KR20120051300A - Polygon duct - Google Patents

Abstract

PURPOSE: A polygonal duct having a fiber coating layer for a multi-composite structure is provided to obtain strong adhesion of the fiber coating layer by forming a core layer out of resin on a molded pipe and coating the fiber coating layer on the outer surface of the core layer. CONSTITUTION: A polygonal duct comprises an inner peripheral member(20), a core layer, and a fiber coating layer(110). In the inner peripheral member, reinforcing projections are formed at regular intervals on the upper side of an inner peripheral part(21) and a sealing protrusion is formed on the right end of the inner peripheral part. The core layer is formed between first resin(31) and second resin(41) coated on the exterior of the inner peripheral member. The fiber coating layer is spirally provided on the outer surface of the second resin.

Description

Polygon duct consisting of multiple composite fiber coating layers

The present invention relates to a multi-deck duct consisting of a multi-coating fiber coating layer, and more particularly, using a body made of a fiber coating layer using an inner diameter portion made of synthetic water quality and a light weight core layer and fiber, and easy construction. The present invention relates to a multi-deck duct composed of a multi-layered fiber coating layer for providing structural stability by forming a polygon and having excellent service life.

In general, various buildings such as general houses or offices are provided with ducts for various wiring in advance in the construction of the building, and ducts are used to purify the air generated during cooking in the air supply, cold, heating and kitchen. Is installed.

As a rule, the duct manufactured using the conventional tin plate or PVC hose is manufactured as a pipe while connecting the tins in the form of a screw.The duct can not be manufactured directly at the site where the duct is to be installed. It is common to manufacture and connect by flange at installation site.

However, since the duct uses a very thin tin, there is a defect that is easily crushed or damaged by an external impact, and there is a defect that can not be used for a long period of time because it is easily corroded by air, heat and food odor.

Among these conventional docs, Utility Model Publication No. 1979-0001811 (October 29, 1979) applied PVC flame retardant coating on non-combustible glass fiber nonwoven fabric to bend freely and use it as needed, but it was difficult to manufacture and economical. There is a drawback.

And Utility Model Publication No. 1995-020117 (published on July 26, 1995) forms a large and small tubular body having a continuous binding part on the upper and lower surfaces except for an arc part on both sides, and has a double space between the two tubes. Although there is a double structure formed by forcibly inserting a heat insulator, it is difficult to bind continuously and is formed by inserting a heat insulator by a double structure, but it is expensive and difficult to apply.

In addition, Utility Model Registration No. 0213249 (Registration of November 30, 2000) allows the construction of wiring lines and telephone lines outside the walls of buildings, making it difficult to use them indoors. It is inconvenient to do, and it is impossible to use for various purposes.

Document 1. Utility Model Notification No. 1979-0001811 (August 29, 1979) Document 2. Publication No. 1995-020117 (published Jul. 26, 1995) Document 3. Utility Model Registration No. 0213249 (Registered on November 30, 2000)

Therefore, the problem of the present invention devised in order to solve the above-mentioned drawbacks, while extruded to have a predetermined width using a synthetic resin (PE, PP, PVC, etc.) while the inner surface is smooth in a shape and the outer surface is predetermined It is supplied spirally while extruding into a shape, and the inner diameter member is prefabricated to form various types of tubes such as square, hexagon, and octagon, and after forming the core layer by resin in the process of discharging the tube, By forming the fiber coating layer is to provide a duct that can be bonded and not separated.

Another problem of the present invention is that by connecting the coupling member at the end while supplying the inner diameter member with a predetermined width, it is possible to form various types of ducts such as square, hexagon, octagon, arch, etc. In addition, the core layer is light and easy to produce and install, and by forming a fiber coating layer on the outer diameter, the workability is excellent and the strength can be greatly improved.

The present invention forms a connection groove between the double fixing projection to the left side of the inner diameter portion and install a locking jaw in the sealing connection portion, and form a reinforcement protrusion at a predetermined interval to the upper side of the inner diameter portion, the double at the right end of the inner diameter portion An inner diameter member which forms a sealing protrusion on the right side of the connecting protrusion formed between the grooves, spirally wound around the winding device, and connects it to any one of a rectangle, a hexagon, and an octagon;

A core layer formed between the primary resin and the secondary resin coated with the outer diameter of the inner diameter member;

It is characterized by consisting of a fiber coating layer spirally wound around the outer diameter of the secondary resin.

