JP2019207000A - Disc brake - Google Patents

Abstract

To provide a disc brake capable of suppressing generation of strange noise.SOLUTION: A pad spring 5 is disposed to extend along a bottom 21 and has pad facing sections 53 facing an outer end 107 in the disc rotation direction of a lug part 106, in which the pad facing section 53 has a pad abutment part 202 abutting against the end 107. The pad abutment part 202 includes a rising portion 211 rising up inward in the disc rotation direction, a bent portion 212 bent from the rising portion 211 toward the side close to a disc in the disc axis direction, and an abutment part body 213 that is extended from the bent portion 212 in a direction of approaching the disc to be positioned at the outer side in the disc rotation direction as advancing to the disc side and abuts on the end 107.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a disc brake.

  Some disc brakes have a pad spring that elastically supports the pad (for example, see Patent Document 1).

JP-A-8-200409

  In the disc brake, it is desired to suppress the occurrence of abnormal noise.

  An object of the present invention is to provide a disc brake capable of suppressing the occurrence of abnormal noise.

  In order to achieve the above object, according to the present invention, the pad spring has a pad abutting portion that abuts the end of the pad ear on the outer side in the disc rotating direction, and the pad abutting portion is located on the inner side in the disc rotating direction. A rising portion that rises toward the disk, a curved portion that is bent from the rising portion toward the side closer to the disk in the axial direction of the disk, and a position closer to the disk from the curved portion toward the disk so And an abutting portion main body that abuts against the end portion.

  According to the present invention, it is possible to suppress the occurrence of abnormal noise.

The perspective view which shows the disc brake of embodiment. The top view which shows the disc brake of embodiment. The front view which shows the attachment member, pad spring, and pad of the disc brake of embodiment. The front view which shows the pad spring of the disc brake of embodiment. The side view which shows the pad spring of the disc brake of embodiment. The perspective view which shows the pad spring of the disc brake of embodiment. The perspective view which shows the pad spring of the disc brake of embodiment. The fragmentary sectional view which shows the attaching member of the disc brake of embodiment, and the principal part of a pad spring. The fragmentary sectional view showing the state at the time of non-braking of the attachment member, pad spring, and pad of the disc brake of an embodiment. The fragmentary sectional view which shows the state at the time of braking of the attachment member of a disc brake of an embodiment, a pad spring, and a pad. The fragmentary sectional view which shows the modification of the attaching member of the disc brake of embodiment, a pad spring, and the principal part of a pad.

  Embodiments according to the present invention will be described below with reference to the drawings.

  The disc brake 10 of the present embodiment shown in FIG. 1 is for a vehicle such as an automobile and applies braking force to the vehicle, and specifically for a four-wheeled vehicle. The disc brake 10 brakes the vehicle by stopping the rotation of the disc-like disc 1 that rotates with a wheel (not shown).

  Hereinafter, the direction of the central axis of the disk 1 is referred to as a disk axis direction, the radial direction of the disk 1 is referred to as a disk radial direction, and the rotation direction of the disk 1, that is, the circumferential direction is referred to as a disk rotation direction. The center side of the disk 1 in the disk radial direction is referred to as the inner side in the disk radial direction, and the side opposite to the center of the disk 1 in the disk radial direction is referred to as the outer side in the disk radial direction. Further, the inlet side in the disk rotation direction is referred to as a disk inlet side, and the outlet side in the disk rotation direction is referred to as a disk outlet side.

  The disc brake 10 includes a mounting member 2 disposed across the outer peripheral side of the disc 1, a caliper 3 slidably provided on the mounting member 2, and a pair of pads attached to the mounting member 2 as shown in FIG. It has a spring 5 and a pair of pads 6 that are supported by the pair of pad springs 5 and arranged to face both surfaces of the disk 1. The attachment member 2 is disposed across the outer peripheral side of the disc 1 by being attached to a non-rotating portion of the vehicle.

  The mounting member 2 includes an inner beam portion 11 shown in FIGS. 1 and 3, a pair of inner torque receiving portions 12 shown in FIG. 3, a pair of pin insertion portions 13 shown in FIG. 2, and FIGS. The outer side torque receiving portion 14 and the outer beam portion 15 shown in FIG. The mounting member 2 is a casting integrally formed by casting, and has a mirror-symmetric shape with respect to the center in the disk rotation direction. The attachment member 2 is made of cast iron, for example.

  As shown in FIG. 1, the inner beam portion 11 is disposed on one side in the disc axial direction with respect to the disc 1 and is attached to a non-rotating portion of the vehicle. Here, the non-rotating portion of the vehicle to which the mounting member 2 is attached is disposed on the inner side in the vehicle width direction of the vehicle, that is, the inner side with respect to the disc 1, and the inner beam portion 11 attached to this non-rotating portion is also the disc 1. Is arranged on the inner side.

  As shown in FIG. 3, the inner beam portion 11 is arranged so as to extend in the disk rotation direction, and mounting holes 17 are provided on both sides of the disk rotation direction, that is, one side in the disk rotation direction and the other side in the disk rotation direction. Is formed. A fastening member such as a bolt (not shown) is screwed into the mounting holes 17 on both sides of the inner beam portion 11 and is attached to the non-rotating portion of the vehicle by these fastening members.

  As shown in FIG. 1, the pair of inner side torque receiving portions 12 has one inner side torque receiving portion 12 extending from the end of the inner beam portion 11 on one side in the disc rotation direction to the outside in the disc radial direction. . The other inner side torque receiving portion 12 shown in FIG. 3 extends from the end of the inner beam portion 11 on the other side in the disc rotation direction to the outside in the disc radial direction. The pair of inner side torque receiving portions 12 is disposed on the inner side with respect to the disk 1, as with the inner beam portion 11.

  As shown in FIG. 1, the pair of pin insertion portions 13 are arranged such that one pin insertion portion 13 is disc-shaped in the disc axial direction from the outer end in the disc radial direction of the inner torque receiving portion 12 on one side in the disc rotation direction. 1 extends over the outer peripheral side. Further, the other pin insertion portion 13 shown in FIG. 3 extends across the outer peripheral side of the disc 1 in the disc axial direction from the outer end portion in the disc radial direction of the inner side torque receiving portion 12 on the other side in the disc rotation direction. Put out.

