KR101247013B1 - Apparatus for splicing composite cable - Google Patents

Abstract

PURPOSE: A connector is provided to simultaneously build a power network and a communication network using a connector which connects optical-power complex cables, to measure and monitor temperature at a cable connection point using an optical cable included in a complex cable and to connect an external communication device or a communication network by branching an optical cable. CONSTITUTION: A neutral line connection unit(410) connects a first neutral line drawn out from a first complex cable and a second neutral line drawn out from a second complex cable(300). A straight line connection unit(420) connects a first conductor drawn out from the first complex cable and a second conductor drawn out from a second complex cable. A second optical connection unit(440) draws out a third and fourth temperature measurement optical cables from the second complex cable. A first connection cable(450) connects the first temperature measurement optical cable and the third temperature measurement optical cable and measuring outdoor air temperature of the first neutral line and the second neutral line connected through the neutral line connection unit. A second connection cable(460) connects the second temperature measurement optical cable and the fourth temperature measurement optical cable and measures outdoor air temperature of the straight line connection unit. A third connection cable(470) connects a first optical communication cable drawn out from the first complex cable and a second communication optical cable drawn out from the second complex cable. An optical signal amplification unit(800) amplifies an optical signal input from the first optical connection unit and outputs the amplified optical signal to the second optical connection unit.

Description

Composite cable attachment {APPARATUS FOR SPLICING COMPOSITE CABLE}

The present invention relates to a composite cable connecting device. More specifically, the present invention relates to a connection device for connecting a composite cable for establishing a power network and a communication network in a distribution system.

Smart Grid is an intelligent grid system that optimizes energy efficiency by exchanging real-time information in both directions by integrating information technology (IT) into the existing grid. Communication networks must be built together.

In the prior art, a communication network was established separately from an existing power network. However, since a power grid such as a distribution system is extensively constructed, there is a problem that it is difficult to establish a communication network associated with the power grid.

The problem to be solved by the present invention is to provide a composite cable connecting device for the connection between the composite cable when simultaneously building a power network and a communication network using the optical-power composite cable.

A composite cable connecting device according to a feature of the present invention includes a neutral wire connecting portion, a straight connecting portion, a first optical connecting portion, a second optical connecting portion, a first connecting cable, and a second connecting cable. The neutral connecting portion connects the first neutral wire drawn out of the first composite cable and the second neutral wire drawn out of the second composite cable. The linear connection portion connects the first conductor drawn out of the first composite cable and the second conductor drawn out of the second composite cable. The first optical connection unit pulls out the first temperature measuring optical cable and the second temperature measuring optical cable from the first composite cable. The second optical connection unit pulls out the third temperature measurement optical cable and the fourth temperature measurement optical cable from the second composite cable. The first connection cable connects the first temperature measuring optical cable and the third temperature measuring optical cable, and measures the outside air temperature of the first neutral wire and the second neutral wire connected through the neutral wire connection part. The second connection cable connects the second temperature measurement optical cable and the fourth temperature measurement optical cable, and measures the outside air temperature of the linear connection portion.

Here, the second connection cable is formed in a structure surrounding the circumference of the linear connection portion.

At this time, the linear connecting portion is formed with a screw-shaped groove on the surface, the second connecting cable is formed along the groove formed in the linear connecting portion.

Here, the first connecting cable is formed adjacent to the first neutral wire and the second neutral wire connected through the neutral wire connection part.

In this case, the first connection cable is formed to be wound around a plurality of structures installed in the first neutral wire, the second neutral wire, or the neutral wire connection part.

Here, the composite cable connecting device further includes a third connection cable connecting the first communication optical cable drawn out of the first composite cable and the second communication optical cable drawn out of the second composite cable.

At this time, the first optical connection unit withdraws the first communication optical cable from the first composite cable, the second optical connection unit withdraws the second communication optical cable from the second composite cable.

Further, the third connecting cable is formed to have a length longer than the shortest distance from the first optical connecting portion provided in the first composite cable to the second optical connecting portion provided in the second composite cable.

In addition, the first optical connecting portion pulls out the first communication optical cable in a direction opposite to the direction in which the second optical connecting portion is located, and the second optical connecting portion pulls out the second communication optical cable in a direction opposite to the direction in which the first optical connecting portion is located.

