JP6793573B2 - Stabilizer link, stabilizer link device, and stabilizer device - Google Patents

Description

The present invention relates to a stabilizer link that connects a wheel support member and a stabilizer bar, a stabilizer link device having the stabilizer link, and a stabilizer device including the stabilizer link device.

Conventionally, a vehicle such as an automobile is provided with a stabilizer device for improving running stability during turning. This stabilizer device is composed of a stabilizer bar which is a torsion spring and a stabilizer link which connects both ends of the stabilizer bar to a suspension arm or the like that supports the left and right wheels.

In such a stabilizer device, there is a so-called active stabilizer device in which the function of the stabilizer is released when the vehicle goes straight by a signal from the vehicle sensor, and the function is improved by twisting the stabilizer bar when turning. Specifically, this active stabilizer device detects the roll generated during turning, calculates the rotation angle, and rotates the actuator (motor) by the required amount to enhance the stabilizer function and suppress the roll of the vehicle. ..

Further, in this stabilizer device, in order to further improve the stabilizer function, a configuration is known in which the length of the stabilizer bar in the vehicle width direction is expanded and contracted by an actuator according to the roll angle of the vehicle (see, for example, Patent Document 1). .).

However, in this configuration, only the expansion and contraction of the stabilizer bar common to both the left and right wheels is controlled, and more precise roll control is not easy.

In this respect, for example, a configuration is known in which more precise roll control is possible by adjusting the positions of the left and right stabilizer links, for example, the mounting position on the suspension arm up and down by an actuator (for example, Patent Document 2 and See 3.).

However, in the case of these configurations, it is necessary to dedicate the shape of the suspension arm, which may lead to an increase in cost.

Japanese Unexamined Patent Publication No. 2008-87715 (pages 9-17, FIG. 1-5) Japanese Patent No. 6035045 (page 3, FIG. 2) Japanese Patent No. 6035074 (pages 4-6, FIG. 1)

As described above, there is a demand for a configuration capable of more precise roll control and suppressing cost increase.

The present invention has been made in view of such a point, and provides a stabilizer link capable of suppressing cost increase while enabling more precise roll control, a stabilizer link device having the stabilizer link device, and a stabilizer device including the stabilizer link device. The purpose is.

The stabilizer link according to claim 1 is a stabilizer link that connects a wheel support member that supports a wheel and a stabilizer bar that generates a roll suppressing force of a vehicle according to its own torsional reaction force, and is a stretchable link. A main body, an actuator operated to change the amount of expansion and contraction of the link main body according to the roll angle of the vehicle, and an actuator provided at one end of the link main body and connected to the wheel support member. It is provided with a wheel joint and another ball joint provided at the other end of the link main body and connected to the stabilizer bar.

The stabilizer link device according to claim 2 operates the stabilizer link according to claim 1, a sensor for detecting the roll angle of the vehicle, and an actuator of the stabilizer link according to the roll angle of the vehicle detected by the sensor. It is equipped with a controller to control.

The stabilizer device according to claim 3 includes a stabilizer bar that generates a roll suppressing force of a vehicle according to its own torsional reaction force, and a stabilizer link device according to claim 2.

According to the stabilizer link according to claim 1, one ball joint at one end of the expandable link main body is connected to the wheel support member, and the other ball joint at the other end is connected to the stabilizer bar to connect the vehicle. By changing the amount of expansion and contraction of the link main body by the operation of the actuator according to the roll angle, the relative vertical position of the stabilizer bar and the wheel support member can be adjusted for each wheel according to the roll angle, which is more precise. Roll control becomes possible. In addition, a small actuator can be used, and it can be applied to a general-purpose stabilizer bar and a wheel support member, so that cost increase can be suppressed.

According to the stabilizer link device according to claim 2, the controller controls the operation of the stabilizer link actuator according to claim 1 according to the roll angle of the vehicle detected by the sensor, so that the stabilizer bar and the wheel support member can be brought together. The relative vertical position can be adjusted accurately for each wheel according to the roll angle, enabling more precise roll control.

According to the stabilizer device according to claim 3, by connecting the stabilizer bar and the wheel support member by the stabilizer link device according to claim 2, it is possible to provide a stabilizer device capable of further improving vehicle running stability. ..

