KR100516798B1 - Connecting structure for pipe - Google Patents

Abstract

Disclosed is a connection structure of a pipe that can be connected to each other without a separate process such as welding to the ends of the pipe to be connected to each other as well as adaptable to the expansion, bending, vibration, rotation of the pipe. The connecting structure according to the present invention has a ring shape between the tube and the tube while forming an inlet inside the inner part on the inner side to form a hollow compression space and a plurality of locking balls to expose a portion of the upper and lower sides They are made of a packing member rotatably embedded, and a clamp for clamping the tube and the packing member while wrapping the packing member inward. Here, the locking groove is further formed on the inner side of the packing member to be fitted to the end of the tube while opening to both sides from the inlet of the compression space. On the other hand, the compression space is preferably formed narrower as it extends to the inlet side.

Description

Connecting structure for pipe

The present invention relates to a pipe connection structure, and more particularly, can be connected to each other without a separate process such as welding to the ends of the pipe to be connected to each other, as well as adaptable to the expansion, bending, vibration, rotation of the pipe The connection structure of the pipe.

In general, plumbing fixtures are closely related to our daily lives. In addition to supplying drinking water and industrial water, the used water not only serves to drain out through pipes, but also to warm or cool the room through pipes. Piping is a general facility piping required for the purpose of building according to the purpose of use.It is used for industrial purposes such as construction piping (water supply, hot water supply, heating and cooling, drainage, exhaust, etc.), crude oil transportation piping, factory piping, dust collector piping, and power plant piping. It can be divided into industrial piping.

These pipes are used differently depending on the temperature, pressure, and the nature of the transport object in the pipe material, such as steel pipes, synthetic resin pipes, cast iron pipes, concrete pipes, copper pipes, etc., and the purpose of use is varied, regardless of climate change It is easy to supply energy and other fragrance, there is little loss of quantity during transportation, and the transportation cost is low.

However, compared with the usefulness of the pipe, the jointing method is not improved in the welding method which is mainly performed. Although the welding method has excellent advantages in airtightness, it requires welding tools and high-paying professional welders, and the working environment is poor, the progress of work is affected by the functional workers, and the reduction reaction, atmospheric corrosion, soil corrosion, stress at the welding site. There was a problem such that corrosion occurs quickly, such as corrosion.

In addition, the above-described welding method is mainly a simple coupling of both sides of the pipe, so if the ground subsides or excessive water pressure is generated inside the pipe, both pipes are separated from the joint to be the main cause of leakage.

On the other hand, considering the situation on the Korean Peninsula, which can not be assured against the risk of earthquakes, the adaptation to earthquakes should be added to the pipe design. In addition, it may be desirable to calculate the error according to the amount of expansion and contraction of the metal tube stretched according to the temperature as well as the earthquake. As shown in FIG. 1, for example, a welding method having the most reliability in the conventional pipe connection method, the couplings 1 'and 2' are welded to the ends of the pipes 1 and 2. , 2 ') connects the pipe by fastening a plurality of bolts (3).

However, such a coupling method will be able to expand and contract the tube depending on the surrounding climatic environment or the temperature of the fluid in the tube. Therefore, the design should take into account the new construction of the pipe and apply suitable parts to it. In addition, in case of earthquakes such as earthquakes, several connected pipes are subjected to torsion or flexural load and designed accordingly. This is a problem of enormous resource waste, cost increase and long air.

The present invention has been made to solve the above problems, the object of the present invention is to form a packing member and a packing with a built-in locking ball on both sides while forming a pressure space therebetween without processing the ends of the pipe to be connected to each other By providing a clamp to press the end of the member and the tube, the coupling structure by the packing member can be adapted to the expansion, bending, vibration, and rotation of the tube, and the higher the pressure in the tube, the stronger the binding force and the sealing force. Termination is to provide a pipe connection structure.

