JP4602226B2 - Front fork - Google Patents

Description

  The present invention relates to a front fork.

  As a front fork that prevents bottom thrust at the most compression stroke, as described in Patent Document 1, an axle side tube is slidably inserted into a vehicle body side tube, and a damper cylinder is erected at the bottom of the axle side tube. The piston rod supported by the side tube is inserted into the damper cylinder, an oil lock collar is provided at the top of the damper cylinder, and the oil lock piece attached to the non-insertion portion of the piston rod into the damper cylinder is oil lock collar near the maximum compression stroke. There is something that fits.

  In the front fork of Patent Document 1, an upper holder and a lower stopper are provided at two positions above and below the piston rod piece mounting portion to which the oil lock piece is mounted, and the oil lock piece has a diameter between the outer periphery of the piston rod piece mounting portion. It has a gap in the direction, and is held with a gap in the axial direction between the flange of the upper holder and the lower stopper.

At this time, a groove flow path is formed in the lower end surface that abuts the lower stopper of the oil lock piece, and when moving from the oil lock state to the extension stroke, the gap between the upper end of the oil lock piece and the flange of the upper holder, oil lock Oil flows into the oil lock chamber from the upper oil reservoir chamber of the oil lock collar via the gap between the inner periphery of the piece and the outer periphery of the piston rod, and the groove flow path of the oil lock piece, and the negative pressure in the oil lock chamber is reduced. Let go. This makes it possible to smoothly remove the oil lock piece from the oil lock collar.
JP 4-175532 A

  In the front fork of Patent Document 1, it is necessary to form a groove flow path in the oil lock piece in order to eliminate the negative pressure in the oil lock chamber when moving from the oil lock state to the extension stroke, resulting in high cost.

  An object of the present invention is to smoothly remove an oil lock piece from an oil lock collar without forming a groove channel in the oil lock piece.

In the first aspect of the invention, the axle side tube is slidably inserted into the vehicle body side tube, a damper cylinder is erected at the bottom of the axle side tube, and a piston rod supported by the vehicle body side tube is inserted into the damper cylinder. An oil lock collar is provided on the upper part of the damper cylinder, and the oil lock piece is attached to the front fork that fits the oil lock piece attached to the non-insertion portion of the piston rod into the damper cylinder in the vicinity of the most compression stroke. An upper holder and a lower stopper are provided at the upper and lower positions of the piston rod piece mounting part, a flange projecting around the outer periphery of the piston rod is provided in the upper holder, and a flow path that opens around the outer periphery of the piston rod is provided in the lower stopper. provided, the oil lock piece, between the outer periphery of the piece attaching portion of the piston rod Has a direction of gap, is held by an axial gap between the flange and the lower stopper of the upper holder can be gaps fraction vertical movement in the axial direction along the outer periphery of the piston rod, the oil lock piece Is provided with an upper plane that presses against the flange of the upper holder by upward movement with respect to the outer periphery of the piston rod, and a lower plane that comes into contact with the lower stopper by downward movement with respect to the outer periphery of the piston rod, and the upper holder is separated from the piston rod, The flow path provided in the lower stopper communicates with the radial gap between the oil lock piece and the outer periphery of the piece mounting portion of the piston rod .

In the invention of claim 2, the axle side tube is slidably inserted into the vehicle body side tube, a piston rod is erected at the bottom of the axle side tube, and the piston rod is inserted into a damper cylinder supported by the vehicle body side tube. An oil lock collar is provided around the piston rod at the bottom of the axle side tube, and the oil lock piece is attached to the front fork that fits the oil lock collar attached to the lower outer periphery of the damper cylinder to the oil lock collar near the maximum compression stroke. An upper holder and a lower stopper are provided at the upper and lower positions of the damper cylinder piece mounting part, a flange that protrudes around the lower outer periphery of the damper cylinder is provided on the upper holder, and a flow that opens around the lower outer periphery of the damper cylinder is provided on the lower stopper. The oil lock piece is the outer periphery of the damper cylinder piece mounting part. A gap in the radial direction between, is held by an axial gap between the flange and the lower stopper of the upper holder can be gaps fraction vertical movement in the axial direction along the outer periphery of the piston rod The oil lock piece includes an upper plane that comes into pressure contact with the flange of the upper holder by upward movement with respect to the outer periphery of the piston rod, and a lower plane that comes into contact with the lower stopper by downward movement with respect to the outer periphery of the piston rod. The path communicates with the radial gap between the oil lock piece and the outer periphery of the piece mounting portion of the piston rod .

