TW201930126A - Suspension system for bicycle - Google Patents

Abstract

A bicycle suspension system includes two tubes which are telescopically connected to each other, and a fluid damper. The fluid damper is disposed in an interior space bounded by inner walls of the two tubes, and has a plurality of operational states for different damping characteristics. The fluid damper includes a valve mechanism configured to change the operational states of the fluid damper, and a control mechanism which is configured to operate the valve mechanism to change the operational states of the fluid damper, and which can be removed and replaced with an alternative control mechanism without unsealing a fluid section of the fluid damper or without having to remove the valve mechanism.

Description

Suspension system for bicycle

FIELD OF THE INVENTION The present disclosure relates to a suspension system for bicycles, and more particularly to a suspension system, in which a control mechanism for adjusting the damping characteristics of a fluid damper can be removed and replaced by another control mechanism Alternatively, this can be done without releasing the seal of a fluid portion of the damper or without removing a valve mechanism in the damper.

BACKGROUND OF THE INVENTION US Patent No. 7163223 discloses a suspension system, which includes a simplified lockout mechanism and an adjustable blow-off mechanism. The system includes a valve mechanism and a valve actuation assembly, a valve mechanism housing, and an elastic element disposed between the valve mechanism and the valve mechanism housing. The valve mechanism is slidably disposed along the valve mechanism housing, and it separates a first chamber from a second chamber. The valve actuation assembly operates the valve mechanism between open and closed positions. The elastic element is configured such that when the valve mechanism is slipped due to the gradual increase in pressure in the first fluid chamber, the elastic element can be deformed by the valve mechanism. The sliding valve mechanism is configured such that when a blow-off pressure reaches within the first fluid chamber to switch the valve mechanism from the closed position to the open position, the sliding valve mechanism will impact the valve actuation Assembly.

US Patent Application Publication No. 2010/0025957 discloses a bicycle suspension system, which is provided with a first pipe, a piston, a piston rod, a first sealing element, and a switching valve. The piston is coupled to the piston rod and is slidably disposed in the first tube. The first sealing element is disposed in the first tube and adjoins so that a first air chamber is formed between the piston and the first sealing element. The switching valve is coupled to the first sealing element. When in the open position, the switching valve opens a communication channel between the first air chamber and a second air chamber to communicate the first and second air chambers, and in the closed position At this time, the switching valve closes the communication channel between the first air chamber and a second air chamber to separate the first and second air chambers.

These conventional suspension systems allow the user to adjust the compression rate of the damper. However, in such suspension systems, the control mechanism for adjusting the compression ratio cannot be moved by the front fork of a bicycle without removing the valve and/or unsealing the damper except.

SUMMARY OF THE INVENTION Therefore, an object of the present disclosure is to provide a novel modular suspension system in which a control mechanism for adjusting the damping characteristics of a fluid damper can be removed and replaced with another control mechanism This can be done without releasing the seal of a fluid portion of the damper or without removing a valve mechanism in the damper. Whenever needed, the user can choose one of the control mechanisms for quick replacement according to his/her preference without searching for a professional mechanic.

According to the present disclosure, a suspension system for a bicycle includes a first tube having a first end, a second tube having a second end, and a fluid damper. The first tube body and the second tube system are configured in a telescopic configuration having the first end as a first remote end of the telescopic configuration and the second end forming a second remote end of the telescopic configuration . The telescopic configuration has an internal space defined by the inner walls of the first tube and the second tube. The fluid damper is arranged in the internal space and has a plurality of operating states for different damping characteristics. The fluid damper is configured for these operating states to slow down the movement of the first tube relative to the second tube. The fluid damper includes a valve mechanism and a control mechanism. The valve mechanism is configured to change the operating states of the fluid damper and divide the inside of the first tube into a first chamber and a second chamber. The first chamber is open to the hydraulic fluid of the fluid damper. The second chamber is isolated from the hydraulic fluid and includes an internal drying space formed by a second housing. The control mechanism is configured to operate the valve mechanism to change the operating states of the fluid damper, and the control mechanism includes a first housing having an outer contour, the outer contour is configured to The internal drying space is removably coupled to the valve mechanism.

DETAILED DESCRIPTION Before this disclosure is described in more detail, it should be noted that, where deemed appropriate, in the drawings, the element numbers are repeatedly marked to indicate corresponding or similar elements, which can be Selectively have similar characteristics.

1 and 2, a suspension system 1 for a bicycle 10 is shown to include a first tube 11 having a first end 111, a second tube 12 having a second end 121, and a Fluid damper 13.

The first tube body 11 and the second tube body 12 are configured as a telescopic configuration 100 having the first end 111 as a first distal end of the telescopic configuration 100 and a first end forming the telescopic configuration 100 The second end 121 at the second remote end. The telescopic configuration 100 has an internal space 101 defined by the inner walls 110 and 120 of the first tube 11 and the second tube 12. In this embodiment, the first remote end 111 of the first tube 11 is connected to a rudder tube 14 through a shoulder cover 15, and the second remote end 121 of the second tube 12 is passed through a The wheel engaging member 17, such as a fork hook or an axle hole, is connected to a wheel axle 16.

The fluid damper 13 is disposed in the internal space 101 and has a plurality of operating states for different damping characteristics. The fluid damper 13 is configured for these operating states to slow down the movement of the first tube 11 relative to the second tube 12. The fluid damper 13 includes a valve mechanism 2 and a control mechanism 3.

In one embodiment, the fluid damper 13 may have a lockout position and an open position. In the locked position, as shown in FIG. 5, the fluid damper 13 does not allow compression of the telescopic configuration 100 or minimal compression of the telescopic configuration 100, and the suspension system 1 becomes substantially rigid, without It will move along with the irregularity of the road surface. In the open position, as shown in FIGS. 3 and 4, the fluid damper 13 allows the compression of the telescopic configuration 100, and the suspension system 1 can absorb the impact and shock received by the rider.

The valve mechanism 2 is configured to change the operating states of the fluid damper 13. As shown in FIG. 3, the valve mechanism 2 divides the inside of the first tube 11 into a first chamber 201 and a second chamber 202. The first chamber 201 is open to the hydraulic fluid of the fluid damper 13. The second chamber 202 is isolated from the hydraulic fluid, and includes an internal drying space 210 or drying chamber formed by a second housing 21.

The control mechanism 3 is configured to operate the valve mechanism 2 to change the operating states of the fluid damper 13. As shown in FIGS. 2, 3 and 6, the control mechanism 3 includes a first housing 30 having an outer contour 301 configured to be removably coupled in the inner drying space 210 To the valve mechanism 2.

