KR20010005334A - A Multi-Channeled Pipe for Cables and a Method and an Apparatus therefor - Google Patents

Abstract

PURPOSE: An apparatus for making a porous pipe for a communication line is provided to reduce an overall cost by making a porous pipe so as to include a plurality of small-sized pipes. CONSTITUTION: An apparatus for making a porous pipe for a communication line comprises a leading-in unit(100) in which a plurality of small-sized pipes tied are inserted. A melt resin supplying unit(200) is located at an outer part of the leading-in unit(100), and supplies melt plastics to an outer surface of the tied small-sized pipes. An external pipe shaping unit(300) is located at a next stage of the melt resin supplying unit(200), and shapes the covered melt resin so as to have a shape of an external pipe. A cooling unit(400) is disposed at a nest stage of the external pipe shaping unit(300), and cools the shaped external pipe. A drawing unit is disposed at a nest stage of the cooling unit, and draws the united small-sized pipes as a porous pipe which is inserted in the external pipe(10).

Description

A multi-channeled pipe for cables and a method and an apparatus therefor}

The present invention relates to a perforated pipe for communication lines, a method for manufacturing the same, and a manufacturing apparatus thereof, which is embedded in the ground and used to protect a communication line, such as a telephone line or an optical cable, that requires an independent occupied space. .

Communication lines such as telephone lines and optical cables are usually buried underground. In this case, hollow tubes for communication lines are used. The hollow pipe for the communication line serves as a protective film to protect the communication line from underground soil and water.

Figure 1 illustrates a hollow tube (1) that is made to be hollow inside. The embedding work of the communication line in which the hollow tube 1 for the communication line is embedded is carried out in the following order.

First, a hollow tube embedding step of embedding a large diameter hollow tube in the ground is performed between the working manhole and the manhole. Next, a guide tube insertion process of inserting small diameter guide tubes 2 for a communication line into the inside of the hollow tube 1 is performed inside the manhole where the open ends of the hollow tubes are exposed. Next, a process of inserting a communication line inserting the communication line 3 into the inside of the guide lines 2 for the communication line is performed.

In the conventional construction of the communication line which proceeds with the above processes, the guide tubes of small diameter are twisted along the length of each other in contact with each other in the inside of the large diameter hollow tube during the insertion process of the guide tube. The guide tubes can no longer be inserted even if the inside of the tube is not sufficiently filled.

That is, the conventional hollow tube for the communication line has a defect that can not sufficiently insert the guide tubes into the inner space.

On the other hand, in recent years, as shown in Figs. 2A and 2B, a plurality of small pipes 4a are manufactured to be distributed so as to be integrally connected to each other as a connecting strip 4b. The strip-shaped guide tube 4 is rolled into a bundle-like shape and inserted into the hollow tube 1. This strip-shaped guide tube 4 is inserted into the inside of the hollow tube 1 with the small tubes maintained at a constant interval as the connecting strip 4b, so that the small tubes 4a inside the hollow tube 1 The distance is kept constant without being twisted along its length. Therefore, the strip-shaped guide tube 4 has an effect of making the most effective internal effective area of the hollow tube 1.

However, it was inevitable that this strip-shaped guide tube 4 also had to be separately inserted into the guide tube after the hollow tube embedding process was completed. In the past, if a plurality of guide tubes are inserted into the hollow tube during the manufacturing process, there is no need to perform the guide tube insertion process separately at the construction site, thereby reducing the overall construction cost. .

For this reason, attempts have been made to integrally extrude a porous tube having a shape in which several guide tubes are integrally inserted into one hollow tube with a synthetic resin. However, these conventional attempts have not been practically possible.

The reason is that the buried pipe buried in the ground should be strong enough to withstand loads such as earth pressure and water pressure so that the thickness of the buried pipe should be relatively thick and guided for the insertion of the communication line inserted inside the guides. The inner diameter of the tube should be constant. In order to mold a porous tube having a relatively large thickness and outer diameter and containing a plurality of guide tubes in one extrusion process, it is practical to cool the inside of the porous tube properly. It was because it became a difficult task.

