KR102136097B1 - Pipe for protecting optical cable - Google Patents

Abstract

The present invention relates to an optical cable communication pipe. The optical cable communication pipe is buried underground, is provided to position one or more inner pipes within an outer pipe, has optical cables inserted into the inner pipes, and is provided in a form of a corrugated pipe body by repetitively continuing to form ridge portions and valley portions on the outer circumferential surface of each of the inner pipes and the outer pipe. The optical cable communication pipe has the outer pipe formed to encompass the inner pipes in a manner of inserting the inner pipes thereinto and extracting the inner pipes after extruding the inner pipes such that the outer circumferential surface of the inner pipe and the inner circumferential surface of the outer pipe are made to have a mutual coupling structure and to be integrally provided, wherein the inner pipe includes inner pipe protrusions formed to protrude on external surfaces of the ridge portions and the outer pipe includes outer pipe protrusions formed to protrude on external surfaces of ridge portions. The present invention can increase the ease and convenience of construction on the spot, can efficiently prevent damages which have occurred in various work processes and preparation processes with respect to the inner pipes and the outer pipe of the optical cable communication pipe, and can manufacture and produce the optical cable communication pipe as a high-quality product.

Description

Optical Cable Communication Center{PIPE FOR PROTECTING OPTICAL CABLE}

The present invention relates to an optical cable communication tube in which a double corrugated pipe structure is grafted to protect a plurality of optical cables provided, and more specifically, to improve the coupling between the inner tube and the exterior to improve the problem that the inner tube is pulled in or out. The present invention relates to an optical cable communication tube that can prevent and minimize damage to the inner and outer tubes, reduce raw materials, reduce physical property changes, improve durability, and provide ease of construction, such as installation work and connection work.

In general, optical cables used as communication lines, such as short-distance and wide area networks or subscriber lines, are made of optical fibers made of very thin glass or fiber material cores, and are very vulnerable to impact or impact from the outside. Accordingly, the optical cable is inserted into a dedicated communication tube to prevent damage from external impact and to be safely protected.

Conventional optical cable communication tubes consist of an inner tube of a straight tube structure and an exterior that is a corrugated corrugated tube to protect and protect the inner tube to maintain water resistance and impact resistance, and the joint structure for every predetermined length where a manhole, such as 600 to 800m, is located (Connectors, etc.) are used to connect and connect communication tubes for optical cables to each other.

In addition, since the optical cable communication tube is made of high-density polyethylene (HDPE) or polypropylene as a raw material, it has excellent impact and compressive strength, and its appearance is made of an uneven structure, so it has the advantage of withstanding soil pressure in a buried state. There is a disadvantage that there is a change in length and elongation contraction due to temperature change after the landfill construction.

As shown in Fig. 1, such an optical cable communication tube is composed of an inner tube 10 made of a straight tube structure without wrinkles on an inner circumferential surface or an outer circumferential surface, and an exterior 20 of a corrugated structure surrounding the inner tube 10.

At this time, the inner peripheral surface of the inner tube 10 is made of a silicone coating to reduce the coefficient of friction by allowing the communication line to be smoothly inserted, and the outer peripheral surface of the inner tube 10 is partially fused to the inner peripheral surface of the exterior 20 or By being configured to be adhered, the inner tube 10 and the outer tube 20 may be integrally formed by the local coupling part.

However, the conventional optical cable communication pipe has a disadvantage that the local coupling part easily falls due to the action of bending moment in the bending portion when the bending is performed in a portion where bending is required during the installation work, and the inner tube 10 has an external appearance 20. There is a problem of being pulled inward.

In addition, in the related art, there is a problem in that a part of the inner tube 10, which is provided in a large number during the installation of the optical cable communication tube, protrudes to the exterior 20, so that the length is not uniformly formed as a whole, and in this case, the length of the inner tube 10 is entirely re-fitted There was inconvenience and hassle to perform the work.

In addition, in the related art, there was a problem of increasing the fatigue of the worker due to the disadvantage that it takes a lot of force even when bending and winding a cable drum for use in laying work, and the appearance (20) due to friction and stress between pipes There was a problem in that defects such as scratches on the surface or the appearance burst.

Incidentally, if a defect occurs during installation on the site or during construction, the entire optical cable communication pipe existing in the section of 600 to 800m between the manhole and the manhole is re-constructed.

