KR200294435Y1 - Flow controlling gear for gas-valve - Google Patents

Abstract

Disclosed is a flow control device for a gas valve which makes it possible to use the gas interchangeably with a simple operation in switching gas appliances according to the type of gas.

The flow rate adjusting device of the gas valve includes a valve cock for opening and closing the gas and determining a flow control position, a bypass coupled to the inside of the valve cock to adjust the flow rate according to the type of gas, and between the rotary shaft and the valve cock. In the spring to adjust the up and down drive, and the O-ring to prevent gas leakage from the valve cock to the outside.

Such a flow control device of the gas valve can save time due to the compatibility of the gas equipment, can not eliminate the risk of gas leakage because the valve is not disassembled, and additional costs such as service costs because the user can easily operate Does not cause

Description

Flow control gear for gas-valve

The present invention relates to a gas valve flow rate control device that can be used interchangeably with a simple operation in switching gas appliances according to the type of gas.

In general, gas equipment has to adjust the flow rate when LPG and LNG are compatible with each other according to the type of feed gas, because LPG has a large amount of heat per unit volume and LNG has a smaller amount of heat per unit volume than LPG.

In the gas flow rate control of such a gas machine, the interaction force is usually determined by a nozzle assembled outside the gas valve, and the neutralizing or weakening force is adjusted by passing through the determined injection diameter of the flow control plate mounted inside the gas valve. do.

1 is a sectional view of a conventional gas valve, FIG. 2 is a perspective view of a conventional flow control plate, FIG. 3 is a plan view of a conventional flow control plate in the case of LPG, and FIG. 4 is a plan view of a conventional flow control plate in the case of LNG. to be.

As shown in FIG. 1, the LPG and LNG combined gas valve is provided with a packing 2 on the inner surface of the valve body 1 to prevent leakage of gas at a portion leading to the gas supply pipe 3, and the packing ( Place the flow control plate (4) on the upper surface of 2) to adjust the flow rate of the gas.

The gas introduced from the gas inlet pipe 5 is supplied to the gas supply pipe 3 through the valve cock 6 controlled by the rotary shaft 7, by the flow control plate 4 according to LPG or LNG. The flow rate of the gas is regulated.

As shown in FIG. 2, the flow regulating plate 4 is provided with an LPG flow regulating hole 8 and an LNG flow regulating hole 9.

Usually, the LNG flow rate adjusting hole 9 has a diameter larger than that of the LPG flow rate adjusting hole 8 because the amount of generated heat of the LNG is lower than that of the LPG.

This flow control plate 4 is the difference in position between the two holes, only one hole is in communication with the gas, the other hole in contact with the packing (2) is sealed.

As shown in Fig. 3, when the? Mark engraved on the flow regulating plate 4 points to LPG, the LPG flow regulating hole 8 communicates with the supply gas, and the LNG flow regulating hole 9 is packed (2). Sealed by).

As shown in FIG. 4, when the flow control plate 4 is rotated 180 degrees in the position shown in FIG. 3 so that the ▲ mark indicates LNG, the flow rate adjusting hole 9 for LNG communicates with the supply gas and the flow rate control for LPG. The hole 8 is sealed by the packing 2.

Thus, in the conventional valve, in order to adjust the flow volume of gas, the direction of the flow control plate was changed according to the kind of gas, and it combined.

However, in the related art, when the type of gas used is changed, since the internal gas must be disassembled in the process of switching the gas device to control the gas flow rate, it takes a lot of time, and additional costs such as after-sales service are generated.

In addition, disassembling the valve also increased the risk of gas leakage.

As described above, in converting the gas equipment for controlling the flow rate of the gas, it takes a long time, additional costs such as after-sales service, and the problem of the risk of gas leakage eventually disassembles the valve of the gas equipment. There is a factor, and in order to solve this, it is necessary to adjust the flow rate of the gas with a simple operation.

Accordingly, an object of the present invention is to provide a gas valve flow rate control device that is switched to a simple operation according to the type of gas.

1 is a cross-sectional view of a conventional gas valve

2 is a perspective view of a conventional flow control plate

3 is a plan view of a conventional flow control plate in the case of LPG

4 is a plan view of a conventional flow control plate for LNG

5 is an exploded perspective view of a gas valve according to the present invention

6 is a cross-sectional view of the flow rate control device of the gas valve in the case of LPG

FIG. 7 is an enlarged view of portion A of FIG. 6; FIG.

8 is a cross-sectional view of the flow rate control device of the gas valve in the case of LNG

9 is an enlarged view of a portion B of FIG. 8;

※ Explanation of main parts of drawing

11: valve cock 12: spring

13: Bypass 14: O-ring

Gas flow rate control device for achieving the above object,

A valve cock that opens and closes gas and determines a flow control position, a bypass coupled to the inside of the valve cock to adjust the flow rate according to the type of gas, and a spring to adjust the vertical drive between the rotary shaft and the valve cock. O-ring for preventing gas leakage from the valve cock to the outside.

A hole penetrating the body is formed on the bypass side, and the lower portion of the hole is inclined, and the inside of the bypass processes the hole downward through the gas so as to communicate with the hole.

