KR0129267Y1 - Oil pump using an eccentric cam - Google Patents

Abstract

The present invention relates to an oil pump using an eccentric cam of an automobile. In the conventional plunger pump using an eccentric cam, the plunger rubs directly with the body, causing severe abrasion, and the check ball of the 첵 valve flows to generate bubbles and break the oil film. In order to improve this and improve the performance of oil and oil pumps, the present invention has an eccentric cam 1 and a spiral protrusion 7 formed therein, and according to the operation of the eccentric cam 1 A plunger 2 reciprocating linearly into the body 6 and a spiral groove 9 for engaging the helical protrusion 7 to reciprocate the body are formed at the tip and a user thread 10 is formed in the body. And a suction piston 11 and a discharge hole 12 communicating with the user room 10 in a direction perpendicular to the center of the body, and a rotating piston 3 installed in the body 6 with bearings 14 and 14 '. And inside the rotary piston 3 and the plunger 2 This is possibly installed to the reciprocating linear motion which consists of a pressure in a reciprocating piston (4) capable of pumping the oil in the user's office (10) of the plunger (2).

Description

Oil Pump Using Eccentric Cam

1 and 2 are longitudinal cross-sectional view of an embodiment of the present invention.

3 is an exploded perspective view of the present invention.

4 is a longitudinal sectional view showing the installation of the rotating piston.

5 is a combined perspective view of the rotary piston and the plunger.

* Explanation of symbols for main parts of the drawings

1: eccentric cam 2: plunger

3: rotating piston 4: reciprocating piston

6: body 7: spiral process

8,15: Spring 9: Spiral groove

10: user room 11: suction hole

12: discharge hole 14,14 ': bearing

The present invention relates to an oil pump using an eccentric cam of an automobile. Conventionally, an oil pump using an eccentric cam is called a plunger pump.

The plunger pump is assembled in the body and operated by an eccentric cam and there is a spring inside the plunger. There are also two suction and discharge check balls above and below.

This plunger pump allows the oil to be pumped by opening the bottom check valve when the plunger is pushed toward the cam by the spring and oil being sucked in as the plunger is pushed to the left by the cam.

However, the problem is that the plunger reciprocally slides the body surface by the cam, so the wear on the body and plunger surface is severe, which reduces the performance of the pump and blocks the inlet and outlet of the oil and flows according to the pressure of the plunger. It is easy to produce bubbles due to up and down fluctuations of the oil film, resulting in impaired oil performance and oil pump function.

The present invention uses an eccentric cam, but taking an operation structure that can minimize the occurrence of wear or foam as described above to provide an oil pump that can further improve the function of the oil pump without affecting the performance of the oil. Is there.

The present invention has an eccentric cam, a helical protrusion is formed therein and a plunger reciprocating linearly into the body according to the operation of the eccentric cam, and a spiral groove that is engaged with the spiral protrusion to reciprocate the body to achieve the above object. It is formed at the tip and a user thread is formed in the body, and a suction hole and a discharge hole communicating with the user thread are formed in a direction perpendicular to the center of the body, and the body is a bearing mounted in the body by a bearing and reciprocating between the rotary piston and the plunger. It is installed in a reciprocating piston that can be installed in a linear motion to pressurize the oil in the user room under the pressure of the plunger.

A description with reference to the following drawings.

1 through 5, reference numeral 1 denotes an eccentric cam, 2 denotes a plunger, 3 denotes a rotary piston, and 4 denotes a reciprocating piston.

The eccentric cam 1 is located on the side of the body 6 so as to have an outer surface eccentrically at the center of the cam shaft 5, and the cam shaft 5 indicates the crank shaft.

The plunger 2 is a reciprocating linear motion into the body 6 in accordance with the operation of the eccentric cam 1, the spiral projection (7) is formed on all sides inside the rotating piston (3) and in the body (6) It is pushed toward the eccentric cam (1) by a spring (8) installed between the. At least one spiral protrusion 7 is formed on the inner surface of the plunger 2.

Rotating piston (3) is formed at the end of the spiral groove (9) for engaging the spiral projection (7) to reciprocate the body and the user room 10 is formed in the body and the user room (10) A suction hole 11 and a discharge hole 12 which communicate with each other are formed at right angles from the center of the body, and are fitted to bearings 14 and 14 'provided on both sides of the flow path 13 in the body 6 on the outer surface of the body. The spiral groove 9 includes at least one formed.

The reciprocating piston 4 is installed so as to reciprocate linearly between the user chamber 10 and the plunger 2 of the rotary piston 3, and the inside of the user chamber 10 receives the pressure of the spring 15 to reciprocate. The piston 4 is in contact with the inside of the plunger 2. The reciprocating piston 4 causes the plunger 2 to pressurize the oil in the user compartment 10 under pressure.

FIG. 1 shows a state in which the plunger 2 has entered the body 6 by the eccentric cam 1, and FIG. 2 shows a state in which the plunger 2 has returned.

Initially, as shown in FIG. 2, the plunger 2 is protruded by the spring 8, the reciprocating piston 4 is pushed to the right by the spring 15, and the suction hole 11 of the rotary piston 3 is a flow path. (13) Facing downward, the discharge hole 12 is in contact with the side wall of the flow path 13, and oil rising from the flow path 13 is filled in the user room 10.

In this state, when the eccentric cam 1 presses the plunger 2, the plunger 2 is linearly moved into the body 6, and the rotating piston 3 is the spiral groove 9 of the tip of the spiral protrusion 7 ) And it is gradually combined deeply and rotates 90 °. Accordingly, the suction hole 11 of the rotary piston 3 is in contact with the side wall of the flow path 13 and the discharge hole 12 faces the flow path 13 upward. In this process, the reciprocating piston 4 is disposed on the inner surface of the plunger 2. Since it is pushed and linearly moved to the left side, the oil in the user room 10 is pumped upward through the flow path 13 through the discharge hole 12.

FIG. 1 shows such a state. In this state, when the eccentric cam 1 rotates and the plunger 2 returns again as shown in FIG. 2 by the force of the spring 8, the spiral protrusion 7 is a spiral groove 9 Since the spiral groove 9 is rotated by 90 ° in the opposite direction at the time of coupling, the rotating piston 3 rotates in the opposite direction to the original rotation direction, and the reciprocating piston 4 is a spring. It returns to the plunger 2 by the force of (15). The suction hole 11 of the rotating piston 3 rotated as described above faces downward of the flow passage 13 again as shown in FIG. 2, and the discharge hole 12 is in contact with the side wall of the flow passage 13, and thus the bottom of the flow passage 13. Oil coming up from the back into the user room 10 is filled.

The present invention not only pumps the oil upwards with a strong pressure due to the repeated operation as described above, but also has less throttling action compared to the prior art, so it does not cause bubbles during the feeding, thereby maintaining the oil performance and the function of the oil pump properly. Since the rotating piston is rotated by the bearing and the plunge does not directly rub with the body, it does not involve frictional wear or thermal deformation, thereby further improving the performance of the oil pump.

Claims (1)

An eccentric cam, a spiral protrusion formed therein, and a plunger reciprocating linearly into the body according to the operation of the eccentric cam, and a spiral groove which is engaged with the spiral protrusion to reciprocate the body, is formed at the tip and the user's room in the body. And a suction hole and a discharge hole communicating with the user's room in a direction perpendicular to the center of the body, and the body is installed so as to reciprocally linearly move between the rotary piston installed in the body as a bearing and between the rotary piston and the plunger. An oil pump using an eccentric cam composed of a reciprocating piston that can pressurize the oil in the user room under pressure.