CN113199918A - Stabilizing system and method of automobile suspension based on horizontal hydraulic cylinder - Google Patents
Stabilizing system and method of automobile suspension based on horizontal hydraulic cylinder Download PDFInfo
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- CN113199918A CN113199918A CN202110670377.8A CN202110670377A CN113199918A CN 113199918 A CN113199918 A CN 113199918A CN 202110670377 A CN202110670377 A CN 202110670377A CN 113199918 A CN113199918 A CN 113199918A
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- stabilizer bar
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60G—VEHICLE SUSPENSION ARRANGEMENTS
- B60G21/00—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces
- B60G21/02—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces permanently interconnected
- B60G21/06—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces permanently interconnected fluid
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60G—VEHICLE SUSPENSION ARRANGEMENTS
- B60G21/00—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces
- B60G21/02—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces permanently interconnected
- B60G21/04—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces permanently interconnected mechanically
- B60G21/05—Interconnection systems for two or more resiliently-suspended wheels, e.g. for stabilising a vehicle body with respect to acceleration, deceleration or centrifugal forces permanently interconnected mechanically between wheels on the same axle but on different sides of the vehicle, i.e. the left and right wheel suspensions being interconnected
- B60G21/055—Stabiliser bars
- B60G21/0551—Mounting means therefor
- B60G21/0553—Mounting means therefor adjustable
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60G—VEHICLE SUSPENSION ARRANGEMENTS
- B60G2204/00—Indexing codes related to suspensions per se or to auxiliary parts
- B60G2204/80—Interactive suspensions; arrangement affecting more than one suspension unit
- B60G2204/83—Type of interconnection
- B60G2204/8304—Type of interconnection using a fluid
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60G—VEHICLE SUSPENSION ARRANGEMENTS
- B60G2204/00—Indexing codes related to suspensions per se or to auxiliary parts
- B60G2204/80—Interactive suspensions; arrangement affecting more than one suspension unit
- B60G2204/83—Type of interconnection
- B60G2204/8306—Permanent; Continuous
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Vehicle Body Suspensions (AREA)
Abstract
The invention relates to a stabilizing system and a method of an automobile suspension based on a horizontal hydraulic cylinder, wherein the stabilizing system at least comprises a first stabilizing unit, a second stabilizing unit and a hydraulic adjusting unit, the first stabilizing unit, the second stabilizing unit and the hydraulic adjusting unit are connected through the hydraulic adjusting unit, a first hydraulic cylinder in the first stabilizing unit is arranged between a first row of wheels advancing in parallel in a transverse arrangement mode, a second hydraulic cylinder in the second stabilizing unit is arranged between a second row of wheels advancing in parallel in a transverse arrangement mode, and at least two energy accumulators on different sides in the hydraulic adjusting unit respectively connect the first hydraulic cylinder and the second hydraulic cylinder from different sides through oil pipes. When the automobile turns, the whole suspension system reduces the acting force of the stretching side wheel to the pressure side wheel, and plays a role of a transverse stabilizer bar between the wheels at two sides to prevent the automobile body from further inclining. When the automobile is off-road, the stress directions of wheels on the same side are different, the suspension stroke of the suspension system is increased, and the off-road performance is improved.
Description
The invention discloses an automobile suspension system with anti-roll and off-road performances, which is a divisional application of an invention patent with the application number of 202010288985.8 and the application date of 2020, 4 months and 13 days.
Technical Field
The invention relates to the technical field of automobile suspensions, in particular to a stabilizing system and a stabilizing method of an automobile suspension based on a horizontal hydraulic cylinder.
Background
In the parameter tuning of the vehicle suspension, the anti-roll performance and the off-road performance are in an opposite relationship, which means that if tuning is biased to one of the performances, the other performance is inevitably sacrificed. The addition of a conventional stabilizer bar can improve the anti-roll performance of the vehicle, but when the vehicle is running off-road, the stroke of the suspension is limited due to the stabilizer bar, resulting in a reduction in the off-road performance of the vehicle. In order to solve the contradiction, the transverse stabilizer bar can be manually removed and installed according to different road conditions, or the connection and disconnection of the transverse stabilizer bar can be controlled through electronic equipment. The manual operation is undoubtedly very cumbersome, while the reliability of the electronic control is not as high as with purely mechanical constructions.
For example, chinese patent CN106476561A discloses an anti-roll stabilizing device for an automobile, comprising: the first hydraulic cylinder and the second hydraulic cylinder are respectively used for being arranged on the inner side of the left wheel and the inner side of the right wheel; one of the push rod and the bottom end of the first hydraulic cylinder is connected with the sprung mass, and the other one of the push rod and the bottom end of the first hydraulic cylinder is connected with the unsprung mass; one of the push rod and the bottom end of the second hydraulic cylinder is connected with the sprung mass, and the other one of the push rod and the bottom end of the second hydraulic cylinder is connected with the unsprung mass; the device further comprises: first oil gas room and second oil gas room, the lower part of first oil gas room and second oil gas room is hydraulic oil, upper portion is compressed gas. When the jumping amplitudes of the left wheel and the right wheel are inconsistent, the push rods in the first hydraulic cylinder and the second hydraulic cylinder apply forces in different directions to the vehicle body, and the forces in different directions generate a moment resisting the vehicle body to roll, so that the vehicle body is prevented from further rolling. The anti-roll stabilizing device for the automobile only considers the anti-roll stabilizing effect and neglects the performance of the anti-roll stabilizing device in the off-road aspect. In particular, the hydraulic cylinder is arranged longitudinally, which requires a large installation space, so that the chassis is low when the automobile is off-road, and the off-road performance of the automobile is not improved.
