KR100684970B1 - Outlet for gas structure of booster - Google Patents

Abstract

A gas discharge port structure for a booster is provided to guide a hazard gas into a port having a purification apparatus without changing structure of a gas discharge hole. A gas discharge port structure for a booster includes a body(10), upper and lower diaphragms(12,13), a stem(15), a gas passage(20), upper and lower sealing members(31,32), and a gas discharge hose(34). The upper and lower diaphragms are installed in the body through the medium of a spacer(11) to space apart the diaphragms from each other. The stem is supported at the center of the lower frame by a spring(14) to open and close a first opening/closing hole(16) formed at the lower diaphragm. The gas passage is formed at a lower side of the body. The upper and lower sealing members are fixed to an outer periphery of the body through the medium of "C" shaped rings(30). The gas discharge hose passes through the gas discharge hole.

Description

Outlet for gas structure of booster

1 is a cross-sectional configuration diagram of a booster generally used;

2A and 2B are cross-sectional views for explaining the booster action which are generally used;

3 is a cross-sectional view for explaining the gas outlet structure of the booster according to the present invention;

4a and 4b are cross-sectional views for explaining the gas outlet structure action of the booster according to the present invention.

※ Explanation of symbols about main part of drawing ※

10: body 11: spacing zone

12: upper diaphragm 13: lower diaphragm

14 spring 15 stem

16: the first opening and closing 17: the second opening and closing

18 gas inlet 19 gas supply port

20: gas furnace 21: gas drain sphere

30: "c" shaped ring 31: Upper sealing member

32: lower sealing member 33: gas discharge hole

34: gas discharge hose

 The present invention is to supply the air or gas of the appropriate pressure that causes the human body or air pollution to the actuator through the booster and to discharge the overpressure gas generated while supplying the actuator to the port without being directly discharged into the atmosphere It relates to the gas outlet structure of a booster that can be induced.

In general, the booster is installed on one side of the valve opening controller to supply a gas of an appropriate pressure to the actuator to induce the actuator to act accurately and quickly, which is shown in FIG. 1 and the configuration is as follows.

 Inside the body 10, the upper and lower diaphragms 12 and 13 are installed to be maintained at a predetermined interval through the interval holding means 11, and the upper and lower diaphragms 12 and 13 are installed to be maintained at the predetermined intervals. In the center of the lower diaphragm 13 is formed a first opening and closing hole 16, the lower end of which is opened and closed by an upper portion of the stem 15 supported by the spring 14, the lower portion of the first opening and closing hole 16 The body 10 has a second opening and closing hole 17 is opened and closed by the lower portion of the stem 15, the lower side of the body 10 is formed with a gas inlet 18 for injecting gas, the other A gas supply port 19 for supplying the injected gas to the actuator is formed on the side, and a gas path 20 for applying pressure to the upper diaphragm 12 is formed on the upper portion of the body, and the body is formed. End of the upper and lower diaphragms (12, 13) installed on the upper side of the (10) to be maintained at the constant interval Minutes and made a gas discharge hole 21 which is communicated to the type by sex.

The conventionally used booster action of the above-described configuration will be described in detail with reference to FIGS. 2A and 2B.

First, when gas is injected into the gas inlet 18 formed at one lower side of the body 10 and gas is supplied from the positioner through the gas passage 20, the upper diaphragm 12 is shown in FIG. 2A. When the upper diaphragm 12 is pressed downward, the lower diaphragm 13 is also pushed downward by the spacer 11 so that the stem 15 moves downward while extruding the spring 14. Will be

At this time, the upper part of the stem 15 moved downward closes the first opening and closing hole 16 formed in the center of the lower diaphragm 13, and the lower part of the stem 15 opens and closes the second. The ball 17 is opened. Therefore, the gas injected from the gas inlet 18 is supplied to the actuator through the second opening and closing hole 17 and the gas supply port 19.

