KR101086199B1 - Rotation prevention structure of control knob of gas pressure regulator using slide locking method - Google Patents

Abstract

The present invention is a gas pressure regulator for adjusting the pressure of the gas (GAS), the well-known regulator-body, regulator-lid, pressure holding means and control knob to adjust and maintain the pressure of the gas flowing through the gas pipe line (KNOB), and the interlocking means that is engaged with each other and fixed to each other and the connection medium which is slidably installed to prevent the rotation of the control knob by using the intermittent means further comprises the initial setting value by the occurrence of long-term vibration A control knob rotation prevention structure of a gas pressure regulator using a slide locking method for preventing this gradually changing.

Gas pressure regulator, Adjustment knob, Anti-rotation, Gas piping line, Slide

Description

KNOB ROTATION PREVENTING STRUCTURE FOR GAS PRESSURE REGULATOR BY SLIDE LOCKING TYPE}

The present invention relates to a gas pressure regulator, and more particularly, to a gas pressure regulator for maintaining the pressure of the gas flowing through the gas piping line to the required pressure required in each process.

In general, the gas pressure regulator keeps the gas supplied to a process requiring gas (GAS) at a required pressure and fine-tunes it, such as a general industrial or semiconductor process that induces chemical reactions and produces products as necessary. It is used to (Regulation).

That is, by adjusting gas knobs in the gas piping lines installed in each process to fine-tune the adjustment knobs, the gas flow pressure is increased or decreased to maintain the gas pressure at the required pressure required for each process. .

Such a gas pressure regulator has a technical configuration published in [Document 1] and [Document 2]. Briefly, the gas pressure regulator includes a regulator connected to a gas pipe line and a body, and a regulator that seals the body. And a lid, pressure holding means for maintaining the pressure of the gas passing through the regulator-body, and adjusting knob KNOB for fine-adjusting the pressure holding means.

Therefore, by rotating the control knob clockwise or in the opposite direction to finely adjust the pressure by using the spring of the regulator-lid and the spring of the regulator-body included in the pressure holding means, through which the gas required in each process Is adjusted to the required pressure.

However, the conventional gas pressure regulator including the above [Document 1] and [Document 2] is gradually set as time passes due to the vibration of the gas pipe line and the micro vibration generated when the gas flows. Due to the change in pressure, it is difficult to maintain the required pressure required for each process.

This is because the pressure holding means for maintaining the pressure of the gas and the adjusting knob for fine-adjusting the gas are simply screwed. If you move even a little by the micro-vibration generated by the micro-vibration caused by the screw-type adjustment knob is slowly rotated to loosen.

As a result, the initial setting value optimized for each process is changed little by little. Thus, for example, a gas is supplied at a pressure of 0.9 Bar or 0.8 Bar to a process in which the gas should be supplied at a pressure of 1 Bar. It occurs frequently or frequently.

When the setting value is changed in this way, instability of the gas supply is caused, and thus, there are various problems such as deterioration of productivity and even worse product.

Document 1 KR 20-1997-0055392, 1997.10.13

[Document 2] KR 10-0753280, 2007.08.22

Therefore, the present invention solves the problem that the setting knob KNOB rotates slowly due to vibration of gas pipe line and other reasons, and the setting value adjusted to the required pressure required in each process changes over time. It is to solve completely.

SUMMARY OF THE INVENTION An object of the present invention is to provide a control knob rotation preventing structure of a gas pressure regulator using a slide locking method that allows the user to freely use the adjusting knob so that the initial setting value for the pressure of various conditions is constantly maintained. have.

An object of the present invention as described above is connected to the gas piping line regulator-body formed with an air supply-port and an exhaust-port to supply and exhaust gas;

An adjuster-lid assembled to the adjuster-body and hermetically sealed;

Pressure holding means embedded in the regulator-body and the regulator-cap to maintain the pressure of the gas, and including a pressure adjusting screw exposed to the outside through the regulator-lid;

An adjusting knob formed by adjusting the pressure while rotating the pressure adjusting screw and having a second accommodation space having a diameter smaller than the first accommodation space such that a first accommodation space and a fixed jaw communicate with each other at an inner center thereof;

Intermittent means fixed to and engaged with each other so that the adjustment knob is not rotated;

The adjusting knob rotates along the pressure adjusting screw and is provided with screw coupling parts fastened to the pressure adjusting screw so as to adjust the pressure, and are installed in the first and second accommodation spaces. It is achieved by including a connecting medium slidably installed in the first and second accommodation space.

