KR20030075398A - composite cable for data transmission and power source supply - Google Patents

Abstract

PURPOSE: A complex cable for transmitting data and supplying power is provided to increase the amount of data transmission by forming a plurality of optical transmission members including a plurality of optical fibers within a cable. CONSTITUTION: A complex cable for transmitting data and supplying power includes a central tensile line(21), a power supply layer(22), an optical transmission portion(24), a waterproof member layer(25), and an external coating member layer(26). The central tensile line(21) is formed in a center of the complex cable. The power supply layer(22) is formed by twisting a conductive line(23a), a plurality of power supply portions(23), and the optical transmission portion(24). The waterproof member layer(25) is used for covering an outer surface of the power supply layer(22). The external coating member layer(26) is used for covering an outer surface of the waterproof member layer(25).

Description

Composite cable for data transmission and power source supply

The present invention relates to a composite cable for data transmission and power supply, to be used in a fiber-to-the curb (FTTC) system, to form a central tension line in the center, a plurality of power supply means A waterproof member surrounding the outer surface of the central tensile line and including a light transmission means to be twisted and twisted together with the power supply means in a twisted and twisted power supply means layer, the waterproof member surrounding the outer surface of the power supply means layer The outer layer of the waterproof member layer and the outer surface of the waterproof member layer is formed to form the outermost outer member layer, the optical fiber can be multi-cored to increase the data transmission amount, improve the branching of the optical fiber construction and repair work The present invention relates to a composite cable for data transmission and power supply that can double the ease of use.

Recently, as data processing devices including computers are widely used, communication systems and communication methods for communication and data transmission have been developed in homes and companies.

In particular, in order to spread the broadband integrated information network to the home recently, instead of the current telephone subscriber line, which is a twisted pair copper wire, each fiber is separately installed in the telephone, fax, data and TV. Fiber-to-the home (FTTH), a subscriber network that can transmit images as a single line of optical fiber, was developed and tested.

However, because FTTH connects optical fiber to each home individually, there is a problem in economics, such as the optical network unit (ONU), which is an optical network termination unit, and there is a problem in economics, and the fiber to the office (FTTO) and the fiber to the curve ( After the FTTC stage, it finally develops into a fiber to the groove (FTTH).

Here, the term 'curb' of the FTTC means the curb of the road, which installs a small box like the curb on the road in front of the house, and lays a copper wire from there to four houses, for example. Sharing the fiber in four homes can make it more economical than FTTH, and shorter copper distances can also transmit broadband signals.

That is, FIG. 1 is a schematic diagram of an FTTC optical cable network, in which an FTTC connection point 1 and an optical network unit (ONU) 3 are connected through a composite cable 2, and this optical network unit 3 Is connected to a network termination (NT) (5) via a termination cable (4). In this case, the termination cable 4 is a coaxial cable or a twisted pair copper wire which is a general telephone subscriber wire. Therefore, it is connected to the personal computer 7, the television 8, etc. in the network terminator 5 installed in each home 6.

As such, FTTC installs fiber optic cables to roads near homes or businesses to replace ordinary telephone services, allowing them to economically deliver vast amounts of information faster than conventional telephone line coaxial cables. As it grows in need, there is an increasing interest.

In such an FTTC optical fiber network, the optical fiber is connected to an optical network unit (ONU) 3 located in a dense residential area, which is a service interface to end users. As an end device of an optical communication network that provides an optical fiber, an optical signal and an electrical signal are switched between each other in an FTTC (fiber to the curb), an FTTB (fiber to the building), an FTTF (fiber to the floor), and an FTTO (fiber to the office). It is a device that connects cables and optical facilities that transmit analog signals of end users.

By the way, it is necessary to supply power for the control and operation of the optical communication network unit (ONU) (3), and for this purpose, an optical fiber, which is an optical signal transmission means for transmitting data, and a copper wire, which is a power supply means for supplying power, are integrated. If a composite cable composed of an in cable is used, a separate power supply line is not required for supplying power to the optical communication network unit (ONU) 3 so that the network can be efficiently configured and convenient for system management.

That is, Figure 2 is a cross-sectional view for explaining the configuration of a conventional composite cable for data transmission and power supply, the composite cable 10 includes an optical fiber (11a) and a filler (11b) and the outer sheath that surrounds the outside It consists of a tube body (11c) formed to be located in the center of the cable and the optical transmission means 11, a conductor wire which is a copper wire and a covering surrounding it, and is twisted to have a twist to surround the outer surface of the optical transmission means (11) A plurality of power supply means 12, a waterproof member 13 formed to surround the outer surface of the power supply means 12, and formed to surround the outer surface of the waterproof means 13 It consists of a tension line member 14 and the outer shell member 15 formed on the outermost side while surrounding the outer surface of the tension line member 14.

