JP2013193663A - Braking device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a braking device which can suppress vibration while improving the durability of a control board.SOLUTION: A braking device includes: a housing in which an oil passage is formed and to which a solenoid valve for opening and closing the oil passage is attached; a case 5 in which a solenoid for driving the solenoid valve is housed inside and which is attached to the housing; an ECU substrate 6 which is supported by a plurality of fixing parts provided integrally to the case 5 and to which a vehicular behavior detecting sensor 7 for detecting the behavior of a vehicle including the sensor; and a substrate fixing part 8 for adjusting the resonant frequency of the ECU substrate 6 provided to the case 5. The ECU substrate 6 is fixed to the substrate fixing part 8.

Description

  The present invention relates to an electronic device mounted on a vehicle, and more particularly to a brake device.

  2. Description of the Related Art Conventionally, a board support structure that suppresses vibration of a control board (circuit board) mounted in a housing (housing) of an electronic device mounted on an automobile is known. For example, the technique described in Patent Document 1 is to fix the boss part (projection part) on one side of the control board by adhering and fixing the peripheral fixing part of the control board to the case, and warping the control board in a convex shape. The vibration of the electronic component mounted on the control board is suppressed.

JP 2009-111171 A

  However, in the technique described in Patent Literature 1, since the control board is stressed by warping the control board, the durability may be reduced. An object of the present invention is to provide an electronic device, particularly a brake device, capable of suppressing vibration while improving durability of a control board.

  In order to achieve the above object, the brake device of the present invention is preferably provided with a board fixing portion for adjusting the resonance frequency of the control board in the case, and the control board is fixed to the board fixing portion.

  Therefore, by fixing the control board to the case side via the board fixing portion, it is possible to suppress vibration while improving the durability of the control board.

It is a disassembled perspective view of the brake device of Example 1. FIG. 1 is an exploded schematic view of a brake device according to a first embodiment. It is a perspective view of the brake device of Example 1. It is a figure which shows the support structure of the brake device of Example 1. FIG. It is the perspective view which looked at the electronic control unit except the cover of Example 1 from the board | substrate side. It is the front view which looked at the electronic control unit except the cover of Example 1 from the board | substrate side. FIG. 3 is a schematic diagram illustrating a mounting / supporting structure of a substrate to a case of Example 1. FIG. 3 is a schematic diagram illustrating an arrangement region of a vehicle behavior detection sensor on a substrate according to the first embodiment. FIG. 3 is a schematic diagram illustrating an arrangement region of a vehicle behavior detection sensor on a substrate according to the first embodiment. FIG. 3 is a schematic diagram illustrating an arrangement region of a vehicle behavior detection sensor on a substrate according to the first embodiment. It is the front view which looked at the electronic control unit except the cover of the other Example from the board | substrate side.

  Hereinafter, the form which implement | achieves the brake device of this invention is demonstrated based on drawing.

[Example 1]
FIG. 1 is an exploded perspective view showing a state in which members constituting the units 3 and 4 of the brake device (hereinafter referred to as device 1) of the first embodiment are assembled in layers. FIG. 2 is a schematic diagram of FIG. FIG. 3 is a perspective view of the device 1 in a state where a part of the cover is made transparent after the assembly and the substrate 6 (sensor 7) is visible.
The device 1 is applied to an automobile brake system. The brake system is a hydraulic brake system including p-line and s-line brake pipes, and is, for example, an X pipe type. The device 1 controls the brake fluid pressure (hydraulic pressure) of each wheel of the vehicle independently of the driver's braking operation, so that in addition to the normal brake, the function of each wheel is ensured by the demand for a function that ensures safety and convenience. The brake control device is provided so as to be able to execute brake control for controlling the braking force. Here, the normal brake is to apply the braking force to each wheel by supplying the master cylinder pressure to each wheel cylinder as it is. The brake control includes vehicle motion control and anti-lock brake control. The motion control controls the vehicle behavior such as suppressing the side slip of the vehicle by controlling the braking force of each wheel. Anti-lock brake control suppresses the occurrence of wheel lock (increase in wheel slip ratio) during driver braking.

