KR100581760B1 - Regulator - Google Patents

Abstract

The present invention relates to a regulator for decompressing and discharging a high-pressure gas discharged from a discharge portion of a bomb. According to the present invention, after the exhaust unit 1a of the cylinder 1 is fixed to the fixing unit 52 of the housing 50, the exhaust unit 1a is operated to exhaust the gas of the cylinder 1. Then, the gas exhausted from the cylinder 1 is supplied to the air supply valve 60, the pressure reducing valve 70 and the flow control valve 80, which are sequentially embedded in the housing 50. At this time, the pressure reducing valve 70 opens and closes the air supply valve 60 in accordance with the pressure of the gas exhausted from the cylinder 1, and decompresses the pressure of the gas supplied into the housing 50. In this way, the pressure-reduced gas is discharged to the upper nozzle 54 of the housing 50. In addition, according to the operating state of the flow control valve 80 built in the lower end of the housing 50 is discharged to the lower nozzle 56 of the housing 50. The retainer ring 90 supporting the edge of the pressure reducing valve 70 described above is disposed at the step 80a of the flow control valve 80. Such a retainer ring 90 prevents contact between the pressure reducing valve 70 and the flow control valve 80. Therefore, the pressure reducing valve 70 does not pressurize the flow control valve 80.

Gas, Regulators, Rings, Valves, Contacts

Description

Regulator {REGULATOR}

1 is an exploded perspective view showing the configuration of a general regulator,

2 is a longitudinal cross-sectional view of the regulator shown in FIG.

3 is an exploded perspective view showing a regulator according to an embodiment of the present invention;

4 is a longitudinal cross-sectional view of the regulator shown in FIG.

Figure 5 is a longitudinal cross-sectional view showing the operation of the regulator according to an embodiment of the present invention,

6 is a longitudinal sectional view showing a regulator according to another embodiment of the present invention;

7 is an exploded perspective view showing the configuration of the flow control valve shown in FIG.

<Explanation of symbols for the main parts of the drawings>

50 housing 52 fixing part 54 top nozzle

56: lower nozzle 54a, 56a: nozzle fixing hole

58: internal diameter expansion groove 60: air supply valve 70: pressure reducing valve

72: valve poppet 72a: central axis 72c: poppet chamber

74: guide ring 76: elastomer 80: flow control valve

80a: step 82: body 82a: euro

84: pinhole disk 84a: pinhole 86: rotation axis

87, 89 Knob 88 Disc cap 88a Vertical axis

90: retaining ring 92: irregularities 94: projection

95 chamber G ring ring gasket

The present invention relates to a regulator for decompressing and discharging high-pressure gas discharged from a discharge part of a bomb, and more particularly, to a regulator for decompressing and discharging high-pressure oxygen stored in a resuscitation cylinder (oxygen communication) at an appropriate pressure. .

In general, a regulator for converting high-pressure oxygen stored in an oxygen cylinder into a low pressure and discharging it is discharged from the cylinder 1 to the gate 12a of the fixing part 12 provided at the upper end of the housing 10, as shown in FIG. The base 1a is inserted. And the exhaust part 1a of the cylinder 1 is fixed by the hendle 12b of the fixing part 12. As shown in FIG. Here, the exhaust part 1a of the cylinder 1 has a discharge port which discharge | releases oxygen according to operation of the exhaust part 1a. The discharge port of the exhaust part 1a is coupled to the air supply valve 16 of the housing 10 as shown in FIG. 2 as the cylinder 1 is fixed to the fixing part 12 of the housing 10. . At this time, the exhaust unit 1a is operated to exhaust oxygen of the cylinder 1 to the discharge port. (Normally, the oxygen is discharged to the discharge port when turning the cylindrical exhaust unit as shown.)

Accordingly, the high pressure oxygen stored in the cylinder 1 is supplied to the inside of the housing 10 through the air supply valve 16. And, the oxygen supplied to the interior of the housing 10, as shown in Figure 2, through the upper flow path (10a) of the housing 10 formed on the upper end side of the pressure reducing valve 18, the upper end of the housing 10 It is supplied to the upper nozzle 14 fixed to the side. At this time, the indicator I is supplied with oxygen of the cylinder 1 through the air supply valve 16, as shown. Accordingly, the upper nozzle 14 of the housing 50 supplies oxygen to a forced respirator (not shown) connected to the discharge end, and the indicator I displays the pressure of the cylinder 1.

At this time, the oxygen of the cylinder 1 supplied to the housing 10 is not only the upper passage 10a of the housing 10, but also the pressure reducing valve 18 and the flow control valve 20 sequentially installed in the housing 10. Also supplied. Thus, when the flow control valve 20 is opened, the supplied oxygen is exhausted to the lower nozzle 15 fixed to the lower nozzle fixing hole 15a of the housing 10. The lower nozzle 15 supplies oxygen to a respirator mask device (not shown) connected to the discharge end.

The pressure reducing valve 18 and the flow control valve 20 are built in the airtight state in the housing 10 by the ring gasket g fitted to the outer circumferential surface. Here, the pressure reducing valve 18 and the flow control valve 20 will be described in more detail as follows.

First, the pressure reducing valve 18 has a valve poppet 18a, a guide ring 18b, and a spring 18c, as shown in FIG. Then, oxygen is supplied from the guide ring 18b connected to the air supply valve 16 in an airtight state. In this way, the supplied oxygen is discharged to the lower part of the valve poppet 18a through the hollow formed in the central axis of the valve poppet 18a. At this time, the hollow formed in the central axis of the valve poppet 18a is formed from the upper end side of the central axis to the lower end as shown. That is, the central axis of the valve poppet 18a has a closed top. This, the valve poppet 18a and the guide ring 18b are elastically supported by the spring 18c as shown. The upper end of the central shaft of the valve poppet 18a is fitted in the airtight state to the guide ring 18b.

The guide ring 18b, the spring 18c, and the valve poppet 18a of the pressure reducing valve 18 are sequentially embedded in the cylinder 22 integrally formed at the upper end of the flow control valve 20 as shown. do. At this time, the edge of the valve poppet 18a is caught by the step 24 formed in the cylinder 22. Step 24 is formed higher than the pinhole disk 26 of the flow control valve 20 to be described later. Thus, step 24 provides chamber C as shown enlarged between valve poppet 18a of pressure reducing valve 18 and pinhole disk 26 of flow control valve 20. Of course, the chamber C is a gap formed between the valve poppet 18a and the pinhole disk 26 by the step 24.