However, when the gas injected from the gas inlet 18 is supplied to the actuator through the second opening and closing hole 17 and the gas supply port 19, the second opening and closing hole 17 and the gas supply port 19 When the pressure of the interspace S is higher than the pressure supplied from the positioner P through the gas passage 20, the high pressure pushes the lower diaphragm 13 upward as shown in Fig. 2B. When the lower diaphragm 13 is pushed upward as described above, the upper part of the stem 15 is spaced apart from the first opening / closing hole 16 to open the first opening / closing hole 16 and the overpressure of the space S. Gas is discharged to the gas discharge hole 21 through the first opening and closing hole 16 and the upper and lower diaphragms 12 and 13.

Meanwhile, a plurality of gas discharge holes 21 may be formed along a circumferential surface, and a plurality of gas discharge holes 21 may be discharged only to the gas discharge holes 21 of any one selected side, or a plurality of gas discharge holes 21 may be discharged. The gas discharge holes 21 may be discharged to all of the formed gas discharge holes 21.

In addition, the gas discharge hole 21 may be coupled to a separate connection pipe 22 to discharge gas to the connection pipe 22, which is the connection pipe 22 inside the gas discharge hole 21. Since the connection tube 22 is fastened to the diameter (inner diameter) is smaller than the diameter of the gas discharge hole 21, there is a problem that the discharge of gas is not made smoothly and quickly.

In order to solve the above problems, the diameter (inner diameter) of the connection pipe 22 should be the same as the diameter of the gas discharge hole 21. In order to do so, the diameter of the gas discharge hole 21 may be changed. It must be extended by the thickness, which causes a problem that comes with the difficulty of working.

Also. The gas discharged to the gas discharge hole 21 is harmful to the human body and increases the air pollution, so when the discharge place is an enclosed space, it may damage the health of the person and may also threaten life. When the discharged place is the air, there is a problem of increasing the air pollution.

The present invention has been invented to solve this problem in view of the above problems, the purpose of which can be used as it is without changing the gas discharge hole of the booster generally used, of course, the letter "c" shaped to the gas discharge hole The ring of the upper and lower sealing member is installed through the medium, the ring of the "c" shaped fixedly installed through the sealing member, the gas discharge hole is formed through the selected place, the gas discharge hole in the end of the gas discharge hose to the gas discharge It is installed to be decomposable and airtight from the ball so that the gas harmful to the human body discharged to the gas discharge hole can be led to a port having a purification facility, and the gas discharge hole can be used without changing the structure. It is to provide a gas outlet structure of the booster.

Characteristic technical features of the present invention for achieving the above object, the upper and lower diaphragms (12, 13) are installed to be maintained at a predetermined interval inside the body 10, the interval holding means 11, In the center of the lower diaphragm 13 among the diaphragms 12 and 13 installed to be maintained at a constant interval, a first opening / closing hole 16 whose lower end is opened and closed by an upper part of the stem 15 supported by the spring 14 is formed. The lower body 10 of the first opening and closing hole 16 is formed with a second opening and closing hole 17 which is opened and closed by a lower portion of the stem 15, and a gas is injected into one lower side of the body 10. A gas injection port 18 is formed, and on the other side, a gas supply port 19 for supplying the injected gas to the actuator is formed, and the upper portion of the body receives pressure from the positioner and presses the upper diaphragm 12. A gas path 20 to be applied is formed, and the upper side of the body 10 In the end portion and in communication with the gas exhaust hole 21 of the upper and lower diaphragm maintained constant gap provided in the conventional booster so as to form,

On the outer circumferential surface of the body on which the gas discharge hole 21 is formed, a "c" shaped ring 30 surrounding the outer circumferential surface is fixedly installed through the upper and lower sealing members 31 and 32 and fixedly installed through the sealing member. Where the "c" shaped ring is selected, the gas discharge hole 33 is formed through the gas discharge hole, and the end of the gas discharge hose 34 is decomposed and coupled from the gas discharge hole and is installed to maintain airtightness. Is done.

