KR100282291B1 - Solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve for air-fuel ratio adjustment of an LPG vehicle having excellent controllability even under high vacuum pressure using a diaphragm.

The valve body is formed with an outlet port, an inlet port and a plunger hole. An extension part is formed toward the plunger hole, and a coil part is fitted to the extension part. A coupling portion is formed at the outlet side to connect the valve body to the fuel injection line.

The plunger is composed of a first plunger, a rubber member, and a second plunger. A rubber member is attached to one end of the first plunger and a second plunger is fitted to the other end, and a diaphragm is fixed between the first plunger and the second plunger to seal the valve body and the coil part. The first plunger has a hole formed in the longitudinal direction at the center thereof, so that the pressure generated in the outlet and the pressure behind the plunger through the hole are minimized even when the plunger is in close contact with the outlet.

An iron core is installed in the coil portion, and a coil is wound around the iron core. When the coil is energized, a magnetic field is formed around the coil, and a magnetic force is generated in the iron core installed in the center of the coil so that the plunger is attached to the iron core. Is restored by the original.

Description

Solenoid valve

The present invention relates to a solenoid valve for adjusting the air-fuel ratio of an LPG vehicle. More specifically, the present invention relates to a solenoid valve having excellent controllability even under high vacuum pressure using a diaphragm.

The solenoid valve is used to open or close the flow of fluid and is used for various purposes. In particular, the fuel supply device of the internal combustion engine is used to adjust the supply of fuel to an optimal state according to the engine condition. The solenoid valve has the advantage of operating the high frequency in response to the digital signal of the automatic control device to open and close the valve.

The timing of opening and closing the solenoid valve is important when controlling fuel injection using the solenoid valve. However, the conventional solenoid valve has a problem that the high vacuum pressure is formed inside the discharge port in the state in which the valve is closed, and thus the controllability is large because the resistance is large at opening and closing. That is, as the opening and closing time of the solenoid valve is delayed, there is a problem that adjustment of the injection amount and injection time of the fuel is not accurate.

In order to solve this problem, the method of adjusting the opening and closing time of the valve by compensating the delay time is used.However, when the engine rotation speed increases, it is difficult to accurately measure the opening and closing delay time. There is a problem that is difficult to do.

Therefore, the present invention has been developed a solenoid valve capable of minimizing the resistance generated when opening and closing the valve to minimize the delay time and control up to a frequency of 20Hz.

It is an object of the present invention to provide a solenoid valve having excellent controllability even under high vacuum pressure.

Another object of the present invention is to provide a solenoid valve that can be easily adjusted by adjusting the angle of the inlet.

Still another object of the present invention is to provide a solenoid valve having excellent durability.

Still another object of the present invention is to provide a solenoid valve that can be fully controlled even with a small magnetic force by maximizing the collection of magnetic force.

1 is a cross-sectional view of the solenoid valve of the present invention closed.

2 is a cross-sectional view of the solenoid valve of the present invention in an open state.

3 is a detailed view of the site where the outlet and the plunger meet.

<Description of Symbols for Main Parts of Drawings>

10: valve body 12: coil part

14: inlet 18: outlet

22: extension part 24: adjusting screw

30: plunger 32: rubber member

34: first plunger 36: through hole

38: second plunger 40: hollow

44: diaphragm 46: cap

48: iron core 52: coil

54: packing 56: spring

The present invention will be described with reference to the drawings. 1 is a sectional view of the solenoid valve of the present invention in a closed state, and FIG. 2 is a sectional view of the open state.

The solenoid valve of the present invention is largely divided into a valve body 10, a coil part 12, and a plunger 30. The valve body 10 has a cylindrical member and three openings are formed. The outlet 18 is formed on one side, the injection port 14 is formed on the side, and the plunger hole into which the plunger is inserted is formed on the opposite side. The fluid enters the inlet 14 and is discharged to the outlet 18 through the space inside the valve body.

An expansion portion 22 is formed toward the plunger hole, and the coil portion 12 is fitted into the expansion portion 22 to be coupled thereto. A packing material 54 is installed and sealed between the valve body 10 and the coil part 12, and the valve body and the coil part can freely rotate with each other. Therefore, the direction of the injection pipe 16 of the valve main body can be arbitrarily adjusted, and it is very easy to install.

