TWI457255B - The body support structure of the calipers for discs - Google Patents

Description

Caliper body support structure for disc brakes for vehicles

The present invention relates to a caliper body support structure for a disc brake for a vehicle mounted on a two-wheeled vehicle, and more particularly to a support structure for a vehicle suspension device such as a front fork that directly supports a caliper body of a disc slide type disc brake. .

In the disc brake type of the two-wheel-drive type, the pair of slide pin attachment portions are integrally formed on the outer peripheral side and the inner peripheral side of the disk of the vehicle suspension device, and are attached to the slide. The slide pin of the pin attachment portion is movably attached to the caliper body disposed across the outer peripheral side of the disk rotor in the disk axial direction. In the pair of slide pin attachment portions, the mounting surface of the slide pin attachment portion on the inner circumferential side of the disk on the opposite side of the disk rotor is disposed on a parallel surface that passes through the center axis of the vehicle suspension device and is parallel to the side surface of the disk rotor. The mounting surface on the opposite side of the disk rotor of the slide pin mounting portion on the outer peripheral side of the disk is disposed on the outer side of the vehicle body from the parallel surface. Further, there is a disc brake in which a slide pin mounting portion on the outer peripheral side of the disc is fastened with a long slide pin having a male screw portion on the proximal end side, and the front end side of the slide pin is inserted through the caliper body The slide pin support portion is fastened to the slide pin attachment portion on the inner circumferential side of the disk, and the short slide pin having the male screw portion on the distal end side is fastened in a state in which the proximal end side is inserted into the slide pin support portion of the caliper body (for example) Refer to Patent Document 1).

[Previous Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Publication No. Sho 59-191434

However, in the caliper body supporting structure, the mounting surface of the disk rotor formed on one of the vehicle suspension devices and the sliding pin mounting portion is disposed on a center axis passing through the vehicle suspension device and parallel to the side surface of the disk rotor The parallel surface and the parallel surface are closer to the outer side of the vehicle body. Since the step of the width direction of the vehicle body is generated at the position where the pair of sliding pin mounting portions are formed, the processing of the sliding pin mounting portion is time consuming and costly. . Moreover, since the mounting structures of the slide pins are different from each other, work efficiency is also poor.

Accordingly, it is an object of the present invention to provide a caliper body support structure for a disc brake for a vehicle, which can reduce the cost by simply forming a slide pin mounting portion in a vehicle suspension device, and can easily mount the slide pin on a slide pin. The department can improve work efficiency.

In order to achieve the above object, the caliper body support structure for a disc brake of a vehicle of the present invention is disposed between the action portion and the action counter portion of the caliper body disposed over the outer circumference of the disc rotor, and opposed to each other via the disc rotor. a pair of friction washers, a pair of guide pins including a slide pin formed on the slide pin support portion, and a slide pin inserted into the slide pin support portion is mounted on one of the pair of vehicle suspension devices The mounting portion is slidably supported along the axis of the disk The caliper body; wherein the sliding pin includes: a sliding pin body sliding on the guiding hole; and a pin mounting bolt for mounting the sliding pin body to the sliding pin mounting portion; and the pair of sliding pin mounting portions The mounting surface on the opposite side of the rotor is disposed on the same plane parallel to the parallel surface as the parallel surface parallel to the side surface of the disc rotor and the parallel surface parallel to the side surface of the disc rotor.

Further, the slide pin main body may be provided with a first flange portion that abuts against the disc rotor side mounting surface of the slide pin attaching portion, and the pin mounting bolt may be provided opposite to the disc rotor of the slide pin attaching portion. a second flange portion abutting on the side mounting surface, and mounting holes of the same diameter are respectively inserted into the two sliding pin mounting portions, and the sliding pin body is fastened to the front end side of the pin mounting bolt inserted into each of the mounting holes, respectively The slide pin attaching portion is sandwiched between the first flange portion and the second flange portion, and the slide pin main body and the pin mounting bolt are coupled and fixed.