For example, chinese patent CN1325799A discloses a regenerative suspension system for an off-road vehicle, the suspension system comprising a hydraulic cylinder having a piston defining a piston head chamber and a piston rod chamber within the cylinder, the hydraulic circuit including; a first node; a second node connected to said piston head chamber; a first control valve having an inlet for connection to a pump supply line of said vehicle and having an outlet coupled to said first junction; a control valve assembly coupling said first junction to a tank return line of said vehicle; an accumulator connected to said first node; a first check valve coupling the first node to the second node, wherein fluid flows only in a direction from the first node to the second node; a first orifice connected in parallel with said first check valve; a second check valve coupling said piston head chamber to said piston rod chamber, wherein fluid flows only in a direction from said piston head chamber to said piston rod chamber; and a second orifice connected in parallel with the second check valve. This patent achieves shock absorption by utilizing an accumulator connected to the first node and two valve sub-circuits. This patent is not purely mechanical, typically with an electronic control unit controlling the hydraulic cylinders and performing a shock absorbing function, which is not capable of performing an anti-toppling function significantly.
Patent CN1193940A also discloses a vehicle suspension system having at least one pair of forward surface engaging means and at least one pair of rearward surface engaging means connected to a vehicle body so as to allow substantially vertical relative movement of each surface engaging means with respect to the vehicle body, the suspension system including resilient support means supporting the vehicle body with respect to the surface engaging means, a force transmitting means interconnecting at least said one pair of laterally adjacent forward surface engaging means, and a force transmitting means interconnecting at least one pair of laterally adjacent rearward surface engaging means, each force transmitting means including adjustment means, longitudinally spaced apart adjustment means and functionally connected so as to progressively vary the magnitude and direction of force transmitted by each force transmitting means between the associated laterally adjacent surface engaging means as a function of the relative position of and application of at least two pairs of interconnected laterally adjacent surface engaging means A function of the load on the surface engaging means to define roll motion of the vehicle and simultaneously twist motion of the surface engaging means. However, the hydraulic cylinder of this patent is not laterally disposed and cannot be laterally disposed and anti-roll as in the present invention.
Furthermore, most of the dynamic adjustment suspension systems on the market at present adopt hydraulic cylinders which are longitudinally arranged, and a large installation space is needed, so that the shock absorption suspension can be seen only on hard-style off-road vehicles at present and can not be seen almost on cars and urban SUVs. Thus, the prior art is not aware of a vehicle suspension system that can accommodate the adjustment of the stabilizer bar in a self-adaptive manner to the road surface without requiring energy input, particularly a suspension system that can dynamically adjust roll and off-road performance.
Furthermore, on the one hand, due to the differences in understanding to the person skilled in the art; on the other hand, since the inventor has studied a lot of documents and patents when making the present invention, but the space is not limited to the details and contents listed in the above, however, the present invention is by no means free of the features of the prior art, but the present invention has been provided with all the features of the prior art, and the applicant reserves the right to increase the related prior art in the background.
Disclosure of Invention
In view of the defects of the prior art, the invention provides an automobile suspension system, which at least comprises a first stabilizing unit, a second stabilizing unit and a hydraulic pressure adjusting unit, wherein the first stabilizing unit at least comprises a first hydraulic cylinder, a first stabilizer bar and a second stabilizer bar which are arranged at two ends of the first hydraulic cylinder, the second stabilizing unit at least comprises a second hydraulic cylinder, a third stabilizer bar and a fourth stabilizer bar which are arranged at two ends of the second hydraulic cylinder, the hydraulic pressure adjusting unit at least comprises an oil pipe arranged between the first stabilizing unit and the second stabilizing unit and at least two non-same-side energy accumulators, the first stabilizer bar, the second stabilizer bar, the third stabilizer bar and/or the fourth stabilizer bar dynamically adjust the hydraulic pressure change of the first hydraulic cylinder and/or the second hydraulic cylinder based on the force exerted by wheels respectively so as to form the hydraulic pressure difference between the first hydraulic cylinder and the second hydraulic cylinder under the condition that a vehicle runs, the at least one accumulator dynamically adjusts the stress state of at least one wheel in a manner of absorbing/releasing the hydraulic pressure difference between the first hydraulic cylinder and the second hydraulic cylinder. The prior art can not realize the anti-roll and off-road performance by a pure mechanical mode and simultaneously give consideration to the anti-roll and off-road performance. The invention realizes the technical effect of mutually influencing the stress state based on the stress of the wheels by the design of the transverse hydraulic cylinder which is completely opposite to the hydraulic cylinder arranged longitudinally in the prior art, so that the suspension system has better anti-roll effect when the vehicle turns, and the vehicle can bear larger bumping amplitude and the wheels can not be suspended in the air in the off-road process.
The existing hydraulic cylinder is arranged vertically, and the stress state of the wheels cannot be reversely adjusted based on the force applied by the wheels. The first stabilizer bar and the second stabilizer bar are connected in a relative rotation manner through one end of the first hydraulic cylinder arranged in a horizontal manner and in the first hydraulic cylinder, and the third stabilizer bar and the fourth stabilizer bar are connected in a relative rotation manner through one end of the second hydraulic cylinder arranged in a horizontal manner and in the second hydraulic cylinder. The hydraulic cylinder is arranged horizontally, so that not only can the height space be saved, but also the wheels can be more conveniently connected with the rotary piston of the hydraulic cylinder, and the mutual influence of the stress state of the wheels and the hydraulic change of the hydraulic cylinder is realized.
