JP2008207640A - Electric brake device and its airtightness detection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reliable electric brake device having excellent environmental resistance. <P>SOLUTION: The electric brake device comprises an electric motor 1311 to generate the rotational torque, a rotation-translation conversion mechanism 1413 for moving brake pads 1306, 1307 by converting the rotational motion of the rotational torque into the translational motion, a casing having the motor and the rotation-translation conversion mechanism, and a harness 600 having an air communicating member 1603 for communicating air. The air pressure inside the casing is kept at a predetermined value or below via the air communicating member of the harness. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electric brake device that generates a braking force by an electric motor and an airtightness detection method thereof.

  In order to improve the controllability of various brake applications such as anti-skid, vehicle attitude control, and inter-vehicle distance tracking control, an electric brake device in which conventional hydraulic control is replaced with electrical control has been developed.

  This electric brake is similar to a mechanical brake in that it uses a hydraulic pressure to press a brake pad against a disk rotor that rotates with the wheels and generates a braking force, but without using hydraulic pressure as described above, A brake that generates a braking force by output (see, for example, Patent Document 1). Specifically, the output torque of the electric motor is converted into a linear motion force, and a braking force is generated by pressing a disk rotor that rotates the brake pad together with the wheel based on the linear motion force.

JP 2003-137081 A

  Since the electric brake device is installed in the vicinity of the wheel, there is a possibility that water or the like may be splashed from the outside. Therefore, the electric brake device needs to have a sealed structure so that water or the like does not enter the electric brake device. In the electric brake device, frictional heat is generated by pressing the brake pad against the disc rotor, and a rapid temperature change occurs. Therefore, the electric brake device needs to have a configuration corresponding to a change in atmospheric pressure inside the device.

  However, it cannot be said that the prior art sufficiently considers the sealed structure and the configuration corresponding to the atmospheric pressure change in the apparatus.

  Therefore, an object of the present invention is to improve the environmental resistance and improve the reliability of an electric brake device used in such a severe environment.

  An electric brake device according to the present invention includes a motor that generates rotational torque, a rotation / linear motion conversion mechanism that converts a rotational motion of the rotational torque into a linear motion and moves a brake pad, and the motor and the rotation / linear motion conversion mechanism. And a harness provided with an air communication member that allows air to pass therethrough, and is configured to breathe through the air communication member of the harness.

  According to the present invention, the environmental resistance is improved, and the reliability can be greatly improved.

  Hereinafter, an embodiment of an electric brake device of the present invention will be described with reference to the drawings.

  FIG. 2 is a schematic configuration diagram of a vehicle brake system equipped with an electric brake device according to an embodiment of the present invention.

  The first electric brake device 1201 is mounted near the axle 1221 on the right front wheel 1211 side. The second electric brake device 1202 is mounted close to the axle 1221 on the left front wheel 1212 side. The third electric brake device 1203 is mounted on the right rear wheel 1213 side in the vicinity of the axle 1222. The fourth brake device 1204 is mounted near the axle 1222 on the left rear wheel 1214 side.

  Although the electric brake devices 1201 to 1204 have the same basic structure, the first electric brake device 1201 and the second electric brake device 1202 corresponding to the front wheel side are the same as the third brake device 1203 and the rear wheel side, respectively. It is preferable to be configured to generate a braking force larger than that of the fourth electric brake 1204.

  The front wheel axle 1221 and the rear wheel axle 1222 are provided with disk rotors 1231 to 1234 fixed to the respective axles. Although not shown in FIG. 2, the mechanism units 1241 to 1244 of each electric brake device include a pair of brake pads that face each surface of the disk rotors 1231 to 1234. Furthermore, the electric motors provided in the mechanism units 1241 to 1244 generate rotational torque, and generate braking force by pressing the disc rotors 1231 to 1234 with the brake pads based on the rotational torque.

  In each of the electric brake devices 1201 to 1204, the electric circuit units 1251 to 1254 for controlling the current for driving the electric motors have an integrated structure that is fixed to the respective mechanism units 1241 to 1244. The electric circuit portions 1251 to 1254 are attached to the surface opposite to the brake pads with respect to the mechanism portions 1241 to 1244 in the axle direction.

Electric power is supplied from the first battery 1261 through the first power supply line 1271 to the first electric brake device 1201 and the second electric brake device 1202 on the front wheel side. Electric power is supplied from the second battery 1262 through the second power supply line 1272 to the third electric brake device 1203 and the fourth electric brake device 1204 on the rear wheel side.

Electric power is supplied from the first battery 1261 to the first electric brake device 1201 for the right front wheel and the fourth electric brake device 1204 for the left rear wheel, and the second electric brake device 1202 for the left front wheel and the third electric brake device 1202 for the right rear wheel. The electric brake device 1203 may be supplied with electric power from the second battery 1262. By using two power supply lines, even if an abnormality occurs in one power supply line, braking by the other power supply line is possible, and safety is improved.

  In the vehicle brake system shown in FIG. 2, information on the stroke of the brake pedal 1281 or the pedal effort is detected by the pedal operation amount detector 1282 and input to the upper control circuit 1299 via the data signal line 1290. The upper control circuit 1299 is disposed, for example, in the passenger compartment, and performs upper control processing as a brake system for the electric circuit portion of each electric brake.

  The upper control circuit 1299 is connected to the states of the first to fourth electric brake devices 1201 to 1204 from the first to fourth electric brake devices 1201 to 1204 via the data signal lines 1291 to 1294, respectively, for example, the current value of the pressing force. , Receive information on the current value of the operation mode. Further, while monitoring the state of the electric motor, a control signal corresponding to information on the stroke of the brake pedal 1281 or the pedal depression force is transmitted to the electric brake devices 1201 to 1204 via the data signal lines 1291 to 1294, and The devices 1201 to 1204 are controlled. Note that the host controller 1299 is disposed in the passenger compartment.

  As described above, the electric brake device can acquire a brake command to be generated as an electric signal, and can control the braking force in accordance with the change in the signal. This electrical signal can be realized in any form such as an analog signal or a communication signal.

The host control circuit 1299 controls each of the electric brake devices 1201 to 1204 independently, or the first electric brake device 1201 and the second brake device 1202 on the front wheel side are grouped and a third on the rear wheel side. The electric brake device 1203 and the fourth brake device 1204 are set as other groups to control each group, or the front wheel side first electric brake device 1201 and the rear wheel side fourth electric brake device 1204 are grouped together and the front wheels. Each group may be controlled with the second electric brake device 1202 on the side and the third electric brake device 1203 on the rear wheel side as other groups. By performing control in groups, effects such as improved control responsiveness, reduced processing load on the control circuit, and increased fail-safe processing functions can be obtained.

  The electric brake devices 1201 to 1204 for automobiles having such a configuration are easily affected by vibration because they are directly attached to a vehicle body or an axle without using a suspension or the like, for example, and water is applied by running in rainy weather. It will be used in an easy environment.

  Further, in this embodiment, the electric brake devices 1201 to 1204 are configured integrally with the mechanism units 1241 to 1244 and the electric circuit units 1251 to 1254 including a large number of semiconductor devices as described above. Since the characteristics of the semiconductor device change due to heat, high-temperature frictional heat generated by the pressing of the brake pads in the mechanism parts 1241 to 1244 against the disk rotors 1231 and 1232 rotating with the wheels is conducted to the electric circuit parts 1251 to 1254. It is necessary to suppress as much as possible. In addition, it is necessary to efficiently dissipate heat generated by the semiconductor device itself.

  FIG. 3 is a conceptual diagram of the electric brake device of FIG. Hereinafter, the electric brake device will be described using the first electric brake device 1201 as a representative example.

  The electric brake device 1201 includes a pair of brake pads 1306 and 1307 arranged to face each other. Between each brake pad 1306 and 1307, a part of the disk rotor 1231 that rotates as the axle rotates is disposed.

  The electric brake device 1201 is configured by integrating a mechanism portion 1241 and an electric circuit portion 1251 with each other. Since the mechanism portion 1241 and the electric circuit portion 1251 are regionally independent, the mechanism portion 1241 and the electric circuit portion 1251 can be structurally separated.

  The mechanism unit 1241 linearly moves the rotational motion of the electric motor 1311 made of, for example, a three-phase motor, the speed reducer 1321 that decelerates the rotation of the electric motor 1311, and the electric motor 1311 decelerated by the speed reducer 1321 in the housing 1301. A rotation / linear motion conversion mechanism 1326 that converts the motion into motion and moves the piston 1331 back and forth is provided.

  The brake pad 1307 is attached to the piston 1331 and presses the disk rotor 1231 from one surface side by the thrust of the piston 1331. At this time, the electric brake device 1201 moves in the direction of arrow α in the figure using the pressing force from one surface side of the disk rotor 1231 as a reaction force, so that the brake pad 1306 presses the disk rotor 1231 from the other surface side. To do.

  The mechanism unit 1241 includes a parking brake (PKB) mechanism 1341. The parking brake mechanism 1341 can maintain the braking force without supplying electric power to the electric motor 1311 by stopping the rotation of the electric motor 1311 while the piston 1331 supplies the thrust to the disk rotor 1231. it can.

In the vicinity of the electric motor 1311, there are a rotation angle detection sensor 1351 for detecting the rotation angle of the electric motor 1311, a thrust sensor 1353 for detecting a thrust generated by the driving force of the electric motor 1311, and a temperature sensor for detecting the temperature of the electric motor 1311. 1355 is arranged. Output signals of the rotation angle detection sensor 1351, the thrust sensor 1353, and the temperature sensor 1355 are output to a lower control circuit 1399 disposed in the electric circuit unit 1251.

