KR20160041478A - Optical fiber and power line composite cable - Google Patents

Abstract

According to an embodiment of the present invention, provided is a photoelectronic composite cable which comprises: an antenna interface standards group (AISG) cable unit; an optical fiber unit; and a power line unit, thereby increasing efficiency of a system, and reducing a time and the costs when installing the photoelectronic composite cable.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a photoelectric composite cable, and more particularly, to a photoelectric hybrid cable for transmitting a mobile communication signal, a power, and a control signal of a base station equipment in a mobile communication base station having a plurality of base station equipments and a plurality of antennas .

In the conventional mobile communication, a communication signal is transmitted from the base station to a base station, and an RF signal transmitted from a base transceiver station (BTS) of the base station is transmitted to the base station antenna unit. Also, a radio signal transmitted from a user's cell phone is applied to the base station antenna, and an applied signal is amplified through a TMA (Tower Mount Amplifier), and the signal strength is amplified and received at the BTS. At this time, the base station, the TMA, and the antenna are connected to a coaxial feeder line.

However, the coaxial feeder has a problem in that signal loss increases as the length of the cable increases. Therefore, when the antenna is installed in a tower having a height of several tens of meters, a loss occurs in a coaxial feeder line connecting a base station on the ground and the antenna, and a signal applied from the base station due to loss of the coaxial feeder It is attenuated without reaching the required signal strength. Therefore, the signal of the amount of attenuation of the coaxial feeder must be amplified, which causes additional power consumption. In addition, the signal transmitted from the mobile phone and received by the base station antenna is very difficult to transmit to the BTS using the coaxial feeder having a relatively small signal intensity. Therefore, it is essential to provide a TMA (Tower Mounted Amplifier) for amplifying the attenuated signal on the input side of the antenna. However, since the TMA consumes a relatively large amount of power in order to amplify the signal, the TMA requires a large amount of maintenance in terms of the overall system, which leads to a problem of inefficiency.

The remote radio head (RRH) is a complement to the inefficient disadvantages of power consumption and maintenance of mobile communication base stations using the TMA. The RRH separates the RRU (Remote RF Unit) from the conventional BTS and places it remotely underneath the antenna of the base station tower.

Here, the remaining parts of the existing BTS in which the RRU is separated from the RRH (i.e., the Baseband Unit (BBU) and the Power Supply Unit (PSU)) and the RRU are the photoelectric hybrid cable including the optical unit and the power line unit, The communication signal from the BBU and the PSU is supplied to the RRU through the optical unit constituting the photoelectric hybrid cable, and the electric power is supplied to the RRU through the power line unit constituting the photoelectric hybrid cable.

Since the RRU can be installed directly below the base station antenna at the top of the base station tower, the length of the coaxial feeder for supplying the RF signal converted by the RRU to the antenna is minimized, Since there is no problem of signal attenuation, the attenuation amount of the signal up to just before the radiation is minimized, and the necessity of the TMA which used the conventional power consumption is eliminated. This technical feature has become a feature of the RRH in terms of the maintenance of the base station.

In recent years, electrical tilting techniques have been applied to antennas in order to efficiently manage the coverage of mobile communication base stations in RRH systems as well as systems using existing BTSs. In order to tilt the antenna installed on the base station tower, a CCU (Central Control Unit) for controlling the electric tilting of the antenna, an RCU (Remote Control Unit) for electrically tilting the antenna by the control signal of the CCU, and a CCU and an RCU And an AISG (Antenna Interface Standards Group) cable for transmitting a control signal.

As described above, the optical fiber unit, the power line unit and the AISG cable are essentially used in the mobile communication base station system using the electric tilting of the antenna. When these three types of cables are separately installed, the cable construction time becomes longer, And also increases. Also, since each of these cables must be managed separately, there is a problem that the cost required for maintenance also increases.

