JP2018008675A - Brake hydraulic pressure control device for vehicle, and brake system for motorcycle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a brake hydraulic pressure control device and a brake system for a motorcycle, capable of satisfying requirements for downsizing.SOLUTION: A brake hydraulic pressure control device includes a base body (10) having a pump hole (2H), a motor hole (13H), and a plurality of adjustment valve holes (3H) formed therein. The motor hole (13H) and the plurality of adjusting valve holes (3H) are formed in a same first side face (10E) of the base body (10). A reference plane (A) including the axis of the motor hole (13H) has the plurality of adjustment valve holes (3H) formed on each of both sides thereof. The motor hole (13H) is formed between the plurality of adjustment valve holes (3H).SELECTED DRAWING: Figure 6

Description

  The present invention relates to a brake fluid pressure control device for a vehicle, and a motorcycle brake system including the brake fluid pressure control device.

  Conventionally, in a brake system for a vehicle such as a motorcycle (motorcycle or motorcycle), when a vehicle occupant operates a brake lever, the pressure of the brake fluid in the hydraulic circuit increases, and the wheel is controlled. Power is generated. There is also known a brake system including a brake fluid pressure control device that adjusts the braking force. This brake fluid pressure control device can adjust the braking force generated on the wheels by increasing or decreasing the pressure of the brake fluid in the fluid pressure circuit. As a brake fluid pressure control device, a pump device that changes the pressure of the brake fluid in the fluid pressure circuit, a fluid pressure adjustment valve that increases or decreases the pressure of the brake fluid, a controller that controls their operation, etc. are unitized. There are some (see, for example, Patent Document 1).

JP 2011-51359 A

  In the conventional brake fluid pressure control device, a pump device that changes the pressure of the brake fluid in the fluid pressure circuit is driven by a motor. Further, the conventional brake fluid pressure control device is provided with a plurality of fluid pressure adjusting valves (switching valves) for opening and closing the flow passage of the brake fluid. The motor and the hydraulic pressure adjustment valve are attached to different side surfaces of the base. With such a structure, there was a problem that it was not possible to meet the demand for downsizing.

  The present invention has been made against the background of the above problems, and an object of the present invention is to obtain a brake hydraulic pressure control device and a motorcycle brake system that can meet the demand for downsizing. .

  The brake fluid pressure control device according to the present invention is accommodated in a base body in which a flow path of brake fluid is formed and a pump hole formed in the base body, and applies pressure to the brake fluid. A pump device, a motor that is at least partially housed in a motor hole formed in the base, and a motor that is a drive source of the pump device, and a plurality of adjustment valve holes that are at least partially formed in the base Each of the plurality of hydraulic pressure control valves that open and close the flow path, and a plurality of drive coils that are provided in each of the plurality of hydraulic pressure control valves and drive the hydraulic pressure control valves, A brake fluid pressure control device for a vehicle, wherein the motor hole and the plurality of adjusting valve holes are formed on the same first side surface of the base body and include a reference plane including an axis of the motor hole. On each side of Serial are formed a plurality of holes for adjustment valve, the motor hole are those which are formed between the plurality of holes for adjustment valve.

  A motorcycle brake system according to the present invention includes the above-described brake fluid pressure control device.

  According to the brake fluid pressure control device of the present invention, the motor hole and the plurality of adjustment valve holes are formed on the same side surface of the base, and are respectively provided on both sides of the reference plane including the shaft of the motor hole. Since a plurality of adjustment valve holes are formed and the motor hole is formed between the plurality of adjustment valve holes, the size can be reduced.

  According to the motorcycle brake system of the present invention, the above-described brake fluid pressure control device can satisfy a severe requirement for downsizing of a mounted device in the motorcycle.

It is a mimetic diagram showing an example of composition of a motorcycle to which a brake system for motorcycles including a brake fluid pressure control device concerning an embodiment of the invention was applied. 1 is a configuration diagram of a motorcycle brake system including a brake fluid pressure control device according to an embodiment of the present invention. It is the perspective view seen from the casing side of the brake fluid pressure control device concerning an embodiment of the invention. It is the perspective view seen from the substrate side of the brake fluid pressure control device concerning an embodiment of the invention. 1 is an exploded perspective view of a brake fluid pressure control device according to an embodiment of the present invention. 1 is a perspective view of a base body of a brake fluid pressure control device according to an embodiment of the present invention. It is the perspective view seen from the 1st surface part side of the periphery of the metal piece of the brake fluid pressure control apparatus which concerns on embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings as appropriate.

  In the following, the case where the brake fluid pressure control device according to the present invention is used in a brake system for motorcycles will be described. However, the brake fluid pressure control device according to the present invention is applicable to vehicles other than motorcycles (for example, automobiles). , Trucks, etc.). In the following, a case where the brake hydraulic pressure control device according to the present invention is applied to a brake system including a front wheel hydraulic pressure circuit and a rear wheel hydraulic pressure circuit will be described. The device may be applied to a brake system including only one of a front wheel hydraulic circuit and a rear wheel hydraulic circuit.

