JP2021030999A - Fluid pressure control unit, brake system, and saddle-riding type vehicle - Google Patents

Abstract

To obtain a fluid pressure control unit capable of achieving downsizing and inhibiting deterioration of airtightness between a housing and a base.SOLUTION: A fluid pressure control unit (1) of a brake system mounted on a saddle-riding type vehicle includes: a base (10) formed with a brake fluid passage; a coil unit (60) having a coil for driving a fluid pressure adjustment valve which opens or closes the passage and a coil housing (65) holding the coil, and adhered to the base (10); a housing (40) connected the base (10) and housing the coil unit (60); and a resin arm (70) which is held at one end by the housing (40) and contacts with a surface of the coil unit (60) that faces an adhesion surface adhered to the base (10).SELECTED DRAWING: Figure 5

Description

The present invention relates to a hydraulic control unit of a brake system mounted on a saddle-type vehicle, a brake system including the hydraulic pressure control unit, and a saddle-type vehicle equipped with the brake system.

Some conventional vehicles are equipped with a braking system that controls the braking force of the wheels by controlling the hydraulic pressure of the brake fluid. Such a braking system includes a hydraulic pressure control unit. Further, the hydraulic pressure control unit is connected to a substrate on which a flow path of the brake fluid is formed, a coil unit having a coil for driving a hydraulic pressure adjusting valve for opening and closing the flow path of the brake fluid, and a coil unit. It is equipped with a housing in which it is stored. The coil unit is fixed to the substrate by, for example, a bolt which is a fastening member.

Here, a saddle-mounted vehicle, which is a type of vehicle, has a lower degree of freedom in component layout and a lower degree of freedom in mounting a hydraulic pressure control unit than a vehicle such as a motorcycle. For this reason, there is an increasing demand for miniaturization of hydraulic pressure control units mounted on saddle-mounted vehicles. However, when trying to miniaturize the hydraulic pressure control unit, it becomes difficult to secure a space for arranging bolts for fastening the coil unit and the substrate. Therefore, as a conventional hydraulic pressure control unit, a unit in which a coil unit is fixed to a substrate without using bolts, that is, without bolts, has been proposed to reduce the size (see Patent Document 1). Specifically, the hydraulic pressure control unit described in Patent Document 1 includes a silicon ball sandwiched between a housing and a coil unit, presses the coil unit toward the substrate side by the repulsive force of the silicon ball, and presses the coil unit toward the substrate. It is fixed to.

Japanese Unexamined Patent Publication No. 2011-150807

As described above, in the conventional hydraulic pressure control unit which has been miniaturized, the coil unit is pressed toward the substrate by the repulsive force of the silicon ball, and the coil unit is fixed to the substrate. Therefore, in the conventional hydraulic pressure control unit that has been miniaturized, the repulsive force of the silicon ball acts on the coil unit permanently with a constant force. Further, the repulsive force of the silicon ball sandwiched between the housing and the coil unit acts permanently with a constant force in the direction of pulling the housing and the coil unit apart. Therefore, in the conventional hydraulic pressure control unit which has been miniaturized, the force for pulling the housing and the substrate apart acts permanently at the connection point between the housing and the substrate with a constant force. Therefore, the conventional hydraulic pressure control unit that has been miniaturized has a problem that the airtightness between the housing and the substrate tends to decrease.

The present invention has been made against the background of the above-mentioned problems, and an object of the present invention is to obtain a hydraulic pressure control unit that can be miniaturized and can suppress a decrease in airtightness between a housing and a substrate. Another object of the present invention is to obtain a brake system including such a hydraulic pressure control unit. Another object of the present invention is to obtain a saddle-type vehicle equipped with such a braking system.

The hydraulic pressure control unit according to the present invention is a hydraulic pressure control unit of a brake system mounted on a saddle-mounted vehicle, and is a substrate on which a flow path of brake fluid is formed and a hydraulic pressure for opening and closing the flow path. A coil unit having a coil for driving an adjustment valve and a coil housing for holding the coil, a coil unit bonded to the substrate, a housing connected to the substrate and accommodating the coil unit, and one end of the housing. It is provided with a resin arm that is held and is in contact with a surface of the coil unit that faces the surface that adheres to the substrate.

Further, the brake system according to the present invention includes the hydraulic pressure control unit according to the present invention.

Further, the saddle-mounted vehicle according to the present invention is provided with the brake system according to the present invention.

In the hydraulic pressure control unit according to the present invention, the hydraulic pressure control unit is assembled so that the arm is elastically deformed by being pushed by the coil unit until the adhesive between the substrate and the coil unit is hardened. The coil unit can be pressed toward the substrate side by the reaction force of. Therefore, in the hydraulic pressure control unit according to the present invention, the coil unit can be fixed to the substrate by adhesion. Further, the hydraulic pressure control unit according to the present invention employs a resin arm. Therefore, due to the creep phenomenon, the pressing force of the coil unit by the arm decreases with the passage of time. Therefore, in the hydraulic pressure control unit according to the present invention, after the coil unit is adhered to the substrate, the force for pulling the housing and the substrate apart decreases with the passage of time. Therefore, the hydraulic pressure control unit according to the present invention can be miniaturized and can suppress a decrease in airtightness between the housing and the substrate.

It is a figure which shows the schematic structure of the bicycle which mounts the brake system which concerns on embodiment of this invention. It is a figure which shows the schematic structure of the brake system which concerns on embodiment of this invention. It is the figure which observed the inside of the hydraulic pressure control unit which concerns on embodiment of this invention from the side. It is the figure which observed the inside of the hydraulic pressure control unit which concerns on embodiment of this invention from above. It is the figure which observed the inside of the hydraulic pressure control unit which concerns on embodiment of this invention from the side. It is the figure which observed the inside of the hydraulic pressure control unit which concerns on embodiment of this invention from the side. It is a figure for demonstrating the state before the coil unit and the main body part of the housing are connected to the substrate in the hydraulic pressure control unit which concerns on embodiment of this invention. It is a figure for demonstrating the process of supporting a coil unit on a pedestal in the hydraulic pressure control unit which concerns on embodiment of this invention.

Hereinafter, the hydraulic pressure control unit, the brake system, and the saddle-mounted vehicle according to the present invention will be described with reference to the drawings.

In the following, the case where the present invention is adopted for a bicycle (for example, a two-wheeled vehicle, a three-wheeled vehicle, etc.) will be described, but the present invention may be adopted for a saddle-mounted vehicle other than a bicycle. Other saddle-mounted vehicles other than bicycles are, for example, motorcycles, tricycles, buggies, etc., which are driven by at least one of an engine and an electric motor. In addition, a bicycle means all vehicles that can be propelled on the road by the pedaling force applied to the pedals. That is, the bicycle includes a normal bicycle, an electrically assisted bicycle, an electric bicycle and the like. Further, a motorcycle or a tricycle means a so-called motorcycle, and the motorcycle includes a motorcycle, a scooter, an electric scooter and the like.

Further, the configuration, operation, etc. described below are examples, and the hydraulic pressure control unit, brake system, and saddle-mounted vehicle according to the present invention are not limited to such configurations, operations, and the like. For example, in the following, the case where the hydraulic pressure control unit according to the present invention is a pumpless type is described, but even if the hydraulic pressure control unit according to the present invention includes a pump that assists the flow of brake fluid. Good. Further, in the following, the case where the brake system according to the present invention executes anti-lock braking control only for the braking force generated on the front wheels is described, but the brake system according to the present invention is the rear wheels. The anti-lock braking control may be executed only for the braking force generated in the front wheels, or the anti-lock braking control may be executed for both the braking force generated in the front wheels and the braking force generated in the rear wheels. There may be.

Further, in each figure, the same or similar members or parts are designated by the same reference numerals, or the reference numerals are omitted. Further, for the detailed structure, the illustration is simplified or omitted as appropriate. In addition, duplicate explanations are simplified or omitted as appropriate.

<Installation of brake system on bicycle>
The mounting of the brake system according to the embodiment on the bicycle will be described.
FIG. 1 is a diagram showing a schematic configuration of a bicycle equipped with a brake system according to an embodiment of the present invention. Although FIG. 1 shows a case where the bicycle 200 is a two-wheeled vehicle, the bicycle 200 may be another bicycle such as a tricycle.

The bicycle 200, which is an example of a saddle-mounted vehicle, includes a frame 210, a turning portion 230, a saddle 218, a pedal 219, a rear wheel 220, and a rear wheel braking portion 260.

