KR20110125289A - Hydraulic pump for electronic control brake system - Google Patents

Abstract

PURPOSE: A hydraulic pump for an electronic control brake system is provided to improve the assembling by removing a separate component for fixing a discharging ball and a supporting spring. CONSTITUTION: A hydraulic pump for an electronic control brake system comprises a bore(120) and a component unit. The bore is formed in a modulator block and is communicated with a suction port and an outlet port. In order to press the fluid of the suction port and discharge to the outlet port, a component unit is installed in the bore. The component unit is installed in the bore in order to reciprocate. The component unit comprises a piston, a suction valve portion(140) and a discharging valve portion(150). According to the location of the piston, the suction valve portion switches the outlet portion of the suction flow passage. The discharge valve portion is included in one side of the bore. The discharging valve portion comprises a valve sheet(151), a pump cap, a discharging ball(152) and a pulsation decreasing member.

Description

Hydraulic pump for electronic control brake system

The present invention relates to a hydraulic pump for an electronically controlled brake system, and more particularly to an hydraulic pump for an electronically controlled brake system provided to effectively reduce the pulsation of the fluid while simplifying the assembly process.

In general, the electronically controlled brake system is for effectively preventing slip phenomenon that may occur during braking, rapid start, or rapid acceleration of the vehicle. As illustrated in FIG. 1, the braking transmitted to the hydraulic brake 1 side of the vehicle wheel is shown. A plurality of solenoid valves 2a and 2b for controlling the hydraulic pressure, a pair of low pressure accumulators 3 and 4 for storing the fluid discharged from the hydraulic brake 1 temporarily, and a low pressure accumulator 3; And a pair of hydraulic pumps 6 provided between the high-pressure accumulator 4 and driven by the motor 5, an ECU for controlling the driving of the solenoid valves 2a and 2b and the motor 5 (not shown). It includes, these components are embedded in the modulator block (10).

The pair of hydraulic pumps 6 serves to pump the low pressure fluid on the low pressure accumulator 3 side to the high pressure accumulator 4 to deliver the hydraulic pressure to the hydraulic brake 1 or the master cylinder 7.

As shown in FIG. 2, the conventional hydraulic pump A employed in the electronically controlled brake system includes a suction port 21 connected to the low pressure accumulator 3 side and a discharge port 22 connected to the high pressure accumulator 4 side. The bore 20 is formed to be open to the modulator block 10 in the transverse direction so as to pass through, and a component unit installed inside the bore 20 to pressurize the fluid on the suction port 21 side and pump it to the discharge port 22 side. Equipped.

Referring to the configuration unit installed in the bore 20 as follows.

First, the piston 30 is disposed inside the bore 20 to be in contact with the spindle 5a of the motor 5 through one end of the bore 20 so as to be capable of linear reciprocating movement from side to side. The valve seat 40 for forming the pressure chamber 41 is disposed at the front end side of the piston 30, and the piston 30 is moved forward to pressurize the fluid in the pressure chamber 41 inside the valve seat 40. Return spring 50 is installed to return.

The piston 30 is installed to be supported by the bore 20 through a sealing housing 60 provided around one outer circumference, and the valve seat 40 is coupled to the sealing housing 60 and fixed to the front end side of the piston 30. .

A suction flow path 31 is formed inside the piston 30 to allow the fluid of the suction port 21 to flow into the pressure chamber 41, and the valve seat 40 is formed in the pressure chamber 41. A discharge passage 42 is formed to guide the pressurized fluid toward the discharge port 22. An outlet valve 70 is installed at the tip of the valve seat 40 to open and close the discharge passage 42. An inlet valve 80 for opening and closing the suction flow path 31 is provided at the tip of the piston 30 at which the outlet of the 31 is formed while operating opposite to the outlet valve 70 according to the reciprocating motion of the piston 30. . The outlet plate 90 is coupled to the periphery of the front end of the valve seat 40 for fixing the outlet valve 70, and a communication hole 91 is formed in the outlet plate 90 to communicate with the discharge port 22. .

Therefore, the hydraulic pump (A) is inserted into the bore 20 in a state in which the valve seat 40 coupled to the outlet plate 90 is coupled to the sealing housing 60 and connected to the piston 30, and in this state. The other end of the bore 20 is assembled to the modulator block 10 by coupling the pump cap 95 for blocking the bore 20 from the outside.