The apparatus 1 is a so-called electromechanical unit in which a hydraulic unit 3 provided so as to be able to control the brake hydraulic pressure of each wheel and an electronic control unit (ECU) 4 as an electronic device for controlling the hydraulic unit 3 are integrated. In addition, a vehicle behavior detection sensor 7 for controlling vehicle motion is attached to the electronic control unit 4 as a unit. The device 1 is provided, for example, in an engine room of a vehicle, and is supported and fixed to the vehicle body.
The hydraulic unit 3 is provided between a tandem master cylinder that generates hydraulic pressure (master cylinder pressure) corresponding to a driver's brake operation state (for example, brake pedal operation force), and a wheel cylinder provided on each wheel. The master cylinder pressure or the control hydraulic pressure can be individually supplied to each wheel cylinder. The hydraulic unit 3 includes a pump that is a hydraulic pressure generation source and a plurality of control valves as hydraulic devices for generating the control hydraulic pressure of each wheel cylinder, and includes these hydraulic devices (pumps and control valves). A housing 30 is provided. The pump is, for example, a reciprocating pump using a plunger. For example, a rotary pump using a circumscribed gear may be used.

The housing 30 is made of, for example, an aluminum-based metal material and is formed in a hexahedron (substantially rectangular parallelepiped) shape. An ECU mounting surface 32 provided on the opposite side, an upper surface 33 arranged on the vehicle vertically upward so as to spread in a substantially horizontal direction, and a lower surface 34 provided on the opposite side (vertically below) substantially parallel to the upper surface 33 It has two side surfaces 35 and 36 arranged on the vehicle so as to spread in the vertical direction at the side.
A motor 3 a for driving the pump is attached to the motor attachment surface 31, and the electronic control unit 4 is attached to the surface ECU attachment surface 32 opposite to the motor attachment surface 31.
A pipe connection port communicating with the master cylinder is formed above the motor mounting surface 31 above the motor 3a, and a pipe connection port communicating with each wheel cylinder is formed on the upper surface 32. Oil passages connected to the respective ports are formed inside the housing 30, and a pump and a control valve are disposed on the oil passages.
A solenoid valve 10 that opens and closes the oil passage is mounted on the ECU mounting surface 32. That is, the control valve is an electromagnetic valve, and one end side (valve portion) thereof is installed in the housing 30, and the other end side protrudes from the ECU mounting surface 32 to the outside of the housing 30 and the case 5 of the electronic control unit 4. Housed inside. In addition, a solenoid for driving the solenoid valve 10 is accommodated in the case 5, and this solenoid is positioned so as to surround the outer periphery on the other end side and generates an electromagnetic force (valve driving force). Further, a hydraulic pressure sensor for measuring the hydraulic pressure (master cylinder pressure) is mounted on the ECU mounting surface 32 and is accommodated in the case 5.

  The electronic control unit 4 includes a case 5, a substrate 6 that is integrally attached to the case 5, and a cover 5 a. The case 5 is a housing member that is attached to the ECU attachment surface 30 of the housing 30 and is made of a resin material. The substrate 6 is accommodated in the case 5, and the cover 5 a seals the opening of the chamber that accommodates the substrate 6 in the case 5.

FIG. 4 is a view showing a support structure of the device 1. 4A is a front view of the device 1 as viewed from the motor mounting surface 31 side, and FIG. 4B is a side view of the device 1 as viewed from one side 35 side.
The lower ends of the housing 30 on the motor mounting surface 31 side (from the axis O of the motor 3a) are formed as projecting portions 311 and 312 that project from other portions of the surface 31. When viewed from the side of the motor mounting surface 31, the shaft O of the motor 3a is disposed so as to be positioned on a vertical line substantially in the middle between the projecting portions 311 and 312. The device 1 is supported by first to third brackets 2a to 2c fixed to the vehicle body via insulators 210 to 240. The insulators 210 to 240 are elastic members that suppress (insulate) vibration.
A first bracket mounting portion (mount) 21 and a second bracket mounting portion 22 are provided at both lower ends of the motor mounting surface 31 so as to extend in the axial direction of the motor 3a. The first bracket 2a has a plate shape bent at a substantially right angle. The portion of the first bracket 2a extending in the substantially vertical direction is attached to the protruding portions 311 and 312 of the motor mounting surface 31 by the first and second bracket mounting portions 21 and 22 via the insulators 210 and 220, respectively. The portion of the first bracket 2 a that extends in the substantially horizontal direction is attached to the lower surface 34 of the housing 30 via the insulator 230 by the third bracket attachment portion 23.
A third bracket mounting portion 23 is provided on the lower surface 34 so as to extend in a direction perpendicular to the axis O of the motor 3a (vertical direction). The third bracket mounting portion 23 is disposed so as to be positioned on a vertical line passing through the axis O when viewed from the motor mounting surface 31 side. The second bracket 2b has a plate shape that is bent into a substantially trapezoidal shape when viewed from the side surface 35 side. A portion of the second bracket 2b that extends in a substantially horizontal direction is attached to the lower surface 34 via the insulator 230 by the third bracket mounting portion 23 while being in partial contact with the lower surface of the first bracket 2a.
A fourth bracket mounting portion 24 is provided above one side surface 35 (above the shaft O of the motor 3a) so as to extend in a direction perpendicular to the shaft O (horizontal direction).
The third bracket 2c has a plate shape bent at a substantially right angle. The portion of the third bracket 2 c that extends in the substantially vertical direction is attached to the side surface 35 via the insulator 240 by the fourth bracket attachment portion 24. The portion of the third bracket 2 c that extends in the substantially horizontal direction is attached to the lower surface 34 of the housing 30 via the insulator 230 by the third bracket attachment portion 23.