The frame 210 is connected to, for example, a head tube 211 that pivotally supports the steering column 231 of the turning portion 230, a top tube 212 and a down tube 213 connected to the head tube 211, and a top tube 212 and a down tube 213. It includes a seat tube 214 that holds the saddle 218 and a stay 215 that is connected to the upper and lower ends of the seat tube 214 and holds the rear wheels 220 and the rear wheel braking portion 260.

The swivel portion 230 includes a steering column 231, a handle stem 232 held by the steering column 231, a handle bar 233 held by the handle stem 232, and a braking operation portion 240 attached to the handle bar 233. The front fork 216 connected to the steering column 231, the front wheel 217 rotatably held by the front fork 216, and the front wheel braking portion 250 are included. Front forks 216 are provided on both sides of the front wheels 217. One end of the front fork 216 is connected to the steering column 231 and the other end is connected to the rotation center of the front wheel 217.

The braking operation unit 240 includes a mechanism used as an operation unit of the front wheel braking unit 250 and a mechanism used as an operation unit of the rear wheel braking unit 260. For example, the mechanism used as the operation unit of the front wheel braking unit 250 is arranged on the right end side of the handlebar 233, and the mechanism used as the operation unit of the rear wheel braking unit 260 is arranged on the left end side of the handlebar 233. To.

The hydraulic pressure control unit 1 is connected to the front fork 216 of the swivel portion 230. The hydraulic pressure control unit 1 is a unit that controls the hydraulic pressure of the brake fluid of the front wheel braking unit 250. The rear wheel braking unit 260 may be a braking unit of a type that generates a braking force by increasing the hydraulic pressure of the brake fluid, or a braking unit of a type that mechanically generates a braking force (for example,). , A type of braking part that generates a braking force by generating tension in the wire, etc.).

For example, a power supply unit 270 that serves as a power source for the hydraulic pressure control unit 1 is attached to the down tube 213 of the frame 210. The power supply unit 270 may be a battery or a generator. The generator includes, for example, one that generates electricity by running a bicycle 200 (for example, a hub dynamo that generates electricity by the rotation of front wheels 217 or rear wheels 220, an electric motor that is a drive source of front wheels 217 or rear wheels 220, and generates regenerative electric power. Includes those that generate electricity from sunlight.

That is, the bicycle 200 is equipped with a brake system 100 including at least a braking operation unit 240, a front wheel braking unit 250, a hydraulic pressure control unit 1, and a power supply unit 270. The brake system 100 can execute anti-lock braking control by controlling the hydraulic pressure of the brake fluid of the front wheel braking unit 250 by the hydraulic pressure control unit 1.

<Brake system configuration>

The configuration of the brake system according to the embodiment will be described.
FIG. 2 is a diagram showing a schematic configuration of a brake system according to an embodiment of the present invention.
The hydraulic pressure control unit 1 includes a substrate 10. The base 10 is formed with a master cylinder port 11, a wheel cylinder port 12, and a flow path 13 for communicating the master cylinder port 11 and the wheel cylinder port 12.

The flow path 13 is a flow path for the brake fluid. The flow path 13 includes a first flow path 14, a second flow path 15, a third flow path 16, and a fourth flow path 17. The master cylinder port 11 and the wheel cylinder port 12 communicate with each other via the first flow path 14 and the second flow path 15. Further, an end portion on the inlet side of the third flow path 16 is connected to the middle portion of the second flow path 15.

The braking operation unit 240 is connected to the master cylinder port 11 via the liquid pipe 101. The braking operation unit 240 includes a brake lever 241, a master cylinder 242, and a reservoir 243. The master cylinder 242 includes a piston portion (not shown) that moves in conjunction with the operation of the user of the brake lever 241, and is located on the inlet side of the first flow path 14 via the liquid pipe 101 and the master cylinder port 11. It is connected to the. The movement of the piston portion increases or decreases the hydraulic pressure of the brake fluid in the first flow path 14. Further, the brake fluid of the master cylinder 242 is stored in the reservoir 243.

The front wheel braking portion 250 is connected to the wheel cylinder port 12 via the liquid pipe 102. The front wheel braking unit 250 includes a wheel cylinder 251 and a rotor 252. The wheel cylinder 251 is attached to the lower end of the front fork 216. The wheel cylinder 251 includes a piston portion (not shown) that moves in conjunction with the hydraulic pressure of the liquid pipe 102, and is connected to the outlet side of the second flow path 15 via the liquid pipe 102 and the wheel cylinder port 12. Has been done. The rotor 252 is held by the front wheels 217 and rotates together with the front wheels 217. The movement of the piston portion causes the brake pads (not shown) to be pressed against the rotor 252, thereby braking the front wheels 217.

Further, the hydraulic pressure control unit 1 includes a hydraulic pressure adjusting valve 20 that opens and closes the flow path 13. In the present embodiment, the hydraulic pressure control unit 1 includes an inlet valve 21 and an outlet valve 22 as the hydraulic pressure adjusting valve 20. The inlet valve 21 is provided between the outlet side of the first flow path 14 and the inlet side of the second flow path 15, and the brake fluid flows between the first flow path 14 and the second flow path 15. Opens and closes. The outlet valve 22 is provided between the outlet side of the third flow path 16 and the inlet side of the fourth flow path 17, and the brake fluid flows between the third flow path 16 and the fourth flow path 17. Opens and closes. The hydraulic pressure of the brake fluid is controlled by the opening / closing operation of the inlet valve 21 and the outlet valve 22.

Further, the hydraulic pressure control unit 1 includes a coil 61 for driving the inlet valve 21 and a coil 63 for driving the outlet valve 22. For example, when the coil 61 is in the non-energized state, the inlet valve 21 releases the flow of the brake fluid in both directions. Then, when the coil 61 is energized, the inlet valve 21 is closed and shuts off the flow of the brake fluid. That is, in the present embodiment, the inlet valve 21 is a solenoid valve that is open when the power is off. Further, for example, when the coil 63 is in a non-energized state, the outlet valve 22 shuts off the flow of the brake fluid. Then, when the coil 63 is energized, the outlet valve 22 is opened to release the flow of the brake fluid in both directions. That is, in the present embodiment, the outlet valve 22 is a solenoid valve that is closed when the power is off.

Further, the hydraulic pressure control unit 1 includes an accumulator 23. The accumulator 23 is connected to the outlet side of the fourth flow path 17, and the brake fluid that has passed through the outlet valve 22 is stored.

Further, the hydraulic pressure control unit 1 includes a hydraulic pressure sensor 103 for detecting the hydraulic pressure of the brake fluid of the wheel cylinder 251. The hydraulic pressure sensor 103 is provided in the second flow path 15 or the third flow path 16.

Further, the hydraulic pressure control unit 1 includes a control unit 30. Signals from various sensors such as a hydraulic pressure sensor 103 and a wheel speed sensor (not shown) for detecting the rotational speed of the front wheels 217 are input to the control unit 30. It should be noted that each part of the control unit 30 may be arranged together or dispersedly. The control unit 30 may be configured to include, for example, a microcomputer, a microprocessor unit, or the like, or may be configured to include an updatable one such as firmware, or is executed by a command from a CPU or the like. It may be configured to include a program module or the like.

The control unit 30 controls energization of the coil 61 and the coil 63. Specifically, the control unit 30 controls the drive (opening / closing operation) of the inlet valve 21 by controlling the energization of the coil 61. Further, the control unit 30 controls the drive (opening / closing operation) of the outlet valve 22 by controlling the energization of the coil 63. That is, the control unit 30 controls the hydraulic pressure of the brake fluid of the wheel cylinder 251, that is, the braking force of the front wheels 217 by controlling the opening / closing operation of the inlet valve 21 and the outlet valve 22.

In the present embodiment, among the configurations of the control unit 30, at least the configuration for controlling the energization of the coil 61 and the coil 63 is configured by the circuit board 31 described later. That is, the circuit board 31 controls the drive of the inlet valve 21 and the outlet valve 22 by controlling the energization of the coil 61 and the coil 63.

For example, the control unit 30 determines from the signal of the wheel speed sensor (not shown) that the front wheels 217 may be locked or locked when the front wheels 217 are being braked by the operation of the brake lever 241 by the user. Then, the anti-lock brake control is started.