In the conventional hydraulic pump A configured as described above, the piston 30 linearly reciprocates by the spindle 5a of the motor 5 which rotates eccentrically, and the inlet valve 80 according to the pressure change in the bore 20. ) And the outlet valve 70 are opened and closed opposite to each other, so that the fluid of the suction port 21 is introduced into the pressure chamber 41 and then pressurized to pump the discharge port 22.

However, the conventional hydraulic pump (A) configured as described above has a long time to assemble the hydraulic pump (A) as the operation of fixing the outlet plate (90) provided to fix the outlet valve (70) to the valve seat (40) is added. There was a problem.

In addition, as described above, in the conventional hydraulic pump (A), the fluid in the pressure chamber 41 exits the communication hole 91 of the outlet plate 90 and is immediately discharged to the discharge port 22. In the structure in which the fluid pressurized in the chamber 41 is quickly discharged to the discharge port 22, the pressure pulsation of the fluid cannot be effectively reduced, so that a large operation noise is often caused during the discharge of the fluid.

The present invention is to solve this problem, it is an object of the present invention to provide a hydraulic pump for an electronically controlled brake system provided to effectively reduce the pressure pulsation of the fluid while the assembly process is simplified.

In order to solve this problem, the hydraulic pump for an electronically controlled brake system according to the present invention is formed in a modulator block and communicates with a suction port and a discharge port, and pressurizes a fluid on the suction port side to discharge to the discharge port side. And a component unit to be installed, wherein the component unit is reciprocally installed in the bore and has a suction channel formed therein, and a suction valve part for opening and closing an outlet side of the suction channel according to the position of the piston; It is provided on one side of the bore includes a discharge valve portion that operates in opposition to the intake valve portion in accordance with the operation of the piston, the discharge valve portion and the valve seat having a discharge passage, and the valve to block the bore from the outside A pump cap coupled to the valve seat to surround the seat end, and to open and close the discharge flow path And a discharge ball provided between the valve seat and the pump cap, and a pulsation reducing member provided between the valve seat and the pump cap around the discharge ball to reduce pulsation of the fluid.

The pulsation reducing member is provided in a ring shape, one end connecting between the inner diameter and the outer diameter of the pulsating reducing member is provided to be in close contact with the valve seat, and the pump cap is supported in close contact with the inner diameter of the pulsating reducing member. An inner diameter support provided to support the other end connecting the inner and outer diameters of the pulsation reducing member in close contact with each other, and the inner diameter and end of the pulsation reducing member corresponding to the inner diameter support and the end supporting portion. The side surface is characterized in that the bypass guide groove for guiding the bypass of the fluid to bypass the fluid discharged through the flow path of the valve seat along the surface of the pulsation reducing member during the opening operation of the discharge ball.

Between the valve seat and the inner diameter support portion is provided a first guide passage for guiding the fluid discharged through the flow path of the valve seat to the bypass guide groove during the opening operation of the discharge ball, the outer diameter of the pulsation reducing member and the A second guide passage for guiding the fluid of the bypass guide groove toward the discharge port is provided between the pump caps.

As described above, the hydraulic pump for an electronically controlled brake system according to the present invention includes a pump cap having a discharge ball for opening and closing the discharge flow path of the valve seat and a support spring for elastically supporting the discharge ball toward the discharge flow path. Since it can be fixed between the valve seat and the pump cap, the separate parts for fixing the discharge ball and the support spring is deleted to improve the assembly.

In the present invention, a pulsation reducing member is provided between the valve seat and the pump cap to reduce the pressure pulsation of the fluid by bypassing the fluid discharged through the discharge passage, and the pulsation reducing member is also coupled to the valve seat. In the process, it is fixed between the valve seat and the pump cap.

Therefore, according to the present invention, the pulsation of the fluid inside the hydraulic pump and thus the flow noise is reduced through the pulsation reducing member, which is simply assembled between the valve seat and the pump cap together with the discharge ball and the support spring.

