KR910006166Y1 - Solenold valve - Google Patents

Abstract

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Description

Solenoid valve

1 is a perspective view of the present invention.

Figure 2 shows the operating state of the present invention, Figure 2a is a non-excited cross-sectional view, Figure 2b is an excited state cross-sectional view.

3 is a cross-sectional view taken along the line A-A of FIG.

* Explanation of symbols for main parts of the drawings

1: Valve body 2, 3: Valve chamber

4: communication path 5: fluid inlet

6, 7: fluid outlet 8, 9: fluid recovery passage

8 ', 9': passage 10: fluid collection port

10 ': recovery communication path 11, 12: valve cone

13, 14: bushing 15, 16: valve rod

17, 18: spring 20: solenoid

21 coil 24 operating rod

The present invention relates to a solenoid valve for use in automobiles or industrial applications. In particular, it is possible to operate two valve cones smoothly using a single solenoid while reducing power consumption. It relates to a solenoid valve that can contribute to cost reduction.

In general, the solenoid valve has been widely used to operate the valve cone by using two solenoids, but there are many problems such as high power consumption required for operation, mechanical overload, and increased rework costs.

In addition, in order to solve such a problem, it is proposed to use the solenoid to smoothly operate the valve cone, and as an example, as shown in Patent No. 31484, which communicates with a central through-hole in the valve body. Two cavities are formed, and each vacancy is provided with respective valve cones connected to both ends of the support pins inserted into the through holes. One valve cone is connected to the solenoid with a shanghai copper pin, and the other valve cone is elastically installed with a spring. There was an air supply port in communication with each other and an air distribution port in each space.

However, the solenoid valve of the patent is used in such a way as to form a closed circuit connecting both ends of the cylinder to the air flow ports communicated to the respective chambers. Since the air pressure in the pneumatic line cannot be smoothly adjusted, the loss of compressed air is large, resulting in energy loss. In addition, mechanically difficult to go, and if necessary, in order to dimension the air in each vacancy into the air tank, the exhaust control hole must be connected to the air tank with a separate connection pipe, which makes the pneumatic line complicated and according to the flow resistance. There was also a problem that caused energy loss.

In addition, since the valve cones installed in each vacancy are integrally connected by one support pin, the power consumption of the solenoid for operating the valve cones on both sides can be reduced, thereby contributing to energy savings such as power and energy savings. It is to provide a solenoid valve that can contribute.

In addition, the present invention is to prevent the energy loss due to the flow resistance of the fluid can be smoothly recovered without using a separate fluid circuit line.

The object of this invention is to form two valve chambers in communication with the central communication path in the valve body, the fluid inlet to the communication path, the fluid inlet to each valve chamber, respectively, and the valve cone in the valve chamber Installed and interlocked with the operating rod of the solenoid installed on one side of the valve body, the valve body forms a fluid return port and a recovery communication path (10 '), and the valve chamber connects the recovery communication path and the valve chamber. Insert and install the bushing perforated with the fluid recovery passage and the passage, and the valve rods integrally fixed to the valve cone are connected in the central communication passage, and the one side valve cone is elastically installed with a spring facing the operating force of the solenoid. And, the other side of the valve rod is achieved by providing a solenoid valve characterized in that the resilient installation with a spring inserted between the bushing.

Hereinafter, the solenoid valve of the present invention will be described in detail according to the embodiment shown in the accompanying drawings.

The solenoid valve according to the present invention, as shown in Figs. The fluid inlet 5 is connected to the communication passage 4, and the fluid inlets 6 and 7 are respectively communicated to the valve chambers 2 and 3, and the valve cones are connected to the valve chambers 2 and 3, respectively. 11) The valve body 1 is provided with a fluid recovery port 10 and a recovery in which the valve body 1 is interlocked with the operating rod 24 of the solenoid 20 installed on one side of the valve body 1. A communication path 10 'is formed, and a fluid recovery path 8 and 9 and a passage are formed in the valve chambers 2 and 3 to connect the recovery communication path 10' and the valve chambers 2 and 3. (8 ') (9') is inserted into the bushings (13) and (14) perforated, and the valve rods (15) and (16) integrally fixed to the valve cones (11) and (12), respectively, in central communication Connected in the furnace (4), one side valve cone 11 is elastic with a spring (17) against the operating force of the solenoid (20) Value, and the other valve cone (12) is characterized in that the resilient installation hayeoseo the spring 18 is inserted between the bushing (14).

In integrally fixing the valve cones 11, 12, and the valve rods 15, 16, the protrusions 25, 26 are formed on the valve rods 15, 16, and the protrusions 25 ( By forming the valve cones 11 and 12 in the portion 26, the valve cones 11 and 12 are firmly fixed without being separated from the valve rods 15 and 16.

In the figure, reference numeral 19 is a solenoid case, 21 is a solenoid coil, 22 is a movable core, and 23 is a solenoid head.

The operation of the solenoid 20 is in a state in which no power is applied to the coil 21, that is, in the non-excited state, the operating rod 24 is moved to the left side in the drawing, and in the state in which power is applied, that is, excitation In this state, the operating rod 24 is moved to the left.