FIG. 5 is a perspective view of the electronic control unit 4 with the cover 50 removed, as viewed from the installation side of the substrate 6. FIG. 6 is a front view of the electronic control unit 4 in the same state as viewed from the installation side of the substrate 6. FIG.
The board 6 is an ECU control board (ECU board), for example, a circuit board on which a plurality of electronic components are mounted on a glass epoxy laminate. The electronic component includes, for example, a control unit that inputs various types of information and executes calculations and outputs control commands. In addition, the device 1 includes a vehicle behavior detection sensor 7 that detects the behavior of the vehicle on which the device 1 is mounted, and the vehicle behavior detection sensor 7 is mounted on the substrate 6. The electronic component and the vehicle behavior detection sensor 7 mounted on the substrate 6 may be mounted on either the surface of the substrate 6 facing the case 5 or the surface on the opposite side. The vehicle behavior detection sensor 7 is a combine sensor that combines and integrates a plurality of sensors that detect various information indicating vehicle behavior such as the yaw rate, lateral acceleration, and longitudinal acceleration of the vehicle. Among them, the yaw rate sensor is a vibration type yaw rate sensor provided with, for example, a vibrating body that detects the change speed of the rotation angle in the turning direction of the vehicle. The acceleration sensor is, for example, a mechanical acceleration sensor that detects a change in mass position due to acceleration. The board 6 outputs a control signal to the motor 3a (pump) and each solenoid valve 10 based on a signal input from a wheel speed sensor for detecting the rotation speed of the wheel, a vehicle behavior detection sensor 7 or the like, and performs brake control. .

  The case 5 is formed in a tray shape having an opening, and integrally includes a base portion 50 that is a plate-like partition wall and a side wall portion 51 that is a cylindrical peripheral wall. The side wall portion 51 extends from the outer periphery of the main body portion 500 of the base portion 50 in one direction substantially perpendicular to the base portion 50. A flange portion 510 is provided at the opening side end portion of the side wall portion 51. Bolt holes 511 for fastening bolts to the ECU mounting surface 30 of the housing 30 are formed in the flange portion 510. The base unit 50 is provided with a hydraulic pressure sensor installation unit 52 in which a hydraulic pressure sensor is accommodated, and a connector unit 53 for electrically connecting the ECU to an external device. The hydraulic pressure sensor installation part 52 and the connector part 53 extend from the base part 50 to the same one side as the side wall part 51. The side wall 51 is in airtight contact with the ECU mounting surface 30 of the housing 30, thereby forming a first storage chamber inside the case 5. On the opposite side of the first storage chamber across the base 50, the substrate 6 is disposed opposite the base 50 and the cover 5a is attached to the case 5 (base 50). Two storage chambers are formed. The substrate 6 is accommodated in the second accommodation chamber. A solenoid is installed in the first storage chamber, and the end of the solenoid valve 10 is stored on the inner peripheral side of the solenoid. A through hole 501 is provided in the main body portion 500 of the base portion 50, and the solenoid terminal 12 protrudes through the through hole 501 to the substrate 6 side of the base portion 50. The terminals of the hydraulic pressure sensor installed in the hydraulic pressure sensor installation part 52 and the terminal 530 of the connector part 53 also protrude toward the substrate 6 side of the base part 50. The solenoid and the hydraulic pressure sensor are electrically connected to the substrate 6 via the respective terminals 12 and 21. A plurality of terminals α projecting and extending toward the substrate 6 are fixed to the periphery of the base portion 50. The plurality of terminals α include, for example, the terminal 530 of the connector portion 53 and the terminal 21 of the hydraulic pressure sensor.