Further preferably, one of the pair of slide pin attachment portions is attached to the slide pin body, and the pin mounting bolt has the same shape.

Further, a notch portion may be formed in a part of the outer peripheral surface of the first flange portion provided in each of the slide pin main bodies, and each of the slide pin attachment portions may be formed to abut against the notch portion to stop the slide pin main body. The turning faces are located on the same plane. Further, a notch portion may be formed in a part of the outer peripheral surface of the first flange portion of each of the slide pin main bodies, and each of the slide pin attachment portions may be formed to abut against the notch portion to stop the slide pin body. a rotation stop surface, each of which is formed in parallel with each other One side of the pin rotation direction of the pin mounting bolt when the slide pin main body is coupled to the pin mounting bolt. .

According to the caliper body supporting structure for a disc brake of a vehicle according to the present invention, the mounting surface on the opposite side of the disc rotor of the pair of slide pin mounting portions is disposed on a side of the center of the disc suspension device and the side of the disc rotor The parallel parallel faces are located on the same plane parallel to the parallel faces on the outer side of the vehicle body, so that the slide pin mounting portion can be easily formed. Further, the slide pin includes a slide pin main body and a pin attachment bolt, the first flange portion is provided on the slide pin main body, the second flange portion is provided on the pin mounting bolt, and the two pin mounting bolts are respectively inserted into the slide pin. The same diameter mounting hole that is bored in the mounting portion, the sliding pin body is fastened to the front end side, and the sliding pin mounting portion is sandwiched between the first flange portion and the second flange portion, and the sliding pin body and the pin are attached Since the mounting bolts are fixed to each other, it is only necessary to pierce the mounting holes of the same diameter in the slide pin attaching portion, and the slide pin attaching portion can be formed more easily. Further, since the two pin mounting bolts have the same shape, the cost can be reduced and the work efficiency can be improved.

Further, each of the slide pin main bodies is formed with a notch portion, and each of the slide pin attachment portions is formed with a rotation stop surface. Therefore, when the slide pin is attached to the slide pin attachment portion, the slide pin body can be prevented from rotating and the pin can be securely fastened. Install the bolts.

Further, when the slide pin main body and the pin attachment bolt are coupled and fixed, the notch portion formed in the slide pin main body is offset from the fastening rotation direction of the pin attachment bolt by the fastening torque of the pin attachment bolt. Connect In the rotation stop surface, the sliding pin is mounted on the opposite side of the rotation stop surface, and the sliding pin system of the two is offset in the same direction, so that the distance between the sliding pins does not change, and the friction gasket can be prevented. Drag.

1 to 4 show a first embodiment of the present invention, and a pin-type sliding type brake type 1 of a two-wheeled vehicle such as a second embodiment of the present invention includes a disc rotor 2, and The wheel (not shown) rotates integrally; the slide pin attachment portion 3 on the outer peripheral side of the disk is attached to the side of one of the disk rotors 2 via the first support leg 3a, the second support leg 3b, and the third support leg 3c. The fork 4 is integrally formed in the front suspension 4 as the vehicle suspension device of the present invention; the slide pin attachment portion 5 on the inner circumferential side of the disk is integrally formed on the front fork 4 via the first support leg 5a and the second support leg 5b; the caliper body 8 Slidably supported by the pair of slide pins 6 and 7 in the direction of the disk axis, and a pair of friction washers 9, 9 on the action portion 8a of the caliper body 8 The opposing portions 8b are disposed to face each other across the disk rotor 2. Further, the arrow A is a rotation direction of the disk rotor that rotates integrally with the front wheel when the vehicle is moving forward, and the disk rotation side and the disk screwing side are set in accordance with the direction in which the disk rotates when the vehicle is moving forward.