That is, in the non-excitation state in which power is not applied to the solenoid 20, the movable iron core 22 is moved to the left side by the magnetic repulsive force of the movable iron core 22 and the sliding head 23 as shown in FIG. The rod 24 moves to the left while the valve cone 11 moves to the left.

The valve cone 11 is moved to the left side and is in close contact with one side of the bushing 13 so that the passage 8 ′ communicating the fluid recovery path 8 with the valve chamber 1 and the fluid inlet 6 is provided. Shut off, the fluid inlet 5 and the communication path 4 and the fluid inlet (6) is in communication.

At this time, the valve rods 15 and 16 of the both side valve cones 11 and 12 which are connected in the center communication path 4 are about to be momentarily spaced apart, and the valve cone 12 is connected to the bushing 14. The spring 18 inserted therebetween is moved toward the central communication path 4 to block the valve chamber 3, the communication path 4, and the fluid inlet 5.

Here, the valve rods 15 and 16 of the valve cones 11 and 12 are momentarily spaced apart from each other, and the operating rods 24 of the solenoids 20 are in a state of pulling only the valve cone 11 of one side. Since the other side of the valve cone 12 is elastically moved by the spring 18 at the next moment, the solenoid 20 has a standard enough to move only the valve cone 11 on one side, and thus the solenoid ( The power required for the operation of 20) is reduced.

In this state, the fluid flows into the valve chamber 2 from the fluid inlet 5 through the communication path 4 and is supplied to the cylinder (not shown) through the fluid inlet 6 to operate the cylinder. The fluid introduced to the other side is introduced into the valve chamber 3 through the fluid inlet 7, through the passage 8 ′ of the bushing 14, the fluid return path 9 and the return communication path 10 ′. Recovered from the fluid recovery port 10 to a fluid tank (not shown).

On the other hand, when power is applied to the solenoid coil 21 and the coil 21 is excited, the sliding head 23 is moved to the right side by the magnetic attraction force of the movable iron core 22 and the sliding head 23, and thus the operating rod 24 ) Moves the valve cone 11 to the right while moving to the right (see also FIG. 2B).

The valve cone 11 is moved to the right while being in close contact with the end of the central communication path (4) to block the fluid inlet (5) and the valve chamber (2) and at the same time open the passage (8 ') fluid inlet ( 6) and the passage (8 ') and the fluid recovery path (8).

At the same time, the valve cone 12 of the other side moves to the right side of the central communication path 4 while moving to the right against the spring 18 as the valve rod 15 of the valve cone 11 pushes the valve rod 16. Opening allows communication between the fluid inlet 5 and the valve chamber 3 and at the same time shuts off the passage 9 'of the bushing 14.

In this state, the fluid flows into the valve chamber 3 from the fluid inlet 5 through the communication path 4 and is supplied to the cylinder through the fluid inlet 7 to operate the cylinder, and flows into the other side of the cylinder. The existing fluid is returned to the valve chamber 2 through the fluid inlet 6 and through the passage 8 'of the bushing 13, the fluid recovery path 8, and the recovery communication path 10'. ) To be returned to the fluid tank.

In the above-described valve operation, the fluid inlet 6 or 7 with the valve cone 11 or 12 blocking the passage 8 'or 9' of the movable bushing 13 or 14 is blocked. If the pressure of the fluid flowing into the valve is greater than the set value, the fluid outlet port is opened with the valve cone 11 or 12 blocking the passage 8 'or 9' of the movable bushing 13 or 14. If the pressure of the fluid flowing into (6) or (7) is greater than the set value, push the valve cone (11) or (12) against the spring (17) or (18), the passage (8 ') or (9). ') Is opened to the fluid tank through the recovery path (8) or (9) and the recovery port (10) while opening the') to perform a pressure control action to maintain a stable and smooth magnetic movement at a stable pressure at all times, pneumatic or hydraulic It can reduce the energy of the lamp and reduce the power consumption of the solenoid for operating two valve cones. Will also contribute.

In addition, the present invention has formed the fluid return path (8) (9) and the recovery communication path (10 ') in the valve body (1), it is possible to smoothly recover the fluid without using a separate fluid sewer line fluid Energy loss due to flow resistance in the recovery line can be prevented.

Claims (1)

In the valve body 1, two valve chambers 2 and 3 are formed to communicate with the central communication path 4, and the fluid passage 5 is connected to the communication path 4, and each valve chamber 2 ( 3) the fluid inlet (6) (7) is in communication with each other, the valve chamber (2) (3) is provided with a valve cone (11) (12) to the solenoid (20) installed on one side of the valve body (1) In the interlocked connection to the operating rod 24 of the, the valve body (1) is formed with a fluid recovery port 10 and the recovery communication path (10 '), the valve chamber (2) (3) is a recovery communication Inserting and installing the bushings 13 and 14 in which the fluid recovery passages 8 and 9 and the passages 8 'and 9' which connect the furnace 10 'and the valve chamber 2 and 3 communicate with each other. In addition, the valve rods (5) and (16) integrally fixed to the valve cones (110, 12), respectively, are connected in the center communication path (4), one side valve cone (11) of the solenoid (20) Resilient installation with a spring (17) facing the operating force, the other side valve cone 12 is burned by a spring (18) inserted between the bushing (14) Solenoid valve, characterized in that the installation by force.