Here, the example of the conventional composite cable of FIG. 2 is to form the power supply means 12 and the waterproof member 13 in a multi-layer, but it is formed in two layers. That is, the first layer power supply means 12a formed to surround the outer surface of the optical transmission means 11 positioned at the center core, and the first layer power supply means 12a formed to surround the outer surface of the first power supply means 12a. Two-layer power supply means (12b) formed to surround the outer surface of the first-layer waterproof means (13a) to the outside of the layer waterproof means (13a), and the outer surface of the two-layer power supply means (12b) It was formed to further include a two-layer waterproof means (13b) formed to surround the.

However, in the conventional composite cable, only one optical transmission means is formed at the center, so that the maximum number of optical fibers that can be mounted is limited. For the branching operation of the optical fiber, the power supply means formed outside the optical transmission means is unwound. You can access the optical fiber.

As such, the limited number of optical fibers may not be able to cope with the increase in the amount of transmission, which may occur when the existing composite cable needs to be removed and a new composite cable may be installed for the expansion of the optical fiber. In other words, the number of optical fibers is not sufficiently included.

In addition, in order to work in the middle of the branch has to dismantle the power supply means copper wire has a problem that the work is inconvenient and takes a lot of time.

In particular, since the penetration rate of the optical fiber is 0, there is a problem that the optical fiber length required for the intermediate branching operation is not secured.

Accordingly, an object of the present invention, in order to solve the problems of the prior art as described above, by including a plurality of optical transmission means on the outer side rather than located in the center of the composite cable, increasing the data transmission capacity to increase the data transmission It can flexibly cope with the capacity, it can shorten the working time to facilitate the branching work can be improved and the work efficiency can be improved, and also to reduce the outer diameter of the cable by strengthening the mechanical strength.

1 is a schematic diagram of an FTTC optical cable network.

2 is a cross-sectional view for explaining the configuration of a conventional composite cable for data transmission and power supply.

3 is a cross-sectional view for explaining the configuration of a composite cable for data transmission and power supply according to a first embodiment of the present invention.

4 is a cross-sectional view illustrating a configuration of a composite cable for data transmission and power supply according to a second embodiment of the present invention.

5 is a cross-sectional view for explaining a configuration of a composite cable for data transmission and power supply according to a third embodiment of the present invention.

-Explanation of symbols for the main parts of the drawings-

A, B, C: Fiber Optic Cable 20: Fiber Optic Core

22: internal waterproof material 24: optical fiber bundle tube

28: waterproof tape 30: aluminum metal body

32: outer layer 34: outer tension line

36: steel tape 38: double skin layer

The present invention is to construct a composite cable for data transmission and power supply in order to achieve the above object, a plurality of power supply formed of a center tensile wire formed in the center of the cable, a conductor wire which is a copper wire and a sheath surrounding the cable A power supply means layer twisted and twisted around the outer surface of the center tension line, and an optical transmission means included in the power supply means layer to be twisted and twisted together with the power supply means, and the power supply Data transmission and power supply means characterized in that it comprises a waterproof member layer formed to surround the outer surface of the means layer and an outer skin member layer formed on the outermost side while covering the outer surface of the waterproof member layer. Provides composite cable for

At this time, the optical transmission means is preferably formed of a tube body which includes an optical fiber and a filler and surrounds the outside thereof.

In addition, it is preferable that the power supply means layer is formed in multiple layers, and a waterproof member layer is formed between each power supply means layer.

In addition, it is preferable that the optical transmission means is included only in the outermost power supply means layer among the power supply means layers formed in multiple layers.

Then, the power supply means and the optical transmission means included in the power supply means layer is preferably stranded by SZ twist.

In addition, it is preferable that the center tensile wire is a metal wire or a fiber reinforced plastic (FRP), which is a steel wire or a galvanized steel wire.

Preferably, the power supply means has an outer diameter of 0.3 mm or more and 2.0 mm or less, and the coating is preferably a resin material including polyethylene, polypropylene, and PVC.

The filler included in the optical transmission means is preferably a jelly compound or a waterproof filler.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, by this, the scope of the present invention is not defined, but is presented as an example.

3 is a cross-sectional view for explaining the configuration of a composite cable for data transmission and power supply according to a first embodiment of the present invention. As shown in FIG. 3, the composite cable 20 for data transmission and power supply according to the present invention includes a center tensile wire 21 formed at the center, a conductor wire 23a which is a copper wire, and a sheath surrounding the same ( A plurality of power supply means 23 formed of 23b) is included in the power supply means layer 22 and the power supply means layer 22 which are twisted and twisted while enclosing the outer surface of the central tension line 21. And a light transmission means 24 formed to be twisted and twisted together with the power supply means 23, a waterproof member layer 25 formed to surround the outer surface of the power supply means layer 22, and the waterproof It consists of the outer skin member layer 26 formed in the outermost side, surrounding the outer surface of the member layer 25. As shown in FIG.

