KR20170040991A - Electromagnetic pump - Google Patents

Abstract

Disclosed is an electromagnetic pump. The electromagnetic pump comprises: a holder unit having a space formed therein to communicate with an intake passage and an outtake passage; a first check valve which is mounted in the space and regulates a movement of a fluid discharged to the outtake passage from the space; a piston to reciprocate in the space; a second check valve which is mounted on the piston to form a fluid accommodation unit between the first check valve and the same, and regulates a movement of a fluid inputted into the space from the intake passage; a motor unit to press the piston towards the first check valve to move the piston; and an elastic member whose both ends come in contact with the first and the second check valve to press the second check valve in a direction in which the second check valve moves away from the first check valve.

Description

ELECTROMAGNETIC PUMP

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic pump, and more particularly, to an electromagnetic pump capable of moving a fluid.

Generally, a pump applied to a vehicle is applied to a vehicle ISG (idle stop and go), and the fluid is moved by interrupting fluid movement and generating an oil pressure using external power.

However, the conventional pump has a complicated structure, making it difficult to manufacture and control the apparatus, high manufacturing cost, and large volume. Therefore, there is a need for improvement.

BACKGROUND OF THE INVENTION [0002] The background of the present invention is disclosed in Published Patent Publication No. 2015-0018390 (entitled " Variable Capacity Transmission Pump and Controller with Adjustable Control Ability "

It is an object of the present invention to provide an electromagnetic pump capable of reducing the manufacturing time and cost, simplifying the control, and reducing the volume of the apparatus by simplifying the configuration of the apparatus. have.

An electromagnetic pump according to the present invention includes: a holder portion having a space formed therein and communicating with a suction path and a discharge path; A first check valve coupled to the space portion and interrupting movement of fluid discharged from the space portion to the discharge passage; A piston reciprocally movable in the space; A second check valve coupled to the piston to form a fluid receiving portion between the first check valve and the first check valve, and to control the movement of fluid entering the space from the suction passage; A driving unit for pressing and moving the piston toward the first check valve; And an elastic member pressing both of the first check valve and the second check valve in a direction in which the second check valve is spaced apart from the first check valve.

The first check valve may include a first valve housing fixed to the discharge-passage-side end of the space and having a first valve space formed therein; A first valve which communicates the first valve space part and the fluid containing part; A first valve-out hole portion communicating the first valve space portion and the discharge passage; A first valve elastic part accommodated in the first valve space part; And a first valve ball elastically supported by the first valve elastic portion toward the hole portion as the first valve and opening and closing the hole portion as the first valve in conjunction with the movement of the piston.

In the present invention, the piston includes: a piston shaft having one end abutting on the electromotive portion and moving in the space portion interlocking with the electromotive portion; And a piston head coupled to the piston shaft and reciprocating in the space portion and coupled to the second check valve.

In the present invention, the second check valve may include: a second valve housing coupled to the piston and having a second valve space formed therein; A second valve that communicates the second valve space and the suction passage; A second valve-out hole portion communicating the second valve space portion and the fluid containing portion; A second valve elastic part accommodated in the second valve space part; And a second valve ball elastically supported by the second valve elastic portion toward the hole portion as the second valve and opening and closing the hole portion as the second valve in cooperation with the piston.

According to an embodiment of the present invention, the transmission unit includes: a transmission housing coupled to the holder; A plunger portion reciprocably received in the transmission housing and in contact with the piston; And an electromagnetic coil part accommodated in the electroconductive housing and moving the plunger part when power is applied.

The electromagnetic pump according to the present invention is capable of moving a fluid by using a change in pressure generated when the piston reciprocates, and can simplify the structure and simplify the control by reducing the manufacturing time and cost.

Further, the present invention can simplify the structure of the apparatus and prevent the piston from being pinched by eliminating the step in the holder portion.

1 is a cross-sectional view schematically showing a cross section of an electromagnetic pump according to an embodiment of the present invention.
2 is a view showing a state in which a piston moves in one direction in an electromagnetic pump according to an embodiment of the present invention.
3 is a view illustrating a state in which the piston moves in the other direction in the electromagnetic pump according to the embodiment of the present invention.