This step 24 not only provides the chamber C, but also prevents contact of the valve poppet 18a and the pinhole disk 26. Therefore, the valve poppet 18a cannot press the pinhole disk 26. Of course, since the step 24 supports the lower surface of the valve poppet 18a, the valve poppet 18a does not pressurize the pinhole disk 26.

The pressure reducing valve 18 supplies the high pressure oxygen supplied from the air supply valve 16 to the chamber C mentioned above through the central axis of the valve poppet 18a. At this time, when the flow control valve 20 is closed and the pressure of the oxygen discharged from the air supply valve 16 exceeds 3.5 kg / cm ² , the valve poppet 18a is the pressure of the oxygen contained in the chamber C. Rises. That is, the oxygen contained in the chamber C is compressed in the chamber C, pushing up the valve poppet 18a. Thus, the valve poppet 18a rises while overcoming the elastic force of the spring 18c. And the valve poppet 18a rises under the guidance of the guide ring 18b.

Thus, the rising valve poppet 18a shields the discharge port of the air supply valve 16 to the upper end of the sealed central shaft. Accordingly, oxygen is not supplied to the inside of the housing 10. At this time, the oxygen present in the housing 10 is exhausted through the upper passage 10a or the flow control valve 20 of the housing 10. In this way, as oxygen existing in the housing 10 is exhausted, the internal pressure of the chamber C is attenuated to about 3.5 kg / cm ² or less. Therefore, the spring 18c presses the raised valve poppet 18a and returns to the original position. Then, as the valve poppet 18a is returned, the air supply valve 16 again supplies oxygen to the inside of the housing 10. Of course, it is obvious that the spring 18c is designed to be stretched based on a pressure of approximately 3.5 kg / cm ² .

Here, the housing 10 maintains an internal pressure of approximately 3.5 kg / cm ² depending on the operation of the pressure reducing valve 18. That is, the oxygen supplied to the housing 10 through the air supply valve 16 always maintains a pressure of about 3.5 kg / cm ² by the pressure reducing valve 18. Of course, the oxygen discharged from the housing 10 is discharged at the same pressure as the pressure of the oxygen reduced by the pressure reducing valve 70.

Next, the flow control valve 20 has a cylindrical shape as shown, and has a flow path 20a for supplying oxygen discharged from the pressure reducing valve 18 to the lower nozzle 15 of the housing 10. In addition, the pressure reducing valve 18 has a pinhole disk 26 for controlling the flow rate of oxygen flowing into the flow path 20a. As shown in the enlarged view, the pinhole disk 26 has a central axis 26b which is connected to the knob 28 and rotates, and a plurality of pinholes 26a formed at equal intervals.

At this time, the pinholes 26a of the pinhole disks 26 have different diameters, and are arranged in order from the smallest diameter to the largest diameter along the circumferential direction of the pinhole disk 26. The pinhole 26a having the smallest diameter and the pinhole 26a having the largest diameter are larger than the other pinholes 26a as shown. Therefore, the pinhole disk 26 has a non-pinhole section in which the pinhole 26a is omitted.

The pinhole disk 26 of the flow control valve 20 is rotated by the knob 28 to correspond to any one of the plurality of pinholes 26a to the inlet of the flow path 20a, or to correspond to the non-pinhole section. Let's do it. Therefore, the flow path 20a of the flow control valve 20 is opened or shielded by the pinhole disk 26. At this time, the flow rate of oxygen supplied to the flow path 20a is determined by the pinhole 26a of the pinhole disk 26 corresponding to the flow path 20a. That is, it is determined by the diameter of the corresponding pinhole 26a.

In conclusion, the flow control valve 20 controls the flow rate of oxygen discharged to the lower nozzle 15 of the housing 10. This flow rate is controlled by the pinhole disk 26 rotating by the knob 28.

Here, the pinhole disk 26 is not subjected to the interference of the valve poppet 18a by the step 24 formed in the cylinder 22 of the flow control valve 20. Thus, the pinhole disc 26 rotates with the knob 28 when the knob 28 rotates. If the valve poppet 18a presses the pinhole disk 26, the pinhole disk 26 cannot be rotated. Therefore, the stepped 24 must be formed in the cylinder 22.

On the other hand, the upper nozzle 14 of the housing 50, as shown, may be composed of two. Thus, when the upper nozzle 14 is composed of two, one of the upper nozzle 14 is connected to the above-described forced respirator, the other upper nozzle 14 is connected to the suction device (not shown) (not shown) do.

However, in such a general regulator, the stepped portion 24 formed in the cylinder 22 of the flow control valve 20 prevents contact between the valve poppet 18a and the pinhole disk 26, and at the same time, the valve poppet 18a. And since the chamber (C) is provided between the pinhole disk 26, in order to rotate the pinhole disk 26 and to elevate the valve poppet (18a), the step 24 is necessarily provided on the upper portion of the flow control valve 20 There is a problem in that a cylinder 22 having is provided.

Such a cylinder 22 not only increases the material cost of the regulator, but also prolongs the manufacturing time of the regulator. In addition, an assembly process that requires the components of the pressure reducing valve 18 to be incorporated in the cylinder 22 is added.

In the case of the general regulator, when the flow control valve 20 is incorporated in the housing 10, a ring gasket g fitted to the outer circumferential surface of the lower end of the flow control valve 20 has a nozzle formed on the lower end side of the housing 10. There is also a problem that is damaged by being caught by the edge of the fixing hole (15a).

The reason why the ring gasket g of the flow control valve 20 is caught by the edge of the nozzle fixing hole 15a is that the ring gasket g is embedded in the compressed state at the lower end of the housing 10, and then the nozzle fixing hole This is because it expands instantaneously at 15a. Therefore, the expanded ring gasket g is cut while being caught by the edge of the nozzle fixing hole 15a.

On the other hand, reference numeral P is a packing fitted to the central axis of the valve poppet 18a constituting the pressure reducing valve 18, S is a snap ring for fixing the flow control valve 20 to the housing 10.

The present invention has been made to solve the above-mentioned conventional problems, and even if the cylinder having the step of the flow control valve is omitted, it is possible to prevent the contact between the pressure reducing valve and the flow control valve while separating the pressure reducing valve and the flow control valve. The purpose of the present invention is to provide a recirculator capable of rotating the pinhole disk of the flow control valve and elevating the valve poppet of the pressure reducing valve.