The caliper body 8 includes the above-described action portion 8a and the action reverse portion 8b which are disposed opposite to both sides of the disk rotor 2, and the bridge portion 8c which is connected to the outer side of the disk rotor 2 and which is connected. The action portion 8a includes a cylinder hole 8d and a pair of slide pin support portions 8e and 8f, and the reaction reverse portion 8b is provided with a reaction force claw 8g. Yuqiao 8c A rectangular ceiling opening 8h penetrating the inner and outer portions is formed substantially at the center, and the torque receiving portions 8i and 8i are disposed on the screw insertion side and the screw-out side of the ceiling opening portion 8h, and are disposed in the torque receiving portion 8i on the disk unwinding side. A torque receiving surface 8k that receives the braking torque is formed on the side of the caliper center of the slide pin support portion 3 on the screw-out side of the disk.

Each of the friction pads 9 is formed by joining a spacer 9a that is in sliding contact with the side surface of the disk rotor 2 to a metal back plate 9b. The hanging pin insertion portion 9c is protruded from the center of the disk in the radial direction of the back plate 9b, and the ears 9d and 9d are provided on both sides of the back plate 9b, and the friction pads 9 and 9 are attached to the suspension. The pin insertion portion 9c is inserted into the hanging pin 10 that penetrates the ceiling opening 8h and is placed on the acting portion 8a and the acting counter portion 8b, and the ears 9d and 9d are locked to the torque receiving portions 8i and 8i along the disk axis. The direction is slidably held on both sides of the disk rotor 2, and is elastically supported on the inner side in the radial direction of the disk by the shim spring 11 which is contracted with the hanging pin 10. The cylinder hole 8d is provided to open to the disk rotor side at substantially the center of the action portion 8a, and a cup-shaped piston 12 is liquid-tightly inserted into the cylinder hole 8d to form a gap between the piston 12 and the bottom of the cylinder hole 8d. There is a hydraulic chamber 13.

The slide pin support portions 8e and 8f are respectively protruded from the side surface of the disk rotor 2 toward the disk rotation side and the disk radial direction from the side surface of the disk rotor 2, and the slide pin support portion 8e on the disk rotation side is The action portion side is extended to the opposite side of the disk in the direction of the disk axis, and a long bag-shaped guide hole 8m opening to the side of the action portion is formed, and the center side of the caliper of the slide pin support portion 8e becomes the above torque bearing Accepted face 8k. The slide pin support portion 8f on the inner side in the radial direction of the disk has a guide hole 8n formed to be shorter than the guide hole 8m on the screw-out side of the disk.

The outer peripheral side sliding pin attachment portion 3 provided on the front fork 4 includes a mounting hole 3d including a slide pin 6, and protrudes to the disk unwinding side via the first support leg 3a, the second support leg 3b, and the third support leg 3c. And the outer peripheral side of the disc. Further, the first support leg 3a is extended from the slide pin attachment portion 3 to the direction in which the brake torque acts, and the second support leg 3b protrudes from the slide pin attachment portion 3 to the direction orthogonal to the first support leg 3a, and the third The support leg 3c protrudes to the intermediate portion between the first support leg 3a and the second support leg 3b. The slide pin attaching portion 5 on the inner peripheral side of the disk includes a mounting hole 5c of the slide pin 7, and protrudes to the disk screw-in side and the inner peripheral side of the disk via the first support leg 5a and the second support leg 5b. The sliding pin mounting portions 3 and 5 of the two are disposed such that the mounting surfaces 3e and 5d on the disk rotor side are disposed closer to the parallel surface F1 that is parallel to the center axis of the front fork 4 and parallel to the side surface of the disk rotor. On the same plane F2 on the outer side of the body parallel to the parallel plane F1, the mounting surfaces 3f and 5e on the opposite sides of the disk rotor are disposed on the same plane F3 parallel to the parallel plane F1, and the mounting holes 3d and 5c are Same diameter and worn to the same length.

