KR20060055735A - Master cylinder for electro hydraulic brake - Google Patents

Abstract

The present invention realizes the performance of the EHB system that detects the driver's braking intention, and transmits the corresponding braking force from the hydraulic source to the wheel cylinder, and the flow path structure of the master cylinder can be changed reliably and accurately during the mode switching of the EHB system. It is a master cylinder for electric hydraulic brakes that not only makes the operator feel a better brake pedal, but also simplifies the process of machining the master cylinder bore, which transmits the pressure of the pedal pressed by the driver to the master cylinder. A first piston to control the flow of oil in the first piston; a second piston to be advanced by the forward operation of the first piston; and a flow of oil inside the second piston. A second valve for controlling and a first chamber configured to compress oil between the first piston and the second piston It is provided between the burr, the first piston and the second piston to compress the oil between the first spring for transmitting the operation of the first piston to the second piston and the inner wall of the second piston and the master cylinder. A second chamber installed between the second chamber and an inner wall of the second piston and the master cylinder to elastically support the second piston, a simulation chamber formed on an outer circumferential surface of the second piston, and an opening in the simulation chamber. A master cylinder comprising a simulator consisting of a simulation piston connected by and supported by an elastic force of a simulation spring, the master cylinder comprising: a center valve slidably provided at an inner center of the second piston and operated by advancing a second piston; By providing a further flow path formed in the second piston to communicate with the simulation chamber through the lower side of the center valve It is an invention that can be written.

Description

Master cylinder for electric hydraulic brakes {MASTER CYLINDER FOR ELECTRO HYDRAULIC BRAKE}             

Figure 1 is a longitudinal cross-sectional view showing a conventional master cylinder

Figure 2 is a longitudinal cross-sectional view showing a master cylinder of one embodiment by the present invention

Figure 3 is a longitudinal cross-sectional view showing a master cylinder of another embodiment according to the present invention

Explanation of symbols on the main parts of the drawings

100: master cylinder 200: first piston

210: first chamber 220: first spring

230: first valve 300, 301: second piston

310: second chamber 320: second spring

330: second valve 370: center valve

371: sealing surface 372, 382: sliding sealing element

373: crossing chamber 374: crossing member

375, 376, 377, 381: Euro 380: Center piston

383: center spring 390: support member                 

391: sealing element 400: simulator

410: simulation piston 420: simulation spring

430 simulation chamber

The present invention relates to a master cylinder for an electromagnetic hydraulic brake used for braking of an automobile.

In particular, it can realize the performance of the Electro Hydraulic Brake System (EHB) that senses the driver's braking intention and transfers the corresponding braking force from the hydraulic source to the wheel cylinder, and gives the driver a better feel of the brake pedal. It relates to a master cylinder for an electric hydraulic brake that can be produced.

In general, the EHB system detects the displacement of the brake pedal from the displacement sensor when the driver presses the brake pedal, closes the shutoff valve to separate the flow path between the master cylinder of the pedal simulator and the wheel, and the wheel in the ECU according to the pressure signal from the pressure sensor. By calculating the pressure, the pressure in the accumulator, which stores the hydraulic pressure generated by the motor pump, is adjusted by the independent feedback control using the solenoid valves of the inlet and outlet ports of each wheel.

At this time, when the EHB system breaks down, the shutoff valve is in the NO (Normally Open) state, so the hydraulic pressure of the master cylinder generated by the driver flows directly into the wheel cylinder. At this time, a pedal simulator is needed to detect the driver's willingness in the EHB system and to provide pedal reaction.

As shown in FIG. 1, the simulator 40 communicates with the master cylinder 10 through the opening 13, and the simulator 40 has a simulation piston 41 and a simulation piston 41. It includes a simulation spring 42 to elastically support the pedal feel composition by the repulsive force of the simulation spring 42 when the braking hydraulic pressure flows into the simulator (40).