Hereinafter, an embodiment of an electromagnetic pump according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a cross-sectional view schematically showing a cross section of an electromagnetic pump according to an embodiment of the present invention. 1, the electromagnetic pump 1 according to the present embodiment includes a holder 100, a first check valve 200, a piston 300, a second check valve 400, a driving unit 500, The fluid contained in the oil pan or the like including the member 600 is moved to a clutch, a brake, or the like of the automatic transmission.

The holder portion 100 has a space portion 111 formed therein and communicates with the suction passage 10 and the discharge passage 30. The holder 300 includes a first check valve 200, a second check valve 400 and a second check valve 400. The first check valve 200, the piston 300, the second check valve 400, and the elastic member 600 And is coupled to the transmission portion 500 by a method such as bolting or bonding.

In this embodiment, the holder 100 may be formed as a separate member from the valve body of the automatic transmission, and may be coupled by a method such as bolting or bonding, or may be integrally formed with the valve body.

The first check valve 200 is coupled to the space portion 111 and interrupts the movement of the fluid discharged from the space portion 111 to the discharge flow path 30. In this embodiment, the first check valve 200 includes a first valve housing 210, a first valve hole 230, a first valve-out hole portion 250, a first valve elastic portion 270, And a ball 290.

The first valve housing 210 is fixed to the end of the space portion 111 on the side of the discharge flow path 30 by fitting or welding and the first valve space portion 211 is formed therein. In this embodiment, the first valve housing 210 is formed in a cylindrical shape elongated in the longitudinal direction (left and right direction in FIG. 1) of the holder part 100, and includes a metal material.

The first valve 230, which is a first valve, communicates the first valve space 211 with the fluid receiving portion 115. The hole 230 as the first valve passes through the end of the first valve housing 210 on the side of the fluid receiving portion 115 to communicate the fluid receiving portion 115 and the first valve space portion 211 .

The first valve outhole portion 250 allows the first valve space portion 211 and the discharge passage 30 to communicate with each other. The first valve-out hole portion 250 communicates the first valve space portion 211 with the discharge passage 30 through the end portion of the first valve housing 210 on the side of the discharge passage 30 in this embodiment.

The first valve elastic part 270 is accommodated in the first valve space part 211. The first valve elastic portion 270 is illustrated as a coil spring and contacts the first valve ball 290 to urge the first valve ball 290 toward the hole 230 as the first valve.

The first valve ball 290 is resiliently supported by the first valve elastic portion 270 toward the hole 230 which is the first valve and interlocked with the movement of the piston 300 to open and close the first valve 230, do.

FIG. 2 is a view showing a state in which the piston moves in one direction in the electromagnetic pump according to the embodiment of the present invention, FIG. 3 is a view showing a state in which the piston moves in the other direction in the electromagnetic pump according to the embodiment of the present invention FIG.

2 and 3, in the present embodiment, the first valve ball 290 is formed by reducing the volume of the fluid receiving portion 115 when the piston 300 moves toward the first check valve 200, Which is the first valve, to open the hole 230 as the first valve.

On the other hand, when the piston 300 moves in the direction away from the first check valve 200, the negative pressure generated as the volume of the fluid receiving portion 115 increases and the elastic force of the first valve elastic portion 270 The first valve 230 is pressed toward the hole 230 to close the hole 230 as the first valve.

The piston 300 is reciprocally movable in the space portion 111 to increase or decrease the volume of the fluid receiving portion 115. In this embodiment, the piston 300 includes a piston shaft 310 and a piston head 330.

One end of the piston shaft 310 is moved in conjunction with the driving unit 500 in contact with the driving unit 500. The piston head 330 is coupled to the piston shaft 310 and reciprocates in the space portion 111, and the second check valve 400 is engaged.

The second check valve 400 is coupled to the piston 300 and forms a fluid receiving portion 115 between the first check valve 200 and the first check valve 200. The second check valve 400 controls the flow of the fluid And the like. In this embodiment, the second check valve 400 includes a second valve housing 410, a hole portion 430 as a second valve, a second valve-out hole portion 450, a second valve elastic portion 470, And a ball 490.

The second valve housing 410 is inserted into the space portion 111 so as to be spaced apart from the first check valve 200 to form a fluid receiving portion 115 between the first check valve 200 and the piston 300, And a second valve space portion 411 is formed therein.

