JP6448362B2 - Disc brake - Google Patents

Description

  The present invention relates to a disc brake used for braking a vehicle.

  Some conventional disc brakes include a piston holding mechanism as a parking disc brake mechanism that operates during parking brake or the like (see Patent Document 1).

JP 2014-70670 A

  According to Patent Document 1, when the parking brake is released, the carrier of the planetary gear speed reduction mechanism is supported by the wave washer and the retaining ring at the axial end surface (cylinder part side) of the radial center part thereof, and the shaft of the outer peripheral part thereof. Since the end face in the direction (planetary gear side) is supported by the annular wall portion of the cover, there is a risk that wear or the like will occur at the sliding portion between the carrier and each component, and rotation due to friction at the sliding portion. There was concern about torque loss.

  Therefore, an object of the present invention is to provide a disc brake that improves reliability.

As means for solving the above-described problems, the present invention provides a pair of pads disposed on both sides in the axial direction of the rotor across the rotor, a piston for pressing one of the pair of pads against the rotor, and the piston A caliper body having a cylinder portion that is movably accommodated , a motor provided in the caliper body, a reduction mechanism that is housed in a housing attached to the caliper body, and that increases and transmits the rotational force from the motor; , is the rotational force is transmitted from the deceleration mechanism, and a rotation-linear motion conversion mechanism that to promote the piston, the speed reduction mechanism transmits the rotational force from the motor to the rotary-linear motion conversion mechanism comprising a carrier, wherein the rotation-linear motion conversion mechanism includes a rotation transmitting member rotational force from said carrier from said cylinder portion is transmitted, provided in the rotation transmission member It is, and a stopper ring to restrict movement to the piston side along the axial direction of the rotation transmission member, the end face of the cylinder portion side of the carrier comes into contact with the stopper ring, the cylinder portion and the housing and features that you have separated from.

  According to the disc brake of the present invention, reliability can be improved.

Sectional drawing which shows the disc brake which concerns on this embodiment. The exploded perspective view in the housing of this disc brake. The exploded perspective view in the housing of this disc brake. The principal part expanded sectional view of FIG. Sectional drawing of the rotation linear motion conversion mechanism of this disc brake. The disassembled perspective view of the rotation / linear motion conversion mechanism of this disc brake.

Hereinafter, the present embodiment will be described in detail with reference to FIGS.
As shown in FIG. 1, the disc brake 1 includes a pair of inner brake pads 2 and outer brake pads 3 disposed on both sides in the axial direction with a disc rotor D attached to a rotating portion of the vehicle, and a caliper 4. And are provided. The disc brake 1 is configured as a caliper floating type. The pair of inner brake pads 2 and outer brake pads 3 and the caliper 4 are supported by a bracket 5 fixed to a non-rotating portion such as a knuckle of the vehicle so as to be movable in the axial direction of the disc rotor D. In the following description, for convenience of explanation, the right side in FIG.

  As shown in FIG. 1, the caliper body 6 that is the main body of the caliper 4 opposes the cylinder portion 7 disposed on the base end side facing the inner brake pad 2 on the vehicle inner side and the outer brake pad 3 on the vehicle outer side. And a claw portion 8 disposed on the distal end side. The cylinder portion 7 is formed with a bottomed cylinder 15 that is a large-diameter opening portion 9 </ b> A that is open on the inner brake pad 2 side and is closed on the opposite side by a bottom wall 11 having a hole 10. The bottom wall 11 side in the cylinder 15 is connected to the large diameter opening 9A, and a small diameter opening 9B having a smaller diameter than the large diameter opening 9A is formed. The cylinder 15 has a piston seal 16 disposed on the inner peripheral surface of the large-diameter opening 9A.

  The piston 18 is formed in a bottomed cup shape including a bottom portion 19 and a cylindrical portion 20. The piston 18 is accommodated in the cylinder 15 so that the bottom portion 19 faces the inner brake pad 2. The piston 18 is housed in the large-diameter opening 9A of the cylinder 15 so as to be movable in the axial direction while being in contact with the piston seal 16. A space between the piston 18 and the bottom wall 11 of the cylinder 15 is defined by a piston seal 16 as a hydraulic chamber 21. The fluid pressure chamber 21 is supplied with fluid pressure from a fluid pressure source (not shown) such as a master cylinder or a fluid pressure control unit through a port (not shown) provided in the cylinder portion 7.

  A plurality of rotation restricting longitudinal grooves 22 (see FIG. 5) are formed on the inner peripheral surface of the piston 18 along the circumferential direction. A recess 25 is provided on the outer peripheral side of the other end surface of the bottom portion 19 of the piston 18 facing the inner brake pad 2. The concave portion 25 is engaged with a convex portion 26 formed on the back surface of the inner brake pad 2. By this engagement, the piston 18 is restricted so as not to rotate relative to the cylinder 15 and, consequently, the caliper body 6. A dust boot 27 is interposed between the outer peripheral surface of the piston 18 on the bottom 19 side and the inner peripheral surface of the large-diameter opening 9 </ b> A of the cylinder 15 to prevent foreign matter from entering the cylinder 15. .

  As shown in FIGS. 1 to 3, a housing 30 in which a motor gear assembly 29 is housed is attached to the bottom wall 11 side of the cylinder 15 of the caliper body 6. An opening 30 </ b> A is provided at one end of the housing 30. A cover 36 that is airtightly closed is attached to the opening 30A. In other words, the opening 30 </ b> A of the housing 30 is closed by the cover 36. A seal member 37 is provided between the housing 30 and the cylinder portion 7. The inside of the housing 30 is kept airtight by the seal member 37. The housing 30 is integrally formed from a first housing part 31 and a first housing part 31 that accommodates a spur multi-stage reduction mechanism 44 and a planetary gear reduction mechanism 45 described later so as to cover the outer periphery of the bottom wall 11 of the cylinder 15. And a second housing portion 32 that houses the motor 200. As described above, the housing 30 is configured to accommodate the motor 200 arranged in line with the caliper body 6 by the bottomed cylindrical second housing portion 32.

