KR100437216B1 - Brake oil pressure control system with pressure sensor for automobile - Google Patents

Abstract

The present invention relates to a brake hydraulic pressure control system for a vehicle equipped with a pressure sensor, the object of which is to improve the arrangement of the pressure sensor for detecting the brake hydraulic pressure generated in the master cylinder and to electrically connect it to the electronic control device stably, the master cylinder Is to make it common to each control system.

According to the brake hydraulic pressure control system for a vehicle equipped with a pressure sensor according to the present invention, the pressure sensor 80 for detecting the brake hydraulic pressure generated in the master cylinder 12 by the driver's brake pedal 10, the hydraulic block 60 The pressure sensor 80 and the circuit board 72 are electrically connected through the connecting device 90 when the electronic control device 70 is assembled. Therefore, the pressure sensor 80 is directly connected to the hydraulic block 60, so that the overall length of the master cylinder 12 is not long. As a result, the master cylinder 12 can be shared with each brake control system. The manufacturing cost can be reduced. In addition, since the pressure sensor 80 and the circuit board 72 are stably and easily electrically connected through the connecting device 90, there is an effect of improving the assembly workability thereof.

Description

Brake oil pressure control system with pressure sensor for automobile

The present invention relates to a vehicle brake hydraulic pressure control system, and more particularly to a vehicle brake hydraulic pressure control system having a pressure sensor for detecting the brake hydraulic pressure generated in the master cylinder side.

In general, a vehicle is equipped with a wheel brake for braking the front and rear wheels for the purpose of deceleration or stopping while driving, and a booster and a master cylinder for forming braking hydraulic pressure and transmitting it to the wheel brake side. The hydraulic pressure generated at is transferred to the wheel brake to generate a braking force. However, when the driver presses the brake pedal to control the braking force increase / hold state, if the braking pressure is greater than the road surface state, or if the frictional force of the wheel brake generated by the braking pressure is greater than the braking force generated from the tire or the road surface, the tire is Slipping occurs at the

Therefore, in recent years, to effectively prevent the slip phenomenon to exhibit a strong and stable braking force and to facilitate the operation, the anti-lock brake system (ABS) to prevent the slip of the wheel during braking, Brake Traction Control System (BTCS), which prevents excessive slippage of the drive wheel during sudden start or acceleration, and when the vehicle is not adjusted to the driver's will by external force during high speed driving of the vehicle. A brake hydraulic pressure control system has been developed with a vehicle dynamic control system (VDC) function that stably maintains the driving state by controlling the brake hydraulic pressure by combining an anti-lock brake system and traction control.

The brake hydraulic control system for vehicles equipped with this function has a hydraulic unit equipped with a plurality of solenoid valves, low pressure accumulators and high pressure accumulators, and electronically operated components for regulating braking hydraulic pressure delivered to the wheel brake side. It is equipped with an electronic control unit (ECU) for controlling.

The solenoid valve is divided into a NO type solenoid valve disposed upstream of the wheel brake and an NC type solenoid valve disposed downstream, and controlled by an electronic controller. That is, the electronic controller detects the vehicle speed through each wheel sensor disposed at the front wheel and the rear wheel, thereby controlling the opening and closing operation of each solenoid valve. In addition, the low pressure accumulator is independently provided on the downstream side of the NC type solenoid valve so that the oil escaping from the wheel brake side is temporarily stored in the decompression mode, and the high pressure accumulator is a type of damping chamber, which is arranged in series with the discharge side of the pump described later. .

In addition, the hydraulic block includes a solenoid valve, a medium pressure accumulator in which brake fluid is accumulated in addition to the low pressure and high pressure accumulator, a motor, a pump for forcibly pumping oil stored in the low pressure accumulator, and a brake hydraulic pressure discharged from the pump to the pump suction side. A flow path and the like for passing are provided. Since the medium pressure accumulator is disposed in the bypass flow path, the brake fluid discharged from the pump is accumulated and supplied to the pump side during the vehicle attitude control operation.

On the other hand, the master cylinder is disposed a pressure sensor for detecting the hydraulic pressure generated by the brake pedal pedal force of the driver delivered to the hydraulic block side, and transmits it as an electrical signal to the electronic control device. Accordingly, the electronic controller controls the additional operation of the pump and the opening / closing operation of each NC / NO solenoid valve based on the signal transmitted from the pressure sensor.

The conventional pressure sensor that performs this function is directly connected to extend in the axial direction to the front end of the master cylinder, it is electrically connected to the circuit board of the electronic control device through a separate wire connector.

