KR20070093784A - Connecting structure for pipe - Google Patents

Abstract

A connecting structure for pipes is provided to achieve secure watertightness regardless of pressure changes within a pipe by connecting structure using a packing member for active adjustment to pressure changes. A connecting structure for pipes(1,2) is characterized by expanding end portions(110,120) of the pipes, inserting a ring-shaped packing member(230) between the expanded portions, and connecting the outer sides of the expanded portions with a clamp(150). The packing member has a square or a diamond-shaped sectional surface, including an open inlet(234) on the opposite sides, a space(232) communicating with the inlet, and movable sections(236) on the upper and lower parts separated by the inlet and the space.

Description

Connecting structure for pipe}

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

Figure 2 is an exploded perspective view showing a pipe connection structure according to the present invention,

3 is a cross-sectional view showing a coupling structure according to the present invention,

4 is a cross-sectional view showing an operating state of the pipe connection structure according to the present invention, and

5 to 7 is a view showing another embodiment of the packing member and the fixing member of the present invention.

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

1, 2 pipe 100,200,300 pipe connection structure

110, 120: Expansion pipe 130, 230, 330: Packing member

232,332: space 234,334: entrance

236,336 Intercept 140,240 Fixing member

150: clamp

The present invention relates to a pipe connecting structure, and more particularly to a pipe connecting structure having a stronger sealing force as the pressure is higher.

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 pipe, synthetic resin pipe, cast iron pipe, concrete pipe, copper pipe, etc. 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, it is necessary to add adaptability to earthquakes in the design of piping. 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, the bolt coupling method is performed by the coupling which has the most reliability in the conventional pipe connection method, and the couplings 1 'and 2' are welded to the ends of the pipes 1 and 2, respectively. A plurality of bolts 3 are fastened to the couplings 1 'and 2' to connect the pipes.

However, this coupling method is a fastening method using a plurality of bolts when fastening a lot of processes and costs, and also the expansion and contraction of the microscopic tube will occur depending on the ambient climatic environment or the temperature of the fluid in the pipe. 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 expand the end of the tube to be connected to each other, and to face each other, and after inserting a special packing member, the fixing member therebetween, from the outside of the expansion pipe By coupling with the clamp, the coupling structure by the packing member is provided to provide a pipe connection structure that can actively act on the pressure change in the pipe to obtain a strong watertight force.

The present invention to achieve the above object,

In connecting the pipe with the pipe,

An end of the tube is expanded, a ring-shaped packing member is inserted between the expansion pipes, and then the outside of the expansion pipe is fastened with a conventional clamp.

Here, the packing member may be used that has a circular cross-sectional shape.

Alternatively, the packing member may have a rectangular cross section or a rhombus shape, and inlet portions may be formed on both sides of the packing member, and spaces may be formed on both sides of the packing member to communicate with the inlet portions. In the separated phase, the bottom may be used to form a flow of fragments.

At this time, the packing member may be further provided with a fixing member to prevent the packing member from being separated while being inscribed.

And it is preferable that the stepped portion is formed on both inner ends of the fixing member so as to span the expansion pipe.

Alternatively, the packing member may have a rectangular cross section or a rhombic shape, and inlet portions may be formed on both sides of the packing member, and spaces may be formed on both sides of the packing member to communicate with the inlet portions. Separated upper and lower portions are formed to flow, the inner end portion of the packing member may be used to integrally formed with the stepped portion so as to span between the expansion pipe.

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

<Example 1>

Figure 2 is a cross-sectional view showing a pipe connection structure according to a first embodiment of the present invention, and Figure 3 is a cross-sectional view of the coupling of FIG.

Referring to FIG. 2, the pipe connection structure 100 according to the first embodiment of the present invention includes a packing member 130 disposed at an end of a pipe 1 and a pipe 2 to be connected to each other, and a fixing member 140. And the clamp 150.

Here, the ends of the pipes 1 and 2 to be connected to each other have a structure in which the pipes 110 and 120 are expanded, and the inclination of the pipes 110 and 120 is preferably 45 degrees to 90 degrees. More preferably, the slope of the expansion tubes 110 and 120 is most effective when the angle is 85 degrees.

