KR20180121822A - Roll control system of tag axle type vehicle - Google Patents

Abstract

The present invention discloses a roll control system of a tag axle type vehicle, comprising: a tag axle unit; a shock absorber; a hydraulic pressure control valve; and a controller. By sharing a hydraulic pressure used in a rear wheel steering system with the shock absorber, roll control can be performed via the shock absorber without using an additional power transferring system.

Description

[0001] ROLL CONTROL SYSTEM OF TAG [0002]

The present invention relates to a roll control system of a tag axle vehicle that performs roll control of a vehicle using hydraulic pressure provided to a rear wheel steering system applied to a pusher or a tag axle of a large vehicle.

Generally, the distribution of load varies depending on the tolerance of the cargo to the truck loaded with the cargo and the load time of the cargo. Accordingly, to reduce the rolling resistance of the tire at the time of allowance, the axial load is transferred to the driving wheel to improve the driving force. In addition, in order to ensure the stable distribution of the axial load, The device is applied.

A rear wheel steering system is applied to the tag axle device to reduce the turning radius and reduce tire wear when driving the vehicle. This tag axle device is operated as the hydraulic pressure is supplied, and operates only at low speeds for safety reasons when the vehicle is running, and does not operate at high speeds.

On the other hand, in the case of trucks, the center of gravity rises when the cargo is loaded, and the behavior of the vehicle becomes unstable during high-speed cornering. In order to solve this problem, a separate electric motor or a hydraulic system for controlling the shock absorber must be provided. If this is applied, there arises a problem of an increase in weight and an increase in cost.

Therefore, it is desirable to solve the problem that the roll behavior of the vehicle becomes unstable at the time of high-speed driving of the vehicle without adding a separate power transmission system, and it is necessary to utilize a rear-wheel steering system that is not operated at the time of high- speed driving.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as an admission that the prior art is known to those skilled in the art.

KR 10-2003-0083184 A (Oct. 30, 2003)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve such problems, and it is an object of the present invention to provide a control system for a roll axle of a tag axle vehicle in which a hydraulic pressure utilized in a rear- The purpose of the system is to provide.

According to another aspect of the present invention, there is provided a roll control system for a tag axle vehicle, comprising: a tag axle unit for adjusting a rear wheel steering angle according to whether a hydraulic pressure is applied; A shock absorber mounted on a rear wheel and filled with hydraulic pressure to perform roll control of the vehicle; A hydraulic control valve that receives hydraulic pressure from a hydraulic pump that generates hydraulic pressure and selectively supplies the supplied hydraulic pressure to the tag axle unit or the shock absorber; And a control unit for controlling the hydraulic control valve so that the rear axle steering angle is controlled by providing the oil pressure to the tag axle unit when the running speed is less than the preset speed, And a controller for controlling the hydraulic control valve so that the roll control of the shock absorber is performed.

The hydraulic control valve is characterized in that the first hydraulic line extended to provide the hydraulic pressure to the tag axle unit and the second hydraulic line extended to provide the hydraulic pressure to the shock absorber are configured.

The tag axle unit includes: a hydraulic cylinder connected to the first hydraulic line and supplied with hydraulic pressure; A push rod slidably installed in the hydraulic cylinder; And a connection arm which is connected to the push rod and controls the steering angle of the rear wheel as the push rod is moved.

The shock absorber is an inner tube filled with oil; An outer tube that surrounds the inner tube from the outside of the inner tube and is filled with oil; And a piston rod having one end inserted into the inner pipe and the other end extended to the outside of the outer pipe, and the second hydraulic line is connected to the inner pipe to supply the hydraulic pressure to the inner pipe.

The controller receives the front wheel steering angle information according to the steering wheel operation and controls the hydraulic control valve so that the oil pressure is supplied to the tag axle unit when the running speed is less than the set speed so that the rear wheel steering angle is steered in the opposite direction corresponding to the front wheel steering angle .

The controller controls the hydraulic control valve so that the state in which the rear wheel faces the straight forward direction is maintained when the running speed is equal to or higher than the set speed.

The controller receives the front wheel steering angle information according to the steering wheel operation and calculates the roll moment value based on the running speed and the front wheel steering angle when the running speed is equal to or higher than the set speed.

When the roll moment value is calculated, the controller determines an amount of hydraulic pressure to be provided to the shock absorber through a necessary pressure calculating equation set in advance according to the roll stiffness characteristic of the vehicle.

The necessary pressure calculation formula is set in consideration of the weight of the vehicle, the number of the shock absorber, the mounting position of the shock absorber, and the mounting distance of the shock absorber.

