JP2004239331A - Disk brake device with parking brake mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To compatibly realize the operation feeling of a parking brake mechanism and the braking force, and to easily route cables to operate the parking brake mechanism. <P>SOLUTION: In a disk brake device with a parking brake mechanism, a lever shaft 22 having a lever 24 connected to an operation cable is rotatably provided on a caliper arm 15a of a brake caliper 15 to convert the rotation of the lever shaft 22 into the thrust of a piston 18 via a cam mechanism 35 and a relay piston 32, and friction pads 12 and 13 are pressed against a brake disk 11 by the thrust of the piston 18 to generate the braking power. The axis L2 of the lever shaft 22 is orthogonal to the axis L1 of the piston 18, and the cam mechanism 35 is constituted of a cam groove 22d formed in an outer circumferential surface of the lever shaft 22, a cam groove 32a formed in an end face of a relay member 32, and a roller 34 abutted on the cam grooves 22d and 32a. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a disc brake device with a parking brake mechanism having a parking brake function operated by a parking brake operator in addition to a normal hydraulic braking function.
[0002]
[Prior art]
Such a disk brake device with a parking brake mechanism is known, for example, from Patent Documents 1 and 2 described below.
[0003]
The one described in Patent Document 1 locks one end of a push rod in a notch formed in a cam shaft that rotates by a lever connected to a cable, and presses a piston with the other end of the push rod to apply a braking force. Is to be generated. Further, in the technique disclosed in Patent Document 2, a rotating disk rotated by a lever connected to a cable is opposed to a fixed disk fixed to a casing, and a plurality of balls are arranged between cam grooves formed on both disks. By rotating the rotating disk relative to the fixed disk, the rotating disk is moved in the axial direction, and the rotating disk presses the piston to generate a braking force.
[0004]
[Patent Document 1]
Japanese Patent Publication No. 6-50677 [Patent Document 2]
Japanese Patent No. 27399879 [0005]
[Problems to be solved by the invention]
By the way, in the structure described in Patent Document 1, since the axis of the camshaft is orthogonal to the axis of the piston, the cable can be freely changed by a design change only by rotating the axis of the camshaft around the axis of the piston. , And can be pulled out in any direction from the position to increase the degree of freedom of handling. However, since the piston is pressed by the other end of the push rod whose one end is locked in the notch formed in the camshaft, the relationship between the rotation angle of the camshaft and the stroke of the piston cannot be set arbitrarily, and the parking brake It is difficult to achieve both the operation feeling of the mechanism and the braking force.
[0006]
Further, in the structure described in Patent Document 2, the relationship between the rotation angle of the rotating disk and the stroke of the piston can be arbitrarily set only by changing the shape of the cam groove. And braking force can be compatible. However, since the axis of the rotating disk is coaxial with the axis of the piston, the cable can be pulled out only in a plane perpendicular to the axis, and there is a problem that the degree of freedom of the cable management is limited.
[0007]
SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances, and has as its object to make the operation feeling of a parking brake mechanism compatible with a braking force, and to facilitate the routing of a cable for operating the parking brake mechanism.
[0008]
[Means for Solving the Problems]
To achieve the above object, according to the first aspect of the present invention, a piston movably provided on a brake caliper is driven by hydraulic pressure, and the piston presses a friction pad against a brake disc to generate a braking force. A disk with a parking brake mechanism that generates a braking force by transmitting a rotation of the lever shaft to a piston via a cam mechanism, with a lever shaft rotatably provided on a brake caliper connected to a parking brake operator via a cable. In the brake device, the axis of the lever shaft is perpendicular to the axis of the piston, and the cam mechanism is formed on a cam groove formed on an outer peripheral surface of the lever shaft and a cam groove formed on an end surface of a relay member that moves in conjunction with the piston. And a disc brake device with a parking brake mechanism, comprising: It is.
[0009]
According to the above configuration, the axis of the lever shaft that is connected to the parking brake operator via a cable and rotates is orthogonal to the axis of the piston that presses the friction pad against the brake disc, and transmits the rotation of the lever shaft to the piston. Since the cam mechanism is composed of a cam groove formed on the outer peripheral surface of the lever shaft, a cam groove formed on an end surface of the relay member that moves in conjunction with the piston, and a rolling member that comes into contact with both the cam grooves, By merely changing the shape of the groove, the characteristics of the amount of movement of the relay member with respect to the rotation angle of the lever shaft can be arbitrarily adjusted, and both the operation feeling of the parking brake mechanism and the braking force can be compatible. In addition, with a slight design change that simply rotates the axis of the lever shaft around the axis of the piston, the mounting position and pull-out direction of the cable that drives the lever shaft can be arbitrarily changed to increase the degree of freedom in handling the cable. Can be.
