JP2006029444A - Shift fork - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shift fork of a manual transmission or a twin clutch type manual transmission free from uneven abrasion of an engagement piece gripping a coupling sleeve. <P>SOLUTION: In this shift fork 1 for axially displacing the coupling sleeve 2 by being engaged with an outer peripheral groove 3 of the coupling sleeve 2 constituting a synchronous engagement mechanism of the manual transmission, a part of the shift fork 1 engaged with the outer peripheral groove 3 of the coupling sleeve is constituted by an engagement piece 5 independent from a main body of the shift fork, the engagement piece 5 has the shape having planes 5a, 5b kept into contact with both side walls 3a, 3b of the outer peripheral groove 3, and the engagement piece 5 is journaled to the main body 4 of the shift fork to be rotated around the radial direction of the coupling sleeve 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention comprises a manual transmission or an automatic clutch for each gear stage grouped between the engine and the manual transmission, and the engagement / release switching (switching control) of these automatic clutches between the two gear group. The present invention relates to a shift fork in a so-called twin-clutch type manual transmission that is useful for performing automatic gear shifting by alternately selecting gear positions.

  As a manual transmission, for example, there is one described in Patent Document 1, and a shift fork used therefor is a circle provided on a coupling sleeve 52 of a synchronous meshing mechanism 51 as shown in FIGS. What consists of the main body 54 of the shift fork which straddles the cyclic | annular outer periphery groove | channel 53 over the half periphery, and the engagement piece 55 engaged with the said outer periphery groove | channel 53 is used widely.

In such a shift fork 56, the shift fork 56 is displaced in the axial direction of the shift shaft 57 by connecting the main body 54 of the shift fork to a shift shaft 57 provided in parallel to the central axis of the coupling sleeve 52. The coupling sleeve 52 of the synchronous meshing mechanism 51 is moved in the axial direction, and a spline portion provided on the inner periphery of the coupling sleeve 53 and a counter (not shown) under the synchronizing action of the synchronizer ring 58 shown in FIG. A gear set of any speed stage can be selected by engaging with a clutch gear 59 of a gear set of any speed stage provided on the shaft or the input shaft.
JP-A-8-320054

  In the shift fork 56 used in such a manual transmission or a twin clutch type manual transmission, the shift fork main body 54 and the engagement piece 55 are conventionally rigidly connected, or as shown in FIG. The piece 55 is formed integrally with the main body 54 of the shift fork, and the engagement piece 55 is in surface contact with both side walls of the outer circumferential groove 53, usually in the direction of arrow A in FIG. As shown in FIG. 7 which is a view, it has a rectangular parallelepiped shape. For this reason, due to the reaction force generated when the coupling sleeve 52 of the synchronous meshing mechanism is displaced in the axial direction thereof, the shift fork main body 54 is bent between the shift shaft and the tip portion, and the groove of the outer peripheral groove 53 is formed. As the width is larger than the width of the engaging piece 55, the engaging piece 55 having a rectangular parallelepiped shape with respect to the both side walls of the outer peripheral groove 53, as shown in FIG. By inclining with respect to both side walls 53a and 53b, the corner portions 55a and 55b of the engagement piece 55 come into contact with both side walls 53a and 53b, and uneven wear is applied to the corner portions 55a and 55b of the engagement piece 55. There was a problem that it might occur.

  Therefore, in the present invention, a shift of a manual transmission or a twin-clutch type manual transmission, which aims to solve the above-described problem and does not cause uneven wear on an engagement piece engaged with an outer circumferential groove of a coupling sleeve. Propose fork.

The shift fork according to claim 1 is a shift fork that engages with an outer circumferential groove of a coupling sleeve forming a synchronous meshing mechanism of a manual transmission and displaces the coupling sleeve in the axial direction.
A portion of the shift fork that engages with the outer peripheral groove of the coupling sleeve is constituted by an engagement piece separate from the main body of the shift fork,
The engaging piece has a shape having flat surfaces that contact both side walls of the outer circumferential groove of the coupling sleeve,
The engaging piece is pivotally supported with respect to the main body of the shift fork so as to be rotatable about the radial direction of the coupling sleeve.

The shift fork according to claim 2 is a shift fork that engages with an outer peripheral groove of a coupling sleeve that forms a synchronous meshing mechanism of a manual transmission and displaces the coupling sleeve in an axial direction.
A portion of the shift fork that engages with the outer peripheral groove of the coupling sleeve is constituted by an engagement piece separate from the main body of the shift fork,
The engagement piece is pivotally supported with respect to the main body of the shift fork so as to be rotatable about the radial direction of the coupling sleeve,
The engagement piece has a cylindrical shape having a central axis as a shaft support axis with respect to a main body of the shift fork.

  According to the shift fork of the first aspect, the portion connected to the shift shaft of the main body of the shift fork and the engagement piece by the reaction force generated when the coupling sleeve of the synchronous meshing mechanism is displaced in the axial direction thereof. Even if a deflection occurs between the portion connected to the main body of the shift fork, the engagement piece can rotate around the radial direction of the coupling sleeve with respect to the main body of the shift fork. The plane contacting the both side walls of the outer circumferential groove is always parallel to both side walls of the outer circumferential groove, and the plane contacting the both side walls of the outer circumferential groove of the engagement piece is brought into surface contact with the both side walls. Therefore, it is possible to prevent uneven wear from occurring on the surfaces contacting the both side walls of the outer peripheral groove of the engagement piece.

