KR20050018181A - Automatic changeover valve - Google Patents

Abstract

PURPOSE: An automatic switching valve is provided to prevent waste of gas, and to check flow direction of high pressure gas simply by connecting a gas storage container to the other gas storage container timely and safely. CONSTITUTION: An automatic switching valve comprises a housing member(10) having a first gas inlet, a second gas inlet, a gas outlet intersecting two gas inlets and an internal space, a valve body(20) installed in the gas inlet of the housing member and moved horizontally in applying high pressure gas, a bellows member(30) embedded in the housing member, contracted and moved up in applying high pressure gas from the gas inlets and moved down by restoring force, a vertical moving shaft member(40) combined with the bellows member, moved up and down in contracting and expanding the bellows member and placed between the gas inlets, a cam contact projection(50) protruded in the surface of the vertical moving shaft member, and a cam member(60) combined with the cam contact projection, contacted to the valve body and inclined to flow gas from the first or second gas inlet in fitting the cam contact projection to the semi-arc.

Description

Automatic changeover valve

The present invention relates to a valve, and more particularly, when gas is provided from two gas inlets and discharged to one gas outlet, when the pressure of the gas provided from one gas inlet supplied is lower than the set pressure, The present invention relates to an automatic switching valve that opens another gas inlet and receives gas from the other gas inlet to prevent the supply of gas.

In general, when various high pressure liquefied gas and high pressure compressed gas are used for reaction, decomposition, replacement, pressurization, combustion, etc., in case of temporarily consuming a large amount of gas, two gas supply storage containers are prepared and stored. When the gas contained in the container is exhausted, the gas contained in the other storage container is discharged so that the supply of high pressure gas is not interrupted. In particular, when the consumption of high pressure gas is not always constant and fluctuates widely, the necessity of ensuring a safe and reliable gas demand becomes even higher. At this time, a switch from one storage container to another storage container was installed by a manual switching device, a high-pressure gas supplier or a consumer (user) opened or closed manually or using a manual reset automatic switching device.

However, the conventional manual switching switchgear is safe because the user or supplier switches manually, but there is an uncertainty of missing the replacement time, and even though the gas remains in one gas storage container, the gas stored in the other gas storage container is used. There was a problem that there is a lot of waste of gas.

In addition, the manual reset automatic switching device loses all of the high pressure gas stored in the two gas storage containers, and there is a problem such as a shortage of supply of the high pressure gas due to the failure of the automatic switching device or a supply uncertainty due to the replacement uncertainty. . When gas supply is insufficient or stops, abnormal pressure is generated to explode due to gas reaction, poisoning due to poor disinfection of water supply, carbon monoxide poisoning due to collective supply of LPG gas, or nitrogen oxide due to insufficient ammonia treatment of boiler exhaust. There was a big problem that an accident such as a mass occurrence of a kind occurs.

In addition, the conventional apparatus uses an axial rotation and a pressure gauge by a glass window, an O-ring, a seal, etc., in order to display the flow direction of a high pressure gas. However, due to this, there is a problem that uncertainty such as wrong operation occurs due to leakage or misunderstanding, and it is easy to secure safety.

The present invention has been proposed to solve the above-mentioned problems, the object of which can be connected to one gas storage container to another gas storage container in a safe and accurate replacement time, there is no waste of gas, To provide an automatic switching valve that can simply know the flow direction of the high pressure gas.

The automatic switching valve according to the present invention for achieving the above object, the first gas inlet and the second gas inlet is formed at both ends, respectively, and includes a gas outlet crossing the respective gas inlet, the inner space A housing member having a housing member, a valve body member installed at the gas inlet inside the housing member and moved horizontally by a high pressure gas provided therein, and a high pressure provided from the gas inlet, A bellows member contracted upward by gas and having a restoring force downward, and coupled with the bellows member, and rising and falling in the same direction as the contracted expansion direction of the bellows member, between the gas inlets; A vertical movable shaft member positioned at the cam, a cam contact protrusion projecting from a surface of the vertical movable shaft member, and coupled to the cam contact protrusion; And both ends thereof come into contact with the valve body member and include an inner space of a half arc formed symmetrically with respect to a center line thereof, and when the cam contact protrusion is caught in the one half arc, gas is introduced from the first gas inlet. It is inclined, characterized in that it comprises a cam member inclined so that the gas flows from the second gas inlet when the cam contact projection is caught in the other half arc.