According to a third aspect of the present invention, in the first or second aspect of the present invention, the lower stopper is an E-shaped retaining ring.

(Claim 1)
(a) A flow path that opens around the outer periphery of the piston rod is provided in the lower stopper where the lower end of the oil lock piece abuts. Therefore, when moving from the oil lock state to the extension stroke, the clearance between the upper end of the oil lock piece and the flange of the upper holder, the gap between the inner periphery of the oil lock piece and the outer periphery of the piston rod, and the flow path of the lower stopper are used. Thus, oil flows into the oil lock chamber from the upper oil reservoir chamber of the oil lock collar, and the negative pressure in the oil lock chamber is eliminated. As a result, the oil lock piece can be smoothly removed from the oil lock collar without forming a groove channel in the oil lock piece.

(Claim 2)
(b) A flow path that opens around the outer periphery of the lower part of the damper cylinder is provided in the lower stopper where the lower end of the oil lock piece abuts. Therefore, when moving from the oil lock state to the extension stroke, the clearance between the upper end of the oil lock piece and the flange of the upper holder, the clearance between the inner periphery of the oil lock piece and the outer periphery of the damper cylinder, and the flow path of the lower stopper are used. Thus, oil flows into the oil lock chamber from the upper oil reservoir chamber of the oil lock collar, and the negative pressure in the oil lock chamber is eliminated. As a result, the oil lock piece can be smoothly removed from the oil lock collar without forming a groove channel in the oil lock piece.

(Claim 3)
(c) Since the lower stopper is an E-type retaining ring, the engagement protrusion on the inner periphery of the E-shaped retaining ring is attached to the outer periphery of the piston rod in (a) above or the outer periphery of the damper cylinder in (b) above. When attached to the groove, the space between adjacent locking projections on the inner periphery of the E-shaped retaining ring becomes the flow path of the lower stopper described in (a) or (b).

  1 is a sectional view showing a front fork, FIG. 2 is an enlarged sectional view of a lower portion of the front fork in FIG. 1, FIG. 3 is an enlarged sectional view of an intermediate portion of the front fork in FIG. FIG. 5 is a cross-sectional view showing an oil lock piece mounting structure, FIG. 6 is a cross-sectional view showing an oil lock state by the oil lock piece, FIG. 7 is a cross-sectional view showing a state in which the oil lock piece is removed, and FIG. It is a top view which shows a shape retaining ring.

  As shown in FIGS. 1 to 4, the front fork 10 is inverted by fitting a vehicle body side outer tube (vehicle body side tube) 11 to an axle side inner tube (axle side tube) 12 slidably. A suspension spring 13 is interposed between the tubes 11 and 12 and the single cylinder damper 14 is installed upright.

  A bush 15, an oil seal 16, and a dust seal 17 that are in sliding contact with the outer peripheral portion of the inner tube 12 are fitted to the inner peripheral portion of the lower end of the outer tube 11. A bush 18 that comes into sliding contact is fitted.

  The outer tube 11 is supported on the vehicle body side via an upper bracket 19A and a lower bracket 19B, and the inner tube 12 is coupled to the axle via an axle bracket 20.

  At the bottom of the inner tube 12, the lower end of the damper cylinder 21 of the damper 14 is attached and stands upright. At this time, the damper cylinder 21 is fixed and held as described later by a bottom bolt 24 engaged with the axle bracket 20 from the outside via a bottom piece 51 described later.