  In addition, the configuration and operation described below are examples, and the brake fluid pressure control device according to the present invention is not limited to such a configuration and operation. For example, the brake fluid pressure control device according to the present invention may perform operations other than the operation as an ABS.

  Moreover, in each figure, the relationship of the magnitude | size of each structural member may differ from an actual thing. Moreover, in each figure, the same code | symbol is attached | subjected to the member or part which is the same or equivalent, or attaching | subjecting code | symbol is abbreviate | omitted. Moreover, in each figure, illustration of a detailed part is simplified or abbreviate | omitted suitably.

<External configuration of motorcycle 200>
The configuration of the motorcycle 200 will be described with reference to FIG. In the following description, the motorcycle brake system according to the embodiment of the present invention is referred to as a brake system 100.
FIG. 1 is a schematic diagram showing an example of a configuration of a motorcycle to which a motorcycle brake system including a brake fluid pressure control device according to an embodiment of the present invention is applied.

  The motorcycle 200 is a combination of the wheel W, the vehicle body B, and the brake system 100. In the present embodiment, the motorcycle 200 is described as being a motorcycle. However, the present invention is not limited to this, and a motorcycle may be used.

<Overall configuration of brake system 100>
The overall configuration of the brake system 100 will be described with reference to FIG.
FIG. 2 is a configuration diagram of a motorcycle brake system including a brake fluid pressure control device according to an embodiment of the present invention.

  The brake system 100 includes a brake fluid pressure control device 1 that changes the braking force generated on the wheels W of the motorcycle 200. The brake system 100 also includes a handle lever 24 and a foot pedal 34 that are operated by a user or the like who operates the motorcycle. When the handle lever 24 is operated, a braking force is generated on the front wheel 20, and when the foot pedal 34 is operated, a braking force is generated on the rear wheel 30.

  The brake system 100 includes a front wheel hydraulic circuit C1 through which brake fluid used for generating braking force at the front wheels 20 flows, and a rear wheel hydraulic circuit C2 through which brake fluid used for generating braking force at the rear wheels 30 flows. including. The front wheel hydraulic circuit C1 and the rear wheel hydraulic circuit C2 generate braking force independently of each other. The front wheel hydraulic circuit C1 corresponds to the “first hydraulic circuit” in the present invention. The rear wheel hydraulic circuit C2 corresponds to a “second hydraulic circuit” in the present invention.

  The brake system 100 includes the following configuration as a mechanism for generating a braking force on the front wheels 20. That is, the brake system 100 includes a front brake pad 21 provided corresponding to the front wheel 20, a front wheel cylinder 22 provided with a front brake piston (not shown) for operating the front brake pad 21 slidably, A brake fluid pipe 23 connected to the front wheel cylinder 22 is provided.

  The front brake pad 21 is provided so as to sandwich a rotor (not shown) that rotates together with the front wheel 20. When the front brake pad 21 is pushed by the front brake piston in the front wheel cylinder 22, the front brake pad 21 comes into contact with the rotor, generates a frictional force, and generates a braking force on the front wheel 20 that rotates together with the rotor.

  The brake system 100 includes a first master cylinder 25 attached to the handle lever 24, a first reservoir 26 for storing brake fluid, and a brake fluid pipe 27 connected to the first master cylinder 25. The first master cylinder 25 is slidably provided with a master cylinder piston (not shown). When the handle lever 24 is operated, the master cylinder piston in the first master cylinder 25 moves. Since the pressure of the brake fluid applied to the front brake piston changes depending on the position of the master cylinder piston, the force with which the front brake pad 21 sandwiches the rotor changes, and the braking force of the front wheels 20 changes.

  The brake system 100 has the following configuration as a mechanism for generating a braking force on the rear wheel 30. That is, the brake system 100 includes a rear brake pad 31 provided corresponding to the rear wheel 30, a rear wheel cylinder 32 provided with a rear brake piston (not shown) that moves the rear brake pad 31 slidably, And a brake fluid pipe 33 connected to the rear wheel cylinder 32.

  The rear brake pad 31 is provided so as to sandwich a rotor (not shown) that rotates with the rear wheel 30. When the rear brake pad 31 is pushed by the rear brake piston in the rear wheel cylinder 32, the rear brake pad 31 comes into contact with the rotor to generate a frictional force, and a braking force is generated in the rear wheel 30 that rotates together with the rotor.

  The brake system 100 includes a second master cylinder 35 attached to the foot pedal 34, a second reservoir 36 for storing brake fluid, and a brake fluid pipe 37 connected to the second master cylinder 35. The second master cylinder 35 is provided with a master cylinder piston (not shown) so as to be slidable. When the foot pedal 34 is operated, the master cylinder piston in the second master cylinder 35 moves. Since the pressure of the brake fluid applied to the rear brake piston changes depending on the position of the master cylinder piston, the force with which the rear brake pad 31 pinches the rotor changes, and the braking force of the rear wheel 30 changes.