Hereinafter, an automatic switching valve according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 show an automatic switching valve according to an embodiment of the present invention, Figure 1 is an external view of the automatic switching valve according to an embodiment of the present invention, Figure 2 is an automatic switching valve shown in FIG. 3 to 6 are views for explaining the state of use of the automatic switching valve shown in Figure 1, respectively.

As shown in Figures 1 to 6, the automatic switching valve 100 according to an embodiment of the present invention is a housing member 10, the valve body member 20, the bellows member 30, The vertical moving shaft member 40, the cam contact protrusion 50, the cam member 60, and the external flow display member 80 are included.

The housing member 10 has a first gas inlet 12 and a second gas inlet 14 at both ends thereof, respectively, and a gas outlet 16 through which gas is discharged at a position crossing the respective gas inlets. It has internal space.

The valve body member 20 is installed in the first gas inlet 12 and the second gas inlet 14 in the housing member 10, respectively, and move in a horizontal direction by the provided high pressure gas, The valve seat 22, the valve sleeve 23, the valve body portion 24, the sleeve spring press plate 25 and the sleeve spring 26 are included.

As shown in FIG. 2, the valve seat 22 contacts and is spaced apart from each of the first gas inlets 12 and the second gas inlets 14 to open and close the respective gas inlets. In addition, the valve seat 22 is preferably made of Teflon or hard rubber material.

The valve sleeve 23 is coupled to the valve seat 22 and surrounds the valve seat 22 and has an inner space.

The valve body 24 is fixed to the valve sleeve 23 in the inner space of the valve sleeve 23 and in contact with the valve seat 22.

The sleeve spring presser plate 25 protrudes from an end of the valve sleeve 23 and contacts the cam member 60.

The sleeve spring 26 is fitted between the sleeve spring pressing plate 25 and the valve body portion 24. The sleeve spring 26 presses the valve seat 22 to the gas inlet through which gas does not flow, thereby maintaining the airtightness of the gas inlet.

The bellows member 30 is embedded in the housing member 10, is contracted upward by the high pressure gas provided from the gas inlet, and is raised to have a restoring force downward.

The vertical movable shaft member 40 is coupled to the bellows member 30, and ascends and descends in the same direction as the shrinkage expansion direction of the bellows member, and is located between the gas inlets.

On the other hand, in the present embodiment, the switching pressure setting member 70 is further provided to set the switching pressure from the first gas inlet 12 to the second gas inlet 14. The switching pressure setting member 70 includes a receiving groove 72, a pressure regulating spring 74, a pressure regulating spring pressing plate 76, and an adjusting bolt 78.

The receiving groove 72 has a shape that is dug downward from the upper end of the vertical movable shaft member 40.

The pressure regulation spring 74 is accommodated in the receiving groove (72).

The pressure regulating spring pressing plate 76 is in contact with the pressure regulating spring 74 at the upper end of the pressure regulating spring 74.

The adjusting bolt 78 presses the pressure regulating spring pressing plate 76 downward to compress the pressure regulating spring 74 downward corresponding to the desired switching pressure. The adjustment bolt 78 is not moved by the nut 79 is fixed to the housing member (10).

Therefore, when the pressure regulating spring 74 is compressed as the bellows member 30 rises, and the force of the gas that raises the bellows member 30 is smaller than the restoring force of the pressure regulating spring 74. By the restoring force of the pressure regulating spring 74, the pressure regulating spring 74 provides a restoring force downward, and accordingly, the bellows member 30 moves downward so that the cam member 60 moves in the opposite direction. It will be tilted.

The cam contact protrusion 50 protrudes from the surface of the vertical movable shaft member 40.