  According to the shift fork according to claim 2, the portion connected to the shift shaft of the main body of the shift fork and the engagement piece by the reaction force generated when the coupling sleeve of the synchronous meshing mechanism is displaced in the axial direction thereof. Even if a deflection occurs between the parts connected to the cylinder, the engagement piece has a cylindrical shape and is rotatable about the radial direction of the coupling sleeve with respect to the main body of the shift fork. The side surface of the cylindrical engagement piece is always in line contact or point contact with both side walls of the outer circumferential groove, and friction on the contact surface accompanying the circumferential rotation of the coupling sleeve can be reduced. For this reason, it is also possible to prevent uneven wear from occurring on the surfaces contacting the both side walls of the outer peripheral groove of the engaging piece.

Hereinafter, embodiments of the present invention will be described in detail based on examples shown in the drawings.
FIG. 1 is a schematic view showing an aspect of a shift fork and a coupling sleeve of a manual transmission synchronous meshing mechanism according to an embodiment of the present invention during a shift operation, and FIG. 2 shows a shift fork configuration and a shift fork. It is a schematic diagram which shows an engagement aspect with a coupling sleeve seeing from the center axis line direction of a coupling sleeve.

  In the figure, reference numeral 1 denotes a shift fork, and a portion of the shift fork that engages with the outer peripheral groove 3 of the coupling sleeve 2 is constituted by an engagement piece 5 that is separate from the main body 4 of the shift fork. 5 is a rectangular parallelepiped shape having flat surfaces 5 a and 5 b that contact both side walls 3 a and 3 b of the outer circumferential groove 3 of the coupling sleeve 2, and the engaging piece 5 is centered in the radial direction of the coupling sleeve 2. Is pivotally supported with respect to the main body 4 of the shift fork. (Equivalent to claim 1)

  The shift fork 1 is provided with the main body 3 of the shift fork 1 and the outer circumferential groove 3 of the coupling sleeve 2 in the circumferential direction so that it is useful for displacing the coupling sleeve 2 in the axial direction during the shift operation. The engagement fork 5 is pivotally supported at both ends of the main body 2 of the shift fork that forms the fork, and each engagement with the two ends of the main body 2 of the shift fork 1 is supported. The shaft support axes C1 and C2 of the combined piece 5 are configured to coincide with each other across the center axis C3 of the coupling sleeve 2 (corresponding to claim 4), and the main body 4 is connected to the shift shaft 6. Here, the width W5 of the engagement piece 5 is smaller than the width W3 of the outer peripheral groove 3. This is because the coupling sleeve 3 can rotate with respect to the shift fork 1.

  According to the configuration corresponding to the third aspect, the support points of the shift fork 1 with respect to the coupling sleeve 2 can be increased to two points, and the shift operation can be made more stable. According to the configuration corresponding to the fourth aspect, the force exerted on the coupling sleeve 2 of the shift fork 1 is maximized by disposing the engaging piece 5 on the diameter passing through the central axis of the coupling sleeve 2. In addition, it is possible to prevent the coupling sleeve 2 from being given a force in the twisting direction during shifting.

  According to the configuration corresponding to the first aspect, the reaction force generated when the coupling sleeve 2 of the synchronous meshing mechanism is displaced in the axial direction thereof causes the shift shaft 6 of the main body 4 of the shift fork 1 shown in FIG. Even if a deflection occurs between the connected portion and the portion connected to the engagement piece 5, the engagement piece 5 rotates about the radial direction C1 of the coupling sleeve 2 with respect to the main body 4 of the shift fork. Since it is movable, the planes 5a and 5b of the engagement piece 5 that contact the both side walls 3a and 3b of the outer circumferential groove 3 shown in FIG. 1 are always parallel to the both side walls 3a and 3b of the outer circumferential groove. Since the flat surfaces 5a and 5b contacting the side walls 3a and 3b of the outer peripheral groove 3 of the engaging piece 5 can be brought into surface contact with the side walls 3a and 3b, the outer peripheral groove of the engaging piece 5 3 wear unevenly on the surface that contacts both side walls 3a and 3b It is possible to prevent occurring.

  FIG. 3 is a schematic view showing a mode of a shift fork and a coupling sleeve of a manual transmission synchronous meshing mechanism according to another embodiment of the present invention during a shift operation, and FIG. It is a schematic diagram which shows the engagement aspect with a fork and a coupling sleeve seeing from the center axis line direction of a coupling sleeve.