The present invention to achieve the above object,

In connecting the pipe with the pipe,

A packing having a ring shape between the tube and the tube and having a hollow space formed therein with an inlet on the inner side thereof, and having a hollow space therein, and a plurality of locking balls rotatably embedded at both sides to expose a portion of the upper and lower portions. It provides a connection structure of a pipe consisting of a member and a clamp that clamps the pipe and the packing member while wrapping the packing member inward.

Here, it is preferable that a locking groove is further formed on the inner side of the packing member to be fitted to the end of the tube while opening to both sides from the inlet of the compression space.

And the compression space is preferably formed narrower as it extends to the inlet side.

On the other hand, on the inner surface of the clamp in contact with the locking ball is formed a hat-shaped inclined surface.

Hereinafter, a connection structure of a pipe according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 2 is a cross-sectional view showing a connection structure of the pipe according to the invention, Figure 3 is a perspective view showing the packing member shown in Figure 2, Figure 4 is a view showing the clamp shown in FIG.

Referring to FIG. 2, the joint 100 according to the present invention includes a packing member 110 disposed at an end of a tube 1 and a tube 2 to be connected to each other, and a tube while receiving the packing member 110 therein. It consists of a clamp 130 is fastened to the ends of 1, 2).

It is a feature of the present invention that the pipes 1 and 2 to be connected to each other can be used as it is without any processing.

The packing member 110 has a ring shape of a resilient rubber material, as shown in Figure 3, both ends are formed integrally with the packing extending portion 112 extending further in the outward direction of the cross-sectional shape It is formed to achieve. Inside the packing member 110, a predetermined compression space portion 114 is formed along the ring shape. The compression space 114 has a shape that is open toward the center on the inner surface of the packing member 110, the narrower it is formed to extend inward. In other words, it is formed while drawing a triangular shape or a fan shape when viewed in the shape of a cross section. And on the inner surface of the packing member 110, the locking groove 116 is formed integrally formed on both sides of the packing member 110 starting from the exit of the compression space 114. Meanwhile, the locking ball 120 is built in the packing extension part 112. At this time, the locking ball 120 is embedded so that a plurality of the upper and lower surfaces of the locking ball 120 is exposed to the outside while a plurality of built-in at equal intervals along the outer peripheral surface of the packing extension 112. And each locking ball 120 is rotated inside the packing extension (112).

As shown in FIG. 2 or 4, the clamp 130 has bolts on one side and the other side of which the semicircular shapes face and contact each other to be fastened to the ring-shaped packing member 110 and the ring-shaped tubes 1 and 2. 132 has a structure to fasten by coupling. Since the inner surface of the clamp 130 is in close contact with the outer surface of the packing member 110 having a lampshade on the outer surface of the pipe (1, 2) to form a step shape corresponding thereto. And the inclined surface 134 having a hat shape is formed on the inner surface of the clamp 130 in contact with the locking ball 120.

Hereinafter, the use state of the connection structure 100 of the pipe formed as described above will be briefly described.

5 is a view showing the operating state of the present invention when the tube is stretched, Figure 6 is a view showing the operating state of the present invention when the tube is subjected to the bending load.

First, the connection structure of the pipe according to the present invention, as shown in Figure 5, the packing member 110 is disposed between the pipe (1) and the pipe (2) of the non-integral processing at the end, both pipes ( Insert the end of 1, 2 into the locking groove 116 of the packing member 110. Then, in accordance with the bending of the packing member 110 and the pipes 1 and 2, the semicircular clamps 130 overlap each other and fasten with bolts 132 to engage the ends of the pipes 1 and 2.

After the coupling of the pipes 1 and 2 is completed as described above, when gas or fluid is passed through the pipes 1 and 2, pressure is generated in the pipes 1 and 2. When pressure is generated, the pressure is uniformly transmitted to the compression space 114, and the gap between the catching grooves 116 is widened. In this way, the pressure and the uniform pressure are transmitted to the compression space 114 so that the arrow F1. ), Compression force is generated in the tube toward the engaging groove 116 and within the compression space 114 toward the engaging groove 116 so that the watertight force between the engaging groove 116 and the ends of the tubes 1 and 2 is increased. Increase it. In other words, the stronger the pressure in the tube, the higher the adhesion between the locking groove 116 and the pipes 1, 2, and the better the water density.

