KR102050760B1 - Pipe connector for earthquake-proof - Google Patents

Abstract

The present invention relates to a seismic piping connector, and more particularly, between the seismic piping brace fixed to the wall of the building and the pipe spaced apart from the wall, preventing the direct pressure of the pipe by the brace and the pipe and The present invention relates to a seismic piping connector that stably connects between pipe braces and prevents pipes from being fixed to a wall by the pipe braces in a longitudinal and lateral direction during an earthquake while preventing physical damage to the pipes due to pressure. .

Description

Pipe connector for earthquake-proof

The present invention relates to a seismic pipe connector, and more particularly, between the seismic pipe brace fixed to the wall of the building and the pipe spaced apart from the wall, to prevent the direct pressure of the pipe by the pipe brace while preventing the pipe and The present invention relates to a seismic piping connector that stably connects pipe braces to prevent physical damage to the pipes by pressing, and prevents pipes from being fixed to the wall by the pipe braces and shaking in the longitudinal and transverse directions during an earthquake.

In general, the piping is designed to withstand the design ground movement at the time of design, but the level of design ground movement in the earthquake-resistant design standards of each country is rising due to the recent earthquakes and the resulting disasters.

Therefore, reinforcement of seismic performance is required not only in the structure but also in piping system, and measures to reinforce the seismic performance of the piping system include modifying the piping plan, using a hanger, a supporter, etc. You can count.

But. Overall modifications to the piping plan or the introduction of damping devices in the piping system designed and optimized for the sole purpose of improving seismic performance can result in excessive costs.

Therefore, in this field, the seismic pipe anti-shake props for fixing the pipes and the inner wall of the building structure are fixed to prevent the independent shaking of the pipes by the earthquake wave, so that the pipes are independently shaken or deformed or damaged when an earthquake occurs. Is preventing.

Conventional piping braces, a fixing bracket fixed to the wall of the building, and a metal clamp for pressing and fixing the outer diameter of the pipe spaced from the wall; And a support arm spaced apart between the fixing bracket and the clamp so as to press the outer diameter of the pipe through the metal clamp to fix the pipe in the longitudinal and transverse directions.

However, if the outer diameter surface of the pipe is directly pressed and fixed through the clamp, in particular in the case of the pipe made of synthetic resin, there is a possibility that uniformity or rupture of the pipe may be caused by pressing by the metal clamp.

In particular, the seismic piping braces should be sufficiently pressurized to fix the pipes spaced from the walls of the building in the transverse and longitudinal directions during an earthquake, which may cause cracking or rupture of the pipes. When the expansion and expansion of the pipe by the temperature change is made, the fixed state of the pipe may be poor, and the pipe may be cracked.

Therefore, it is not preferable to fix the pipe made of the synthetic resin by pressing through the clamp of the metal in terms of durability or fixability of the pipe.

KR 10-1422333 B1 KR 20-2016-0001755 Y

An object of the present invention devised to solve the above problems is disposed between the seismic piping brace fixed to the wall of the building and the pipe spaced apart from the wall, while preventing the direct pressure of the pipe by the pipe brace and the pipe and It provides a seismic piping connector that stably connects the pipe braces to prevent physical damage to the pipes by pressing and prevents the pipes from being fixed to the wall by the pipe braces to shake in the longitudinal and transverse directions when an earthquake occurs. .

The above object is achieved by the following configuration provided in the present invention.

