KR101685563B1 - Light systemline for underwater - Google Patents

Abstract

A light line system for underwater according to an embodiment of the present invention relays bidirectional communication between an underwater worker working underwater and an external worker working outside and connects the underwater and the outside so that the underwater worker Wherein the first sound wave generating module is configured to convert a sound related to the first information of the underwater operator into a sound wave, and a second sound wave generating module A first underwater communication unit having a first sound conversion module for converting sound waves related to information into sound and a first amplification unit for amplifying a sound wave converted into the first sound wave generation module or a sound converted into the first sound conversion module, A second sound wave generating module for converting a sound related to the second information of the external worker into a sound wave, a sound wave relating to the first information of the underwater worker And a second amplifying unit for amplifying the sound converted into the second sound wave generating module or the sound converted into the second sound converting module, a second underwater communicating unit including the second underwater communicating unit, And an audio signal corresponding to the second information is provided to the second sound wave generating module, and the sound converted into the second sound converting module is received as an electrical signal A communication unit for transmitting an electrical signal relating to the first information and an electrical signal relating to the second information, and a communication unit for surrounding the communication unit so as not to be exposed to the outside, Wherein the enclosing portion is capable of preventing water from flowing into the communication portion in the water, have.

Description

Light systemline for underwater

More particularly, the present invention relates to a light line system for submerging, which relays bidirectional communication between an underwater worker working underwater and an external worker working outside, and connecting the underwater and the outside to the underwater worker, And is prevented from drifting in the water.

In general, an example of a lighting device used in water is used in a bathtub or a fountain to produce various visual effects, and also to provide advertisement lighting in shallow water.

In the case of underwater lighting, it is installed at shallow water depth, so it can be used underwater by technical treatment of general waterproof level.

However, in order to illuminate underwater in a place with a deep water such as sea, it is required to solve technical problems such as breakage of the lighting device by water pressure and occurrence of water leakage.

An example of an LED underwater illumination device that can be used in such a deep sea is the registered patent 10-1297069 (Registered August 9, 2013, a deepwater LED underwater illumination device using a pressure compensator).

The above-mentioned Patent No. 10-1297069 discloses a structure in which pressure can be adjusted according to the water depth by using a pressure compensator, but it is specified to be used by being mounted on the hull of AUV.

Such a conventional technique can not be used as illumination for guiding the diver's sight and to guide the diving position, and is mounted on the AUV for use as exploration illumination while adjusting the angle.

For example, when a submarine is submerged directly into the sea for the purpose of rescue or lifting of a person on a sinking ship, it may be difficult to secure the visibility, and in particular, in order to guide the structure or lifting position, However, if there are a plurality of power lines for supplying power to each of a plurality of lights, a dangerous situation may occur when a diver hangs on a power line.

In addition, when the diver is working underwater, there is a need to separately provide a device capable of communicating between the diver and the external worker, and a problem has been urgently needed to solve this problem.

An object of the present invention is to relate bi-directional communication between an underwater worker working underwater and an external worker working outside, and connecting the underwater and the outside to prevent the underwater worker from being disconnected from the outside and drifting in the water A light line system for underwater having a stubbing function.

A light line system for underwater according to an embodiment of the present invention relays bidirectional communication between an underwater worker working underwater and an external worker working outside and connects the underwater and the outside so that the underwater worker Wherein the first sound wave generating module is configured to convert a sound related to the first information of the underwater operator into a sound wave, and a second sound wave generating module A first underwater communication unit having a first sound conversion module for converting sound waves related to information into sound and a first amplification unit for amplifying a sound wave converted into the first sound wave generation module or a sound converted into the first sound conversion module, A second sound wave generating module for converting a sound related to the second information of the external worker into a sound wave, a sound wave relating to the first information of the underwater worker And a second amplifying unit for amplifying the sound converted into the second sound wave generating module or the sound converted into the second sound converting module, a second underwater communicating unit including the second underwater communicating unit, And an audio signal corresponding to the second information is provided to the second sound wave generating module, and the sound converted into the second sound converting module is received as an electrical signal A communication unit for transmitting an electrical signal relating to the first information and an electrical signal relating to the second information, and a communication unit for surrounding the communication unit so as not to be exposed to the outside, Wherein the enclosing portion is capable of preventing water from flowing into the communication portion in the water, have.

The external communication unit of the underwater light line system according to an embodiment of the present invention may include an output unit for outputting the sound related to the first information and an input unit for inputting the silver for the second information.

The external communication unit of the light line system for underwater according to an embodiment of the present invention may further include an adjustment unit for adjusting the length of the transmission unit and a display unit for displaying the length of the transmission unit changed by the adjustment unit.

