KR20180109485A - In-building Communication repeater - Google Patents

Abstract

The present invention relates to a communication repeater coupled to a composite cable previously installed in a work site to solve a communication shadow region in a building site. The communication repeater comprises a composite terminal receiving a communication signal and power from the composite cable; a communication module transmitting the received communication signal to a connected communication terminal; and a power supply control module converting the received power and supplying power to the communication module.

Description

[0001] In-building Communication Repeater [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication repeater installed in a drying site of a ship or an offshore plant, and more particularly, to a communication repeater connected to a composite cable installed in a work site to solve a communication shadow area in a drying site.

In the field of building or constructing large ships and offshore plants, tens or hundreds of workers work together. In the field where many workers are building or constructing a ship or an offshore plant, the environment where mutual communication can be done frequently is very important. Until now, communication has not been smooth among workers in almost all workplaces. This is due to the fact that the large ships and offshore plant work sites are made up of many steel structures and the signals transmitted from the existing mobile communication network and wireless WiFi can not be easily reached to the operator's terminal. There have been problems and inconveniences in the offshore plant workshop where workers are carrying around a radio and communicating with other workers to the outside of the work site where there is no steel structure.

In addition, recently, interest in safety of life at ship or offshore plant work places has increased, and real-time communication between workers at the shipyard work site and location of worker are becoming major problems. In other words, for real-time communication between workers and grasping the position of the worker, communication environment should be established so that there is no shaded area at the ship or offshore plant work site. As described above, It is very difficult to establish a communication environment.

In order to solve the above-described problem, a power line communication technique has been proposed in which a communication signal is transmitted to a power source and transmitted. However, as a result of applying the power line communication to the actual dry site, it was concluded that excessive noise was introduced from the working environment and it could not be practically used. Therefore, current power line communication is not used in actual dry site.

Patent Registration No. 10-1478858 (Feb. 22, 2012)

Accordingly, it is an object of the present invention to provide a communication repeater, which is coupled to a composite cable installed in a work site to solve a communication shadow area in a drying site, in consideration of the above matters.

In order to achieve the above object, a communication repeater in a dry field according to the technical idea of the present invention includes a composite terminal for receiving a communication signal and electric power from a composite cable, a communication terminal for transmitting the received communication signal to a communication terminal And a power control module for converting the received power to supply power to the communication module.

The communication module receives the Ethernet signal of the conversion unit and converts the 2-line analog signal into an Ethernet signal. The communication module receives the Ethernet signal of the conversion unit, And an AP unit for transmitting the AP information.

The converting unit may include an Ethernet socket capable of wired connection to confirm normal operation of the converting unit and the AP unit.

The mobile communication terminal may further include a movement detection module for detecting movement of the in-the-field communication repeater.

The apparatus may further include a movement detection module for detecting an activity of an operator in the detection area.

The apparatus may further include an environment detection module for detecting the concentration and the temperature of the gas.

The broadcasting system may further include a broadcasting module for outputting a broadcasting signal transmitted from the central control system.

According to the on-site communication repeater as described above,

First, it is possible to solve the shaded areas in the ship or the drying site of the plant.

Second, it collects the environmental information of the location where the communication repeater is installed, detects the occurrence of the dangerous situation, and warns the operator, thereby enabling the safe work of the operator.

Third, since only one composite cable can be installed without separately installing the telephone cable and the power cable, it is easy to replace the cable requiring frequent replacement, and the maintenance cost is greatly reduced.

Fourth, by providing a multi-connector capable of dividing and distributing a communication signal or power, a communication signal or electric power can be supplied regardless of equipment or terminal type installed at a work site. Accordingly, Can be used.

1 shows an example in which a composite cable, a multi-connector and a communication repeater are applied in a ship drying site.
Fig. 2 schematically shows a hub of a distribution board and a communication signal extending from the main MLC connected to a communication repeater via a composite cable. Fig.
3 is a configuration diagram of a communication repeater according to an embodiment of the present invention;
Fig. 4 is a view showing a combination of a composite cable and a multi-connector extending in a distribution board, and a system in which a communication repeater and a power outlet are connected to a multi-connector.
5 is a view showing an internal configuration of a composite cable.
6 is a cross-sectional view of a fabricated composite cable.
7 is a view showing a detailed structure of a multi-connector.

