DE10315088A1 - Suspension system, especially for use in bicycles, has valve with at least two independently adjustable valve members - Google Patents

Abstract

The suspension system comprises a valve, which has at least two valve members, which are adjustable, independently of each other. The adjusting mechanism consists of two adjusting elements. One spring valve member is pre-tensioned by a spring element against the pressure of damping fluid. The pressure is built during the pressurization of the suspension system.

Description

The The invention relates to a damping system according to the preamble of claim 1.

such damping systems are preferred for bicycles used to dampen impacts on the bike. In particular such damping systems used in suspension forks or in the rear of a bicycle. At the The damping system is used in suspension forks usually arranged in one or both fork legs. alternative the damping system can also be arranged in the middle part of the suspension fork. When used in Rear triangle connects the damping system usually two frame parts that can be rotated about an axis, e.g. the seat post spar and the rear wheel spars.

A damping system according to the preamble of claim 1 is in the US-A 5 190 126 disclosed.

In the known damping system is in a housing 12 a main piston 16 arranged, the one with damping fluid 24 Main chamber filled with a damping fluid 24 filled secondary chamber separates. There is a gas spring in the side chamber 80 intended. Passages run through the main piston 56 . 58 , wherein the damping fluid in the pressure stage through the passages 56 and at the rebound through the passageways 58 flows. There is a second piston in the main piston 20 added. There is a second gas spring between the two pistons 22 arranged.

The damping characteristics of the known damping system can be changed by changing the gas pressure of the gas spring 22 to be changed. The greater the pressure of the gas spring 22 is, the harder the damping characteristic. By changing the gas pressure of the gas spring, the volume ratio between the two gas springs changes at the same time, ie, when the pressure of the second piston increases, it disengages from the main piston.

The Dämpfungscharakterisktik of the known damping system can also change the volume of the damping fluid to be changed. For example, the volume of the two gas springs decreases by adding damping fluid. Increased at the same time the pressure of the gas springs. Therefore, by the change the amount of damping fluid again both the hardness as well also the stroke of the damping system changed at which the second piston as a result of contact with the main piston Druchgänge for the damping fluid closes.

The known damping system thus has the disadvantage that in the event of changes the damping characteristic Always several parameters are adjusted, which is very much the setting complicates.

The The invention is therefore based on the object of a damping system to be specified for the damping characteristics is particularly easy and quick to set.

The The object of the invention is with a damping system according to the features solved by claim 1.

advantageous Embodiments of the invention are specified in the dependent claims.

A Execution of the damping system according to the invention comprises two telescopically movable towards each other against a spring force Parts, a chamber for receiving a damping fluid in a of the two parts is included, a piston to displace the damping fluid out of the chamber during compression of the damping system, the piston with the other part of the two against each other a spring force is connected telescopically movable parts in a boundary wall of the chamber formed channels through which the damping fluid while compression of the damping system flows at least partially, Valve means for change the free cross-sectional area of the channels, and adjusting means for the valve means for change the damping characteristic of the damping system, wherein the valve means at least two independently adjustable Valve members and the adjustment means at least two adjustment elements for independent from each other Include adjustment of the valve members.

According to the invention, at least a valve member by a spring element against the during Compression of the damping system resulting pressure of the damping fluid be biased, preferably the bias of the spring element changeable by the adjusting member for adjusting the valve member is.

According to the at least two independently adjustable valve members each against a spring element the while compression of the damping system Damping fluid pressure be biased, preferably the bias of the spring elements changeable by the adjustment members for independent adjustment of the valve member are.

According to the invention the spring element associated with a valve member has a lower preload exert on the valve member assigned to it than that of the other valve member assigned spring element.

According to the invention the spring element associated with a valve member is softer than that other valve member associated spring element.

at an execution According to the invention, the spring element associated with the one valve member can be a smaller spring constant than that assigned to the other valve member Have spring element.

Preferably the one valve member is a needle valve.

at an execution According to the invention, one valve member can be a tapered one Have a needle tip.

According to the invention other valve member can also be a needle valve.

at an execution According to the invention, the other valve member can be a strongly tapered one Have a needle tip.

According to the invention other valve member also comprise a spring plate stack (shim package). The spring plate stack can be loaded by a cap, which in turn is biased against the valve member by a spring member.

According to one execution the other valve member can have an annular plate.

Preferably can that or the spring elements be coil springs.

at an execution the invention is the damping system a bicycle rear shock. Alternatively, the damping system according to the invention can also be part of a Suspension fork for be a bike. The suspension fork can be a shock absorber and a shock absorber, each with two against each other against a spring force comprise telescopically movable parts, preferably the Means for applying at least the main part of the spring force in the strut are arranged.

The The object of the invention is also a damper leg of a suspension fork with two against each other against a spring force in a damping direction telescoping moving parts, a damping system for damping the Movement of the two parts, and adjusting means for adjusting at least two the damping characteristics of the damping system influencing valve members solved, the adjusting means are designed such that at an actuation of the adjusting means on at least one of the valve members in force acting in an adjustment direction changes and / or a movement causes at least one of the valve members in an adjustment direction being the direction of damping and the adjustment direction are different.

there can the damping direction and the adjustment direction define a plane and / or the damping direction approximately are at a right angle to the adjustment direction.

According to the invention. one valve member a needle valve and the other valve member be a spring plate package.

