KR101402711B1 - Hydraulic pump for electronic control brake system - Google Patents

Abstract

Disclosed is a hydraulic pump for an electronically controlled brake system that can reduce the number of components and the time of assembly process. The hydraulic pump includes a piston having a flow path communicating with an inlet port and reciprocatingly installed in a bore formed in a modulator block having an inlet port and a discharge port and a discharge port communicating with the compression chamber in which the piston is located and the discharge port A pump cap which is coupled to an end of the valve seat to form a discharge chamber and an outlet valve which is provided in the discharge chamber so as to open and close the orifice, And a flow groove for guiding the flow of oil to the discharge port side when the orifice is opened is formed at the end of the valve seat.

Description

Technical Field [0001] The present invention relates to a hydraulic pump for an electronically controlled brake system,

The present invention relates to a hydraulic pump for an electronically controlled brake system, and more particularly, to a hydraulic pump for an electronically controlled brake system capable of reducing the number of component parts and the time of assembly process.

Generally, an electronically controlled brake system mounted on a vehicle controls the braking hydraulic pressure transmitted to the wheel side of the vehicle to prevent the wheel from slipping on the road surface, thereby achieving safe braking.

Such an electronically controlled brake system includes a plurality of solenoid valves, a low pressure accumulator and a high pressure accumulator for temporarily storing oil, a motor and a pump for pumping oil of the low pressure accumulator, an electronic control unit And these components are compactly built into the modular block.

1 is a hydraulic circuit diagram of a typical electronically controlled brake system.

1, the modulator block 10 of the electronically controlled brake system includes a plurality of solenoid valves 11a and 11b for opening and closing a flow path formed therein, a motor 13 for pressing the return oil, Pressure accumulator 12 and a high-pressure accumulator 15 which are disposed on the upstream side and the downstream side flow path of the pump 20 and the hydraulic pump 20, respectively. These components are interconnected through a plurality of flow passages formed in the modulator block 10 and are controlled by the electronic control unit (not shown) from the master cylinder 16 to the wheel-side wheel cylinder 17 And performs a function of interrupting the braking hydraulic pressure to be transmitted.

Here, the hydraulic pump 20 pressurizes the brake oil returned to the low-pressure accumulator 12 along the hydraulic line, and presses the brake oil to the wheel-side wheel cylinder 17 so that the wheels are braked.

2 is a cross-sectional view schematically showing a conventional hydraulic pump.

2, the hydraulic pump 20 is installed in a modulator block 10 having an inlet port 10a and a discharge port 10b, compresses the oil flowing through the inlet port 10a, And is discharged through the discharge port 10b.

The hydraulic pump 20 includes a piston 30 in the modulator block 10 and a valve seat 40 for partitioning the inside of the modulator block 10 into a compression chamber 23 and a discharge chamber 25, An outlet valve 50 for opening and closing the orifice 41 provided in the valve seat 40 to communicate the discharge chamber 23 and the discharge chamber 25 with each other, An inlet valve 60 for opening and closing a flow path connecting the inlet chamber 21 and the compression chamber 23 provided in the inlet port 10a, a filter 70 for filtering the oil flowing through the inlet port 10a, 25 which is connected to the modulator block 10 to close the pump cap 80.

At this time, the outlet valve 50 includes a shielding member 51 for blocking the orifice 41, a valve spring 53 for elastically supporting the shielding member 51, a valve seat 53 for supporting the valve spring 53, And an outlet plate 55 coupled to an end of the plate.

However, in the conventional hydraulic pump 20, the pump cap 80 is assembled to the modulator block 10 after the valve seat 40 and the outlet plate 55 are assembled to the modulator block 10. In other words, the assembly process of the conventional hydraulic pump 20 has a problem in that the cycle time of the assembling process is increased because the three types of parts are assembled by dividing the parts into two parts.

In addition, the conventional hydraulic pump 20 has a problem in that the number of component parts increases as the outlet plate 55 is assembled, thereby increasing the cost for assembling.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a hydraulic pump for an electronically controlled brake system which can reduce the number of component parts and assembly time.

In order to achieve the above object, a hydraulic pump for an electronically controlled brake system according to the present invention comprises: a piston reciprocably installed in a bore formed in a modulator block having an inlet port and a discharge port and having a flow path communicating with the inlet port; A valve seat provided in the bore and having a bore that divides the bore into a compression chamber in which the piston is located and a discharge chamber communicating with the discharge port and has an orifice communicating the compression chamber and the discharge chamber; And an outlet valve provided in the discharge chamber to open and close the orifice,

Wherein the pump cap is disposed so as to surround a part of an outer surface of the valve seat and an end thereof,

And a flow groove for guiding the flow of oil to the discharge port side when the orifice is opened is formed at an end of the valve seat.

Wherein the outlet valve includes a shielding member for shielding the orifice and a valve spring for elastically supporting the shielding member,

Wherein the pump cap is formed with a support groove for supporting the shield member and the valve spring of the outlet valve.

