JP7257302B2 - disc brake - Google Patents

Description

The present invention relates to disc brakes used for braking vehicles.

2. Description of the Related Art Conventionally, disc brakes equipped with a parking brake mechanism have been required to be downsized in order to improve mountability on vehicles. For example, the disc brake described in Patent Document 1 has a parking brake mechanism in which a pawl member engages with a ratchet gear fixed to the rotating shaft of an electric motor by energizing a solenoid, thereby indicating the braking state. keeping.

JP 2015-108412 A

However, in the electric disc brake disclosed in Patent Document 1, the body portion of the solenoid is arranged to protrude from the range of the outer circumference circle of the body portion of the electric motor. There is a risk that the size will increase along the radial direction of the , and it is necessary to improve it.

Another object of the present invention is to provide a disc brake that can be made compact.

As a means for solving the above problems, a disc brake according to the present invention comprises an electric motor having a cylindrical main body, a piston that receives thrust from the electric motor to propel a braking member, and a thrust of the piston. and a solenoid actuator, wherein the axis of the rotating shaft of the electric motor and the radial center of the piston do not coincide in the radial direction, wherein the solenoid actuator moves in the axial direction of the cylindrical main body of the electric motor. On an extension line, the entirety is arranged within the range of the outer circumference circle of the cylindrical main body of the electric motor, and the operating direction of the solenoid actuator is substantially parallel to the radial direction surface of the cylindrical main body of the electric motor. , the solenoid actuator has a columnar body portion, the axial length of the columnar body portion is longer than the radial length, and the outer peripheral surface of the columnar body portion of the solenoid actuator is adapted to rotate the electric motor. It is characterized in that it is arranged so as to be close to the shaft and overlap the rotation shaft of the electric motor when viewed from the radial direction of the columnar main body of the electric motor.

According to the disc brake of the present invention, miniaturization can be achieved.

FIG. 2 is a cross-sectional view of the essential parts of the disc brake according to the present embodiment; FIG. 2 is an enlarged view of a main portion of FIG. 1; FIG. 2 is a perspective view showing the inside of the housing of the disc brake according to the present embodiment, excluding parking brake means; FIG. 2 is an exploded perspective view of parking brake means employed in the disc brake according to the present embodiment; FIG. 2 is a plan view of a state in which the parking brake means employed in the disc brake according to the present embodiment is installed in the housing;

The present embodiment will be described in detail below with reference to FIGS. 1 to 5. FIG.
The disc brake 1 according to this embodiment is an electric brake device that generates a braking force by driving an electric motor 40 during normal running. In the following description, the vehicle inner side (inner side) will be referred to as one end side (cover member 39 side), and the vehicle outer side (outer side) will be referred to as the other end side (disk rotor D side). That is, in FIGS. 1 and 2, the right side is referred to as the one end side, and the left side is referred to as the other end side.

As shown in FIG. 1, a disc brake 1 according to the present embodiment includes a pair of inner brake pads 2 serving as braking members, which are arranged on both sides in the axial direction with a disc rotor D in between, which is attached to a rotating portion of a vehicle. , and an outer brake pad 3 and a caliper 4. This disc brake 1 is constructed as a caliper floating type. The pair of inner and outer brake pads 2 and 3 and the caliper 4 are movably supported in the axial direction of the disc rotor D by a bracket 5 fixed to a non-rotating portion such as a knuckle of the vehicle.

As shown in FIG. 1, the caliper 4 transmits rotation from a caliper main body 8, which is the main body of the caliper 4, and an electric motor 40 to a piston 18 in a cylinder portion 13 of the caliper main body 8 to generate a thrust force on the piston 18. and a transmission mechanism 9 that provides The caliper body 8 is arranged on the base end side facing the inner brake pad 2, and has a cylindrical cylinder portion 13 that opens facing the inner brake pad 2, and an outer side extending from the cylinder portion 13 across the disk rotor D. A pair of claw portions 14, 14 arranged on the tip side extending to the outer brake pad 3 and facing the outer brake pad 3 are provided.

A piston 18 is accommodated in the cylinder portion 13 of the caliper main body 8, that is, in the cylinder bore 16 of the cylinder portion 13 so as to be non-rotatable relative to the cylinder portion 13 and movable in the axial direction. The piston 18 presses the inner brake pad 2 and is formed in a cylindrical shape with a bottom. The piston 18 is accommodated in the cylinder bore 16 of the cylinder portion 13 so that its bottom faces the inner brake pad 2 . The piston 18 is supported so as not to rotate relative to the cylinder bore 16 and thus to the caliper body 8 by the anti-rotation engagement between the bottom portion of the piston 18 and the inner brake pad 2 .

