KR100491661B1 - Coupler for isolating fluid - Google Patents

Abstract

The present invention relates to a fluid shut-off coupler, and in particular, when the inner passage is opened so that the fluid flows from one side pipe to the other side when coupled to each other, and when separated from each other to prevent the flow of fluid to be discharged to the outside The first coupler 100 connected to one side pipe and the second coupler 200 connected to the other side pipe, characterized in that the present invention is connected to each coupler connected to each pipe, the fluid flows while As a result, the separation of each coupler has the outstanding effect of shutting down the fluid flowing through each pipework, enabling safe troubleshooting without affecting the system.

Description

Fluid Shut Off Coupler {COUPLER FOR ISOLATING FLUID}

The present invention relates to a fluid shutoff coupler in a cooling water supply device in a mobile communication system. More particularly, when a coupler connected to each pipe is connected to supply a fluid, a fluid flows, while each fluid shutoff occurs. By separating the coupler of the present invention relates to a fluid shutoff coupler that can not only block the fluid flowing through each pipe, but also can be easily coupled in one touch.

In general, a coupler is a connection between two parts to connect two pipes to deliver a fluid (cooling water), or to connect a cable to transmit a signal.

Conventional couplers connect two tubing through each coupler to deliver fluid through the two tubing.

However, the conventional coupler has a problem in that the fluid flowing through each coupler cannot be blocked even when the coupler is disconnected because there is no means for blocking the fluid supplied to the system in order to troubleshoot the cooling water supply device in the mobile communication system.

Therefore, the present invention has been made to solve the conventional problems as described above, the object of the present invention is to connect the respective couplers connected to each pipe, the fluid flows, while separating each coupler to separate each pipe It is to provide a fluid blocking coupler that can not only block the fluid flowing through, but also can be easily combined with one touch.

In order to achieve the above object, the fluid shutoff coupler of the present invention is opened to allow the fluid to flow from one side pipe to the other side when the fluid blocking coupler is coupled to each other. And a first coupler connected to one pipe and a second coupler connected to the other pipe.

Hereinafter, a fluid shutoff coupler according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a functional block diagram of a fluid shutoff coupler according to an embodiment of the present invention, the fluid shutoff coupler according to an embodiment of the present invention is composed of a first coupler 100 and a second coupler 200.

When the first coupler 100 is coupled with the second coupler 200, an internal flow path e-1 is opened to allow fluid to flow from one pipe 1 to the other pipe 2, and the When separated from the second coupler 200, it blocks the flow path c-1 to prevent the fluid from being discharged to the outside and blocks the flow of the fluid. As shown in FIGS. 1 and 2, the first coupler ( 100 is composed of a pipe connection 110, coupler connection 120, coil spring 130, fluid flow intermittent 140 and coupler coupling 150.

The pipe connection part 110 of the first coupler 100 has a cylindrical shape and a first fixing jaw 113 is formed at the end of the passage (a-1) of the inner circumferential surface, and one side of the pipe coupler 110 is fastened to the one side pipe 1. 2, the first coupling part 111 and the second coupling part 112 are formed.

The first coupling portion 111 on one side of the pipe connecting portion 110 has a cylindrical outer circumferential surface is formed of a screw groove (male screw) serves to engage with the one side pipe (1).

In addition, the second coupling portion 112 on the other side of the pipe connecting portion 110 has a cylindrical inner circumferential surface is formed with a screw groove (female thread) and fastened with a screw groove (male screw) formed at one outer circumferential surface of the coupler connecting portion 120. Play a role.

In addition, the coupler connecting portion 120 of the first coupler 100 has a cylindrical shape with a predetermined interval along the other outer circumferential surface, and the second fixing jaw 123 at the center of the flow paths b-1 and b-2 of the inner circumferential surface. ) Is formed and one side thereof is fastened to the pipe connection 110, and as shown in FIG. 2, the third coupling part 121 and the fourth coupling part 122 are formed.