Seismic piping connector according to the present invention,
It is attached to the synthetic resin pipes installed in the building, and one end of the synthetic resin pipe is fixed to the wall of the building, and the other end is fixed by annular pressing on the metal clamp formed on the other end of the pipe prop formed with a clamp,
An arc-shaped grip groove which is inscribed on the outer diameter surface of the synthetic resin pipe is formed on the inner diameter surface, respectively, to enclose the outer diameter surface of the synthetic resin pipe, and is divided into a first division coupling and a second injection molded molded synthetic resin material of the same material as the synthetic resin pipe. A pair of split couplings including split couplings;
Between the outer diameter surface of the synthetic resin pipe and the grip groove inner diameter surface of each split coupling wrapped around the outer diameter surface of the synthetic resin pipe, and between the outer diameter surface of the synthetic resin pipe and the grip groove inner diameter surface of each split coupling An adhesive layer for laminating bonding;
It is formed to correspond to both sides of the first divided coupling and the second divided coupling wrapped around the outer diameter surface of the synthetic resin pipe coated with the adhesive material, the laminated joint by the pressing force provided through the through and fastening of the assembly bolt Auxiliary assembly pieces which annularly press the split couplings to the outer diameter surface of the synthetic resin pipe, such that the split couplings are laminated and bonded to the outer diameter surface of the synthetic resin pipe coated with the adhesive material in an annular pressed state; And
At least one of the split couplings is formed to protrude on one side of the split coupling to form a tubular structure, the one end is fixed to the wall of the building and the other end of the annular pressing on the metal clamp formed on the other end of the pipe brace formed with a clamp It is configured to include a connecting end to prevent the rupture of the synthetic resin pipe due to the pressure by the metal clamp by connecting in a state connected to the piping brace and the synthetic resin pipe indirectly,
The first split couplings and the second split couplings formed of the injection molded article made of the synthetic resin to surround the outer diameter surface of the synthetic pipe,
Laminated and bonded to the outer diameter surface of the synthetic resin pipe to which the adhesive is applied by the pressing force provided through the adjusting bolt passing through the auxiliary assembly pieces to locally strengthen the strength of the synthetic resin pipe, and protrudes on one side to form a tubular structure By indirect connection between the metal clamp of the pipe brace and the synthetic resin pipe through the connection end formed,

The synthetic resin pipe reinforced with strength through the split coupling of the synthetic resin material is suppressed from flowing in the longitudinal and transverse directions in the split coupling due to the impact applied in the longitudinal direction and the transverse direction by the earthquake, and the metal material The synthetic resin laminated by pressing in the split coupling through the direct annular pressing of the synthetic resin pipe by the pipe brace clamp, the flexibility of the split coupling itself of the synthetic resin material, and the reinforcement of the strength of the synthetic pipe through the split coupling. Characterized in that configured to prevent the occurrence of rupture of the pipe.

delete

delete

delete

delete

delete

More preferably, the connection end is composed of a split connection end formed symmetrically divided on one side of the first split coupling and the second split coupling,
When the first split coupling and the second split coupling wrap around the outer diameter surface of the pipe, the split connecting ends formed in the first split coupling and the second split coupling are closely supported to each other to protrude to one side. It is configured to form a connecting end of.

In addition, the connecting end is formed in an arc shape to form a hollow tube by closely contacting the edges, and configured to press and fix the outer diameter surface by the clamp of the pipe brace made of the hollow tube.

delete

In addition, one or more auxiliary pieces are formed to correspond to the pair of split couplings that surround the outer diameter surface of the pipe so that the pair of split couplings that surround the outer diameter surface of the pipe divide the flanges by bringing the auxiliary pieces into close contact with each other. After being joined, it is configured to be stably in close contact with the outer diameter surface of the pipe by the assembly bolt fastened through the auxiliary piece.

In addition, the pair of split couplings are formed so that the semi-circular grip grooves are recessed in the inner diameter, so as to surround the upper and lower outer diameter surfaces of the pipe to be divided.

As described above, the present invention proposes a seismic piping connector for easily connecting a pipe to a clamp of a pipe brace without cutting the pipe or directly pressing the pipe.

In particular, the pipe connector is configured to be divided by the split coupling wraps the outer surface of the pipe to be divided and then secured by the pipe and the adhesion, to achieve a stable connection and assembly between the pipe and the pipe connection without direct pressure of the pipe, As a result, the rupture or cracking of the pipe due to the pressure of the pipe can be suppressed.

And, even though the pipe expands and contracts due to temperature change, the split coupling that surrounds the pipe is made of the same synthetic resin as the pipe and adhered to the outer diameter surface of the pipe through fixing so that the pipe ruptures even when the pipe expands and contracts. Or cracking can be prevented.

In addition, the present invention does not cut the pipe, so the pipe is fixed by overlapping the outer coupling surface of the pipe, the construction hassle in connection between the cutting through the 'T' type branch pipe after cutting the pipe It has a specificity that there is no possibility of leaking at the site connected through the 'T' type branch after being cut.

