KR102500288B1 - Pipe joint drvice - Google Patents

Abstract

The present invention relates to a fluid transfer pipe connecting device, and more particularly, to a fluid transfer pipe connecting device capable of preventing leakage and leakage of a fluid to be transferred by suppressing a nut loosening phenomenon due to vibration.
When the connector body and the union nut are screwed together, the fluid transfer pipe connection device according to the present invention can easily recognize whether or not they are initially fastened with each other by the operator's hand feeling or sound, and has a sawtooth coupling structure, so in a tightly fastened state Even if external vibration is applied, it has the advantage of effectively suppressing the loosening of the union nut part.

Description

Fluid transfer pipe connection device {Pipe joint drive}

The present invention relates to a fluid transfer pipe connecting device, and more particularly, to a fluid transfer pipe connecting device capable of preventing leakage and leakage of a fluid to be transferred by suppressing a nut loosening phenomenon due to vibration.

With the rapid development of semiconductor technology, the use of flat panel display devices that are lightweight and take up less space is rapidly increasing. There are various types of flat panel displays, and among them, a liquid crystal display (LCD), which consumes less power and has a smaller volume and is driven at a low voltage, is widely used.

In order to manufacture such a liquid crystal display, various substrate treatment processes such as deposition, etching, and cleaning are performed, and among these processes, a process using a chemical solution is included. A structure for supplying a chemical solution to a process device in which the chemical solution is used includes a pipe through which the chemical solution flows and a fitting device that is a structure connecting the pipe. The fitting mechanism has excellent heat resistance and high purity, and is used for machine assembly in semiconductor and high-tech industries that use ultra-pure water and high-purity chemical solutions.

The fitting mechanism is composed of a male connector and a nut. The male connector has a hollow for inserting a pipe through which the chemical liquid flows, and a threaded portion is formed on the outer circumferential surface. The pipe inserted into the hollow of the male connector is fixed by screwing the nut and male connector.

The chemical solution supplied through the fixed pipe is connected to another pipe or the like through an opening on the other side of the male connector. However, in the conventional fitting mechanism, the male connector and the nut are coupled only with a male screw and a female screw without a separate locking device.

Therefore, when used in semiconductor equipment, nut loosening may occur due to vibration of the chemical supply motor, and if the nut is loosened, chemical may leak through the gap between the connector and the nut. There is a problem in that the nut must be tightened by checking it from time to time.

Republic of Korea Patent Publication 10-2015-0019500 Korean Registered Patent No. 10-1644596 Korean Registered Patent No. 10-1887676

The present invention is to solve the above conventional problems, and an object of the present invention is to provide a fluid transfer pipe connecting device capable of preventing leakage and leakage of a fluid to be transferred by suppressing a nut loosening phenomenon due to vibration.

A fluid transfer pipe connection device according to the present invention for achieving the above object is a body provided with a main flow path so that fluid can flow therein, and at least two or more flanges provided on the body and provided at the end of the fluid transfer pipe are in close contact and connected. and a connector body including a connection part having a connection passage communicating with the main passage therein, respectively; In the fluid transfer pipe connecting device having a; union nut portion that is screwed into the connection portion of the connector body and pressurizes and couples the flange portion of the fluid transfer pipe to the end portion of the connection portion, wherein the connection portion extends from the body and the connection portion extends from the body. A branch coupling tube having a first screw coupling portion formed on the circumferential surface so as to be screwed with the union nut portion, and an extension tube extending from one side of the branch coupling tube to have an outer diameter larger than the branch coupling tube, The union nut part has a screw fastening pipe part having a second screw fastening part formed on an inner circumferential surface so as to be screwed into the first screw fastening part of the branch coupling pipe, and toward the center of the screw fastening pipe part from one end of the screw fastening pipe part. It extends and has an insertion hole formed therein so that the fluid transport pipe can pass therein, and includes a pressurizing portion pressurizing the flange portion of the fluid transport pipe to be brought into close contact with the connecting portion, and the connector body and the union nut portion are connected to each other by vibration. A locking portion preventing the nut portion from being released from the connector body; is characterized in that it is further provided.