According to the invention a valve member or the valve members with one or more spring elements be biased.

According to the Adjustment means comprise adjustment elements, the adjustment elements preferably knobs include that when actuated (Rotation) over a threaded connection a displacement of a valve member and / or a shift in recording for cause a spring element.

The The object of the invention is also a damper leg of a suspension fork with two telescopically movable against each other against a spring force Share, a chamber for receiving a damping fluid, which in a of the two parts is included, and adjusting means for adjusting the damping characteristic of the damping system influencing valve members solved, the adjusting means are arranged with the valve members in an adjustment chamber, the above channels communicates with the chamber.

According to the invention the adjustment chamber through a recess in the receiving chamber Part of the shock absorber leg be educated.

Preferably the recess can be a hole.

there can the adjusting means according to the invention be designed so that they can be removed from the adjustment chamber as a unit.

Preferably can the adjustment means a sleeve have, in which the valve members are received.

According to the invention, the sleeve can be ge in the adjustment chamber with a screw connection be secured.

The object of the invention is also achieved with a spring strut of a suspension fork with two parts which are telescopically movable against a spring force, the one part in a gas spring chamber containing a gas spring and the other part ( 520 ) immersed in one part, and released a negative spring element that biases the two parts towards each other with the strut disengaged, the negative spring element comprising a gas spring which is formed in a space between the inner wall of one part and the outer wall of the other part lies.

there can the other part on the side immersed in the first part have a piston.

According to the invention a part has a first section, the inner diameter of which outer diameter of the piston essentially corresponds.

According to the invention part have a second section, the inside diameter larger than the outside diameter of the piston. The second section preferably closes to the first section.

According to the invention a part have a third section, the inside diameter the outside diameter of the piston essentially corresponds. Preferably closes the third section follows the second section.

The The invention also relates to a suspension fork with a shock absorber leg and / or a shock absorber according to the invention.

According to one execution can the damping system also a secondary connection that connects the main chamber with the secondary chamber connects, and a closure member comprise, which is designed such that it is the secondary connection in a certain first stroke range or a certain first Damping system stroke at least partially closed and in a certain second stroke range or in a certain second stroke of the damping system at least compared to the first stroke range or the first stroke partially releases.

there can the closure member Depending on the application, be designed such that it Secondary connection in the specific first stroke range of the damping system Completely closes.

alternative it can close the secondary connection almost completely and only partially close.

According to one execution of the invention the stroke dependent cushioning system thus a secondary connection that connects the main chamber with the secondary chamber connects, and a closure member that the secondary connection in a certain first stroke range of the damping system closes and at least partially in a certain second stroke range of the damping system releases.

The construction according to the invention has the advantage that the damping characteristics of the damping system is easily and quickly adjustable. The setting through the construction of the damping system be fixed and / or an adjusting device is provided with which the damping characteristic can be customized can.

For example can in the construction of the damping system the damping characteristic be set such that the Closure member the The secondary connection in the compression stage is closed at the start of compression and if it is exceeded a certain hub at least partially releases.

advantageously, can in the construction of the damping system the damping characteristic can be adjusted by the provision of valve members in such a way that the or the passages between the main chamber and the secondary chamber only in the event of strong impacts, i.e. at. high compression and rebound speeds for the flow of a damping medium released, and for small bumps, such as the arising from pedaling to drive the bicycle Bumps, yet are closed. You can do this, for example the valve members, e.g. Spring plate stack or "Shimpakete", the passages or the first release at a certain pressure. At lower pressures, i.e. for smaller bumps the passages locked. The secondary connection is preferably through the closure element also closed in the first stroke range, so that the damping is very is strong. If the damping system is so far compressed that a certain stroke is reached, the closure element gives the secondary connection at least partially free, so that damping fluid even at low compression rates from the main chamber flow to the side chamber can.

According to one preferred execution the invention is the closure member connected to the housing. This has the advantage that the closure member one relative to the housing has a fixed position, which is why the particular stroke at which the closure element at least partially releases the secondary connection, precisely adjusted can be. The particular stroke is also advantageously not from the pressure of the damping fluid dependent.

advantageously, the closure member can be needle-shaped his. This allows achieve a particularly simple construction. For example the closure member have a head portion and a neck portion, the head portion a larger diameter than the neck section has. For example, the head section an opening close, which is fixed relative to the lifting member. When compressing the damping system would then the closure member move relative to the lifting member so that the neck portion comes in front of the opening and releases it because of its smaller diameter.

According to one execution can the closure member additionally have a third section that has a diameter that corresponds to the diameter of the head section, the neck section arranged between the head section and the third section is. This will make the secondary connection again at the end of compression locked and damping elevated.

According to one execution the closure member of the invention be designed so that the free Cross sectional area the secondary connection at a certain stroke of the damping system smaller than with a certain other stroke of the damping system is.

alternative could the damping system too be reversed, i.e. that the closure element relative to the lifting element and the connecting channel relative to the casing be firm. In both cases can be guaranteed be that the secondary link released at a certain stroke.

According to one preferred execution is a sleeve in the lifting member provided, in which the closure element dips. The sleeve can an opening have, which can be closed by the closure element. This allows the damping system according to the invention realize in a simple way and with few components.

advantageously, is in the damping system according to the invention an adjusting device is provided with which the first and second Stroke range changeable are. This has the advantage that the damping characteristics individually to the needs adapted to the driver can be. For example, the setting range of the setting device, by which the specific stroke can be varied, 5-15 mm, preferably 6-12 mm, more preferably 7-10 mm and particularly preferably 8 mm.

