KR101680583B1 - composite connection socket for duct line - Google Patents

Abstract

The present invention relates to a composite material connection socket for a drain pipeline, which is disposed between both adjacent ends of drain pipelines in order to connect the drain pipelines consecutively disposed along a length direction, thereby ensuring a light weight and improving durability against surroundings. The composite material connection socket for a drain pipeline comprises: a first mating end having an internal mating surface fitted to an external surface of one end of a drain pipeline provided upstream of water; and a second mating end having one end integrally connected to the other end of the first mating end to be stepped with each other, and having an external mating surface fitted to an internal surface of the other end of the drain pipeline provided downstream of the water.

Description

Composite connection socket for duct line for drain pipe

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite connection socket for a drain pipe, and more particularly, to a composite connection socket for a drain pipe having a light weight and improved durability to the surrounding environment.

Generally, a drainpipe is installed to discharge rainwater or wastewater to the outside of the structure. Particularly, bridges formed such that people, vehicles, and the like can pass through rivers, canals, lowlands, valleys, and the like are installed continuously along the longitudinal direction.

In detail, the bridge comprises a top plate, a barrier wall formed at the top plate edge to prevent fall, and a bridge supporting the top plate. At this time, the top plate or the barrier wall is provided with a drainage system for draining the road surface water such as rainwater or sewage.

Here, the drainage system is divided into a point drainage system in which a collection port at which the inflow and drainage of road surface water are concurrently formed at regular intervals, and an upstream water supply system in which an inlet is formed as a whole along the longitudinal direction of the bridge and an outlet is formed at intervals .

At this time, the pre-existing water system includes a plurality of the lateral water pipes which penetrate the barrier wall in the width direction and discharge the road surface water collected on the top plate to the outside of the bridge, And a drain pipe connected continuously along the longitudinal direction of the drain pipe.

Conventionally, the drain pipe is made of an aluminum material having a relatively light weight and corrosion resistance to water, and installed in the bridge. However, the drain pipe of the aluminum material is easily deformed by an external impact, and when the external surface is scratched during the installation, the periphery of the scratch is whitened and corroded. Further, when a snow remover such as calcium chloride is sprayed on the bridge top plate in winter, there is a problem that it is corroded by the snow remover component mixed with the road surface water.

This causes a corrosion hole due to corrosion in the drain pipe, which causes the road surface water to fail to flow and discharge properly. In addition, the durability of the corroded portion is lowered, and the load on the road surface or the impact from the bridge damages the drain pipe.

As a result, there is a problem that excessive cost and manpower are consumed for repairing or replacing the broken drain pipe, resulting in a reduction in economy. In addition, there is a problem that when a broken drain pipe falls down to a facility provided below the bridge, or a person traveling on the lower side of the bridge or an upper side of the vehicle, there is a problem of human accidents and economic loss.

Further, the drain pipe is formed to have a structure in which the adjacent both ends are continuously connected by extending to a predetermined length. At this time, a sealing member made of a rubber material is provided at a portion where the drain pipe is connected to prevent leakage of the road surface water while stably overlapping the end portions. However, as the installation and use period of the drainage system has elapsed, there has been a problem that the elastic force of the sealing member of the rubber material is lowered and corroded to prevent leakage between the drain pipes. This causes a cost for replacing the sealing member and waste of manpower.

In order to solve the above-mentioned problems, some techniques for replacing a conventional pipe material made of a metal material with a synthetic resin material such as fiber reinforced plastics (FRP) have been disclosed. The synthetic resin material of high strength as described above is lighter than the metal material, and its strength is maintained, and corrosion resistance is improved, so that the service life of the drain pipe is extended.

However, even if the drain pipe is made of a high-strength synthetic resin material, the accessory device for connecting or installing the drain pipe is made of a conventional metallic material, so that the effect of preventing corrosion is insufficient.

Therefore, it is urgently required to develop a technique for manufacturing an accessory device for installing the same on a structure such as a bridge, as well as the drain pipe by using the synthetic resin material described above.

Korea Patent No. 10-0301217

In order to solve the above problems, it is an object of the present invention to provide a composite connection socket for a drain pipe which is light in weight and has improved durability against the surrounding environment.

