FR3120105A1 - FLOW LIMITER WITH DEGRESSIVE LEAK FOR HYDRAULIC VEHICLE SUSPENSION SHOCK ABSORBER - Google Patents

Abstract

The invention relates to a flow restrictor (1a, 1b) for motor vehicle suspension shock absorber fluid comprising a body (2) traversed by a central passage (3) for the fluid and a mobile device (4) positioned in the central passage (3) and comprising a main element (5) sliding in sealed manner in the central passage (3). The main element (5) is in mechanical connection with two pistons (7, 8) arranged in the central passage (3) on either side of the main element (5) which is held by two springs (17, 18) including a first spring (17) and a second spring (18) positioned on each side of the main element (5) in opposition, the springs (17, 18) at least partially surrounding the pistons (7, 8) and being capable of maintaining the movable device (4) in the position of maximum opening of the escape passages (13, 14) when the main element (5) is at rest. (Fig.2)

Description

FLOW LIMITER WITH DEGRESSIVE LEAK FOR HYDRAULIC VEHICLE SUSPENSION SHOCK ABSORBER

Technical field of the invention

The invention relates, in general, to the technical field of flow limiters for shock absorber fluid and more particularly for hydraulic shock absorbers for the suspension of unmanned vehicles, as well as a damping device provided with at least one such flow limiter. debit.

Hydraulic shock absorbers can be monotube or twin tube shock absorbers.

Known twin-tube shock absorbers include a fixed leak to manage low damping speeds and valves comprising a preload chosen according to the type of vehicle and the compromises chosen between comfort and behavior.

However, the compromise between comfort and behavior for a given type of vehicle is difficult to achieve with known hydraulic shock absorbers.

State of the prior art

The document FR3080162 discloses a flow limiter or hydraulic stop for vehicle suspension hydraulic shock absorber fluid with the aim of improving rolling.

The flow restrictor comprises a body with a central passage for the fluid and a device movable in the central passage under the effect of the pressure of the fluid. The mobile device is capable of modifying the passage section of the fluid during its movement by sliding in an essentially sealed manner in the central passage. A leakage passage is provided between the device and the central passage. The section of the leak passage varies with the sliding of the device so as to limit the fluid flow progressively.

The mobile device comprises a main element or shuttle sliding in the central passage, and in mechanical connection with two pistons arranged on either side of the main element. The pistons are capable of sliding in respective cavities in an essentially leaktight manner, however, with respective auxiliary leakage passages, so as to brake the main element respectively in its two directions of movement. Each of the cavities is preferably provided with a non-return valve allowing a return of fluid into the cavity during a movement of the piston opposite to the movement braking the main element. Each of the cavities also comprises a spring making it possible to hold the mobile device in the central position and to bring it back to the rest position. The mobile device undergoes the pressure of the fluid exerted during the compression movements or the relaxation movements.

However, this solution is not optimal in the operating range of an uncontrolled damper.

The desire to differentiate the software part from the mechanical part, particularly on roll, leads to bagging phenomena. A minimum of robustness is obtained with respect to the problems of dispersion and forfeiture. However, the large number of parts that make up the shock absorber (more than 50 parts) is conducive to decay/dispersion and therefore not conducive to robustness.

Vibration phenomena are also significantly degraded with unfiltered vehicle cradles.

The document FR3080162B1 is also known, which describes a second chamber in a shock absorber comprising a valve held in position by springs. The valve is associated with a derivative circuit, thus generating a damping force which is proportional to the acceleration of the relative sliding movement between first and second sliding elements.

The document US3127958A describes a shock absorber cylinder comprising an external chamber of inertia with valve. The valve system is positioned in the main chamber and allows the passage of the fluid in the parallel chamber but only in attack.

Nevertheless, the solutions of these documents do not make it possible to dissociate attack and trigger leaks.

The various known flow limiters (progressive like that of document FR3080162, decreasing, linear, short or long) make it possible to obtain a low main damping. However, a flow limiter that absorbs as much as possible is hardly compatible with linear and homogeneous operation. This not very linear operation poses problems in behavior on the agreement in roll and on the behavior of body in pitch in particular.

In addition, flow limiters of simplistic concept using a low oil reserve are not efficient during efforts.

There is therefore a compromise between comfort and behavior to be made for a given type of vehicle.