In this case, the composite cable connection device further includes an optical signal amplifying unit for amplifying the optical signal input from the first optical connecting unit and outputting the amplified optical signal to the second optical connecting unit.

In addition, the third connection cable transmits the amplified optical signal.

At this time, the first optical connection unit branches the first communication optical cable, and connects the branched optical cable to the fourth connection cable.

According to a feature of the invention, it is possible to establish a power network and a communication network at the same time using a connection device that provides a connection between the optical-power composite cable, and to measure the temperature of the cable connection point using the optical cable included in the composite cable It can monitor and branch the optical cable to connect with external communication device or communication network.

1 is a cross-sectional view of a composite cable according to an embodiment of the present invention.
2 is a view showing the structure of a composite cable according to an embodiment of the present invention.
3 is a diagram illustrating a cable connection structure according to a first embodiment of the present invention.
4 is a diagram illustrating a structure of forming a connection cable according to an exemplary embodiment of the present invention.
5 is a view showing the structure of the bracket according to an embodiment of the present invention.
6 is a view showing the structure of a linear connection member according to an embodiment of the present invention.
7 illustrates a structure of an optical connection device according to an embodiment of the present invention.
8 is a front view of a fixing device according to an embodiment of the present invention.
9 is a view showing the side of the fixing device according to an embodiment of the present invention.
10 is a diagram illustrating a cable connection structure according to a second embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Here, the repeated description, the notification function that may unnecessarily obscure the gist of the present invention, and the detailed description of the configuration will be omitted. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

Now, a description will be given of a composite cable connection device according to an embodiment of the present invention with reference to the drawings.

First, a composite cable constituting a distribution system according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

1 is a cross-sectional view of a composite cable according to an embodiment of the present invention.

As shown in FIG. 1, the composite cable 100 is an optical-power composite cable constituting a distribution system, and includes a first stainless steel tube 110 and a second stainless steel tube 120 formed in the neutral layer. Here, the first tube 110 and the second tube 120 contains an optical cable.

2 is a view showing the structure of a composite cable according to an embodiment of the present invention.

As shown in FIG. 2, the first stainless tube 110 includes a first cable 111, a second cable 112, a third cable 113, and a fourth cable 114. Here, the first cable 111, the second cable 112, the third cable 113, and the fourth cable 114 correspond to optical cables.

The first cable 111 is an optical cable for measuring the temperature of the composite cable 100.

The second cable 112, the third cable 113, and the fourth cable 114 are optical cables for constructing an optical communication network for a distribution system.

The second stainless steel tube 120 includes a fifth cable 121, a sixth cable 122, a seventh cable 123, and an eighth cable 124. Here, the fifth cable 121, the sixth cable 122, the seventh cable 123, and the eighth cable 124 correspond to an optical cable.

The fifth cable 121 is an optical cable for measuring the temperature of the composite cable 100.

The sixth cable 122, the seventh cable 123, and the eighth cable 124 are optical cables for constructing an optical communication network for a distribution system.

Next, a connection structure between the composite cables according to the first embodiment of the present invention will be described with reference to FIG. 3.

3 is a diagram illustrating a cable connection structure according to a first embodiment of the present invention.

As shown in FIG. 3, the composite cable connecting device 400 connects the first composite cable 200 and the second composite cable 300, and the neutral wire connecting member 410, the linear connecting member 420, and the first optical fiber. The connection part 430, the second optical connection part 440, the first connection cable 450, the second connection cable 460, and the third connection cable 470 are included. Here, the first optical connecting portion 430 and the second optical connecting portion 440 are connected through the first connecting cable 450, the second connecting cable 460, and the third connecting cable 470 corresponding to the optical cable. .

In this case, the first composite cable 200 includes a first tube 210, a second tube 220, a first neutral wire 230, and a first conductor 240, and the second composite cable 300 includes The third tube 310, the fourth tube 320, the second neutral line 330, and the second conductor 340 are included. Here, the first tube 210, the second tube 220, the third tube 310, and the fourth tube 320 correspond to stainless steel tubes in which optical cables are embedded.

In addition, each of the first tube 210, the second tube 220, the third tube 310, and the fourth tube 320 includes an optical cable for temperature measurement and an optical cable for communication.