[0010]
The first and second friction pads 12, 13 of the embodiment correspond to the friction pad of the present invention, the relay piston 32 of the embodiment corresponds to the relay member of the present invention, and the roller 34 of the embodiment corresponds to the rolling of the present invention. It corresponds to the member.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described based on examples of the present invention shown in the accompanying drawings.
[0012]
1 to 4 show an embodiment of the present invention. FIG. 1 is a cross-sectional view of a disc brake device, FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1, and FIG. FIG. 4 is an explanatory view of the operation when the parking brake is operated.
[0013]
As shown in FIG. 1, the disc brake device with a parking brake mechanism has a first friction pad 12 and a second friction pad 13 arranged on both sides of a brake disc 11 that rotates together with the wheels. The second friction pads 12, 13 are composed of linings 12a, 13a which can be brought into contact with the brake disc 11, and back plates 12b, 13b fixed to the back surfaces of the linings 12a, 13a. 12b and 13b are supported by a bracket 14 fixed to the vehicle body so as to be movable in the direction of an axis L1 of a piston 18 described later. A brake caliper 15 straddling the first and second friction pads 12 and 13 is supported by the bracket 14 so as to be movable in the direction of the axis L1.
[0014]
The brake caliper 15 includes a first sandwiching arm 15a facing the back plate 12b of the first friction pad 12, and a second sandwiching arm 15b facing the back plate 13b of the second friction pad 13. The second sandwiching arms 15a and 15b are integrally connected by a bridging portion 15c passing through the outer peripheral portion of the brake disc 11. A cylinder 16 is formed on the first pinching arm 15a so as to be located on the axis L1, and a cup-shaped piston 18 is slidably fitted to the cylinder 16 via a seal member 17. The front end of the piston 18 which is opposed to the back plate 12b of the first friction pad 12 is connected to the open end of the cylinder 16 by a bellows-shaped dust cover 19, and the hydraulic chamber 20 which faces the recess 16a of the cylinder 16. Is connected to a master cylinder (not shown) via a port 15d.
[0015]
2, a concave portion 15 e having a circular cross section with an open end is formed in the first pinching arm 15 a of the brake caliper 15, and has a cylindrical shape having a bottom through a bush 21. The lever shaft 22 is housed rotatably around an axis L2 orthogonal to the axis L1. One end of the lever shaft 22 is exposed to the outside from the opening of the concave portion 15e of the first pinching arm 15a via the sealing member 23. Fixed. A return spring 26 made of a torsion coil spring is housed in the hollow portion 22 b of the lever shaft 22, and one end thereof is locked in a locking hole 22 c formed in the bottom wall of the hollow portion 22 b of the lever shaft 22. At the same time, the other end is locked by a locking hole 15f formed in the bottom wall of the concave portion 15e of the first pinching arm 15a. A preload is applied to the return spring 26, and the lever 24 is urged in the direction of arrow A in FIG.
[0016]
A stepped relay piston 32 is slidably fitted via a seal member 33 to a stepped relay cylinder 31 formed coaxially with the cylinder 16 of the first pinching arm 15a. Cam grooves 32a and 22d are formed on the right end of the relay piston 32 (far side from the brake disk 11) and the outer peripheral surface of the lever shaft 22 opposed thereto, and the axis of the lever shaft 22 is provided between the cam grooves 32a and 22d. A roller 34 parallel to L2 is arranged. The cam grooves 32a and 22d and the roller 34 constitute a cam mechanism 35. Since the relay piston 32 is connected to the lever shaft 22 via the cam mechanism 35, rotation around the axis L1 is regulated without requiring a special rotation preventing mechanism.
[0017]
As shown in FIG. 3A, the lever shaft 22 is urged in the direction of the arrow (counterclockwise) by the elastic force of the return spring 26, but the cam groove 22d of the lever shaft 22 is locked in an arc shape. When the roller 34 is engaged with the surface a and the arcuate locking surface c of the cam groove 32a of the relay piston 32, the rotation of the lever shaft 22 in the direction of the arrow is restricted, and the lever shaft 22 stops at the initial position.