The support groove includes a first support groove in which the valve spring is supported and a second support groove in which the shield member is supported when the orifice is opened.

As described above, the hydraulic pump of the electronically controlled brake system according to the present invention does not need to assemble the outlet plate by changing the shapes of the valve seat and the pump cap, so that the cost is reduced and the pump cap is press- The hydraulic pump including the valve seat is installed in the modulator block, and the final pump cap is installed in the modulator block, thereby reducing the assembly time.

1 is a hydraulic circuit diagram of a typical electronically controlled brake system.
2 is a schematic cross-sectional view of a conventional hydraulic pump for an electronically controlled brake system.
3 is a schematic cross-sectional view of a hydraulic pump for an electronically controlled brake system according to the present invention.

3, a hydraulic pump 100 for an electronically controlled brake system according to the present invention is installed in a modulator block 110 having an inlet 112 and a discharge port 113. A motor 13 (see FIG. 1) in which a spindle 14 protrudes to drive a pair of hydraulic pumps 100 disposed at left and right sides is installed at a central portion of one side of the modulator block 110. 1) of the motor 13 is formed integrally with the eccentric shaft 105 and disposed between the pistons 120 of the respective hydraulic pumps 100 so that the pair of hydraulic pumps 100 The motor 100 is driven while having a phase difference of 180 degrees from each other.

The hydraulic pump 100 includes a piston 120 installed to be reciprocatable in a bore 111 formed in the modulator block 110 and a piston 120 installed in the bore 111 to connect the bore 111 to the compression chamber 117, An outlet valve 150 for opening and closing the orifice 131 provided in the valve seat 130 to communicate the compression chamber 117 and the discharge chamber 118, An inlet valve 140 for opening and closing a flow path 121 connecting the inflow chamber 116 and the compression chamber 117 provided upstream of the compression chamber 117 so as to be separated from the compression chamber 117, 112 for filtering the incoming oil.

The bore 111 formed in the modulator block 110 includes an inflow chamber 116 communicating with the inlet 112 and a compression chamber 117 provided downstream of the inflow chamber 116 and compressed by the piston action of the oil, And a discharge chamber 118 provided in the downstream of the compression chamber 117 and communicating with the discharge port 113. At this time, the inflow chamber 116 and the compression chamber 117 are partitioned by the piston 120 and the seal housing 125, and the compression chamber 117 and the discharge chamber 118 are partitioned by the valve seat 130 .

The piston 120 has a length from the operating chamber 106 in which the eccentric shaft 105 provided in the motor 13 is located to the inflow chamber 116 and the compression chamber 117. A first sealing member 122 for sealing the piston 120 and a stopper 123 for restricting the reciprocating motion of the piston 120 are provided between the operation chamber 106 and the inflow chamber 116, The first backup ring 125 prevents the first sealing member 122 from being damaged during the reciprocating movement of the first sealing member 122. A flow path 121 communicating the inflow chamber 116 and the compression chamber 117 is provided at a downstream portion of the piston 120, that is, at a position where the inflow chamber 116 and the compression chamber 117 are located. 121 are opened and closed by an inlet valve 140 provided at an end of the piston 120. [

The inlet valve 140 includes a spherical first shielding member 141 that contacts the downstream end of the piston 120 to block the flow path 121 and a first valve spring 143 that elastically supports the first shielding member 141 And an inlet plate 145 coupled to the downstream end of the piston 120 to support the first valve spring 143. [ The first shielding member 141 closes the flow path 121 by the elastic force of the first valve spring 143. When the oil is discharged from the compression chamber 117 and the pressure in the compression chamber 117 drops, And the compression chamber 117, the pressure oil is released from the downstream side end of the piston 120 to open the oil passage 121.

The filter assembly 160 is installed in the inlet chamber 116 to filter the oil entering the inlet chamber 116 through the inlet 112. The filter assembly 160 includes a filter housing 161 which is press-fitted into the bore 111 to guide the piston 120 and a plurality of openings provided around the filter housing 161, And a filter member 163 for filtering the oil introduced into the inside of the filter housing 161 from the outside.

At the downstream end of the filter housing 161, an actual housing 125 is provided as shown. A second sealing member 126 for sealing the piston 120 is provided between the inner diameter of the thread housing 125 and the outer diameter of the piston 120 and a second sealing member 126 for sealing the second sealing member 126 during the reciprocating motion of the piston 120. [ A second backup ring 127 for preventing damage is provided.

The valve seat 130 is provided inside the bore 111 to divide the bore 111 into a compression chamber 117 and a discharge chamber 118 as described above. This valve seat 130 is press-fitted into the inner diameter of the downstream end of the seal housing 125 as shown and presses into the inner diameter of the upstream end of the pump cap 170.