In one embodiment, many control mechanisms may have the outer profile so as to be removably coupled to the valve mechanism. Each of these control mechanisms can be configured to operate the valve in different actuation modes. For example, a control mechanism may be configured for cable actuation, a control mechanism may be configured to allow an operator to twist an interface element for actuation, and/or a control mechanism may be configured for piston or button actuation . In one embodiment, other actuation techniques for the control mechanism with this outer profile can also be used.

The valve mechanism can be actuated by a portion of the valve mechanism that moves linearly along an axis. Other valve mechanisms can also be used. For example, the valve mechanism can be actuated by part of the valve mechanism rotating around an axis.

In an embodiment, as shown in FIG. 3, the second housing 21 is fitted into the first tube 11 and is located at or near the first remote end 111 of the telescopic configuration 100 And the second casing 21 has a through hole 211 which extends along the actuating axis (A) and has an inner peripheral surface 212 which defines a dry interior The first size section 213 of the space 210 and a second size section 214 smaller than the first size section 213, so that the first size section 213 and the second size section in the through hole 211 Between 214, a neck portion 215 is formed.

In one embodiment, the first size section 213 is formed with a female threaded portion 216, and the first housing 30 has an outer peripheral surface 302 formed with the outer contour 301, the outer contour 301 includes a structure The component can be brought to the male threaded portion 303 screwed to the female threaded portion 216, thereby allowing the control mechanism 3 to be removably coupled to the valve mechanism 2 in the internal drying space 210.

In one embodiment, as shown in FIGS. 3 and 6, an outer peripheral surface 218 of the second housing 21 may have a first surface portion 2181 and a second surface portion 2182, and the second surface portion 2182 has a The externally threaded area 2183 is configured to be screwed into an internally threaded area 112 on an inner surface of the first pipe body 11, at this time, the first surface portion 2181 is disposed on the first pipe body 11 Outside. The first surface portion 2181 may have a plurality of concave portions 2184, which are equivalent to surround the actuation axis (A) in a manner angularly offset from each other.

As shown in FIG. 3, a seal (S), such as an O-ring or a gasket, may be disposed between the second housing 21 and the first tube 11.

In one embodiment, as shown in FIG. 3, the valve mechanism 2 includes a valve sleeve 22, a valve seat 23, a rod element 24, a biasing element 25, and a valve element 26. More or fewer components can be used to form the valve mechanism 2.

As shown, the valve sleeve 22 may have a first set of end sections 221 connected to the second size section 214 and a second set of end sections 222 opposite the first set of end sections 221. The valve sleeve 22 defines a guideway 223 and a fluid chamber 224 therein. The guide groove 223 and the fluid chamber 224 are close to and away from the first remote end 111, respectively. The fluid chamber 224 is configured to have a larger size than the guide groove 223 so as to define a blocking shoulder 225 between the guide groove 223 and the fluid chamber 224. In one embodiment, as shown in FIG. 3, the first set of end sections 221 has a male threaded portion 226, and the second size section 214 has a structure configured to screw with the male threaded portion 226 Female thread part 217. Other configurations for a valve sleeve can also be used.

In one embodiment, the valve seat 23 includes a mounting body 231 having a through hole 230 extending along the actuation axis (A) and configured to be fixed to the first tube Within 11 so as to divide the first chamber 201 into a first sub-chamber 203 and a second sub-chamber 204 that are close to and away from the first remote end 111, respectively. In this embodiment, the valve seat 23 further includes a tubular rod 232 that extends from the mounting body 231 and ends at an end face 233. The end face 233 has an inner seat edge 234 that defines an opening 235. The opening 235 extends along the actuation axis (A) and is aligned with the through hole 230.

In one embodiment, as shown in FIGS. 3 and 4, a seal S1, such as an O-ring or a gasket, can be disposed between the mounting body 231 and the first tube 11.

In one embodiment, as shown in FIGS. 4 and 5, the mounting body 231 has a close surface 2311 and a far surface 2312 relative to the blocking shoulder 225. Each of the approaching surface 2311 and the away surface 2312 has a central portion 2313 and a surrounding portion 2314 surrounding the central portion 2313. The surrounding portion 2314 has an inner ring area 2315 and an outer ring area 2316. The tubular rod 232 may include a tubular portion 2321 and a cover portion 2322. The tubular portion 2321 extends from the central portion 2313 of the approaching surface 2311 and ends at a tube end portion 2323, and has an externally threaded surface 2324. The cover portion 2322 has a cover end 2325 and a tubular portion 2326. The cover end 2325 has the end surface 233 having the aperture 235 defined by the inner seat edge 234. The tubular portion 2326 extends from a periphery of the cap end 2325 and terminates at an end edge 2327, and the tubular portion 2326 has an internally threaded surface 2328 configured to be threaded with the externally threaded surface 2324 to facilitate The cap end 2325 is allowed to be spaced from the tube end 2323 by a predetermined gap (C), and is used to allow a seal S2, for example, an O-type when the fluid damper 13 is in the locked position A ring or a gasket provides a seal between an outer circumferential surface 261 of the valve element 26 and an inner circumferential surface 2320 of the tubular rod 232. At this time, the end edge 2327 and the approaching surface 2311 are brought closer to each other to serve as two facing clamping surfaces. Other configurations for a valve seat can also be used.

In one embodiment, the rod element 24 is disposed in the guide groove 223 and extends into the fluid chamber 224 and has an enlarged end section 241. The lever element 24 in turn extends through the neck portion 215 and terminates in the actuating surface 242, the actuating surface 242 is configured to be actuated by the control mechanism 3, and along the actuating axis (A) from a first position (Figures 3 and 4) Move to a second position (Figure 5). When the actuating surface 242 is in the first position, the enlarged end section 241 is in abutment engagement with the blocking shoulder 225. When the actuation surface 242 is in the second position, the enlarged end section 241 is disengaged from the blocking shoulder 225. As shown in FIG. 3, in this embodiment, the upper end 243 of the rod element 24 is enlarged and has the actuation surface 242. Other configurations for one rod element can also be used.

The biasing element 25 is configured to bias the lever element 24 to the first position. In one embodiment, as shown in FIG. 3, the biasing element 25 is a coil spring, the coil spring is sleeved on the rod element 24 and is disposed on the enlarged upper end of the rod element 24 243 and the first set of end sections 221. Other configurations for a biasing element can also be used.

In one embodiment, the valve element system 26 is associated with the enlarged end section 241 and is configured to be moved along the actuation axis (A) so that when the actuation surface 242 is on the first When one of the position (FIGS. 3 and 4) and the second position (FIG. 5) corresponds to the locked position of the fluid damper 13, the valve element 26 is provided to restrict the hydraulic fluid from passing through the The flow of the through hole 230, and when the actuating surface 242 is in the other of the first position and the second position and corresponds to the open position of the fluid damper 13, the valve element 26 is arranged to The flow of the hydraulic fluid through the through hole 230 is allowed. Other configurations for a valve element can also be used.