  As shown in FIG. 1, the pair of outer side torque receiving portions 14 includes one inner side torque receiving portion 12 of the pin insertion portion 13 on one side in the disk rotation direction. Extends from the opposite end, that is, the outer end, to the inner side in the disk radial direction. Further, the outer side torque receiving portion 14 on the other side in the other disk rotation direction shown in FIG. 3 extends inward in the disk radial direction from the outer side end of the pin insertion portion 13 on the other side in the disk rotation direction. . The pair of outer side torque receiving portions 14 are arranged on the outer side in the vehicle width direction of the vehicle, that is, on the outer side with respect to the disc 1.

  The outer beam portion 15 extends in the disc rotation direction and connects the inner sides of the pair of outer side torque receiving portions 14 in the disc radial direction. The outer beam portion 15 is disposed on the outer side with respect to the disk 1, similarly to the pair of outer side torque receiving portions 14.

  As described above, the attachment member 2 is provided across the outer peripheral side of the disk 1 and attached to the non-rotating portion of the vehicle. The inner beam portion 11 and the pair of inner torque receiving portions 12 are disposed on the inner side of the attachment member 2 on the attachment side to the non-rotating portion of the vehicle, and the pair of outer side torque receiving portions 14 and the outer beam portions. 15 is disposed on the outer side of the mounting member 2 opposite to the inner side.

  As shown in FIG. 3, a pair of outer side torque receiving portions 14 are formed with similar concave shaped guide portions 20, and only one of the pair of inner side torque receiving portions 12 is also shown in FIG. 1. Although illustrated, similar concave guide portions 20 are respectively formed. That is, the attachment member 2 is formed with four similar concave guide portions 20 in total. These four guide portions 20 are aligned in the disk radial direction. Further, the two guide portions 20 provided in the inner side torque receiving portion 12 and the outer side torque receiving portion 14 on one side in the disk rotation direction are aligned with each other in the disk rotation direction, and the inner side on the other side in the disk rotation direction. The two guide portions 20 provided in the side torque receiving portion 12 and the outer side torque receiving portion 14 are aligned in the disk rotation direction.

  As shown in FIG. 3, the outer side torque receiving portion 14 on one side in the disk rotation direction has an outer side in the disk rotation direction (mounting from the inner side in the disk rotation direction of the mounting member 2) in the disk rotation direction. The guide portion 20 is formed in a concave shape that is recessed toward the opposite side of the center of the member 2 in the disk rotation direction. The outer side torque receiving portion 14 on the other side in the disk rotation direction is also formed with a guide portion 20 that is recessed from the inner surface in the disk rotation direction toward the outer side in the disk rotation direction. Therefore, the pair of outer side torque receiving portions 14 is formed with a guide portion 20 having a concave shape that is recessed in a direction away from each other along the disk rotation direction on the opposite sides.

  As shown in FIG. 1, a guide portion 20 is formed in the inner torque receiving portion 12 on one side in the disk rotation direction so as to be recessed from the inner surface in the disk rotation direction toward the outer side in the disk rotation direction. Has been. Although not shown, the inner torque receiving portion 12 on the other side of the disk rotation direction is also formed with a guide portion 20 having a concave shape that is recessed from the inner surface in the disk rotation direction toward the outer side in the disk rotation direction. Yes. Accordingly, the pair of inner side torque receiving portions 12 are also formed with concave guide portions 20 that are recessed in the direction away from each other along the disk rotation direction on the opposite sides.

  As shown in FIG. 3, the guide portion 20 includes a bottom portion 21 on the back side in the recess direction, an outer wall portion 22 (wall portion) on the outer side in the disk radial direction, and an inner wall portion 23 on the inner side in the disk radial direction. (Wall part). The outer wall portion 22 extends from the edge of the bottom portion 21 on the outer side in the disk radial direction toward the inner side in the disk rotation direction. The inner wall portion 23 extends from the end portion of the bottom portion 21 on the inner side in the disk radial direction toward the inner side in the disk rotation direction. In other words, the guide portion 20 includes a bottom portion 21 and a pair of outer wall portions 22 and inner wall portions 23 provided on both sides of the bottom portion 21.

  These bottom portion 21, outer wall portion 22, and inner wall portion 23 all extend in the disk axial direction. Further, the bottom portion 21 is along a disc radial line passing through the center of the mounting member 2 in the disc rotation direction and the center of the disc 1, and the outer wall portion 22 and the inner wall portion 23 are surfaces orthogonal to this line. It is along. Therefore, the outer wall portion 22 and the inner wall portion 23 both extend perpendicular to the bottom portion 21 and are parallel to each other.

  As shown in FIG. 1, the mounting member 2 has pin insertion holes (not shown) formed in each of a pair of pin insertion portions 13 on both sides of the disk rotation direction, and the caliper 3 is inserted into these pin insertion holes. A pair of slide pins 31 on both sides of the disk rotation direction are slidably fitted. Thereby, the attachment member 2 supports the caliper 3 so as to be slidable in the disk axial direction at the pair of pin insertion portions 13. In other words, the caliper 3 is slidably fitted into pin insertion holes (not shown) of the pair of pin insertion portions 13 of the mounting member 2, in which a pair of slide pins 31 provided on both sides of the disk rotation direction are respectively fitted. Thus, the mounting member 2 is supported so as to be slidable in the disk axial direction.

  A common pad spring 5 is attached to the inner side torque receiving portion 12 and the outer side torque receiving portion 14 that are aligned in the disk rotation direction. Further, a common pad spring 5 is also attached to the inner side torque receiving portion 12 and the outer side torque receiving portion 14 on the other side where the positions in the disk rotation direction are matched. That is, two pad springs 5 are attached to one attachment member 2. These pad springs 5 are common parts having the same shape.

