WO2015078190A1

WO2015078190A1 - Vehicle suspension unit and mutually connected suspension system

Info

Publication number: WO2015078190A1
Application number: PCT/CN2014/082644
Authority: WO
Inventors: 徐光中; 张农
Original assignee: 徐光中
Priority date: 2013-11-27
Filing date: 2014-07-21
Publication date: 2015-06-04

Abstract

Disclosed are a vehicle suspension unit and a mutually connected suspension system, wherein the vehicle suspension unit (1) comprises an outer cylinder (14) and an inner cylinder (13), a piston rod (17) is provided in the outer cylinder (14), an upper end of the piston rod (17) is provided with an inner piston (15), the inner piston is located at the inner cylinder (13); a lower end of the inner cylinder (13) is provided with an annular outer piston (16), the annular outer piston (16) is located in an annular cavity between the outer cylinder (14) and the piston rod (17); and the inner cylinder (13) has an inner cylinder upper oil port (4) and an inner cylinder lower oil port (5), and the outer cylinder (14) has an outer cylinder upper oil port (8) and an outer cylinder lower oil port (9). The vehicle suspension unit (1) can simultaneously provide the functions of elastic support and damping shock-absorption, and multiple vehicle suspension units (1) can form a passive and semi-active mutually connected suspension system.

Description

Vehicle suspension unit and interconnect suspension system

Technical field

The present invention relates to a vehicle suspension unit and an interconnect suspension system having the suspension unit.

Background technique

In general, a two-axle four-wheel vehicle suspension system provides vertical, pitch, roll and twist stiffness and damping to the body. Vehicle comfort and tire grip require less vertical and torsional stiffness of the suspension, and lateral and longitudinal operational stability of the vehicle requires higher suspension roll and pitch stiffness. As a traditional four-wheel independent suspension system, there are contradictions between different requirements, and it is often necessary to make compromises between the two in suspension design.

The transverse stabilizer bar, also known as the anti-roll bar, provides high roll stiffness without affecting the vertical stiffness and pitch stiffness, but at the same time increases the torsional stiffness, which can result in greatly reduced tire grip performance for off-road conditions. And it will cause problems such as body distortion, stress fatigue, and reduced life.

In US patent application US20040080124, US20050001401 The four double-acting hydraulic cylinders disclosed in the suspension system are interconnected by two separate lines and combined with a hydraulic accumulator to provide additional roll stiffness without affecting the vertical, pitch and torsional stiffness of the body. The vertical and pitch stiffness of the body is provided by a parallel steel coil spring, thus overcoming the shortcomings of the stabilizer bar and improving the performance of urban and off-road conditions. However, its disadvantage is that as the suspension design is biased towards higher comfort, reduced vertical stiffness and pitch stiffness result in: 1. The probability of the suspension anti-collision limit block being broken down is greatly increased, causing the vehicle occupant to feel uncomfortable; 2 Head-up and nodding during rapid acceleration and braking significantly cause excessive front and rear tire load changes that affect acceleration and braking performance, ie extended acceleration time and emergency braking distance, and line of sight changes resulting in safety risks and deteriorating ride comfort Sex.

In an announcement number CN101765727 In the interconnected suspension system disclosed in the Chinese patent, the method of servo valve control is used to switch the connection mode of the pipeline, thereby realizing the anti-roll or anti-tilt function. However, the disadvantage is that the cost and failure rate are high, and at the same time, only one direction of rigidity can be provided, and the change of the body angle in both the lateral direction and the longitudinal direction cannot be suppressed at the same time.

In the US patent US5480188 In the disclosed suspension system, each tire uses two double-acting hydraulic cylinders to combine the anti-roll and anti-pitch interconnected suspensions while providing high roll and pitch stiffness. The disadvantage is that the number of double hydraulic cylinders increases the number of mounting brackets and occupies a larger chassis space, correspondingly increases the unsprung mass and restricts the space in the vehicle; and the excessive pitch stiffness, in the absence of a certain pitch damping In this case, when the front wheel of the vehicle passes over the obstacle, the road surface impact is transmitted to the rear wheel, thereby reducing ride comfort.

Summary of the invention

It is an object of the present invention to provide a vehicle suspension unit and an interconnect suspension system having the same that utilizes minimal chassis space and mass to improve vehicle comfort while providing suspension operational stability. .

The vehicle suspension unit provided by the present invention includes An outer cylinder tube and an inner cylinder tube, wherein the outer cylinder tube is provided with a piston rod coaxial with the outer cylinder tube, the upper end of the piston rod is provided with an inner piston, and the inner piston is located in the inner cylinder tube Dividing the inner cylinder into an inner cylinder upper chamber and an inner cylinder lower chamber;

The lower end of the inner cylinder is provided with an annular outer piston, the annular outer piston is located in the annular cavity between the outer cylinder and the piston rod, and the annular cavity is divided into an upper cylinder and an outer cylinder. Cavity

An upper portion of the inner cylinder tube is provided with an inner cylinder oiling port communicating with an upper chamber of the inner cylinder, and an upper portion of the inner cylinder tube or a lower portion of the outer cylinder tube is provided to be connected to the inner cylinder lower chamber Passing the inner cylinder port;

An upper portion of the outer cylinder tube is provided with an outer cylinder oiling port communicating with the upper chamber of the outer cylinder, and a lower portion of the outer cylinder tube is provided with an outer cylinder lower oil port communicating with the lower chamber of the outer cylinder.

In the vehicle suspension unit of the present invention, the inside of the piston rod has a passage extending from a lower portion of the piston rod to an upper portion, and an upper end of the passage is in communication with the lower chamber of the inner cylinder. The lower portion of the outer cylinder is provided with an inner cylinder lower port that communicates with the lower end of the passage.

In the vehicle suspension unit of the present invention, the inner wall of the inner cylinder has a passage therein, the passage extending from a lower portion of the inner wall of the inner cylinder to an upper portion, and the lower end of the passage is The inner cylinder lower chamber is in communication, and the upper portion of the inner cylinder tube is provided with an inner cylinder lower oil port communicating with the upper end of the passage.