The cam member 60 has an inner space in which two half arc shapes composed of a first inner half arc 62 and a second inner half arc 64 are attached to each other side by side, and the first inner half arc 62 and the first inner half arc 62 and the second inner half arc 64 are attached to each other. The point where the inner half arc 64 meets the center line of the cam member 60. The cam contact protrusion 50 is in contact with any one of the first inner half 62 and the second inner half 64 and has an arc shape having a circular arc shape opposite to the half arc of the inner space. 66 is formed in the outer surface. And both ends of the arc portion 66 is in contact with the valve body member 20, respectively. That is, the cam member 60 has a shape of a mortar, as a whole, the first inner half 62 and the second inner half 64 in a direction opposite to the circular arc 66 opposite to the center line thereof. Side by side is formed in the interior space. Therefore, when the cam contact projection 50 is caught in the one half arc, the gas is inclined so that the gas enters from the first gas inlet, and when the cam contact protrusion 50 is caught in the other half arc, The gas is inclined to flow in.

The external flow display member 80 is provided to view the flow direction of the gas to the outside, and includes a depression 82, a display 84, and a permanent magnet 86.

The depression 82 is formed on the outer surface of the housing member 10 and its surface is curved in a yaw shape.

The display portion 84 is formed with an English alphabet letter T formed on the surface of the depression 82.

The permanent magnet 86 is located on the upper surface of the display portion 84 and is coupled to the cam member 60, and flows to the left and right along the depression (82). The permanent magnet 86 moves in accordance with the flow of the cam member 60 to cover a part of the display unit 84 so that the direction of flow of the gas in the direction of the arrow of the display unit 84 can be confirmed.

On the other hand, in the present embodiment is provided to be able to check the flow direction of the gas at a long distance, the transmitter 90 is further provided.

The transmitter 90 is installed at both ends of the housing member 10, and includes a reed switch (not shown) coupled to the permanent magnet 86 and operated according to the position of the permanent magnet 86, According to the left and right positions of the permanent magnet 86, the reed switch corresponding to each position is to generate a signal.

Automatic switching valve 100 according to an embodiment of the present invention having the configuration as described above is used as follows.

The automatic switching valve 100 according to the embodiment of the present invention is mainly used when consuming high pressure gas as a transportable high pressure gas container, and as shown in FIG. 3, the first gas storage container 200 in the left pipe. And, the manual on-off valve 210 and the strainer 220 is attached to the first gas inlet 12 of the automatic switching valve 100, the second gas storage container 300 in the same way to the right pipe And, the manual on-off valve 310, the strainer 320 is attached and installed in the second gas inlet 14 of the automatic switching valve 100.

The gas outlet 16 is connected to a consumer side pipe using gas, and a bypass valve (410) is attached in order to ensure the gas flow so that high pressure gas can be supplied even by manual operation. -Pass) Install the valve 510 in the left and right pipes respectively. In this way, even during regular inspection and overhaul (removable for repair), high-pressure gas can be continuously supplied by manual operation. Reference numeral 700 in FIG. 3 shows an example of a pipe on the consumer side using gas, and reference numeral 800 shows a signal generated by the oscillator 90.

Next, the operation of the automatic switching valve 100 of the present invention will be described.

Set the desired switching pressure in the preceding operation. To this end, by rotating the control bolt 78 to press the pressure control spring pressing plate 76 pressure control spring 74 to compress the pressure control spring (74). In other words, when the pressure regulating spring 74 is compressed according to a desired switching force, and the pressure of the gas flowing into the housing member 10 is smaller than the restoring force of the pressure regulating spring 74, that is, the desired switching When the pressure is reached, the restoring force of the pressure regulating spring 74 is acted to flow the cam member 60.

Next, a description will be given from a case where a gas is supplied from the first gas inlet 12 and no gas is supplied to the second gas inlet 14 at this time.

That is, when the pressure of the gas provided from the first gas inlet 12 is higher than the pressure of the gas provided from the second gas inlet 14, the valve body member provided on the first gas inlet 12 side ( 20 retreats in the traveling direction of the gas, and gas flows into the housing member 10 from the first gas inlet 12.

Accordingly, the end of the sleeve spring pressing plate 25 of the valve body member 20 pushes the cam member 60, and the bellows member 30 moves upward by the force of the supplied gas. The vertical movement shaft member 40 moves upward while the pressure regulating spring 74 coupled with the bellows member 30 is compressed with the upward movement of the bellows member 30.