In order to solve the above problems, the present invention provides a composite material connection structure for a drain pipe disposed between neighboring ends of a drain pipe for connection to a drain pipe of the same size, A first type joint having an inner side mating surface formed on an upstream side of water and fitted to an outer surface of one end of the water pipe; And a second type joint having a first type joint portion formed integrally with the other end portion of the first type joint portion and having an outer joint surface to be fitted to an inner surface of the other end portion of the water pipe provided on the downstream side of the water, An acrylonitrile-butadiene styrene copolymer (ABS) resin, a soft polycarbonate resin, and a polycarbonate resin so that each of the ends of the first and second molds is elastically pressed in. , A flexible polypropylene resin, a soft polyethylene resin, polystyrene, styrene butadiene rubber (SBR), and the like. Wherein an inner surface profile of the inner mating surface is formed to correspond to an outer surface profile of an end surface of the drain pipe so that the outer surface of the drain pipe is securely coupled to the inner surface of the inner mating surface, Wherein the outer surface profile of the outer mating surface is formed so as to correspond to the inner surface profile of the end surface of the water pipe so that the outer surface of the outer mating surface is in interference fit with the inner surface of the drain pipe, A first restraining end and a second restraining end stepped by the thickness of the angled joint are formed on the inner side and the outer side of the abutment part in which the first and second type abutments are integrally joined so that the inner surface of the abutment is formed into a continuous profile, And the first and second mold assemblies are formed at the upper edges of the first and second mold assemblies, The upper surface of the fastening extension portion formed on the first type joint is in close contact with the lower surface of the fastening blade portion formed on the drain pipe and the lower surface of the fastening extension portion formed on the second type fastener is connected to the drain pipe And a slot hole is formed in the fastening extension portion so as to be communicated with the fastening hole formed in the fastening wing portion and to be fastened to the fastening member at the same time in the longitudinal direction, Provide a connection socket.

In this case, it is preferable that a bottom surface of the second type joint is formed with a downwardly inclined sidewall to the outside of the other end edge.

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Through the above solution, the composite connection socket for a drain pipe according to the present invention provides the following effects.

First, the connection socket for connecting the drain pipe line made of high-strength synthetic resin for corrosion prevention is also made of a composite synthetic resin material which is lightweight and maintains its strength substantially more than conventional metal materials, so that corrosion resistance and durability can be remarkably improved.

Second, since the connection socket is made of a soft synthetic resin material and is resiliently fitted to the end of the drain pipe, it can be firmly coupled with the actual leakage prevention without any separate coupling means or sealing means.

Third, the inner surface of the first type joint formed at one side from the middle stepped joint portion is fitted to the outer surface of the end portion of the drain pipe path disposed on the upstream side, and the outer surface of the second type joint is connected to the drain pipe As a result, a natural downward step is formed along the direction of the water flow, so that the flow of water can be stably guided.

1 is a schematic view showing a bridge to which a drainage system is applied;
2 is an exploded perspective view of a leading water tube according to an embodiment of the present invention;
3 is a schematic view showing a side view of a composite connection socket for a drain pipe according to an embodiment of the present invention;
FIG. 4 is a schematic view showing a side of a composite connection socket for a drain pipe connected to a drain pipe according to an embodiment of the present invention; FIG.

Hereinafter, a composite connection socket for a drain pipe according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a bridge to which a drainage system is applied.

In detail, the drainage system 1 is installed on the outside of the object structure exposed to the external environment and is formed as a flow path for discharging rainwater or the like to one side of the structure. Particularly, the drainage system 1 is applied in order to prevent the vehicle from slipping or overflowing with rainwater due to the road surface water collected on the upper plate B of the structure such as the bridge A to cover the field of view.

Here, the drainage system 1 is provided along the longitudinal direction of the bridge A so that the road surface water collected on the upper plate B is discharged to the outside. Generally, the drainage system 1 and the overhead water pipe 3 ).

In detail, the lateral water pipe portion 2 may be provided in a plurality of through holes so that the lower ends of the barrier walls C protruding above the widthwise ends of the bridge A are downwardly sloped at predetermined intervals. At this time, the one end of the transverse water pipe portion 2 is provided with a grating 4 for filtering off leaves and foreign substances discharged together with the rainwater from the upper panel B to prevent clogging of the transverse water pipe portion 2 .