Another object of the present invention is to provide a regulator capable of raising and lowering the valve poppet by using gas supplied from the air supply valve, without forming a chamber while spaced between the valve poppet of the pressure reducing valve and the pinhole disk of the flow control valve.

In addition, another object of the present invention is to provide a regulator capable of preventing damage to the ring gasket by reducing the coefficient of friction of the ring gasket against the edge of the nozzle fixing hole formed at the lower side of the housing.

The regulator according to the present invention for achieving the above object has a fixing part for fixing the exhaust part of the cylinder in which the high-pressure gas is stored on the upper surface, and the internal gas is external to the nozzle fixing holes provided at the upper and lower ends. A cap-shaped housing to which upper and lower nozzles to be exhausted are mounted; An air supply valve fixed to the housing and supplying gas discharged from the exhaust of the above-mentioned cylinder into the housing; A pressure reducing valve for discharging the gas of the air supply valve to the inside lower side of the housing and opening and closing the air supply valve in accordance with the pressure of the gas supplied from the air supply valve, thereby reducing the pressure of the gas supplied to the housing; It is built in the airtight state in the housing described above, aligned in line with the pressure reducing valve described above, has a step on the upper edge, and controls the flow rate of the gas discharged from the pressure reducing valve, which is provided to the lower nozzle of the housing described above And; And a retainer ring disposed at the step of the flow control valve, supporting the lower edge of the pressure reducing valve and preventing contact between the pressure reducing valve and the flow control valve.

Here, the above-mentioned pressure reducing valve, for example, is provided with a ring gasket for providing airtightness to the inner circumferential surface of the housing described above on the outer circumferential surface, and has a top-closed central shaft having a hollow for supplying gas discharged from the air supply valve to the lower side, A disk-shaped valve poppet which opens and closes the air supply valve to the upper end of the central axis while lifting in accordance with the pressure of the gas supplied to the lower part; It is closely connected to the lower part of the air supply valve described above, and the upper end of the central axis of the above-described valve poppet is fitted in the airtight state on the inner circumferential surface to supply gas discharged from the air supply valve to the hollow of the central axis, and guide the lifting of the valve poppet. To guide and; It may be configured to include; an elastic body to elastically support the above-described valve poppet and the guide ring.

At this time, the above-described pressure reducing valve, a poppet raising means for raising the valve poppet by using a gas of a high pressure supplied through the central axis of the above-described valve poppet; Such a poppet raising means forms, for example, a lower open poppet chamber connected to the central axis of the valve poppet described above at the center of the lower surface of the valve poppet, so that the high-pressure gas supplied from the central axis of the valve poppet is formed in the valve poppet. It is preferable to configure to push up the valve poppet while being compressed at the bottom.

The retainer ring may be configured such that the upper surface protrudes above the flow control valve to support the lower edge of the pressure reducing valve and space the pressure reducing valve and the flow control valve apart. have.

This retaining ring determines the separation distance of the pressure reducing valve and the flow control valve. That is, the distance between the pressure reducing valve and the flow control valve is determined by the retaining ring. In this case, the retaining ring may be spaced apart from the pressure reducing valve and the flow control valve so that the chamber is provided between the pressure reducing valve and the flow control valve, otherwise, the chamber may be spaced apart without providing a chamber between the pressure reducing valve and the flow control valve. You can also

On the other hand, the above-described flow control valve has, for example, a ring gasket for providing airtightness to the inner circumferential surface of the housing described above is provided on the outer circumferential surface, and has a flow path for providing gas discharged from the pressure reducing valve described above to the lower nozzle of the housing. A cylindrical body; While rotatably installed in the central portion of the upper surface of the body, it provides the above-described step on the upper end of the body, and has a plurality of pinholes having different diameters at equal intervals along the circumferential direction, in the flow path of the body when rotating A pinhole disk that corresponds to any one of the plurality of pinholes or corresponds between the plurality of pinholes to control the flow rate of the gas supplied to the lower nozzle of the housing; It is connected to the pinhole disk, the rotating member for rotating the pinhole disk; can be configured to include.

In this case, the above-mentioned rotating member may include, for example, a rotating shaft extending from the center of the pinhole disk and vertically penetrating the above-described body; It may be configured to include; a knob coupled to the rotary shaft to rotate.

On the other hand, the rotating member, for example, shields the upper surface of the above-mentioned pinhole disk, has an air supply hole on the upper surface for supplying gas discharged from the above-described pressure reducing valve to the pinhole disk, and the center of the body and the pinhole disk described above. A disk cap having a vertical axis penetrating therethrough and integrally coupled with the pinhole disk; It may be configured to include; a knob that is coupled to rotate in the vertical axis of the disc cap.

On the other hand, the above-mentioned housing, when the pressure-reducing valve and the flow control valve described above, the damage prevention means for preventing the above-mentioned ring gasket is damaged while being pressed against the inner peripheral surface of the lower side of the above-mentioned housing; Can be. Such damage preventing means is formed in the inner circumferential surface of the housing in which the nozzle fixing hole at the lower end of the housing is located in the circumferential direction, so that the friction coefficient of the ring gasket on the inner circumferential surface of the housing is reduced. It is preferable to construct.

Hereinafter, a regulator according to the present invention will be described with reference to the accompanying drawings. FIG. 3 is an exploded perspective view showing a regulator according to an embodiment of the present invention, and FIG. 4 is a regulator shown in FIG. 5 is a longitudinal cross-sectional view showing the operation of the regulator according to an embodiment of the present invention.

As shown in Figures 3 and 4, the regulator according to an embodiment of the present invention, the cylindrical housing 50 in the form of a cap having an indicator (I); The air supply valve 60, the pressure reducing valve 70, the uneven ring 90, and the flow control valve 80 which are built in this housing 50 are included. The configuration of the regulator will be described in more detail as follows.

First, as shown in FIG. 3, the housing 50 has a hollow with an open lower portion, and a fixing portion 52 for fixing the exhaust portion 1a of the cylinder 1 at the upper end thereof. As shown in the drawing, the fixing portion 52 is a chuck for pressing and fixing the gate 52a into which the exhaust portion 1a of the cylinder 1 is fitted and the exhaust portion 1a fitted to the gate 52a. It comprises a 52b. At this time, the chuck 52b is preferably applied to the 'T' shaped handle of the alphabet that is screwed to the upper portion of the gate 52a as shown in the figure.