That is, although the conventional optical transmission means is located at the center, in the present invention, the optical transmission means 26 is twisted and twisted together with the power supply means 23 in the power supply means layer 22 to form a center tensile line 21. Will be wrapped.

Therefore, by positioning the optical transmission means 24 to surround the central tension line 21 with the power supply means 23 without placing the optical transmission means 24 in the center of the composite cable, it is possible to include a plurality of optical transmission means 24 as well. If the outer skin member layer 26 and the waterproof member layer 25 are peeled off from the outside, the light transmission means 24 can be immediately reached, thereby facilitating the work during the branching operation and reducing the time. In particular, since the optical transmission means 24 are twisted and connected with a certain twist, it is more convenient because the optical transmission means 24 can be properly drawn out and utilized during the branching operation.

In this case, a coating layer 21a is formed on the outer surface of the central tension line 21 to protect the power supply means 23 and the light transmission means 24 from the effects of physical friction with the central tension line 21.

The optical transmission means 24 is composed of a tube body 24c which includes an optical fiber 24a and a filler 24b, and is an envelope covering the outside thereof.

Here, the optical fiber 24a is configured to include at least one core. That is, the number of cores can be increased as needed. In addition, the fillers 24b included in the optical transmission means 24 are all made to prevent the penetration of moisture to be made of a jelly compound or a waterproof filler.

The tube body 24c is formed by extruding a mixture of PBT (Polybytylene Terephtalate), Polypropylene, Polyethylene, and the like.

In addition, the center tensile wire 21 is formed by selecting from a metal wire (Fiber Reinforced Plastic) (FRP) or a wire or galvanized steel wire.

The twist of the power supply means 23 and the optical transmission means 24 described above is made of SZ twist.

In addition, the power supply means 23 preferably uses an outer diameter of 0.3 mm or more and 2.0 mm or less. In addition, the cover 23b of the power supply means 23 is formed by selecting from a resin material including polyethylene, polypropylene or PVC.

4 is a cross-sectional view illustrating a configuration of a composite cable for data transmission and power supply according to a second embodiment of the present invention.

In this second embodiment, the power supply means layer is formed in multiple layers, and a waterproof member layer is formed between each power supply means layer.

Therefore, the composite cable 20 for data transmission and power supply has a plurality of power supply means 23 formed of a central tension line 21 formed at the center, a conductor wire 23a which is a copper wire, and a sheath 23b surrounding the copper wire. ) Is included in the power supply means layer 22 and the power supply means layer 22 that is twisted and twisted while enclosing the outer surface of the center tensile line 21, and twists together with the power supply means 23. And a light transmission means 24 formed to be stranded and having a waterproof member layer 25 formed to surround the outer surface of the power supply means layer 22, and the outer surface of the waterproof member layer 25. Consists of the outermost member layer 26 formed on the outermost side, the power supply means layer 22 is formed in a multi-layer, and the waterproof member layer 25 is formed between each of the power supply means layer 22. .

In FIG. 4, the power supply means layer 22 is formed in two layers. However, it can also be formed by multiple layers of three or more layers.

Detailed description of the same reference numerals and portions as those in Embodiment 1 of the present invention will be omitted.

Meanwhile, the optical transmission means 24 is included only in the outermost power supply means layer 22a among the power supply means layers 22 formed in a multilayer.

That is, it is not necessary to include the optical transmission means 24 in each power supply means layer 22, but rather, if the optical transmission means 24 are included in each power supply means layer 22, In order to reach the optical transmission means 24, all the outer power supply means 22 must be dismantled, which is inconvenient. Further, even if the optical transmission means 24 is included only in the outermost power supply means layer 22, the optical transmission means 24 can be included in a large number, so that the transmission capacity is not short. In other words, where a large amount of transmission is required, the composite cable 20 designed to include a plurality of optical transmission means 24 may be provided.

5 is a cross-sectional view for explaining a configuration of a composite cable for data transmission and power supply according to a third embodiment of the present invention.

Here, a plurality of optical transmission means 24 are included, and the optical transmission means 24 are arranged side by side, not stranded, and are separated from each other so that the power supply means 23 are arranged on both sides of the optical transmission means 24. It is shown.

