JP6757592B2 - Disc brake - Google Patents

Description

The present invention relates to a disc brake.

Some pad springs are provided with a projecting piece portion that is bent inward in the radial direction of the disc at the radial urging portion of the pad spring (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2008-298198

In disc brakes, if the spring load of the pad spring is set in the direction that suppresses the drag of the friction pad, abnormal noise is likely to occur, and if the spring load of the pad spring is set in the direction that suppresses the generation of abnormal noise, the friction pad is dragged. Is likely to occur.

An object of the present invention is to provide a disc brake capable of suppressing the dragging of a friction pad and the generation of abnormal noise.

In order to achieve the above object, in the present invention, the pad spring is arranged in contact with the pad guide, and the base plate portion having a protruding portion protruding outward in the disc axial direction from the pad guide and the base end side are It is folded back inward in the disc axial direction from the protruding portion, and the tip side extends between the base plate portion and the friction pad to the extending portion on which the friction pad slides and the moving position of the friction pad. Correspondingly, it has a protrusion that changes the fulcrum position of the extension with respect to the base plate to bring the extension and the base plate into contact with each other, and the protrusion is the base plate. Is provided so as to project outward in the radial direction of the disc, and a position where the extension portion and the base plate portion are brought into contact with each other in a state where the friction pad is located closer to the disc than the protrusion. The protrusion and the linear recess provided in the extension along the extending direction of the extension come into contact with each other to bring the extension and the base plate into contact with each other. Is in contact with each other.

According to the present invention, it is possible to suppress the dragging of the friction pad and the generation of abnormal noise.

The plan view which shows the disc brake which concerns on one Embodiment of this invention. The front view which shows the disc brake which concerns on one Embodiment of this invention. A side sectional view showing a disc brake according to an embodiment of the present invention. The rear view excluding the caliper which shows the disc brake which concerns on one Embodiment of this invention. The perspective view which excluded the caliper which shows the disc brake which concerns on one Embodiment of this invention. The front view which shows the pad spring of the disc brake which concerns on one Embodiment of this invention. The side view which shows the pad spring of the disc brake which concerns on one Embodiment of this invention. The perspective view which shows the pad spring of the disc brake which concerns on one Embodiment of this invention. A partially enlarged front view showing a pad spring of a disc brake according to an embodiment of the present invention. A partially enlarged normal cross-sectional view showing a pad spring and a pad of a disc brake according to an embodiment of the present invention. A partially enlarged normal cross-sectional view showing a pad spring and a pad of a disc brake according to an embodiment of the present invention. A partially enlarged front view showing a modified example of a pad spring of a disc brake according to an embodiment of the present invention.

An embodiment according to the present invention will be described with reference to the drawings. The disc brake 1 of the present embodiment shown in FIGS. 1 to 3 is attached to a vehicle such as an automobile, and a frictional resistance is applied to a disc 10 rotating together with a wheel (not shown) to be braked to rotate the wheel. Is to brake. In the following, the axial direction of the disc 10 is the disc axial direction, the rotation direction of the disc 10 is the disc rotation direction, and the radial direction of the disc 10 is the direction of the line passing through the center of the disc rotation direction of the disc brake 1. Referred to as the radial direction. Further, in the disc radial direction, the direction away from the center of the disc 10 is referred to as the outer side in the disc radial direction, and the direction closer to the center of the disc 10 is referred to as the inner side in the disc radial direction.

As shown in FIG. 1, the disc brake 1 includes the above-mentioned disc 10, a mounting member 11 that straddles the outer peripheral side of the disc 10 in the disc axial direction and is attached to a non-rotating portion of the vehicle, and the disc 10 in the axial direction. A pair of friction pads 12 and 12 shown in FIG. 3 which are arranged facing each other on both sides and supported by the mounting member 11 and a pair of friction pads 12 and 12 slidably provided on the mounting member 11 are provided on both sides of the disc 10. It is provided with a caliper 14 that presses against. The caliper 14 has a piston 13 that presses one of the pair of friction pads 12, 12. As shown in FIGS. 2, 4, and 5, the disc brake 1 is attached to a part of the mounting member 11, and a pair of pad springs 16 for urging the friction pads 12 and 12 outward in the disc radial direction. , 16 are provided.

The mounting member 11 is an integrally molded product having a mirror-symmetrical shape, and has a pair of disc path portions 20 and 20, a mounting base portion 21, and an outer beam portion 22 as shown in FIG.

The pair of disk path portions 20, 20 are separated from each other. The mounting base portion 21 connects a pair of disc path portions 20, 20 on one side. As shown in FIG. 2, the outer beam portion 22 connects the pair of disc path portions 20, 20 on the other side. A pair of mounting holes 24, 24 are formed in the mounting base portion 21 at both end positions on the pair of disc path portions 20, 20 side, and the mounting member 11 is a fastening member inserted into these mounting holes 24, 24. Will be attached to the non-rotating part of the vehicle.

In the state of being attached to the non-rotating portion of the vehicle, as shown in FIG. 1, the pair of disc path portions 20, 20 straddle the outer peripheral side of the disc 10 in the disc axial direction, and each other. They are arranged apart from each other in the disc rotation direction. Further, in a state where the mounting member 11 is mounted on the non-rotating portion of the vehicle, as shown in FIG. 2, the outer beam portion 22 is located inside the pair of disc path portions 20 and 20 in the disc radial direction in the disc rotating direction. As shown in FIG. 4, the mounting base portion 21 extends in the disc rotation direction at the inner position of the pair of disc path portions 20 and 20 in the disc radial direction and connects them. To do. As shown in FIG. 3, the mounting base portion 21 and the outer beam portion 22 are arranged on both sides in the axial direction with respect to the disc 10. Here, the mounting base portion 21 is arranged inside the disc 10 in the vehicle width direction (hereinafter, referred to as the inner side). Further, the outer beam portion 22 is arranged outside the disc 10 in the vehicle width direction (hereinafter, referred to as the outer side).