For example can the adjusting device means for changing the relative position the sleeve include in the lifting member. Advantageously, the sleeve can the lifting member over a screw connection can be coupled. For example, this can the adjusting device an adjusting screw and a receptacle include that about thread means are interconnected.

According to one execution of the invention has the damping system a valve member that opens at least one of the passages, when the pressure in the main chamber is higher than a certain value is the pressure in the side chamber. This applies to the pressure level. advantageously, are these or this passage at the rebound through a check valve locked.

Farther can the damping system according to the invention have a valve member that opens a passage when the Pressure in the secondary chamber is a certain value higher than the pressure in the main chamber is. That applies to the rebound. This passage is advantageously at the pressure stage through a check valve locked.

The Invention is not limited to these statements. Separate Characteristics can can be exchanged for alternatives that are obvious to the expert.

The Invention is based on the embodiment shown in the figures described below.

1 shows a sectional view of a stroke-dependent damping system of the invention.

2 shows a section of the damping system of 1 in the disengaged state, with the spring omitted for the sake of clarity.

3 shows one of the 2 corresponding section of the damping system from 1 in the indented or sprung state.

4 shows an enlarged section of a sectional view of the damping system of FIG 1 through the passages between the main chamber and the secondary chamber for the rebound.

5 shows an enlarged section of a sectional view of the damping system of 1 through the passages between the main chamber and the secondary chamber for the pressure stage, the closure member closing the secondary connection.

6 shows an enlarged section of a sectional view of the damping system of FIG 1 through the passages between the main chamber and the secondary chamber for the pressure stage, wherein the closure member at least partially releases the secondary connection.

7 shows a partial sectional view through the pressure stage adjustment device of the damping system of FIG 1 ,

8th shows an external perspective view of the damping system of FIG 1 ,

9 shows an external perspective view of a further embodiment of the damping system according to the invention.

10 shows a sectional view through a further embodiment of the invention.

11 shows a partial sectional view through the pressure stage adjustment device of the damping system of FIG 10 ,

12 shows an external perspective view of a suspension fork with the damping system of FIG 10 ,

13A shows a sectional view through a further embodiment of the invention in the disengaged state.

13B shows a sectional view of the embodiment of FIG 13A in indented condition.

14 shows enlarged partial sectional views of the embodiment of FIG 13A ,

15 shows still further enlarged partial sectional views of the embodiment of FIG 13A ,

16A shows a sectional view through a further embodiment of the invention in the disengaged state.

16B shows a sectional view of the embodiment of FIG 16A in indented condition.

17 shows the perspective view of a suspension fork with the embodiments of 13A and 16A ,

The 1 to 8th show an embodiment of the damping system according to the invention, which is suitable for damping the rear of a bicycle. For this purpose, the damping system is installed between the rear wheel mount and the saddle mount, which are pivotally connected to one another. The damping system has fastening elements for installation 21 and 51 on, which are designed as eyelets in the illustrated embodiment.

1 shows a sectional view through an inventive damping system. Between a housing 2 and a lifting link 5 is a feather 1 arranged. In the case 2 is an internal housing element 3 provided in the form of a cylindrical wall. The lifting link 5 carries a main piston 4 that in the housing 2 inside the housing inner element 3 is arranged and a main chamber 10 from a side room 11 separates that are filled with a non-compressible damping fluid.

The main piston 4 has a groove 43 on, in the o-ring 42 and a sliding band 41 for sealing the main piston against the inner housing element 3 is provided.

In the main piston 4 are passages 46 for the compression stage (the damping fluid should flow through these passages during compression) and passages 47 intended for the rebound (the damping fluid should flow through these passages during compression). The arrangement and number of passes can be chosen arbitrarily. For example, one pass can be provided for the compression stage and one pass for the rebound stage. In the illustrated embodiment are each 2 crossings 46 . 47 provided, which are alternately evenly distributed in the circumferential direction. 4 shows the passages 47 for the rebound, while the other figures the passageways 46 show for the pressure level.

Valve members are located above and below the main piston 44 . 45 arranged. The valve members 44 are designed so that they the passages 46 close like a check valve when the pressure in the sub chamber 11 higher than in the main chamber 10 is (rebound). At the same time, the valve members 44 trained so that the passages 46 release at least partially when the pressure in the main chamber 10 a certain value higher than in the secondary chamber 11 is (pressure stage). The valve members 45 are designed so that they the passages 47 close like a check valve when the pressure in the main chamber 10 higher than in the side room 11 is (pressure stage). At the same time, the valve members 45 trained so that the passages 47 release at least partially when the pressure in the main chamber 11 a certain value higher than in the secondary chamber 10 is (rebound). Such valve members are known to the person skilled in the art.

The glide band 41 , the O-ring 42 and the valve members 44 . 45 are only in 4 shown. In these parts are not shown for the sake of clarity.

As in 4 shown, spring plate packs (shim packs) are used as valve members in the illustrated embodiment. Alternatively, other valve members known to the person skilled in the art can also be used according to the invention.