In the light line system for underwater light according to an embodiment of the present invention, the transmission unit may further include a light emitting unit formed along the longitudinal direction and emitting light, and the light emitting unit may have an intensifying function .

The first size of the light line system for underwater according to an embodiment of the present invention may be 2500 N / mm ² or more, and the length of the transmission portion may be 200 m or more.

According to the present invention, when fire occurs in large structures and underground facilities, effective fire suppression and personnel structure can be implemented by enabling communication between the field personnel and outside support personnel of firefighters due to the interruption of electricity and communication facilities .

In addition, it is possible to provide internal and external relaying and sound amplification of the existing fire-fighting radio or mobile communication line, and thus, it is possible to give utility to communication of firefighters.

In addition, even when a fire is caused by a flame-retardant or nonflammable coating material, it is possible to prevent light emission and communication interruption in the middle.

1 is a schematic perspective view showing an example in which an underwater light line system according to an embodiment of the present invention is used.
2 is a schematic perspective view illustrating a water line light line system according to an embodiment of the present invention;
3 and 4 are schematic views for explaining a light line system for underwater according to an embodiment of the present invention;

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

FIG. 1 is a schematic perspective view showing an example in which an underwater light line system according to an embodiment of the present invention is used.

1, a waterline light line system 1 (hereinafter referred to as a light line system 1) according to an embodiment of the present invention is a water line light line system in which an underwater worker working underwater and an external worker working externally communicate bidirectionally And an intensifying function for connecting the underwater and the outside to prevent the underwater worker from being disconnected from the outside and drifting in the water.

The light line system 1 is for solving the problem that the communication between the underwater worker and the support worker, that is, the external worker, is disconnected due to the inability of the underwater worker to perform the underwater work when the underwater worker is used for underwater structure / rescue work. It is based on a waterproof material and can be used for life-fighting work because it does not break even a strong algae.

In addition, the light line system 1 of the present invention is used not only in the above-described marine environment but also in the case of large structures and underground facilities, and under the condition that electricity and communication facilities are shut off in case of fire, And outside support personnel to maintain effective fire suppression and manpower structures.

FIG. 2 is a schematic perspective view illustrating a submerged light line system according to an embodiment of the present invention, and FIGS. 3 and 4 are schematic views for explaining a submerged light line system according to an embodiment of the present invention.

2 to 4, a water light line system 1 according to an embodiment of the present invention includes a first underwater communication unit 10, a second underwater communication unit 20, an external communication unit 30, (40).

The first underwater communication unit 10 and the second underwater communication unit 20 are located in the water and relay communication between the underwater worker and the external worker. The external operator communicates with the underwater operator through the external communication unit (30), and the underwater operator communicates with the external operator through the first underwater communication unit (10). The second underwater communication unit 20 plays a role of relaying the first underwater communication unit 10 and the external communication unit 30.

The first underwater communication unit 10 includes a first sound wave generating module 12, a first sound converting module 14, and a first amplifying unit 16.

The first sound wave generating module 12 converts sound related to the first information P of the underwater operator into sound waves. Here, the first information P is information including various situations or the like that occur during underwater work by the underwater worker, that is, information that the underwater worker wants to transmit to the external worker.

The first amplifying unit 16 amplifies the sound wave related to the first information P and transmits it to the second underwater communication unit 20. That is, the sound wave related to the first information P amplified by the first amplification unit 16 can be transmitted to the second underwater communication unit 20 without loss.

The first voice conversion module 14 converts the sound wave related to the second information (Q) of the external worker into voice. The sound related to the second information Q is converted into a sound wave by the second sound wave generating module 22 to be described later and the sound wave thus converted is amplified by the second amplifying unit 26, ). At this time, the first voice conversion module 14 converts the sound wave related to the second information (Q) into voice and transmits it to the underwater worker.

Here, the voice relating to the second information (Q) converted by the first voice conversion module (14) is amplified by the first amplification part (16) so that the underwater worker can recognize a larger and clear voice.

Meanwhile, the second underwater communication unit 20 includes a second sound wave generating module 22, a second sound converting module 24, and a second amplifying unit 26.

The second sound wave generating module 22 converts sound related to the second information (Q) of the external operator into sound waves. Here, the second information (Q) is information including information on various external conditions or the like that occur during underwater work by the underwater worker, that is, information that the external worker wants to deliver to the underwater worker.

The second amplifying unit 26 amplifies the sound wave related to the second information Q and transmits the amplified sound wave to the first underwater communication unit 10. That is, the sound wave related to the second information (Q) amplified by the second amplifying unit 26 can be transmitted to the first underwater communication unit 10 without loss.