The present invention is extruded using a synthetic resin (PE, PP, PVC, etc.) to have a predetermined width while the inner surface is smooth in the shape of the outer and the outer surface is formed with a locking projection and double fixing projections and connecting grooves are supplied spirally double The inner diameter member is continuously assembled by the combination of the groove, the connecting protrusion and the locking groove to form various shapes such as square, hexagon, and octagon, and the core layer is formed by resin in the process of discharging the forming tube. By forming a fiber coating layer on the outer diameter after forming it is possible to form a duct that can be bonded integrally and not separated.

The present invention is capable of forming a variety of ducts by connecting the inner diameter member to a predetermined width while maintaining the watertight by the coupling structure at the end, so that the production of high speed is possible, and the light weight by the core layer It is easy to install, and by forming a fiber coating layer on the outer diameter, the workability is excellent and the strength can be greatly improved, so that it can be used very usefully in the field.

The present invention is capable of continuously producing the duct so that the joint is not formed at regular intervals in the construction site.

1 is a plan view of a production process showing a preferred embodiment of the present invention
Figure 2a is a front view of the cross-sectional state of the inner diameter member of the present invention
Figure 2b is a front view of the engaged state for the inner diameter member of the present invention
Figure 2c is an enlarged front view of the main portion of the engaging portion for the inner diameter member of the present invention
Figure 3a is a cross-sectional view of the core layer formed on the inner diameter member of the present invention
Figure 3b is a cross-sectional view of the fiber coating layer formed on the core layer of the present invention
Figure 4 is a cross-sectional view showing the interior of the duct of the present invention
5 is a perspective view of the winding apparatus of the present invention;
6 is a plan view of another embodiment of a polygonal manhole of the present invention.
7 is a plan view of another embodiment of a polygonal manhole of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a plan view of a production process showing a preferred embodiment of the present invention.

The winding device 11 is installed in front of the extruder 10 for supplying and melting the synthetic resin to extrude the inner diameter member 20 in a predetermined form, and spirally wound the inner diameter member 20 to form a circle, a square, a hexagon, an octagon, and Like this, it is formed into various types of pipes and cut into desired lengths.

Resin in the primary resin supply device 30 in the process of rotating the inner diameter member 20 is formed into a tube (dact) having a polygonal shape such as square, hexagon, octagon, cut to a predetermined length and supplied to a conventional rotating device to rotate This is supplied so that the entire upper surface of the inner diameter portion 21 is coated.

The resin may be supplied in the form of a spray or the method in which the inner diameter member 20 is wound and impregnated in the tank containing the resin is passed.

The core layer 41 is formed from the core supplier 40 on the upper side of the drawing of the inner diameter portion 21 supplied with the primary resin 31 supplied from the primary resin supplier 30.

The outer diameter of the core layer 41 is coated by supplying the secondary resin 51 from the secondary resin supply device 50.

In the outer diameter of the secondary resin 51, the fiber is supplied in one direction from the left-hand fiber winding device 60, and the fibers supplied from the right-hand fiber winding device 70 are wound in opposite directions to each other and the fiber coating layer 110 is formed. Will form.

The outer diameter of the fiber coating layer 110 is formed by coating a protective layer 120, the duct 100 formed of the protective layer 120 will be cooled by the cooling device (80).

Figure 2a is a cross-sectional front view of the inner diameter member of the present invention, Figure 2b is a front view of the coupling state for the inner diameter member of the present invention, Figure 2c shows an enlarged front view of the main portion of the coupling portion for the inner diameter member of the present invention.

The inner diameter member 20 molded by injection molding of synthetic resin has a locking protrusion 22 formed at the left end of the inner diameter portion 21 having a predetermined thickness and width, and to the right of the locking protrusion 22. The double fixing protrusions 23 are installed at regular intervals, and the connection grooves 24 are formed at the center between the double fixing protrusions 23.

A sealing connecting portion 25 is formed on the right side of the double fixing protrusion 23, and a locking jaw 26 is formed on the right side of the sealing connecting portion 25 in a “┒” shape, and at a predetermined interval from the locking jaw 26. As a result, a plurality of reinforcing protrusions 28 having a coupling protrusion 28a formed thereon protrude.

