KR200230190Y1 - Assembled Structure of Solenoid Valve and Valve Block for Oxygen Generator - Google Patents

Abstract

The present invention relates to a combination structure of the solenoid valve and valve block for oxygen generator that can improve the work efficiency by easy piping work by converging the piping equipment of the solenoid valve connected by the hose to form a structure. The solenoid valve and valve block combination structure has an inlet through which compressed air is introduced, and a port a is formed integrally with the inlet and one pipeline, and ports b and c disposed on both sides of the port a and the port. a supply pipeline block for connecting the port d arranged in a symmetrical direction of a with a single pipeline, an outlet supply air direction switching valve block installed at an upper front of the supply pipeline block and having an outlet pipe and an inlet pipe formed at an upper end thereof; The top of the supply passage block is arranged in parallel with the direction switching valve block and the discharge port is formed on the upper side and one side includes a discharge solenoid block connected to the inlet and the pressure supply pipe. Accordingly, the piping equipment of the solenoid valve is integrated into a single block, which saves space by simplifying the function, improves the work efficiency of the piping work, and at the same time, ensures fluid reliability, thereby achieving stable performance.

Description

Assembled Structure of Solenoid Valve and Valve Block for Oxygen Generator}

The present invention relates to a combination of a solenoid valve and a valve block, and more specifically, by converging the piping equipment of the solenoid valve connected by a hose to form a single block structure, the work efficiency can be improved by easy piping work. To a solenoid valve and valve block combination structure for an oxygen generator.

In the conventionally used solenoid valve for oxygen supply, as shown in FIG. 5, the solenoid valve 1 for discharging is disposed at the upper end, and the direction switching solenoid valve 2 of the supply air is positioned at the lower end thereof. By using the various assembly means and the tube (3) is configured by connecting the discharge solenoid (1) and the switching solenoid valve (2) of the supply air.

It is divided into two flows according to the signal. Compressed air is supplied from the compressor to the port A, and connected to the port C according to the first operation signal. The air from port C circulates and returns to port B and is exhausted through the discharge solenoid valve (1) to the outlet of port E along the pipeline of port G.

In the opposite case, air flows through the pipeline in the order of A-B-C-G-E according to the second operation signal.

However, conventional pipes have many types of components, and accordingly, there is a problem in that airtightness is not maintained well if it is difficult to assemble and care is not taken during assembly. In addition, the space occupied by the construction is also large, there is a problem in that the assembly of the piping with the other connection pipe is very complicated and difficult to assemble.

The object of the present invention is to provide a solenoid valve that can conserve space and facilitate piping work by consolidating the solenoid valve piping equipment connected by the existing hose, thereby simplifying the function into a single block, thereby improving work efficiency. .

Another object of the present invention is to provide a solenoid valve that achieves accurate operation in the fluid operation surface, while stabilizing the performance while achieving a stable oxygen concentration by blocking the pipes and preventing pipe mistakes.

Technical features of the present invention for achieving the above object in forming a solenoid valve for oxygen generator,

A port a having an inlet through which compressed air is introduced, the port a being integrally formed with one inlet and a channel, and ports b and c disposed on both sides of the port a, and a port arranged in a symmetrical direction of the port a. A supply pipe block for connecting a pipe to one pipe, an outlet supply air direction switching valve block installed at an upper front of the supply pipe block and having an outlet pipe and an inlet pipe formed at an upper end thereof, and the direction from the top of the supply pipe block; It is arranged side by side with the switching valve block and the outlet is formed on the upper side and comprises a discharge solenoid block connected to the inlet side and the pressure supply pipe on one side.

The supply pipe block is connected to the direction switching valve block to form a passage through which the compressed air is discharged to the discharge pipe via the port a through the inlet, the predetermined pipe of the port d from the port c through the inlet pipe of the direction switching valve block It is made along the path to the discharge port of the discharge solenoid block disposed on the top of the supply pipeline block along.

The supply pipe block is connected to the direction switching valve block to form a passage through which the compressed air is discharged through the port a to the inlet pipe, and through the discharge pipe of the directional residual valve block, a predetermined amount of the port d to the port d. It includes a path that is discharged to the discharge port of the discharge solenoid block disposed on the top of the supply pipeline block along the pipeline.

1 is an overall perspective view of a structure combining a solenoid valve and a valve block according to the present invention,

2 is a perspective view showing a supply pipeline block according to the present invention,

3 is a first operation flow state according to the present invention,

4 is a second operation flow state according to the present invention,

5 is a structure of a conventional solenoid valve.

<Description of Symbols for Main Parts of Drawings>

10: supply pipeline block 12: inlet

20: direction switching valve block 22: discharge pipe

24: inlet pipe 30: discharge solenoid block

32: outlet 40: pressure supply pipe

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is an overall perspective view of a structure combining a solenoid valve and a valve block according to the present invention, Figure 2 is a perspective view showing a supply pipe block according to the present invention.

The solenoid valve and valve block combination structure for the oxygen generator of the present invention has a solenoid by arranging the direction switching valve block 20 and the discharge solenoid block 30 side by side at the top of the supply line block 10 as shown in FIG. 1. The solenoid assembly 100 which combined the valve and the valve block is comprised.

