JP6118697B2 - Disc brake - Google Patents

Description

  The present invention relates to a disc brake.

  In disc brakes, the increase in sliding resistance over time may cause so-called friction pad dragging, in which the friction pad does not move away from the disc even when the press of the friction pad by the caliper is released. In order to suppress such dragging of the friction pad, there is a pad spring that presses the friction pad provided with a rib so as to reduce the contact area with the friction pad (see, for example, Patent Document 1).

JP 2007-271064 A

  In the above-described disc brake, since the contact area between the friction pad and the rib is small, the surface pressure between them becomes high. For this reason, the roughness of the contact part of a friction pad and a rib becomes coarse over time, and the sliding property of a friction pad may fall after all.

  Accordingly, an object of the present invention is to provide a disc brake capable of stably improving the sliding performance of the friction pad and suppressing the drag of the friction pad.

  In order to achieve the above object, according to the present invention, an opening groove that opens to face the pad spring is formed on at least one of the inner side and the outer side in the disk radial direction of the fitting portion of the back plate of the friction pad. In this configuration, an elastic member stored in the opening groove and an abutting member disposed between the elastic member and the pad spring and having lower friction than the back plate are provided.

  According to the disc brake of the present invention, drag of the friction pad can be suppressed.

It is a top view which shows the disc brake of 1st Embodiment which concerns on this invention. It is a front view which shows the disc brake of 1st Embodiment which concerns on this invention. 1 is a side sectional view showing a disc brake of a first embodiment according to the present invention. It is a perspective view which shows the pad guide of the disc brake of 1st Embodiment which concerns on this invention. The friction pad of the disc brake of 1st Embodiment which concerns on this invention is shown, (a) is a rear view, (b) is a front view, (c) is a side view. It is XX sectional drawing of Fig.5 (a). It is sectional drawing which shows the state which supported the friction pad of the disc brake of 1st Embodiment which concerns on this invention to the ditch | groove. It is a fragmentary sectional view showing the modification of the fitting part of the disc brake of a 1st embodiment concerning the present invention. It is a fragmentary perspective view which shows the pad guide of the disc brake of 2nd Embodiment which concerns on this invention. It is a partial back view which shows the friction pad of the disc brake of 2nd Embodiment which concerns on this invention. It is a fragmentary sectional view showing the state where the friction pad of the disc brake of a 2nd embodiment concerning the present invention was supported by the ditch.

“First Embodiment”
1st Embodiment which concerns on this invention is described with reference to FIGS. The disc brake 1 according to the first embodiment shown in FIGS. 1 to 3 is attached to a vehicle such as an automobile, and imparts frictional resistance to a disc 10 that rotates together with a wheel (not shown) to be braked to provide the wheel brake. Rotation is braked. In the following description, unless otherwise specified, the description will be made with the state of being attached to the vehicle. The rotation direction is referred to as the disk rotation direction. Further, the entrance side of the rotation direction of the disk 10 when the vehicle moves forward (arrow R in FIG. 2) is referred to as the disk entry side, and the rotation direction of the disk 10 when the vehicle moves forward (arrow R in FIG. 2). The exit side is called the disk delivery side.

  As shown in FIGS. 1 to 3, the disc brake 1 is disposed on the both sides in the axial direction of the disc 10, the mounting member 11 attached to the non-rotating portion of the vehicle across the disc 10, and the disc 10. And a pair of friction pads 12, 12 supported by the mounting member 11, and a caliper 14 that presses the friction pads 12, 12 against the disk 10.

  As shown in FIGS. 1 and 2, the attachment member 11 includes a carrier 15 and a pair of pad guides 16. The carrier 15 is an integrally molded product having a mirror-symmetric shape, and includes a pair of disk path portions 20, 20, a mounting base portion 21 shown in FIG. 2, and an outer beam portion 22.

  The pair of disk path portions 20 and 20 are arranged apart from each other in the disk rotation direction. The mounting base portion 21 extends in the disc rotation direction, and connects the pair of disc path portions 20 and 20 on one axial side of the disc 10. The outer beam portion 22 extends in the disc rotation direction, and connects the pair of disc path portions 20 and 20 on the other axial side of the disc 10. A pair of mounting holes 24, 24 are formed in the mounting base portion 21 at both end positions in the disk rotation direction, and the carrier 15 is a non-rotating portion of the vehicle by a fastening member inserted through the mounting holes 24, 24. Will be attached to.

  In the carrier 15, the mounting base portion 21 is disposed on the inner side in the vehicle width direction of the vehicle (hereinafter referred to as the inner side) than the disk 10. In addition, the outer beam portion 22 of the carrier 15 is disposed outside the disc 10 in the vehicle width direction of the vehicle (hereinafter referred to as the outer side). As shown in FIG. 1, the carrier 15 is disposed so that the pair of disk path portions 20, 20 cross the outer diameter side of the disk 10 in the disk axial direction.

  As shown in FIG. 2, the pair of disc path portions 20, 20 are formed with recesses 27, 27 that are recessed along the disc rotation direction on the outer side from the disc 10. The concave portion 27 formed in the disk path portion 20 on the disk supply side is recessed in a direction away from the disk path portion 20 on the disk supply side, and the concave portion 27 formed in the disk path portion 20 on the disk supply side is a disk. It is recessed in a direction away from the disk path portion 20 on the entry side. That is, the outer side recesses 27 are recessed in a direction away from each other along the disk rotation direction. In the pair of disc path portions 20 and 20, recesses (not shown) similar to the recesses 27 and 27 on the outer side are formed on the inner side of the disc 10.

