A shock absorber assembly includes a damping adjustment mechanism that can easily be incorporated into a twin cylinder design. The shock absorber includes an outer cylinder and an inner cylinder mounted within the outer cylinder. The inner cylinder is spaced apart from the outer cylinder to define a gap. A piston is mounted within a fluid filled chamber formed within the inner cylinder to dampen vibrations. Holes are drilled into the wall of the inner cylinder to provide fluid ports that can communicate with the gap to form a bi-directional fluid path as the piston moves back and forth within the chamber to dampen vibrations. To provide variable damping, the outer cylinder includes an eccentric inner diameter to outer diameter profile that allows damping adjustment between high and low damping forces. The damping force is adjusted by rotating the outer cylinder relative to the inner cylinder to vary the size of the gap with respect to the ports.
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1. A shock absorber assembly comprising:
a first cylinder having an outer wall with a thickness defined by a constant outer diameter and a variable inner diameter;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber, wherein said first cylinder comprises an outermost shock absorber cylinder and said second cylinder comprises an innermost shock absorber cylinder with said inner wall being spaced apart from said outer wall to define a gap extending longitudinally between said first outermost and second innermost shock absorber cylinders;
a piston mounted within said second cylinder to separate said chamber into a rebound side and a compression side, said piston being movable along a longitudinal path relative to said inner wall to dampen vibrations;
a plurality of ports formed within said inner wall to define a sealed fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression sides of said chamber via said plurality of ports in response to said piston moving back and forth within said chamber; and
an actuator for selectively adjusting the a damping force by axially translating said outer wall relative to said inner wall in a direction parallel to said longitudinal path to vary the size of said gap.
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0. 11. A shock absorber assembly comprising:
a first cylinder having an outer wall with a thickness defined by a constant outer diameter and a variable inner diameter;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber and spaced apart from said outer wall to define a gap extending longitudinally between said first and second cylinders;
a damping mechanism mounted within said second cylinder to separate said chamber into a rebound side and a compression side wherein said damping mechanism moves longitudinally relative to said inner wall for damping vibrations; and
a plurality of ports formed within said inner wall to define a fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression sides of said chamber via said ports as said first cylinder is moved relative to said second cylinder to selectively adjust damping by varying gap size.
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19. The assembly according to
a first cylinder having an outer wall with a thickness defined by a constant outer diameter and a variable inner diameter;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber wherein said first cylinder comprises an outermost shock absorber cylinder and said second cylinder comprises an innermost shock absorber cylinder, said outermost shock absorber cylinder surrounding a substantial length of said innermost shock absorber cylinder such that said inner wall is spaced apart from said outer wall to define a gap extending longitudinally between said outermost and innermost shock absorber cylinders;
a damping mechanism mounted within said second cylinder to separate said chamber into a rebound side and a compression side wherein said damping mechanism moves longitudinally relative to said inner wall for damping vibrations; and
a plurality of ports formed within said inner wall to define a fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression sides of said chamber via said plurality of ports as said first cylinder is moved relative to said second cylinder to selectively adjust damping by varying a size of said gap wherein said first cylinder is axially translated relative to said second cylinder to vary gap a size of said gap.
0. 20. The assembly according to
0. 21. The assembly of
0. 22. A method for adjusting damping force in a shock absorber comprising the steps of:
(a) mounting a first cylinder having an inner wall defining a chamber within a second cylinder having a solid outer wall with a variable thickness defined by a constant outer diameter and a variable inner diameter by spacing the outer wall apart from the inner wall to define a gap extending longitudinally between said first and second cylinders;
(b) mounting a damping mechanism within the chamber of the first cylinder to define a compression side and a rebound side with the damping mechanism moving longitudinally relative to the inner wall for damping vibrations; and
(c) moving the second cylinder with respect to the first cylinder to adjust the size of the gap to selectively change the damping force.
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28. The method according to
(a) mounting a first cylinder having an inner wall defining a chamber within a second cylinder having a solid outer wall with a variable thickness defined by a constant outer diameter and a variable inner diameter by spacing the outer wall apart from the inner wall to define a gap extending longitudinally between the first and second cylinders and wherein the first cylinder comprises an innermost shock absorber cylinder and the second cylinder comprises an outermost shock absorber cylinder with the outermost shock absorber cylinder surrounding a substantial length of the innermost shock absorber cylinder such that the gap is formed between the outermost and innermost shock absorber cylinders;
(b) mounting a damping mechanism within the chamber of the first cylinder to define a compression side and a rebound side with the damping mechanism moving longitudinally relative to the inner wall for damping vibrations;
(c) forming a plurality of longitudinally spaced ports in the inner wall on one side of the first cylinder to define a fluid flow path wherein fluid flows bi-directionally within the gap and into and out of the rebound and compression sides via the plurality of longitudinally spaced ports; and
(d) moving the second cylinder with respect to the first cylinder to adjust the size of the gap to selectively change a damping force wherein step (c) (d) further includes axially translating the second cylinder relative to the first cylinder.