The locking part extends by a certain length from the other end of the screw fastening tube facing the branch coupling tube so as to be positioned outside the expansion tube when the screw fastening tube is screwed into the branch coupling tube, and in a circumferential direction of the screw fastening tube. A plurality of locking wings spaced apart at regular intervals along and formed of a flexible material so that the screw fastening pipe can be bent outwardly by external force, and the locking wing when the screw fastening pipe is screwed into the branch coupling pipe And a locking protrusion protruding from the outer circumferential surface of the extension tube to have a certain thickness in the outer radial direction of the extension tube and extending to have a left and right width corresponding to the distance between the locking wings, A locking groove is formed on the upper surface in the thickness direction of the locking protrusion and is drawn downward at a predetermined depth along the center of the width direction of the locking protrusion, and the locking groove enters the locking groove on the inner circumferential surface of the locking wing so as to be caught in the locking groove. Characterized in that a locking protrusion protruding to a certain thickness is formed along the center of the width direction of the wing.

The locking groove is spaced apart from each other at a predetermined interval and is formed inclined in opposite directions and is formed to be inclined at an angle of 45 ° with respect to the upper surface of the locking protrusion, and extends between the left inclined surface and the right inclined surface It is formed by the bottom surface, and the locking groove is characterized in that it is formed to become narrower as it is drawn into the interior of the locking protrusion.

The locking wing extends to a certain width along the circumferential direction of the screw fastening pipe part and is formed on the longitudinal end side of the locking wing, and a second section extending obliquely toward the end of the screw fastening pipe part from both ends of the longitudinal cross section in the width direction. It is characterized in that it includes a first slope and a second slope.

The fluid transfer pipe connection device according to the present invention is provided with a locking part having a sawtooth coupling structure capable of suppressing and preventing loosening of the union nut due to vibration between the connector body and the union nut portion, thereby preventing leakage of the fluid to be transferred due to vibration and It has the advantage of preventing leaks.

When the connector body and the union nut are screwed together, the fluid transfer pipe connection device according to the present invention can easily recognize whether or not they are initially fastened with each other by the operator's hand feeling or sound, and has a sawtooth coupling structure, so in a tightly fastened state Even if external vibration is applied, it has the advantage of effectively suppressing the loosening of the union nut part.

1 is a perspective view showing a fluid transfer pipe connection device according to the present invention.
Figure 2 is an exploded perspective view showing a fluid transfer pipe connection device according to the present invention.
Figure 3 is a perspective view showing a locking projection of the fluid transfer pipe connecting device according to the present invention.
Figure 4 is a perspective view showing the locking wing of the fluid transfer pipe connecting device according to the present invention.
5 is a view showing a state in which the locking wing of the fluid transfer pipe connecting device according to the present invention is coupled to the locking protrusion.

Hereinafter, a fluid transfer pipe connection device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 5 show a fluid transfer pipe connecting device 1 according to the present invention. 1 to 5, the fluid transfer pipe connection device 1 according to the present invention includes a connector body 10, a union nut portion 20, and a locking portion.

The connector body 10 transfers the fluid supplied from the fluid transport pipe 5 coupled to one side to the fluid transport pipe 5 coupled to the other side, or transfers the fluid supplied from several fluid transport pipes 5 into one fluid transport pipe. (5), or a part that branches the fluid supplied from one fluid transfer pipe 5 to several fluid transfer pipes 5, and includes a body 110 and a plurality of connection parts 120.

The body 110 is provided with a main flow path so that fluid can flow therein. In the present embodiment, the body 110 has a 'T'-shaped structure, but, differently from this, a '一' or '十' shape may be applied. Depending on the shape of the body 110, the shape of the main flow path also extends to a corresponding structure.