When the anti-lock brake control is started, the control unit 30 energizes the coil 61, closes the inlet valve 21, and shuts off the flow of brake fluid from the master cylinder 242 to the wheel cylinder 251. The pressure increase of the brake fluid of the cylinder 251 is suppressed. On the other hand, the control unit 30 energizes the coil 63, opens the outlet valve 22, and enables the flow of the brake fluid from the wheel cylinder 251 to the accumulator 23, thereby reducing the pressure of the brake fluid in the wheel cylinder 251. Do. As a result, the lock of the front wheel 217 is released or avoided. When the control unit 30 determines from the signal of the hydraulic pressure sensor 103 that the brake fluid of the wheel cylinder 251 has been depressurized to a predetermined value, the control unit 30 de-energizes the coil 63 and closes the outlet valve 22 for a short period of time. The coil 61 is de-energized and the inlet valve 21 is opened to increase the pressure of the brake fluid of the wheel cylinder 251. The control unit 30 may increase or decrease the pressure of the wheel cylinder 251 only once, or may repeat it a plurality of times.

When the anti-lock brake control is completed and the brake lever 241 is returned, the inside of the master cylinder 242 becomes an atmospheric pressure state, and the brake fluid in the wheel cylinder 251 is returned. Further, when the anti-lock brake control is completed and the brake lever 241 is returned, the outlet valve 22 is opened. When the pressure of the brake fluid in the flow path 13 becomes lower than the pressure of the brake fluid stored in the accumulator 23, the brake fluid stored in the accumulator 23 is discharged to the outside of the accumulator 23 without boosting (that is, pumpless). Then, it returns to the flow path 13 and eventually returns to the master cylinder 242.

<Structure of hydraulic pressure control unit>
The configuration of the hydraulic pressure control unit of the brake system according to the embodiment will be described.
As will be described later, the hydraulic pressure control unit 1 includes a base 10 and a housing 40 connected to the base 10. Hereinafter, the configuration of the hydraulic pressure control unit 1 will be described while observing the hydraulic pressure control unit 1 in a state where the housing 40 is arranged above the substrate 10.

FIG. 3 is a side view of the inside of the hydraulic pressure control unit according to the embodiment of the present invention. Specifically, FIG. 3 is a view of observing the hydraulic pressure control unit 1 in the direction of arrow A in FIG. 4, and the portion of the housing 40 on the front side in the direction of arrow A is deleted to observe the hydraulic pressure control unit 1. It is a figure. That is, FIG. 3 is a side view of the inside of the hydraulic pressure control unit 1 in a state where the housing 40 is arranged above the substrate 10. Note that FIG. 4 shows a pair of connecting portions 80. Of these, FIG. 3 omits the illustration of the connection portion 80 described on the right side of the paper in FIG. Further, in FIG. 3, a part of one of the plurality of lid fixing portions 50 and a part of the circuit board 31 are shown in cross section.

FIG. 4 is a view of the inside of the hydraulic pressure control unit according to the embodiment of the present invention observed from above. Specifically, FIG. 4 is a view of the hydraulic pressure control unit 1 with the lid 48 of the housing 40 and the circuit board 31 removed, observed from above.

FIG. 5 is a side view of the inside of the hydraulic pressure control unit according to the embodiment of the present invention. Specifically, FIG. 5 is a view of observing the hydraulic pressure control unit 1 in the direction of arrow B of FIG. 4, and the portion of the housing 40 on the front side in the direction of arrow B is deleted to observe the hydraulic pressure control unit 1. It is a figure. That is, FIG. 5 is a side view of the inside of the hydraulic pressure control unit 1 in a state where the housing 40 is arranged above the substrate 10. In FIG. 5, the lid fixing portion 50 and the connecting portion 80 located in front of the coil unit 60 in the direction of arrow B in FIG. 4 are not shown.

FIG. 6 is a side view of the inside of the hydraulic pressure control unit according to the embodiment of the present invention. Specifically, FIG. 6 is a view of observing the connection portion 80 of the hydraulic pressure control unit 1 in the direction of arrow C in FIG. That is, FIG. 6 is a side view of the inside of the hydraulic pressure control unit 1 in a state where the housing 40 is arranged above the substrate 10.

Hereinafter, the configuration of the hydraulic pressure control unit 1 according to the present embodiment will be described with reference to FIGS. 3 to 6.
The hydraulic pressure control unit 1 includes a substrate 10, a housing 40, a coil unit 60, and a circuit board 31.

The substrate 10 is, for example, a substantially rectangular parallelepiped member made of an aluminum alloy. A housing 40 is connected to the upper surface 18 of the substrate 10. In this embodiment, the housing 40 is connected to the upper surface 18 of the substrate 10 by adhesion. By connecting the base 10 and the housing 40 by adhesion, the airtightness between the base 10 and the housing 40 can be improved. Each surface of the substrate 10 may be flat, may include a curved portion, or may include a step.

The housing 40 has a box shape, for example, a substantially rectangular parallelepiped. In this embodiment, the housing 40 is made of resin. That is, the housing 40 is a resin-formed product. A coil unit 60 and a circuit board 31 are housed inside the housing 40. Further, the housing 40 according to the present embodiment includes a main body portion 41 and a lid 48. The lower surface portion 42 of the main body portion 41 is connected to the upper surface 18 of the housing 40 by adhesion. Further, the main body 41 is formed with an opening 43a in a region facing the circuit board 31. In the present embodiment, the opening 43a is formed on the upper surface 43 of the main body 41. The lid 48 is a member that covers the opening 43a of the main body 41. In the present embodiment, the lid 48 is connected to the main body 41 by adhesion. Specifically, the lower surface portion of the lid 48 is adhered to the peripheral edge of the opening 43a in the upper surface portion 43 of the main body portion 41. By connecting the lid 48 and the main body 41 with an adhesive, the airtightness between the lid 48 and the main body 41 can be improved.

The coil unit 60 includes a coil that drives the hydraulic pressure adjusting valve 20. That is, the coil unit 60 includes a coil 61 and a coil 63. Further, the coil unit 60 includes a coil housing 65 that holds the coil 61 and the coil 63. In the present embodiment, the coil housing 65 includes an upper surface portion 66 arranged above the coil 61 and the coil 63, a lower surface portion 67 arranged below the coil 61 and the coil 63, and an upper surface portion 66 and a lower surface portion 67. It is provided with a side surface portion 68 for connecting to and. In the present embodiment, a notch 66c is formed in the corner portion of the upper surface portion 66 of the coil housing 65, which is in the vicinity of the loading platform 90 described later. The side surface portion 68 of the coil housing 65 connects a portion of the upper surface portion 66 where the notch 66c is not formed and a lower surface portion 67.

The coil unit 60 is connected to the upper surface 18 of the substrate 10. In the present embodiment, the coil unit 60 is connected to the upper surface 18 of the substrate 10 by adhesion. Specifically, an opening 42a is formed in the lower surface 42 of the main body 41 of the housing 40 at a position facing the coil unit 60. Further, the coil unit 60 passes through the opening 42a of the lower surface portion 42 of the main body portion 41. Then, the lower surface portion 67 of the coil housing 65 is connected to the upper surface 18 of the substrate 10 by adhesion.

The circuit board 31 is arranged above the coil unit 60. The circuit board 31 is electrically connected to the connection terminal 62 of the coil 61 and the connection terminal 64 of the coil 63. As a result, the circuit board 31 is configured to be able to control the energization of the coil 61 and the coil 63.

Here, as shown in FIGS. 3 to 5, the hydraulic pressure control unit 1 according to the present embodiment includes at least one resin arm 70. In this embodiment, an example including two arms 70 is shown. One end of one of these arms 70 is held by a first side surface portion 44a, which is one of the side surface portions of the main body portion 41 of the housing 40. Further, the other end of these arms 70 is held by the second side surface portion 44b, which is the side surface portion facing the first side surface portion 44a in the main body portion 41. These arms 70 are in contact with the upper surface 66a of the upper surface 66 of the coil housing 65. In other words, these arms 70 are in contact with the surface of the coil unit 60 facing the adhesive surface with the substrate 10. The arm 70 according to the present embodiment is provided with a protrusion 71 projecting downward in the vicinity of the end portion on the side opposite to the side held by the housing 40. The protrusion 71 is in contact with the upper surface 66a of the upper surface 66 of the coil housing 65. That is, in the present embodiment, the protrusion 71 is the contact point of the arm 70 with the coil unit 60.

