KR102480195B1 - Leakage Coaxial Cable And Feeding System Thereof - Google Patents

Abstract

The present invention is a leaky coaxial cable capable of implementing MIMO (Multi Input Multi Output) to enable 4th generation or higher mobile communication capable of transmitting large amounts of data using the leaky coaxial cable when laying a leaky coaxial cable in a place such as a tunnel. This is for a two-end power supply system.

Description

Leakage coaxial cable and feeding system at both ends of leaky coaxial cable using the same {Leakage Coaxial Cable And Feeding System Thereof}

The present invention relates to a leaky coaxial cable and a power supply system at both ends of a leaky coaxial cable using the same. In more detail, the present invention can implement MIMO (Multi Input Multi Output) to enable 4th generation or higher mobile communication capable of transmitting large amounts of data using the leaky coaxial cable when laying a leaky coaxial cable in a place such as a tunnel. It is about a leaky coaxial cable and a power supply system at both ends of the leaky coaxial cable.

Recently, with the spread of mobile devices and the increase in capacity of data communication, the amount of data transmission in communication networks is explosively increasing at an annual average speed of more than twice, and smooth provision of mobile communication services is required anywhere.

For example, in a space such as a tunnel, since the radio signal of an external base station antenna is not transmitted to the inside of the tunnel, mobile communication service cannot be used when using the tunnel by foot, car, train, or subway. Therefore, a mobile communication antenna is separately installed inside the tunnel, etc., so that users can use the mobile communication service without any inconvenience.

However, in the case of an antenna installed inside a tunnel, a number of shadow areas in which wireless signals are not transmitted may occur depending on the path inside the tunnel, the length of the tunnel, and the shape of the tunnel.

In particular, when a disaster such as an earthquake occurs in a place such as a tunnel, since the antenna inside the tunnel can be easily damaged, communication using the antenna is not smooth in the case of a disaster. That is, the above-mentioned antenna system is not suitable for emergency communication equipment for tunnels.

Therefore, conventionally, a leaky coaxial cable (LCX, Leaky Coaxial Cable) is installed in a tunnel or the like, and is used as a disaster communication means in case of a disaster. That is, a mobile communication service is provided by installing a mobile communication antenna inside the tunnel, and when communication with the antenna is difficult in a disaster situation, disaster communication is performed using a leaky coaxial cable.

However, the above configuration requires installation of an antenna system for mobile communication service, a disaster communication system, and an AM/FM radio communication system in a place such as a tunnel. A lot of time and money may be consumed in the installation and equipment operation.

Therefore, in the case of installing the leaky coaxial cable in the above-mentioned tunnel, etc., mobile communication service and AM/FM radio communication service are provided using the leaky coaxial cable in normal times, and disaster communication is provided in case of disaster. How to use it is required.

In order to enable mobile communication using the leaky coaxial cable, for example, 4th generation or higher mobile communication capable of transmitting large amounts of data, it is necessary to implement MIMO (Multi Input Multi Output). To this end, a system capable of supplying power to both ends of the leaky coaxial cable is required.

9 shows an example of a system for feeding both ends of a leaky coaxial cable 950 installed in a tunnel or the like.

As shown in FIG. 9, when a leaky coaxial cable 950 is laid along a place such as a tunnel, mobile communication equipment 900 such as a repeater and a remote radio unit (RRU) and the leaky coaxial cable ( 950) requires a first feeding cable 910 connecting one end and a second feeding cable 930 connecting the other end of the leaky coaxial cable 950.

In this case, one end of the leaky coaxial cable 950 adjacent to the mobile communication equipment 900 can be easily connected using a relatively short first power supply cable 910 . However, in order to connect the other end of the leaky coaxial cable 950 far from the mobile communication device 900 by the second power feeding cable 930, a length longer than the length of the leaky coaxial cable 950 is required. The second power feeding cable 930 having to be laid separately.

Therefore, in the case of the above system, since the second power supply cable 930 needs to be laid separately, enormous costs, manpower, and time are required, resulting in various realistic and economical limitations.

