KR101082539B1 - Quick coupler - Google Patents

Abstract

The present invention relates to a quick coupler, an object of the present invention is to easily check the internal contamination state of the quick coupler, and to provide a quick coupler that is easy to disassemble and assemble the parts to be reused after cleaning the parts. The present invention for this purpose is a first valve cylinder formed in the flow path for the flow of the fluid, the first valve unit is installed inside the first valve cylinder to control the fluid flowing through the first valve cylinder and the A first coupler composed of a first limit bolt screwed to be disassembled to the first valve cylinder to prevent separation of the first valve unit and having a first through hole for movement of a fluid supplied through the flow path; A second valve cylinder coupled to the first valve cylinder and having another flow path continuously communicating with the flow path of the first valve cylinder and having a fluid installed therein, and installed in the second valve cylinder to provide a second valve; A second valve unit for controlling the fluid flowing through the cylinder, and a second limit screwed to be disassembled to the second valve cylinder to prevent separation of the second valve unit and having a second through hole for moving the fluid; A second coupler consisting of a bolt; And it relates to a quick coupler comprising a coupling means for binding the first coupler and the second coupler to the technical gist.

Quick coupler, limit bolt, sealing member, valve shaft, valve unit

Description

Quick coupler

The present invention relates to a quick coupler, and more particularly, to a quick coupler having improved airtightness through structural improvement, easy disassembly and assembly, easy to clean and replace parts.

In general, a quick coupler is a device that connects two pipes so that pipes and pipes for transporting a fluid such as gas or liquid to another place can be connected quickly and easily. In addition, when the two pipes are separated by intermittent flow paths of the two pipes, the fluid inside the pipe is prevented from leaking out.

Currently, quick couplers having various structures are used, and the conventional problems will be described through the 'quick coupler device' disclosed in Korean Patent Laid-Open No. 2004-0084215.

1 illustrates a cross-sectional view of a conventional quick coupler.

The quick coupler is composed of a female coupler (F) and a male coupler (M), the assembly is made in such a way that the male coupler (M) is inserted into the female coupler (F).

The female coupler F includes a female valve cylinder 10 having a flow path for fluid flow, a valve unit 20 installed inside the female valve cylinder 10 to control the flow path, and the female valve cylinder. The coupling cylinder 30 and the female valve cylinder 10 installed to enable the sliding movement from the outside of the 10 and pressurized by the coupling cylinder 30 to the female coupler (F) and the male coupler (M). It consists of several steel balls 31 which bind together.

The male coupler (M) has a flow path for the flow of fluid and the water valve cylinder 40 is coupled to one end is inserted into the female valve cylinder 10, the inside of the water valve cylinder 40 It is comprised by the valve unit 50 which is provided and interrupts a flow path.

On the other hand, the valve unit 20 of the female coupler F and the valve unit 20 of the male coupler M have the same configuration, and are disposed inside the valve cylinder to control the flow path of the valve cylinder 21, 51. And sealing members 22 and 52 provided on the valve shaft 21, support members 23 and 53 fixed inside the valve cylinder so as to support the valve shafts 21 and 51, and the valve shaft ( It is comprised between the springs 24 and 54 provided between the 21 and 51 and the support members 23 and 53 to elastically support the valve shafts 21 and 51.

When the quick coupler is coupled to the female coupler and the male coupler, the ends of the two valve shafts are in contact with each other and the two valve shafts are moved in opposite directions to open the flow path for the flow of the fluid. When separated, the valve shaft is restored to its original position by a spring to block the flow path to prevent the outflow of the fluid.

This conventional quick coupler has the following problems.

The sealing member is installed to surround the valve shaft to maintain the airtight between the valve cylinder and the valve shaft, wherein the sealing member is installed in a structure protruding out of the valve shaft for airtight between the valve shaft and the valve cylinder have. The sealing member installed in such a structure comes into contact with the inner surface of the valve cylinder before the valve shaft when the valve shaft moves to close the flow path of the valve cylinder. The friction is generated in the seal member to promote the wear of the sealing member, moreover, the torsional force acts on the sealing member as the valve shaft moves while the sealing member is in close contact with the valve cylinder, and the sealing member is easily damaged and loses its function. I have a problem.