In addition, as the pressure in the pipes 1 and 2 is generated, both pipes 1 and 2 open around the joint 100, or due to the contraction of the pipes, the both pipes 1 and 2 open the joint 100. Opening to the center is the locking ball 120 is rotated in the Fb direction at the same time as the pipe (1, 2) in the Fa direction, the locking ball 120 is moved in the Fc direction. Here, the locking balls 120 are inserted into the inclined surface 134 formed in the shape of the hatshade on the inner surface of the clamp 130 and then moved into the narrow space to penetrate the pipes 1 and 2 and the locking ball 120 and the clamp. (130) serves to make the tightening force more powerful.

On the contrary, when the pipe expands due to the temperature rise and both pipes 1 and 2 are lifted about the joint 100, the pipes 1 and 2 are dug in the opposite inclined surface 134 while acting in the opposite direction to the above action. ) And fastening force of the locking ball 120 and the clamp 130.

On the other hand, when a bending load is generated in the pipes 1 and 2 due to a seismic action such as an earthquake or the shaking of the building, the pipes 1 and 2 are subjected to the bending load as shown in FIG. Assuming that the tube 2 will bend the other side of the tube 2 about the end of the tube 2. If a tube, such as a welded joint, is destroyed or is not destroyed when the tube is subjected to a bending load, Although there is a risk that the stress may be generated and later destroyed, the present invention provides that the locking groove 116 of the packing member 110 that surrounds the end of the tube at the same time as the tube is bent and rotated flexibly along the end of the tube. Because it is moved, there is no difficulty in the tube being bent.

In addition, vibration caused by the flow of fluid in the pipe and vibration of various mechanical equipment is absorbed by the pipe, which causes severe vibration and noise to the pipe or various connectors of the pipe and the support of the pipe and the building. This threatens us with various evils. Accordingly, the present invention absorbs vibrations caused by fluids of various kinds of equipment or pipes, so that each of the independent vibrations can be solved in a generous tube, a generous tube part, and a tube part tube part.

As described above, according to the present invention, while the compression space is formed therein is formed on the inner surface of the engaging groove is wrapped on the end of the tube is formed on both sides of the pipe to be connected to each other by having a packing member with a built-in locking ball pressing the tube It is possible to reduce the cost and air cost of construction by connecting to direct without any processing, and also has the advantage of adaptability to the expansion, expansion, bending, vibration and rotation of the pipe.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims You will understand.

1 is a view showing a pipe connection structure according to the prior art,

2 is a cross-sectional view showing a connection structure of a pipe according to the present invention;

3 is a perspective view showing the packing member shown in FIG.

4 is a view showing the clamp shown in FIG.

5 is a view showing the operating state of the present invention when the tube is stretched,

6 is a view showing the operating state of the present invention when the tube is subjected to the bending load.

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

1, 2: pipe 100: pipe connection structure

110: packing member 112: packing extension part

114: compression space 116: locking groove

120: locking ball 130: clamp

132: bolt 134: slope

Claims (4)

In connecting the pipe with the pipe, It has a ring shape between the tube and the tube while forming an inlet inside the inner surface on the inner side to form a hollow compression space and both lock balls are rotatably embedded so that a portion of the upper and lower portions are exposed on both sides. And a packing member and a clamp for clamping the tube and the packing member while wrapping the packing member inward. The pipe connecting structure according to claim 1, wherein a locking groove is formed on the inner surface of the packing member so as to be fitted to an end of the pipe while opening to both sides from the inlet of the compression space. The pipe connecting structure according to claim 1, wherein the compression space is formed narrower as it extends toward the inlet side. According to claim 1, The connection structure of the pipe, characterized in that the hatched inclined surface is formed on the inner surface of the clamp in contact with the locking ball.