In the upper and lower ends of the housing 50, nozzle fixing holes 54a and 54b as shown in FIG. 4 are provided, and upper and lower nozzles 54 and 56 are mounted. At this time, the upper nozzle 54 is preferably composed of two as shown in FIG. In addition, one of the two upper nozzles 54 connects an unillustrated forced respirator, and the other connects a non-illustrated rotator. Unlike this, the lower nozzle 56 is configured as one, and connects the breath mask device not shown.

In addition, as shown in the upper portion of the housing 50, an upper flow path 50a communicating with the upper nozzle 54 is formed. The inner peripheral surface of the lower end portion of the housing 50 is provided with an inner diameter expansion groove 58 for preventing damage to the ring gasket G of the pressure reducing valve 70 and the flow control valve 80 described later. At this time, the inner diameter expansion groove 58 is formed in the circumferential direction on the inner circumferential surface of the housing 50 in which the lower nozzle fixing hole 56a is located. The inner diameter expansion groove 58 is a damage preventing means for preventing the ring gasket G from being damaged.

Next, as shown in FIG. 4, the air supply valve 60 is fixed to the lower side of the gate 52a of the housing 50 in a vertical state. Therefore, the air supply valve 60 connects the exhaust part 1a of the cylinder 1 fixed to the fixed part 52 of the housing 50 and the hollow of the housing 50. At this time, the air supply valve 60 is connected to the indicator (I) as shown. Therefore, the indicator I expresses the pressure of oxygen passing through the air supply valve 60, that is, the pressure of the cylinder 1.

Subsequently, as shown in FIGS. 3 and 4, the pressure reducing valve 70 includes a disc shaped valve poppet 72; A cylindrical guide ring 74 in close contact with the air supply valve 60 fixed to the housing 50; And an elastic body 76 that elastically supports the guide ring 74 and the valve poppet 72. Such, the components of the pressure reducing valve 70 in more detail as follows.

The valve poppet 72 has a central axis 72a at the center of the upper surface as shown in FIG. 4. This central axis 72a has a hollow connecting from the upper end side to the lower end as shown, and a packing ring PR providing airtightness at the upper end of the central axis 72a. At this time, the central axis 72a has a shielded upper end due to the hollow shape. In addition, the valve poppet 72 has a ring gasket G formed on the outer circumferential surface of the housing 50 in an airtight state with the inner circumferential surface thereof.

As illustrated in FIG. 4, the guide ring 74 has an outward flange at the top and a grommet 74a at the edge of the upper surface. The guide ring 74 is built in the housing 50 and takes a state directly connected to the air supply valve 60 described above. At this time, the grommet 74a provides airtightness to the guide ring 74 and the air supply valve 60.

The elastic body 76 is a coil spring, as shown in FIG. At this time, the elastic body 76 must be specifically designed to shrink when the pressure of oxygen discharged from the cylinder 1 exceeds 3.5kg / cm ² . This elastic body 76 has a diameter that can surround the outer peripheral surface of the guide ring 74 and the central axis 72a of the valve poppet 72.

As such, the guide ring 74, the elastic member 76 and the valve poppet 72 of the pressure reducing valve 70 is sequentially coupled to the inside of the housing 50, as shown in FIG. At this time, the upper end of the central axis 72a of the valve poppet 72 is located on the inner circumferential surface of the guide ring 74. Then, the elastic member 76 surrounds the central axis 72a of the valve poppet 72 and the outer circumferential surface of the guide ring 74 as shown, and at the same time elastically supports the valve poppet 72 and the guide ring 74. do.

Subsequently, the flow control valve 80 takes the form of being continuous with the pressure reducing valve 70, as shown in FIGS. 3 and 4. And a cylindrical body 82 as shown; Pinhole disk 84; It includes; a rotating member for rotating the pinhole disk 84. Such a configuration of the flow control valve 80 will be described in more detail as follows.

As shown in FIG. 4, the body 82 has a flow path 82a for supplying oxygen discharged from the pressure reducing valve 70 to the lower nozzle 56 of the housing 50. The outer circumferential surface also has a ring gasket G that provides airtightness to the inner circumferential surface of the housing 50.

The pinhole disk 84 has a plurality of pinholes 84a having different diameters at equal intervals, as shown in FIG. The pinholes 84a are arranged along the circumferential direction of the pinhole disk 84 in order from smallest to largest. At this time, the pinhole 84a having the smallest diameter and the pinhole 84a having the largest diameter have a larger gap than the other pinholes 84a. That is, the pinhole 84a is omitted between the pinhole 84a having the smallest diameter and the pinhole 84a having the largest diameter. Therefore, the pinhole disk 84 has a non-pinhole section in which the pinhole 84a is omitted between the pinhole 84a having the smallest diameter and the pinhole 84a having the largest diameter.

Here, the pinhole disk 84 is disposed in the center of the upper surface of the body 82 to provide a step 80a on the upper edge of the body 82 as shown in an enlarged view of FIG. 4. This, the pinhole disk 84 is rotated by the rotating member. The pinhole disk 84 corresponds to an inlet of the flow path 82a formed in the body 82 according to the rotation state. Therefore, the flow volume of the flow path 82a is adjusted. In contrast, the pinhole disk 84 corresponds to the inlet of the flow path 82a according to the rotated state. Therefore, the flow path 82a is shielded.

That is, the pinhole disk 84 opens and closes the flow path 82a or adjusts the flow rate flowing into the flow path 82a. Of course, as the flow rate 82a is opened or closed and the flow rate is adjusted, the flow rate discharged to the lower nozzle 56 of the housing 50 is naturally controlled.

As shown in FIG. 4, the rotating member extends from the center of the pinhole disk 84 and passes through the body 82; The knob 87 is coupled to the rotary shaft 86 to rotate the rotary shaft 86. Therefore, when the knob 87 rotates, the rotation shaft 86 rotates the pinhole disk 84.

As shown in FIG. 4, the flow control valve 80 is fixed to the housing 50 by a snap ring S that is fitted to the lower end of the housing 50.