SUMMARY OF THE INVENTION It is a principal object of the present invention to provide an optical fiber unit for transmitting and receiving an optical signal and a power line unit for transmitting power simultaneously to improve the efficiency of the system and further provide an AISG cable unit, And a power line unit at the same time to improve the efficiency of the system, and to provide a photoelectric composite cable capable of reducing time and cost in installing the photoelectric composite cable.

A photoelectric hybrid cable according to an embodiment of the present invention is a photoelectric hybrid cable for transmitting mobile communication signals and electric power in a mobile communication base station having a plurality of base station equipments and a plurality of antennas, At least one power line unit having an insulator surrounding the conductor, the at least one power line unit transmitting the power; An optical fiber unit comprising a plurality of optical fiber subunits each having an optical fiber and a tube accommodating the optical fiber, the optical fiber unit transmitting the mobile communication signal; An AISG cable unit for transmitting a RET (Remote Electrical Tilting) signal for controlling electrical tilting of the antenna; A metal protective layer surrounding the power line unit, the optical fiber unit, and the AISG cable unit; And an outer coating layer formed outside the metal protective layer; And the power line units and the AISG cable unit may be disposed along the outer periphery of the optical fiber unit.

In the present invention, the AISG cable unit and the power line unit may have substantially the same diameter.

In the present invention, the AISG cable unit may be circumscribed with neighboring power line units.

In the present invention, the metal protective layer may be formed with wrinkles in which the wrinkles and the wrinkles are repeatedly formed.

In the present invention, when the power line units form a cable core disposed along the outer periphery of the optical fiber unit, the outer diameter of the cable core is Dc, the inner diameter of the wrinkle mountain is Do, and the inner diameter of the wrinkle core is Di , The relationship of Di < Dc &amp;le; Do can be satisfied.

In the present invention, a filling material may be further provided in the hollow space of the cable core.

In the present invention, when the base station equipment includes a remote radio unit (RRU), a remote control unit (RCU), or a central control unit (CCU), the AISG cable units include the RCU, And the RCU may transmit the RET signal from the CCU to the RCU to control the electrical tilting of the antenna.

In the present invention, when the base station equipment includes a Tower Mounted Amplifier (TMA), the AISG cable unit may transmit a signal for controlling the TMA.

According to an embodiment of the present invention, an optical fiber unit for transmitting and receiving an optical signal, a power line unit for transmitting power, and an AISG cable unit for transmitting an RET signal for controlling the electrical tilting of the antenna, The efficiency of the entire system can be improved, cable installation time and cost can be saved, and the optical fiber unit, the AISG cable unit, and the power line unit can be protected from the external force.

According to an embodiment of the present invention, there is provided a metal protection layer in the form of a corrugated pipe, wherein the inner diameter of the corrugated pipe is made smaller than the outer diameter of the inner cable core, do. Thus, even when the photoelectric composite cable according to the embodiment of the present invention is installed in a vertical direction such as a tower, the cable core of the photoelectric composite cable is securely fixed without causing a problem of falling downward due to gravity Can be installed.

1 is a block diagram schematically illustrating the configuration of a mobile communication base station having a photoelectric hybrid cable according to an embodiment of the present invention.
Fig. 2 is a cross-sectional view schematically showing the photoelectric composite cable shown in Fig. 1. Fig.
3 is a perspective view schematically showing the photoelectric composite cable shown in Fig.
4 is a cross-sectional view of each of the power line unit and the AISG cable shown in Fig.
5 is a longitudinal sectional view schematically showing the metal protective layer shown in Fig.
Fig. 6 is a cross-sectional view schematically showing the cable core shown in Fig. 2. Fig.
Fig. 7 is a cross-sectional view schematically showing the power line unit shown in Fig. 2. Fig.

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 but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like reference numerals designate like elements throughout the specification.

1 is a block diagram schematically illustrating the configuration of a mobile communication base station having a photoelectric hybrid cable 100 according to an embodiment of the present invention.

