KR100801478B1 - The gas regulation governor of the carbon dioxide - Google Patents

Abstract

The present invention relates to a gas pressure regulator of carbon dioxide.

According to the present invention, a regulator body and a regulator cap are coupled to each other, and a diaphragm is interposed between the regulator body and the regulator cap, and the screw shaft having a handle is coupled to the regulator cap. The cap is formed integrally with a plurality of heat dissipation pieces having a rectangular panel shape on the surface formed in a conical shape, a low pressure gauge fastening groove is formed on one side of the regulator body and a first male screw on the other side of the low pressure gauge fastening groove. A fastening portion having a fastening portion, a space portion is formed at the center of the fastening portion, and a non-return valve connected to the high pressure flow path is coupled to the center of the space portion, and a taper is connected between the end portion of the low pressure gauge fastening groove and the space portion. A plurality of low pressure flow passages having a shape are formed, and a safety valve on the regulator body It becomes combined features arranged to be safe flow path is connected to the safety valve is connected to the space portion.

Regulator Cap, Diaphragm, Carbon Dioxide, Heat Sink, High Pressure Channel, Low Pressure Channel, Safety Valve

Description

The gas regulation governor of the carbon dioxide

1 is an exemplary view showing a state in which a gas pressure regulator according to the present invention is coupled to a gas tank.

Figure 2 is an exploded perspective view of the gas pressure regulator according to the present invention.

Figure 3a is a state in which the non-return valve of the gas pressure regulator according to the present invention is blocked, 3b is a longitudinal cross-sectional view of the open state check valve.

Figure 4 is a rear perspective view of the gas pressure regulator according to the present invention.

5 is a rear perspective view of the gas pressure regulator according to the present invention;

Figure 6 is a perspective view of the regulator body of the gas pressure regulator according to the present invention.

<Brief description of symbols for the main parts of the drawings>

100: regulator body 110: heat dissipation piece

120: Low pressure gauge fastening groove 130: Fastening portion

131: first male thread 140: space

150: high pressure flow path 160: low pressure flow path

170: Safety flow path 200: Regulator cap

210: handle 220: screw shaft

300: diaphragm 400: check valve

500: safety valve

The present invention relates to a gas pressure regulator of carbon dioxide, in particular, a high pressure gas is introduced into the space portion is divided into a diaphragm through the backflow prevention valve inside the regulator body, a plurality of low pressure gas introduced into the space portion formed in the space portion By allowing the low temperature heat generated in the process of being pushed down through the seizure furnace to be easily released to the outside, the diaphragm embedded in the inside caused by the cryogenic temperature is not damaged, so that it can be used for a long time. Using a high pressure and low pressure gauge coupled to the body to easily control the opening and closing amount of the non-return valve using a single handle coupled to the regulator cap.

In general, carbon dioxide is a colorless gas with a specific gravity of 1.529 and sublimation point of -78.50 ℃ for air 1. Its purpose is to use liquefied carbonic acid, dissolved in water, as a soft drink. It is used as a fire extinguishing agent, and thermally expands it to be used as a refrigerant called dry ice.

Carbon dioxide is usually used to reduce the pressure through a separate carbon dioxide gas supply device. The carbon dioxide gas supply device is composed of a gas tank, a pressure regulator coupled to the outlet of the gas tank, and a line hose connected to the pressure regulator. It is.

The pressure regulator used in such a carbon dioxide gas supply device is typically configured such that a valve is coupled to a space portion formed inside the regulator body, and a diaphragm is installed on the upper portion thereof so that gas introduced into the space portion through the valve is formed at one side thereof. It is configured to reduce the pressure while being discharged through the discharge line.

In addition, the upper part of the diaphragm is coupled to the adjustment screw for controlling the movement of the diaphragm is discharged while the gas is reduced pressure through the space portion is discharged is controlled.

However, the pressure regulator having such a configuration causes a pressure difference due to the diaphragm freezing due to poor heat exchange in the process of discharging the low temperature gas through the discharge line after the low temperature gas is introduced into the space part. There was a problem.

In addition, there is another problem that the decompression rate is lowered as the low-temperature gas introduced into the space is discharged through one discharge line.