  The pad spring 5 has the shape shown in FIGS. 4 to 7 and has a mirror-symmetric shape. The pad spring 5 is formed by press molding from a single plate material having a constant thickness. The pad spring 5 includes a pair of pad support portions 41 and a connection portion 42 that connects the pair of pad support portions 41. In the pad spring 5, a pair of pad support portions 41 are arranged on both sides of the disc axial direction with respect to the disc 1, and a connection portion 42 is arranged on the outer side of the disc 1 in the disc radial direction. In other words, in the pad spring 5, the disk 1 is disposed between the pair of pad support portions 41.

  In one pad spring 5, the pair of pad support portions 41 have a mirror-symmetric shape, and therefore, one pad support portion 41 will be described.

  The pad support portion 41 includes an outer end plate portion 51 on the connection portion 42 side and an outer support plate portion that extends perpendicularly to the outer end plate portion 51 from the end portion on the opposite side to the connection portion 42 of the outer end plate portion 51. 52 and an intermediate plate portion 53 (pad facing portion) extending from the end of the outer support plate portion 52 opposite to the outer end plate portion 51 in a direction perpendicular to the outer support plate portion 52 and away from the outer end plate portion 51. And a base plate portion 54 extending from the end 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 perpendicular to the intermediate plate portion 53. Yes.

  The outer end plate portion 51 and the intermediate plate portion 53 are parallel, and the outer support plate portion 52 and the base plate portion 54 are parallel. The continuous outer support plate portion 52, intermediate plate portion 53, and base plate portion 54 are connected in a concave shape as a whole to constitute a guide plate portion 55 (guide facing portion).

  In one pad support portion 41, the intermediate plate portion 53 includes a flat plate main plate portion 201 and a contact plate portion 202 (pad contact portion) formed inside the main plate portion 201. The intermediate plate portion 53 extends to the side opposite to the other pad support portion 41 from the outer support plate portion 52 and the base plate portion 54. One of the pad support portions 41 extends from the end edge portion of the intermediate plate portion 53 on the side opposite to the other pad support portion 41 in the direction opposite to the other pad support portion 41 toward the tip side. An extension plate portion 61 is provided so as to extend away from the outer support plate portion 52 and the base plate portion 54 in the plate thickness direction.

  One pad support portion 41 is folded back from the end of the base plate portion 54 opposite to the other pad support portion 41 to the outer support plate portion 52 side and arranged on the outer support plate portion 52 side of the base plate portion 54. The urging plate portion 80 (radial urging portion) is provided.

  One pad support portion 41 has a biasing plate portion 80 whose base plate portion 54 extends from the end opposite to the other pad support portion 41 in the opposite direction to the other pad support portion 41. The end-side extending plate 81 (first extending portion) and a curl that is folded back in an arc from the end opposite to the base plate 54 of the base-side extending plate 81 to the outer support plate 52 side. From the plate portion 82 (curl portion) and the end of the curl plate portion 82 on the side opposite to the base end side extending plate portion 81 in the direction of the other pad support portion 41, the other pad support portion 41 side, A distal end side extending plate portion 83 (second extending portion) extending away from the base plate portion 54 in the thickness direction of the base plate portion 54.

  The intermediate plate portion 53 has a main plate portion 201 having a frame shape and an inner opening 205 penetrating in the thickness direction at the center. The inner opening 205 is a portion punched out to form the contact plate 202.

  In one pad support portion 41, the contact plate portion 202 rises on the same side as the outer support plate portion 52 and the base plate portion 54 from the edge of the inner opening 205 opposite to the other pad support portion 41. The upright portion 211, the bending portion 212 (curved portion) that curves from the edge portion of the upright portion 211 opposite to the main plate portion 201 toward the other pad support portion 41, and the rising portion 211 of the bending portion 212 A plate-like main body plate portion 213 (abutment portion main body) extending from the opposite edge portion toward the other pad support portion 41 side so as to approach the main plate portion 201 toward the other pad support portion 41 side, A tip plate 214 that protrudes from the edge of the main body plate 213 opposite to the curved portion 212 toward the other pad support 41, and away from the main plate 201 toward the other pad support 41; have. The contact plate 202 is provided within the range of the inner opening 205. As shown in FIG. 4, in one pad support portion 41, the upright portion 211 is formed at a position closer to the other pad support portion 41 than the curl plate portion 82.

  The connection portion 42 that connects the one pad support portion 41 described above and the other pad support portion 41 that is mirror-symmetrical with the pad support portion 41 is an outer support plate of the outer end plate portion 51 of the pair of pad support portions 41. It has the connection board part 91 which connects the opposite side to the part 52, and the positioning part 92 provided between the pair of outer end board parts 51 in the connection plate part 91.

  One pad spring 5 is attached to the inner side torque receiving portion 12 and the outer side torque receiving portion 14 that are both on the same side in the disk rotation direction of the attachment member 2. At this time, the one pad spring 5 has a concave guide plate portion of the one pad support portion 41 in a state where the connection portion 42 is disposed on the outer side in the disk radial direction from the pad support portion 41 as shown in FIG. 55 is fitted to the guide portion 20 of the outer side torque receiving portion 14 and the concave guide plate portion 55 of the other pad support portion 41 is fitted to the guide portion 20 of the inner side torque receiving portion 12 for positioning. The portion 92 is fitted between the inner side torque receiving portion 12 and the outer side torque receiving portion 14.

  As a result, the one pad spring 5 is in a state in which the pair of pad support portions 41 are arranged on both sides in the axial direction of the disk 1, and the respective guide plate portions 55 of the pair of pad support portions 41 are attached to the mounting member 2. In this state, the inner side torque receiving portion 12 and the outer side torque receiving portion 14 on the one side in the disk rotation direction are arranged on the guide portion 20.

  This one pad spring 5 is provided in the mounting member 2 such that the movement in the disk axial direction is restricted when the positioning portion 92 is fitted between the inner side torque receiving portion 12 and the outer side torque receiving portion 14. As a result, the one pad spring 5 is also restricted from moving in the disk axial direction with respect to the disk 1.