The present invention is a leaky coaxial cable capable of implementing MIMO (Multi Input Multi Output) to enable 4th generation or higher mobile communication capable of transmitting large amounts of data using the leaky coaxial cable when laying a leaky coaxial cable in a place such as a tunnel. And to provide a power supply system at both ends of the leaky coaxial cable as a problem to be solved.

In order to solve the above problems, the present invention is a leaky coaxial cable provided with an electrical signal unit through which electrical signals are transmitted and an optical unit through which optical signals are transmitted; a first power supply unit connecting a mobile communication device and one end of the leaky coaxial cable to transmit an electric signal to one end of the electrical signal unit; and a second power supply unit connecting the mobile communication device and the other end of the leaky coaxial cable to transmit an electrical signal to the other end of the electrical signal unit, wherein both ends of the leaky coaxial cable are connected to the mobile communication device. It is possible to provide a power supply system at both ends of a leaky coaxial cable that supplies power.

In addition, it may be connected to the other end of the leaky coaxial cable through one end of the leaky coaxial cable to which the first power supply unit is connected.

In this case, the second power supply unit is connected to one end of the leaky coaxial cable, converts the electrical signal into an optical signal, transmits the optical signal through the optical unit of the leaky coaxial cable, and receives the optical signal through the optical unit. A pair of photoelectric conversion modules converting the optical signal into an electrical signal and transmitting the electrical signal to the other end of the electrical signal unit may be provided.

The photoelectric conversion module connects the mobile communication device and one end of the leaky coaxial cable, and converts an electrical signal received from the mobile communication device into an optical signal and transmits the optical signal through the optical unit. and a second photoelectric conversion module connected to the other end of the leaky coaxial cable to convert the optical signal received through the optical unit into an electrical signal and transmit the electrical signal to the other end of the electrical signal unit.

Here, the leaky coaxial cable includes an inner conductor, an insulator surrounding the inner conductor, and an outer conductor provided to surround the insulator and having slots of a predetermined pattern formed in one direction to radiate electromagnetic waves in the one direction. An electric signal unit, a sheath surrounding the outer conductor, and a notch provided in the sheath in a direction opposite to the slot along the longitudinal direction of the leaky coaxial cable, and the optical unit is provided among the inner conductor, the sheath, and the notch At least one location may be installed along the longitudinal direction of the leaky coaxial cable.

Also, when the light unit is installed in the inner conductor, the light unit may be located in the hollow of the central part of the inner conductor.

In this case, when the optical unit is installed in the sheath or the notch, the optical unit may be extruded together with the sheath or the notch.

Also, when the light unit is installed in the sheath, the thickness of the sheath may be twice or more than the diameter of the light unit.

Here, the leaky coaxial cable is provided on one side of the sheath and further includes a support line in which a plurality of metal wires are twisted therein along the longitudinal direction of the leaky coaxial cable, and the optical unit is a central portion of the metal wire of the support line can be located in

In addition, in order to solve the above problems, the present invention can provide a leaky coaxial cable applied to the above-described power supply system at both ends of the leaky coaxial cable.

According to the leaky coaxial cable and the power supply system at both ends of the leaky coaxial cable according to the present invention, when the leaky coaxial cable is installed to provide mobile communication, disaster communication and AM / FM radio service in places such as tunnels, a separate power supply cable It is possible to supply power to both ends of the leaky coaxial cable without installing a 4th generation or higher mobile communication service capable of transmitting large amounts of data using the leaky coaxial cable.

In addition, according to the leaky coaxial cable and the power supply system at both ends of the leaky coaxial cable according to the present invention, by providing a mobile communication service, user inconvenience can be reduced by minimizing a shadow area where wireless signals are not transmitted in a tunnel or the like.