A seal member (not shown) is arranged on the inner peripheral surface of the other end of the cylinder bore 16 of the cylinder portion 13 . The piston 18 is accommodated in the cylinder bore 16 so as to be axially movable while contacting the seal member. A dust boot 20 is interposed between the outer peripheral surface on the bottom side of the piston 18 and the inner peripheral surface on the other end side of the cylinder bore 16 . These seal members and the dust boot 20 prevent foreign matter from entering the cylinder bore 16 of the cylinder portion 13 .

A gear housing 25 is integrally connected to the bottom wall 23 side (one end side) of the cylinder portion 13 of the caliper body 8 . Inside the gear housing 25, an electric motor 40, a spur-tooth multistage reduction mechanism 41, and a planetary gear reduction mechanism 42, which will be described later, are arranged. The gear housing 25 includes a first gear housing portion 27 that mainly accommodates the electric motor 40 and a second gear housing portion 28 that mainly accommodates the planetary gear reduction mechanism 42 . The first gear housing portion 27 includes a motor housing portion 27A in which a columnar body portion 40B of the electric motor 40 is accommodated, and a rotary shaft 40A extending from the columnar body portion 40B of the electric motor 40 in the motor housing portion 27A. and a gear housing portion 27B. As can be seen from FIG. 3, in the gear housing portion 27B, a housing recess 35 for housing a compression coil spring 159 of a braking force holding mechanism 152, which will be described later, is provided at a position close to the pinion gear 47 of the spur-tooth multi-stage speed reduction mechanism 41, which will be described later. is formed. Further, a support pin 36 protrudes toward one end of the gear housing portion 27B at a position close to the accommodation recess 35 . Further, in the gear housing portion 27B, a housing portion 37 for housing a solenoid actuator 155 of a braking force holding mechanism 152, which will be described later, is formed at a position close to the housing recess portion 35. As shown in FIG.

As shown in FIG. 1, the bottom wall 23 of the cylinder portion 13 is integrally connected to the second gear housing portion 28 from the other end side. As a result, the cylinder portion 13 and the motor housing portion 27A (the electric motor 40) of the first gear housing portion 27 are arranged substantially parallel to each other. As a result, the radial center of the piston 18, which is accommodated in the cylinder bore 16 of the cylinder portion 13 so as to be relatively non-rotatable and axially movable, and the axial center of the rotary shaft 40A of the electric motor 40 are aligned in the radial direction. inconsistent along The second gear housing portion 28 is formed with an insertion hole 29 through which a small-diameter cylindrical portion 86 of the carrier 72 including a spindle 93 (to be described later) is inserted. A cylindrical restraining portion 32 is projected from the bottom surface of the second gear housing portion 28 to restrict radial movement of an internal gear 71, which will be described later. An annular groove portion 33 is formed between the cylindrical restraining portion 32 and a wall surface facing the cylindrical restraining portion 32 on the radially outer side of the cylindrical restraining portion 32 . A plurality of engaging recesses (not shown) are formed at intervals in the circumferential direction on the wall surface facing the cylindrical restraining portion 32 . A notch (not shown) is formed in the cylindrical restraining portion 32 so as to avoid interference with a large-diameter gear 53 of a first reduction gear 48, which will be described later. One end side opening of the gear housing 25 is closed by a cover member 39 . The cover member 39 is airtightly attached to the gear housing 25 .

Rotation from the electric motor 40 is transmitted to the piston 18 via the transmission mechanism 9 . The transmission mechanism 9 includes a rotary shaft 40A extending from a cylindrical main body portion 40B of the electric motor 40, a spur-tooth multistage reduction mechanism 41 and a planetary gear reduction mechanism 42 for increasing the rotational torque from the rotary shaft 40A, and the planetary gear reduction and a rotation/linear motion conversion mechanism 43 that converts rotation from the mechanism 42 into linear motion and applies thrust to the piston 18 . Referring also to FIG. 2, the columnar main body portion 40B of the electric motor 40 is arranged inside the motor housing portion 27A of the first gear housing portion 27 as described above, and the rotating shaft 40A extends through the gear housing portion 27B. It is inserted through the hole 38 and extends into the gear housing portion 27B. The spur-tooth multistage reduction mechanism 41 includes a pinion gear 47 , a first reduction gear 48 and a second reduction gear 49 . The first reduction gear 48 and the second reduction gear 49 are made of metal or resin such as fiber-reinforced resin.

