vehicle speed immediately before the lock detection,
Unless the turning ratio is further changed to the same phase side, the running stability of the vehicle cannot be ensured. Therefore, from the standpoint of traveling safety, the lock control operation is naturally canceled and the rear wheels are steered at the turning ratio according to the current vehicle speed.

As described above, in this embodiment, when the vehicle speed is to be accelerated after the detection of the lock, the lock control operation is canceled when the current detected vehicle speed is more than the vehicle speed immediately before the lock detection. Then, by starting the normal turning ratio control operation, traveling safety is ensured.

Next, the third condition for canceling the lock control operation will be described below. The third condition is that a constant vehicle speed is continuously input for a predetermined time T ₂ regardless of whether the break switch is on or off. That is, after the lock is detected,
Vehicle speed information from the predetermined time T ₂ by the first vehicle speed sensor 122 when entered, it releases the lock control operation is performed. In this way, the normal steering ratio control operation as shown by the solid line I in FIG. 5 is restored.

In detail, as shown in the left half of FIG.6C, for example, when the vehicle is traveling at 50 km / h, the wheels are locked by stepping on a sudden break, the lock is detected, and the lock control operation is started. Will be. Here, there is a case where the driver notices that the vehicle body is completely stopped, releases the brake pedal, and depresses the accelerator pedal to start the vehicle. In such a case, since the wheels are gripped, the output of the first vehicle speed sensor 122 increases as the accelerator pedal is depressed, as indicated by the solid line in the figure. Then, the vehicle speed information is continuously from the vehicle speed sensor 122, the output only 917msec set as the predetermined time T _2, since the wheels are grips, the steering ratio is set according to the detected vehicle speed Unless it is changed to the normal steering ratio control, the running stability of the vehicle cannot be ensured. Therefore, from the standpoint of traveling safety, the lock control operation is naturally canceled and the rear wheels are steered at the turning ratio according to the current vehicle speed.

On the other hand, under the third condition, as shown in the right half of FIG. 6C, when the driver is relatively fast with the wheels locked, in other words, when the actual vehicle speed does not decrease so much. Then, reduce the amount of depression of the brake pedal,
In some cases, the wheels are gripped on the road surface. in this case,
Since the foot is not released from the brake pedal, the break switch 140 is kept on. However, when the wheels grip the road surface, the output of the first vehicle speed sensor 122 returns as indicated by the solid line in the figure. Therefore, as described above, at the time point when 917 msec has elapsed from the time point at which the vehicle speed information is output from the first vehicle speed sensor 122, unless the steering ratio is changed according to the detected vehicle speed, the running stability of the vehicle is not changed. Cannot be secured.
Therefore, from the standpoint of traveling safety, the lock control operation is naturally canceled and the rear wheels are steered at the turning ratio according to the current vehicle speed.

Thus, in this embodiment, after the lock detection, only when the vehicle speed information is output a predetermined time T _2, the wheels have been grips the road surface, and the detected vehicle speed and the actual vehicle speed coincides Judge that it is. In such a state in which the wheels are gripped, whether the brake switch is on or off, the lock control is immediately released, and the normal steering ratio control operation is started, thereby improving the driving safety. Will be secured.

Next, the condition in the second mode for canceling the lock control operation, that is, the fourth condition will be described.

Under the above-described first to third conditions, as described above, when the detected vehicle speed and the actual vehicle speed match,
This means that the wheels are gripping the road surface, so there is no need to perform the lock control operation.It is set so that this lock post-birth operation is released and the normal steering ratio control operation is returned. ing.

However, the fourth condition is that the timing is judged to be sufficiently safe even if the lock control operation is canceled in real time without waiting for the detected vehicle speed and the actual vehicle speed to match as described above. It is set. That is, the fourth condition, after the Bureikisuitsuchi 140 is turned off operation, are set by the predetermined time T ₂ has elapsed. This fourth
By satisfying the condition of, the wheel is moving in the direction of gripping the road surface after the break is released,
The actual vehicle speed and the vehicle speed detected by the first vehicle speed sensor 122 will eventually substantially match. Then, the lock control operation is canceled at this timing, thereby returning to the normal steering ratio control operation as shown by the solid line I in FIG.