  A cylindrical portion 25A of the cap 25 is liquid-tightly inserted and screwed into the upper end portion of the outer tube 11 via an O-ring 26, and a spring load adjustment adjuster 28 is provided on the inner periphery of the lid portion 25B of the cap 25. It is inserted through the O-ring 27 so as to be liquid-tight and rotatable. A base end portion of a piston rod 29 is screwed to the inner periphery of the lower end of the adjuster 28 and is locked by a lock nut 30. The tip of the piston rod 29 is inserted into the damper cylinder 21.

  An oil lock collar 31 is fixed to the outer periphery of the upper end of the damper cylinder 21 inside the inner tube 12, and a spring receiver 32 is provided on the upper end of the oil lock collar 31. On the other hand, inside the outer tube 11, a groove portion 25 </ b> C is provided along the axial direction on the inner periphery of the cylindrical portion 25 </ b> A of the cap 25, and the slider is prevented from rotating between the groove portion 25 </ b> C of the cap 25 on the outer periphery of the adjuster 28. 33 is screwed together. The slider 33 supports the upper end of the suspension spring 13 via the spring collar 34 </ b> A, and supports the lower end of the suspension spring 13 by the spring receiver 32. By rotating the adjuster 28, the slider 33 is moved up and down, and the initial load of the suspension spring 13 can be set via the spring collar 34A. At this time, the screw portion of the adjuster 28 and the screw portion of the slider 33 are set to reverse screws that cause the slider 33 to be lowered by the clockwise rotation of the adjuster 28 and compress the suspension spring 13.

  The adjuster 28 has an annular shape between the lower surface of the lid portion 25B of the cap 25 and a collar 28B supported by a retaining ring 28A attached to the upper portion of the screw portion for the slider 33 of the adjuster 28. The leaf spring 28C is interposed in an elastically compressed state. An assembly backlash based on a dimensional error between the cap 25 and the adjuster 28 is absorbed by elastic deformation of the leaf spring 28C, and unexpected rotation of the adjuster 28 due to vibration is prevented by a frictional force exerted on the adjuster 28 by the leaf spring 28C.

  Inside the outer tube 11 and the inner tube 12, an oil reservoir chamber 35A and a gas chamber 35B are provided on the outer periphery of the damper cylinder 21, and the gas confined in the gas chamber 35B constitutes a gas spring. The hydraulic oil in the oil reservoir 35A contributes to adjustment of the spring constant of the gas chamber 35B, lubrication of the sliding contact bushes 15 and 18 of the outer tube 11 and the inner tube 12, and wetting of the oil seal 16 at the lower end of the inner tube 12. To do. And the elastic force of these suspension spring 13 and gas spring absorbs the impact force which a vehicle receives from a road surface.

  The damper 14 includes a piston valve device (extension-side damping force generation device) 40 and a bottom valve device (compression-side damping force generation device) 50. The damper 14 suppresses the expansion and contraction vibration of the outer tube 11 and the inner tube 12 due to the absorption of the impact force by the suspension spring 13 and the gas spring by the damping force generated by the piston valve device 40 and the bottom valve device 50.

  A rod guide 36 is swaged and fixed to the upper end opening of the damper cylinder 21, and a bush 37 for slidingly guiding the piston rod 29 is press-fitted into the rod guide 36.

  In addition, a rebound spring 38 is held directly below the rod guide 36 on the inner periphery of the damper cylinder 21 so as to be compressed with a piston holder 41 (to be described later) at the time of maximum extension and perform a buffering action.

  Further, an oil lock piece 39 held as will be described later is held on the outer periphery of the piston rod 29 with a gap between the piston rod 29 and the oil lock collar 31 described above when the oil lock piece 39 is compressed most. It acts as a buffer at the time of maximum compression.