As shown in FIGS. 4 and 5, the pair of disc path portions 20 and 20 have pad guides 26A extending in the disc radial direction on the inner side to movably support the friction pad 12 on the inner side. As shown in FIG. 4, recesses 27A and 27A are formed on the opposite sides of the pad guides 26A and 26A. The recess 27A formed in one pad guide 26A is recessed in the direction away from the other pad guide 26A, and the recess 27A formed in the other pad guide 26A is recessed in the direction away from the one pad guide 26A. It is dented. That is, the recesses 27A and 27A on the inner side are recessed in a direction away from each other along the disc rotation direction.

As shown in FIG. 2, the pair of disc path portions 20 and 20 also have pad guides 26B extending in the disc radial direction to movably support the friction pad 12 on the outer side. Recesses 27B and 27B are formed on the opposite sides of the pad guides 26B and 26B. The recess 27B formed in one pad guide 26B is recessed in the direction away from the other pad guide 26B, and the recess 27B formed in the other pad guide 26B is recessed in the direction away from the one pad guide 26B. It is dented. That is, the recesses 27B and 27B on the outer side are recessed in a direction away from each other along the disc rotation direction.

The inner recess 27A and the outer recess 27B on the same side in the disc rotation direction have the same shape, and are aligned in the disc rotation direction and the disc radial direction. The inner recess 27A and the outer recess 27B on the same opposite side of the disc rotation direction have the same shape, and are aligned in the disc rotation direction and the disc radial direction.

As shown in FIG. 5, the pair of disc path portions 20 and 20 have a connecting portion 28 for connecting the pad guide 26A on the inner side and the pad guide 26B on the outer side, respectively. The connecting portion 28 of the disc path portion 20 connects the outer ends of the inner side pad guide 26A and the outer side pad guide 26B on one side in the disc rotation direction in the disc radial direction. The connecting portion 28 of the other disc path portion 20 connects the outer ends of the inner side pad guide 26A and the outer side pad guide 26B on the other side in the disc rotation direction in the disc radial direction. As shown in FIG. 1, the connecting portions 28, 28 are arranged so as to overlap the disc 10 and the disc axial position and to be radially outside the disc 10.

As shown in FIGS. 4 and 5, a pair of fitting holes 31 and 31 are formed in the pair of disc path portions 20 and 20 at the outer end portions in the disc radial direction from the inner side to the middle position on the outer side. ing. One fitting hole 31 penetrates one connecting portion 28, and the other fitting hole 31 penetrates the other connecting portion 28.

The pair of pad springs 16 and 16 are common parts having a common configuration. The pad springs 16 shown in FIGS. 6 to 8 are formed by press forming from a single plate material having a constant thickness, and have a mirror-symmetrical shape as shown in FIGS. 6 and 8. The pad spring 16 has a pair of pad support portions 41, 41 and a connecting portion 42 connecting the pair of pad support portions 41, 41.

The pair of pad support portions 41, 41 are perpendicular to the outer end plate portion 51 on the connection portion 42 side and the end portion of the outer end plate portion 51 opposite to the connection portion 42, respectively. An intermediate extending from the outer support plate portion 52 extending from the end opposite to the outer end plate portion 51 of the outer support plate portion 52 in a direction perpendicular to the outer support plate portion 52 and away from the outer end plate portion 51. It has a plate portion 53 and a base plate portion 54 extending from an end portion of the intermediate plate portion 53 opposite to the outer support plate portion 52 to the same side as the outer support plate portion 52 substantially perpendicular to the intermediate plate portion 53. are doing. In each of the pair of pad support portions 41 and 41, the continuous outer support plate portion 52, the intermediate plate portion 53, and the base plate portion 54 are connected in a concave shape as a whole to form a concave portion 55. The base plate portion 54 has a protruding portion 54a projecting to the opposite side of the other pad supporting portion 41.

Each of the pair of pad support portions 41, 41 is folded back toward the outer support plate portion 52 side from the end portion of the protrusion 54a of the base plate portion 54 opposite to the other pad support portion 41, and the base plate portion 54 It has an extension plate portion (extension portion) 56 arranged on the outer support plate portion 52 side of the above.

Here, one pad support portion 41 when the pad spring 16 is in the natural state as shown in FIGS. 6 to 9 will be described. The extension plate portion 56 of one pad support portion 41 is folded back in an arc shape from the end portion of the protrusion portion 54a of the base plate portion 54 opposite to the other pad support portion 41 to the outer support plate portion 52 side. The folded-back portion 57 and the end portion of the folded-back portion 57 opposite to the base plate portion 54 are inclined in the direction of the other pad support portion 41 so as to be away from the base plate portion 54 toward the other pad support portion 41. It has an inner support plate portion 58 that extends linearly.

In the inner support plate portion 58, a rib 61 that bulges toward the outer support plate portion 52 extends from a position near the folded portion 57 to an end portion opposite to the folded portion 57, and is formed in the center in the width direction. There is. The rib 61 is also formed by press molding. As a result, the inner support plate portion 58 has a linear recess 62 shown in FIG. 8 extending from a position near the folded portion 57 to an end opposite to the folded portion 57 on the base plate portion 54 side at the position of the rib 61. Is formed. The rib 61 and the linear recess 62 have an arcuate cross section orthogonal to the extending direction.