The slide pin 6 on the screw-out side includes a slide pin body 6a slidable in the guide hole 8m formed in the slide pin support portion 8e, and a convex portion to which the slide pin body 6a is attached to the slide pin mounting portion 3 Hexagon bolt 6b (pin mounting bolt of the present invention). The slide pin body 6a includes a slide shaft portion 6c slidable in the guide hole 8m, and a disc rotor side mounting with the slide pin mounting portion 3. The first flange portion 6d that the surface 3e abuts and the female screw hole 6e that opens to the first flange portion 6d. The hexagonal bolt 6b is provided between the hexagonal head portion 6f and the shaft portion 6g, and includes a second flange portion 6h that abuts against the disk rotor opposite side mounting surface 3f of the slide pin attachment portion 3, and is formed at the front end of the shaft portion 6g. There is an external thread portion 6i. The slide pin 7 on the inner peripheral side of the disk has the same configuration as the slide pin 6 on the outer peripheral side of the disk, and includes a slide pin body 7a and a hexagon bolt 7b, and the slide pin body 7a includes a slide shaft portion 7c and a first flange. The portion 7d and the female screw hole 7e include a hexagonal head portion 7f, a shaft portion 7g, a second flange portion 7h, and a male screw portion 7i. Further, the hexagon bolt 6b of the slide pin 6 and the hexagon bolt 7b of the slide pin 7 are formed in the same shape.

Each of the slide pins 6 and 7 inserts the hexagon bolts 6b and 7b into the mounting holes 3d and 5c of the slide pin mounting portions 3 and 5 from the opposite sides of the disc rotor, and protrudes from the mounting holes 3d and 5c. 6i, 7i are screwed into the internally threaded holes 6e, 7e of the slide pin bodies 6a, 7a, respectively. Thereby, the slide pin 6 is such that the first flange portion 6d and the second flange portion 6h sandwich the mounting faces 3e and 3f of the slide pin attaching portion 3, and the slide pin 7 is composed of the first flange portion 7d and the second projection. The edge portion 7h sandwiches the attachment surfaces 5d and 5e of the slide pin attachment portion 5, and the hexagon bolts 6b and 7b and the slide pin bodies 6a and 7a can be coupled and fixed.

In this manner, the slide pin 6 of the slide pin attachment portion 3 attached to the screw-out side of the disk is inserted into the guide hole 8m of the disk-sliding-side slide pin support portion 8e of the caliper body 8 via the dust cover 14, and is mounted in the disk. The slide pin 7 of the slide pin mounting portion 5 on the peripheral side is inserted into the disc of the caliper body 8 via the dust cover 15 The guide hole 8n of the peripheral side slide pin support portion 8f is slidably supported by the caliper body 8 in the disk axial direction. Further, the dust covers 14 and 15 can have the same shape.

In the disc brake 1 formed as described above, the disc rotor opposite side mounting surfaces 3f and 5e and the disc rotor side mounting surfaces 3e and 5d formed on one of the front fork 4 and the slide pin mounting portions 3 and 5 are respectively Arranging on the same plane F3, F2 parallel to the parallel plane F1 on the outer side of the vehicle body, which is parallel to the central axis of the front fork 4 and parallel to the side surface of the disk rotor 2, and then having the same diameter and the same The length of the mounting holes 3d, 5c is sufficient, so that the slide pin mounting portions 3, 5 can be easily formed. The slide pins 6 and 7 can be attached to the slide pin mounting portion 3 only by screwing the screw portions 6i and 7i of the hexagon bolts 6b and 7b into the screw holes 6e and 7e of the slide pin bodies 6a and 7a, respectively. 5, the slide pins 6, 7 can be easily attached to the slide pin attachment portions 3, 5, and the assemblage of the caliper body 8 can be improved. Further, since the two hexagon bolts 6b and 7b are formed in the same shape, and the two dust covers 14 and 15 have the same shape, the cost can be reduced and the work efficiency can be improved.

It is to be noted that the same reference numerals are given to the same components as those in the first embodiment, and the detailed description thereof will be omitted.

5 to 8 show a second embodiment of the present invention. The slide pins 6 and 7 of the present embodiment are formed in a planar shape on a part of the outer peripheral surface of the first flange portions 6d and 7d of the slide pin bodies 6a and 7a. Notched portions 6k, 7k. Again, sliding pin Each of the mounting portions 3 and 5 is formed in a plate shape that expands in a substantially triangular shape. In the side faces of the disk rotors of the sliding pin mounting portions 3 and 5, the rotation preventing surfaces 3g and 5f of the anti-rotation sliding pin bodies 6 and 7 are formed. They are formed on the same plane parallel to the central axis CL1 of the front fork 4, respectively.