The invention aims to remedy all or part of the drawbacks of the state of the art by proposing in particular a flow limiter for shock absorber fluid providing a decreasing variable leak in a hydraulic vehicle suspension shock absorber making it possible to increase the compromise between comfort and behavior for a given type of vehicle, improving road safety.

Thus, the invention makes it possible to cause little stress on the shock absorber when there are few stresses whatever the type of vehicle and to cause increasing stresses with the stresses of the body caused by the road or the driver. The leakage is reduced in the shock absorber with the increase of the forces demanded on the shock absorber by the road or the driver. The forces (for a given shock absorber piston) increase from a given spring rate. The damping of the piston limits or increases the growth of the force (40 to 60 mm stroke to reach the minimum leakage).

This solution also makes it possible to use shorter flow limiters while benefiting from the same advantages, with more continuity in the progressiveness.

The expansion efforts are reduced, which represents an advantage compared to known flow limiter systems.

The potential and operating range of an unmanned damper and the felt are also improved.

Vibration and percussion in the damper are reduced. Body handling (pumping, pitching, rolling, roll forwards, pitching, diving) is improved.

Fluidity is improved by greater absorption with an open initial leak. There is a reduction in copying and better control of roll references and body movements thanks to the degressive flight.

There is also a reduction in rolling noise, acoustic modulations and rebound noise in the shock absorber.

The flow limiter is also more robust thanks to its limited number of parts and the provision of larger (and therefore more robust) springs than those of document FR3080162.

The proposed flow limiter makes it possible to improve the vibration and vertical filtration potential of a suspension damper without going through an expensive controlled system which is unreliable. The cost is thus reduced.

To do this, it is proposed, according to a first aspect of the invention, a flow limiter for motor vehicle suspension damper fluid comprising a body through which passes a central passage for the fluid and a mobile device positioned in the passage central. The mobile device comprises a main element sliding in an essentially sealed manner in the central passage under the effect of the pressure of the fluid along a guide surface delimiting the central passage.

The main element is in mechanical connection with two pistons, arranged in the central passage on either side of the main element. The pistons are able to slide in damping devices comprising respective cavities in an essentially sealed manner.

The damping devices comprise respective escape passages so as to brake the main element respectively in its two directions of movement. Each of the damping devices is provided with a non-return valve allowing a return of fluid into the cavity during a movement of the piston opposite to the movement braking the main element.

The main element is held by two springs including a first spring and a second spring, positioned on each side of the main element in opposition. The springs at least partially surround the pistons and are capable of maintaining the movable device in the position of maximum opening of the leakage passages when the main element is at rest.

According to one embodiment, the first spring is held in compression between a first support surface of the main element and a first stop projecting from the guide surface of the central passage. The second spring is held in compression between a second support surface of the main element and a second abutment projecting from the guide surface of the central passage.

According to another embodiment, the leakage passages are leakage grooves cut into each piston and extending longitudinally along the piston. The damping devices each comprise a housing partially delimiting one of the cavities. The leak groove moves along one of the hydraulic cartridges to allow the fluid contained in the cavity to gradually escape while generating a resistive force on the piston.

According to another embodiment, the body comprises a first fluid circuit at the periphery of the central passage. The first fluid circuit opens into the central passage at a first end and comprises a second end provided with a first flexible valve, so as to allow a flow of fluid in one direction through the first fluid circuit when the main element is at rest.

According to another embodiment, the main element hermetically separates the central passage into a first part and a second part. The first end of the first fluid circuit opens into the first part of the central passage and the second end of the first fluid circuit is in fluid communication with the second part of the central passage. When the fluid is under pressure in the second part of the central passage, the main element is moved towards the first part of the central passage so as to close off the first end of the first fluid circuit.

According to another embodiment, the body comprises a second fluid circuit at the periphery of the central passage. The second fluid circuit opens into the central passage at a first end and comprises a second end provided with a second flexible valve, so as to allow a flow of fluid in one direction through the second fluid circuit when the main element is at rest.

According to another embodiment, the first end of the second fluid circuit opens into the second part of the central passage. The second end of the second fluid circuit is in fluid communication with the first portion of the central passage. When the fluid is under pressure in the first part of the central passage, the main element is moved towards the second part of the central passage so as to close off the first end of the second fluid circuit.