More specifically, as shown in the right half of FIG. 6D, for example, while the vehicle is running at 50 km / h, the driver accidentally steps on a sudden break and the wheels are temporarily locked. In this locked state, if the driver notices that the wheels are locked,
When the foot is released from the brake pedal, the wheel operates in a direction to grip the road surface. In this case, when the foot is released from the brake pedal, the brake switch 140 is turned off. From the time when the brake switch 140 is turned off, a predetermined time T ₂ , in this embodiment, 786 msec
Is set, the lock control operation is canceled and the normal steering ratio control operation is restored.

That is, since the sampling time of this 786 msec is 131 msec, under the fourth condition, the control contents are changed from the lock control by waiting for the input of the six vehicle speed information.
It is intended to return to the normal steering ratio control. Here, as described above, the vehicle speed is set to be calculated by taking the moving average of six pieces of vehicle speed information. In this way, the fourth condition is that six wheels necessary for taking the moving average are taken from the time when the locked state of the wheels is released by the break release and the vehicle speed information starts to be output from the first vehicle speed sensor 122. 786m, the time when vehicle speed information is output
Waiting sec, it is set to be satisfied.

Here, 786mse after the break was released like this
Since the detected vehicle speed at the time when c has elapsed is the average value of the six pieces of vehicle speed information up to that point, even if the vehicle speed at this time actually matches the actual vehicle speed, the detected vehicle speed does not match the actual vehicle speed. It does not. However, as described above, such a behavior of the vehicle is caused by an excessive depression due to an erroneous operation of the brake pedal by the driver. Therefore, unlike the above three conditions, the vehicle travels relatively stably. Is what it is. Thus, before 3
Unlike the condition, it is possible to return to the normal steering ratio control operation without causing any problem without waiting for the actual vehicle speed to match the detected vehicle speed.

In addition, under the fourth condition, in other words, at a stage before the detected vehicle speed matches the actual vehicle speed, the lock control is positively released to return to the normal steering ratio control operation. ing. For this reason, the detected vehicle speed at the time of return is slower than the actual vehicle speed. Here, in order to change and control the turning ratio, the above-described stepping motor 100 is directly driven by the stepping motor 100 in accordance with an instruction from the control unit 132 so as to achieve the turning ratio according to the detected vehicle speed information. Is what is done. The operating speed of the stepping motor 100 is in the operating range, in other words,
It is set so as to change according to the change width of the detected vehicle speed.

Therefore, if the vehicle returns to the normal steering ratio control operation, the actual vehicle speed information is directly input to the control unit 132, and based on this, the control unit 132 attempts to drive-control the stepping motor 100. Then, since the vehicle speed information up to now has been zero, the stepping motor 100 is operated with a short operation time to make up for the difference. In this way, the rear wheels RL and RR are steered rapidly, and in the worst case, there is a possibility that the so-called scooping reduction as described above may occur.

However, in this embodiment, when returning to the normal steering ratio control operation, the vehicle speed information based on the actual vehicle speed is not input to the control unit 132, but the six vehicle speeds including the zero information are used. A value obtained by averaging the information is employed as detected vehicle speed information. As a result, the detected vehicle speed is certainly lower than the actual vehicle speed. In this manner, at the beginning of the return, the stepping motor 100 is driven and controlled based on the detected vehicle speed lower than the actual vehicle speed, so that the rear wheels RL and RR are relatively loosely steered and the above-described problem does not occur. become.

The detected vehicle speed gradually approaches the actual vehicle speed as the sampling time of 131 msec elapses. As a result, the stepping motor 100 can also operate by following the change in the vehicle speed information, and the stepping motor 100 does not have an unreasonable operating state, and a good operating state is achieved. It will be.

This concludes the description of the release operation of the lock control operation, in other words, the return operation from the lock control state to the normal steering ratio control operation, and will now be described with reference to the flowcharts shown in FIGS. 7A and 7B. With reference to the control unit described above
A schematic control procedure of a series of lock control operations in 132 will be described.

The control procedure shown in FIG. 7A and FIG.
It is executed every sampling time of c. That is, when this control procedure is started, first, in step S1, it is determined whether or not the lock flag F is "1". Here, the lock flag F is set to 0 when the control operation is activated, and is set to 1 when the lock detection operation described later is executed. In this step S1, if the lock flag F is set to 0, the lock detection operation is started, and if 1 is set, as described later, the process skips to step S13, where Matching of second vehicle speed sensors 122 and 124
It is set to exercise control to detect inconsistencies.