<Configuration of brake fluid pressure control device 1>
The configuration of the brake fluid pressure control device 1 will be described with reference to FIGS.
FIG. 3 is a perspective view of the brake hydraulic pressure control device according to the embodiment of the present invention as viewed from the casing side. FIG. 4 is a perspective view of the brake fluid pressure control apparatus according to the embodiment of the present invention as viewed from the base side. FIG. 5 is an exploded perspective view of the brake fluid pressure control apparatus according to the embodiment of the present invention.

  The brake fluid pressure control device 1 includes a base body 10 in which an internal flow path 4 (see FIG. 2) through which brake fluid flows, a pump device 2 assembled to the base body 10, a front wheel hydraulic circuit C1, and a rear wheel hydraulic circuit. An openable / closable hydraulic pressure regulating valve 3 provided in C2, a driving coil 11 for driving the hydraulic pressure regulating valve 3, a casing 12 for housing the driving coil 11, a motor 13 as a driving source of the pump device 2, The controller 7 includes a controller 7 that controls operations of the pump device 2 and the hydraulic pressure adjusting valve 3, a controller casing 14 that houses a circuit board 7 </ b> F of the controller 7, and the like.

  Next, the configuration of each part of the brake fluid pressure control device 1 will be described with reference to FIGS.

(Substrate 10)
The base 10 is made of a metal such as aluminum, and is formed from a substantially rectangular parallelepiped block. The base 10 has a side surface 10A, a side surface 10B, a side surface 10C, a side surface 10D, a side surface 10E, and a side surface 10F. Each side is not limited to being flat. That is, each side surface may include a step or the like. The side surface 10E corresponds to the “first side surface” in the present invention. The side surface 10D corresponds to a “second side surface” in the present invention.

  The side surface 10A refers to a side surface that is located on the upper side in FIG. 3 and FIG. The side surface 10B refers to a side surface that is located on the left side in FIG. The side surface 10C refers to a side surface located on the left side in FIG. The side surface 10D refers to the side surface located on the lower side in FIG. 3 and FIG. The side surface 10E refers to the side surface to which the casing 12 is attached in FIG. The side surface 10F refers to a side surface that is located on the right side in FIG. That is, the side surface 10A and the side surface 10D face each other, the side surface 10B and the side surface 10C face each other, and the side surface 10E and the side surface 10F face each other.

  An internal flow path 4 through which brake fluid flows is formed inside the base body 10. The internal flow path 4 constitutes a first internal flow path 4A, a second internal flow path 4B, a third internal flow path 4C that constitute a part of the front wheel hydraulic circuit C1, and a part of the rear wheel hydraulic circuit C2. The fourth internal flow path 4D, the fifth internal flow path 4E, and the sixth internal flow path 4F are configured.

  Various ports P are opened on the side surface 10 </ b> A of the base 10. The various ports P include a first port P1 corresponding to a drive mechanism such as a handle lever 24, a second port P2 corresponding to a drive mechanism such as a foot pedal 34, and a third port corresponding to a drive mechanism such as a front brake pad 21. The port P3 and the fourth port P4 corresponding to the driving mechanism such as the rear brake pad 31 are configured. A brake fluid pipe 27 is connected to the first port P1. A brake fluid pipe 37 is connected to the second port P2. A brake fluid pipe 23 is connected to the third port P3. A brake fluid pipe 33 is connected to the fourth port P4.

  Of the internal flow paths 4, the first internal flow path 4 </ b> A is connected to the brake fluid outflow side of the pump device 2, the first pressure increasing valve 3 </ b> A that is one of the hydraulic pressure adjusting valves 3, and the first port P <b> 1. ing. The first internal flow path 4A is provided with a first flow restrictor 5A that regulates the flow rate of the brake fluid flowing through the internal flow path 4. Of the internal flow path 4, the second internal flow path 4B is connected to the first pressure increasing valve 3A, the first pressure reducing valve 3B that is one of the hydraulic pressure regulating valves 3, and the third port P3. The third internal flow path 4C among the internal flow paths 4 is connected to the brake fluid inflow side of the pump device 2 and the first pressure reducing valve 3B. The third internal flow path 4C is provided with an accumulator 6 that stores the brake fluid in the internal flow path 4.

  4th internal flow path 4D among the internal flow paths 4 is connected to the outflow side of the brake fluid of the pump apparatus 2, the 2nd pressure increase valve 3C which is one of the hydraulic pressure adjustment valves 3, and the 2nd port P2. ing. The fourth internal flow path 4D is provided with a second flow restrictor 5B that regulates the flow rate of the brake fluid flowing through the internal flow path 4. The fifth internal flow path 4E among the internal flow paths 4 is connected to the second pressure increasing valve 3C, the second pressure reducing valve 3D that is one of the hydraulic pressure adjusting valves 3, and the fourth port P4. The sixth internal flow path 4F among the internal flow paths 4 is connected to the brake fluid inflow side of the pump device 2 and the second pressure reducing valve 3D. The sixth internal flow path 4F is provided with an accumulator 6 that stores the brake fluid in the internal flow path 4.