The packing member 130 has a ring shape inserted between the expansion pipes 110 and 120, and is a general rubber ring having a circular cross section.

The fixing member 140 is formed in a ring shape like the packing member 130, and has a shape inscribed to the packing member 130. A semicircular seating portion 142 is formed in the center portion on the outer surface of the fixing member 140 to form a close contact with the packing member 130 to increase the bonding force with the packing member 130. In addition, the stepped portion 142 is formed at both ends of the fixing member 140.

The stepped portion 142 has a stepped shape of one bending, the upper portion is designed to be inserted between the expansion pipe 110 and expansion pipe 120, the lower portion is inserted between the expansion pipe 110 and expansion pipe 120. It is designed to span without being.

On the other hand, the outer side of the expansion pipe 110, 120 is provided with a clamp 150 for coupling the pipe 1 and the pipe (2). The clamp 150 may be fastened by bolts or one-touch with a conventional pipe clamp.

As shown in FIG. 3, the pipe connection structure 100 according to the first embodiment of the present invention is inserted between the packing member 130 and the fixing member 140 between the expansion pipes 110 and 120, and then the clamp ( 150, the expansion pipe (110, 120) is retracted to press the packing member 130, and the pressurized packing member 130 is pressed close contact with the expansion pipe (110, 120) to increase the watertight force.

<Example 2>

Figure 4 is an exploded perspective view showing a pipe connection structure according to a second embodiment of the present invention, and Figure 5 is a coupling cross-sectional view showing a pipe connection structure according to a second embodiment of the present invention.

4 and 5, the pipe connection structure 200 according to the second embodiment of the present invention expands the pipes 110 and 120 to the ends of the pipes 1 and 2 to be connected to each other as in the first embodiment. After inserting the packing member 230 and the fixing member 240 between the expansion pipe (110, 120), it has a configuration that is fastened by the clamp 150.

Here, the packing member 230 has a ring shape inserted between the expansion pipe (110, 120), the cross-sectional shape of the cross section so as to fit the inclination of the expansion pipe (110, 120) will be formed in a square shape from a rhombus. At this time, it is preferable that the inclination of the side surface of the packing member 230 becomes 85 degrees according to the most effective 85 degrees inclination of the expansion pipes 110 and 120.

A predetermined space portion 232 is formed on both sides of the packing member 230, and the space portion 232 communicates with the side surface of the packing member 230. Here, the space portion 232 is formed in a relatively large space, the inlet portion 234 is formed relatively narrow. The sections 236 separated by the inlet 234 and the space 232 are formed upside down and have a structure capable of flowing left and right. In addition, the central portion on the inner surface of the packing member 230 is formed with a projection 238 protruding in a ring shape in the center direction.

The fixing member 240 is formed in a ring shape like the packing member 230, and has a shape inscribed to the packing member 230. A concave seating portion 242 corresponding to the protrusion 238 formed on the inner circumferential surface of the packing member 230 is formed at the center portion on the outer surface of the fixing member 240 to increase the coupling force with the packing member 230. In addition, the stepped portion 244 is formed at both ends of the fixing member 240.

The stepped portion 244 has a stepped shape of one bending, the upper portion is designed to be inserted between the expansion pipe 110 and expansion pipe 120, the lower portion is inserted between the expansion pipe 110 and expansion pipe 120. It is designed to span without being.

Hereinafter, the operation state of the pipe connection structure 200 according to the second embodiment of the present invention formed as described above will be briefly described.

6 is a cross-sectional view showing an operating state of the pipe connection structure according to the second embodiment of the present invention.

The pipe connection structure 200 according to the second embodiment of the present invention is a structure designed to be applicable to both positive (+) pressure and negative (-) pressure. First, the positive pressure is weighted from the inside of the pipe to the outside of the connection portion. Explain.

Referring to FIG. 6, when a positive pressure is generated by filling fluid or gas into the pipe, the pressure is primarily applied to the side of the packing member 230. In the case of a small positive pressure, the packing member 230 is sufficiently prevented, but when a larger pressure is applied, the packing member 230 is lifted up to the outside by the side of the packing member 230.