In the illustrated embodiment, the valve element 26 is disposed within the fluid chamber 224 and is configured to move with the rod element 24 so that once the actuation surface 242 is in the first position (FIG. 3 4) and moved to the second position (FIG. 5), the valve element 26 is moved into engagement with the inner seat rim 234 to restrict the flow of the hydraulic fluid through the orifice 235. As shown in FIGS. 3 to 5, the valve element 26 is formed in the enlarged end section 241 and extends downward from the enlarged end section 241. When the actuation surface 242 is moved to the second position (FIG. 5 ), the valve element 26 is sealingly engaged with the inner seat rim 234 to prevent the flow of the hydraulic fluid through the orifice 235.

In one embodiment, as shown in FIG. 3, the valve mechanism 2 further includes a sealing member 27, and the sealing member 27 is disposed between the rod element 24 and the valve sleeve 23 to separate the second or drying chamber The chamber 202 is isolated from this hydraulic fluid. The sealing member 27 is formed as an annular compliant sealing structure. In one embodiment, for example as shown in FIG. 3, the annular flexible sealing structure 27 is an O-ring disposed around the rod element 24.

In one embodiment, as shown in FIGS. 4 and 5, a blow-off mechanism 20 can be used to release: when the fluid damper 13 is in the locked position, the excess of the suspension system 1 pressure. The blow-off mechanism 20 may have a first one-way valve unit 28 and a second one-way valve unit 29.

Referring to FIGS. 3 to 5, it is shown that the first one-way valve unit 28 may include a first communication port 281 formed in the inner ring region 2315 of the proximity surface 2311, and a first communication port The port 281 extends to the flow channel 282 of the inner ring region 2315 away from the surface 2312, and a first check shim 283, the first check shim 283 has an inner edge 2831, the inner The edge 2831 is configured to be sandwiched between the two opposing clamping surfaces of the end edge 2327 and the approaching surface 2311 of the mounting body 231. The first non-return gasket 283 is configured to be coupled with the first communication port 281 to allow the hydraulic fluid to pass through the flow channel 282 and the first communication port 281 to enter the second sub-chamber 204 One-way flow of the first sub-chamber 203. The first one-way valve unit 28 may include one or more of the first communication ports 281 and corresponding flow channels 282, and the first non-return gasket 283 may be an annular type.

The second one-way valve unit 29 may include a second communication port 291 formed in the outer ring region 2316 of the remote surface 2312, and an outer ring region 2316 extending from the second communication port 291 to the close surface 2311 Reverse flow channel 292, and a second check shim (second check shim) 293, the second check shim 293 is biased by a biasing element 294, and the second communication port 291 is fluid It is sealed to allow a unidirectional flow of the hydraulic fluid from the first sub-chamber 203 into the second sub-chamber 204 through the reverse flow channel 292 and the second communication port 291. As shown in FIG. 4, a tubular seat 295 is disposed on the away surface 2312 between the inner and outer ring regions 2315, 2316, and has an annular flange end 296, which is Spaced apart from the outer ring region 2315 of the away surface 2312 to allow the biasing element 294, such as a coil spring, to be sleeved on the tubular seat 295 and disposed on the annular flange end 296 and the second stop Between the reverse gaskets 293, the second check gasket 293 is biased to fluidly seal the second communication port 291. The second one-way valve unit 29 may include one or more of the second communication ports 291 and the corresponding reverse flow channels 292, and the second non-return gasket 293 may be an annular type. Other configurations for a blow-off mechanism can also be used.

Referring to FIGS. 7 to 9, it can be observed that in the embodiment shown, the first housing 30 of the control mechanism 3 is tubular and has a first extending through the first housing 30 Passing holes 300 of the end surface 304 and a second end surface 305, the first end surface 304 and the second end surface 305 are away from and close to the valve sleeve 22 shown in FIG. 3, respectively. In addition, the first housing 30 has an inner circumferential surface 306 that defines the through hole 300.

In an embodiment, as illustrated in FIG. 7, the control mechanism 3 further includes an actuating element 400, an actuated element 600, and a cam unit 800.

In one embodiment, the actuating element 400 is movably disposed in the through hole 300, and has an operation end section 41 disposed outside the first end surface 304, and an operation opposite to the operation The end section 42 of the end section 41 is actuated.

The actuated element 600 is disposed in the through hole 300, and has a first end 61 and a second end 62, the second end 62 is configured to abut the The actuation surface 242. As shown in FIGS. 8 and 9, the second end 62 may have an output surface 621 configured to engage the actuation surface 242 of the lever element 24 shown in FIG. 3.

The cam unit 800 can be disposed between the actuation end section 42 and the first end 61, so that in response to the movement of the actuation element 400, the actuated element 600 is allowed to drive against the display A biasing force of the biasing element 25 of FIG. 3 moves along an actuation axis (A) from an unactivated position (FIG. 8) to an actuated position (FIG. 9), which is not actuated The position corresponds to the first position (FIGS. 3 and 4), and the actuated position corresponds to the second position (FIG. 5).

In one embodiment, the actuating element 400 is rotatably disposed in the through hole 300, the rotation is around the actuating axis (A) in a locked position (Figure 9) and an unlocked position Rotating between the positions (Figure 8), the locked position and the unlocked position correspond to the second position (Figure 5) and the first position (Figures 3 and 4), respectively.

In addition, as shown in FIG. 7, the actuating end section 42 may have an outer surrounding surface 421, and the first end 61 is tubular and has an inner surrounding surface 611 surrounding the outer surrounding surface 421.

Furthermore, in an embodiment shown in FIGS. 7-9, the cam unit 800 includes an outer spiral cam surface 81, an inner spiral driven surface 82, a spline member 83, a A spline groove 84 and a holding recess 85.

The outer spiral cam surface 81 is formed on the outer circumferential surface 421. The inner spiral driven surface 82 is formed on the inner circumferential surface 611 to cooperate with the outer spiral cam surface 81.

The spline element 83 is disposed above the actuated element 600 to limit the rotation of the actuated element 600 relative to the first housing 30 so as to allow angular movement of the actuated element 400 while allowing The axial movement of the actuated element 600.

The bolt groove 84 is formed on the inner circumferential surface 306 of the first housing 30 and is located in a distant portion 306A relative to the first end surface 304 to guide the spline element 83 and the bolt groove The groove 84 is tied in one direction of the actuation shaft (A), extends away from the first end surface 304 and ends at an end portion 841.

The holding recess 85 extends from the end 841 of the bolt groove 84 in a circumferential direction, and the holding recess 85 is configured such that when the actuated element 600 is moved to the actuated position (FIG. 9) At this time, a key 831 of the spline element 83 is allowed to be rotated around the actuation axis (A) and held in the holding recess 85.