The lifting link 5 has a main section 55 and a minor section 56 which has a smaller outer diameter than the main section. The transition is in the illustrated embodiment by a return 54 educated. The main piston 4 is on minor section 56 of the lifting member 5 recorded and between one recording 57 and a fastener 53 secured. The fastener 53 is with a threaded connection on the secondary section 56 fastens and tensions the main piston 4 with the valve members arranged in between 45 and 44 against admission 57 that at the return 54 is supported.

The lifting link 5 is tubular. In the lifting link 5 is a sleeve 6 added, which is also tubular. The outer diameter of the sleeve 6 corresponds to the inside diameter of the subsection 56 of the lifting member 5 , In the area of the main section 55 is between the sleeve 6 and the lifting member 5 a chamber formed over one or more openings 61 communicates with the interior of the sleeve.

Between the main chamber 10 and the side room 11 is a secondary connection 110 formed as follows in the illustrated embodiment. The interior of the sleeve 6 is with the main chamber 10 connected. In the sleeve 6 is an opening designed as an elongated hole 62 provided the how to best in 4 can see with one in the lifting link 5 trained opening 52 communicates. The opening 52 is connected to the secondary chamber via conduit means, not shown. In the illustrated embodiment, there are two openings 52 and 62 provided that in 4 from the front and in the 5 and 6 shown cut from the side. It is also possible to provide only one or more openings at a time.

The damping system also has a closure member 7 on that firmly with the case 2 on the side of the fastener 21 connected is. In the illustrated embodiment, the closure member 7 needle-shaped. The closure member 7 has a head section 71 and a neck section 72 smaller pressure gauge. The outside diameter of the head section 71 corresponds to the inside diameter of the sleeve 6 , The outside diameter of the neck section 72 is smaller than the inside diameter of the sleeve 6 , With the damping system disengaged ( 2 ) closes the head section 71 the openings 62 and thus the secondary connection 110 , From a certain stroke ( 3 ) comes instead of the head section 71 the neck section 72 in front of the openings 62 and gives the secondary connection 110 at least partially free.

To change the specific stroke at which the closure member 7 the openings 62 at least partially releases, is an adjusting device in the illustrated embodiment 63 intended. The adjustment device 63 has an adjusting screw 64 and a recording 65 which are connected to each other via a screw connection. The recording 65 takes the sleeve 6 and determines the relative position of the sleeve 6 in the lifting member 5 , By turning the adjusting screw 63 the sleeve moves 6 in the lifting member 5 and thus the specific hub at which the secondary connection 110 is released at least in part. In the illustrated embodiment, the possible adjustment range is 8 mm.

The damping system also has a compensation chamber 14 on that with the side chamber through openings 112 in the housing inner element 3 between the housing 2 and the housing inner element 3 trained space 12 and a channel 13 connected is. The compensation chamber 14 is in an expansion tank 8th intended. In the expansion tank 8th is a floating piston 9 provided the compensation chamber 14 and a pressure chamber filled with a gas (air) 15 separates. Via an adjusting screw 81 is the position of an adjusting piston 82 and thus the volume or pressure of the pressure chamber adjustable. The pressure can also be changed via a valve, not shown, by introducing or releasing gas into the pressure chamber via the valve.

Instead of the gas spring can also have another spring device, for example a coil spring may be provided.

Between the space 12 and the channel 13 is also preferably an adjusting device 200 provided, through which the damping fluid must flow. The adjustment device 200 has a rebound adjustment device 210 and a pressure adjustment device 220 with which the damping characteristics for the rebound and compression can be adjusted independently. The pressure stage adjustment device preferably has 220 two separate adjustment means for different speed ranges, more precisely in connection with 7 to be discribed.

In the event of an impact, the lifting element can 6 against the force of the spring 1 in the housing 2 indent and moves the piston 4 , The volume of the main chamber 10 is reduced and the volume of the secondary chamber 11 increased. At the same time, the total volume of the main chamber increases 10 and the side room 11 by the lifting member immersed in the housing. When compressed, the damping fluid is released from the main chamber 10 via the adjustment device 200 and the space 12 in the side room 11 and further into the compensation chamber 14 repressed. Above a certain pressure difference between the main chamber 10 and the side room 11 open the valve members 44 and give the passages 46 for the flow of damping fluid from the main chamber 10 in the side room 11 free. In addition, from a certain stroke, the secondary connection 110 from the closure member 7 Approved.

When rebounding, the damping fluid flows from the secondary chamber 11 and the compensation chamber 14 across the gap 12 or the channel 13 and the adjustment device 200 back to the main chamber 10 , Above a certain pressure difference between the secondary chamber 11 and the main chamber 10 open the valve members 45 and give the passages 47 for the flow of damping fluid from the secondary chamber 11 into the main chamber 10 free. Was the specified stroke exceeded during compression, at which the secondary connection 110 the secondary connection remains for the flow of damping fluid 110 when rebounding, it is open until the rebound falls below the specified stroke and the secondary connection 110 again through the closure member 7 is closed.