As shown in FIG. 2, the pinion gear 47 is formed in a cylindrical shape and is press-fitted and fixed to the rotating shaft 40A of the electric motor 40. As shown in FIG. The first reduction gear 48 is composed of a stepped gear. The first reduction gear 48 includes a large-diameter gear 53 that meshes with the pinion gear 47, and a small-diameter gear 54 that axially extends concentrically from the large-diameter gear 53 toward one end. . The large-diameter gear 53 of the first reduction gear 48 is attached to a notch (not shown) provided in the cylindrical restraint portion 32 of the second gear housing portion 28 and the cylindrical wall portion 80 of the internal gear 71. It is arranged so as to straddle the first gear housing portion 27 and the second gear housing portion 28 so as to enter the provided notch portion (not shown). As a result, the outer peripheral surface of the large-diameter gear 53 of the first reduction gear 48 is arranged in close proximity to the outer peripheral surface of the large-diameter annular plate portion 85 of the carrier 72, which will be described later. The first reduction gear 48 is rotatably supported by a support rod 60 . The support rod 60 is press-fitted and fixed to the gear housing portion 27B of the first gear housing portion 27. As shown in FIG. The axial length of the small-diameter gear 54 is considerably longer than the axial length of the large-diameter gear 53 . The axial length of the small-diameter gear 54 is substantially the same as the axial length of the large-diameter gear 57 of the second reduction gear 49, which will be described later.

The small diameter gear 54 of the first reduction gear 48 meshes with the second reduction gear 49 . The second reduction gear 49 includes a large-diameter large-diameter gear 57 that meshes with the small-diameter gear 54 of the first reduction gear 48, and a small-diameter sun gear that axially extends concentrically from the large-diameter gear 57 toward the other end side. 58 and . A second reduction gear 49 is housed within the second gear housing portion 28 . A through hole 62 is formed in the radially central portion of the second reduction gear 49 so as to extend therethrough in the axial direction. The sun gear 58 is configured as part of the planetary gear reduction mechanism 42 . The large-diameter gear 57 and the sun gear 58 have substantially the same axial length. An annular space 63 is formed between the inner peripheral surface of the large-diameter gear 57 and the outer peripheral surface of the sun gear 58 . One end of the large-diameter gear 57 of the second reduction gear 49 and one end of the sun gear 58 are connected by an annular annular wall portion 65 . An annular stopper portion 66 projecting toward the planetary gear reduction mechanism 42 (the other end side) is formed near the outer peripheral end of the other end side surface of the annular wall portion 65 .

The planetary gear reduction mechanism 42 includes a sun gear 58 of the second reduction gear 49 , a plurality of planetary gears 70 (five in this embodiment), and an internal gear 71 . Rotation from the planetary gear reduction mechanism 42 , that is, rotation from each planetary gear 70 is transmitted to the carrier 72 . Each planetary gear 70 has a gear 75 that meshes with the internal teeth 78 of the sun gear 58 and the internal gear 71, and a hole 76 through which a pin 90 erected from the carrier 72 is rotatably inserted. Each planetary gear 70 is arranged around the sun gear 58 at regular intervals along the circumferential direction. Specifically, each planetary gear 70 is arranged in an annular space 63 between the inner peripheral surface of the large-diameter gear 57 and the outer peripheral surface of the sun gear 58 at regular intervals along the circumferential direction. It meshes with the internal teeth 78 of the null gear 71 .

The internal gear 71 includes internal teeth 78 that mesh with the gears 75 of the planetary gears 70, and an annular wall that extends continuously from one end of the internal teeth 78 toward the center in the radial direction and restricts axial movement of the planetary gears 70. A portion 79 and a cylindrical wall portion 80 extending from the inner tooth 78 toward the other end. A portion of the internal tooth 78 of the internal gear 71 is arranged between the inner peripheral surface of the large diameter gear 57 of the second reduction gear 49 and each planetary gear 70 . As a result, the second reduction gear 49 is rotatably supported with respect to the internal gear 71 . The inner teeth 78 of the internal gear 71, the planetary gears 70, and the sun gear 58 have surfaces on the other end side substantially coplanar. The cylindrical wall portion 80 of the internal gear 71 is formed with a plurality of engagement projections (not shown) protruding radially outward at intervals in the circumferential direction.

The cylindrical wall portion 80 of the internal gear 71 is formed with a notch portion (not shown) in a part of its circumferential direction so as to avoid interference with the large-diameter gear 53 of the first reduction gear 48 . One end surface of the cylindrical wall portion 80 of the internal gear 71 is brought into contact with the bottom surface of the second gear housing portion 28 , and the inner peripheral surface of the cylindrical wall portion 80 is brought into contact with the cylinder of the second gear housing portion 28 . The engaging projections protruding from the cylindrical wall portion 80 are engaged with the engaging recesses provided on the wall surface of the second gear housing portion 28 . An annular stopper portion 66 provided on the annular wall portion 65 of the second reduction gear 49 abuts against the surface of the internal gear 71 on the one end side. As a result, the internal gear 71 is restricted from moving radially and axially, and is supported so as not to rotate relative to the gear housing 25 .