Accordingly, as the cam contact protrusion 50 moves to the upper end of the second inner half 64, the cam member 60 is inclined. Accordingly, the end of the sleeve spring pressing plate 25 of the valve body member 20 provided at the side of the second gas inlet 14 is pressed in the direction in which the second gas inlet 14 is located. The valve body portion 24 and the valve sleeve 23 move in the direction in which the second gas inlet 14 is located, and the valve seat 22 is in close contact with the second gas inlet 14 so that the second gas inlet is closed. 14 is completely enclosed and no gas is introduced. At this time, the sleeve spring 26 is in a compressed state, and the airtightness of the second gas inlet 14 is made more firm by the restoring force of the sleeve spring 26, and the second gas inlet 14 is positioned. Flow other than the flow in the horizontal direction is absorbed by the sleeve spring 26.

At this time, since the permanent magnet 86 connected to the cam member 60 is moved to the right to obscure the arrow on the right side, the display unit 84 has an "a" shaped arrow, so that the first externally It can be seen that gas is introduced from the gas inlet 12 and discharged to the gas outlet 16. In addition, the reed switch of the oscillator 90 which is coupled to the permanent magnet 86 and located at the right side of the housing member 10 operates to generate a signal so that the flow direction of the gas can be checked even at a long distance.

When the high pressure gas is continuously supplied from the first gas inlet 12, and the amount of supply of the high pressure gas decreases or disappears, that is, when the pressure of the supplied gas becomes smaller than the preset switching pressure, the pressure regulating spring 74 is restored. It moves downward so that the bellows member 30 is also moved downward, and thus the vertical movement shaft member 40 is also moved downward.

The cam contact protrusion 50 also moves downward as the vertical movement shaft member 40 moves downward, and the cam contact protrusion 50 moves downward along the second inner half 64. The first inner half 62 is crossed by the first inner half 62 and the second inner half 62.

Accordingly, the cam member 60 is inclined again in a direction opposite to the direction inclined again. As the cam member 60 is inclined in the opposite direction, the first gas inlet 12 is positioned with the valve body member 20 in which the cam member 60 is positioned at the first gas inlet 12. To the first gas inlet 12, the valve seat 22 of the valve body member 20 located at the side of the first gas inlet 12 blocks the first gas inlet 12. ) No more gas flow.

At the same time, as the cam member 60 pushes the valve body member 20 located at the second gas inlet 14 side, the valve body member located at the second gas inlet 14 side is removed. 20 is moved in the direction where the first gas inlet 12 is located. Therefore, the high pressure gas flows in from the second gas inlet 14.

Accordingly, since the permanent magnet 86 is moved to the left to cover the left part of the display, it can be seen that there is a flow of gas from the second gas inlet 14 to the gas outlet 16 from the outside. will be. As described above, the gas flow direction can be confirmed at a long distance by the signal sent from the oscillator 90.

In this way, the switch from the first gas inlet 12 to the second gas inlet 14 takes approximately 0.01 seconds. Therefore, the switching is made in a very short time.

When the high-pressure gas flows from the second gas inlet 14, the operation as described above is repeated.

That is, the vertical movement shaft member 40 is moved upward while the bellows member 30 and the pressure regulating spring 74 are compressed upward by the high pressure gas provided from the second gas inlet 14. . Accordingly, the cam contact protrusion 50 is moved to the upper end of the first inner half 62 of the cam member 60, the gas pressure provided from the second gas inlet 14 is smaller than the set switching pressure When the bellows member 30 and the pressure control spring 74 is expanded downward, the vertical movable shaft member 40 is moved downward. Accordingly, the cam contact protrusion 50 moves from the first inner half 62 to the second inner half 64 and the cam member 60 is inclined in the opposite direction.

As the above-described process is repeated, the gas inlet from the first gas inlet 12 and the gas inlet from the second gas inlet 14 are repeated.

As described above, according to the automatic switching valve according to the present invention, it is possible to connect to one gas storage container to another gas storage container at a safe and accurate replacement time, there is no waste of gas, and simply It is effective to know the flow direction.

Although the present invention has been described with reference to the embodiments shown in the accompanying drawings, it is intended to be illustrative, and those skilled in the art will understand that various modifications and equivalent embodiments are possible from this. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1 is an external view of an automatic switching valve according to an embodiment of the present invention

Figure 2 is an internal cross-sectional view of the automatic switching valve shown in FIG.