In addition, as the period of using the quick coupler elapses, foreign matter contained in the fluid adheres to the valve cylinder and the valve unit. As a result, the fluid may not be contaminated or the valve shaft may not move smoothly. Since this causes a problem of leaking to the outside, in the case of a quick coupler that has been used and contaminated for a period of time, there was a problem that the entire quick coupler has to be replaced even though there is no problem with the internal parts.

The present invention has been made in consideration of the above problems, and an object of the present invention is easy to visually check the internal contamination state of the quick coupler, easy disassembly and assembly of parts to enable quick reuse after washing of the parts In providing a coupler.

Another object of the present invention is to provide a quick coupler that is capable of replacing only a defective component without replacing the entire quick coupler when a defective or damaged part occurs.

Yet another object of the present invention is to provide a quick coupler that can reduce maintenance and repair costs.

The quick coupler of the present invention to achieve the object as described above and to solve the conventional drawbacks is installed in the first valve cylinder and the inside of the first valve cylinder has a flow path for fluid flow therein; And a first valve unit for controlling the fluid flowing through the first valve cylinder, the first valve unit being screwed to be disassembled to the first valve cylinder and having a first through hole for movement of the fluid supplied through the flow path. A first coupler composed of limit bolts; A second valve cylinder coupled to the first valve cylinder and having another flow path continuously communicating with the flow path of the first valve cylinder and having a fluid installed therein, and installed in the second valve cylinder to provide a second valve; A second coupler comprising a second valve unit for intermitting a fluid flowing through the cylinder, and a second limit bolt screwed to the second valve cylinder so as to be disassembled and having a second through hole for movement of the fluid; And a binding means for binding the first coupler and the second coupler.
At this time, the first valve unit, the stem portion for regulating the flow path formed inside the first valve cylinder is formed at one end and the other end is protruded to the outside of the first valve cylinder through the first through hole of the first limit bolt 2 the third valve shaft in contact with the valve unit, a third flat washer provided on the third valve shaft so as to be located between the stem portion and the first limit bolt, and between the stopper and the third flat washer of the first valve cylinder. It is composed of a third spring is installed in the third spring to elastically support the third valve shaft, the second valve unit, the stem portion for regulating the flow path formed inside the second valve cylinder is formed at one end and the other end is the second limit bolt A fourth valve shaft protruding outward from the second limit bolt through the second through hole of the second limit bolt to be in contact with the third valve shaft, and a fourth flat washer mounted on the fourth valve shaft to be positioned between the stem portion and the second limit bolt. Wow, And a fourth spring installed between the stopper of the second valve cylinder and the fourth flat washer to elastically support the fourth valve shaft.

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At this time, the third sealing member is installed on the side of the stem portion of the third valve shaft to maintain the airtight state between the third valve shaft and the first valve cylinder is in close contact with the side of the stopper formed in the first valve cylinder; And a fourth sealing member installed on the side of the stem of the fourth valve shaft to be in close contact with the side of the stopper formed on the second valve cylinder to maintain an airtight state between the fourth valve shaft and the second valve cylinder. have.

According to the present invention having the above characteristics, it is possible to visually check the internal contamination state of the first coupler and the second coupler through the through holes formed in the first limit bolt and the second limit bolt, the contamination of the parts is confirmed If parts are required to be cleaned, the rest of the limit bolts can be easily disassembled, allowing the parts to be cleaned and reused.

Furthermore, only damaged parts can be replaced in case of damage to some parts, such as valve shafts, springs or sealing members, thereby reducing the cost of maintenance and repair of quick couplers.