The fuel injection pipe 16 is connected to the injection hole 14 to supply fuel.

A cylindrical coupling portion 20 is formed toward the outlet 18 of the valve body, and an external thread is formed on an outer surface of the coupling portion 20 to connect the valve body 10 to the fuel injection line.

An internal thread for fitting the adjusting screw 24 is formed at the inner side of the coupling part 20. The adjusting screw 24 is a cylindrical member, and a male screw is formed on one surface thereof, and a groove 26 for rotating the screwdriver is formed at one end thereof, and the other end 28 protrudes into the valve body internal space. . The adjustment screw 24 is rotated to adjust the clearance between the end of the adjustment screw and the plunger 30.

The plunger 30 is composed of a first plunger 34, a rubber member 32 and a second plunger 38 attached to one end of the first plunger.

Jaws are formed at both ends of the first plunger 34, and a ring-shaped rubber member 32 is attached to the jaw of one end and the second plunger 38 is fitted to the jaw of the other end. The rubber member 32 has a larger outer diameter than the outer diameter of the outlet 18 to block the discharge of the fluid in contact with the outlet (18). The first plunger 34 has a hole 36 penetrating in the longitudinal direction at the center thereof. Therefore, in the state where the plunger 30 is in close contact with the outlet 18 and the flow of the fluid is blocked, a passage between the inside of the outlet 18 and the plunger is formed so that the pressure in the outlet and the pressure behind the plunger are the same. The resistance generated when opening and closing the valve is minimized.

The second plunger 38 is a cylindrical member having a hollow 40 formed therein, and the first plunger 34 is press-fitted and fixed to one side so that the first plunger 34 and the second plunger 38 behave integrally. do. The second plunger 38 is made of steel, and moves laterally by magnetic force generated by the coil 52 as described later. On the other hand, the first plunger 34 is made of aluminum, which is to facilitate the movement of the plunger by reducing the load of the front portion of the plunger 30.

The diaphragm 44 is fixed between the first plunger 34 and the second plunger 38. The diaphragm 44 is made of an elastic material and is fixed to the first plunger 34 in a ring shape. The outer side of the diaphragm 44 is pressed by the cap 46 attached to the coil part to be in close contact with the valve body 10 to seal the valve body and the coil part with each other.

The spring 56 is inserted into the hollow 40 of the second plunger 38. One side of the spring 56 is supported by the first plunger 34 fitted to the second plunger 38, and the other side of the spring 56 is supported by the iron core 48 described later. The spring 56 basically forces the plunger toward the outlet so that the plunger can be in close contact with the outlet to block the flow of fluid.

One side of the plunger 30 is inserted into the valve body 10, and the other side of the plunger 30 is inserted into a hole formed in the coil part 12. One side of a hollow is formed in the coil part 12, The iron core 48 is provided in the inside of the said hollow, The coil 52 is wound around the said iron core. The plunger 30 is inserted into the hollow formed in the coil part 12 and is installed with a slight gap with the iron core 48. Therefore, when electricity is supplied to the coil 52, a magnetic field is formed around the coil, and the iron core 48 provided at the center of the coil becomes an electromagnet. Since the second plunger 38 is made of steel, while the electricity flows through the coil 52, the second plunger 38 overcomes the elasticity of the spring 56 and adheres to the iron core, and when the current is cut off, the spring 56 is installed inside the second plunger again. It is returned to its original state by the elasticity of).

The plunger end 50 of the iron core 48 is formed in a conical shape to maximize the cross-sectional area. The coil end of the second plunger is also formed obliquely to have the same slope as the conical end 50 of the iron core so that the conical end 50 is inserted into the hollow 40 of the second plunger 38. .