1 is a schematic diagram showing a state in which a leaky coaxial cable is disposed inside a tunnel in a power supply system at both ends of a leaky coaxial cable according to an embodiment of the present invention.
2 is a view showing the internal configuration of the leaky coaxial cable according to an embodiment of the present invention;
FIG. 3 is a cross-sectional view showing the configuration of the light unit in FIG. 2 .
Figure 4 shows a schematic diagram showing the configuration of a power supply system at both ends of a leaky coaxial cable according to an embodiment of the present invention.
FIG. 5 is a block diagram showing a configuration according to an example of a photoelectric conversion module in the power supply system at both ends of the leaky coaxial cable shown in FIG. 4 .
6 to 8 show views showing the internal configuration of a leaky coaxial cable according to another embodiment of the present invention.
9 is a view showing a power supply system at both ends using a leaky coaxial cable according to the prior art.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete, and the spirit of the invention will be sufficiently conveyed to those skilled in the art. Like reference numbers indicate like elements throughout the specification.

1 is a state in which the leaky coaxial cable 100 is installed inside the tunnel 10 through which the vehicle 12 or the like passes in the power supply system 1000 at both ends of the leaky coaxial cable (see FIG. 4) according to an embodiment of the present invention. It is a drawing showing

Referring to FIG. 1 , the leaky coaxial cable 100 may be installed on a sidewall of the tunnel 10 or the like. In the drawings, the leaky coaxial cable 100 is shown as being installed on the sidewall of the tunnel 10, but is not limited thereto, and the leaky coaxial cable 100 can also be installed in an area such as the ceiling of the tunnel 10. .

In this case, the leaky coaxial cable 100 may be formed to extend along the tunnel 10 . Specifically, the leaky coaxial cable 100 is supported by the clamp 14 installed on the inner wall of the tunnel 10 .

Therefore, when a telecommunications user moves by using the vehicle 12, walking, subway, train, etc. using the tunnel 10, the 4th generation can transmit large amounts of data using the leaky coaxial cable 100. The above mobile communication and AM/FM communication can be used. In addition, when a disaster such as an earthquake occurs in the tunnel 10, the leaky coaxial cable 100 can be used for disaster communication. Referring to the following drawings, a power supply system at both ends of the leaky coaxial cable will be described.

First, the internal configuration of the leaky coaxial cable 100 will be described with reference to FIGS. 2 and 3, and then the power supply system 1000 at both ends of the leaky coaxial cable according to the present invention will be described.

2 is a view showing the internal configuration of the leaky coaxial cable 100 in the power supply system 1000 at both ends of the leaky coaxial cable according to the present invention, and FIG. 3 is an optical unit 180 included in the leaky coaxial cable 100 4 is a schematic diagram showing the configuration of the power supply system 1000 at both ends of the leaky coaxial cable. In FIG. 2, (a) of FIG. 2 is a perspective view showing the internal configuration of the leaky coaxial cable 100, and (b) of FIG. 2 is a cross-sectional view.

2 and 3, the leaky coaxial cable 100 includes an electrical signal unit 190 and a sheath 150 through which electrical signals are transmitted. At this time, the electrical signal unit 190 is composed of an inner conductor 110, an insulator 120, and an outer conductor 130 sequentially from the center of the leaky coaxial cable 100.

The leaky coaxial cable 100 can radiate electromagnetic waves to the outside or transmit electromagnetic waves to the inside through a plurality of slots 140 formed in the outer conductor 130 in the length direction of the cable, and the slots formed in the outer conductor 130 The use frequency and electromagnetic wave leakage mode can be adjusted by adjusting the shape, size, or spacing (slot period) of 140.

Meanwhile, the inner conductor 110 may be made of a conductive metal material and may be of a bar or hollow (tube) type. In this case, the inner conductor 110 may be formed in a hollow type having a hollow inside, as shown in (b) of FIG. 2, or may be formed in a solid bar type (not shown). As the metal material, for example, copper wire, annealed wire, annealed copper wire, copper-clad steel wire, tin-plated annealed-copper wire, silver-plated wire, or copper-clad aluminum may be used, but it is not particularly limited as long as it has conductivity. In addition, the inner conductor 110 may function as a transmission path for electromagnetic wave energy transmitted and received through the slot 140 .