According to another aspect of the invention, the latter relates to a damping device for a motor vehicle comprising a rod connected to a suspension piston. The rod is intended to slide in a cylindrical body. The suspension piston hermetically separates two volumes of fluid in the cylindrical body including a first volume and a second volume. The damping device advantageously comprises two flow limiters including a first flow limiter and a second flow limiter as defined previously. The flow restrictors are mounted in the suspension piston so that they operate in opposition.

According to one embodiment, the second part of the central passage and the second end of the first fluid circuit of the first flow limiter are in fluid communication with the second volume of the cylindrical body. The first end of the first fluid circuit and the first part of the central passage of the first flow restrictor are in fluid communication with the first volume of the cylindrical body.

In contrast, the second part of the central passage and the second end of the first fluid circuit of the second flow limiter are in fluid communication with the first volume of the cylindrical body. The first end of the first fluid circuit and the first part of the central passage of the second flow limiter are in fluid communication with the second volume of the cylindrical body.

According to another embodiment, the suspension piston comprises a first channel connected to the second part of the central passage of the first flow limiter. The first channel opens via a first face of the suspension piston into the second volume.

The suspension piston includes a second channel connected to the first part of the central passage of the first flow restrictor. The second channel opens via a second face of the suspension piston into the first volume.

In contrast, the suspension piston comprises a third channel connected to the first part of the central passage of the second flow limiter and which opens via the first face of the suspension piston into the second volume.

The suspension piston comprises a fourth channel connected to the second part of the central passage of the second flow limiter and which opens via the second face of the suspension piston into the first volume.

The invention thus provides a hydraulic suspension damper making it possible to increase the compromise between pleasure, comfort and maintenance under stresses by the driver and the road for a given type of vehicle.

The non-return valves of the leakage circuits, associated with the two separate pistons, make it possible, unlike the prior art, to separate the attack and expansion leaks.

Vibration and percussion in the damper are reduced. Body handling (pumping, pitching, rolling, roll transmissions, pitching, diving) is improved.

The invention also relates to a motor vehicle comprising four damping devices or hydraulic vehicle suspension dampers as described above.

brief description of figures

Other characteristics and advantages of the invention will become apparent on reading the following description, with reference to the appended figures, which illustrate:
: a sectional view of a flow limiter housed in a shock absorber piston, according to one embodiment of the invention;
: a sectional view of a flow limiter housed in a shock absorber piston, according to another embodiment of the invention;
: a view in longitudinal section of two flow limiters housed in a shock absorber piston;
: a cross-sectional view of these two flow restrictors.

For greater clarity, identical or similar elements are identified by identical reference signs in all the figures.

DETAILED description of an embodiment

There illustrates a flow limiter 1a, 1b for motor vehicle suspension damper fluid, according to one embodiment of the invention. The flow limiter 1a, 1b comprises a body 2 traversed by a central passage 3 for the fluid and a mobile device 4 positioned in the central passage 3. The body 2 forms a single cartridge. The fluid may be oil.

The mobile device 4 comprises a main element 5 sliding in an essentially sealed manner in the central passage 3 under the effect of the pressure of the fluid and along a guide surface 6 delimiting the central passage 3.

The main element 5 is in mechanical connection with two pistons 7, 8 arranged in the central passage 3 on either side of the main element 5. The pistons 7, 8 are able to slide in damping devices 9 , 10 comprising respective cavities 11, 12 in an essentially sealed manner.

The damping devices 9, 10 each comprise a housing 25, 26. A first housing 25 partially delimits a first cavity 11 and a second housing 26 partially delimits a second cavity 12.

The damping devices 9, 10 comprise respective escape passages 13, 14 so as to brake the main element respectively in its two directions of movement. Each of the damping devices 9, 10 is provided with a non-return valve 15, 16 allowing fluid to return into the cavity 11, 12 during a movement of the piston 7, 8 opposed to the movement braking the main element. 5.

The non-return valves 15, 16 can be a ball or a membrane.

According to the invention, the main element 5 is held by two springs 17, 18 including a first spring 17 and a second spring 18 positioned on each side of the main element 5 in opposition. The springs 17, 18 are capable of maintaining the mobile device 4 in the position of maximum opening of the escape passages 13, 14 when the main element 5 is at rest.