The RRU (Remote Radio Unit) is a complement to the power consumption and maintenance inefficiency of the mobile communication base station using the conventional TMA. Hereinafter, a system having an RRU will be described in detail with reference to the drawings.

1, the mobile communication base station transmits / receives a communication signal to / from a mobile communication terminal or a mobile phone of a user, and includes a base transceiver station (BTS) 10 (for example, A photoelectric hybrid cable 100 for optically and electrically connecting the base station 10 and a remote radio unit (RRU) 40 to each other, an optical fiber unit, a power line unit, and an AISG cable An outdoor terminal (hereinafter referred to as a 'terminal box') 70 for a photoelectric hybrid cable separating the units from the optical fiber unit and the power line unit separated from the photoelectric terminal box 70 An RRU 40 for receiving an optical signal and power or for transmitting an optical signal to an optical fiber unit separated from the terminal box 70 and an AISG cable unit 160 separated from the photoelectric terminal box 70, Receiving a signal An RCU 80 includes an antenna 20 that receives a wireless communication signal from the RRU 40 or transmits a wireless communication signal to the RRU 40 and is electrically tilted under the control of the RCU 80 .

As is well known, an optical fiber unit with an optical fiber has an advantage that a signal loss according to the length of the cable is relatively small as compared with a coaxial cable. Therefore, when the optical signal is transmitted to the input portion of the antenna as close as possible to the antenna, the attenuation of the signal can be minimized. The RRU 40 is provided adjacent to an antenna input terminal and converts an optical signal transmitted through an optical fiber into an RF signal capable of being radiated from an antenna. Therefore, the amount of attenuation due to the loss of the signal applied to the antenna is minimized, and it is possible to omit the conventional TMA which consumes a large amount of power.

As a result, the photoelectric hybrid cable 100 according to an embodiment of the present invention includes an optical fiber unit 130 connected from the base station 10 to the RRU 40 and having an optical fiber, And a power line unit 110 for connecting the power line unit 110 to the power line unit 110. The use of such a photoelectric hybrid cable 100 makes it relatively easy to install in a tower equipped with an antenna as compared with a structure in which an optical fiber unit and a power line unit are separated from each other and a plurality of RRUs 40 are connected to a single terminal box 70 So that the installation cost is relatively reduced.

The AISG cable unit 160 may include an optical fiber unit 130 and a power line unit 110 and an AISG cable unit 160 at the same time. Signal to the RCU 80. &lt; RTI ID = 0.0 &gt; More specifically, when an RRH system and an existing BTS system including BTSs 12 and 13 and antennas 22 and 23 are installed together in one mobile communication base station as shown in FIG. 1, in the case of RRH, The RET signal of the antenna 21 can be transmitted through the optical fiber unit 130 of the composite cable 100. In order to electrically tilt the antennas 22 and 23 of the existing BTS system, The RCU 80 is installed and the RCU 80 can electrically tilt the antennas 22 and 23 according to the RET signal transmitted from the CCU 14 disposed in the shelter of the mobile communication base station. The RCU 80 and the CCU 14 are connected by an AISG cable unit 160 provided in the photoelectric hybrid cable 100 and the AISG cable unit 160 can transmit the RET signal.

In addition, when the photoelectric hybrid cable 100 having the optical fiber unit 130, the power line unit 110, and the AISG cable unit 160 at the same time is used, compared with a structure in which they are separated from each other, It is relatively easy to install in a tower, installation time can be reduced, and maintenance cost can be reduced.

Hereinafter, the configuration of the photoelectric hybrid cable 100 will be described with reference to the drawings.

FIG. 2 is a cross-sectional view schematically showing the photoelectric composite cable shown in FIG. 1, and FIG. 3 is a perspective view schematically showing the photoelectric composite cable shown in FIG.

Referring to FIGS. 2 and 3, the photoelectric hybrid cable 100 may include a cable core 105 and an outer layer 150 surrounding the cable core 105.