In addition, conventionally, communication pipes for optical cables are connected to and connected to each other by using a joint structure (connector, etc.) for every predetermined length where a manhole, such as 600 to 800m, is located, but it is inconvenient to easily check the connection state between the optical cable communication pipes during connection work. There is also a repair work is required after the completion of the construction, there was a problem that the inner tube 10 is damaged.

In addition, in the related art, an air sealing bar is installed on a mold when injection molding the inner tube 10 to trap and supply air. Scratch is formed on the inner surface of the inner tube 10 that is injection molded by air supply. There was a problem that back damage occurs.

Furthermore, in the related art, as shown in FIG. 2, the color is displayed using a color pigment to easily distinguish the type according to the use of each inner tube with respect to the inner tube 10 provided on the inner side of the exterior 20. It is manufactured and used as a number of distinct color tubes, and since each inner tube 10 is manufactured in a form having a color over the entire outer periphery of the body, there is a problem in that the amount of color pigment is used excessively, which causes the price of the optical cable communication tube. Not only is this expensive factor, but there is also a problem that causes environmental pollution due to excessive use of color pigments, and it is a method of adding color pigment to the plastic material of the optical cable communication tube, so it causes a change in material properties of the optical cable communication tube itself. It is becoming and overall, it is acting as a factor that shortens durability and life.

Republic of Korea Registered Patent Publication No. 10-1666912 Republic of Korea Registered Patent Publication No. 10-1773978 Republic of Korea Registered Patent Publication No. 10-1166118

The present invention is to solve the above-mentioned conventional problems and to have been devised in consideration of this, a disadvantage that the local coupling part easily falls due to the action of the bending moment during bending according to the laying operation, and thereby the problem that the inner tube is easily drawn into the inside of the exterior. The purpose of the present invention is to provide an optical cable communication tube that can improve the problem of protruding the inner tube and improve the ease of construction and convenience in the field.

The present invention allows to reduce the fatigue of the operator when winding on the cable drum, and to improve the problem of defects such as scratches on the exterior surface or bursting of the exterior due to friction and stress between the tubes, An object of the present invention is to provide an optical cable communication tube that can improve the problem of damage such as scratches formed on the inner surface of the inner tube by the air supply process during extrusion molding of the inner tube.

The present invention allows the usage of color pigments contained in raw materials to be reduced to classify the types according to the use of the inner tube, thereby reducing the environmental pollution factor and reducing the manufacturing cost. The object of the present invention is to provide an optical cable communication tube capable of maintaining strength and durability as well as extending the service life by eliminating physical property changes.

An object of the present invention is to provide an optical cable communication tube that enables easy checking of a fastening state during connection work of an optical cable communication tube, and enables easy implementation during connection work.

The optical cable communication tube according to the present invention for achieving the above object is buried in the ground, and is provided with one or more inner tubes embedded inside the outer surface, an optical cable is inserted into the inner tube, and an outer peripheral surface in each of the inner tube and the outer surface. With respect to the optical cable communication tube provided with a corrugated tube by repeatedly forming the mountain and valley parts, the outer tube is formed by extruding the inner tube and then inserting the inner tube to form an outer tube so as to surround the inner tube. The inner peripheral surface has a structure that is mutually coupled to be provided integrally; The inner tube includes an inner tube protrusion protruding from the outer surface of the mountain portion, and the outer wall includes an outer protrusion protruding from the outer surface of the mountain portion.

Here, the inner tube may be configured to form an outer color coating layer by extruding a color pigment by line extrusion to be coated with a portion of the outer circumferential surface of the inner tube where extrusion molding is performed.

Here, the inner tube is formed with a flat portion having a flat structure having an end portion with respect to the mountain portion, and forming a tip portion with a round portion having a round structure with respect to the valley portion; The external appearance may have a configuration in which the end portion is formed as a round portion having a round structure with respect to the mountain portion, and the end portion is formed as a flat portion having a flat structure with respect to the valley portion.

Here, the inner tube protrusion formed in the inner tube is formed to protrude in a pair structure on the flat side on the mountain side, and is placed on the left and right sides to be spaced apart; The exterior protrusions formed on the exterior may be formed to protrude in a pair structure on the round side on the mountain side, and may be placed on the left and right sides to have a configuration arranged at intervals.

Here, the outer color coating layer formed on the inner tube can be configured so that the type of inner tube can be easily matched and inserted by easily sorting the types of the inner tube by arranging the inner tube to face each other when a plurality of inner tubes are arranged in the exterior.