  In the pair of pad guides 16, the pad guide 16A on the disk entry side and the pad guide 16B on the disk delivery side have a substantially common configuration. The pad guide 16A differs from the pad guide 16B in that the pad guide 16A has a circumferential urging portion 46 that presses the friction pads 12 and 12 toward the disk delivery side. Hereinafter, the pad guide 16A will be described. As shown in FIG. 4, the pad guide 16 </ b> A has a pair of concave portions 31, 31, a connecting portion 32 that connects these concave portions 31, 31, and a side opposite to the connecting portion 32 of the concave portions 31, 31. It has a pair of pad springs 33, 33 provided. Each of the pair of concave portions 31, 31 has an outer plate portion 35 on the connecting portion 32 side, an inner plate portion 36 on the opposite side of the connecting portion 32, and a side plate portion 37 that connects them. Note that the pad springs 33 and 33 shown in FIG. 4 are not in a natural state, but show a state in which the friction pads 12 and 12 are fitted for convenience of explanation.

  One pad spring 33 extends from the end of the inner plate portion 36 of the one recessed portion 31 on the side opposite to the other recessed portion 31 to the side opposite to the other recessed portion 31 while temporarily extending to the connecting portion 32 side. And a urging portion 42 that enters from the folded portion 41 into one concave portion 31 and extends in the direction of the other concave portion 31. The other pad spring 33 extends from the end of the inner plate portion 36 of the other recessed portion 31 on the side opposite to the one recessed portion 31 to the side opposite to the one recessed portion 31 while temporarily extending to the connecting portion 32 side. And a urging portion 42 that extends from the folded portion 41 into the other recessed portion 31 and extends in the direction of the one recessed portion 31.

  From the inner plate portions 36, 36 of the pad guide 16A, circumferential urging portions 46, 46 extending in the disk radial direction are formed. The circumferential urging portions 46 and 46 press the friction pads 12 and 12 toward the disk delivery side. As a result, the friction pads 12 and 12 are turned right to the pad guide 16B on the disk delivery side, and the brake pads squeal without moving the friction pads 12 and 12 to the disk delivery side at the start of braking. It is possible to suppress so-called pad cronk noise. The circumferential urging portions 46 are not provided in the pad guide 16B on the disk delivery side.

  As shown in FIG. 2, one pad guide 16A is attached to the disk path portion 20 on the disk insertion side, and the other pad guide 16B is turned in the opposite direction to the disk guide 16 on the disk insertion side. It is attached to the disk path unit 20 on the side.

  Each of the pad guides 16A and 16B is in a state in which the connecting portion 32 is disposed on the outer side in the disk radial direction and the pad spring 33 is disposed on the inner side in the disk radial direction. In the pad guide 16A disposed on the disk entry side, one concave portion 31 is fitted in the recess 27 on the outer side of the disk path part 20 on the disk entry side. 11 is formed with a groove 45 on the disk entry side and the outer side that is recessed in the disk rotation direction. Specifically, the groove 45 on the disk insertion side and the outer side is formed by the outer plate portion 35 and the side plate portion 37 of the outer concave portion 31 of the pad guide 16A on the disk insertion side, and the inside of the concave portion 31. And an outer side pad spring 33 extending in the direction. In the same manner, the pad guide 16 on the disk entry side is fitted into the recess on the inner side (not shown) of the disk path part 20 on the disk entry side so that the other concave portion 31 is fitted. A concave groove (not shown) on the disk insertion side and the inner side that is recessed in the disk rotation direction is formed in the member 11.

  The pad guide 16B disposed on the disk delivery side has one concave portion 31 fitted into the outer side recess 27 of the disk delivery side disk path portion 20, thereby allowing the mounting member 11 to A groove 45 on the disk delivery side and the outer side that is recessed in the disk rotation direction is formed. Specifically, the groove 45 on the disk delivery side and the outer side is formed by the outer plate portion 35 and the side plate portion 37 of the outer concave portion 31 of the pad guide 16B on the disk delivery side, and the inside of the concave portion 31. And an outer side pad spring 33 extending in the direction. Similarly, in the pad guide 16B on the disk delivery side, the other concave portion 31 is fitted into a recess on the inner side of the disk delivery part 20 on the disk delivery side (not shown). A concave groove (not shown) on the disk delivery side and the inner side that is recessed in the disk rotation direction is formed in the member 11.

  The outer friction pad 12 is supported by a pair of outer grooves 45, 45 recessed in the disk rotation direction formed by the pair of pad guides 16A, 16B so that the outer friction pad 12 can move in the disk axial direction. The inner friction pads 12 are supported by a pair of recesses on the inner side (not shown) that are recessed in the disk rotation direction formed by the pad guides 16A and 16B so as to be movable in the disk axial direction.

  The outer side friction pad 12 and the inner side friction pad 12 are common parts. As shown in FIG. 5, the friction pad 12 has a mirror surface shape, and includes a back plate 51 and a lining 52 supported by the back plate 51. The back plate 51 is opposite to each other along the width direction from both ends of the main plate portion 53 to which the lining 52 is attached and the width direction of the main plate portion 53 (the left-right direction in FIGS. 5A and 5B). It has a pair of protruding ears 54, 54. The pair of ear portions 54, 54 are formed near one side of the main plate portion 53 in the height direction (the vertical direction in FIGS. 5A to 5C).