The present invention also provides an interconnect suspension system comprising four vehicle suspension units as described above, wherein the first vehicle suspension unit is mounted on the left front wheel and the second vehicle suspension unit is mounted on the right front wheel, The three vehicle suspension unit is mounted on the right rear wheel, and the fourth vehicle suspension unit is mounted on the left rear wheel;

An inner cylinder oil inlet of the first vehicle suspension unit, an inner cylinder lower oil port of the second vehicle suspension unit, an inner cylinder lower oil port of the third vehicle suspension unit, and an inner cylinder of the fourth vehicle suspension unit The oil inlet is connected through a pipeline and connected to the first gas accumulator;

An inner cylinder lower port of the first vehicle suspension unit, an inner cylinder oil inlet of the second vehicle suspension unit, an inner cylinder oil inlet of the third vehicle suspension unit, and an inner cylinder of the fourth vehicle suspension unit The oil port is connected through a pipeline and connected to a second gas accumulator.

In the interconnected suspension system of the present invention, The outer cylinder upper oil port and the outer cylinder lower oil port of the first vehicle suspension unit are connected through a pipeline and connected to the third gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the second vehicle suspension unit are connected through a pipeline and connected to the fourth gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the third vehicle suspension unit are connected through a pipeline and connected to the fifth gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected through a pipeline and connected to the sixth gas accumulator.

In the interconnected suspension system of the present invention, the outer cylinder lower oil port of the first vehicle suspension unit is connected to the third gas accumulator through a pipeline;

The outer cylinder lower oil port of the second vehicle suspension unit is connected to the fourth gas accumulator through a pipeline;

The outer cylinder lower oil port of the third vehicle suspension unit is connected to the fifth gas accumulator through a pipeline;

The outer cylinder lower oil port of the fourth vehicle suspension unit is connected to the sixth gas accumulator through a pipeline;

The outer cylinder oiling ports of the first vehicle suspension unit, the second vehicle suspension unit, the third vehicle suspension unit, and the fourth vehicle suspension unit are respectively in communication with the air.

In the interconnected suspension system of the present invention, The interconnected suspension system further includes a hydraulic oil tank and a hydraulic pump, and an oil inlet of the hydraulic pump is connected to the hydraulic oil tank;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the first vehicle suspension unit via a first check valve and a first control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the second vehicle suspension unit via a second check valve and a second control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the third vehicle suspension unit via a pipeline through a third one-way valve and a third control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the fourth vehicle suspension unit via a pipeline via a fourth check valve and a fourth control valve.

In the interconnected suspension system of the present invention, The outer cylinder upper oil port, the outer cylinder lower oil port of the first vehicle suspension unit and the outer cylinder oil inlet port and the outer cylinder lower oil port of the second vehicle suspension unit are connected through a pipeline and are connected to the third Gas accumulators are connected;

The outer cylinder upper oil port, the outer cylinder lower oil port of the third vehicle suspension unit and the outer cylinder oil inlet port and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected through the pipeline and the fourth The gas accumulators are connected.

In the interconnected suspension system of the present invention, The outer cylinder lower oil port of the first vehicle suspension unit and the outer cylinder lower oil port of the second vehicle suspension unit are connected through a pipeline and connected to the third gas accumulator;

An outer cylinder lower oil port of the third vehicle suspension unit and an outer cylinder lower oil port of the fourth vehicle suspension unit are connected through a pipeline and connected to the fourth gas accumulator;

The oil outlet of the hydraulic pump passes through the first check valve, the first control valve, and the outer cylinder lower port of the first vehicle suspension unit and the outer cylinder of the second vehicle suspension unit The oil ports are connected;

The oil outlet of the hydraulic pump passes through the pipeline through the second check valve, the second control valve, and the outer cylinder lower port of the third vehicle suspension unit and the outer cylinder of the fourth vehicle suspension unit The ports are connected.

In the interconnected suspension system of the present invention, An outer cylinder lower port of the first vehicle suspension unit, an outer cylinder lower port of the second vehicle suspension unit, an outer cylinder oiling port of the third vehicle suspension unit, and a fourth vehicle suspension unit The oil port of the outer cylinder is connected through the pipeline and connected to the third gas accumulator;

An outer cylinder oiling port of the first vehicle suspension unit, an outer cylinder oiling port of the second vehicle suspension unit, an outer cylinder lower oil port of the third vehicle suspension unit, and a fourth vehicle suspension unit The outer cylinder lower port is connected through the pipeline and connected to the fourth gas accumulator.

The oil outlet of the hydraulic pump passes through the first check valve through the pipeline, the first control valve and the outer cylinder lower port of the first vehicle suspension unit, and the outer cylinder lower port of the second vehicle suspension unit And an outer cylinder oiling port of the third vehicle suspension unit and an outer cylinder oiling port of the fourth vehicle suspension unit;

The oil outlet of the hydraulic pump passes through the second check valve, the second control valve, and the outer cylinder oil port of the first vehicle suspension unit and the outer cylinder oil port of the second vehicle suspension unit through the pipeline The outer cylinder lower oil port of the third vehicle suspension unit and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected.

The vehicle suspension unit and the interconnecting suspension system embodying the present invention have the following beneficial effects: the vehicle suspension unit of the present invention can simultaneously provide elastic support and damping shock absorption without requiring additional shock absorbers, The vehicle suspension unit can constitute a passive, semi-active interconnected suspension system, which can be adjusted for different performance requirements by adjusting the inner diameter of the inner and outer cylinders of the vehicle suspension unit and the size of the gas accumulator. Independent optimization greatly eliminates or improves the contradiction between the comfort and operational stability of the traditional suspension system. In addition, the interconnected suspension system based on the present invention can be conveniently Achieve height adjustment without affecting suspension stiffness performance.