  As shown in FIG. 5, a bottomed motor hole 13H in which the motor 13 and the like are accommodated is formed in the approximate center of the side surface 10E of the base 10. Further, a bottomed adjustment valve hole 3H in which the hydraulic pressure adjustment valve 3 is accommodated is formed around the motor hole 13H. Further, a positioning hole 12H for positioning the casing 12 is formed in the side surface 10E of the base 10. A screw hole 18H that engages with the screw 18 is formed in the side surface 10E of the base body 10. On the side surface 10B and the side surface 10C of the base 10, a pump hole 2H in which the pump device 2 is accommodated is formed. An accumulator hole 6H in which the accumulator 6 is accommodated is formed on the side surface 10D of the base 10. Each hole will be described in detail later.

(Pump device 2)
The pump device 2 conveys the brake fluid in the internal flow path 4 of the base body 10 to the first master cylinder 25 and the second master cylinder 35 side. The pump device 2 is driven by a motor 13. For example, there are two pump devices 2. One pump device 2 is used for conveying brake fluid in the front wheel hydraulic circuit C1, and conveys brake fluid in the third internal flow path 4C to the first internal flow path 4A side. The other pump device 2 is used for conveying brake fluid in the rear wheel hydraulic circuit C2, and conveys brake fluid in the sixth internal channel 4F to the fourth internal channel 4D side. The pump device 2 includes, for example, a piston (not shown) that reciprocates in the pump hole 2H, an elastic body (not shown) attached to the piston, a pump cover (not shown) that closes the pump hole 2H, It is comprised by.

(Motor 13 and reduction mechanism 60)
The motor 13 includes an electric unit 13A including a stator, a rotor, an output shaft, and the like. The motor 13 is provided on the casing 12 side with respect to the base body 10. At the end of the motor 13 on the circuit board 7F side, two motor terminals 13T are erected toward the circuit board 7F. One of the motor terminals 13T is a plus terminal 13T1, and the other of the motor terminals 13T is a minus terminal 13T2. The operation of the motor 13 is controlled by the controller 7.

  The speed reduction mechanism 60 decelerates the rotation generated by the motor 13. That is, the torque generated by the motor 13 is amplified by the speed reduction mechanism 60. The speed reduction mechanism 60 is fitted to the output shaft of the electric part 13 </ b> A of the motor 13. That is, the speed reduction mechanism 60 is attached to the end of the motor 13 on the bottom side of the motor hole 13H. One end of the motor 13 and the speed reduction mechanism 60 are accommodated in the motor hole 13 </ b> H and are fixed to the base body 10 integrally.

(Eccentric mechanism 17)
The eccentric mechanism 17 drives the pump device 2 by the rotational force transmitted from the motor 13. That is, the eccentric mechanism 17 transmits the rotational force amplified by the speed reduction mechanism 60 to the pump device 2. The outer peripheral surface of the eccentric mechanism 17 is eccentric with respect to the rotation shaft of the motor 13. The piston (not shown) of the pump device 2 that is in contact with the outer peripheral surface is pushed by the outer peripheral surface and reciprocates in a direction orthogonal to the rotation axis of the motor 13.

(Hydraulic pressure adjusting valve 3 and drive coil 11)
The hydraulic pressure adjusting valve 3 is a valve provided to open and close the internal flow path 4 of the base body 10. As shown in FIGS. 2 and 5, the hydraulic pressure adjusting valve 3 includes a first pressure increasing valve 3A, a first pressure reducing valve 3B, a second pressure increasing valve 3C, and a second pressure reducing valve 3D. The hydraulic pressure adjusting valve 3 is, for example, an electromagnetic valve that uses the drive coil 11 as a drive source. The energization of the drive coil 11 is controlled by the controller 7 so that the open / close state is switched.

  The drive coil 11 houses a winding inside a cylindrical coil housing 15. One end side of the hydraulic pressure regulating valve 3 is accommodated in a cylindrical opening 15 </ b> A penetrating the coil housing 15. The other end side is accommodated in the adjustment valve hole 3H. In this state, when the energization of the drive coil 11 is turned on and off, the mover housed in the base body 10 of the hydraulic pressure adjusting valve 3 moves, and the valve body interlocked with the mover moves between the closed position and the open position. Move between.

  One end of the coil housing 15 is fixed to the side surface 10 </ b> E of the base 10. A pair of terminal blocks 16 are erected on the other end 15 </ b> C of the coil housing 15. The terminal block 16 is provided with a coil terminal 16A, and power is supplied to the drive coil 11 via the coil terminal 16A.

  The first pressure increasing valve 3A is a valve that is opened when the pressure of the brake fluid in the front wheel cylinder 22 is increased during ABS operation. That is, when the first pressure increasing valve 3A is opened, the brake fluid on the first internal flow path 4A side is pushed into the second internal flow path 4B side by the action of the first master cylinder 25. As a result, the brake fluid pressure in the front wheel cylinder 22 increases, and the braking force of the front wheels 20 increases.