The cable core 105 may include a plurality of power line units 110 for supplying power, a plurality of optical fiber units 130 for transmitting optical signals, and an AISG cable unit 160. The cable core 105 further includes a filler material 120 filling the gap between the plurality of power line units 110, the optical fiber unit 130, and the AISG cable unit 160 and having a circular outer periphery can do.

The outer layer 150 may include a metal protective layer 151 on which a corrugation 152 is repeatedly formed so as to surround the cable core 105 and a corrugation 152A and a corrugation 152B. Further, the cable core 105 may further include a nonwoven fabric tape (not shown) surrounding the outer circumference of the cable core 105.

Each power line unit 110 may include a conductor 113 and an insulator 115 surrounding the conductor 113. The power line unit 110 may have a shape conforming to a standard used for general power, and the plurality of conductors 113 may be twisted together. The conductor 113 may be formed of a metal such as copper or aluminum. The insulator 115 may be formed of a polymer resin such as polyethylene, polypropylene, or polyvinyl chloride.

The optical fiber unit 130 may be configured in any form including an optical fiber for transmitting an optical signal, and may be formed of a plurality of optical fiber subunits 131, for example.

The optical fiber subunit 131 may include at least one core optical fiber 133 and a tube 135 for receiving the optical fiber 133. The tube 135 may comprise, for example, polybutylene terephthalate (PBT), polypropylene, polyethylene or polyvinyl chloride. In addition, the tube 135 may be filled with filler. For example, be filled with jelly or filled with a tensile material 137, such as an aramid yarn. The tensile material 137 is excellent in tensile force and is flexible, so that the cable can be stably installed.

The AISG cable unit 160 may include eight transmission lines including a conductor and an insulator surrounding the conductor, and an insulator surrounding the transmission lines. The AISG cable unit 160 may transmit a RET signal from the CCU 14 to the RCU 80 via RS485 communication as an example. The RCU 80 can control the electrical tilting of the antennas 22 and 23 by changing the phase of the RF signal flowing into the antenna by operating a driving unit (not shown) inside the antenna according to the RET signal. In yet another embodiment, the AISG cable unit 160 may transmit a control signal of a TMA (not shown) that is located at the top of the base station tower and amplifies the RF signal transmitted to the antennas 22 and 23.

The AISG cable unit 160 is connected to the terminal box 70 by the photoelectric hybrid cable 100 as shown in Figure 1 and is branched from the terminal box 70 and disposed adjacent to the antennas 22 and 23 May be connected to the RCU 80.

The AISG cable unit 160 may be arranged to circumscribe the optical fiber unit 130 around the optical fiber unit 130 together with the power line unit 110. [ In addition, the AISG cable unit 160 can be circumscribed with the power line unit 110. As an example, the AISG cable unit 160 may have a diameter D2 that is the same as the diameter D1 of the power line unit 110, as shown in FIG. Accordingly, the AISG cable unit 160 and the power line units 110 having the same diameter are disposed around the optical fiber unit 130, thereby contributing to maintaining the outer shape of the photoelectric hybrid cable 100 in a circular shape.

The outer cover layer 150 provided at the outermost portion of the photoelectric hybrid cable 100 forms an outer shape of the photoelectric composite cable 100 and includes an optical fiber unit 130 included in the photoelectric hybrid cable 100, (110), and the AISG cable unit (160) can protect the power line unit (110). For example, the outer cover layer 150 is in contact with the cable core 105 and surrounds the cable core 105 in a circular shape, and includes a metal protective layer 151 for protecting the cable core 105 from external impact, And an outer coating layer 155 surrounding the metal protective layer 151.