  The first housing portion 31 includes an outer wall portion 31F and a bottom surface portion 31G that surround a housing chamber 31E that houses a later-described spur gear multi-stage reduction mechanism 44 and a planetary gear reduction mechanism 45 together with a cover 36, and a part of the bottom wall 11 of the cylinder 15. A mounting opening 31A through which a polygonal shaft portion 81 of a base nut 75 of the rotation / linear motion conversion mechanism 43, which will be described later, is inserted, and an inner cylindrical wall portion 31B protruding around the mounting opening 31A, The outer cylindrical wall portion 31C projecting radially outward from the inner cylindrical wall portion 31B, and a plurality of engagements formed at intervals in the circumferential direction of the outer cylindrical wall portion 31C It has a groove 31D and an annular wall 31H (see FIG. 4) located between the attachment opening 31A and the inner cylindrical wall 31B. A cylindrical support member 33 is integrally fixed inside the inner cylindrical wall portion 31 </ b> B of the first housing portion 31. Inside the cylindrical support member 33, a carrier 62 of a planetary gear reduction mechanism 45 described later is disposed.

  The caliper body 6 includes a flat-tooth multi-stage speed reduction mechanism 44 and a planetary gear speed reduction mechanism 45 that reinforces the driving force of the motor 200, and a rotation / linear motion conversion mechanism 43 that propels the piston 18 and holds the piston 18 in a braking position. Is provided. The spur multi-stage speed reduction mechanism 44 and the planetary gear speed reduction mechanism 45 as the speed reduction mechanism are accommodated in an accommodation chamber 31 </ b> E in the first housing portion 31 of the housing 30.

  As shown in FIG. 1, the spur multi-stage reduction mechanism 44 has a pinion gear 46, a first reduction gear 47, a non-reduction spur gear 48, and a second reduction gear 49. The first reduction gear 47, the non-reduction spur gear 48, and the second reduction gear 49 are metal or resin such as fiber reinforced resin.

  As shown in FIGS. 1 to 3, the pinion gear 46 is formed in a cylindrical shape, and has a hole 50 that is press-fitted and fixed to the rotation shaft 201 of the motor 200, and a gear 51 that is formed on the outer periphery. . The first reduction gear 47 has a shaft hole 47 </ b> A extending in the axial direction, a large-diameter large gear 53 that meshes with the gear 51 of the pinion gear 46, and a small-diameter gear that extends from the large gear 53 in the axial direction. The small gear 54 is integrally formed. The first reduction gear 47 is rotatably supported by a shaft 52 inserted through the shaft hole 47A with respect to a support plate 59 and a holder 205 described later. One end of the shaft 52 is supported by the support plate 59 close to the cover 36, and the other end is supported by the holder 205.

  The small gear 54 of the first reduction gear 47 meshes with the non-reduction spur gear 48. The non-reducing spur gear 48 is rotatably supported by the shaft 55 with respect to the support plate 59 and the holder 205. One end of the shaft 55 is supported by a support plate 59 close to the cover 36, and the other end is supported by a holder 205. The second reduction gear 49 is integrally formed with a large-diameter large gear 56 that meshes with the non-reducing spur gear 48 and a small-diameter sun gear 57 that extends from the large gear 56 in the axial direction. The sun gear 57 is configured as a part of a planetary gear reduction mechanism 45 described later. A hole 49A is formed at the center of the second reduction mechanism 49, and the shaft 58 is inserted therethrough. The shaft 58 is press-fitted and fixed to a support plate 59 provided at one end close to the cover 36. The second reduction gear 49 is rotatably supported by the shaft 58. Further, an annular stopper portion 56 </ b> A that protrudes toward the planetary gear reduction mechanism 45 is formed on the annular wall portion of the large gear 56 of the second reduction gear 49.

  The planetary gear reduction mechanism 45 includes a sun gear 57 of the second reduction gear 49, a plurality (four in this embodiment) of planetary gears 60, an internal gear 61, and a carrier 62. Each planetary gear 60 has a gear 63 meshed with the sun gear 57 of the second reduction gear 49 and a hole 64 through which a pin 65 erected from the carrier 62 is rotatably inserted. The planetary gears 60 are arranged at equal intervals on the circumference of the carrier 62. An annular plate 66 is disposed on the other end side of each planetary gear 60.

  As shown in FIG. 4, the carrier 62 has a small-diameter disc-like portion 62A located at the radial center portion, and the small-diameter disc-like portion integrally with the small-diameter disc-like portion 62A on one end side in the axial direction (each planetary gear 60 side). It consists of a large-diameter disk-shaped part 62B formed concentrically with the disk-shaped part 62A. The total thickness of the carrier 62 including the thickness of the small-diameter disk-shaped portion 62A and the thickness of the large-diameter disk-shaped portion 62B is the same as the stopper ring 90 provided in the base nut 75 of the rotation / linear motion converting mechanism 43 described later. The clearance is set smaller than the gap dimension along the axial direction between the annular plate 66 and the annular plate 66. In FIG. 4, the upper side of the figure is described as one end side, and the lower side of the figure is described as the other end side. A polygonal hole 68 extending in the axial direction is formed at substantially the center in the radial direction of the carrier 62. The outer diameter of the large-diameter disk-shaped portion 62B of the carrier 62 is substantially the same as the outer diameter of the revolution trajectory of each planetary gear 60. An annular notch 62B 'extending in the circumferential direction is formed on the outer peripheral edge of the other axial end surface of the large-diameter disk-shaped portion 62B. The thickness of the portion of the annular notch 62B ′ of the large-diameter plate-like portion 62B of the carrier 62 is smaller than the gap dimension along the axial direction between the annular wall portion 31E of the first housing portion 31 and the annular plate 66. Is set. A plurality of pin holes 69 along the axial direction are formed in the large-diameter disk-shaped portion 62B of the carrier 62 at intervals in the circumferential direction. A pin 65 is press-fitted and fixed in each pin hole 69. Each pin 65 is rotatably inserted into a hole 64 of each planetary gear 60. The polygonal hole 68 of the carrier 62 and a polygonal shaft portion 81 of the base nut 75 to be described later are fitted, so that the rotational torque can be transmitted between the carrier 62 and the base nut 75. The carrier 62 is restricted from moving in the radial direction by the cylindrical support member 33 provided integrally inside the inner cylindrical wall portion 31 </ b> B of the first housing portion 31.