The hole portion 430, which is a second valve, communicates the second valve space portion 411 and the suction passage 10. In the present embodiment, the hole portion 430, which is the second valve, is formed radially through the second valve housing 410, and is formed in the center of the second valve housing 410 in the longitudinal direction of the second valve housing 410 So that the second valve space portion 411 and the suction passage 10 are communicated with each other.

The second valve out-hole portion 450 allows the second valve space portion 411 and the fluid receiving portion 115 to communicate with each other. In this embodiment, the second valve-out hole portion 450 is formed at an end of the second valve housing 410 on the side of the fluid accommodating portion 115 to communicate the second valve space portion 411 and the fluid accommodating portion 115 .

The second valve elastic part 470 is accommodated in the second valve space part 411 and presses the second valve ball 490 toward the hole part 430 which is the second valve. In this embodiment, the second valve elastic portion 470 is illustrated as a coil spring and contacts the second valve ball 490 to press the second valve ball 490 toward the hole portion 430 which is the second valve.

The second valve ball 490 is resiliently supported by the second valve elastic part 470 toward the hole 430 as the second valve and opens and closes the hole part 430 as the second valve interlocking with the piston 300. The second valve ball 490 is pressed toward the hole 430 as the second valve by the second valve elastic part 470 to close the hole 430 as the second valve, When the first check valve 200 moves in a direction away from the first check valve 200, the second valve, which is the second valve, is opened by the oil pressure reduced by the fluid receiving portion 115.

When the electric power is applied from the outside, the electromotive unit 500 presses and moves the piston 300 toward the first check valve 200 using an electromagnetic force. In this embodiment, the electromotive section 500 includes the electromotive section housing 510, the plunger section 530, and the electromagnetic coil section 550.

The electromechanical housing 510 is coupled to the holder 100 by means of bolting, welding, or the like. In this embodiment, the electro-conductive housing 510 includes a metal material and is formed in a substantially cylindrical shape to support the plunger portion 530 and the electromagnetic coil portion 550 accommodated therein.

The plunger portion 530 is reciprocably received in the electric motor housing 510 and contacts the piston 300. In this embodiment, the plunger portion 530 moves by the electromagnetic force generated when power is applied to the electromagnetic coil portion 550, and moves the piston 300 toward the first check valve 200 side.

The electromagnetic coil portion 550 is accommodated in the electromagnetic housing 510 and is formed to surround the plunger portion 530. When the power is applied, the electromagnetic coil portion 550 moves the plunger portion 530 using an electromagnetic force.

The elastic member 600 has two end portions connected to the first check valve 200 and the second check valve 400 so that the piston 300 is separated from the first check valve 200 together with the second check valve 400 And is illustrated as a coil spring.

The resilient member 600 prevents the volume of the fluid receiving portion 115 from varying due to vibration of the vehicle to prevent leakage of fluid or the like and prevents the piston 300 from rotating with the second check valve 400, Specifically, the plunger portion 530 so that the piston 300 and the driving portion 500 are brought into close contact with each other.

The elastic member 600 presses the piston 300 together with the second check valve 400 to restore the position of the piston 300 to the initial position when power is not applied to the electromotive unit 500.

Hereinafter, the operation principle and effects of the electromagnetic pump 1 according to an embodiment of the present invention will be described.

When the plunger portion 530 is located at the initial position (the reference right side in FIG. 1), the piston 300 is pressed to the right side by the elastic member 600 and contacts the plunger portion 530. The first check valve 200 and the second check valve 400 are connected to the first valve elastic part 270 and the second valve elastic part 470 respectively Thereby closing the hole portion 230, which is the first valve, and the hole portion 430, which is the second valve, and blocks the flow of the fluid.

When power is applied to the electromotive unit 500 in the ECU of the vehicle or the like, an electromagnetic force is generated in the electromagnetic coil part 550 to move the plunger part 530 toward the piston 300 side.

When the plunger portion 530 moves toward the piston 300, the second check valve 400 coupled to the piston 300 moves toward the first check valve 200 together with the piston 300, The fluid pressure in the fluid receiving portion 115 is increased.