In the conventional master cylinder 10 having the simulator 40 as described above, when the driver presses the brake pedal when the EHB system is in normal mode, the pressure is transmitted to the master cylinder 10 through the first piston 20. .

The pressure is transmitted to the second piston 30 by the first spring 22 supporting the first piston 20, and the movement of the first piston 20 and the second piston 30 is performed by the second chamber. The axial advancement continues until the flow path 35 between the 31 and the reservoir RESERVOIR is closed by the second valve 33.

At this time, the flow path (not shown) connected to each wheel cylinder (not shown) from the first chamber 21 and the second chamber 31 by the NO valve is closed so that there is no place for the brake fluid to flow out. The piston 20 and the second piston 30 are no longer advanced.

An interval greater than the distance between the second valve 33 and the sealing surface 34 mounted on the second piston 30 is formed between the cylinder bore step 11 and the sealing element 36, so that the first chamber The flow path 12 between the 21 and the simulation chamber 43 is maintained.

If the driver presses the pedal continuously, the first piston 20 continues to compress while compressing the first spring 22, and the brake fluid of the first chamber 21 is reduced by the bore step 11 and the sealing element. It flows into the simulation chamber 43 through the flow path 12 between 36, and makes the equilibrium between the hydraulic force in the simulation chamber 43, and the force of the simulation spring 42 which supports the simulation piston 41. As shown in FIG.

At this time, the force generated by the simulation spring 42 forms a pressure in the simulation chamber 43 and the first chamber 21, and thus the driver receives a pedal feeling similar to that of pressing the pedal of the conventional brake.

When the EHB system operates in the backup mode, the NO valves between the wheel cylinders connected to the first chamber 21 and the second chamber 31 remain open to brake the first chamber 21 and the second chamber 31. The liquid flows out to the wheel cylinder, and as the brake fluid of the second chamber 31 flows out to the wheel cylinder, the second piston 30 is advanced and the gap of the flow path 12 formed in the bore step portion 11 is reduced. The flow path 36 between the first chamber 21 and the second chamber 31 is closed at the moment when the stroke of the second piston 30 is increased.

Therefore, the master cylinder 10 operates in the same manner as the master cylinder applied to the conventional conventional brake, and the vehicle braking is performed by the pressure of the driver's brake pedal.

Grooves and bore steps 11 circumferentially generated in the cylinder bore of the prior art are difficult to shape, not easy to measure after machining, and in particular, seals with grooves and bore steps 11. Since the relative position between the elements 36 is not accurate, it is difficult to form a good pedal feel in the normal mode, and there is a problem that the pressure generation function may be degraded in the backup mode.

Accordingly, an object of the present invention is to solve the conventional problems, to realize the performance of the EHB system that detects the driver's braking intention, and transfers the corresponding braking force from the hydraulic source to the wheel cylinder, and the mode switching of the EHB system In addition to ensuring that the cylinder structure of the master cylinder can be changed reliably and accurately, it also provides the operator with a master cylinder for the electric hydraulic brake that creates a better feel of the brake pedal and simplifies the machining process of the master cylinder bore. have.

The object of the present invention is a first piston for transmitting the pressure of the pedal stepped by the driver to the master cylinder, a first valve for controlling the flow of oil inside the first piston, and forward by the forward operation of the first piston A second piston, a second valve controlling the flow of oil in the second piston, a first chamber configured to compress oil between the first piston and the second piston, and the first piston. A first spring installed between the piston and the second piston to transfer the motion of the first piston to the second piston, and a second chamber configured to compress oil between the second piston and the inner wall of the master cylinder; A second spring installed between the second piston and the inner wall of the master cylinder to elastically support the second piston, a simulation chamber formed on an outer circumferential surface of the second piston, and an opening in the simulation chamber. A master cylinder comprising a simulator consisting of a simulation piston connected by and supported by an elastic force of a simulation spring, the master cylinder comprising: a center valve slidably provided at an inner center of the second piston and operated by advancing the second piston; And a flow path formed in the second piston to communicate with the simulation chamber through the lower side of the center valve.