  The electric circuit unit 1251 receives power supply from a battery 1261 disposed on the vehicle body side. Further, various control signals are sent via a CAN (Controller Area Network) to which an engine control unit 1381, an AT control unit 1383, a pedal operation amount detector 1282 and the like are connected, or from the CAN via a host control circuit 1299. get.

  The electric circuit unit 1251 includes an inverter circuit 1391 and a lower control device 1399. The inverter circuit 1391 is a circuit for controlling a current flowing through the electric motor 1311. The lower control circuit 1399 obtains a control signal via CAN, and further obtains output information signals such as the rotation angle detection sensor 1351, the thrust sensor 1353, and the temperature sensor 1355 from the mechanism unit 1241 side, and based on these signals. The inverter circuit 1391 is controlled.

  The electric motor 1311 receives supply of electric power from the inverter circuit 1391, generates rotational torque, and causes the piston 1331 to generate a predetermined thrust via the speed reducer 1321 and the rotation / linear motion conversion mechanism 1326. In the figure, reference numeral 1395 indicates a vehicle-side structure.

  FIG. 4 is a circuit configuration diagram of the electric circuit unit 1251 of FIG.

  In the figure, a thick line frame 1251 corresponds to the electric circuit portion 1251 shown in FIG. 3, and a one-dot chain line frame 1391 corresponds to the inverter circuit 1391 shown in FIG. In the drawing, a dotted frame 1503 corresponds to the mechanism part 1241.

  The circuit in the mechanism part 1241 and the electric circuit part shown in FIG. 4 are covered with a metal housing, and are protected from external injury factors such as stepping stones. In addition, by using a metal housing having high heat conductivity, heat generated from each circuit can be radiated. Furthermore, the shielding effect with respect to electromagnetic waves etc. is provided by using the metal housing | casing with high shielding property.

  The electric circuit unit 1251 is supplied with electric power supplied via a power line in the vehicle. The filter circuit 1521 removes noise from the power supplied into the electric circuit unit 1251 via the relay 1519 and supplies the power from which the noise has been removed to the three-phase motor inverter circuit 1517.

The power (VCC, VDD) stabilized by the power supply circuit 1511 is supplied to a central control circuit (CPU) 1599. Note that the power supply (VCC) from the power supply circuit 1511 is detected by the VCC high voltage detection circuit 1513. The VCC high voltage detection circuit 1513 operates the fail-safe circuit 1515 and cuts off the power supply to the three-phase motor inverter when detecting a high voltage that causes an element in the electric circuit unit 1251 to malfunction.

  The fail safe circuit 1515 operates a relay 1519 that switches power supplied to a three-phase motor inverter circuit 1517 described later. When a high voltage is detected by the VCC high voltage detection circuit 1513, the power supply is turned off.

The central control circuit 1599 acquires a control signal from the host control circuit 1299 via the CAN communication interface circuit 1523, and from the thrust sensor 1353, the rotation angle detection sensor 1351, and the temperature sensor 1355 arranged on the mechanism unit 1241 side. Are obtained via a thrust sensor interface circuit 1525, a rotation angle detection sensor interface circuit 1527, and a temperature sensor interface circuit 1529, respectively. Information regarding the operating state of the electric motor 1311 is acquired from various sensors, and feedback control is performed based on a control signal from the host control circuit 1299, thereby causing the electric motor 1311 to generate an appropriate rotational torque.

  The three-phase motor inverter circuit 1517 includes a phase current monitor circuit 1533 and a phase voltage monitor circuit 1535. Phase current monitor circuit 1533 and phase voltage monitor circuit 1535 monitor the phase current and the phase voltage, respectively, and output the monitoring results to central control circuit 1599. The central control circuit 1599 operates the three-phase motor pre-driver circuit 1531 appropriately according to the monitoring result.

  Note that the three-phase motor inverter circuit 1517 controls a current and a voltage for driving the electric motor 1311 and therefore includes a semiconductor device having a relatively large output. For this reason, high heat is generated by the operation of the semiconductor device, but the countermeasure is taken by the configuration described in detail later.

  The central control circuit 1599 also receives a PKB solenoid in the mechanism unit 1241 via a parking brake (hereinafter, PKB) solenoid driver circuit 1537 based on a control signal from the host control circuit 1299, detection values of each sensor, and the like. 1342 is operated to activate the parking brake. The PKB solenoid driver circuit 1537 is supplied with part of the power supplied to the three-phase motor inverter circuit 1517.

  In addition, the electric circuit unit 1251 includes a monitoring control circuit 1539 that transmits and receives signals to and from the central control circuit 1599, for example, a storage circuit 1541 that includes an EEPROM that stores failure information and the like.

  The electrical circuit unit 1251 has many connections with the mechanism unit 1241, but there are very few connections with circuits other than the mechanism unit 1241 (battery 1261, host controller 1299). Therefore, in the manufacturing process of the electric brake device 1201 having an integrated structure of the mechanism part 1241 and the electric circuit part 1251, complicated connection between the mechanism part 1241 and the electric circuit part 1251 can be performed. When the electric brake device 1201 is attached to the vehicle body after the electric brake device 1201 is completed, the connection with the battery 1261 or the host control device 1299 can be performed very easily.

  FIG. 1 is a cross-sectional view of a specific internal configuration of the electric brake device of FIG.

  A line segment XX in FIG. 1 indicates a boundary between the mechanism unit 1241 and the electric circuit unit 1251, and the left side of the line segment XX is the mechanism unit 1241 and the right side is the electric circuit unit 1251.

  The thick line frame 1341 corresponds to the parking brake mechanism 1341 shown in FIG. 3, the thick line frame 1321 corresponds to the speed reducer 1321 shown in FIG. 3, and the thick line frame 1326 corresponds to the rotation / linear motion conversion mechanism 1326. 1, the same reference numerals as those in FIG. 3 denote the same members as those shown in FIG.

  The electric motor 1311 is a brushless three-phase motor, and includes a stator fixed to the housing 1301 and a rotor 1342 disposed in the stator. The stator is disposed so as to be in contact with the metal casing 1301 so that heat can be efficiently radiated when the stator itself generates heat.

  The electric motor 1311 operates to rotate the rotor 1342 with a desired torque by a desired angle in response to a command from the host controller 1299. The rotation angle of the rotor 1342 is installed between the speed reducer 1321 and the electric motor 1311 and is detected by the rotation angle sensor 1351.

  The reducer 1321 decelerates the rotation of the electric motor 1311 and increases the torque. Therefore, a small-sized electric motor 1311 can be used.

  The thrust plate 1421 is disposed on the electric circuit portion 1251 side in the mechanism portion 1241 and has a function of receiving the thrust of the piston 1331 as a reaction force. The thrust sensor 1353 is disposed at the center of the thrust plate 1241.

  Further, the thrust plate 1421 is disposed at a position slightly recessed toward the brake pad portion side with respect to the end surface of the housing 1301 (part indicated by a line XX in the drawing). A gap (space) is formed between the constituent members of the mechanism unit 1241 excluding the housing 1301 and the electric circuit unit 1251. On the other hand, the thrust sensor 1353 slightly protrudes toward the electric circuit portion 1251 beyond the end face of the housing 1301 (the line XX in the figure). For this reason, the interface module (hereinafter referred to as I / F module) 200 provided in the electric circuit portion 1251 is formed with a recessed portion so as to avoid interference with the thrust sensor 1353.

In the electric brake device, frictional heat is generated by pressing the brake pad against the disc rotor. On the other hand, since the frictional heat is radiated to the outside, it is necessary to have a structure capable of rapid cooling. Most of the constituent members of the mechanism portion 1241 including the housing 1301 are made of metal and have high heat conduction efficiency. Therefore, heat from the brake pad portion (brake pads 1306 and 1307 and its peripheral portion) is transmitted to the peripheral mechanism portion 1241 and easily radiated to the outside via the housing 1301.

Further, since the electric circuit portion 1251 is provided on the surface opposite to the brake pad portion with the mechanism portion 1241 in between, heat transfer to the electric circuit portion 1251 is reduced. Further, since the above-described gap (space) is formed between the structural member of the mechanism unit 1241 and the electric circuit unit 1251, heat transfer from the mechanism unit 1241 to the electric circuit unit 1251 is further reduced.

  In addition, if there is a puddle on the road, water may be applied to the electric brake device. For this reason, unlike other devices, a rapid temperature change occurs. As a result, the air inside the electric brake device expands or contracts, and the air pressure in the electric brake device changes suddenly. Since the electric brake device is used under severe conditions where water or the like is applied from the outside, it is desirable that the electric brake device itself has a secret structure. On the other hand, sudden changes in the atmospheric pressure in the apparatus are very severe as compared to other devices, and there is a risk that the sealing function of a means for making the casing a sealing structure, such as a sealing material, will be lowered. Moreover, the fluctuation range of the atmospheric pressure in the apparatus due to a rapid temperature change is large, and there is a possibility that a problem of water vapor occurs in the electric brake apparatus.

  There are a plurality of spaces having air inside the electric brake device 1201. For example, the space A between the thrust plate 1421 and the I / F module 200 shown in FIG. 1, the space B between the I / F module 200 and the inner case 300 described later, and the electrons of the electric circuit unit 1251 described later. A component mounting area 316 and the like.