The pre-water pipe section 3 is continuously connected along the longitudinal direction of the bridge A by the fixing device 20, and the number of road surfaces discharged through the lateral water pipe section 2 flows to one side. (5) are included. Of course, the side water pipe portion 2 may not be provided as a separate pipe portion, but may be formed as a through hole formed at one side of the bridge (A) to the barrier wall (C). Furthermore, it is also possible that the pre-water tube portion 3 is directly installed along both ends of the upper plate B. [

Here, the pre-water pipe section 3 may be formed to be inclined downward at a predetermined slope from the upstream side to the downstream side of the water so that the flow of water, such as the road surface number, is made in one direction. A drain pipe may be formed on the downstream side of the water to discharge the water below the bridge.

At this time, the side of the water pipe 5 is formed with side portions 5b on both sides in the width direction of the bottom surface 5a extending in the longitudinal direction so as to form a channel through which the water can move. A coupling wing 5c extending in a predetermined width is formed on the upper edge of the side portion 5b. Here, the drain pipe 5 may be formed as an open top side as shown in the drawing, and may have a shape in which the top side is covered to close the flow path. The drain pipe 5 may be formed in a bent shape so that an edge is formed between the bottom surface 5a and the side surface portion 5b. However, the bottom surface may be rounded in some cases.

The connecting wings 5c may be formed by bending the upper end of the side wall 5b but may be formed by a side wall 5b protruding from both sides of the bottom wall 5a, It is preferable that a high-strength synthetic resin is extruded into a metal mold corresponding to the cross-sectional shape of the fastening vane 5c formed in the body 1,

In particular, high strength synthetic resin materials such as fiber reinforced plastics (FRP) have a lower material cost than conventional metal materials, and are lightweight, easy to process, and excellent in strength and corrosion resistance. Accordingly, the manufacturing cost of the drain pipe 5 is reduced, and corrosion of the drain pipe 5 is prevented in an environment where frequent exposure to water occurs, so that the service life can be remarkably prolonged.

At this time, the drain pipe 5 is manufactured by extrusion molding in the longitudinal direction continuously, and is cut to a predetermined length so as to be easily transported and installed to the installation place. A plurality of the drain pipes 5 are continuously provided so as to correspond to the length of the bridge A and the composite connection socket for a drain pipe according to the present invention for connecting the adjacent both ends of the drain pipe 5 (10) is disposed.

3 is a schematic view showing a side surface of a composite material connection socket for a drain pipe according to an embodiment of the present invention, and FIG. 4 is a cross- FIG. 2 is a schematic view showing a side where a composite connection socket for a drain pipe and a drain pipe are connected according to an embodiment of the present invention. FIG.

2 to 4, the composite connection socket 10 for a drain pipe according to the present invention includes a lower wall portion 10a corresponding to a bottom surface 5a side of the drain pipe path 5, And a side wall portion 10b extending upward from both ends of the side wall portion 10a and corresponding to the side wall portion 5b of the drain pipe path 5. [ It is preferable that the composite connection socket 10 for the drain pipe includes the first type joint 11 and the second type joint 12.

The composite material connection socket 10 for a drain pipe integrally connects neighboring ends of a plurality of drain pipes 5F and 5B arranged so that both longitudinal ends thereof are adjacent to each other. Are formed to have substantially the same dimensions.

In detail, the first type joint 11 is connected to the drain pipe 5F provided on the upstream side of the water flowing along the pre-water pipe 3, and the outer surface of one end of the upstream water pipe 5F It is preferable that an inner mating face 13 to be fitted and held is formed.

One end of the second type joint 12 is integrally connected to the other end of the first type joint 11 in a stepped manner and is connected to the water pipe path 5B provided on the downstream side of the water. At this time, it is preferable that the second type joint 12 is formed with an outer mating surface 14 which is fitted to the inner surface of the other end of the downstream water pipe 5B.