In the figure, 11 indicates a shift fork, and the shift fork portion that engages with the outer peripheral groove 13 of the coupling sleeve 12 is constituted by an engagement piece 15 that is separate from the main body 14 of the shift fork,
The engagement piece 15 is pivotally supported with respect to the main body of the shift fork so that the engagement piece 15 can be rotated around the radial direction of the coupling sleeve 12, and the engagement piece 15 has a pivot axis CC2 with respect to the main body 14 of the shift fork as a central axis. It has a cylindrical shape. (Equivalent to claim 2)

  The shift fork 11 is provided with the main body 14 of the shift fork 11 and the outer circumferential groove 13 of the coupling sleeve 12 in the circumferential direction so that it is useful for displacing the coupling sleeve 12 in the axial direction during the shift operation. The engagement forks 15 are pivotally supported at both ends of the main body 14 of the shift fork having a bifurcated shape, respectively (corresponding to claim 3). The axial support axes C1 and C2 of the piece 5 are configured to coincide with each other across the central axis C3 of the coupling sleeve 2 (corresponding to claim 4), and the main body 4 is connected to the shift shaft 16. Again, the width W15 of the engagement piece 15 is smaller than the width W13 of the outer circumferential groove 13. This is also because the coupling sleeve 13 can rotate with respect to the shift fork 11.

According to the configuration corresponding to claim 2, the reaction force generated when the coupling sleeve 12 of the synchronous meshing mechanism is displaced in the axial direction thereof causes the shift shaft 16 of the main body 14 of the shift fork 11 shown in FIG. Even if a deflection occurs between the portion to be connected and the portion to be connected to the engagement piece 15, the engagement piece 15 has a cylindrical shape as shown in FIG. On the other hand, since the coupling sleeve 12 is rotatable about the radial direction, the side surface of the cylindrical engagement piece 15 is always brought into line or point contact with both side walls 13a and 13b of the outer circumferential groove 13, Further, the friction on the contact surface 15a accompanying the rotation of the coupling sleeve 12 in the circumferential direction indicated by the arrow F in FIG. 3 is reduced by the engagement piece 15 rotating in the R direction. It can therefore, also it is possible to prevent the uneven wear occurs on both side walls 13a, faces 15a which contacts the 13b of the outer peripheral groove 13 of the engaging piece 15. Of course, the effect is the same even if the rotation direction of the coupling sleeve 12 is reversed.
Since the effects corresponding to claims 3 and 4 are repeated, they are omitted.

  In addition, this invention is not limited only to the said embodiment, Many deformation | transformation or a change is possible.

It is a schematic diagram which shows the engagement aspect with the coupling sleeve of the shift fork of the synchronous meshing mechanism of the manual transmission which becomes one Example of this invention. It is a schematic diagram which shows the shift fork of the synchronous meshing mechanism of the manual transmission which becomes one Example of this invention. It is a schematic diagram which shows the engagement aspect with the coupling sleeve of the shift fork of the synchronous meshing mechanism of the manual transmission which becomes one Example of this invention. It is a schematic diagram which shows the shift fork of the synchronous meshing mechanism of the manual transmission which becomes one Example of this invention. It is a schematic diagram which shows the general structure of the synchronous meshing mechanism of a manual transmission. It is a schematic diagram which shows the general structure of the shift fork of the synchronous meshing mechanism of a manual transmission. It is a schematic diagram which shows the engagement aspect with the coupling sleeve of the shift fork of the synchronous meshing mechanism of the conventional manual transmission.

Explanation of symbols

1 Shift fork 2 Coupling sleeve 3 Peripheral groove (cuboid)
4 Body (shift fork)
5 Engagement piece 6 Shift shaft 11 Shift fork 12 Coupling sleeve 13 Outer peripheral groove 14 Main body (shift fork)
15 Engagement piece (cylindrical)
16 Shift shaft

Claims (4)

In a shift fork that engages with an outer circumferential groove of a coupling sleeve that forms a synchronous meshing mechanism of a manual transmission and displaces the coupling sleeve in the axial direction.
A portion of the shift fork that engages with the outer peripheral groove of the coupling sleeve is constituted by an engagement piece separate from the main body of the shift fork,
The engaging piece has a shape having a flat surface that contacts both side walls of the coupling sleeve outer circumferential groove,
A shift fork in which the engagement piece is pivotally supported with respect to the main body of the shift fork so as to be rotatable about the radial direction of the coupling sleeve. In a shift fork that engages with an outer circumferential groove of a coupling sleeve that forms a synchronous meshing mechanism of a manual transmission and displaces the coupling sleeve in the axial direction.
A portion of the shift fork that engages with the outer peripheral groove of the coupling sleeve is constituted by an engagement piece separate from the main body of the shift fork,
The engagement piece is pivotally supported with respect to the main body of the shift fork so as to be rotatable about the radial direction of the coupling sleeve,
The shift fork is characterized in that the engagement piece has a cylindrical shape whose center axis is a shaft support axis with respect to a main body of the shift fork. The shift fork according to claim 1 or 2,
The main body of the shift fork has a bifurcated shape straddling the outer peripheral groove of the coupling sleeve in the circumferential direction, and the engaging pieces are pivotally supported at both ends of the bifurcated shift fork main body, respectively. Shift fork. The shift fork according to claim 3,
The shift fork is configured so that the shaft support axis of each engaging piece with respect to both ends of the main body of the shift fork is aligned across the axis of the coupling sleeve.

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