  FIG. 7 is a diagram schematically showing a cross section of the electronic control unit 4 with the cover 5 a removed, taken along a plane substantially perpendicular to the substrate 6 (a plane including the axis of the substrate fixing portion 8). The attachment and support structure of the substrate 6 is shown. A plurality of (three) protrusions 54 are formed on the peripheral portion of the base portion 50 as a first support member for supporting the substrate 6 so as to protrude to the substrate 6 side and extend integrally with the base portion 50. Has been. As shown in FIG. 6, the protrusion 54 includes a peripheral portion between the hydraulic pressure sensor installation portion 52 and the connector portion 53, a peripheral portion on the side facing the connector portion 53 in the main body portion 500, and the main body portion 500 and the connector. One is provided at each peripheral portion between the portions 53. A snap fit is formed at the tip of each projection 54 on the substrate 6 side. Further, one substrate fixing portion 8 is provided as a second support member for supporting the substrate 6 on the center side, which is a portion other than the peripheral portion of the base portion 50. The board fixing part 8 is a substantially columnar column member provided integrally with the base part 50 so as to protrude and extend toward the board 6 side, and as shown in FIG. In this case, they are arranged within a triangular range having the three projections 54 as vertices. The length (height) of the substrate fixing portion 8 is set to a dimension substantially equal to the distance L0 between the substrate 6 (supported by the protrusion 54) and the base portion 50 of the case 5. Bolt holes 80 are formed through the shaft of the substrate fixing portion 8, and the diameter of the substrate fixing portion 8 is sufficiently large so that the bolt holes 80 can be formed. The substrate fixing portion 8 is formed of, for example, a resin material, and preferably has rigidity (elastic modulus) higher than that of the substrate 6. The substrate fixing part 8 and the base part 50 of the case 5 may be formed of a metal material such as aluminum.

  The case 5 is provided with a plurality of attachment portions for supporting the substrate 6 integrally with the case 5, and the substrate 6 is attached to the case 5 by the plurality of attachment portions. The attachment portion has a first attachment portion A and a second attachment portion B, and supports (holds) the peripheral edge portion of the substrate 6. The first mounting portion A has the plurality of terminals α provided on the peripheral portion of the base portion 50, and these terminals α are connected to holes (through holes) of the substrate 6 by soldering, press fitting, or the like. Thus, the substrate 6 is supported and fixed to the case 5. The plurality of terminals α constitute one first attachment portion A for each group. In the first embodiment, as illustrated in FIG. 6, the five first attachment portions A1 to A5 are provided, but the number is not limited to five. The second mounting portion B has the protrusion 54 (first support member) provided at the peripheral edge of the base portion 50, and the snap fit of the protrusion 54 is fitted to the peripheral edge of the substrate 6. Thus, the substrate 6 is supported and fixed to the case 5. In the first embodiment, the three protrusions 54 are provided, but the number is not limited to three. Further, an engagement hole may be provided on the peripheral edge of the substrate 6 and a snap fit may be engaged with the engagement hole.

  The substrate 6 is fixed to the substrate fixing portion 8 (second support member) and fixed to the case 5 via the substrate fixing portion 8. That is, the board 6 and the case 5 (base part 50) are integrally coupled by screws (bolts 9) via the board fixing part 8. Specifically, bolt holes 502 and 60 are formed in the base portion 50 and the substrate 6 of the case 5, respectively. Bolts 9 are inserted into these bolt holes in a state where the bolt holes 502, 60, 80 of the base part 50, the board 6, and the board fixing part 8 are arranged substantially coaxially. The head 90 of the bolt 9 is locked to the substrate 6, and the male screw of the bolt 9 (for example, the male screw formed at the tip 91) is formed in the female screw of the bolt holes 502, 60, 80 (for example, the bolt hole 502). The board 6 and the board fixing part 8 are fastened together with the case 5 (base part 50) and fixed together. In this state, the length (height) of the substrate fixing portion 8 is adjusted so that the axial end of the substrate fixing portion 8 and the substrate 6 abut, and the substrate 6 is fixed to the head 90 of the bolt 9 and the substrate. If sandwiched between the axial ends of the portion 8, the substrate 6 can be more firmly fixed to the substrate fixing portion 8 (case 5).