7 shows a sectional view through the pressure stage adjusting device 220 , The pressure adjustment device 220 has two separate valve members 227 and 228 on. The valve member 227 is with a spring element 225 biased. The strength of the preload is via the adjustment element 221 variable. The adjustment element 221 is with a spring mount 223 connected via a threaded connection. By turning the adjustment element 221 the spring holder shifts 223 in a sleeve in the direction of the spring element 227 or moves away from it, whereby the preload can be changed. The valve member 228 is with a spring element 226 biased. The strength of the preload is via the adjustment element 222 variable. The adjustment element 222 is with a spring mount 224 connected via a threaded connection. By turning the adjustment element 222 the spring holder shifts 224 towards the spring element 228 or moves away from it, whereby the preload can be changed.

The biasing force of the spring element is advantageous 225 less than the biasing force of the spring element 226 , Furthermore, the spring element 225 advantageously a smaller spring constant than the spring element 226 on. This enables a speed-dependent damping characteristic that can be set quickly and easily for low and high speeds.

The valve elements act when rebounding (rebound) 227 and 228 as a check valve and close the channels 233 respectively. 234 , The flow flow of the damping fluid passes through the rebound adjustment device when rebounding 210 , which has separate flow paths and is adjustable independently of the pressure stage adjustment device.

The rebound adjustment device 210 has a spring-loaded needle valve. The spring preload is adjustable. The structure is known to the person skilled in the art and will not be explained further here. It is clear that any training for the rebound damping known to the person skilled in the art can be used according to the invention.

By the construction according to the invention can be a damping characteristic achieve the small bumps strong damps and big Softly dampens shocks. For example when driving uphill, those that occur by pedaling small bumps almost Completely steamed, so that no energy draining Compression occurs. On the other hand, big shocks become less strong when driving downhill steamed, so that you can be cushioned well.

In 9 Another embodiment of the damping system according to the invention is shown. This embodiment corresponds essentially to that in the 1 to 8th shown embodiment. Only the differences are discussed below. Incidentally, reference is made to the previous description of the context in the 1 to 8th described embodiment.

This in 9 The embodiment shown shows a damping system that instead of the coil spring 1 a gas spring 1' which the housing 2 ' at least partially surrounds. The compensation chamber is integrated in the gas spring in a manner known to the person skilled in the art. The damping system can with the eyelets 21 ' and 51 ' be mounted on frame parts of the rear of a bicycle to dampen impacts on the rear wheel.

The 10 to 12 show a further embodiment of the present invention.

10 shows a section through a damper leg of a suspension fork. The shock absorber shows casing 302 in which a lifting link 305 dips. In the case 302 is a main chamber 310 intended. On the lifting member is on the in the housing 302 immersed side of a main piston 304 intended. The main chamber 10 is through a cylindrical wall from a compensation chamber 314 Cut. The top of the link 305 is filled with gas (air) and serves as a pressure chamber 315 in order to rebound the damping fluid from the compensation chamber into the main chamber 310 to displace. The compensation chamber 314 extends into the lifting link and is through the parting plane 316 between the pressure chamber 315 (filled with gas or air) and the compensation chamber 314 (filled with damping fluid) from the pressure chamber 315 Cut.

The main piston 304 is similar to the piston 4 of the embodiment of the 1 to 8th built up and separates the main chamber 310 from a side room 311 , Otherwise, the corresponding description of the embodiment of the 1 to 8th directed.

11 shows a partial sectional view of the pressure stage adjustment device 320 that in an adjustment chamber 330 of the housing 302 is included.

The pressure adjustment device 320 has two separate valve members 327 and 328 on. The valve member 327 is a needle valve that operates the adjustment element 321 that with the valve element 327 is connected by a threaded connection, is displaceable in the direction of the arrows X. The position of the valve member 327 in the channel 333 determines the free cross-sectional area for the flow of the damping fluid. Since no spring element is provided, it is independent of the pressure. The flow can take place at both the compression and the rebound. To check the flow only in the compression or rebound stage, a check valve can be provided in a manner known to those skilled in the art. The valve member 328 is with a spring element 326 biased which is a cap 326A applied. The strength of the preload is via the adjustment element 322 variable.

When compressing (compression stage) damping fluid flows through the inlet opening 331 into the valve chamber 332 , The valve element 327 is open or closed depending on the setting. As a rule, it will be at least partially open. Then the damping fluid flows through the channel 333 on the valve element 326 over to the exit opening 336 , If the pressure is sufficient to pre-tension the spring element 326 to overcome, the valve element also opens 328 , The damping fluid also flows through the channel 334 to the exit opening 336 and on to the compensation chamber 314 ,

The valve member 328 is a spring plate stack (shim package) with a very specific spring constant. The damping characteristics can be easily adjusted by installing certain spring plate stacks. Therefore, a damping system in which the spring plate stack can be easily replaced is desirable. In particular, a damping system is desirable that does not require the damping fluid to be drained to replace the spring plate stack.

The pressure adjustment device 320 is according to the invention in the adjustment chamber 330 by means of the sleeve 350 screwed in and with a seal 341 sealed. This has the advantage that when the pressure adjustment device 320 for example, for the maintenance and / or replacement of the valve members, it is not necessary, as in the prior art, to disassemble the entire fork, for which purpose the damping fluid would have to be drained. In the embodiment according to the invention, only about 1/300 of the damping fluid is contained in the pressure stage adjustment device. The remaining damping fluid remains in the damper leg when the compression adjustment device is removed. This results in a simple and quick adjustability of the damping system, for example by replacing the spring elements and / or the valve members. According to the invention, the rebound adjustment device can also be constructed in such a way that it can be removed as a unit from the damper leg without having to disassemble the damper. For example, the rebound adjustment device can also have a sleeve that is screwed into an adjustment chamber. Because of the low demands on the rebound damping, it is sufficient to provide only one preferably adjustable valve.