  In the pair of ear portions 54, 54, opening grooves 56, 56 are formed on the surfaces 55, 55 on both sides in the height direction of the friction pads 12. One opening groove 56 is the center of one surface 55 in the thickness direction of the friction pad 12 (the left-right direction in FIG. 6) as shown in FIG. 6, and as shown in FIGS. 4 (a) and 4 (b). Further, the friction pad 12 is formed in a predetermined intermediate range in the width direction. As shown in FIG. 6, one opening groove 56 is recessed from one surface 55 toward the other surface 55, and opens in the direction opposite to the other surface 55. The other opening groove 56 is the center in the thickness direction of the friction pad 12 on the other surface 55 as shown in FIG. 6, and the width direction of the friction pad 12 as shown in FIGS. 4 (a) and 4 (b). The intermediate predetermined range is formed. The other opening groove 56 is recessed from the other surface 55 toward the one surface 55, and opens in the direction opposite to the one surface 55.

  As shown in FIG. 6, each of the opening grooves 56 and 56 includes flat wall surface portions 57 and 57 that are orthogonal to the thickness direction of the friction pad 12 and flat bottom surface portions that are orthogonal to the height direction of the friction pad 12. 58.

  Each of the opening grooves 56 and 56 is provided with an elastic member 61 that is stored so as to contact the bottom surface portion 58 and a resin member 62 that is disposed on the opposite side of the bottom surface portion 58 of the elastic member 61. . The elastic member 61 is made of an elastic material such as rubber such as EPDM, and has a plate shape with a constant width. The resin member 62 is a contact member made of a material having a lower friction than at least the back plate 51, and is made of a low friction material such as PTFE. The resin member 62 includes a narrow portion 63 that fits to the wall surface portions 57 of the opening groove 56, and a wide portion 64 that is disposed outside the opening groove 56 and can contact the surface 55. The width of the narrow portion 63, that is, the length in the thickness direction of the friction pad 12 is shorter than the length of the wide portion 64 in the same direction. The resin member 62 is fixed to the elastic member 61 by bonding or the like, and the elastic member 61 is press-fitted into the wall surface portions 57 and 57 of the opening groove 56 with an allowance. The resin member 62 is movable in the height direction of the friction pad 12 with respect to the opening groove 56. Although the elastic member 61 is press-fitted into the opening groove 56, it can be removed from the opening groove 56 if it is pulled out with a predetermined force.

  Then, as shown in FIG. 4, a pair of elastic members 61, 61 and a pair of resin members 62, 62 are attached to one ear portion 54 to form one fitting portion 67, and the other ear portion 54. In addition, a pair of elastic members 61, 61 and a pair of resin members 62, 62 are mounted to form the other fitting portion 67. As shown in FIG. 2, the friction pad 12 in this state is formed in the groove 45 on the disk insertion side and the outer side in one fitting portion 67, and on the disk feeding side and the outer side in the other fitting portion 67. Each of the grooves 45 is slidably fitted.

  At this time, opening grooves 56 and 56 are formed in both the inner and outer surfaces 55 and 55 in the disk radial direction, as shown in FIG. 7, in the fitting portion 67 on the disk insertion side of the friction pad 12 on the outer side. Is done. Of these opening grooves 56, 56, the opening groove 56 on the inner side in the disk radial direction opens facing the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk insertion side, and is on the outer side in the disk radial direction. The opening groove 56 is opposed to the outer plate portion 35 on the outer side of the pad guide 16 on the disk insertion side.

  Further, at this time, the outer friction pad 12 is such that the resin member 62 on the outer side in the disk radial direction is connected to the elastic member 61 on the outer side in the disk radial direction and the pad guide on the disk inlet side in the fitting portion 67 on the disk insertion side. 16 between the outer plate portions 35 on the outer side. The resin member 62 on the outer side in the disk radial direction comes into contact with the outer plate portion 35 on the outer side of the pad guide 16 on the disk insertion side. Further, at this time, the outer friction pad 12 is such that the resin member 62 on the inner side in the disk radial direction is connected to the elastic member 61 on the inner side in the disk radial direction and the pad guide on the disk inlet side in the fitting portion 67 on the disk insertion side. It is arranged between the urging portions 42 of the pad springs 33 on the outer side of the sixteen. The resin member 62 on the inner side in the disk radial direction contacts the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk insertion side. The resin members 62 and 62 are sandwiched between the outer side outer plate portion 35 of the pad guide 16 on the disk insertion side and the urging portion 42 of the pad spring 33 on the outer side, and are fitted to the fitting portion on the disk insertion side. 67 elastic members 61, 61 are compressed and deformed.

  Therefore, the biasing portion 42 of the outer pad spring 33 of the pad guide 16 on the disk insertion side is formed to extend in the disk axial direction, and the fitting portion 67 on the disk insertion side of the outer friction pad 12. Is urged outward in the disk radial direction. The fitting portion 67 on the disk insertion side of the outer friction pad 12 has an elastic member 61 on the inner side in the disk radial direction and a biasing portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk insertion side. The resin member 62 on the inner side in the disk radial direction is disposed so as to abut against the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk insertion side.

  Similarly, in the fitting portion 67 on the disk delivery side of the outer friction pad 12, opening grooves 56 are formed on both the inner and outer surfaces 55, 55 in the disk radial direction, and these opening grooves are formed. 56 and 56, the opening groove 56 on the inner side in the disk radial direction opens facing the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk delivery side, and the opening groove on the outer side in the disk radial direction. 56 opens to the outer plate portion 35 on the outer side of the pad guide 16 on the disk delivery side.