  The carrier 62 is supported in the axial direction by a stopper ring 90 provided between a cylindrical portion 76 of a base nut 75 and a polygonal shaft portion 81, which will be described later. Specifically, the small-diameter disk-shaped portion 62A of the carrier 62 and the head portion of each pin 65 are disposed in the mounting opening 31A of the first housing portion 31, and the other axial end surface (cylinder portion) of the small-diameter disk-shaped portion 62A. 7 end face) comes into contact with one axial end face (end face on each planetary gear 60 side) of a stopper ring 90 provided on a base nut 75 described later. Further, one axial end surface (end surface on the planetary gear 60 side) of the outer peripheral portion of the large-diameter disk-shaped portion 62B of the carrier 62 is separated from the annular plate 66 and the outer peripheral portion of the large-diameter disk-shaped portion 62B. An annular notch 62B ′ provided on the other axial end face (end face on the cylinder part 7 side) of the first housing part 31 is separated from the annular wall part 31H. As a result, the carrier 62 is supported in the axial direction only by the stopper ring 90 provided in the base nut 75.

  As shown in FIGS. 1 to 3, the internal gear 61 continuously extends in the radial direction from the inner teeth 71 with which the gears 63 of the planetary gears 60 are respectively meshed and one end of the inner teeth 71 on the cover 36 side. An annular wall portion 72 that restricts the movement of each planetary gear 60 in the axial direction and a cylindrical wall portion 73 that extends from the inner teeth 71 toward the bottom wall 11 of the cylinder 15 are provided. The internal gear 61 is fixed to the housing 30 by inserting the cylindrical wall portion 73 into an annular space between the inner cylindrical wall portion 31B and the outer cylindrical wall portion 31C of the first housing portion 31. . An annular plate 66 is disposed inside the internal gear 61. The annular plate 66 is sandwiched between the end surface of the internal teeth 71 of the internal gear 61 and the inner cylindrical wall portion 31 </ b> B of the first housing portion 31. Thereby, each planetary gear 60 is arrange | positioned between the annular wall part 72 of the internal gear 61, and the annular plate 66, and the movement of an axial direction is controlled.

  In addition, a plurality of protrusions 74 are provided on the other end side of the outer peripheral surface of the internal gear 61 so as to be spaced apart in the circumferential direction. Each protrusion 74 protrudes outward and is engaged with each engagement groove 31 </ b> D provided in the first housing portion 31. The internal gear 61 is supported in the first housing portion 31 so as not to rotate by inserting and engaging the protrusions 74 with the engaging grooves 31 </ b> D of the first housing portion 31. Further, the internal gear 61 is not movable in the axial direction because the annular stopper portion 56A provided on the large gear 56 of the second reduction gear 49 is disposed on the cover 36 side of the annular wall portion 72. It is supported in the first housing part 31.

  The motor 200 is supported by a holder 205 disposed on the flange portion 202. The holder 205 is configured by integrally connecting a motor support portion 206 and a ring-shaped support portion 207. The motor support portion 206 is arranged between the first reduction gear 47 and the non-reduction spur gear 48 and the flange portion 202 of the motor 200 to support the motor 200. The ring-shaped support portion 207 is disposed around the internal gear 61 of the planetary gear reduction mechanism 45 so as to surround the internal gear 61. The motor support portion 206 is formed with a rotation shaft insertion hole 208 through which the pinion gear 46 press-fitted and fixed to the rotation shaft 201 of the motor 200 is inserted. Around the rotating shaft insertion hole 208, two terminal insertion holes through which the motor terminals 203 of the motor 200 are inserted are formed. A pair of terminal insertion holes is formed on both sides in the radial direction of the rotation shaft insertion hole 208. Harnesses 250 and 251 are connected to the motor terminals 203 of the motor 200, respectively.

  The motor support portion 206 of the holder 205 includes a holder-side first convex portion 211, a holder-side second convex portion 212, and a holder-side first portion on the opposite side of the planetary gear speed reduction mechanism 45 around the rotation shaft insertion hole 208. Three convex portions 213 are formed at intervals from each other. The holder-side first convex portion 211, the holder-side second convex portion 212, and the holder-side third convex portion 213 are columnar and project toward the cover 36 side. Two fastening holes 216 are formed in the motor support portion 206. Each mounting bolt 215 is fastened to the fastening hole 216 of the motor support portion 206 via each through hole 202 </ b> A of the flange portion 202 of the motor 200. By this fastening, the motor 200 is supported by the motor support part 206 of the holder 205. The ring-shaped support portion 207 is disposed on each protrusion 74 so as to contact the outer peripheral surface of the internal gear 61 of the planetary gear reduction mechanism 45.

  Cylindrical support portions 217 and 217 are integrally formed at two locations on the holder 205 between the motor support portion 206 and the ring-shaped support portion 207. A support plate 59 is disposed on each cylindrical support portion 217, and each mounting bolt 218 is fastened to each cylindrical support portion 217 of the holder 205 via the support plate 59, whereby the support plate 59 is placed on the holder 205. Be supported at intervals.

  On the inner surface of the cover 36, a cover-side first cylindrical portion 221, a cover-side second convex portion 222, and a cover-side third convex portion 223 are provided so as to protrude from each other at intervals. The cover-side first cylindrical portion 221, the cover-side second convex portion 222, and the cover-side third convex portion 223 are a holder-side first convex portion 211, a holder-side second convex portion 212, and a holder-side provided on the holder 205. Each is formed at a position facing the third convex portion 213. And the cover side 1st cylindrical part 221, the cover side 2nd convex part 222, the cover side 3rd convex part 223 of the cover 36, the holder side 1st convex part 211, the holder side 2nd convex part of the holder 205 A rubber 230, which is an elastic member, is interposed between 212 and the holder-side third convex portion 213.

  The rubber 230 is formed by integrating the first cup portion 231, the second cup portion 232, the third cup portion 233, and the opening side end portions of the first cup portion 231, the second cup portion 232, and the third cup portion 233. And a plate-like base portion 234 connected to each other.

  Then, the first cup portion 231 of the rubber 230 is fitted to the holder-side first convex portion 211 of the holder 205, the second cup portion 232 of the rubber 230 is fitted to the holder-side second convex portion 212 of the holder 205, The third cup portion 233 of the rubber 230 is fitted to the holder-side third convex portion 213 of the holder 205 so that the rubber 230 is unitized with the holder 205. Thereafter, the cover-side first cylindrical portion 221 of the cover 36 is fitted into the first cup portion 231 of the rubber 230, and the cover-side second convex portion 222 of the cover 36 is fitted to the second cup portion 232 of the rubber 230. In addition, the cover 36 is covered so that the cover side third convex portion 223 of the cover 36 contacts the third cup portion 233 of the rubber 230. Harnesses 250 and 251 extending from the motor terminals 203 of the motor 200 are arranged along the base portion 234 of the rubber 230.

