KR101334654B1 - standing pipe droop preventing structure using pipe clip - Google Patents

Abstract

The present invention relates to a standing pipe deflection prevention structure using a pipe clip, and relates to a standing pipe deflection prevention structure for preventing the deflection of the standing pipe installed through each floor of a building. According to the granular pipe deflection prevention structure using the tightening force reinforcing pipe clip according to the present invention is made by a simple operation of fixing the pipe clip to the granular pipe in a state in which the pipe clip of the deflector of the granular pipe is in close contact with the granular pipe fixing fixture. As a result, the work process is simple, quick, and the parts used are simplified.

Description

Standing pipe droop preventing structure using pipe clip}

The present invention relates to a standing pipe deflection prevention structure using a pipe clip, and relates to a standing pipe deflection prevention structure for preventing the deflection of the standing pipe installed through each floor of a building.

In high-rise buildings such as apartments, sleeves made of steel or plastic are laid on the top of each floor to install ventilation pipes, gas pipes, cold and hot water supply pipes, and wastewater discharge pipes.

And it is installed by inserting the stabilization fixture to fix the pipe between the pipe and the through sleeve. The entire pipe passing through the sleeve is also commonly referred to as a standing tube.

FIG. 6 is a perspective view illustrating a structure of preventing standing tube sag using a conventional pipe girder. FIG. As shown in FIG. 6, the conventional granular pipe deflection prevention structure fixes the pipe girder 100 to the bottom around the granular pipe 2 penetrating the bottom surface 1 of each layer and attaches to the pipe girder 100. Combining the horseshoe-shaped fastening clip (110) to prevent the granular tube (2) sag down.

Specifically, one side of the granular tube 2 is brought into close contact with the pipe girder 100, and then the horseshoe-shaped fastening clip 110 is brought into close contact with the other side of the granular tube 2. Strongly fastened to the mounting portion 102 of the pipe girder 100 using the bolt 112, the granular pipe 2 is fixed between the pipe girder 100 and the horseshoe-shaped fastening clip 110.

However, this conventional method requires the pipe girders to be installed on each floor, and also when the pipe girders are installed on the floor of each floor, the pipe girders should be fixed to the floor after positioning the pipe girders so that the pipe girders closely contact the standing pipes. Therefore, the process of installing the pipe girder is difficult and takes a long time.

In addition, in summer and winter, the expansion and contraction of the granular pipe and pipe girder is so large that the connection between the pipe girder and the horseshoe-shaped fastening clip and the granular pipe becomes low, resulting in loosening of the granular pipe. have.

The present invention has been made to solve the problems of the prior art as described above, the present invention to effectively prevent the deflection of the granular tube even when the granular tube fixed structures expand or contract according to the temperature difference in the summer and winter. It is a problem to provide a granular pipe deflection prevention structure.

The above object of the present invention is buried in the interlayer floor of the building and the inner space is formed through the sleeve, the standing tube is installed through the inner space of the sleeve, between the inner surface of the sleeve and the standing tube And a pipe clip fastening to be fitted into a space of the pipe fitting, and a pipe clip surrounding and tightening the granular pipe in a state in contact with the upper surface of the pipe fitting, wherein the pipe clips each end is bolted to each other. A pair of spring portions, each spring portion being formed in a semicircle along the circumferential direction so as to correspond to the circumferential shape of the riser tube, and a fastening portion which is bolted to both end portions of the circumferential direction and formed in a width direction perpendicular to the circumferential direction; The shape of the cross section of the tightening force reinforcement, characterized in that the center portion is convex outward and both ends are horizontal shape The life is achieved by a mouth care deflection prevention structure using a clip.

In order to achieve the above object, it is preferable that a close contact portion of a synthetic resin material is formed inside the pair of spring portions.