The carrier 72 includes a large-diameter annular plate-shaped portion 85 and a small-diameter cylindrical portion 86 concentrically protruding from the large-diameter annular plate-shaped portion 85 toward the other end side. The carrier 72 is formed so that a spline hole portion 87 penetrates in the axial direction at substantially the center in the radial direction. The large-diameter annular plate-shaped portion 85 is arranged inside the cylindrical restraint portion 32 of the second gear housing portion 28 . A plurality of pin holes 89 are formed on the outer peripheral side of the large-diameter annular plate-like portion 85 of the carrier 72 at intervals along the circumferential direction so as to correspond to the respective planetary gears 70 . A pin 90 is press-fitted and fixed in each pin hole 89 . Each pin 90 is rotatably inserted through the hole 76 of each planetary gear 70 . The small-diameter cylindrical portion 86 of the carrier 72 is inserted through the insertion hole 29 of the second gear housing portion 28 .

The rotation from the carrier 72 is transmitted to the spindle 93 , and the rotational torque is transmitted to the rotation/linear motion conversion mechanism 43 . One end of the spindle 93 is integrally connected with a spline shaft portion 96 that engages with the spline hole portion 87 of the carrier 72 . The spindle 93 extends into the cylinder bore 16 and is connected to the rotation/linear motion converting mechanism 43 . By engaging the spline shaft portion 96 of the spindle 93 with the spline hole portion 87 of the carrier 72 , rotational torque can be transmitted between the carrier 72 and the spindle 93 .

Further, as shown in FIGS. 2 and 4, a parking brake means 150 is provided inside the gear housing portion 27B of the first gear housing portion 27. As shown in FIG. The parking brake means 150 includes a ratchet gear 151 that is press-fitted and fixed to one end of the rotating shaft 40A of the electric motor 40, which is the transmission mechanism 9, and a solenoid actuator 155 that drives the ratchet gear 151 in the direction of releasing the braking force. and a braking force holding mechanism 152 that regulates the rotation and holds the braking force. The ratchet gear 151 is press-fitted and fixed to one end of the rotating shaft 40A protruding from the pinion gear 47 . The braking force holding mechanism 152 includes a solenoid actuator 155, a holding member 157 that is moved by driving the solenoid actuator 155 and restricts the rotation of the ratchet gear 151 in the direction of releasing the braking force, and the holding member 157. A locking member 158 that is coupled and rotatably supported by a support pin 36 provided in the gear housing portion 27B of the first housing 27 to suppress movement of the holding member 157 toward the ratchet gear 151; and a compression coil spring 159 as an elastic member that urges in a direction away from the ratchet gear 151 .

Referring to FIG. 4, the solenoid actuator 155 includes a columnar main body portion 155A and a plunger 155B that moves retractably from one end surface of the columnar main body portion 155A. Referring also to FIG. 5, the columnar body portion 155A is configured such that its axial length is longer than its radial length. An annular flange 156 is provided at the tip of the plunger 155B. The outer diameter of the annular collar portion 156 is larger than the outer diameter of the plunger 155B. When the solenoid actuator 155 is energized, the plunger 155B moves so as to sink into the cylindrical main body 155A. The solenoid actuator 155 operates based on commands from the control board 116, which will be described later.

4 and 5, the holding member 157 has a complicated shape, and includes a pawl portion 168 that can be engaged with the gear portion 151A of the ratchet gear 151 and an annular flange of the plunger 155B of the solenoid actuator 155. It integrally has a plunger connection portion 169 connected to the inside of the portion 156 and a curved portion 170 provided between the claw portion 168 and the plunger connection portion 169 and extending in a curved shape in plan view. A shaft portion 173 extending in the same direction as the plunger 155B of the solenoid actuator 155 is integrally connected to the claw portion 168 . The curved portion 170 is integrally connected to the shaft portion 173 at the end opposite to the claw portion 168 . The curved portion 170 extends in a U-shape in plan view so as to be folded back from the shaft portion 173, and is formed such that its open side faces the ratchet gear 151 side. A plunger connecting portion 169 is integrally connected to the end portion of the curved portion 170 . The plunger connecting portion 169 is formed in a semicircular arc shape so as to surround and support the inner peripheral surface of the plunger 155B from the annular flange portion 156 from the cover member 39 side. A pin 175 projecting toward the cover member 39 side (one end side) is integrally connected to the shaft portion 173 . A plate-like pressing portion 176 that protrudes toward the electric motor 40 side (the other end side) is integrally connected to the shaft portion 173 .