According to the configuration of the present invention, the interlocking means which is engaged with each other and fixed to each other further comprises a connecting medium for preventing the rotation of the adjustment knob using the control means, the setting value initially set by the adjustment knob using the slide locking method There is an effect that can be prevented from changing over time.

Therefore, by constantly supplying gas on the basis of the setting value set by the adjusting knob, stable production of the product using the gas is achieved, and the defective rate is minimized.

In addition, the connection medium includes a nut accommodating space to accommodate the upper assembly and the nut of the polygon has the effect of improving the connectivity and safety of use with the adjustment knob.

Furthermore, the configuration of the present invention further includes an O-ring, which is a very useful invention that can absorb the micro vibrations such as the gas pipe line and more effectively prevent the rotation of the control knob using the control means and the connection medium. .

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

1 is an exploded perspective view of a gas pressure regulator according to an exemplary embodiment of the present invention, in which the gas pressure regulator including a control knob rotation preventing structure is disassembled and shown.

Figure 2 is a cross-sectional view showing a state of engagement of the gas pressure regulator according to an embodiment of the present invention, it is shown by combining the gas pressure regulator comprising a control knob rotation prevention structure.

Figure 3 is an exploded perspective view of the control means according to an embodiment of the present invention, it is shown that the first gear and the second gear that is engaged with each other is formed on the adjustment handle and the adjuster-lid, respectively.

4 to 5 is a view showing the use state by partially expanding the fixed handle is not rotated by the anti-rotation structure according to the present invention, the first gear and the second gear through each other by sliding movement using the connection medium Interlocking adjustment knob showing fixed to regulator-body

That is, the present invention adjusts the pressure of the gas by the vibration of the gas pipe line 2 and the vibration of the gas flow rate in the process of using the gas pressure regulator 1 to adjust the pressure of the gas (GAS). The adjusting knob 40 is slowly rotated to prevent the setting value from being initially set to change.

To this end, the gas pressure regulator 1 according to the present invention includes a regulator-body 10 connected to the gas pipe line 2, a regulator-cap 20 for hermetically sealing the regulator-body 10, and a gas. Intermittent means for preventing the rotation of the adjustment knob 40 through the engagement fixed to a known configuration including a pressure holding means 30 for maintaining a constant pressure and an adjustment knob 40 for adjusting the pressure of the gas ( 50) and the connection medium 60 are further included as basic features of the technical configuration.

That is, the present invention includes a known regulator-body 10, as shown in Figures 1 and 2, and is connected to the gas pipe line 2 using the regulator-body 10, the air supply-port ( Gas is supplied through 11) to exhaust through the exhaust-port 12.

The gas pressure regulator 1 according to the present invention includes the regulator-body 10 and a known regulator-lid 20, and the regulator-body 10 is hermetically sealed using the regulator-lid 20. This prevents the gas from flowing out of the gas pressure regulator 1 and causing a safety accident.

The regulator-body 10 and the regulator-lid 20 are built with a known pressure holding means 30 to maintain the pressure of the gas, as is known, the pressure holding means 30 is a locking plate ( 31) and the compression spring 32 to maintain the pressure of the gas through the main valve pin (Pin), which determines the degree of pressure substantially.

Here, the pressure holding means 30 is a pressure adjusting screw exposed to the outside through the regulator-cap 20 to enable the movement of the main valve-pin 33 through the adjusting knob 40 according to the present invention ( 34), wherein the adjustment knob 40 rotates the pressure adjusting screw 34 to compress the compression spring 32, and accordingly, the main valve-pin 33 is raised or lowered so that the gas The exhaust pressure of the gas pressure regulator 1 is well known in the art of the gas pressure regulator 1.