Specifically, immediately after the hydraulic pressure control unit 1 is assembled, that is, in a state where the adhesive for adhering the base 10 and the coil unit 60 is not yet solidified, the arm 70 is the upper surface portion 66 of the coil housing 65. The protrusion 71 is pushed upward by the upper surface 66a of the housing, and is elastically deformed. Therefore, in a state where the adhesive for adhering the base 10 and the coil unit 60 is not solidified, the coil unit 60 can be pressed toward the base 10 by the reaction force of the arm 70. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, the coil unit 60 can be fixed to the substrate 10 by adhesion. Therefore, the hydraulic pressure control unit 1 according to the present embodiment can fix the coil unit 60 to the substrate 10 by adhesion without using bolts as fastening members, that is, without bolts. In the hydraulic pressure control unit 1 according to the present embodiment, since the coil unit 60 can be fixed to the substrate 10 without bolts, it is not necessary to secure a space for arranging bolts in the coil unit 60, and the coil unit 60 is downsized. The hydraulic pressure control unit 1 can be miniaturized.

By the way, one end of the arm 70 is held by the housing 40. Therefore, the reaction force of the arm 70 also acts as a force for separating the housing 40 and the base 10 at the connection point between the housing 40 and the base 10. Therefore, when the arm 70 is adopted, there may be a concern that the adhesive portion between the housing 40 and the base 10 is peeled off and the airtightness between the housing 40 and the base 10 is lowered. However, the arm 70 according to this embodiment is made of resin. Therefore, due to the creep phenomenon, the pressing force of the coil unit 60 by the arm 70 decreases with the passage of time. Further, since the progress of the creep phenomenon is also affected by the ambient temperature, when the temperature inside the housing 40 rises due to the heat generated by the circuit board 31, the coil 61 and the coil 63, the creep phenomenon is promoted and the coil unit 60 is pushed by the arm 70. The pressure tends to drop. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, after a certain period of time has elapsed, the pressing force of the coil unit 60 by the arm 70 is peeled off at the adhesive portion between the housing 40 and the substrate 10. It decreases to a size that does not occur. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, it is possible to prevent the adhesive portion between the housing 40 and the base 10 from peeling off, and it is also possible to prevent the airtightness between the housing 40 and the base 10 from being lowered. it can.

The holding position of the arm 70 in the housing 40 is not limited to the first side surface portion 44a and the second side surface portion 44b of the main body portion 41. For example, one end of the arm 70 may be held by the third side surface portion 44c and the fourth side surface portion 44d, which are the side surface portions connecting the first side surface portion 44a and the second side surface portion 44b in the main body portion 41. Further, for example, one end of the arm 70 may be held by the lower surface portion 42 of the main body portion 41.

Further, as shown in FIG. 5, in the present embodiment, the arm 70 is arranged between the coil unit 60 and the circuit board 31. The upper surface 72 of the arm 70 is tilted with respect to the lower surface 32 of the circuit board 31. In other words, in the observation direction perpendicular to the arrangement direction of the coil unit 60, the arm 70, and the circuit board 31, the surface of the arm 70 facing the circuit board 31 is tilted with respect to the surface of the circuit board 31 facing the arm 70. There is. By forming the arm 70 in such a shape, the space between the arm 70 and the circuit board 31 becomes larger than in the case where the upper surface 72 of the arm 70 and the lower surface 32 of the circuit board 31 are parallel, and the circuit board 31 It is possible to expand the area for mounting electronic components and the like. In the present embodiment, the upper surface 72 of the arm 70 is an inclined surface having a linear side view, but may be an inclined surface having a curved side view, and is an inclined surface having a staircase shape in the side view. You may. If the upper surface 72 of the arm 70 is tilted with respect to the lower surface 32 of the circuit board 31, the area for mounting electronic components or the like on the circuit board 31 can be expanded.

Further, as shown in FIG. 5, the shaft 74 of the arm 70 is tilted with respect to the lower surface 32 of the circuit board 31. Moreover, the shaft 74 of the arm 70 is tilted with respect to the upper surface 66a of the upper surface portion 66 of the coil housing 65. In other words, in the observation direction perpendicular to the arrangement direction of the coil unit 60, the arm 70, and the circuit board 31, the axis 74 of the arm 70 is the surface of the circuit board 31 facing the coil unit 60, and the circuit board 31 of the coil unit 60. It is tilted with respect to the surface facing the. The shaft 74 of the arm 70 is a virtual line connecting points at equal distances from the upper surface 72 and the lower surface 73 from one end to the other end of the arm 70.

By arranging the shaft 74 of the arm 70 in this way, for example, as shown in FIG. 5, the upper surface 72 of the arm 70 can be tilted with respect to the lower surface 32 of the circuit board 31. By tilting the upper surface 72 of the arm 70 with respect to the lower surface 32 of the circuit board 31, the space between the arm 70 and the circuit board 31 is compared with the case where the upper surface 72 of the arm 70 and the lower surface 32 of the circuit board 31 are parallel. Can be increased, and the area for mounting electronic components and the like on the circuit board 31 can be expanded. Further, for example, by arranging the shaft 74 of the arm 70 in this way, the lower surface 73 of the arm 70 can be tilted with respect to the upper surface 66a of the upper surface portion 66 of the coil housing 65. By tilting the lower surface 73 of the arm 70 with respect to the upper surface 66a of the upper surface 66 of the coil housing 65, the lower surface 73 of the arm 70 and the upper surface 66a of the upper surface 66 of the coil housing 65 are parallel to each other. The space between the coil unit 60 and the coil unit 60 is increased, and the storage area for stored items can be expanded in the housing 40.

Further, the arm 70 and the main body 41 of the housing 40 are integrally formed of resin. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, the step of assembling the arm 70 to the main body 41 can be deleted, and the assembly man-hours can be reduced.

Further, by providing a plurality of arms 70, the coil unit 60 can be pressed more firmly than when the coil unit 60 is pressed by one arm 70. Therefore, by providing a plurality of arms 70, the certainty of adhesion between the substrate 10 and the coil unit 60 is improved.

Further, in the present embodiment, as shown in FIG. 4, the two arms 70 are in contact with the coil unit 60 at a position symmetrical with respect to the center 69 of the coil unit 60. In other words, in the present embodiment, at least two of the plurality of arms 70 are positioned symmetrically with respect to the center 69 of the coil unit 60 in the observation direction parallel to the arrangement direction of the coil unit 60 and the arm 70. So, it is in contact with the coil unit 60. Therefore, the locational variation of the load applied from the arm 70 to the coil unit 60 is reduced, and the certainty of adhesion between the substrate 10 and the coil unit 60 is improved.

As shown in FIGS. 3 and 4, the hydraulic pressure control unit 1 according to the present embodiment includes at least one lid fixing portion 50 for fixing the lid 48 to the main body portion 41 of the housing 40. In this embodiment, an example including two lid fixing portions 50 is shown. The lid fixing portion 50 is provided inside a space surrounded by the main body portion 41 and the lid 48. Further, the lid fixing portion 50 includes an engaged portion 51 and an engaging portion 55 engaged with the engaged portion 51. The engaged portion 51 is held by one of the main body portion 41 and the lid 48. The engaging portion 55 is held by the other of the main body portion 41 and the lid 48. This embodiment shows an example in which the engaged portion 51 is held by the main body portion 41 and the engaged portion 55 is held by the lid 48. In the present embodiment, of the two configurations that engage with each other when the lid 48 is fixed to the main body 41, the one with the higher rigidity is the engaged portion 51, and the one with the lower rigidity is the engaging portion 55. And.

In the conventional hydraulic pressure control unit, since the structure for fixing the lid to the main body portion is provided so as to project outward from the main body portion and the outer peripheral portion of the lid, it is difficult to reduce the size. On the other hand, the lid fixing portion 50 is provided inside the space surrounded by the main body portion 41 and the lid 48. Therefore, the lid fixing portion 50 does not protrude outward from the outer peripheral portions of the main body portion 41 and the lid 48. Therefore, by fixing the lid 48 to the main body 41 using the lid fixing portion 50, the hydraulic pressure control unit 1 can be made smaller than the conventional hydraulic pressure control unit. Further, after the assembly of the hydraulic pressure control unit 1 is completed, the lid fixing portion 50 is not visible from the outside of the hydraulic pressure control unit 1, so that the design of the hydraulic pressure control unit 1 can be improved. Further, in the hydraulic pressure control unit 1 according to the present embodiment, since the lid 48 can be fixed to the main body 41 without bolts, the number of assembly steps is reduced as compared with the case where the lid 48 is fixed to the main body 41 with bolts. can do.