1 is a hydraulic circuit diagram of a general electronically controlled brake system.
2 is a cross-sectional view showing the structure of a conventional hydraulic pump for an electronically controlled brake system.
3 is a cross-sectional view showing the structure of a hydraulic pump for an electronically controlled brake system according to an embodiment of the present invention.
4 is an enlarged cross-sectional view of the structure of the pulsation reducing member side in FIG.
FIG. 5 is a perspective view illustrating an pulsation reducing member in the hydraulic pump for an electronically controlled brake system according to an exemplary embodiment of the present invention.

Next will be described in detail the structure of the hydraulic pump for an electronically controlled brake system according to an embodiment of the present invention.

For reference, since the electronically controlled brake system has already been described above, the following reference numerals and names are used for the components related to the electronically controlled brake system.

In addition, the hydraulic pump B according to the embodiment is basically composed of a pair arranged to face each other around the spindle 5a of the motor 5, 180 by the eccentric rotation of the spindle 5a of the motor 5 The pumping operation is performed by the phase difference of FIG. Since the pair of hydraulic pumps B have the same structure, only the structure of one hydraulic pump B will be described below.

As shown in FIG. 3, the hydraulic pump B according to the present embodiment includes a bore 120 formed in the modulator block 10 and a configuration unit installed in the bore 120.

The constituent unit is inserted into the bore 120 by the spindle 5A of the motor 5 to reciprocate and has a suction passage 131 formed therein and a suction passage according to the position of the piston 130 ( Suction valve unit 140 for opening and closing the outlet side of the 131, and the discharge valve unit 150 is provided on the open end side of the bore 20 to operate opposite to the suction valve unit 140.

The modulator block 10 has a suction port 121 for communicating the inlet side of the suction passage 131 formed in the piston 130 with the low pressure accumulator 3 side, and the inlet side and the discharge valve portion of the high pressure accumulator 4. The discharge port 122 for communicating the outlet side of the 150 is formed.

One end of the piston 130 is provided to contact the spindle (5a) is to reciprocate in the bore 120 in accordance with the rotation of the spindle (5a). In addition, the suction valve 140 is installed at the other end of the piston 130, and around the piston 130 between both ends of the piston 130, a fluid is formed through the clearance between the outer circumference of the piston 130 and the inner wall of the bore 120. The seal 123 is installed to prevent the leakage. In addition, a filter for fixing a filter 124 and a filter 124 for filtering the fluid flowing into the suction channel 131 from the suction port 121 on the outer circumference of the inlet side piston 130 of the suction channel 131. The housing 125 is installed.

The suction valve 140 is a suction ball 141, a support spring 142 for supporting the suction ball 141, and a spring fixing member 143 for fixing the suction ball 141 and the support spring 142. It is configured to include.

The suction ball 141 is provided at the outlet side end of the suction passage 131 of the piston 130 to open and close the suction passage 131, the spring fixing member 143 is the piston 130 at the outlet side of the suction passage 131. It is coupled to the stepped portion provided in the outer diameter, the support spring 142 is disposed so that both ends are supported by the spring fixing member 143 and the suction ball 141 so that the suction ball 141 is in close contact with the suction passage 131. Elastic support. The communication hole 143a is provided at the end of the spring fixing member 143.

The discharge valve unit 150 provided at the open end of the bore 20 may include a valve seat 151 in which the discharge passage 151a is provided, and a discharge ball for opening and closing the discharge passage 151a of the valve seat 151. 152 and the pump cap 153 is provided to fix the discharge ball 152 to the valve seat 151 and at the same time block the bore 120 from the outside.

The valve seat 151 is disposed to surround the spring fixing member 143 so that the pressurizing chamber 151b for pressurizing the fluid is formed therein, and the discharge passage 151a is located at the end center side of the valve seat 151. Prepared.

The piston 130 is installed to be supported on the inner wall of the bore 120 through a sealing housing 161 provided around one outer circumference, and the valve seat 151 has an outer diameter at an end opposite to the discharge passage 151a. It is coupled to be pressed into the inner diameter can be fixed to the front end side of the piston (130). In the valve seat 151, a return spring 162 exerting an elastic force to push the piston 130 toward the spindle 5a is provided.

In addition, the discharge valve unit 150 includes a support spring 154 for elastically supporting the discharge ball 152 to be in close contact with the discharge flow path 151a, the support spring 154 and the discharge ball 152 is a bore ( It is fixed between the pump cap 153 and the valve seat 151 through the pump cap 153 coupled to the open end of the 120.