Finally, the retainer ring 90 is disposed at the step 80a of the flow control valve 80 as shown in an enlarged view in FIG. 4 so as to support the lower edge of the pressure reducing valve 70. At this time, the retainer ring 90 is formed thicker than the pinhole disk 84 of the flow control valve 80, the upper surface is configured to protrude to the top of the flow control valve 80 as shown in FIG. Thus, the retaining ring 90 provides a chamber 95 as shown between the pressure reducing valve 70 and the flow control valve 80, while separating the pressure reducing valve 70 and the flow control valve 80. That is, the retaining ring 90 should be configured to have a thickness sufficient to provide the chamber 95. Such a retaining ring 90 is sufficient to provide a chamber 95 having a height of approximately 1 mm to 3 mm. In other words, the height of the chamber 95 is approximately 1 mm to 3 mm.

Such a retainer ring 90 may be configured as a ring having a flat surface. However, as shown in FIG. 3, the retainer ring 90 may be configured to have the unevenness 92 along the circumferential direction. Thus, in order to provide the unevenness | corrugation 92, the retainer ring 90 may be bent in an up-down direction. Of course, the surface of the retainer ring 90 may be interrupted to provide the irregularities 92.

Alternatively, the retainer ring 90 may be configured to have a plurality of protrusions 94 along the circumferential direction, as shown enlarged in FIG. 3. Such a protrusion 94 is preferably embossed as shown. .

Thus, when providing the concave-convex 92 or the protrusion 94 in the retainer ring 90, the oxygen supplied from the air supply valve 60 to the edge of the valve poppet 72 of the pressure reducing valve 70 can be provided. Of course, oxygen of the air supply valve 60 is provided between the valleys of the unevenness 92 or the projection 94. That is, the unevenness 92 or the protrusion 94 provide a flow path through which oxygen of the pressure reducing valve 70 flows. In addition, the unevenness 92 or the protrusion 94 support the edges of the valve poppet 72 of the pressure reducing valve 70 at equal intervals.

On the other hand, reference numeral 50b in the drawing is a vent hole to prevent the vacuum is formed on the inner peripheral surface of the housing 50 in which the elastic member 76 of the pressure reducing valve 70 is located.

In the regulator according to the embodiment of the present invention configured as described above, as shown in FIG. 4, the pressure reducing valve 70 is first inserted into the housing 50, and then the step 80a of the flow control valve 80 is provided. The retainer ring 90 is inserted into the tube. Then, the lower end of the flow control valve 80 is fixed with a snap ring (S) so that the separation of the flow control valve 80 is prevented.

At this time, the ring gasket G fitted to the valve poppet 72 of the pressure reducing valve 70 and the body 82 of the flow control valve 80 is a housing (when the valve poppet 72 and the body 82 are built-in). After compression at the lower inner circumferential surface of 50), it is slightly expanded in the inner diameter expansion groove 58 of the housing 50 and then compressed again through the inner diameter expansion groove 58. Therefore, the ring gasket G provides airtightness to the inner circumferential surface of the housing 50 in a compressed state when the incorporation of the pressure reducing valve 70 and the flow control valve 80 is completed.

Since the ring gasket G is expanded as described above in the inner diameter expansion groove 58 of the housing 50, the ring gasket G is formed at the edge of the lower nozzle fixing hole 56a on which the lower nozzle 56 of the housing 50 is fixed. It does not rub badly. Therefore, the ring gasket G is not damaged by the edge of the nozzle fixing hole 56a.

As described above, when the interior of the pressure reducing valve 70, the retaining ring 90 and the flow control valve 80 is completed, as shown in FIG. The exhaust part 1a of 1) is fixed. Then, the gas is exhausted from the exhaust section 1a of the cylinder 1. Accordingly, the gas of the exhaust unit 1a is supplied to the indicator I and the pressure reducing valve 70 through the air supply valve 60 of the housing 50, and the indicator I is discharged from the cylinder 1. Express the pressure of the gas. Here, the oxygen supplied to the pressure reducing valve 70 is filled in the chamber 95 provided in the lower portion of the pressure reducing valve 70 through the guide ring 74 and the valve poppet 72 of the pressure reducing valve 70. Of course, the oxygen to be supplied is supplied to the chamber 95 through the hollow formed in the central axis 72a of the valve poppet 72.

In this way, the oxygen charged in the chamber 95 is supplied to the upper flow path 50a of the housing 50 while flowing backward when the lower flow control valve 80 is closed. This oxygen is supplied to the upper nozzle 54 of the housing 50 through the upper flow passage 50a. Thus, the upper nozzle 54 exhausts oxygen to the outside of the housing 50. Of course, when the lower flow rate control valve 80 is opened, oxygen charged in the chamber 95 is exhausted to the lower nozzle 56 of the housing 50 through the flow rate control valve 80.

At this time, when the oxygen supplied from the air supply valve 60 exceeds the pressure of 3.5kg / cm ² , the oxygen charged in the chamber 95 is suddenly compressed in the chamber 95, the lower portion of the valve poppet 72 Push up the face. Of course, the oxygen compressed in the chamber 95 is supplied to the lower edge of the valve poppet 72 through the unevenness 92 or the protrusion 94 of the retainer ring 90. Accordingly, as shown in FIG. 5, the valve poppet 72 compresses the elastic body 76 by the pressure of oxygen compressed in the chamber 95 and at the same time the guide ring 74 which surrounds the central axis 72a. Ascend with guidance. Then, as shown in FIG. 5, the air supply valve 60 is shielded to the upper end of the sealed central shaft 72a. Of course, the air supply valve 60 is stopped by the central axis (72a) of the valve poppet (72).

As such, when the air supply is stopped, oxygen remaining inside the housing 50 is exhausted to the upper nozzle 54 or the lower nozzle 56 of the housing 50 according to the opening / closing state of the flow control valve 80. do. Thus, the pressure in the chamber 95 drops. At this time, the elastic body 76 compressed by the valve poppet 72 is circularly restored again and lowers the valve poppet 72 as shown in FIG. 4. Of course, the descending valve poppet 72 is returned to its original position while being guided by the guide ring 74 by the central axis 72a, and simultaneously opens the shielded air supply valve 60 again. Let's do it. Accordingly, the air supply valve 60 supplies oxygen to the inside of the housing 50 again.

Thus, oxygen supply to the air supply valve 60 to exceed the pressure of 3.5kg / cm ^2, as the poppet valve 72 is interrupted the supply valve 60 based on the pressure of 3.5kg / cm ^2, the valve By intermittent operation of the poppet 72 is reduced to a pressure of 3.5kg / cm ² or less. Therefore, the pressure of oxygen supplied from the air supply valve 60 and supplied into the housing 50 is always maintained at 3.5 kg / cm ² or less. That is, the pressure of the oxygen supplied to the inside of the housing 50 cannot always exceed the pressure of 3.5 kg / cm <^2> or more.