The third coupling portion 121 on one side of the coupler connection portion 120 has a cylindrical outer circumferential surface formed of a screw groove (male screw), and serves to fasten with one side formed of a screw groove (female screw) on the inner circumferential surface of the pipe connecting portion 110. Do it.

In addition, the fourth coupling part 122 on the other side of the coupler connection part 120 has a cylindrical shape and a coupling groove is formed along the outer circumferential surface to serve to engage with the second coupler coupling part 150.

In addition, one side of the coil spring 130 in the first coupler 100 is fixed to the first fixing jaw 113 formed in the pipe connection 110 to generate elasticity.

In addition, one side of the fluid flow control unit 140 in the first coupler 100 is in contact with the coil spring 130 and is separated from the second coupler 200 by the elasticity of the coil spring 130. 2 is tightly adhered to the fixing jaw 123 to block the fluid, and when coupled with the second coupler 200, the fluid is separated from the second fixing jaw 123 in the coupler connection part 120 by interaction. It serves to flow, and as shown in Figure 2 is composed of a coil spring inserting portion 141, a fixed disk 142, the fluid blocking portion 143 and the fluid pipe 144.

The coil spring inserting portion 141 in the fluid flow control part 140 serves to be inserted into the coil spring 130 in a conical shape.

In addition, the fixed disk 142 in the fluid flow control unit 140 extends to the coil spring insertion unit 141 to serve to fix the coil spring 130.

In addition, the fluid blocking part 143 in the fluid flow control part 140 extends to the fixed disc 142 so that the second fixing jaw when the first coupler 100 and the second coupler 200 are separated from each other. It is hermetically adhered to 123 and serves to block the flow of the fluid.

In addition, the fluid pipe 144 in the fluid flow control unit 140 extends a predetermined length in a cylindrical shape from the fluid blocking unit 143 and at the same time a flow path e-1 is formed therein to form the first coupler 100. And the second coupler 200 are separated from the second fixing jaw 123 and serve to allow fluid to flow through the hole 145 and the flow path e-1.

In addition, the second coupler coupling part 150 in the first coupler 100 is coupled to the coupler connection part 120 and serves to connect with the second coupler 200, as shown in FIG. 2. The jaw 151 and the coupling groove 152 is composed of.

The coupling jaw 151 in the second coupler coupling part 150 is cylindrical and protrudes to a predetermined length on one end inner circumferential surface and serves to engage with the coupling groove 152 formed on one outer circumferential surface of the coupler connection part 120.

In addition, the coupling groove 152 in the second coupler coupling portion 150 is cylindrical and formed symmetrically with each other in a 'b' shape on the other side to serve to engage with the second coupler 200.

In addition, when the second coupler 200 is coupled to the first coupler 100, an inner flow path e-2 is opened to allow fluid to flow from one pipe 1 to the other pipe 2. When the first coupler 100 and the first coupler 100 are separated from each other, the fluid may block the flow path c-2 so that the fluid is not discharged to the outside and block the flow of the fluid, as shown in FIGS. 1 and 3. 210, a coupler connection 220, a coil spring 230, and a fluid flow interrupter 240.

The pipe coupler 210 in the second coupler 200 has a cylindrical shape, and a third fixing jaw 213 is formed at the end of the passage (a-2) of the inner circumferential surface, and one side of the pipe coupler 210 is fastened to the other pipe 2. And, as shown in Figure 4 is composed of a tenth coupling portion 211 and the twentieth coupling portion (212).

The tenth coupling part 211 at one side of the pipe connection part 210 has a cylindrical shape and has an outer circumferential surface formed of a screw groove (male screw) to serve to be coupled to the one side pipe 1.

In addition, the twentieth coupling portion 212 on the other side of the pipe connecting portion 210 has a cylindrical inner circumferential surface is formed with a screw groove (female thread) and fastened with a screw groove (male screw) formed at one outer circumferential surface of the coupler connecting portion 220. Play a role.

In addition, the coupler connecting portion 220 of the second coupler 200 has a cylindrical shape, and a fourth fixing jaw 224 is formed at the center of the flow paths b-3 and c2 of the inner circumferential surface, and one side thereof is connected to the pipe connecting portion 210. As shown in FIG. 4, it is composed of a thirtieth coupling part 221, a coupler coupling part 222, and a coupler extension part 223.