If the pressure adjustment device 320 is removed, the screw 344 be removed to access the screw 345 to obtain. By loosening the screw 345 For example, the shock absorber leg can be disassembled for maintenance in a known manner.

The 13A to 17 show a further embodiment of the invention. The 13A to 15 show the shock leg 400 a suspension fork while the 16A to 16B the corresponding shock absorber 500 and the 17 show a perspective view of the suspension fork.

The damper leg 400 is compared to that in the 10 to 12 Shock strut shown constructed the other way around, that is, the lifting member 405 from below into the housing 402 immersed and with the piston 404 the damping fluid pushes up. The piston 404 can again as in the 1 to 8th shown embodiment builds a flow of damping fluid from the main chamber 410 in the side room 411 to enable. Because of the compression in the housing 402 immersed lifting link 405 the volume in the housing decreases, which in turn damping fluid through the pressure adjustment device 420 into the compensation chamber 414 must flow against the force of the gas (air) in the pressure chamber.

The pressure adjustment device 420 has two independently adjustable valve members 427 and 428 on. The valve member 427 is a needle valve with a spring element 425 is biased into the valve seat. The spring element 425 has a relatively small spring constant, so the valve member 427 The valve head is already relatively blunt at impacts of relatively low speed so that the damping does not decrease too quickly. The valve member 427 is in a spring holder together with the spring element 423 added, which has an external thread that engages in an internal thread. By rotating the adjustment element 421 the spring receptacle moves relative to the spring element and the valve member, whereby the bias is changed. The structure of the second valve member is corresponding. The reference numerals are each increased by one.

To avoid repetition, refer to the description of the valve member 427 referenced and only pointed out the differences. The spring constant of the spring element 426 is larger than that of the spring element 427 , Therefore the valve member opens 428 only at high speed impacts. The valve head is the valve member so that lower damping can be achieved quickly 428 formed relatively tapered. Of course, depending on the application, the valve heads can be the same or different.

The main piston plunges when compressed 404 into the main chamber 410 on. This displaces damping fluid through the main piston into the secondary chamber. At the same time damping fluid through the pressure stage adjustment device 420 into the compensation chamber 414 against the force of the pressure chamber 415 repressed. Valves known to those skilled in the art can be provided with known adjusting devices for the reflux at the rebound stage.

The 16A and 16B show a shock absorber 500 , 16A shows the shock absorber in the disengaged state while 16B the strut shows in the engaged state.

The strut 500 has a part 501 on which another part 520 dips. In one part 501 is a gas spring chamber 510 arranged. The other part dips when compressed 520 in one part 501 and reduces the volume of the gas spring chamber 510 against the rising pressure of the gas spring. The other part has a piston on the side immersed in the part 521 on. A groove is provided in the piston, in the as a seal 522 an O-ring is arranged against the inner wall of one part. A seal is also provided in a groove at the lower end of one part in order to seal against the outer wall of the other part.

The inner wall of one part 501 has a first section 504 with an inner diameter that corresponds essentially to the diameter of the piston. The first section is followed by a second section 503 whose inner diameter compared to the first section 504 is bigger. The second section is followed by a third section 502 whose inner diameter compared to the second section 503 is again smaller and essentially the diameter of the piston 521 equivalent.

In the embodiment shown, the change in inner diameter is in the first section 504 achieved in that in one part 501 a sleeve 505 is arranged, which reduces the inner diameter. Alternatively, it would also be conceivable to arrange the sleeve on the other side of one part, such that the sleeve has the inside diameter in the third section 502 reduced. Alternatively, two sleeves, one in the first and one in the third section, can also be provided. The provision of a sleeve is not absolutely necessary, but is advantageous in terms of production technology.

Opposite the area in which the seal is received in the groove is the inside diameter of the first section 504 slightly larger.

When disengaged ( 16A ) is between that of the outer wall of the other part 520 and the inner wall of one part 501 a room 512 formed, which serves as a negative chamber. The gas spring contained therein helps to overcome the initial friction during compression. Once the seal 522 of the piston 521 when compressing the second section 503 the space is reached 512 the negative chamber connected to the main chamber. By enlarging the main chamber, the progression of the gas spring is reduced and the linearity of the spring characteristic is improved. Once the seal 522 of the piston 521 the third section during compression 502 the space is reached 512 again from the gas spring chamber 510 separated. This has the advantage that a strongly increasing progression of the spring characteristic is obtained at the end of the spring travel.

When rebounding, the gas spring chamber is first again 510 with the room 512 connected so that in the gas spring chamber 510 and the room 512 the pressure is always the same. Once the seal 522 of the piston 521 the first section when rebounding 503 the space is reached 512 again from the gas spring chamber 510 separated. This makes the room work 512 as a negative chamber 512 , The rebound takes place against the force of the compressing gas building up in the negative chamber. This construction has the advantage that when the spring characteristics change by increasing or decreasing the pressure in the gas spring chamber 510 at the same time the pressure in the negative chamber is changed. With each stronger deflection (reaching the second section), the pressure is automatically adjusted to each other by connecting the chambers. A separate readjustment of the negative chamber or negative spring is not necessary according to the invention.