According to the roll control system of the tag axle vehicle having the above-described structure, since the hydraulic pressure provided to the tag axle unit can be provided to the shock absorber, the hydraulic pressure is transmitted to the tag axle unit in the low- And in the high-speed running state of the vehicle, the hydraulic pressure provided to the tag axle unit is transmitted to the shock absorber, so that the roll control is performed.

In this way, the roll control through the shock absorber is performed by the hydraulic pressure provided to the tag axle unit, thereby eliminating the separate electric motor or the hydraulic system for performing the roll control, thereby reducing manufacturing cost and weight.

1 is a configuration diagram according to a roll control system of a tag axle vehicle according to an embodiment of the present invention;
Fig. 2 is a view for explaining a roll control system of the tag axle vehicle shown in Fig. 1. Fig.

Hereinafter, a roll control system for a tag axle vehicle according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a configuration diagram according to a roll control system of a tag axle vehicle according to an embodiment of the present invention, and FIG. 2 is a view for explaining a roll control system of the tag axle vehicle shown in FIG.

As shown in FIG. 1, a roll axle control system for a tag axle vehicle according to the present invention includes a tag axle unit 10 for adjusting a rear wheel steering angle according to whether a hydraulic pressure is applied or not; A shock absorber 20 installed at a rear wheel and filled with hydraulic pressure to perform roll control of the vehicle; A hydraulic control valve 40 that is supplied with hydraulic pressure from a hydraulic pump 30 that generates a hydraulic pressure and selectively supplies the supplied hydraulic pressure to the tag axle unit 10 or the shock absorber 20; And a control unit for controlling the hydraulic pressure control valve 40 so that the rear axle steering angle is controlled by providing the oil pressure to the tag axle unit 10 when the running speed is lower than a predetermined set speed, And a controller (50) for controlling the hydraulic control valve (40) so that a roll control of the shock absorber (20) is performed by providing a hydraulic pressure to the shock absorber (20).

As described above, the present invention comprises the tag axle unit 10, the shock absorber 20, the hydraulic pump 30, the hydraulic control valve 40, and the controller 50. The hydraulic pressure generated by the hydraulic pump 30 Is selectively provided toward the tag axle unit 10 or the shock absorber 20 by the hydraulic control valve 40 controlled by the controller 50. [ Here, the hydraulic pump 30 is provided to supply the oil pressure to the tag axle unit 10. Conventionally, the tag axle unit 10 and the shock absorber 20 are configured as separate parts. In the present invention, So that the roll control of the shock absorber 20 is performed by utilizing the hydraulic pressure provided to the axle unit 10. [

That is, in the case of the conventional tag axle unit 10, the rear wheel steering angle is adjusted by receiving the hydraulic pressure generated by the hydraulic pump 30. However, there is a problem that the roll generation becomes large when the running speed of the vehicle is high, It is operated only when the vehicle travels at low speed. Accordingly, the hydraulic pressure supplied to the tag axle unit 10 is not utilized when the running speed of the vehicle is traveling at a high speed.

Accordingly, in the present invention, the roll control of the shock absorber 20 is performed by using the oil pressure of the tag axle unit 10, which is not utilized at the time of high-speed travel, so that the roll occurrence occurring at high speed traveling is reduced.

Prior to the description of the present invention, the tag axle unit 10 described above includes, as shown in Fig. 1, a hydraulic cylinder 11 supplied with hydraulic pressure; A push rod 13 slidably installed in the hydraulic cylinder 11; And a connection arm 15 connected to the push rod 13 and adapted to adjust the rear wheel steering angle as the push rod 13 is moved.

Here, the hydraulic cylinder 11 is supplied with the hydraulic pressure generated by the hydraulic pump 30 so that the push rod 13 provided in the hydraulic cylinder 11 is pulled or drawn out from the hydraulic cylinder 11 by the hydraulic pressure supplied thereto Sliding. The push rod 13 is connected to the rear wheel so that the rear wheel steering angle is adjusted as the push rod 13 is moved. Here, the connection structure, which is rotatably connected through a connection structure including a hinge structure when the push rod 13 is connected to the rear wheel, and the steering angle of the rear wheel is switched by the hydraulic pressure in the tag axle, is a known technology, The description is omitted.

2, the shock absorber 20 includes an inner tube 21 filled with oil; An outer tube 23 surrounding the inner tube 21 from the outside of the inner tube 21 and filled with oil; And a piston rod 25 whose one end is inserted into the inner tube 21 and the other end is extended to the outside of the outer tube 23. The shock absorber 20 is connected to the axle of the rear wheel and the vehicle body to absorb the shock and is configured not only to constitute the internal pipe 21, the external pipe 23 and the piston rod 25, (Not shown).