  Thus, the pad spring 5 provided on one side in the disk rotation direction is fitted to the pair of guide portions 20 as shown in FIG. 3 while being attached to the inner side torque receiving portion 12 and the outer side torque receiving portion 14. The pair of guide plate portions 55 to be joined has a shape that is recessed in the disc rotation direction. Specifically, the pair of guide plate portions 55 are recessed toward the outside in the disk rotation direction.

  One pad spring 5 is attached to the attachment member 2, and the base plate portion 54 of the guide plate portion 55 that fits into the guide portion 20 is disposed on the inner side in the disk radial direction of the guide plate portion 55. The inner wall portion 23 of the portion 20 is opposed and abutted. Further, in this state, the outer support plate portion 52 of the guide plate portion 55 is disposed on the outer side in the disk radial direction of the guide plate portion 55 and faces and contacts the outer wall portion 22 of the guide portion 20. In addition, the intermediate plate portion 53 of the guide plate portion 55 is disposed outside the guide plate portion 55 in the disk rotation direction and faces and contacts the bottom portion 21 on the back side of the guide portion 20. Thus, the concave guide plate portion 55 abuts against the concave guide portion 20.

  The outer support plate 52 is from the outer edge of the intermediate plate 53 in the radial direction of the disk, and the base plate 54 is from the inner edge of the intermediate plate 53 in the radial direction of the disk. It is extended. The outer support plate portion 52, the intermediate plate portion 53, and the base plate portion 54 are all spread along the disk axial direction. Further, the intermediate plate portion 53 is along a disc radial line passing through the center of the mounting member 2 in the disc rotation direction and the center of the disc 1, and the outer support plate portion 52 and the base plate portion 54 are in this line. Along an orthogonal plane. Therefore, the outer support plate portion 52 and the base plate portion 54 both extend perpendicular to the intermediate plate portion 53 and are parallel to each other.

  The urging plate portion 80 has a base end side extending plate portion 81 extending from the guide plate portion 55 facing the guide portion 20 in a direction away from the disc 1 in the disc axial direction, and a curl plate portion 82 extending from the base end side. The leading end of the output plate 81 extends outward in the radial direction of the disk and is folded back. The leading end extending plate 83 extends from the front end of the curl plate 82 toward the disk 1 in the direction of the disk axis. . Further, the upright portion 211 of the contact plate portion 202 is formed at a position closer to the disc 1 than the curl plate portion 82 in the disc axial direction.

  When one pad spring 5 is attached to the attachment member 2, the upright portion 211 of the contact plate portion 202 is on the opposite side of the inner opening 205 from the disk 1, and the attachment member 2 rotates in the disk rotation direction. An end edge extending along a line in the radial direction of the disk passing through the center and the center of the disk 1 rises on the opposite side to the bottom 21, and the curved portion 212 is an end opposite to the bottom 21 of the rising portion 211. The disc 1 is curved toward the disc 1 side in the disc axial direction from the edge, and the main body plate portion 213 approaches the disc 1 in the disc axial direction from the edge on the opposite side of the rising portion 211 of the curved portion 212. The tip plate 214 extends from the edge on the disk 1 side of the main body plate 213 toward the disk 1 in the disk axial direction, and the bottom toward the disk 1 side. Projecting from 1 away in the direction of disk rotation. The plate-like main body plate portion 213 extends along a line in the disk radial direction passing through the center of the mounting member 2 in the disk rotation direction and the center of the disk 1, and along this line, the curved portion 212 and the main body plate are spread. The boundary line with the part 213 and the boundary line between the main body plate part 213 and the tip plate part 214 extend. As shown in FIG. 8, the abutting plate portion 202 is disposed at a position where the bending portion 212, the main body plate portion 213, and the tip plate portion 214 overlap the bottom portion 21 in the disk axial direction.

  Both the other pad spring 5 and the attachment member 2 are attached to the inner side torque receiving portion 12 and the outer side torque receiving portion 14 on the other side in the disk rotation direction in the same manner as the one side pad spring 5. In this way, the pair of pad springs 5 are attached to the attachment member 2.

  As shown in FIG. 3, the guide plate portions 55 and the urging plates that are recessed in opposite directions of the pair of pad springs 5 and fitted into the guide portions 20 of the outer side torque receiving portions 14 on both sides of the disk rotation direction, respectively. The outer side pad 6 is supported by the portion 80 so as to be movable in the disk axial direction. The pair of pad springs 5 are recessed in opposite directions and fitted to the guide portions 20 of the inner side torque receiving portions 12 on both sides of the disk rotation direction. The side pad 6 is supported so as to be movable in the disk axial direction.

  The outer side pad 6 and the inner side pad 6 are the same common parts. The pad 6 has a mirror surface shape, and includes a back plate 101 and a lining 102 attached to one surface side of the back plate 101 as shown in FIG. As shown in FIG. 3, the back plate 101 includes a main body portion 105 and a pair of ear portions 106 that protrude in opposite directions along the width direction from both ends in the width direction of the main body portion 105. Yes. A lining 102 is attached to the main body 105 on the back plate 101.

  Further, the outer side pad 6 has an ear portion 106 on one side in the disk rotation direction with respect to the pad spring 5 on the one side in the disk rotation direction, and a distal end side extending plate portion 83 of the outer side biasing plate portion 80. Is elastically deformed so as to approach the outer side base plate portion 54, and is sandwiched between the outer side outer support plate portion 52 and the distal end side extending plate portion 83.

  In this manner, the ear portion 106 on the one side in the disk rotation direction of the pad 6 on the outer side is inserted into the guide plate portion 55 on the outer side of the pad spring 5 on the one side in the disk rotation direction. It is pressed against the outer support plate part 52 by the urging force. In other words, the outer urging plate portion 80 of the pad spring 5 on one side in the disk rotation direction urges the ear portion 106 on one side in the disk rotation direction of the outer pad 6 toward the outer side in the disk radial direction. . Thus, the ear portion 106 on one side in the disc rotation direction inserted into the guide plate portion 55 is also inserted into the guide portion 20 of the outer side torque receiving portion 14 on one side in the disc rotation direction.