  As shown in FIG. 2, in this embodiment, a plurality of types of rubbers 281, 282, and 283 different from the rubber 230 described above are provided in the housing 30. A U-shaped support section 280 is formed at the end of the holder 205 on the motor support section 206 side, and a U-shaped rubber section 281 is integrally disposed therein. Block-shaped rubbers 282 are respectively disposed between the outer peripheral surface at a position close to each cylindrical support portion 217 and the inner wall surface of the first housing portion 31 in the ring-shaped support portion 207 of the holder 205. A cylindrical rubber 283 is disposed between the main body side end portion of the motor 200 and the bottom wall portion of the second housing portion 32.

  Thus, the motor gear assembly 29 is configured by assembling the motor 200, the spur multi-stage reduction mechanism 44, the planetary gear reduction mechanism 45, and the rubbers 230, 281, 282, and 283 to the holder 205 and the support plate 59. The motor gear assembly 29 is attached to the housing 30 and the cover 36 by rubbers 230, 281, 282, and 283 in a suspended state, that is, a so-called floating state. In other words, the motor gear assembly 29 is fixed to the housing 30 and the cover 36 via the rubbers 230, 281, 282, and 283 without the holder 205 coming into contact with the housing 30 and the cover 36. As described above, the motor gear assembly 29 is fixed to the housing 30 and the cover 36 via the rubbers 230, 281, 282, and 283, so that the motor 200, the spur multi-stage reduction mechanism 44, and the planetary gear reduction mechanism 45 are generated. The transmission of the vibration to be transmitted to the housing 30 or the cover 36 is suppressed, and the generation of sound accompanying the vibration can be suppressed.

  In the present embodiment, in order to obtain the rotational force for propelling the piston 25, the spur multi-stage reduction mechanism 44 and the planetary gear reduction mechanism 45 as the reduction mechanism that reinforces the driving force by the motor 200 are employed. You may comprise only the deceleration mechanism 45. FIG. Further, a speed reducer according to another known technique such as a cycloid speed reduction mechanism or a wave speed reducer may be combined with the planetary gear speed reduction mechanism 45.

Next, the rotation / linear motion conversion mechanism 43 will be specifically described with reference to FIGS. 1, 5 and 6. In the following description, for convenience of explanation, the right side of FIG. 5 will be described as one end side and the left side as the other end side.
The rotation / linear motion converting mechanism 43 converts the rotational motion from the spur multi-stage speed reducing mechanism 44 and the planetary gear speed reducing mechanism 45, that is, rotation of the motor 200 into motion in a linear direction (hereinafter referred to as linear motion for convenience), and piston. A thrust is applied to 18 to hold the piston 18 in the braking position. The rotation / linear motion converting mechanism 43 includes a base nut 75 as a rotation transmitting member that is rotatably supported by transmitting rotational motions from the spur multi-stage reduction mechanism 44 and the planetary gear reduction mechanism 45, and the base nut 75. A push rod 102 that is screwed to the female screw portion 97 and is rotatably supported by the rotation of the base nut 75, and a push rod 102 that is screwed to the push rod 102 to rotate the push rod 102. And a ball and ramp mechanism 127 that applies axial thrust to the piston 18. The rotation / linear motion conversion mechanism 43 is accommodated between the cylinder 15 and the piston 18 of the caliper body 6.

  The base nut 75 includes a cylindrical portion 76 and a nut portion 77 provided integrally with the other end portion of the cylindrical portion 76. A washer 80 is disposed so as to contact the bottom wall 11 of the cylinder 15. The cylindrical portion 76 of the base nut 75 is inserted into each of the insertion hole 80 </ b> A of the washer 80 and the hole portion 10 provided in the bottom wall 11 of the cylinder 15. A polygonal shaft portion 81 is integrally connected to the tip of the cylindrical portion 76. The polygon shaft 81 is inserted through the attachment opening 31 </ b> A of the first housing portion 31 and is fitted into the polygon hole 68 of the carrier 62. The nut portion 77 of the base nut 75 is formed in a bottomed cylindrical shape. The nut portion 77 includes a circular wall portion 82 and a cylindrical portion 83 projecting integrally from the other end surface of the circular wall portion 82. The outer peripheral surface of the circular wall portion 82 is close to the inner wall surface of the small-diameter opening 9B of the cylinder 15. A small-diameter circular wall 84 protrudes from the radial center of one end face of the circular wall 82. A cylindrical portion 76 projects from one end surface of the small-diameter circular wall portion 84 toward one end side. The outer diameter of the cylindrical portion 76 is formed smaller than the outer diameter of the cylindrical portion 83 of the nut portion 77.

  A thrust bearing 87 is disposed between the washer 80 and the circular wall portion 82 around the small-diameter circular wall portion 84 provided in the nut portion 77 of the base nut 75. The base nut 75 is rotatably supported by the bottom wall 11 of the cylinder 15 by a thrust bearing 87. A seal member 88 and a sleeve 89 are provided between the outer peripheral surface of the cylindrical portion 76 of the base nut 75 and the hole 10 of the bottom wall 11 of the cylinder 15. Thereby, the fluid tightness of the hydraulic chamber 21 is maintained. A stopper ring 90 is mounted in an annular groove provided between the cylindrical portion 76 of the base nut 75 and the polygonal shaft portion 81. The stopper ring 90 restricts the movement of the base nut 75 toward the piston 18 along the axial direction. As described above, the small-diameter disk-shaped portion 62A of the carrier 62 of the planetary gear speed reduction mechanism 45 is in contact with one end surface of the stopper ring 90, and the carrier 62 of the planetary gear speed reduction mechanism 45 is brought into contact with the stopper ring 90 alone. Supported in the axial direction.

  The cylindrical portion 83 of the nut portion 77 of the base nut 75 includes a large diameter cylindrical portion 91 disposed on one end side and a small diameter cylindrical portion 92 disposed on the other end side. One end of the large-diameter cylindrical portion 91 is integrally connected to the circular wall portion 82. A plurality of through holes 95 extending in the radial direction are formed in the peripheral wall portion of the large diameter cylindrical portion 91. A plurality of through holes 95 are formed at intervals in the circumferential direction. A female thread portion 97 is formed on the inner peripheral surface of the small diameter cylindrical portion 92 of the nut portion 77. A plurality of locking grooves 98 are formed on the other end surface of the peripheral wall portion of the small diameter cylindrical portion 92 at intervals in the circumferential direction. In the present embodiment, four locking grooves 98 are formed.