DRAWINGS

The present invention will be further described below in conjunction with the accompanying drawings and embodiments, in which:

Figure 1 is a schematic view of a first embodiment of a vehicle suspension unit of the present invention;

Figure 2 is a schematic view of a second embodiment of the vehicle suspension unit of the present invention;

Figure 3 is a schematic illustration of a first embodiment of an interconnected suspension system of the present invention;

Figure 4 is a schematic illustration of a second embodiment of the interconnected suspension system of the present invention;

Figure 5 is a schematic illustration of a third embodiment of the interconnected suspension system of the present invention;

Figure 6 is a schematic illustration of a fourth embodiment of the interconnected suspension system of the present invention;

Figure 7 is a schematic illustration of a fifth embodiment of the interconnected suspension system of the present invention;

Figure 8 is a schematic illustration of a sixth embodiment of the interconnected suspension system of the present invention;

Figure 9 is a schematic illustration of a seventh embodiment of the interconnected suspension system of the present invention;

Figure 10 is a schematic illustration of an eighth embodiment of the interconnected suspension system of the present invention.

detailed description

For a better understanding of the technical features, objects and effects of the present invention, the embodiments of the present invention are described in detail with reference to the accompanying drawings.

The embodiments of the vehicle suspension unit and the interconnecting suspension system of the present invention are described in detail below, and examples of the embodiments are illustrated in the accompanying drawings, in which the same or similar reference numerals are used to refer to the same or similar elements or have the same or similar Functional components.

In the description of the vehicle suspension unit and the interconnect suspension system of the present invention, it is to be understood that the terms 'front', 'back', 'upper', 'lower', 'upper end', 'lower end', 'upper part The orientation or positional relationship of the ', 'lower' and the like is based on the orientation or positional relationship shown in the drawings, and is merely for the convenience of the description of the invention and the simplified description, and does not indicate or imply that the device or component referred to has a specific The orientation, construction and operation in a particular orientation are not to be construed as limiting the invention. Moreover, the terms 'first', 'second', etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

1 is a schematic view of a first embodiment of a vehicle suspension unit of the present invention, the vehicle suspension unit 1 of the embodiment includes The inner cylinder tube 13 and the outer cylinder tube 14 are provided with a piston rod 17 coaxial with the outer cylinder tube 14 in the outer cylinder tube 14. The lower end of the piston rod 17 is disposed on the bottom of the outer cylinder tube 14, and the upper end of the piston rod 17 An inner piston 15 is disposed, and the inner piston 15 is disposed in the inner cylinder tube 13 and divides the inner cavity of the inner cylinder tube 13 into an inner cylinder upper chamber 2 and an inner cylinder lower chamber 3, and the piston rod 17 has a passage 171 therein, and the passage 171 Extending from the lower portion of the piston rod 17 to the upper portion, the upper portion of the piston rod 17 is provided with a passage communicating with the piston rod 17 and a hole of the inner cylinder lower chamber 3; the lower end of the inner cylinder tube 13 is provided with an annular outer piston 16 and an annular outer piston 16 The annular cavity is located between the outer cylinder 14 and the piston rod 17 and divides the annular cavity into an outer cylinder upper chamber 6 and an outer cylinder lower chamber 7; an inner cylinder upper chamber 2 and an inner cylinder lower chamber 3 of the inner cylinder tube 13 And the outer cylinder upper chamber 6 and the outer cylinder lower chamber 7 of the outer cylinder tube 14 are isolated from each other; the upper portion of the inner cylinder tube 13 is provided with an inner cylinder oil inlet port 4 communicating with the upper cylinder upper chamber 2, and the inner cylinder lower chamber 3 In communication with the passage 171 of the piston rod 17, the lower portion of the outer cylinder tube 14 is provided with an inner cylinder lower oil port 5 communicating with the passage 171 of the piston rod 17, that is, the inner cylinder lower oil port 5 is connected to the inner cylinder lower chamber 3. Pass An upper cylinder 14 is provided on the outer cylinder chamber 6 and communicating the oiling port 8 of the outer cylinder, a lower outer cylinder 14 is provided at the outer cylinder and the outer cylinder lower chamber 7 in communication port 9.

In the present embodiment, in order to facilitate the connection of the vehicle suspension unit 1 with other components of the vehicle, further, an upper support 11 is provided at the upper end of the inner cylinder tube 13, and the upper support 11 can facilitate the vehicle suspension unit and the vehicle body. The lower end of the outer cylinder tube 14 is provided with a lower support 12, which can facilitate the connection of the vehicle suspension unit to the vehicle.

The inner cylinder upper chamber 2, the inner cylinder lower chamber 3, the outer cylinder upper chamber 6 and the outer cylinder lower chamber 7 of the vehicle suspension unit 1 of the present invention and the inner cylinder upper oil port 4 and the inner cylinder corresponding thereto The oil port 5, the outer cylinder oil port 8 and the outer cylinder oil port 9 can be connected to the gas accumulator through a pipe to provide elastic rigidity. Adjustment of parameters such as the inner diameter of the inner cylinder 13 and the outer cylinder 14 of the vehicle suspension unit 1 and the size of the gas accumulator It can be independently optimized for different performance requirements, greatly eliminating or improving the contradiction between the comfort and operational stability requirements of traditional suspension systems.

In the present embodiment, in order to make the vehicle suspension unit 1 have a damping damping effect, the inner cylinder upper port 4, the inner cylinder lower port 5, the outer cylinder upper port 8 and the outer cylinder of the vehicle suspension unit 1 may be provided. The lower port 9 is connected to the damper valve 10, respectively, so that the vehicle suspension unit 1 of the present invention can simultaneously provide elastic support and damping damping without requiring an additional damper. The vehicle suspension unit of the present invention can be applied to a passive, semi-active suspension system. The damping valve 10 can be preset to be non-adjustable, or can be designed to have an adjustable valve opening degree. The damping control unit can control the damping size, and can be obtained by adjusting the damping force under a small energy consumption condition. Optimum ride comfort and handling stability.