  The ear portion 106 on one side in the disk rotation direction of the outer side pad 6 is guided by the fitting destination guide plate portion 55 and the biasing plate portion 80 and moves in the disk axial direction. At that time, the guide plate portion 55 guides the end surface on the outer side of the ear portion 106 in the disk rotation direction with the intermediate plate portion 53 and the end surface on the outer side in the disk radial direction of the ear portion 106 with the outer support plate portion 52. Thus, the biasing plate portion 80 guides the end surface of the ear portion 106 on the inner side in the disk radial direction.

  In addition, the outer side pad 6 is configured such that the ear portion 106 on the other side in the disc rotation direction has a distal end side extension plate portion 83 of the urging plate portion 80 on the outer side with respect to the pad spring 5 on the other side in the disc rotation direction. Is elastically deformed so as to approach the outer side base plate portion 54, and is sandwiched between the outer side outer support plate portion 52 and the distal end side extending plate portion 83.

  In this way, the ear portion 106 on the other side of the disk rotation direction of the pad 6 on the outer side is inserted into the guide plate portion 55 on the outer side of the pad spring 5 on the other side of the disk rotation direction. It is pressed against the outer support plate part 52 by the urging force. In other words, the outer urging plate portion 80 of the pad spring 5 on the other side of the disk rotation direction urges the ear portion 106 on the other side of the outer pad 6 in the disk rotation direction outward in the disk radial direction. . Thus, the ear portion 106 on the other side in the disc rotation direction inserted into the guide plate portion 55 is also inserted into the guide portion 20 of the outer side torque receiving portion 14 on the other side in the disc rotation direction.

  The ear portion 106 on the other side of the outer pad 6 in the disc rotation direction is guided by the fitting destination guide plate portion 55 and the biasing plate portion 80 and moves in the disc axial direction. At that time, the guide plate portion 55 guides the end surface on the outer side of the ear portion 106 in the disk rotation direction with the intermediate plate portion 53 and the end surface on the outer side in the disk radial direction of the ear portion 106 with the outer support plate portion 52. Thus, the biasing plate portion 80 guides the end surface of the ear portion 106 on the inner side in the disk radial direction.

  When the pad 6 on the outer side is attached to the attachment member 2 via the pair of pad springs 5 in this way, the pair of ears 106 protrudes in the disk rotation direction, in other words, both sides in the disk rotation direction. The ear portion 106 is provided so as to project. These ears 106 of the outer pad 6 and the pair of outer guides 20 of the mounting member 2 interpose the outer guide plate 55 and the urging plate 80 of the pad spring 5 therebetween. Mate.

  The mounting member 2 has a pair of guide portions 20 on the outer side that are recessed in the disc rotation direction and into which the ear portions 106 of the outer pad 6 are inserted, and these guide portions 20 each have an ear in the disc rotation direction. A bottom 21 is provided outside the portion 106 (on the side away from the center of the outer pad 6 in the disc rotation direction). The intermediate plate portion 53 of the guide plate portion 55 on the outer side of the pad spring 5 is disposed along the bottom portion 21 of the guide portion 20 that is the fitting destination, and the end portion 107 on the outer side in the disk rotation direction of the inserted ear portion 106. Opposite to.

  In the intermediate plate portion 53 on the outer side of the pair of pad springs 5, each main plate portion 201 comes into contact with the bottom portion 21 of the guide portion 20 to be fitted. In addition, the respective contact plate portions 202 of the outer side intermediate plate portion 53 of the pair of pad springs 5 are in contact with the corresponding end portions 107 of the ear portions 106 of the outer side pads 6.

  Each abutment plate portion 202 on the outer side has a rising portion 211 that rises toward the pad 6 side in the disc rotation direction, and a curved portion 212 that is closer to the disc 1 in the disc axial direction from the rising portion 211, that is, the inner side. The main body plate portion 213 is bent toward the disc 1 in the disc axial direction from the end portion on the disc 1 side of the curved portion 212 so that the disc 1 side is away from the outer pad 6 in the disc rotation direction. It extends and comes into contact with the end portion 107 of the ear portion 106 of the pad 6 on the outer side.

  Here, the main body plate 213 is also inclined so that the abutting surface portion 221 that abuts on the outer side pad 6 is further away from the outer side pad 6 in the disc rotation direction as the disc 1 side in the disc axial direction. Therefore, when the main body plate portion 213 is elastically deformed by receiving a force in the disk rotation direction from the abutting outer side pad 6, a spring force in a direction perpendicular to the abutting surface portion 221 is generated on the outer side pad 6. . This spring force is decomposed into a component facing inward in the disc rotation direction and a component facing toward the disc 1 in the disc axial direction. Therefore, the abutting plate portion 202 urges the ear portion 106 with which the outer side pad 6 abuts toward the disc 1 side in the disc axial direction, and the urging force is applied from the outer side pad 6. The greater the force received and the greater the deformation, the greater.

  Similarly to the outer side pad 6, the inner side pad 6 has an ear portion 106 on one side in the disk rotation direction of the inner side biasing plate portion 80 with respect to the pad spring 5 on the one side in the disk rotation direction. The distal side extension plate 83 is elastically deformed so as to approach the inner side base plate 54 and is sandwiched between the inner side outer support plate 52 and the distal side extension plate 83.

  In this way, the ear portion 106 on the one side in the disc rotation direction of the inner pad 6 is inserted into the guide plate portion 55 on the inner side of the pad spring 5 on the one side in the disc rotation direction. It is pressed against the outer support plate part 52 by the urging force. In other words, the inner urging plate portion 80 of the pad spring 5 on one side in the disk rotation direction urges the ear portion 106 on one side in the disk rotation direction of the inner pad 6 toward the outer side in the disk radial direction. . Thus, the ear portion 106 on one side in the disc rotation direction inserted into the guide plate portion 55 is also inserted into the guide portion 20 of the inner side torque receiving portion 12 on one side in the disc rotation direction.