The base plate portion 54 is formed with a protrusion 63 that protrudes toward the outer support plate portion 52 at a position near the folded portion 57. The protruding portion 63 has a spherical shape (a dome shape forming a circle when viewed from the front in the protruding direction). When the extension plate portion 56 is elastically deformed toward the base plate portion 54, the protrusion portion 63 partially enters the linear recess 62 and comes into contact with the extension plate portion 56. At this time, the base plate portion 54 does not come into contact with the extension plate portion 56 except for the protrusion 63. The protrusion 63 is also formed by press molding. The protrusion 63 is arranged on the base plate 54 so as to abut the central portion of the extension plate 56 in the width direction.

Similarly, the extension plate portion 56 of the other pad support portion 41 also has a folded-back portion 57 and an inner support plate portion 58 including a rib 61 and a linear recess 62, and the other pad support portion 41 of the other pad support portion 41. A similar protrusion 63 is also provided on the base plate portion 54.

The connection portion 42 is positioned between the connection plate portion 66 that connects the outer end plate portions 51, 51 of the pair of pad support portions 41, 41 and the outer end plate portions 51, 51 of the connection plate portion 66. It has a part 67.

As shown in FIGS. 2, 4 and 5, one pad spring 16 is attached to one disc path portion 20 on one side in the disc rotation direction. At that time, one pad spring 16 has a concave portion of one pad support portion 41 as shown in FIG. 4 in a state where the connection portion 42 is arranged outside the pair of pad support portions 41, 41 in the disc radial direction. The 55 is fitted into the recess 27A of the pad guide 26A on the inner side, and the concave portion 55 of the other pad support portion 41 is fitted into the recess 27B of the pad guide 26B on the outer side as shown in FIG. As shown in FIG. 5, the positioning portion 67 is fitted between the pad guides 26A and 26B. As a result, the pad spring 16 on one side is in a state in which the pair of pad support portions 41, 41 are arranged on both side surfaces of the disc 10.

When the positioning portion 67 is fitted between the pad guides 26A and 26B, the pad spring 16 is provided on the mounting member 11 with the movement in the disc axial direction restricted. As a result, the pad spring 16 on one side is restricted from moving in the disc axial direction with respect to the disc 10. In this way, with the one pad spring 16 attached to the one disc path portion 20, the concave portions 55 and 55 fitted into the recesses 27A and 27B as shown in FIGS. 2 and 4 are in the disc rotation direction. It has a dented shape. In this state, the base plate portion 54 of the concave portion 55 that fits into the concave portion 27A is arranged inside the concave portion 55 in the disc radial direction and comes into contact with the concave portion 27A, and the protruding portion 54a is in contact with the concave portion 27A. As shown in the above, the pad guide 26A projects outward in the disc axial direction. Similarly, the base plate portion 54 of the concave portion 55 that fits into the concave portion 27B is arranged inside the concave portion 55 in the disc radial direction and comes into contact with the concave portion 27B, and the protruding portion 54a is from the pad guide 26B. Also protrudes outward in the disc axial direction.

In the one pad spring 16, the one extending plate portion 56 extending from the concave portion 55 fitted in the concave portion 27A has a disc shaft whose base end side is from the protruding portion 54a of the base plate portion 54 of the concave portion 55. It is folded back inward in the direction, and its tip side is arranged outside in the disc radial direction of the base plate portion 54 of the concave portion 55. The base plate portion 54 is provided with a protrusion 63 that projects outward in the radial direction of the disc. Similarly, one of the extending plate portions 56 extending from the concave portion 55 fitted in the concave portion 27B has its base end side folded back inward in the disc axial direction from the protruding portion 54a of the base plate portion 54 of the concave portion 55. The tip end side thereof is arranged outside the disc radial direction of the base plate portion 54 of the concave portion 55. The base plate portion 54 is provided with a protrusion 63 that projects outward in the radial direction of the disc.

The other pad spring 16 is attached to the other disc path portion 20 on the other side in the disc rotation direction in the same manner as described above. At that time, the other pad spring 16 fits the concave portion 55 of the one pad support portion 41 into the concave portion 27A of the pad guide 26A on the inner side, and the concave portion 55 of the other pad support portion 41 is attached to the outer. It is fitted into the recess 27B of the pad guide 26B on the side, and the positioning portion 67 is fitted between the pad guides 26A and 26B. In this way, the other pad spring 16 has a shape in which the concave portions 55 and 55 fitted in the recesses 27A and 27B are recessed in the disc rotation direction while being attached to the other disc path portion 20. In this state, the base plate portion 54 of the concave portion 55 that fits into the concave portion 27A is arranged inside the concave portion 55 in the disc radial direction and comes into contact with the concave portion 27A, and the protruding portion 54a abuts on the pad guide 26A. It protrudes outward in the disc axial direction. Similarly, the base plate portion 54 of the concave portion 55 that fits into the concave portion 27B is arranged inside the concave portion 55 in the disc radial direction and comes into contact with the concave portion 27B, and the protruding portion 54a is from the pad guide 26B. Also protrudes outward in the disc axial direction.