[0018]
Returning to FIG. 1, a fixed clutch body 36 slidably fitted to the relay cylinder 31 is integrally formed on the left end (the side close to the brake disk 11) of the relay piston 32, and a cone-shaped left end surface thereof is provided. A cylinder hole 36b opens through the clutch surface 36a. A movable clutch body 38 and a small piston 39 are integrally formed at the right end of an adjustment bolt 37 disposed on the axis L1, and the cone-shaped clutch surface 38a of the movable clutch body 38 is engaged with the clutch surface 36a of the fixed clutch body 36. , The small piston 39 is fitted into the cylinder hole 36b of the fixed clutch body 36 via the seal member 40. In order to press the clutch surface 38a of the movable clutch body 38 against the clutch surface 36a of the fixed clutch body 36, the other end of the clutch spring 43, which has one end supported on the inner surface of the cylinder 16 via the clip 41 and the retainer 42, is connected to the ball bearing 44. And comes into contact with the movable clutch body 38 through the contact.
[0019]
The adjusting bolt 37 and the adjusting nut 45 fitted on the outer periphery of the adjusting bolt 37 are meshed by a fast screw 46 having a plurality of threads and a thread groove having a coarse pitch. The other end of the over-adjustment preventing screw 49 whose one end is supported by the concave portion 18a of the piston 18 via the clip 47 and the retainer 48 so that the end portion 45a of the adjusting nut 45 abuts against the bottom wall of the concave portion 18a of the piston 18 is adjusted. It contacts the step 45b of the nut 45. The adjustment nut 45 and the piston 18 cannot rotate relative to each other due to the uneven engagement of their abutting portions, and the back plate 12b of the first friction pad 12 and the piston 18 cannot rotate relative to each other due to the uneven engagement. is there.
[0020]
Next, the normal braking action by hydraulic pressure of the disk brake device with the parking brake mechanism having the above configuration will be described.
[0021]
When hydraulic pressure is supplied to the hydraulic chamber 20 through the port 15d connected to the master cylinder, the piston 18 receiving the hydraulic pressure moves inside the cylinder 16 to the left in FIG. When the friction pad 12 is pressed against one side surface of the brake disc 11, the brake caliper 15 moves to the right in the direction opposite to the moving direction of the piston 18 by the reaction, and the second pinching arm 15 b causes the second friction pad 13 to move the second friction pad 13 to the brake disc 11. Press it against the other side. As a result, the first and second friction pads 12, 13 abut against both surfaces of the brake disc 11 with an equal surface pressure, and a braking force for braking the wheels is generated.
[0022]
During the braking, the hydraulic pressure supplied to the hydraulic chamber 20 does not generate a load on the adjusting nut 45 in the direction of the axis L1, but the movable clutch body 38 integrated with the adjusting bolt 37 meshing with the adjusting nut 45 has a small piston. A rightward load having a magnitude obtained by multiplying the sectional area 39 by the hydraulic pressure is generated, and a frictional engagement force corresponding to the load acts between the clutch surface 38a of the movable clutch body 38 and the clutch 36a of the fixed clutch body 36.
[0023]
In the normal braking state, the hydraulic pressure acting on the hydraulic chamber 20 is relatively low, so that the frictional engagement force acting between the clutch surfaces 38a, 36a of the movable clutch body 38 and the fixed clutch body 36 is relatively small. Therefore, if the piston 18 advances as the linings 12a, 13a of the first and second friction pads 12, 13 advance, the adjusting nut 45 advances with the piston 18 by the elastic force of the over-adjustment preventing screw 49. Then, the movable clutch body 38 integral with the adjustment bolt 37 meshing with the adjustment nut 45 is separated from the fixed clutch body 36 against the hydraulic pressure acting on the hydraulic chamber 20 and the elastic force of the clutch spring 43.
[0024]
When the clutch surface 38a of the movable clutch body 38 separates from the clutch surface 36a of the fixed clutch body 36, the adjustment bolt 37 urged rightward by the hydraulic pressure acting on the movable clutch body 38 and the elastic force of the clutch spring 43 rotates. It moves to the right while rotating relative to the impossible adjustment nut 45 with the fast screw 46, and the clutch surface 38 a of the movable clutch body 38 is engaged again with the clutch surface 36 a of the fixed clutch body 36. At this time, the operation of the ball bearing 44 disposed between the clutch spring 43 allows the movable clutch body 38 to rotate smoothly.
[0025]
In this manner, as the wear of the linings 12a, 13a of the first and second friction pads 12, 13 advances, the adjustment nut 45 moves to the left relative to the adjustment bolt 37 so as to compensate for the wear. Therefore, the clearance between the linings 12a, 13a of the first and second friction pads 12, 13 and the brake disc 11 during non-braking can be automatically kept constant.