At the center of the downstream end of the valve seat 130 is formed an orifice 131 for communicating the compression chamber 117 and the discharge chamber 118. The orifice 131 is opened and closed by an outlet valve 150 installed in the discharge chamber 118. The outlet valve 150 is connected to the downstream end of the valve seat 130 and the valve seat 130 Is provided between the pump cap (170).

A flow groove 133 is formed at the downstream end of the valve seat 130 to allow the oil to flow to the discharge port 113 when the orifice 131 is opened by the outlet valve 150. This flow groove 133 is formed at one side of the downstream end of the valve seat 130 as shown in the figure.

The valve seat 130 supports the piston spring 124 that elastically supports the piston 120 together with the inlet plate 145. The piston spring 124 pushes the piston 120 toward the eccentric shaft 105 to reciprocate the piston 120 together with the eccentric shaft 105.

The outlet valve 150 includes a spherical second shielding member 151 for blocking the orifice 131 and a second valve spring 153 for elastically supporting the second shielding member 151. At this time, the second shielding member 151 closes the orifice 131 by the elastic force of the second valve spring 153, and when the oil in the compression chamber 117 is compressed by the piston 120, And is released from the valve seat 130 to open the orifice 131.

The pump cap 170 is press-fitted into the downstream end of the valve seat 130 so as to enclose the valve seat 130 at a certain portion as shown in the figure. That is, the pump cap 170 is installed inside the bore 111 of the modulator block 110 in a state in which the valve seat 130 is press-fitted. The pump cap 170 is formed with a support groove 155 in which a part of the second shielding member 151 of the outlet valve 150 and the second valve spring 153 can be disposed. The support groove 155 at this time has a first support groove 156 directly supporting the second valve spring 153 and a second shield member 151 falling from the valve seat 130 when the orifice 131 is opened, And a second support groove 157 for supporting a part of the second support groove 157.

In the hydraulic pump 100 for the electronically controlled brake system having the above structure, the oil introduced into the inflow chamber 116 through the inlet 112 flows into the interior of the filter assembly 160 and then flows into the center of the piston 120 To the flow path 121 formed in the flow path. When the piston 120 is compressed by the eccentric shaft 105 and moved to the compression chamber 117, the oil in the compression chamber 117 is compressed and the oil is compressed by the second shield member of the outlet valve 150 151 are separated from the valve seat 130 and the orifice 131 is opened. At this time, the oil in the compression chamber 117 is discharged to the discharge port 113 through the flow groove 133 formed at the downstream end of the valve seat 130.

Subsequently, when the eccentric shaft 105 moves away from the piston 120, the piston 120 is pushed toward the working chamber 106 by the resilient restoring force of the piston spring 124. At this time, since the pressure of the compression chamber 117 becomes lower than the pressure of the passage of the piston 120, the first shielding member 141 of the inlet valve 140 is released from the piston 120 to open the oil passage 121, The oil is supplied to the compression chamber 117.

In this embodiment, since the outlet plate 55 is not assembled by changing the shape of the valve seat 130 and the pump cap 170, the cost is reduced, Since the hydraulic pump 100 including the valve seat 130 is installed on the modulator block 110 and the final pump cap 170 is installed on the modulator block 110 The assembling time can be shortened.

110: Modulator block 111: Bohr
112: inlet 113: outlet
116: inflow chamber 117: compression chamber
118: Discharge chamber 120: Piston
121: EURO 125: Actual housing
130: valve seat 131: orifice
133: flow groove 140: inlet valve
141: first shielding member 143: first valve spring
150: outlet valve 151: second shield member
153: second valve spring 155: support groove
156: first support groove 157: second support groove
160: Filter assembly 170: Pump cap

Claims (3)

A piston 120 having a flow path 121 communicating with the inlet 112 so as to be reciprocally movable in a bore 111 formed in a modulator block 110 having an inlet 112 and a discharge port 113, The bore 111 is divided into a compression chamber 117 in which the piston 120 is located and a discharge chamber 118 in communication with the discharge port 113, A pump cap 170 coupled to an end of the valve seat 130 to form the discharge chamber 118, and a pump cap 170 connected to an end of the valve seat 130. The valve seat 130 has an orifice 131 communicating with the discharge chamber 118, And an outlet valve (150) installed in the discharge chamber (118) to open and close the orifice (131)
The pump cap 170 is disposed so as to surround a part of an outer surface and an end of the valve seat 130,
A flow groove 133 for guiding the flow of oil to the discharge port 113 side when the orifice 131 is opened is formed at an end of the valve seat 130,
The outlet valve 150 includes a shielding member 151 for shielding the orifice 131 and a valve spring 153 for elastically supporting the shielding member 151,
The pump cap 170 is formed with a support groove 155 for supporting the shield member 151 and the valve spring 153 of the outlet valve 150,
The support groove 155 has a first support groove 156 in which the valve spring 153 is supported and a second support groove 157 in which the shield member 151 is supported when the orifice 131 is opened And a hydraulic pump for an electronically controlled brake system.
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