  The interior of the electric brake device has a sealed structure so that outside air, water, mud, etc. do not enter these spaces. For example, the seal member 1340 installed between the hole for sliding the moving member (piston) 1331 and the moving member 1331, or the seal 202 for making the I / F module 200 and the mechanism portion 1241 airtight. In addition, the inside of the electric brake device has a sealed structure by, for example, adhesion for making the lid 800 and the outer case 500 airtight.

  However, the electric brake device becomes very hot due to frictional heat between the brake pads 1306 and 1307 and the disc rotor 1231 during braking of the vehicle, and is cooled to the outside temperature with time during non-braking. In conjunction with such a temperature change, the air pressure in the space inside the electric brake device described above changes greatly.

  Under a use environment in which the atmospheric pressure changes greatly, the air filling the space inside the electric brake device may repeatedly expand or contract, which may reduce the sealing function of the sealing member. In addition, there may be a problem of water vapor that corrodes various metal members inside the electric brake device. Therefore, the electric brake device according to the present embodiment has a structure capable of breathing through the air communication member provided in the harness 600.

  FIG. 5 is an exploded perspective view of each component of the electric circuit unit 1251.

The I / F module 200 is attached to the housing 1301 of the mechanism unit 1241 and has a relay function for electrically connecting a terminal (not shown) arranged on the mechanism unit 1241 side and a terminal of the electric circuit unit 1251. Have. In addition, since the material of the I / F module 200 is a synthetic resin, heat transfer from the brake pad portion can be reduced.

  Furthermore, the I / F module 200 has an opening for allowing a terminal disposed on the mechanism portion 1241 side to pass therethrough. This opening portion has a function as a communication hole that makes the internal space of the electric circuit portion 1251 and the mechanism portion 1241 the same space via the I / F module 200.

  The seal 202 is disposed around the surface of the I / F module 200 on the mechanism portion 1241 side so as to surround the central portion of the I / F module 200, and the I / F module 200 is disposed through the seal 202. Therefore, the intrusion of moisture, foreign matter, and the like from between the mechanism portion 1241 and the I / F module 200 is prevented.

  The inner case 300 is attached to the I / F module 200. Further, since the material of the inner case 300 is a synthetic resin, heat transfer from the brake pad portion can be minimized. Since the inner case 300 is attached to the I / F module 200 via the seal 302, it is possible to prevent intrusion of moisture, foreign matter, and the like from between the inner case 300 and the I / F module 200.

  The inner case 300 has a function as a substrate on which electronic components to be described later are mounted. An aluminum metal plate 402 and a control circuit board 404 are sequentially mounted on the surface of the inner case 300 on the I / F module 200 side. The aluminum metal plate 402 can avoid damage to the control circuit board 404 due to twisting or the like.

A concave portion (not shown) is formed on the surface where the inner case 300 and the I / F module 200 face each other, excluding the peripheral portion including the seal 302. The metal plate 402 and the control circuit board 404 are disposed in the recess.

  The wall portion 305 is formed on the surface of the inner case 300 opposite to the I / F module 200 so as to surround one region obtained by dividing the region of the surface into two substantially. A relatively large electronic component 406 such as a capacitor or reactance is mounted in an area surrounded by the wall portion 305 (hereinafter referred to as an electronic component mounting area). In a region outside the wall portion 305, a through hole 306 having a relatively large area is formed in a part of the region. A power module 408 is disposed inside the through hole 306.

  The power module 408 is obtained by modularizing the three-phase motor inverter circuit 118, the phase current monitor circuit 134, and the phase voltage monitor circuit 136 shown in FIG. 5 by resin molding.

  Furthermore, the outer case 500 is attached to the surface of the inner case 300 opposite to the I / F module 200. The outer case 500 includes an opening 504. With this opening 504, the electronic component mounting region 316 of the inner case 300 can be visually confirmed from the outside, and workability is improved. Further, the outer case 500 is attached so as to cover the peripheral side surface of the inner case 300, the peripheral side surface of the wall portion 305, the through hole 306, and the periphery of the through hole 306, respectively. The outer case 500 is made of metal, for example, an aluminum alloy whose surface is anodized, covers most of the outer peripheral surface of the electric circuit portion 1251, and protects the circuit from external impact.

  On the surface of the outer case 500 on the inner case 300 side, the seal 502 is disposed so as to surround the through hole 306 at a portion facing the periphery of the through hole 306 and the through hole 306. The seal 502 prevents moisture from entering the I / F module 200 side surface of the inner case 300 through the through hole 306 from the opening 504.

  A harness 600 for supplying power or a control signal is fixed to the outer case 500 by a harness stopper 602 from the outside of the electric brake device. Each wiring (not shown) in the harness 600 is led to an electronic component mounting region 316 in the wall 305 through a through hole (not shown) formed in the wall 305 of the inner case 300.

  The I / F module 200, the inner case 300, and the outer case 500 are integrated by bolts 700a, 700b (not shown), 700c, and 700d inserted into the screw holes formed at the four corners from the outer case 500 side. And attached to the mechanism part 1241.

  The cover 800 is screwed to the outer case 500 so as to cover the opening 504 of the outer case 500. The material of the cover 800 is a metal, for example, an aluminum alloy. Thereby, it is possible to prevent damage to external obstacles (for example, stepping stones).

  FIG. 6 is a detailed configuration diagram of the outer case 500. FIG. 6A is a perspective view seen from the inner case 300 side, and FIG. 6B is a perspective view seen from the opposite side of the inner case 300.

The outer contour of the outer case 500 has substantially the same shape as the outer contour of the inner case 300. Large diameter holes 512a, 512b, 512c, and 512d are formed at the four corners of the outer case 500, respectively. In the large-diameter hole, the aforementioned bolts 700a, 700b, 700c,
700 d is inserted, and the electric circuit 1251 is fixed to the mechanism part 1241.

  A substantially rectangular groove 502a is formed in a portion excluding the opening 504 on the inner side surface of the outer case 500 shown in FIG. 6A, and the aforementioned seal 502 (not shown) is embedded therein. Screw holes 510a and 510b for fixing a power module 408, which will be described later, are formed in a region surrounded by the groove 502a.

  The screw holes 511a and 511b are formed so as to be close to the screw holes 510a and 510b, respectively. In order to position the screw holes 511a and 511b in the region surrounded by the groove 502a, the groove 502a is formed so as to bypass the screw holes 511a and 511b. The screw holes 511a and 511b are arranged coaxially with the screw holes 310a and 310b shown in FIG. Furthermore, the outer case 500 is fixed to the inner case 300 by screws 320a and 320b shown in FIG.

  A protruding body 508 shown in FIG. 6B is formed on the outer surface of the outer case 500. For this reason, the surface area which touches the external air of the outer case 500 becomes large. The heat dissipation effect can be increased.

  The wall portion 505 is formed on the outer side of the wall portion 305 of the inner case 300 in contact with the wall portion 305, and becomes an outer frame of the electronic component mounting region 316 together with the wall portion 305 of the inner case 300. Thereby, the mechanical strength of the outer frame of the electronic component mounting region 316 is improved.

  A bridge 505a to which the upper end surface is connected is formed on the wall 505 in which the opening 505b is formed. When the outer case 500 is incorporated in the inner case 300, the protruding wall portion 305a of the inner case 300 is positioned in the opening 505b as will be described later with reference to FIG. Further, the bridge 505a covers the peripheral side surface of the protruding wall portion 305a.

  Screw holes 512a, 512b, and 512c for screwing the cover 800 that closes the opening 504 are formed in a part of the periphery of the wall 505.

As shown in FIG. 6B, a harness fixing portion 506 that fixes a harness 600 described later is formed on the outer surface of the outer case 500. A groove 506a is formed at the center of the protruding base so as to be directed toward the opening 504. A harness 600 is fixed to the harness fixing portion 506 by a harness stopper 602 described later, and screw holes 507a and 507b for fixing the harness stopper 602 are formed on both sides of the groove 506a in the harness fixing portion 506. Has been.

  FIG. 7 is a configuration diagram illustrating an example of the inner case 300. FIG. 7A is a perspective view of the inner case 300 viewed from the I / F module 200 side. FIG. 7B is a perspective view as viewed from the side opposite to the I / F module 200 and also shows wiring embedded therein.

  The inner case 300 has a function as a substrate on which electronic components to be described later are mounted. Inner case 300 is made of a synthetic resin and can suppress heat transfer from mechanism portion 1241.

As shown in FIG. 7A, the outer contour of the inner case 300 has substantially the same shape as the outer contour of the I / F module 200. Large diameter holes 304 a, 304 b, 304 c, and 304 d are formed at the four corners of the inner case 300. The electric circuit part 1251 including the inner case 300 is fixed to the mechanism part 1241 by inserting the bolts 700a, 700b, 700c, and 700d into the large diameter holes 304a, 304b, 304c, and 304d. The projecting members 208a and 208b formed in the I / F module 200 are inserted into the holes 308a and 308b.

  The relatively large rectangular through hole 306 is formed at a position slightly deviated from the center of the inner case 300. A power module 408 described later is disposed in the through hole 306.

  The terminals 312a and 312b are juxtaposed on the opposite sides of each periphery of the through hole 306, and are connected to electrodes (terminals) formed to protrude from the power module 408 by welding. The terminal 314 is formed on the back side of the electronic component mounting area 316. A small electronic component is disposed in the vicinity of the terminal 314, and the electrode of the electronic component and the terminal 314 are connected.