The present invention has been created to solve the above problems, so that the low-temperature gas introduced into the space of the regulator body is easily decompressed while gathering to one place through a plurality of low pressure passages, and also generated during the decompression process. It is an object of the present invention to provide a gas pressure regulator of carbon dioxide that can be used for a long time by preventing the diaphragm interposed therein due to cryogenic temperature by allowing the low temperature heat to be easily released to the outside.

The present invention for achieving the above object is the regulator body 100 and the regulator cap 200 is coupled and the diaphragm 300 is interposed between the regulator body 100 and the regulator cap 200, the regulator In the carbon dioxide gas regulator configured to be coupled to the screw shaft 220 having a handle 210 to the cap 200, the regulator body 100 and the regulator cap 200 is formed in the form of a rectangular panel on the surface formed in a cone shape A plurality of heat dissipation pieces 110 having are integrally formed, the low pressure gauge fastening groove 120 is formed on one side of the regulator body 100 and the first male screw on the other side of the low pressure gauge fastening groove 120 The fastening part 130 having the 131 is formed, and the space part 140 is formed in the center of the fastening part 130, and is connected to the high pressure flow path 150 to the center of the space part 140. Loss of the non-return valve 400 is coupled, the low pressure gauge fastening groove (1) A plurality of low pressure flow paths 160 having a tapered shape are formed between the ends of the space 20 and the space 140, and the safety valve 500 is coupled to the regulator body 100 and the safety valve 500 is provided. The safety passage 170 connected to the space portion 140 is characterized in that it is configured to be connected.

In addition, the non-return valve 400 is a valve having a hollow valve cap 410 having a hexagonal head 412 having a first through hole 411 formed at the end of the high-pressure flow path 150 of the regulator body 100. The rod 430 is screwed into the groove 180, the compression coil spring 420 is inserted into the valve groove 180, and the locking jaw 431 is formed in the compression coil spring 420. A ring pad 441 is interposed between the compression coil spring 420 and the locking jaw 431 by the pad guider 440, and the pressure jaw 451 penetrated through the outer circumferential surface of the locking jaw 431. The rod cap 450 having a screw is screwed and the disk pad 460 is interposed between the locking jaw 431 and the pressure jaw 451, the pressing pin 470 in the center of the disk pad 460 One side of the screw is coupled and the other side of the screwed pressure pin 470 is exposed to the through pressure jaw 451 of the rod cap 450, the rod It is characterized by a main portion formed of a plurality of flow path 452 and the convex portion flow path 453 to the outer peripheral surface of 450.

In addition, the safety valve 500 is a second male screw 511 is formed on the outer peripheral surface of one side end of the safety valve body 510 having a hollow shape and the female screw 512 is formed on the inner peripheral surface of the other end, A piston cap in which a safety valve cap 520 having a third male thread 521 is screwed to the female thread 512, and an elastic spring 530 is fitted between the safety valve body 510 and the safety valve cap 520. 540 is coupled, the O-ring 550 is interposed between the safety valve body 510 and the piston cap 540, the discharge groove 522 is formed at the bottom of the safety valve cap 520 It is characterized by.

In addition, the diaphragm 300 is provided such that the support piece 320 abuts on one side of the louver plate 310 having a disk shape in which the second through hole 311 is formed, and the fixing piece (the other side of the louver plate 310) 330 is provided to abut, but a part of the fixing piece 330 is pressed to the support piece 320 through the second through groove 311, the ring on the edge side of the louver plate 310 The purpose is achieved by providing a gas pressure regulator of carbon dioxide, characterized in that the protective ring 340 is in contact with the form is interposed between the regulator body 100 and the regulator cap 200.

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

Gas pressure regulator of the carbon dioxide according to the present invention, as shown in Figure 1 to Figure 6, regulator body 100, regulator cap 200, diaphragm 300, check valve 400 and safety valve 500 Consists of

Herein, the regulator body 100 allows the gas discharged from the gas tank 600 to be first reduced in pressure at the same time as it is introduced therein, and to easily reduce the low temperature heat generated in the process of being reduced in pressure to the outside. The regulator body 100 is provided with a function to discharge is formed with a plurality of heat dissipation pieces 110 having a rectangular panel form integrally formed on the surface formed in a cone shape, the low pressure gauge 800 on one side of the regulator body 100 ) Is configured to form a low pressure gauge fastening groove 120 is coupled.