The springs 17, 18 at least partially surround the pistons 7, 8. The first spring 17 at least partially surrounds a first piston 7 and the second spring 18 surrounds a second piston 8. The springs 17, 18 run along the guide surface 6.

The flow limiter 1a, 1b represented on the is in the rest position. The springs 17, 18 ensure a central positioning of the main element 5 and the pistons 7, 8.

The main element 5 hermetically separates the central passage 3 into a first part 32 and a second part 33. At rest, the pressure of the fluid in these two parts 33 is substantially equal.

The damping devices 9, 10 are rigidly linked to the body 2. The pistons 7, 8 can be in mechanical pressure contact with a pusher of the mobile device 4 or be rigidly linked to the mobile device 4.

The non-return valves 15, 16 in the two cavities 11, 12 allow the mobile device 4 to be very reactive to the oscillations of the suspension and also to avoid any panic of the mobile device 4.

The main element 5 and the pistons 7, 8 have a circular section. The mobile device 4 has a longitudinal section having the general shape of a hospital cross.

Naturally, the invention is described in the foregoing by way of example. It is understood that the person skilled in the art is able to carry out different variant embodiments of the invention without departing from the scope of the invention.

For example, the first spring 17 is held in compression between a first bearing surface 19 of the main element 5 and a first abutment 21 projecting from the guide surface 6 of the central passage 3. The second spring 18 is also held in compression between a second bearing surface 20 of the main element 5 and a second abutment 22 projecting from the guide surface 6 of the central passage 3.

The first stop 21 and the second stop 22 are positioned at the height of the damping devices 9, 10. Other positions are possible.

The first stop 21 and the second stop 22 have a circular section.

The springs 17, 18 make it possible to ensure a central positioning at rest of the mobile device 4 and of its respective pistons, as represented in FIGS. 1 and 2.

The leakage passages 13, 14 are leakage grooves 13, 14 cut into each piston 7, 8 and extending longitudinally along the piston 7, 8.

When the damper is in attack, that is to say when there is a compression of the fluid in the first part 32 of the central passage 3, the mobile device 4 is moved towards the second part 33 which is in relaxation, i.e. in the direction A shown on the . A second leakage groove 14 moves with the second piston 8 along the second housing 26 to allow the fluid contained in the second cavity 12 to gradually escape while generating a resisting force at the level of the second piston 8.

By analogy, when the shock absorber is in expansion, that is to say when there is a compression of the fluid in the second part 33 of the central passage 3, the mobile device 4 is moved towards the first part 32 which is in depression , that is to say in a direction opposite to direction A. A first leakage groove 13 moves with the first piston 7 along the first housing 25 to allow the fluid contained in the first cavity 11 to gradually escape while generating a resistant force at the level of the first piston 7.

Alternatively, the leakage passages 13, 14 may include nozzles (not shown). The damping at the level of the pistons 7, 8 takes place by means of a damping chamber formed by the cavity 11, 12, the piston 7, 8 sliding therein, a ball check valve and the nozzle. During a movement of the mobile device 4, the latter pushes one of the pistons 7, 8 which compresses the fluid in the cavity, this fluid escaping through the nozzle. A constant characteristic damping of the movement of the mobile device 4 is thus obtained.

As illustrated on the , the body 2 comprises a first fluid circuit 27 at the periphery of the central passage 3. The first fluid circuit 27 opens into the central passage 3 at a first end 29. The first fluid circuit 27 comprises a second end 30 provided with a first flexible valve 31, so as to allow a flow of fluid in a direction B through the first fluid circuit 27, when the main element 5 is at rest.

The first end 29 of the first fluid circuit 27 opens into the first part 32 of the central passage 3 and the second end 30 of the first fluid circuit 27 is in fluid communication with the second part 33 of the central passage 3.

In expansion, when there is a compression of the fluid in the second part 33 of the central passage 3, the fluid circulates in the first fluid circuit 27 in the direction B shown in Figures 1 and 2, until the mobile device 4 is moved towards the first part 32 which is under depression, causing the closure of the first end 29 of the first fluid circuit 27 by a peripheral surface 47 of the main element 5.