It is explanatory perspective view which shows typically the stabilizer apparatus of one Embodiment of this invention. It is a perspective view which shows the stabilizer link of the stabilizer apparatus as above. It is a perspective view which shows a part of the stabilizer link apparatus of the same | stabilizer apparatus. It is a flow chart of operation and control of the stabilizer device of the same as above.

Hereinafter, the configuration of one embodiment of the present invention will be described with reference to the drawings.

In FIG. 1, 10 indicates a stabilizer device. The stabilizer device 10 forms a part of a suspension device used for, for example, the left and right wheels 11 of a vehicle such as an automobile, and suppresses the roll of the vehicle when turning, for example, during cornering. The roll refers to the rotation of the vehicle around an axis along the front-rear direction of the vehicle. The stabilizer device 10 includes a stabilizer bar 15 and a stabilizer link device 16.

The wheel 11 is, for example, a front wheel which is a steering wheel, and is steered in response to an operation of a steering wheel (steering wheel) by a driver who is a driver's seat occupant.

The stabilizer bar 15 is a torsion bar that generates a roll restraining force of a vehicle according to its own torsional reaction force by twisting according to the roll of the vehicle. The stabilizer bar 15 integrally includes a bar main body 21 and connecting portions 22 and 22 that are continuous at both ends of the bar main body 21.

The bar body 21 is provided in a longitudinal shape. The bar main body 21 is arranged along the vehicle width direction. Further, although not shown, the bar main body 21 is held at the lower part of the vehicle via a rubber bush or the like.

The connecting portions 22 and 22 are portions to be connected to the stabilizer link device 16. These connecting portions 22, 22 are bent in a direction intersecting the longitudinal direction of the bar main body portion 21. Therefore, the stabilizer bar 15 is provided in a U shape.

As the stabilizer bar 15, it is possible to use a general-purpose stabilizer bar 15 according to the vehicle.

The stabilizer link device 16 connects the suspension arm 25, which is a wheel support member that elastically supports the wheel 11, and the stabilizer bars 15 (connecting portions 22, 22). The stabilizer link device 16 includes a stabilizer link 31. Further, the stabilizer link device 16 includes a sensor 32 that detects the roll angle of the vehicle. Further, the stabilizer link device 16 includes a controller (ECU) 33 that controls the behavior of the stabilizer link 31. The stabilizer link device 16 is an active stabilizer link device capable of varying the stabilizer function (the function of the stabilizer bar 15 to generate a torsional reaction force), in other words, the anti-roll function.

Here, as the suspension arm 25, in the present embodiment, a damper main body portion (cylinder portion) of a damper (shock absorber) that attenuates the touch of the suspension spring is used (FIG. 3). For example, a lower suspension arm or a strut bar. Can also be used.

The stabilizer link 31 shown in FIGS. 1 and 2 includes a stretchable link main body 41. Further, the stabilizer link 31 includes an actuator 42 that is operated so as to change (increase or decrease) the amount of expansion and contraction of the link main body 41 according to the roll angle of the vehicle. Further, the stabilizer link 31 is provided with one and other ball joints 43 and 44 at both ends of the link main body 41.

A plurality of link main bodies 41 are composed of, for example, a pair of links 41a and 41b in the present embodiment, and are provided in a longitudinal shape. The link main body 41 is arranged along a substantially vertical direction intersecting the stabilizer bar 15.

The actuator 42 has, for example, a linear mechanism, and is configured to expand and contract the link main body 41 by changing the axial position of one of the links 41a and 41b of the link main body 41 with respect to the other. For example, in the present embodiment, the actuator 42 includes a motor as a drive unit and a conversion unit including a gear, a speed reducer, or the like that converts the rotational operation of the motor into linear thrust. Further, the operating amount of the actuator 42 is detected by the operating amount detecting unit. For example, as the operation amount detecting unit, a rotary encoder or the like that detects the rotation speed of the motor is used. Further, the actuator 42 is arranged at, for example, the central portion of the link main body portion 41. The power supply for the actuator 42 is supplied from the inside of the vehicle, for example, via wiring.