The purpose of the present invention is to manufacture a number of small pipes in the interior of one hollow tube during the manufacturing process to reduce the overall construction cost by reducing the labor required to perform the guide tube insertion process at the construction site The present invention provides a porous pipe for a communication line, a manufacturing method thereof, and a manufacturing apparatus thereof.

1 is an exemplary view showing a conventional communication line laying method

Figure 2a, Figure 2b is an exemplary view showing a conventional band-shaped guide tube

3 is an exemplary view showing a manufacturing apparatus of a porous pipe for a communication line according to the present invention.

Figure 4 is a schematic diagram showing a method for manufacturing a porous tube using the manufacturing apparatus for the present invention communication line

5a to 5f show embodiments of the multiple small tube according to the present invention

6a to 6f show embodiments of the porous tube according to the present invention.

7 and 8 are exemplary views showing another embodiment of the manufacturing apparatus of the porous pipe for communication line of the present invention.

<Explanation of symbols for main parts of drawing>

10; Outer tube 20; Small tube 30; Bundle

40; Perforated tube 100; Feeding means 200; supply means

300; Molding means 400; Cooling means 500; Withdrawal means

600; Cutting means

Hereinafter, the technical configuration of the present invention in detail.

3 shows an apparatus for manufacturing a porous tube used to manufacture a porous tube for a communication line of the present invention.

The apparatus for manufacturing a porous pipe for communication lines according to the present invention includes a plurality of small pipes, which are bundled into a predetermined bundle and are inserted into the plurality of small pipe entry means 100 and the outside of the pull means of the bundle small pipe. A molten resin supply means (200) which is located at and supplies molten synthetic resin to the outer circumferential surface of the bundle-shaped tubes, and a molten resin which is positioned next to the melt-feeding means and covered by the outer circumferential surface of the bundle-shaped tubes A shaping means 300 of the outer tube to be shaped into a shape; a cooling means 400 arranged next to the shaping means of the outer tube to cool the outer tube shaped into a predetermined shape; And a plurality of small tubes which are integrally bound within the outer tube 10 are composed of the drawing means 500 of the porous tube for drawing out a finished one of the porous tube 40.

The manufacturing method of the porous tube using the manufacturing apparatus of the present invention configured as described above is as follows.

First, at the inlet of the inlet means 100 of the bundle small tube bundles several small tubes 20 into a bundle to form a bundle small tube 30 to draw into the inside of the means for the introduction of the bundle small tube Perform the drawing process of. The specific way to bundle small tubes is described in detail below.

Next, the molten resin is supplied to the outer circumferential surface of the bundle-shaped tube 30 through the supply means 200 of the molten resin, and a molten resin is supplied to surround the outer circumferential surface of the bundle-shaped tube with molten resin.

Next, a molding process of molding the molten resin wrapped around the outer circumferential surface of the bundle-shaped small tubes by the forming means 300 of the outer tube into an outer tube having a predetermined shape is performed. Specific forming method of the outer tube will be described in detail below.

Next, a cooling process of cooling the outer tube formed into a predetermined shape to complete the outer tube 10 and the plurality of small tubes disposed therein into one porous tube 40 is performed.

Next, a plurality of small pipes 20 which are integrally bound inside the outer pipe 10 are subjected to the withdrawal process of the porous pipe to pull out the completed one single porous pipe 40.

As described above, the present invention covers the outer tube 10 by covering a new molten resin on the outer circumferential surface of the bundle-shaped tube 40, which is formed by tying a plurality of small tubes 20, which have been molded and cooled in advance, into bundles. ) Is manufactured through the manufacturing process of integrally molding the melt, the cooling of the molten resin is relatively easy, it is possible to produce a porous tube realistically without difficulty.