In attack, when there is a compression of the fluid in the first part 32 of the central passage 3, the first flexible valve 31 prevents the fluid from circulating from the first fluid circuit 27 towards the volume communicating with the second part 33 of the central passage 3, that is to say according to a meaning contrary to meaning B.

According to another variant illustrated in the , the body 2 comprises a second fluid circuit 34 at the periphery of the central passage 3. The second fluid circuit 34 opens into the central passage 3 at a first end 35 and comprises a second end 36 provided with a second flexible valve 37 , so as to allow a flow of fluid in a direction C through the second fluid circuit 34 when the main element 5 is at rest.

The first end 35 of the second fluid circuit 34 opens into the second part 33 of the central passage 3. The second end 36 of the second fluid circuit 34 is in fluid communication with the first part 32 of the central passage 3.

When the fluid is not under pressure in the central passage 3, the mobile device 4 is at rest in a central position. The first end 29 of the first fluid circuit 27 and the first end 35 of the second fluid circuit 34 are not closed off by the main element 5.

In expansion, when there is a compression of the fluid in the second part 33 of the central passage 3, the fluid circulates in the first fluid circuit 27 until the mobile device 4 is moved towards the first part 32 which is in depression, causing the closure of the first end 29 of the first fluid circuit 27 by the peripheral surface 47 of the main element 5.

The second flexible valve 37 of the second fluid circuit 34 prevents the fluid from circulating from the second part 33 of the central passage 3 towards the volume communicating with the first part 32 of the central passage 3, that is to say in the opposite direction. in the C sense.

By contrast, in attack, when the fluid is under pressure in the first part 32 of the central passage 3, the fluid circulates in the second fluid circuit 34 in the direction C, until the main element 5 is moved towards the second part 33 of the central passage 3 in the direction A so as to close off the first end 35 of the second fluid circuit 34 by the peripheral surface 47 of the main element 5.

The first flexible valve 31 of the first fluid circuit 27 prevents the fluid from circulating from the volume communicating with the second part 33 of the central passage 3 towards the first part 32 of the central passage 3, that is to say in a direction opposite to the sense c.

The invention also relates to a damping device 38 for a motor vehicle comprising a rod 39 having one end connected to a suspension piston 40, as illustrated in FIGS. 3 and 4.

Rod 39 is intended to slide in a cylindrical body (not shown). The suspension piston 40 hermetically separates two volumes of fluid 23, 24 in the cylindrical body including a first volume 23 and a second volume 24.

The damping device comprises two flow limiters 1a, 1b including a first flow limiter 1a and a second flow limiter 1b as defined previously. The flow limiters 1a, 1b are mounted in the suspension piston 40 so as to operate in opposition.

In this example, the first flow limiter 1a is a compression limiter and the second flow limiter 1b is an expansion limiter. The springs 17, 18 are not shown for simplification.

Preferably, the flow limiters 1a, 1b are mounted parallel in the suspension piston 40 and perpendicular to the rod 39.

The second part 33 of the central passage 3 and the second end 30 of the first fluid circuit 27 of the first flow limiter 1a are in fluid communication with the second volume 24 of the cylindrical body.

The first end 29 of the first fluid circuit 27 and the first part 32 of the central passage 3 of the first flow limiter 1a are in fluid communication with the first volume 23 of the cylindrical body.

In contrast, the second part 33 of the central passage 3 and the second end 30 of the first fluid circuit 27 of the second flow limiter 1b are in fluid communication with the first volume 23 of the cylindrical body. The first end 29 of the first fluid circuit 27 and the first part 32 of the central passage 3 of the second flow limiter 1b are in fluid communication with the second volume 24 of the cylindrical body.

When the first and the second flow limiter 1a, 1b each comprise a second fluid circuit 34, the first part 32 of the central passage 3 and the second end 36 of the second fluid circuit 34 of the first flow limiter 1a are in fluid communication with the first volume 23 of the cylindrical body.

The first end 35 of the second fluid circuit 34 and the second part 33 of the central passage 3 of the first flow limiter 1a are in fluid communication with the second volume 24 of the cylindrical body.

In contrast, the second part 33 of the central passage 3 and the first end 35 of the second fluid circuit 34 of the second flow limiter 1b are in fluid communication with the first volume 23 of the cylindrical body. The second end 36 of the second fluid circuit 34 and the first part 32 of the central passage 3 of the second flow limiter 1b are in fluid communication with the second volume 24 of the cylindrical body.