On the other hand, the downstream side of the water is preferably understood as a direction relatively adjacent to the above-described discharge pipe line on the basis of the composite connection socket 10 for one pipe. The upstream side of the water is preferably understood as the opposite direction of the downstream side with respect to the connecting socket 10. [

The connection socket 10 including the first type joint 11 and the second type joint 12 includes a lower wall portion 10a, a side wall portion 10b, and a fastening extension portion 10c, And injecting a molten synthetic resin material into the mold corresponding to the formed mold. At this time, the lower wall portion 10a and the side wall portion 10b may be formed so as to correspond to the cross-sectional shape of the above-described water pipe 5.

That is, if the bottom surface 5a and the side surface portion 5b of the drain pipe path 5 are formed in a corner shape, the lower wall portion 10a and the side wall portion 10b of the connection socket 10 are also bent . Also, if the bottom surface of the water pipe 5 is rounded, the bottom wall of the connection socket 10 may be rounded. In this way, the drainpipe 5 connected using the connection socket 10 can be installed in a substantially continuous profile.

The connection socket 10 includes a first mold half 11 and a second mold half 12 formed on one side of the central stepped joint 10f and the second mold half 12 formed on the other side, Injection molding can be performed by injecting a synthetic resin material. Of course, the first type joint 11 and the second type joint 12 may be formed by extruding or extruding a synthetic resin material, respectively, but the other end of the first type joint 11 and the second type joint 12 ) May be thermally fused so as to overlap one end of the thermoplastic elastomer with a predetermined width.

At this time, the inner surface profile of the inner mating surface 13 corresponds to the outer surface profile of the end of the water pipe 5, more preferably, it may be formed to be smaller than the outer surface profile of the end surface of the water pipe 5. As a result, the outer surface of the end of the water pipe 5 can be firmly and tightly engaged with the inner surface of the inner mating surface 13, which is a soft synthetic resin material.

The outer surface profile of the outer mating surface 14 corresponds to the inner surface profile of the end of the water pipe 5, and more preferably the inner surface profile of the end pipe of the water pipe 5 may be formed larger. Accordingly, the inner surface of the end of the water pipe 5 can be firmly and tightly coupled to the outer surface of the outer joint surface 14, which is a soft synthetic resin material.

The composite connection socket 10 for the drain pipe is made of a soft synthetic resin material so that the inner mating face 13 and the outer mating face 14 are resiliently restrained with the end of the drain pipe route 5 . In this case, the soft synthetic resin material has a rigidity such that the above-described shape of the connection socket 10 can be maintained, while the angled mating surfaces 13 and 14 of the angled joints 11 and 12 are connected to the drain pipe It is desirable to understand that the material is elastic enough to be stretched and restored corresponding to the end profile of the end portions 5,

That is, when both mutually adjacent end portions of the water pipe 5 are coupled to the connection socket 10, the inner mating face 13 and the outer mating face 13 corresponding to the inner or outer profile of the water pipe 5, (14) is resiliently compressed and engaged. When the connection socket 10 and the drain pipe 5 are fitted together, the inner mating face 13 and the inner mating face 13, which have been compressed, are resiliently restored and the inner face of the drain pipe 5 And the outer surface. Thus, even if there is no separate adhesive or coupling means, the connection socket 10 and the drain pipe 5 can be stably fitted into each other.

In addition, since a clearance is not substantially formed between the inner mating face 13 and the outer mating face 14 of the connecting socket 10 and between the outer and inner surfaces of the end of the drain pipe route 5, May also provide a sealing function. In this way, leakage can be substantially blocked at each connecting portion of the elongated water receiving portion (3) by merely inserting the connecting socket (10) and the water discharging pipe (5) into each other without a separate sealing means.

The first type joint 11 is fitted to receive substantially the end portion of the drain pipe path 5 and the second type joint 12 is inserted into the end portion of the water pipe path 5 substantially Respectively. At this time, it is preferable that the angled joints 11 and 12 have a thickness corresponding to each other. The first and second mold assemblies 11 and 12 are integrally joined to each other at an inner side and an outer side of the joint 10f, The restricting end 15 and the second restricting end 16 are preferably formed.