One and the other ball joints 43 and 44 connect the stabilizer bar 15 to the suspension arm 25 so as to be relatively movable. These one and other ball joints 43, 44 are a bottomed cylindrical one and other housings 51, 52 integrated with the link body 41, and one and other housings 51, 52 (not shown) housed in this one and other housings 51, 52. The other bearing sheet (ball sheet), the ball part (not shown) is held rotatably (swingable) in this one and the other bearing sheet, and the stud parts 55b and 56b are opened from the openings of the one and the other housings 51 and 52. It is equipped with one and other ball studs 55, 56 protruding, and one and other dust covers (boots) 57, 58 covering the open side of one and other housings 51, 52. The one ball joint 43 is provided at one end of the link main body 41 and is connected to the suspension arm 25. Further, the other ball joint 44 is provided at the other end of the link main body 41 and is connected to the stabilizer bar 15 (connecting portion 22). In the present embodiment, the stud portion 55b of one ball stud 55 of one ball joint 43 is connected to the suspension arm 25, and the stud portion 56b of the other ball stud 56 of the other ball joint 44 is a stabilizer bar. It is connected to 15 (connecting part 22). Therefore, in the present embodiment, one ball joint 43 is located on the upper side and the other ball joint 44 is located on the lower side, but depending on the positional relationship between the suspension arm 25 and the connecting portions 22 and 22 of the stabilizer bar 15. , These may be upside down. Further, in the present embodiment, the axial direction of one ball joint 43 and the axial direction of the other ball joint 44 are, that is, the stud portion 55b of one ball stud 55 and the stud portion 56b of the other ball stud 56. , Although they are arranged so as to follow the same direction in a no-load state, they may be arranged so as to follow different directions depending on the vehicle type and the like.

The sensor 32 includes, for example, a wheel speed sensor that detects the rotation speed of each wheel 11, a lateral acceleration sensor that detects the speed of the vehicle in the vehicle width direction, a steering angle sensor that detects the rotation angle (steering angle) of the handle by the driver, and the like. , A plurality of sensors may be provided, or a gyro type sensor or the like may be used. The sensor 32 is configured to output the detected roll angle of the vehicle to the controller 33.

In the present embodiment, the controller 33 uses, for example, an electronic board (electronic control unit) on which a microcomputer or the like equipped with a CPU, ROM, RAM, memory, etc. is mounted, and a predetermined control program is introduced. The controller 33 controls the operation of the actuator 42 according to the roll angle of the vehicle detected by the sensor 32. Specifically, this controller 33 calculates the required expansion / contraction length of the stabilizer link 31 (link main body 41) based on the optimum roll rigidity corresponding to the roll angle detected by the sensor 32, and corresponds to this required expansion / contraction length. The operation command is output to the actuator 42, and the stop command of the actuator 42 is output when the stabilizer link 31 (link main body 41) reaches the calculated required expansion / contraction length. That is, this controller 33 has a calculation unit that calculates the required expansion / contraction length of the stabilizer link 31 (link main body 41) based on the roll angle, and a required expansion / contraction length of the stabilizer link 31 (link main body 41), that is, an operation amount detection unit. It is equipped with a signal output unit that commands the operation / stop of the actuator 42 based on the detection of the operation amount of the actuator 42 by. The optimum roll rigidity can be calculated by the calculation unit based on the detected roll angle, for example, or a table stored in advance in the memory can be referred to. The controller 33 may be configured to be able to control the entire operation of the vehicle, for example.

Next, the operation of the above-described embodiment will be described with reference to the flow chart shown in FIG.

For example, when the vehicle is tilted (operation M1) due to driver handling during cornering, the vehicle rolls (operation M2). With the generation of this roll, the stabilizer bar 15 twists and follows, and the actuator 42 of the stabilizer link 31 connected to the stabilizer bar 15 swings (or slides) (operation M3).

At this time, the sensor 32 detects the roll angle of the vehicle (electronic control C1), and the controller 33 calculates the required expansion / contraction length of the stabilizer link 31 (link main body 41) from the optimum roll rigidity based on this roll angle. (Electronic control C2). Next, the operation command of the actuator 42 (motor) is output from the controller 33 (electronic control C3), the motor of the actuator 42 rotates (electronic control C4), and this rotation is converted into linear thrust by the conversion unit to link. The main body 41 expands and contracts (electronically controlled C5).