In addition, the insulator 120 is a low-loss dielectric surrounding the inner conductor 110, insulates between the inner conductor 110 and the outer conductor 130 and reduces electromagnetic wave energy loss. It is molded with high foam. For reference, the insulator 120 may be formed of a material such as HDPE (high density polyethylene) or LDPE (low density polyethylene), but the degree of foaming is shown. It may be used as long as it can satisfy requirements such as flame retardant performance, dielectric strength or insulation resistance.

The external conductor 130 may be formed around the insulator 120 described above. The external conductor 130 may be formed of a conductive metal material such as copper or aluminum. In addition, the external conductor 130 functions as a shield layer for shielding electromagnetic waves, and may be connected to a separate ground line for grounding.

In this case, one or more slots 140 having a predetermined pattern are formed in the outer conductor 130 so that electromagnetic waves generated by electric signals flowing along the inner conductor 110 can be leaked to the outside or radiated to the inside. . At this time, the leaky coaxial cable 100 operates in a coupling mode or a radiation mode according to the relative relationship between the wavelength and the slot 140 spacing. When the electromagnetic wave is radiated, the electromagnetic wave is radiated in one direction in which the slot 140 is formed in the external conductor 130 .

The shape of the slot 140 shown in FIG. 2 is an example, and the slot 140 may have various shapes according to attenuation and coupling loss characteristics in consideration of a main frequency used in a wireless communication service. In addition, the arrangement direction of the slots may be changed to 90 degrees or 180 degrees according to the place where the leaky coaxial cable 100 is laid (for example, a tunnel wall, a central pillar, etc.).

Meanwhile, the sheath 150 is coated around the external conductor 130 by extrusion molding to prevent corrosion and damage of the external conductor 130 . It is preferable to use a flexible resin for the sheath 150 . In addition, a plastic tape (not shown) may be reinforced between a portion of the external conductor 130 where the slot 140 is formed and the sheath 150 in contact with each other.

Meanwhile, as described above, the leaky coaxial cable 100 radiates electromagnetic waves toward one direction in which the slot 140 is formed. At this time, when the leaky coaxial cable 100 is installed inside the tunnel 10 as shown in FIG. 1, the direction in which the slot 140 is formed faces the inside of the tunnel 10. It should be. This is because electromagnetic waves emitted from the leaky coaxial cable 100 must be arranged to face a terminal (not shown) of a user moving along the inside of the tunnel 10 so that wireless communication is possible.

However, since the outer conductor 130 in which the slot 140 is formed is covered by the aforementioned sheath 150, when the operator installs the leaky coaxial cable 100, the direction in which the slot 140 is formed difficult to ascertain

Therefore, the sheath 150 of the leaky coaxial cable 100 may be provided with a notch 160 in an opposite direction in which the slot 140 is formed. The notch 160 protrudes from the surface of the sheath 150 along the longitudinal direction of the leaky coaxial cable 100 and is installed in the opposite direction where the slot 140 is formed.

When a worker installs the leaky coaxial cable 100 inside the tunnel 10, the notch 160 can be checked to recognize the direction in which the slot 140 is formed. In this case, the slot 140 ) is laid toward the inside of the tunnel 10.

Meanwhile, the leaky coaxial cable 100 according to the present invention may include an optical unit 180 for transmitting an optical signal to at least one of the inner conductor 110, the sheath 150, and the notch 160. there is. 2 shows a case where the light unit 180 is provided in the notch 160 .

When the light unit 180 is installed in the notch 160, the light unit 180 is disposed inside the notch 160 and extruded together with the notch 160 as shown in the drawing. It can be.

At this time, the optical unit 180 can be configured in any form including an optical fiber for transmitting an optical signal, for example, at least one or more optical fibers 183 and a tube surrounding the optical fiber 183 ( 187) may be included.

The tube 187 may be made of, for example, polybutylene terephthalate (PBT), polypropylene, polyethylene, or polyvinyl chloride. In addition, a filler 185 may be additionally filled in the tube 187 . For example, jelly may be filled, or a tension member such as aramid yarn may be filled. The tension member has excellent tensile force and is flexible, so that the cable can be stably installed.