At least one first rotary piston which is in sealing contact with the inner wall of the first hydraulic cylinder and can move is fixed at one end of the first stabilizer bar, at least one second rotary piston which is in sealing contact with the inner wall of the first hydraulic cylinder and can move is fixed at one end of the second stabilizer bar, at least one third rotary piston which is in sealing contact with the inner wall of the second hydraulic cylinder and can move is fixed at one end of the third stabilizer bar, at least one fourth rotary piston which is in sealing contact with the inner wall of the second hydraulic cylinder and can move is fixed at one end of the fourth stabilizer bar, wherein the one end of the fourth stabilizer bar is located in the second hydraulic cylinder. The setting of rotary piston can influence and change the hydraulic pressure in the suspension system through the wheel stress state that the stabilizer bar is connected to influence the wheel stress state of opposite side through hydraulic dynamic adjustment, reduce the influence of the heeling force, the resistance that the vehicle received, strengthen the equilibrium of vehicle.
The prior art can not adjust the stress state of the wheel through pure machinery. The hydraulic adjusting unit at least comprises a first oil pipe, a first energy accumulator connected with the first oil pipe, a second oil pipe and a second energy accumulator connected with the second oil pipe, the first oil pipe is connected between the first end of the first hydraulic cylinder and the first end of the second hydraulic cylinder, the second oil pipe is connected between the second end of the first hydraulic cylinder and the second end of the second hydraulic cylinder, and therefore the first energy accumulator and the second energy accumulator are arranged on the same side. The energy accumulator can effectively absorb or release hydraulic energy changed by hydraulic pressure, and the adjustment of the stress state of the wheel is realized by adjusting the hydraulic pressure difference.
Preferably, the first hydraulic cylinder is dynamically partitioned into at least two cavities by a first rotary piston and a second rotary piston in a dynamic movement manner, the second hydraulic cylinder is dynamically partitioned into at least two cavities by a third rotary piston and a fourth rotary piston in a dynamic movement manner, and the number of the cavities in the hydraulic cylinder may be two, three or more.
The first oil pipe provided with the first energy accumulator is arranged between the first cavity of the first hydraulic cylinder and the third cavity of the second hydraulic cylinder in a mode of deviating from the center of the hydraulic cylinder, and the second oil pipe provided with the second energy accumulator is arranged between the non-first cavity of the first hydraulic cylinder and the non-third cavity of the second hydraulic cylinder in a mode of deviating from the center of the hydraulic cylinder. The cavity body at the same geometric position is connected, and the correlation of hydraulic change of wheels at the same side is realized, so that the wheels are mutually influenced through hydraulic change, and the dynamic adjustment and balance of the whole vehicle are facilitated.
Preferably, in the longitudinal direction, the position of the first cavity of the first hydraulic cylinder is higher than the horizontal central axis of the first hydraulic cylinder, and the position of the third cavity of the second hydraulic cylinder is higher than the horizontal central axis of the second hydraulic cylinder.
Preferably, one end of the first stabilizer bar connected with the first hydraulic cylinder is provided with a first bushing; one end of the second stabilizer bar connected with the first hydraulic cylinder is provided with a second bushing; one end of the third stabilizer bar connected with the second hydraulic cylinder is provided with a third bushing; and a fourth bushing is arranged at one end of the fourth stabilizer bar connected with the second hydraulic cylinder. The setting of bush is favorable to avoiding the friction and the collision of stabilizer bar, increase of service life.
Preferably, in the event of a vehicle cornering, the at least one accumulator on the at least one oil line absorbs hydraulic energy in the oil line and the at least one accumulator on the at least one oil line releases hydraulic energy in the oil line.
Preferably, the first stabilizer bar and the second stabilizer bar are relatively oppositely hinged, and the third stabilizer bar and the fourth stabilizer bar are relatively oppositely hinged. The hinge joint is beneficial to the free rotation of the rotary piston and can more sensitively reflect the change of the stress state of the wheel.
Preferably, the first stabilizer bar, the second stabilizer bar, the third stabilizer bar and/or the fourth stabilizer bar are in a zigzag bending structure, one end of the zigzag bending structure is connected with the wheel, and the other end of the zigzag bending structure is connected with the first hydraulic cylinder or the second hydraulic cylinder.
The invention can effectively prevent the side-tipping through the purely mechanical connection, also has better off-road performance and better wheel balance.
The utility model provides a stable system of automotive suspension based on horizontal pneumatic cylinder, stable system includes first stabilizing element, second stabilizing element and hydraulic pressure regulating unit at least, first stabilizing element and second stabilizing element and hydraulic pressure regulating unit pass through hydraulic pressure regulating unit connects, first pneumatic cylinder in the first stabilizing element sets up between the first row of wheel that advances side by side with the mode of horizontal setting, second pneumatic cylinder in the second stabilizing element sets up between the second row of wheel that advances side by side with the mode of horizontal setting, the energy storage ware of two at least non-homonymies in the hydraulic pressure regulating unit is connected first pneumatic cylinder and second pneumatic cylinder from the non-homonymy through oil pipe respectively.
Preferably, the first stabilizer bar and the second stabilizer bar are connected to each other through one end of the first hydraulic cylinder disposed in a lateral manner and in a relatively rotatable manner in the first hydraulic cylinder to constitute a first stabilizer unit, and the third stabilizer bar and the fourth stabilizer bar are connected to each other through one end of the second hydraulic cylinder disposed in a lateral manner and in a relatively rotatable manner in the second hydraulic cylinder to constitute a second stabilizer unit.
Preferably, the first hydraulic cylinder is dynamically partitioned into at least two cavities by a first rotary piston and a second rotary piston in a dynamic movement manner, and the second hydraulic cylinder is dynamically partitioned into at least two cavities by a third rotary piston and a fourth rotary piston in a dynamic movement manner, wherein the first cavity of the first hydraulic cylinder is higher than the horizontal central axis of the first hydraulic cylinder, and the third cavity of the second hydraulic cylinder is higher than the horizontal central axis of the second hydraulic cylinder in the longitudinal direction.
Preferably, a first oil line connects the first chamber to the third chamber off-center of the cylinder, and a second oil line connects the non-first chamber to the non-third chamber off-center of the cylinder.
