JP2005121051A - Floating type disk brake - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a floating type disk brake capable of easily moving a pad to an axial direction of a disk. <P>SOLUTION: A guide section 42 is provided on an edge of one end at a disk rotatable side of the pad 4 in the floating type disk brake 1, the guide section 42 is movably supported to the axial direction of the disk by a support section 20 formed on a mount 2, and the guide section 42 is also prevented from passing through to a radial direction of the disk. When the pad 4 moves to the disk rotating direction, an outer pressed force receiving section 43 receiving pressed force from a mound 2 side at an outer peripheral side rather than the guide section 42 and an inner pressed force receiving section 44 receiving pressed force from the mount 2 side at a disk center side rather than the guide section 42 are formed on the edge of one end at the disk rotatable side of the pad 4. Movement of the pad 4 to a disk rotating direction R is restrained with both pressed force receiving section 43 and 44 which are formed on the same edge of one end. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a floating disc brake. In particular, there is a guide part at the edge of the pad on the disk delivery side of the pad, and the guide part is supported so as to be movable in the disk axial direction by the support part formed on the mount, and prevents it from coming out in the disk radial direction. Related to floating disc brakes.

Conventionally, floating disc brakes having various configurations are known. For example, the disc brake according to Patent Document 1 has convex guide portions at both ends of the pad in the disc rotation direction. The guide portion is supported by a concave support portion formed on the mount so as to be movable in the disk axis direction.
A liner was provided between the pad and the mount. The liner was provided with an elastic arm for tilting the pad in the disk rotation direction. Therefore, the pad receives torque by the elastic arm, is pressed against the mount by the torque, and is prevented from rattling against the mount.
Furthermore, when the pad is slidably contacted with the disk, the pad receives a force in the disk rotating direction by the disk and simultaneously receives the force with a couple. Therefore, the pad also received the torque generated by the couple. Therefore, the pad is strongly pressed against the mount, and it is strongly prevented that the pad is rattled against the mount.
Japanese Patent No. 3303780

However, since the pad according to Patent Document 1 is strongly pressed against the mount by the elastic arm and couple as described above, when the pad is moved in the disk axial direction, the pad is not placed between the pad and the mount. A large dynamic friction force was generated. For this reason, it may be difficult to move the pad.
Accordingly, an object of the present invention is to provide a floating disc brake that can easily move a pad in the disc axial direction.

In order to solve the above-mentioned problems, the present invention is a floating disc brake having a configuration as described in each claim.
According to the first aspect of the present invention, the outer end of the pad that is pressed from the mount side at the outer peripheral side of the disk relative to the guide portion when the pad moves in the disk rotation direction is provided at one end edge of the pad on the disk delivery side. A receiving portion and an inner pressure receiving portion that receives pressure from the mount side closer to the center of the disc than the guide portion are formed. And the movement to the disk rotation direction of a pad is controlled by both the press receiving parts formed in these same edge.

That is, a guide portion and two pressure receiving portions are formed at one end edge of the pad on the disk delivery side. When the pad moves in the disk rotation direction, the two pressure receiving portions receive pressure from the mount side.
Therefore, a pad can receive two presses from the same edge side. And since these presses arise in the same edge side, they hardly produce a couple. Therefore, it is possible to suppress the torque from being generated in the pad. Therefore, the force with which the pad is pressed against the mount is smaller than that of the conventional structure that actively generates torque.
Thus, the dynamic friction force when the pad moves in the disk axial direction is smaller than that of the conventional structure. This makes it easier for the pad to move in the disk axis direction with respect to the mount. Further, since the movement of the pad in the disc rotation direction is regulated by the two press receiving portions, the movement in the disc rotation direction can be regulated stably.