  At this time, the outer friction pad 12 is such that the resin member 62 on the outer side in the disk radial direction is connected to the elastic member 61 on the outer side in the disk radial direction and the pad guide on the disk outlet side in the fitting portion 67 on the disk delivery side. 16 between the outer plate portions 35 on the outer side. The resin member 62 on the outer side in the disk radial direction comes into contact with the outer side plate portion 35 on the outer side of the pad guide 16 on the disk delivery side. Further, at this time, the outer friction pad 12 is such that the resin member 62 on the inner side in the disk radial direction is connected to the elastic member 61 on the inner side in the disk radial direction and the pad guide on the disk outlet side in the fitting portion 67 on the disk outlet side. It is arranged between the urging portions 42 of the pad springs 33 on the outer side of the sixteen. The resin member 62 on the inner side in the disk radial direction contacts the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk delivery side. The resin members 62 and 62 are sandwiched between the outer side outer plate portion 35 of the pad guide 16 on the disk delivery side and the urging portion 42 of the pad spring 33 on the outer side, and are fitted to the fitting portion on the disk delivery side. 67 elastic members 61, 61 are compressed and deformed.

  Therefore, the urging portion 42 of the outer pad spring 33 of the pad guide 16 on the disk delivery side is formed to extend in the disk axial direction, and the fitting portion 67 on the disk delivery side of the friction pad 12 on the outer side. Is urged outward in the disk radial direction. The fitting portion 67 on the disk delivery side of the outer friction pad 12 has an elastic member 61 on the inner side in the disk radial direction and a biasing portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk delivery side. The resin member 62 on the inner side in the radial direction of the disk is disposed so as to contact the urging portion 42 of the pad spring 33 on the outer side of the pad guide 16 on the disk delivery side.

  As described above, the outer friction pad 12 is supported by the mounting member 11 as shown in FIG. In this state, the outer friction pad 12 has a pair of fitting portions 67 and 67 provided at the end portions extending in the disk rotation direction and slidably fitted into the concave grooves 45 and 45. The inner friction pad 12 is also supported by the mounting member 11 in the same manner.

  As shown in FIG. 1, the caliper 14 is supported on the carrier 15 of the mounting member 11 by a pair of slide pins 68, 68 provided on both sides of the disk rotation direction so as to be slidable in the disk axis direction. As shown in FIG. 3, the caliper 14 has a cylindrical portion 70 and a bottom portion 71 that closes one end of the cylindrical portion 70. The caliper 14 has an opening 72 facing the disc 10 of the inner friction pad 12 on the opposite side. A bottom cylindrical cylinder portion 73, a bridge portion 74 extending from one side in the radial direction of the cylinder portion 73 across the outer periphery of the disk 10, and an outer side from the opposite side to the cylinder portion 73 of the bridge portion 74 It has a caliper body 76 having a claw portion 75 extending so as to face the disk 10 of the friction pad 12 on the side opposite to the opposite side. Hereinafter, the inner peripheral surface of the cylindrical portion 70 is referred to as a bore 77.

  A central through hole 81 that penetrates along the axial direction of the bore 77 is formed in the bottom portion 71 of the caliper main body 76 at a central position of the bore 77, and is positioned outside the central through hole 81 in the radial direction of the bore 77. A pin hole 82 is formed from the bore 77 side to a predetermined depth position. A cylindrical stop pin 83 is fitted and fixed in the pin hole 82. The central through hole 81 has a stepped shape in which the end on the bore 77 side has a larger diameter than the other part.

  In the bore 77, a bottom hole 84 having a constant diameter is formed on the most bottom 71 side, and a medium diameter hole 85 having a diameter larger than that of the bottom hole 84 is formed coaxially on the opening 72 side of the bottom hole 84. ing. An annular engagement groove 86 having a diameter larger than that of the medium diameter hole 85 is coaxially formed at an intermediate position in the axial direction of the medium diameter hole 85.

  The bore 77 has a large diameter hole 87 coaxially formed on the opening 72 side with respect to the medium diameter hole 85, and is larger than the large diameter hole 87. A sliding hole 88 having a smaller diameter than the large diameter hole 87 and a larger diameter than the medium diameter hole 85 is formed on the 72 side. Further, an annular seal groove 89 having a diameter larger than that of the slide hole 88 is coaxially formed in the bore 77 in the vicinity of the end of the slide hole 88 on the opening 72 side. An annular boot groove 90 having a diameter larger than that of the sliding hole 88 is coaxially formed on the opening 72 side of 89.

  Further, the caliper 14 is formed in a cylindrical shape with a lid, and a piston 95 slidably inserted into a sliding hole 88 in the cylinder portion 73 with the lid side facing the friction pad 12 side, and a seal groove of the cylinder portion 73 89, an annular piston seal 96 that seals the gap between the piston 95 and the bore 77, one end is fitted into the boot groove 90 of the cylinder portion 73, and the other end is fitted to the outer peripheral portion of the piston 95. And a stretchable boot 97.

  The caliper 14 slides the piston 95 in the sliding hole 88 of the cylinder part 73 by the brake hydraulic pressure introduced between the cylinder part 73 and the piston 95 so that the friction pad 12 on the inner side from the cylinder part 73 is moved. Project in the direction. Accordingly, the pair of friction pads 12 and 12 are pressed from both sides by the piston 95 and the claw portion 75, and the friction pads 12 and 12 are pressed against the disk-shaped disk 10 (described later).