In the present embodiment, the operating amount of the actuator 42 is detected by the operating amount detecting unit by detecting the rotation speed of the motor (electronic control C6), and when the stabilizer link 31 (link main body 41) reaches the required expansion / contraction length, A stop command for the actuator 42 (motor) is output from the controller 33 (electronic control C7), and the motor stops (electronic control C8) to stop the expansion and contraction of the stabilizer link 31 (link main body 41) by the actuator 42. ..

Then, the stabilizer function of the stabilizer device 10 is adjusted by reflecting the expansion and contraction of the link main body 41. For example, when the link main body 41 is extended, the stabilizer function is adjusted so that the wheel 11 on the side to which the link main body 41 is connected suppresses the upward roll, and the link main body 41 is contracted. In this case, the stabilizer function is adjusted so that the wheel 11 on the side opposite to the wheel 11 to which the link main body 41 is connected suppresses the upward roll. Then, this adjusted stabilizer function suppresses the roll of the vehicle (operation M4), and the grip force between the wheel 11 and the road surface is increased (operation M5).

As described above, according to the above embodiment, one ball joint 43 at one end of the stretchable link body 41 is connected to the suspension arm 25, and the other ball joint 44 at the other end is a stabilizer bar. By connecting to 15 and changing the amount of expansion and contraction of the link main body 41 by the operation of the actuator 42 according to the roll angle of the vehicle, the relative vertical position between the stabilizer bar 15 and the suspension arm 25 is adjusted according to the roll angle. It can be adjusted for each wheel 11, that is, the relative angle between the stabilizer bar 15 and the stabilizer link 31 (link body 41) can be adjusted, and it is more precise according to the movement of the vehicle such as going straight, turning, and riding on a step. Roll control becomes possible. Further, compared with an active stabilizer device that changes the stabilizer function by expanding and contracting the stabilizer bar, for example, a smaller actuator 42 (motor with a smaller rating and size) can be used, and a general-purpose stabilizer bar 15 and suspension arm can be used. It can be applied to 25, that is, it does not use a dedicated stabilizer bar or suspension arm, and it does not involve a significant change in the shape of the stabilizer bar or suspension arm, so cost increase can be suppressed and the stabilizer link 31 can be expected to be smaller and lighter. Therefore, it is possible to suppress an increase in unsprung weight and secure the road surface followability of the wheel 11.

Specifically, the controller 33 controls the operation of the actuator 42 of the stabilizer link 31 according to the roll angle of the vehicle detected by the sensor 32, so that the relative vertical position between the stabilizer bar 15 and the suspension arm 25 can be determined. It can be adjusted accurately for each wheel 11 according to the roll angle, and more precise roll control becomes possible.

By connecting the stabilizer bar 15 and the suspension arm 25 with the stabilizer link device 16 described above, the stabilizer function is improved, the roll of the vehicle is suppressed, and the grip force between the road surface and the wheels 11 can be improved. , A stabilizer device 10 capable of further improving vehicle running stability and safety can be provided.

The present invention can be suitably used as an active stabilizer device for a suspension device for a vehicle such as an automobile.

10 Stabilizer device
11 wheels
15 Stabilizer bar
16 Stabilizer link device
25 Suspension arm that is a wheel support member
31 Stabilizer link
32 sensor
33 controller
41 Link body
42 Actuator
43 One ball joint
44 Other ball joints

Claims (3)

It is a stabilizer link that connects a wheel support member that supports wheels and a stabilizer bar that generates a roll restraining force of the vehicle according to its own torsional reaction force.
Telescopic link body and
An actuator that is operated to change the amount of expansion and contraction of the link body according to the roll angle of the vehicle, and
A ball joint provided at one end of the link main body and connected to the wheel support member,
A stabilizer link provided at the other end of the link main body and provided with another ball joint connected to the stabilizer bar. The stabilizer link according to claim 1 and
A sensor that detects the roll angle of the vehicle and
A stabilizer link device including a controller that controls the operation of the actuator of the stabilizer link according to the roll angle of the vehicle detected by the sensor. A stabilizer bar that generates a roll restraining force for the vehicle according to its own torsional reaction force,
A stabilizer device according to claim 2, further comprising the stabilizer link device.

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