In addition, the sealing member for maintaining the airtight state is installed on the side of the stem portion provided in the valve shaft to prevent the wear of the sealing member due to friction between the valve cylinder inner wall and the sealing member, and to prevent damage of the sealing member by torsion In addition, the life of the sealing member can be extended, and the fluid pressure in the quick coupler is added to the elasticity of the spring to increase the adhesion between the sealing member and the valve shaft, thereby maintaining a more robust sealing state.

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

2 is a cross-sectional view of a quick coupler according to an embodiment of the present invention.

Quick coupler of the present invention is to facilitate the disassembly and assembly of parts for easy replacement or cleaning of parts, the quick coupler according to an embodiment of the present invention is the first coupler 100 and the second coupler 200 and The coupling means 300, wherein the first coupler 100 is composed of a first valve cylinder 110, the first valve unit 120 and the first limit bolt 130, the second coupler 200 The second valve cylinder 210, the second valve unit 220 and the second limit bolt 230 is composed of.

Figure 3 is a cross-sectional view of the first coupler according to the present invention, Figure 4 shows an exploded perspective view of the first coupler according to the present invention.

The first valve cylinder 110 is a member having a cylindrical structure, the flow path (L1) for the flow of the fluid is provided inside, the outer surface is formed with a groove 111 for binding with the second coupler (200). The stopper 112 for supporting the first valve unit 120 at an appropriate position is configured to be formed on the inner surface.

The first valve unit 120 opens the flow path L1 of the first valve cylinder 110 when the first coupler 100 and the second coupler 200 are coupled to enable the flow of fluid. When disassembling the coupler 100 and the second coupler 200 to block the flow of the fluid by blocking the flow path (L1) of the first valve cylinder (110). The first valve member 120 is in close contact with the side of the first limit bolt 130 to maintain the airtight state between the first valve unit 120 and the first limit bolt 130 ( 140) is installed.

In more detail, the first valve unit 120 includes a first valve shaft 121 and a first spring 122, and the first sealing member 140 is connected to the first valve shaft 121. Is installed.

On the other hand, the first valve shaft 121 is a stem for controlling the first through hole 131 of the first limit bolt 130 to be described later in the central portion of the circular-bar extending in the longitudinal direction of the first valve cylinder 110 The part 121-1 is formed to be disposed in the first valve cylinder 110, and one end 121 a of the first valve cylinder is formed through the first through hole 131 of the first limit bolt 130. It is provided in the structure which protruded out of the 110. The first valve shaft 121 is moved by the elasticity of the first spring 122 so that the stem 121-1 blocks the first through hole 131 so that the flow path L1 of the first valve cylinder 110 can be obtained. Or to move in the opposite direction by the second valve unit 220 to open the flow path L1 of the first valve cylinder 110 by opening the first through hole 131. do.

When the first coupler 100 and the second coupler 200 are separated, the first spring 122 moves the first valve shaft 121 so that the first through hole 131 of the first limit bolt 130 is moved. Elastically supporting the first valve shaft 121 so as to shut off the valve, and is installed between the stem portion 121-1 of the first valve shaft 121 and the stopper 112 of the first valve cylinder 110. do.

On the other hand, in installing the first sealing member 140 on the first valve shaft 121, the first sealing member 140 on the side of the stem portion 121-1 in close contact with the side of the first limit bolt 130. By installing the, the first sealing member 140 is worn by friction with the inner surface of the first valve cylinder 110 or damaged between the first valve cylinder 110 and the first valve shaft 121 is damaged. It is possible to prevent, and since the fluid pressure in the first coupler 100 is added to the elastic force of the first spring 122 to pressurize the first sealing member 140, there is an advantage that it can be more surely maintained airtight state.

The first limit bolt 130 is screwed to the end of the first valve cylinder 110 to prevent the first valve shaft 121 is separated from the outside by the elasticity of the first spring 122, 1 The first through-hole 131 for the movement of the fluid supplied through the flow path (L1) of the valve cylinder 110 is formed. Meanwhile, although the first through hole 131 is formed in the same shape as the three leaf clover in the drawing, the shape of the first through hole 131 may be formed in various shapes without being limited thereto.