The metal protection layer 151 may be formed of a metal pipe such as aluminum in a corrugated form in which the corrugation 152A and the corrugation 152B are repeatedly formed. The optical fiber unit, the power line unit, and the AISG cable unit 160 supply the plate type metal plate together with the cable core including the power line unit 110, The metal plate is rolled so as to surround the outer circumference of the cable core, and then both end portions of the metal plate are joined together by welding or the like to form a pipe having a predetermined diameter. Then, the pipe is pressed at predetermined intervals to form corrugations to the outside of the pipe. In this case, the wrinkle score (152B) inside diameter (D _i) and the cable core 105 outer diameter (D _c) between the relevant bars between the, as will examine in detail later.

In the case of using a photoelectric composite cable formed to wrap the cable core with a tape-like metal protective layer without wrinkles or wrinkles in advance, when the cable is installed vertically, there is a problem that the cable core is not fixed Will still occur. Also, the metal protection layer according to an embodiment of the present invention may be formed of a rigid material so that the cable core can be tightly held and fixed.

On the other hand, the outer coating layer 155 may be made of a resin having a flame retardant property and being environmentally friendly. For example, the outer coating layer 155 may be composed of polyethylene, polypropylene, polyvinyl chloride (PVC), or the like.

The cable core 105 may further include a nonwoven fabric tape (not shown) that surrounds the outer circumference of the cable core 105 and surrounds the power line unit 110 and the optical fiber unit 130 in a circular shape. The nonwoven fabric tape is a compressed nonwoven fabric and is disposed in a manner to enclose an optical fiber unit and a power line unit therein. The nonwoven fabric tape may be formed in such a manner that a tape-like material is horizontally or extensively applied.

Meanwhile, in the photoelectric hybrid cable 100, the voids in the cable core 105 may be filled with the filler material 120. That is, since the power line unit 110 has a circular shape, voids are generated between neighboring power line units. In such a configuration, the entire outer shape of the photoelectric composite cable 100 can not maintain its circular shape, and thus it is vulnerable to warping or impact acting on the outside. Accordingly, the voids in the cable core 105 may be filled with the filler 120, and the outer shape of the filler 120 may be maintained in a circular shape to have a structure capable of withstanding external impacts.

2, a plurality of optical fiber units 130 are disposed in the cable core 105, and the plurality of optical fiber units 130 are disposed along the outer periphery of the optical fiber unit 130 It can be seen that the power line units 110 and the AISG cable unit 160 are disposed. Comparing the optical fiber unit 130 and the power line unit 110 shows that the optical fiber unit 130 is more susceptible to bending or breakage than the optical fiber unit 130, do. In this case, a protective layer 140 may be further provided between the plurality of power line units 110 and the optical fiber unit 130 to protect the plurality of optical fiber units 130.

In addition, a center line 145 may be provided at the center of the photoelectric hybrid cable 100 to prevent the photoelectric hybrid cable 100 from being bent more than necessary. The center line 145 is located at the center of the photoelectric composite cable 100 to provide a repulsive force to the photoelectric composite cable 100 when the bending force acts on the photoelectric composite cable 100, And serves to support the shrinkage of the tube due to the temperature change. As a result, damage to the optical fiber unit 130 can be prevented.

Since the photoelectric hybrid cable 100 is basically installed in a vertical direction along a tower provided with an antenna and further includes a copper conductor for power transmission having a large internal weight, the present inventor has developed an internal optical fiber unit and a power line unit It became clear that a structure that can be fixed was necessary. In the case of using a photoelectric composite cable formed without a wrinkle or with a tape-like metal protective layer that is wrinkled in advance to wrap the cable core, there is a problem that the cable core is not fixed Will still occur.

For example, when a photoelectric composite cable is installed in a vertical direction along a tower, if the power cable unit or the optical fiber unit is separated from the outer layer of the photoelectric composite cable by its own weight, it takes a long time to install the photoelectric composite cable A process for recovering the photoelectric composite cable is required, and the efficiency of the work is significantly lowered. Hereinafter, a configuration of a photoelectric hybrid cable for solving the above problems will be described.