  In the vicinity of the through-hole 306, through-holes 310a and 310b are formed in the vicinity of the remaining two sides having the opposite side relationship excluding the portion where the terminals 312a and 312b are arranged in parallel. The through holes 310 a and 310 b serve as screw holes for fixing the inner case 300 and the power module 408 to the outer case 500.

  The inner case 300 is disposed at a fixed position so as to face the I / F module 200. A bifurcated terminal 210 formed in the I / F module 200 is inserted into the terminal hole group 318, and a bifurcated terminal 212 is inserted into the terminal hole group 320, respectively. These terminal holes contain terminals that are in contact with the bifurcated portions of the bifurcated terminals 210 and 212.

  As shown in FIG. 7B, a through hole 306 and an electronic component mounting region 316 are provided on the outer surface of the inner case 300. The electronic component mounting region 316 is formed so as to be surrounded by the wall portion 305. The recessed portion 322 formed in the electronic component mounting region 316 mounts an electronic component such as a capacitor, and the shape of the recessed portion 322 matches the shape of the electronic component such as a capacitor. A terminal 324 is implanted in the vicinity of the recessed portion 322. The terminal 324 is connected to the electrode of the electronic component described above. Therefore, the wiring layer embedded in the inner case 300 can be electrically connected without error. The wiring layer embedded in the inner case 300 includes a wiring layer (communication bus) having a relatively small line width for transmitting and receiving signals and a wiring layer (power bus) having a large line width to which a high voltage power supply is supplied. ).

  A step portion 310 is formed between the peripheral portion of the inner case 300 where the large-diameter holes 304a, 304b, 304c, and 304d are formed and the central portion that extends slightly inward from the peripheral portion. A recess is formed. A control circuit board 404 and the like which will be described later are disposed in the recessed portion, and an air layer is formed between the inner case 300 and the I / F module 200. By this air layer, heat transfer from the mechanism part 1241 to the electronic component can be suppressed.

  The groove 302a is formed so that the large-diameter holes 304a, 304b, 304c, and 304d are arranged on the outside and so as to surround the center portion of the inner case 300. The above-described seal 302 is incorporated in the groove 302a. For this reason, it is possible to prevent moisture and foreign matter from entering the air layer between the inner case 300 and the I / F module 200.

In the through holes 326 a and 326 b, the inner case 300 is disposed at a fixed position so as to face the I / F module 200. Then, terminals 214a and 214b formed in the I / F module 200 are inserted. The tips of the terminals 214a and 214b are connected to the through holes 326a,
It protrudes to the outer surface (electronic component mounting area 316) of the inner case 300 through 326b.

  The through holes 326a and 326b are formed to be larger than the inserted terminals 214a and 214b. Therefore, the air in the electric brake can be sufficiently convected through the through holes 326a and 326b. Therefore, local fluctuations in atmospheric pressure in the electric brake device can be suppressed, and deterioration of the sealing function such as a seal can be suppressed (atmospheric pressure adjustment function).

  The protruding wall portion 305 a having a thick wall portion 305 is formed on the wall portion 305 facing the through hole 306. A through hole 305b is formed in the protruding wall portion 305a so as to penetrate from the through hole 306 side to the electronic component mounting region 316 side. The front end portion of the harness 600 is fixed by fixing a flange 606 attached to the front end of the harness 600 to be described later to the protruding wall portion 305a which is thick. Each wiring in the harness 600 is led to the electronic component mounting region 316 through the through hole 305b.

  FIG. 8 is a diagram illustrating a process of incorporating the outer case 500 into the inner case 300.

  FIG. 8A shows the inner case 300 described in FIG.

  Screw holes 305c and 305d for fixing the flange 606 of the harness 600 are formed on both sides of the through hole 305b. A ring-shaped seal 305S is disposed around the through hole 305b so as to surround the through hole 305b. As a result, the flange 606 is disposed in contact with the protruding wall portion 305a, and entry of moisture, foreign matter, and the like from the interface between the protruding wall portion 305a and the flange 606 can be prevented.

  FIG. 8B shows an inner case 300 in which electronic components are mounted on the electronic component mounting region 316. The electronic components 328a to 328d are, for example, capacitors or reactances, and are electrically connected to the terminals 324 and the like implanted in the vicinity of the electronic components 328a to 328d, for example, by welding.

  FIG.8 (c) shows the outer case 300 demonstrated in FIG.

FIG. 8D shows a state after the inner case 300 is assembled in the outer case 500. The outer case 500 exposes the electronic component mounting region 316 of the inner case 300 through the opening 504, but is incorporated into the inner case 300 so as to cover other regions. That is, the wall portion 505 of the outer case 500 is. It arrange | positions so that it may be located in the outer wall surface side of the wall part 305 of the inner case 300. FIG. The bridge 505a formed on the wall portion 505 of the outer case 500 is disposed so as to surround the protruding wall portion 305a of the inner case 300, and the surface of the protruding wall portion 305 and the wall on the surface on the harness fixing portion 506 side. The surface of the portion 505 is substantially flush.

  FIG. 9 is a diagram illustrating a process for attaching the power module 408, the metal plate 402, and the control circuit board 404 to the inner case 300.

First, as shown in FIG. 9A, electronic components 328e and 328f that are relatively smaller than the electronic components 328a to 328d are mounted on the inner surface of an electronic component mounting substrate 900 to which a harness 600 described later is attached. Furthermore, a power module 408 is disposed in the portion of the through hole 306 on the inner side surface of the electronic component mounting substrate 900. The power module 408 includes a screw hole (not shown), and screws 410a and 410b are screwed into screw holes 510a and 510b (not shown) formed in the outer case 500 through the screw holes. The module 408 is fixed.

  In addition, on the back surface of the inner case 300 before the power module 408 is mounted, a through hole 306 of the inner case 300 closed by the outer case 500 is formed as a recessed portion, and the power module 408 is accommodated in the recessed portion. In this case, the bottom surface of the recessed portion is a part of the outer case 500 formed of metal, and the power module 408 is disposed so as to contact the outer case 500. For this reason, the heat generated by the power module 408 is radiated through the outer case 500, and the reliability of braking force control is improved. Further, although not shown in the figure, heat radiation grease or a heat radiation sheet is interposed between the outer case 500 and the power module 408 so as to improve the efficiency of heat transfer from the power module 408 to the outer case 500. Good.

  In addition, the power module 408 includes terminals that serve as electrodes of the power module 408 on its side surface. When the power module 408 is disposed at a fixed position on the inner case 300, the terminals of the power module 408 come into contact with the terminals 312 a and 312 b of the inner case 300. The terminals of the power module 408 and the terminals of the inner case 300 are electrically connected to each other, for example, by welding. The terminals of the power module 408 and the terminals of the inner case 300 are bent approximately 90 degrees, and the surfaces of the bent tips are in contact with each other. Therefore, welding work from the inner side surface of the inner case 300 is facilitated, and assembly workability is improved.

  Next, as illustrated in FIG. 9B, the insulating sheet 400 is disposed on the upper surface of the power module 408 (the surface on the I / F module 200 side). Thereby, each terminal part of the power module 408 is electrically insulated from the metal plate 402 described below. As a material of the insulating sheet 400, for example, a polyimide resin is used. Therefore, between each terminal portion of the power module 408 and the metal plate 402, the insulating sheet 400 has a heat resistance of 150 ° C. or more and an insulating property of 200 kV / mm. .

  The insulating sheet 400 extends so as to cover the terminal portion of the power module 408 and is bonded to the upper surface of the power module 408. The insulating sheet 400 has a pattern having a notch 400a for avoiding the heads of the screws 410a and 410b without covering the heads of the screws 410a and 410b with the power module 408 fixed to the outer case 500. Formed.

  Next, as shown in FIG. 9C, a metal plate 402 made of, for example, an aluminum plate is disposed on the upper surface (surface on the I / F module 200 side) of the insulating sheet 400. Thereby, the control circuit board 404 arranged on the upper surface of the metal plate 402 (surface on the I / F module 200 side) can be mechanically reinforced. Furthermore, the heat generated by the control circuit board 404 can be radiated efficiently.

The metal plate 402 is large enough to cover the power module 408 and the insulating sheet 400. The through holes 408a and 408b formed in the metal plate 402 are exposed without protruding the heads of the screws 410a and 410b for fixing the power module 408 to the outer case 500 from the through holes 408a and 408b. I am letting. As a result, the metal plate 402 can be disposed in close contact with the insulating sheet 400, and a control circuit board 404 (to be described later) can be disposed in close contact with the upper surface of the metal plate 402, thereby contributing to downsizing of the electric brake device. To do.

  Furthermore, a patterned recess 402d is formed on the surface of the metal plate 402 that faces a control circuit board 404 described later. On the other hand, the control circuit board 404 has, for example, an inspection check terminal (not shown) exposed on the surface facing the metal plate 402. The concave portion 402d is formed so that the inspection check terminal faces the formation region of the concave portion 402d, and direct contact between the inspection check terminal and the metal plate 402 is avoided. This prevents each terminal for inspection check from being electrically connected to the metal plate 402, and contributes to downsizing of the electric brake device. Further, the concave portion 402d also has a function of releasing the adhesive when the control circuit board 404 is bonded to the upper surface of the metal plate 402 using an adhesive.