The in-the-field communication repeater 300 according to the embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Referring to FIGS. 1 and 2, the embodiment of the present invention is a technology for solving the problem of inability to communicate in a giant structure such as a ship or an offshore plant when drying, and general wireless communication is applied to a plurality of steel structures In order to solve the problem that smooth communication can not be achieved, a technique for disposing a communication repeater 300 in various places in a complex cable 100 installed in a work site to eliminate a communication shadow area.

The communication repeater 300 according to an exemplary embodiment of the present invention enables communication of a received communication signal with another communication terminal, e.g., a wired computer, or a portable terminal of a wirelessly connected worker.

3, the in-the-field communication repeater 300 according to an exemplary embodiment of the present invention includes a composite terminal 390 for receiving a communication signal and power from the composite cable 100, And a power control module 380 for converting the received power and supplying power to the communication module 310. [

The composite cable 100 includes a telephone cable and a power cable at the same time. The composite cable 100 is preferably composed of three lines to which AC power is supplied and two lines to which a communication signal is supplied.

The composite terminal 390 includes a socket and an electrode that can be combined with a composite cable 100 composed of three power lines and two communication lines. When the composite cable 100 is coupled to the composite terminal 390, three lines for supplying power are connected to the power control module 380, and two lines for supplying communication signals are connected to the communication module 310 .

The power control module 380 supplies power to the configuration contained in the communication repeater 300. When the power supplied from the composite terminal 390 is AC power, the power control module 380 may be configured as an AC / DC converter to supply DC power to the configuration included in the communication repeater 300. In addition, the power control module 380 is provided with a noise filter to remove noise from the power received by the composite cable 100, thereby more reliably supplying power to the configuration of the communication repeater 300.

 The communication signal received at the composite cable 100 is a two-line analog signal received via a telephone cable. The communication module 310 includes a conversion unit 312 for converting the 2-line analog signal into an Ethernet signal, and an AP unit 314 for receiving the Ethernet signal of the conversion unit 312 and transmitting the Ethernet signal to the communication terminal connected thereto.

The converting unit 312 converts an analog signal supplied to the composite cable 100 into an Ethernet signal and converts the Ethernet signal received from the AP unit 314 into an analog signal to be transmitted to the composite cable 100. The analog signal transmitted to the composite cable 100 is connected to the main MLC of the central system which provides the communication signal to the drying site. The main MLC converts the analog signal to the Ethernet signal and transmits it to the hub connected to the external communication system .

The converting unit 312 preferably includes an Ethernet socket capable of wired connection to confirm normal operation of the converting unit 312 and the AP unit 314. [ A plurality of Ethernet sockets may physically be provided on one side of the conversion unit 312, one of the plurality of Ethernet sockets may be connected to the AP unit 314, and the remaining Ethernet sockets may be redundantly provided for a separate wired connection . In order to check the normal operation of the communication repeater 300, the communication speed, the signal strength, etc., the operator can wire the notebook or the separately provided inspection device to the Ethernet socket provided in the conversion unit 312.

The AP unit 314 receives the Ethernet signal of the converting unit 312 and communicates with the connected communication terminal. The AP unit 314 wirelessly transmits an Ethernet signal such as Wi-Fi to communicate with an internal or external person by communicating with an operator's mobile phone, a wearable device, a portable device dedicated to the workplace, It is possible to provide necessary information. The information required by the operator may include work instructions, accident situations, and the like.