  During normal braking by a depressing operation on the brake pedal, the piston 95 is protruded from the cylinder portion 73 toward the claw portion 75 by the brake fluid pressure introduced from the master cylinder (not shown) into the cylinder portion 73. The friction pads 12 and 12 are pressed against the disk 10 to generate a braking force. In the cylinder portion 73, a pair of friction is generated by mechanically propelling the piston 95 instead of such brake hydraulic pressure. A propulsion mechanism 101 that presses the pads 12 and 12 against the disk 10 to generate a braking force is disposed. The propulsion mechanism 101 is locked in the cylinder portion 73 by a locking member 103 and a spacer 104 that are engaged with an engagement groove 86 formed in the cylinder portion 73.

  The propulsion mechanism 101 includes a ball and ramp mechanism 102 that is disposed in the cylinder portion 73 of the caliper body 76 with a part protruding outward from the central through hole 81 of the bottom portion 71. The ball and ramp mechanism 102 includes a fixed ramp member 105 disposed in the cylinder portion 73 and abutting against the bottom portion 71, a ball 106 provided on the opposite side of the bottom portion 71 of the fixed ramp member 105, and the ball 106 as a fixed ramp. A moving ramp member 107 held between the members 105 is provided.

  The fixed ramp member 105 has a through hole 111 that penetrates in the axial direction in the center in the radial direction, and a stop hole 112 that penetrates in the axial direction also at a position outside the radial through hole 111. Has been. Further, the fixed ramp member 105 is formed with a ramp groove 113 whose depth varies depending on the position in the circumferential direction on the side opposite to the bottom 71, and a projection 114 protruding radially outward is formed on the outer peripheral surface. ing. When the fixed ramp member 105 abuts against the bottom portion 71, the locking pin 83 fitted into the pin hole 82 of the bottom portion 71 is inserted into the rotation stopping hole 112. To prevent rotation.

  The moving ramp member 107 includes a shaft portion 121 and a disc portion 122 that is coaxial with the shaft portion 121 and extends in the radial direction from one end of the shaft portion 121, and is located on the shaft portion 121 side of the disc portion 122. A ball holding recess 123 is formed on the surface. In the shaft portion 121 of the moving ramp member 107, a serration 125 is formed over the entire circumference on the tip end side, and a male screw 126 is formed on the tip end side further than the serration 125.

  The moving ramp member 107 allows the shaft portion 121 to be inserted into the through hole 111 of the fixed ramp member 105 while the ball 106 is accommodated in the ball holding recess 123 in a state where the ball 106 is disposed in the ramp groove 113 of the fixed ramp member 105. Then, the shaft portion 121 is further inserted into the central through hole 81 of the bottom portion 71 so as to protrude outward from the bottom portion 71. Here, the collar 128 and the O-ring 129 are fitted into the central through hole 81 of the bottom 71, and the moving ramp member 107 is inserted into the O-ring 129 and the collar 128 at the shaft 121. The O-ring 129 seals the gap between the moving ramp member 107 and the cylinder portion 73.

  The serration 125 and the male screw 126 of the shaft portion 121 of the moving ramp member 107 protrude outward from the cylinder portion 73, the lever 131 is fitted and fixed to the serration 125, and the nut 132 is screwed to the male screw 126. ing. The lever 131 is non-rotatably fitted to the shaft portion 121 of the moving ramp member 107 by the serration 125, and when the nut 132 is fastened to the shaft portion 121, the lever 131 is fixed integrally to the moving ramp member 107. A shaft cover 133 is fitted to the outside of the bottom portion 71 of the cylinder portion 73, and this shaft cover 133 is fitted to the shaft portion 121 and abuts against the surface of the lever 131 on the cylinder portion 73 side.

  As described above, the lever 131 is integrally coupled to the moving ramp member 107 outside the cylinder portion 73. When an operation member including a parking brake lever or a parking brake pedal provided in the driver's cab is operated and the lever 131 receives a rotation input, the ball and ramp mechanism 102 is operated by the moving ramp member 107 coupled to the lever 131. It will rotate together with 131. In accordance with the rotation of the moving ramp member 107, the ball 106 held in the ball holding recess 123 moves in the circumferential direction in the ramp groove 113 of the fixed ramp member 105 so that the moving ramp member 107 is moved in the axial direction. It will move. That is, the ball and ramp mechanism 102 converts the rotational motion of the lever 131 into the linear motion of the moving ramp member 107. As shown in FIG. 1, a cable guide 134 that supports a cable (not shown) that operates the lever 131 is attached to the bottom 71 of the cylinder portion 73.

  As shown in FIG. 3, the propulsion mechanism 101 has an annular sliding plate disposed in the cylinder portion 73 on the side opposite to the shaft portion 121 of the disc portion 122 of the moving ramp member 107 of the ball & ramp mechanism 102. 141 and a push rod 142 that is disposed on the opposite side of the disc portion 122 of the sliding plate 141 and that moves in the axial direction of the cylinder portion 73 by receiving the direct-acting pressing force of the moving ramp member 107. ing. That is, the push rod 142 is disposed in the cylinder portion 73 and moves in the same direction by the linear motion of the ball and ramp mechanism 102.

  The push rod 142 has substantially the same diameter as the end surface of the disc portion 122 of the moving ramp member 107 opposite to the shaft portion 121, and receives a direct-acting pressing force of the moving ramp member 107 via the sliding plate 141. It has a plate-like flange portion 145 and a screw shaft portion 147 formed with a male screw 146 that protrudes in the shape of a shaft from the center of the flange portion 145 to the side opposite to the moving ramp member 107. The push rod 142 is formed with a positioning protrusion 148 that protrudes opposite to the screw shaft portion 147 at the center of the flange portion 145. The positioning projection 148 is fitted to the inner periphery of the sliding plate 141 when the push rod 142 holds the sliding plate 141 between the push rod 142 and the moving ramp member 107, so that the sliding plate 141 is centered. To position and hold.