In addition, the bypass is screwed to the valve cock to turn the upper portion of the bypass so that the inclined surface of the bypass off the inner surface of the valve cock to form a predetermined space, in the case of LPG to be fitted to fit the inner surface of the valve cock The gas passes only through the hole, and in the case of LNG, the gas passes not only through the hole but also into the space between the valve cock and the bypass.

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

In the accompanying drawings, Figure 5 is an exploded perspective view of the gas valve according to the present invention, Figure 6 is a sectional view of the flow regulator of the gas valve in the case of LPG, Figure 7 is an enlarged view of a portion A of Figure 6, Figure 8 is LNG In the case, it is sectional drawing of the flow regulating apparatus of a gas valve, and FIG. 9 is the B part enlarged view of FIG.

As shown in FIG. 5, the gas valve is operated by the rotary shaft 22 connected to the gas cock 21, and is configured to be opened and closed by pressing and rotating the rotary shaft 22 to supply gas to the burner. .

The gas valve, the valve cock 11 for opening and closing the gas in the body 10 to determine the flow rate adjustment position, and a spring positioned between the rotary shaft 22 and the valve cock 11 to adjust the vertical movement ( 12), a bypass 13 for determining the flow rate according to the type of gas, and an O-ring 14 for preventing external leakage of the gas.

Here, the role of the bypass 13 is important, and if the bypass 13 is turned according to the gas used, the flow rate is adjusted so that a small amount of gas is discharged in the case of LPG, more in the case of LNG A positive amount of gas will flow out.

As shown in FIG. 6, a bypass 13, an o-ring 14, and a spring 12 enter and couple into the valve cock 11, and a lower portion of the bypass 13 is connected to the valve cock ( 11) It fits perfectly in the inner surface.

In the bypass 13, a hole 13a penetrating the body is processed to pass gas. In the case of LPG, the gas is passed only through the hole 13a. Therefore, the hole 13a is bypassed accordingly. (13) should be processed.

As shown in FIG. 7, a hole 13a is formed in the body of the bypass 13. The hole 13a communicates with the hole 13a and the center of the bypass 13 is drilled downward.

The bottom of the hole 13a is inclined to fit snugly to the inner surface of the valve cock 11, and LPG flows downward through the hole 13a through the hole 13a as indicated by the arrow.

As shown in FIG. 8, the bypass 13 coupled to the inside of the valve cock 11 is coupled to the inner surface of the valve cock 11 at a lower portion with a predetermined space, compared with FIG. 6. The bypass 13 is coupled to the upper by a predetermined height.

In this case, the bypass 13 is raised from the valve cock 11 by a predetermined height when it is returned from the upper portion by a simple operation using a driver or the like.

Therefore, in the case of LNG, since the gas passes through the hole 13a processed in the bypass 13 and the space away from the inner surface of the valve cock 11, more gas is passed than in the case of LPG. .

In particular, the space formed between the inner surface of the valve cock 11 and the bypass 13 is determined by the calorific value of LNG.

As shown in FIG. 9, a hole 13a is formed in the body of the bypass 13. The hole 13a communicates with the hole 13a and the center of the bypass 13 is drilled downward. The bottom of) is raised and coupled with the predetermined height from the valve cock 11 while being inclined to form a space.

Here, the LNG passes through the hole 13a and into the space formed by the valve cock 11 and the lower portion of the bypass 13 as indicated by the arrow, and flows downward of the bypass 13.

In this way, the flow control device of the gas valve according to the present invention is provided with a bypass to adjust the amount of gas inside the valve cock, by using a tool to simply return the bypass when the gas is used for LPG and LNG Make them compatible.

As described above, by providing a bypass in the valve cock which can adjust the amount of gas by simple operation according to the type of gas, it is possible to save time due to the compatibility of the gas equipment and risk of gas leakage because the valve is not disassembled. It can be excluded, and the user can easily operate, so that no additional costs such as service costs are incurred.

Claims (3)

In the flow control device of the gas valve, A valve cock 11 for opening and closing the gas and determining a flow control position; Bypass 13 is coupled to the inside of the valve cock 11 to adjust the flow rate according to the type of gas; A spring 12 for adjusting up and down driving between the rotary shaft 22 and the valve cock 11; Flow control device of the gas valve including an O-ring 14 for preventing gas leakage from the valve cock 11 to the outside The method of claim 1, The side of the bypass 13 is formed with a hole 13a penetrating the body, and the lower part of the hole 13a forms an inclined surface, and the inside of the bypass 13 communicates with the hole 13a. Flow regulating device of the gas valve, characterized in that the drilled downward The method of claim 2, Bypass 13 is screwed to the valve cock 11 to return the upper portion of the bypass 13 to the driver, the inclined surface of the bypass 13 is separated from the inner surface of the valve cock 11 to a predetermined space In the case of LPG, the valve cock 11 and the bypass 13 are connected by fitting the inner surface of the valve cock 11 so as to fit snugly, and in the case of LNG, by turning the bypass 13. Flow control device of the gas valve, characterized in that to form a space between the lower portion