The thirtieth coupling portion 221 on one side of the coupler connection portion 220 has a cylindrical outer circumferential surface formed as a screw groove (male screw) to engage with one side formed as a screw groove (female screw) in the pipe connection portion 210. do.

In addition, the coupler coupling portion 222 in the coupler connection portion 220 is cylindrical, the connecting projection 225 is formed on the outer peripheral surface 'b' shaped coupling groove 152 formed on one outer peripheral surface of the second coupler coupling portion 150 ) And the role to be concluded.

In addition, the coupler extension part 223 in the coupler connection part 220 extends to the coupler coupling part 222 in a cylindrical shape so that the coupler connection part 220 is coupled to the first coupler 100 and the second coupler 200. It is bound to one side inner circumferential surface of the) serves to enable the fluid flow control unit 240 to flow. At this time, the coupler extension part 223 is a cylinder formed with a flow path (c-2) for allowing the fluid pipe 244 in the fluid flow control unit 240 to flow stably and the first coupler 100 And the second coupler 200 are in close contact with the second fixing jaw 123 in the fluid flow control unit 120 of the first coupler 100.

In addition, one side of the coil spring 230 in the second coupler 200 is fixed to the third fixing jaw 213 formed in the pipe connecting portion 210, and the third fixing jaw in the piping connecting portion 210. Fixed to 213 serves to generate elasticity.

In addition, one side of the fluid flow control unit 240 in the second coupler 200 is in contact with the coil spring 230 so that the coupler is elastic by the coil spring 230 when separated from the first coupler 100. The fourth fixing jaw (224) formed in the connecting portion 220 is hermetically close to close the fluid, while the fourth fixing jaw in the coupler connecting portion 220 by interaction when engaging the first coupler 100 ( It is separated from the 224 and serves to allow the fluid to flow, it is composed of a coil spring inserting portion 241, fixed disk 242, fluid blocking portion 243 and the fluid pipe 244 as shown in FIG. It is.

The coil spring insertion part 241 in the fluid flow control part 240 serves to be inserted into the coil spring 230 in a conical shape.

In addition, the fixed disk 242 in the fluid flow control unit 240 extends to the coil spring inserting portion 241 and serves to fix the coil spring 230.

In addition, the fluid blocking part 243 in the fluid flow control part 240 extends to the fixed disc 242 so that the fourth fixing jaw when the first coupler 100 and the second coupler 200 are separated. It is hermetically adhered to 224 and serves to block the flow of the fluid.

In addition, the fluid pipe 244 in the fluid flow control unit 240 extends a predetermined length in a cylindrical shape from the fluid blocking unit 243 and at the same time a flow path e-2 is formed therein to form the first coupler 100. And the second coupler 200 are separated from the fourth fixing jaw 224 to serve to allow fluid to flow through the hole 245.

Next, an operation process of the fluid shutoff coupler having the above configuration will be described with reference to FIGS. 4 to 7.

First, in order to allow fluid to flow from one pipe 1 to the other pipe 2, the first coupler 100 connected to one pipe 1 and the second coupler connected to the other pipe 2 ( Combine the respective configurations of 200).

Thereafter, the first coupler 100 and the second coupler 200 are coupled by any action. At this time, the second coupler coupling portion 150 in the first coupler 100 into a cylindrical shape in the coupling groove 152 and the coupler connecting portion 220 symmetrically formed on the other side 'b' shape on the other side When the coupler coupling part 222 having the connection protrusion 225 formed on the outer circumferential surface is inserted into the coupling groove 152 of the letter 'B', the second coupler 200 is one-touched by rotating the second coupler coupling part 150. It is fastened as shown in FIG.

Then, the coupler extension part 223 in the coupler connection part 220 of the second coupler 200 is inserted into the flow path b-2 in the coupler connection part 120 of the first coupler 100.