The light unit 180 may be configured in a necessary form among various forms such as a tight buffer method in addition to the above tube type.

The power supply system 1000 at both ends of the leaky coaxial cable according to the present invention configures a system capable of feeding power at both ends through the light unit 180 included in the leaky coaxial cable 100. Referring to FIG. 4, the leakage The configuration of the power feeding system 1000 at both ends of the coaxial cable will be described.

Referring to FIG. 4, a power supply system 1000 at both ends of a leaky coaxial cable that supplies power to both ends of a leaky coaxial cable in a mobile communication device 900 is disposed inside a tunnel 10 along the tunnel 10, The leaky coaxial cable 100 accommodating the electrical signal unit 190 through which electrical signals are transmitted and the optical unit 180 through which optical signals are transmitted therein, the mobile communication equipment 900 and the leaky coaxial cable 100 By connecting one end and connecting the other end of the leaky coaxial cable 100 with the first power supply unit 200 and the mobile communication equipment 900 for transmitting electrical signals to one end of the electrical signal unit 190, A second power supply unit 300 for transmitting an electrical signal to the other end of the electrical signal unit 190 may be included.

The mobile communication equipment 900 may be installed on the ground, and the leaky coaxial cable 100 may be installed along an area where radio signals are not well received, such as a tunnel 10.

The mobile communication equipment 900 may include, for example, a remote radio unit (RRU) for transmitting and receiving LTE signals. In this case, the leaky coaxial cable 100 according to the present invention is configured to enable MIMO (Multi Input Multi Output) communication with a wireless terminal possessed by a user or the like.

That is, the LTE signal incident from the mobile communication equipment 900 is incident from both ends of the leaky coaxial cable 100, and is radiated into the air through the leaky coaxial cable 100 having a MIMO function, and the mobile terminal and MIMO make communication possible. Conversely, the signal transmitted from the wireless terminal is incident on the leaky coaxial cable 100 and is transmitted to the mobile communication equipment 900 to enable MIMO communication.

As a result, the leaky coaxial cable 100 according to the present invention not only serves as a simple antenna, but also can feed power at both ends by the power supply units 200 and 300 connected to both ends of the leaky coaxial cable 100, so that a pair of leaky coaxial cables ( 100) alone can perform MIMO. That is, electrical signals are transmitted from the mobile communication equipment 900 connected to both ends of the leaky coaxial cable 100 laid in one set to the leaky coaxial cable 100, and the signals transmitted to both ends of the leaky coaxial cable 100 are leaky coaxial cables. MIMO is made possible by radiating through the slot for signal leakage of the cable 100 .

The leaky coaxial cable 100 of the present invention performs MIMO communication as described above and can be used for mobile communication of 4th generation or higher that transmits large-capacity signals at high speed, and the MIMO communication function is implemented with only one set of laying You can get the effect of reducing CAPEX such as bar, construction cost, and material cost. In addition, when the leaky coaxial cable 100 is laid in an underground space such as a tunnel, since signals are radiated in the length direction of the leaky coaxial cable 100, communication connectivity increases, and thus communication quality can be improved.

Specifically, the power supply system 1000 at both ends of the leaky coaxial cable includes a power supply unit to supply power to both ends of the leaky coaxial cable 100 .

Specifically, the first power supply unit 200 connects the mobile communication equipment 900 and one end of the leaky coaxial cable 100 to transmit an electrical signal to one end of the electrical signal unit 190. In addition, the second power supply unit 300 connects the mobile communication equipment 900 and the other end of the leaky coaxial cable 100 to transmit an electrical signal to the other end of the electrical signal unit 190. .

The first power supply unit 200 may connect one end of the leaky coaxial cable 100 located relatively close to the mobile communication equipment 900 to the mobile communication equipment 900 , for example.

At this time, the first power supply unit 200 may be composed of a cable for power supply. Therefore, the first power supply unit 200 connects the mobile communication equipment 900 and the leaky coaxial cable 100 .