One end of the pump cap 153 corresponding to the valve seat 151 is provided with a coupling portion 153a which is press-fitted to the valve seat 151 so as to surround the outer periphery of the valve seat 151, and the discharge ball 152. And the support spring 154 is fixed between the valve seat 151 and the pump cap 153 in the process of coupling the pump cap 153 to the valve seat 151 through the coupling portion 153a. An accommodating groove 153b for accommodating the support spring 154 is formed at the center of the end of the pump cap 153 toward the valve seat 151. It is pressed into the inner wall to block the bore 120 from the outside. When the discharge passage 151a is opened, the fluid discharged from the discharge passage 151a is guided toward the discharge port 122 through the valve seat 151 and the pump cap 153.

Therefore, the hydraulic pump (B) configured as described above can be fixed to the discharge ball and the support spring using the pump cap, the separate parts for the fixing of the discharge ball and the support spring is deleted to improve the assembly.

In addition, the hydraulic pump (B) and the piston seat 130 and the valve seat 151 in such a way to couple the valve seat 151, the sealing cap 153 is coupled to the piston 130 through the sealing housing 161 It is possible to assemble the sealing cap 153 to form a body from the outside of the bore 120, the bore 120 and the valve seat 151 and the sealing cap 153 provided to form a mutual body as described above (120) When inserted into the sealing cap 153, the outer diameter of the bore 120 is pressed into the inner wall of the open end, so the installation of the hydraulic pump (B) is completed, according to this embodiment the installation work of the hydraulic pump (B) is also faster Can be done.

In addition, in the hydraulic pump according to the present embodiment, the discharge valve unit 150 is for reducing the pulsation of the fluid inside the oil pump (B), the valve seat 151 and the pump cap around the discharge ball 152 It further comprises a ring-shaped pulsation reducing member 170 provided between (153).

4 and 5 together, one end connecting between the inner diameter and the outer diameter of the pulsation reducing member 170 is supported to be in close contact with the valve seat 151 around the outlet of the discharge passage 151a, and the receiving groove 153b. At the end of the sealing cap 153, an insertion groove 153c for insertion of the pulsation reducing member 170 is provided.

In the sealing cap 153, an inner diameter support portion 153d is formed between the insertion groove 153c and the accommodation groove 153a to support the inner diameter of the pulsation reducing member 170 in close contact with the insertion groove 153c. The inner portion forms an end support portion 153e provided to support the other end connecting the inner and outer diameters of the pulsation reducing member 170 in intimate state.

The fluid discharged through the discharge passage 151a during the opening operation of the discharge ball 152 is applied to the inner diameter and the end surface of the pulsation reducing member 170 corresponding to the inner diameter supporting portion 153d and the end supporting portion 153e. A bypass guide groove 171 is formed to guide the bypass of the fluid to bypass the surface of the member 170. The bypass guide groove 171 is configured through the inner diameter side first bypass guide groove 171a and the end side second bypass guide groove 171b.

In addition, between the valve seat 151 and the inner diameter support part 153d, the first guide passage 181 for guiding the fluid discharged through the discharge passage 151a to the bypass guide groove 171 during the opening operation of the discharge ball 152. A second guide flow path 182 is provided between the outer diameter of the pulsation reducing member 171 and the pump cap 153 to guide the fluid of the bypass guide groove 171 toward the discharge port 122.

The fluid discharged from the discharge passage 151a during the opening operation of the discharge passage 151a through the pulsation reducing member 170 is guided to the bypass guide groove 171 through the first guide passage 181 to reduce the pulsation reducing member. By-pass along the surface 170, the fluid guided to the bypass guide groove 171 is a state in which the flow distance is long in the process of bypassing along the bypass guide groove 171, the pressure pulsation is reduced. The fluid that has passed through the bypass guide groove 171 is continuously guided toward the discharge port 122 along the second guide passage 182 and discharged.

Therefore, the hydraulic pump B according to the present embodiment can effectively reduce the pressure pulsation and the noise of the fluid in the fluid in the hydraulic pump B through the configuration of the pulsation reducing member 170. In addition, the pulsation reducing member 170 is located between the closed cap 153 and the valve seat 151 and is fixed therebetween when the valve seat 151 and the sealing cap 153 are coupled to each other, thereby assembling the hydraulic pump B. There is no fear of degrading. In FIG. 4, the thick solid line arrow indicates the movement path of the fluid discharged through the discharge channel 151a.