In particular, in the present invention, the shock absorber 20 can perform the roll control by receiving the hydraulic pressure provided to the tag axle unit 10. [ This will be described in detail below.

1, a hydraulic control valve 40 is provided with a tag control unit 40 for controlling the roll control system using the hydraulic pressure provided to the tag axle unit 10, The first hydraulic line 41 extended to provide the hydraulic pressure to the axle unit 10 and the second hydraulic line 43 extended to provide the hydraulic pressure to the shock absorber 20 may be constructed.

The hydraulic pressure control valve 40 receives the hydraulic pressure generated by the hydraulic pump 30 and receives the hydraulic pressure supplied by the control of the controller 50 to be described later to the tag axle unit 10 or the shock absorber 20, . To this end, the hydraulic control valve 40 is provided with a first hydraulic line 41 extended to provide hydraulic pressure to the tag axle unit 10 and a second hydraulic line extended to provide hydraulic pressure to the shock absorber 20 43).

The first hydraulic line 41 is connected to the hydraulic cylinder 11 of the tag axle unit 10 so that when the hydraulic control valve 40 is opened to flow fluid toward the first hydraulic line 41, 11 are moved so that the rear wheel steering angle is adjusted.

On the other hand, the second hydraulic line 43 may be connected to the inner tube 21 side of the shock absorber 20. 2, the second hydraulic line 43 extending from the hydraulic control valve 40 can be connected to the lower end of the inner pipe 21 or connected to the lower end of the inner pipe 21 And to the base valve 27 constituted. When the hydraulic control valve 40 is opened to flow the fluid to the second hydraulic line 43 when the roll control through the shock absorber 20 is required, the inner tube 21 is additionally filled with the fluid, It is possible to perform the roll control according to the adjustment of the damping force of the motor 20. Here, the second hydraulic line 43 is further provided with a check valve 29 so that the hydraulic pressure filled in the inner pipe 21 is isolated, so that the desired damping force can be smoothly adjusted.

On the other hand, the controller 50 for controlling the opening and closing operations of the hydraulic pressure control valve 40 receives the front wheel steering angle information according to the steering wheel operation. Here, the front wheel steering angle information and the traveling speed of the vehicle according to the steering wheel operation are generally input through the steering angle sensor S1 and the speed sensor S2, which are applied to the vehicle.

The controller 50 may control the hydraulic control valve 40 so that the oil pressure is supplied to the tag axle unit 10 when the running speed is less than the set speed so that the rear wheel steering angle is steered in the opposite direction corresponding to the front wheel steering angle. Here, the preset speed pre-stored in the controller 50 may be less than 50 km / h, which is a low speed range, and when the running speed of the vehicle is equal to or lower than the set speed, the rear wheel steering angle is steered along the front wheel steering angle, . That is, when the running speed of the vehicle is equal to or lower than the set speed, the controller 50 controls the hydraulic control valve 40 to be supplied to the tag axle unit 10 through the first hydraulic line 41 to the hydraulic pressure, So that the rear wheel steering angle is steered. At this time, in order to reduce the tire wear, it is possible to make the steering angle only when the rear wheel steering angle is steered.

On the other hand, when the running speed is equal to or higher than the set speed, the controller 50 controls the hydraulic control valve 40 so that the rear wheel is maintained in the straight direction. That is, when the running speed of the vehicle is increased, the roll generation becomes large. In this case, the controller 50 maintains the steering angle of the rear wheel in the straight direction when the running speed is equal to or higher than the set speed, have.

More specifically, the controller 50 receives the front wheel steering angle information according to the steering wheel operation, and can calculate the roll moment value based on the running speed and the front wheel steering angle when the running speed is equal to or higher than the set speed.

Here, the roll moment value can be calculated through the following equation.

R: Turn radius

L: Hue base

sinα: outer ring steering angle

r: Distance from the center of the kingpin to the tire centerline

When the turning radius is calculated in this way, the traveling speed of the measured vehicle is applied, and the centrifugal force is calculated by the following equation.

m: Body mass

V: Driving speed

R: Turn radius

When the centrifugal force is calculated in this way, the roll moment value can be calculated by multiplying the centrifugal force calculated on the length of the roll moment arm, which is the difference between the center of gravity of the vehicle and the roll center.