At least two or more connection parts 120 are provided on the body 110, the flange part 5b provided at the end of the fluid transfer pipe 5 is in close contact and connected, and the connection passage 123 communicating with the main passage is provided inside. provided In this embodiment, since the body 110 is formed in a 'T' shape, three connection parts 120 are provided.

Here, the fluid transfer pipe 5 is applied with a pipe body 5a having a flow path therein, and a flange portion 5b extending radially from the end of the pipe body 5a and having an outer diameter larger than that of the pipe body 5a. .

The connection part 120 includes a branch coupling pipe 121 and an extension pipe 125, respectively.

The branch coupling pipe 121 extends from each end of the body 110 to have a diameter larger than that of the body 110, and a first screw coupling portion 122 on the circumferential surface so that it can be screwed with the union nut portion 20 to be described later. ) is formed. In addition, connection passages 123 are provided inside the branch coupling pipe 121, respectively, and the plurality of connection passages 123 communicate with the main passage, respectively.

The expansion tubes 125 each extend from the branch coupling tube 121 to have an outer diameter larger than that of the branch coupling tube 121 . Extension tube 125 consists of two parts.

When the union nut part 20 described later is fastened to the connection part 120, the expansion tube 125 includes a first extension part 126 where the locking wing 320 provided in the union nut part 20 is located, It is configured to include a second extension portion 127 extending from the end of the first extension portion 126 so that the outer diameter is expanded.

The union nut part 20 is coupled to the connection part 120 of the connector body 10 and presses the flange part 5b of the fluid transfer pipe 5 in close contact with the end of the connection part 120 to couple it, and the screw fastening pipe part (210) and a pressing part (220).

The screw fastening pipe part 210 is formed with a second screw fastening part 212 on the inner circumferential surface so that it can be screwed to the branch coupling pipe 121 .

The pressurization part 220 extends from one end of the screw fastening pipe part 210 toward the center of the screw fastening pipe part 210, and has an insertion hole 211 formed therein so that the fluid transfer pipe 5 can pass therethrough. , When the screw fastening pipe part 210 is screwed into the connection part 120, the flange part 5b of the fluid transfer pipe 5 is pressed to be in close contact with the connection part 120.

The locking part prevents the union nut part 20 from being loosened from the connector body 10 by vibration in the connector body 10 and the union nut part 20, and includes a locking protrusion 310 and a locking wing 320. It is composed by

The locking wing 320 is from the other end of the screw fastening pipe 210 toward the branch coupling pipe 121 so that it can be located outside the expansion tube when screwing the screw fastening pipe 210 to the branch coupling pipe 121. It extends a certain length and is formed with a plurality spaced at regular intervals along the circumferential direction of the screw fastening pipe part 210 . The locking wing 320 is selectively engaged with the locking protrusion 310 .

The locking wing 320 is formed of a flexible material so that it can be bent outwardly of the screw fastening pipe part 210 when an external force, more specifically, when contacting and interfering with the locking protrusion 310 to be described later.

The locking protrusion 310 is an expansion pipe 125, more specifically, a first extension part so that it can contact and interfere with the locking wings 320 when screwing the screw fastening pipe 210 to the branch coupling pipe 121. (126) and the second extension portion 127 protrudes from the outer circumferential surface of the first extension portion 126 near the boundary in the outer radial direction of the first extension portion 126 to have a certain thickness, and the locking wings 320 It extends to have a left and right width corresponding to the gap between the two sides.

At least one locking protrusion 310 is preferably provided on the circumferential surface of the first extension 126 along the circumferential direction of the first extension 126 . In this case, it is preferable to be spaced apart from each other at equal intervals along the circumferential direction of the first extension part 126.

In addition, the locking protrusion 310 has a locking groove 315 drawn downward at a predetermined depth along the center of the width direction of the locking protrusion 310 on its upper surface in the thickness direction.