  8 and 9 are diagrams schematically showing the arrangement configuration of the vehicle behavior detection sensor 7 with respect to the substrate fixing portion 8 and the plurality of attachment portions A and B in the substrate 6. As shown in FIG. 8, the vehicle behavior detection sensor 7 is a region surrounded by a peripheral portion supported by the first and second mounting portions A and B and a portion fixed by the substrate fixing portion 8 in the substrate 6. Located in β. Here, the “enclosed region β” is, for example, a plurality of both attachment portions A and B (in the direction along the outer periphery of the substrate 6) (in the case of the first attachment portion A, a plurality of ones). The terminal α is located at both ends of the terminal α, and in the case of the second mounting portion B, the region sandwiched by two straight lines connecting the both ends of the projections 54) and the axis (or outer peripheral surface) of the substrate fixing portion 8. It is. When there are a plurality of regions β as shown in FIG. 8, the vehicle behavior detection sensor 7 is arranged in any of them.

  Further, as shown in FIG. 9, the vehicle behavior detection sensor 7 is arranged closer to the portion fixed by the substrate fixing portion 8 than the portions supported by the first and second attachment portions A and B. Specifically, the shortest distance between the vehicle behavior detection sensor 7 and the board fixing portion 8 is L1, and the shortest distance between the vehicle behavior detection sensor 7 and the attachment portions A and B is L2. The vehicle behavior detection sensor 7 is arranged on the substrate 6 so that L1 is shorter than L2 (L1 <L2). In FIG. 9, the distances L1 and L2 are defined based on the center position of the vehicle behavior detection sensor 7. However, when the size of the vehicle behavior detection sensor 7 is sufficiently small, the outer peripheral surface of the vehicle behavior detection sensor 8 is used as a reference. It is good also as prescribing distance L1, L2. In FIG. 8, the distances L1 and L2 are defined with respect to the outer peripheral surface of the substrate fixing part 8. However, when the diameter of the substrate fixing part 8 is large, the distances L1 and L2 are based on the center position of the substrate fixing part 8. It is good also as prescribing.

  Further, the vehicle behavior detection sensor 7 is disposed at a position where the distance from the straight line l connecting the first bracket mounting portion 21 (insulator 210) and the fourth bracket mounting portion 24 (insulator 240) is shorter. Specifically, as shown in FIG. 6, the vehicle behavior detection sensor 7 (within the range satisfying the above conditions of “within the region β” to “L1 <L2”) It is arranged so that the length h) of the perpendicular drawn from the center position of the behavior detection sensor 7 to the straight line l is the shortest. In FIG. 6, the distance h is defined based on the center position of the vehicle behavior detection sensor 7. However, when the size of the vehicle behavior detection sensor 7 is sufficiently small, the distance is defined based on the outer peripheral surface of the vehicle behavior detection sensor 7. h may be defined.

[Operation of Example 1]
Next, the operation of the device 1 will be described. When the sensor 7 for detecting the vehicle behavior is mounted on the board 6, the board 6 is caused by the vibration of the apparatus 1 itself (due to the operation of the motor 3 a or the like) or the vibration input from the outside of the apparatus 1 (vehicle body side). There is a risk of vibration. When the substrate 6 vibrates, the sensor 7 mounted on the substrate 6 also vibrates. Therefore, information other than the vehicle behavior (hereinafter referred to as disturbance) is superimposed on the output of the vehicle behavior detection sensor 7 and may affect the vehicle behavior control using the sensor output.
On the other hand, in the apparatus 1, the substrate 6 is fixed to the case 5 side through the substrate fixing portion 8. The board fixing unit 8 changes the vibration characteristics of the board 6, specifically, the resonance frequency and gain (transfer characteristics) of vibration. That is, the portion fixed by the substrate fixing portion 8 becomes a node of vibration of the substrate 6, and the number of nodes of vibration of the substrate 6 increases as a whole. Therefore, the resonance frequency of the substrate 6 changes to the high frequency side, and the gain is changed. In this way, the board fixing portion 8 for adjusting the resonance frequency of the board 6 is provided, and the vibration of the board 6 is suppressed by shifting the resonance frequency of the board 6, and disturbance to the output of the vehicle behavior detection sensor 7 is prevented. The influence can be suppressed. Therefore, the accuracy of behavior detection by the vehicle behavior detection sensor 7 can be improved, and the brake control (vehicle behavior control) using the sensor output can be made more accurate.