[0026]
When the hydraulic pressure acting on the hydraulic chamber 20 is reduced in order to release the braking, the piston 18 retreats due to the deformation restoring force of the seal member 17, but the retreating force is then applied to the movable clutch body 38 via the adjustment nut 45 and the adjustment bolt 37. Since the clutch surface 38a is engaged with the clutch surface 36a of the fixed clutch body 36, the relative rotation of the adjustment bolt 37 with respect to the adjustment nut 45 is restricted. Therefore, the piston 18 can retreat only by the stroke of the backlash between the adjustment nut 45 and the adjustment bolt 37, and the space between the first and second friction pads 12 and 13 and the brake disc 11 The appropriate clearance is given.
[0027]
When strong braking is performed, the automatic adjustment is performed until the hydraulic pressure in the hydraulic chamber 20 rises to a predetermined value that deforms the brake caliper 15, and when the hydraulic pressure exceeds the predetermined value, Since the clutch body 38 is strongly pressed against the fixed clutch body 36 by hydraulic pressure, the clutch surfaces 38a, 36a are connected to each other so that they cannot rotate relative to each other. As a result, the adjusting bolt 37 is restrained from rotating and the originally non-rotatable adjusting nut 45 stays on the adjusting bolt 37. Therefore, when the piston 18 further advances due to the elastic deformation of the brake caliper 15 by hydraulic pressure, overadjustment is prevented. While compressing the screw 49, only the piston 18 moves forward, leaving the adjustment nut 45. In this way, over-adjustment between the adjustment nut 45 and the adjustment bolt 37 when strong braking is performed is prevented.
[0028]
Next, the function of the disc brake device with a parking brake mechanism as a parking brake will be described.
[0029]
When the lever 24 connected via a cable to the parking brake pedal or the parking brake lever operated by the driver rotates in the direction of arrow B in FIG. 1 against the elasticity of the return spring 26, as shown in FIG. When the roller 34 pressed against the cam surface b of the cam groove 22d of the lever shaft 22 that rotates integrally with the lever 24 presses the cam surface d of the cam groove 32a of the relay piston 32, the relay piston 32 moves in the axis L direction. Move to the left of. As a result, as shown in FIG. 4, the movement of the relay piston 32 causes the piston 18 to move to the left through the fixed clutch body 36, the movable clutch body 38, the adjustment bolt 37 and the adjustment nut 45, and the above-described case of the hydraulic braking described above. Similarly, the linings 12a and 13a of the first and second friction pads 12 and 13 are pressed against both surfaces of the brake disc 11 to generate a braking force.
[0030]
In the course of this braking, the clutch surfaces 36a and 38a of the fixed clutch body 36 and the movable clutch body 38 are engaged by the pressing force of the cam mechanism 35 so that they cannot rotate relatively, so that the relative rotation of the adjustment bolt 37 and the adjustment nut 45 is restricted. You. Therefore, when the disc brake device with the parking brake mechanism functions as a parking brake, the above-described automatic adjustment is not performed.
[0031]
When the cable is loosened to release the parking brake, the lever 24 returns in the direction of the arrow a in FIG. 1 by the elastic force of the return spring 26, and the cam groove 22d of the lever shaft 22 does not press the roller 34. The movable clutch body 38 and the fixed clutch body 36 move to the right due to the resiliency. As a result, the adjustment bolt 37 integrated with the movable clutch body 38 and the adjustment nut 45 meshing with the movable clutch body 38 move to the right, so that the piston 18 connected to the adjustment nut 45 via the over-adjustment prevention screw 49 moves to the right. Then the parking brake is released.
[0032]
Next, the operation of the cam mechanism 35 provided between the lever shaft 22 and the relay piston 32 will be described in detail. FIG. 3A shows a state in which the lever shaft 22 is at the initial position (rotation angle = 0 °), and FIGS. 3B, 3C, and 3D show the state in which the lever shaft 22 is 10 degrees from the initial position. , 20 and 30 degrees.
[0033]
When the lever shaft 22 rotates from 0 ° to 10 °, the stroke in which the relay piston 32 moves in the direction of the axis L is 0.8 mm, and the boost ratio is small because the stroke with respect to the rotation angle is large. When the lever shaft 22 rotates from 10 ° to 20 ° and when the lever shaft 22 rotates from 20 ° to 30 °, the stroke of the relay piston 32 moving in the direction of the axis L is 0.6 mm, Since the stroke with respect to the rotation angle is small, the boost ratio becomes large. That is, in this embodiment, the stroke of the relay piston 32 is set large in the first half of the rotation of the lever shaft 22 in order to minimize the effect of the invalid stroke of the piston 18, and in the middle and late stages of the rotation of the lever shaft 22. In order to obtain a sufficient braking force, the boosting ratio is set large to increase the thrust of the relay piston 32.