The center valve is operated in a state of being sealed by the sliding sealing element of the circumferential surface when operated by the forward operation of the second piston, it is characterized in that it is configured to close to the sealing surface by the operation to close the flow path .

The center valve may be formed in the second piston provided with the center valve to form a flow path that is formed at the front of the center valve and opened and closed by the center valve, and at the same time, a flow path connected to the crossing chamber provided at the rear of the center valve. When the pressure is characterized in that it is configured.

The center valve is characterized in that the hydraulic pressure acting on both sides of the center valve so that the center valve does not open in the state of blocking the flow path by making the diameter of the flow path provided on the front side smaller than the diameter of the crossing chamber provided on the back side. It is done.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 2, the simulator 400 communicates through the master cylinder 100 and the opening 130, and the simulator 400 operates the simulation piston 410 and the simulation piston 410. It includes a simulation spring 420 to support the elastic force of its own, so that when the braking hydraulic pressure flows into the simulator 400, the pedal feeling by the repulsive force of the simulation spring 420 is made possible.

In the master cylinder 100 having the simulator 400 as described above, when the driver presses the brake pedal when the EHB system is in normal mode, the pressure is transmitted to the master cylinder 100 through the first piston 200.

The pressure is transmitted to the second piston 300 by the first spring 220 supporting the first piston 200 provided with the first valve 230, the first piston 200 and the second spring. Movement of the second piston 300 under the elastic force of the 320 closes the flow path 350 between the second chamber 310 and the reservoir RESERVOIR by contacting the sealing surface 340 with the second valve 330. Axial advancement continues until

At this time, since the distance between the center valve 370 and the sealing surface 371 is greater than the distance between the second valve 330 and the sealing surface 340 toward the second chamber 310 and the second valve 330 Even though the sealing surface 340 is in contact with the flow path 350, the center valve 370 is not in contact with the sealing surface 371 so that the flow path 376 between the simulation chamber 430 and the first chamber 210 is closed. 377 is maintained, whereby the pressure of the driver's pedaling increases, the first piston 200 advances and is driven by the flow paths 376 and 377 between the center valve 370 and the sealing surface 371. The pedal feeling by 400 is transmitted to the driver.

Meanwhile, when the EHB system according to the present invention operates in the backup mode, the NO valve between the first chamber 210 and the second chamber 310 and each wheel cylinder is kept open so that the first chamber 210 and the second chamber are open. The brake fluid of 310 flows out to the wheel cylinder, and accordingly, the second piston 300 moves forward, and the first chamber 210 and the simulation chamber are brought into contact with the center valve 370 and the sealing surface 371. Since the flow paths 376 and 377 between the 430 are closed, the master cylinder 100 operates in the same manner as the master cylinder applied to the conventional conventional brake, and vehicle braking is performed by the pressure of the driver's pedal.

That is, since the center valve 370 is installed between the simulation chamber 430 and the first chamber 210 of the present invention, when the second piston 300 moves forward and the center valve 370 touches the sealing surface 371, the simulation is performed. The flow paths 376 and 377 between the chamber 430 and the first chamber 210 are closed.

As described above, the closing operation of the flow paths 376 and 377 may include a crossing chamber 373 formed by the first chamber 210 and the crossing member 374 connected to both sides of the center valve 370 to the flow path 375. By connecting, the center valve 370 having the sliding sealing element 372 slides smoothly without being affected by the hydraulic force, thereby smoothly opening and closing the flow paths 376 and 377.

At this time, the diameter of the crossing chamber 373 formed toward the rear side of the center valve 370 that opens and closes the flow paths 376 and 377 is larger than the diameter of the flow path 376 provided in front of the center valve 370. The center valve 370 maintains the stable flow paths 376 and 377 closed by the hydraulic force acting in the closing direction, and the master cylinder 100 is the same as the master cylinder applied to the conventional conventional brake. The vehicle can be braked and braked by the pressure of the driver's pedals.