Hereinafter, the damping mechanism of the front fork 10 will be described.
(Piston valve device 40)
In the piston valve device 40, a piston holder 41 is mounted on the tip of the piston rod 29, and a piston 42 and a valve stopper 41C are mounted by a nut 41A and a valve stopper 41B that are screwed onto the piston holder 41. The piston 42 slidably contacts the inside of the damper cylinder 21 and divides the inside of the damper cylinder 21 into a piston side oil chamber 43A in which the piston rod 29 is not accommodated and a rod side oil chamber 43B in which the piston rod 29 is accommodated. The piston 42 includes an expansion side valve 44A, and includes an expansion side flow path 44 that enables communication between the piston side oil chamber 43A and the rod side oil chamber 43B, and a pressure side valve (check valve) 45A, and includes a piston side oil chamber 43A. And a pressure-side flow path 45 (not shown) that enables the rod-side oil chamber 43B to communicate with each other.

  In addition, the piston valve device 40 includes a damping force adjusting tube 47 that is inserted into the adjuster 28 through an O-ring 46A in a liquid-tight manner and is screwed to the damping force adjusting rod 46 that can be operated from the outside. The passage area of the bypass passage 48 between the piston-side oil chamber 43A and the rod-side oil chamber 43B provided in the piston holder 41 is adjusted by the needle 47A at the tip of the damping force adjusting tube 47 through the hollow portion of the rod 29. Make it possible.

  Therefore, when the front fork 10 is compressed, the oil in the piston-side oil chamber 43A passes through the pressure-side flow path 45, opens the pressure-side valve 45A, and is guided to the rod-side oil chamber 43B.

  Further, when the front fork 10 is extended, when the relative speed between the damper cylinder 21 and the piston rod 29 is low, the oil in the rod side oil chamber 43B is guided to the piston side oil chamber 43A through the bypass passage 48 having the needle 47A. In the meantime, the expansion side damping force is generated by the diaphragm resistance by the needle 47A. This damping force is adjusted by adjusting the position of the needle 47A by the damping force adjusting rod 46.

  Further, when the front fork 10 is extended and the relative speed between the damper cylinder 21 and the piston rod 29 is medium to high, the oil in the rod side oil chamber 43B passes through the extension side passage 44 to bend and deform the extension side valve 44A. It is guided to the piston side oil chamber 43A and generates an extension side damping force.

(Bottom valve device 50)
In the bottom valve device 50, a pressure side valve 56A, a valve housing 53, and a valve stopper 54 are held by a bolt 52 on a bottom piece 51 to which the damper cylinder 21 is fixed as described later. The valve stopper 54 holds an extension side valve (check valve) 57A and a spring 57B between the valve housing 53 and the valve stopper 53. The valve housing 53 is in liquid-tight contact with the middle portion of the damper cylinder 21 and forms a bottom valve chamber 55 below the piston-side oil chamber 43A. The valve housing 53 includes a pressure-side flow path 56 that enables communication between the piston-side oil chamber 43A including the pressure-side valve 56A and the bottom valve chamber 55, and an extension-side valve (check valve) 57A. An extension-side flow channel 57 (not shown) that can communicate with the bottom valve chamber 55 is provided. The bottom valve chamber 55 can communicate with an oil reservoir chamber 35 </ b> A provided outside the damper cylinder 21 by an oil passage 58 provided on the wall surface of the damper cylinder 21.

  Further, the axle bracket 20, the bottom bolt 24, the bottom piece 51, and the bolt 52 provided at the bottom of the inner tube 12 bypass the pressure side flow path 56 and the extension side flow path 57, and the piston side oil chamber 43 </ b> A and the oil reservoir. A bypass channel 59 is provided to allow communication with the chamber 35A. Further, a damping force adjusting rod 62 is liquid-tightly inserted through an O-ring 63 and screwed to a cap 61 that is inserted in a liquid-tight manner by gripping the O-ring 61A on the axle bracket 20 and is attenuated. The flow path area of the bypass flow path 59 of the inner tube 12 can be adjusted by the tip needle 62A of the force adjusting rod 62.