As shown in FIG. 2, which is a schematic view of a second embodiment of the vehicle suspension unit of the present invention, the structure of the second embodiment of the vehicle suspension unit is substantially the same as that of the first embodiment, and only the inner cylinder lower port The position of 5 and the structure of the piston rod 17 are different. In the present embodiment, the inner cylinder lower oil port 5 is provided at the upper portion of the inner cylinder tube 13, specifically, in the present embodiment, the inner cylinder tube 13 is barrel The wall has a passage 131 extending from a lower portion of the inner wall of the inner cylinder 13 to an upper portion, the passage 131 being an annular passage of the annular wall, or a single one or a plurality of openings in the wall of the cylinder When the passage 131 is an annular passage, the inner cylinder 13 is a double cylinder wall structure, that is, the cylinder wall of the inner cylinder 13 is composed of an outer cylinder wall and an inner cylinder wall, and the passage 131 is formed between the inner cylinder wall and the outer cylinder wall. The lower end of the passage 131 communicates with the inner cylinder lower chamber 3 of the inner cylinder tube 13, and the inner cylinder lower oil port 5 provided at the upper end of the inner cylinder tube 13 communicates with the upper end of the passage 131, that is, the inner cylinder lower oil port 5 It is in communication with the inner cylinder lower chamber 3. In the present embodiment, the piston rod 17 is a solid piston rod which is hollow with respect to the piston rod of the first embodiment. Under the same cylinder size, the diameter of the piston rod 17 of the present embodiment can be reduced, and the outer cylinder The volume of the cylinder will increase, or it can be said that under the same area difference, the size of the cylinder can be made smaller, the cylinder is more compact, and the sealing structure, reliability and processability are simplified. Also greatly improved. Other structures of the vehicle suspension unit of the present embodiment are the same as those of the first embodiment, and are not described herein.

3 is a schematic view of a first embodiment of an interconnected suspension system of the present invention, which is a passive interconnected suspension system. As shown, the interconnected suspension system includes four vehicle suspension units as described above, wherein the first vehicle suspension unit 101 is mounted to the left front wheel and the second vehicle suspension unit 201 is mounted to the right front wheel, third The vehicle suspension unit 301 is mounted on the right rear wheel, and the fourth vehicle suspension unit 401 is mounted on the left rear wheel.

Referring to FIG. 3, in the present embodiment, the inner cylinder upper port of the first vehicle suspension unit 101, the inner cylinder lower port of the second vehicle suspension unit 201, and the inner cylinder of the third vehicle suspension unit 301 are oiled. The port and the inner cylinder oiling port of the fourth vehicle suspension unit 401 are connected by a pipeline and connected to the first gas accumulator 21a to form a closed oil passage 21; the inner cylinder lower port of the first vehicle suspension unit 101, The inner cylinder oiling port of the second vehicle suspension unit 201, the inner cylinder oiling port of the third vehicle suspension unit 301, and the inner cylinder lower oil port of the fourth vehicle suspension unit 401 are connected through the pipeline and the second The gas accumulators 22a are connected to form a closed oil passage 22. The first gas accumulator 21a and the second gas accumulator 22a and the closed oil passages 21, 22 in which they are located are used to provide additional roll stiffness and can reduce the side of the vehicle when cornering without affecting comfort Tilt angle.

The outer cylinder upper oil port of the first vehicle suspension unit 101 and the outer cylinder lower oil port communicate with each other through the pipe 20 and are connected to the third gas accumulator 101a; the outer cylinder oil port of the second vehicle suspension unit 201 and The outer cylinder lower oil port communicates with the fourth gas accumulator 201a through the pipeline 20; the outer cylinder upper oil port of the third vehicle suspension unit 301 and the outer cylinder lower oil port communicate with each other through the pipeline 20 and The five gas accumulators 301a are connected; the outer cylinder upper port and the outer cylinder lower port of the fourth vehicle suspension unit 401 are in communication with the pipe 20 and connected to the sixth gas accumulator 401a. The third to sixth gas accumulators 101a, 201a, 301a, 401a are independent of one another and can provide vertical spring stiffness to the interconnected suspension system as well as supporting vehicle weight and load.

4 is a schematic illustration of a second embodiment of an interconnected suspension system of the present invention, which is a passive interconnect suspension system. The embodiment is improved on the basis of the first embodiment. Specifically, in the embodiment, the outer cylinder lower oil port of the first vehicle suspension unit 101 is connected through the third gas accumulator 101a of the pipeline 20; The outer cylinder lower oil port of the second vehicle suspension unit 201 is connected to the fourth gas accumulator 201a through the pipeline 20; the outer cylinder lower oil port of the third vehicle suspension unit 301 is stored through the pipeline 20 and the fifth gas. The 301a is connected; the outer cylinder lower port of the fourth vehicle suspension unit 401 is connected to the sixth gas accumulator 401a via the pipeline 20; the first vehicle suspension unit 101, the second vehicle suspension unit 201, and the third vehicle The outer cylinder oil inlets of the suspension unit 301 and the fourth vehicle suspension unit 401 are respectively in communication with the air, and since the upper chamber of the outer cylinder communicates with the atmosphere, the effective force receiving area of the annular piston can be maximized. The other structure of this embodiment is the same as that of the first embodiment of the interconnect suspension system and will not be described again.

5 is a schematic view of a third embodiment of the interconnected suspension system of the present invention, which is further improved on the basis of the first embodiment of the interconnected suspension system, increasing the height of the vehicle body Adjustment function.

Referring to FIG. 5, in this embodiment, The interconnected suspension system further includes a hydraulic oil tank 36 and a hydraulic pump 32. The hydraulic pump 32 is driven by a motor 31. The oil inlet of the hydraulic pump 32 is connected to the hydraulic oil tank 36, and the oil outlet of the hydraulic pump 32 is connected with a relief valve 33. The oil outlet of the relief valve 33 is connected to the hydraulic oil tank 36. In order to adjust the height of the vehicle body, the oil outlet of the hydraulic pump 32 is connected to the outer cylinder oil port and the outer cylinder oil port of the first vehicle suspension unit 101 via the first check valve 35a and the first control valve 37a. The oil outlet of the hydraulic pump 32 is connected to the outer cylinder oil port and the outer cylinder oil port of the second vehicle suspension unit 201 via the second check valve 35b and the second control valve 37b through the pipeline; the hydraulic pump 32 The oil outlet is connected to the outer cylinder oil port and the outer cylinder oil port of the third vehicle suspension unit 301 through the third check valve 35c and the third control valve 37b through the pipeline; the oil outlet of the hydraulic pump 32 passes through the pipe The road is connected to the outer cylinder upper oil port and the outer cylinder lower oil port of the fourth vehicle suspension unit 401 via the fourth check valve 35d and the fourth control valve 37d.