The first limit bolt 130 is fastened to the first valve cylinder 110 to prevent the separation of the first valve shaft 121, and when the cleaning or replacement of parts is required, the first valve cylinder 110 Since it can be easily disassembled from, the inner surface of the first valve shaft 121, the first spring 122, the first sealing member 140, the first valve cylinder 110 can be easily carved or replaced only the corresponding parts. do.

On the other hand, between the first limit bolt 130 and the first valve cylinder 110 in order to prevent the fluid leakage into the coupling portion, that is, the screw portion of the first limit bolt 130 and the first valve cylinder 110 Another sealing member 150 is installed.

Figure 5 is a cross-sectional view of the second coupler according to the present invention, Figure 6 shows an exploded perspective view of the second coupler according to the present invention.

As described above, the second coupler 200 includes a second valve cylinder 210, a second valve unit 220, and a second limit bolt 230.

The second valve cylinder 210 is formed in a cylindrical structure so that the first coupler 100 can be inserted through one end portion 210a, and is continuously connected to the flow path L1 of the first valve cylinder 110 therein. Another flow path L2 for transporting the fluid is formed. In addition, a stopper 212 is formed on an inner surface of the second valve cylinder 210 to support the second valve unit 220 at an appropriate position. The stopper 212 is inserted into the groove 111 of the first valve cylinder 110 to be inserted into the first valve cylinder 210. A plurality of balls 213 for coupling the coupler 100 and the second coupler 200 are provided, and when the first and second couplers 100 and 200 are fastened, a sealing member 214 for airtightness between the two couplers is provided on the inner surface. It is provided.

The second valve unit 220 opens the flow path L2 of the second valve cylinder 210 when the first and second couplers 100 and 200 are coupled, and the second valve when the first and second couplers 100 and 200 are disassembled. It blocks the flow path L2 of the cylinder 210. The second sealing member 240 is in close contact with the side of the second limit bolt 230 to the second valve unit 220 to maintain the airtight state between the second valve unit 220 and the second limit bolt 230. ) Is installed.

In more detail, the second valve unit 220 includes a second valve shaft 221 and a second spring 222, and the second sealing member 240 is connected to the second valve shaft 221. Is installed.

On the other hand, the second valve shaft 221 is a stem for interrupting the second through hole 231 of the second limit bolt 230 to be described later in the central portion of the circular-bar extending in the longitudinal direction of the second valve cylinder 210 The part 221-1 is formed and disposed inside the second valve cylinder 210, and one end 221 a is connected to the second limit bolt through the second through hole 231 of the second limit bolt 230. 230 is provided in a structure protruding outward. The second valve shaft 221 is moved by the elasticity of the second spring 222 so that the stem portion 221-1 blocks the second through hole 231 so that the flow path L2 of the second valve cylinder 210. Or the stem portion 221-1 moves in the opposite direction by the first valve unit 120 to open the flow path L2 of the second valve cylinder 210 by opening the second through hole 231. do.

When the first coupler 100 and the second coupler 200 are separated, the second spring 222 moves the second valve shaft 221 to allow the second through hole 231 of the second limit bolt 230 to be moved. Elastically supporting the second valve shaft 221 so as to shut off the valve, and installed between the stem portion 221-1 of the second valve shaft 221 and the stopper 212 of the second valve cylinder 210. do.

On the other hand, in installing the second sealing member 240 on the second valve shaft 221, the second sealing member 240 on the side of the stem portion (221-1) in close contact with the side of the second limit bolt 230 By installing the same, as in the first sealing member 140 described above, the damage of the second sealing member 240 can be prevented, and the airtightness can be improved.

The second limit bolt 230 is screwed to the end of the second valve cylinder 210 to prevent the second valve shaft 221 is separated from the outside by the elasticity of the second spring 222, The second through hole 231 for the movement of the fluid supplied through the flow path L2 of the two-valve cylinder 210 is formed. In this case, although the second through hole 231 is formed in the same shape as the three-leaf clover in the drawing, the shape of the second through hole 231 is not limited thereto and may be formed in various shapes.