On the other hand, in order to supply oxygen to the lower nozzle 56 of the housing 50, the knob 87 of the flow control valve 80 is rotated. Then, the pinhole disk 84 is rotated by the knob 87 to correspond to any one of the plurality of pinholes 84a to the flow path 82a of the body 82 as shown in FIG. 5. Therefore, oxygen discharged through the valve poppet 72 of the pressure reducing valve 70 is exhausted to the lower nozzle 56 through the flow path 82a of the body 82.

Here, to adjust the flow rate of oxygen exhausted to the lower nozzle 56, the knob 87 may be rotated again. Then, the pinhole disk 84 corresponds to the flow path 82a with another pinhole 84 having a diameter different from that of the pinhole 84a corresponding to the flow path 82a. Therefore, the flow rate of the oxygen exhausted to the lower nozzle 56 can be freely adjusted. That is, the flow rate of oxygen exhausted to the lower nozzle 56 is determined by the diameter of the pinhole 84a of the pinhole disk 84 corresponding to the flow path 82a.

At this time, to stop the exhaust of the lower nozzle 56, the knob 87 is rotated to the end. Then, the pinhole disk 84 corresponds to the flow path 82a so that the non-pin hole section in which the pinhole 84a is omitted, shields the flow path 82a. Therefore, exhaust of the lower nozzle 56 is stopped.

In conclusion, the flow control valve 80 may stop the exhaust of the lower nozzle 56 or freely adjust the flow rate of oxygen exhausted to the lower nozzle 56 according to the operation of the knob 87. That is, the flow rate control valve 80 may control the flow rate of oxygen discharged from the lower nozzle 56 in accordance with the operation of the knob 87.

Such a regulator of the present invention may be configured as shown in FIGS. 6 and 7, as described above. 6 is a longitudinal sectional view showing a regulator according to another embodiment of the present invention, Figure 7 is an exploded perspective view showing the configuration of the flow control valve shown in FIG.

At this time, the regulator according to another embodiment of the present invention, the valve poppet 72 of the pressure reducing valve 70, the thickness of the retainer ring 90, and the rotation member of the flow control valve 80 described above Different from the regulator of one embodiment, the remaining components are all the same. Therefore, in the description, the same components as those of the regulator described above will be described with the same reference numerals. As described above, components different from those of one embodiment will be described in detail as follows.

First, the valve poppet 72 of the pressure reducing valve 70 has a lower open poppet chamber 72c as shown in FIG. At this time, the depth and diameter of the poppet chamber (72c) is preferably about 3mm ~ 6mm and 1.2cm ~ 1.8cm. In addition, the depth and diameter of the poppet chamber 72c are most preferably about 5 mm and 1.5 cm. The poppet chamber 72c is provided by drawing or cutting the lower portion of the valve poppet 72.

Next, the retainer ring 90 has a thickness thinner than the retainer ring 90 of one embodiment, as shown in FIG. 6. Such, the thickness of the retaining ring 90 is slightly thicker than the thickness of the disk cap 88 of the flow control valve 80 described later as shown. At this time, the retaining ring 90 is preferably configured to have a thickness of about 0.1mm to 0.3mm thicker than the disk cap 88. In particular, it is more preferable to configure it to have a thickness thicker by about 0.3 mm. As such, when the thickness of the retainer ring 90 is configured to be about 0.3 mm thicker than the disc cap 88, the upper end of the retainer ring 90 is enlarged in the drawing due to the thickness of the disc cap 88. Protrude 0.3mm more upward.

At this time, the valve poppet 72 and the upper surface of the flow control valve 80 of the pressure reducing valve 70 is spaced apart by the retainer ring 90 protruded by about 0.3 mm. Therefore, the pressure reducing valve 70 and the flow control valve 80 are prevented from contacting. Of course, the pressure reducing valve 70 cannot pressurize the flow control valve 80. As such, as the pressure reducing valve 70 does not pressurize the flow control valve 80, the disc cap 88 of the flow control valve 80 may be rotated by a rotating member to be described later.

Here, the retaining ring 90 has an unevenness 92 or a protrusion 94, as described above in one embodiment. Therefore, the retainer ring 90 supplies the compressed oxygen of the poppet chamber 72c provided in the valve poppet 72 of the pressure reducing valve 70 to the edge of the valve poppet 72. Of course, the oxygen supplied to the edge of the valve poppet 72 is supplied between the valleys of the concave-convex 92 of the retainer ring 90 and the gap of the protrusion 94. Thus, as the retaining ring 90 supplies the compressed oxygen of the poppet chamber 72c to the edge of the valve poppet 72, the valve poppet 72 rises smoothly while being provided with the floating force on the entire lower surface.

Finally, the rotating member of the flow control valve 80, as shown in Figure 7, the disk cap 88 having a vertical axis (88a) in the center; And a knob 89 which is integrally coupled to and rotates on the vertical axis 88a of the disc cap 88.

Here, the disk cap 88 has an air supply hole H as shown in FIG. 7 on the upper surface to supply oxygen to the pinhole disk 84. In addition, the vertical axis 88a of the disc cap 88 sequentially passes through the pinhole disk 84 and the body 82 as shown. Of course, the disk cap 88 shields the upper surface of the pinhole disk 84 as shown in FIG. 6, where the pinhole disk 84 is splined to the vertical axis 88a of the disk cap 88. Thus, the pinhole disk 84 is integral with the vertical axis 88a. As such, the vertical axis 88a of the disc cap 88 is integrally fixed to the knob 89 as shown, and rotates upon the rotation of the knob 89.

At this time, the pinhole disk 84 is preferably formed to a thickness of the thin plate, as shown in FIG. Thus, it is possible to prevent the height of the flow control valve 80 from rising. That is, the pinhole disk 84 must be formed in a thin plate shape, so that the flow rate control valve 80 can be manufactured compactly. Of course, when the pinhole disk 84 is formed of a thin plate, the pinhole 84a can be easily formed on the pinhole disk 84. Therefore, not only the flow control valve 80 can be easily manufactured, but also the manufacturing cost can be reduced.