  The first pressure reducing valve 3B is a valve that is opened when the pressure of the brake fluid in the front wheel cylinder 22 is reduced during ABS operation. That is, when the first pressure reducing valve 3B is opened, the brake fluid in the front wheel cylinder 22 flows into the accumulator 6 through the second internal flow path 4B. As a result, the brake fluid pressure in the front wheel cylinder 22 decreases and the braking force of the front wheels 20 weakens.

  The second pressure increasing valve 3C is a valve that is opened when the pressure of the brake fluid in the rear wheel cylinder 32 is increased during the ABS operation. That is, when the second pressure increasing valve 3C is opened, the brake fluid on the fourth internal flow path 4D side is pushed into the fifth internal flow path 4E side by the action of the second master cylinder 35. As a result, the brake fluid pressure in the rear wheel cylinder 32 increases, and the braking force of the rear wheel 30 increases.

  The second pressure reducing valve 3D is a valve that is opened when the pressure of the brake fluid in the rear wheel cylinder 32 is reduced during ABS operation. That is, when the second pressure reducing valve 3D is opened, the brake fluid of the rear wheel cylinder 32 flows into the accumulator 6 through the fifth internal flow path 4E. As a result, the brake fluid pressure in the rear wheel cylinder 32 is reduced, and the braking force of the rear wheel 30 is weakened.

(Accumulator 6)
The accumulator 6 stores the brake fluid in the internal flow path 4. For example, there are two accumulators 6. One accumulator 6 is used for storing brake fluid in the front wheel hydraulic circuit C1. The other accumulator 6 is used for storing brake fluid in the rear wheel hydraulic circuit C2. The accumulator 6 includes, for example, a piston (not shown) that reciprocates in the accumulator hole 6H, an elastic body (not shown) attached to the piston, and an accumulator cover (not shown) that closes the accumulator hole 6H. It is configured.

(Controller 7)
As shown in FIG. 5, the controller 7 includes a circuit board 7F provided with an input unit that receives a signal from the detection mechanism, a processor unit that performs an operation, a storage unit that stores a program, and the like. The circuit board 7F and the motor terminal 13T are electrically connected through the metal piece 7E. The metal piece 7E will be described in detail later.

  The circuit board 7F is formed with a first terminal hole 7Da into which the tip of the metal piece 7E (the tip 7Ea1 of the first end 7Ea in FIG. 7) is inserted. The circuit board 7F has a second terminal hole 7Db into which the tip of the coil terminal 16A is inserted. Further, the circuit board 7F is formed with a pin hole 7Dc into which the tip of the pin 13X standing on the first surface portion 50 of the casing 12 is inserted.

  The controller 7 includes various detection mechanisms that output detection signals to the circuit board 7F. As the detection mechanism, for example, an acceleration sensor used to acquire a road gradient value, a front wheel speed sensor used to calculate the wheel speed of the front wheel 20, and a wheel speed of the rear wheel 30 are used. There are rear wheel speed sensors and the like.

(Casing 12)
The casing 12 includes a frame portion 12 </ b> A and a storage portion 12 </ b> B that is formed on the side of the frame portion 12 </ b> A and stores a connector 7 </ b> A connected to the controller 7. A surface portion of the casing 12 that faces the circuit board 7F is defined as a first surface portion 50, and a surface portion of the casing 12 that faces the base body 10 is defined as a second surface portion 40.

  As shown in FIG. 5, a coil insertion hole 53 and a motor insertion hole 56 are formed in the frame portion 12A. When the drive coil 11 is housed in the coil insertion hole 53, the coil terminal 16A protrudes from the first surface portion 50 of the casing 12, and the circuit board 7F can be connected. When the motor 13 is housed in the motor insertion hole 56, the motor terminal 13 </ b> T passes through the motor terminal opening 56 </ b> B formed in the bottom portion 56 </ b> A of the motor insertion hole 56 and protrudes from the first surface portion 50 of the casing 12. Thus, the metal piece 7E is connected to the end portion (second end portion 7Eb in FIG. 7) on the side not connected to the circuit board 7F. The metal piece 7E will be described in detail later.

  A screw insertion hole 18A for inserting a screw 18 is formed in the frame portion 12A. The screw 18 engages with a screw hole 18H formed in the base body 10, and the casing 12 is held on the side surface 10E of the base body 10.

  A positioning protrusion (not shown) is formed on the second surface portion 40 of the casing 12. The casing 12 is attached to the base body 10 with the positioning projections inserted into the positioning holes 12H. That is, the metal piece 7E is held at a specified position with respect to the base body 10 in a state where the casing 12 is attached to the base body 10.

(Control device casing 14)
The control device casing 14 is attached to the first surface portion 50 of the casing 12 and functions as a lid member that houses the circuit board 7F of the controller 7 therein.

<Details of essential parts of brake fluid pressure control device 1>
The detail of the principal part of the brake hydraulic pressure control apparatus 1 is demonstrated using FIGS.
FIG. 6 is a perspective view of the base body of the brake fluid pressure control apparatus according to the embodiment of the present invention. FIG. 7 is a perspective view of the periphery of the metal piece of the brake fluid pressure control device according to the embodiment of the present invention as seen from the first surface portion side.