In addition, the object of the present invention is the step of fixing the sleeve formed therein through the space in the bottom formwork, the concrete is cast in the formwork to fix the sleeve to the bottom surface, the inner tube of the sleeve Installing the granular tube by passing through the tube; inserting a granular tube fixture into a space between the sleeve and the granular tube; positioning a pipe clip to surround the granular tube; Fastening the pipe clip to the granular tube by bolting the pipe clip in a state in which the pipe clip is in close contact with the upper surface of the granular tube fixture while surrounding the circumference of the boss and fixing the pipe clip to the upper surface of the granular tube fixture In this state, the pipe clip is further tightened with the bolt to cause deformation of the pipe clip. And the pipe clip is formed in a semicircle along the circumferential direction so as to correspond to the circumferential shape of the granular tube, and the cross section in the width direction is horizontally curved at both sides and the center portion is convex outwardly. A pair of springs are formed at the end to be fastened with bolts, and both ends of each spring are fastened with bolts to tighten the periphery of the granular pipe, and the pipe clip is further tightened with the bolts. Deformation occurring in the pipe clip in the tightening step is also achieved by the granular tube fixing method using a tightening force reinforcing pipe clip, characterized in that the center portion of the spring portion is a deformation close to the outer surface of the granular tube.

According to the granular pipe deflection prevention structure using the tightening force reinforcing pipe clip according to the present invention is made by a simple operation of fixing the pipe clip to the granular pipe in a state in which the pipe clip of the deflector of the granular pipe is in close contact with the granular pipe fixing fixture. As a result, the work process is simple, quick, and the parts used are simplified.

In addition, according to the granular pipe sag prevention structure using the tightening force reinforcing pipe clip according to the present invention, since the pipe clip is fixed by tightening only the granular pipe itself, unnecessary external force is not applied to the granular pipe to prevent loosening of the granular pipe. Can be.

In addition, the pipe clip of the riser tube deflection prevention structure using the tightening force reinforcing pipe clip according to the present invention exhibits an excellent fixing force to reliably and continuously tighten the stationary tube by the restoring action by deformation.

1 is a perspective view of a granular pipe deflection prevention structure using a tightening force reinforcing pipe clip according to the present invention,
Figure 2 is a cross-sectional view of the granular pipe deflection prevention structure using a pipe clip for tightening force in accordance with the present invention,
3 is a perspective view of a pipe clip of the granular pipe deflection prevention structure using a tightening force reinforcing pipe clip according to the present invention,
Figure 4 is a cross-sectional view showing a state in which the pipe clip of the riser tube sag prevention structure using the tightening force reinforcement pipe clip according to the present invention is fixed to the standing tube,
5 is a cross-sectional view showing a state in which a pipe clip tightens the granular pipe in the structure of the riser tube sag prevention structure using the tightening force reinforcing pipe clip according to the present invention,
FIG. 6 is a perspective view illustrating a structure of preventing standing tube sag using a conventional pipe girder. FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the standing pipe (2) deflection prevention structure using the pipe clip for tightening force 10 in accordance with a preferred embodiment of the present invention.

1 is a perspective view of a structure for preventing sag of a standing tube 2 using a tightening force reinforcing pipe clip 10 according to the present invention, and FIG. 2 is a standing tube using a tightening force reinforcing pipe clip 10 according to the present invention. ) Is a cross-sectional view of the deflection prevention structure, Figure 3 is a perspective view of the pipe clip 10 of the riser pipe (2) deflection prevention structure using the tightening force reinforcing pipe clip 10 according to the present invention.

As shown in Figures 1 to 3, the standing pipe 2 deflection prevention structure (hereinafter referred to as the 'standing pipe 2 deflection prevention structure') using the tightening force reinforcing pipe clip 10 according to the present invention is the bottom A sleeve 3 embedded in the surface 1, a pipe fitting 10 installed between the sleeve 3 and the standing tube 2, and a pipe clip 10 installed on an upper portion of the standing tube fixing 5 It is configured to include.