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

5A to 5F illustrate specific methods in which the small pipes 20 are bundled to form one bundle pipe 30 at the inlet of the inlet 100 of the bundle pipe.

FIG. 5A illustrates a circular bundle tube 31 in which a plurality of circular small tube 21 independently produced and supplied to each other is bundled in the form of a bundle in front of the introduction means 100 of the bundled small tube.

FIG. 5B illustrates a square bundle tube 32 in which a plurality of square tube tubes 22 independently produced and supplied to each other are bundled in the form of a bundle in front of the introduction means 100 of the bundle tube.

5C is a band-shaped bundle-shaped tube in which a band-shaped guide tube in which the small tubes 20 are integrally connected to each other as a connecting strip 23 is formed in a bundle in front of the inlet means 100 of the bundle-shaped tube ( 33) is illustrated.

FIG. 5D illustrates the protrusion-shaped bundle-shaped tube 34 having a form in which the protrusions 24 are integrally formed on the outer surface of the small tubes 20 when the band-shaped guide tube 33 is bundled into a bundle shape.

FIG. 5E illustrates an angular tubular tubular tube 35 in which angular tubular tubular tubes manufactured to have a rectangular cross section such as a pentagon or a hexagon and whose inner surface are manufactured to have a circular cross section.

Bundle small tube (30) It is noted that may be made in various shapes in addition to the shape illustrated above.

6A to 6F illustrate various shapes of the porous tube 40 of the present invention, which includes an outer tube 10 and a bundle-shaped tube 30 disposed therein.

In FIG. 6A, an outer tube 10 having a quadrangular cross-sectional shape and a square rectangular porous tube 40 in which square small tubes 22 having a quadrangular cross section are disposed therein are illustrated.

In FIG. 6B, an outer tube 10 having a quadrangular cross-sectional shape and a circular circular porous tube 40 having a circular circular tube 21 having a circular cross section therein are illustrated.

In FIG. 6C, an outer tube 10 having a circular cross section and a hexagonal circular hole porous tube 40 having hexagonal outer tubes and circular inner surfaces 25 are disposed therein. Is illustrated.

In FIG. 6D, an outer tube 10 having a circular cross-sectional shape and a circular rectangular hole porous tube 40 in which pentagonal small tubes 26 having a pentagonal cross section are disposed therein are illustrated. 6E illustrates an outer tube 10 having a circular cross-sectional shape and a circular inner circumferential perforated tube 40 disposed on the inner circumferential surface thereof with each other in contact with each other and not disposed at the center thereof.

In Fig. 6F, not only the outer tube 10 having a circular cross-sectional shape, but also the inner circumferential surface thereof, as well as the circular overlapping porous tube 40, which are overlapped at the center, are illustrated.

In the porous tube of the present invention, the outer tube 10 is generally shaped to have a cross-sectional shape of a smooth outer tube as its outer circumferential surface as described above, but if necessary, the outer tube as shown below It may have the shape of a corrugated outer tube in which wrinkles are formed.

Hereinafter, the technical configuration of the apparatus for manufacturing a porous tube of the present invention and its operation state will be described in detail.

The inlet means 100 of the bundle-shaped pipe is composed of a circular or rectangular tubular body 110 and a flange 120 which is integrally fixed to the front surface of the tubular body portion, and the bundle-shaped tube (inside one side of the inlet of the tubular body) The inner rod 130 for pushing the small tubes 20 of the 30 to the outer tube 10 may be fixed.

The inner rod 130 is installed to extend to the forming means 300 of the outer tube, as shown in Figure 3, and serves to push the small tube 20 to the outer tube 10 side by the small tube 20 They are in close contact with the inner surface of the outer tube (10).

The cross-sectional shape of the tubular body 110 in the drawing means 100 of the bundle-shaped tube is manufactured to have a cross-sectional shape of a circular or square pipe according to the cross-sectional shape of the outer tube 10.