The supply pipeline block 10 has an inlet 12 through which compressed air is introduced, and a port a is integrally formed with the inlet 12 into one pipeline, and ports b disposed on both sides of the port a, Port c disposed in the symmetrical direction of the port a is connected to one pipe to make a pipe inside the block so that the air controlled by the solenoid valve assembly 100 can flow.

Directional valve block 20 for outflow supply air is installed in the upper front of the supply line block 10 and the discharge pipe 22 and the inlet pipe 24 is formed on the top. It has a function to change the air supplied from the compressor to the "B" or "C" direction at regular intervals according to the control electronic signal.

Discharge solenoid block 30 is arranged in parallel with the direction switching valve block 20 in the upper portion of the supply pipe block 10 and the discharge port 32 is formed on the upper side and the inlet 12 side and the pressure supply pipe 40 is connected. It has a function of turning on / off the exhaust gas used at regular intervals according to the control electronic signal.

The pressure supply pipe 40 is made of a small diameter tube and is used as a pilot pressure forming pipe in the discharge solenoid block 30 by connecting the discharge solenoid block 30 and the compressed air inlet of a predetermined pressure or more sent from the compressor.

3 is a first operational flow state according to the present invention, Figure 4 is a second operational flow state according to the present invention.

Supply passage block 10 of the present invention is connected to the direction switching valve block 20 as shown in Figure 3 has a passage through which the compressed air is discharged to the discharge pipe 22 via the port a through the inlet 12 have. In addition, the outlet 32 of the discharge solenoid block 30 disposed on the upper end of the supply passage block 10 along the predetermined passage of the port d from the port c through the inlet tube 24 of the directional valve block 20 Including the discharge path to the.

In addition, the supply pipe block 10 is connected to the direction switching valve block 20 as shown in Figure 4 has a passage through which the compressed air is discharged to the inlet pipe 24 via the port a through the inlet (12) have. In addition, through the discharge pipe 22 of the diverter valve block 20 from the port b to the discharge port 32 of the discharge solenoid block 30 disposed on the upper end of the supply pipe block 10 along a predetermined pipe of the port d. Including the discharge path.

It describes the operating state of the present invention made of such a configuration.

First, the flow of fluid (compressed air) is divided into a first operation and a second operation according to the electronic signal as shown in FIGS. 3 and 4.

In the first operation, the compressed air is supplied from the compressor to “A” as shown in FIG. 3. First, according to the signal, the system operation starts with “A” and then connects to the “F” pipe port a through C as shown in FIG. 3. It is done. The air from this C circulates and returns to B, where port c and port d of the G pipe are connected, and port b is blocked by the solenoid. The air discharged along the conduit is exhausted through the outlet through the discharge solenoid block 30 for a predetermined time according to the control signal.

In the second operation, as shown in FIG. 4, air flows through the conduit in the order of A-F (port a) -B-C-G (port b and port d) -E.

In the case of the discharge solenoid block, when the inner spool of the solenoid is returned, a pressure of 0.1 Mpa or more is required. When the exhaust is completely discharged, this pressure is lowered. Therefore, the return pressure is discharged using the additional pipe “D” using the pressure supply pipe 40. In addition to the block, it helps complete recovery to ensure reliable operation and stabilize the performance of the system.

From the above description, those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

As described above, the oxygen generator solenoid valve and the valve block combination structure according to the present invention can simplify the function by converging the plumbing facilities of the solenoid valve to make a single block to save space and easy piping work efficiency In addition, it improves the fluid operation and at the same time improves the performance of the stabilization of the performance, and the concentration of oxygen caused by the block is generated to prevent the mistakes in the pipe to achieve product reliability.

Claims (3)

In forming the solenoid valve and valve block combination structure for oxygen generator, A port a having an inlet through which compressed air is introduced, the port a being integrally formed with one inlet and a channel, and ports b and c disposed on both sides of the port a, and a port arranged in a symmetrical direction of the port a. Supply pipeline block for connecting a single pipeline, A supply air direction switching valve block installed at an upper front of the supply pipe block and having a discharge pipe and an inlet pipe formed at an upper end thereof; The solenoid valve for the oxygen generator, characterized in that formed in the upper side of the supply line block block and the outlet valve is formed in parallel with the discharge valve is connected to the inlet side and the pressure supply pipe on the upper side And valve block combination structure. The method of claim 1, The supply pipe block is connected to the direction switching valve block to form a passage through which the compressed air is discharged to the discharge pipe via the port a through the inlet, the predetermined pipe of the port d from the port c through the inlet pipe of the direction switching valve block A solenoid valve and valve block combination structure for an oxygen generator, characterized in that it comprises a path that is discharged to the outlet of the discharge solenoid block disposed on the top of the supply pipe block along. The method of claim 1, The supply passage block is connected to the direction switching valve block to form a passage through which the compressed air is discharged to the inlet pipe via the port a, and through the discharge pipe of the direction switching valve block from the port b to the predetermined pipe of the port d A solenoid valve and valve block combination structure for an oxygen generator, characterized in that it comprises a path that is discharged to the outlet of the discharge solenoid block disposed on the top of the supply pipe block along.