The electrical signal transmitted from the mobile communication device 900 is transmitted through the first power supply unit 200, in this case, through the first connector 104 provided at one end of the leaky coaxial cable 100. It is transmitted to one end of the electrical signal unit 190.

Meanwhile, the second power supply unit 300 connects the mobile communication equipment 900 and the other end of the leaky coaxial cable 100 so that both ends can be fed.

At this time, when the leaky coaxial cable 100 and a separate power feeding cable are laid for power feeding at both ends, the cost and time required for laying the power feeding cable are required, which is economically and practically constrained. this will follow

Therefore, in the present invention, a very economical double-end power feeding system is provided by laying the leaky coaxial cable 100 according to the present invention and providing a power supply unit without laying a separate power feeding cable for power feeding at both ends of the leaky coaxial cable 100. can be built

Specifically, the second power supply unit 300 may be connected to the other end of the leaky coaxial cable 100 through one end of the leaky coaxial cable 100 to which the first power feed unit 200 is connected.

That is, when the leaky coaxial cable 100 according to the present invention is laid, the first power supply unit 200 is connected to one end of the leaky coaxial cable 100 adjacent to the mobile communication device 900, and the second The power supply unit 300 is also connected to the other end of the leaky coaxial cable 100 through one end of the leaky coaxial cable 100 .

Therefore, in the case of the present invention, there is no need to lay a separate power supply cable for power supply at both ends of the leaky coaxial cable 100, and at one end of the leaky coaxial cable 100 adjacent to the mobile communication device 900. By connecting the power supply unit, it is possible to implement power supply at both ends.

At this time, the second power supply unit 300 is connected to one end of the leaky coaxial cable 100 and converts the electrical signal into an optical signal through the optical unit 180 of the leaky coaxial cable 100. A pair of photoelectric conversion modules 310 and 330 are provided to transmit a signal, convert the optical signal received through the optical unit 180 into an electrical signal, and transmit the electrical signal to the other end of the electrical signal unit 190. can do.

That is, the second power supply unit 300 includes photoelectric conversion modules 310 and 330 at both ends of the leaky coaxial cable 100, and converts electrical signals into optical signals by the photoelectric conversion modules 310 and 330. Alternatively, the optical signal is converted into the electrical signal and transmitted through the optical unit 180 .

For example, the photoelectric conversion modules 310 and 330 connect the mobile communication device 900 and one end of the leaky coaxial cable 100, and convert an electrical signal received from the mobile communication device 900 to the optical fiber. The light received through the optical unit 180 connected to the first photoelectric conversion module 310 that converts into a signal and transmits the signal through the optical unit 180 and the other end of the leaky coaxial cable 100. A second photoelectric conversion module 330 may be provided to convert the signal into an electrical signal and transmit the electrical signal to the other end of the electrical signal unit 190 .

The first photoelectric conversion module 310 connects one end of the leaky coaxial cable 100 and the mobile communication device 900, and converts an electrical signal transmitted from the mobile communication device 900 into an optical signal. do. Accordingly, the converted optical signal is transmitted through the optical unit 180 of the leaky coaxial cable 100 .

5 is a schematic diagram showing a connection relationship between the photoelectric conversion modules 310 and 330. Referring to FIG.

Referring to FIG. 5 , the first photoelectric conversion module 310 is connected to the mobile communication equipment 900 through a first power supply cable 312, and an electrical signal from the first photoelectric conversion module 310 is transmitted to a light source. It is converted into a signal and connected to the optical unit 180 of the leaky coaxial cable 100 through the first feeding optical cable 314.

Meanwhile, the optical signal transmitted to the other end of the leaky coaxial cable 100 through the optical unit 180 is transmitted through the second optical power supply cable 332 connected to the other end of the leaky coaxial cable 100. 2 is transmitted to the photoelectric conversion module 330. In the second photoelectric conversion module 330, the optical signal is converted into an electrical signal, and the converted electrical signal is passed through the second power supply cable 334 to the second connector 102 at the other end of the leaky coaxial cable 100. ) is transmitted to the other end of the electrical signal unit 190.