  The ear portion 106 on one side in the disk rotation direction of the inner pad 6 is guided by the fitting destination guide plate portion 55 and the biasing plate portion 80 and moves in the disk axial direction. At that time, the guide plate portion 55 guides the end surface on the outer side of the ear portion 106 in the disk rotation direction with the intermediate plate portion 53 and the end surface on the outer side in the disk radial direction of the ear portion 106 with the outer support plate portion 52. Thus, the biasing plate portion 80 guides the end surface of the ear portion 106 on the inner side in the disk radial direction.

  Further, the inner side pad 6 has an ear portion 106 on the other side in the disk rotation direction with respect to the pad spring 5 on the other side in the disk rotation direction. Is elastically deformed so as to approach the inner base plate portion 54, and is sandwiched between the inner side outer support plate portion 52 and the distal end side extension plate portion 83.

  In this manner, the ear portion 106 on the other side of the disc rotation direction of the inner pad 6 is inserted into the guide plate portion 55 on the inner side of the pad spring 5 on the other side of the disc rotation direction. It is pressed against the outer support plate part 52 by the urging force. In other words, the inner urging plate portion 80 of the pad spring 5 on the other side in the disk rotation direction urges the ear portion 106 on the other side in the disk rotation direction of the inner pad 6 toward the outer side in the disk radial direction. . Thus, the ear portion 106 on the other side in the disc rotation direction inserted into the guide plate portion 55 is inserted into the guide portion 20 of the inner side torque receiving portion 12 on the other side in the disc rotation direction.

  The ear portion 106 on the other side of the inner pad 6 in the disk rotation direction is guided by the fitting destination guide plate portion 55 and the biasing plate portion 80 and moves in the disk axial direction. At that time, the guide plate portion 55 guides the end surface on the outer side of the ear portion 106 in the disk rotation direction with the intermediate plate portion 53 and the end surface on the outer side in the disk radial direction of the ear portion 106 with the outer support plate portion 52. Thus, the biasing plate portion 80 guides the end surface of the ear portion 106 on the inner side in the disk radial direction.

  When the inner pad 6 is attached to the attachment member 2 via the pair of pad springs 5 in this way, the pair of ears 106 protrudes in the disk rotation direction, in other words, both sides of the disk rotation direction. The ear portion 106 is provided so as to project. These ears 106 of the pad 6 on the inner side and the pair of guide parts 20 on the inner side of the mounting member 2 interpose the guide plate part 55 and the biasing plate part 80 on the inner side of the pad spring 5 therebetween. Mate.

  The mounting member 2 has a pair of guide portions 20 on the inner side that are recessed in the disc rotation direction and into which the ear portions 106 of the inner pad 6 are inserted, and each of these guide portions 20 has an ear in the disc rotation direction. A bottom 21 is provided outside the portion 106 (on the side away from the center of the inner pad 6 in the disc rotation direction). The intermediate plate portion 53 of the guide plate portion 55 on the inner side of the pad spring 5 is disposed along the bottom portion 21 of the guide portion 20 to be fitted, and an end portion 107 on the outer side in the disk rotation direction of the ear portion 106 to be inserted. Opposite to.

  In the intermediate plate portion 53 on the inner side of the pair of pad springs 5, each main plate portion 201 comes into contact with the bottom portion 21 of the guide portion 20 to be fitted. Further, each contact plate portion 202 of the inner side intermediate plate portion 53 of the pair of pad springs 5 contacts the corresponding end portion 107 of the ear portion 106 of the pad 6 on the inner side.

  Each abutment plate portion 202 on the inner side has a rising portion 211 rising toward the pad 6 side in the disk rotation direction, and a curved portion 212 from the rising portion 211 to the side close to the disk 1 in the disk axial direction, that is, the outer side. The main body plate portion 213 is bent toward the disc 1 in the disc axial direction from the end portion on the disc 1 side of the bending portion 212 so that the disc 1 side is away from the inner pad 6 in the disc rotation direction. It extends and comes into contact with the end portion 107 of the ear portion 106 of the pad 6 on the inner side.

  Here, in the main body plate portion 213, the contact surface portion 221 that contacts the inner pad 6 is also inclined so as to move away from the inner pad 6 in the disc rotation direction as the disc 1 side in the disc axial direction. Therefore, when the main body plate portion 213 is elastically deformed by receiving a force in the disk rotation direction from the abutting inner pad 6, a spring force in a direction perpendicular to the abutting surface portion 221 is generated on the inner pad 6. . This spring force is decomposed into a component facing inward in the disc rotation direction and a component facing toward the disc 1 in the disc axial direction. Therefore, the abutting plate portion 202 urges the ear portion 106 with which the inner side pad 6 abuts toward the disc 1 side in the disc axial direction, and the urging force is applied from the inner side pad 6. The greater the force received and the greater the deformation, the greater.

  As described above, one pad spring 5 is elastic in the disk radial direction by the urging plate portion 80 and the outer support plate portion 52 on the ear portion 106 on one side in the disk rotation direction of the pair of pads 6 on the inner side and the outer side. The other pad spring 5 supports the ear portion 106 on the other side in the disc rotation direction of the pair of pads 6 on the inner side and the outer side by the biasing plate portion 80 and the outer support plate portion 52. It is elastically supported in the disk radial direction.

  Further, as shown in FIG. 9, the contact plate 202 on one side in the disk axial direction of the pad spring 5 on one side in the disk rotation direction is connected to the end 107 of the ear portion 106 on one side in the disk rotation direction of one pad 6. The abutting plate 202 on one side in the disk axial direction of the pad spring 5 on the other side in the disk rotation direction abuts against the end 107 of the ear portion 106 on the other side in the disk rotation direction of the one pad 6. The one pad 6 is elastically supported in the disk rotation direction by contact and elastic deformation. The contact plate 202 on the other side of the disk axial direction of the pad spring 5 on the one side in the disk rotation direction comes into contact with the end 107 of the ear portion 106 on the one side in the disk rotation direction of the other pad 6 and elastically deforms. The abutting plate 202 on the other side of the disk axial direction of the pad spring 5 on the other side of the direction abuts against the end 107 of the ear portion 106 on the other side of the disk 6 in the direction of disk rotation, thereby elastically deforming. The other pad 6 is elastically supported in the disk rotation direction.