When the roll moment value is calculated, the controller 50 can determine the amount of hydraulic pressure to be provided to the shock absorber 20 through the required pressure calculating equation set in advance according to the roll stiffness characteristics of the vehicle. Here, the necessary pressure calculating equation can calculate the required pressure according to the change of the acting force and the roll moment value derived from the hydraulic pressure acting on the effective area of the shock absorber 20. [ The necessary pressure calculation formula can be set in consideration of the weight of the vehicle, the number of the shock absorbers 20 mounted, the mounting position of the shock absorber 20, and the mounting distance of the shock absorber 20, and the predetermined shock absorber 20 The amount of oil pressure to be provided to the shock absorber 20 can be set by making a change in the roll moment value with respect to the mounting number of the shock absorber 20, the mounting position of the shock absorber 20, and the mounting distance of the shock absorber 20.

That is, the weight of the vehicle, the mounting number of the shock absorber 20, the mounting position of the shock absorber 20, the mounting distance of the shock absorber 20, and the specifications of the shock absorber 20 are determined in advance The amount of hydraulic pressure supplied to the shock absorber 20 is determined so that a stable posture can be maintained by using the roll moment value that varies according to the turning radius and the traveling speed of the vehicle.

Thus, by providing the shock absorber 20 with the hydraulic pressure that is not provided to the tag axle unit 10 when the vehicle travels at high speed, the roll control is performed using the hydraulic pressure that can not be utilized at high speed traveling, The running performance can be ensured.

According to the roll control system of the tag axle vehicle having the above-described structure, the hydraulic pressure provided to the tag axle unit 10 can be provided to the shock absorber 20, so that the tag axle unit 10, So that the hydraulic pressure supplied to the tag axle unit 10 is transmitted to the shock absorber 20 to perform the roll control.

As described above, since the roll control through the shock absorber 20 is performed by the hydraulic pressure provided to the tag axle unit 10, the separate electric motor or the hydraulic system for performing the roll control is eliminated, Effect is generated.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

10: Tag axle unit
20: Shock absorber
30: Hydraulic pump
40: Hydraulic control valve
41: First hydraulic line
43: second hydraulic line
50:

Claims (9)

A tag axle unit for adjusting the rear wheel steering angle according to whether the hydraulic pressure is supplied or not;
A shock absorber mounted on a rear wheel and filled with hydraulic pressure to perform roll control of the vehicle;
A hydraulic control valve that receives hydraulic pressure from a hydraulic pump that generates hydraulic pressure and selectively supplies the supplied hydraulic pressure to the tag axle unit or the shock absorber; And
The control unit controls the hydraulic pressure control valve so that the rear axle steering angle is controlled by providing the oil pressure to the tag axle unit when the travel speed is less than the preset speed. And a controller for controlling the hydraulic valve so that the roll control of the shock absorber is performed. The method according to claim 1,
Wherein the hydraulic control valve comprises a first hydraulic line extended to provide hydraulic pressure to the tag axle unit and a second hydraulic line extended to provide hydraulic pressure to the shock absorber. The method of claim 2,
The tag axle unit includes: a hydraulic cylinder connected to the first hydraulic line and supplied with hydraulic pressure;
A push rod slidably installed in the hydraulic cylinder; And
And a connection arm connected to the push rod to adjust the steering angle of the rear wheel as the push rod is moved. The method of claim 2,
The shock absorber is an inner tube filled with oil;
An outer tube that surrounds the inner tube from the outside of the inner tube and is filled with oil; And
And a piston rod having one end inserted into the inner tube and the other end extending to the outside of the outer tube,
And the second hydraulic line is connected to the inner pipe so that the hydraulic pressure is supplied to the inner pipe. The method according to claim 1,
The controller receives front wheel steering angle information according to steering wheel operation,
Wherein the hydraulic control valve is controlled so that the oil pressure is supplied to the tag axle unit when the running speed is less than the set speed, so that the rear wheel steering angle is steered in the opposite direction corresponding to the front wheel steering angle. The method according to claim 1,
Wherein the controller controls the hydraulic control valve to maintain the state of the rear wheel in the straight forward direction when the running speed is equal to or higher than the set speed. The method according to claim 1,
Wherein the controller receives the front wheel steering angle information according to the steering wheel operation and calculates the roll moment value based on the running speed and the front wheel steering angle when the running speed is equal to or higher than the set speed. The method of claim 7,
Wherein the controller determines the amount of hydraulic pressure to be provided to the shock absorber through a necessary pressure calculation formula set in advance according to the roll stiffness characteristics of the vehicle when the roll moment value is calculated. The method of claim 8,
Wherein the required pressure calculation formula is set in consideration of the weight of the vehicle, the number of the shock absorber, the mounting position of the shock absorber, and the mounting distance of the shock absorber.

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