KR102632000B1 - A maritime distress identification system - Google Patents

Abstract

A victim identification system according to an embodiment of the present invention includes work clothes that are designed to be worn by the wearer and have a life-saving function; A distress transmitting device mounted on the work clothes; and a distress identification device that communicates with the distress transmission device, wherein the distress identification device acquires a distress signal from the distress transmission device and determines the wearer's information and whether the wearer is in distress.

Description

{A MARITIME DISTRESS IDENTIFICATION SYSTEM}

The present invention relates to a maritime casualty identification system, and more specifically, to a maritime casualty identification system that includes work clothes incorporating IoT technology to maximize the probability of survival in case of distress.

Marine workers, such as fishermen, the navy, and the coast guard, often die in marine crashes while on the job. Prompt rescue activities in the event of a fall accident are the most essential factor in reducing deaths and disappearances.

For rapid distress rescue activities, it is important that the ship's warning system, such as a siren, is activated at the same time as a distress incident to notify colleagues on board and quickly identify the location of the person in distress.

In particular, a lifesaving suit that can increase buoyancy, maintain body temperature, and is convenient for everyday work is needed so that the person in distress can survive on their own until rescue is achieved.

Conventionally developed lifesaving suits are mainly in the form of workwear vests to be worn only as tops. There are various products for transmitting the location of victims, but there is a problem that their use cannot be expanded because they are inconvenient to carry separately or are large in size.

Therefore, there is a need for work clothes and a distress system with a new concept of life-saving function that does not interfere with normal work at all and has a function for survival in times of distress.

In particular, in preparation for situations where it is impossible to respond in case of distress due to the aging of the fishing population, the size of the water, and the increase in the number of single-person operators in coastal waters, simply connect your existing smartphone to the IoT distress identification device and immediately respond even if you become distressed while fishing. It was configured to send a distress signal.

Meanwhile, the following prior art document describes a rescue device and rescue method consisting of a rope composed of a tension line with a loop fixed to the tension line in order to rescue a shipwrecked person at sea, and where the rope is wrapped around the body of the shipwrecked person. is disclosed, but the technical gist of the present invention is not disclosed.

Republic of Korea Patent Publication No. 10-2003-0025268

The maritime distress identification system according to an embodiment of the present invention aims to solve the following problems in order to solve the above-mentioned problems.

The goal is to ensure that the golden time for rescuing victims is not missed through the development of work clothes that can automatically transmit distress signals and locations in the event of a distress accident, and a victim identification system that includes the same.

The problems to be solved by the present invention are not limited to those mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

A victim identification system according to an embodiment of the present invention includes work clothes that are designed to be worn by the wearer and have a life-saving function; A distress transmitting device mounted on the work clothes; and a distress identification device that communicates with the distress transmission device, wherein the distress identification device obtains a distress signal from the distress transmission device and determines the wearer's information and whether the wearer is in distress.

The workwear has at least one variable tightness tube that accommodates a smaller amount of air than the maximum capacity formed at the uppermost part of one side of the workwear corresponding to the wearer's body circumference, and when the variable tightness tube is introduced into water, water pressure As the air filled in the lower part rises to the upper part, the thickness of the upper part is preferably changed to a thickness where the air is maximally accommodated inside, so that it adheres closely to the wearer's body.

The distress transmitting device includes a battery module; A water sensor that detects whether the distress transmitting device is submerged; A GNSS receiver that generates coordinate information based on signals received from satellites; and a communication module provided for communication with the victim identification device.

The communication module transmits a distress signal to the distress identification device at a preset first cycle based on the detection contents of the water sensor, and when a response signal corresponding to the distress signal is received from the distress identification device more than a preset number of times, The communication module transmits a distress signal to the distress identification device in a preset second cycle, and the second cycle is preferably shorter than the first cycle.

The distress transmitting device further includes a motion detection sensor that detects movement of the distress transmitting device, and the communication module transmits a distress signal to the distress identification device when the wearer reaches the highest point of the sea wave. The highest point is preferably calculated based on the cycle of wind waves or sea waves generated using the detection value of the motion detection sensor.

The distress transmitting device includes an emergency button arranged to be operated by the wearer; Sound output means for outputting sound whether a distress signal is transmitted from the communication module; And it is preferable to further include a flash generating means provided to visually determine the position of the wearer from the outside.