If NO is determined in step S1,
In other words, if it is determined that the lock flag F is 0, a rapid increase in vehicle speed is determined in steps S2 and S3 based on the wheel spin of the wheels, the sensor chattering, and the like. That is, in step S2,
The increase change amount D ₂ of the output of the second vehicle speed sensor 124 on the speedometer side, specifically, is defined by the difference in the increasing direction between the vehicle speed detection result detected at the previous sampling timing and the vehicle speed detection result detected this time. that numeric D ₂ is the predetermined value, in this embodiment, whether or not 7km / h / 131msec or more is determined. This predetermined value is set at an acceleration speed of 7 km / h per sampling time, and approximately 53 km / h per second.
Is equivalent to the amount of change.

In this step S2, if it is determined that the NO, that is, when the increasing change amount D ₂ of the output of the second vehicle speed sensor 124, is determined to be smaller than the predetermined value, in step S3, the transaxle side increasing the amount of change D ₁ of the output of the first vehicle speed sensor 122, a predetermined value, in this embodiment, whether or not 7km / h / 131msec or more is determined.

Then, in step S2 or step S3, YES
If it is determined that, i.e., increase the amount of change in the output of the first vehicle speed sensor 122 D ₁ or, when increasing the amount of change D ₂ of the output of the second vehicle speed sensor 124, it is determined to be larger than a predetermined value It is determined that the vehicle speed is rapidly increasing, and the flag A indicating the vehicle speed rapidly increasing condition is set to 1 in step S4.
Here, when the vehicle speed rapid increase flag A is 1, the vehicle speed is rapidly increasing, and the lock detection operation is prohibited. On the other hand, if the vehicle speed rapid increase flag A is 0, it indicates that the vehicle speed is not rapidly increasing, and the lock detection operation and the lock control operation are performed.

In the vehicle speed rapid increase state, the lock detection operation is not executed as described above, and therefore, as described below,
Even if this sudden increase in vehicle speed is due to the chattering peculiar to the sensor, the control procedure is set to return and return to the initial state.

In other words, after the flag A is set to 1 in step S4, if the above-mentioned rapid vehicle speed increase state is chattering in step S5, it is determined whether or not the chattering has been completed. In this decision,
If the outputs of both vehicle speed sensors 122 and 124 are both 56 km / h or less, it is determined that chattering has been completed. If the determination in step S5 is NO, that is, if it is determined that the vehicle speed detected by the two sensors 122 and 124 is equal to or higher than 56 km / h and that the chattering has not yet been completed, the lock detection operation is not performed. Must be set as follows. Therefore, as described above, the control procedure returns to the initial state.

On the other hand, if YES is determined in step S5,
That is, when the outputs of both vehicle speed sensors 122 and 124 both reach 56 km / h or less, it is determined that the chattering is coming to an end. Therefore, in this case, it is determined in step S6 whether a predetermined time, for example, 0.786 seconds has elapsed after the rapid increase determination was performed. That is, when the detected vehicle speed drops to 56 km / h or less, this 0.
After the elapse of 786 seconds, it can be determined that chattering is substantially completed, and the above-described determination is performed.

If NO is determined in this step S5, that is, if 0.786 seconds have not yet elapsed, the lock detection must still be prohibited, so the control procedure returns and returns to the initial state. . On the other hand, in step S5, if YES is determined, that is, if 0.786 seconds have elapsed, the rapid increase in vehicle speed is, for example, whether it is based on the wheel spin or the cheat ring. It is determined that the vehicle speed sudden increase flag A is set to 0 in step S7, and the control procedure returns.

On the other hand, if it is determined to be NO in step S3 described above, that is, if it is determined that the vehicle speed is not in the rapid increase state, it is determined in step S8 whether the vehicle speed rapid increase flag A is 1. If the determination in step S8 is YES, that is, if it is determined that the vehicle speed is rapidly increasing, the vehicle speed is rapidly increased by wheel spin, but the vehicle speed is not rapidly increased by chattering. Therefore, the process returns to step S5, and waits until the chattering is completed.

If the determination in step S8 is NO, that is, if it is determined that the vehicle speed is not rapidly increasing, the lock detection operation and the lock control operation will be executed below.