  One of the locking grooves 98 of the small-diameter cylindrical portion 92 of the base nut 75 is fitted with a tip portion 100A of the first spring clutch 100 as a one-way clutch that applies rotational resistance to rotation in one direction. . The first spring clutch 100 includes a distal end portion 100A facing outward in the radial direction and a coil portion 100B wound continuously from the distal end portion 100 in a single layer. And the front-end | tip part 100A of the 1st spring clutch 100 is fitted by either of each locking groove 98 of the small diameter cylindrical part 92 of the base nut 75, and the coil part 100B is the male thread part 103 of the push rod 102 mentioned later. It is wound around the other end. The first spring clutch 100 applies a rotational resistance torque in the rotational direction (the rotational direction at the time of release) when the push rod 102 moves toward the bottom wall 11 side of the cylinder 15 with respect to the base nut 75. The push rod 102 is configured to allow rotation in the rotation direction (rotation direction at the time of application) when the push rod 102 moves to the bottom 19 side of the piston 18 with respect to the base nut 75.

  One end side of the push rod 102 is inserted into the nut portion 77 of the base nut 75. On one end side of the push rod 102, a male screw portion 103 that is screwed into the female screw portion 97 of the small diameter cylindrical portion 92 of the base nut 75 is formed. The first screw fitting portion 105 between the male screw portion 103 of the push rod 102 and the female screw portion 97 of the small-diameter cylindrical portion 92 of the base nut 75 causes the base nut to move in the axial direction from the piston 18 to the push rod 102. In order not to rotate 75, the reverse efficiency is set to 0 or less, that is, it is configured as a screw fitting portion having a large irreversibility.

  On the other hand, on the other end side of the push rod 102, a male screw portion 104 that is screw-fitted to a female screw portion 162 provided on a rotary linear motion lamp 151 of a ball and ramp mechanism 127 described later is formed. Here again, the second screw fitting portion 106 between the male threaded portion 104 of the push rod 102 and the female threaded portion 162 provided on the rotary linear motion ramp 151 is used for the axial load from the piston 18 to the rotational linear motion ramp 151. In order to prevent the push rod 102 from rotating, the reverse efficiency of the push rod 102 becomes 0 or less, that is, the screw fitting portion has a large irreversibility.

  The push rod 102 is provided with a spline shaft 108 between a male screw portion 103 on one end side and a male screw portion 104 on the other end side. The outer diameter of the male screw portion 103 on one end side is formed larger than the outer diameter of the male screw portion 104 on the other end side. The outer diameter of the male screw portion 103 on one end side is formed larger than the outer diameter of the spline shaft 108. A small-diameter cylindrical portion 107 is continuously formed on the other end side from the male screw portion 104 of the push rod 102. The outer peripheral surface of the cylindrical portion 107 is knurled. A stopper member 172 is integrally fixed to the cylindrical portion 107 of the push rod 102 by press-fitting. The stopper member 172 defines a relative rotation range of the rotary linear movement lamp 151 with respect to the push rod 102. The other end surface of the cylindrical portion 107 of the push rod 102 faces the bottom portion 19 of the piston 18.

  The retainer 110 is supported between the outer peripheral surface of the small diameter cylindrical portion 92 of the cylindrical portion 84 constituting the nut portion 77 of the base nut 75 and the inner peripheral surface of the cylindrical portion 20 of the piston 18 so as to be movable in the axial direction. . The retainer 110 has an annular wall portion 111 on one end side, and is configured in a substantially cylindrical shape as a whole. A plurality of through holes 114 and 115 are formed in the outer peripheral wall of the retainer 110.

  Within the retainer 110, one end side washer 120, a coil spring 121, the other end side washer 122, a support plate 123, a second spring clutch 124, a rotating member 125, a thrust bearing 126, a ball and ramp mechanism 127, in order from one end side. A thrust bearing 128 and an annular pressing plate 129 are arranged. The one end side washer 120 is disposed so as to contact the other end surface of the annular wall portion 111 of the retainer 110.

  A coil spring 121 is interposed between the one end side washer 120 and the other end side washer 122. The coil spring 121 urges the one end side washer 120 and the other end side washer 122 in a direction to separate them. A plurality of locking grooves 132 having a predetermined depth are formed on the other end surface of the peripheral wall portion of the retainer 110 at intervals in the circumferential direction. Each locking groove 132 includes a narrow locking groove 133 positioned on one end side and a wide locking groove 134 positioned on the other end side. The locking groove 132 is formed in three places in this embodiment. At the other end of the retainer 110, a plurality of claw portions 136 are formed toward the bottom portion 19 of the piston 18. Inside the retainer 110, one end side washer 120, coil spring 121, other end side washer 122, support plate 123, second spring clutch 124, rotating member 125, thrust bearing 126, ball and ramp mechanism 127, thrust bearing 128, and annular pressure After the plate 129 is accommodated, the claws 136 of the retainer 110 are folded toward the accommodating recess 171 of the annular pressing plate 129, which will be described later, so that a large number of the above-described constituent members are integrally disposed in the retainer 110. It can be assembled.

  An annular support plate 123 is disposed so as to contact the other end surface of the other end washer 122. A plurality of protruding pieces 137 are provided on the outer peripheral surface of the support plate 123 at intervals along the circumferential direction. In the present embodiment, three protrusion pieces 137 are formed. The protrusions 137 of the support plate 123 are fitted into the narrow locking grooves 133 of the retainer 110 and the rotation restricting vertical grooves 22 provided on the inner peripheral surface of the piston 18, respectively. As a result, the retainer 110 is supported together with the one end side washer 120, the coil spring 121, the other end side washer 122, and the support plate 123 so as not to rotate relative to the piston 18 and to be relatively movable in the axial direction.