Referring to FIG. 5, the first vehicle suspension unit 101 is taken as an example to illustrate how the vehicle height adjustment is implemented. When it is necessary to increase the height of the first vehicle suspension unit 101, the first control valve 37a connects the hydraulic pump 32 with the first The outer cylinder upper oil port 8 and the outer cylinder lower oil port 9 of the vehicle suspension unit 101 communicate, and the extra hydraulic oil from the hydraulic pump 32 pushes the inner cylinder tube 13 of the first vehicle suspension unit 101 upward relative to the outer cylinder tube 14 , Thereby raising the body. On the contrary, when it is required to lower the vehicle body height, the first control valve 37a connects the outer cylinder oil port 8 and the outer cylinder oil port 9 of the first vehicle suspension unit 101 with the hydraulic oil tank 36, and the first vehicle is due to the gravity of the vehicle body. The hydraulic oil in the outer cylinder 14 of the suspension unit 101 is pushed out, and the inner cylinder 13 is moved downward relative to the outer cylinder 14, and the height of the vehicle body is lowered. The height adjustment of the other vehicle suspension unit is the same as the height adjustment of the first vehicle suspension unit 101, and can be simultaneously adjusted or separately adjusted under the control of the suspension control system.

In order to achieve precise control of the height of the vehicle body, a displacement sensor 38 for detecting the displacement of the inner cylinder tube 13 relative to the outer cylinder tube 14 is provided on each vehicle suspension unit, and the displacement sensor 38 may be a linear displacement sensor. In the present embodiment, the first to fourth control valves 37a, 37b, 37c, 37d may be electrically controlled valves or hydraulically controlled valves.

When the vehicle body height is adjusted, the gas pressure and volume of the third to sixth gas accumulators 101a, 201a, 301a, 401a remain substantially unchanged, so the vertical and pitch stiffness properties of the interconnected suspension system do not vary with the height adjustment of the vehicle body.

The improvement made by the interconnect suspension system of the present embodiment on the basis of the first embodiment is also applicable to the second embodiment of the interconnect suspension system, that is, the first vehicle suspension unit 101 and the second vehicle suspension unit 201. The outer cylinder oiling ports of the third vehicle suspension unit 301 and the fourth vehicle suspension unit 401 are respectively disconnected from the hydraulic system, and the first vehicle suspension unit 101, the second vehicle suspension unit 201, and the third The outer cylinder oil ports of the vehicle suspension unit 301 and the fourth vehicle suspension unit 401 are respectively in communication with the air.

As shown in FIG. 6, a schematic view of a fourth embodiment of the interconnected suspension system of the present invention is a passive interconnect suspension system. As shown, the interconnected suspension system includes four vehicle suspension units as described above, wherein the first vehicle suspension unit 101 is mounted to the left front wheel and the second vehicle suspension unit 201 is mounted to the right front wheel, third The vehicle suspension unit 301 is mounted on the right rear wheel, and the fourth vehicle suspension unit 401 is mounted on the left rear wheel.

Referring to FIG. 6, in the present embodiment, the inner cylinder upper port of the first vehicle suspension unit 101, the inner cylinder lower port of the second vehicle suspension unit 201, and the inner cylinder of the third vehicle suspension unit 301 are oiled. The port and the inner cylinder oiling port of the fourth vehicle suspension unit 401 are connected by a pipeline and connected to the first gas accumulator 21a to form a closed oil passage 21; the inner cylinder lower port of the first vehicle suspension unit 101, The inner cylinder oiling port of the second vehicle suspension unit 201, the inner cylinder oiling port of the third vehicle suspension unit 301, and the inner cylinder lower oil port of the fourth vehicle suspension unit 401 are connected through the pipeline and the second The gas accumulators 22a are connected to form a closed oil passage 22. The first gas accumulator 21a and the second gas accumulator 22a and the closed oil passages 21, 22 in which they are located are used to provide additional roll stiffness and can reduce the side of the vehicle when cornering without affecting comfort Tilt angle.

In the interconnected suspension system of the embodiment, The outer cylinder oil inlet port and the outer cylinder lower oil port of the first vehicle suspension unit 101 and the outer cylinder oil inlet port and the outer cylinder lower oil port of the second vehicle suspension unit 201 are connected through a pipeline and are stored with a third gas. The energy device 18a is connected to form a closed oil passage 18; the outer cylinder oil inlet port, the outer cylinder lower oil port of the third vehicle suspension unit 301, and the outer cylinder oil port and the outer cylinder oil port of the fourth vehicle suspension unit 401 pass through The lines are in communication and are connected to a fourth gas accumulator 19a to form a closed oil line 19. The interconnection suspension system of the present embodiment can further reduce the vehicle torsional rigidity in the case where the performance of the interconnection suspension system of the first embodiment can be obtained, thereby obtaining an uneven road surface, that is, better grip performance under off-road conditions. To reduce or eliminate body torsional stress.

As shown in Figure 7, an illustration of a fifth embodiment of the interconnected suspension system of the present invention is a passive interconnect suspension system. This embodiment is based on the fourth embodiment of the interconnected suspension system. Specifically, the outer cylinder lower port of the first vehicle suspension unit 101 and the outer cylinder of the second vehicle suspension unit 201 are oiled. The port is connected by a pipeline and connected to the third gas accumulator 18a to form a closed oil passage 18; the outer cylinder lower port of the third vehicle suspension unit 301 and the outer cylinder lower port of the fourth vehicle suspension unit 401 pass The pipeline is in communication with and connected to the fourth gas accumulator 19a to form a closed oil passage 19; a first vehicle suspension unit 101, a second vehicle suspension unit 201, a third vehicle suspension unit 301, and a fourth vehicle suspension unit The outer cylinder oil ports of the 401 are respectively connected to the air. The other structure of this embodiment is the same as that of the fourth embodiment of the interconnect suspension system and will not be described again.