  The propulsion mechanism 101 is interposed between a cover member 151 provided so as to cover a part of the push rod 142, a flange portion 145 of the push rod 142, and the cover member 151, and the push rod 142 is inserted into the ball and ramp mechanism. And a push rod biasing spring 152 that presses in the direction of 102. In other words, the cover member 151 holds the push rod biasing spring 152 with the push rod 142. The cover member 151 and the push rod biasing spring 152 are also arranged in the cylinder portion 73.

  The cover member 151 has a cup shape having an annular lid portion 155 and a body portion 156 extending from the outer peripheral edge of the annular lid portion 155 to one side in the axial direction. A locking piece 157 that protrudes radially outward and is locked to the locking member 103 is formed at an intermediate position in the axial direction of the body 156, and is opposite to the annular lid 155 of the body 156. On the side, a regulation groove 158 for fitting the projection 114 of the fixed lamp member 105 is formed.

  As described above, the cover member 151 is locked to the bottom 71 side of the locking member 103 held in the engagement groove 86 of the cylinder portion 73 in the locking piece portion 157, and as a result, the opening 72. Movement in the direction of is controlled. Further, the cover member 151 is restricted from rotating with respect to the cylinder portion 73 by fitting the protrusion 114 of the fixed ramp member 105 into the restriction groove 158.

  The push rod 142 described above is restricted in rotation with respect to the cover member 151 by a rotation restriction mechanism (not shown) and can move in the axial direction. Therefore, when receiving the direct acting pressure of the moving ramp member 107, The screw shaft portion 147 transmits the direct acting pressing force of the moving ramp member 107 in a state where the rotation with respect to the cylinder portion 73 is restricted, and outputs the direct acting force.

  The propulsion mechanism 101 includes a substantially cylindrical clutch member 162 that is disposed in the cylinder portion 73 and is screwed to the male screw 146 of the screw shaft portion 147 of the push rod 142 with a female screw 161 formed on the inner diameter side. Yes. The clutch member 162 is formed with a fitting head 164 fitted to the piston 95 on the distal end side, and a pressing flange portion 165 extending in the radial direction adjacent to the fitting head 164 in the axial direction is formed. Has been. The outer peripheral portion of the pressing flange portion 165 on the side of the fitting head 164 is formed in a tapered shape, and the clutch member 162 presses the piston 95 in the axial direction at this portion. A ring-shaped clutch member seal 166 is held on the fitting head 164 of the clutch member 162. The clutch member seal 166 seals a gap between the fitting head 164 of the clutch member 162 and the piston 95. In the clutch member 162, the end on the fitting head 164 side in the axial direction of the inner peripheral portion where the female screw 161 is formed is closed by a lid 167.

  Here, when the moving ramp member 107 is linearly moved to the push rod 142 side by rotating the moving ramp member 107 of the ball and ramp mechanism 102, the push rod 142 is pressed by the moving ramp member 107 and the axial direction of the push rod 142 is increased. The clutch member 162 is linearly moved in the axial direction by being pressed by the push rod 142, and the clutch member 162 forcibly slides the piston 95 toward the friction pad 12 with respect to the cylinder portion 73. . That is, the clutch member 162 transmits the direct-acting pressing force of the moving ramp member 107 to the piston 95.

  The male screw 146 of the screw shaft portion 147 of the push rod 142 and the female screw 161 of the clutch member 162 have a clearance that can move in the axial direction by a predetermined amount without rotating with each other.

  The propulsion mechanism 101 has an adjustment mechanism 171 that adjusts the position of the clutch member 162 and the push rod 142 in the cylinder portion 73. The adjustment mechanism 171 is supported between the piston 95 and the pressing flange portion 165 of the clutch member 162 by a C-shaped retaining ring 172 that is locked to the inner peripheral portion of the piston 95, and the piston 95 is a cylinder portion. When moving in the axial direction by the brake fluid pressure introduced into 73, the push rod 142 which is substantially stopped is moved in the axial direction by following the piston 95 while rotating the clutch member 162. Let The adjustment mechanism 171 does not rotate the clutch member 162 relative to the push rod 142 when the push rod 142 moves linearly in the axial direction. As a result, the male screw 146 and the female screw 161 of the screw shaft portion 147 As a result, the clutch member 162 is linearly moved integrally with the push rod 142.

  In the disc brake 1 having such a configuration, when a parking brake lever or a parking brake pedal (not shown) is operated, when the lever 131 rotates and the moving ramp member 107 of the ball and ramp mechanism 102 rotates, the moving ramp member 107 The ball 106 is moved in the ramp groove 113 of the fixed ramp member 105, and is pushed by the ball 106 to move linearly. Then, the push rod 142 is pressed by the moving ramp member 107, and moves in the direction of the disk 10 without rotating with respect to the cylinder portion 73. Then, the clutch member 162 moves integrally with the push rod 142 and moves the piston 95 in the direction of the disk 10, thereby moving the inner friction pad 12 in the disk axis direction and pressing it against the disk 10. In addition, the caliper body 76 moves to the inner side so that the claw 75 moves to the disk 10 side by the reaction force of this pressing, and the outer friction pad 12 moves in the disk axial direction to press the disk 10. .