In addition, the communication repeater 300 according to an embodiment of the present invention may further include a movement detection module 320 for detecting that the communication repeater 300 is moved. The communication repeater 300 can perform an indoor positioning function for confirming the position of the operator in a complex and wide working environment. The communication repeater 300 is intermittently connected to the composite cable 100 installed in the workplace to remove the shaded area in the workplace and the unique number and installation location of each communication repeater 300 are registered in the central control system The position of the operator can be tracked by which communication repeater 300 the operator's portable device is connected to. However, when the communication repeater 300 is moved from an existing position, there is a difference from the registered position in the central control system, so that the position of the worker can not be accurately grasped, and a communication shadow area may occur in the workplace. The movement detection module 320 reports that the communication repeater 300 has been moved to the central control system when the movement of the communication repeater 300 is detected. The administrator who recognizes that the communication repeater 300 has moved can access the communication repeater 300 and restore the original position, or re-register the corrected position in the central control system.

 The movement detection module 320 may include a gyroscope sensor that detects a change in the posture.

In addition, the movement detection module 320 may perform a function of detecting an activity of an operator in the detection area. If the movement detection module 320 includes a sensor capable of identifying an adjacent object such as an ultrasonic sensor or an infrared sensor, the activity of the worker or the work vehicle around the communication repeater 300 can be detected. The central control system can identify the operator's identity through the electronic equipment of the worker connected to the AP unit 314 and can more accurately discriminate the worker's position with the activity information detected by the movement detection module 320. [

In addition, the communication repeater 300 according to an embodiment of the present invention may include an environment detection module 330 for detecting concentration and temperature of the gas. When gas used for a drying operation leaks or a fire occurs, the environmental detection module 330 can detect a dangerous situation in advance and report it to the central control system. The hazard conditions detected by the environmental detection module 330 may be provided to each operator to help them avoid access to hazardous areas or to evacuate. The type of gas detected by the environment detection module 330 may be oxygen, carbon monoxide, carbon dioxide, or the like. In addition, the environment detection module 330 can additionally detect humidity.

In addition, the communication repeater 300 according to an embodiment of the present invention may include a broadcasting module 340 for outputting a broadcasting signal transmitted from the central control system. Operators may not be able to quickly identify operational instructions or risk situations provided to mobile devices due to noise and other factors. The broadcasting module 340 outputs the broadcasting signal transmitted from the central control system, so that it is possible to promptly transmit a message to the operator. In addition, the broadcasting module 340 may be implemented to transmit the voice of the operator to the central control system so as to enable conversation among the operators.

In addition, the communication repeater 300 according to an embodiment of the present invention may include a lighting module 360. The lighting module 360 is illuminated and can provide illumination to the operator and can be a means for easily identifying the position of the communication repeater 300. [ In addition, when the location where the communication repeater 300 is installed is determined as a dangerous area through the environment detection module 330, light of different colors may be lighted or repeatedly blinked, thereby visually warning the operator.

The communication module 310, the power control module 380, the movement detection module 320, the environment detection module 330, the broadcasting module 340, and the communication module 340 according to the embodiment of the present invention, The lighting module 360 and the composite terminal 390 may be embodied by being electrically connected to each other in one physical case.

4, in an embodiment of the present invention, a composite cable 100 extending from a main distribution board is branched through a multi-connector and one of the branched composite cables 100 is connected to a communication repeater 300 .

5, the composite cable 100 refers to a cable including the telephone cable 110 and the power cable 130 at the same time, and the distribution board 600 is connected to a data communication cable and an electric cable And provides a communication signal and electric power to a work site with one composite cable 100. [

The composite cable 100 is for providing communication signals and electric power to a communication terminal installed in various places in a ship or an offshore plant operation site, typically a communication repeater 300 or a telephone, It improves problems that were very difficult.

In the case of constructing a network system by installing only one composite cable 100 on a job site, it is possible to reduce the cost Not only can be saved, but also the space occupied by the cable can be greatly reduced, thereby increasing the working space.

The composite cable 100 includes a power cable 130 consisting of a power cable of two cores and a core cable of a core and may include a telephone cable 110 of two lines.