1

feather

2

casing

21

fastener (Eyelet)

3

Housing inner element (Cylinder)

4

main piston

41

sliding

42

O-ring

43

groove

44

valve member for the Pressure rating (shim)

45

valve member for rebound (Shim)

46

passage (Compression)

47

passage (Rebound)

5

lifting member

51

fastener (Eyelet)

52

opening

53

fastener (Mother)

54

return

55

main section

56

next section

57

admission

G

shell

61

connecting opening

62

Opening (slot)

63

adjustment

64

adjustment

65

admission

7

Closure member (needle)

71

header

72

neck section

8th

surge tank

81

adjustment

82

adjusting piston

9

floating piston

10

main chamber

11

secondary chamber

110

Besides connection

112

opening

12

gap

13

channel

14

compensation chamber

15

pressure chamber

200

adjustment

210

Zugstufenverstelleinrichtung

220

Druckstufenverstelleinrichtung

221

adjustment

222

adjustment

223

spring mount

224

spring mount

225

spring element

226

spring element

227

valve member

228

valve member

231

inlet opening

232

valve chamber

233

channel

234

channel

235

connecting opening

236

outlet opening

302

casing

304

main piston

305

lifting member

310

Haupkammer

311

secondary chamber

314

compensation chamber

315

pressure chamber

316

parting plane between pressure chamber (with gas or air

filled) and Compensation chamber (with damping fluid filled)

320

Druckstufenverstellvorrichtung

321

adjustment

322

adjustment

323

spring mount

324

spring mount

326

spring element

326A

cap

327

valve member

328

valve member

330

adjusting chamber

331

inlet opening

332

valve chamber

333

channel

334

channel

336

outlet opening

341

poetry (O-ring)

342

screw (Threaded connection)

343

valve receiving

344

screw

345

screw

350

shell

400

damper strut

402

casing

404

main piston

405

lifting member

410

Haupkammer

411

secondary chamber

414

compensation chamber

415

pressure chamber

416

parting plane between pressure chamber (with gas or air

filled) and Compensation chamber (with damping fluid filled)

420

Druckstufenverstellvorrichtung

421

adjustment

422

adjustment

423

spring mount

423A

threaded element

424

spring mount

424A

threaded element

425

spring element

426

spring element

427

valve member

428

valve member

431

inlet opening

432

valve chamber

500

strut

501

on part

502

third section

503

second section

504

first section

505

shell

510

Gas spring chamber

511

gap

512

room

520

other part

521

piston

522

poetry (O-ring)

Claims (41)