Accordingly, in the conventional brake fluid control system for a vehicle, the overall length of the master cylinder is further extended due to the pressure sensor, and the pressure sensor and the electronic control device are electrically connected through a wire connector, which makes it difficult to install.

In addition, since master cylinders that are applied to anti-lock brake systems, brake traction systems, and vehicle attitude control systems are manufactured separately, pressure sensors are attached to them, so that parts of the master cylinders cannot be shared, and as a result, the overall brake hydraulic pressure control system There is a problem that the manufacturing cost of the rise.

The present invention is to solve this problem, an object of the present invention is to prevent the extension of the total length of the master cylinder by placing a pressure sensor on the hydraulic block side for detecting the brake hydraulic pressure generated in the master cylinder delivered to the hydraulic block side. It is to provide a brake hydraulic control system for vehicles with a pressure sensor that allows the master cylinder to be shared with each brake hydraulic control system.

Another object of the present invention is to provide a brake hydraulic pressure control system for a vehicle having a pressure sensor that can easily and stably electrically connect the circuit board and the pressure sensor of the electronic controller.

1 is a hydraulic system diagram of a brake hydraulic pressure control system for a vehicle to which the present invention is applied.

2 is a block diagram of a brake hydraulic pressure control system for a vehicle according to the present invention.

Figure 3 shows a pressure sensor arrangement of the brake hydraulic pressure control system for a vehicle according to the present invention.

Figure 4 is an exploded view showing the pressure sensor assembly structure according to the present invention.

* Description of the symbols for the main parts of the drawings *

12. Master cylinder 20a, 20b. Solenoid valve

40.Motor 41.Pump

60. Hydraulic block 61. Mounting port

70. Electronic control device 72. Circuit board

80. Pressure sensor 82. Mounting part

90. Connecting device 91. Mail connector

92. Female connector 91a, 92a ..

The present invention for achieving this object is;

A master cylinder that forms brake hydraulic pressure according to the operation of the brake pedal, a brake hydraulic pressure formed in the master cylinder flows in, a hydraulic block having a built-in pump for sucking the brake fluid and pumping it to the wheel brake side, and a wheel brake mounted on the hydraulic block A plurality of solenoid valves for adjusting the brake hydraulic pressure delivered to the side, a circuit board is built to control the operation of the solenoid valve and the pump, the electronic control unit assembled with the hydraulic block, and connected to the circuit board of the electronic control unit master cylinder In the vehicle brake hydraulic pressure control system having a pressure sensor for detecting the brake hydraulic pressure formed in the,

One end of the pressure sensor is mounted on the hydraulic block so as to communicate with the flow path of the brake hydraulic pressure generated in the master cylinder,

A connecting device is provided between the other end of the pressure sensor and the circuit board to electrically connect them.

The connecting device is provided at the other end of the pressure sensor and is provided in a cylindrical shape such that a male connector having an annular first terminal disposed on an outer circumference thereof and a male connector is inserted into a circuit board corresponding to the pressure sensor. It is a configuration characterized in that it comprises a female connector provided with a second terminal in the inner circumference.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. 1 and 2 is a hydraulic system diagram showing a brake hydraulic pressure control system for a vehicle according to the present invention, Figures 3 and 4 is an extract showing the pressure sensor assembly and connection structure according to the present invention.

1 and 2, the vehicle brake hydraulic pressure control system according to the present invention is a hydraulic block (60, HU (Hydraulic Unit), and a solenoid valve in which the solenoid valve 20a (20b) and the pump 41, etc. are built) (20a, 20b) and electronic control unit 70 (ECU) incorporating a circuit board 72 for electrically controlling driving of the pump 41 and the like, and the front wheel FR and the rear wheel of the vehicle ( RR (RL) is disposed and is provided with a wheel sensor 15 for sensing the wheel speed to transmit an electrical signal to the electronic control device (70).

The hydraulic block 60 is made of aluminum, and therein, a plurality of solenoid valves for adjusting brake hydraulic pressure transmitted to the wheel brakes 14 installed at the front wheel FR and the rear wheel RR. 20a) and 20b, a pair of low pressure accumulators 30 temporarily storing the oil escaping from the wheel brake 14 side during the decompression braking operation, and oil stored in the low pressure accumulator 30 during the boosting and maintaining braking operation. A motor 40 which drives a pair of pumps 41 to pump the pumps, and a pair of directly connected to the discharge side of each pump 41 to reduce pressure pulsation of oil pressurized and discharged by driving the pump 41. A high pressure accumulator 31 and a medium pressure accumulator 32 or the like in which the brake fluid discharged from the pump 41 is accumulated are compactly installed.