The sleeve 3 is cylindrical and has a hollow space penetrated therein, and the granular tube 2 can pass through the hollow space inside. A locking portion 4 is formed on the outer surface of the sleeve 3 so that the locking portion 4 is held in the concrete forming the bottom surface, thereby preventing the sleeve 3 from being pushed upward and downward from the bottom surface. The sleeve 3 first secures the sleeve 3 to the top of the formwork before placing the concrete to form the floor of the building and casts the concrete so that the sleeve 3 is embedded in concrete so that the floor surface of the building 1 It is installed to be integrally fixed to).

The granular tube fixture 5 has a ring structure in which one side is cut and tapered to reduce the thickness in the downward direction. The standing tube fixture 5 enters the side of the standing tube 2 in the state where the incision is opened, and then the open portions of the standing tube fixture 5 surround the standing tube 2 while approaching each other. The granular tube fixture 5 surrounding the granular tube 2 is inserted into the space between the sleeve 3 and the granular tube 2 and pushed downwards so that the granular tube fixture 5 is connected to the sleeve 3 and the granular tube ( The granular pipe 2 is fixed to the sleeve 3 by being sandwiched and engaged between 2). The granular tube fixture 5 is sandwiched between the outer surface of the granular tube 2 and the inner surface of the sleeve 3 to perform a wedge action to fix the granular tube 2 to the sleeve 3.

Pipe clip 10 is composed of a pair of spring portion 12 which is fastened to each other. Each spring 12 forms a semicircle in the circumferential direction. Both ends of the spring portion 12 in the circumferential direction are bent to form a fastening part 13 extending outwardly, and a fastening part 13 is formed with a bolt hole 14 to be fastened with a bolt. The shape of the cross section in the width direction of the spring portion 12 is convex in the center portion 16 in the outward direction of the standing tube 2 (corresponding to a U-shaped groove when viewed from the inside of the spring portion) and the center portion 16 is referred to. Both end portions 17 have a flat shape. On the inner surface of the spring portion 12 which is in contact with the granular tube 2, the contact portion 11 of a synthetic resin material (for example, urethane, rubber, etc.) having good adhesion performance in order to prevent slipping against the granular tube 2. Is formed to surround the inside of the spring portion 12. By the convex center portion 16 of the spring portion 12 (corresponding to a U-shaped groove when viewed from the inside of the spring portion), the rigidity of the spring portion 12 is increased, so that a stronger force (bending load) can be received.

The fixing method of the granular pipe 2 for forming the sag prevention structure 2 according to the present invention consists of the following steps.

The sleeve 3 is fixed to the top of the formwork prior to the concrete pouring to form the floor of the building, and the concrete is placed on the formwork so that the sleeve 3 is embedded in the concrete to be integrally fixed to the floor of the building. do.

The standing pipe 2 is installed so that the standing pipe 2 passes through the inner space of the sleeve 3 embedded in the bottom surface.

Open the granular tube fixture 5 in the lateral direction of the granular tube 2 installed through the sleeve 3 to enter the granular tube fixture 5 into the granular tube 2 to surround the granular tube 2 and then the sleeve ( The granular tube fixture 5 is forcibly pressed into the space between 3) and the granular tube 2. A hammer and a tablet can also be used when forcibly pressing the granular tube fixture 5.

The pair of springs 12 of the pipe clip 10 are approached to both sides of the riser tube 2 so that the pair of springs 12 of the pipe clip 10 surround the riser tube 2 on the upper surface of the riser tube fixture 5. Position it.

A pair of spring portions in a state in which the pair of spring portions 12 of the pipe clip 10 are in close contact with the upper surface of the riser tube fixture 5 while the riser tube fixture 5 surrounds the riser tube 2. Fasten the pipe clip 10 to the riser pipe 2 by fastening the fastening part 13 of 12) with a bolt. At this time, the pipe clip 10 secures the pipe clip 10 to the riser tube 2 with a bolt in a state where the lower end is in close contact with the upper surface of the riser fixture 5. Therefore, in the state in which the pipe clip 10 is fixed to the standing pipe 2, the lower end of the pipe clip 10 is in a state of being in close contact with the upper surface of the standing pipe fixing tool 5.