When the first valve ball 290 is pressed while increasing the pressure inside the fluid accommodating portion 115, the first valve ball 290 is separated from the first valve 230, And the fluid in the fluid receiving portion 115 is discharged to the discharge flow path 30 through the first valve space portion 211 and the first valve out hole portion 250 through the hole portion 230 which is the first valve .

When the electric power supplied to the electromotive unit 500 is cut off, the pressing force of the plunger unit 530 against the piston 300 is released and the elastic member 600 moves the second check valve 400 and the piston 300 to the front And moves to the east side 500 side.

When the second check valve 400 and the piston 300 are moved to the transmission portion 500 side, the volume of the fluid receiving portion 115 is increased and the pressure inside the fluid receiving portion 115 is lowered. The second valve ball 490 is spaced apart from the hole portion 430 which is the second valve and the first valve ball 290 is in close contact with the hole portion 230 which is the first valve. The fluid in the suction passage 10 flows into the fluid receiving portion 115 through the hole portion 430, the second valve space portion 411 and the second valve-out hole portion 470, which are the second valves.

Accordingly, the electromagnetic pump 1 according to the present embodiment can move the fluid by using the positive pressure and the negative pressure generated when the piston 300 reciprocates, and the construction of the apparatus is simple, thereby reducing the manufacturing time and cost .

In addition, the electromagnetic pump 1 according to the present embodiment can simplify the structure of the apparatus and prevent the piston 300 from being pinched by eliminating the step inside the holder 100.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

1: Electromagnetic pump 10: Suction flow path
30: Discharge channel 100:
111: Space part 115: Fluid receiving part
200: first check valve 210: first valve housing
211: first valve space part 230: first valve,
250: first valve out-hole part 270: first valve elastic part
290: first valve ball 300: piston
310: Piston shaft 330: Piston head
400: second check valve 410: second valve housing
411: second valve space part 430: second valve,
450: second valve out-hole part 470: second valve elastic part
490: second valve ball 500:
510: Electric drive housing 530: Plunger part
550: Electromagnetic coil part 600: Elastic member

Claims (5)

A holder portion having a space formed therein and communicating with the suction passage and the discharge passage;
A first check valve coupled to the space portion and interrupting movement of fluid discharged from the space portion to the discharge passage;
A piston reciprocally movable in the space;
A second check valve coupled to the piston to form a fluid receiving portion between the first check valve and the first check valve, and to control the movement of fluid entering the space from the suction passage;
A driving unit for pressing and moving the piston toward the first check valve; And
An elastic member having opposite ends thereof in contact with the first check valve and the second check valve, respectively, and urging the second check valve in a direction away from the first check valve;
And an electromagnetic pump.
2. The apparatus of claim 1, wherein the first check valve comprises:
A first valve housing fixed to the discharge-passage-side end of the space portion and having a first valve space formed therein;
A first valve which communicates the first valve space part and the fluid containing part;
A first valve-out hole portion communicating the first valve space portion and the discharge passage;
A first valve elastic part accommodated in the first valve space part; And
A first valve ball elastically supported by the first valve elastic portion toward the hole portion as the first valve and opening / closing the hole portion as the first valve in conjunction with the movement of the piston;
And an electromagnetic pump.
2. The piston according to claim 1,
A piston shaft having one end abutting on the electromotive portion and moving in the space portion interlocking with the electromotive portion; And
A piston head coupled to the piston shaft and reciprocating in the space portion and coupled with the second check valve;
And an electromagnetic pump.
4. The apparatus according to any one of claims 1 to 3, wherein the second check valve comprises:
A second valve housing coupled to the piston and having a second valve space formed therein;
A second valve that communicates the second valve space and the suction passage;
A second valve-out hole portion communicating the second valve space portion and the fluid containing portion;
A second valve elastic part accommodated in the second valve space part; And
A second valve ball elastically supported by the second valve elastic portion toward the hole portion as the second valve and opening / closing the hole portion as the second valve interlocking with the piston;
And an electromagnetic pump.
The power transmission apparatus according to claim 1,
A driving unit housing coupled to the holder unit;
A plunger portion reciprocably received in the transmission housing and in contact with the piston; And
An electromagnetic coil part accommodated in the electroconductive housing and moving the plunger part when power is applied;
And an electromagnetic pump.

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