According to the second aspect of the present invention, the guide portion formed on the pad and the support portion formed on the mount have an uneven relationship. The clearance formed between them is such that when the pad is tilted in the disc rotation direction, the outer press receiving portion and the inner press receiving portion hit the mount side before the guide portion and the support portion are twisted. It has a configuration that is large enough to allow
That is, when the pad is tilted in the disc rotation direction, the outer press receiving portion and the inner press receiving portion hit the mount side without the guide portion and the support portion being twisted. Therefore, when the pad receives a force in the disc rotation direction, the pad can surely receive the pressure from the outer pressure receiving portion and the inner pressure receiving portion.
Note that “twist” refers to a state in which the guide portion and the support portion cannot be relatively rotated by abutting at two or more points.

According to the third aspect of the present invention, the guide portion is on the disk rotation tangent at the centroid of the pad so that the pressure received by the outer pressure receiving portion is substantially equal to the pressure received by the inner pressure receiving portion. Is provided.
That is, when the pad moves in the disc rotation direction, the outer press receiving portion and the inner press receiving portion formed on one end edge of the pad receive substantially equal pressure from the mount side.
Therefore, when the pad is moved in the disk axial direction in this state, the dynamic friction force generated in the outer press receiving portion is substantially equal to the dynamic friction force generated in the inner press receiving portion. Therefore, the pad can move stably in the disk axis direction without tilting in the disk axis direction, that is, the thickness direction of the pad. Thus, the pad moves in a stable posture and easily moves in the disk axis direction.

  According to the present invention, the pad can easily move with respect to the mount.

(Embodiment 1)
An embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, the disc brake 1 is a floating disc brake and has a pair of pads 4, a mount 2, and a caliper 3.
The mount 2 is attached to the vehicle and supports one pad 4 on each of the vehicle inner side and the vehicle outer side of the disk D.

The caliper 3 is attached to the mount 2 via a slide pin 10. The slide pin 10 is slidably attached to the mount 2. Therefore, the caliper 3 is supported by the slide pin 10 so as to be movable in the disk axial direction with respect to the mount 2.
As shown in FIG. 3, the caliper 3 has a piston 30 on the inner side and a claw 31 on the outer side. The piston 30 presses the inner pad 4 against the disk D. Then, the caliper body moves to the inside of the vehicle by the reaction force, and the claw 31 moves together with the caliper body. Thereby, the claw 31 presses the pad 4 on the outer side against the disk D.

The pad 4 has a friction material 40 and a back plate 41 as shown in FIG.
The friction material 40 is pressed against the disk D and slidably contacts the disk D, thereby applying a frictional force to the disk D.
The back plate 41 is made of metal or resin, and is attached to the back surface of the friction material 40. The back plate 41 has guide portions 42 and press receiving portions 43 and 44 at both ends in the disk rotation direction, that is, at the edges of the disk delivery side (left side in FIG. 2) and the disk delivery side (right side in FIG. 2). have.

As shown in FIG. 2, the guide portion 42 protrudes in the disk rotation direction R from one end edge of the back plate 41. That is, it is formed in a convex shape. The guide portion 42 is inserted into the concave support portion 20 formed on the mount 2. Therefore, the guide portion 42 is prevented from coming off in the disk radial direction N by the support portion 20.
The support portion 20 extends in the disk axial direction (the thickness direction of the pad 4). Therefore, the guide part 42 is supported by the support part 20 so as to be movable in the disk axial direction.

Moreover, the guide part 42 is provided in the position corresponding to the centroid 45 of the pad 4 as shown in FIG. That is, it is provided on an orthogonal line orthogonal to a line connecting the centroid 45 of the pad 4 and the axis center of the disk D, in other words, on the disk rotation tangent 46 in the centroid of the pad 4.
The pad 4 is provided at a position where the outer peripheral edge of the pad 4 is along the outer peripheral edge of the disk D. The guide portion 42 is provided closer to the center side of the disk D than the outer peripheral edge of the disk D. On the other hand, the slide pin 10 is provided outside the outer peripheral edge of the disk D. Accordingly, the guide portion 42 and the slide pin 10 do not interfere with each other, and the slide pin 10 is provided at a desired position. For example, it is provided at a position where the distance between the two slide pins 10 becomes narrow.