The second limit bolt 230 is fastened to the second valve cylinder 210 to prevent the separation of the second valve shaft 221, and when the cleaning or replacement of parts is required, the second valve cylinder 210 Since it can be easily disassembled from, the remaining parts can be easily cleaned or replaced.

On the other hand, between the second limit bolt 230 and the first valve cylinder 210 in order to prevent the fluid leakage to the coupling portion, that is, the screw portion of the second limit bolt 230 and the second valve cylinder 210 Another sealing member 250 is installed.

The binding means 300 shown in FIG. 2 is a binding of the first coupler 100 and the second coupler 200, and moves along the second valve cylinder 210 from the outside of the second valve cylinder 210. It may be composed of a fastening cylinder 310, which is possibly installed, and a spring 320 installed between the fastening cylinder 310 and the second valve cylinder 210.

The binding means 300 is moved so that the fastening cylinder 310 presses the ball 213 installed in the second valve cylinder 210 in a state in which the first coupler 100 and the second coupler 200 are coupled. As a result, the first coupler 100 and the second coupler 200 are bound, and when the separation of the first coupler 100 and the second coupler 200 is required, the ball 213 is fastened to release the pressure. The cylinder 310 is moved.

Meanwhile, the binding means 300 of the present invention is not limited to such a structure and may be configured in various structures.

In the quick coupler of the present invention configured as described above, the first valve shaft 121 and the second valve shaft 221 are pushed in contact with each other when the first and second couplers 100 and 200 are coupled, as in the conventional quick coupler. The flow paths L1 and L2 for movement are opened, and on the contrary, when the first and second couplers 100 and 200 are separated, the first valve shaft 121 and the second valve shaft 221 are connected to the first spring 122. The flow paths L1 and L2 are blocked while being restored to the original position by the second spring 222. Since the operation of the quick coupler is the same as the conventional quick coupler, a detailed description thereof will be omitted.

On the other hand, the quick coupler of the present invention can easily visually check the contamination state inside the first coupler 100 and the second coupler 200, and the contamination check process will be described with reference to the first coupler 100 as an example.

When the first coupler 100 and the second coupler 200 are separated from each other by pressing the end 121a of the first valve shaft 121 protruding outward of the first coupler 100 by hand, the first valve A space is formed between the stem portion 121-1 of the shaft 121 and the first limit bolt 130, and the manager visually views the first valve cylinder 110 through the formed space and the first through hole 131. It is possible to check the internal contamination status of.

In addition, when the parts are to be cleaned, the limit bolt can be easily disassembled by rotating the first limit bolt 130 or the second limit bolt 230. Thus, when the limit bolt is disassembled, the remaining parts can be easily disassembled. do. Meanwhile, a dedicated tool manufactured to be inserted into the through hole of the limit bolt may be used for the rotation of the limit bolt.

In the case of the quick coupler configured as described above, since the flow path is interrupted between the stem portion of the valve shaft and the limit bolt, there is a difficulty in securing a flow path having a sufficient area in accordance with the restriction on the size expansion of the through hole formed in the limit bolt.

As described above, a quick coupler having a structure in which parts can be easily cleaned or replaced, and a structure in which an area of a flow path is easily secured, will be described.

7 is a cross-sectional view of a quick coupler according to another embodiment of the present invention.

The quick coupler according to the present exemplary embodiment includes a first coupler 100, a second coupler 200, and a binding means 300, and the first coupler 100 includes a first valve cylinder 110 and a first valve unit. It is composed of the 120 and the first limit bolt 130, the second coupler 200 is composed of a second valve cylinder 210, the second valve unit 220 and the second limit bolt 230 Same as the quick coupler described with reference to FIG. 2.