Then, as shown in FIG. 9D, the control circuit board 404 is disposed on the upper surface of the metal plate 402 (the surface on the I / F module 200 side). The control circuit board 404 is formed of, for example, ceramic, and a relatively large electronic component 328g is mounted on the upper surface (the surface opposite to the metal plate 402). Since the substrate of the control circuit board 404 is ceramic, the heat resistance and vibration resistance of the control circuit board are improved. Further, since the control circuit board 404 is disposed on the upper surface of the metal plate 404, even when the inner case 300 or the like is distorted due to some cause, for example, an excessive reaction force from the piston 1331, the control circuit board 404. Can be prevented from being damaged.

  Each electronic component 414 is mounted on the control circuit board 404, and wiring layers 412a to 412c are embedded on the surface of the board or in the board. Terminals 340 a to 340 c connected to the wiring layer are formed in parallel on a part of the periphery of the control circuit board 404. Between these corresponding terminals, for example, the terminal 340a and the terminal 412a are electrically connected to each other by bonding of a wire made of aluminum.

  Then, a gel-like member (not shown) is applied to the side of the control circuit board 404 on which electronic components are mounted. As a result, the electronic component 414 and the wire bonding of the control circuit board 404 can be protected from dust and dew condensation, and vibration transmission can be reduced.

  FIG. 10 is a detailed view of the harness 600 used in this embodiment.

The power line 1600a supplies power for operating an electric actuator mounted on the electric brake device. The ground line 1600b is paired with the power line 1600a. The power line covering member 1606 covers the power line 1600a and the ground line 1600b, and protects the power line 1600a from external impact.

  The signal lines 1601a to 1601d transmit a thrust command signal corresponding to the depression amount of the brake pedal, a start end command signal of the electric brake device, and the like.

  The communication line covering member 1605 covers the communication lines 1601a to 1601d and protects the communication lines from external impacts. Further, by covering the communication line covering member 1605 with a shielding material, radiation of radio noise from the communication lines 1601a to 1601d may be reduced.

  The air communication member 1603 is a member through which air can pass. When the pressure difference between the air communication members 1603 exposed at both ends of the harness 600 becomes a predetermined value or more, air flows from the end of the harness 600 having a high pressure to the end of the harness 600 having a low pressure. For this reason, the pressure difference between the two spaces connected by the harness 600 is suppressed within a predetermined range. As a material of the air communication member 1603, a polymer compound, for example, a fiber material manufactured by a plant or a scientific process is suitable.

  The shield material 1604 covers the outside of the air communication member 1603 to prevent noise emission. The harness 600 that connects the vehicle body and the electric brake device is used in an environment where there is a lot of vibration such as unsprung vibrations, and is required to be severely flexible because it is fixed to the vehicle body. By using a sheet-like material in which metal thin wires are knitted for the shield material 1604, the vibration resistance and the flexibility of the harness 600 can be improved.

  The covering member 1602 covers the outside of the shield material 1604 and prevents damage to the shield material and disconnection of the communication line and the power supply line due to external impact. As a material for the covering member 1602, a polymer compound having a waterproof function and excellent flexibility is used.

  FIG. 11 is a diagram illustrating a process for attaching the harness 600 to the electronic component mounting substrate 900 described with reference to FIG. 9.

  FIG. 11A shows the outer surface of the electronic component mounting substrate 900. In the electronic component mounting substrate 900, a ring-shaped seal 305s is provided on a protruding wall portion 305a formed on the inner case 300 so as to surround the periphery of the through hole 305b.

  FIG. 11B shows an electronic component mounting substrate 900 in which the harness 600 is disposed at a fixed position. The flange 606 includes a through hole (not shown) into which the harness 600 is inserted, and screw holes 610c and 610 formed with the through hole therebetween.

  The harness 600 is disposed in the groove 506a of the harness fixing portion 506 at a location slightly spaced from the end of the flange 606. The groove 506a restricts movement in the direction crossing the longitudinal direction of the harness 600.

  Next, as shown in FIG. 11C, the flange 606 of the harness 600 is fixed to the protruding wall portion 305a by bolts 614c and 614d. At this time, the flange 606 of the harness 600 is brought into close contact with the protruding wall portion 305a via the ring-shaped seal 305s. Therefore, moisture can be prevented from penetrating into the electronic component mounting region 316 inside the wall portion 305 through the interface between the protruding wall portion 305a and the flange 606.

  Further, as shown in FIG. 11C, the harness stopper 602 is placed above the harness fixing portion 506 so as to sandwich the harness 600 between the harness stopper 602 and the harness fixing portion 506.

  The shape of the clamping portion of the harness stopper 602 is, for example, a semi-cylindrical shape so as to match the shape of the harness 600. Further, screw holes 610a and 610b are formed at both end portions of the harness stopper 602 with the harness 600 interposed therebetween.

  Next, as shown in FIG. 11D, the harness stopper 602 is fixed to the harness fixing portion 506 by bolts 612a and 612b. The bolts 612a and 612b are screwed into the corresponding screw holes of the harness fixing portion 506 from the screw holes 610a and 610b of the harness stopper 602, and fix the harness 600. The harness 600 is clamped between the harness fixing portion 506 and the harness stopper 602, and the axial movement is restricted by the pressing force generated by the clamping.

  The pull-out of the harness 600 attached to the outer case 500 from the device main body extends once in a direction perpendicular to the direction of movement of the electric brake device during braking, and then extends in a free direction. The Therefore, the harness 600 can be routed so that the harness 600 always has play with respect to the movement of the electric brake device during braking. Therefore, the disconnection accompanying the tension state of the harness 600 can be prevented.

Then, as shown in FIG. 11E, each wiring 608 drawn from the harness 600 to the electronic component mounting region 316 is connected to each terminal 324 by welding, for example. Each terminal 324 is connected to a wiring layer implanted in the inner case 300 and is formed to protrude from the surface of the electronic component mounting region 316.

  Instead of the flange 606, an electric brake device and a detachable connector may be used. The connector on the electronic component mounting board 900 side is installed in the vicinity of the electronic component mounting region 316, for example, on the wall 305, and is electrically connected to the electronic components 328a to 328d in the electronic component mounting region 316 by conducting wires or the like. The connector on the harness 600 side is fitted and electrically connected to the connector on the electronic component mounting board 900 side.

  FIG. 12 is a detailed configuration diagram of the I / F module 200. FIG. 12A is a perspective view of the I / F module 200 viewed from the inner case 300 side. FIG.12 (b) is the perspective view seen from the opposite side to Fig.12 (a).

  The I / F module 200 has a function as a printed circuit board having planted wiring and terminals formed integrally with the wiring. The material of the substrate covering this wiring is a synthetic resin. Synthetic resins generally have a low thermal conductivity, and heat transfer from the mechanism portion 1241 can be suppressed by the I / F module 200.

  As shown in FIG. 12A, the thickness of the peripheral portion of the I / F module 200 is formed larger than the thickness of the central portion excluding the peripheral portion. Therefore, the stepped portion 202 is formed in a portion that extends slightly inward from the outer contour of the I / F module 200.

  Large-diameter holes 204a to 204d are formed at the four corners of the peripheral portion which is thick. The large diameter holes 204 a to 204 d are screw holes for fixing the I / F module 200 to the mechanism part 1241 together with the inner case 300 and the outer case 500.

  Small-diameter holes 206a to 206d are formed in the thin portions of the I / F module 200 adjacent to the large-diameter holes 204a to 204d, respectively. The small diameter holes 206 a to 206 d are screw holes for temporarily fixing the I / F module 200 to the mechanism portion 1241.

The protruding column bodies 208a and 208b are formed close to, for example, two large-diameter holes 204a and 204b among the large-diameter holes 204a to 204d. The protruding column bodies 208 a and 208 b have a function as alignment between the I / F module 200 and the inner case 300 when the inner case 300 is disposed opposite to the I / F module 200.

  Wiring layers 216 a to 216 d are embedded in the I / F module 200. The wiring layers 216a to 216d shown in FIG. 13 (a) are shown through. The wiring layers 216 a to 216 d are electrically connected to the terminal 214. Note that the wiring layers 216 a to 216 d may be formed on the surface of the I / F module 200, and are not necessarily embedded in the I / F module 200.

  The terminal 106 extending from the rotation angle sensor 1353 is inserted into the through hole 220. This terminal 106 is connected to a terminal 218 implanted in the I / F module 200 by, for example, welding. The terminal 218 is led out to the right side of the center of the I / F module 200 through the wiring layer 216a and connected to the bifurcated terminal 210 implanted in the I / F module 200.

The terminal 108 extending from the thrust sensor 1353 is inserted into the through hole 222. This terminal 108 is connected to a terminal 224 implanted in the I / F module 200 by, for example, solder. The terminal 224 is drawn out to the left side of the center of the I / F module 200 via the wiring layer 216b and connected to the bifurcated terminal 212 implanted in the I / F module 200. The terminal 110 extending from the PKB solenoid 1342 is inserted into the through hole 228. This terminal 110 is connected to a terminal 230 implanted in the I / F module 200 by, for example, welding. The terminal 230 is drawn out to the left side of the center of the I / F module 200 through the wiring layer 216c and connected to the bifurcated terminal 226 implanted in the I / F module 200.