First, each hole formed in the base 10 will be described in detail.
As shown in FIG. 6, the motor hole 13 </ b> H and the plurality of adjustment valve holes 3 </ b> H are formed on the same side surface of the base body 10, that is, the side surface 10 </ b> E of the base body 10. Specifically, a plurality of adjustment valve holes 3H are formed on both sides of the reference plane A including the axis of the motor hole 13H. The motor hole 13H is formed between the plurality of adjustment valve holes 3H.

  A regulating valve hole 3H in which the first pressure increasing valve 3A and the first pressure reducing valve 3B included in the front wheel hydraulic circuit C1 are accommodated is formed on the left side of FIG. An adjustment valve hole 3H in which the second pressure increasing valve 3C and the second pressure reducing valve 3D included in C2 are accommodated is formed on the right side of the sheet of FIG. That is, the adjustment valve hole 3H in which the first pressure increasing valve 3A and the first pressure reducing valve 3B included in the front wheel hydraulic pressure circuit C1 are housed, and the second pressure increasing valve 3C and the second pressure reducing valve included in the rear wheel hydraulic pressure circuit C2. An adjustment valve hole 3H in which the valve 3D is accommodated is formed separately on both sides of the reference plane A.

  Further, the adjustment valve hole 3H in which the first pressure increasing valve 3A and the first pressure reducing valve 3B included in the front wheel hydraulic pressure circuit C1 are housed, and the second pressure increasing valve 3C and the second pressure reducing valve included in the rear wheel hydraulic pressure circuit C2. The adjustment valve hole 3H in which the valve 3D is accommodated is formed at a position separated from the reference plane A by an equal distance.

  Screw holes 18H that engage with the screws 18 are formed between the motor holes 13H and the plurality of adjusting valve holes 3H on both sides of the reference plane A.

  The accumulator hole 6H in which the accumulator 6 is accommodated is formed on the side surface 10D of the base 10 that is a side surface different from the side surface 10E. Specifically, the accumulator 6 of the front wheel hydraulic circuit C1 is the same as the adjustment valve hole 3H in the reference plane A in which the first pressure increasing valve 3A and the first pressure reducing valve 3B included in the front wheel hydraulic circuit C1 are accommodated. Formed on the side. The accumulator 6 of the rear wheel hydraulic circuit C2 is formed on the same side of the reference plane A as the adjustment valve hole 3H in which the second pressure increasing valve 3C and the second pressure reducing valve 3D of the rear wheel hydraulic circuit C2 are accommodated. Yes.

Next, the metal piece 7E will be described in detail.
As shown in FIG. 7, the metal piece 7 </ b> E is attached to the first surface portion 50 of the casing 12. The metal piece 7E includes a first end 7Ea that is an end connected to the circuit board 7F, a second end 7Eb that is an end connected to the motor terminal 13T, and a first end 7Ea. And an intermediate extending portion 7Ec that connects the second end portion 7Eb. The metal piece 7E can be formed by processing one sheet metal member. The first end 7Ea corresponds to the “end connected to the circuit board” in the present invention.

  The tip end portion 7Ea1 of the first end portion 7Ea extends in a direction parallel to the rotation axis of the motor 13. The distal end portion 7Ea1 has a tapered shape so that it can be easily inserted into the first terminal hole 7Da of the circuit board 7F. Further, the base portion 7Ea2 of the first end portion 7Ea is inserted into a concave portion 50A formed on the protrusion 56D of the first surface portion 50 of the casing 12. That is, the base portion 7Ea2 of the first end portion 7Ea is supported from the casing 12 side by the concave portion 50A.

  The second end portion 7Eb has a flat plate shape, and a slit portion 7Eb1 is formed substantially at the center. The slit portion 7Eb1 communicates with the motor terminal opening 56B of the casing 12. The motor terminal 13T penetrating through the motor terminal opening 56B and protruding from the first surface portion 50 is sandwiched between the slit portions 7Eb1.

  The intermediate extending portion 7Ec has a shape that meanders a region between the first end portion 7Ea and the second end portion 7Eb. That is, a spring structure for suppressing transmission of vibration is provided in the middle of the intermediate extending portion 7Ec.

  As shown in FIGS. 5 and 7, when the circuit board 7F is attached to the casing 12, the front end 7Ea1 of the first end 7Ea is inserted into the first terminal hole 7Da of the circuit board 7F. Each of the pair of motor terminals 13T is provided with a metal piece 7E. The first end 7Ea of the metal piece 7E connected to one motor terminal 13T and the metal connected to the other motor terminal 13T. The first end 7Ea of the piece 7E is provided at a position shifted to the opposite side with respect to the reference plane A including the straight line L passing through the motor terminals 13T. With such a configuration, it is possible to secure a component mounting space on the circuit board 7F. Further, since the first end portion 7Ea approaches the coil terminal 16A, it is possible to attach the circuit board 7F while supporting only a limited area of the circuit board 7F, and the motor terminal 13T and the coil terminal 16A The workability of connection with the circuit board 7F is improved.