In one embodiment, as shown in FIGS. 7-9, two spline elements 83 are formed on the actuated element 600 and extend radially from the actuated element 600. Two bolt grooves 84 and two holding recesses 85 are provided correspondingly. More or fewer spline elements can be used.

In one embodiment, as shown in FIGS. 7 to 9, the control mechanism 3 further includes an actuation knob 32 coupled to the operation end section 41 to allow the actuation element 400 to follow the actuation The knob 32 rotates together around the actuation axis (A) between the locked position (FIG. 9) and the unlocked position (FIG. 8 ). In other words, the actuation element 400 can be actuated by rotation of the actuation knob 32 about the actuation axis (A).

In one embodiment, as shown in FIGS. 7 to 9, the actuating knob 32 can be fastened to the operating end section 41 through a fixing member 321 (for example, a screw-type fixing member).

In one embodiment, as shown in FIGS. 3 and 7-9, a seal S3, such as an O-ring or a gasket, may be provided in the first housing 30 and the second housing 21 between.

In an embodiment, as shown in FIGS. 7 to 9, a seal S4, such as an O-ring or a gasket, may be disposed in the middle of the first housing 30 and the actuating element 400 Between segments 43, the centered segment 43 is between the operating end segment 41 and the actuating end segment 42.

In an embodiment, as shown in FIGS. 7 to 9, relative to the first end surface 304, a proximate portion 306B of the inner circumferential surface 306 of the first housing 30 is formed to accommodate a An annular groove 306C of a spring bearing 44 is provided with a bearing surface for the central section 43 to allow the central section 43 to angularly move on the spring bearing 44.

10 to 12 show a control mechanism 3 of a suspension system 1 according to a second embodiment of the present disclosure. The second embodiment is similar to the first embodiment, except that in the second embodiment, the control mechanism 3 includes a cable attachment member 45, and the actuating element 400 is controlled by a control cable The movement of the wire 35 is actuated and can be controlled remotely.

In one embodiment, as shown in FIGS. 10-12, the cable attachment member 45 may have a ring-shaped mounting section 451 and a guide section 452, the guide section 452 having a control cable 35 through hole 457.

The ring-shaped mounting section 451 is arranged to surround the first surface portion 2181 of the second housing 21 shown in FIGS. 3 and 6, and the ring-shaped mounting section 451 can be fixed by a fixing member 453 (for example, a spiral type) Pieces) to be fastened to the first surface portion 2181. As shown in FIG. 10, the annular mounting section 451 may have a radially extending through hole 450 formed with a female threaded portion 454, and the fixing member 453 has a rod body 458 that extends longitudinally and terminates in An engaging end 455 and the rod body 458 are formed with a male threaded portion 456 which is configured such that once the male threaded portion 456 is brought into threading engagement with the female threaded portion 454, the engagement of the fixing member 453 The end 455 is brought into frictional engagement with one of the recesses 2184 shown in FIGS. 3 and 6.

In one embodiment, as shown in FIGS. 10 to 12, the control mechanism 3 further includes a hub unit 33, a biasing element 34 such as a spring, and the control cable 35.

The hub unit 33 is coupled to the operating end section 41 to allow common rotation of the actuating element 400 and the hub unit 33.

The biasing element 34 has two ends 341 connected to the actuating element 400 and the first housing 30, respectively, so as to bias the actuating element 400 to the unlocked position (see FIG. 8).

In one embodiment, as shown in FIGS. 10 to 12, the control cable 35 has an actuating cable end 351 and a connecting end section 352 opposite to the actuating cable end 351, the connecting end The section 352 is connected to the hub unit 33 so that when the actuation cable end 351 is actuated (eg, the actuation cable end 351 is pulled or otherwise moved), the actuation element 400 is opposed A biasing force of the biasing element 34 follows the rotation of the hub unit 33 from the unlocked position (FIG. 8) to the locked position (FIG. 9). The actuation cable end 351 can be coupled to an actuation lever (not shown) and actuated by the actuation lever, which can be placed on a handle or any suitable position of the bicycle 10.

In one embodiment, as shown in FIGS. 10 to 12, the operation end section 41 is formed with a female threaded hole 411 extending along the actuation axis (A). The hub unit 33 includes an annular cover 36, a hub element 37, a guide 38, a first splined member 331, a second splined member 332, and a fixing element 39 .

The hub element 37 has a hub body 371 and a flange body 374. The hub body 371 can be sleeved on the operation end section 41 and between the annular cover 36 and the actuating element 400. Relative to the ring-shaped cover 36, an outer peripheral surface 370 of the hub body 371 has a near edge portion 372 and a far edge portion 373. The flange body 374 extends from the remote edge portion 373 in a plurality of radial directions.

In one embodiment, as shown in FIGS. 11 and 12, the guide 38 extends from the ring cover 36 toward the flange body 374 and extends in a circumferential direction around the actuation axis (A) . The guide 38 has an inner surface 381 facing the near edge portion 372 to define a receiving groove 380 for accommodating the connecting end section 352 of the control cable 35.

The first keyway member 331 is disposed between the annular cover 36 and the hub body 371 to allow the annular cover 36 and the hub element 37 to rotate together. In one embodiment, the first keyway member 331 includes a plurality of first male splined portions 333 (FIG. 11) formed on the ring cover 36, and a plurality of first male splined portions 333 (FIG. 11) formed on the hub body 371 First female splined portions 334 (FIG. 10), the first female splined portions 334 are configured to engage with the first male key portions 333 respectively.

The second keyway member 332 is disposed between the hub body 371 and the operating end section 41 to allow the hub element 37 and the actuating element 400 to rotate together. In one embodiment, the second keyway member 332 includes a plurality of second male splined portions 335 (FIG. 10) formed on the operation end section 41, and formed on the hub body 371 A plurality of second female splined portions 336 (FIG. 10 and FIG. 11), the second female splined portions 336 are configured to engage with the second male key portions 335, respectively.

The fixing element 39 may have an enlarged head 391 and a rod body 392 having a male threaded portion 393. The male threaded portion 393 is configured to be screwed with the female threaded hole 411 to force the enlarged head 391 to The annular cover 36 abuts against engagement, thereby bringing the connecting end section 352 of the control cable 35 into frictional engagement with the near-edge portion 372. Because the connecting end section 352 is in frictional engagement with the near edge portion 372, in response to the actuation or pulling force of the actuation cable end 351, the hub element 37 is driven to rotate about the actuation axis (A), Thus, the actuating element 400 and the actuated element 600 are moved to the locked position and the actuated position, respectively (FIG. 9).

In one embodiment, as shown in FIGS. 10 to 12, relative to the first end surface 304, a remote portion 306A of the inner circumferential surface 306 of the first housing 30 is formed to accommodate a An annular groove 306D of an opening holding ring 46 is used to hold the biasing element 34 inside the through hole 300.