Adjusting knob (KNOB) according to the present invention, as described above, to perform the function of adjusting the pressure of the gas by rotating the pressure adjusting screw 34.

At this time, the control knob 40 is indirectly fastened to the pressure adjusting screw 34 by using the connection medium 60 which will be described in detail below, rather than being directly coupled to the pressure adjusting screw 34, unlike the existing method. As shown in FIG. 2, the first accommodation space 41 and the second accommodation space 42 communicate with each other at the inner center thereof.

In addition, the first accommodation space 41 is formed so that the connection medium 60 is accommodated therein and the control knob 40 is formed to a depth that can be moved in one direction (downward direction on the drawing) by using the same. The second accommodation space 42 has a diameter smaller than that of the first accommodation space 41 so that the fixing jaw 43 is formed in the first accommodation space 41 to allow tightening through the nut 44. .

That is, the adjustment knob 40 according to the present invention includes the first accommodation space 41 and the second accommodation space 42, so that the indirect connection with the pressure adjusting screw 34 using the connection medium 60 is possible. And, it further comprises a fixing jaw 43 formed by the second accommodation space 42 it is possible to tighten the fixing through the known nut 44.

Accordingly, the adjustment knob 40 includes a first accommodating space 41 and a second accommodating space 42 so as to be fastened with the pressure adjusting screw 34 and tightened using the nut 44. It is shown by the cross section in FIG. 2 which is hollow all over up and down.

The intermittent means 50 according to the present invention prevents the adjustment knob 40 from being rotated finely as time passes by self-vibration of the gas pipe line 2 due to gravity or vibration caused by the flow rate of gas. They are interlocked and fixed together so that

In the present invention, the control means 50 uses the first and second gears 51 and 52, which are gears. As shown in FIG. 3, the first gear is located in the lower part of the adjustment knob 40 as an embodiment. A 51 is formed inward, and a second gear 52 to which the first gear 51 is engaged and fixed is formed outwardly on the adjuster-cap 20.

That is, as the first gear 51 is formed toward the inside, and the teeth of each gear are fixed to each other as the second gear 52 is formed to the outside, the adjustment knob 40 due to the engagement fixed. Is slowly rotated by the micro-vibration to prevent loosening.

At this time, the position where the first gear 51 and the second gear 52 are formed is only one embodiment for preventing the rotation of the adjustment knob 40 through the engagement method which is the main function of the control means 50. It is possible to change freely wherever they can interlock.

Connection medium 60 according to the present invention, as shown in Figure 2 so that the adjusting knob 40 to adjust the pressure while rotating the pressure adjusting screw 34, the screw coupling portion fastened to the pressure adjusting screw 34 ( 61 is formed inside and installed in the first and second accommodating spaces 41 and 42. The first and second gears 51 and 52, which are the aforementioned control means 50, are engaged with and fixed to each other to adjust the adjustment knob ( 40 is slidably installed in the first and second accommodation spaces 41 and 42 to prevent the 40 from being rotated.

The connecting medium 60 is mainly formed of synthetic resin, aluminum or brass (Brass) as an address material, and by slidably installing it in the first and second accommodation spaces (41, 42), the screw coupling formed in the inner center The pressure adjusting screw 34 and the adjusting knob 40 are mutually fastened by using the part 61 to be able to adjust the pressure through the adjusting knob 40, and further, the adjusting knob 40 to adjust the pressure. ) Is pushed downward in the drawing so that the slide locking (Slide Locking) through the control means 50 can be made.

 As shown in FIG. 2 or FIG. 4, the upper assembly part 62 slides in the first accommodation space 41 and the screw coupling part 61 therein. ) Is formed in the second receiving space (42) accommodated in the state, wherein the upper assembly 62 and the lower assembly 63 is formed integrally or separately.

Connection medium 60 according to an embodiment of the present invention includes the upper assembly portion 62 and the lower assembly portion 63, the upper assembly portion 62 is limited to being formed in a polygon, the upper assembly portion ( The inside of the 62 further includes a nut receiving space 64 is formed.

Therefore, as the upper assembly part 62 of the polygon is accommodated in the first accommodating space 41, the adjusting knob 40 and the connecting medium 60 are adjusted in the process of adjusting the pressure using the adjusting knob 40. It is prevented from rotating independently of each other.