Preferably, the first stabilizer bar is relatively oppositely hinged to the second stabilizer bar, and the third stabilizer bar is relatively oppositely hinged to the fourth stabilizer bar.
Preferably, in the case of a vehicle turning, the wheel on the compressed side drives the two connected rotary pistons to rotate, and the two rotary pistons on the compressed side drive the two rotary pistons on the stretched side to rotate in the same direction, so that the pressure of one accumulator is increased, and the pressure of the other accumulator is decreased to reduce the acting force of the wheel on the stretched side on the wheel on the pressure side.
Preferably, under the condition that the stress directions of the wheels on the same side are different, in two cavities on the same side of the first hydraulic cylinder and the second hydraulic cylinder, the hydraulic pressure of one cavity is instantaneously increased, and the hydraulic pressure of the other cavity is instantaneously decreased, so that the hydraulic oil between the first hydraulic cylinder and the second hydraulic cylinder flows under the action of pressure, and the suspension stroke is increased.
Preferably, under the condition that the rotation frequencies of the front wheel and the rear wheel are different, the hydraulic pressure in the first cavity and the hydraulic pressure in the third cavity change, the hydraulic pressure in the second cavity and the hydraulic pressure in the fourth cavity change, and under the condition that the hydraulic pressure in the oil pipe changes rapidly, the first energy accumulator or the second energy accumulator converts the hydraulic pressure energy in the oil pipe into compression energy or potential energy to be stored.
The invention also provides a method for stabilizing the automobile suspension based on the horizontal hydraulic cylinder, which at least comprises the following steps: the first hydraulic cylinder in the first stabilizing unit is arranged between the first row of wheels which advance in parallel in a transverse arrangement mode, the second hydraulic cylinder in the second stabilizing unit is arranged between the second row of wheels which advance in parallel in a transverse arrangement mode, and the first hydraulic cylinder and the second hydraulic cylinder are connected from different sides through oil pipes by the energy accumulators on at least two different sides in the hydraulic adjusting unit respectively.
Preferably, the method further comprises: the first hydraulic cylinder is dynamically divided into at least two cavities by a first rotary piston and a second rotary piston in a dynamic movement mode,
the second hydraulic cylinder is dynamically divided into at least two cavities by a third rotary piston and a fourth rotary piston in a dynamic moving mode, a first oil pipe provided with a first energy accumulator connects the first cavity with the third cavity in a mode of deviating from the center of the hydraulic cylinder, and a second oil pipe provided with a second energy accumulator connects the non-first cavity with the non-third cavity in a mode of deviating from the center of the hydraulic cylinder.
Drawings
FIG. 1 is a schematic structural view of an automotive suspension system of the present invention;
FIG. 2 is an enlarged, fragmentary, schematic structural view of the automotive suspension system of the present invention;
FIG. 3 is a schematic view of the anti-roll principle of the present invention;
FIG. 4 is a schematic illustration of the principle of the off-road performance of the present invention;
FIG. 5 is a schematic representation of steering wheel angle over time;
FIG. 6 is a graphical representation of amplitude over time;
FIG. 7 is a graphical representation of the change in roll angle of the present invention; and
FIG. 8 is a graphical representation of the vertical load profile of a prior art four wheel suspension system in accordance with the present invention.
List of reference numerals
101: first stabilizer bar, 102: first bushing, 103: first hydraulic cylinder, 104: second bushing, 105: second stabilizer bar, 106: first accumulator, 107: first oil pipe, 108: third stabilizer bar, 109: fourth bushing, 110: second hydraulic cylinder, 111: third bushing, 112: fourth stabilizer bar, 113: second accumulator, 114: second oil pipe, 115: first rotary piston, 116: a second rotary piston.
Detailed Description
The following detailed description is made with reference to fig. 1 to 8 of the drawings.
The automobile suspension system with the anti-tilting and anti-off-road performances can also be called a dynamically adjusted automobile suspension system, a stable automobile suspension, a dynamically adjusted hydraulic circuit system and the like.
As shown in fig. 1, the automotive suspension system with both anti-roll and anti-off-road performance of the present invention includes a first stabilizing unit and a second stabilizing unit, wherein the first stabilizing unit and the second stabilizing unit are connected through a hydraulic pressure adjusting unit composed of an oil pipe and at least one accumulator. The first stabilizing unit and the second stabilizing unit do not contain an electronic control device. The first stabilizing unit is arranged between the front wheels of the vehicle, and the second stabilizing unit is arranged between the rear wheels of the vehicle.
As shown in fig. 2, the first stabilizing unit includes a first stabilizer bar 101, a second stabilizer bar 105, and a first hydraulic cylinder 103 disposed in a landscape configuration. The first stabilizer bar 101 and the second stabilizer bar 105 are respectively bent in a zigzag shape, one end of which is rotatably connected to the first hydraulic cylinder and the other end of which is connected to an axle of a wheel. That is, the first stabilizer bar 101 and the second stabilizer bar 105 are symmetrically disposed at both ends of the first hydraulic cylinder 103 of the transverse type and are rotatable relative to each other.
The second stabilizing unit includes a third stabilizing bar 108, a fourth stabilizing bar 112, and a second hydraulic cylinder 110 arranged in a landscape configuration. The third stabilizer bar 108 and the fourth stabilizer bar 112 are respectively a zigzag bent bar, one end of which is rotatably connected to the second hydraulic cylinder 110 and the other end of which is connected to an axle of a wheel. That is, the third stabilizer bar 108 and the fourth stabilizer bar 112 are symmetrically disposed at both ends of the horizontal second hydraulic cylinder 110 and are rotatable relative to each other. In the prior art, a vehicle body is easy to roll when the vehicle turns, and a general stability system needs to be provided with a hydraulic cylinder on each side respectively, and the two hydraulic cylinders apply forces with different magnitudes to wheels on different sides respectively to achieve the technical effect of roll prevention. The design structure of the invention is just opposite to the prior art. The invention connects the wheels on two sides to form transverse connection, thereby realizing transverse stability of the wheels on two sides through the time difference from unidirectional rotation to equidirectional rotation.