The neutral wire connecting member 410 connects the first neutral wire 230 and the second neutral wire 330.

The linear connecting member 420 connects the first conductor 240 and the second conductor 340.

The first optical connector 430 is formed around the first composite cable 200 and is connected to the first tube 210 and the second tube 220 drawn out of the first composite cable 200.

The first optical connector 430 connects the optical cable for temperature measurement included in the first tube 210 to the first connection cable 450, and connects the optical cable for temperature measurement included in the second tube 210 to the second connection. The cable 460 is connected, and a plurality of communication optical cables included in the first tube 210 or the second tube 220 are connected to the third connection cable 470.

The second optical connector 440 is formed around the second composite cable 300 and is connected to the third tube 310 and the fourth tube 320 drawn from the second composite cable 300.

The second optical connector 440 connects the optical cable for temperature measurement included in the third tube 310 to the first connection cable 450, and connects the optical cable for temperature measurement included in the fourth tube 320 to the second connection. The cable 460 is connected, and the plurality of communication optical cables included in the third tube 310 or the fourth tube 320 are connected to the third connection cable 470.

The first connection cable 450 is connected to the first neutral wire 230 and the second neutral wire 330 connected through the neutral wire connecting member 410 to measure the outside temperature of the first neutral wire 230 and the second neutral wire 330. It is formed adjacent to, the first end is connected to the first optical connecting portion 430, the second end is connected to the second optical connecting portion 440 to connect the first optical connecting portion 430 and the second optical connecting portion 440. Connect.

The first connection cable 450 is connected to the temperature measurement optical cable included in the first tube 210 in the first optical connection unit 430, and the third tube 310 in the second optical connection unit 440. It is connected to the optical cable for temperature measurement included in). Through this, the first connection cable 450 connects the optical cable for temperature measurement included in the first tube 210 and the optical cable for temperature measurement included in the third tube 310.

The second connection cable 460 is formed in a structure surrounding the circumference of the linear connection member 420 in order to measure the outside air temperature of the linear connection member 420, and the first end is connected to the first optical connection unit 430. The second end is connected to the second optical connector 440 to connect the first optical connector 430 and the second optical connector 440.

The second connection cable 460 is connected to the temperature measurement optical cable included in the second tube 220 in the first optical connection 430, and the fourth tube 320 in the second optical connection 440. It is connected to the optical cable for temperature measurement included in). Through this, the second connection cable 460 connects the optical cable for temperature measurement included in the second tube 220 and the optical cable for temperature measurement included in the fourth tube 320.

The third connection cable 470 is connected to the plurality of communication optical cables included in the first tube 210 or the second tube 220 in the first optical connection unit 430, the second optical connection unit 440 It is connected to a plurality of communication optical cables included in the third tube 310 or the fourth tube 320 in the interior. Through this, the third connection cable 470 connects the plurality of communication optical cables included in the first composite cable 200 and the plurality of communication optical cables included in the second composite cable 300.

The third connecting cable 470 has a first end connected to the first optical connecting portion 430 in a direction opposite to the linear connecting member 420, and a second end connecting the second optical connecting portion (420) in a direction opposite to the linear connecting member 420. 440 is connected to connect the first optical connector 430 and the second optical connector 440. In this case, since the third connection cable 470 is formed to be stretched down from the linear connection member 420, even if a failure occurs in the linear connection member 420, damage of the communication optical cables may be minimized.

Next, the formation structure of the connection cable of the composite cable connection device according to an embodiment of the present invention with reference to Figures 4 to 6 will be described.

4 is a diagram illustrating a structure of forming a connection cable according to an exemplary embodiment of the present invention.

As shown in FIG. 4, the first connection cable 450 of the composite cable connection device 400 uses the neutral connection member 410 to measure the outside air temperature of the first neutral wire 230 and the second neutral wire 330. It is formed in the vicinity of the first neutral line 230 and the second neutral line 330 connected through.

Since the outside temperature of the first neutral wire 230 or the second neutral wire 330 measured by the first connection cable 450 is different depending on the structure in which the first connection cable 450 is formed, the first connection cable 450 It is formed uniformly through this structure.