8 is a schematic view of a sixth embodiment of the interconnected suspension system of the present invention, which is further improved on the basis of the fourth embodiment of the interconnected suspension system, and the height of the vehicle body is increased. Adjustment function.

Referring to FIG. 8, in this embodiment, The interconnected suspension system further includes a hydraulic oil tank 36 and a hydraulic pump 32. The hydraulic pump 32 is driven by a motor 31. The oil inlet of the hydraulic pump 32 is connected to the hydraulic oil tank 36, and the oil outlet of the hydraulic pump 32 is connected with a relief valve 33. The oil outlet of the relief valve 33 is connected to the hydraulic oil tank 36. In order to adjust the height of the vehicle body, the oil outlet of the hydraulic pump 32 passes through the first check valve 35a, the first control valve 35a, and the outer cylinder oil port of the first vehicle suspension unit 101, the outer cylinder oil port, and The outer cylinder upper oil port and the outer cylinder lower oil port of the second vehicle suspension unit 201 are connected; the oil outlet of the hydraulic pump 32 passes through the second check valve 35b, the second control valve 37b and the third vehicle suspension through the pipeline The outer cylinder upper oil port of the unit 301, the outer cylinder lower oil port, and the outer cylinder oil inlet port and the outer cylinder lower oil port of the fourth vehicle suspension unit 401 are connected.

Referring to FIG. 8, the first vehicle suspension unit 101 and the second vehicle suspension unit 201 are taken as an example to illustrate how the vehicle height adjustment is implemented, and the first vehicle suspension unit 101 and the second vehicle suspension unit 201 need to be added. The first control valve 37a communicates the hydraulic pump 32 with the closed oil passage 18, and the additional hydraulic oil from the hydraulic pump 32 pushes the inner cylinder 13 of the first vehicle suspension unit 101 and the second vehicle suspension unit 201 relative to each other. The outer cylinder 14 is moved up to raise the body. On the contrary, when it is required to lower the vehicle body height, the first control valve 37a connects the closed oil passage 18 with the hydraulic oil tank 36, and the outer cylinder tube 14 of the first vehicle suspension unit 101 and the second vehicle suspension unit 201 due to the gravity of the vehicle body The hydraulic oil inside is pressed out, and the inner cylinder 13 is moved downward relative to the outer cylinder 14, and the height of the vehicle body is lowered.

When the height of the vehicle body is adjusted, the gas pressure and volume in the third gas accumulator 18a and the fourth gas accumulator 19a remain substantially unchanged, so the vertical and pitch stiffness properties of the interconnected suspension system do not vary with the height adjustment of the vehicle body. The cross-sectional area of the inner cylinder upper chamber and the inner cylinder lower chamber of the inner cylinder of the vehicle suspension unit is nearly equal. When the vehicle height changes, the oil flows from the inner cylinder upper chamber of one side of the vehicle suspension unit to the other side of the vehicle. The inner cylinder lower chamber of the inner cylinder of the suspension unit, so that the gas pressure and volume in the first gas accumulator 21a and the second gas accumulator 22a remain substantially unchanged, so the roll stiffness of the interconnected suspension system constant. That is to say, the height adjustment does not affect the stiffness performance of the vehicle suspension system, that is, it does not affect the comfort and operational stability.

In order to achieve precise control of the height of the vehicle body, a displacement sensor 38 for detecting the displacement of the inner cylinder tube 13 relative to the outer cylinder tube 14 is provided on each vehicle suspension unit, and the displacement sensor 38 may be a linear displacement sensor. In the present embodiment, the first to second control valves 37a, 37b may be electrically controlled valves or hydraulically controlled valves.

The improvement made by the interconnection suspension system of the present embodiment on the basis of the fourth embodiment is also applicable to the fifth embodiment of the interconnection suspension system, that is, the first vehicle suspension unit 101 and the second vehicle suspension unit 201. The outer cylinder oiling ports of the third vehicle suspension unit 301 and the fourth vehicle suspension unit 401 are respectively disconnected from the hydraulic system, and the first vehicle suspension unit 101, the second vehicle suspension unit 201, and the third The outer cylinder oil ports of the vehicle suspension unit 301 and the fourth vehicle suspension unit 401 are respectively in communication with the air.

Referring to Figure 9, a schematic view of a seventh embodiment of an interconnected suspension system of the present invention is a passive interconnect suspension system. The interconnected suspension system of the present embodiment includes four vehicle suspension units as described in the preferred embodiment of the above vehicle suspension unit, wherein the first vehicle suspension unit 101 is mounted to the left front wheel, and the second vehicle suspension unit 201 Mounted on the right front wheel, the third vehicle suspension unit 301 is mounted on the right rear wheel, and the fourth vehicle suspension unit 401 is mounted on the left rear wheel.

Referring to FIG. 9, in the present embodiment, the inner cylinder upper oil port of the first vehicle suspension unit 101, the inner cylinder lower oil port of the second vehicle suspension unit 201, and the inner cylinder of the third vehicle suspension unit 301 are oiled. The port and the inner cylinder oiling port of the fourth vehicle suspension unit 401 are connected by a pipeline and connected to the first gas accumulator 21a to form a closed oil passage 21; the inner cylinder lower port of the first vehicle suspension unit 101, The inner cylinder oiling port of the second vehicle suspension unit 201, the inner cylinder oiling port of the third vehicle suspension unit 301, and the inner cylinder lower oil port of the fourth vehicle suspension unit 401 are connected through the pipeline and the second The gas accumulators 22a are connected to form a closed oil passage 22. The first gas accumulator 21a and the second gas accumulator 22a and the closed oil passages 21, 22 in which they are located are used to provide additional roll stiffness and can reduce the side of the vehicle when cornering without affecting comfort Tilt angle.