  In the retainer 110, the rotation member 125 is rotatably supported on the other end side of the support plate 123. The rotating member 125 includes a large-diameter annular portion 141 having a spline hole 140 and a small-diameter cylindrical portion 142 that projects integrally from one end surface of the large-diameter annular portion 141. One end of the small diameter cylindrical portion 142 is brought into contact with the other end surface of the support plate 123. The push rod 102 is inserted into the rotating member 125, and the spline hole 140 of the large-diameter annular portion 141 of the rotating member 125 and the spline shaft 108 of the push rod 102 are splined. As a result, the rotating member 125 and the push rod 102 can transmit mutual rotational torque.

  A second spring clutch 124 that imparts rotational resistance to rotation in one direction is wound around the outer peripheral surface of the small-diameter cylindrical portion 142 of the rotating member 125. Similar to the first spring clutch 100, the second spring clutch 124 includes a distal end portion 124A facing outward in the radial direction and a coil portion 124B continuously wound from the distal end portion 124A. . Then, the distal end portion 124 </ b> A of the second spring clutch 124 is fitted into one of the narrow locking grooves 133 of the retainer 110, and the coil portion 124 </ b> B is wound around the outer peripheral surface of the small diameter cylindrical portion 142 of the rotating member 125. . The second spring clutch 124 applies a rotational resistance torque to the rotational direction (the rotational direction at the time of application) when the rotating member 125 (push rod 102) moves toward the bottom 19 side of the piston 18 with respect to the retainer 110. On the other hand, it is configured to allow rotation in the rotation direction (rotation direction at release) when moving to the bottom wall 11 side of the cylinder 15.

  The rotational resistance torque when the second spring clutch 124 is applied is greater than the rotational resistance torque of the first screw fitting portion 105 between the male screw portion 103 of the push rod 102 and the female screw portion 97 of the base nut 75. Set to be larger. A ball and ramp mechanism 127 is disposed on the other end side of the rotating member 125 via a thrust bearing 126. The rotating member 125 is rotatably supported by a ball and ramp mechanism 127 via a thrust bearing 126.

  The ball-and-ramp mechanism 127 includes a fixed lamp 150, a rotation / linear motion lamp 151, and each ball 152 interposed between the fixed lamp 150 and the rotation / linear motion lamp 151. The fixed lamp 150 is disposed on the other end side of the rotating member 125 via a thrust bearing 126. The fixed lamp 150 includes a disk-shaped fixed plate 154 and a plurality of convex portions 155 that protrude from the outer peripheral surface of the fixed plate 154 at intervals along the circumferential direction. In the present embodiment, three convex portions 155 are formed. An insertion hole 156 through which the push rod 102 is inserted is formed at the center in the radial direction of the fixed plate 154. The fixed ramp 150 has its convex portions 155 fitted into the wide locking grooves 134 of the retainer 110 and fitted into the rotation restricting vertical grooves 22 provided on the inner peripheral surface of the piston 18. The piston 18 is supported so as not to rotate relative to the piston 18 and to be movable in the axial direction. On the other end surface of the fixed plate 154, a plurality of ball grooves 157 having a predetermined inclination angle along the circumferential direction and extending in an arc shape and having an arc-shaped cross section in the radial direction are formed in the present embodiment. ing.

  The rotation / linear motion ramp 151 includes an annular rotation / linear motion plate 160 and a cylindrical portion 161 that protrudes integrally from a central portion in the radial direction of the other end surface of the rotation / linear motion plate 160. On the inner peripheral surface from the rotary translation plate 160 to the cylindrical portion 161, a female screw portion 162 into which the male screw portion 104 of the push rod 102 is screwed is formed. On the surface of the rotary linear motion plate 160 facing the fixed plate 154 of the fixed lamp 150, a plurality of books having a predetermined inclination angle along the circumferential direction and extending in an arc shape and having an arc-shaped cross section in the radial direction In the embodiment, three ball grooves 163 are formed. In addition, each ball groove 157 of the fixed ramp 150 and each ball groove 163 of the rotary linear motion ramp 151 may be configured by forming a recess in the middle of the inclination along the circumferential direction or changing the inclination in the middle. good.

  The ball 152 is interposed between each ball groove 163 of the rotation linear motion ramp 151 (rotation linear motion plate 160) and each ball groove 157 of the stationary ramp 150 (fixation plate 154). Then, when a rotational torque is applied to the rotation / linear motion ramp 151, each ball 152 between each ball groove 163 of the rotation / linear motion plate 160 and each ball groove 157 of the fixed plate 154 rolls. Due to the rotational difference between the plate 160 and the fixed plate 154, the relative distance in the axial direction between the rotary translation plate 160 and the fixed plate 154 varies.

  An annular pressing plate 129 is disposed on the other end surface around the cylindrical portion 161 of the rotary translation plate 160 via a thrust bearing 128. On the outer peripheral surface of the annular pressing plate 129, a plurality of convex portions 168 are provided protruding at intervals along the circumferential direction. In the present embodiment, three convex portions 168 are formed. Each of the convex portions 168 of the annular pressing plate 129 is fitted into each of the wide locking grooves 134 of the retainer 110 and is fitted into each of the rotation restricting vertical grooves 22 provided on the inner peripheral surface of the piston 18. The piston 18 is supported so as not to rotate relative to the piston 18 and to be movable in the axial direction.

  The rotation / linear motion ramp 151 of the ball and ramp mechanism 127 is supported by an annular pressing plate 129 through a thrust bearing 128 so as to be rotatable. The other end surface of the annular pressing plate 129 comes into contact with the bottom portion 19 of the piston 18 to press the piston 18. On the other end surface of the annular pressing plate 129, an accommodation recess 171 for accommodating each claw portion 136 of the retainer 110 that is folded inward is formed on the outer peripheral portion between the projections 168.

  Further, as shown in FIG. 1, the motor 200 is electrically connected to an ECU 175 composed of an electronic control unit that drives and controls the motor 200. The ECU 175 is connected to a parking switch 176 that is operated to instruct the operation / release of the parking brake. Further, the ECU 175 can be operated regardless of the operation of the parking switch 176 based on a signal from the vehicle side (not shown).