  Moreover, since the board | substrate 6 is fixed to the case 5 side via the board | substrate fixing | fixed part 8, durability can be improved. Conventionally, for example, the technique described in Patent Document 1 is such that one end of a boss part (projection part) is bonded and fixed to one side of a control board, and the other end of the boss part is brought into contact with the case side, thereby By curving into a convex shape and further fixing the peripheral portion of the control board to the case, vibration of electronic components mounted on the control board is suppressed. However, in this configuration, since the stress is applied to the electronic component and the soldered portion on the control board by warping the control board, the durability of the electronic component and the soldering, that is, the durability of the control board may be reduced. . Further, in this configuration, the other end of the boss portion only abuts on the case side, and the boss portion is not fixed to the case. For this reason, if the height of the boss part is lowered to reduce the warpage of the control board in order to improve the durability, the force for pressing the boss part (the other end) against the case side decreases, and the boss part ( The other end) is likely to float away from the case. Therefore, the vibration of the control board cannot be sufficiently suppressed. That is, in the above configuration, it is difficult to achieve both suppression of vibration and improvement of durability. Moreover, in the said structure which fixes the peripheral part to a case, curving a control board, there exists a possibility that the installation process (assembly process of the apparatus 1) of a control board may become complicated.

  On the other hand, in the apparatus 1, the substrate 6 is fixed to the case 5 side through the substrate fixing portion 8 as a support column. That is, the substrate fixing portion 8 is fixed to the case 5, and the substrate 6 is fixed to the substrate fixing portion 8. Therefore, it is possible to suppress a situation where the substrate 6 side is separated from the case 5 and floats without having to bend the substrate 6. Therefore, since it is not necessary to always apply stress to the mounted components on the substrate 6, vibration of the substrate 6 can be suppressed while improving the durability of the substrate 6 (mounted components, etc.). Moreover, since it is not necessary to warp the board | substrate 6, the installation process (assembly process of the apparatus 1) of the board | substrate 6 can be simplified. Specifically, the height of the substrate fixing portion 8 is such that the distance L0 between the base portion 50 of the case 5 and the substrate 6 (fixed to the case 5 by the protrusions 54 or the plurality of attachment portions A and B). Is set to be approximately equal to. Therefore, it is possible to fix the substrate 6 to the substrate fixing portion 8 in a state where the axial end portion of the substrate fixing portion 8 and the substrate 6 are in contact with each other, thereby fixing the substrate 6 to the case 5 side. And while improving assembly | attachment property, the curvature of the board | substrate 6 can be suppressed to the minimum and durability can be improved. As long as the stress (durability) of the substrate 6 is within the allowable range, the substrate 6 is allowed to be slightly warped.

In the first embodiment, the case 5 and the substrate 6 are rigidly coupled to each other by a screw via the substrate fixing portion 8 (fixed so that the case 5 and the substrate become one rigid body). Alternatively, these may be rigidly connected by press fitting of pins, adhesive, soldering or other means.
In the first embodiment, the substrate fixing portion 8 is a separate member from the case 5, but the substrate fixing portion 8 may be provided integrally with the case 5. For example, the case 5 and the substrate fixing part 8 may be integrally formed. In the first embodiment, the male screw formed at the tip 91 of the bolt 9 is screwed into the female screw formed in the bolt hole 502 of the base unit 50. The board 6 may be fixed to the board fixing part 8 (case 5) by screwing the male screw of the bolt 9 into the female screw formed in the bolt hole 80 of the board fixing part 8).
Further, the length (height) of the substrate fixing portion 8 may be shorter than the distance between the substrate 6 (supported by the protrusions 54 and the like) and the base portion 50 of the case 5. In other words, there may be a gap between the end of the substrate fixing portion 8 and the substrate 6 in a state where the substrate 6 is fastened and fixed to the case 5 via the substrate fixing portion 8 by the bolts 9. In this case, a nut or the like may be used to fasten and fix the bolt 9 and the substrate 6. Furthermore, the board fixing part 8 may be omitted, and the board 9 may be directly fastened and fixed to the case 5 (base part 50) with the bolts 9 so that the bolts 9 have the function of the board fixing part. For example, by screwing the male screw of the bolt 9 into the female screw formed in the bolt hole 502 of the base portion 50 and fastening and fixing the bolt 9 to the substrate 6 using a nut or the like, the substrate 6 is It is good also as fixing to case 5 via the volt | bolt 9 (as a board | substrate fixing | fixed part). Moreover, the board | substrate fixing | fixed part 8 should just be fixed to the case 5, for example, is good also as fixing to the cover 5a side.