Here, the inner tube may be configured to prevent damage to the inner tube side by extrusion molding using a vacuum sizing method using a vacuum suction.

Here, it is possible to have a configuration that is provided with a transparent connector to assemble and use the transparent connector so as to be able to easily check the fastening state of each other when connecting the optical cable communication tube.

According to the present invention, due to the action of the bending moment during bending according to the installation work, the local coupling part easily falls, and thereby the inner tube is easily pulled into the inside of the exterior, or on the contrary, the problem that the inner tube protrudes to the exterior can be improved. , It can effectively prevent the damage that occurred in various work process and preparation process for the inner tube and the exterior of the optical cable communication tube side, and can achieve usefulness to improve the ease and convenience of construction in the field.

According to the present invention, it is possible to reduce the fatigue of an operator when winding by winding the cable communication tube around the cable drum for use in laying work, and scratching or bursting of the exterior may occur due to friction and stress between the exteriors. It is possible to improve the problem that the defect occurs, and to improve the method during extrusion molding of the inner tube, it is possible to achieve the usefulness of improving the problem of damage such as scratches on the inner surface.

According to the present invention, the amount of color pigment contained in the raw material can be greatly reduced to classify the types according to the use of the inner tube, thereby reducing the environmental pollution factor and reducing the manufacturing cost as well as the material for the communication side. It is possible to eliminate the change in properties caused by the factor, and maintain the strength and durability, as well as achieve usefulness to extend the service life.

According to the present invention, it is possible to easily check the fastening state by assembling and using the transparent connector during the connection work of the optical cable communication tube, and it is possible to achieve the usefulness to realize the ease in the connection work.

1 is a block diagram showing a conventional general optical cable communication tube.
FIG. 2 is a product picture showing a conventional optical cable communication tube, and is a picture showing a configuration in which a color tube is applied to the inner tube.
Figure 3 is a perspective view showing an optical cable communication tube according to an embodiment of the present invention, a view showing the configuration including the appearance of a straight corrugated tube body.
Figure 4 is a perspective view showing an optical cable communication tube according to an embodiment of the present invention, a view showing the configuration including the appearance of a spiral corrugated tube.
5 and 6 are front cross-sectional views showing an optical cable communication tube according to an embodiment of the present invention.
7 is a side cross-sectional view showing an optical cable communication tube according to an embodiment of the present invention.
8 is a view including a connector shown to explain the connection assembly of the optical cable communication tube according to an embodiment of the present invention.

When describing a preferred embodiment with reference to the accompanying drawings for the present invention is as follows, through the detailed description will be able to better understand the object and configuration of the present invention and features accordingly.

The optical cable communication tube 1 according to the embodiment of the present invention is made of an integral structure including the inner tube 100 and the outer tube 200 as shown in FIGS. 3 to 8.

The optical cable communication tube 1 is buried in the ground, and is provided with one or more inner tubes 100 embedded inside the exterior 200.

The inner tube 100 is arranged in a plurality of two or more in one exterior 200, an optical cable is inserted into the inner tube 100.

The inner tube 100 and the outer tube 200 are provided with a corrugated tube by repeatedly forming the mountain parts 110 and 210 and the valley parts 120 and 220 with respect to the outer circumferential surface, respectively.

At this time, the inner tube 100 is manufactured by extrusion molding using an extrusion molding apparatus having an extrusion die, and after extruding the inner pipe 100, inserting the inner pipe 100 to perform extrusion molding again. The exterior 200 is formed to surround the inner tube 100.

By extruding by the insert method in this way, a portion of the outer circumferential surface of the inner tube 100 and the inner circumferential surface of the exterior 200 have a structure that is mutually coupled by fusion bonding, and is integrally provided.

That is, in the present invention, by using an insert method for the inner tube 100 and the outer tube 200, the inner tube 100 is built-in and coupled to the inner side of the outer tube 200 to manufacture the optical cable communication tube 1 integrally provided. In addition, it is possible to have an integral configuration in which the inner tube 100 and the outer tube 200 are stably combined.

Through this, when the laying or winding or bending process using the optical cable communication pipe (1). It is possible to eliminate the phenomenon that a part of the inner tube 100 which is provided in large numbers is drawn into the interior of the exterior 200 or vice versa, and it is inconvenient to additionally perform the work of adjusting the length due to the imbalance of the conventional length. And it is possible to escape the hassle, it is possible to provide advantages that can be easily installed, as well as to reduce the construction time.