In addition, the other side of the low-pressure gauge fastening groove 120 is formed with a fastening portion 130 having a first male screw 131 is configured to be screwed to the regulator cap 200 to be described later and the fastening portion 130 The space 140 having a predetermined space is formed at the center of the space.

In addition, the center of the space portion 140 is configured to be coupled to the non-return valve 400 is connected to the high-pressure flow path 150 having a form penetrated from the side of the regulator body 100 at a right angle, Between the end of the low pressure gauge fastening groove 120 and the space portion 140, a plurality of low pressure passages 160 having a tapered shape are formed to be connected to the low pressure gauge fastening groove 120. The high pressure flow path 150 formed in the regulator body 100 is coupled to a high pressure gauge 700 so that the pressure flowing from the gas tank 600 into the regulator body 100 can be checked.

And the other side of the regulator body 100 is coupled to the high pressure gauge 700 is coupled to the safety valve 500 having a function to prevent the excessive pressure is applied to the safety flow path 170 connected to the safety valve 500 ) Is configured to be connected between the low pressure passage (160) formed in the space 140.

The regulator cap 200 is coupled to the first male screw portion 131 formed in the regulator body 100 to prevent the high-pressure gas is discharged to the outside and at the same time to limit the amount of movement of the diaphragm 300 diaphragm Pressing the pressure pin 470 of the non-return valve 400 to be in contact with the (300) to the main passage 452 of the rod cap 450 and the first through hole 411 of the valve cap 410 Through this, the amount of gas introduced into the space 140 may be adjusted.

To this end, the regulator cap 200 is formed with a first female screw 201 to be coupled to the first male screw 131, the shape is formed to be the same as the regulator body 100 as a whole. That is, a plurality of heat dissipation fins 110 are formed on a surface thereof, and a guide groove 230 having a stepped shape having a predetermined space is formed therein so that the pressure disk 240 and the pressure spring 250 are inserted therein. .

In addition, the screw shaft 220 coupled to the handle 210 is screwed along the guide groove 230 where the pressure disk 240 and the pressure spring 250 are opposed to the guide groove 230 into which the pressure disk 240 is inserted. Pressing disk 240 is configured to move in the axial direction by a predetermined length to press the diaphragm 300 to be described later.

The diaphragm 300 is interposed between the regulator body 100 and the regulator cap 200 to prevent the low-temperature and high-pressure gas from being supplied or discharged to the space portion 140 of the regulator body 100 to leak to the outside. At the same time, the pressure is reduced through the low pressure passage 160 formed in the space 140, and the pressure pin 470 of the non-return valve 400 is pressurized according to the movement amount of the screw shaft 220. The amount of gas introduced into the space 140 through the 150 is configured to be adjusted.

In addition, the diaphragm 300 is provided such that the support piece 320 abuts on one side of the louver plate 310 having a disk shape having a second through hole 311, and is fixed to the other side of the louver plate 310. It is comprised so that the piece 330 may be provided to abut.

And a portion of the fixing piece 330 is coupled to be pressed to the support piece 320 through the second through groove 311, the protective ring 340 having a ring shape on the edge side of the louver plate 310 Is interposed between the regulator body 100 and the regulator cap 200 to abut this to prevent the edge of the louver plate 310 from being damaged by excessive coupling force in the process of coupling the regulator cap 200 to the regulator body 100. It is configured to be.

The non-return valve 400 has a function of preventing the high-pressure gas supplied to the space 140 through the high-pressure flow path 150 to flow back. The hexagonal head 412 having the first through hole 411 is formed. The hollow valve cap 410 is screwed into the valve groove 180 formed at the end of the high-pressure flow path 150 of the regulator body 100, the compression coil spring 420 is inserted into the valve groove 180 The rod 430 in which the locking step 431 is formed is inserted into the compression coil spring 420.

In addition, a ring pad 441 is interposed between the compression coil spring 420 and the locking jaw 431 by the pad guider 440, and the pressure jaw 451 penetrates through the outer circumferential surface of the locking jaw 431. The rod cap 450 having a is configured to be screwed.