  As shown in FIG. 8, the vehicle behavior detection sensor 7 is a region of the substrate 6 surrounded by a portion fixed by the substrate fixing portion 8 and a peripheral portion fixed by the first and second mounting portions A and B. Located in β. This region β is located closer to the vibration node of the substrate 6 than the other regions, and the amount of bending (vibration amplitude) of the substrate 6 is small. That is, the amplitude decreases as the distance from the fixed point = node (the portion fixed by the substrate fixing portion 8 or the peripheral portion fixed by the attachment portions A and B) becomes smaller. Therefore, in this region β, the amount of movement (amplitude) of the vehicle behavior detection sensor 7 due to the vibration of the substrate 6 is reduced and is less susceptible to vibration. Therefore, disturbance input to the sensor output can be suppressed, and vehicle behavior control using the sensor output can be made more accurate. Note that the vehicle behavior detection sensor 7 does not have to be strictly located in the region β. If the vehicle behavior detection sensor 7 is in the vicinity of the region β (for example, if the vehicle behavior detection sensor 7 is in a position that partially overlaps the region β), the region It can be said that it is located at β, and the above-mentioned effects can be obtained.

As shown in FIG. 9, the vehicle behavior detection sensor 7 is arranged closer to the portion fixed by the board fixing portion 8 which is a rigid body than the portions supported by the first and second mounting portions A and B. . The latter part has a higher fixing strength of the substrate 6 than the former part. This is because the diameter of the substrate fixing portion 8 is sufficiently large, the rigidity of the substrate fixing portion 8 itself is high, the bonding strength between the substrate fixing portion 8 and the substrate 6 is relatively high, and the like. For this reason, in the board | substrate 6, the bending (amplitude of vibration) of the board | substrate 6 becomes small, so that it is closer to the fixing | fixed part by the board | substrate fixing | fixed part 8 than the support part by attachment part A, B. That is, the amount of movement of the vehicle behavior detection sensor 7 due to the vibration of the substrate 6 is reduced, and is less susceptible to vibration. Therefore, disturbance input to the sensor output can be suppressed, and vehicle behavior control using the sensor output can be made more accurate.
In the above case where the vehicle behavior detection sensor 7 is arranged near the portion fixed by the board fixing portion 8, the vehicle behavior detection sensor 7 is located in the region β and in other regions. There is a case to do. FIG. 10 shows the positional relationship of the vehicle behavior detection sensor 7 with respect to the board fixing portion 8 and the plurality of attachment portions A and B in the latter case. The shortest distance between the vehicle behavior detection sensor 7 and the board fixing portion 8 is L3, and the shortest distance between the vehicle behavior sensor and the attachment portions A and B is L4. As shown in FIG. 10, the above-described effects can be obtained by arranging the vehicle behavior detection sensor 7 on the substrate 6 so that L3 is shorter than L4 (L3 <L4). In contrast to this arrangement configuration, when L1 <L2 and the vehicle behavior detection sensor 7 is arranged in the region β as in the first embodiment, the influence of vibration of the substrate 6 can be more effectively suppressed. .

  Further, as described above, the device 1 vibrates due to the operation of the device 1 itself (hydraulic device mounted on the device 1) (for example, rotational vibration due to torque fluctuation of the motor 3a) or vibration input from the vehicle side. . As a result of the applicant's research (experiment, etc.), the apparatus 1 connects the fourth bracket mounting portion 24 that supports the side surface 35 of the hydraulic unit 3 and the first bracket mounting portion 21 that supports the motor mounting surface 31. It has been found that it swings around the axis (straight line 1). Based on this knowledge, in the first embodiment, the vehicle behavior detection sensor 7 is arranged so that the distance h from the straight line l that is the swing axis of the hydraulic unit 3 is shortened. Therefore, the movement amount (amplitude) of the vehicle behavior detection sensor 7 due to the swinging is reduced, and the position of the vehicle behavior detection sensor 7 is stabilized. Therefore, the disturbance component generated by the swing of the hydraulic unit 3 in the acceleration or yaw rate detected by the vehicle behavior detection sensor 7 is reduced. Therefore, the vehicle behavior control using the sensor output can be made more accurate. Note that the vehicle behavior detection sensor 7 does not have to be disposed at the position closest to the axis l, and is located in the vicinity of the position closest to the axis l (for example, the axis to the substrate 6 as shown in FIG. 6). The above effect can be obtained if the l-axis motor axis direction projection partially overlaps the vehicle behavior detection sensor 7). That is, if the vehicle behavior detection sensor 7 is disposed at a position closest to the axis l within a range in which the original layout (valve position or the like) on the substrate 6 is not changed, an increase in cost due to the layout change is suppressed, The disturbance component of the vehicle behavior detection sensor 7 due to the swing of the hydraulic unit 3 can be suppressed. Note that the mounting structure of the apparatus 1 on the vehicle body side (the structure or arrangement and number of brackets and bracket mounting portions) is not limited to that of the first embodiment. In this case as well, the above-described operation and effect can be obtained by specifying the swing shaft that connects the attachment portions and arranging the vehicle behavior detection sensor 7 so that the distance from this shaft is short.