As shown in FIG. 2, the outer pressure receiving portion 43 is provided on the outer peripheral side of the disc with respect to the guide portion 42. On the other hand, the inner pressure receiving portion 44 is provided closer to the center of the disc than the guide portion 42. The press receiving portions 43 and 44 are provided at positions sandwiching the guide portion 42, and are provided at positions adjacent to the guide portion 42.
The outer press receiving portion 43 and the inner press receiving portion 44 are formed on the same plane (on the same straight line). The plane is preferably a plane parallel to a line 47 connecting the centroid 45 and the center of the disk and perpendicular to the thickness direction of the pad 4.

The mount 2 has support portions 20 on both sides in the disk rotation direction R as shown in FIG. An outer support receiving surface 21 is provided on the outer peripheral side of the disc with respect to the support portion 20, and an inner support receiving surface 22 is provided on the disc center side with respect to the support portion 20.
The support receiving surfaces 21 and 22 have shapes that can be in contact with the press receiving portions 43 and 44, respectively. Therefore, when the pad 4 slides on the disk D and moves in the disk rotation direction R, the press receiving portions 43 and 44 on the disk delivery side come into contact with the support receiving surfaces 21 and 22, respectively. Receiving pressure from Thereby, the movement of the pad 4 in the disc rotation direction R is restricted.

The outer support receiving surface 21 and the inner support receiving surface 22 are formed on the same plane. On the other hand, as described above, the pressure receiving portions 43 and 44 on the pad 4 side are also formed on one plane. Accordingly, even when the pad 4 is displaced in the disk radial direction N with respect to the mount 2, the press receiving portions 43 and 44 can reliably contact the support receiving surfaces 21 and 22.
Moreover, these have a large contact area. Therefore, the movement of the pad 4 in the disc rotation direction R is stably regulated by the press receiving portions 43 and 44 and the support receiving surfaces 21 and 22.

The plane having the support receiving surfaces 21 and 22 is preferably a plane parallel to a line 47 connecting the centroid 45 and the center of the disk and perpendicular to the thickness direction of the pad 4.
Thereby, the support receiving surfaces 21 and 22 can stably regulate the movement of the pad 4 in the disk rotation direction R. That is, when the pad 4 comes into sliding contact with the disk D, the pad 4 moves in the direction of the disk rotation tangent 46 at the centroid 45. The support receiving surfaces 21 and 22 are orthogonal to the moving direction. Thus, the movement of the pad 4 in the disk rotation direction R can be restricted from the front in the movement direction. Therefore, it is possible to prevent the rotational force (torque) from being generated in the pad 4 when the movement of the pad 4 is restricted.

  Further, a clearance C is provided between the guide portion 42 and the support portion 20 as shown in FIG. When the pad 4 is tilted in the disk rotation direction R, the clearance C is formed such that the outer pressure receiving portion 43 and the inner pressure receiving portion 44 provided on the same surface before the guide portion 42 and the support portion 20 are twisted. Are large enough to allow them to hit the mount 2 side.

Therefore, when the pad 4 is tilted in the disk rotation direction R, the outer press receiving portion 43 and the inner press receiving portion 44 come into contact with the mount 2 side without the guide portion 42 and the support portion 20 being twisted. Therefore, when the pad 4 receives a force in the disk rotation direction R, the pad 4 can reliably receive the pressure from the outer pressure receiving portion 43 and the inner pressure receiving portion 44.
Note that “twisting” means that the guide portion 42 and the support portion 20 abut on each other at two or more points and cannot rotate relatively.

The disc brake 1 is configured as described above.
That is, a guide portion 42 and two press receiving portions 43 and 44 are formed on one end edge of the pad 4 on the disk delivery side (left side in FIG. 2). When the pad 4 moves in the disc rotation direction R, the two press receiving portions 43 and 44 are pressed from the mount 2 side.
Therefore, the pad 4 receives two pressings from the same edge side. And since these presses arise in the same edge side, they hardly produce a couple. Therefore, it is possible to suppress the torque from being generated in the pad 4. Therefore, the force with which the pad 4 is pressed against the mount 2 is smaller than that of the conventional structure that actively generates torque.