The plurality of solenoid valves 20a and 20b are connected to the upstream side and the downstream side of the wheel brake 14, and are normally open solenoid valves 20a (hereinafter, NO-type solenoids) disposed on the upstream side and kept open in a normal state. Valves), and normally closed solenoid valves 20b (hereinafter referred to as NC solenoid valves) which are arranged downstream and are normally kept closed. The opening and closing operations of the solenoid valves 20a and 20b are respectively controlled by the electronic controller 70 which detects the vehicle speed through the wheel sensor 15, and the NC-type solenoid valve 20b is controlled by the decompression braking action. The oil that is opened and exited from the wheel brake 14 side is temporarily stored in the low pressure accumulator 30.

The pair of pumps 41 have a predetermined phase difference by the motor 40 and are simultaneously driven to discharge oil stored in the low pressure accumulator 30 to the pressurized high pressure accumulator 31, and the oil introduced into the high pressure accumulator 31. The pressure pulsation is reduced while being delivered to the wheel brake 14 side again along the hydraulic line or returned to the master cylinder 12.

In addition, the hydraulic block 60 is provided with a master cylinder 12 having an oil storage tank 13 and a first flow passage 51 connecting the discharge side of the pump 41 to the NO-type solenoid valve 51a. Is additionally installed. The NO-type solenoid valve 51a is normally maintained in an open state so that the brake hydraulic pressure generated in the booster 11 and the master cylinder 12 passes during the normal braking action through the brake pedal 10, and the brake described later. It is closed by the electronic controller 70 during the traction control and the vehicle attitude control operation.

In addition, a first relief valve 52a is installed in another second flow path 52 connecting between the discharge side of the pump 41 and the master cylinder 12, which is provided in the pump 41 during traction control or vehicle posture control. When the discharged brake fluid pressure rises more than necessary, the brake fluid is returned to the master cylinder 12 side. In addition, a third flow passage 53 connecting the master cylinder 12 and the pump 41 to the suction side thereof is provided, and an NO type electric shuttle valve 53a is additionally installed in the middle of the third flow passage 53.

In addition, a bypass flow passage 54 for bypassing the brake hydraulic pressure discharged from the pump 41 to the suction side thereof is provided, and a medium pressure accumulator 32 is provided in the bypass flow passage 54 to accumulate predetermined brake fluid. do. In addition, the NC-type solenoid valve which maintains the accumulated pressurized brake fluid on the downstream side of the medium pressure accumulator 32 and is opened during brake traction control or vehicle control to communicate the suction side of the medium pressure accumulator 32 and the pump 41 ( 54b). In addition, a second relief valve 54a is provided on the upstream side of the medium pressure accumulator 32 for returning the brake hydraulic pressure discharged from the pump 41 to the medium pressure accumulator 32 side when it rises above a predetermined pressure required for control. . Further, the first flow path 51, the second flow path 52, the third flow path 52, the bypass flow path 54, and the like are formed in the hydraulic block 60 through a drilling process or the like.

In addition, the electronic controller 70 (ECU) is made of a plastic injection molding to form a housing body 71, and is disposed in the housing 71 and electrically connected to each solenoid valve 20a, 20b, a motor 40, and the like. A circuit board 72 is connected and controls the driving thereof, and is assembled to the hydraulic block 60 by a mounting bolt.

On the other hand, the electronic control device 70 detects the brake hydraulic pressure generated in the master cylinder 12 through the pressure sensor 80, each of the solenoid valve 20a during the anti-lock brake control, brake traction control and vehicle attitude control operation It is programmed in the circuit board 72 to control the opening and closing operation of the 20b and the additional operation of the motor 40, the arrangement of the pressure sensor 80 according to the present invention with reference to FIGS. The connection structure is as follows.

First, the mounting port 61 is processed on one side of the hydraulic block 60 so that the pressure sensor 80 is mounted. The mounting port 61 is formed by processing the side of the hydraulic block 60, and the bottom thereof has the brake hydraulic pressure generated from the master cylinder 12 by the driver's brake pedal 10 pedal force toward the hydraulic block 60 side. It is in communication with the first flow path 51 introduced. In addition, a female screw 61a is processed on the inner circumference of the mounting port 61 so as to be engaged with the mounting portion 82 described later.

In addition, the pressure sensor 80 includes a body 81 through which the brake hydraulic pressure is transmitted and sensed, a mounting portion 82 provided at one end of the body 81 and coupled to the mounting port 61, and electronically controlled. And a connecting device 90 in electrical connection with the device 70.