In the interconnected suspension system of the embodiment, An outer cylinder lower port of the first vehicle suspension unit 101, an outer cylinder lower port of the second vehicle suspension unit 201, an outer cylinder oiling port of the third vehicle suspension unit 301, and a fourth vehicle suspension unit 401 The oil supply port of the outer cylinder is connected through the pipeline and connected to the third gas accumulator 23a to form a closed oil passage 23; the outer cylinder oil inlet of the first vehicle suspension unit 101 and the outer cylinder of the second vehicle suspension unit 201 The oiling port, the outer cylinder lower oil port of the third vehicle suspension unit 301 and the outer cylinder lower oil port of the fourth vehicle suspension unit 401 are connected through a pipeline and connected to the fourth gas accumulator 24b to form a closed oil passage. twenty four.

In the interconnected suspension system of this embodiment, the closed oil passages 23, 24 Providing the vertical stiffness and the roll stiffness of the vehicle body, the interconnected suspension system of the present embodiment can improve the heading during acceleration and braking under the performance conditions of the first embodiment and the third embodiment of the interconnect suspension system. , nodding, thus further improving the stability of the vehicle.

See Figure 10, It is an illustration of an eighth embodiment of the interconnected suspension system of the present invention which is further improved on the basis of the fifth embodiment of the interconnected suspension system, adding a body height adjustment function.

Referring to FIG. 10, in this embodiment, The interconnected suspension system further includes a hydraulic oil tank 36 and a hydraulic pump 32. The hydraulic pump 32 is driven by a motor 31. The oil inlet of the hydraulic pump 32 is connected to the hydraulic oil tank 36, and the oil outlet of the hydraulic pump 32 is connected with a relief valve 33. The oil outlet of the relief valve 33 is connected to the hydraulic oil tank 36. In order to adjust the height of the vehicle body, the oil outlet of the hydraulic pump 32 is passed through the first check valve 35a, the first control valve 37a and the pipeline through the pipeline. An outer cylinder lower port of the first vehicle suspension unit 101, an outer cylinder lower port of the second vehicle suspension unit 201, an outer cylinder oiling port of the third vehicle suspension unit 301, and a fourth vehicle suspension unit 401 The outer cylinder is connected to the oil port The oil outlet of the hydraulic pump 32 is passed through the second check valve 35b, the second control valve 37b, and An outer cylinder oiling port of the first vehicle suspension unit 101, an outer cylinder oiling port of the second vehicle suspension unit 201, an outer cylinder oil lowering port of the third vehicle suspension unit 301, and a fourth vehicle suspension unit 401 The outer cylinder is connected to the oil port .

Referring to Fig. 10, the height adjustment is now explained by taking the oil path of the first check valve 35a and the first control valve 37a as an example. When the vehicle body needs to be lifted, the first control valve 37a connects the hydraulic pump 32 and the closed oil circuit. 23, the additional hydraulic oil from the hydraulic pump 32 pushes the inner cylinder 13 of the first vehicle suspension unit 101 and the second vehicle suspension unit 201 upward relative to the outer cylinder tube 14, thereby raising the first vehicle suspension unit 101 And the vehicle body at the location where the second vehicle suspension unit 201 is located. On the contrary, when it is required to lower the vehicle body height, the first control valve 37a connects the closed oil passage 23 with the hydraulic oil tank 36, and the outer cylinder cylinder 14 of the first vehicle suspension unit 101 and the second vehicle suspension unit 201 due to the gravity of the vehicle body The hydraulic oil inside is pressed out, and the inner cylinder tube 13 is moved downward relative to the outer cylinder tube 14, thereby lowering the vehicle body at the position where the first vehicle suspension unit 101 and the second vehicle suspension unit 201 are located.

The vehicle suspension unit in the above interconnected suspension system employs the interconnecting suspension unit shown in the first embodiment of the interconnecting suspension unit, it being understood that the interconnections in the above interconnected suspension systems The suspension unit can be replaced with the interconnected suspension unit of the second embodiment, and the same function can be achieved as well.

It is to be understood that the number of gas accumulators in the various embodiments is not limited to the number illustrated in the equivalent volume conditions, and the numbers in the figures are only schematic.

The embodiments of the present invention have been described above with reference to the drawings, but the present invention is not limited to the specific embodiments described above, and the specific embodiments described above are merely illustrative and not restrictive, and those skilled in the art In the light of the present invention, many forms may be made without departing from the spirit and scope of the invention as claimed.

Claims

A vehicle suspension unit, comprising: an outer cylinder tube and an inner cylinder tube; a piston rod coaxial with the outer cylinder tube is disposed in the outer cylinder tube, and an inner piston is disposed at an upper end of the piston rod The inner piston is located in the inner cylinder and divides the inner cylinder into an inner cylinder upper chamber and an inner cylinder lower chamber;

The lower end of the inner cylinder is provided with an annular outer piston, the annular outer piston is located in the annular cavity between the outer cylinder and the piston rod, and the annular cavity is divided into an upper cylinder and an outer cylinder. Cavity

An upper portion of the inner cylinder tube is provided with an inner cylinder oiling port communicating with an upper chamber of the inner cylinder, and an upper portion of the inner cylinder tube or a lower portion of the outer cylinder tube is provided to be connected to the inner cylinder lower chamber Passing the inner cylinder port;

An upper portion of the outer cylinder tube is provided with an outer cylinder oiling port communicating with the upper chamber of the outer cylinder, and a lower portion of the outer cylinder tube is provided with an outer cylinder lower oil port communicating with the lower chamber of the outer cylinder.
A vehicle suspension unit according to claim 1, wherein said piston rod has a passage therein, said passage extending from a lower portion of said piston rod to an upper portion, an upper end of said passage and said inner cylinder The lower chamber is in communication, and a lower portion of the outer cylinder is provided with an inner cylinder lower port communicating with a lower end of the passage.
A vehicle suspension unit according to claim 1, wherein said inner cylinder bore has a passage therein, said passage extending from a lower portion of said inner wall of said inner cylinder to an upper portion, said passage The lower end is in communication with the lower chamber of the inner cylinder, and the upper portion of the inner cylinder is provided with an inner cylinder lower port communicating with the upper end of the passage.
An interconnected suspension system, comprising: the vehicle suspension unit according to any one of claims 1 to 3, wherein the first vehicle suspension unit is mounted on the left front wheel, and the second vehicle suspension unit Installed on the right front wheel, the third vehicle suspension unit is mounted on the right rear wheel, and the fourth vehicle suspension unit is mounted on the left rear wheel;