  Accordingly, when the front fork 10 is compressed, the oil corresponding to the volume of the piston rod 29 that has entered the damper cylinder 21 passes from the piston-side oil chamber 43A through the bypass channel 59 to the oil reservoir 35A or the pressure-side channel 56. The bottom valve chamber 55 and the oil passage 58 on the wall surface of the damper cylinder 21 are discharged to the oil reservoir chamber 35A. At this time, when the relative speed between the damper cylinder 21 and the piston rod 29 is low, a compression-side damping force is obtained by the throttling resistance of the needle 62A provided in the bypass passage 59. This damping force is adjusted by adjusting the position of the needle 62 </ b> A by the damping force adjusting rod 62. Further, when the relative speed between the damper cylinder 21 and the piston rod 29 is medium to high, the oil passing through the pressure side flow passage 56 from the piston side oil chamber 43A is deflected and deformed to be guided to the bottom valve chamber 55, and the pressure side A damping force is generated.

  When the front fork 10 is extended, the oil corresponding to the retraction volume of the piston rod 29 retreating from the damper cylinder 21 is returned from the oil reservoir chamber 35A to the piston-side oil chamber 43A through the bottom valve chamber 55 and the expansion-side flow passage 57. The

Accordingly, the front fork 10 performs a damping action as follows.
(When compressed)
When the front fork 10 is compressed, in the bottom valve device 50, the pressure side damping force is generated by the oil flowing through the pressure side valve 56A or the needle 62A of the valve housing 53, and the piston valve device 40 generates almost no damping force.

(When stretched)
When the front fork 10 is extended, in the piston valve device 40, an extension side damping force is generated by the oil flowing through the needle 47A of the piston 42 or the extension side valve 44A, and the bottom valve device 50 hardly generates a damping force.

The damping force on the compression side and the extension side suppresses the stretching vibration of the front fork 10.
However, in the front fork 10, the oil lock collar 31 is provided on the upper portion of the damper cylinder 21, and the oil lock piece 39 attached to the non-insertion portion of the piston rod 29 to the damper cylinder 21 is oil-locked near the most compression stroke. When the clearance channel 39A is formed between the outer periphery of the oil lock piece 39 and the outer periphery of the oil lock collar 39, the oil lock piece 39 is configured as follows.

  As shown in FIG. 5, an upper holder 70 and a lower stopper 80 are provided at two upper and lower positions of the piece attachment portion 29 </ b> A of the piston rod 29 to which the oil lock piece 39 is attached.

  The upper holder 70 has a fitting portion 71 that fits on the outer periphery of the piston rod 29 and a flange 72 that protrudes outward from the lower end portion of the fitting portion 71 so as to protrude around the outer periphery of the piston rod 29. The upper holder 70 has a caulking portion 71 </ b> A that locks the upper end portion of the fitting portion 71 on a stopper ring 73 that is engaged with the outer periphery of the piston rod 29 and extends from the upper end portion of the fitting portion 71. The piston rod 29 is fixed to the outer periphery of the piston rod 29 by bending the stopper ring 73 so as to contact the outer periphery of the piston rod 29.

  The lower stopper 80 is provided with a flow path 83 that opens around the outer periphery of the piston rod 29. The lower stopper 80 of the present embodiment is composed of an E-shaped retaining ring 80A. As shown in FIG. 8, the E-shaped retaining ring 80 </ b> A includes locking projections 82 at a plurality of positions (three positions in the present embodiment) on the inner periphery of the arc portion 81 over a range exceeding 180 degrees around the center. When the locking projection 82 of the E-shaped retaining ring 80A is mounted in the annular mounting groove 29B provided immediately below the piece mounting portion 29A of the piston rod 29, the space between the adjacent locking projections 82 of the E-shaped retaining ring 80A This space is the flow path 83 described above.

  The oil lock piece 39 attached to the piece attachment portion 29A of the piston rod 29 has a radial gap 39B between the oil lock piece 39 and the outer periphery of the piece attachment portion 29A of the piston rod 29, and the flange 72 and the lower stopper 80 of the upper holder 70. A gap 39C in the axial direction is held between the E-type retaining rings 80A. The oil lock piece 39 can move up and down along the outer periphery of the piston rod 29 by a gap 39C.