In one embodiment, as shown in FIGS. 10 to 12, a washer 47 has an inner diameter smaller than the biasing element 34 and the split retaining ring 46 and has an outer diameter larger than the biasing element 34 It can be placed between the biasing element 34 and the retaining arc 46 to prevent the biasing element 34 from falling.

13 to 16 show a control mechanism 3 of a suspension system 1 according to a third embodiment of the present disclosure. This third embodiment is similar to the first embodiment, except that in the third embodiment, the actuating element 500 is actuated by pressing a button.

In this embodiment, the control mechanism 3 includes a first housing 31, the actuating element 500, an actuated element 700, and a cam unit 900.

The first housing 31 is similar to the first housing 30 in the first and second embodiments, and has an outer peripheral surface 302 formed with an outer contour 301, the outer contour 301 includes a male threaded portion 303, so that It is brought to screw with the female screw part 216 shown in FIG. 6. The first casing 31 also has an inner circumferential surface 310 which extends through a first end surface 304 and a second end surface 305 of the first casing 31 and the inner circumferential surface 310 is A through hole 300 is defined. The inner circumferential surface 310 includes a first size portion 314 and a second size portion 315 larger than the first size portion 314 to form an inner ring shoulder 316.

The actuating element 500 is movably disposed in the through hole 300. The actuating element may also include an operating end section 51 disposed outside the first end surface 304, and/or an actuating end section 52. In one embodiment, the actuation end section 52 is disposed on the opposite end of the actuation element from the operation end section 51.

The actuated element 700 is disposed in the through hole 300, and has a first end 71 and a second end 72, the second end 72 is configured to abut the致面面242. As shown in FIGS. 14, 16 and 17, the second end 72 may have an output surface 721 configured to engage the actuation surface 242 of the lever element 24 shown in FIG. 3.

In one embodiment, as shown in FIGS. 13 to 17, the button mechanism is a cam-based mechanism. In other embodiments, other types of button mechanisms can also be used.

In one embodiment, as shown in FIGS. 13 to 17, the cam unit 900 is disposed between the actuation end section 52 and the first end 71 so as to respond to the movement of the actuation element 500 , The actuated element 700 is allowed to drive against a biasing force of the biasing element 25, and moves along an actuation axis (A) from an un-actuated position (Figures 14 and 16) to a The actuated position (FIG. 17), the un-actuated position corresponds to the first position (FIG. 3 and FIG. 4), and the actuated position corresponds to the second position (FIG. 5).

In one embodiment, the actuating element 500 has an outer peripheral portion 50 configured to be guided by the inner circumferential surface 310 of the first housing 31 to allow the actuated element 700 to follow the actuation The moving shaft (A) moves axially.

In one embodiment, as shown in FIG. 15, the inner circumferential surface 310 of the first housing 31 has a plurality of positioning portions 311 that surround the actuation axis in a manner that is angularly offset from each other ( A). Each of the positioning portions 311 has a leading non-holding area 312 and a trailing holding area 313. The leading non-holding area 312 and the trailing holding area 313 are close to and away from the first end surface 304, respectively.

The cam unit 900 includes a plurality of cam parts 91 and a plurality of driven elements 92.

As shown in FIGS. 13 and 14, the cam portions 91 are formed on an end surface 521 of the actuation end section 52 of the actuation element 500, and surround the actuation axis in a manner angularly offset from each other ( A).

In an embodiment, as shown in FIGS. 13 to 17, the driven elements 92 extend radially from an outer peripheral surface 70 of the actuated element 700 and surround the actuation axis in a staggered manner (A). Each of the driven elements 92 has a driven portion 921 configured to be coupled to a corresponding one of the cam portions 91, such that in response to an axial movement of the actuating element 500, the driven element The moving element 700 is advanced by a predetermined distance in angle to displace the follower 921 to a selected one of the leading non-holding area 312 and the trailing holding area 313, thereby allowing the actuated element 700 to be held at Correspondence between one of the unactivated position (FIG. 16) and the actuated position (FIG. 17).

In one embodiment, as shown in FIG. 13, FIG. 16 and FIG. 17, the actuated element 700 is tubular and has an inner shoulder surface 701, and the control mechanism 3 may further include a handle element 55, the handle The rod element 55 extends along the actuation axis (A) and has a shank body 551 and an enlarged end 552. During assembly, the shank element 55 can be introduced into the actuated element 700 from the second end 72 side to allow the shank body 551 to be forced into tight frictional engagement with an inner peripheral portion 502 of the actuated element 500 . Therefore, in response to the axial movement of the actuation element 500, the actuated element 700 can be maintained to rotate about the actuation axis (A) relative to the handle element 55. In this case, the inner shoulder surface 701 can be frictionally engaged with the enlarged end 552 portion.

In one embodiment, as shown in FIGS. 13, 16 and 17, the first end 71 of the actuated element 700 has an outer circumferential surface 710. The actuating end section 52 is tubular and has an inner surrounding surface 522 surrounding the outer surrounding surface 710 of the first end 71 to stabilize the angular movement of the actuated element 700 relative to the actuating element 500.

In one embodiment, a plurality of keys 501 are formed on the outer peripheral portion 50 of the actuating element 500, and the keys 501 surround the actuating axis (A) angularly offset from each other. The first size portion 314 is formed with a plurality of key grooves 317 and a plurality of concave portions 318.

The key slots 317 surround the actuation axis (A) in a manner angularly offset from each other. Each of the keyways 317 extends from the inner ring shoulder 316 in a direction of the actuation axis (A) toward the first end surface 304, so that when the actuation element 500 is along the actuation axis ( A) When being moved, the keys 501 are allowed to be guided by the key slots 317, respectively. The leading non-retaining area 312 is disposed in one of the corresponding key slots 317.

The recesses 318 are alternately arranged with the key grooves 317 around the actuation axis (A) in a manner angularly offset from each other. Each of the recesses 318 extends from the inner ring shoulder 316 and terminates in the respective trailing holding area 313, and each of the recesses 318 is configured to allow the respective follower 921 and the respective The trailing holding area 313 abuts and engages, thereby holding the actuated element 700 in the actuated position (FIG. 17 ).

In one embodiment, the actuated element 700 has an outer ring flange 73 configured such that when the actuated element 700 is moved toward the unactivated position (FIG. 16), the outer The ring flange 73 is brought into abutting engagement with the inner ring shoulder 316 to allow the follower 921 to be positioned in the leading non-retaining area 312.

In one embodiment, as shown in FIG. 13, FIG. 16 and FIG. 17, a seal S5, such as an O-ring or a gasket, can be disposed between the first housing 31 and the actuating element 500 between.