0. 29. The method according to
0. 30. A shock absorber assembly comprising:
a first cylinder having a solid outer wall with a thickness defined by a constant outer diameter and a variable inner diameter;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber, said inner wall being spaced apart from said outer wall to define a gap extending longitudinally between said first and second cylinders;
a piston mounted within said second cylinder to separate said chamber into a rebound chamber and a compression chamber, said piston being longitudinally movable relative to said inner wall to dampen vibrations;
a plurality of longitudinally spaced ports formed within said inner wall to define a fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression chambers via said ports in response to said piston moving back and forth within said chamber; and
an actuator for selectively adjusting the damping force by moving said inner and outer walls relative to each other to vary the size of said gap.
0. 31. The assembly according to
32. The assembly according to
a first cylinder having a solid outer wall with a thickness defined by a constant outer diameter and a variable inner diameter wherein said variable inner diameter varies in both a radial direction and a longitudinal direction along a length of the outer wall;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber wherein said first cylinder comprises an outermost shock absorber cylinder and said second cylinder comprises an innermost shock absorber cylinder, said outermost shock absorber cylinder surrounding a substantial length of said innermost shock absorber cylinder such that said inner wall is spaced apart from said outer wall to define a gap extending longitudinally between said outermost and innermost shock absorber cylinders;
a piston mounted within said second cylinder to separate said chamber into a rebound chamber and a compression chamber, said piston being longitudinally movable relative to said inner wall to dampen vibrations;
a plurality of longitudinally spaced ports formed within said inner wall to define a fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression chambers via said plurality of longitudinally spaced ports in response to said piston moving back and forth within said chamber; and
an actuator for selectively adjusting a damping force by moving said inner and outer walls relative to each other to vary the size of said gap wherein said variable inner diameter is formed with a wave profile having alternating minimum and maximum diameters.
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0. 35. The assembly according to
36. The assembly according to
a first cylinder having a solid outer wall with a thickness defined by a constant outer diameter and a variable inner diameter wherein said variable inner diameter varies in both a radial direction and a longitudinal direction along a length of the outer wall;
a second cylinder mounted within said first cylinder and having an inner wall enclosing a chamber wherein said first cylinder comprises an outermost shock absorber cylinder and said second cylinder comprises an innermost shock absorber cylinder, said outermost shock absorber cylinder surrounding a substantial length of said innermost shock absorber cylinder such that said inner wall is spaced apart from said outer wall to define a gap extending longitudinally between said outermost and innermost shock absorber cylinders;
a piston mounted within said second cylinder to separate said chamber into a rebound chamber and a compressive chamber, said piston being longitudinally movable relative to said inner wall to dampen vibrations;
a plurality of longitudinally spaced ports formed within said inner wall to define a fluid path wherein fluid flows bi-directionally within said gap and into and out of said rebound and compression chambers via said plurality of longitudinally spaced ports in response to said piston moving back and forth within said chamber; and
an actuator for selectively adjusting a damping force by moving said inner and outer walls relative to each other to vary the size of said gap wherein said outer wall is longitudinally translated relative to said inner wall to adjust the size of said gap.
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This invention relates to a device and method for adjusting damping in a vehicle shock absorber.
Vehicles utilize shock absorbers to dampen vibrations and shocks experienced by a vehicle. Variations in payload and ground conditions can affect vehicle control and handling. Having the ability to selectively adjust the damping force in a shock absorber is desirable to improve vehicle control and handling in response to these variables. Some shock absorbers include position sensing technology and damping adjustment that permit a vehicle operator to selectively change damping to a desired level.
Current adjustment systems rely on external components or adjuster modules to provide adjustment. Utilizing additional components significantly increases cost and assembly time. Thus, the adjustment feature is not typically incorporated on most vehicles.
It is desirable to provide a shock absorber with an adjustment mechanism that utilizes components already found within the shock absorber, and which can be easily adjusted by a vehicle operator to control damping levels. The adjustment mechanism should also be cost effective in addition to overcoming the above referenced deficiencies with prior art systems
The subject invention provides a shock absorber that includes damping adjustment for a twin cylinder configuration having an inner cylinder mounted within an outer cylinder in a spaced relationship to form a flow gap. Simultaneous and/or independent compression and rebound damping adjustment is achieved by moving the outer cylinder with respect to the inner cylinder to adjust flow gap size around flow ports formed within the inner cylinder. The outer cylinder can be rotated or axially translated relative to the inner cylinder to adjust gap size.
In the preferred embodiment, this is accomplished by the outer cylinder having an eccentric inner diameter to outer diameter profile to control the width of the flow gap is in relation to the ports. The outer cylinder forms an outer wall of the shock absorber and the inner cylinder forms an inner wall of the shock absorber. The outer wall is defined by an outer diameter that has a first center and an inner diameter that has a second center that is different than the first center to form the eccentric profile. The eccentricity of the outer wall adjusts flow gap size as the outer cylinder is rotated or translated to adjust damping. The eccentricity is formed by varying the wall thickness or profile of the outer cylinder. Multiple eccentricities to provide multiple gap size variations are achieved by forming the outer wall with several different thicknesses about the circumference.