FIG. 5 is a longitudinal sectional view schematically showing the metal protective layer 151 of the photoelectric composite cable 100 shown in FIG. 2. FIG. 6 is a cross-sectional view of the metal protective layer 151 in the photoelectric composite cable 100 shown in FIG. And a cable core 105 from which the outer coating layer 155 is removed.

5, the metal protection layer 151 is provided in the form of a metal pipe made of aluminum or the like, and the corrugations 152 (see FIG. 5) in which the corrugated cores 152A and the corrugated corrugations 152B are repeatedly formed Is formed. 5 and 6, the metal protective layer 151 is disposed so as to surround the outer surface of the cable core 105, and the inner diameter Do and the corrugation of the corrugate 152A of the metal protective layer 151, and the relationship between the goal (152B) inside diameter (D _i) and a photoelectric composite cable 100 of cable core 105 outer diameter (Dc) of an important factor.

If the cable core 105 by crease score (152B) inside diameter (D _i), the cable core 105 outer diameter (Dc) greater than or, or if it is determined in the same dimension wrinkles bone (152B) relative to the The effect of fixing will be very small. Therefore, the power line unit 110 and the optical fiber unit 130 located inside the cable core 105 are not fixed in the same manner. When the photoelectric composite cable 100 is installed, the power line unit 110, The antenna 130, and the AISG cable unit 160 move in the sheath layer. Accordingly, the photoelectric composite cable according to one embodiment of the present invention 100 is smaller than the outer diameter (Dc) of the inner diameter (D _i) a cable core 105 of the wrinkle score (152B) of the metal protective layer 151 . In this case, the inner diameter Do of the corrugate 152A may be determined to be equal to or greater than the outer diameter Dc of the cable core 105 '. In other words, the inner diameter of the corrugate 152A may be equal to or larger than the outer diameter Dc of the cable core 105.

In the end, the outer diameter (Dc of the cable core 105 of the metal protective layer 151 folds acid (152A), the inner diameter (Do) and wrinkles bone inner diameter of the (152B), (D _i) and a photoelectric composite cable 100 in the ) Can be expressed by Equation (1) as follows.

In the end, than the outer diameter (Dc) of the metal protective layer 151 folds acid (152A) and the blank-bone inner diameter (D _i) a cable core 105 of the wrinkle score (152A) in the case of forming a (152B) of And the inner diameter Do of the corrugate 152A may be determined to be equal to or greater than the outer diameter Dc of the cable core 105. [ The power line unit 110, the optical fiber unit 130, and the twisted pair unit 160, which are disposed inside the cable core 105 according to the shape of the corrugation 152B of the metal protection layer 151, So that it can be fixed.

If the inside diameter D _i of the corrugation 152B of the metal protective layer 151 is smaller than the outside diameter Dc of the cable core 105 as described above, 105, the power line unit 110 of the cable core 105 may be damaged. Accordingly, the inner diameter (D _i) of the corrugation valley (152B) of the metal protective layer 151 may be determined so as to prevent damage to the power line unit 110, on the one hand, the cable core 105 or the power line unit ( 110 may be prevented from being separated from the metal protective layer 151.

Meanwhile, as described above, the power line unit 110 may include a conductor 113 at a central portion and an insulator 115 that surrounds the conductor 113. Therefore, when the metal protection layer 151 is pressed by the corrugated trough 152B, the corrugated trough 152B of the metal protection layer 151 is formed to have a thickness T of the insulator 115 of the power line unit 110 _p , see FIG. 7), the power line unit 110 may be damaged. 2, when the power line unit 110 and the AISG cable unit 160 are symmetrical with respect to the center of the photoelectric hybrid cable 100 on both sides of the power line unit 110, And the like. Therefore, it is preferable that the corrugated troughs 152B do not push over the thickness of the insulator 115 of the two power line units 110 arranged on both sides of the center of the photoelectric composite cable 100. After all, the inner diameter (D _i) of the wrinkle score (152B) can be determined to better satisfy the conditions such as the following [Equation 2].