3 to 6 are views for explaining the use state of the automatic switching valve shown in FIG.

<Description of Symbols for Main Parts of Drawings>

10. Housing member 20. Valve body member

30. Bellows member 40. Vertical moving shaft member

50. Cam contact protrusion 60. Cam member

70. Switching pressure setting member 80. External flow display member

90. Transmitter

Claims (8)

A housing member having a first gas inlet and a second gas inlet at both ends thereof, the gas outlet intersecting the respective gas inlets, and having an inner space; Valve body members installed at the gas inlets inside the housing member and moved in a horizontal direction by the high pressure gas provided; A bellows member embedded in the housing member and contracted upward by a high pressure gas provided from the gas inlet and having a restoring force upwardly; A vertical movement shaft member coupled to the bellows member and rising and falling in the same direction as the shrinkage expansion direction of the bellows member and positioned between the gas inlets; A cam contact protrusion projecting from the surface of the vertical movable shaft member; It is coupled to the cam contact projections and both ends thereof are in contact with the valve body member, and includes an inner space of the half arc formed symmetrically with respect to the center line, and when the cam contact projection is caught in any one of the half arc, the first gas inlet And a cam member inclined such that gas is introduced from the cam contact protrusion and the cam contact protrusion is inclined to allow gas to be introduced from the second gas inlet when the cam contact protrusion is caught on the other half of the door. The method of claim 1, The cam member, A first inner half arc and a second inner half arc formed in an inner space and attached side by side opposite to a center line thereof; It is formed on the outer surface and has an arc portion having an arc shape in the opposite direction to the inner half arc, Each valve body member is in contact with both ends of the arc portion, the automatic switching valve characterized in that it has a mortar shape as a whole. The method of claim 1, In order to set the switching pressure from the first gas inlet to the second gas inlet, The upper end of the vertical shaft member is provided with a receiving groove that is dug downwards, A pressure regulating spring accommodated in the receiving groove; A pressure regulating spring press plate in contact with the pressure regulating spring at the upper end of the pressure regulating spring; Further comprising a control bolt for pressing the pressure control spring pressing plate downward to compress the pressure control spring downward corresponding to the desired switching pressure, When the pressure regulating spring is compressed according to the rising of the bellows member, and the force of the gas that raises the bellows member is smaller than the restoring force of the pressure regulating spring, the pressure regulating spring is restored by the restoring force of the pressure regulating spring. Providing a restoring force downward and thus the bellows member is moved downward so that the cam member is inclined in the opposite direction. The method of claim 1, Each valve body member, A valve seat contacting and spaced apart from each gas inlet to open and close each gas inlet; A valve sleeve coupled to the valve seat and having an inner space surrounding the valve seat; A valve body portion fixed to the valve sleeve in the inner space of the valve sleeve and in contact with the valve seat; A sleeve spring pressing plate protruding from an end of the valve sleeve and contacting the cam member; A sleeve spring fitted between the sleeve spring pressing plate and the valve body portion, Automatic switching valve, characterized in that to maintain the air tightness of the gas inlet gas is not introduced by the compression force of the sleeve spring. The method of claim 4, wherein The valve seat is an automatic switching valve, characterized in that made of Teflon material. The method of claim 4, wherein The valve seat is an automatic switching valve, characterized in that made of hard rubber material. The method of claim 1, In order to make the flow direction of the gas visible to the outside, A depression formed on an outer surface of the housing member; A display unit in which an arrow having an English alphabet letter T formed on a surface of the recess is formed; Located on the upper surface of the display unit and coupled to the cam member, provided with a permanent magnet that flows from side to side along the depression, And the permanent magnet moves together with the flow of the cam member to cover a portion of the display unit, thereby checking the flow direction of the gas in the direction of the arrow of the display unit. The method of claim 1, In order to check the flow direction of the gas at a long distance, Respectively provided at both ends of the housing member, the transmitter having a transmitter coupled to the permanent magnet and including a reed switch operated according to the position of the permanent magnet, And a reed switch of the transmitter corresponding to the position according to the left and right positions of the permanent magnets to generate a signal.