The disk pad 460 is interposed between the locking jaw 431 and the pressure jaw 451, and one side of the pressure pin 470 is screwed to the center of the disk pad 460, and the screw coupled to the disk pad 460. The other side of the pressing pin 470 is configured to be exposed to the through pressure jaw 451 of the rod cap 450.

In addition, a plurality of concave flow passages 452 and convex flow passages 453 are formed on the outer circumferential surface of the rod cap 450 so that the high-pressure gas introduced into the valve groove 180 through the high pressure flow passage 150 is the concave flow passage 452. It is configured to be discharged through the space portion 140 through.

When the safety valve 500 is subjected to a high pressure of a predetermined pressure or more due to abnormal operation of the space 140 and the low pressure passage 160 and the diaphragm 300 formed in the regulator body 100, the gas is automatically moved to the outside. The second male screw 511 is formed on the outer peripheral surface of one end of the safety valve body 510 having a hollow shape and the second female screw 512 is formed on the inner peripheral surface of the other end thereof. .

In addition, a safety valve cap 520 having a third male thread 521 formed on the second female thread 512 is screwed together, and an elastic spring 530 is provided between the safety valve body 510 and the safety valve cap 520. Piston cap 540 is fitted is configured to be coupled.

And the O-ring 550 is interposed between the safety valve body 510 and the piston cap 540, and the discharge groove 522 is formed at the lower end of the safety valve cap 520.

The process of depressurizing the high pressure gas using the gas pressure regulator having such a configuration is as follows.

First, as illustrated in FIG. 4A, the diaphragm may be released as the screw shaft 220 moves from left to right in a state in which it is coupled to the adjuster cap 200, and thus the pressing force applied to the pressure spring 250 is released. The fixing piece 330 of 300 is separated from the pressure pin 470 of the non-return valve 400.

The pressure jaw 451 of the rod cap 450 coupled to the rod 430 by the elastic force of the compression coil spring 420 constituting the non-return valve 400 inserted into the valve groove 180 is the valve cap ( As it is in close contact with the inside of the 410, the high pressure gas introduced into the valve groove 180 through the high pressure flow path 150 does not move to the space 140 but is blocked.

Next, as shown in Figure 4b and at the same time rotate the handle 210 and the screw shaft 220 presses the pressing disk 240 inserted into the guide groove 230 and at the same time the pressing spring 250 is pressed As the pressure spring 250 is pressurized, the fixing piece 330 constituting the diaphragm 300 moves from the right side to the left side and moves the fixing piece 330 located inside the space 140 to prevent the check valve. The pressure pin 470 exposed to the first through hole 411 of 400 is pressed.

At this time, the pressure pin 470 is moved toward the inside of the valve groove 180 and at the same time the compression coil spring 420 is compressed, the pressure jaw 451 of the rod cap 450 and the inner surface of the valve cap 410 By separating or spaced apart, the high-pressure gas inside the valve groove 180 moves through a plurality of recessed flow passages 452 formed at the outer periphery of the rod cap 450, and then the first through groove formed in the valve cap 410. It is supplied to the space 140 through 411.

Next, the high pressure gas supplied to the space 140 is moved to the outside through the low pressure flow path 160 and the low pressure gauge fastening groove 120, and the low-temperature heat is reduced in the process of the regulator body 100 and the regulator cap ( 200) and is conducted to the diaphragm 300 interposed therein, and the low-temperature heat that is conducted is smoothly exchanged by the heat dissipation piece 110 formed on the surface of the regulator body 100 and the regulator cap 200. By doing so, the louver plate 310 constituting the diaphragm 300 is prevented from being operated while being hardened at low temperature, and is prevented from being damaged, thereby obtaining a reduced pressure gas having a stable pressure.

Next, when a high pressure of a predetermined limit or more acts on the space portion 140 in the process of using the reduced pressure through this process, the pressure acts on the safety valve body 510 through the safety passage 170. In addition, the high pressure applied to the safety valve body 510 is greater than the elastic force of the elastic spring 530 and at the same time the elastic spring 530 is compressed, the piston cap 540 is moved to the bottom, the piston cap 540 Due to the movement, the portion blocked by the O-ring 550 is opened, and at the same time, the high pressure is always released to the atmosphere through the discharge groove 522 formed in the lower portion of the safety valve cap 520. It is possible to prevent the above pressure from working.