That is, if the vehicle speed rapid increase flag A is 0, it is determined in step S9 whether the brake switch 140 is on. Then, in this step S9,
If the determination is YES, that is, if the break switch 140 is on, in step S10, the first sampling time of the previous sampling time, in other words, 131 msec before, is set.
It is determined whether the vehicle speed detected by the vehicle speed sensor 122 is faster than 30 km / h.

If YES is determined in this step S10, that is, if it is determined that the preceding vehicle speed detection value is faster than 30 km / h, in step S11, the first vehicle speed sensor 122 detects the current detection operation. It is determined whether the vehicle speed is substantially 0 km / h. If it is determined YES in this step S11, that is, if it is determined that the current detected vehicle speed is substantially 0 km / h, as described above, the three conditions for detecting the lock are satisfied. Since it is satisfied, lock detection will now be performed.

Based on this lock detection, the lock flag F is set to 1 in step S12. On the other hand, if NO is determined in each of the above-described steps S10 and S11, the lock detection is not established, so that the process returns to step S9 and executes step S9.

After the lock flag F is set to 1 in step S12, it is determined in step S13 whether the detection result of the first vehicle speed sensor 122 matches the detection result of the second vehicle speed sensor 124. If NO is determined in this step S13, that is, if the detection outputs of the two sensors 122 and 124 do not match, since the state is the fail state as described above, the failsafe control operation is executed in step S14. And return.

On the other hand, if YES is determined in step S13, that is, if the two detected vehicle speeds are the same, the lock detection described above is performed in a normal state, and therefore, in step S15, the lock described above is performed. Start the control operation.

Here, the reason why the determination that the lock detection is performed in the normal state is necessary is as follows. That is, as mentioned above,
In this lock detection, only the first vehicle speed sensor 122 is used for vehicle speed detection. If the normal state is not determined in this step S13, the output of the second vehicle speed sensor 124 is different from the output of the first vehicle speed sensor 122, and this file has to be actually detected as a file. No detection will be performed. As a result, the lock may be detected based on the detection result of the first vehicle speed sensor 122 which may be incorrect.

After the lock control operation is started in step S15, it is determined in step S16 whether any of the above four lock release conditions is satisfied. If the determination in step S16 is NO, that is, if no lock release condition is satisfied, the process returns to step S15, and the lock control operation is continued.

On the other hand, if it is determined YES in step S16,
That is, if any lock release condition is satisfied, the lock control operation is released in step S17,
The normal turning ratio control operation is restored. And
In step S18, the vehicle speed sudden increase flag A is set to 0 and the control operation is returned to the initial state.

Here, if the determination in step S9 is NO, that is, if it is determined that the brake switch 140 is off, the lock detection operation described above is not executed. Then, in steps S19 and S20, a sudden decrease in the output of each of the vehicle speed sensors 122 and 124 is determined for fail detection.

That is, in step S19, it is determined whether the output value of the first vehicle speed sensor 122 has sharply decreased. This determination is based on the deceleration change amount E ₁ of the output of the first vehicle speed sensor 122 on the transaxle side, specifically, the deceleration direction between the vehicle speed detection result detected at the previous sampling timing and the vehicle speed detection result detected this time. numerical E ₁ defined by difference, the predetermined value, in this embodiment, whether or not 10km / h / 131msec or more is determined. This predetermined value is 10 per sampling time.
km / h deceleration, about 76km per second
/ h.

If YES is determined in this step S19, that is, if the first vehicle speed sensor 122 determines that the vehicle speed sharply decreases, a failure is detected and the above-described step is performed.
Skipping to S14, the failsafe control operation is executed.

Also, in step S19, if it is determined NO,
That is, if the first vehicle speed sensor 122 does not determine a rapid decrease in vehicle speed, then in step S20, a rapid decrease in the output value of the second vehicle speed sensor 124 is determined. This determination deceleration change amount E ₂ outputs of the second vehicle speed sensor 124 of the speedometer side, a predetermined value, in this one embodiment, 10 km / h / 1
It is determined whether it is 31 msec or more.

If the determination in step S20 is YES, that is, if the second vehicle speed sensor 124 determines that the vehicle speed has sharply decreased, a failure is detected and the above-described step is performed.
Skipping to S14, the failsafe control operation is executed.

Also, in step S20, if the determination is NO,
That is, if the first and second vehicle speed sensors 122 and 124 do not determine a rapid decrease in vehicle speed, step S2 is executed.
At 1, it is determined whether the detection result of the first vehicle speed sensor 122 and the detection result of the second vehicle speed sensor 124, which have the same contents as in step S13 described above, match. NO at this step S21
If it is determined, that is, if the detection outputs of the two sensors 122 and 124 do not match, as described above, it is in the fail state, and therefore the step S14 is skipped to execute the fail-safe control operation. To do.