3 is a longitudinal sectional view showing another embodiment of the present invention, a first piston for transmitting a pressure of a pedal stepped by a driver to a master cylinder, a first valve for controlling the flow of oil inside the first piston, The second piston is advanced by the forward operation of the first piston, the second valve for controlling the flow of oil in the interior of the second piston, so that the oil can be compressed between the first piston and the second piston Compresses oil between a first chamber to be provided, a first spring installed between the first piston and the second piston to transfer the motion of the first piston to the second piston, and an inner wall of the second piston and the master cylinder. A second chamber provided so as to be provided, a second spring installed between the second piston and an inner wall of the master cylinder to elastically support the second piston, and a simulation chamber formed on an outer circumferential surface of the second piston; A master cylinder comprising a simulator consisting of a simulation piston connected to an opening of the simulation chamber and supported by an elastic force of a simulation spring, the master cylinder being slidably provided at an inner center of the second piston to operate by advancing the second piston. A center piston, a flow path formed in the center of the center piston in an axial direction, and a flow path formed in the second piston to connect the simulation chamber and the first chamber together with the flow path of the center piston. do.                     

When the center piston is operated by the forward movement of the second piston, the center piston is operated in a state of being sealed by a sliding sealing element on the circumferential surface, and the tip of the center piston is in close contact with the sealing element provided on the support member by the operation. Characterized in that configured to close the.

The center piston is divided into two second pistons and inserted into the second piston of one side, and the center spring is inserted into the rear side, and the two second pistons separated from each other are forcibly fitted and fixed to the elastic force of the center spring. It characterized in that the line is made to be in close contact with the sealing element of the support member.

Another embodiment of the present invention is produced by dividing the second piston 300, 301 into two pieces for mounting the center piston 380, the center piston 380 and the center spring (Sliding sealing element 382 is provided) After assembling 383, the two pieces of the second pistons 300 and 301 are assembled by interference fitting to be integrated.

According to another embodiment of the present invention, the center piston 380 is spaced apart from the sealing element 391 provided in the support member 390 in an initial state, and the interval is the second valve (2) of the second chamber 310. 330 is larger than the interval formed by the sealing surface 340.

Therefore, when the EHB system operates in the normal mode, the pressure of the driver's pedal is transmitted through the first piston 200, and is transmitted to the second pistons 300 and 301 by the first spring 220 and the second chamber ( The flow path between the reservoir 310 and the reservoir is axially advanced until the second valve 330 is closed. At this time, the flow path between the second chamber 310 and the first chamber 210 and the respective wheel cylinders is closed by the NO valve so that there is no place for the brake fluid to flow out, and the second pistons 300 and 301 are no longer provided. The first chamber is formed between the end of the center piston 380 and the sealing element 391, which is greater than the distance between the second valve 330 toward the second chamber 310 and the sealing surface 340. The flow paths 302 and 381 between 210 and the simulation chamber 430 are maintained.

Subsequently, when the driver's step force increases, the first piston 200 is further advanced, and the brake fluid of the first chamber 210 flows into the simulation chamber 430 through the flow paths 302 and 381 to flow in the simulation chamber 430. A balance is established between the pressure and the force of the simulation spring 420 supporting the simulation piston 410.

At this time, the force generated by the simulation spring 420 forms pressure in the simulation chamber 430 and the first chamber 210, and forms a pedal feeling similar to the pedal feeling of the conventional brake to the driver, and the center piston 380. The opening and closing of the flow paths 302 and 381 may not only perform the opening and closing function of the flow path more precisely than the groove or bore stepped shape, but also form an improved pedal feeling through the accurate mode division of the master cylinder 100. And simplify the master cylinder bore machining process.