Thus, the present invention is introduced into the space portion is divided into the diaphragm gas of the high pressure through the backflow prevention valve coupled to the inside of the regulator body, the high pressure gas introduced into the space portion is a plurality of low pressure flow path formed in the space portion The low temperature heat generated in the process of decompression while gathering to one place is easily released to the outside through the heat dissipation piece to prevent damage to the diaphragm interposed therein due to the cryogenic temperature so that it can be used for a long time.

In addition, when excessive pressure acts on the space part, the part of the pressure is automatically discharged through the safety valve, so that it can be used safely.

Claims (4)

The regulator body 100 and the regulator cap 200 are coupled and a diaphragm 300 is interposed between the regulator body 100 and the regulator cap 200, and the handle 210 is placed on the regulator cap 200. In the carbon dioxide gas regulator configured to be coupled to the screw shaft 220 having, The regulator body 100 and the regulator cap 200 are formed integrally with a plurality of heat dissipation pieces 110 having a rectangular panel shape on the surface formed in a conical shape, the low pressure gauge on one side of the regulator body 100 A fastening groove 120 is formed, and a fastening portion 130 having a first male screw 131 is formed at the other side of the low pressure gauge fastening groove 120, and a space portion at the center of the fastening portion 130. 140 is formed, but the non-return valve 400, which is connected to the high pressure flow path 150 to the center of the space portion 140 is coupled, the end portion and the space portion of the low pressure gauge fastening groove 120 ( A plurality of low pressure passages 160 having a tapered shape are formed between the 140, safety valves 500 coupled to the regulator body 100, and safety passages 170 connected to the safety valves 500. Gas pressure regulator of carbon dioxide, characterized in that configured to be connected to the space 140. The method of claim 1, The non-return valve 400 has a hollow valve cap 410 having a hexagonal head 412 having a first through hole 411 formed at an end of the high pressure flow path 150 of the regulator body 100. Is screwed to the 180, the compression coil spring 420 is inserted into the valve groove 180 and the rod 430 having a locking jaw 431 is formed in the compression coil spring 420 is inserted, A ring pad 441 is interposed between the compression coil spring 420 and the locking jaw 431 by the pad guider 440, and has a pressure jaw 451 penetrating through the outer circumferential surface of the locking jaw 431. Cap 450 is screwed and the disk pad 460 is interposed between the locking jaw 431 and the pressure jaw 451, one side of the pressing pin 470 in the center of the disk pad 460 The other side of the pressure pin 470 that is screwed and screwed is exposed to the through pressure jaw 451 of the rod cap 450, the rod cap 450 The gas pressure regulator of carbon dioxide characterized by a main portion formed of a plurality of flow path 452 and the convex portion flow path 453 to the outer peripheral surface. The method of claim 1, The safety valve 500 has a second male screw 511 is formed on the outer peripheral surface of one side end of the safety valve body 510 having a hollow shape, the female screw 512 is formed on the inner peripheral surface of the other end, the female screw ( A piston cap 540 in which a safety valve cap 520 having a third male thread 521 is screwed to 512 is screwed, and an elastic spring 530 is fitted between the safety valve body 510 and the safety valve cap 520. ) Is coupled, the O-ring 550 is interposed between the safety valve body 510 and the piston cap 540, the discharge groove 522 is formed at the bottom of the safety valve cap 520 CO2 gas pressure regulator. The method of claim 1, The diaphragm 300 is provided such that the support piece 320 abuts on one side of the louver plate 310 having a disk shape in which the second through hole 311 is formed, and the fixing piece 330 on the other side of the louver plate 310. ) Is provided to abut, but a part of the fixing piece 330 is pressed to the support piece 320 through the second through groove 311, the ring shape on the edge side of the louver plate 310 Gas ring regulator of carbon dioxide, characterized in that the protective ring 340 is abutted between the regulator body 100 and the regulator cap 200.

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