  Therefore, in the front fork 10, in the oil lock state in which the oil lock piece 39 is fitted to the oil lock collar 31 in the compression stroke, the upper end of the oil lock piece 39 is the flange 72 of the upper holder 70 as shown in FIG. The oil lock chamber 31A is formed inside the oil lock collar 31, and the oil flow from the oil lock chamber 31A through the gap 39B between the inner periphery of the oil lock piece 39 and the outer periphery of the piston rod 29 is blocked. As a result, the oil trapped in the oil lock chamber 31A flows out into the upper oil reservoir chamber 35A through the clearance channel 39A on the outer periphery of the oil lock piece 39 and the inner periphery of the oil lock collar 31, and the clearance channel 35A. An oil lock load based on the resistance of

  When moving from the oil lock state to the extension stroke, as shown in FIG. 7, the oil lock piece 39 stays downward due to the negative pressure in the oil lock chamber 31A, and a gap 39C between the upper end of the oil lock piece 39 and the flange 72 of the upper holder 70 is obtained. Oil from the upper oil reservoir 35A to the oil lock chamber 31A via the gap 39B between the inner periphery of the oil lock piece 39 and the outer periphery of the piston rod 29 and the flow path 83 of the lower stopper 80 (E-type retaining ring 80A). To eliminate the negative pressure in the oil lock chamber 31A. The oil lock piece 39 can be smoothly pulled out from the oil lock collar 31.

According to the present embodiment, the following operational effects can be obtained.
(a) A flow path 83 that opens around the outer periphery of the piston rod 29 is provided in the lower stopper 80 where the lower end of the oil lock piece 39 abuts. Therefore, when moving from the oil lock state to the extension stroke, a gap 39C between the upper end of the oil lock piece 39 and the flange 72 of the upper holder 70, a gap 39B between the inner periphery of the oil lock piece 39 and the outer periphery of the piston rod 29, and Oil flows into the oil lock chamber 31A from the upper oil reservoir chamber 35A of the oil lock collar 31 via the flow path 83 of the lower stopper 80, and the negative pressure in the oil lock chamber 31A is released. Accordingly, the oil lock piece 39 can be smoothly pulled out from the oil lock collar 31 without forming the groove channel 83 in the oil lock piece 39.

  (b) When the lower stopper 80 is the E-shaped retaining ring 80A, when the engaging protrusion 82 on the inner periphery of the E-shaped retaining ring 80A is mounted in the annular mounting groove 29B of the piston rod 29 in (a) above, The space between the adjacent locking projections 82 on the inner periphery of the E-shaped retaining ring 80A becomes the flow path 83 of the lower stopper 80 described above (a).

  The present invention can also be applied to an inverted front fork in which a damper is inverted and installed. That is, the axle side tube is slidably inserted into the vehicle body side tube, the piston rod is erected at the bottom of the axle side tube, the piston rod is inserted into the damper cylinder supported by the body side tube, and the bottom of the axle side tube An oil lock collar is provided around the piston rod of the damper cylinder, and the oil lock piece attached to the lower outer periphery of the damper cylinder is fitted to the oil lock collar near the maximum compression stroke. An upper holder and a lower stopper are provided at two positions above and below the flange, a flange that protrudes around the lower outer periphery of the damper cylinder is provided on the upper holder, and a flow path that opens around the lower outer periphery of the damper cylinder is provided on the lower stopper. The lock piece is diametrically spaced from the outer periphery of the damper cylinder piece mounting part. Of a gap, it may be held by an axial gap between the upper holder flange and the lower stopper. According to this, the flow path opened around the outer periphery of the lower part of a damper cylinder was provided in the lower stopper which the lower end of an oil lock piece collides. Therefore, when moving from the oil lock state to the extension stroke, the clearance between the upper end of the oil lock piece and the flange of the upper holder, the gap between the inner periphery of the oil lock piece and the outer periphery of the damper cylinder, and the flow path of the lower stopper are used. Thus, oil flows into the oil lock chamber from the oil reservoir chamber above the oil lock collar, and the negative pressure in the oil lock chamber is eliminated. As a result, the oil lock piece can be smoothly removed from the oil lock collar without forming a groove channel in the oil lock piece.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration of the present invention is not limited to this embodiment, and even if there is a design change or the like without departing from the gist of the present invention. It is included in the present invention.