As a specific structure of the engaged portion 51 and the engaging portion 55 of the lid fixing portion 50, various structures adopted in the conventional snap-fit structure can be adopted, but in the present embodiment, the engaged portion is engaged. The joint portion 51 and the engaging portion 55 have the following structure.

The engaged portion 51 has a tubular shape such as a substantially cylindrical shape. The engaging portion 55 has a columnar shape such as a substantially cylindrical shape. The engaging portion 55 extends inward of the engaged portion 51 and engages with the engaged portion 51 from the inside. Specifically, a convex portion 52 protruding inward is provided on the inner peripheral side of the engaged portion 51. On the other hand, for example, the tip portion of the engaging portion 55 is provided with a convex portion 56 protruding outward from the engaging portion 55. The engaging portion 55 is engaged with the engaged portion 51 from the inside by hooking the convex portion 56 on the convex portion 52 of the engaged portion 51.

Further, in the present embodiment, a hole 33 is formed in the circuit board 31, and the lid fixing portion 50 penetrates the hole 33 of the circuit board 31. When the lid fixing portion 50 does not penetrate the hole 33 of the circuit board 31, the lid fixing portion 50 is arranged on the outer peripheral side of the circuit board 31. Therefore, by penetrating the hole 33 of the circuit board 31 through the lid fixing portion 50, the hydraulic pressure control unit 1 can be downsized as compared with the case where the lid fixing portion 50 is arranged on the outer peripheral side of the circuit board 31. it can.

Here, in the present embodiment, the hole 33 of the circuit board 31 is a position reference hole of the circuit board 31. The position reference hole is a hole that serves as a reference position when mounting an electronic component on the circuit board 31, and is a hole that is always formed on the circuit board 31. By penetrating the lid fixing portion 50 through the position reference hole, it is not necessary to form a dedicated hole for penetrating the lid fixing portion 50 in the circuit board 31. Therefore, by penetrating the lid fixing portion 50 through the position reference hole, the circuit board 31 can be downsized and the hydraulic pressure control unit can be made smaller than the case where a dedicated hole for penetrating the lid fixing portion 50 is formed in the circuit board 31. 1 can be miniaturized.

Further, in the present embodiment, the engaging portion 55 of the lid fixing portion 50 penetrates the hole 33 of the circuit board 31. The engaging portion 55 can be formed thinner than the engaged portion 51. Therefore, by configuring the engaging portion 55 to penetrate the hole 33 of the circuit board 31, the hole 33 can be formed smaller than the configuration in which the engaged portion 51 penetrates the hole 33 of the circuit board 31. The substrate 31 can be miniaturized, and the hydraulic pressure control unit 1 can be miniaturized.

Further, in the present embodiment, the engaged portion 51 and the engaging portion 55 are elastically deformed. Specifically, the engaged portion 51 is formed with a slit 53 extending from the tip end toward the base portion held by the main body portion 41. As a result, the engaged portion 51 is divided into two columnar portions. By configuring the engaged portion 51 in this way, when the engaged portion 55 is inserted into the engaged portion 51, the engaged portion 51 has the tip portion of the engaged portion 51 outward. It can be elastically deformed to spread. The engaged portion 51 may be divided into three or more columnar portions. Further, the engaging portion 55 is formed with a slit 57 extending from the tip end toward the base portion held by the lid 48. As a result, the engaging portion 55 is divided into two columnar portions. By configuring the engaging portion 55 in this way, when the engaging portion 55 is inserted into the engaged portion 51, the engaging portion 55 is elastic so that the tip portion of the engaging portion 55 narrows inward. It can be transformed. The engaging portion 55 may be divided into three or more columnar portions.

When assembling the hydraulic pressure control unit 1, the position of the engaging portion 55 with respect to the engaged portion 51 may deviate from the specified position due to an assembly error of each component of the hydraulic pressure control unit 1. Even in such a case, if the engaged portion 51 and the engaging portion 55 are configured to be elastically deformed, the engaged portion 51 and the engaging portion 55 absorb the assembly error and the engaged portion 51. The engaging portion 55 can be engaged with. Therefore, the hydraulic pressure control unit 1 can be easily assembled by elastically deforming the engaged portion 51 and the engaging portion 55. If the engaged portion 51 or the engaging portion 55 is elastically deformed, the engaged portion 51 and the engaging portion 55 absorb the assembly error and engage the engaged portion 51 with the engaged portion 51. The 55 can be engaged, and the hydraulic pressure control unit 1 can be easily assembled. However, a configuration in which both the engaged portion 51 and the engaging portion 55 are elastically deformed absorbs a larger assembly error than in the case where the engaged portion 51 or the engaging portion 55 is elastically deformed. This makes it easier to assemble the hydraulic pressure control unit 1.

Further, in the present embodiment, the engaged portion 51 of the lid fixing portion 50 and the main body portion 41 of the housing 40 are integrally formed of resin. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, the step of assembling the engaged portion 51 to the main body portion 41 can be deleted, and the assembly man-hours can be reduced. In the case where the engaged portion 51 is held by the lid 48, the man-hours for assembling the hydraulic pressure control unit 1 can be reduced by forming the engaged portion 51 and the lid 48 as an integrally formed product of resin. be able to. Further, in the present embodiment, the engaging portion 55 of the lid fixing portion 50 and the lid 48 of the housing 40 are integrally formed of resin. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, the step of assembling the engaging portion 55 to the lid 48 can be eliminated, and the assembly man-hours can be reduced. When the engaging portion 55 is held by the main body 41, the man-hours for assembling the hydraulic pressure control unit 1 can be reduced by forming the engaging portion 55 and the main body 41 as an integrally formed product of resin. be able to.

Further, in the present embodiment, the hydraulic pressure control unit 1 includes a plurality of lid fixing portions 50. Therefore, in the present embodiment, the lid 48 is fixed to the main body 41 at two or more places. Therefore, when the lid 48 is fixed to the main body 41 by the lid fixing portion 50, the position of the lid 48 can be positioned with respect to the main body 41. Therefore, by providing the plurality of lid fixing portions 50, the hydraulic pressure control unit 1 can be easily assembled.

Further, the hydraulic pressure control unit 1 according to the present embodiment includes a plurality of lid fixing portions 50, and has a configuration in which the lid 48 cannot be fixed to the main body portion 41 in an incorrect orientation. By having the hydraulic pressure control unit 1 having such a configuration, it is possible to prevent the lid 48 from being erroneously attached, and the hydraulic pressure control unit 1 can be easily assembled. Specifically, the virtual axis 58 parallel to the penetrating direction of the opening 43a of the main body 41 of the housing 40 is defined as the virtual axis 58. When the virtual shaft 58 is defined in this way, when the lid 48 is rotated 180 ° from the regular mounting position with the virtual shaft 58 as the center of rotation, at least one engaging portion 55 of the plurality of lid fixing portions 50 becomes , It is configured not to engage with any of the engaged portions 51 of the plurality of lid fixing portions 50. Such a configuration can be realized, for example, by arranging at least two of the plurality of lid fixing portions 50 at positions that are not point-symmetrical about the virtual axis 58. Further, for example, such a configuration can be realized by making the sizes of the engaged portion 51 and the engaging portion 55 different in at least two of the plurality of lid fixing portions 50.

As shown in FIGS. 4 and 6, the hydraulic pressure control unit 1 according to the present embodiment includes at least one connecting portion 80 for connecting the base 10 and the housing 40. In this embodiment, an example including two connecting portions 80 is shown. Further, as described above, the housing 40 according to the present embodiment includes a main body portion 41 and a lid 48. Therefore, in the present embodiment, the connecting portion 80 connects the base 10 and the main body portion 41 of the housing 40. The connecting portion 80 includes a recess 81 formed in the substrate 10. In the hydraulic pressure control unit 1 according to the present embodiment, the main body 41 of the housing 40 is connected to the upper surface 18 of the substrate 10. Therefore, in the present embodiment, the recess 81 is formed so as to be recessed downward from the upper surface 18 of the substrate 10. Further, the connecting portion 80 includes a pin 82 which is held by the main body portion 41 of the housing 40 and whose lower end portion 83 is press-fitted into the recess 81. That is, the lower end portion 83 of the pin 82 held by the main body portion 41 of the housing 40 is press-fitted into the recess 81 of the base 10, so that the base 10 and the main body portion 41 of the housing 40 are connected. ..