In addition, by using a general tool in addition to the operator with a dedicated tool that can loosen the nut 44 by receiving the nut 44 to be fastened so as not to be separated from the pressure adjusting screw 34 through the nut accommodation space 64 By preventing the handle 40 to be separated to prevent a safety accident.

Connection medium 60 according to another embodiment of the present invention includes all of the configuration of the above embodiment, as shown in Figures 4 to 5, the lower assembly 63 is an O-ring (O-ring) It will further include the fastened.

That is, the o-ring 65 maintains the airtightness of the control knob 40 and the connection medium 60 processed in the tolerance range (±), induces a smooth sliding movement of the control knob 40, gas piping By the vibration transmitted from the line (2) it is prevented from being loosened while the control knob 40 which is engaged by using the control means 50 is gradually pushed out.

Accordingly, the O-ring 65 is slidably fastened to the first and second accommodating spaces 41 and 42 by being connected to the lower assembly part 63 in the clockwise or reverse direction. As shown in the imaginary line of FIG. 5, the adjusting knob 40 adjusting the pressure while rotating the pressure adjusting screw 34 is slid in the downward direction in the drawing to intercept the first gear 51, which is an intermittent means 50. The second gear 52 is engaged with each other and is prevented from being rotated by the adjustment knob 40 of the gas pressure regulator 1 according to the present invention through the slide locking method.

1 is an exploded perspective view showing a gas pressure regulator according to an embodiment of the present invention.

Figure 2 is a cross-sectional view showing a combined state of the gas pressure regulator according to an embodiment of the present invention.

Figure 3 is an exploded perspective view showing a control means according to an embodiment of the present invention.

Figures 4 to 5 is a state of use showing a part enlarged that is fixed so that the adjustment knob is not rotated by the anti-rotation structure according to the present invention.

Explanation of symbols on the main parts of the drawings

1-Gas pressure regulator 2-Gas piping line

10-adjuster-body 20-adjuster-lid

30-Pressure holding means 34-Pressure adjusting screw

40-Adjusting Knob 41-1st Accommodating Space

42-2nd Accommodating Space 43-Fixed Jaw

50-control means 51-first gear

52-2nd Gear 60-Connecting Media

65-O-ring

Claims (4)

A regulator-body connected to the gas pipe line, the regulator-body having an air supply port and an exhaust port configured to supply and exhaust gas; An adjuster-lid assembled to the adjuster-body and hermetically sealed; Pressure holding means embedded in the regulator-body and the regulator-cap to maintain the pressure of the gas, and including a pressure adjusting screw exposed to the outside through the regulator-lid; An adjusting knob formed by adjusting the pressure while rotating the pressure adjusting screw and having a second accommodation space having a diameter smaller than the first accommodation space such that a first accommodation space and a fixed jaw communicate with each other at an inner center thereof; A first gear formed on the adjusting knob and a second gear formed on the adjuster-cap to be engaged with the first gear; A screw coupling part fastened to the pressure adjusting screw is formed therein, and the first and second gears are slidably installed in the first and second accommodation spaces so that the first and second gears are engaged with each other during the sliding movement of the adjusting knob. Adjusting knob rotation prevention structure of the gas pressure regulator using a slide locking method characterized in that it comprises a. The method of claim 1, wherein the first gear is formed in the lower inner side of the adjustment knob toward the inside, the second gear is a control knob of the gas pressure regulator using a slide locking method, characterized in that formed on the adjuster-cap outward. Anti-rotation structure. The method of claim 1, wherein the connection medium is composed of an upper assembly that is accommodated in the first accommodation space and slide, and a lower assembly that is accommodated in the second accommodation space with a screw coupling portion formed therein, the upper assembly is a polygon It is formed, the rotation preventing structure of the adjustment knob of the gas pressure regulator using the slide locking method, characterized in that the receiving space is formed to accommodate the nut therein. The method of claim 3, wherein the O-ring (O-ring) is fastened to the lower assembly, characterized in that the locking knob rotation prevention structure of the gas pressure regulator using a slide locking method.

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