As described above, the present invention implements the performance of the EHB system that senses the driver's braking intention, and transmits the corresponding braking force from the hydraulic source to the wheel cylinder, and reliably and accurately the flow path structure of the master cylinder when switching modes of the EHB system. Not only does this change, but it also gives the operator the ability to create a better brake pedal feel and simplify the master cylinder bore machining process.

Claims (7)

A first piston that transmits the pressure of the pedal pedal of the driver to the master cylinder, a first valve that controls the flow of oil inside the first piston, a second piston that is advanced by the forward operation of the first piston, A second valve for controlling the flow of oil in the second piston, a first chamber configured to compress oil between the first piston and the second piston, and between the first piston and the second piston. A first spring installed at the first spring to transfer the motion of the first piston to the second piston, a second chamber provided to compress oil between the second piston and the inner wall of the master cylinder, and the second piston and the master A second spring installed between the inner walls of the cylinder to elastically support the second piston, a simulation chamber formed on an outer circumferential surface of the second piston, and connected to the simulation chamber by an opening and simulated In the master cylinder consisting of the simulator piston consisting of a simulation that is supported by the elastic force of the spring design, A center valve slidably provided at an inner center of the second piston and operated by advancing the second piston; And a flow path formed in the second piston to communicate with the simulation chamber through the lower side of the center valve. The method of claim 1, The center valve is operated in a state of being sealed by the sliding sealing element of the circumferential surface when the center valve is operated by the forward operation of the second piston, it is configured to be in close contact with the sealing surface by the operation to close the flow path Master cylinder for electric hydraulic brakes. The method of claim 1, The center valve may be formed in the second piston provided with the center valve to form a flow path that is formed at the front of the center valve and opened and closed by the center valve, and at the same time, a flow path connected to the crossing chamber provided at the rear of the center valve. An electric hydraulic brake master cylinder, characterized in that it is configured not to be subjected to pressure. The method of claim 1, The center valve is characterized in that the hydraulic pressure acting on both sides of the center valve differently configured so that the diameter of the flow path provided on the front side is smaller than the diameter of the crossing chamber provided on the rear side so that the center valve does not open in the state of blocking the flow path. A master cylinder for an electronic hydraulic brake. A first piston that transmits the pressure of the pedal pedal of the driver to the master cylinder, a first valve that controls the flow of oil inside the first piston, a second piston that is advanced by the forward operation of the first piston, A second valve for controlling the flow of oil in the second piston, a first chamber configured to compress oil between the first piston and the second piston, and between the first piston and the second piston. A first spring installed at the first spring to transfer the motion of the first piston to the second piston, a second chamber provided to compress oil between the second piston and the inner wall of the master cylinder, and the second piston and the master A second spring installed between the inner walls of the cylinder to elastically support the second piston, a simulation chamber formed on an outer circumferential surface of the second piston, and connected to the simulation chamber by an opening and simulated In the master cylinder it is configured in the simulator comprising a simulation piston which is supported by the elastic force of the spring design, A center piston slidably provided at an inner center of the second piston and operated by advancing the second piston; A channel formed in the center of the center piston in the axial direction; And a flow path formed in the second piston and configured to further connect a simulation chamber and the first chamber together with the flow path of the center piston. The method of claim 1, When the center piston is operated by the forward movement of the second piston, the center piston is operated in a state of being sealed by a sliding sealing element on the circumferential surface, and the tip of the center piston is in close contact with the sealing element provided on the support member by the operation. Master cylinder for an electric hydraulic brake, characterized in that configured to close the. The method of claim 1, The center piston is divided into two second pistons and inserted into the second piston of one side, and the center spring is inserted into the rear side, and the two second pistons separated from each other are forcibly fitted and fixed to the elastic force of the center spring. An electric hydraulic brake master cylinder, characterized in that configured to be in close contact with the sealing element of the support member.

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