As a connection configuration between the base and the housing in the conventional hydraulic pressure control unit, a connection by a bolt which is a fastening member is known. Here, the bolt includes a male screw forming portion on which a male screw is formed and a head to which a tool is connected. When the width in the direction perpendicular to the axial direction of the bolt is defined as the width, the width of the head is larger than the width of the male screw forming portion. Therefore, it is difficult to miniaturize the conventional hydraulic pressure control unit because it is necessary to secure a large space for arranging the head of the bolt connecting the housing and the substrate. On the other hand, since the hydraulic pressure control unit 1 according to the present embodiment can connect the base 10 and the main body 41 of the housing 40 without using bolts (without bolts), it is necessary to secure a space for arranging the heads of the bolts. There is no. Therefore, the hydraulic pressure control unit 1 according to the present embodiment can be downsized as compared with the conventional hydraulic pressure control unit.

Further, in the hydraulic pressure control unit 1 according to the present embodiment, as described above, the substrate 10 and the main body 41 of the housing 40 are adhered to each other. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, when a force that separates the main body 41 of the housing 40 from the base 10 acts, the force is applied to the connecting portion 80 to the base 10 and the housing 40. It can also be received by the adhesive force of the adhesive that adheres to the main body 41. Therefore, in the case where the base 10 and the main body 41 of the housing 40 are adhered to each other, the pin 82 of the connecting portion 80 is made thinner than the configuration in which the base 10 and the main body 41 of the housing 40 are not adhered. Therefore, the hydraulic pressure control unit 1 can be miniaturized.

Further, in the present embodiment, the hydraulic pressure control unit 1 includes a plurality of connecting portions 80. Therefore, in the present embodiment, the main body 41 of the housing 40 is fixed to the substrate 10 at two or more points. Therefore, when the main body 41 of the housing 40 is connected to the base 10 by the connecting portion 80, the position of the main body 41 of the housing 40 can be positioned with respect to the base 10. Therefore, by providing the plurality of connecting portions 80, the hydraulic pressure control unit 1 can be easily assembled.

The material of the pin 82 is not particularly limited, and the pin 82 may be made of resin or the pin 82 may be made of metal. In the case of the resin pin 82, the man-hours for assembling the hydraulic pressure control unit 1 can be reduced by forming the pin 82 integrally with the housing 40. On the other hand, since the metal pin 82 does not cause a creep phenomenon, when the pin 82 is made of metal, the force of connecting the main body 41 of the housing 40 and the base 10 in the connecting portion 80 decreases with the passage of time. Can be suppressed.

Further, the configuration in which the main body 41 of the housing 40 holds the pin 82 is not particularly limited. The pin 82 may not come off from the main body 41 after the assembly of the hydraulic pressure control unit 1 is completed. For example, the pin 82 may be hooked on the step portion of the main body 41. If the pin 82 is sandwiched between the step portion of the main body 41 and the base 10, it is possible to prevent the pin 82 from coming off the main body 41 after the assembly of the hydraulic pressure control unit 1 is completed. In the present embodiment, the pin 82 is fixed to the main body 41 of the housing 40 by molding. Specifically, the pin 82 is fixed by molding at the holding portion 45 of the main body portion 41 made of resin. That is, the holding portion 45 is a portion for molding the pin 82. By fixing the pin 82 to the main body 41 of the housing 40 by molding, the pin 82 can be held by the main body 41 when the main body 41 is formed. Therefore, by fixing the pin 82 to the main body 41 of the housing 40 by molding, the man-hours for assembling the hydraulic pressure control unit 1 can be reduced.

Further, in the present embodiment, the pin 82 is provided with at least one protruding portion 85 at a portion of the pin 82 that is molded in the main body portion 41 of the housing 40. The protruding portion 85 projects in a direction that is not parallel to the direction in which the pin 82 is press-fitted into the recess 81. As shown in FIG. 6 and the like, in the present embodiment, the pin 82 is pushed downward and press-fitted into the recess 81. Therefore, in the present embodiment, the protruding portion 85 protrudes in the lateral direction. By providing the pin 82 with the protruding portion 85, it is possible to prevent the pin 82 from coming out of the holding portion 45, and the reliability of the connection between the base 10 and the main body portion 41 of the housing 40 is improved.

Further, in the present embodiment, the end portion of the pin 82 opposite to the end portion of the pin 82 that is press-fitted into the recess 81, that is, the upper end portion 84 of the pin 82 is the pin 82 in the main body portion 41 of the housing 40. It protrudes from the holding portion 45, which is a portion for molding. As a result, the pin 82 can be directly pushed into the recess 81, so that the hydraulic pressure control unit 1 can be easily assembled.

Further, in the present embodiment, the pin 82 has a plate shape. By making the pin 82 into a plate shape, the pin 82 can be elastically deformed, so that the pin 82 can be press-fitted into the recess 81 while absorbing the assembly error of each component of the hydraulic pressure control unit 1. Therefore, by making the pin 82 into a plate shape, the hydraulic pressure control unit 1 can be easily assembled.

Further, in the present embodiment, a through hole 86 is formed at the end of the plate-shaped pin 82 on the side pressed into the recess 81, that is, at the lower end 83 of the plate-shaped pin 82. As a result, when the lower end 83 of the pin 82 is press-fitted into the recess 81, the lower end 83 of the pin 82 can be elastically deformed in the recess 81. Therefore, by forming the through hole 86 in the lower end portion 83 of the plate-shaped pin 82, the lower end portion 83 of the pin 82 can be easily press-fitted into the recess 81, and the hydraulic pressure control unit 1 can be easily assembled.

As shown in FIGS. 3 to 5, the hydraulic pressure control unit 1 according to the present embodiment includes at least one loading platform 90 held in the housing 40. In this embodiment, an example including two loading platforms 90 is shown. Further, as described above, the housing 40 according to the present embodiment includes a main body portion 41 and a lid 48. In the present embodiment, the loading platform 90 is held by the main body 41 of the housing 40.

At least a part of the cradle 90 is arranged below a part of the coil housing 65 of the coil unit 60. In this embodiment, an example is shown in which the entire portion of the loading platform 90 is arranged below the upper surface portion 43 of the coil housing 65. Here, the loading platform 90 supports a part of the coil housing of the coil unit 60 in a state before the coil unit 60 and the main body 41 of the housing 40 are connected to the base 10. Therefore, if the platform 90 can support the coil unit 60, at least a part of the platform 90 may be arranged below a portion of the coil housing 65 other than the upper surface portion 43. For example, a step portion may be provided on the side surface portion 68 of the coil housing 65, and at least a part of the loading platform 90 may be arranged below the step portion of the side surface portion 68 of the coil housing 65. In this case, in the state before the main body 41 of the coil unit 60 and the housing 40 is connected to the base 10, the pedestal 90 can support the step portion of the side surface portion 68 of the coil housing 65, and the pedestal 90 can be supported. Can support the coil unit 60. Further, if a part of the pedestal 90 is arranged below a part of the coil housing 65 of the coil unit 60, the remaining part of the pedestal 90 may be arranged above the coil housing 65. For example, the platform 90 may be held by the main body 41 of the housing 40 at a position higher than the coil housing 65. If a part of the pedestal 90 is arranged below a part of the coil housing 65 of the coil unit 60, the pedestal 90 is in a state before the coil unit 60 and the main body 41 of the housing 40 are connected to the base 10. Can support the coil unit 60.

FIG. 7 is a diagram for explaining a state before the coil unit and the main body of the housing are connected to the substrate in the hydraulic pressure control unit according to the embodiment of the present invention.
As shown in FIG. 7, in the state before the main body 41 of the coil unit 60 and the housing 40 is connected to the base 10, the loading platform 90 is a portion arranged below the upper surface 43 of the coil housing 65. The lower surface 66b of the upper surface 43 of the coil housing 65 is supported from below by the support 91 which constitutes at least a part of the above. As described above, in the present embodiment, the entire portion of the loading platform 90 is arranged below the upper surface portion 43 of the coil housing 65. Therefore, the lower end portion 92 of the loading platform 90 is held by the main body portion 41 of the housing 40, and the upper end portion 93 serves as the support portion 91.