When the vehicle turns, the vehicle body rolls outward due to the lateral acceleration, and the outer suspension compresses and the inner suspension stretches. Relative movement of the left and right suspensions causes the stabilizer bar to rotate relative to the cylinder, thereby causing the pressure in one hydraulic branch accumulator to increase and the pressure in the other hydraulic branch accumulator to decrease. The transverse stabilizer bar generates an anti-rolling moment to act on the vehicle body under the action of the pressure difference of the two hydraulic branch circuits, so that the transverse stabilizing effect is realized, and the vehicle body is prevented from further rolling.
As shown in fig. 2, the first stabilizer 101 and the second stabilizer 105 each penetrate the first hydraulic cylinder 103 from one end of the first hydraulic cylinder 103, and the first stabilizer 101 and the second stabilizer 105 are connected in a relative-rotation manner inside the first hydraulic cylinder 103. Preferably, the first stabilizer bar 101 and the second stabilizer bar 105 are hinged to each other for relative rotation. Preferably, the articulation facilitates the first stabilizer bar 101 and the second stabilizer bar 105 to act as lateral stabilizer bars, facilitating co-rotation of the wheels on both sides, thereby resisting further roll of the vehicle body. The advantage of using a hinge is also that it allows the stabilizer bar with the compression direction to rotate first, and the two stabilizer tubes to rotate together in the same direction after the oil pressure in the oil tube is balanced. So that the stabilizer bars on both sides of the hydraulic cylinder can have a time difference between the independent rotation and the same-direction rotation.
Preferably, a first rotary piston 115 and a second rotary piston 116 are arranged transversely in the first hydraulic cylinder 103. A first rotary piston 115 in the first hydraulic cylinder 103 is fixedly connected to the first stabiliser bar 101 and is arranged between the first stabiliser bar and the inner wall of the hydraulic cylinder, sealing against the inner wall. A second rotary piston 116 in the first hydraulic cylinder 103 is fixedly connected to the second stabiliser bar 105 and is arranged between the second stabiliser bar and the inner wall of the hydraulic cylinder, sealing against the inner wall. Therefore, the first rotary piston 115 and the second rotary piston 116 are disposed in approximately opposite directions, so that the first rotary piston 115 and the second rotary piston 116 can contact the inner wall of the first hydraulic cylinder 103 and perform pressurization or depressurization, respectively, while rotating in the same direction. Similarly, a third rotary piston and a fourth rotary piston are transversely arranged in the second hydraulic cylinder 110. A third rotary piston in a second hydraulic cylinder 110 is fixedly connected to the third stabilizer bar 108 and is disposed between the third stabilizer bar and the inner wall of the hydraulic cylinder. The fourth rotary piston in the first hydraulic cylinder 103 is fixedly connected to the fourth stabilizer bar 112 and is disposed between the second stabilizer bar and the inner wall of the hydraulic cylinder. The third rotary piston and the fourth rotary piston are disposed in approximately opposite directions, so that the third rotary piston and the fourth rotary piston can contact the inner wall of the second hydraulic cylinder 110 and perform pressurization or depressurization, respectively, when rotating in the same direction. The advantage of the reverse fixation of the two rotary pistons in the horizontally arranged hydraulic cylinder is that the rotary pistons and the wheels can rotate in the same direction to realize the pressure change of the hydraulic cylinder and the oil pressure balance in the oil pipe. In the case where the two stabilizer bars are connected in a rotatable hinge manner, the two rotary pistons can freely rotate at any angle within the hydraulic cylinder. In particular, in the case where the stabilizer bars on both sides of the hydraulic cylinder are not rotated simultaneously at the initial stage, the hydraulic pressure adjusting unit can quickly absorb or release the hydraulic pressure. Under the condition that the oil pressure is balanced, the rotation of one rotary piston drives the rotation of the other rotary piston. Therefore, the stabilizer bar fixed with the other rotary piston starts to rotate in the same direction, and the effects of the two rotary pistons rotating in the same direction and the two stabilizer bars connected with the two rotary pistons rotating in the same direction are finally achieved, so that the two stabilizer bars rotating in the same direction have a transverse stabilizing function and block the vehicle from further inclining.
Preferably, in case the first and second rotary pistons 115 and 116 in the first hydraulic cylinder 103 separate the chamber of the first hydraulic cylinder 103 into two chambers, one chamber is connected to the first accumulator 106 in the hydraulic pressure regulation unit via a first oil line 107 and the other chamber is connected to the second accumulator 113 in the hydraulic pressure regulation unit via a second oil line 114. In case the third and fourth rotary pistons in the second hydraulic cylinder 110 separate the cavity of the second hydraulic cylinder 110 into two cavities, one cavity is connected to the first accumulator 106 in the hydraulic pressure regulation unit via a first oil pipe 107 and the other cavity is connected to the second accumulator 113 in the hydraulic pressure regulation unit via a second oil pipe 114. In particular, in the case where the first hydraulic cylinder and the second hydraulic cylinder are disposed opposite to each other, the first oil pipe 107 and the second oil pipe 114 are also disposed opposite to each other. The first accumulator 106 and the second accumulator 113 disposed on the oil pipe may be disposed symmetrically or asymmetrically. The first hydraulic cylinder 103, the first accumulator 106, the second hydraulic cylinder 110 and the second accumulator 113 thus form a hydraulic pressure regulating unit under connection of the oil pipe.
An accumulator is an energy storage device in a hydropneumatic system. The energy in the system is converted into compression energy or potential energy to be stored at a proper time, and when the system needs the energy, the compression energy or the potential energy is converted into hydraulic energy or air pressure and the like to be released, and the energy is supplied to the system again. When the system pressure is increased instantaneously, it can absorb the energy of the part to ensure the pressure of the whole system is normal.