That is, the present invention provides a 'T' type connection structure to the pipe by the split couplings that divide the outer diameter surface of the pipe and the connecting end formed to protrude on one side of each of the split couplings without cutting and joining the pipe. By forming, the pipe can be easily fixed to the clamp of the pipe brace without direct crimp of the pipe.

1 is a perspective view showing the overall configuration of the seismic piping connector proposed as a preferred embodiment in the present invention,
2 to 4 is a view showing a construction state connecting the pipe and the pipe brace using the seismic pipe connector proposed in the preferred embodiment of the present invention,
Figure 5 shows the seismic piping connectors and piping process proposed in the present invention, and the sequential connection state of the seismic piping connectors and pipe brace connected to the pipe.

Hereinafter, with reference to the accompanying drawings will be described in detail the seismic piping connector proposed as a preferred embodiment in the present invention.

1 is a perspective view showing the overall configuration of the seismic piping connector proposed as a preferred embodiment in the present invention, Figures 2 to 4 is a pipe and a pipe using the seismic piping connector proposed as a preferred embodiment in the present invention; Figure 5 shows the construction state connecting the pipe brace, Figure 5 is a process of connecting the seismic piping connector and the pipe proposed in the preferred embodiment of the present invention, and the sequential connection state of the seismic piping connector and the pipe brace connected to the pipe To show.

Seismic piping connector 1 proposed as a preferred embodiment in the present invention, as shown in Figures 2 to 4 assembled and fixed to the pipe (P) made of synthetic resin material spaced apart from the wall (W) of the building By indirectly connecting the pipe (P) and the pipe brace 100 fixed to the wall (W) of the building, without damaging the direct compression of the pipe (P) by the clamp 130 formed on the pipe brace 100 It is a kind of auxiliary fixture for fixing the pipe (P) to the wall (W) of the building through the pipe brace 100 to be standardized.

And, the pipe prop 100 for fixing the pipe (P) to the wall (W) is fixed bracket 110 is fixed to the wall (W) of the building; A clamp 130 composed of a pair of clamp members 131 and 132; And a support arm 120 spaced apart from each other between the clamp 130 and the fixing bracket 110, wherein the support arm 120 connects the fixing bracket 110 and the clamp 130 to a hinge structure, respectively. do.

In the present embodiment, the pipe (P) is fixed to the wall (W) of the building through the pipe brace 100 to prevent the pipe (P) from shaking in the transverse direction and longitudinal direction during the earthquake, the pipe disposed in the building ( P) can be shaken independently to prevent physical damage.

In particular, in the present invention by directly pressing the outer diameter surface of the pipe (P) through the clamp 130 formed in the pipe brace 100 to fix the pipe brace made of synthetic resin material and the pipe brace 100 made of metal material Instead, after fixing the pipe (P) through a pipe connector (1) having a unique connection structure according to this embodiment, the pipe connector (1) fixing the pipe (P) clamp 130 of the pipe brace 100 ), So that the pipe P is stably fixed to the pipe prop 100 without excessive pressure of the pipe P by the pipe prop 100.

On the other hand, the seismic pipe connector is fixed to the pipe indirectly connecting the clamp of the pipe and the pipe brace is an arc-shaped grip groove inscribed in the inner diameter surface to the outer diameter surface of the pipe (P) as shown in Figure 1 to 4 ( 10A-a and 10B-a are formed, respectively, and include two or more split couplings 10A and 10B to partition the outer diameter surface of the pipe P.

In this embodiment, at least one or more of the split couplings 10A and 10B is formed to protrude a connection end 20 which is pressed against the clamp 130 of the pipe brace 100. .

In the present embodiment, the seismic piping connector 1 is divided into a first split coupling 10A for dividing one outer diameter surface of the pipe P and a second split coupling 10B for dividing the other outer diameter surface of the pipe. ).

The first split coupling 10A and the second split coupling 10B each have semi-arc grip grip grooves 10A-a and 10B-a formed on inner surfaces thereof, and these grip grooves 10A-a are respectively formed. The first split coupling 10A and the second split coupling 10B are in close contact with the outer diameter surface of the pipe P and are arranged concentrically on the outer diameter surface of the pipe P via, 10B-a.