The booster gas outlet structure of the present invention having the above characteristics will be described in detail with reference to FIGS. 3 to 4A and 4B as follows.

Booster action of the present invention is the same as the conventional booster action when described in detail as follows.

When the gas is injected into the gas inlet 18 formed at one lower side of the body 10 and the gas is supplied through the gas passage 20 from the positioner, the upper diaphragm 12 is pressurized as shown in FIG. 4A. The lower diaphragm 13 is also pushed downward by the gap retaining hole 11 while being pressed downward to move the stem 15 downward. At this time, the spring 14 installed below the stem 15 is compressed.

As described above, when the stem 15 is moved downward, the upper part of the stem 15 closes the first opening and closing hole 16 formed in the center of the lower diaphragm 13 and closes the stem ( The lower part of 15) opens the second opening and closing hole 17. Therefore, the gas injected from the gas inlet 18 is supplied to the actuator through the second opening and closing hole 17 and the gas supply port 19.

However, when the gas injected from the gas inlet 18 is supplied to the actuator through the second opening and closing hole 17 and the gas supply port 19, the second opening and closing hole 17 and the gas supply port 19 When the pressure of the interspace S is higher than the pressure supplied from the positioner through the gas passage 20, the high pressure pushes the lower diaphragm 13 upward as shown in Fig. 4B, and thus the lower dia. If the upper part of the stem 15 is pushed to the upper part of the stem 15 is opened from the first opening and closing hole 16, the first opening and closing hole 16 is opened.

When the stem 15 moves upwards, since the lower part of the stem does not rise any more due to the second opening / closure hole 17, the upper portion of the stem 15 is spaced apart from the first opening / closing hole 16 to open the first opening / closing. Opening the ball 16, therefore, the gas pressurized gas in the space (S) is a gas discharge hole 21 between the first opening and closing hole 16 and the upper and lower diaphragms (12, 13) Will be released.

As such, when the pressure in the space S between the second opening and closing hole 17 and the gas supply port 19 is released to the gas discharge hole 21, the internal pressure of the booster maintains a uniform pressure. When the uniform pressure is maintained, normal gas is maintained as shown in FIG. 4A to supply an appropriate pressure to the actuator.

On the other hand, the gas discharged to the gas discharge hole 21 is harmful to the human body and should not be emitted directly to the atmosphere, and guides the harmful gas to a port having a purification facility (not shown) and then harmful components from the port. After removing the bar should only release the harmless gas, the upper and lower sealing members (31, 32) of the "c" shaped ring 30 surrounding the outer circumferential surface on the outer circumferential surface of the body for the gas discharge hole 21 is formed therefor. The gas discharge hole 33 is formed in the selected position of the "C" shaped ring 30 fixedly installed through the sealing member, and the gas discharge hole 33 is formed in the gas discharge hole 33. ) End is installed to be decomposable from the gas discharge hole 33 and to maintain airtightness.

The reason why the “c” shaped ring 30 surrounding the outer circumferential surface is installed on the outer circumferential surface of the body 10 in which the gas discharge hole 21 is formed, the end of the gas discharge hose 34 is firm and airtight. In order to be able to maintain the installation and at the same time to secure a space of a predetermined size between the outer circumferential surface of the body 10 formed with the gas discharge hole 21 and the inner circumferential surface of the "c" shaped ring 30.

The reason why a predetermined size of space is secured between the outer circumferential surface of the body 10 in which the gas discharge hole 21 is formed and the inner circumferential surface of the “c” shaped ring 30 is provided in the “c” shaped ring 30. This is because the groove height t is larger than the inner diameter of the gas discharge hole 21.

However, when the shape of the ring 30 is not a "c" shape but a vertical type, when the ring 30 is coupled to the body 10, the gas discharge hole 33 and the body 10 formed in the ring 30 are formed. The gas discharge hole 21 formed in the) should be aligned in a straight line, because the matching operation is difficult to form a "c" shaped ring 30.