Next, the operation of the disc brake 1 according to this embodiment will be described.
First, the action at the time of braking of the disc brake 1 as a normal hydraulic brake by the operation of a brake pedal (not shown) will be described.
When the driver depresses the brake pedal, the hydraulic pressure corresponding to the depressing force of the brake pedal is supplied from the master cylinder to the hydraulic chamber 21 in the caliper 4 via a hydraulic circuit (both not shown). Thereby, the piston 18 moves forward (moves leftward in FIG. 1) from the original position during non-braking while elastically deforming the piston seal 16, and presses the inner brake pad 2 against the disc rotor D. The caliper body 6 moves to the right in FIG. 1 with respect to the bracket 5 by the reaction force of the pressing force of the piston 18, and presses the outer brake pad 3 attached to the claw portion 8 against the disc rotor D. As a result, the disc rotor D is sandwiched between the pair of inner and outer brake pads 2 and 3 to generate a frictional force, and hence a braking force for the vehicle.

  And when a driver | operator releases a brake pedal, supply of the hydraulic pressure from a master cylinder stops, and the hydraulic pressure in the hydraulic pressure chamber 21 falls. As a result, the piston 18 is retracted to the original position by the restoring force of the elastic deformation of the piston seal 16 and the braking force is released. Incidentally, when the amount of movement of the piston 18 increases with wear of the inner and outer brake pads 2 and 3 and exceeds the limit of elastic deformation of the piston seal 16, slip occurs between the piston 18 and the piston seal 16. By this slip, the original position of the piston 18 with respect to the caliper body 6 is moved, and the pad clearance is adjusted to be constant.

Next, an operation as a parking brake, which is an example of an operation for maintaining the vehicle stop state, will be described.
First, when the parking switch is operated from the released state of the parking brake and the parking brake is operated (applied), the ECU 175 drives the motor 200 and the planetary gear reduction mechanism via the spur multi-stage reduction mechanism 44. 45 sun gears 57 are rotated. Due to the rotation of the sun gear 57, the carrier 62 is rotated through each planetary gear 60. Then, the rotational torque from the carrier 62 is transmitted to the base nut 75. At this time, the carrier 62 has one end face in the axial direction (end face on each planetary gear 60 side) of the outer peripheral portion of the large-diameter disc-like portion 62B separated from the annular plate 66, and The annular notch 62B ′ provided on the other axial end face (end face on the cylinder part 7 side) is also away from the annular wall part 31H of the first housing part 31, and the sliding part of the carrier 62 with other components Therefore, the transmission efficiency of the rotational torque can be increased.

  Next, the rotational resistance torque in the apply direction of the rotating member 125 (push rod 102) to the retainer 110 (piston 18) by the second spring clutch 124 causes the first screw fit between the push rod 102 and the base nut 75. It is set to be larger than the rotational resistance torque by the joint portion 105. Accordingly, the first spring clutch 100 is allowed to rotate the push rod 102 in the apply direction with respect to the base nut 75. Therefore, the rotation of the base nut 75 in the apply direction causes the first screw fitting portion 105 to rotate relatively, that is, only the base nut 75 rotates in the apply direction, while the push rod 102 extends along the axial direction. The piston 18 moves forward toward the bottom 19 side.

  As a result, the one end side washer 120 in the retainer 110 including the retainer 110 together with the push rod 102, the coil spring 121, the other end side washer 122, the support plate 123, the second spring clutch 124, the rotating member 125, the thrust bearing 126, the ball and The constituent members of the ramp mechanism 127, the thrust bearing 128, and the annular pressing plate 129 are integrally moved toward the bottom 19 side of the piston 18 along the axial direction. By advancement of these components, the annular pressing plate 129 comes into contact with the bottom 19 of the piston 18, the piston 18 advances, and one end surface of the bottom 19 of the piston 18 comes into contact with the inner brake pad 2.

  When the rotation of the motor 200 in the apply direction is continued, the piston 18 starts to press the disc rotor D via the inner and outer brake pads 2 and 3 by the movement of the push rod 102. When this pressing force starts to be generated, this time, the rotational resistance torque in the first screw fitting portion 105 between the push rod 102 and the base nut 75 increases due to the axial force that is the reaction force against the pressing force. Thus, the rotational resistance torque of the second spring clutch 124 becomes larger. As a result, the push rod 102 starts to rotate in the apply direction together with the rotating member 125 as the base nut 75 rotates. Then, due to the reaction force from the pressing force of the disk rotor D, the rotational resistance torque in the second screw fitting portion 106 between the push rod 102 and the ball and ramp mechanism 127 also increases due to the reaction force of the pressing force of the disk rotor D. For this reason, the rotational torque in the apply direction of the push rod 102 is transmitted to the rotary linear motion lamp 151 of the ball and ramp mechanism 127 via the second screw fitting portion 106.

  At this time, the rotational torque in the apply direction of the push rod 102 causes a relative rotation difference (the rotation linear motion lamp 151 rotates slightly behind the push rod 102) at the second screw fitting portion 106. Then, it is transmitted to the rotation / linear motion lamp 151 of the ball and ramp mechanism 127. Then, each of the balls 152 rolls while the rotary linear motion lamp 151 of the ball and ramp mechanism 127 rotates in the apply direction, and the rotary linear motion ramp 151 and the fixed ramp 150 resist the urging force of the coil spring 121. Then, the annular pressing plate 129 further presses the bottom portion 19 of the piston 18 by being separated. Thereby, the pressing force of the disc rotor D by the inner and outer brake pads 2 and 3 increases.

  In the disc brake 1 according to the present embodiment, first, the first screw fitting portion 105 between the push rod 102 and the base nut 75 relatively rotates, the push rod 102 moves forward, and the piston 18 is moved. Advancing to obtain a pressing force to the disk rotor D. For this reason, the operation of the first screw fitting portion 105 can adjust the original position of the push rod 102 with respect to the piston 18 that changes due to the wear of the inner and outer brake pads 2 and 3 with time.

  The ECU 175 drives the motor 200 until the pressing force from the pair of inner and outer brake pads 2 and 3 to the disc rotor D reaches a predetermined value, for example, until the current value of the motor 200 reaches a predetermined value. Thereafter, when the ECU 175 detects that the pressing force to the disk rotor D has reached a predetermined value by the fact that the current value of the motor 200 has reached a predetermined value, the ECU 175 stops energization of the motor 200. Then, the linear motion accompanying the rotation of the rotary linear motion lamp 151 of the ball and ramp mechanism 127 is stopped.

  Eventually, the reaction force of the pressing force from the disk rotor D acts on the rotary linear motion lamp 151, but the second screw fitting portion 106 between the push rod 102 and the ball and ramp mechanism 127 is The first screw fitting portion 105 between the push rod 102 and the base nut 75 is also constituted by a screw fitting portion that does not reversely operate. Since the first spring clutch 100 applies a rotational resistance torque in the release direction to the push rod 102 with respect to the base nut 75, the piston 18 is held in the braking position. As a result, the braking force is maintained and the operation of the parking brake is completed.