<Effect of brake fluid pressure control device 1>
In the brake fluid pressure control device 1 according to the embodiment, the motor hole 13H and the plurality of adjusting valve holes 3H are formed in the same side surface 10E of the base body 10, and include a reference plane including the axis of the motor hole 13H. A plurality of adjustment valve holes 3H are formed on both sides of A, and a motor hole 13H is formed between the plurality of adjustment valve holes 3H. That is, the motor hole 13H is formed at a position where the space between the plurality of adjustment valve holes 3H is utilized. Therefore, it is possible to reduce the size of the brake fluid pressure control device 1.

  Preferably, in the brake hydraulic pressure control device 1 according to the embodiment, a plurality of adjustment valve holes 3H for accommodating a plurality of hydraulic pressure adjustment valves 3 of the front wheel hydraulic pressure circuit C1, and a plurality of rear wheel hydraulic pressure circuits C2 are provided. A plurality of adjusting valve holes 3 </ b> H for accommodating the hydraulic pressure adjusting valve 3 are formed separately on both sides of the reference plane A. Therefore, it is possible to share the manufacturing process and the manufacturing equipment with the brake hydraulic pressure control device having one hydraulic circuit, and the manufacturing cost is reduced.

  In particular, a plurality of adjustment valve holes 3H for accommodating the plurality of hydraulic pressure adjustment valves 3 of the front wheel hydraulic pressure circuit C1, and a plurality of adjustment valve holes for accommodating the plurality of hydraulic pressure adjustment valves 3 of the rear wheel hydraulic pressure circuit C2. 3H may be formed at a position separated from the reference plane A by an equal distance. With such a configuration, it becomes possible to further share the manufacturing process and manufacturing equipment with the brake hydraulic pressure control device having one hydraulic circuit, and the manufacturing cost is further reduced.

  In particular, the accumulator hole 6H for accommodating the accumulator 6 of the front wheel hydraulic circuit C1 is on the same side as the plurality of adjustment valve holes 3H for accommodating the plurality of hydraulic pressure adjustment valves 3 of the front wheel hydraulic circuit C1 on the reference plane A. The accumulator hole 6H that accommodates the accumulator 6 of the rear wheel hydraulic circuit C2 is formed in the reference plane A, and a plurality of adjustment valves that accommodate the plurality of hydraulic pressure adjustment valves 3 of the rear wheel hydraulic circuit C2 It is good to be formed on the same side as the hole 3H. With such a configuration, it becomes possible to further share the manufacturing process and manufacturing equipment with the brake hydraulic pressure control device having one hydraulic circuit, and the manufacturing cost is further reduced.

  In particular, the plurality of accumulator holes 6 </ b> H may be formed on the side surface 10 </ b> D different from the side surface 10 </ b> E of the base body 10. With such a configuration, it is possible to reduce the size of the brake fluid pressure control device 1 by shortening the internal flow path 4 of the base 10.

  Preferably, in the brake hydraulic pressure control device 1 according to the embodiment, a plurality of screw holes 18H are formed on the side surface 10E of the base body 10, and the screw holes 18H are motors on both sides of the reference plane A, respectively. It is formed between the use hole 13H and the plurality of adjustment valve holes 3H. Therefore, the limited space of the base body 10 can be used effectively, and the brake fluid pressure control device 1 can be further downsized.

  Preferably, in the brake hydraulic pressure control device 1 according to the embodiment, the first end portion 7Ea of the metal piece 7E connected to one of the pair of motor terminals 13T and the other of the pair of motor terminals 13T are connected. The first end portion 7Ea of the metal piece 7E is located on the opposite side with respect to the reference plane A. Therefore, it is possible to secure a large component mounting space in a region facing the motor 13 of the circuit board 7F to mount a large electronic component or to integrate and mount many electronic components. , Design flexibility is improved.

  Although the embodiment has been described above, the present invention is not limited to the description of the embodiment. That is, only a part of the embodiment may be implemented.

  For example, in the brake fluid pressure control apparatus 1 in which the motor hole 13H is not formed between the plurality of adjustment valve holes 3H, the accumulator hole 6H is different from the motor hole 13H and the plurality of adjustment valve holes 3H. It may be formed on the side surface. Further, in such a brake fluid pressure control device 1, the first end 7Ea of one metal piece 7E and the first end 7Ea of the other metal piece 7E are opposite to each other with respect to the reference plane A. It may be located on the side. Even with such a configuration, the same effect as described above is exhibited.