The operating principle of the solenoid valve of the present invention will be described. Basically, the plunger 30 receives the force toward the outlet 18 by the spring 56 installed inside the second plunger 38 to maintain the valve closed. When a current is supplied to the coil 52, a magnetic field is formed and the plunger 30 overcomes the elasticity of the spring 56 and clings to the iron core 48 to open the valve. In the case of the conventional solenoid valve, since the vacuum pressure is generated inside the discharge port 18, resistance occurs at the moment when the plunger is released from the discharge port. However, the magnetic force of the coil 52 alone is not easy to overcome the resistance, so the response speed becomes slow and a delay time occurs when opening and closing the valve. However, the solenoid valve of the present invention has a hole 36 penetrating in the center of the first plunger 34, the hollow 40 is also formed in the second plunger 38, the outer surface of the plunger and the coil portion There is some play between the holes, and the valve body 10 and the coil part 12 are sealed by the diaphragm 44 so that the pressure inside the coil part 12 is equal to the vacuum pressure formed in the outlet 18. do. That is, a passage through which the fluid flows without forming the outlet 18 and the inside of the coil part 12 is formed so that the pressure state of both is the same. Therefore, since the resistance does not occur when the plunger 30 leaves the outlet 18, the response delay time may be minimized. As the plunger 30 moves toward the iron core 48, the plunger 30 is dropped from the outlet 18 and the valve is opened. When the supply of current is again cut off, the iron core 48 loses its magnetic force and the plunger 30 is pushed toward the outlet 18 by the elasticity of the spring 56 so that the valve is closed.

The operating frequency of the solenoid valve of the present invention is a high frequency of about 20 Hz, wherein the frictional resistance generated between the rubber member 32 and the outlet 18 is large. In order to reduce the frictional resistance, the end of the rubber member 32 was coated with Teflon to reduce the frictional resistance. In addition, the end section of the discharge port 18 is not formed at right angles and is formed in an arc shape so that the rubber member 32 and the discharge port 18 can be point contact instead of surface contact, thereby minimizing frictional resistance.

In the solenoid valve of the present invention, a through hole is formed inside the plunger and the valve body and the coil part are sealed to each other by a diaphragm, so that the inside of the outlet port and the coil part form the same vacuum pressure so that the resistance does not occur when the plunger is separated from the outlet port. Even under the high vacuum pressure generated in the outlet, only a small magnetic force generated in the coil can be sufficiently controlled.

In addition, Teflon is coated on the end of the plunger, and the end surface of the outlet is formed in an arc shape to minimize the frictional resistance during opening and closing of the valve.

In addition, the solenoid valve of the present invention is free to rotate the valve body and the coil portion can be arbitrarily adjusted the angle of the inlet port, it is easy to install the solenoid valve.

Claims (5)

As a member having a hollow formed therein, an outlet 18 is formed on one side thereof, and a coupling portion 20, which is a cylindrical male screw member, protrudes outwardly of the outlet 18, and a plunger hole is formed on the opposite side thereof. A valve body 10 having an injection hole 14 into which the injection pipe 16 is inserted; The plunger is inserted and installed through the plunger hole coaxially with the outlet port 18 to contact the outlet port 18 to open and close the flow of the fluid, and a plunger having a hole 36 penetrating in the longitudinal direction at the center thereof. 30; A hollow is formed so that the plunger 30 can be inserted, the coil portion 12 is coupled to the valve body 10; It is fitted in the middle of the plunger 30 in the shape of a ring is fixed, the outer side is pressed by the cap 46 fixed to the coil portion 12 is in close contact with the valve body 10 and the valve body 10 and A diaphragm 44 for sealing the coil part 12 to each other; Elastic means (56) for biasing the plunger (30) towards the outlet (18); And, A coil 52 installed at an outer circumferential surface of the plunger 30 to generate a magnetic force for controlling the plunger 30 according to an electrical signal; The pressure inside the coil part 12 and the pressure in the outlet 18 are equal by the hole 36 formed in the center of the plunger 30 in the state in which the outlet 18 is closed. Solenoid valve characterized by. In claim 1, the inner portion of the coupling portion 20 is formed with a female screw, a male screw is formed to be fastened to the female screw on the outside and a cylindrical adjustment screw 24 formed with a hollow through which fluid can flow Further installed, the solenoid valve, characterized in that the plunger (30) in contact with the end of the adjustment screw (24) to control the flow of the fluid. 2. The solenoid valve according to claim 1, wherein a portion of the outlet port (18) contacting the plunger (30) may be in point contact with the plunger (30) by forming an arc in cross section. The iron core 48 is inserted into the center of the coil 52, the plunger end portion 50 of the iron core 48 protrudes in a conical shape, and the end of the plunger 30 is also conical. Solenoid valve, characterized in that the cross-section is formed so that it can be inserted to increase the collection of magnetic force. 2. The solenoid valve according to claim 1, wherein the end of the plunger (30) in contact with the outlet (18) has a Teflon coating.