Subsequently, as the fluid flow control unit 140 of the first coupler 100 and the fluid flow control unit 240 of the second coupler 200 are connected, the second fixing jaw 123 in the first coupler 100 is connected. And the second fixing coupler 200 is not fixed to the fourth fixing jaw 224 and is positioned at the center of the flow paths c-1 and c-2 through the respective coil springs 130 and 230. Fluid flows along the holes 145 and 245 in the fluid flow interruptions 140 and 240. At this time, when the fluid flow control unit 140 of the first coupler 100 and the fluid flow control unit 240 of the second coupler 200 are connected, their lengths are fixed from the second fixing jaw 123 to the fourth fixing unit. It is larger than the length of the jaw 224, so that the fluid flows through the holes 145 and 245 in the respective fluid pipes 144 and 244 when engaged. At this time, the flow path of the fluid flows in the order of the flow paths a-1, b-1, e-1, e-2, b-3, a-2.

Meanwhile, when the first coupler 100 and the second coupler 200 are separated as shown in FIG. 5, the first coupler 100 has a first fixing jaw 113 in the pipe connection 110. The fluid blocking part 143 in the fluid flow control part 140 of the first coupler 100 is connected to the second fixing jaw 123 in the coupler connecting part 120 by the elasticity of the coil spring 130 fixed to the coil spring 130. It is in close contact with the airtight, and blocks the flow of fluid.

 As shown in FIG. 6, the second coupler 200 is formed by the elasticity of the coil spring 230 fixed to the third fixing jaw 213 in the pipe connecting portion 210. The fluid blocking part 243 in the fluid flow control part 140 of the c) is hermetically adhered to the fourth fixing jaw 224 in the coupler connecting part 220 to block the flow of the fluid.

As described above, according to the fluid shutoff coupler according to the present invention, when each coupler connected to each pipe is connected, fluid flows, while separating each coupler affects the system by blocking the fluid flowing through each pipe. There is an excellent effect that allows you to safely troubleshoot without the need.

In addition, there is another outstanding effect of reducing the production cost and flow resistance by one-touch detachment when coupling between each coupler.

1 is a block diagram showing the configuration of a fluid blocking coupler according to an embodiment of the present invention,

2 is a configuration diagram showing a detailed configuration of the first coupler of the fluid blocking coupler according to FIG.

3 is a configuration diagram showing a detailed configuration of a second coupler of the fluid blocking coupler according to FIG.

Figure 4 is a cross-sectional view showing a cross section when the coupling of the fluid blocking coupler according to an embodiment of the present invention,

5 is a cross-sectional view showing a cross section of the first coupler when each coupler of the fluid blocking coupler according to Figure 4,

Figure 6 is a cross-sectional view showing a cross-section of the second coupler when each coupler of the fluid blocking coupler according to Figure 4,

7 is a coupling diagram of a fluid blocking coupler according to an embodiment of the present invention.

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

100: first coupler 110: pipe connection

111: first coupling portion 112: second coupling portion

120: coupler connection portion 121: third coupling portion

122: fourth coupling portion 130: coil spring

140: fluid flow intermittent portion 141: coil spring insertion portion

142: fixed disk 143: fluid blocking portion

144: fluid pipe 150: coupler coupling portion

151: engaging jaw 152: engaging groove

200: second coupler 210: piping connection

211: 10th coupling part 212: 20th coupling part

220: coupler connection portion 221: 30th coupling portion

222 coupler coupler 223 coupler extension

230: coil spring 240: fluid flow interruption

241: coil spring insertion portion 242: fixed disk

243: fluid block 244: fluid pipe

Claims (10)