This embodiment is formed as described above, whereby when the slide pins 6 and 7 are attached to the slide pin attachment portions 3 and 5, the notch portions 6k and 7k can be prevented from abutting against the rotation preventing surfaces 3g and 5f. By sliding the pin bodies 6a, 7a, the hexagon bolts 6b, 7b can be satisfactorily fastened.

Further, when the slide pin bodies 6a and 7a are coupled to the hexagon bolts 6b and 7b, the tightening torque of the slit portions 6k and 7k of the slide pin bodies 6a and 7a through the hexagon bolts 6b and 7b is shifted from the hexagonal mounting bolt 6b, 7b is in contact with the rotation stop surface in the state of tightening the rotation direction R1 side, and the slide pins 6, 7 are attached to the opposite side of the rotation stop surface, and the slide pins 6, 7 of the two are deviated in the same direction. Therefore, the distance between the sliding pins 6, 7 will not change, and the drag of the friction pad 9 can be prevented.

FIG. 9 is a view showing a third embodiment of the present invention. The slide pin attachment portions 3 and 5 of the present embodiment are formed in a plate shape extending in a substantially triangular shape in the same manner as in the second aspect, and are mounted on the slide pin. In the third and fifth portions, the notched portions 6k and 7k are formed in the first flange portions 6d and 7d of the slide pin bodies 6a and 7a. The rotation preventing faces 3h and 5g formed in the slide pin attachment portions 3 and 5 are formed in parallel with each other in the fastening rotation direction R1 of the hexagon bolts 6b and 7b when the slide pin bodies 6a and 7a are coupled to the hexagon bolts 6b and 7b. One side.

1. . . Disc brake

2. . . Disc rotor

3. . . Slide pin mounting

3a. . . First support foot

3b. . . 2nd support foot

3c. . . 3rd support foot

3d. . . Mounting holes

3e. . . Disc rotor side mounting surface

3f. . . Mounting surface on the opposite side of the disc rotor

3g, 3h. . . Stopping surface

4. . . Fork

5. . . Slide pin mounting

5a. . . First support foot

5b. . . 2nd support foot

5c. . . Mounting holes

5d. . . Disc rotor side mounting surface

5e. . . Mounting surface on the opposite side of the disc rotor

5f, 5g. . . Stopping surface

6, 7. . . Slide pin

6a, 7a. . . Sliding pin body

6b, 7b. . . Hex Bolts

6c, 7c. . . Sliding shaft

6d, 7d. . . First flange

6e, 7e. . . Internal threaded hole

6f, 7f. . . Hex head

6g, 7g. . . Shaft

6h, 7h. . . Second flange

6i, 7i. . . External thread

6k, 7k. . . Cutting section

8. . . Caliper body

8a. . . Action department

8b. . . Counteraction

8c. . . Bridge

8d. . . Cylinder bore

8e, 8f. . . Slide pin support

8g. . . Counterforce claw

8h. . . Ceiling opening

8i. . . Torque bearing

8k. . . Torque bearing surface

8m, 8n. . . Guide hole

9. . . Friction washer

9a. . . pad

9b. . . Backplane

9c. . . Hanging pin insertion part

9d. . . Ear piece

10. . . Hanging pin

11. . . Gasket spring

12. . . piston

13. . . Hydraulic room

14,15. . . Dust cover

A. . . turn around

R1. . . Fastening direction of rotation

F1. . . Parallel plane

F2, F3. . . flat

Fig. 1 is a front view showing a state in which a disk brake according to a first aspect of the present invention is mounted.

Fig. 2 is a cross-sectional side view showing the main part of the same state in which the disc brake is mounted.

Figure 3 is a cross-sectional view taken along line III-III of Figure 1.