  As shown in FIG. 2, the caliper 3 has a substantially mirror-symmetric shape, and includes a caliper body 120 and a piston (not shown) that is slidably provided on the caliper body 120.

  As shown in FIG. 1, the caliper body 120 includes a cylinder portion 126 disposed on the inner side in the disc axial direction with respect to the disc 1, and a disc so as to straddle the outer circumference of the disc 1 from the outside in the disc radial direction of the cylinder portion 126. A bridge portion 127 that extends to the outer side along the axial direction, and an inner side in the radial direction of the disc from the opposite side of the cylinder portion 126 of the bridge portion 127 and is arranged on the outer side of the disc 1 in the disc axial direction. Claw portion 128. Further, as shown in FIG. 2, the caliper body 120 has a pair of pin attachment portions 131 that extend from the cylinder portion 126 to both sides in the disk rotation direction.

  In the caliper body 120, the slide pin 31 is attached to the pin attachment part 131 on one side in the disk rotation direction, and the slide pin 31 is also attached to the pin attachment part 131 on the other side in the disk rotation direction. The slide pins 31 are slidably fitted into pin insertion holes (not shown) of the pin insertion portions 13 on both sides of the mounting member 2 in the disk rotation direction. In the caliper body 120, a piston (not shown) is disposed in the cylinder portion 126 so as to be movable in the disk axis direction so as to be close to and away from the claw portion 128.

  The hydraulic fluid is introduced into the cylinder portion 126 into the disc brake 10 via a brake pipe (not shown). Then, the brake fluid pressure acts on a piston (not shown). As a result, the piston moves forward toward the disk 1, and presses the inner pad 6 disposed between the piston and the disk 1 toward the disk 1. As a result, the inner pad 6 is guided by the inner guide plate 55 and the biasing plate 80 of the pair of pad springs 5 and moves in the disc axial direction to contact the disc 1.

  Further, the caliper body 120 slides the slide pin 31 with respect to the mounting member 2 and moves in the disc axial direction by the reaction force of the pressing, and the claw portion 128 is disposed between the claw portion 128 and the disc 1. The pad 6 on the outer side is pressed toward the disk 1. As a result, the outer side pad 6 is guided by the outer side guide plate portion 55 and the biasing plate portion 80 of the pair of pad springs 5 and moves in the disc axial direction to contact the disc 1.

  In this manner, the caliper 3 presses the both sides of the disk 1 by holding the pair of pads 6 from both sides in the disk axial direction by the piston and the claw portion 128 by the operation of the piston (not shown). As a result, the caliper 3 gives a frictional resistance to the disk 1 to generate a braking force. The caliper 3 is a fist type caliper.

  During the above braking, the pad 6 contacts the disk 1 moving in the R direction on both the outer side and the inner side as shown in FIG. The side ear portion 106 comes into contact with the main plate portion 201 in contact with the bottom portion 21 and stops while increasing the amount of elastic deformation of the contact plate portion 202 on the disk delivery side. At this time, the pad 6 reduces the amount of elastic deformation of the contact portion 202 on the disk insertion side by the ear portion 106 on the disk insertion side. The pad 6 is pressed against the disk 1 with a force F1 that is stronger on the disk insertion side than the disk extraction side due to the wedge effect caused by contacting the disk 1. On the other hand, as described above, the component F2 of the spring force generated when the contact plate 202 of the pad spring 5 on the disk delivery side largely elastically deforms is directed to the disk 1 side. Will be pressed against the disk 1 side. On the other hand, the abutting plate portion 202 on the disk insertion side has a small amount of elastic deformation, and the force for pressing the disk insertion side of the pad 6 against the disk 1 side is greatly reduced. The force F1 due to As described above, the component F2 of the spring force toward the disk 1 side is generated on the disk delivery side so as to match the force F1 due to the wedge effect on the disk entry side. Suppresses the uneven surface pressure distribution.

  Patent Document 1 discloses a configuration in which a pad spring presses the pad in a direction away from the disc in the disc axial direction (configuration that functions as a return spring). By the way, the pad has a surface pressure on the disk entry side higher than that on the disk delivery side due to the wedge effect during braking. The uneven surface pressure distribution between the disk inlet side and the disk outlet side causes the generation of abnormal noise such as brake noise.

  On the other hand, the disc brake 10 of the present embodiment has a contact plate portion 202 with which the pad spring 5 contacts the end 107 of the ear portion 106 of the pad 6 on the outer side in the disk rotation direction. 202 is a rising portion 211 that rises inward in the disk rotation direction, a bending portion 212 that is bent from the rising portion 211 toward the side close to the disk 1 in the disk axial direction, and the disk 1 in a direction that approaches the disk 1 from the bending portion 212. And a main body plate portion 213 that extends so as to be located on the outer side in the disk rotation direction and contacts the end portion 107. Thus, as described above, the pad 6 is a component F2 of the spring force generated when the contact plate portion 202 of the pad spring 5 on the disk delivery side is pressed and greatly deformed by the pad 6 and directed toward the disk 1 side. The disc delivery side is pressed against the disc 1 side, and the difference from the surface pressure on the disc delivery side where the surface pressure increases due to the wedge effect is reduced. Therefore, it is possible to reduce the unevenness of the surface pressure distribution between the disk inlet side and the disk outlet side, to minimize energy loss during brake braking, and to suppress the generation of abnormal noise such as brake noise. be able to.

  Further, the spring force of the abutting plate portion 202 can mitigate the collision of the ear portion 106 of the pad 6 with the bottom portion 21 of the guide portion 20, so that the generation of a cronk sound can be suppressed.

  Further, since the curved portion 212 is disposed at a position overlapping the bottom portion 21 in the disk axial direction, the base end side of the contact plate portion 202 can be favorably supported by the bottom portion 21. Therefore, the contact plate portion 202 can be favorably deformed with respect to the main plate portion 201.