The conventional hydraulic pressure control unit has a configuration in which a coil unit is attached to a substrate and then a housing is attached to the substrate. Here, in order to reduce the size of the hydraulic pressure control unit, the gap between the coil unit and the housing must be reduced. However, in the conventional hydraulic pressure control unit, when the gap between the coil unit and the housing becomes small, when the coil unit is displaced from the specified position and attached to the substrate, the upper part of the coil unit and the lower part of the housing are separated from each other. It interferes and makes assembly difficult. Further, there is a concern that the connection terminal of the coil may be bent due to the interference between the upper part of the coil unit and the lower part of the housing.

On the other hand, in the hydraulic pressure control unit 1 according to the present embodiment, both the coil unit 60 and the main body 41 of the housing 40 are positioned together with respect to the substrate 10 by supporting the coil unit 60 on the loading platform 90. can do. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, even when the gap between the coil unit 60 and the main body 41 of the housing 40 becomes small, the upper part of the coil unit 60 and the main body 41 of the housing 40 It is possible to suppress interference with the lower part of the housing. Therefore, the hydraulic pressure control unit 1 according to the present embodiment can be downsized as compared with the conventional hydraulic pressure control unit. Further, since the hydraulic pressure control unit 1 according to the present embodiment can suppress the interference between the upper part of the coil unit 60 and the lower part of the main body 41 of the housing 40, the connection terminal 62 of the coil 61 and the coil 63 are connected. It is also possible to prevent the terminal 64 from bending.

Here, as shown in FIG. 3, the length La and the length Lb are defined as follows in a state where the main body 41 of the coil unit 60 and the housing 40 is connected to the substrate 10. The length La is the length in the vertical direction from the connection point between the main body 41 of the housing 40 and the upper surface 18 of the base 10 to a part of the coil housing 65 supported by the support 91 of the loading platform 90. As described above, in the present embodiment, the lower surface 66b of the upper surface 66 of the coil housing 65 is supported by the support 91 of the pedestal 90. Therefore, in the present embodiment, the length La is the length in the vertical direction from the connection point between the main body 41 of the housing 40 and the upper surface 18 of the base 10 to the lower surface 66b of the upper surface 66 of the coil housing 65. It has become. The length Lb is the length in the vertical direction from the connection point between the main body 41 of the housing 40 and the upper surface 18 of the base 10 to the support 91 of the loading platform 90. When the length La and the length Lb are defined in this way, the length La is longer than the length Lb.

By making the length La longer than the length Lb, a part supported by the support portion 91 of the mounting base 90 in the coil housing 65 in a state where the main body portion 41 of the coil unit 60 and the housing 40 is connected to the substrate 10. A gap is formed between the and the support portion 91 of the loading platform 90. As a result, when the coil unit 60 and the main body 41 of the housing 40 are connected to the base 10, the coil unit 60 is not pressed upward by the pedestal 90, and the coil unit 60 and the base 10 are adhered to each other. Increased certainty.

Further, as described above, in the present embodiment, the loading platform 90 is arranged below the upper surface portion 66 of the coil housing 65, the lower end portion 92 is held by the main body portion 41 of the housing 40, and the upper end portion 93. Is the support portion 91. When a part of the pedestal 90 is provided above the upper surface portion 66 of the coil housing 65, the part of the pedestal 90 is laterally provided between the upper surface portion 66 of the coil housing 65 and the main body portion 41 of the housing 40. It will be placed in the gap to be formed. On the other hand, by arranging the entire portion of the loading platform 90 below the upper surface portion 66 of the coil housing 65, a gap formed in the lateral direction between the upper surface portion 66 of the coil housing 65 and the main body portion 41 of the housing 40 is formed. It is not necessary to arrange a part of the housing 90. Therefore, by arranging the entire portion of the loading platform 90 below the upper surface portion 66 of the coil housing 65, the gap formed laterally with the main body portion 41 of the housing 40 can be reduced, and the hydraulic pressure can be controlled. The unit 1 can be miniaturized.

Further, the hydraulic pressure control unit 1 according to the present embodiment includes a plurality of mounting stands 90. When the coil unit 60 is supported by one mounting table 90, the mounting table 90 supports the vicinity of the position of the center of gravity of the coil unit 60 in a plan view. However, when trying to miniaturize the hydraulic pressure control unit 1, it may be difficult to secure a space supported by the mounting table 90 in the vicinity of the position which is the center of gravity of the coil unit 60 in a plan view. On the other hand, when the coil unit 60 is supported by a plurality of pedestals 90, the plurality of pedestals 90 are brought into contact with the vacant space without supporting the vicinity of the position of the center of gravity of the coil unit 60 in a plan view. , The coil unit 60 can be supported. Therefore, the hydraulic pressure control unit 1 can be miniaturized by providing a plurality of mounting stands 90.

Further, in the present embodiment, the main body 41 of the housing 40 and the pedestal 90 are integrally formed of resin. Therefore, in the hydraulic pressure control unit 1 according to the present embodiment, the step of assembling the loading platform 90 to the main body 41 can be deleted, and the assembly man-hours can be reduced.

Further, in the present embodiment, as described above, the arm 70 is provided. Therefore, as shown in FIG. 7, the coil housing 65 is sandwiched between the arm 70 and the cradle 90 before the coil unit 60 and the main body 41 of the housing 40 are connected to the base 10. Therefore, by providing the arm 70, the coil unit 60 can be stably held in the main body 41 of the housing 40, and the hydraulic pressure control unit 1 can be easily assembled. This effect can be obtained even when the arm 70 is made of metal. When the arm 70 is made of resin, it is preferable that the main body 41 of the housing 40, the cradle 90, and the arm 70 are integrally formed of resin. The step of assembling the mounting base 90 and the arm 70 to the main body 41 of the housing 40 can be eliminated, and the assembly man-hours can be reduced.

FIG. 8 is a diagram for explaining a process of supporting the coil unit on the platform in the hydraulic pressure control unit according to the embodiment of the present invention.
As shown in FIG. 8, in the present embodiment, the platform 90 is elastically deformable up to a position outside the coil unit 60 when the inside of the hydraulic pressure control unit 1 is observed from above. ing. As shown in FIG. 4, a notch 66c is formed in the upper surface portion 66 of the coil housing 65 of the coil unit 60. Further, in FIG. 8, the loading platform 90 has a configuration that can be elastically deformed up to a position outside the notch 66c when the inside of the hydraulic pressure control unit 1 is observed from above. By configuring the loading platform 90 in this way, the degree of freedom in designing the hydraulic pressure control unit 1 is improved.

Specifically, when the mounting table 90 is not elastically deformed to a position outside the coil unit 60 when the inside of the hydraulic pressure control unit 1 is observed from above, the coil unit 60 is lowered from above the mounting table 90. The coil unit 60 will be supported by the pedestal 90. In such a case, it is necessary to take care so that the parts arranged in the main body 41 of the housing 40 do not interfere with each other when the coil unit 60 is lowered toward the pedestal 90.

On the other hand, as shown in FIG. 8, when the mounting table 90 can be elastically deformed to a position outside the coil unit 60 when the inside of the hydraulic pressure control unit 1 is observed from above, the coil unit 60 is formed from below the mounting table 90. Can be raised to support the coil unit 60 on the platform 90. Specifically, the coil unit 60 is passed from below through the opening 42a formed in the lower surface portion 42 of the main body portion 41 of the housing 40, and the coil unit 60 is raised. As the coil unit 60 is raised, the pedestal 90 comes into contact with the edge of the notch 66c of the upper surface portion 66 of the coil housing 65. Then, the loading platform 90 elastically deforms outward as the coil unit 60 rises. Then, when the coil unit 60 is further raised and the upper surface portion 66 of the coil housing 65 goes above the support portion 91 of the mounting base 90, the mounting base 90 returns to its original shape, and the support portion 91 of the mounting base 90 returns. It will be located below the lower surface portion 42 of the main body portion 41. As a result, the coil unit 60 can be supported by the pedestal 90. In this way, when the mounting table 90 can be elastically deformed to a position outside the coil unit 60 when the inside of the hydraulic pressure control unit 1 is observed from above, the coil unit 60 is moved from both above and below the mounting table 90. Since it can be supported by the loading platform 90, the degree of freedom in designing the hydraulic pressure control unit 1 is improved.