On the other hand, the reason why the poppet chamber 72c is provided in the valve poppet 72 of the pressure reducing valve 70 according to another embodiment as described above, the thickness of the retainer ring 90 according to the embodiment described above It is because it became thinner than the thickness of 90. This is because the chamber 95 as shown in FIG. 4 is not provided between the pressure reducing valve 70 and the flow control valve 80 due to the thin thickness of the retaining ring 90. That is, the poppet chamber 72c formed on the lower surface of the valve poppet 72 replaces the chamber 95 of FIG. If the poppet chamber 72c is not provided in the valve poppet 72, the valve poppet 72 cannot be lifted. This is because oxygen supplied from the air supply valve 60 is not compressed. Thus, when the oxygen supplied from the air supply valve 60 is not compressed, the valve poppet 72 is not lifted because it does not receive the floating force.

Here, the chamber 95 shown in FIG. 4 according to one embodiment and the poppet chamber 72c of the valve poppet 72 according to another embodiment have almost the same volume. This is because the chamber 95 shown in FIG. 4 has the same diameter as the inner circumferential surface of the housing 50 and a height of about 1 mm to 3 mm. The poppet chamber 72c has a diameter of about 1.2 cm to 1.8 cm and a depth of 3 mm to 6 mm. Such a poppet chamber 72c has a depth corresponding to the height of the chamber 95 although the diameter is smaller than that of the chamber 95 described above. Therefore, the volumes of the poppet chamber 72c and the chamber 95 are almost the same. Of course, the poppet chamber 72c and the chamber 95 have almost the same action of compressing gas by volume.

In this way, since the poppet chamber 72c and the chamber 95 operate almost the same, the valve poppet 72 according to another embodiment may be elevated by oxygen compressed in the poppet chamber 72c. Therefore, in another embodiment, even if the retaining ring 90 spaces the pressure reducing valve 70 and the flow control valve 80 into a space, the valve poppet 72 of the pressure reducing valve 70 can be elevated.

Referring to the operation of the regulator according to another embodiment of the present invention configured as described above is as follows, the operation of such a regulator can be easily understood with reference to Figure 5 described above, the description of the operation see FIG. Will be explained.

The regulator according to another embodiment of the present invention is supplied with oxygen by the air supply valve 60 as shown in FIG. This oxygen is passed through the guide ring 74 of the pressure reducing valve 70 and the central axis 72a of the valve poppet 72, the poppet chamber 72c of the valve poppet 72 and the disk of the flow control valve 80. Supplied to the cap 88. At this time, oxygen supplied to the disc cap 88 is supplied through the air supply hole H of the disc cap 88. Thus, when the flow control valve 80 is closed, the supplied oxygen is flowed back and exhausted through the upper flow path 50a of the housing 50.

At this time, when the pressure of the oxygen supplied from the air supply valve 60 exceeds 3.5kg / cm ² , the oxygen supplied to the poppet chamber 72c is compressed by the poppet chamber 72c and the lower portion of the valve poppet 72 Push up the face. Of course, oxygen compressed in the poppet chamber 72c is supplied to the edge of the valve poppet 72 through the retainer ring 90. Therefore, the valve poppet 72 rises smoothly while being guided by the guide ring 74 surrounding the central axis 72a. Then, the valve poppet 72 shields the discharge port of the air supply valve 60 to the upper end of the central axis 72a. Of course, the valve poppet 72 ascends and compresses the elastic body 76 (see FIG. 5).

In this way, as the discharge port of the air supply valve 60 is shielded, oxygen remaining in the housing 50 is exhausted through the upper passage 50a. Therefore, the oxygen pressure formed in the poppet chamber 72c of the valve poppet 72 drops. At this time, the elastic member 76 returns to the original position while restoring the circular shape. Of course, as the valve poppet 72 returns, the air supply valve 60 supplies oxygen to the inside of the housing 50 again. As such, since the valve poppet 72 interrupts the air supply valve 60 according to the pressure of oxygen supplied from the air supply valve 60, the oxygen supplied to the inside of the housing 50 is always about 3.5 kg / cm ² . Maintain pressure (see Figure 5).

The oxygen supplied to the inside of the housing 50 may be exhausted to the lower nozzle 56 of the housing 50 by the flow control valve 80. In this way, in order to exhaust the internal oxygen of the housing 50 to the lower nozzle 56, the knob 89 is operated and rotated. The knob 89 then rotates the disc cap 88 along with the vertical axis 88a of the disc cap 88.

At this time, the pinhole disk 84 rotates together with the disk cap 88. The pinhole disk 84 rotates to correspond to any one of the plurality of pinholes 84a or the pinholes 84a in the flow path 82a formed in the body 82 of the flow control valve 80. Correspond to non-pin pin holes. Therefore, the flow path 82a of the body 82 connected to the lower nozzle 56 is shielded by the pinhole disk 84 or is opened only by the diameter of the corresponding pinhole 84a. As a result, as the flow path 82a of the body 82 is opened or closed by the pinhole disk 84 or the flow rate is adjusted, the exhaust amount exhausted to the lower nozzle 56 is naturally controlled. Of course, oxygen exhausted to the lower nozzle 56 through the flow path 82a of the body 82 is oxygen discharged from the pressure reducing valve 70 and introduced into the air supply hole H of the disc cover 88.

On the other hand, the flow control valve 80 disclosed in the above-described other embodiments, can be applied to the regulator of the embodiment described above. At this time, the retainer ring 90 should provide a chamber 95 as shown in FIG. 4, or space the space between the pressure reducing valve 70 and the flow control valve 80.

In addition, the flow control valve 80 disclosed in one embodiment may be applied to the regulator of another embodiment. At this time, the retaining ring 90 should provide a chamber 95 as shown in FIG.

The above embodiment is merely a description of the preferred embodiment of the present invention, the scope of application of the present invention is not limited to such, and can be changed as appropriate within the scope of the same idea. Accordingly, the components, shapes, structures, and the like shown in the embodiments of the present invention may be modified and implemented, and such modifications are naturally within the scope of the appended claims.

In the regulator according to the present invention as described above, since the retaining ring separates the pressure reducing valve and the flow control valve and prevents contact between the pressure reducing valve and the flow control valve, the cylinder having the stepped as in the prior art can be omitted. In addition, it is possible to reduce the manufacturing process and manufacturing cost of the recirculator, and to produce the recirculator in a very compact manner.