After fixing the pipe clip 10 with the bolt in the state in which the pipe clip 10 is in close contact with the upper surface of the standing pipe fixture 5, the deformation of the pair of springs 12 of the pipe clip 10 is performed. The tightening part 13 of the spring part 12 is further tightened by giving a strong force to the bolt to generate. When the pipe clip 10 is fixed to the standing tube 2 and a further force is applied to the tube to further tighten the bolt, the center portion 16 based on the width direction of the spring part 12 is the standing tube (2). ) And the both end portions 17 are in a state of fine lifting on the outer surface of the granular pipe 2.

Hereinafter will be described the operation and effect of the standing pipe (2) deflection prevention structure using the tightening force reinforcing pipe clip (10) according to the present invention.

Figure 2 is a cross-sectional view of the standing tube (2) deflection prevention structure using a tightening force reinforcing pipe clip (10) according to the present invention.

As shown in Figure 2, according to the riser tube 2 sag prevention structure according to the present invention, the riser tube fixture 5 is fitted and fixed to the upper end of the sleeve 3 fixed to the bottom surface (1). And the pipe clip 10 is closely fixed to the upper surface of the standing pipe fixture 5. At this time, since the pipe clip 10 is tightened around the granular tube 2 and fixed to the granular tube 2, the pipe clip 10 is fixed to the granular tube 2 integrally.

Therefore, when the standing pipe 2 sags downward due to its own weight or an external force, the pipe clip 10 fixed to the standing pipe 2 is caught by the standing pipe fixture 5 and can no longer go down. Because of this, the standing tube 2 remains in position and no longer sags down.

That is, the top of the sleeve (3) fixed to the bottom surface (1) is fixed to the position of the standing tube fixture (5) tightly fixed and the pipe clip (10) is caught on the upper surface of the standing tube fixture (5) and further down In the end, as long as the granular tube 2 does not slide in the pipe clip 10, the granular tube 2 may be self-weighted or deflected by the granular tube 2 according to the present invention. The granular tube fixing device 5 is fitted and fixed to the upper end of the sleeve 3 fixed to the bottom surface 1. And the pipe clip 10 is closely fixed to the upper surface of the standing pipe fixture 5. At this time, since the pipe clip 10 is tightened around the granular tube 2 and fixed to the granular tube 2, the pipe clip 10 is fixed to the granular tube 2 integrally.

Therefore, when the standing pipe 2 sags downward due to its own weight or an external force, the pipe clip 10 fixed to the standing pipe 2 is caught by the standing pipe fixture 5 and can no longer go down. Because of this, the standing tube 2 remains in position and no longer sags down.

That is, the top of the sleeve (3) fixed to the bottom surface (1) is fixed to the position of the standing tube fixture (5) tightly fixed and the pipe clip (10) is caught on the upper surface of the standing tube fixture (5) and further down As a result, the granular pipe 2 does not sag downward due to its own weight or external force unless the granular pipe 2 slides on the pipe clip 10.

Figure 4 is a cross-sectional view showing a state in which the pipe clip 10 of the standing pipe (2) deflection prevention structure using the tightening force reinforcing pipe clip 10 according to the present invention is fixed to the standing pipe (2), Figure 5 is Fig. 2 is a cross-sectional view illustrating a state in which the pipe clip 10 tightens the granular pipe 2 in the structure of the riser tube 2 using the tightening force reinforcing pipe clip 10 according to the present invention.

As shown in Figures 4 and 5, the pipe clip (10) surrounding and tightening the riser tube (2) above the riser tube fixture (5) is a pair of spring portion 12 that constitutes the pipe clip (10) ) Does the following:

Since the cross-sectional shape in the width direction of the spring part 12 is convex outward from the center, the spring part 12 is formed by enclosing the standing tube 2 and then fastening each end of the two spring parts 12 with a bolt between each other. ) Is a state in which the lower portion of the spring portion 12 is in close contact with the outer surface of the granular tube (2) while the tensile force acts in the circumferential direction.