In the present embodiment, as shown in Figures 2 and 5, the adhesive 30 is applied between the pipe P made of the synthetic resin and the pair of split couplings 10A and 10B made of the synthetic resin to form these pipes ( P) and the split couplings 10A, 10B are bonded and fixed by the adhesive layer 30 formed by the adhesive.

That is, in the present embodiment, the split couplings 10A and 10B are not forced by pressing the pipes P through the split couplings 10A and 10B, but are made of the same material as the pipes P made of synthetic resin. To the adhesive 30 through the pipe (P) to be fixed in the transverse direction and longitudinal direction.

That is, the seismic pipe connector 1 is fixed to the outer diameter surface of the pipe 10 by adhesion, and as a result, is fixed stably to the outer diameter surface of the pipe 10 without excessively pressing the pipe 10. .

Therefore, the seismic piping connector 1 according to the present embodiment is fixed to the pipe through the adhesion without undue pressure of the pipe made of synthetic resin, so as to press the pipe by clamping the synthetic resin pipe excessively through the clamp of the conventional pipe brace This bursting phenomenon is prevented.

In the present embodiment, one or more auxiliary assembly pieces 10A-b and 10B-b are formed to correspond to the pair of split couplings 10A and 10B, each of which surrounds the outer diameter surface of the pipe P. .

When configured in this way, the pair of split couplings 10A, 10B wrapped around the outer diameter surface of the pipe P are flanged by closely adhering the auxiliary assembly pieces 10A-b and 10B-b to each other. The assembly bolt B fastened through the auxiliary assembly pieces 10A-b and 10B-b is stably in close contact with the outer diameter surface of the pipe P.

Thus, the adhesive 20 formed between the outer diameter surface of the pipe P and the grip grooves 10A-a and 10B-a of the split couplings 10A and 10B surrounding the pipe P is auxiliary assembled during curing as shown in FIG. 5B. It is possible to maintain a stable close contact with the pieces 10A-b and 10B-b, and as a result, stable adhesion between the pipe 10 and the split couplings 10A and 10B circumscribed thereto can be achieved.

Meanwhile, in the present embodiment, at least one of the split couplings 10A and 10B surrounding the pipe P in a concentric structure is connected to the clamp 130 of the pipe brace 100 on at least one side of the split coupling. The end 20 protrudes, and the clamp 130 of the pipe pedestal 100 is bound to the connection end 20 of the split couplings 10A and 10B wrapping the outer diameter of the pipe P to be divided so that the pipe ( Connect to P).

1 and 5A show a preferred embodiment, the split connection ends 21 and 22 are formed on one side of the first split coupling 10A and the second split coupling 10B so as to be vertically symmetrical to form a first When the split coupling 10A and the second split coupling 10B respectively surround the outer diameter surfaces of the pipes P, the split couplings formed in the first split coupling 10A and the second split coupling 10B are divided. The ends 21 and 22 are closely supported to each other so as to form a connection end 20 protruding to one side of the pipe P.

In this case, it is preferable that the split coupling end and the split connection end protruding to one side of the split coupling are integrally formed by injection or cutting.

In addition, the split connection ends 21 and 22 are formed in a half arc shape, when the first split coupling 10A and the second split coupling 10B surround the outer diameter surface of the pipe P to be divided, and are made in a half arc shape. The split connecting ends 21 and 22 are in close contact with each other to form a tubular connecting end 20.

Therefore, when the seismic piping connector 1 according to the present embodiment is arranged concentrically in the pipe P and fixed by adhesion, the clamp 130 of the pipe brace 100 is connected to one side of the pipe P. As a result, the tubular connecting end 20 which is fixed by pressing the outer diameter surface is formed to protrude.

Thus, the operator arranges the first split coupling 10A and the second split coupling 10B in a concentric manner by bonding to one point outer diameter surface of the pipe P that needs fixing as shown in FIGS. 5A and 5B. 5C, the clamp 130 of the pipe brace 100 is connected to the tubular connection end 20 formed on one side of the split couplings 10A and 10B concentrically arranged in the pipe P as shown in FIG. 5C. By pressing and fixing, the pipe P is stably fixed to the wall W of the building through the seismic pipe connecting member 1 without direct pressure of the pipe P.