On the other hand, when the electric signal transmitted from the user's wireless terminal is incident on the leaky coaxial cable 100 and transmitted to the mobile communication equipment 900, the electric signal and the optical signal are transmitted in the opposite direction to the above description.

That is, the electric signal transmitted from the user's wireless terminal is transmitted to the second power supply cable 334 through the leaky coaxial cable 100 . The electrical signal is incident to the second photoelectric conversion module 330 through the second power feeding cable 334 and is converted into an optical signal, and the optical signal is transmitted through the second power feeding optical cable 332 to the leakage. It is incident on the light unit 180 of the coaxial cable 100.

The optical signal is transmitted to the first photoelectric conversion module 310 through the first optical power feeding cable 314 and converted into an electrical signal, and the mobile communication device 900 through the first power feeding cable 312 ) is sent to

As a result, by feeding electric signals to both ends of the leaky coaxial cable 100, power can be supplied to both ends of the leaky coaxial cable 100, and thus the aforementioned MIMO communication is possible.

The configurations of the above-described first photoelectric conversion module 310 and the second photoelectric conversion module 330 are only described as an example, and in the power supply system 1000 at both ends of a leaky coaxial cable according to the present invention, the photoelectric conversion module The configuration may be modified as appropriate.

Meanwhile, in FIG. 2 described above, it is shown that the optical unit 180 is installed in the notch 160 of the leaky coaxial cable 100, but the optical unit 180 includes the inner conductor 110 and the sheath 150 And at least one of the notches 160 may be installed along the length direction of the leaky coaxial cable 100 .

6 shows a case where the light unit 180 is installed in the inner conductor 110 of the leaky coaxial cable 100'.

Referring to FIG. 6 , the inner conductor 110 may be formed in a hollow shape with a hollow 112 formed in the center thereof, as described above. At this time, the light unit 180 is disposed in the hollow 112. can

That is, the diameter of the optical unit 180 is relatively very small compared to the overall diameter of the leaky coaxial cable 100', and the optical fiber 183 provided in the optical unit 180 has a relatively small diameter such as bending or disconnection. Since it is more vulnerable, when arranging the optical unit 180 on the leaky coaxial cable 100', it is advantageous to dispose it in the center of the leaky coaxial cable 100', and to arrange it on the inner conductor 110 In this case, it is preferable to arrange in the hollow 112 located in the center of the inner conductor 110.

Accordingly, by minimizing an external force such as bending that may act on the light unit 180, damage or breakage such as disconnection of the light unit 180 can be maximally prevented.

Meanwhile, FIG. 7 shows a case in which the optical unit 180 is installed in the sheath 150 of the leaky coaxial cable 100''.

Referring to FIG. 7 , when the sheath 150 of the leaky coaxial cable 100'' is formed by extruding, the light unit 180 may be formed by being extruded together.

In this case, the thickness of the sheath 150 may be relatively thicker than in the prior art in order to prevent pressure or the like from acting on the light unit 180 when the sheath 150 is extruded. For example, the thickness t of the sheath 150 is larger than the outer diameter D of the light unit 180, and the thickness t of the sheath 150 is It may be composed of more than twice the diameter (D). The thickness of the sheath 150 is just an example, and the thickness t of the sheath 150 is the environment of the tunnel in which the leaky coaxial cable 100'' is installed, and the optical unit 180 It may be appropriately deformed depending on the diameter and the like.

Meanwhile, FIG. 8 shows a configuration of a leaky coaxial cable 100''' according to another embodiment.

Referring to FIG. 7, the leaky coaxial cable 100''' further includes a support line 170 in which a plurality of metal wires 172 are twisted along the longitudinal direction of the leaky coaxial cable 100'''. can be provided

In the support wire 170, a support metal wire 172 arranged along the longitudinal direction at a position parallel to the external conductor 130 at regular intervals is covered with the sheath 150 together with the external conductor 130. can be formed.