Next will be described the operation of the hydraulic pump (B) configured as described above.

As the spindle 5a of the motor 5 rotates, the piston 130 linearly reciprocates in the bore 120, and accordingly, the suction flow passage 131 and the discharge flow passage are changed by the pressure change in the bore 120. The hydraulic pump B is pumped to the discharge port 122 by pressurizing the fluid on the suction port 121 side while the 151a is opened and closed oppositely to each other.

That is, when the piston 130 moves toward the closing cap 153 through the rotation of the spindle 5a of the motor 5, the fluid pressure of the pressure chamber 151b is increased, and the suction passage 131 is the suction ball 141. The discharge passage 151a is opened by the discharge bell 152. Therefore, the fluid pressurized in the pressure chamber 151b is discharged to the discharge passage 151a and then guided to the bypass guide groove 171 through the first guide passage 181 and guided to the bypass guide groove 171. The pressure pulsation can be reduced in the process of bypassing along the bypass guide groove 171. The fluid passing through the bypass guide groove 171 is pumped toward the high pressure accumulator 4 via the second guide flow path 182 and the discharge port 122.

On the other hand, when the piston 130 moves toward the motor 5, this time a low pressure is formed in the pressure chamber 151b, the suction flow path 131 is opened and the discharge flow path 151a is closed. Therefore, at this time, the low pressure accumulator 3 side fluid introduced into the suction passage 131 through the suction port 121 is filled into the pressure chamber 151b via the suction passage 131.

In this state, the piston 130 moved back to the pump cap 153 by the spindle 5a pressurizes the fluid in the pressure chamber 151b and pumps it toward the discharge port 122, and the fluid by the hydraulic pump B The pumping operation of is continuously made by repeating this process.

140: suction valve portion 150: discharge valve portion
151: valve seat 151a: discharge flow path
151b: pressurizing chamber 152: discharge ball
153: sealing cap 153a: coupling portion
153b: receiving groove 153c: insertion groove
153d: inner diameter support 153e: end support
154: support spring 170: pulsation reducing member
171: Bypass Guide Home

Claims (3)

A hydraulic pump for an electronically controlled brake system including a bore formed in a modulator block and communicating with a suction port and a discharge port, and a component unit installed in the bore to pressurize the suction port side fluid and discharge the fluid toward the discharge port side. ,
The constituent unit is installed in the bore reciprocally and has a piston having a suction flow path therein, a suction valve portion for opening and closing an outlet side of the suction flow path according to the position of the piston, and provided at one side of the bore. Including a discharge valve portion which operates in opposition to the intake valve portion in accordance with the operation of,
The discharge valve unit has a valve seat having a discharge flow path, a pump cap coupled to the valve seat to surround the valve seat end to block the bore from the outside, the valve seat and the pump to open and close the discharge flow path. And a pulsation reducing member provided between the valve seat and the pump cap around the discharge ball to reduce pulsation of the fluid. The method of claim 1,
The pulsation reducing member is provided in a ring shape,
One end connecting between the inner diameter and the outer diameter of the pulsation reducing member is provided to be in close contact with the valve seat,
The pump cap includes an inner diameter support portion provided to support the inner diameter of the pulsation reducing member in close contact, and an end support portion provided to support the other end connecting the inner and outer diameters of the pulsation reducing member in close contact,
On the inner diameter and the end surface of the pulsation reducing member corresponding to the inner diameter supporting portion and the end supporting portion, the fluid discharged through the flow path of the valve seat is bypassed along the surface of the pulsating reducing member when the discharge ball is opened. Hydraulic pump for electronically controlled brake system, characterized in that the bypass guide groove is formed to guide the bypass. The method of claim 2,
Between the valve seat and the inner diameter support portion is provided a first guide passage for guiding the fluid discharged through the flow path of the valve seat to the bypass guide groove during the opening operation of the discharge ball, the outer diameter of the pulsation reducing member and the A hydraulic pump for an electronically controlled brake system, characterized in that a second guide passage for guiding the fluid in the bypass guide groove toward the discharge port is provided between the pump caps.

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