1. Seismic piping connector
10A. First Coupling Member 10A-a. Grip Home
10A-b. Auxiliary Assembly 10B. Second coupling member
10B-a. Grip Groove 10B-b. Secondary Assembly
20. Connections 21. Split Connections
21a. Departure prevention rim
22. Split Connection 22a. Departure prevention rim
30. Adhesive layer (adhesive)
100. Piping brace 110. Retention bracket
120. Support arm 130. Clamp
131 Clamp Member 132. Clamp Member
W. Wall P. Tubing
B. Assembly Bolt

Claims (4)

It is attached to the synthetic resin pipes installed in the building, and one end of the synthetic resin pipe is fixed to the wall of the building, and the other end is fixed by annular pressing on the metal clamp formed on the other end of the pipe prop formed with a clamp,
An arc-shaped grip groove which is inscribed on the outer diameter surface of the synthetic resin pipe is formed on the inner diameter surface so as to enclose the outer diameter surface of the synthetic resin pipe, and is divided into a first division coupling and a second injection molded injection molded of synthetic resin material of the same material as the synthetic resin pipe. A pair of split couplings including split couplings;
It is applied between the outer diameter surface of the synthetic resin pipe and the inner diameter surface of the grip groove of each split coupling wrapped around the outer diameter surface of the synthetic resin pipe, and between the outer diameter surface of the synthetic resin pipe and the inner diameter surface of the grip groove of each split coupling. An adhesive material for laminating and bonding;
It is formed to correspond to both sides of the first divided coupling and the second divided coupling wrapped around the outer diameter surface of the synthetic resin pipe coated with the adhesive material, the laminated joint by the pressing force provided through the through and fastening of the assembly bolt Auxiliary assembly pieces which annularly press the split couplings to the outer diameter surface of the synthetic resin pipe, so that the split couplings are laminated and bonded to the outer diameter surface of the synthetic resin pipe to which the adhesive is applied; And
At least one of the split couplings is formed to protrude on one side of the split coupling to form a tubular structure, the one end is fixed to the wall of the building and the other end of the annular pressing on the metal clamp formed on the other end of the pipe brace formed with a clamp It is configured to include a connecting end to prevent the rupture of the synthetic resin pipe due to the pressure by the metal clamp by connecting in a state connected to the piping brace and the synthetic resin pipe indirectly,
The first split couplings and the second split couplings formed of the injection molded article made of the synthetic resin to surround the outer diameter surface of the synthetic pipe,
Laminated and bonded to the outer diameter surface of the synthetic resin pipe coated with the adhesive material by the pressing force provided through the control bolt penetrating the auxiliary assembly pieces to locally strengthen the strength of the synthetic resin pipe, and protrudes on one side to form a tubular structure By indirect connection between the metal clamp of the pipe brace and the synthetic resin pipe through the formed connection end,
The synthetic resin pipe reinforced with strength through the split coupling of the synthetic resin material, the phenomenon that the flow in the longitudinal and transverse direction in the split coupling is suppressed by the impact applied in the longitudinal direction and the transverse direction by the earthquake, the metal material The synthetic resin laminated by pressing in the split coupling through the direct annular pressing of the synthetic resin pipe by the pipe brace clamp, the flexibility of the split coupling itself of the synthetic resin material, and the reinforcement of the strength of the synthetic pipe through the split coupling. A seismic piping connector configured to prevent the occurrence of rupture of the pipe. delete The method of claim 1, wherein the connection end is composed of divided connection ends formed symmetrically divided on one side of the first split coupling and the second split coupling,
When the first split coupling and the second split coupling wrap around the outer diameter surface of the pipe, the split connecting ends formed in the first split coupling and the second split coupling are closely supported to each other to protrude to one side. A seismic piping connector characterized in that configured to form a connection end. The inner end of claim 3, wherein the connecting end is formed in an arc shape to form a hollow tube by bringing the edges into close contact with each other, and the outer diameter is pressed and fixed by a clamp of a pipe brace made of the hollow tube. Line piping connections.

Images