Here, one end of the upstream side water passage 5F is inserted into the first type joint 11 so as to be inserted into the first type joint 11, and is in contact with the first constraint end 15 to restrict the engagement position. The other end of the downstream side water passage 5B is fitted into the second type joint 11 so as to cover the outside of the second type joint 11 and is in contact with the second restricting end 16 to restrain the engagement position.

A coupling extension portion 10c is formed at the upper edge of the opened upper end of the first type joint 13 and the second type joint 14 so as to overlap the coupling vane 5c formed in the drain pipe path 5 . The fastening extension 10c is formed with a slot 10d which is long in the longitudinal direction so that the through hole 5d formed in the fastening vane 5c communicates with the fastening member 17, desirable. It should be understood that the slot hole 10d is elongated in the longitudinal direction and is opened long in the continuous direction of the first type joint 13 and the second type joint 14. [

The upper surface of the fastening extension 10c formed on the first type joint 11 and the lower surface of the fastening vane 5c formed on the drain pipe 5 are in close contact with each other and the second type joint 12 and the upper surface of the fastening vane 5c formed on the water line 5 are in close contact with each other.

Accordingly, the upper surface of the fastening extension portion 10c of the second type joint 12 and the upper surface of the fastening blade portion 5c of the upstream side water passage 5 are substantially continuous. 1) is fastened to the fixing device 20 (see FIG. 1) fixed to one side of the bridge A, the one side of the fastening part of the fastening device (20 of FIG. 1) So that the fastening portions of the tube portion 3 can be stably fixed to each other while maintaining mutual equilibrium. Here, the fastening portion of the line pipe 3 is understood to be a portion where the fastening extension portion 10c and the fastening wing portion 5c are overlapped.

The through hole 5d formed in the fastening vane 5c can be formed only by connecting the end of the drain pipe 5 to the first constraint stage 15 and the second constraint stage 16, And the slot hole 10d are substantially communicated with each other. In addition, since the slot hole 10d is elongated along the longitudinal direction of the elongated water tube portion 3, the through hole 5d can be formed even though the dimensional precision between the water pipe 5 and the connection socket 10 is somewhat low. And the slot hole 10d can be naturally communicated.

At this time, the through hole 5d may also be opened long along the longitudinal direction like the slot hole 10d. Of course, it is also possible to perform the drilling operation so that the coupling wing 5c and the coupling extension 10c are simultaneously passed after the coupling socket 10 and the drain pipe 5 are fitted together.

The thicknesses of the angled joints 11 and 12 may be substantially equal to the thickness of the water pipe 5. Accordingly, the inner surface of the water pipe path 5F disposed on the upstream side and the inner surface of the second type joint 12 can be formed in a substantially continuous profile. A predetermined step may be formed so as to be lower by the thickness of the second mold half 12 from the other end of the second mold half 12 toward the downstream of the drain pipe path 5B disposed on the downstream side. Accordingly, since the downward stepped section is naturally formed in each of the portions where the connection socket 10 is disposed, the flow of water can be always made in a constant direction.

At this time, on the bottom surface of the second type joint 12, a spherical surface 12a inclined downward toward the outside of the other end rim 12a may be formed. That is, since the water flows more smoothly along the sloping sidewall 12a to further stabilize the flow of the water, the impact applied to the pre-water pipe 3 due to the swinging of water may be minimized.

The connecting socket 10 is made of a soft synthetic resin and is made of a resin such as an acrylonitrile butadiene styrene copolymer (ABS) resin, a soft polycarbonate resin, a flexible polypropylene resin , A soft polyethylene resin, a polystyrene resin, a styrene butadiene rubber (SBR), or the like.

That is, not only the drain pipe 5 manufactured by extruding a high strength synthetic resin material such as a fiber reinforced plastic but also the connecting socket 10 continuously connecting the same is also made of a synthetic resin material, It is possible to prevent breakage. Further, since the connection socket 10 is made of a composite material in which at least one kind of material is mixed, the connection socket 10 can be elastically fitted to the drain pipe path 5, Strength can be provided.

At this time, since the connection socket 10 is manufactured by injecting the melted synthetic resin material mixture into the mold having the above-mentioned shape, it is easy to manufacture even a complicated shape and can be mass-produced in a constant size. In addition, the composite synthetic resin material is light in weight and easy to install by workers, and the load applied to the bridge A by the load can be minimized even if the bridge A is installed in the bridge.