In addition, in the prior art, when winding the optical cable communication pipe 1 to the cable drum or bending it at the bent portion during installation, it is possible to improve the disadvantages that the operator takes a lot of force and increases fatigue due to the action of the bending moment. It is possible to provide an advantage that can improve the disadvantages of the appearance 200 is blown defects and the problems of re-construction caused thereby.

The inner tube 100 is preferably formed with a flat portion having a flat structure with an end portion with respect to the mountain portion 110, and a tip portion with a round structure having a round structure with respect to the valley portion 120.

The exterior 200 is preferably formed with a round portion having a rounded structure with respect to the peak portion 210 and a flat portion having a flat structure with respect to the valley 220.

Here, the inner tube 100 and the outer tube 200 have a flat portion structure with respect to the surfaces adjacent to each other in each of the hills and valleys of the inner tube 100 and the outer tube 200, thereby supporting and durability of each other. It can provide an advantage to increase the.

In particular, the inner tube 100 is provided to have a configuration in which the inner tube projection 130 is protruded on the outer surface of the mountain portion 110, that is, on the flat portion.

The inner tube protrusion 130 is formed to protrude in a pair structure on the flat portion on the side of the mountain portion 110, and is preferably disposed at left and right sides to be spaced apart.

However, the inner tube protrusion 130 is an example of a preferred type of a pair structure, and is not particularly limited thereto, and one or three protruding structures may be possible.

Here, the inner tube projection 130 is a configuration in which the inner tube 100 is inserted into the outer tube 200 in close contact with the valleys 220 of the outer wall 200 during extrusion molding, and the outer wall 200 side bonding property is improved. It plays a role of acting while providing elasticity. Through this, the inner tube 100 absorbs the stress applied between the inner tube and the stress acting between the inner tube and the outer surface, and of course, it can exhibit an elastic supporting function. 200) can provide advantages of protecting and preventing damage.

Here, the inner tube projection 130 is not having a surface contact with the exterior 200, but has a bonding force by point contact, and is flexible when winding or winding an optical cable communication tube 1 on a cable drum during laying work. It is possible to provide the ease of bending due to the provision, which can improve the disadvantages and increased fatigue, which require a lot of force on the operator's side, and serves to fix the inner tube 100 to the exterior 200, so that the movement of the conventional inner tube 100 is performed. It is possible to provide an advantage to prevent the appearance 200 from popping due to the frictional force.

In particular, the exterior 200 is provided to have a configuration in which the exterior protrusion 230 is protruded on the outer surface of the mountain portion 210, that is, the round portion.

The external protrusions 230 are formed to protrude in a pair structure on the round portion on the side of the mountain portion 210, and are preferably placed on the left and right sides to be spaced apart.

However, the inner tube protrusion 130 is an example of a preferred type of a pair structure, and is not particularly limited thereto, and one or three protruding structures may be possible.

Here, the exterior protrusion 230 is pulled out of the cable drum for land burial during installation in the field and dragged to the ground, and prevents the surface from directly contacting the exterior of the exterior 200. Since an open space is provided between the ground, frictional forces with the ground can be minimized, and an advantage of preventing damage to the surface of the exterior 200 may be provided.

In addition, the exterior protrusion 230 is wound between the cable drum or unwound or reversed, and is used between the exterior 200 and exterior 200 when used for laying, providing a clearance gap and elasticity. To prevent damage to the surface of the exterior 200 by exerting it, it is possible to absorb the stress acting between the exteriors when winding or unwinding the exterior 200 on the cable drum and to minimize the friction coefficient, thereby preventing surface damage of the exterior 200. It can provide advantages that can be prevented.

In addition, when the inner tube 100 is provided by extrusion molding, it is preferable to extrude the vacuum sealing method using a vacuum suction to escape the method of supplying air by installing an air sealing bar for exerting the cooling function. Do.

That is, by grafting such a vacuum sizing method, it is possible to provide an advantage of preventing damage such as scratches generated on the inner surface side during extrusion molding of the conventional inner tube 100.

Furthermore, it is preferable that the inner tube 100 has a configuration to form the outer color coating layer 140 by subjecting the color pigment to line extrusion to coat a portion of the outer circumferential surface of the inner tube where extrusion molding is performed.

That is, by attaching a color pigment by mounting a line extrusion having a flow path on the extruding die, a local outer color coating layer 140 can be continuously formed in a line on a portion of the outer peripheral surface of the inner tube 100.