  From this state, when the lever 131 is rotated in the direction opposite to the above, the piston 95 is separated from the disk 10 by the roll back by the piston seal 96. Then, the inner friction pad 12, the outer friction pad 12 and the claw portion 75 move in the disk axial direction due to the vibration of the disk 10 and the like, and are separated from the disk 10, respectively.

  On the other hand, when the brake fluid pressure is introduced between the cylinder portion 73 and the piston 95 by a brake operation with a normal brake pedal, the fluid pressure acts on the piston 95 with respect to the pressure receiving area by the piston seal 96 and the disk 10 However, the hydraulic pressure also acts on the clutch member 162 with respect to the pressure receiving area by the clutch member seal 166 to generate a propulsive force in the direction of the disk 10. In addition, the piston 95 is pushed by moving in the axial direction without rotating by the amount of the screwing clearance of the male screw 146 of the screw shaft portion 147 of the push rod 142.

  When the brake fluid pressure is further introduced into the cylinder portion 73 and becomes equal to or higher than a predetermined fluid pressure, the clutch member 162 is pressed against the piston 95 by the fluid pressure acting on the clutch member 162, and the fluid pressure is applied to the piston 95. Acts to generate a driving force in the direction of the disk 10, and hydraulic pressure also acts on the clutch member 162 to generate a driving force in the direction of the disk 10. Then, the clutch member 162 moves and moves the piston 95 in the direction of the disk 10, thereby moving the inner friction pad 12 in the disk axial direction and pressing it against the disk 10. In addition, the caliper body 76 moves to the inner side so that the claw 75 moves to the disk 10 side by the reaction force of this pressing, and the outer friction pad 12 moves in the disk axial direction to press the disk 10. .

  When the brake hydraulic pressure is reduced from this state, the piston 95 is separated from the disk 10 by the rollback by the piston seal 96. Then, the inner friction pad 12, the outer friction pad 12 and the claw portion 75 move in the disk axial direction due to the vibration of the disk 10 and the like, and are separated from the disk 10, respectively.

  When the outer friction pad 12 moves in the disk axial direction as described above, the resin member 62 on the outer side in the disk radial direction of the fitting portion 67 on the disk insertion side is the outer side of the pad guide 16 on the disk insertion side. The resin member 62 inside the disk radial direction of the fitting portion 67 on the disk insertion side slides on the pad spring 33 on the outer side of the pad guide 16 on the disk insertion side. Further, the resin member 62 on the outer side in the disk radial direction of the fitting part 67 on the disk delivery side slides on the outer side plate 35 on the outer side of the pad guide 16 on the disk delivery side. The resin member 62 inside the disk 67 in the radial direction of the portion 67 slides on the outer pad spring 33 of the pad guide 16 on the disk delivery side.

  Even when the inner friction pad 12 moves in the disk axial direction as described above, the resin member 62 on the outer side in the disk radial direction of the fitting portion 67 on the disk insertion side is the inner side of the pad guide 16 on the disk insertion side. The resin member 62 inside the disk radial direction of the fitting portion 67 on the disk insertion side slides on the inner pad spring 33 of the pad guide 16 on the disk insertion side. Further, the resin member 62 on the outer side of the disk radial direction of the fitting part 67 on the disk delivery side slides on the outer side plate part 35 on the inner side of the pad guide 16 on the disk delivery side. The resin member 62 inside the disk 67 in the disk radial direction slides on the pad spring 33 on the inner side of the pad guide 16 on the disk delivery side.

  According to the first embodiment described above, the opening groove 56 opened to face the pad spring 33 is formed on the inner surface 55 in the disk radial direction of the fitting portion 67 of the back plate 51 of the friction pad 12. The opening groove 56 includes an elastic member 61 housed in the opening groove 56, and a resin member that is a contact member that is disposed between the elastic member 61 and the pad spring 33 and has lower friction than the back plate 51. 62 is provided. For this reason, the low-friction resin member 62 facilitates sliding of the friction pad 12 with respect to the pad spring 33. Further, an opening groove 56 is formed on the outer surface 55 in the disk radial direction so that the fitting portion 67 of the friction pad 12 opens to face the outer plate portion 35, and the opening groove 56 is formed in the opening groove 56. An elastic member 61 to be stored, and a low friction resin member 62 disposed between the elastic member 61 and the outer plate portion 35 are provided. For this reason, the low-friction resin member 62 makes the sliding of the friction pad 12 with respect to the outer plate portion 35 smooth. By providing the elastic member 61, it is possible to apply a load to the contact surface between the resin member 62 and the pad spring 33 with an equal load distribution. Therefore, since the sliding can be made smooth by the low frictional resin member 62 while keeping the surface pressure low, the sliding property of the friction pad 12 is not easily lowered over time. Can be improved stably. Therefore, dragging of the friction pad 12 can be suppressed stably over time.

  Moreover, since the elastic member 61 and the resin member 62 can be removed from the ear | edge part 54, replacement | exchange to a new article becomes easy even if it will be in the situation where slidability falls.

  Further, since the resin member 62 contacts the biasing portion 42 that extends in the disc axial direction of the pad spring 33 and biases the fitting portion 67 of the friction pad 12 in the disc radial direction, the resin member 62 is biased. The slider 42 slides on the urging portion 42 while receiving the urging force from 42. Therefore, it is possible to effectively improve the slidability of the portion of the fitting portion 67 that is always subjected to an urging force and whose contact surface tends to be rough.

  In addition, as shown in FIG. 8, the bottom face part 58 of the opening groove | channel 56 is good also as a cylindrical surface instead of a flat surface. Thereby, the space part 175 can be formed between the elastic member 61 and the bottom face part 58, and the space part 175 ensures the deformation allowance of the elastic member 61. If comprised in this way, the elastic member 61 will become easy to elastically deform, and transmission of a vibration can be suppressed.