Damping system with two parts telescopically movable against a spring force, a chamber for receiving a damping fluid, which is received in one of the two parts, a piston for displacing the damping fluid from the chamber during the compression of the damping system, the piston with the other part of the is connected to each other telescopically movable parts against a spring force, channels formed in a boundary wall of the chamber through which the damping fluid at least partially flows during the compression of the damping system, valve means for changing the free cross-sectional area of the channels, and adjusting means for the valve means for changing the damping characteristic of the damping system, characterized in that the valve means at least two independently adjustable valve members ( 227 . 228 ; 327 . 328 ; 427 . 428 ) and the adjustment means at least two adjustment elements ( 221 . 222 ; 321 . 322 ; 421 . 422 ) for independent adjustment of the valve members. Damping system according to claim 1, characterized in that at least one valve member ( 227 . 228 ; 328 ; 427 . 428 ) by a spring element ( 225 . 226 ; 326 ; 425 . 426 ) is prestressed against the pressure of the damping fluid which arises during the compression of the damping system, preferably the prestressing of the spring element by the adjusting member ( 221 . 222 ; 322 ; 421 . 422 ) can be changed to adjust the valve member. Damping system according to one of the preceding claims, characterized in that the at least two valve members ( 227 . 228 ; 427 . 428 ) each with a spring element ( 225 . 226 ; 425 . 426 ) are prestressed against the pressure of the damping fluid which arises during the compression of the damping system, preferably the prestressing of the spring elements by the adjusting elements ( 221 . 222 ; 421 . 422 ) can be changed for independent adjustment of the valve member. Damping system according to claim 3, characterized in that the one valve member ( 227 ; 427 ) assigned spring element ( 225 ; 425 ) a smaller preload on the valve member assigned to it ( 227 ; 427 ) than the other valve member ( 228 ; 428 ) assigned spring element ( 226 ; 426 ). Damping system according to claim 3 or 4, characterized in that the one valve member ( 227 ; 427 ) assigned spring element ( 225 ; 425 ) softer than that of the other valve member ( 228 ; 428 ) assigned spring element ( 226 ; 426 ) is. Damping system according to claim 3, 4 or 5, characterized in that the one valve member ( 227 ; 427 ) assigned spring element ( 225 ; 425 ) a smaller spring constant than that of the other valve member ( 228 ; 428 ) assigned spring element ( 226 ; 426 ) having. Damping system according to one of the preceding claims, characterized in that a valve member ( 227 ; 327 ; 427 ) is a needle valve. Damping system according to one of the preceding claims, characterized in that the one valve member ( 227 ; 327 ; 427 ) has a weakly tapering needle tip. Damping system according to claim 7 or 8, characterized in that the other valve member ( 428 ) is a needle valve. Damping system according to claim 9, characterized in that the other valve member ( 428 ) has a sharply tapering needle tip. Damping system according to one of claims 1 to 7, characterized in that the other right valve member ( 328 ) comprises a spring plate stack (shim package). Damping system according to claim 11, characterized in that the spring plate stack is supported by a cap ( 326A ), which in turn is supported by a spring element ( 326 ) against the valve member ( 328 ) is biased. Damping system according to one of claims 1 to 7, characterized in that the other valve member ( 228 ) has an annular plate. Damping system according to one of claims 2 to 13, characterized in that the spring element or elements ( 225 . 226 ; 326 ; 425 . 426 ) Are coil springs. cushioning system according to one of the preceding claims, characterized in that this cushioning system is a bicycle rear shock. cushioning system according to one of the preceding claims, characterized in that it's part a suspension fork for is a bike. cushioning system according to claim 16, characterized in that the suspension fork is a damper leg and a shock absorber, each with two against each other against a spring force includes telescopically movable parts, preferably the Means for applying at least the main part of the spring force in the strut are arranged. Damper leg of a suspension fork with two parts which are telescopically movable against a spring force in a damping direction (Y), a damping system for damping the movement of the two parts, and adjusting means for adjusting at least two valve members influencing the damping characteristics of the damping system ( 327 . 328 ), the adjustment means being designed such that when the adjustment means is actuated, one on at least one of the valve members ( 328 ) force acting in an adjustment direction (X) changes and / or a movement of at least one of the valve members ( 327 ) in an adjustment direction (X), characterized in that the damping direction (Y) and the adjustment direction (X) are different. damper strut according to claim 18, characterized in that the damping direction (Y) and the Define the adjustment direction of a plane. damper strut according to claim 18 or 19, characterized in that the damping direction (Y) approximately is at a right angle to the adjustment direction (X). Damper leg according to one of claims 18 to 20, characterized in that a valve member ( 327 ) is a needle valve. Damper leg according to one of claims 18 to 21, characterized in that a valve member ( 328 ) is a spring plate package. Damper leg according to one of claims 18 to 22, characterized in that one or the valve members ( 328 ) with a spring element ( 326 ) are biased. Damper leg according to one of claims 18 to 23, characterized in that the adjusting means adjusting elements ( 321 . 322 ) include. Damper leg according to one of claims 18 to 24, characterized in that the adjusting elements ( 321 . 322 ) Comprise rotary knobs, which upon actuation (rotation) via a threaded connection cause displacement of a valve member ( 327 ) and / or a displacement of the receptacle for a spring element ( 326 ) cause. damper strut according to one of the claims 18 to 25 with a damping system according to one of the claims 1 to 17. Damper leg of a suspension fork with two parts which are telescopically movable against a spring force, a chamber for receiving a damping fluid, which is received in one of the two parts, and adjusting means for adjusting valve elements influencing the damping characteristic of the damping system ( 327 . 328 ), characterized in that the adjustment means with the valve members in an adjustment chamber ( 330 ) are arranged via channels ( 331 ) communicates with the chamber. Damper leg according to claim 27, characterized in that the adjustment chamber ( 330 ) through a recess in which the chamber ( 310 ) receiving part of the shock absorber leg is formed. damper strut according to claim 28, characterized in that the recess is a bore is. Damper leg according to one of claims 27 to 29, characterized in that the adjusting means are designed such that they come out of the adjusting chamber ( 330 ) can be expanded as a unit. Damper leg according to one of claims 27 to 30, characterized in that the adjusting means comprise a sleeve ( 350 ) have, in which the Ventilglie the ( 327 . 328 ) are included. Damper leg according to claim 31, characterized in that the sleeve ( 350 ) in the adjustment chamber ( 330 ) with a screw connection ( 342 ) is secured. damper strut according to one of the claims 18 to 26 and one of the claims 27 to 32. Suspension strut of a suspension fork with two parts that are telescopically movable against a spring force ( 501 . 520 ), the one part ( 501 ) in a gas spring chamber ( 510 ) contains a gas spring and the other part ( 520 ) into which a part is immersed, and a negative spring element which prestresses the two parts towards one another when the shock absorber is disengaged, characterized in that the negative spring element comprises a gas spring which in a space ( 512 ) is formed between the inner wall of one part ( 501 ) and the outer wall of the other part ( 520 ) lies. Suspension strut according to claim 34, characterized in that the other part ( 520 ) a piston on the side immersed in the first part ( 521 ) having. Suspension strut according to claim 35, characterized in that the one part ( 501 ) a first section ( 504 ), the inside diameter of which corresponds to the outside diameter of the piston ( 521 ) corresponds essentially. Suspension strut according to claim 36, characterized in that the one part ( 501 ) a second section ( 503 ), the inside diameter of which is larger than the outside diameter of the piston ( 521 ) is. Suspension strut according to claim 37, characterized in that the second section ( 503 ) to the first section ( 504 ) connects. Suspension strut according to claim 37 or 38, characterized. characterized that the one part ( 501 ) a third section ( 502 ), the inside diameter of which corresponds to the outside diameter of the piston ( 521 ) corresponds essentially. Suspension strut according to claim 39, characterized in that the third section ( 503 ) to the second section ( 504 ) connects. Suspension fork with a damper leg according to one of claims 18 to 33 and a shock absorber according to one of claims 34 to 40.