In the other pad spring 16, one of the extending plate portions 56 extending from the concave portion 55 fitted in the concave portion 27A has a disc shaft whose base end side is from the protruding portion 54a of the base plate portion 54 of the concave portion 55. It is folded back inward in the direction, and its tip side is arranged outside in the disc radial direction of the base plate portion 54 of the concave portion 55. The base plate portion 54 is provided with a protrusion 63 that projects outward in the radial direction of the disc. Similarly, one of the extending plate portions 56 extending from the concave portion 55 fitted in the concave portion 27B has its base end side folded back inward in the disc axial direction from the protruding portion 54a of the base plate portion 54 of the concave portion 55. The tip end side thereof is arranged outside the disc radial direction of the base plate portion 54 of the concave portion 55. The base plate portion 54 is provided with a protrusion 63 that projects outward in the radial direction of the disc.

Then, as shown in FIG. 4, the friction pads 12 on the inner side are recessed in opposite directions of the pair of pad springs 16 and 16 and the friction pads 12 on the inner side are fitted in the recesses 27A and 27A on the inner side in the disc axial direction. It is supported so that it can be moved to. As shown in FIG. 2, the friction pads 12 on the outer side are recessed in opposite directions of the pair of pad springs 16 and 16 and the friction pads 12 on the outer side are fitted in the recesses 27B and 27B on the outer side in the disc axial direction. It is supported so that it can be moved.

The friction pad 12 on the inner side and the friction pad 12 on the outer side are common parts. As shown in FIG. 4 for the inner side and FIG. 2 for the outer side, the friction pad 12 has a mirror-like shape, and is attached to the back plate 71 and the back plate 71 in FIG. It has the lining 72 shown. The back plate 71 is a pair of a main plate portion 75 to which the lining 72 is attached and a pair of main plate portions 75 projecting in opposite directions along the width direction from both ends of the main plate portion 75 in the width direction as shown in FIGS. It has convex portions 76 and 76.

Then, in the friction pad 12 on the inner side, one of the first convex portions 76 makes the inner support plate portion 58 of the extension plate portion 56 on the inner side of the inner side of the first pad spring 16 on the inner side. It is elastically deformed so as to be close to the base plate portion 54 of the above, and is sandwiched between the outer support plate portion 52 of the concave portion 55 on the inner side and the inner support plate portion 58 of the extension plate portion 56 on the inner side. Further, the other second convex portion 76 brings the inner support plate portion 58 of the extension plate portion 56 on the inner side closer to the base plate portion 54 on the inner side with respect to the other second pad spring 16. It is elastically deformed and sandwiched between the outer support plate portion 52 of the concave portion 55 on the inner side and the inner support plate portion 58 of the extension plate portion 56 on the inner side. In this state, the friction pad 12 on the inner side is in a state in which the convex portions 76, 76 protrude in the disc rotation direction, and the convex portions 76, 76 and the concave portions 27A, 27A on the inner side of the mounting member 11 are between. The pad springs 16 and 16 are fitted with the concave portions 55 and 55 on the inner side and the extension plate portions 56 and 56 on the inner side interposed therebetween.

At this time, in the first pad spring 16, the inner support plate 58 on the tip end side of the extension plate 56 on the inner side is the first convex portion of the base plate 54 on the inner side and the friction pad 12 on the inner side. It will be in a state of being extended to 76. Further, at this time, in the second pad spring 16, the inner support plate portion 58 on the tip end side of the extension plate portion 56 on the inner side is the second of the base plate portion 54 on the inner side and the friction pad 12 on the inner side. It is in a state of being extended from the convex portion 76.

Further, at this time, in the friction pad 12 on the inner side, the first convex portion 76 is urged outward in the disc radial direction by the extending plate portion 56 on the inner side of the first pad spring 16, and the second convex portion is provided. The portion 76 is urged outward in the disc radial direction by the extension plate portion 56 on the inner side of the second pad spring 16. The friction pad 12 on the inner side slides between the outer support plate portions 52 and 52 on the inner side and the inner support plate portions 58 and 58 of the extension plate portions 56 and 56 on the inner side.

As shown in FIG. 10, the first convex portion 76 of the friction pad 12 on the inner side is in contact with the outer support plate portion 52 of the concave portion 55 on the inner side of the first pad spring 16. The extension plate portion 56 on the inner side of the pad spring 16 is separated from the protrusion 63 on the inner side of the first pad spring 16. From this state, as shown in FIG. 11, friction on the inner side of the first pad spring 16 until the extension plate portion 56 on the inner side of the first pad spring 16 comes into contact with the protrusion 63 on the inner side of the first pad spring 16. A spring load is applied to the first convex portion 76 of the pad 12 with the folded portion 57 of the extension plate portion 56 on the inner side of the first pad spring 16 as a fulcrum.

Here, in a state where the friction pad 12 on the inner side receives a small force from the disc 10, as shown in FIG. 10, the extension plate portion 56 is separated from the protrusion 63 on the inner side of the first pad spring 16. A spring load is applied to the first convex portion 76 of the friction pad 12 on the inner side with the folded-back portion 57 of the extending plate portion 56 on the inner side of the first pad spring 16 as a fulcrum.

The first convex portion 76 of the friction pad 12 on the inner side moves in the direction away from the outer support plate portion 52 on the inner side of the first pad spring 16 (inward in the disc radial direction), and is shown in FIG. As described above, when the extension plate portion 56 on the inner side of the first pad spring 16 comes into contact with the protrusion 63 on the inner side of the first pad spring 16, after that, the first friction pad 12 on the inner side A spring load is applied to the convex portion 76 with the protruding portion 63 of the extending plate portion 56 on the inner side of the first pad spring 16 as a fulcrum.