FIG. 1 is a sectional view showing a front fork. 2 is an enlarged cross-sectional view of the lower portion of the front fork of FIG. FIG. 3 is an enlarged cross-sectional view of an intermediate portion of the front fork of FIG. 4 is an enlarged cross-sectional view of the upper portion of the front fork of FIG. FIG. 5 is a cross-sectional view showing the mounting structure of the oil lock piece. FIG. 6 is a cross-sectional view showing an oil lock state by the oil lock piece. FIG. 7 is a cross-sectional view showing a state where the oil lock piece is detached. FIG. 8 is a plan view showing an E-shaped retaining ring.

Explanation of symbols

10 Front fork 11 Outer tube (vehicle body side tube)
12 Inner tube (Axle tube)
21 Damper cylinder 29 Piston rod 29A Non-insertion portion 31 Oil lock collar 39 Oil lock piece 39A Clearance flow path 39B, 39C Clearance 70 Upper holder 72 Flange 80 Lower stopper 80A E-type retaining ring 83 Flow path

Claims (3)

Insert the axle side tube slidably into the body side tube,
A damper cylinder is erected at the bottom of the axle side tube, and a piston rod supported by the vehicle body side tube is inserted into the damper cylinder.
In the front fork where an oil lock collar is provided at the top of the damper cylinder and the oil lock piece attached to the non-insertion portion of the piston rod into the damper cylinder is fitted to the oil lock collar near the most compression stroke,
An upper holder and a lower stopper are provided at the top and bottom positions of the piston rod piece mounting part to which the oil lock piece is mounted. A flange that projects around the outer periphery of the piston rod is provided on the upper holder, and a lower stopper is provided around the outer periphery of the piston rod. Provide a flow channel that opens to
Oil lock piece has a radial gap between the outer periphery of the piece attaching portion of the piston rod, is held by an axial gap between the flange and the lower stopper of the upper holder, the piston rod Can move up and down along the circumference of
The oil lock piece includes an upper plane that comes into pressure contact with the flange of the upper holder by moving upward with respect to the outer periphery of the piston rod, and a lower plane that comes into contact with the lower stopper by moving downward with respect to the outer periphery of the piston rod.
The upper holder is separated from the piston rod,
The front fork, wherein the flow path provided in the lower stopper communicates with the radial gap between the oil lock piece and the outer periphery of the piece mounting portion of the piston rod . Insert the axle side tube slidably into the body side tube,
A piston rod is erected at the bottom of the axle side tube, and the piston rod is inserted into a damper cylinder supported by the vehicle body side tube.
In the front fork in which an oil lock collar is provided around the piston rod at the bottom of the axle tube, and the oil lock piece attached to the lower outer periphery of the damper cylinder is fitted to the oil lock collar near the most compression stroke.
An upper holder and a lower stopper are provided at the upper and lower positions of the damper cylinder piece mounting part to which the oil lock piece is mounted. A flange that protrudes around the lower outer periphery of the damper cylinder is provided on the upper holder. Provide a channel that opens around the outer periphery,
The oil lock piece has a radial clearance with the outer periphery of the damper cylinder piece mounting portion, and is held with an axial clearance between the flange of the upper holder and the lower stopper . It can move up and down along the outer circumference by the axial gap,
The oil lock piece includes an upper plane that comes into pressure contact with the flange of the upper holder by moving upward with respect to the outer periphery of the piston rod, and a lower plane that comes into contact with the lower stopper by moving downward with respect to the outer periphery of the piston rod.
The front fork, wherein the flow path provided in the lower stopper communicates with the radial gap between the oil lock piece and the outer periphery of the piston rod piece mounting portion . The front fork according to claim 1 or 2, wherein the lower stopper is an E-shaped retaining ring.

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