And, on the inner circumferential surface of the locking wing 320, a locking protrusion 325 protruding to a certain thickness along the center of the width direction of the locking wing 320 is formed so that it can enter the locking groove 315 and be caught in the locking groove 315. do.

That is, when the screw fastening pipe 210 is rotated to be screwed into the branch coupling pipe 121, the locking wing 320 gradually approaches the locking protrusion 310 side, and the locking wing 320 attaches to the locking protrusion 310. Upon contact and interference, the locking wings 320 open outward. And, when the screw fastening pipe part 210 is further rotated in a state where the locking wing 320 is open, the locking protrusion 325 of the locking wing 320 enters the locking groove 315 side of the locking protrusion 310 .

The locking groove 315 is formed to become narrower as it enters the locking protrusion 310 and is formed by the left inclined surface 312, the right inclined surface, and the bottom surface 311.

The left inclined surface 312 and the right inclined surface 313 are formed to be inclined in directions opposite to each other toward the inside of the locking projection 310 at a point spaced apart from each other at a predetermined interval on the upper surface of the locking projection 310, respectively. It is formed inclined at an angle of 45° with respect to the upper surface. The left inclined surface 312 and the right inclined surface 313 have a structure that is 90° apart from each other.

The bottom surface 311 extends between the left inclined surface 312 and the right inclined surface 313, parallel to the circumferential surface of the first extension, and in a direction parallel to the longitudinal section 321 formed on the end side of the locking wing 320. is formed

The locking groove 315 formed in the locking protrusion 310 has a trapezoidal structure in which the bottom surface 311 is shorter than the distance between the upper end of the left inclined surface 312 and the upper end of the right inclined surface 313, and is connected to the locking groove 315. The locking protrusion 325 of the locking wing 320 that enters also has a corresponding structure. For example, the locking protrusion 325 and the locking groove 315 have a sawtooth coupling structure.

On the other hand, the locking wing 320 has a longitudinal section 321, a first slope 322 and a second slope 323.

The longitudinal section 321 is a portion forming the end side of the locking wing 320, and extends with a certain width along the circumferential direction of the screw fastening pipe part 210. Also, the first slope 322 and the second slope 323 obliquely extend from both ends of the longitudinal section 321 in the width direction toward the end of the screw-in pipe portion 210 .

Since the locking wing 320 has to be bent outward and pass over the locking protrusion 310 when the screw fastening pipe 210 is screwed into the branch coupling pipe 121 and turned, the first slope 322 and the second slope 323 allows the locking wing 320 to be easily bent outward.

The first slope 322 and the second slope 323 have a certain inclination with the end of the screw fastening pipe part 210, and the first slope 322 and the second slope 323 with respect to the end of the screw fastening pipe part 210. ) As the inclination of the locking wing 320 increases, when the first slope 322 or the second slope 323 of the locking wing 320 contacts and interferes with the locking protrusion 310, the locking wing 320 must be turned with greater force. , As the inclination of the first slope 322 and the second slope 323 with respect to the end of the screw fastening pipe 210 is reduced, the first slope 322 or the second slope 323 of the locking wing 320 is locked. When contacting and interfering with the protrusion 310, the locking wing 320 can be turned with less force.

As described above, the fluid transfer pipe connection device according to the present invention has a structure in which the locking wing 320 passes through the locking protrusion 310 when the connector body and the union nut portion are screwed together, so that the operator can determine whether or not they are initially fastened together. It can be easily recognized by hand sensation or sound, and in a tightly fastened state, even when external vibration is applied, the locking protrusion 325 of the locking wing 320 has a sawtooth coupling structure, so that the locking protrusion 310 has a locking groove 315 ), it has the advantage of effectively suppressing the loosening of the union nut part because it enters and maintains a restrained state.

The fluid transfer pipe connection device according to the present invention described above has been described with reference to the accompanying drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments therefrom. you will understand the point.

Therefore, the scope of true technical protection of the present invention should be determined only by the technical spirit of the appended claims.