Here, when the force received by the friction pad 12 on the inner side from the disc 10 becomes large, vibration is likely to occur, and such vibration causes the first convex portion 76 of the friction pad 12 on the inner side to move inward in the disc radial direction. When the extension plate portion 56 comes into contact with the protrusion 63 on the inner side of the first pad spring 16, the first convex portion 76 of the friction pad 12 on the inner side has a first pad. A spring load is applied with the protrusion 63 of the extension plate 56 on the inner side of the spring 16 as a fulcrum. This spring load is larger than the spring load with the folded-back portion 57 as a fulcrum.

In the pad support portion 41 on the inner side of the first pad spring 16, the protrusion 63 is provided on the side opposite to the disc 10 with respect to the friction pad 12 on the inner side of the base plate portion 54, and is the first convex portion. When the 76 is moved inward in the disc radial direction, it comes into contact with the extension plate portion 56, and when the first convex portion 76 is moved outward in the disc radial direction, it is separated from the extension plate portion 56. In other words, in the pad support portion 41 on the inner side of the first pad spring 16, the protrusion 63 is an extension plate in a state where the friction pad 12 on the inner side is located closer to the disc 10 than the protrusion 63. The portion 56 and the base plate portion 54 are brought into contact with each other. The pad support portion 41 on the inner side of the first pad spring 16 is provided with a protrusion 63, so that the extension plate portion 56 has a structure in which the fulcrum changes according to the amount of bending thereof. In other words, in the pad support portion 41 on the inner side of the first pad spring 16, the protrusion 63 is a fulcrum position of the extension plate portion 56 with respect to the base plate portion 54 according to the movement position of the friction pad 12 on the inner side. To change.

Similarly, the second pad spring 16 is in a state where the second convex portion 76 of the friction pad 12 on the inner side is in contact with the outer support plate portion 52 of the concave portion 55 on the inner side of the second pad spring 16. The extension plate portion 56 on the inner side of the second pad spring 16 is separated from the protrusion 63 on the inner side of the second pad spring 16. From this state, until the extension plate portion 56 on the inner side of the second pad spring 16 comes into contact with the protrusion 63 on the inner side of the second pad spring 16, the second convex portion of the friction pad 12 on the inner side A spring load is applied to the 76 with the folded-back portion 57 of the extension plate portion 56 on the inner side of the second pad spring 16 as a fulcrum.

When the force received by the friction pad 12 on the inner side from the disc 10 is small, the extension plate portion 56 is separated from the protrusion 63 on the inner side of the second pad spring 16, and the friction pad 12 on the inner side is the second. A spring load is applied to the convex portion 76 of 2 with the folded portion 57 of the extending plate portion 56 on the inner side of the second pad spring 16 as a fulcrum.

The second convex portion 76 of the friction pad 12 on the inner side moves in the direction away from the outer support plate portion 52 on the inner side of the second pad spring 16 (inward in the disc radial direction), and the second pad When the extension plate portion 56 on the inner side of the spring 16 comes into contact with the protrusion 63 on the inner side of the second pad spring 16, after that, the second convex portion 76 of the friction pad 12 on the inner side has a second A spring load is applied with the protrusion 63 of the extension plate 56 on the inner side of the pad spring 16 of 2 as a fulcrum.

When the force received by the friction pad 12 on the inner side from the disc 10 becomes large, vibration is likely to occur, and such vibration causes the second convex portion 76 of the friction pad 12 on the inner side to move inward in the disc radial direction. When the extension plate portion 56 comes into contact with the protrusion 63 on the inner side of the second pad spring 16, the second convex portion 76 of the friction pad 12 on the inner side is exposed to the second pad spring 16. A spring load is applied with the protrusion 63 of the extension plate 56 on the inner side as a fulcrum. This spring load is larger than the spring load with the folded-back portion 57 as a fulcrum.

In the pad support portion 41 on the inner side of the second pad spring 16, the protrusion 63 is provided on the side opposite to the disc 10 with respect to the friction pad 12 on the inner side of the base plate portion 54, and is a second convex portion. When the 76 is moved inward in the disc radial direction, it comes into contact with the extension plate portion 56 and is separated from the extension plate portion 56 when the second convex portion 76 is moved outward in the disc radial direction. In other words, in the pad support portion 41 on the inner side of the second pad spring 16, the protrusion 63 is an extension plate in a state where the friction pad 12 on the inner side is located closer to the disc 10 than the protrusion 63. The portion 56 and the base plate portion 54 are brought into contact with each other. The pad support portion 41 on the inner side of the second pad spring 16 is provided with a protrusion 63, so that the extension plate portion 56 has a structure in which the fulcrum changes according to the amount of bending thereof. In the pad support portion 41 on the inner side of the second pad spring 16, the protrusion 63 changes the fulcrum position of the extension plate portion 56 with respect to the base plate portion 54 according to the movement position of the friction pad 12 on the inner side. ..

Similarly, in the friction pad 12 on the outer side, one of the third convex portions 76 has the inner support plate portion 58 of the extension plate portion 56 on the outer side on the outer side with respect to the first pad spring 16. It is elastically deformed so as to be close to the base plate portion 54, and is sandwiched between the outer support plate portion 52 of the concave portion 55 on the outer side and the inner support plate portion 58 of the extension plate portion 56 on the outer side. Further, the other fourth convex portion 76 is elastic so as to bring the inner support plate portion 58 of the extension plate portion 56 on the outer side closer to the base plate portion 54 on the outer side with respect to the second pad spring 16. It is deformed and sandwiched between the outer support plate portion 52 of the concave portion 55 on the outer side and the inner support plate portion 58 of the extension plate portion 56 on the outer side. In this state, in the friction pad 12 on the outer side, the convex portions 76, 76 protrude in the disc rotation direction, and the convex portions 76, 76 and the concave portions 27B, 27B on the outer side of the mounting member 11 are between. The pad springs 16 and 16 are fitted with the concave portions 55 and 55 on the outer side and the extension plate portions 56 and 56 on the outer side interposed therebetween.