The rightmost side of the reinforcing protrusion 28 is formed with a double groove 23a to which the double fixing protrusion 23 is coupled to the right side on which the engaging groove 22a is formed, and a connection groove 24 between the double grooves 23a. The coupling protrusion 24a to which the coupling is provided is provided, and the central protrusion 29 is formed on the coupling protrusion 24a.

On the right side of the central protrusion 29, a sealing protrusion 25a protrudes and is caught by the locking jaw 26, and a portion of the sealing protrusion 25a is formed with a sealing groove 27 in which the sealing material 27a is located. Watertightness is maintained at the sealing connection 25.

The inner diameter member 20 is spirally supplied to the winding device 11 is coupled at a predetermined interval to each other is wound in the form of a circle or square.

3A is a cross-sectional view of a state in which a core layer is formed on an inner diameter member of the present invention, and FIG. 3B illustrates a cross-sectional view of a state in which a fiber coating layer is formed on a core layer of the present invention.

The inner diameter member 20 is molded into a tube (dact) having a predetermined shape so that the resin is supplied from the primary resin supply device 30 in the process of supplying while rotating so that the entire upper surface of the inner diameter portion 21 is coated. .

The resin may be supplied in the form of a spray or the method in which the inner diameter member 20 is wound and impregnated in the tank containing the resin is passed.

The core layer 41 is formed from the core supplier 40 on the upper side of the drawing of the inner diameter portion 21 supplied with the primary resin 31 supplied from the primary resin supplier 30.

The core layer 41 is preferably supplied with sand, or a mixture of sand and resin (resin) or a mixture of sand and cement.

The outer diameter of the core layer 41 is coated by supplying the secondary resin 51 from the secondary resin supply device 50.

The outer diameter of the secondary resin 51 is supplied with either glass-fiber or carbon-fiber impregnated with the resin (resin) in one direction from the left-hand fiber winding device 60, One side of the left-hand fiber winding device 60 is wound, either glass-fiber or carbon-fiber impregnated in the resin (resin) from the right-hand fiber winding device 70 Is supplied and wound, wherein the fiber or carbon fibers are wound in opposite directions to form the fiber coating layer 110 to form the duct 100.

The outer diameter of the fiber coating layer 110 is formed by coating a protective layer 120, the protective layer 120 is preferably formed of a tape made of vinyl.

Figure 4 is a cross-sectional view showing the interior of the duct of the present invention, the inner diameter member 20 is molded by injection molding, the inner diameter member 20 can be injected and stored to be supplied and molded when necessary After the inner diameter member 20 is injected into a synthetic resin and molded, the core layer 41 including the primary and secondary resins 31 and 51 is formed in the outer diameter, and then the fiber coating layer 110 spirals in the left and right directions. The duct 100 is molded by impregnating and supplying the resin so as to cross each other in the direction.

Figure 5 shows a perspective view of the winding device of the present invention, the winding device 11 is provided with a chain 250 made of a square, the chain 250 is installed inside the rotating rod 260 at a predetermined interval Connected.

The chain 250 is connected to the transfer gear box 210, the hydraulic hose 240 is connected from the outside to receive the hydraulic pressure, in the transfer gear box 210 and the rotating rod 260 of the chain 25 It is connected to be rotated at the same time is connected so as to proceed in one direction by the rotational power to rotate by supplying power to the coupling roller (22).

The coupling roller 22 has a concave-convex shape, such as the outer shape of the inner diameter member 20 is pressed to the inner diameter member 20 to be coupled in a spiral.

One side of the transfer gear box 210 is a supply guide 230 is installed to guide the inner diameter member 20.

Figure 6 shows a plan view of another embodiment of the hexagonal water and sewage pipe of the present invention, the duct 100 forming a polygonal water and sewage pipe can be formed in a square by forming the winding device 11 in a square, but formed in a hexagon By forming the inner diameter member 20 to be wound in a hexagon, it is possible to form a synthetic resin tube into a hexagon.

Figure 7 shows a plan view of another embodiment of the octagonal water and sewage pipe of the present invention, the duct 100 constituting the water and sewage pipe can be formed in a square by forming a winding device 11 in a square, it is formed in an octagon By forming the inner diameter member 20 to be wound in an octagon, it is possible to form a synthetic resin tube in an octagon.