The supply means of the molten resin 200 is a resin supply pipe that is fixed to the inlet means 100 so that the resin space portion 210 which is a passage through which the molten resin is supplied is formed between the outer surface of the tubular body 110. (220), resin melting means (220b) connected to the resin supply hole (220a) drilled in the resin supply pipe 220 to supply the molten resin to the resin space 210, and the tubular body (110) It is composed of a gap adjusting ring 230 is connected to the distal end of the resin supply pipe 220 to adjust the gap with.

The supply means of the melted resin configured as described above passes through the resin space portion 210 in which the resin supplied from the resin melting means 220a is formed by the resin supply pipe 220 and the gap adjusting ring 230 and the tubular body 110. While supplying the molten resin to the forming means 300 of the outer tube according to the shape of the outer tube (10).

The forming means 300 of the outer tube, as shown in Figure 3, has the shape of the forming tube 310 is set in accordance with the shape of the outer tube 10, the position required as the inner surface of the forming tube 310 The inner hole 310a which is drilled every time, the integrated passage 320 which communicates with the inner hole 310a and integrates into one, and communicates with one side of the integrated passage to suck air to form the inside of the molded tube 310. It consists of a vacuum means 330 to allow the molten resin passing through the adsorbed toward the forming tube (310).

The forming means 300 of the outer tube configured as described above serves to absorb the molten resin supplied into the forming tube 310 toward the inner surface of the forming tube 310 so that the shape of the molten resin is formed according to the shape of the tubular tube. Do this.

The shaping means 300 of such an outer tube may have various embodiments in which specific technical configurations are distinguished according to the shape of the outer tube to be molded, but three types will be described as representative herein.

The first is a type of smooth outer tube forming means, the second is a type of spiral wave shaped outer tube forming means, and the third is a type of ring wave shaped outer tube forming means.

The shaping means of the smooth outer tube has a shape of a molded tube 310 which is set according to the shape of the outer tube 10 as shown in FIG. 7, and is drilled into the inner surface of the molded tube 310 at every necessary position. The inner surface hole 310a, the integrated passage 320 which communicates with the inner surface holes 310a and is integrated with each other, and communicates with one side of the integrated passage, sucks air and passes through the inside of the molded tube 310. In the configuration of the vacuum means 330 to allow the molten resin to be adsorbed toward the molded tube 310, the molded tube 310 has an inner surface of the smooth tube.

The shaping means of the spiral wave-shaped outer tube has a shape of a molded tube 310 set according to the shape of the outer tube 10 as shown in FIG. 7, and at every position necessary for the inner surface of the molded tube 310. Inner holes 310a to be drilled, an integrated passage 320 which communicates with the inner holes 310a and integrates into one, and communicates with one side of the integrated passage to suck air into the interior of the molded tube 310. In the configuration of the vacuum means 330 for allowing the molten resin to be adsorbed toward the forming tube 310, the forming tube 310 has an inner surface of the spiral wave and at one side of the forming tube 310 Orthogonally rotating means 340 for rotating the molded body in the direction perpendicular to the traveling direction is further included.

As shown in Fig. 8, the shaping means of the ring-shaped outer tube has a shape of a molded tube 310 which is set according to the shape of the outer tube 10, and for each position necessary for the inner surface of the molded tube 310. Inner holes 310a to be drilled, an integrated passage 320 which communicates with the inner holes 310a and integrates into one, and communicates with one side of the integrated passage to suck air into the interior of the molded tube 310. In the configuration of the vacuum means 330 for allowing the molten resin to be adsorbed toward the forming tube 310, the forming tube 310 is formed of a catapillar type surrounding the molten resin, the caterpillar shaped tube Rotating means (not shown) for rotating in the advancing direction.

Here, the smooth outer tube may be manufactured regardless of the circular or rectangular cross-sectional shape as a whole, but it is noted that the spiral or ring-shaped external tube is manufactured only in the circular cross-sectional shape.