The second voice conversion module 24 converts the sound wave related to the first information P of the underwater operator into voice. The sound related to the first information P is converted into a sound wave by the first sound wave generating module 12 and the sound wave thus converted is amplified by the first amplifying unit 16 and is then supplied to the second sound converting module 24 . At this time, the second sound conversion module 24 converts the sound wave related to the first information P into sound and delivers it to an external worker.

Here, the voice relating to the first information P converted by the second voice conversion module 24 is amplified by the second amplification unit 26 so that the external operator can recognize a larger and clear voice.

The external communication unit 30 is connected to the second underwater communication unit 20 through the transmission unit 40. The external communication unit 30 transmits an electric signal relating to the second information Q so that the sound related to the second information Q is provided to the second sound wave generating module 22, Is received as an electrical signal and output so that it can be recognized by an external operator.

More specifically, the external communication unit 30 includes an output unit for outputting the voice relating to the first information P and an input unit for inputting the voice relating to the second information Q. The output section is a kind of speaker for outputting sound, and the input section is a kind of microphone for inputting sound. That is, the user recognizes the information about the first information P to be delivered by the underwater worker through the output unit through a method of sound (voice), and the user also recognizes through the input unit the second information Q) through a method called sound (voice).

Specifically, the output unit may output audio data received from the communication unit or stored in the memory unit in a call signal reception, a call mode or a recording mode, a voice recognition mode, a broadcast reception mode, and the like. The output unit may include a receiver, a speaker, a buzzer, and the like.

The input unit receives an external acoustic signal by a microphone in a communication mode, a recording mode, a voice recognition mode, or the like, and processes it as electrical voice data. The processed voice data can be converted into a form that can be transmitted to the mobile communication base station through the mobile communication module and output when it is in the call mode. In addition, various noise reduction algorithms for eliminating noise generated in the process of receiving an external sound signal can be implemented.

The external communication unit 30 further includes an adjustment unit 32 for adjusting the length of the transmission unit 40 and a display unit 34 for indicating the length of the transmission unit 40 changed by the adjustment unit 32.

The regulating portion 32 is a kind of power transmission wire, which is wound or unwound by a member rotated by a power source supplied by the power supply portion so as to be adjusted in length. Here, the increase or decrease in the length of the transfer unit 40 is indicated by the display unit 34, so that the external operator can confirm the position of the second underwater communication unit 20 at the time of the operation.

The underwater worker can be connected to the second underwater communication unit 20 when an emergency occurs during underwater work, and can escape from the water by adjusting the length by the control unit 32.

The transmitting unit 40 connects the second underwater communication unit 20 and the external communication unit 30 and transmits an electrical signal relating to the first information P and an electrical signal relating to the second information Q And a surrounding portion having a tensile strength of a first size so as to surround the communication portion and the communication portion so as not to be exposed to the outside.

The communication unit may include at least one of a wired module, a wireless Internet module, a short distance communication module, and a location information module.

A wired module is an electrical signal module that is transmitted and received by a normal wire. The communication unit includes the PLC MODEM to connect the external communication unit 30 and the second underwater communication unit 20. The PLC MODEM is connected to the control board of the external communication unit 30.

Specifically, the external communication unit 30 further includes a battery set, a keypad, a monitor set, and a camera set. Specifically, the external communication unit 30 includes a LAN communication board, a battery and a charging / discharging circuit, a communication button, a camera module and a camera light, an emergency lighting PLC modem, a display, a TRS repeater, and a connector for ELWIRE connection.

The transmissive portion 40 is formed of an EL wire. Specifically, the transmissive portion 40 will be described in detail from the outer side to the inner side. The outer surface exposed to the outside is formed of a transparent Teflon coating, .

A tensile strength pile or piano wire is located at the center of the fluorescent coating, and three identical EL Wires are formed in a twisted twisted structure about the tensile strength? O piano or piano wire. That is, each EL wire along the ply or piano wire is contacted with a twist, which causes each EL wire to also be in a twisted position.

Here, in the EL WIRE, the EL electrode line is located at the center, and the fluorescent material and the transparent Teflon coating are sequentially positioned in the direction of the outside of the EL electrode line. Additional EL electrode lines may be located within the transparent Teflon coating.

Further, the string or piano wire for tensile strength forming the center of the transmitting portion 40 is minus, and the EL electrode line forming the EL WIRE acts as a plus to be used for communication in the communication unit.

The wireless Internet module refers to a module for wireless Internet access, and the wireless Internet module can be built in or externally connected to the communication unit. WLAN (WiFi), Wibro (Wireless broadband), Wimax (World Interoperability for Microwave Access), HSDPA (High Speed Downlink Packet Access) and the like can be used as wireless Internet technologies.