A terminal 112 extending from the temperature sensor 1355 is inserted into the through hole 232. This terminal 112 is connected to a terminal 234 implanted in the I / F module 200 by, for example, welding. The terminal 234 is drawn out to the right side of the center of the I / F module 200 via a wiring layer (not shown), and is connected to the bifurcated terminal 236 implanted in the I / F module 200.

  Further, the terminal 114 extending from the three-phase electric motor 1311 is inserted into the through hole 232. This terminal 114 is connected to a terminal 238 implanted in the I / F module 200, for example, by welding. The terminal 238 is led out to the center of the I / F module 200 through the wiring layer 216d and connected to the terminals 214a and 214b implanted in the I / F module 200.

  The line width of the wiring layer 216d is formed larger than the line widths of the other wiring layers 216a to 216c. This is because the wiring layer 216d is a power bus that supplies power, and the wiring layers 216a to 216c are communication buses that send and receive signals.

  Further, the heights of the terminals 214a and 214b protruding from the I / F module 200 are formed larger than the heights of the other terminals 218 and the like. This is for inserting into the through holes (indicated by reference numerals 326a and 326b in FIG. 7A) formed in the inner case 300 and projecting to the opposite surface of the inner case 300.

  Of the terminals implanted in the I / F module 200, the terminals other than the bifurcated terminals described above have a flat plate shape, and their main surfaces (surfaces other than the side surfaces) are wide. Opposed and connected by welding. For this reason, the reliability of electrical connection can be achieved.

  As shown in FIG. 12B, the I / F module 200 has a recessed portion 244 formed at a portion facing the thrust sensor 1353. The depth of the recessed portion 244 is formed larger than the thickness of the I / F module 200. Therefore, as shown in FIG. 12A, the I / F module 200 is formed as a protrusion 240 on the opposite surface. Thereby, even if the thrust sensor 1353 provided on the mechanism portion 1241 side is disposed so as to slightly protrude from the end surface of the frame body 100a, the electric brake device can be downsized without interfering with the I / F module 200.

  The recessed portion 246 is formed in an arc shape around the protruding portion 240 around the protruding portion 240. The recessed portion 246 is a portion facing an electronic component or the like mounted on the inner case 300. The recessed portion 246 can accommodate the electronic component or the like while preventing the electronic component or the like from interfering with the I / F module 200. Since the depth of the recessed portion 246 is formed to be greater than the thickness of the I / F module 200, as shown in FIG. 12B, the recessed portion 246 is formed as a protruding portion 242 on the opposite surface.

  Further, the protrusions 248a and 248b are arranged in contact with the inner side surface of the frame 100a when the I / F module 200 is in contact with the frame 100a of the mechanism portion 1241, and the I / F with respect to the frame 100a. It functions as a positioning mechanism for the module 200.

  As shown in FIG. 12 (b), the groove 202a is arranged so that the large-diameter holes 204a to 204d are arranged on the outer side in the periphery of the surface attached to the mechanism part 1241, and so as to surround the center part. It is formed. A seal 202 (not shown) is incorporated in the groove 202a. When the I / F module 200 is brought into contact with the frame body 100a of the mechanism portion 1241, the seal 202 is interposed at the interface between the I / F module 200 and the frame body 100a. Intrusion can be prevented.

FIG. 13 is a diagram illustrating a process for attaching the I / F module 200 described in FIG. 12 to the mechanism unit 1241. FIG. 13A is a perspective view of the mechanism portion 1241 and shows a surface to which the I / F module 200 is attached. FIG. 13B is a perspective view of the I / F module 200 and shows a surface opposite to the surface attached to the mechanism portion 1241 (surface facing the inner case 300). FIG. 13C is a perspective view when the I / F module 200 is attached to the mechanism portion 1241.

  As shown in FIG. 13A, the thrust plate 1421 is visible on the surface side of the mechanism portion 1241 to which the I / F module 200 is attached and inside the frame 100a. The thrust plate 1421 receives a reaction force due to the linear motion of the piston 1331, and the thrust sensor 104 is disposed at the center thereof. The thrust plate 1421 and the thrust sensor 104 have a circular shape, and the frame 100a has a substantially rectangular shape.

  The frame 100a is formed so as to slightly protrude toward the I / F module 200 from the thrust plate 1421. The thrust plate 1421 is deeper than the end surface of the frame 100a (the surface that contacts the I / F module 200). It is arranged at the place where For this reason, even when a gap (air layer) is formed between the thrust plate 1421 (and the thrust sensor 104) and the I / F module 200, and heat generated from the brake pad portion as a heat source is conducted in the mechanism portion 1241, Heat transfer to the electric circuit 1251 side can be suppressed by the gap (air layer).

  Terminals 106, 108, 110, 112, and 114 are implanted in part of the periphery of the thrust plate 1421 in the mechanism unit 1241, and power or signals are acquired from the electric circuit unit 1251 by these terminals. When the thrust plate 1421 is viewed from the visible side, the PKB solenoid terminal 324 is located at the upper part of the mechanism part 1241, the three-phase terminal 114 and the temperature sensor terminal 112 are rotated at the upper right part of the mechanism part 1241, and the lower part of the mechanism part 1241 is rotated. An angle sensor terminal 106 and the like are disposed. Further, the terminal 108 of the thrust sensor 104 is disposed near the center of the thrust plate 1421. Each of these terminals is a flat conductor, and the tip of the terminal extends sufficiently beyond the end surface of the frame 100a (the surface in contact with the I / F module 200). As a result, the distal end portion of each terminal can be inserted into the through hole 222 formed in the I / F module 200 and protrude to the surface of the I / F module 200 on the inner case 300 side.

As shown in FIG. 13C, when the I / F module 200 is attached to the mechanism portion 1241, the terminal 110 of the PKB solenoid is from the through hole 228, and the three-phase terminal 114 and the temperature sensor terminal 112 are from the through hole 232. The rotation angle sensor terminal 106 protrudes from the through hole 220, and the terminal 108 of the thrust sensor 104 protrudes from the through hole 222.

  Note that each through hole of the I / F module 200 is formed large enough to have a sufficient gap around a terminal inserted therethrough. Thereby, each through-hole functions as an air entrance / exit hole between the mechanism part 1241 and the electric circuit part 1251, and can perform atmospheric pressure adjustment following the change of the outside air in the electric brake device.

  FIG. 14 is a diagram illustrating a process for assembling the mechanism unit assembly 810 described in FIG. 13 and the electric circuit unit assembly 820 described in FIG. 11.

  FIG. 14A shows each surface of the mechanism unit assembly 810 and the electric circuit unit assembly 820 that should face each other.

As shown in FIG. 14B, three lead-like terminals 214a,
214b is implanted in the I / F module 200. Two of the three terminals are adjacent to each other, and the remaining one is spaced apart. Thereby, each terminal 214a, 214b can be protruded to a predetermined location in the electronic component mounting region 316.

  These three terminals 214 a and 214 b are formed integrally with a wiring layer 216 d embedded in the I / F module 200, and the wiring layer 216 d is bent in the I / F module 200, thereby It is formed to protrude from the surface of the F module 200.

  As shown in FIG. 14C, the inner case 300 is formed with through holes 326a and 326b. Terminals 214a and 214b are inserted into the through holes 326a and 326b. These terminals protrude to the electronic component mounting region 316 formed on the opposite surface of the inner case 300 and are connected to other terminals in the electronic component mounting region 316.

As shown in FIG. 14D, the I / F module 200 includes a bifurcated terminal 210,
234 are planted in parallel. These bifurcated terminals are also formed integrally with a wiring layer embedded in the I / F module 200. This wiring layer is formed relatively thin because it is in charge of signal transmission. Further, the wiring layer is formed thick in the portion of the I / F module 200 that reaches the bifurcated terminals 210 and 234, and is formed by being led to the surface of the I / F module 200 by being bent at this portion. The

  As shown in FIG. 14 (e), a groove 354 is formed in the inner case 300 facing the bifurcated terminals 210 and 234, and each bifurcated terminal is inserted into the groove 354. Inside the groove 354, a terminal 352 is juxtaposed. The terminal 352 is sandwiched between the branch portions of the bifurcated terminals 210 and 234 and is connected to a wiring embedded in the inner case 300.

  14A to 14E, when the electric circuit unit assembly 820 is assembled to the mechanism unit assembly 810, the terminals 214a and 214b on the I / F module 200 side are connected to the inner case 300. While being able to appear in the electronic component mounting region 316, the bifurcated terminal 210 and the like can be connected to the wiring in the inner case 300 via the terminal 352.

  Next, as shown in FIG. 14 (f), the electric circuit assembly 820 is brought into contact with the mechanism assembly 810 to be assembled. At this time, the projecting column bodies 208a and 208b formed to project to the I / F module 200 side are inserted into the holes 308a and 308b formed on the inner case 300 side for positioning. Then, they are fixed to each other by bolts 700 a, 700 b, 700 c, and 700 d that are screwed into the screw holes of the mechanism unit assembly 810 through the screw holes formed at the four corners of the electric circuit unit assembly 820.

  As shown in FIG. 14 (g), the terminals 214a and 214b inserted into the through holes 326a and 326b protrude into the electronic component mounting region 316, and the terminals 350a and 350b implanted in the inner case 300 are electrically connected. Connected. At this stage, the terminals 214a and 214b and the terminals 350a and 350b are electrically connected to each other by welding, for example.

  As shown in FIG. 14H, the terminal 352 on the inner case 300 side is sandwiched between the forked terminal 234 on the I / F module 200 side and is electrically connected to the forked terminal 234.