1, the photoelectric hybrid cable 100 is connected from the BBU 11 to the RRU 40 via the terminal box 70. [ In this case, in the photoelectric hybrid cable 100, the power line unit 110, the optical fiber unit 130, and the AISG cable unit 160 are branched in the terminal box 70, and the RRU 40 of each antenna 21 is branched, As shown in FIG. For example, a single optical fiber unit 130, a pair of power line units 110, and an AISG cable unit 160 form a combination inside the terminal box 70, The cable may be connected to the RRU 40 described above.

As described above, the photoelectric hybrid cable according to one embodiment of the present invention includes an optical fiber unit for transmitting and receiving an optical signal, a power line unit for transmitting power, and an AISG cable unit for transmitting a RET signal for controlling the electrical tilting of the antenna It is possible to prevent the loss of the conventional coaxial feeder line, thereby improving the efficiency of the entire system, reducing the cable installation time and cost, and protecting the optical fiber unit, the AISG cable unit, and the power line unit from external force .

In addition, the photoelectric composite cable according to an embodiment of the present invention includes a metal protective layer in the form of a corrugated tube, and the inner diameter of the corrugated tube is made smaller than the outer diameter of the inner cable core, . Thus, even when the photoelectric composite cable according to the embodiment of the present invention is installed in a vertical direction such as a tower, the cable core of the photoelectric composite cable is securely fixed without causing a problem of falling downward due to gravity Can be installed.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims. . It is therefore to be understood that the modified embodiments are included in the technical scope of the present invention if they basically include elements of the claims of the present invention.

100 .. Photoelectric Composite Cable
105 .. Cable core
110 .. Power line unit
113. Conductor
115 .. Insulator
130 .. Optical fiber unit
133 .. Optical fiber
135. Tube
137 .. Tension material

Claims (8)

A photoelectric hybrid cable for transmitting a mobile communication signal and electric power in a mobile communication base station having a plurality of base station equipments and a plurality of antennas,
Wherein the photoelectric composite cable comprises:
At least one power line unit having a conductor and an insulator surrounding the conductor, the at least one power line unit transmitting the power;
An optical fiber unit comprising a plurality of optical fiber subunits each having an optical fiber and a tube accommodating the optical fiber, the optical fiber unit transmitting the mobile communication signal;
An AISG cable unit for transmitting a RET (Remote Electrical Tilting) signal for controlling electrical tilting of the antenna;
A metal protective layer surrounding the power line unit, the optical fiber unit, and the AISG cable unit; And
An outer coating layer formed outside the metal protective layer; And,
Wherein the power line units and the AISG cable unit are disposed along an outer periphery of the optical fiber unit. The method according to claim 1,
Wherein the AISG cable unit and the power line unit have substantially the same diameter. The method according to claim 1,
Wherein the AISG cable unit is in contact with neighboring power line units. The method according to claim 1,
Wherein the metal protective layer is formed with wrinkles in which the wrinkles and the wrinkles are repeatedly formed. 5. The method of claim 4,
When the power line units form a cable core disposed along the outer periphery of the optical fiber unit,
The outer diameter of the cable core is Dc, the inner diameter of the corrugation is Do, and the inner diameter of the corrugation is Di,
Di < Dc &lt; Do. 5. The method of claim 4,
Further comprising a filling material in an empty space of the cable core. The method according to claim 1,
If the base station equipment includes a remote radio unit (RRU), a remote control unit (RCU), or a central control unit (CCU)
Wherein the AISG cable unit connects the RCU and the CCU which are spaced apart from each other and transmits the RET signal from the CCU to the RCU so that the RCU controls the electrical tilting of the antenna. The method according to claim 1,
If the base station equipment includes a Tower Mounted Amplifier (TMA)
Wherein the AISG cable unit transmits a signal for controlling the TMA.

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