Preferably, the cavity of the first hydraulic cylinder 103 connected to the first oil pipe 107 is a first cavity, and the cavity of the second hydraulic cylinder 110 connected to the first oil pipe 107 is a third cavity. The cavity of the first hydraulic cylinder 103 connected with the second oil pipe 114 is a second cavity, and the cavity of the second hydraulic cylinder 110 connected with the second oil pipe 114 is a fourth cavity. Under the condition that the stabilizer bars at the two ends of the first hydraulic cylinder and/or the second hydraulic cylinder rotate in different directions or rotate at the same frequency, the hydraulic pressure in the first cavity and the third cavity is changed, and the hydraulic pressure in the second cavity and the fourth cavity is changed. Thus, fluid oil in the first and third chambers may flow into or out of the first accumulator 106 based on changes in hydraulic pressure within the chambers. The liquid oil in the second and fourth chambers flows into or out of the second accumulator 113 based on the change in the hydraulic pressure in the chambers.
Similarly, under the condition that the rotation frequencies of the front wheel and the rear wheel are different, the hydraulic pressure in the first cavity and the third cavity is changed, and the hydraulic pressure in the second cavity and the fourth cavity is changed. Under the condition that the hydraulic pressure in the oil pipe changes rapidly, the first energy accumulator 103 or the second energy accumulator 113 converts the hydraulic energy in the oil pipe into compression energy or potential energy to be stored, and the normal flow of hydraulic oil in the oil pipe and the stability of the whole energy storage system are facilitated.
Preferably, as shown in fig. 1 and 2, one end of the first stabilizer bar 101 connected to the first hydraulic cylinder 103 is provided with a first bushing 102. One end of the second stabilizer bar 105 connected to the first hydraulic cylinder 103 is provided with a second bushing 104. One end of the third stabilizer bar 108 connected to the second hydraulic cylinder 110 is provided with a third bushing 109. One end of the fourth stabilizer bar 112 connected to the second hydraulic cylinder 110 is provided with a fourth bushing 111. Preferably, the stabilizer bar of the present invention is hingedly coupled to the bushing. The bushing has the advantages that the stabilizer bar can be prevented from moving relative to other suspension parts in the shaking or rotating process, and the stabilizer bar can be prevented from being impacted and vibrated from the outside.
Fig. 3 illustrates the principle of the present invention in terms of anti-roll operation. As shown in FIG. 3, when the vehicle turns on the road, the force direction of the wheels on the same side is consistent. The wheel on the side subjected to compression rotates the rotary piston, for example, the first rotary piston rotates clockwise, and the third rotary piston rotates counterclockwise. The first hydraulic cylinder first cavity and the second hydraulic cylinder third cavity squeeze hydraulic oil into the first accumulator 103. After the oil pressure in the pipeline is balanced, the first rotary piston and the third rotary piston on the compressed side drive the rotary piston on the stretched side to rotate in the same direction, for example, the second rotary piston rotates clockwise, and the fourth rotary piston rotates counterclockwise. At this time, the second accumulator 113 discharges the hydraulic oil, so that the hydraulic oil flows into the first hydraulic cylinder second cavity and the second hydraulic cylinder fourth cavity respectively. The whole suspension system of the invention equivalently reduces the acting force of the tension side wheel on the pressure side wheel, and plays the role of a transverse stabilizer bar between the wheels at two sides, thereby preventing the vehicle body from further inclining. When the vehicle turns in the reverse direction, the two accumulators have opposite effects and the working principle is the same.
Fig. 4 illustrates the working principle of the present invention to improve the off-road property. As shown in FIG. 4, when the vehicle is running on a cross-country road, the wheels on the same side are stressed in different directions. For example, the first rotary piston of the first stabilizer bar connection rotates clockwise, and the second rotary piston of the second stabilizer bar connection rotates counterclockwise. The third rotary piston connected to the third stabilizer bar rotates counterclockwise and the fourth rotary piston connected to the fourth stabilizer bar rotates clockwise. The hydraulic pressure in the first chamber increases instantaneously and the hydraulic pressure in the third chamber decreases instantaneously. Based on the action of the pressure, the liquid oil in the first cavity flows to the third cavity. The hydraulic pressure in the second chamber decreases instantaneously and the hydraulic pressure in the fourth chamber increases instantaneously. The liquid oil in the fourth chamber flows to the second chamber based on the action of the pressure. At the moment, the suspension system does not have the function of anti-roll, the suspension stroke is increased, and the off-road property is improved.
The automotive suspension system of the present invention is dynamically adjustable. The dynamic response of the vehicle was studied by simulation experiments on different conditions, and the vehicle equipped with the present invention was compared with the vehicle equipped with the conventional stabilizer bar, as shown in tables 1 to 2.
TABLE 1 Main parameters of the entire vehicle
1) Snake shape experiment
To verify the effect of the suspension system on the anti-roll performance of the vehicle, a serpentine path was followed as shown in fig. 5. Fig. 5 illustrates the change of the steering wheel angle. In fig. 5, the ordinate represents the steering wheel angle, and the abscissa represents time. The turning angle of the steering wheel is subject to a serpentine angle change.
The simulated vehicle speed is uniformly 6 different values from 10 km/h to 60km/h, the simulated time length is 10s, the vehicle roll angle is subjected to simulation analysis under the working condition, the time domain response of the suspension system when the vehicle speed is 60km/h is shown in figure 7, and the maximum vehicle roll angle under different vehicle speeds is shown in table 2. In fig. 7, the ordinate represents the angle of the roll angle, and the abscissa represents time. The solid line represents the change in roll angle of the suspension system of the present invention. The dashed line represents the change in roll angle of a conventional prior art suspension. As is apparent from fig. 7, the vehicle mounted with the suspension system of the present invention has a small change in roll angle, i.e., the vehicle has a small roll amplitude and a low possibility of rolling, under the same road conditions.