The locking member 158 is formed in a substantially L shape including a plate-like portion 180 and a weight portion 181 extending from the base end portion of the plate-like portion 180 toward the cover member 39 side (one end side). The plate-like portion 180 is formed in a substantially rectangular shape, and its longitudinal direction substantially coincides with the direction orthogonal to the extending direction of the plunger 155B. At the tip of the plate-like portion 180, a U-shaped engagement groove portion 183 is formed in plan view. By engaging the pin 175 of the holding member 157 with the engaging groove portion 183 , both 158 and 157 are connected to each other so as to be rotatable about the pin 175 . A support hole 184 is formed in the substantially central portion of the plate-like portion 180 in the longitudinal direction. A support pin 36 provided in the gear housing portion 27B of the first housing 27 is inserted through the support hole 184 . As a result, the locking member 158 is rotatably supported by the gear housing portion 27B about the support hole 184 (support pin 36). Weight 181 is formed to have a D-shaped cross section. A linear portion of the weight portion 181 faces the plate-like portion 180 side. The weight portion 181 is located on the opposite side of the engagement groove portion 183 with respect to the support hole 184 . The center of gravity of the locking member 158 is located at the weight portion 181 .

As shown in FIGS. 3 to 5, the solenoid actuator 155 is fixed by mounting bolts 186 via brackets 185 in the housing portion 37 of the gear housing portion 27B of the first housing 27. As shown in FIG. As a result, referring to FIG. 5, the solenoid actuator 155 is arranged on the side of the rotating shaft 40A of the electric motor 40 in plan view on the extension line of the one axial end side of the columnar main body portion 40B of the electric motor 40. The cylindrical main body 155A is arranged on the side of the first and second reduction gears 48, 49, and the plunger 155B is arranged at a position away from the first and second reduction gears 48,49. In addition, the solenoid actuator 155 is arranged on an extension line of one axial end side of the columnar main body portion 40B of the electric motor 40 so that the entirety including the plunger 155B is the outer circumference circle R1 of the columnar main body portion 40B of the electric motor 40 (see FIG. 5). (indicated by a two-dot chain line). In other words, the entire solenoid actuator 155 including its plunger 155B is arranged within the range R3 (indicated by the two-dot chain line in FIG. 5). The range R3 is defined by the outer circumference R1 of the cylindrical main body 40B of the electric motor 40 and the outer circumference R2 of the large diameter gear 57 of the second reduction gear 49 (indicated by the chain double-dashed line in FIG. 5). , R2. In this embodiment, the entire solenoid actuator 155 including the plunger 155B is arranged within the range of the outer circumference R1 of the columnar body portion 40B of the electric motor 40. may be arranged within the range of the outer circumference R1 of the columnar body portion 40B.

Further, the axial direction of the cylindrical main body portion 155A and the plunger 155B of the solenoid actuator 155 is perpendicular to the rotary shaft 40A of the electric motor 40 and along the longitudinal direction of the cover member 39 (longitudinal direction of the gear housing 25). extended. Further, the columnar body portion 155A and the plunger 155B of the solenoid actuator 155 are arranged such that their axial directions are substantially parallel to the radial surface of the columnar body portion 40B of the electric motor 40 . That is, the plunger 155B of the solenoid actuator 155 operates in a direction (projection/retraction direction) that is perpendicular to the rotary shaft 40A of the electric motor 40 and along the longitudinal direction of the cover member 39 (the longitudinal direction of the gear housing 25). It is substantially parallel to the radial surface of the columnar main body portion 40B of the electric motor 40 . Furthermore, the columnar main body portion 155A of the solenoid actuator 155 is arranged so as to overlap the rotating shaft 40A of the electric motor 40 in the radial direction of the columnar main body portion 40B of the electric motor 40 .

Also referring to FIG. 2, a compression coil spring 159 is arranged in the housing recess 35 of the gear housing portion 27B. At this time, one end of the compression coil spring 159 is arranged so as to contact the wall surface 35A of the housing recess 35 near the ratchet gear 151 . A holding member 157 is arranged on the cover member 39 side (one end side) of the compression coil spring 159 . Specifically, the holding member 157 is arranged such that the claw portion 168 faces the outer peripheral surface of the ratchet gear 151, the shaft portion 173 overlaps the compression coil spring 159 in plan view, and the pressing portion 176 is compressed. It is arranged so as to contact the other end of the coil spring 159 .