And as shown in FIG.14 (i), the cover 800 is attached so that the exposed electronic component mounting area | region 316 may be covered. The cover 800 passes through the screw holes formed in the cover 800 and passes through the screw holes formed in the outer case 500 to the screws 804a,
The outer case 500 is fixed by screwing 804b and 804c.

  Here, in the electric brake device shown in FIG. 14 (i), the metal casing 1301 of the mechanism part 1241 and the metal outer case 500 and the cover 800 of the electric circuit part 1251 are connected to each other. Rather, they are separated from each other with an I / F module 200 made of synthetic resin in between. Thereby, the heat generated on the mechanism part 1241 side is not easily transmitted to the electric circuit part 1251 side. The heat generated in the mechanism part 1241 is dissipated to the atmosphere side through the housing 1301 of the mechanism part 1241, while the heat generated in the electric circuit 1251 is dissipated to the atmosphere side through the outer case 500 and the cover 800. Thereby, the mechanism part 1241 and the electric circuit 1251 can be thermally made substantially independent.

FIG. 15 is a perspective view of the attachment structure of the harness 600 to the outer case 500 as viewed from the harness 600 side.

The flange 606 is integrally formed with a cylindrical body 620 that projects in a direction perpendicular to the main surface of the flange 606 at the center thereof. The harness 600 is attached by fixing the outer peripheral surface of the covering member 1602 of the harness 600 inserted into the hole from the cylindrical body 620 side to the inner peripheral surface of the hole of the cylindrical body 620. Then, each wiring (power supply line 1 and communication line) included in the covering member 1602 is guided to the opposite side of the flange 606 where the cylindrical body 620 is formed.

  The main surface of the flange 606 is oval or rectangular in a plane orthogonal to the axial direction of the harness 600. A pair of screw holes are provided on both sides of the hole of the cylinder 620. That is, the flange 606 is formed so as to have a relatively large width in the juxtaposed direction of the hole of the cylindrical body 620 and the screw hole, and is formed so as to reduce the length in the height direction perpendicular to the width direction. The For this reason, while fixing the front-end | tip part of the harness 600 to the wall part 305 of the inner case 300 reliably, it contributes to size reduction of an electric brake device.

In the present embodiment, the length of the flange 606 in the height direction is formed to be larger than the height of the wall portion 305 (the wall portion 305 other than the bridge portion 505a). The height of the bridge portion 505a is set larger than the wall portion 305 so that the bridge portion 505a can be fixed to the wall portion 305 in contact with the flange 606.

  The fixed portion of the flange 606 of the harness 600 is located at the approximate center of the outer case 500 viewed in a plan view. That is, as shown in FIG. 15, when the width of the outer case 500 is W and the height is H, the flange 606 is positioned at about half the width W and about half the height H. As shown in FIG. 14 (i), when the electric brake device is viewed as a whole, the width of the electric brake device is almost W and the height is almost H. When the electric brake device vibrates, the attachment position of the flange 606 is a position around the central axis of the electric brake device where vibration (vibration in the direction of arrow T in FIG. 15) is minimized. For this reason, the attachment to the wall part 305 of the flange 606 and the fixation to the flange 606 of the harness 600 are stabilized with respect to the vibration of the electric brake device.

  Furthermore, the harness 600 is clamped by a harness fixing portion 506 formed integrally with the outer case 500 and a harness stopper 602 formed separately from the harness fixing portion 506 at a position slightly spaced from the flange 606. Fixed by. Thereby, the force applied to the harness 600 in the harness 600 portion on the vehicle body side from the harness fixing portion 506 is not transmitted to the flange 606 fixed to the wall portion 305, and the attachment of the flange 606 to the wall portion 305 is stabilized.

  FIG. 16 shows a configuration diagram of the harness 600. The harness 600 is routed from an electric brake device mounted under the vehicle spring, and one end portion is taken into the vehicle interior. In the middle of the routing route of the harness 600, the harness 600 is fixed by a fixing jig 1610 in order to maintain a predetermined route. When this fixing jig 1610 crushes a part of the outer periphery of the harness 600, a part of the air communication member 1603 described above is also crushed and air communication may be reduced, or the air flow may be interrupted. There is. Therefore, as shown in FIG. 16, the number of air communication members 1603 at the tightening points by the fixing jig 1610 is increased, and the diameter of the electric wire is increased. Thereby, it is possible to prevent a decrease in the air flow rate due to tightening of the fixing jig 1610. Further, the harness 600 can be prevented from being damaged by the friction between the covering member 1602 and the fixing jig 1610 described above.

  Next, a place where the end of the harness 600 on the vehicle connection side and the vehicle side harness (not shown) are connected will be described.

  Note that an end portion on the vehicle connection side of the harness 600 of the electric brake device installed on the rear wheel is connected to the vehicle side harness, for example, in a space between the vehicle body and the trunk room or in the trunk room. By adopting such a configuration, there is little possibility of water or mud adhering to the harness connection part, and the air communication member 1603 at the end of the harness 600 on the vehicle connection side may be in contact with the outside air. it can.

  On the other hand, the harness of the electric brake device installed on the front wheels is connected to the vehicle-side harness in the engine room so that the distance of the harness is not increased. However, since there is a large amount of water or oil in the engine room, there is a possibility that the air hole through which the air of the air communication member passes is blocked by water or oil. Therefore, in the engine room, the connection portion between the end of the harness 600 on the vehicle connection side and the vehicle side harness is sealed so that water and outside air do not enter. An air communication member is used as a harness member routed to the column room in the vehicle side harness so that air can flow in and out from the electric brake device inside the column room.

According to the embodiment described above, in order to adjust the atmospheric pressure inside the electric brake device, the air filling the space inside the electric brake device is communicated with the outside air via the harness 600 including the air communication member 1603. be able to. Specifically, the air communication member 1603 is configured to be in contact with the air that fills the component mounting region 316 of the electric circuit unit 1251 shown in FIG.

  Furthermore, the space between the thrust plate 1421 and the I / F module 200 shown in FIG. 12A is formed through holes 110, 232, 106, and 222 formed in the I / F module 200 shown in FIG. Through this, the space between the I / F module 200 and the inner case 300 shown in FIG. Further, the space between the I / F module 200 and the inner case 300 shown in FIG. 5 is an electric circuit portion 1251 shown in FIG. 7 through the through holes 326a and 326b formed in the inner case 300 shown in FIG. Connected to the component mounting area 316. As described above, the spaces inside the electric brake device are connected to each other through the through holes, so that a local pressure change does not occur inside the electric brake device.

  Further, in order to make the operation of the rotation / linear motion conversion mechanism 1326 and the speed reducer 1321 smooth, lubricating oil is applied to these movable parts. This lubricating oil flows down due to secular change, accumulates in the lower part of the electric brake device, and may block a hole through which air flows in and out of the electric brake device.

  Therefore, in this embodiment, a plurality of through holes that connect a plurality of spaces inside the electric brake device are provided. Further, the position of the through hole is provided at a position away from the position where the lubricating oil is accumulated. For example, the through holes 110, 232, 106, and 222 are provided at positions farther from the ground than the positions where the lubricating oil is accumulated.

  Further, as in this embodiment, the interior of the electric brake device is partitioned by a plurality of spaces by the I / F module 200, and the through hole is provided at a position away from the position where the lubricating oil is accumulated, so that the lubricating oil is harnessed. The air communication member 1603 does not flow to 600, and the air communication member 1603 does not hinder the inflow and outflow of air.

  Furthermore, the air pressure adjusting function of the present embodiment causes the air inside the electric brake device to flow out to the outside, and the outside air to flow into the electric brake device. Therefore, air convection is generated inside the electric brake device. By this convection, it is possible to protect heat-sensitive components from the heat in the electric brake device.

For example, a heat-sensitive component in the electric brake device is an electronic component installed on the control circuit board 404. This electronic component is disposed in contact with the space between the I / F module 200 and the inner case 300 shown in FIG. Therefore, this electronic component can be cooled by air convection and protected from heat.

  Further, a method of an airtight test of the electric brake device using the above-described atmospheric pressure adjusting function will be described.

  Conventionally, for the airtight test of the electric brake device, a special opening that communicates with the space inside the electric brake device is provided in the electric brake device, and a tube for an airtight test is connected to the opening, or the electric brake device A tube for an airtight test was connected to an opening for harness connection. Then, immerse the electric brake device in a liquid such as water, and increase the air pressure inside the electric brake device by a pressure adjusting device such as a high-pressure pump connected to the tube for the airtightness test, and confirm whether the electric brake device is in a sealed state To do. In this case, even if the atmospheric pressure adjusting device shows a predetermined atmospheric pressure, it can be confirmed that the air-tightness is maintained if no bubbles are generated from the electric brake device.

  However, it is necessary to provide a special opening for the airtight test in the electric brake device or to connect a pipe for the airtight test to the opening, resulting in an increase in the number of man-hours for manufacturing and the number of airtight tests. .

  Therefore, as described with reference to FIG. 10, the outside air can be introduced into the electric brake device via the harness 600 including the air communication member 1603. And the atmospheric pressure adjustment apparatus 1800 is connected to the edge part of the harness 600, the atmospheric pressure inside an electric brake device is adjusted via the harness 600, and the above-mentioned airtight test is implemented.