TABLE 2 vehicle hunting test simulation results
As can be seen from Table 2, the anti-roll performance of the suspension system of the invention is better than that of the conventional suspension at different vehicle speeds, although the roll improvement degree is slightly reduced along with the increase of the vehicle speed. As can be seen from FIG. 7, when the vehicle speed is 60km/h, the improvement degree is still about 28%, which shows that the vehicle body posture of the vehicle provided with the suspension system is more stable when the vehicle is bent over, and the safety is obviously improved.
2) Test on twisted road surface
In order to study the influence of the suspension system of the invention on the off-road performance of the vehicle, the design period is 5.522m (twice the wheel base, which ensures that the vehicle is in a pure torsional working condition during running), the phase difference is 180 degrees, and the amplitude is 0.15m under the working condition of two asynchronous sine oppositely-torsional road surfaces, as shown in fig. 6. In fig. 6, the ordinate represents amplitude, and the abscissa represents distance. The solid line represents the right wheel ground input and the dashed line represents the left wheel ground input.
The actual running speed of the vehicle on such a road surface is generally small, and the vehicle speed is set to 1 m/s. The vertical dynamic load response of four wheels of the vehicle is researched through simulation, and the simulation result is shown in fig. 8. In the test, the stress deformation degree of the tire is reflected and is an important index influencing the vehicle handling performance, if the dynamic load is 0, namely the tire is not stressed, the tire is in a suspended state at the moment.
As shown in fig. 8, the ordinate represents the vertical load, and the abscissa represents time. The first solid line represents the vertical load to the left and the second dashed line represents the vertical load to the right front wheel. The third dense dot line represents the vertical load of the left rear wheel. The vertical load staggered line of the fourth point section represents the vertical load of the right rear wheel. Figure 8 a shows the four wheel vertical load of a vehicle fitted with a conventional suspension of the prior art. b shows the vertical load of a vehicle on which the suspension system of the present invention is mounted. In a diagram, since the conventional stabilizer bar in the prior art limits the relative motion of the left and right wheels, the rear wheel load of a vehicle equipped with a conventional suspension appears to be 0, which means that the tires are suspended, which is fatal to a rear wheel-driven all terrain vehicle and causes the rear wheels to spin, making it difficult to get out of the way. In the b diagram, four tires of a vehicle equipped with the suspension system of the invention are always uniformly stressed, i.e. the grounding performance is good, and the vehicle is still in a safe state. Therefore, the suspension system of the present invention has the advantage of dynamically adjusting the vertical load based on actual road conditions.
It should be noted that the above-mentioned embodiments are exemplary, and that those skilled in the art, having benefit of the present disclosure, may devise various arrangements that are within the scope of the present disclosure and that fall within the scope of the invention. It should be understood by those skilled in the art that the present specification and figures are illustrative only and are not limiting upon the claims. The scope of the invention is defined by the claims and their equivalents.
Claims (10)
1. A stabilizing system for a vehicle suspension based on a transverse hydraulic cylinder, said stabilizing system comprising at least a first stabilizing unit, a second stabilizing unit and a hydraulic regulating unit, said first and second stabilizing units and hydraulic regulating unit being connected by said hydraulic regulating unit, characterized in that,
the first hydraulic cylinder in the first stabilizing unit is arranged between the first row of wheels advancing in parallel in a transverse arrangement mode,
a second hydraulic cylinder in the second stabilizing unit is arranged between the second row of wheels advancing in parallel in a transverse arrangement mode,
and at least two energy accumulators on different sides in the hydraulic adjusting unit respectively connect the first hydraulic cylinder and the second hydraulic cylinder from different sides through oil pipes.
2. The system of claim 1 wherein the vehicle suspension comprises a hydraulic cylinder,
a first stabilizer bar (101) and a second stabilizer bar (105) are connected in a relative rotation manner through one end of the first hydraulic cylinder (103) arranged in a horizontal manner and inside the first hydraulic cylinder (103) to constitute a first stabilizer unit,
the third stabilizer bar (108) and the fourth stabilizer bar (112) are connected in a relative rotation manner through one end of the second hydraulic cylinder (110) arranged in a horizontal manner and in the second hydraulic cylinder (110) to constitute a second stabilizer unit.
3. The system of claim 2 wherein the hydraulic cylinder is a single cylinder type hydraulic cylinder,
the first hydraulic cylinder (103) is dynamically divided into at least two cavities by a first rotary piston and a second rotary piston in a dynamic movement mode,
the second hydraulic cylinder (110) is dynamically divided into at least two cavities by a third rotary piston and a fourth rotary piston in a dynamic movement mode, wherein,
in the longitudinal direction of the machine tool,
the position of the first cavity of the first hydraulic cylinder (103) is higher than the horizontal central axis of the first hydraulic cylinder (103),
the third cavity of the second hydraulic cylinder (110) is higher than the horizontal central axis of the second hydraulic cylinder (110).
4. The system of claim 3 wherein the hydraulic cylinder is a single cylinder type hydraulic cylinder,
a first oil line (107) connects the first chamber with the third chamber in a manner offset from the centre of the cylinder,
a second oil line (114) connects the non-first chamber with the non-third chamber in an off-center manner from the cylinder center.
5. Hydraulic cross-cylinder based automotive suspension stabilizing system according to one of the preceding claims, characterized in that the first stabilizer bar (101) is articulated in a relatively counter-rotatable manner with respect to the second stabilizer bar (105),
the third stabilizer bar (108) and the fourth stabilizer bar (112) are hinged so as to be capable of relative opposition.