Since the fastening portion 13 at the circumferential end of each spring portion 12 is still in a state of being spaced apart from each other while the lower portion of the spring portion 12 is in close contact with the outer surface of the standing tube 2. The end of the spring portion 12 may be brought into close contact by tightening the bolt. When the lower portion of the pair of springs 12 is in close contact with the standing tube 2, a pair of springs 12 is tightened with a bolt by applying a stronger force to the pair to further tighten the pair. Each fastening portion 13 of the spring portion 12 of the closer to each other, the spring portion 12 is pressed against the outer surface of the standing tube 2 with a greater force at this time the width direction of the spring portion 12 The cross section deforms. That is, the deformation of the spring portion 12 is such that the convex outward portion of the center portion of the spring portion 12 in the cross section in the width direction of the spring portion 12 is closer to the outer surface of the standing tube 2 and the width of the spring portion 12. The flat part which is a both end part of a direction becomes a shape which floats somewhat in the surface of the granular pipe 2 as the edge part closer to the width direction.

By the deformation of the spring portion 12, the spring portion 12 generates the following two tightening forces with respect to the standing pipe (2).

The first force is the tightening force that the spring portion 12 wraps around the granular tube 2 by the bolt fastening force, and the lower portion of the spring portion 12 presses the outer surface of the granular tube 2 in the vertical direction.

The second force is a force generated by the restoring force to close the convex part of the center in the width direction of the spring part 12 to the granular conduit 2 by the deformation of the spring part 12 and to restore it to its original state. It is a force which tightens the granular pipe 2, while the part of the both ends 17 of the width direction of () contracts to the center part of the width direction of the spring part 12. As shown in FIG.

Since the second force is added to the first force in this way, consequently, the pipe clip 10 generates a larger tightening force around the granular tube 2 by the restoring force of the convex portion of the spring portion 12.

Particularly, the effect of the second force is that in the winter, when the granular tube 2 is contracted and the outer diameter is reduced, the deformation of the center portion of the spring portion 12 in the width direction of the granular tube 2 is closer to that of the granular tube 2. Due to the reduction in the outer diameter, the center portion in the width direction of the spring portion 12 moves away from the standing tube 2, so that both end portions 17 in the width direction of the spring portion 12 come closer to each other. The outer diameter of the inner space formed by both side end portions 17 in the width direction of the spring portion 12 in close contact with the lower portion decreases, so that the lower portion of the spring portion 12 still tightly tightens the outer surface of the granular tube 2. do.

That is, when the distance between the two end portions 17 in the width direction of the spring portion 12 is closer due to the decrease in the outer diameter of the standing tube 2, the inner space formed by the pair of spring portions 12 becomes smaller. Even though the outer diameter of the standing tube 2 decreases, the lower part of the spring portions 12 remain in close contact with the standing tube 2, so that the spring portion 12 applies a sufficient tightening force to the standing tube 2. do. If there is no convex portion in the center of the spring portion 12 in the width direction, if the outer diameter of the standing tube 2 decreases due to a decrease in temperature in winter or the like when the pair of spring portions 12 are fastened, the spring portion 12 Since there is no portion to be restored in the) between the spring portion 12 and the riser tube (2) is loose, and thus the riser tube (2) can be drooped down. However, the pipe clip 10 of the riser tube 2 sag prevention structure according to the present invention has a riser tube 2 because the deformation of the convex part of the spring portion 12 is restored even if the outer diameter of the riser tube 2 is reduced. The pipe clip 10 can be prevented from loosening.

Even if the spring portion 12 itself also contracts when the outer diameter of the standing tube 2 decreases, restoring of the center portion of the spring portion 12 still occurs, so that the standing tube 2 and the spring portion 12 ), The degree of adhesion is relatively greater than the case where there is no convex portion in the spring portion 12, so that the spring portion 12 generates a greater tightening force on the granular tube (2).