The short-range communication module is a module for short-range communication. Bluetooth, RFID, IrDA, UWB, ZigBee, WiHD, WiGig, and the like can be used as the short distance communication technology.

The location information module is a module for confirming or obtaining the location of the communication unit. A typical example of the location information module is a Global Position System (GPS) module. According to the present technology, the GPS module calculates information on a distance (distance) from three or more satellites to one point (object), information on the time when the distance information is measured, and then trigonometry is performed on the calculated distance information It is possible to calculate three-dimensional position information according to latitude, longitude, and altitude of one point (object) in one hour. Further, a method of calculating position and time information using three satellites and correcting the error of the calculated position and time information using another satellite is also used. The GPS module continuously calculates the current position in real time and uses it to calculate speed information.

The display unit 34 is formed of an LCD or an OLED for displaying a situation, displays information such as a wire breakage, a remaining battery level, etc., and may separately notify an emergency situation by displaying an emergency situation.

The enclosing part has a tensile strength of the first size so as to prevent the electric wires and the like of the communication part from being exposed to the outside so as to prevent the inflow of water into the communication part in the water.

Here, the first size means that the first size is at least 2500 N / mm ² , and the length of the transmission unit 40 is at least 200 m. The first size and the length of the transmission unit 40 may vary according to the user's setting.

As described above, when an emergency occurs during the underwater work of the underwater worker, the transfer unit 40 is connected to the second underwater communication unit 20 and escapes from the water by adjusting the length by the adjustment unit 32 The magnitude of the tensile force is an important factor to make it possible. That is, the adjusting unit 32 is provided with a stiffening function.

Further, the transmitting unit 40 includes a light emitting unit that is formed along the longitudinal direction and emits light, and the light emitting unit is identifiable in the water.

The light emitting portion is a kind of EL wire (emission inducing line). The light emitting part can be used to measure the distance by using products of different colors and brightness step by step for every 20m of EL wire for rescue / rescue work, large structures and underground facilities.

On the other hand, when the light line system 1 of the present invention is used for fire occurrence for large structures and underground facilities, the surrounding portion is formed of a flame retardant material and is prevented from being damaged / damaged by high temperature.

For example, in the case of a large structure and an underground facility, the high frequency speaker operation (pattern use) of the external communication unit 30 and the operation pattern of the organic EL device line (blinking / lighting ).

In the case of large structures and underground facilities, it can be spread in emergency situations in the situation of radio communication short-circuit by a fixed-ring luminaires (small-sized squirrels) and high-frequency loudspeaker operation, .

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that such modifications or variations are within the scope of the appended claims.

1: Underwater light line system
10: first underwater communication section
12: first sound wave generating module
14: first voice conversion module
16:
20: second underwater communication section
22: second sound wave generating module
24: second voice conversion module
26:
30: External communication section
32:
34:
40:
P: First information
Q: The second information

Claims (5)

And an intensifying function for relaying bidirectional communication between an underwater worker working in the water and an external worker working from the outside and preventing the underwater worker from being disconnected from the outside and drifting in the water by connecting the underwater and the outside, In a light-water line system,
A first sound wave generating module for converting a sound relating to the first information of the underwater operator into a sound wave; a first sound converting module for converting a sound wave related to the second information of the external worker into sound; A first amplifying unit for amplifying a sound wave or a sound converted by the first sound converting module;
A second sound wave generating module for converting a sound relating to the second information of the external worker into a sound wave, a second sound converting module for converting the sound wave related to the first information of the underwater worker into sound, A second amplifying unit for amplifying a sound wave or a sound converted into the second sound converting module;
And a second audio conversion module connected to the second underwater communication unit for transmitting an electrical signal relating to the second information so that audio related to the second information is provided to the second sound wave generation module, An external communication unit for receiving the electric signal and outputting the electric signal so that the external operator can recognize the electric signal; And
A communication unit for transmitting an electrical signal related to the first information and an electrical signal relating to the second information, and a surrounding unit surrounding the communication unit so as not to be exposed to the outside, and having a surrounding unit having a tensile strength of a first size; / RTI >
Wherein the surrounding unit prevents water from flowing into the communication unit in the water. The method according to claim 1,
Wherein the external communication unit comprises:
And an input unit for inputting an audio output relating to the first information and an audio corresponding to the second information. 3. The method of claim 2,
Wherein the external communication unit comprises:
And a display unit for displaying the length of the transfer unit changed by the control unit, wherein the control unit controls the length of the transfer unit. The method according to claim 1,
[0030]
Further comprising a light emitting portion formed along the longitudinal direction and emitting light,
Wherein the light emitting unit is identifiable in the water. The method according to claim 1,
The first size is at least 2500 N / mm ² ,
Wherein the length of the transmission portion is 200 m or more.

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