The cooling means 400 and the withdrawal means 500 of the porous tube are technical means that are commonly known in the field of the molding apparatus of the synthetic resin tube, and thus a detailed description thereof will be omitted.

4 illustrates that the cutting means 600 is further included to cut the porous tube 40 completed through the withdrawal means 500 to an appropriate length. However, the cutting means 600 is also a synthetic resin tube. Since it is a general technical means used in the molding apparatus, specific description is omitted.

As described above, the present invention enables a plurality of guide tubes therein to realistically produce a porous tube included in one hollow tube, so as to make the best use of the internal effective area of the hollow tube. In addition, the insertion process of the guide tube does not need to be carried out separately, so it is very useful to greatly reduce the overall construction cost.

Claims (10)

A plurality of small pipes are bundled into a predetermined bundle and inserted into the bundle small inlet means 100 and the molten synthetic resin is placed on the outer circumferential surface of the bundle small pipes outside the inlet means of the bundle small pipes. Forming means 300 of the outer tube for forming a molten resin in the form of an outer tube and the supply means for supplying a molten resin (200) for supplying the molten resin which is located next to the supply means of the molten resin is covered on the outer peripheral surface of the bundle pipe And cooling means (400) arranged next to the forming means of the outer tube to cool the outer tube shaped into a predetermined shape, and arranged integrally inside the outer tube (10) after the cooling means. Apparatus for manufacturing a porous tube, characterized in that consisting of a plurality of small withdrawal means 500 of the porous tube for withdrawing the finished one of the porous tube (40). According to claim 1, wherein the forming means 300 of the outer tube has a shape of the forming tube 310 is set in accordance with the shape of the outer tube 10, the position required as the inner surface of the forming tube 310 The inner hole 310a which is drilled every time, the integrated passage 320 which communicates with the inner hole 310a and integrates into one, and communicates with one side of the integrated passage to suck air to form the inside of the molded tube 310. Apparatus for producing a porous tube, characterized in that consisting of a vacuum means (330) for allowing the molten resin passing through the adsorbed toward the forming tube (310). The apparatus for manufacturing a porous tube according to claim 2, wherein the forming means of the outer tube has a shape of a smooth tube in an inner surface of the forming tube body (310). According to claim 2, wherein the forming means of the outer tube, the forming tube 310 has an inner surface of the spiral wave and at one side of the forming tube 310 to rotate the forming tube in a direction perpendicular to the traveling direction. Orthogonal rotation means 340 is an apparatus for manufacturing a porous tube, characterized in that it further comprises. The method of claim 2, wherein the forming means of the outer tube is formed of a caterpillar shape of the molded tube body 310 surrounds the molten resin, characterized in that it comprises a rotating means for rotating the caterpillar shaped tube body in the advancing direction Apparatus for manufacturing porous pipes. A plurality of small pipes 20 are bundled into a bundle to form a bundle small tube 30 so that the bundle small tube 20 is introduced into the inside of the inlet means of the bundle tube, and the outer peripheral surface of the bundle small tube 30. Supplying molten resin to the outer peripheral surface of the bundle-shaped tube to surround the molten resin, and supplying the molten resin wrapped around the outer peripheral surface of the small-size tube to form the outer tube 10 having a predetermined shape Forming the porous tube through a molding process and a cooling process of cooling the outer tube formed into a predetermined shape to complete the outer tube 10 and the plurality of small tubes disposed therein into one porous tube 40. Method for producing a porous tube characterized in that. Perforated pipe, characterized in that the plurality of small pipes 20 through the manufacturing method of claim 6 are manufactured to be integrally included in one of the outer tube (10). 8. The porous tube according to claim 7, wherein the outer tube has a shape of a smooth tube. 8. The porous tube according to claim 7, wherein the outer tube has a shape of a spiral wave tube. 8. The porous tube according to claim 7, wherein the outer tube has a shape of a ring wave tube.