On the other hand, in this step S21, if it is determined to be YES, that is, if the detection outputs of the vehicle speed sensors 122 and 124 match, it is not in a fail state, so return,
It returns to the initial state of the control operation.

 As described above, a series of control operations ends.

As described above in detail, in this embodiment, the wheel lock is detected, and in accordance with the detection result, the vehicle speed sensitive four-wheel steering device with the wheel locked prevents the danger of traveling. In order to solve the above-mentioned problems, it is not necessary to mount a so-called anti-lock break system (ABS) for preventing the locking of the wheels.

Needless to say, the present invention is not limited to the configuration of the above-described embodiment, and various modifications can be made without departing from the scope of the invention.

For example, in the above-described embodiment, in the lock control operation, basically, the normal steering ratio control indicated by the solid line I in FIG. 5 is stopped to maintain the running state of the vehicle on the stable side. The steering ratio is set so as to be controlled with specific characteristics, and specifically, is set so as to be fixed to a steering ratio corresponding to the vehicle speed immediately before the lock is detected.

However, the present invention is not limited to fixing the steering ratio according to the vehicle speed immediately before the detection of the lock as lock control on the stable side different from the normal steering ratio control. As shown by a chain line III as a first modified example, as a mode for setting the running state to the stable side in the lock control, the steering ratio is fixed to 0 and the 2WS is forcibly set.
It may be configured to set to.

Although not shown, as an aspect of setting the running state to the stable side in the lock control, as a second modification, a delay control may be performed. That is, in the second modification, the lock control when the lock is detected has the same characteristics as the normal steering ratio control, but the change speed is set to be slow, in other words, stepping. The operation speed of the motor 100 is set to be low. As a result, in the lock control on the stable side in the second modified example, although the steering ratio changes according to the characteristic shown by the solid line I in FIG. The time during which the turning ratio is changed to the opposite phase according to the vehicle speed is set to be long.

Specifically, the steering ratio changes from the same phase side to the opposite phase with a delay when the actual vehicle speed reaches zero due to friction while the brake pedal is continuously depressed and the wheels are slipping. Then, the steering ratio is set to be near zero to some extent.

As described above, by setting the control content on the stable side in the lock control as in the first and second modified examples, the stable control is sufficiently implemented, though not as stable as the content of the one embodiment. The effect that the return timing is set faster when the lock state is released and the control is returned to the normal control is achieved.

That is, in the above-described embodiment, the steering ratio according to the detected vehicle speed immediately before the lock is detected is fixed according to the lock detection. On the other hand, when the lock state is released, when the normal steering ratio control is resumed, the vehicle speed at the time of return, for example, if the vehicle is stopped, the vehicle speed determined to be 0 km / h. The setting is changed to the steering ratio corresponding to the steering ratio. Therefore, assuming that the steering ratio fixed according to the lock detection is on the same phase side, the stepping motor 100 must be driven to change the steering ratio to the opposite phase side. In this way, this stepping motor
Until the 100 operates and finishes the setting operation to the predetermined turning ratio, the normal turning ratio control operation is not substantially started.

On the other hand, in the first modified example, the steering ratio is fixed to zero at the time when the lock control operation is released, and in the second modified example, the steering ratio is roughly adjusted. Has reached zero. In this way, in the first and second modifications, the time required for the return operation can be shorter than in the case of the first embodiment, and the actual return timing can be set earlier. Will be achieved.

[Advantages of the Invention] As described in detail above, the vehicle rear wheel steering system according to the present invention detects the vehicle speed and steers the rear wheels according to the detected vehicle speed and the steering of the front wheels. In the rear wheel steering system, a vehicle speed detecting means for detecting a vehicle speed, a lock detecting means for detecting a locked state of the wheels, and a steering characteristic of the rear wheel when the locked state is detected by the lock detecting means, Setting means for changing the normal first characteristic to the second characteristic on the stable side to set the lock control state, and setting when a predetermined time has elapsed from the time when the lock state of the wheel was detected by the lock detecting means. And a releasing means for releasing the lock control state by changing the steering characteristic in the means from the second characteristic to the first characteristic.