In this embodiment, the control mechanism 3 further includes a button 53 coupled to the operation end section 51 to force an axial movement of the actuating element 500 to move the actuated element 700 to One of the unactivated position (FIG. 16) and the actuated position (FIG. 17) is selected.

In one embodiment, as shown in FIGS. 13, 16 and 17, the control mechanism 3 may further include an annular guide element 54 having an inner circumferential surface 540 extending around the actuation axis (A), And an outer surrounding surface 541 opposite to the inner surrounding surface 540. The inner circumferential surface 540 is formed with a plurality of guided grooves 542, and a plurality of protrusions 543, the guided grooves 542 surround the actuation axis (A) angularly offset from each other, the protrusions 543 are These guided grooves 542 are alternately provided. When the ring-shaped guide element 54 is assembled to the second housing 21, the guided grooves 542 are guided by the outline of the first surface portion 2181 of the second housing 21 shown in FIG. 6 in order to ensure the A positive lock engagement between each of the equal protrusions 543 and a corresponding one of the concave portions 2184. The outer circumferential surface 541 may have an annular flange 544 configured to guide one of the buttons 53 to move axially, so as to stabilize the movement of the button 53.

In one embodiment, as shown in FIG. 13, FIG. 14, FIG. 16 and FIG. 17, relative to the second end surface 305, a proximity area 315A of the second size portion 315 of the first housing 31 is formed There is an annular groove 315B for accommodating an opening retaining ring 56. The opening retaining ring 56 is used to prevent the actuating element 500 and the actuated element 700 from falling.

In the above description, in order to provide a complete understanding of the implementation, many specific details have been proposed for explanatory purposes. However, it is obvious to those skilled in the art that one or other implementations can be implemented without certain specific details. It should also be understood that references throughout the specification to "one embodiment", "one embodiment", an embodiment with a sequence number, etc. mean that a particular feature, structure, or characteristic may be included Within the implementation of this disclosure. It should also be understood that, for the purpose of simplifying the present disclosure and helping to understand various inventive viewpoints, in the specification, many features are sometimes gathered in a single embodiment, drawing, or description thereof.

Although this disclosure has been described in terms of exemplary implementations, it should be understood that this disclosure is not limited to the disclosed implementations, but is intended to cover various configurations included within the spirit and scope of the broadest interpretation, To cover all such variants and equivalent configurations.