In addition, when the poppet chamber is formed in the valve poppet of the pressure reducing valve, and the pressure reducing valve and the flow control valve are spaced apart by the retainer ring, the gas compressed in the poppet chamber pushes up the valve poppet, thereby elevating the valve poppet. In addition, the gap between the pressure reducing valve and the flow control valve can be minimized, so that the length of the regulator can be shortened more compactly.

In addition, since the retaining ring provides a chamber between the pressure reducing valve and the flow control valve, or in addition, the compressed gas is supplied to the valve poppet rim of the pressure reducing valve, even if the cylinder with the step is formed as in the prior art, There is also an effect that can lift the valve poppet by using the exhaust oxygen.

In addition, since the ring gasket of the pressure reducing valve and the flow control valve does not rub against the edge of the nozzle fixing hole formed at the lower end of the housing by the inner diameter expansion groove of the housing, the ring gasket can be prevented from being damaged. .

Claims (10)

In the regulator for reducing the pressure of the high pressure gas discharged from the exhaust (1a) of the cylinder (1), The upper part has a fixing part 52 which fixes the exhaust part 1a of the said cylinder 1 in the upper surface, and the nozzle fixing hole 54a, 56a provided in the upper-lower side is an image which exhausts internal gas to the outside. A housing 50 in the form of a cap on which the lower nozzles 54, 56 are mounted; An air supply valve (60) fixed to the housing (50) to supply gas discharged from the exhaust (1a) of the cylinder (1) into the housing (50); The gas of the air supply valve 60 is discharged to the inside lower side of the housing 50, and is supplied to the housing 50 while opening and closing the air supply valve 60 according to the pressure of the gas supplied from the air supply valve 60. A pressure reducing valve 70 for reducing the pressure of the gas; It is built in the airtight state in the housing 50 is aligned in line with the pressure reducing valve 70, the upper edge has a step 80a, and controls the flow rate of the gas discharged from the pressure reducing valve 70, the housing A flow control valve 80 provided to the lower nozzle 56 of the tank 50; A retainer ring disposed at the step 80a of the flow control valve 80 to support the lower edge of the pressure reducing valve 70 and to prevent contact between the pressure reducing valve 70 and the flow control valve 80; 90); regulator comprising a. According to claim 1, wherein the pressure reducing valve 70, A ring gasket G for providing airtightness to the inner circumferential surface of the housing 50 is provided on the outer circumferential surface, and an upper sealed central shaft 72a having a hollow for supplying gas discharged from the air supply valve 60 to the lower portion. A valve poppet 72 having a disk-shaped valve for opening and closing the air supply valve 60 to an upper end of the central axis 72a while being raised and lowered according to the pressure of the gas supplied downward; The upper end of the central shaft 72a of the valve poppet 72 is tightly connected to the lower portion of the air supply valve 60, and the gas discharged from the air supply valve 60 is centered on the inner circumferential surface thereof. A guide ring 74 for guiding the lifting and lowering of the valve poppet 72 at the same time as being supplied to the hollow of; And an elastic body (76) elastically supporting the valve poppet (72) and the guide ring (74). The pressure reducing valve 70 of claim 2, Poppet ascending means for raising the valve poppet (72) by using a high-pressure gas supplied through the central axis (72a) of the valve poppet (72); The poppet ascending means forms a lower open poppet chamber 72c connected to the central axis 72a of the valve poppet 72 at the center of the lower surface of the valve poppet 72 to form a center of the valve poppet 72. The high pressure gas supplied from the shaft (72a) is compressed in the lower portion of the valve poppet (72) and configured to push up the valve poppet (72). The method according to any one of claims 1 to 3, The retainer ring 90 is formed so that the upper end protrudes above the flow control valve 80 to support the lower edge of the pressure reducing valve 70, and at the same time, the pressure reducing valve 70 and the flow control valve ( 80) is configured to be spaced apart from the regulator. The method of claim 4, wherein the retainer ring 90, Continuously formed along the circumferential direction, a plurality of irregularities 92 for supplying the gas supplied from the air supply valve 60 to the lower surface edge of the pressure reducing valve 70 through the bone; regulator. The method of claim 4, wherein the retainer ring 90, It is formed along the circumferential direction, a plurality of projections (94) for providing the gas supplied from the air supply valve 60 to the lower surface edge of the pressure reducing valve 70 through the spaced apart gap; A regulator characterized by the above. According to claim 1, wherein the flow control valve 80, A ring gasket G for providing airtightness to the inner circumferential surface of the housing 50 is provided on the outer circumferential surface, and a flow path for supplying gas discharged from the pressure reducing valve 70 to the lower nozzle 56 of the housing 50. Cylindrical body 82 having 82a; While being rotatably installed at the center of the upper surface of the body 82, the step 80a is provided at the upper end of the body 82, a plurality of pinholes 84a having different diameters along the circumferential direction, etc. The lower nozzle of the housing 50 by having a distance therebetween and corresponding one of the plurality of pinholes 84a to the flow path 82a of the body 82 or between the plurality of pinholes 84a A pinhole disk 84 for controlling the flow rate of the gas supplied to the 56; And a rotating member connected to the pinhole disk (84) to rotate the pinhole disk (84). The method of claim 7, wherein the rotating member, A rotation shaft 86 extending from the center of the pinhole disk 84 and vertically penetrating the body 82; And a knob (87) coupled to the rotating shaft (86) to rotate. The method of claim 7, wherein the rotating member, The upper surface of the pinhole disk 84 is shielded, and has an air supply hole (H) on the upper surface for supplying the gas discharged from the pressure reducing valve 70 to the pinhole disk 84, the body 82 and the pinhole A disk cap 88 having a vertical axis 88a integrally coupled with the pinhole disk 84 while penetrating the center of the disk 84; And a knob (89) coupled to and rotated on the vertical axis (88a) of the disc cap (88). The method according to any one of claims 2, 3 or 7, The housing 50 is prevented from being damaged when the pressure reducing valve 70 and the flow control valve 80 are embedded, and the ring gasket G is pressed against the inner circumferential surface of the lower side of the housing 50. Means; further comprising, The damage preventing means is formed by forming an inner diameter expansion groove 58 in the circumferential direction on the inner circumferential surface of the housing 50 in which the lower nozzle fixing hole 56a of the housing 50 is located, and thereby the lower side of the housing 50. And a coefficient of friction of the ring gasket (G) with respect to an inner circumferential surface thereof.

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