A first pipe connection part having a cylindrical shape, one side of which is fastened to the one side pipe and a first fixing jaw formed at an end of the flow path of the inner circumferential surface; A first coupler connecting portion having a cylindrical shape, at one side of which is coupled to the first pipe connecting portion, and along the other outer circumferential surface fastened to the first pipe connecting portion, and having a predetermined interval, and a second fixing jaw formed at the center of the flow path of the inner circumferential surface; A first coil spring having one side fixed to a first fixing jaw formed in the first pipe connection part to generate elasticity; A first coil spring insertion part inserted into the first coil spring in a conical shape, a first fixing disc extending to the first coil spring insertion part to fix the first coil spring, and the first fixing disc. A first fluid shutoff portion which is extended to be in airtight contact with the second fixing jaw to separate the flow of the fluid when the first coupler and the second coupler are separated from each other, and extends in a cylindrical shape from the first fluid shutoff portion; At the same time, a flow path is formed inside the first fluid flow intermittent portion consisting of a first fluid pipe which is separated from the second fixing jaw when the first coupler and the second coupler is coupled to allow the fluid to flow through the hole; And A first coupler comprising a second coupler coupling portion which is a connection means with a second coupler which is fastened to the first coupler connecting portion: A second pipe connection portion having a cylindrical shape, one side of which is fastened to the other pipe and a third fixing jaw formed at an end of the flow path of the inner circumferential surface; A second coupler connection portion having a cylindrical shape, one side of which is fastened to the second pipe connection portion and a fourth fixing jaw formed at the center of the flow path of the inner circumferential surface; A second coil spring having one side fixed to a third fixing jaw formed in the second pipe connecting portion and being fixed to a third fixing jaw in the second pipe connecting portion to generate elasticity; And A second coil spring insertion portion inserted into the second coil spring in a conical shape, a second fixing disk extending to the second coil spring insertion portion to fix the second coil spring, and extending to the second fixing disk And a second fluid blocking part which is in close contact with the fourth fixing jaw to seal the flow of fluid when the first coupler and the second coupler are separated, and extends a predetermined length in a cylindrical shape from the second fluid blocking part. A second coupler configured of a fluid flow intermittent part formed of a second fluid tube having a flow path formed therein to be separated from the fourth fixing jaw when the first coupler and the second coupler are coupled to allow the fluid to flow through the hole Fluid shutoff coupler comprising a. delete The method of claim 1, The first pipe connection portion, the first coupling portion is formed in a cylindrical groove one side outer peripheral surface is fastened to the one side pipe; And The fluid blocking coupler further comprises a second coupling portion formed in a cylindrical shape with the other inner circumferential surface of the coupler coupled to a screw groove formed at one outer circumferential surface of the coupler connection portion. The method of claim 1, The first coupler connecting portion has a cylindrical shape, one outer peripheral surface of which is formed as a screw groove, and a third coupling portion which engages with one side formed as a screw groove on the inner peripheral surface of the pipe connection portion; And The fluid blocking coupler further comprises a fourth coupling portion formed in a cylindrical shape along the other outer circumferential surface thereof and fastened to the second coupler coupling portion. The method of claim 1, The second coupler coupler may include: a coupling jaw that protrudes in a predetermined length on one end inner circumferential surface of a cylindrical shape and engages with a coupling groove formed on one outer circumferential surface of the coupler connection portion; And The fluid blocking coupler further comprises a coupling groove formed in a cylindrical shape and symmetrical with each other in a 'b' shape and fastened to the second coupler. delete delete The method of claim 1, The second pipe connection part may include a tenth coupling part having a cylindrical shape and having one outer circumferential surface formed as a screw groove to be coupled to the one pipe; And The fluid blocking coupler further comprises a twentieth engaging portion formed in a cylindrical shape with the other inner circumferential surface formed with a screw groove and fastened with the screw groove formed at one outer circumferential surface of the coupler connection portion. The method of claim 1, The second coupler connection portion is formed in a cylindrical groove on one side of the outer circumferential surface of the thirtieth coupling portion for fastening with one side formed as a screw groove in the pipe connection portion; A coupler coupling part formed in a cylindrical shape with a connection protrusion formed at one side of the outer circumferential surface thereof and engaged with a coupling groove of a 'b' formed at one outer circumferential surface of the second coupler coupling part; And And a coupler extension that extends into the coupler coupler in a cylindrical shape and is coupled to an inner circumferential surface of one side of the coupler coupler when the first coupler and the second coupler are coupled to allow the fluid and the fluid flow control unit to flow. Blocking coupler. delete