1 Brake fluid pressure control device, 2 pump device, 2H pump hole, 3 fluid pressure adjustment valve, 3H adjustment valve hole, 4 internal flow path, 6 accumulator, 6H accumulator hole, 7 controller, 7Da for 1st terminal Hole, 7Db second terminal hole, 7Dc pin hole, 7E metal piece, 7Ea first end, 7Ea1 tip, 7Ea2 base, 7Eb second end, 7Eb1 slit, 7Ec intermediate extension, 7F circuit board 10 substrate, 10A to 10F side surface, 11 drive coil, 12 casing, 12H positioning hole, 13 motor, 13H motor hole, 13T motor terminal, 13X pin, 14 control device casing, 15 coil housing, 16A coil terminal, 17 eccentric Mechanism, 18 screws, 18H screw holes, 20 front wheels, 21 front brake pads, 22 front wheel cylinders, 3 brake fluid pipe, 24 handle lever, 25 first master cylinder, 26 first reservoir, 27 brake fluid pipe, 30 rear wheel, 31 rear brake pad, 32 rear wheel cylinder, 33 brake fluid pipe, 34 foot pedal, 35 first 2 master cylinder, 36 second reservoir, 37 brake fluid pipe, 50 first surface portion, 50A recess, 53 coil insertion hole, 56 motor insertion hole, 56A bottom portion, 56B motor terminal opening, 56D protrusion, 60 deceleration mechanism, 100 brake System, 200 motorcycle, C1 front wheel hydraulic circuit, C2 rear wheel hydraulic circuit, A reference plane, L straight line.

Claims (8)

A base body (10) in which a flow path (4) for brake fluid is formed;
A pump device (2) that is at least partially housed in a pump hole (2H) formed in the base body (10) and applies pressure to the brake fluid;
A motor (13) which is at least partially housed in a motor hole (13H) formed in the base (10) and is a drive source of the pump device (2);
A plurality of hydraulic pressure control valves (3) that are at least partially housed in a plurality of adjustment valve holes (3H) formed in the base body (10) and open and close the flow path (4);
A plurality of drive coils (11) provided on the plurality of hydraulic pressure control valves (3), respectively, for driving the hydraulic pressure control valves (3);
A brake fluid pressure control device (1) for a vehicle comprising:
The motor hole (13H) and the plurality of adjustment valve holes (3H) are formed on the same first side surface (10E) of the base body (10),
The plurality of adjustment valve holes (3H) are formed on both sides of the reference plane (A) including the shaft of the motor hole (13H),
The motor hole (13H) is formed between the plurality of adjustment valve holes (3H).
Brake fluid pressure control device. The plurality of adjustment valve holes (3H) for accommodating the plurality of hydraulic pressure adjustment valves (3) of the first hydraulic pressure circuit (C1), and the plurality of hydraulic pressure adjustment valves of the second hydraulic pressure circuit (C2) The plurality of adjusting valve holes (3H) for storing (3) are formed separately on both sides of the reference plane (A).
The brake fluid pressure control device according to claim 1. The plurality of adjustment valve holes (3H) for accommodating the plurality of hydraulic pressure adjustment valves (3) of the first hydraulic pressure circuit (C1), and the plurality of hydraulic pressures of the second hydraulic pressure circuit (C2) The plurality of adjustment valve holes (3H) for accommodating the adjustment valve (3) are formed at positions separated by an equal distance from the reference plane (A).
The brake fluid pressure control device according to claim 2. And a plurality of accumulators (6) for storing the brake fluid, each of which is housed in a plurality of accumulator holes (6H) formed in the base body (10).
The accumulator hole (6H) for accommodating the accumulator (6) of the first hydraulic circuit (C1) is the plurality of hydraulic pressures of the first hydraulic circuit (C1) of the reference plane (A). It is formed on the same side as the plurality of adjustment valve holes (3H) for accommodating the adjustment valve (3),
The accumulator hole (6H) for accommodating the accumulator (6) of the second hydraulic circuit (C2) is the plurality of hydraulic pressures of the second hydraulic circuit (C2) on the reference plane (A). It is formed on the same side as the plurality of adjustment valve holes (3H) for accommodating the adjustment valve (3).
The brake fluid pressure control device according to claim 2 or 3. The plurality of accumulator holes (6H) are formed on a second side surface (10D) different from the first side surface (10E) of the base (10).
The brake fluid pressure control device according to claim 4. And a casing (12) for housing the motor (13) and the plurality of drive coils (11).
The casing (12) is fixed to the base (10) with a plurality of screws (18),
A plurality of screw holes (18H) that respectively engage with the plurality of screws (18) are formed in the first side surface (10E) of the base body (10),
The screw holes (18H) are formed between the motor holes (13H) and the plurality of adjusting valve holes (3H) on both sides of the reference plane (A).
The brake fluid pressure control apparatus according to any one of claims 1 to 5. Furthermore, a circuit board (7F) of a controller (7) for controlling driving of the motor (13) is provided,
A pair of motor terminals (13T) of the motor (13) are connected to the circuit board (7F) via metal pieces (7E),
The end (7Ea) of the metal piece (7E) connected to one of the pair of motor terminals (13T) on the side connected to the circuit board (7F), and the pair of motor terminals (13T) The end (7Ea) on the side connected to the circuit board (7F) of the metal piece (7E) connected to the other is located opposite to the reference plane (A). ing,
The brake fluid pressure control apparatus according to any one of claims 1 to 6. The brake fluid pressure control device (1) according to any one of claims 1 to 7 is provided.
Brake system for motorcycles.

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