In addition, the semicircular plunger connection portion 169 of the holding member 157 is connected to the outer peripheral surface of the plunger 155B inside from the annular flange portion 156 so as to surround the cover member 39 side. As a result, the support pin 36 projecting from the gear housing portion 27B of the first housing 27 is positioned inside the curved portion 170 of the holding member 157 . Further, the locking member 158 is arranged on the cover member 39 side of the holding member 157 so that the longitudinal direction of the plate-like portion 180 substantially coincides with the direction orthogonal to the extending direction of the plunger 155B. Then, the pin 175 of the holding member 157 is engaged with the engagement groove portion 183 which is U-shaped in plan view provided at the tip of the plate-like portion 180 of the locking member 158, and the pins 175 are engaged with each other. It is rotatably connected to the center. In addition, the support pin 36 projecting from the gear housing portion 27B of the first housing 27 is inserted into the support hole 184 provided in the plate-like portion 180 of the holding member 157, and the tip portion of the support pin 36 is retained. A ring 187 is attached. As a result, the locking member 158 is rotatably supported around the support pin 36 projecting from the gear housing portion 27B of the first housing 27 .

With this configuration, the claw portion 168 of the holding member 157 is normally urged by the compression coil spring 159 in the direction away from the ratchet gear 151 . In this normal state, when an external excitation force acts on the holding member 157, the weight portion 181 of the locking member 158 acts on the holding member 157 to cancel the external excitation force. can be done. That is, when an exciting force acts on the holding member 157 in the direction in which the pawl portion 168 of the holding member 157 faces the outer peripheral surface of the ratchet gear 151, the supporting hole 184 (the supporting pin 36) acts on the locking member 158. 5, in other words, the weight portion 181 (center of gravity) of the locking member 158 moves in the direction opposite to the direction in which the excitation force acts on the holding member 157. A force arises to try. As a result, weight portion 181 of locking member 158 exerts a force on holding member 157 in a direction in which pawl portion 168 moves away from the outer peripheral surface of ratchet gear 151 (claw portion 168 moves toward the outer peripheral surface of ratchet gear 151 ). In addition, the weight portion 181 of the locking member 158 can cancel the vibration force applied to the holding member 157 from the outside.

This situation occurs when the excitation force applied to the holding member 157 exceeds the biasing force of the compression coil spring 159 . Next, when the parking brake is operated to maintain the stopped state of the vehicle, the plunger 155B of the solenoid actuator 155 is retracted by energizing the solenoid actuator 155 . As a result, the pawl portion 168 of the holding member 157 moves toward the outer peripheral surface of the ratchet gear 151 against the biasing force of the compression coil spring 159 and engages with the gear portion 151A. At that time, the locking member 158 rotates counterclockwise in FIG. 5 around the support pin 36 (support hole 184). In other words, when the solenoid actuator 155 is actuated, the locking member 158 causes the weight portion 181 (center of gravity) to move in a direction opposite to the actuation direction of the solenoid actuator 155 (the direction in which the plunger 155B appears and retracts).

As shown in FIGS. 1 and 2, the rotation angle detection means 103 is arranged on one end side of the ratchet gear 151 of the parking brake means 150 . The rotation angle detection means 103 detects the rotation angle of the rotary shaft 40A of the electric motor 40. As shown in FIG. The rotation angle detection means 103 has a magnet member 106 and a magnetic detection IC chip 107 . A press-fit recess 109 is formed in one end surface of the rotating shaft 40A of the electric motor 40 . A support rod 110 is press-fitted into the press-fit recess 109 . A ring-shaped magnet member 106 arranged in a cup-shaped support member 113 is supported by the support rod 110 . A magnetic detection IC chip 107 is arranged so as to face one end of the magnet member 106 . The magnetic detection IC chip 107 detects changes in the magnetic field generated by the magnet member 106 . The magnetic detection IC chip 107 is attached to the control board 116 . The magnetic detection IC chip 107 detects a change in the magnetic flux from the magnet member 106 that rotates as the rotary shaft 40A rotates, and the control board 116 calculates the rotation angle of the rotary shaft 40A of the electric motor 40. detected.

As shown in FIG. 1, the rotary-to-linear motion conversion mechanism 43 converts the rotary motion from the spur-tooth multi-stage reduction mechanism 41 and the planetary gear reduction mechanism 42, that is, the rotary motion of the spindle 93, into linear motion (hereinafter referred to as linear motion for convenience). A thrust force is applied to the piston 18 by the movement of the direct acting member (not shown). The rotation/linear motion converting mechanism 43 is arranged inside the cylinder bore 16 and between the bottom surface thereof and the piston 18 . Then, when the spindle 93 rotates with the rotation of the carrier 72, the linear motion member advances toward the other end side by the rotation-to-linear motion conversion mechanism 43, and the piston 18 advances. The inner brake pad 2 can be pressed against the disk rotor D.