The suspension piston 40 comprises a first channel 41 connected to the second part 33 of the central passage 3 of the first flow limiter 1a and opening via a first face 42 of the suspension piston 40 into the second volume 24.

The suspension piston 40 comprises a second channel 43 connected to the first part 32 of the central passage 3 of the first flow limiter 1a and opening via a second face 44 of the suspension piston 40 into the first volume 23.

In contrast, the suspension piston 40 comprises a third channel 45 connected to the first part 32 of the central passage 3 of the second flow limiter 1b and opening via the first face 42 of the suspension piston 40 into the second volume 24.

The suspension piston 40 comprises a fourth channel 46 connected to the second part 33 of the central passage 3 of the second flow limiter 1b and opening via the second face 44 of the suspension piston 40 into the first volume 23.

When the damping device 38 is in attack, there is a compression of the fluid in the second volume 24 and therefore in the second part 32 of the central passage 3 of the first flow limiter 1a which reacts as described above. The fluid circulates in the first fluid circuit 27 in the direction B shown in Figures 1 and 2, until the mobile device 4 is moved towards the first part 32 which is under depression, causing the closure of the first end 29 of the first fluid circuit 27 by the peripheral surface 47 of the main element 5.

The fluid is blocked by the second flexible valve 37 in the second fluid circuit 34.

In the second flow limiter 1b, the fluid is blocked by the first flexible valve 31 in the first fluid circuit 27.

The fluid circulates in the second fluid circuit 34 of the second flow limiter 1b in the direction C, until the mobile device 4 is moved towards the second part 33 which is under depression, in the direction A, causing the closing of the first end 35 of the second fluid circuit 34 by the peripheral surface 47 of the main element 5.

The use of two flow limiters 1a, 1b makes it possible to improve the compromise with respect to driving comfort and behavior. It significantly reduces the rolling noise going up into the body by the shock absorbers. Rebound end-of-stroke noise is improved/reduced or removed. The body control under road and driver stress is also better braked/controlled or even excellent.

It is emphasized that all the characteristics, as they emerge for a person skilled in the art from the present description, the drawings and the attached claims, even if concretely they have only been described in relation to other characteristics determined, both individually and in arbitrary combinations, can be combined with other characteristics or groups of characteristics disclosed here, provided that this has not been expressly excluded or that technical circumstances make such combinations impossible or invalid. sense.

Claims (10)