The present invention having such a configuration is to supply and melt the synthetic resin raw material by extruding and cooling the inner diameter member 20 in front of the extruder 10, and then spirally supplied to the winding device 11 or wound around the drum.

When the inner diameter member 20 is supplied to the supply guide 230 in the winding device 11 to guide the spiral, the inner diameter member 20 is supplied to the feed gear box 210 by the hydraulic hose 240. When supplied to the 230 and guided in a spiral, the inner diameter member 20 is pressed by the power supplied to the hydraulic gear 240 to the transfer gear box 210 while supplying the sealing protrusion 25a to be caught by the catching jaw 26. While the sealing groove 27 is positioned at the sealing connection portion 25 by the pressure pressed in, the sealing material 27a formed in the sealing groove 27 is in close contact with the sealing connection portion 25 to maintain the watertight stability.

As the double fixing protrusion 23 is coupled to the double groove 23a formed at the lower side of the central protrusion 29, the connecting protrusion 24a is coupled to the connecting groove 24, and the locking protrusion 22a is provided at the locking protrusion 22a. 22) are spirally coupled at the same time.

Since the inner diameter member 20 is helically supplied and supplied through the supply guide 230, the inner diameter member 20 is coupled by the coupling roller 220, so that the central axis of the transfer gear box 210 is connected to the rotating rod 260. ) Coupled to the transfer gear box 210 is rotated in the clockwise direction, the transfer gear box 210 is generated by the inner diameter member 20 is caught in the supply guide 230 to push forward and gradually move forward Will rotate.

Since the transfer gear box 210 rotates in a clockwise direction and the inner diameter member 20 is coupled, the transfer gear box 210 moves forward, and since the shape of the chain 250 is a quadrangle, the inner diameter member 20 is quadrangular along the shape of the chain 250. ) Are combined to form a continuous tube.

Since the inner diameter member 20 is spirally supplied and the coupling is performed by a continuous coupling structure, since the solid and stable coupling force is achieved at a low height, the double fixing protrusion 23, the double groove 23a, and the connecting groove ( The combination of 24 and the connecting protrusion 24a prevents the loosening phenomenon in the horizontal direction in the drawing, the watertightness is stably maintained by the sealing material 27a, and the sealing protrusion 25a and the locking jaw 26 are prevented. As the seal is made by the bonding force is provided.

Since the inner diameter member 20 wound in a quadrangular shape by the chain 250 may be difficult to maintain a quadrangle, it is possible to install a rectangular frame at regular intervals on an inner diameter at which the inner diameter member 20 is formed into a quadrangle. Do.

According to the shape of the winding device 11 by the spiral coupling of the inner diameter member 20 can be wound in various shapes such as square, hexagon, octagon, etc., the inner diameter member 20 wound by the winding device 11 is In the process of supplying while rotating, the primary resin 31 is sprayed or impregnated from the primary resin supply device 30 to the outer surface of the inner diameter member 20.

The inner resin member 20 coated with the primary resin 31 is supplied with a core or a mixture of sand, a mixture of sand and resin (resin), or a mixture of concrete mixed with sand from the core supply device 40. Form layer 41.

The core layer 41 is preferably formed at the end of the reinforcement protrusion 28 or at the same height as the middle height of the engaging projection 28a.

The secondary resin 51 is sprayed or impregnated from the secondary resin supply device 50 to the outer diameter of the core layer 41.

In the outer diameter coated with the secondary resin 51, the fiber is supplied to the left direction from the left fiber winding device 60 and wound, and the fiber is supplied to the right direction from the right fiber winding device 70 and wound. It is to form a fiber coating layer (110).

The fiber coating layer 110 is a fiber or carbon fiber is impregnated in the resin or resin is supplied in different directions and wound to form the duct 100.

The duct 100 is cooled by the cooling device 80, and then the fiber coating layer 110 to protect the protective layer 120 by coating with a vinyl or the like.

The duct 100 is formed in a rectangular shape when the winding device 11 has a rectangular shape, so that the duct 100 may be molded in various shapes using the winding device 11, and thus manufactured in various shapes according to the spatial shape and range of the building. It can be supplied by.