  Further, since the upright portion 211 is formed at a position closer to the disc 1 than the curl plate portion 82 in the disc axial direction, the leading side extension plate on the disc 1 side of the urging plate portion 82 relative to the curl plate portion 82 is provided. The arrangement efficiency of the contact plate portion 202 that contacts the pad 6 supported by the portion 83 can be improved.

  Here, in the embodiment, as shown in FIG. 11, the disc rotation direction outside (the disc rotation direction of the mounting member 2) is positioned on the bottom portion 21 of the guide portion 20 at a position overlapping the front end side region of the main body plate portion 213 in the disc axial direction. You may provide the recessed part 231 depressed toward the direction which leaves | separates from the center in (). As a result, the contact plate portion 202 can enter the recess 231 during deformation, and can be greatly deformed without reducing the angle. Therefore, it is possible to suppress the contact angle of the main body plate portion 213 to the ear portion 106 from becoming shallow, and the contact plate portion 202 presses the pad 6 against the disk 1 with a small contact angle. Can be suppressed.

  In the above embodiment, the pad 6 has the ears 106 on both sides of the disk rotation direction, and the pad springs 5 on both sides of the disk rotation direction have the contact plate parts 202. In any of the braking operations, it is possible to suppress unevenness of the surface pressure distribution between the disk inlet side and the disk outlet side. Note that the pad 6 has, for example, an ear 106 on the disk delivery side during forward braking of the vehicle, and only the pad spring 5 on the disk delivery side during forward braking of the vehicle has the contact plate 202. May be. That is, the pad 6 only needs to have the ear portion 106 on at least one side in the disk rotation direction, and the pad spring 5 that supports the ear portion 106 has the contact plate portion 202.

  Further, instead of the curved portion 212, a bent portion that is bent from the upright portion 211 toward the side close to the disc 1 in the disc axial direction may be used.

  The first aspect of the embodiment described above includes an attachment member that is attached to a non-rotating portion of a vehicle and is disposed across the outer peripheral side of the disc, a caliper that is slidably provided on the attachment member, and the disc A pair of pads that are pressed against both sides of the disk, and a pad spring that is attached to the mounting member and elastically supports the pair of pads, and the pair of pads protrudes from at least one side in the disk rotation direction. The mounting member has a guide part composed of a bottom part provided outside the ear part in the disk rotation direction and a pair of wall parts provided on both sides of the bottom part, The pad spring is disposed along the bottom portion and has a pad facing portion that faces an end portion of the ear portion on the outer side in the disk rotation direction, and the pad facing portion touches the end portion. The pad abutting portion has a raised portion that rises inward in the disc rotation direction, a bent portion that is bent from the raised portion toward the disc axial side, and the disc from the bent portion. An abutting portion main body extending so as to be located on the outer side in the disc rotation direction toward the disc side in a direction approaching the disc, and abutting on the end portion. Thereby, generation | occurrence | production of unusual noise can be suppressed.

  According to a second aspect, in the first aspect, the curved portion is arranged at a position overlapping the bottom portion in the disc axial direction.

  Further, according to a third aspect, in the first or second aspect, the bottom portion has a concave portion that is recessed toward the outer side in the disk rotation direction at a position overlapping the tip end side region of the abutting portion main body in the disk axial direction. Is formed.

  According to a fourth aspect, in any one of the first to third aspects, the pad spring includes a first extension portion extending in a disk axial direction from a guide facing portion facing the guide portion, and the first extension portion. A curl portion extending outwardly in the radial direction of the disk on the front end side of the extending portion and a second extending portion extending in a direction approaching the disk from the front end of the curled portion, and the pad being a disk A radial urging portion that urges radially outward is provided, and the upright portion is formed at a position closer to the disc than the curl portion in the disc axial direction.

DESCRIPTION OF SYMBOLS 1 Disc 2 Mounting member 3 Caliper 5 Pad spring 6 Pad 10 Disc brake 20 Guide part 21 Bottom part 22 Outer wall part (wall part)
23 Inner wall (wall)
53 Intermediate plate (pad facing part)
80 Biasing plate (radial urging portion)
81 Base end side extension plate part (first extension part)
82 Curl plate (curl)
83 Leading end extending plate portion 106 Ear portion 202 Contact plate portion (pad contact portion)
211 Upright part 212 Curved part (curved part)
213 Body plate (contact body)
231 recess

Claims (4)

An attachment member that is attached to a non-rotating part of the vehicle and arranged across the outer periphery of the disk;
A caliper provided slidably on the mounting member;
A pair of pads pressed against both sides of the disc;
A pad spring attached to the attachment member and elastically supporting the pair of pads;
The pair of pads have ears protruding on at least one side in the disk rotation direction,
The attachment member has a guide portion composed of a bottom portion provided outside the ear portion in the disk rotation direction and a pair of wall portions provided on both sides of the bottom portion,
The pad spring is disposed along the bottom portion, and has a pad facing portion facing the outer end of the ear portion in the disk rotation direction,
The pad facing portion has a pad contact portion that contacts the end portion,
The pad contact portion is
An upright standing up toward the inside of the disk rotation direction,
A curved portion bent from the upright portion toward the side close to the disk in the disk axial direction;
An abutting portion main body extending from the curved portion toward the disc in a direction approaching the disc so as to be positioned on the outer side in the disc rotation direction and abutting on the end portion;
A disc brake comprising:   The disc brake according to claim 1, wherein the curved portion is disposed at a position overlapping the bottom portion in the disc axial direction.   3. The recess according to claim 1, wherein a concave portion that is recessed outward in the disk rotation direction is formed at a position overlapping the tip side region of the abutting section main body in the disk axial direction. Disc brake.   The pad spring includes a first extending portion extending in a disc axial direction from a guide facing portion facing the guide portion, and a curled portion extending outwardly in the disc radial direction on the tip end side of the first extending portion, and turned back And a second urging portion extending in a direction approaching the disc from the tip of the curl portion, and having a radial urging portion for urging the pad outward in the radial direction of the disc. 4. The disc brake according to claim 1, wherein the upper portion is formed at a position closer to the disc than the curl portion in the disc axial direction. 5.

Images