Accordingly, in order to prevent corrosion, the connection socket 10 for connecting the drain pipe 5 made of high-strength synthetic resin such as fiber-reinforced plastic is also made of a synthetic resin material. As a result, the corrosion resistance and the salt resistance are remarkably improved, so that the corrosion by the snow remover applied for excellent / wastewater and snow removal can be prevented, and the service life can be remarkably prolonged. Also, since the synthetic resin material is lighter than the conventional metal material and the strength is substantially maintained, the installation property may be remarkably improved.

At this time, since the connection socket 10 is made of a soft synthetic resin material and is resiliently resiliently fitted to the end portion of the water pipe 5, it is possible to securely block the leakage and to block the leakage without a separate coupling means or sealing means have. Furthermore, the connection socket 10 and the water pipe 5 are not permanently fixed by welding or the like, but can be easily fixed and repaired due to fitting, thereby improving maintenance.

The inner surface of the first type joint 11 formed at one side from the middle stepped joint portion 10f is fitted to the outer surface of the end portion of the water path 5F disposed on the upstream side and the second type joint 12 Is fitted to the inner surface of the end portion of the drainpipe passage 5B disposed on the downstream side. Accordingly, a natural downward step is formed along the flow direction of the water flowing through the pre-water pipe portion 3, so that the flow of water can be stably induced. Accordingly, since the impact applied to the pre-water pipe 3 by the flow of water is minimized, a stable installation state can be maintained.

In addition, the bridge A is also provided with a street lamp and electric pipelines for supplying electric power to various electric installations. At this time, since the drain pipe 5 and the connection socket 10 constituting the line drain pipe 3 are made of a nonconductive, non-magnetic synthetic resin material, they can be safely used even if the electric pipe is installed around the line.

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And these modifications fall within the scope of the present invention.

1: drainage system 3:
5,5F, 5B: Drain line 10: Composite connection socket for drain line
11: Type 1 joint 12: Type 2 joint
13: inner side mating surface 14: outer side mating surface
15: first restraining stage 16: second restraining stage
17: fastening member 20: fastening device

Claims (5)

A composite material connection socket for a drain pipe disposed between neighboring ends of a drain pipe for connection to a drain pipe of the same size, the composite metal material being continuously disposed along the longitudinal direction,
A first type joint formed on an upstream side of the water and having an inner mating surface which is fitted to an outer surface of one end of the water pipe; And
And a second type joint formed at one end of the first type joint so as to be integral with the other end of the first type joint so as to be fitted to the inner surface of the other end of the water pipe provided at the downstream side of the water,
An acrylonitrile-butadiene styrene copolymer (ABS) resin, a soft polycarbonate resin, and a polycarbonate resin so that each of the ends of the first and second molds is elastically pressed in. , A flexible polypropylene resin, a soft polyethylene resin, polystyrene, styrene butadiene rubber (SBR), and the like. And is made of a soft synthetic resin material,
Wherein an inner surface profile of the inner molding surface is formed so as to correspond to an outer surface profile of an end portion of the drain pipe so that the outer surface of the inner pipe joint surface is securely coupled to the inner surface of the inner pipe molding surface, The inner surface of the drain pipe connected to the first type joint and the inner surface of the second type joint are connected to each other by a continuous profile A first restricting end and a second restricting end stepped by the thickness of the angled joint are formed on the inner side and the outer side of the joint portion in which the first and second type joints are integrally joined,
The upper end of the first type joint and the second type joint is formed with a fastening extension portion which overlaps with a fastening wing portion formed along an upper end edge of the drain pipe, And the lower surface of the fastening extension portion formed on the second type joint is in close contact with the upper surface of the fastening blade portion formed on the drain pipe,
Wherein the fastening extension portion is formed with a slot hole that is long in the longitudinal direction so as to communicate with the through hole formed in the fastening blade portion and fasten the fastening member at the same time. delete The method according to claim 1,
And a bottom surface of the second type joint is formed with a spherical surface inclined downwardly to the outside of the other end rim. delete delete

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