Figure 4 is a cross-sectional view taken along line IV-IV of Figure 2.

Fig. 5 is a front view showing a state in which the disc brake of the second embodiment of the present invention is mounted.

Figure 6 is a cross-sectional view taken along line VI-VI of Figure 5.

Figure 7 is a cross-sectional view taken along line VII-VII of Figure 6.

Fig. 8 is a cross-sectional side view showing the main part of the same state in which the disc brake is mounted.

Fig. 9 is a cross-sectional view showing the essential part of a state in which a disk brake according to a third aspect of the present invention is mounted.

1‧‧‧ disc brakes

2‧‧‧disc rotor

3‧‧‧Sliding pin installation

3a‧‧‧1st support foot

3b‧‧‧2nd support foot

3c‧‧‧3rd support foot

4‧‧‧ Front fork

5‧‧‧Sliding pin installation

5a‧‧‧1st support foot

5b‧‧‧2nd support foot

6, 7‧‧‧ sliding pin

6b, 7b‧‧‧ hexagon bolts

8‧‧‧ caliper body

8a‧‧‧Action Department

8c‧‧‧Bridge

8d‧‧‧Cylinder bore

8e, 8f‧‧‧ sliding pin support

10‧‧‧ hanging pin

12‧‧‧Piston

Claims (6)

A caliper body support structure for a disc brake for a vehicle, wherein a pair of friction washers are disposed between the action portion and the action reverse portion of the caliper body disposed over the outer circumference of the disc rotor, and opposed to each other via the disc rotor; Forming a sliding pin supporting portion of one of the guiding holes including the sliding pin, and mounting the sliding pin inserted into the sliding pin supporting portion to the sliding pin mounting portion of the vehicle suspension device The ram body is slidably supported in the direction of the disk shaft; wherein the sliding pin includes: a sliding pin body sliding on the guiding hole; and a pin mounting bolt for mounting the sliding pin body on the sliding pin mounting portion; and the pair The mounting surface on the opposite side of the disc rotor of the slide pin mounting portion is disposed on the outer side of the vehicle body parallel to the parallel surface parallel to the side surface of the disc rotor and parallel to the parallel surface on flat surface. The caliper body support structure for a disc brake for a vehicle according to claim 1, wherein the slide pin main body is provided with a first flange portion that abuts against a disc rotor side mounting surface of the slide pin attachment portion, The pin mounting bolt is provided with a second flange portion that abuts against the mounting surface opposite to the disk rotor of the sliding pin mounting portion, and the mounting holes of the same diameter are respectively inserted into the two sliding pin mounting portions. The slide pin main body is fastened to the front end side of the pin mounting bolt of the mounting hole, and the slide pin attaching portion is sandwiched between the first flange portion and the second flange portion, and the slide pin main body and the pin mounting bolt are fixed to each other. . The caliper body support structure for a disc brake for a vehicle according to claim 1, wherein one of the pair of slide pin attachment portions is attached to the slide pin body and has the same shape. The caliper body support structure for a disc brake for a vehicle according to claim 2, wherein one of the pair of slide pin attachment portions is attached to the slide pin body, and the pin mounting bolt has the same shape. The caliper body supporting structure according to the second or fourth aspect of the invention, wherein a part of the outer peripheral surface of the first flange portion of each of the sliding pin bodies is formed with a notch portion, and each of the sliding pin mounting portions is formed separately The notch portions abut against each other to stop the rotation preventing surface of the sliding pin body, and the respective rotation preventing surfaces are located on the same plane. The caliper body supporting structure according to the second or fourth aspect of the invention, wherein a part of the outer peripheral surface of the first flange portion of each of the sliding pin bodies is formed with a notch portion, and each of the sliding pin mounting portions is formed separately The notch portion abuts against the rotation preventing surface of the sliding pin main body, and each of the rotation preventing surfaces is formed in parallel with the fastening rotation direction of the pin mounting bolt when the sliding pin main body is coupled to the pin mounting bolt. One side.