The electric motor 40 is composed of a columnar body portion 40B and a rotating shaft 40A extending from one end surface of the columnar body portion 40B. The columnar main body portion 40B has an axial direction that coincides with the moving direction of the piston 18, and a rotating shaft 40A extends from one end surface thereof. As described above, referring to FIGS. 1 and 2, the columnar main body portion 40B of the electric motor 40 is disposed within the motor housing portion 27A of the first gear housing portion 27, and the rotating shaft 40A thereof extends through the gear housing portion. 27B and extends into the gear housing portion 27B. The driving of the electric motor 40 is controlled by commands from the control board 116 . During braking during normal running, the control board 116 detects signals from detection sensors corresponding to driver requests and various detection sensors for detecting various situations requiring braking, and detection signals from the rotation angle detection means 103 . The driving of the electric motor 40 is controlled based on the signal and the detection signal from a thrust sensor (not shown) or the like. The control board 116 is electrically connected to a parking brake switch (not shown) and a brake pedal (not shown) operated to instruct parking operation. controls the actuation of the solenoid actuator 155 .

Next, in the disc brake 1 according to this embodiment, the operation of braking and braking during normal running will be described.
During braking during normal running, the electric motor 40 is driven by a command from the control board 116, and its rotation in the forward direction, that is, in the braking direction, is transmitted through the spur-tooth multistage reduction mechanism 41 to the sun gear 58 of the planetary gear reduction mechanism 42. is transmitted to The rotation of the sun gear 58 of the planetary gear reduction mechanism 42 causes each planetary gear 70 to rotate about its own rotation axis while revolving about the rotation axis of the sun gear 58 , thereby rotating the carrier 72 . That is, the rotation from the electric motor 40 is transmitted to the carrier 72 through the spur-tooth multi-stage speed reduction mechanism 41 and the planetary gear speed reduction mechanism 42 , reduced and increased at a predetermined reduction ratio. Rotation from the carrier 72 is then transmitted to the spindle 93 .

Subsequently, when the spindle 93 rotates with the rotation of the carrier 72 , the linear motion member advances due to the action of the rotation/linear motion conversion mechanism 43 to advance the piston 18 . The inner brake pad 2 is pressed against the disc rotor D by advancing the piston 18 . Then, the caliper body 8 moves toward the inner side with respect to the bracket 5 due to the reaction force against the pressing force of the piston 18 to the inner brake pad 2, and the outer brake pad 3 is moved toward the disc rotor D by the claw portions 14, 14. impose. As a result, the disc rotor D is sandwiched between the pair of inner and outer brake pads 2, 3 to generate frictional force, which in turn generates braking force for the vehicle.

On the other hand, when the brake is released, the rotation shaft 40A of the electric motor 40 rotates in the opposite direction, that is, in the braking release direction, in response to a command from the control board 116, and the rotation in the opposite direction causes the spur-tooth multistage reduction mechanism 41 and the planetary gear reduction mechanism to rotate. It is transmitted to the spindle 93 via the mechanism 42 . As a result, as the spindle 93 rotates in the opposite direction, the linear motion member retreats due to the action of the rotation/linear motion conversion mechanism 43 to return to the initial state, and the pair of inner and outer brake pads to the disk rotor D is restored. The braking force by 2 and 3 is released.

Next, operation of the parking brake in the disc brake 1 according to this embodiment will be described.
When the parking brake switch or brake pedal is operated, the electric motor 40 is driven by a command from the control board 116 as in normal braking. It is transmitted to the carrier 72 via the planetary gear reduction mechanism 42 . The electric motor 40 can also be driven by a command from the control board 116 based on a signal from the vehicle side, regardless of the driver's operation. Subsequently, when the spindle 93 rotates with the rotation from the carrier 72, the piston 18 advances due to the action of the rotation-to-linear motion conversion mechanism 43, and the disk rotor D is sandwiched between the pair of inner and outer brake pads 2, 3. A braking force is generated when it is attached.

In this state, by energizing the solenoid actuator 155 according to a command from the control board 116, the plunger 155B of the solenoid actuator 155 is retracted. As a result, the pawl portion 168 of the holding member 157 moves toward the outer peripheral surface of the ratchet gear 151 against the biasing force of the compression coil spring 159 and engages with the gear portion 151A. At this time, the locking member 158 rotates counterclockwise in FIG. 5 around the support pin 36 (support hole 184) to move in the direction opposite to the direction in which the solenoid actuator 155 is pushed (the direction in which the plunger 155B is retracted). , the weight portion 181 (center of gravity) of the locking member 158 moves.