1 : Connection device
10: connector body
110: body 120: connection
121: branch coupling pipe 125: extension pipe
126: first extension 127: second extension
20: union nut part
210: screw fastening part 220: pressing part
310: locking protrusion
315: locking groove 311: bottom surface
312: left inclined surface 313: right inclined surface
320: locking wing 325: stumbling block

Claims (4)

A body provided with a main flow path so that fluid can flow therein, and at least two or more flanges provided on the body and provided at the end of the fluid transfer pipe are in close contact with and connected to each other, and a connection portion provided with a connection flow path communicating with the main flow path therein And the connector body; In the fluid transfer pipe connecting device having a; union nut portion that is screwed into the connection portion of the connector body and pressurizes and couples the flange portion of the fluid transfer pipe to the end portion of the connection portion,
The connection part extends from the body and has a branch coupling pipe having a first screw coupling part formed on the circumferential surface so as to be screwed with the union nut portion, and one side of the branch coupling pipe to have an outer diameter larger than that of the branch coupling tube. Including an extension tube extending from,
The union nut part has a screw fastening pipe part having a second screw fastening part formed on an inner circumferential surface so as to be screwed into the first screw fastening part of the branch coupling pipe, and toward the center of the screw fastening pipe part from one end of the screw fastening pipe part. It extends and has an insertion hole formed therein so that the fluid transport pipe can pass therein, and includes a pressing portion for pressing the flange portion of the fluid transport pipe in close contact with the connecting portion,
The connector body and the union nut portion are further provided with a locking portion preventing the union nut portion from being loosened from the connector body by vibration,
The locking part
When the screw fastening pipe is screwed into the branch coupling pipe, a certain length extends from the other end of the screw fastening pipe facing the branch coupling pipe so as to be located outside the expansion tube, and is constant along the circumferential direction of the screw fastening pipe. A plurality of locking wings spaced apart from each other and formed of a flexible material so as to be bent in an outward direction of the screw fastening pipe by an external force;
The screw fastening pipe protrudes from the outer circumferential surface of the expansion tube toward the outer radial direction of the expansion tube to have a certain thickness so as to interfere with the locking wings when the screw fastening pipe is screwed into the branch coupling pipe, and the gap between the locking wings Including a locking protrusion extending to have a left and right width corresponding to,
A locking groove is formed on the upper surface of the locking protrusion in the thickness direction, drawn downward at a predetermined depth along the center of the locking protrusion in the width direction,
A locking protrusion protruding with a predetermined thickness along the center of the width direction of the locking wing is formed on the inner circumferential surface of the locking wing to enter the locking groove and be caught in the locking groove,
The locking wing extends to a certain width along the circumferential direction of the screw fastening pipe part and is formed on the longitudinal end side of the locking wing, and when the screw fastening pipe part is fastened to the branch coupling pipe, the locking protrusion is easily bent outward. Including a first slope and a second slope extending obliquely from both ends of the longitudinal section in the width direction toward the end of the screw fastening pipe so as to pass over,
The extension pipe includes a first extension portion in which the locking wings are positioned when the union nut portion is fastened to the connection portion, and a second extension portion extending from an end of the first extension portion so that the outer diameter is expanded,
The locking protrusion has a certain thickness in the outer radial direction of the first extension from the outer circumferential surface of the first extension near the boundary between the first extension and the second extension so as to contact and interfere with the locking wings. The fluid transfer pipe connecting device, characterized in that at least one protruding to the right and left to have a width corresponding to the distance between the locking wings, and provided along the circumferential direction of the first expansion part. delete According to claim 1,
The locking groove is spaced apart from each other at a predetermined interval and is formed inclined in opposite directions and is formed to be inclined at an angle of 45 ° with respect to the upper surface of the locking protrusion, and extends between the left inclined surface and the right inclined surface formed by the bottom surface,
The fluid transfer pipe connecting device, characterized in that the locking groove is formed to become narrower as it enters the inside of the locking protrusion.
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