A male screw 82a is provided on the outer circumference of the mounting portion 82 so that the outer circumference is tabbed to the mounting port 61, and a pressure transfer passage 82b is formed in the mounting portion 82 in the axial direction.

In addition, the connecting device 90 has a male connector 91 provided to extend in the axial direction at the other end of the pressure sensor body 81 and a male connector 91 on the circuit board 72 side so that the male connector 91 is inserted and connected. It includes a female connector 92 provided. The male connector 91 is configured to protrude in a rod shape, and an annular first terminal 91a is provided on the outer circumference thereof. The first terminal (91a) is composed of three, it is arranged on the outer periphery of the male connector 91 spaced apart at regular intervals, respectively. And the female connector 92 is provided in a cylindrical shape on one side of the circuit board 72 corresponding to the pressure sensor 80, the male connector 91 is fitted to be coupled thereto. On the inner circumference of the cylindrical female connector 92, three second terminals 92a are arranged at the same interval as the first terminal 91a, which is connected to the circuit board 72 through the inserted lead wire 92b. Electrical connection with the

Therefore, when the mounting portion 82 is coupled to the mounting port 61 in a two-membered manner, the body 81 of the pressure sensor 80 is directly fastened to the side of the hydraulic block 60 and at the same time the pressure transmission with the first flow path 51. As the flow path 82b is linked, the brake hydraulic pressure is transferred into the body 81 of the pressure sensor 80 so as to sense the pressure thereof.

Subsequently, after pre-assembling the housing 71 of the electronic control device 70 to the side of the hydraulic block 60, tightening the mounting bolt, the hydraulic block 60 and the electronic control device 70 is firmly assembled.

At this time, the mail terminal 91 protruding from the body 81 of the pressure sensor 80 is inserted into the female terminal 92 and at the same time the first terminal 91a and the second terminal 92a come into contact with each other. By being connected to each other, they are stably connected without a separate connecting member such as a wire connector. In addition, since the entirety of the male terminal 91 is fitted into the cylindrical female terminal 92, the assembly is made easier even if the assembly position of the pressure sensor 80 is slightly changed due to manufacturing tolerances.

In addition, the electronic controller 70 senses a brake hydraulic pressure generated in the master cylinder 12 through an electrical signal transmitted from the pressure sensor 80, and based on this, opening and closing of each solenoid valve 20a and 20b. Operation and further operation of the pump 41 are controlled through the motor 40.

As described in detail above, according to the brake pressure control system for a vehicle equipped with a pressure sensor according to the present invention, a pressure sensor for detecting the brake hydraulic pressure generated in the master cylinder by the driver's brake pedal effort is mounted directly on the side of the hydraulic block. When the electronic controller is assembled, the pressure sensor and the circuit board are electrically connected through the connecting device. Therefore, the pressure sensor is directly connected to the hydraulic block, so that the overall length of the master cylinder is not long, and thus the master cylinder can be shared with each brake control system, thereby reducing the overall manufacturing cost of the brake hydraulic control system. In addition, since the pressure sensor and the circuit board are stably and easily electrically connected through the connecting device, there is an effect of improving the assembly workability thereof.

Claims (1)

The hydraulic cylinder is built in the master cylinder for forming the brake hydraulic pressure in accordance with the operation of the brake pedal, the brake hydraulic pressure formed in the master cylinder is introduced and a pump for sucking the brake fluid to pump to the wheel brake side, and is mounted on the hydraulic block A plurality of solenoid valves for adjusting the brake hydraulic pressure delivered to the wheel brake side, an electronic control device having a circuit board embedded therein and assembled with the hydraulic block to control driving of the solenoid valve and the pump, and a circuit of the electronic control device In a vehicle brake hydraulic pressure control system having a pressure sensor connected to the substrate and detects the brake hydraulic pressure formed in the master cylinder, One end of the pressure sensor 80 is mounted to the hydraulic block 60 so as to communicate with the flow path 51 through which the brake hydraulic pressure generated in the master cylinder 12 is transmitted. A connecting device 90 is provided between the other end of the pressure sensor 80 and the circuit board 72 to electrically connect them. The connecting device (90) is; The mail connector 91 provided at the other end of the pressure sensor 80 and having an annular first terminal 91a disposed at an outer circumference thereof, and the circuit board 72 corresponding to the pressure sensor 80 may be mounted on the mail connector 91. It is provided with a pressure sensor, characterized in that it comprises a female connector 92 is provided in a cylindrical shape so that the connector 91 is inserted and the second terminal 92a is provided on the inner circumference so as to be electrically connected to the first terminal 91a. Automotive brake hydraulic pressure control system.