The first connection cable 450 may include a first bracket 451 fixed to the first neutral wire 230, a second bracket 452 fixed to the neutral wire connecting member 410, and a first fixed cable fixed to the second neutral wire 330. It is formed in the form wound around 3 brackets 453.

As a result, since the first connection cable 450 is formed in a predetermined shape through the plurality of brackets, the first connection cable 450 may accurately measure the outside air temperature of the first neutral wire 230 or the second neutral wire 330. Can be.

The second connection cable 460 of the composite cable connection device 400 is formed in a structure surrounding the circumference of the linear connection member 420 in order to measure the outside air temperature of the linear connection member 420.

Since the outside air temperature of the linear connecting member 420 measured by the second connecting cable 460 is different depending on the number and method of winding the second connecting cable 460 on the linear connecting member 420, the second connecting cable 460 It is formed along the groove 421 formed in the surface of this linear connection material 420. Here, the groove 421 is formed on the surface of the linear connection member 420 in the form of a screw.

As a result, since the second connection cable 460 is formed in the linear connection member 420 in a predetermined number and manner, the second connection cable 460 can accurately measure the outside air temperature of the linear connection member 420.

5 is a view showing the structure of the bracket according to an embodiment of the present invention.

As shown in FIG. 5, the bracket 500 includes a first structure 510 for fixing the bracket 500 to the first neutral wire 230, the second neutral wire 330, or the neutral wire connecting member 410. And a second structure 520 for installing the first connecting cable 450.

6 is a view showing the structure of a linear connection member according to an embodiment of the present invention.

As shown in FIG. 6, a groove 421 for forming the second connection cable 460 is formed on the surface of the linear connection member 420.

Next, an optical connection device according to an embodiment of the present invention will be described with reference to FIG. 7.

7 illustrates a structure of an optical connection device according to an embodiment of the present invention.

As shown in FIG. 7, the optical connection device 600 corresponds to the first optical connection part 430 and the second optical connection part 440 included in the composite cable connection device 400, and the input part 610 and the connection part. 620, and an output unit 630. Hereinafter, the optical connection device 600 will be described based on the first optical connection unit 430.

The input unit 610 is a plurality of the first tube 210 and the second tube 220 withdrawn from the first composite cable 200 is input, and included in the first tube 210 or the second tube 220 Optical cables are output.

The connection unit 620 receives a plurality of optical cables included in the first tube 210 or the second tube 220 from the input unit 610, and inputs the plurality of input optical cables to the first connection cable 450 and the second connection. The cable 460, the third connection cable 470, or the fourth connection cable 480 are output in correspondence with each other, and the temperature measurement optical cable connection 621, the communication optical cable connection 622, and the optical branch 623 are provided. Include.

The temperature measuring optical cable connection part 621 corresponds to the temperature measuring optical cable included in the first tube 210 to the first connection cable 450, and the optical cable for temperature measurement included in the second tube 220 to the second. It corresponds to the connection cable 460.

The communication optical cable connection unit 622 corresponds to the third connection cable 470 a plurality of communication optical cables included in the first tube 210 or the second tube 220.

The optical branch unit 623 branches one of the plurality of communication optical cables included in the first tube 210 or the second tube 220, and corresponds the branched optical cable to the fourth connection cable 480. Here, the fourth connection cable 480 is connected to another communication device or communication network.

The output unit 630 receives a plurality of optical cables from the connection unit 620, and inputs the plurality of input optical cables to the first connection cable 450, the second connection cable 460, the third connection cable 470, or the first connection cable. 4 Connect to the connection cable (480).

The output unit 630 connects the temperature measurement optical cable included in the first tube 210 among the input optical cables to the first connection cable 450.

The output unit 630 connects the optical cable for temperature measurement included in the second tube 220 among the plurality of input optical cables to the second connection cable 460.

The output unit 630 connects a plurality of communication optical cables included in the first tube 210 or the second tube 220 to the third connection cable 470 among the plurality of input optical cables.

The output unit 630 connects the optical cable branched among the plurality of input optical cables to the fourth connection cable 480.

Next, a fixing device for fixing an optical connection device according to an embodiment of the present invention to a composite cable will be described with reference to FIGS. 8 and 9.