An inner cylinder oil inlet of the first vehicle suspension unit, an inner cylinder lower oil port of the second vehicle suspension unit, an inner cylinder lower oil port of the third vehicle suspension unit, and an inner cylinder of the fourth vehicle suspension unit The oil inlet is connected through a pipeline and connected to the first gas accumulator;

An inner cylinder lower port of the first vehicle suspension unit, an inner cylinder oil inlet of the second vehicle suspension unit, an inner cylinder oil inlet of the third vehicle suspension unit, and an inner cylinder of the fourth vehicle suspension unit The oil port is connected through a pipeline and connected to a second gas accumulator.
The interconnected suspension system of claim 4 wherein:

The outer cylinder upper oil port and the outer cylinder lower oil port of the first vehicle suspension unit are connected through a pipeline and connected to the third gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the second vehicle suspension unit are connected through a pipeline and connected to the fourth gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the third vehicle suspension unit are connected through a pipeline and connected to the fifth gas accumulator;

The outer cylinder upper oil port and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected through a pipeline and connected to the sixth gas accumulator.
The interconnected suspension system of claim 4 wherein:

The outer cylinder lower oil port of the first vehicle suspension unit is connected to the third gas accumulator through a pipeline;

The outer cylinder lower oil port of the second vehicle suspension unit is connected to the fourth gas accumulator through a pipeline;

The outer cylinder lower oil port of the third vehicle suspension unit is connected to the fifth gas accumulator through a pipeline;

The outer cylinder lower oil port of the fourth vehicle suspension unit is connected to the sixth gas accumulator through a pipeline;

The outer cylinder oiling ports of the first vehicle suspension unit, the second vehicle suspension unit, the third vehicle suspension unit, and the fourth vehicle suspension unit are respectively in communication with the air.
The interconnected suspension system according to claim 5 or 6, wherein the interconnected suspension system further comprises a hydraulic oil tank and a hydraulic pump, and an oil inlet of the hydraulic pump is connected to the hydraulic oil tank;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the first vehicle suspension unit via a first check valve and a first control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the second vehicle suspension unit via a second check valve and a second control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the third vehicle suspension unit via a pipeline through a third one-way valve and a third control valve;

The oil outlet of the hydraulic pump is connected to the outer cylinder lower oil port of the fourth vehicle suspension unit via a pipeline via a fourth check valve and a fourth control valve.
The interconnected suspension system of claim 4 wherein:

The outer cylinder upper oil port, the outer cylinder lower oil port of the first vehicle suspension unit and the outer cylinder oil inlet port and the outer cylinder lower oil port of the second vehicle suspension unit are connected through a pipeline and are connected to the third Gas accumulators are connected;

The outer cylinder upper oil port, the outer cylinder lower oil port of the third vehicle suspension unit and the outer cylinder oil inlet port and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected through the pipeline and the fourth The gas accumulators are connected.
The interconnected suspension system according to claim 4, wherein the outer cylinder lower port of the first vehicle suspension unit and the outer cylinder lower port of the second vehicle suspension unit are connected by a pipeline Passing through to the third gas accumulator;

An outer cylinder lower oil port of the third vehicle suspension unit and an outer cylinder lower oil port of the fourth vehicle suspension unit are connected through a pipeline and connected to the fourth gas accumulator;

The outer cylinder oiling ports of the first vehicle suspension unit, the second vehicle suspension unit, the third vehicle suspension unit, and the fourth vehicle suspension unit are respectively in communication with the air.
The interconnected suspension system according to claim 8 or 9, wherein the interconnected suspension system further comprises a hydraulic oil tank and a hydraulic pump, the oil inlet of the hydraulic pump being connected to the hydraulic oil tank;

The oil outlet of the hydraulic pump passes through the first check valve, the first control valve, and the outer cylinder lower port of the first vehicle suspension unit and the outer cylinder of the second vehicle suspension unit The oil ports are connected;

The oil outlet of the hydraulic pump passes through the pipeline through the second check valve, the second control valve, and the outer cylinder lower port of the third vehicle suspension unit and the outer cylinder of the fourth vehicle suspension unit The ports are connected.
The interconnected suspension system of claim 4 wherein:

An outer cylinder lower port of the first vehicle suspension unit, an outer cylinder lower port of the second vehicle suspension unit, an outer cylinder oiling port of the third vehicle suspension unit, and a fourth vehicle suspension unit The oil port of the outer cylinder is connected through the pipeline and connected to the third gas accumulator;

An outer cylinder oiling port of the first vehicle suspension unit, an outer cylinder oiling port of the second vehicle suspension unit, an outer cylinder lower oil port of the third vehicle suspension unit, and a fourth vehicle suspension unit The outer cylinder lower port is connected through the pipeline and connected to the fourth gas accumulator.
The interconnected suspension system of claim 11 wherein said interconnected suspension system further comprises a hydraulic oil tank and a hydraulic pump, said oil pump inlet being connected to said hydraulic oil tank;

The oil outlet of the hydraulic pump passes through the first check valve through the pipeline, the first control valve and the outer cylinder lower port of the first vehicle suspension unit, and the outer cylinder lower port of the second vehicle suspension unit And an outer cylinder oiling port of the third vehicle suspension unit and an outer cylinder oiling port of the fourth vehicle suspension unit;

The oil outlet of the hydraulic pump passes through the second check valve, the second control valve, and the outer cylinder oil port of the first vehicle suspension unit and the outer cylinder oil port of the second vehicle suspension unit through the pipeline The outer cylinder lower oil port of the third vehicle suspension unit and the outer cylinder lower oil port of the fourth vehicle suspension unit are connected.