[Effect of Example 1]
Hereinafter, effects produced by the device 1 of the first embodiment will be listed.
(1) A housing 30 in which an oil passage is formed and a solenoid valve 10 for opening and closing the oil passage is mounted; a case 5 in which a solenoid 11 for driving the solenoid valve 10 is housed and attached to the housing 30; An ECU board 6 on which a vehicle behavior detection sensor 7 for detecting the behavior of a vehicle mounted and supported by a plurality of mounting portions A and B provided integrally with the case 5 is mounted. A substrate fixing portion 8 for adjusting the resonance frequency of the ECU was provided, and the ECU substrate 6 was fixed to the substrate fixing portion 8.
Therefore, it is possible to improve the controllability by suppressing the vibration of the ECU board 6 while improving the durability of the ECU board 6 (mounting parts or the like).

(2) The plurality of attachment portions A and B support the peripheral portion of the ECU board 6, and the vehicle behavior detection sensor 7 is surrounded by the peripheral portion of the ECU substrate 6 and the portion fixed by the substrate fixing portion 8. Arranged in the region β.
Therefore, the influence of the vibration of the ECU board 6 on the vehicle behavior detection sensor 7 can be suppressed.

(3) The vehicle behavior detection sensor 7 is arranged closer to the portion fixed by the substrate fixing portion 8 than the portion supported by the plurality of attachment portions A and B.
Therefore, the influence of the vibration of the ECU board 6 on the vehicle behavior detection sensor 7 can be suppressed.

[Other embodiments]
As mentioned above, although the form for implement | achieving this invention has been demonstrated based on the Example, the concrete structure of this invention is not limited to an Example, The design change of the range which does not deviate from the summary of invention Are included in the present invention. For example, the shape and position of the substrate fixing portion 8 are not limited to those of the first embodiment. For example, the substrate fixing portion 8 may have a polygonal column shape or the like. Further, for example, even when the substrate fixing portion 8 is disposed at the position shown in FIG. 11, the above-mentioned various conditions such as “within the region β” and “L1 <L2” are satisfied, so that the same effects as those of the first embodiment are obtained. be able to. Moreover, the number of the board | substrate fixing | fixed part 8 is not restricted to 1, and multiple (2 or more) may be sufficient. In the first embodiment, the first support member (the plurality of protrusions 54) is provided, but this may be omitted.

DESCRIPTION OF SYMBOLS 1 Brake device 10 Solenoid valve 11 Solenoid 30 Housing 5 Case 6 ECU board 7 Vehicle behavior detection sensor 8 Board fixing part A Attachment part B Attachment part

Claims (3)

A housing in which an oil passage is formed and a solenoid valve for opening and closing the oil passage is mounted;
A case in which a solenoid for driving the solenoid valve is housed and attached to the housing;
An ECU board on which a vehicle behavior detection sensor for detecting the behavior of a vehicle mounted and supported by a plurality of mounting portions provided integrally with the case is mounted;
A brake device, wherein a substrate fixing portion for adjusting a resonance frequency of the ECU substrate is provided in the case, and the ECU substrate is fixed to the substrate fixing portion. The brake device according to claim 1, wherein
The plurality of attachment portions support a peripheral portion of the ECU board,
The vehicle behavior detection sensor is disposed in a region surrounded by the peripheral portion and a portion fixed by the substrate fixing portion on the ECU substrate. The brake device according to claim 1 or 2,
The brake device, wherein the vehicle behavior detection sensor is disposed closer to a portion fixed by the board fixing portion than a portion supported by the plurality of attachment portions.

Images