1‧‧‧Suspension system

2‧‧‧Valve mechanism

3‧‧‧Control agency

10‧‧‧bicycle

11‧‧‧The first tube

12‧‧‧Second tube

13‧‧‧ fluid damper

14‧‧‧ Rudder tube

15‧‧‧Shoulder cover

16‧‧‧axle

17‧‧‧Wheel joint parts

20‧‧‧Blow-off mechanism

21‧‧‧Second shell

22‧‧‧Valve sleeve

23‧‧‧Valve seat

24‧‧‧ Rod element

25, 294, 34 ‧‧‧ bias element

26‧‧‧Valve element

27‧‧‧Seals, annular flexible seal structure

28‧‧‧First check valve unit

29‧‧‧Second check valve unit

30、31‧‧‧First shell

32‧‧‧Actuating knob

33‧‧‧ Hub unit

35‧‧‧Control cable

36‧‧‧Ring cover

37‧‧‧Hub components

38‧‧‧Guide

39‧‧‧Fixed components

41、51‧‧‧Operation end section

42、52‧‧‧Actuated end section

43‧‧‧Central section

44‧‧‧Spring bearing

45‧‧‧Cable attachment parts

46‧‧‧Open retaining ring, retaining arc

50‧‧‧Outer periphery

53‧‧‧ button

54‧‧‧Circular guide element

55‧‧‧Handle element

56‧‧‧Open retaining ring

61、71‧‧‧First end

62, 72‧‧‧ second end

73‧‧‧Outer ring flange

81‧‧‧External spiral cam surface

82‧‧‧Inner spiral driven surface

83‧‧‧Spline element

84‧‧‧Slot groove

85‧‧‧Retaining recess

91‧‧‧Cam

92‧‧‧Following element

100‧‧‧telescopic configuration

101‧‧‧Internal space

110、120‧‧‧Inner wall

111‧‧‧ First end, first far end

112‧‧‧ Internal thread area

121‧‧‧Second end, second far end

201‧‧‧ First chamber

202‧‧‧ Second chamber

203‧‧‧The first sub-room

204‧‧‧Second sub-room

210‧‧‧Inner dry space

211‧‧‧through hole

212、2320‧‧‧Inner peripheral surface

213‧‧‧ First size segment

214‧‧‧Second size segment

215‧‧‧Neck

216, 217, 454

218, 302, 370, 70

221‧‧‧The first set of end sections

222‧‧‧The second set of end sections

223‧‧‧Guide ditch

224‧‧‧ fluid chamber

225‧‧‧block shoulder

226, 303, 456

230, 457‧‧‧through hole

231‧‧‧Installation

232‧‧‧Tubular rod

233、521‧‧‧End

234‧‧‧Inner rim

235‧‧‧ Orifice

241‧‧‧Enlarge the end section

242‧‧‧Actuating surface

243‧‧‧Upper

261, 421, 541, 710

281‧‧‧First communication port

282‧‧‧Flower

283‧‧‧ First check gasket

291‧‧‧Second communication port

292‧‧‧Reverse flow path

293‧‧‧Second check gasket

295‧‧‧tubular seat

296‧‧‧ring flange end

300‧‧‧Through hole

301‧‧‧Outline

304‧‧‧First end

305‧‧‧Second end face

306, 310‧‧‧ facing inward

306A‧‧‧Faraway Department

306B‧‧‧ Proximity Department

306C, 306D, 315B ‧‧‧ annular groove

311‧‧‧Positioning Department

312‧‧‧Leading non-holding area

313‧‧‧ Trailing holding area

314‧‧‧ First Dimension Department

314A‧‧‧Nearby District

315‧‧‧Second size department

316‧‧‧Inner ring shoulder

317‧‧‧Keyway

318‧‧‧recess

321,453‧‧‧Fixed parts

331‧‧‧The first keyway

332‧‧‧Second keyway parts

333‧‧‧The first male key part

334‧‧‧The first female trough part

335‧‧‧The second male key part

336‧‧‧Second female trough

341‧‧‧ end

351‧‧‧Actuated cable end

352‧‧‧ connecting end section

371‧‧‧ Hub body

372‧‧‧ Close to the edge

373‧‧‧ away from the edge

374‧‧‧Flange body

380‧‧‧ containment ditch

381‧‧‧Inner surface

391‧‧‧Enlarge head

392‧‧‧Pole

393‧‧‧Male thread part

400, 500‧‧‧actuator

411‧‧‧Female threaded hole

450‧‧‧Radially extending through hole

451‧‧‧Annular installation section

452‧‧‧Guide section

455‧‧‧Joint end

458‧‧‧bar

501,831‧‧‧key

502‧‧‧Inner periphery

522, 540, 611

542‧‧‧Guided ditch

543‧‧‧protrusion

544‧‧‧Ring flange

551‧‧‧Handle body

552‧‧‧Large end

600, 700 ‧‧‧ actuated components

621, 721‧‧‧ output face

701‧‧‧Inner shoulder surface

800、900‧‧‧Cam unit

841‧‧‧End

921‧‧‧ Follower

2181‧‧‧First surface part

2182‧‧‧Second surface part

2183‧‧‧ External thread area

2184‧‧‧Depression

2311‧‧‧ close to the face

2312‧‧‧ away from the face

2313‧‧‧Central Department

2314‧‧‧Encircling Department

2315‧‧‧Inner Ring

2316‧‧‧ Outer Ring District

2321‧‧‧Tubular part

2322‧‧‧ Cover part

2323‧‧‧tube end

2324‧‧‧Male thread surface

2325‧‧‧Cover

2326‧‧‧Tubular part

2327‧‧‧End

2328‧‧‧Internal thread surface

2831‧‧‧Inner edge

A‧‧‧Actuating shaft

C‧‧‧Scheduled gap

S, S1, S2, S3, S4, S5‧‧‧‧seals

Other features and functions of the present disclosure will be clearly presented in the detailed description of the following embodiments with reference to the accompanying drawings, in which: FIG. 1 is a side view of a bicycle; FIG. 2 is a A cross-sectional view of the bicycle suspension system; FIG. 3 is a partial enlarged view of FIG. 2 in which a control mechanism is omitted; FIG. 4 is a partial enlarged view of FIG. 3; FIG. 5 is similar to FIG. 4 but shows a The valve element is sealingly engaged with a valve seat; FIG. 6 is an exploded perspective view of a fluid damper of a suspension system according to a first embodiment of the disclosure; FIG. 7 is the first embodiment of the disclosure An exploded perspective view of a control mechanism of the suspension system; FIG. 8(a) is a bottom view of a combined state of the control mechanism of FIG. 7; FIG. 8(b) is the combination of the control mechanism of FIG. 7 A cross-sectional view of the state; Figure 9(a) and Figure 9(b) are similar to Figure 8(a) and Figure 8(b), respectively, but show the spline element accommodated in the holding groove; Figure 10 is based on An exploded perspective view of a control mechanism of a suspension system according to a second embodiment of the present disclosure; FIG. 11 is similar to FIG. 10, but shows the control mechanism viewed from a bottom side; FIG. 12 is FIG. 10 FIG. 13 is an exploded perspective view of a control mechanism of a suspension system according to a third embodiment of the present disclosure; FIG. 14 is the control mechanism of FIG. 13 A side view of an actuating element, an actuated element, and a cam unit; FIG. 15 is a bottom perspective view of a first housing of the control mechanism of FIG. 13; FIG. 16 is a view of the control mechanism of FIG. 13 A sectional view of a combined state for displaying an actuated element in an unactuated position; and FIG. 17 is a different sectional view of the combined state of the control mechanism of FIG. 13 for displaying in a The actuated element in the actuated position.

Claims (18)