  In the first embodiment described above, since the pad spring 33 is provided only on the inner side in the disk radial direction of the fitting part 67, the fitting part 67 of the friction pad 12 is opened only on the inner surface 55 in the disk radial direction. A groove 56 may be formed, and an elastic member 61 and a resin member 62 may be provided in the opening groove 56. When the pad spring is provided on the outer side in the disk radial direction of the fitting portion 67, an opening groove 56 is formed only on the outer surface 55 in the disk radial direction of the fitting portion 67 of the friction pad 12, and this opening is formed. An elastic member 61 and a resin member 62 may be provided in the groove 56. That is, with respect to the fitting portion 67 of the friction pad 12, the elastic member 61 and the resin member 62 may be provided by forming the opening groove 56 in at least one of the inner and outer surfaces 55, 55 in the disk radial direction.

“Second Embodiment”
Next, the second embodiment will be described mainly based on FIGS. 9 to 11 with a focus on differences from the first embodiment. In addition, about the site | part which is common in 1st Embodiment, it represents with the same name and the same code | symbol.

  In the second embodiment, as shown in FIG. 9, two ridges 181 and 181 are formed on the urging portion 42 of the pad guide 16A ′ along the extending direction of the urging portion 42. ing. Further, in the second embodiment, as shown in FIG. 10, a spherical convex portion 182 protrudes inward in the disk radial direction on the resin member 62 inside the disk radial direction of the fitting portion 67 contacting the urging portion 42. Is formed. And as shown in FIG. 11, the convex part 182 contact | abuts to the two protrusions 181 and 181 at the time of the fitting to the concave groove 45 of the fitting part 67. As shown in FIG.

  According to such 2nd Embodiment, the fitting part 67 will contact | abut to the two protrusions 181 and 181 of the urging | biasing part 42 in the convex part 182 of the resin member 62, These protrusions 181, Guided at 181 moves along the urging portion 42. Therefore, the posture at the time of sliding of the friction pad 12 is stabilized. Therefore, drag of the friction pad 12 can be suppressed.

  The above embodiment includes a mounting member having a pad guide that is attached to a non-rotating portion of a vehicle across a disk and that forms a concave groove that is recessed in the disk rotation direction, and a caliper that is slidably provided on the mounting member, A friction pad having a lining pressed against the disk by a caliper and a back plate having a fitting portion extending in the disk rotation direction and slidably fitted into the concave groove provided at an end; and provided in the pad guide And a pad spring on which the fitting portion of the friction pad slides, wherein the fitting portion of the back plate of the friction pad has at least an inner side and an outer side in the disc radial direction. An opening groove that opens to face the pad spring is formed on one side. The opening groove includes an elastic member that is stored in the opening groove, the elastic member, and the pad. And the contact member is provided with an arrangement, low-friction than the back plate between the spring. Thereby, the elastic member can load a load with equal load distribution on the contact surface between the contact member and the pad spring. Therefore, since the sliding can be smoothed by the resin member while keeping the surface pressure low, the sliding property of the friction pad is hardly lowered over time, and the sliding property of the friction pad is stably improved. be able to.

  Further, the pad spring is provided with an urging portion that extends in the disc axial direction and urges the fitting portion of the friction pad in the disc radial direction, and the contact member includes the urging portion. It is arrange | positioned at the said fitting part so that it may contact | abut. Thereby, the contact member slides on the urging portion while receiving the urging force from the urging portion. Accordingly, it is possible to effectively improve the slidability of the portion where the contact surface tends to become rough due to the urging force.

  Further, the urging portion is formed with two protrusions formed along the extending direction, and the abutting member is formed with a convex portion that contacts the two protrusions. Therefore, the fitting portion of the friction pad is guided by the two protrusions and moves along the biasing portion. Therefore, the posture when the friction pad slides is stabilized.

DESCRIPTION OF SYMBOLS 1 Disc brake 10 Disc 11 Mounting member 12 Friction pad 14 Caliper 15 Carrier 16 Pad guide 33 Pad spring 42 Energizing part 45 Concave groove 55 Surface 56 Opening groove 61 Elastic member 62 Resin member (contact member)
67 Fitting part 181 ridge 182 convex part

Claims (3)

An attachment member having a pad guide that is attached to a non-rotating portion of the vehicle across the disc and that forms a concave groove that is recessed in the disc rotation direction;
A caliper provided slidably on the mounting member;
A friction pad having a lining that is pressed against the disk by the caliper and a back plate that extends in the disk rotation direction and is fitted to the groove so as to be slidably fitted to the groove;
A pad spring provided on the pad guide, on which the fitting portion of the friction pad slides;
A disc brake comprising:
In the fitting portion of the back plate of the friction pad, an opening groove that opens to face the pad spring is formed in at least one of the inner side and the outer side in the disk radial direction,
The opening groove is provided with an elastic member stored in the opening groove and a contact member disposed between the elastic member and the pad spring and having lower friction than the back plate. Disc brake characterized by that.   The pad spring is provided with an urging portion that extends in the disc axial direction and urges the fitting portion of the friction pad in the disc radial direction, and the abutting member contacts the urging portion. The disc brake according to claim 1, wherein the disc brake is disposed in contact with the fitting portion.   Two ridges formed along the extending direction are formed on the urging portion, and a convex portion that contacts the two ridges is formed on the contact member. 3. The disc brake according to claim 2, wherein

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