Thus, the dynamic friction force when the pad 4 moves in the disk axial direction is smaller than that of the conventional structure. Therefore, the pad 4 is easy to move in the disk axis direction with respect to the mount 2.
As a result, the pad 4 is easy to move in the thickness direction, and energy when pressed against the disk D is reduced. Further, the pad 4 tends to be separated from the disk D during non-braking. Therefore, when the disk D swings and the disk D comes into sliding contact with the pad 4, the pad 4 can easily move away from the disk D. Therefore, the frictional force generated between the pad 4 and the disk D, that is, the drag force is reduced. In addition, brake noise can be reduced.
Further, since the movement of the pad 4 in the disc rotation direction R is regulated by the two press receiving portions 43 and 44, the movement in the disc rotation direction can be regulated stably.

Further, as shown in FIG. 2, the guide portion is provided on the disk rotation tangent 46 at the centroid 45 of the pad 4. Therefore, the press received by the outer press receiving portion 43 and the press received by the inner press receiving portion 44 are substantially equal.
That is, when the pad 4 moves in the disc rotation direction R, the outer press receiving portion 43 and the inner press receiving portion 44 formed at one end edge of the pad 4 on the disc delivery side apply substantially equal pressure from the mount 2 side. receive.

  Accordingly, when the pad 4 is moved in the disk axial direction in this state, the dynamic friction force generated in the outer press receiving portion 43 and the dynamic friction force generated in the inner press receiving portion 44 are substantially equal. Therefore, the pad 4 can stably move in the disc axis direction without being inclined in the disc axis direction, that is, in the thickness direction of the pad 4. Thus, the pad 4 moves in a stable posture and easily moves in the disk axis direction.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and may be the following form.
(1) That is, the guide part and support part which concern on embodiment were formed in the convex shape in the guide part, and the support part was formed in the concave shape. However, the guide portion may be formed in a concave shape and the support portion may be formed in a convex shape.
(2) The pad according to the above embodiment has a guide portion and two press receiving portions at both end edges in the rotation direction of the disk. However, the pad may have a form having a guide portion and two press receiving portions only at one end edge on the disk delivery side when the vehicle moves forward.

It is a top view of a disc brake. FIG. 2 is a cross-sectional view taken along line AA in FIG. 1. FIG. 3 is a cross-sectional view taken along line BB in FIG. 1.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Disc brake 2 ... Mount 3 ... Caliper 4 ... Pad 20 ... Support part 21 ... Outer side support receiving surface 22 ... Inner side support receiving surface 42 ... Guide part 43 ... Outer side pressure receiving part 44 ... Inner side pressure receiving part 46 ... disk rotation tangent C ... clearance D ... disk

Claims (3)

The pad has a guide portion at one end edge on the disk delivery side, and the guide portion is supported by the support portion formed on the mount so as to be movable in the disk axial direction and is prevented from coming out in the disk radial direction. A floating disc brake,
An outer edge of the pad on the disk delivery side is provided with an outer pressure receiving portion that receives pressure from the mount side on the outer periphery side of the disk relative to the guide portion when the pad moves in the disk rotation direction. An inner pressure receiving portion that receives pressure from the mount side is formed closer to the center of the disc than the portion, and the pad is moved in the disc rotation direction by both of the pressure receiving portions formed on the same edge. The floating disc brake is characterized in that the structure is regulated. The floating disc brake according to claim 1,
The guide part formed on the pad and the support part formed on the mount are in a concave-convex relationship, and the clearance formed between them is such that when the pad is tilted in the disk rotation direction, A floating type disc having a size sufficient to allow the outer press receiving portion and the inner press receiving portion to contact the mount side before the support portion is twisted. brake. The floating disc brake according to claim 1 or 2,
The guide portion is provided on the disk rotation tangent at the centroid of the pad so that the pressure received by the outer pressure receiving portion is substantially equal to the pressure received by the inner pressure receiving portion. Type disc brake.

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