That is, the composite cable 20 for data transmission and power supply has a plurality of power supply means 23 formed of a central tension line 21 formed at the center, a conductor wire 23a which is a copper wire, and a sheath 23b surrounding the copper wire. ) Is included in the power supply means layer 22 and the power supply means layer 22 that is twisted and twisted while enclosing the outer surface of the center tensile line 21, and twists together with the power supply means 23. A plurality of light transmission means 24 formed so as to be twisted and connected, a waterproof member layer 25 formed to surround the outer surface of the power supply means layer 22, and an outer surface of the waterproof member layer 25. The outer cover member layer 26 is formed on the outermost side while being wrapped, and the plurality of optical transmission means 24 included in the power supply means layer 22 are arranged apart from each other.

Detailed description of the same reference numerals and portions as those in Embodiment 1 of the present invention will be omitted.

This is because when the optical transmission means 24 are arranged together, when the external impact is applied to the sheath of the composite cable 20 where the optical transmission means 24 are gathered, the mechanical strength is slightly weaker than that of the power supply means 23. Although it may affect (24), if the power supply means 23 is arranged on both sides of the optical transmission means 24, it is possible to minimize the external physical impact on the optical transmission means 24, and the like.

Therefore, the mechanical stress can be minimized, so that a tube having a small outer diameter can be used, so that the outer diameter of the composite cable can be reduced accordingly.

As seen above, the present invention can diversify the optical fiber. That is, in the related art, since only one optical transmission means is included, the maximum number of optical fibers that can be mounted is limited. However, in the present invention, since the optical transmission means may include a large number of optical transmission means, the optical fibers in the optical transmission means are also included. Since it includes much more than the conventional composite cable has the advantage that it is possible to transmit a large amount of optical signal to increase the data transmission capacity. Therefore, it is possible to flexibly cope with the increase in the data transmission amount of users.

In addition, there is an advantage that the intermediate branch operation is convenient. In order to perform the intermediate branching operation in the conventional composite cable, it is necessary to disassemble the waterproof member layer and the shell member layer to access the optical transmission means located at the center, and to unwind all power supply means connected to the outer layer. However, in the present invention, since the optical transmission means is located at the outside instead of the center of the composite cable, the optical transmission means can be directly accessed by dismantling only the waterproof member layer and the skin member layer, thereby reducing the work time and making it easier to work. There is an advantage that can be improved.

In particular, the optical transmission means are twisted and twisted in the form of SZ.

There is an advantage that can secure the position.

In addition, the mechanical strength of the composite cable is improved. There is a possibility that the optical transmission means is subjected to mechanical stress by the copper wire when the copper transmission wire is placed around the optical transmission means with the optical transmission means in the center and the power supply means around. However, since the optical transmission means in the present invention is stranded by SZ twisted side by side between the copper wire and the copper wire in the same layer, the mechanical stress can be minimized, so that the outer diameter of the optical transmission means can be reduced, and thus, the outer diameter of the composite cable There is an advantage to being able to shrink.

Claims (8)

In the composite cable for data transmission and power supply, A center tensile line formed at the center of the cable, A power supply means layer in which a plurality of power supply means formed of a conductor wire, which is a copper wire, and a sheath surrounding the same, is twisted and twisted while enclosing an outer surface of the center tensile wire; An optical transmission means included in the power supply means layer so as to be twisted and twisted together with the power supply means; A waterproof member layer formed to surround the outer surface of the power supply means layer; Composite cable for data transmission and power supply means characterized in that it consists of an outer shell member layer formed on the outermost side surrounding the outer surface of the waterproof member layer. The method of claim 1, The optical transmission means is a composite cable for data transmission and power supply means, characterized in that formed of a tube body including an optical fiber and a filler and surrounding the outside thereof. The method of claim 1, The power supply means layer is formed in a multi-layer, the composite cable for data transmission and power supply means, characterized in that forming a waterproof member layer between each power supply means layer. The method of claim 3, wherein The composite cable for data transmission and power supply means, characterized in that the optical transmission means is included only in the outermost power supply means layer of the power supply means layer formed in a multi-layer. The method according to any one of claims 1, 3 or 4, The power supply means and the optical transmission means included in the power supply means layer is a composite cable for data transmission and power supply means, characterized in that the twisted twisted wire SZ. The method of claim 1, The central tensile wire is a metal wire or a fiber reinforced plastic (FRP), which is a steel wire or galvanized steel wire (FRP) composite cable for data transmission and power supply means. The method of claim 1, The power supply means has an outer diameter of 0.3mm or more and 2.0mm or less, the cover is a composite cable for data transmission and power supply means, characterized in that the resin material containing Polyethylene, Polypropylene and PVC. The method according to claim 1 or 2, Filler included in the optical transmission means is a composite compound for data transmission and power supply means, characterized in that the jelly compound or waterproof filler.