  By adopting such a configuration, it is not necessary to provide a special opening for the airtight test in the electric brake device or to connect a pipe for the airtight test to the opening, and the man-hours for manufacturing and the air-tightness test are eliminated. Can be suppressed. Furthermore, the harness 600 as well as the electric brake device 1201 can be soaked in water for an air tightness test, and it can be confirmed before shipping that the covering member 1602 of the harness 600 is broken.

  In the present embodiment, an air pressure adjusting function of the mechanism unit 1706 will be described in an electric brake device having a configuration in which the mechanism unit 1706 is installed under the spring and an electric circuit unit for controlling the mechanism unit is installed inside the vehicle body.

  FIG. 17 (a) is a cross-sectional view of a specific internal configuration of the electric brake device according to the second embodiment of the present invention, and FIG. 17 (b) is viewed from the direction α in FIG. 17 (a). It is sectional drawing of an internal structure. 17 having the same reference numerals as those in FIG. 1 have the same functions as the corresponding components in FIG. 1 in the first embodiment, and the description thereof will be omitted.

  The difference between the first embodiment and the second embodiment is that harnesses 1704 and 1705 having an air communication member are directly connected to the mechanism unit 1706. With such a configuration, it is possible to adjust the atmospheric pressure in the mechanism unit 1706 installed under the unsprung environment, which is an environment where the atmospheric pressure changes drastically.

  Further, two harnesses 1704 and 1705 are provided. In this embodiment, the harness 1704 is a power line for supplying power to the motor, and the harness 1705 is a signal line for transmitting and receiving control signals to and from an electric circuit unit installed in the vehicle body. Thus, when connecting the some harness 1704 and 1705 to a mechanism part, you may make it use an air communication member only for either one harness.

The sectional view of the concrete internal configuration of the electric brake device which constitutes one example of the present invention is shown. 1 is a schematic configuration diagram of a vehicle brake system equipped with an electric brake device according to an embodiment of the present invention. The conceptual diagram of the electric brake device of FIG. 2 is shown. The circuit block diagram of the electric brake device of FIG. 2 is shown. The disassembled perspective view of each structural member in the electric circuit part of the electric brake device of FIG. 1 is shown. The block diagram of the outer case of the electric brake device of FIG. 5 is shown. The block diagram of the inner case of the electric brake device of FIG. 5 is shown. FIG. 6 shows an assembly process diagram of the outer case and the inner case of FIG. 5. FIG. 6 is a process diagram for mounting electronic components on the inner case of FIG. 5. The block diagram of the harness which makes one Example of this invention is shown. The process figure at the time of attaching a harness to the inner case of FIG. 5 is shown. The block diagram of the I / F module of FIG. 5 is shown. The block diagram of the mechanism part to which the I / F module of FIG. 5 was attached is shown. The assembly process drawing of the assembly which consists of an assembly which integrates a mechanism part and an I / F module, and an assembly which integrates an inner case, an outer case, and a harness is shown. It is the perspective view which looked at one Example of the attachment structure of the harness with respect to an outer case from the harness side. The block diagram of the harness which makes one Example of this invention is shown. The specific internal block diagram of the electric brake device which makes one Example of this invention is shown. The schematic of the electric brake device airtight test method which makes one Example of this invention is shown.

Explanation of symbols

305b Through-hole 305s Ring-shaped seal 600 Harness 1201 Electric brake device 1231 Disc rotor 1301 Cases 1306 and 1307 Brake pad 1311 Electric motor 1326 Rotation linear motion conversion mechanism 1331 Moving member 1340 Seal member 1603 Air communication member

Claims (19)

A brake pad that presses the disc rotor that rotates with the wheels;
A motor that generates rotational torque;
A rotary linear motion conversion mechanism that converts the rotational motion of the rotational torque into a linear motion;
A moving member that moves the brake pad based on a linear motion by the rotation / linear motion conversion mechanism;
A harness connected to the internal equipment of the car body,
A housing having a space for housing the motor and the rotation / linear motion conversion mechanism, a first hole portion for allowing the moving member to slide, and a second hole portion for inserting the harness;
A first seal member that seals a gap between the first hole and the moving member;
A second seal member that seals a gap between the second hole and the harness;
With
The harness is an electric brake device having an air communication member that communicates air inside the housing and outside air. The electric brake device according to claim 1,
The motor is a three-phase motor;
The harness includes a power supply line of a three-phase motor,
The electric power supply line is an electric brake device that connects the three-phase motor and an inverter installed in a vehicle body. The electric brake device according to claim 1,
An electric brake is provided such that an air communication member is exposed at both ends of the harness, one end of the harness is installed in the space of the housing, and the other end is in contact with outside air. apparatus. The electric brake device according to claim 1,
One end of the harness is installed in the space of the housing, and the other end of the harness is installed in a space between a vehicle body and a trunk room. The electric brake device according to claim 1,
One end of the harness is installed in the space of the housing, and the other end of the harness is installed in a space in a trunk room. The electric brake device according to claim 1,
The harness includes a signal line for transmitting and receiving a signal for controlling the motor,
The electric brake device, wherein the signal line is covered with the air communication member. The electric brake device according to claim 1,
A plurality of the harnesses are provided,
The housing includes the plurality of second holes for inserting the plurality of harnesses,
The plurality of second seal members that seal gaps between the plurality of second holes of the housing and the plurality of inserted harnesses, and
An electric brake device including a power line in which at least one of the plurality of harnesses supplies power to the motor. An airtight detection method for an electric brake device according to claim 1,
The atmospheric pressure adjustment device adjusts the atmospheric pressure inside the housing to a predetermined atmospheric pressure via the harness,
An airtightness detection method for an electric brake device that determines that the airtightness of the casing is maintained when the predetermined atmospheric pressure is within a predetermined change range for a predetermined time. A brake pad that presses the disc rotor that rotates with the wheels;
A motor that generates rotational torque;
A rotation / linear motion conversion mechanism for converting the rotational motion of the motor into linear motion;
A moving member that moves the brake pad based on a linear motion by the rotation / linear motion conversion mechanism;
Electronic components for controlling the rotational torque of the motor;
A harness connected to the internal equipment of the car body,
A first space for housing the motor and the rotation / linear motion conversion mechanism; a second space for housing the electronic component; located on the opposite side of the first space to the brake pad; and the movement A first hole that allows the member to slide, and a housing having a second hole for inserting the harness;
A first seal member that seals a gap between the first hole and the moving member;
A second seal member that seals a gap between the second hole and the harness;
With
The harness is an electric brake device having an air communication member that communicates air inside the housing and outside air. The electric brake device according to claim 9,
An electric brake device in which an air communication member is exposed at both ends of the harness, one end of the harness is installed in the second space, and the other end is installed in contact with outside air. The electric brake device according to claim 9,
The housing includes a first fixing portion that fixes the harness to the second hole, and a second fixing portion that fixes the harness to the housing and is spaced apart from the first fixing portion. An electric brake device including a fixing portion. An airtight detection method for an electric brake device according to claim 9,
The atmospheric pressure adjustment device adjusts the atmospheric pressure inside the housing to a predetermined atmospheric pressure via the harness,
An airtightness detection method for an electric brake device that determines that the airtightness of the casing is maintained when the predetermined atmospheric pressure is within a predetermined change range for a predetermined time. A brake pad that presses the disc rotor that rotates with the wheels;
A motor that generates rotational torque;
A rotation / linear motion conversion mechanism for converting the rotational motion of the motor into linear motion;
A moving member that moves the brake pad based on a linear motion by the rotation / linear motion conversion mechanism;
A control circuit board for controlling the rotational torque of the motor;
A harness connected to the internal equipment of the car body,
A first space for accommodating the motor and the rotation / linear motion converting mechanism, a second space for accommodating the control circuit board, a first hole for allowing the moving member to slide, and a first space for inserting the harness. A housing having two holes;
A first seal member that seals a gap between the first hole and the moving member;
A second seal member that seals a gap between the second hole and the harness;
A resin plate provided between the first space and the second space, the resin plate having a hollow hole communicating the first space and the second space;
With
The harness is an electric brake device having an air communication member that communicates air inside the housing and outside air. The electric brake device according to claim 13,
An electric brake in which an air communication member is exposed at both ends of the harness, one end of the harness is installed in the second space, and the other end is installed in contact with outside air. apparatus. The electric brake device according to claim 13,
The power supply line of the motor is inserted into the hollow hole of the resin plate, and communicates the first space and the second space through a gap between the hollow hole and the power supply line. Electric brake device. The electric brake device according to claim 13,
The control circuit board is an electric brake device in which an electronic circuit mounting surface of the control circuit board is disposed so as to face the resin plate, and an air layer is provided between the mounting surface and the resin plate. The electric brake device according to claim 13,
The housing includes a first fixing portion that fixes the harness to the second hole, and a second fixing portion that fixes the harness to the housing and is spaced apart from the first fixing portion. An electric brake device including a fixing portion. The electric brake device according to claim 13,
The control circuit board includes a power module having an inverter element that converts a direct current into an alternating current,
The resin plate is an electric brake device that fixes a power supply line that connects the power module and the motor. An airtight detection method for an electric brake device according to claim 13,
The atmospheric pressure adjustment device adjusts the atmospheric pressure inside the housing to a predetermined atmospheric pressure via the harness,
An airtightness detection method for an electric brake device that determines that the airtightness of the casing is maintained when the predetermined atmospheric pressure is within a predetermined change range for a predetermined time.

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