  Next, when the parking brake is released (released), the motor 200 is rotationally driven in the release direction for separating the piston 18 from the disk rotor D by the ECU 175 based on the parking release operation of the parking switch 176. Thereby, the spur multi-stage reduction mechanism 44 and the planetary gear reduction mechanism 45 are driven to rotate in the release direction for returning the piston 18, and the rotation drive in the release direction is transmitted to the base nut 75 via the carrier 62.

  At this time, the reaction force of the pressing force from the disk rotor D acts on the push rod 102. In other words, the push rod 102 has a second force between the push rod 102 and the ball and ramp mechanism 127. The rotation resistance torque of the screw fitting portion 106, the rotation resistance torque of the first screw fitting portion 105 between the push rod 102 and the base nut 75, and the base nut 75 of the push rod 102 by the first spring clutch 100. And a rotational resistance torque in the release direction with respect to. For this reason, the rotational torque in the release direction from the base nut 75 is transmitted to the push rod 102 (including the rotating member 125) and is also transmitted to the rotation linear motion lamp 151 of the ball and ramp mechanism 127. As a result, the rotation linear motion lamp 151 only rotates in the release direction and returns to the initial position in the rotation direction.

  Next, the reaction force to the push rod 102 is reduced, and the rotation resistance torque of the second screw fitting portion 106 between the push rod 102 and the ball and ramp mechanism 127 becomes the base nut by the first spring clutch 100. The rotational resistance torque in the release direction of the push rod 102 with respect to 75 is added to the rotational resistance torque of the first screw fitting portion 105 between the push rod 102 and the base nut 75, so that the rotational resistance becomes smaller. Since the dynamic ramp 151 can no longer rotate in the release direction, only the second screw fitting portion 106 relatively rotates, and the rotary linear motion ramp 151 of the ball and ramp mechanism 127 along with the retainer 110 along the axial direction. Then, it moves to the bottom wall 11 side (release direction) of the cylinder 15 and returns to the initial position in the axial direction.

  Further, when the motor 200 is driven to rotate in the release direction and the rotation of the base nut 75 continues in the release direction, the rotation linear motion lamp 151 of the ball and ramp mechanism 127 returns to the initial position in the axial direction, and the push rod The second screw fitting portion 106 between the ball 102 and the ball and ramp mechanism 127 returns to the initial screwing position, and the rotation of the push rod 102 in the release direction is stopped.

  When the rotation of the base nut 75 is further continued, the push rod 102 moves in the axial direction against the rotational resistance torque in the release direction of the push rod 102 with respect to the base nut 75 by the first spring clutch 100. Along the bottom wall 11 side (release direction) of the cylinder 15. As a result, the one end side washer 120 in the retainer 110 including the retainer 110 together with the push rod 102, the coil spring 121, the other end side washer 122, the support plate 123, the second spring clutch 124, the rotating member 125, the thrust bearing 126, the ball and The constituent members of the ramp mechanism 127, the thrust bearing 128, and the annular pressing plate 129 are integrally retreated toward the bottom wall 11 side (release direction) of the cylinder 15 along the axial direction. Then, the piston 18 is retracted to the original position by the restoring force of the elastic deformation of the piston seal 16 and the braking force is completely released.

  As described above, in the disc brake 1 according to the present embodiment, the carrier 62 of the planetary gear reduction mechanism 45 is supported in the axial direction only by the stopper ring 90 provided in the base nut 75, and has a large-diameter disk shape. One axial end surface (the end surface on each planetary gear 60 side) of the outer peripheral portion of the portion 62B is separated from the annular plate 66, and the other axial end surface (on the cylinder portion 7 side) of the outer peripheral portion of the large-diameter disk-shaped portion 62B. Since the annular notch 62B ′ provided on the end face is also separated from the annular wall 31H of the first housing portion 31, it is possible to suppress the occurrence of wear between the carrier 62 and other constituent members as compared with the conventional case. Can do. In addition, since the carrier 62 is supported in the axial direction only by the stopper ring 90 provided in the base nut 75 and the sliding portion with the other constituent members is minimized, the transmission efficiency of the rotational torque can be improved. . Further, the reliability of the disc brake 1 can be improved.

  Further, in the disc brake 1 according to the present embodiment, the cylindrical support member 33 that regulates the radial movement of the carrier 62 is integrated with the first housing portion 31, so that the position of the cylindrical support member 33 is The accuracy can be improved, and consequently the positional accuracy of the carrier 62 can also be improved.

  DESCRIPTION OF SYMBOLS 1 Disc brake, 2 Inner brake pad, 3 Outer brake pad, 4 Caliper, 6 Caliper main body, 7 Cylinder part, 15 cylinder, 18 piston, 30 Housing, 31 1st housing, 33 Cylindrical support member, 43 Rotation linear motion conversion Mechanism, 45 planetary gear reduction mechanism, 62 carrier, 62A small-diameter disk-shaped part, 75 base nut (rotation transmission member), 90 stopper ring, 200 motor, D disk rotor

Claims (2)

A pair of pads disposed on both axial sides of the rotor across the rotor;
A piston that presses one of the pair of pads against the rotor;
A caliper body having a cylinder portion in which the piston is movably accommodated;
A motor provided in the caliper body;
A speed reduction mechanism that is housed in a housing attached to the caliper body, and that increases and transmits the rotational force from the motor;
Rotational force from the deceleration mechanism is transmitted, and a rotation-linear motion conversion mechanism that to promote the piston,
The deceleration mechanism is
A carrier for transmitting a rotational force from the motor to the rotation / linear motion conversion mechanism;
The rotation / linear motion conversion mechanism is:
A rotation transmitting member for transmitting a rotational force from the carrier from the cylinder part ;
A stopper ring that is provided in the rotation transmission member and restricts movement of the rotation transmission member toward the piston along the axial direction of the rotation transmission member;
The end face of the cylinder portion side of the carrier comes into contact with the stopper ring, disc brake characterized that you have separated from the cylinder portion and the housing. The speed reduction mechanism,
The disc brake according to claim 1, wherein a cylindrical support member integrated with the housing is disposed between an outer peripheral surface of the carrier and the housing.

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