Through the configuration of the outer color coating layer 140, the color pigment can be greatly reduced and used to about one tenth or less compared to the prior art, so that the amount of use can be greatly reduced, and through this, the material of the optical cable communication tube 1 side is reduced. Not only can the physical properties change be eliminated, it can also reduce environmental pollution and provide the advantage of lowering the production cost.

At this time, since the material property change of the optical cable communication pipe 1 side can be eliminated through the outer color coating layer 140 formed locally on a portion of the inner tube 100, it is possible to maintain durability such as rigidity for a long time. In comparison, it can provide an advantage of extending the service life.

Here, the outer color coating layer 140 formed on the inner tube 100 is arranged to form a structure that faces each other when multiple inner tubes 100 are arranged in the outer surface 200, thereby easily classifying the types of inner tubes to separate the optical cables. Matching can be inserted.

That is, as shown, it is possible to have more discriminating power by arranging the outer color coating layer 140 to be densely located in the center.

On the other hand, in the present invention, it is possible to have a configuration in which a transparent connector 300 is provided and assembled to be used in order to easily check the fastening state between the optical cable communication tubes 1 having the above-described configuration.

At this time, it is preferable that the transparent connector 300 is made of polycarbonate (PC) or polyethylene terephthalate (PET) among transparent materials in order to maintain rigidity due to underground landfill.

Accordingly, through the optical cable communication pipe 1 according to the present invention having the above-described configuration, it is possible to improve the ease of construction and convenience in the field, which is conducted by underground buried work, and various work processes for the inner tube and the exterior of the optical cable communication pipe side. And it is possible to effectively prevent the damage that occurred during the preparation process, it can provide the advantage of manufacturing and manufacturing an optical cable communication tube with a high-quality product.

The embodiments described above are merely for explaining preferred embodiments of the present invention, and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the technical spirit and claims of the present invention. It will be said that this can be made, which will fall within the technical scope of the invention.

1: Optical cable communication tube 100: Inner tube
110: pregnant part 120: bone
130: inner tube projection 140: outer color coating layer
200: appearance 210: mountain
220: bone 230: protrusion
300: transparent connector

Claims (7)

As buried in the ground, at least one inner tube is provided inside the exterior, and an optical cable is inserted into the inner tube, and repeatedly provided with a corrugated tube by continuously forming an acid and a valley on the outer circumferential surface in each of the inner tube and the exterior. In the optical cable communication tube,
After extruding the inner tube, the inner tube is inserted and extruded to form an outer surface to surround the inner tube, so that the outer circumferential surface of the inner tube and the inner circumferential surface of the outer tube are mutually coupled;
The inner tube includes an inner tube protrusion formed to protrude on the outer surface of the mountain portion, and the outer surface includes an outer protrusion formed to protrude on the outer surface of the mountain portion;
The inner tube protrusion formed in the inner tube is formed to protrude in a pair structure on the flat side on the mountain side, and is placed on the left and right sides to be spaced apart;
The appearance protrusion formed on the exterior is formed to protrude in a pair structure on the round side of the mountain side, and is positioned on the left and right sides to be spaced apart. According to claim 1,
The inner tube,
When extruding, an optical cable communication tube characterized in that the color pigment is line-extruded to form an outer color coating layer by processing to be coated with a portion of the outer circumferential surface of the inner tube where extrusion molding is performed. According to claim 1,
The inner tube,
Forming an end portion with a flat portion having a planar structure with respect to the hill portion, and forming an end portion with a round portion having a round structure with respect to the valley portion;
The appearance,
An optical cable communication tube, characterized in that the end portion is formed as a round portion having a round structure with respect to the mountain portion, and the end portion is formed as a flat portion having a flat structure with respect to the valley portion. delete According to claim 2,
The outer color coating layer formed on the inner tube,
Optical cable communication tube, characterized in that by arranging the inner tube to form a structure facing each other when a plurality of inner tubes are arranged in the exterior, the type of the inner tube can be easily classified and configured to be matched and inserted. According to claim 1,
The inner tube,
Optical cable communication tube characterized in that it is configured to prevent damage to the inner tube side by extrusion molding by a vacuum sizing method using a vacuum suction (suction). According to claim 1,
An optical cable communication tube characterized by having a transparent connector and assembling and using the transparent connection port so that the connection state between the optical cable communication tubes can be easily confirmed.

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