The pressure that rises on both sides of the packing member 230 penetrates into the inlet 234 to act in the space 232 having a wide cross-sectional area. At this time, the pressure generated in the space 232 is transferred to the same as the pressure in the pipe, the force of F1 is to be extinguished. Therefore, the force acting on the intercept is increased in proportion to the cross-sectional area of the F2 only to be in close contact with the inner side of the expanded surface (110, 120) has a strong watertight force.

On the contrary, when negative pressure is generated, pressure is increased from the outside of the connection portion to the inside of the pipe. At this time, the pressure generated in the space portion is transferred to the same as the pressure in the atmosphere, and the force of F2 is lost. Therefore, the force acting on the intercept 236 increases only in proportion to its cross-sectional area, so that the F1 is in close contact with the inner side of the expanded surfaces 110 and 120 and thus has a strong vacuum force. At this time, the fixing member 240 is to resist so that the force of F1 can be preserved.

<Example 3>

7 is a sectional view showing a pipe connection structure 300 according to a third embodiment of the present invention.

The pipe connection structure 300 according to the third embodiment of the present invention is almost the same as the second embodiment, except that the packing member 230 and the fixing member 240 of the second embodiment are integrated. do.

That is, as shown in FIG. 7, the ends of the pipe 1 and the pipe 2 connected to each other are expanded pipes 110 and 120, a packing member 330 is inserted therebetween, and the outside of the pipes 110 and 120 is clamped normally. It has a structure to fasten to 150.

That is, the packing member 330 in the third embodiment has a shape such that the fixing member 240 in the second embodiment is integrally formed on the lower side of the packing member 230. Therefore, the packing member 330 has a rectangular or rhombic shape in cross section, and a constant space portion 332 is formed on both sides of the packing member 330, and the space portion 332 communicates with the side surface of the packing member 330. Here, the space 332 is formed into a relatively large space, and the inlet 334 is formed relatively narrow. In addition, the segments 336 formed by separating the upper and lower portions by the inlet portion 334 and the space portion 332 have a structure capable of flowing left and right. And the stepped portion 344 is further formed on both inner ends of the packing member 330 integrally.

As described above, the pipe connection structure according to the present invention actively acts on the change of pressure in which the upper and lower sections are formed to block when the pressure is transferred from the high pressure to the low pressure when a pressure difference is generated between the expanded connection parts. It can have a strong sealing force.

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.

Claims (6)

In connecting the pipe 1 and the pipe 2, Ends of the pipes 1 and 2 are expanded through the pipes 110 and 120, and ring-shaped packing members 130, 230 and 330 are inserted between the pipes 110 and 120, and then the outside of the pipes 110 and 120 is normally clamped 150. Pipe connection structure, characterized in that for fastening with). The pipe connecting structure according to claim 1, wherein the packing member (130) has a circular cross section. The method of claim 1, wherein the packing member 230 has a cross-sectional shape of a square or rhombic, the inlet portion 234 is formed on both sides of the packing member 230, the packing member 230 of the Space portions 232 communicating with the inlet portion 234 are formed on both sides of the inside, and upper and lower segments 236 are formed on the upper and lower portions separated by the inlet portion 234 and the space portion 232. Pipe connection structure characterized in that. 4. The pipe connecting structure according to claim 2 or 3, wherein the packing member (130,230) is further provided with a fixing member (140,240) which is inscribed and prevents the packing member (130,230) from being separated. 5. The pipe connecting structure according to claim 4, wherein stepped parts (144, 244) are formed at both inner ends of the fixing members (140, 240) so as to span between the expansion pipes (110, 120). The method of claim 1, wherein the packing member 330 has a rectangular or rhombic cross-section, the inlet 334 is formed on both sides of the packing member 330, the packing member 330 Space portions 332 communicating with the inlet portion 334 are formed on both sides of the inside, and upper and lower segments 336 are formed at upper and lower portions separated by the inlet portion 334 and the space portion 332. And a stepped portion 344 is integrally formed on both inner ends of the packing member 330 so as to span between the expansion pipes 110 and 120.

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