However, the quick coupler according to the present exemplary embodiment has the following differences in the first valve unit 120 and the second valve unit 220, and thus, the first coupler 131 of the first limit bolt 130 may be formed. The second through hole 231 of the second limit bolt 230 has a difference in that the larger area can be formed.

Therefore, a detailed description of the first valve cylinder 110 and the first limit bolt 130 and the second valve cylinder 210 and the second limit bolt 230 can be made in the same structure as in the above-described embodiment Omit it.

8 illustrates a cross-sectional view of a first coupler according to another embodiment of the present invention.

The first valve unit 120 includes a third valve shaft 321, a third flat washer 322, and a third spring 323.

The third valve shaft 321 has a stem portion 321-1 intermittently configured to intercept a flow path L1 formed in the first valve cylinder 110 at one end thereof, and the other end portion 321a has a first limit. It is installed in a structure protruding to the outside of the first valve cylinder 110 through the first through hole 131 of the bolt 130. At this time, the stem portion 321-1 is in close contact with the side surface of the stopper 112 provided in the first valve cylinder 110 to interrupt the flow path L1 of the first valve cylinder 110.

The third flat washer 322 is fixedly installed on the third valve shaft 321 to move together with the third valve shaft 321 to support the third spring 323. In this case, in order to fix the third flat washer 322 to the third valve shaft 321, a known fixing stop ring 322-1 may be used.

The third spring 323 is installed between the stopper 112 and the third flat washer 322 of the first valve cylinder 110 to elastically support the third valve shaft 321.

According to the first valve unit 120 having such a configuration, the flow path L1 is interrupted between the first valve cylinder 110 and the stem portion 321-1 of the third valve shaft 321. Since the first through hole 131 of the limit bolt 130 can be expanded to a sufficient area without limitation, it is possible to configure the first coupler 100 in which the fluid flow is more smooth.

Meanwhile, the third sealing member 330 for maintaining the airtight state between the third valve shaft 321 and the first valve cylinder 110 faces the side surface of the stopper 112 formed in the first valve cylinder 110. It is preferable to be provided in the side of the stem part 321-1 of the 3rd valve shaft 321.

9 illustrates a cross-sectional view of a second coupler according to another embodiment of the present invention.

The second valve unit 220 includes a fourth valve shaft 421, a fourth flat washer 422, and a fourth spring 423.

The fourth valve shaft 421 is formed with a stem portion 421-1 at one end of the stem portion 421-1 for controlling the flow path L2 formed in the second valve cylinder 210, and the other end 421a is at the second limit. It is installed in a structure protruding to the outside of the second limit bolt 230 through the second through hole 231 of the bolt 230. At this time, the stem portion 421-1 is in close contact with the side surface of the stopper 212 provided in the second valve cylinder 210 to intermittently control the flow path L2 of the second valve cylinder 210.

The fourth flat washer 422 is fixedly installed on the fourth valve shaft 421 to move together with the fourth valve shaft 421 to support the fourth spring 423. In this case, a known fixing stop ring 422-1 may be used to fix the fourth flat washer 422 to the fourth valve shaft 421.

The fourth spring 423 is installed between the stopper 212 and the fourth flat washer 422 of the second valve cylinder 210 to elastically support the fourth valve shaft 421.

According to the second valve unit 220 having such a configuration, since the flow path L2 is interrupted between the second valve cylinder 210 and the stem portion 421-1 of the fourth valve shaft 421, The second through hole 231 of the second limit bolt 230 can be expanded to a sufficient area without limitation, thereby making it possible to configure the second coupler 200 with more smooth flow of the fluid.

Meanwhile, the fourth sealing member 430 for maintaining the airtight state between the fourth valve shaft 421 and the second valve cylinder 210 faces the side of the stopper 112 formed in the second valve cylinder 210. It is preferable to be provided in the side of the stem part 421-1 of the 4th valve shaft 421.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a cross-sectional view of a conventional quick coupler,

2 is a cross-sectional view of a quick coupler according to an embodiment of the present invention;

3 is a cross-sectional view of a first coupler according to the present invention;

4 is an exploded perspective view of a first coupler according to the present invention;

5 is a cross-sectional view of a second coupler according to the present invention;

6 is an exploded perspective view of a second coupler according to the present invention;

7 is a cross-sectional view of a quick coupler according to another embodiment of the present invention;

8 is a cross-sectional view of a first coupler according to another embodiment of the present invention;

9 is a cross-sectional view of a second coupler according to another embodiment of the present invention.