In addition, although the end of the gas discharge hose 34 may be directly installed in the gas discharge hole 21, the upper and lower diaphragms 12 and 13 are positioned at the upper and lower surfaces of the gas discharge hole 21. There is a problem that the end of the gas discharge hose 34 can not be installed to maintain the airtightness. Therefore, to install the "c" shaped ring 30 surrounding the outer circumferential surface on the outer circumferential surface of the body 10, the gas discharge hole 21 is formed.

The upper and lower sealing members 31 and 32 are interposed between the ring-shaped ring 30 and the body 10, respectively, for the reason of the ring-shaped ring 30 and the body 10. This is to ensure airtightness between) and prevent leakage.

In addition, the gas discharge hole 33 formed in the "c" -shaped ring 30 is installed to maintain the airtightness and the end of the gas discharge hose 34 can be decomposed and coupled from the gas discharge hole 33, The reason is that when the gas supplied to the gas injection hole 18 is a harmless gas instead of a harmful gas, the gas discharge hose 34 does not need to be fastened, so the gas discharge hose 34 is replaced by the gas discharge hole 33. What is necessary is to separate it from) and discharge it directly to the gas discharge hole 33.

However, the end of the gas discharge hose 34 which is fastened to the gas discharge hole 33 is formed with a fastener so that the gas discharge hole 33 is decomposable.

In addition, the gas discharge hole 33 formed at the selected position of the "c" -shaped ring 30 may be formed at one position of any one selected side of the ring 30 or may be formed at two or more positions. do.

The present invention as described above can be used as it is without changing the gas discharge hole of the booster generally used, of course, the "c" shaped ring is fixed to the gas discharge hole via the upper and lower sealing members, The “c” shaped ring fixedly installed through the sealing member has a gas discharge hole formed therethrough, and the gas discharge hole is installed in the gas discharge hole so that the end of the gas discharge hose is decomposable from the gas discharge hole and is kept airtight. It is possible to direct harmful gas emitted to the gas discharge hole to the port where the purification facility is located, so that the harmful gas used in the booster is not directly discharged to the atmosphere.

Claims (3)

The upper and lower diaphragms 12 and 13 are installed in the body 10 so as to be maintained at a predetermined interval through the interval holding means 11, and the lower dia of the diaphragms 12 and 13 installed to be maintained at the predetermined intervals. The first opening and closing hole 16 of the first opening and closing hole 16 is formed at the center of the fram 13, the lower end of which is opened and closed by an upper portion of the stem 15 supported by the spring 14. The second opening and closing hole 17 which is opened and closed by the lower part of the stem (15) is formed, the lower side of the body 10 is formed with a gas inlet 18 for injecting gas, the other side of the injection A gas supply port 19 for supplying a gas to an actuator is formed, and a gas passage 20 for applying pressure from the positioner to the upper diaphragm 12 is formed at an upper portion of the body, and the body 10 The upper side of the communication with the end of the upper and lower diaphragm installed to maintain the predetermined interval In the ordinary booster formed by forming the gas discharge hole 21, On the outer circumferential surface of the body on which the gas discharge hole 21 is formed, a "c" shaped ring 30 surrounding the outer circumferential surface is fixedly installed through the upper and lower sealing members 31 and 32 and fixedly installed through the sealing member. Where the "c" shaped ring is selected, a gas discharge hole 33 is formed through the gas discharge hole, and the end of the gas discharge hose 34 is decomposable from the gas discharge hole and installed to maintain airtightness. The gas outlet structure of the booster characterized by the above-mentioned. 2. The gas outlet structure of the booster according to claim 1, wherein at least two gas outlet holes (33) formed at the selected portion of the "-" ring are selected. The gas outlet structure of the booster according to claim 1, wherein the height t of the inner ring of the '-' shape is larger than the inner diameter of the gas discharge hole.

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