The core layer 41 and the fiber coating layer 110 is able to provide superiority in strength by the reinforcing protrusions 28 of the inner diameter member 20, the coupling protrusion formed on the reinforcing protrusions 28 ( By 28a), the bonding force between the core layer 41 and the fiber coating layer 110 is greatly improved, so that the mechanical strength can be greatly improved.

The duct 100 may be cut and supplied to a predetermined length and then installed using a connector. If necessary, the duct 100 may be produced and embedded without cutting tens or hundreds of meters when directly produced in the field.

The duct 100 can be used for the purpose of the pipe buried in the ground except when installed in a building, and can be applied to various uses such as a pipe for installing electric wires or cables.

The water and sewage pipe 100 may be formed into a hexagon when the chain 250 is formed by forming a hexagon as shown in FIG. 6, and as shown in FIG. 7, the chain 250 may be formed into an octagon. In this case, since it is possible to form the octagonal water and sewage pipe 100, it is possible to form a polygon, such as a square and a hexagon, an octagon.

The present invention is a synthetic resin layer of the inner diameter is formed by extrusion into a synthetic resin and then assembled by molding while supplying in a spiral shape and the outer is composed of a core layer and a high-strength fiber coating layer is capable of mutual adhesion, excellent mechanical strength, large strength and durability It is possible to provide a product that is easy to use because it is improved and light.

10: extruder 11: winding device
20: inner diameter member 21: inner diameter portion
22: locking projection 22a: locking groove
23: double fixing protrusion 23a: double groove
24: connecting groove 24a: connecting projection
25: sealing connection portion 25a: sealing projection
26: jam jaw 27: sealing groove
27a: locking groove 28: reinforcing protrusion
28a: engaging projection 29: central projection
30: primary resin supply device 31: primary resin
40: core supply device 41: core layer
50: secondary resin supply device 51: secondary resin
60: left direction fiber winder 70: right direction fiber winder
100: duct 110: fiber coating layer
120: protective layer 210: transfer gear box
220: combined roller 230: supply guide
240: hydraulic hose 250: chain
260: rotating rod

Claims (5)

A connecting groove 24 is formed between the double fixing protrusions 23 to the left side of the inner diameter portion 21, and a locking jaw 26 is installed at the sealing connecting portion 25, and a predetermined distance to the upper side of the inner diameter portion 21 is provided. The reinforcing protrusion 28 is formed on the right side of the inner diameter portion 21, and the sealing protrusion 25a is formed on the right side of the connecting protrusion 24a formed between the double grooves 23a at the right end portion of the winding device 11. An inner diameter member 20 wound spirally and connected to any one of a square, a hexagon, and an octagon;
A core layer 41 formed between the primary resin 31 and the secondary resin 41 coated with the outer diameter of the inner diameter member 20;
A duct made of a multi-coating fiber coating layer, characterized in that made of a fiber coating layer 110 to spirally wound around the outer diameter of the secondary resin (41).
The method of claim 1,
The inner diameter member 20 connecting to any one of a quadrangle, a hexagon, and an octagon has a sealing groove 27 formed in the sealing protrusion 25a to further install the sealing material 27a so that the fiber coating layer for the multiple composite structure can be sealed. A doc made up of.
The method of claim 1,
The inner diameter member 20 connecting to any one of a quadrangle, a hexagon, and an octagon has a locking groove 22a formed at the lower side of the double groove 23a and the connecting protrusion 24a, and is formed to the left side of the double fixing protrusion 23. The protrusion 22 is coupled, the duct consisting of a multi-component fiber coating layer, characterized in that the central projection (29) protrudes on the upper side of the double groove (23a).
The method of claim 1,
The fiber coating layer 110 is supplied to the outer diameter of the secondary resin 51 by winding any one of the glass fiber or carbon fiber spirally in different directions in the left and right directions to form a multi-structured fiber, characterized in that A duct consisting of a coating layer.
The method of claim 1,
The inner diameter member 20 connecting to any one of a rectangle, a hexagon, and an octagon has a core layer 41 formed at the center or the end of the reinforcement protrusion 28, and the core layer 41 or the fiber coating layer 110 is a reinforcement protrusion. A duct consisting of a multi-coating fiber coating layer, characterized in that the coupling to be integral with the coupling projection (28a) of (28).

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