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

100: first coupler 110: first valve cylinder

120: first valve unit 121: first valve shaft

(121-1): stem portion 122: first spring

130: first limit bolt (131): first through hole

140: first sealing member 150: sealing member

200: second coupler 210: second valve cylinder

220: second valve unit 221: second valve shaft

(221-1): stem portion 222: second spring

230: second limit bolt 231: second hole

240: second sealing member 250: sealing member

300: binding means 321: third valve shaft

(321-1): stem portion 322: third flat washer

323: third spring 330: third sealing member

(421): fourth valve shaft (421-1): stem portion

(422): fourth flat washer 423: fourth spring

430: fourth sealing member

Claims (5)

delete delete delete A flow path (L1) for the flow of fluid is installed inside the first valve cylinder 110, and the first valve cylinder 110 is intermittent to the fluid flowing through the first valve cylinder (110) The first limit is screwed to the first valve unit 120, the first valve cylinder 110 so as to be disassembled, the first limit formed with a first through-hole 131 for the movement of the fluid supplied through the flow path (L1) A first coupler 100 composed of bolts 130; The second valve cylinder 210 coupled to the first valve cylinder 110 and having another flow path L2 continuously communicating with the flow path L1 of the first valve cylinder 110 to continuously transfer the fluid. And a second valve unit 220 installed inside the second valve cylinder 210 to control the fluid flowing through the second valve cylinder 210 and the second valve cylinder 210. A second coupler (200) consisting of a second limit bolt (230) screwed to be capable of forming a second through hole (231) for movement of the fluid; And Consists of the binding means 300 for binding the first coupler 100 and the second coupler 200, The first valve unit 120 has a stem portion 321-1 intermittently configured to intercept a flow path L1 formed in the first valve cylinder 110 at one end thereof, and the other end portion 321a has a first limit. A third valve shaft 321 protruding out of the first valve cylinder 110 through the first through hole 131 of the bolt 130 to contact the second valve unit 220, and the stem 321-1. ) And a third flat washer 322 installed on the third valve shaft 321 so as to be positioned between the first limit bolt 130 and the stopper 112 and the third flat washer of the first valve cylinder 110. It is comprised between the 322, the 3rd spring 323 which elastically supports the 3rd valve shaft 321, The second valve unit 220 has a stem portion 421-1 intermittently configured to intercept a flow path L2 formed in the second valve cylinder 210 at one end thereof, and the other end portion 421a has a second limit. A fourth valve shaft 421 protruding out of the second limit bolt 230 through the second through hole 231 of the bolt 230 to contact the third valve shaft 321, and the stem 421-1; ) And a fourth flat washer 422 installed on the fourth valve shaft 421 so as to be positioned between the second limit bolt 230 and the stopper 212 and the fourth flat washer of the second valve cylinder 210. Quick coupler, characterized in that composed of a fourth spring (423) provided between the (422) for elastically supporting the fourth valve shaft (421). The method of claim 4, wherein The first valve cylinder 110 is installed at a side of the stem portion 321-1 of the third valve shaft 321 to maintain an airtight state between the third valve shaft 321 and the first valve cylinder 110. A third sealing member 330 in close contact with the side surface of the stopper 112 formed at the side; And The second valve cylinder 210 is installed at a side of the stem portion 421-1 of the fourth valve shaft 421 to maintain an airtight state between the fourth valve shaft 421 and the second valve cylinder 210. Quick coupler characterized in that it further comprises a fourth sealing member (430) in close contact with the side of the stopper (112) formed in the.

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