A suspension system for a bicycle, the suspension system comprising: a first pipe body having a first end and a second pipe body having a second end, the first pipe body and the second pipe system structure In a telescopic configuration, the telescopic configuration has the first end as a first remote end of the telescopic configuration, and the second end forming a second remote end of the telescopic configuration, the telescopic configuration has a An internal space defined by the tube body and the inner wall of the second tube body; and a fluid damper disposed in the internal space and having a plurality of operating states for different damping characteristics, the fluid damper is Configured for the operating states to slow down the movement of the first tube relative to the second tube, the fluid damper includes a valve mechanism configured to change the operating states of the fluid damper, And the inside of the first pipe body is divided into a first chamber and a second chamber, the first chamber is open to the hydraulic fluid of the fluid damper, the second chamber is isolated from the hydraulic fluid And includes an internal dry space formed by a second housing, and a control mechanism configured to operate the valve mechanism to change the operating states of the fluid damper, and the control mechanism includes a A first housing having an outer contour is configured to be removably coupled to the valve mechanism within the inner dry space. The suspension system according to claim 1, wherein the second housing is tightly fitted into the first tube body and is located at or near the first remote end of the telescopic configuration, and the second housing has a consistent Hole, the through hole extends along the actuating axis and has an inner peripheral surface, the inner peripheral surface has a first size section that defines the internal drying space, and a second size section that is smaller than the first size section A size section so that a neck portion is formed between the first size section and the second size section in the through hole, the valve mechanism includes a valve sleeve having a connection to the second size section The first set of end sections of the segment, and a second set of end sections opposite to the first set of end sections, the valve sleeve defines a guide groove and a fluid chamber therein, the guide groove and the The fluid chamber is close to and away from the first distal end, respectively, the fluid chamber is configured to have a size larger than the guide groove, so as to define a blocking shoulder between the guide groove and the fluid chamber, A valve seat, which defines a through hole, a rod element, which is disposed in the guide groove and extends into the fluid chamber to have an enlarged end section, and the rod element extends through the neck portion and terminates in unison A moving surface, the actuating surface is configured to be actuated by the control mechanism, and moves from a first position to a second position along the actuating axis, at the first position, the enlarged end section Is in abutting engagement with the blocking shoulder, and in the second position, the enlarged end section is disengaged from the blocking shoulder, and a biasing element is provided to bias the rod element to the first Position, and a valve element associated with the enlarged end section and configured to be moved along the actuation axis so that when the actuation surface is in one of the first position and the second position At this time, the valve element is provided to restrict the flow of the hydraulic fluid through the through hole, and so that when the actuating surface is at the other of the first position and the second position, the valve element is provided To allow the flow of the hydraulic fluid through the through hole. The suspension system according to claim 2, wherein the valve seat includes a mounting body having the through hole extending along the actuation axis and configured to be fixed within the first tube body to The first chamber is divided into a first sub-chamber and a second sub-chamber that are close to and away from the first remote end, respectively. The suspension system according to claim 3, wherein: the valve seat further includes a tubular rod extending from the mounting body and terminating at an end face, the end face having an inner seat edge defining an orifice, the orifice is Extending along the actuation axis to align the through hole; and the valve element is disposed within the fluid chamber and is configured to move with the rod element so that once the actuation surface is moved from the first position Moving to the second position, the valve element is moved into engagement with the inner seat rim to restrict the flow of hydraulic fluid through the orifice. The suspension system of claim 2, wherein the valve mechanism further includes a seal member disposed between the rod element and the valve sleeve to isolate the second chamber from the hydraulic fluid. The suspension system of claim 5, wherein the seal is formed as an annular flexible seal structure. The suspension system of claim 6, wherein the annular flexible sealing structure is an O-ring disposed around the rod element. The suspension system of claim 2, wherein the first size section is formed with a female threaded portion, and the first housing has an outer peripheral surface formed with the outer contour, the outer contour including a structure configured to be Bring to the male threaded portion screwed to the female threaded portion. The suspension system according to claim 2, wherein the first shell is tubular and has a through hole extending through a first end face and a second end face of the first shell, the first end face and the second The end faces are away from and close to the valve sleeve, respectively, and the control mechanism includes an actuating element, which is movably disposed in the through hole, and has an operating end section provided outside the first end face, and a Opposite to the actuation end section of the operation end section, an actuated element is disposed within the through hole and has a first end and a second end, the second end is constructed It is used to abut the actuating surface and a cam unit, which is disposed between the actuating end section and the first end, so that in response to the movement of the actuating element, the actuated element is Allowing to drive, against a biasing force of the biasing element, move along an actuation axis from an unactuated position to an actuated position, the unactuated position corresponds to the first position, the The actuated position corresponds to the second position. The suspension system according to claim 9, wherein: the actuating element is rotatably disposed in the through hole, and the rotation is about actuation axis between a locked position and an unlocked position, The locked position and the unlocked position correspond to the second position and the first position, respectively; the actuation end section may have an outer circumferential surface, and the first end is tubular and has a ring surrounding the outer circumferential surface An inner circumferential surface; and the cam unit includes an outer spiral cam surface formed on the outer circumferential surface, and an inner spiral driven surface formed on the inner circumferential surface to face the outer spiral cam surface Mating, and a spline element, which is disposed above the actuated element to limit the rotation of the actuated element relative to the first housing so as to allow the angular movement of the actuated element while allowing the The axial movement of the actuated element. The suspension system according to claim 10, wherein the first housing has an inner circumferential surface defining the through hole, and the cam unit further includes a bolt groove formed in the direction of the first housing In the inner peripheral surface, to guide the spline element, and the bolt groove is tied to one side of the actuating shaft, extends away from the first end surface and ends at one end, and a holding recess is formed by the bolt groove The end of the groove extends in a circumferential direction, and the holding recess is configured to allow a key of the spline element to be wound around the actuation axis when the actuated element is moved to the actuated position It is rotated and held in the holding recess. The suspension system of claim 10, wherein the control mechanism further includes an actuation knob coupled to the operating end section to allow the actuation element to rotate about the actuation axis along with the actuation knob . The suspension system of claim 10, wherein the control mechanism further includes a hub unit coupled to the operating end section to allow common rotation of the actuating element and the hub unit, a biasing element, which Has two ends respectively connected to the actuating element and the first housing, so as to bias the actuating element to the unlocking position, and a control cable having an actuating cable end and an opposite to the actuating The connecting end section of the moving cable end is connected to the hub unit so that when the actuating cable end is actuated, the actuating element acts against a biasing force of the biasing element, following The hub unit is rotated from the unlocked position to the locked position. The suspension system of claim 13, wherein the operation end section is formed with a female threaded hole extending along the actuation shaft, and the hub unit includes an annular cover, a hub element having a hub body , Which is sleeved on the operation end section and between the annular cover and the actuating element, relative to the annular cover, an outer peripheral surface of the hub body has a near edge portion and a far edge Part, and a flange body extending from the remote edge in a plurality of radial directions, a guide member extending from the ring cover toward the flange body and extending around a circumference around the actuation shaft Direction, the guide member has an inner surface facing the near edge portion to define a receiving groove for accommodating the connecting end section of the control cable, and a first key groove member disposed on the ring cover And the hub body to allow the ring cover and the hub element to rotate together, a second spline member disposed between the hub body and the operating end section to allow the hub element and the actuation Co-rotation of the element and a fixed element with an enlarged head and a rod body with a male threaded portion, the male threaded portion is configured to screw with the female threaded hole to force the enlarged head with The ring-shaped cover abuts against engagement, thereby bringing the connecting end section of the control cable into frictional engagement with the near edge portion. The suspension system according to claim 9, wherein: the first housing has an inner circumferential surface that defines the through hole, and the actuating element has an inner circumferential surface that is configured by the first housing The outer peripheral portion of the guide so as to allow the actuated element to move axially along the actuating axis; the inner peripheral surface of the first housing has a plurality of positioning portions, which are angularly offset from each other Around the actuation axis, each of the positioning portions has a leading non-retaining area and a trailing retaining area, the leading non-retaining area and the trailing retaining area are respectively close to and away from the first end face; and the The cam unit includes a plurality of cam parts, which are formed on one end surface of the actuation end section of the actuation element, and surround the actuation axis in a manner angularly offset from each other, and a plurality of driven elements , Etc., which extend radially from an outer peripheral surface of the actuated element and surround the actuation axis in a staggered manner, each of the driven elements has a structure A follower coupled to the counterpart, such that in response to an axial movement of the actuating element, the actuated element is angularly advanced a predetermined distance to displace the follower to the leading unheld A selected one of the zone and the trailing holding area, thereby allowing the actuated element to be held at a counterpart of the un-actuated position and the actuated position. The suspension system of claim 15, wherein the first end of the actuated element has an outer circumferential surface, and the actuated end section is tubular and has an outer circumference surrounding the first end The inner surrounding surface of the surrounding surface stabilizes the angular movement of the actuated element relative to the actuating element. The suspension system of claim 15, wherein: the inner circumferential surface of the first housing includes a first size portion and a second size portion larger than the first size portion to form an inner ring shoulder A plurality of keys are formed on the outer peripheral portion of the actuating element, and the key systems surround the actuating axis in a manner that is angularly offset from each other; The actuating shaft is surrounded in a staggered manner, and each of the keyways extends from the shoulder of the inner ring in a direction of the actuating shaft toward the first end surface, such that when the actuating element is along the When the actuating shaft is moved, the keys are allowed to be guided by the key grooves respectively, a plurality of recesses, etc. are alternately arranged with the key grooves around the actuating shaft in a manner angularly offset from each other. Each extends from the inner ring shoulder and terminates in the respective trailing holding area, and each of the recesses is configured to allow the respective follower portion to abut the respective trailing holding area, Thereby holding the actuated element in the actuated position; the leading non-holding area is provided in one of the corresponding key slots; and the actuated element has an outer ring flange configured such that when the When the actuating element is moved towards the un-actuated position, the outer ring flange is brought into abutting engagement with the inner ring shoulder to allow the driven part to be positioned in the leading non-retaining area. The suspension system of claim 15, wherein the control mechanism further includes a button coupled to the operating end section to force an axial movement of the actuating element to move the actuated element to the The selected one of the unactivated position and the actuated position.