At this time, in the first pad spring 16, the inner support plate portion 58 on the tip end side of the extension plate portion 56 on the outer side is the third convex portion of the base plate portion 54 on the outer side and the friction pad 12 on the outer side. It will be in a state of being extended to 76. Also in the second pad spring 16, the inner support plate portion 58 on the tip end side of the extension plate portion 56 on the outer side is the base plate portion 54 on the outer side and the fourth convex portion 76 of the friction pad 12 on the outer side. It will be in a state of being extended during.

Further, at this time, in the friction pad 12 on the outer side, the third convex portion 76 is urged outward in the disc radial direction by the extending plate portion 56 on the outer side of the first pad spring 16, and the fourth convex portion 76 is formed. The portion 76 is urged outward in the disc radial direction by the extension plate portion 56 on the outer side of the second pad spring 16. The friction pad 12 on the outer side slides between the outer support plate portions 52 and 52 on the outer side and the inner support plate portions 58 and 58 of the extension plate portions 56 and 56 on the outer side.

The outer side of the first pad spring 16 is in a state where the third convex portion 76 of the friction pad 12 on the outer side is in contact with the outer support plate portion 52 of the concave portion 55 on the outer side of the first pad spring 16. The extension plate portion 56 of the first pad spring 16 is separated from the protrusion 63 on the outer side of the first pad spring 16. From this state, the third convex portion of the friction pad 12 on the outer side until the extension plate portion 56 on the outer side of the first pad spring 16 comes into contact with the protrusion 63 on the outer side of the first pad spring 16. A spring load is applied to the 76 with the folded-back portion 57 of the extension plate portion 56 on the outer side of the first pad spring 16 as a fulcrum.

When the force received by the friction pad 12 on the outer side from the disc 10 is small, the extension plate portion 56 is separated from the protrusion 63 on the outer side of the first pad spring 16, and the friction pad 12 on the outer side is the first. A spring load is applied to the convex portion 76 of No. 3 with the folded portion 57 of the extending plate portion 56 on the outer side of the first pad spring 16 as a fulcrum.

The third convex portion 76 of the friction pad 12 on the outer side moves in the direction away from the outer support plate portion 52 on the outer side of the first pad spring 16 (inward in the disc radial direction), and the first pad When the extension plate portion 56 on the outer side of the spring 16 comes into contact with the protrusion 63 on the outer side of the first pad spring 16, after that, the third convex portion 76 of the friction pad 12 on the outer side has a third A spring load is applied with the protrusion 63 of the extension plate portion 56 on the outer side of the pad spring 16 of 1 as a fulcrum.

When the force received by the friction pad 12 on the outer side from the disc 10 becomes large, vibration is likely to occur, and such vibration causes the third convex portion 76 of the friction pad 12 on the outer side to move inward in the disc radial direction. When the extension plate portion 56 comes into contact with the protrusion 63 on the outer side of the first pad spring 16, the first pad spring 16 is attached to the third convex portion 76 of the friction pad 12 on the outer side. A spring load is applied with the protrusion 63 of the extension plate 56 on the outer side as a fulcrum. This spring load is larger than the spring load with the folded-back portion 57 as a fulcrum.

In the pad support portion 41 on the outer side of the first pad spring 16, the protrusion 63 is provided on the side opposite to the disc 10 with respect to the friction pad 12 on the outer side of the base plate portion 54, and is a third convex portion. When the 76 is moved inward in the disc radial direction, it comes into contact with the extension plate portion 56 and is separated from the extension plate portion 56 when the third convex portion 76 is moved outward in the disc radial direction. In other words, in the pad support portion 41 on the outer side of the first pad spring 16, the protrusion 63 is an extension plate in a state where the friction pad 12 on the outer side is located closer to the disc 10 than the protrusion 63. The portion 56 and the base plate portion 54 are brought into contact with each other. The pad support portion 41 on the outer side of the first pad spring 16 is provided with a protrusion 63, so that the extension plate portion 56 has a structure in which the fulcrum changes according to the amount of bending thereof. In the pad support portion 41 on the outer side of the first pad spring 16, the protrusion 63 changes the fulcrum position of the extension plate portion 56 with respect to the base plate portion 54 according to the movement position of the friction pad 12 on the outer side. ..

Similarly, the second pad spring 16 is in a state where the fourth convex portion 76 of the friction pad 12 on the outer side is in contact with the outer support plate portion 52 of the concave portion 55 on the outer side of the second pad spring 16. The extension plate portion 56 on the outer side of the second pad spring 16 is separated from the protrusion 63 on the outer side of the second pad spring 16. From this state, the fourth convex portion of the friction pad 12 on the outer side until the extension plate portion 56 on the outer side of the second pad spring 16 comes into contact with the protrusion 63 on the outer side of the second pad spring 16. A spring load is applied to the 76 with the folded-back portion 57 of the extension plate portion 56 on the outer side of the second pad spring 16 as a fulcrum.