In this case, the support line 170 serves to provide appropriate rigidity so that the leaky coaxial cable 100''' is not bent or bent when the leaky coaxial cable 100''' is installed.

As described above, when the leaky coaxial cable 100''' is provided with the support line 170, the light unit 180 may be disposed along the support line 170.

For example, the light unit 180 may be disposed at the center of the plurality of metal wires 172 constituting the support line 170 .

As described above, since the light unit 180 is vulnerable to external forces such as bending, it is preferable to be disposed at the center of the metal wire 172 to prevent damage or disconnection.

Although this specification has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims described below. will be able to carry out Therefore, if the modified implementation basically includes the elements of the claims of the present invention, all of them should be considered to be included in the technical scope of the present invention.

100: leaky coaxial cable
180: light unit
200: first power supply unit
300: 2nd power supply unit
310: first photoelectric conversion module
330: second photoelectric conversion module
900: mobile communication network base station
1000: Power supply system at both ends of leaky coaxial cable

Claims (10)

A leaky coaxial cable provided with an electrical signal unit through which electrical signals are transmitted and an optical unit through which optical signals are transmitted;
a first power supply unit connecting a mobile communication device and one end of the leaky coaxial cable to transmit an electric signal to one end of the electrical signal unit; and
A second power supply unit connecting the mobile communication device and the other end of the leaky coaxial cable to transmit an electrical signal to the other end of the electrical signal unit; and
The second power supply unit is connected to the other end of the leaky coaxial cable through one end of the leaky coaxial cable to which the first power supply unit is connected, and both ends of the leaky coaxial cable supplying power from the mobile communication device to both ends of the leaky coaxial cable. power supply system. delete According to claim 1,
The second power supply unit
It is connected to one end of the leaky coaxial cable to convert the electrical signal into an optical signal, transmit the optical signal through an optical unit of the leaky coaxial cable, and convert the optical signal received through the optical unit into an electrical signal. A power supply system at both ends of a leaky coaxial cable, characterized in that it comprises a pair of photoelectric conversion modules for transmitting to the other end of the electrical signal unit. According to claim 3,
The photoelectric conversion module
a first photoelectric conversion module that connects the mobile communication device and one end of the leaky coaxial cable, converts an electrical signal received from the mobile communication device into an optical signal, and transmits the optical signal through the optical unit;
and a second photoelectric conversion module connected to the other end of the leaky coaxial cable to convert the optical signal received through the optical unit into an electrical signal and transmit the electrical signal to the other end of the electrical signal unit. Power supply system at both ends of coaxial cable. According to claim 1,
The leaky coaxial cable
The electrical signal unit including an inner conductor, an insulator surrounding the inner conductor, and an outer conductor provided to surround the insulator and having slots of a predetermined pattern formed in one direction to radiate electromagnetic waves in the one direction, the outer conductor A sheath surrounding the sheath, and a notch provided in the opposite direction of the slot along the longitudinal direction of the leaky coaxial cable to the sheath,
The power supply system at both ends of the leaky coaxial cable, characterized in that the optical unit is installed in at least one of the inner conductor, the sheath, and the notch along the longitudinal direction of the leaky coaxial cable. According to claim 5,
When the light unit is installed in the inner conductor, the power supply system at both ends of the leaky coaxial cable, characterized in that the light unit is located in the hollow of the central part of the inner conductor. According to claim 5,
When the optical unit is installed in the sheath or the notch, the optical unit is extruded together with the sheath or the notch. According to claim 7,
When the optical unit is installed in the sheath, the thickness of the sheath is twice or more than the diameter of the optical unit. According to claim 5,
The leaky coaxial cable
It is provided on one side of the sheath and further includes a support line in which a plurality of metal wires are twisted along the longitudinal direction of the leaky coaxial cable,
The power supply system at both ends of the leaky coaxial cable, characterized in that the optical unit is located in the center of the metal wire of the support line. A leaky coaxial cable applied to the power supply system at both ends of the leaky coaxial cable according to any one of claims 1 and 3 to 9.

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