Further, in a mounting table 90 that can be elastically deformed to a position outside the coil unit 60 when the inside of the hydraulic pressure control unit 1 is observed from above, the lower end portion 92 is arranged below the upper surface portion 66 of the coil housing 65. When the housing 40 is held by the main body 41 and the upper end 93 serves as the support 91, it is preferable that the loading platform 90 has the shape shown in FIG. Specifically, the width of the loading platform 90 decreases from the lower end 92 to the middle 94 as it goes upward, increases as it goes upward from the middle 94, and the width of the upper end 93 becomes halfway. It is preferably wider than the width of the portion 94. In the mounting table 90 configured in this way, since the lateral width decreases from the lower end portion 92 to the middle portion 94 toward the upper side, elastic deformation is likely to occur, and the coil unit 60 is easily deformed from below the mounting table 90. It becomes easy to support the loading platform 90. Further, in the mounting table 90 configured in this way, the width increases from the middle portion 94 toward the upper side, and the width of the upper end portion 93 is wider than the width of the middle portion 94. Therefore, the area supporting the coil housing 65 can be increased. Therefore, in the mounting table 90 configured in this way, the stability when the coil unit 60 is supported by the mounting table 90 is improved. Therefore, by using the mounting table 90 configured in this way, the hydraulic pressure control unit 1 can be easily assembled.

Further, as described above, the hydraulic pressure control unit 1 according to the present embodiment includes an accumulator 23 that stores the brake fluid at the time of depressurization in the antilock brake control, and discharges the brake fluid in the accumulator 23 to the outside of the accumulator 23 without a pump. It is configured to. The pumpless hydraulic pressure control unit is desired to be miniaturized. Therefore, it is preferable to implement the hydraulic pressure control unit 1 according to the present embodiment as a pumpless hydraulic pressure control unit.

<Effect of hydraulic pressure control unit>
The effect of the hydraulic pressure control unit according to the embodiment will be described.

The hydraulic pressure control unit 1 according to the present embodiment is, for example, the hydraulic pressure control unit 1 of the brake system 100 mounted on a saddle-mounted vehicle such as a bicycle 200. The hydraulic pressure control unit 1 includes a base 10, a coil unit 60, a housing 40, and a resin arm 70. A flow path 13 for the brake fluid is formed on the substrate 10. The coil unit 60 has coils 61, 63 for driving the hydraulic pressure adjusting valve 20 for opening and closing the flow path 13, and a coil housing 65 for holding the coils 61, 63, and is adhered to the substrate 10. The housing 40 is connected to the base 10 and houses the coil unit 60. One end of the resin arm 70 is held by the housing 40 and is in contact with the upper surface 66a, which is a surface of the coil unit 60 facing the adhesive surface with the substrate 10.

In the hydraulic pressure control unit 1 configured in this way, the hydraulic pressure control unit 1 is assembled so that the arm 70 is elastically deformed by being pushed by the coil unit 60, so that the coil unit 60 is attached to the base 10 by boltless adhesion. Since it can be fixed to the coil unit 60, it is not necessary to secure a space for arranging bolts in the coil unit 60, the coil unit 60 can be miniaturized, and the hydraulic pressure control unit 1 can be miniaturized. Further, in the hydraulic pressure control unit 1 configured in this way, after a certain period of time has elapsed, the pressing force of the coil unit 60 by the arm 70 does not cause peeling at the connection portion between the housing 40 and the base 10. Since the size is reduced, it is possible to prevent the airtightness between the housing 40 and the substrate 10 from being reduced.

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

1 Hydraulic control unit, 10 base, 11 master cylinder port, 12 wheel cylinder port, 13 flow path, 14 first flow path, 15 second flow path, 16 third flow path, 17 fourth flow path, 18 upper surface, 20 hydraulic pressure adjustment valve, 21 inlet valve, 22 outlet valve, 23 accumulator, 30 control unit, 31 circuit board, 32 lower surface, 33 holes, 40 housing, 41 main body, 42 lower surface, 42a opening, 43 upper surface, 43a opening, 44a first side surface, 44b second side surface, 44c third side surface, 44d fourth side surface, 45 holding part, 48 lid, 50 lid fixing part, 51 engaged part, 52 convex part, 53 Slit, 55 Engagement, 56 Convex, 57 Slit, 58 Virtual Axis, 60 Coil Unit, 61 Coil, 62 Connection Terminal, 63 Coil, 64 Connection Terminal, 65 Coil Housing, 66 Top, 66a Top, 66b Bottom , 66c Notch, 67 Bottom, 68 Side, 69 Center, 70 Arm, 71 Protrusion, 72 Top, 73 Bottom, 74 Axis, 80 Connection, 81 Recess, 82 Pin, 83 Bottom, 84 Top, 85 Protruding part, 86 through hole, 90 cradle, 91 support part, 92 lower end part, 93 upper end part, 94 middle part, 100 brake system, 101 liquid pipe, 102 liquid pipe, 103 hydraulic pressure sensor, 200 bicycle, 210 frame, 211 Head Tube, 212 Top Tube, 213 Down Tube, 214 Seat Tube, 215 Stay, 216 Front Fork, 217 Front Wheel, 218 Saddle, 219 Pedal, 220 Rear Wheel, 230 Swing, 231 Steering Column, 232 Handle Stem, 233 Handle Bar, 240 braking operation unit, 241 brake lever, 242 master cylinder, 243 reservoir, 250 front wheel braking unit, 251 wheel cylinder, 252 rotor, 260 rear wheel braking unit, 270 power supply unit.

Claims (10)

It is a hydraulic pressure control unit (1) of the brake system (100) mounted on the saddle-mounted vehicle (200).
The substrate (10) on which the brake fluid flow path (13) is formed, and
The substrate (10) has a coil (61,63) for driving a hydraulic pressure adjusting valve (20) for opening and closing the flow path (13), and a coil housing (65) for holding the coil (61,63). ), And the coil unit (60)
A housing (40) connected to the substrate (10) and accommodating the coil unit (60), and
A resin arm (70) having one end held by the housing (40) and in contact with a surface (66a) of the coil unit (60) facing an adhesive surface with the substrate (10).
Hydraulic pressure control unit (1). In a state where the adhesive for adhering the substrate (10) and the coil unit (60) is not solidified,
The hydraulic pressure control unit (1) according to claim 1, wherein the arm (70) presses the coil unit (60) toward the substrate (10). A circuit board (31) that is electrically connected to the coil (61,63) and controls energization of the coil (61,63) is provided.
The arm (70) is arranged between the coil unit (60) and the circuit board (31).
In the observation direction perpendicular to the arrangement direction of the coil unit (60), the arm (70), and the circuit board (31).
The surface (72) of the arm (70) facing the circuit board (31) is inclined with respect to the surface (32) of the circuit board (31) facing the arm (70). The hydraulic pressure control unit (1) according to claim 2. A circuit board (31) that is electrically connected to the coil (61,63) and controls energization of the coil (61,63) is provided.
The arm (70) is arranged between the coil unit (60) and the circuit board (31).
In the observation direction perpendicular to the arrangement direction of the coil unit (60), the arm (70), and the circuit board (31).
The shaft (74) of the arm (70) faces the surface (32) of the circuit board (31) facing the coil unit (60) and the circuit board (31) of the coil unit (60). The hydraulic pressure control unit (1) according to claim 1 or 2, which is tilted with respect to the surface (66a). The housing (40) is a resin-formed product.
The hydraulic pressure control unit (1) according to any one of claims 1 to 3, wherein the housing (40) and the arm (70) are integrally formed products. The hydraulic pressure control unit (1) according to any one of claims 1 to 5, further comprising a plurality of the arms (70). In the observation direction parallel to the arrangement direction of the coil unit (60) and the arm (70).
According to claim 6, at least two of the plurality of arms (70) are in contact with the coil unit (60) at positions symmetrical with respect to the center (69) of the coil unit (60). The hydraulic pressure control unit (1) described. Equipped with an accumulator (23) that stores brake fluid during decompression in antilock brake control.
The hydraulic pressure control unit (1) according to any one of claims 1 to 7, wherein the brake fluid in the accumulator (23) is discharged to the outside of the accumulator (23) without a pump. A brake system (100) including the hydraulic pressure control unit (1) according to any one of claims 1 to 8. A saddle-mounted vehicle (200) comprising the brake system (100) according to claim 9.

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