When the force received by the friction pad 12 on the outer side from the disc 10 is small, the extension plate portion 56 is separated from the protrusion 63 on the outer side of the second pad spring 16, and the friction pad 12 on the outer side is the first. A spring load is applied to the convex portion 76 of 4 with the folded-back portion 57 of the extending plate portion 56 on the outer side of the second pad spring 16 as a fulcrum.

The fourth convex portion 76 of the friction pad 12 on the outer side moves in the direction away from the outer support plate portion 52 on the outer side of the second pad spring 16 (inward in the disc radial direction), and the second pad When the extension plate portion 56 on the outer side of the spring 16 comes into contact with the protrusion 63 on the outer side of the second pad spring 16, after that, the fourth convex portion 76 of the friction pad 12 on the outer side has a second A spring load is applied with the protrusion 63 of the extension plate portion 56 on the outer side of the pad spring 16 of 2 as a fulcrum.

When the force received by the friction pad 12 on the outer side from the disc 10 becomes large, vibration is likely to occur, and such vibration causes the fourth convex portion 76 of the friction pad 12 on the outer side to move inward in the disc radial direction. When the extension plate portion 56 comes into contact with the protrusion 63 on the outer side of the second pad spring 16, the second pad spring 16 is attached to the fourth convex portion 76 of the friction pad 12 on the outer side. A spring load is applied with the protrusion 63 of the extension plate 56 on the outer side as a fulcrum. This spring load is larger than the spring load with the folded-back portion 57 as a fulcrum.

In the pad support portion 41 on the outer side of the second pad spring 16, the protrusion 63 is provided on the side opposite to the disc 10 with respect to the friction pad 12 on the outer side of the base plate portion 54, and is a fourth convex portion. When the 76 is moved inward in the disc radial direction, it comes into contact with the extension plate portion 56 and is separated from the extension plate portion 56 when the fourth convex portion 76 is moved outward in the disc radial direction. In other words, in the pad support portion 41 on the outer side of the second pad spring 16, the protrusion 63 is an extension plate in a state where the friction pad 12 on the outer side is located closer to the disc 10 than the protrusion 63. The portion 56 and the base plate portion 54 are brought into contact with each other. The pad support portion 41 on the outer side of the second pad spring 16 is provided with a protrusion 63, so that the extension plate portion 56 has a structure in which the fulcrum changes according to the amount of bending thereof. In the pad support portion 41 on the outer side of the second pad spring 16, the protrusion 63 changes the fulcrum position of the extension plate portion 56 with respect to the base plate portion 54 according to the movement position of the friction pad 12 on the outer side. ..

The caliper 14 shown in FIG. 1 slidably fits the pair of slide pins 90, 90 into the pair of fitting holes 31 and 31 of the mounting member 11 shown in FIGS. 4 and 5. The caliper 14 is slidably supported by the mounting member 11 in the disc axial direction.

As shown in FIG. 3, the caliper 14 has a bottomed tubular cylinder portion 91 that slidably supports the piston 13 in the disc axial direction and is arranged on the inner side of the friction pad 12 on the opposite side of the disc 10. The bridge portion 92 extending from the outside of the cylinder portion 91 in the disc radial direction across the outer peripheral portion of the disc 10, and the disc 10 of the friction pad 12 on the outer side from the opposite side to the cylinder portion 91 of the bridge portion 92. It has a caliper main body 94 having a claw portion 93 extending so as to face the opposite side.

When the brake hydraulic pressure is introduced between the cylinder portion 91 and the piston 13 by the brake operation by the brake pedal, the hydraulic pressure acts on the piston 13 to generate a propulsive force in the direction of the disc 10. Then, as the piston 13 moves in the direction of the disc 10, the friction pad 12 on the inner side is moved with respect to the mounting member 11 and the disc 10 in the disc axial direction and pressed against the disc 10. At that time, the friction pad 12 on the inner side slides the pad support portions 41 and 41 on the inner side of the pair of pad springs 16 and 16 provided on the pad guides 26A and 26A on the inner side of the mounting member 11. Will be done.

Further, by the reaction force of this pressing, the caliper main body 94 moves to the inner side so as to move the claw portion 93 to the disc 10 side, and the friction pad 12 on the outer side is moved to the mounting member 11 and the disc 10 by the claw portion 93. The disc is moved in the axial direction of the disc and pressed against the disc 10. At that time, the friction pad 12 on the outer side slides the pad support portions 41 and 41 on the outer side of the pair of pad springs 16 and 16 provided on the pad guides 26B and 26B on the outer side of the mounting member 11. Will be done.

As described above, the pair of friction pads 12, 12 are pressed against the disc 10. Then, the pair of friction pads 12 and 12 integrally with the disc 10 try to move to the exit side in the disc rotation direction, and the torque of the friction pads 12 and 12 generated at this time is mainly applied to the disc rotation direction of the mounting member 11. The pad guides 26A and 26B on the outlet side are received via the pad support portions 41 and 41 of the pad spring 16 on the outlet side in the disc rotation direction.

The disc brake described in Patent Document 1 has a projecting piece portion bent inward in the disc radial direction at a radial biasing portion of the pad spring. The projecting piece portion abuts on the lower side wall surface of the pad guide to prevent the radial urging portion from abutting on the lower surface plate of the pad spring. In such a pad spring, when the spring load is large, the friction pad is likely to be dragged, and conversely, when the spring load is small, abnormal noise is likely to be generated.