According to the standing pipe 2 sag prevention structure according to the present invention, the structure for preventing the standing pipe 2 itself from sagging down is much simpler than the case of using a pipe girder.

In the case of using a pipe girder, the pipe girder fixed to the bottom pushes or pulls up the granular pipe (2). Therefore, when the temperature change is large in summer or winter, the shrinkage of the pipe girder and the granular pipe (2) is the same. In this case, the pipe girder generates unnecessary external force on the standing pipe 2. The reason is that the pipe girder is fixed to the floor of the building, so if the distance between the granular pipe (2) and the pipe girder is slightly different due to the temperature change, the pipe girder pulls the pipe (2) laterally. Since the external force to be pulled or pushed acts, there is a concern that the fixing of the granular tube 2 may be loosened in relation to the bottom surface of another layer.

However, the pipe clip 10 of the standing pipe 2 sag prevention structure according to the present invention is because the pipe clip 10 only tightens the standing pipe 2 itself and does not pull or push the standing pipe 2 from the outside. , The unnecessary external force is not applied to the standing pipe (2). Therefore, since the external force is not applied to the standing tube 2, the possibility of loosening the standing tube 2 is much smaller.

In addition, when the number of floors of a building is high, pipe girder is often installed for each of 3 to 4 floors. In this case, the distance between one pipe girder and an adjacent pipe girder is about 10 to 15 meters. The expansion or contraction in the longitudinal direction causes slippage of the fixed part of the granular pipe 2 and the pipe girder, and thus frequent slippage weakens the clamping force of the granular pipe 2 and the pipe girder. However, in the case of the present invention, the pipe clip 10 only prevents the granular pipe 2 from moving downward and does not prevent the granular pipe 2 from moving upward, so that the granular pipe 2 expands in the longitudinal direction. If it is assumed that there are two pipe clips (10) up and down, the lower pipe clip (10) can be lowered further down, so it can slide with respect to the standing pipe (2), but the pipe pipe (10) of the upper Ascending upward along the correlation 2 is not impeded so no slip occurs. In this way, the frequency of slipping of the pipe clip 10 to prevent sagging of the standing pipe 2 is much reduced than in the case of using a conventional pipe girder. In the case of fixing the standing pipe 2 by the conventional pipe girder, when looking at the two pipe girders, the sliding occurs between the upper and lower pipe girders and the standing pipe 2 during the expansion of the standing pipe 2. Slip occurs between the upper and lower pipe girder and the granular tube 2 even when the correlator 2 contracts, so that the frequency of slipping is large, thereby weakening the tightening force of the granular tube 2 and the pipe girder more rapidly. .

The standing pipe 2 sag prevention structure according to the present invention is to use the pipe clip 10 in the standing pipe 2 itself, so that it does not occupy the space around the standing pipe 2 and is effective in utilizing the space.

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and those skilled in the art will be able to make various modifications, changes and additions within the spirit and scope of the present invention. And additions should be regarded as falling within the claims of the present invention.

1: bottom surface, 2 standing pipes, 3 sleeves, 4 locking parts, 5 standing pipe fixtures, 10 pipe clips, 11 close contact parts, 12 spring parts

Claims (3)

A sleeve embedded in an interlayer floor of the building and having a space therein;
A riser tube installed through an inner space of the sleeve;
A granular tube fixture fitted into a space between the inner surface of the sleeve and the granular tube;
And a pipe clip surrounding and tightening the granular tube in contact with the upper surface of the granular tube fixture.
The pipe clip includes a pair of springs, each end of which is bolted to each other,
Each spring portion is formed in a semi-circular shape along the circumferential direction to correspond to the circumferential shape of the standing tube, and a fastening portion is formed at both ends of the circumferential direction by bolts, and the cross-sectional shape in the width direction perpendicular to the circumferential direction has a center portion. Convex outward and both ends are horizontal,
The pair of spring portion is prevented from falling pipe structure using a tightening force reinforcement pipe clip, characterized in that the close contact portion of the synthetic resin material is installed to surround the inside of the spring portion. delete delete

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