The power cable 130 may preferably be a single phase AC 220V cable and the telephone cable 110 may be a CPEV cable. CPEV cable refers to a pair of cables in a polyethylene insulated vinyl sheath. CPEV cables are mainly used for telephone lines and security communication lines in certain areas. In addition, since CPEV cables use insulators with excellent moisture resistance, they are less susceptible to malfunction due to moisture, are highly resistant to voltage, can be arranged in parallel with transmission and distribution lines, are free from corrosion by cables, are relatively inexpensive, The CPEV cable is suitable for use in a work site. Therefore, the CPEV cable can be used to construct a network environment inherent to the composite cable 100 of the present invention .

Since the composite cable 100 is frequently installed and dismantled at the work site, the composite cable 100 can be realized as a stranded structure composed of a plurality of strands of one core, thereby further enhancing the durability of the cable.

The composite cable 100 may further include an additional protective layer such that the inner telephone cable 110 and the power cable 130 are coated 150 with a thermoplastic elastomer (TPE) material.

Meanwhile, the cover 150 surrounding the telephone cable 110 and the power cable 130 may be made of low smoke zero halogen (LSZH) material. The use of LSZH material is advantageous in that it can reduce the emission of toxic gas even if a fire occurs on the floating surface and prevent the spread of fire.

Although only the telephone cable 110 is referred to as means for transmitting a communication signal in the composite cable 100 in this description, it should be understood that an optical fiber can be used as a means for transmitting a communication signal. Utilizing the optical fiber as a means for transmitting communication signals enables not only voice signals but also large-volume data to be transmitted together, enabling more effective communication among workers.

6, the composite cable 100 includes a telephone cable 110 and a power cable (not shown) to prevent the telephone cable 110 or the power cable 130 from being fused to the cover 150 of the composite cable 100 130) of the nonwoven fabric 152 (see (b)). The sheath 150 of the composite cable 100, the power cable 130 and the telephone cable 110 can be melted and fused to each other by the heat generated from the power cable 130. Since the nonwoven fabric 152 contacts the telephone cable 110, And the power cable 130 are wrapped around the cover 150, it is possible to prevent a situation where the cover 150 is enclosed and a fusion splice is generated.

The composite cable 100 includes a first foil 154 surrounding the telephone cable 110 to block noise input to the telephone cable 110, a twisted wire 155 surrounding the first foil 154, And a second foil 156 surrounding the twisted wire 155 (see (d)).

Referring to FIG. 7, the multi-connector 200 is basically a device that is assumed to be connected to the composite cable 100, receives a communication signal and power through the composite cable 100, To another communication terminal connected to the communication terminal (200).

The multi-connector 200 includes a small-sized plastic injection molded article, that is, an inlet plug 210 into which the composite cable 100 is plugged into the housing 290, a distribution section for acquiring and distributing communication signals and electric power, And an outlet plug 230, 250, 270 through which a cable used to transmit a signal or power to an externally connected terminal is extended.

The multi-connector 200 contributes greatly to the maintenance cost of the entire network system in addition to the composite cable 100. In the worksite, many workers are moved, or the cable is broken or the cover 150 is peeled off during the process of moving the fixture and moving the work tools. In such a case, the cable breakage frequently occurs. Immediate maintenance is needed because it may interfere with the power supply required for the operation or indirectly lead to a short circuit or fire accident. The composite cable 100 and the multi-connector 200 are components that are very easy to replace. Even if the cable is damaged, the telephone cable 110, the power cable 130, It is possible to repair only the composite cable 100 connecting the cable 200 by partially replacing it.

The multi-connector 200 largely includes an inlet plug 210, a distribution portion (dotted rectangle), outlet plugs 230, 250 and 270, and a housing 290.

The inlet plug 210 is a portion where the composite cable 100 is directly connected to the multi-connector 200. More specifically, the inlet plug 210 includes a telephone cable 110 and a power cable 130 in the composite cable 100, a 5-pin plug 213 extending therefrom, and a connection pin 215 for fixing the cable do.

The distribution unit of the multi-connector 200 performs a function of extracting and distributing a communication signal or power from the plug-in composite cable 100 (the center rectangular dotted line inner region in Fig. 7 is a distribution unit). The multi-connector 200 includes two or more outlet plugs. The distribution unit receives a communication signal or signal from the composite cable 100 depending on whether the resource supplied to the outside via the outlet plug is a communication signal, a power, Extract power.