8 is a front view of a fixing device according to an embodiment of the present invention.

As shown in FIG. 8, the fixing device 700 includes a support 710 and a cable fixing 720.

The supporting unit 710 is provided with an optical connection device 600.

The cable fixing part 720 fixes the fixing device 700 to the composite cable 100.

9 is a view showing the side of the fixing device according to an embodiment of the present invention.

As shown in FIG. 9, the supporting part 710 of the fixing device 700 is formed with a groove for fixing the optical connecting device 600, and the optical connecting device 600 is formed in the groove of the supporting part 710. It is formed in a corresponding structure. Through this, the optical connection device 600 can be stably installed in the composite cable through the fixing device 700.

Next, a connection structure between the composite cables according to the second embodiment of the present invention will be described with reference to FIG. 10.

10 is a diagram illustrating a cable connection structure according to a second embodiment of the present invention.

As shown in FIG. 10, the composite cable connection device 400 may further include an optical signal amplifier 800 and a connection cable 810 when amplification of an optical signal is required. Hereinafter, a description will be given focusing on the difference between the composite cable connecting device according to FIG.

The optical signal amplifier 800 is disposed between the first optical connector 430 and the second optical connector 440, and amplifies the optical signal amplified by amplifying the optical signal input from the first optical connector 430. 2 to the optical connection unit 440.

The optical signal amplifier 800 is connected to the first optical connection unit 430 through the connection cable 810 to receive an optical signal from the first optical connection unit 430, and the second through the third connection cable 470. The optical signal amplified by being connected to the optical connector 440 is output to the second optical connector 440.

Through this, it is possible to solve the problem of optical loss in a distribution system having a long communication section and a long branching section.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (12)

A neutral wire connection unit connecting the first neutral wire drawn out of the first composite cable and the second neutral wire drawn out of the second composite cable;
A straight connection connecting the first conductor drawn out of the first composite cable and the second conductor drawn out of the second composite cable;
A first optical connection part for drawing out a first temperature measuring optical cable and a second temperature measuring optical cable from the first composite cable;
A second optical connection part for drawing out a third temperature measurement optical cable and a fourth temperature measurement optical cable from the second composite cable;
A first connection cable connecting the first temperature measuring optical cable and the third temperature measuring optical cable and measuring outside temperature of the first neutral wire and the second neutral wire connected through the neutral wire connection unit;
A second connection cable connecting the second temperature measuring optical cable and the fourth temperature measuring optical cable and measuring the outside air temperature of the linear connection part;
A third connection cable connecting the first communication optical cable drawn out of the first composite cable and the second communication optical cable drawn out of the second composite cable; And
An optical signal amplifying unit for amplifying the optical signal inputted from the first optical connecting unit and outputting the amplified optical signal to the second optical connecting unit,
The third connection cable is formed to have a length longer than the shortest distance from the first optical connection part provided on the first composite cable to the second optical connection part provided on the second composite cable and installed to extend below the linear connection part. To transmit the amplified optical signal,
The first optical connection unit withdraws the first communication optical cable from the first composite cable, the second optical connection unit withdraws the second communication optical cable from the second composite cable,
The first optical connecting portion pulls out the first communication optical cable in a direction opposite to the direction in which the second optical connecting portion is located, and the second optical connecting portion pulls the second communication optical cable in a direction opposite to the direction in which the first optical connecting portion is located. Composite cable connecting device to be drawn out. The method according to claim 1,
The second connection cable is
Composite cable connecting device formed of a structure surrounding the circumference of the straight connection. The method according to claim 2,
The straight connection portion
On the surface a threaded groove is formed,
The second connection cable is
Composite cable connecting device formed along the groove formed in the straight connection portion. The method according to claim 1,
The first connection cable is
And a composite cable connecting device formed adjacent to the first neutral wire and the second neutral wire connected through the neutral wire connection part. The method of claim 4,
The first connection cable is
The composite cable connecting device is formed in the form of winding around a plurality of structures provided in the first neutral wire, the second neutral wire, or the neutral wire connection. delete delete delete delete delete delete The method according to claim 1,
The first optical connecting portion
A composite cable connecting device for branching the first communication optical cable, and connecting the branched optical cable to the fourth connection cable.

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