At this time, the gear portion 151A of the ratchet gear 151 and the pawl portion 168 of the holding member 157 may interfere with each other and may not be engaged. By rotating, the gear portion 151A of the ratchet gear 151 and the pawl portion 168 of the holding member 157 are reliably engaged. Then, after stopping power supply to the electric motor 40 and confirming the pressing force of the pair of brake pads 4 and 5 against the disk rotor D, power supply to the solenoid actuator 155 is stopped and the gear portion 151A of the ratchet gear 151 is stopped. and the engagement state with the claw portion 168 of the holding member 157 is maintained. As a result, the braking state can be maintained while the electric motor 40 and the solenoid actuator 155 are de-energized. Since the gear portion 151A of the ratchet gear 151 and the pawl portion 168 of the holding member 157 are reliably engaged with each other, the gear portion 151A of the ratchet gear 151 and the holding member are not engaged even when the power supply to the solenoid actuator 155 is stopped. 157 can be kept engaged with the claw portion 168 .

Next, when releasing the parking brake, the solenoid actuator 155 is not energized, and the electric motor 40 is slightly rotated in the braking direction according to a command from the control board 116, causing the ratchet gear 151 to rotate. The engagement between the gear portion 151A and the claw portion 168 of the holding member 157 is loosened, and the claw portion 168 of the holding member 157 moves away from the outer peripheral surface of the ratchet gear 151 by the biasing force of the compression coil spring 159. When the rotation restriction of the ratchet gear 151 is released, the electric motor 40 rotates in the braking release direction, causing the piston 18 to move backward and the braking force by the pair of inner and outer brake pads 4 and 5 to be released.

As described above, the solenoid actuator 155 of the disc brake 1 according to the present embodiment is arranged on the extension line of the cylindrical main body portion 40B of the electric motor 40 from one end in the axial direction. It is arranged within the range of the outer circumference R1 of the columnar body portion 40B. In addition, the operating direction (extending/retracting direction) of the plunger 155B of the solenoid actuator 155 is perpendicular to the rotating shaft 40A of the electric motor 40 and along the longitudinal direction of the cover member 39 (the longitudinal direction of the gear housing 25). It is substantially parallel to the radial surface of the columnar main body portion 40B of the electric motor 40 . As a result, the size of the caliper 4 can be reduced along the radial direction of the cylindrical body portion 40B of the electric motor 40 . Moreover, the columnar body portion 155A of the solenoid actuator 155 is configured such that its axial length is longer than its radial length. Further, the columnar main body portion 155A of the solenoid actuator 155 is arranged so as to overlap the rotating shaft 40A of the electric motor 40 in the radial direction of the columnar main body portion 40B of the electric motor 40 . As a result, the size of the caliper 4 can be reduced also in the axial direction of the columnar body portion 40B of the electric motor 40 .

In the above description, this embodiment is applied to the disc brake 1 as an electric braking device. By advancing the piston 18 with hydraulic pressure, braking force is generated by the pair of inner and outer brake pads 2 and 3, and the driving force from the electric motor 40 is applied to the spur-toothed multistage only during parking brakes such as when parking. The force is transmitted to the piston 18 via a speed reduction mechanism 41, a planetary gear speed reduction mechanism 42, and a rotation/linear motion conversion mechanism 43 to move the piston 18 forward and generate a braking force by the pair of inner and outer brake pads 2 and 3. , may be employed in disc brakes.

1 disc brake, 2 inner brake pad (braking member), 3 outer brake pad (braking member), 18 piston, 40 electric motor (electric motor), 40A rotating shaft, 40B cylindrical main body, 155 solenoid actuator, 155A cylindrical main body part 155B plunger

Claims (1)

an electric motor having a cylindrical body;
a piston that receives thrust from the electric motor and propels the braking member;
a solenoid actuator that holds the thrust of the piston,
In a disc brake in which the axis of the rotating shaft of the electric motor and the radial center of the piston do not coincide in the radial direction,
The solenoid actuator is arranged entirely within the range of the outer circumference of the columnar body of the electric motor on the axial extension line of the columnar body of the electric motor, and the actuation direction of the solenoid actuator is the substantially parallel to the radial plane of the cylindrical main body of the electric motor,
The solenoid actuator has a cylindrical body portion, the axial length of the cylindrical body portion being longer than the radial length,
The outer peripheral surface of the cylindrical main body of the solenoid actuator is arranged so as to be close to the rotating shaft of the electric motor and overlap the rotating shaft of the electric motor when viewed from the radial direction of the cylindrical main body of the electric motor. disc brakes characterized by

Images