In one embodiment, the eccentricity is uniform such that the gap is uniform in cross-section along the length of the cylinders. The shock absorber is adjustable between a low damping force where the gap size is defined by a first width in relation to the ports and a high damping force where the gap size is defined by a second width in relation to the ports that is less than the first width.
In an alternate embodiment, the eccentricity is variable such that the gap is nonuniform in cross-section along the length of the cylinders. The variable eccentricity results from an inner surface of the outer wall having a stepped or tapered profile. The steps or taper provide variable gap widths for each of the ports.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
Referring to
The inner wall 20 defines a chamber 22 in which a plunger or piston member 24 is mounted. Fluid is sealed within the chamber 22, as is known in the art, and is compressed by the piston 24 to dampen vibrations. Any type of known fluid can be used, including hydraulic fluid or gas either of which could be compressible or incompressible, for example.
Multiple ports 26 are formed within the inner wall 20. The ports 26 are preferably formed on only one side of the inner cylinder 14 to define a ported side 28 and non-ported side 30 of the inner cylinder 14. The ports 26 allow fluid communication with the gap 16 as the piston 24 moves within the chamber 22.
The piston 24 separates the chamber 22 into a compression side 22a and a rebound side 22b. There are ports 26 positioned on both the compression 22a and rebound 22b sides. As vibrations are dampened, fluid flows from the rebound side 22b to the compression side 22a and/or vice versa via the ports 26 and gap 16. Thus, fluid flow can be bi-directional between the rebound 22b and compression 22a sides or check valves can be used to allow fluid to flow in one direction while preventing fluid flow in an opposite direction. Fluid also flows back and forth between the rebound 22b and compression 22a sides via disc valves (not shown) through the piston 24 as known in the art. The operation of disc and check valves is well known and will not be discussed in further detail.
The subject invention provides an adjustment mechanism for varying the damping force of the shock absorber 10 that can be selectively actuated by a vehicle operator. It is desirable to control damping force to provide improved vehicle control and handling to accommodate vehicle payload changes or ground condition changes. For example, one vehicle application in which shock absorber damping adjustment is desirable is for snowmobiles. Aggressive drivers may desire high damping forces while non-aggressive drivers desire lower damping forces. Or, if more than one passenger is riding on the snowmobile it may be desirable to change the damping force to accommodate the additional weight.
Damping force adjustment is accomplished by selectively rotating or axially translating the outer cylinder 12 with respect to the inner cylinder 14 to vary the size of the gap 16 in relation to the ports 26. The rotation or translation of the outer cylinder 12 is accomplished by any of various types of actuation methods. For example, the outer cylinder 12 can be manually moved by the operator or can be electrically moved upon selection of a desired damping position by the operator.
For manual rotation or translation, a grip portion 32 can be formed on the outer surface of the outer cylinder 12 and a label or markings 34 can be made on the outer cylinder 12 to indicate various adjustment positions. The grip portion 32 can be positioned anywhere along the length of the outer cylinder 12 and can be a separate member attached to or formed within the cylinder 12, as shown in
For electrical rotation or translation, a controller and motor 36 can be selectively actuated by the operator to move the outer cylinder 12. A push-button, switch, dial, or toggle (not shown) can be selected to power the system.
As discussed above, the damping adjustment occurs as a result of variation in flow gap size. One way to vary the flow gap size is by varying the thickness or profile of the outer wall 18. In prior art systems, shown in
As indicated above, in one embodiment the subject invention varies flow gap size by eccentrically forming the outer wall 18, as shown in
An alternate embodiment for a cross-section of the outer cylinder 12 is shown in FIG. 6B. In this embodiment, the outer cylinder 12 is defined by an inner diameter that presents a variable profile. An example of this is shown in
Thus, the eccentric inner diameter to outer diameter profile changes the flow gap width in relation to the ports 26 to vary damping. It should be understood that while only two (2) ports 26 are shown in
In one embodiment, shown in
In an alternate embodiment, shown in
In the low damping force configuration, shown in
In an alternate embodiment, shown in
In the low damping force configuration, shown in
The aforementioned description is exemplary rather that limiting. Many modifications and variations of the present invention are possible in light of the above teachings. The preferred embodiments of this invention have been disclosed. However, one of ordinary skill in the art would recognize that certain modifications would come within the scope of this invention. Hence, within the scope of the appended claims, the invention may be practiced otherwise than as specifically described. For this reason the following claims should be studied to determine the true scope and content of this invention.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 05 2004 | ArvinMeritor Technology, LLC | (assignment on the face of the patent) | / | |||
Dec 10 2012 | RIDE CONTROL, LLC | Wells Fargo Bank, National Association | SECURITY AGREEMENT | 029499 | /0232 | |
Aug 22 2014 | RIDE CONTROL, LLC | Wells Fargo Bank, National Association | SECURITY INTEREST | 033680 | /0923 |
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