At this time, the multi-connector 200 may further include a converter (not shown) for converting an AC voltage to a DC voltage. Since the power provided through the composite cable 100 is based on an AC voltage, a device driven only by a DC voltage may exist in the multi-connector 200, so that a device connected to the multi- Regardless of whether a voltage is used, it is possible to provide an appropriate current.

Meanwhile, the distributing unit may be configured to contact the cable with the outlet plugs 230, 250, 270 to extract a communication signal or power. In another embodiment, an active circuit device, for example, an integrated circuit such as an ASIC The communication signal and the electric power can be extracted from the composite cable 100 and managed by the manager directly (signal amount and power amount control). That is, it should be understood that there is no limitation in the internal implementation method as long as the distribution unit can extract a communication signal or power from the composite cable 100 and transmit it to each of the outlet plugs 230, 250, and 270.

Next, the output cable 500 is a portion through which the outlet plugs 230, 250, and 270 extend, and collectively refers to a communication signal, a power, or a communication signal extracted by the distribution unit and a cable through which electric power is transmitted. Each of the output cables 500 may be different from each other. The output cable 500 may be the same as the composite cable 100, or may include an output cable 500 that transmits only a communication signal, only an output cable 500, And an output cable 500 for transmitting the data.

In addition, it is to be understood that the plurality of outlet plugs 230, 250, and 270 have the same outer shape, but different resources may be transmitted depending on the type of the output cable connected to the plug. The first outlet plug 230 may include a connection pin 215 connected to the power cable so as to output only electric power. The third outlet plug 270 may include a composite cable And a connection pin 215 connected to the connector 100.

The multi-connector 200 includes a total of three outlet plugs. For the sake of convenience, the first outlet plug 230 outputs only power, the second outlet plug 250, The third outlet plug 270 may be adapted to output a communication signal and power.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

100: Composite cable 200: Multi connector
300: communication repeater 310: communication module
312: conversion unit 314: AP unit
320: movement detection module 330: environment detection module
340: broadcasting module 360: lighting module
380: Power control module 390: Composite terminal
642: Network switch hub 644: Main communication controller

Claims (8)

A composite terminal for receiving communication signals and power from the composite cable;
A communication module for transmitting the received communication signal to a connected communication terminal;
And a power control module for converting the received power to supply power to the communication module. The method according to claim 1,
The communication signal received at the composite cable is a two-line analog signal,
Wherein the communication module includes a conversion unit converting the two-line analog signal into an Ethernet signal, and an AP unit receiving the Ethernet signal of the conversion unit and transmitting the Ethernet signal to a communication terminal connected thereto. 3. The method of claim 2,
Wherein the conversion unit includes an Ethernet socket capable of wired connection to confirm normal operation of the conversion unit and the AP unit. The method according to claim 1,
Further comprising a movement detection module for detecting movement of the in-situ communication repeater. The method according to claim 1,
And a movement detection module for detecting an activity of an operator within the detection area. The method according to claim 1,
Further comprising an environment detection module for detecting the concentration and the temperature of the gas. The method according to claim 1,
And a broadcasting module for outputting a broadcast signal transmitted from the central control system. A composite terminal for receiving communication signals and power from the composite cable;
A communication module for transmitting the received communication signal to a connected communication terminal;
A power control module for converting the received power to supply power to the communication module;
A movement detection module for detecting an activity of a worker in a movement or detection area of the in-situ communication repeater,
An environment detection module for detecting the concentration and the temperature of the gas,
And a broadcasting module for outputting a broadcast signal transmitted from the central control system,
The communication signal received at the composite cable is a two-line analog signal,
Wherein the communication module includes a conversion unit converting the two-line analog signal into an Ethernet signal, and an AP unit receiving the Ethernet signal of the conversion unit and transmitting the Ethernet signal to a communication terminal connected thereto,
Wherein the conversion unit includes an Ethernet socket capable of wired connection to confirm normal operation of the conversion unit and the AP unit.

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