6. Hydraulic cross-cylinder based vehicle suspension stabilising system according to any preceding claim,
under the condition that the vehicle turns, the wheel on one side which is compressed drives the two connected rotary pistons to rotate respectively, and the two rotary pistons on one side which is compressed drive the two rotary pistons on one side which is stretched to rotate in the same direction respectively, so that the pressure of one energy accumulator is increased, and the pressure of the other energy accumulator is reduced to reduce the acting force of the wheel on the pressure side from the stretching side to the wheel on the pressure side.
7. The system of any preceding claim, wherein when the wheel on the same side is forced in different directions, one chamber is hydraulically increased and the other chamber is hydraulically decreased instantaneously in the two chambers on the same side of the first and second cylinders, so that the hydraulic oil between the first and second cylinders flows under the action of pressure, thereby increasing the suspension stroke.
8. The system of any preceding claim wherein the fluid pressure in the first and third chambers, the fluid pressure in the second and fourth chambers varies at different frequencies of rotation of the front and rear wheels,
under the condition that the hydraulic pressure in the oil pipe changes rapidly, the first energy accumulator or the second energy accumulator converts the hydraulic energy in the oil pipe into compression energy or potential energy to be stored.
9. A method for stabilizing a vehicle suspension based on a hydraulic transverse cylinder, characterized in that it comprises at least:
arranging a first hydraulic cylinder in the first stabilizing unit between the first row of wheels advancing in parallel in a transverse arrangement mode,
a second hydraulic cylinder in the second stabilizing unit is arranged between a second row of wheels advancing in parallel in a transverse arrangement mode,
and connecting the first hydraulic cylinder and the second hydraulic cylinder from different sides by at least two energy accumulators at different sides in the hydraulic adjusting unit through oil pipes respectively.
10. The method of stabilizing a cross-hydraulic cylinder based automotive suspension of claim 9, further comprising:
the first hydraulic cylinder (103) is dynamically divided into at least two cavities by a first rotary piston and a second rotary piston in a dynamic movement mode,
the second hydraulic cylinder (110) is dynamically divided into at least two cavities by a third rotary piston and a fourth rotary piston in a dynamic movement mode,
a first oil line (107) provided with a first accumulator (106) connects the first chamber with the third chamber in an off-centre manner,
a second oil line (114) provided with a second accumulator (113) connects the non-first chamber with the non-third chamber in a manner offset from the center of the hydraulic cylinder.
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CN202110670377.8A CN113199918A (en) | 2020-04-13 | 2020-04-13 | Stabilizing system and method of automobile suspension based on horizontal hydraulic cylinder |
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CN202010288985.8A CN111422021B (en) | 2020-04-13 | 2020-04-13 | Automobile suspension system with anti-roll and off-road performances |
CN202110670377.8A CN113199918A (en) | 2020-04-13 | 2020-04-13 | Stabilizing system and method of automobile suspension based on horizontal hydraulic cylinder |
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CN202110670377.8A Withdrawn CN113199918A (en) | 2020-04-13 | 2020-04-13 | Stabilizing system and method of automobile suspension based on horizontal hydraulic cylinder |
CN202010288985.8A Active CN111422021B (en) | 2020-04-13 | 2020-04-13 | Automobile suspension system with anti-roll and off-road performances |
CN202110682833.0A Active CN113212095B (en) | 2020-04-13 | 2020-04-13 | Automobile and horizontal setting method for hydraulic cylinder of suspension of automobile |
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CN202010288985.8A Active CN111422021B (en) | 2020-04-13 | 2020-04-13 | Automobile suspension system with anti-roll and off-road performances |
CN202110682833.0A Active CN113212095B (en) | 2020-04-13 | 2020-04-13 | Automobile and horizontal setting method for hydraulic cylinder of suspension of automobile |
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DE1105290B (en) * | 1959-10-31 | 1961-04-20 | Daimler Benz Ag | Device for stabilizing the curve of the car body in motor vehicles, especially those with air suspension |
CN2106224U (en) * | 1990-11-15 | 1992-06-03 | 牟均福 | Full cycle rotary piston type internal-combustion engine |
TW355699B (en) * | 1995-08-21 | 1999-04-11 | Kiectic Ltd | Vehicular suspension systems |
AUPQ294899A0 (en) * | 1999-09-20 | 1999-10-14 | Kinetic Limited | Pressure compensation in hydraulic vehicles suspension systems |
AUPQ934600A0 (en) * | 2000-08-11 | 2000-09-07 | Kinetic Pty Limited | Hydraulic suspension system for a vehicle |
KR20080034699A (en) * | 2006-10-17 | 2008-04-22 | 현대자동차주식회사 | Stabilizer bar for vehicle using hydraulic resistance |
JP5761578B2 (en) * | 2011-09-27 | 2015-08-12 | アイシン精機株式会社 | Vehicle suspension system |
CN204641316U (en) * | 2015-06-04 | 2015-09-16 | 合肥工业大学 | A kind of anti-rolling vehicle active lateral stabilizer rod |
CN108327479A (en) * | 2018-01-25 | 2018-07-27 | 湖南大学 | A kind of active power for offroad vehicle adjusts suspension system |
CN208134006U (en) * | 2018-03-09 | 2018-11-23 | 南京艾默格机械科技有限公司 | Hydraulic active variation rigidity lateral stability lever system |
CN110722955A (en) * | 2018-07-16 | 2020-01-24 | 郑州宇通客车股份有限公司 | Vehicle and stabilizer bar system thereof |
-
2020
- 2020-04-13 CN CN202110670377.8A patent/CN113199918A/en not_active Withdrawn
- 2020-04-13 CN CN202010288985.8A patent/CN111422021B/en active Active
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CN111422021A (en) | 2020-07-17 |
CN113212095A (en) | 2021-08-06 |
CN111422021B (en) | 2021-07-13 |
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