Therefore, according to the present invention, at the time of cornering traveling, in order to maintain good traveling performance in conformity with the traveling state, the wheel locking state is detected when the locking state of the wheel is detected and the locking control is performed. After the lock is released, the lock control is quickly released to return to the normal control state of the steering characteristics to ensure the running stability in normal running and to improve the commercialability of the vehicle. A wheel steering system will be provided.

[Brief description of drawings]

FIG. 1 is a plan view schematically showing the structure of a four-wheel steering mechanism equipped with an embodiment of the rear wheel steering system for a vehicle according to the present invention; FIG. 2 is a schematic view showing the structure of the rear wheel steering system. FIG. 3 is a perspective view showing the setting states of the first and second vehicle speed sensors; FIG. 4 is a connection diagram of the control unit of the rear wheel steering system; FIG. 5 is various characteristics in turning ratio control. 6A to 6D are timing charts for explaining four lock control release conditions respectively; and FIGS. 7A and 7B are schematic control procedures of the control unit. It is a flow chart shown. In the figure, 10: rear wheel steering device, 12: four wheel steering mechanism, 14:
… Front wheel steering device, 16L; 16R …… Nickle arm, 18L; 18R
… Tie rod, 20… relay rod, 22… steering mechanism, 24… steering wheel, 26… power steering mechanism, 28… first rack, 30… first pinion, 32… steering shaft, 34L; 34R ……
Knuckle arm, 36L; 36R ... Tie rod, 38 ... Relay rod, 40 ... Power cylinder, 40a ... Piston, 4
0b; 40c …… Hydraulic chamber, 40d …… Return spring, 42; 44
... pipe, 46 ... control valve, 46a ... valve casing, 48 ... reserve tank, 50 ... oil supply pipe, 52 ... oil discharge pipe, 54 ... hydraulic pump, 56 ... connecting member, 58 ... ... second rack, 60 ... rear steering shaft, 62 ... second pinion, 64 ... steering ratio control mechanism,
66 …… Control rod, 68 …… Holder, 70 …… Support pin, 72 …… Swing arm, 74 …… Support shaft, 76 …… Ball joint, 78 …… Connecting rod, 80 …… Ball JOINT, 82 …… Rotating force imparting member, 84 …… Ball JOINT, 86 …… Support shaft, 88 …… Large bevel gear, 90 …… Small bevel gear, 92 …… Sector gear, 94 …… Rotary shaft, 96 ...... Worm gear, 98 ... Bevel gear, 100 ... Stepping motor, 1
00a output shaft, 102 bevel gear, 104; 106 stopper member, 108 rod stopper, 110 oil filter 112 oil branch pipe 112a; 11b tip, 114; 116
Solenoid valve, 118, return oil pipe, 118a; 118b, return oil branch pipe, 120, steering ratio sensor, 122, first vehicle speed sensor,
124: second vehicle speed sensor, 126: transaxle,
128… Speedometer shaft, 130… Speedometer, 13
2 ...... Control Units -, 134 ...... relay timer circuit, 136 ...... oil level Sui Tutsi, 138 ...... alternator, 140 ...... Bureikisensa, 142 ...... inhibitor task i Tutsi, 144 ...... Fueiru warning lamp, theta _{R ......} steering Horn, FL ...
… Front left wheel, FR …… right front wheel, RL …… left rear wheel, RR …… right rear wheel.

Claims (2)

(57) [Claims] 1. A vehicle rear wheel steering system for detecting a vehicle speed and steering a rear wheel according to the detected vehicle speed and steering of a front wheel, a vehicle speed detecting means for detecting a vehicle speed, and a wheel lock. Lock detecting means for detecting the state, and when the lock state is detected by the lock detecting means, the steering characteristic of the rear wheel is changed from the normal first characteristic to the stable second characteristic and locked. Setting means for setting a control state, and when a predetermined time has elapsed since the wheel lock state was detected by the lock detecting means, the steering characteristic in the setting means was changed from the second characteristic to the first characteristic. do it,
A rear wheel steering device for a vehicle, comprising: a release unit that releases a lock control state. 2. The releasing means is a time required to stop for a predetermined time due to friction between a wheel and a road surface when the brake pedal is continuously depressed and the wheel slides on the road surface in a locked state. The rear wheel steering system for a vehicle according to claim 1, wherein the rear wheel steering system is set as follows.