Flow restrictor (1a, 1b) for motor vehicle suspension shock absorber fluid comprising a body (2) traversed by a central passage (3) for the fluid and a mobile device (4) positioned in the central passage (3) and comprising a main element (5) sliding in an essentially sealed manner in the central passage (3) under the effect of the pressure of the fluid, the main element (5) being in mechanical connection with two pistons (7, 8) arranged in the central passage (3) on either side of the main element (5) and capable of sliding in damping devices (9, 10) comprising respective cavities (11, 12) in an essentially sealed manner, the damping devices (9, 10) comprising respective escape passages (13, 14) so as to brake the main element (5) respectively in its two directions of movement, each of the damping devices (9, 10 ) being provided with a non-return valve (15, 16) allowing a return of fluid in the cavity (11, 12) during a movement of the piston (7, 8) opposite to the movement braking the main element (5) characterized in that the main element (5) is held by two springs (17 , 18) including a first spring (17) and a second spring (18), positioned on each side of the main element (5) in opposition, the springs (17, 18) at least partially surrounding the pistons (7, 8 ) and being capable of maintaining the mobile device (4) in the position of maximum opening of the escape passages (13, 14) when the main element (5) is at rest. Flow limiter (1a, 1b) according to Claim 1, characterized in that the first spring (17) is held in compression between a first bearing surface (19) of the main element (5) and a first stop ( 21) protruding from a guide surface (6) delimiting the central passage (3), the second spring (18) being held in compression between a second support surface (20) of the main element (5) and a second stop (22) protruding from the guide surface (6). Flow limiter (1a, 1b) according to any one of Claims 1 or 2, characterized in that the leakage passages (13, 14) are leakage grooves (13, 14) hollowed out in each piston (7, 8 ) and extending longitudinally along the piston (7, 8), the damping devices (9, 10) each comprising a housing (25, 26) partially delimiting one of the cavities (11, 12), the leakage groove (13, 14) moving along a hydraulic cartridge (25, 26) to allow the fluid contained in the cavity (11, 12) to gradually escape while generating a resistive force at the piston (7, 8). Flow limiter (1a, 1b) according to any one of Claims 1 to 3, characterized in that the body (2) comprises a first fluid circuit (27) at the periphery of the central passage (3), the first circuit of fluid (27) opening into the central passage (3) at a first end (29) and comprising a second end (30) provided with a first flexible valve (31), so as to allow a flow of fluid in one direction through the first fluid circuit (27) when the main element (5) is at rest. Flow limiter (1a, 1b) according to Claim 4, characterized in that the main element (5) hermetically separates the central passage (3) into a first part (32) and a second part (33), the first end (29) of the first fluid circuit (27) opening into the first part (32) of the central passage (3) and the second end (30) of the first fluid circuit (27) being in fluid communication with the second part (33 ) of the central passage (3), when the fluid is under pressure in the second part (33) of the central passage (3), the main element (5) is moved towards the first part (32) of the central passage (3) so as to close the first end (29) of the first fluid circuit (27). Flow limiter (1a, 1b) according to any one of Claims 4 or 5, characterized in that the body (2) comprises a second fluid circuit (34) at the periphery of the central passage (3), the second circuit of fluid (34) opening into the central passage (3) at a first end (35) and comprising a second end (36) provided with a second flexible valve (37), so as to allow a flow of fluid in one direction through the second fluid circuit (34) when the main element (5) is at rest. Flow limiter (1a, 1b) according to Claim 6, characterized in that the first end (35) of the second fluid circuit (34) opens into the second part (33) of the central passage (3), the second end ( 36) of the second fluid circuit (34) being in fluid communication with the first part (32) of the central passage (3), when the fluid is under pressure in the first part (32) of the central passage (3), the main element (5) is moved towards the second part (33) of the central passage (3) so as to close off the first end (35) of the second fluid circuit (34). Damping device (38) for a motor vehicle comprising a suspension piston (40) connected to a rod (39), the rod (39) being intended to slide in a cylindrical body, the suspension piston (40) hermetically separating two volumes of fluid (23, 24) in the cylindrical body including a first volume (23) and a second volume (24), characterized in that it comprises two flow limiters (1a, 1b) including a first flow limiter ( 1a) and a second flow limiter (1b) as defined according to any one of claims 5 to 7, the flow limiters (1a, 1b) being mounted in the suspension piston (40) so as to operate in opposition . Damping device (38) according to Claim 8, characterized in that the second part (33) of the central passage (3) and the second end (30) of the first fluid circuit (27) of the first flow limiter (1a ) are in fluid communication with the second volume (24) of the cylindrical body, the first end (29) of the first fluid circuit (27) and the first part (32) of the central passage (3) of the first flow limiter (1a ) being in fluid communication with the first volume (23) of the cylindrical body, in contrast, the second part (33) of the central passage (3) and the second end (30) of the first fluid circuit (27) of the second flow limiter flow rate (1b) being in fluid communication with the first volume (23) of the cylindrical body, and the first end (29) of the first fluid circuit (27) and the first part (32) of the central passage (3) of the second limiter flow rate (1b) being in fluid communication with the second volume (24) of the body cylindrical. Damping device (38) according to Claim 9, characterized in that the suspension piston (40) comprises a first channel (41) connected to the second part (33) of the central passage (3) of the first flow limiter ( 1a) and opening via a first face (42) of the suspension piston (40) into the second volume (24), the suspension piston (40) comprising a second channel (43) connected to the first part (32) of the passage (3) of the first flow limiter (1a) and opening via a second face (44) of the suspension piston (40) into the first volume (23), in contrast, the suspension piston (40) comprising a third channel (45) connected to the first part (32) of the central passage (3) of the second flow limiter (1b) and opening via the first face (42) of the suspension piston (40) into the second volume (24), the suspension piston (40) comprising a fourth channel (46) connected to the second part (33) of the central passage (3) of the second flow limiter (1 b) and emerging via the second face (44) of the suspension piston (40) in the first volume (23).