On the other hand, in the disc brake 1 of the present embodiment, the disc diameter of the convex portion 76 of the friction pad 12 is on the connecting side of the base plate portion 54 of the pad spring 16 to the extending plate portion 56, that is, on the side opposite to the disc 10. A protrusion 63 that comes into contact with the extension plate 56 when moving inward in the direction is provided. Therefore, even if the extension plate portion 56 elastically deforms with the folded-back portion 57 as a fulcrum to reduce the spring load when urging the convex portion 76 to suppress the dragging of the friction pad 12, the friction pad 12 vibrates. Occasionally, the extending plate portion 56 abuts on the protruding portion 63 of the base plate portion 54 and elastically deforms with the protruding portion 63 as a fulcrum to urge the convex portion 76, thereby increasing the spring load. It is possible to suppress the generation of abnormal sounds such as pad rattle sounds. Therefore, it is possible to suppress the dragging of the friction pad 12 and the generation of abnormal noise.

Moreover, in the protruding portion 63, the base plate portion 54 and the extending plate portion 56 are brought into contact with each other in a state where the friction pad 12 is located closer to the disc 10 than the protruding portion 63, so that the base plate portion 54 and the extending plate portion 56 are extended. The protrusion 63 is provided on the interconnected side of the friction pad 12 of the protrusion plate 56, and the degree of freedom in setting the spring load of the extension plate portion 56 after contacting the protrusion 63 is increased. Therefore, the effect of suppressing the generation of abnormal noise such as pad rattle sound is high.

Further, since the base plate portion 54 is provided with the protrusion portion 63 projecting outward in the disc radial direction, the pad spring 16 can be easily manufactured by press working.

Further, since the protrusion 63 is arranged on the base plate 54 so as to abut the central portion in the width direction of the extension plate 56, even when the extension plate 56 is in contact with the protrusion 63. The urging direction of the friction pad 12 on the extension plate portion 56 does not change, and the occurrence of brake squeal can be suppressed even when the friction pad 12 is worn.

Here, as shown in FIG. 12, a plurality of protrusions 63 may be provided on the extension plate portion 56 of the pad spring 16 at different distances from the disc 10. By providing a plurality of protrusions 63, which serve as fulcrums for elastic deformation of the extension plate 56, at different distances from the disc 10, the convex portion 76 in the disc axial direction changes depending on the amount of wear of the lining 72. The spring load during vibration can be satisfactorily increased according to the position.

The protrusion 63 may be projected from the base plate portion 54 toward the extension plate portion 56, or may be projected from the extension plate portion 56 toward the base plate portion 54. Further, the protrusion 63 may have a prismatic shape as well as a spherical shape. However, since the cross section of the linear recess 62 orthogonal to the extending direction is arcuate, the contact state is more stable when the linear recess 62 is spherical. Further, the protrusion 63 may be a convex portion extending in a direction orthogonal to the sliding direction of the friction pad 12.

In the above embodiment, a mounting member having a pad guide that is mounted on a vehicle so as to straddle the outer peripheral side of the disc in the disc axial direction and movably supports at least a pair of friction pads arranged to face each other on both sides of the disc. A caliper that is slidably provided on the mounting member and presses the pair of friction pads on both sides of the disc, and a pad that is mounted on a part of the mounting member and urges each friction pad in the disc radial direction. In a disc brake having a spring, the pad spring is arranged in contact with the pad guide, and has a base plate portion having a protruding portion protruding outward in the disc axial direction from the pad guide, and the base end side is the said. Folded inward in the disc axial direction from the protruding portion, the tip side extends between the base plate portion and the friction pad, and the extension portion on which the friction pad slides and the moving position of the friction pad Correspondingly, the extension portion has a protrusion that changes the position of the fulcrum with respect to the base plate portion to bring the extension portion into contact with the base plate portion, and the protrusion has the friction pad. It is arranged at a position where the extension portion and the base plate portion are brought into contact with each other in a state of being located closer to the disc than the protrusion portion. As a result, it is possible to suppress the dragging of the friction pad and the generation of abnormal noise.

Further, since the protruding portion is provided on the base plate portion so as to project outward in the radial direction of the disc, the pad spring can be easily manufactured.

1 Disc brake 10 Disc 11 Mounting member 12 Friction pad 16 Pad spring 27A, 27B Recess 54 Base plate 55 Concave 56 Extension plate (extension)
76 Convex part 81 Contact part

Claims (2)

A mounting member having a pad guide that is mounted on the vehicle so as to straddle the outer peripheral side of the disc in the disc axial direction and movably supports at least a pair of friction pads arranged to face each other on both sides of the disc.
A caliper that is slidably provided on the mounting member and presses the pair of friction pads on both sides of the disc.
In a disc brake having a pad spring attached to a part of the mounting member and urging each friction pad in the disc radial direction.
The pad spring
A base plate portion that is arranged in contact with the pad guide and has a protruding portion that protrudes outward in the disc axial direction from the pad guide.
The base end side is folded back from the protruding portion inward in the disc axial direction, the tip end side is extended between the base plate portion and the friction pad, and the extending portion on which the friction pad slides.
It has a protrusion that changes the fulcrum position of the extension portion with respect to the base plate portion according to the movement position of the friction pad to bring the extension portion into contact with the base plate portion.
The protrusion is provided on the base plate portion so as to project outward in the radial direction of the disc, and the friction pad is located closer to the disc than the protrusion, and the protrusion portion and the extension portion are provided. It is arranged at a position where it comes into contact with the base plate portion .
The protrusion and the linear recess provided in the extension along the extending direction of the extension come into contact with each other, so that the extension and the base plate come into contact with each other. Disc brake. The linear recess has an arcuate cross section orthogonal to the extending direction.
The disc brake according to claim 1, wherein the protrusion has a spherical shape.

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