[0034]
Thus, by changing the shape of the cam groove 22d of the lever shaft 22 and the shape of the cam groove 32a of the relay piston 32, the characteristic of the amount of movement of the relay piston 32 with respect to the rotation angle of the lever shaft 22 can be arbitrarily set. Thus, it is possible to achieve both an improvement in the operation feeling of the parking brake pedal and the parking brake lever and a good use of the parking brake.
[0035]
Further, according to the present embodiment, since the lever 24 is attached at an arbitrary angle around the axis L2 of the lever shaft 22, it is easy to route the cable connecting the lever 24 to the parking brake pedal or the parking brake lever. Further, in FIG. 1, the axis L2 of the lever shaft 22 is arranged in a direction orthogonal to the plane of the paper, but only by making a slight design change to rotate the axis L2 to an arbitrary position around the axis L1 of the piston 18, Since the lever 24 can be moved to any position on the front side or the back side of the paper surface of FIG. 1, the degree of freedom of the cable management can be further increased.
[0036]
Further, a return spring 26 for urging the lever shaft 22 to the initial position is housed inside the lever shaft 22 without being exposed to the outside of the first holding arm 15a. Is sealed by the seal member 23, so that water and dust can be prevented from adhering to the return spring 26 and protected from corrosion. As a result, it is not necessary to perform a special rust preventive treatment on the return spring 26 or use a material that does not easily rust, such as stainless steel, thereby contributing to cost reduction. In addition, since it is not necessary to use a thick wire in order to increase the durability of the return spring 26, the return spring 26 can be easily stored in the narrow internal space of the lever shaft 22. Further, since it is not necessary to provide a locking portion for locking the end of the return spring 26 on the lever 24, the shape of the lever 24 can be simplified.
[0037]
The embodiments of the present invention have been described above. However, various design changes can be made in the present invention without departing from the gist thereof.
[0038]
For example, in the embodiment, the roller 34 is used for the cam mechanism 35, but a ball can be used instead of the roller 34.
[0039]
【The invention's effect】
As described above, according to the first aspect of the invention, the axis of the lever shaft that is connected to the parking brake operation member by a cable and rotates is orthogonal to the axis of the piston that presses the friction pad against the brake disc. A cam mechanism for transmitting the rotation of the lever shaft to the piston, a cam groove formed on the outer peripheral surface of the lever shaft, a cam groove formed on an end surface of the relay member that moves in conjunction with the piston, and the two cam grooves. Since it is composed of rolling members in contact with each other, it is possible to arbitrarily adjust the characteristics of the amount of movement of the relay member with respect to the rotation angle of the lever shaft simply by changing the shape of the cam groove, and the operating feeling and braking force of the parking brake mechanism And can be compatible. In addition, with a slight design change that simply rotates the axis of the lever shaft around the axis of the piston, the mounting position and pull-out direction of the cable that drives the lever shaft can be arbitrarily changed to increase the degree of freedom in handling the cable. Can be.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a disc brake device. FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1. FIG. 3 is an explanatory diagram of an operation of a cam mechanism. FIG. Description】
11 Brake disc 12 First friction pad (friction pad)
13 2nd friction pad (friction pad)
15 Brake caliper 18 Piston 22 Lever shaft 22d Cam groove 32 Relay piston (Relay member)
32a Cam groove 34 Roller (rolling member)
35 Cam mechanism L1 Piston axis L2 Lever axis

Claims (1)

A piston (18) movably provided on the brake caliper (15) is hydraulically driven, and the piston (18) presses the friction pads (12, 13) against the brake disc (11) to generate a braking force. A lever shaft (22) connected to the parking brake operator via a cable is rotatably provided on the brake caliper (15), and the rotation of the lever shaft (22) is transmitted to the piston (18) via the cam mechanism (35). In a disk brake device with a parking brake mechanism that generates a braking force by
The axis (L2) of the lever shaft (22) is orthogonal to the axis (L1) of the piston (18), and the cam mechanism (35) is formed with a cam groove (22d) formed on the outer peripheral surface of the lever shaft (22). A cam groove (32a) formed on an end face of a relay member (32) that moves in conjunction with the piston (18), and a rolling member (34) that comes into contact with the cam grooves (22d, 32a). A disc brake device with a parking brake mechanism.

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