It is preferable to further include an emergency power source that supplies power to at least one of the heating means and the battery module provided inside the workwear.

The emergency power source includes a fan rotating by at least one of seawater or sea breeze flowing in from the outside; Speed increasing means for increasing the rotation of the fan; Power generation means for producing electric power based on rotation of the gearbox; Power storage means for storing power produced by the power generation means; and a power distribution means for distributing and supplying the power stored in the power storage means to at least one of the heat generation means and the battery module.

Preferably, the power distribution means distributes and supplies the power based on the wearer's body temperature and the charging rate of the battery module.

The distress identification system according to an embodiment of the present invention can be expected to have the effect of maximizing the survival probability of distressed persons by resolving the inconvenience of life jackets at sea sites and promoting rapid transmission and reception of distress signals in times of distress.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description below.

1 is a conceptual diagram of a maritime distress identification system according to an embodiment of the present invention.
Figure 2 is a schematic diagram of work clothes included in the maritime casualty identification system according to an embodiment of the present invention.
Figure 3 is a side cross-sectional view of work clothes included in the configuration of the maritime casualty identification system according to an embodiment of the present invention.
Figure 4 is a diagram showing a change in the state of the variable tightness tube of the work clothes in the configuration of the maritime casualty identification system according to an embodiment of the present invention.
Figure 5 is a block diagram schematically showing the detailed configuration of a distress transmitting device in the maritime distress identification system according to an embodiment of the present invention.
Figure 6 is a block diagram schematically showing the detailed configuration of an emergency power source in the maritime distress identification system according to an embodiment of the present invention.

Preferred embodiments according to the present invention will be described in detail with reference to the attached drawings, but identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

Additionally, when describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted. In addition, it should be noted that the attached drawings are only intended to facilitate easy understanding of the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the attached drawings.

Hereinafter, a maritime distress identification system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6.

The maritime distress identification system according to an embodiment of the present invention is configured to include work clothes 100, a distress transmitting device 200, and a distress identification device 300, as shown in FIG. 1.

The work clothes 100 are designed to be wearable by the wearer 10 and have a life-saving function, and are preferably made of two or more layers of fabric.

Here, the fabric used for the work clothes 100 may be neoprene, which has buoyancy, excellent waterproofing, insulation, and elasticity, and is easy to repair, but the present invention is not limited thereto. , any alternative material that satisfies the above functions can be used.

As shown in FIG. 2, the work clothes 100 include a torso portion 110 formed to surround the torso of the wearer 10, and a torso portion 110 extending downward from the torso portion 110 to cover both legs of the wearer 10. It includes a pair of lower part 120 formed to surround the body part 120 and a shoulder strap part 130 where both ends are coupled to the front and rear tops of the body part 110 and fastened to the wearer's shoulder.

In particular, as shown in FIG. 3, the workwear 100 of the present invention has one upper part of the torso 110 corresponding to the circumference of the upper torso of the wearer 10 and each lower limb corresponding to the circumference of the lower legs of the wearer 10. A variable adhesion tube 140 that accommodates a smaller amount of air than the maximum capacity may be formed inside one side of the lower part of the unit 120.

This variable adhesion tube 140 is preferably formed with a thickness that allows it to be in close contact with the wearer's body when the maximum amount of air is accommodated inside. In particular, when it is introduced into the water and water pressure is applied, the air filled in the lower part flows to the upper part. It is desirable that it be formed at a sufficient height so that it can float and fill the upper part with air corresponding to the maximum capacity.

Hereinafter, looking at the variable tightness tube 140 in more detail with reference to FIG. 4, as shown in FIG. 4(a), the variable tightness tube 140 accommodates a smaller amount of air inside than the maximum capacity. Normally, it has a relatively thinner thickness than when the air is maximally accommodated inside.

When the wearer 10 enters the water due to a drowning accident, the air filled in the lower part floats to the upper part due to the influence of water pressure, which increases as the water pressure increases, as shown in FIG. 4(b). Accordingly, the thickness of the upper part becomes the same as the thickness when the air is maximally accommodated inside.

That is, in normal times, by maintaining the distance between the variable adhesion tube 40 and the body of the wearer 10 as shown in Figure 4 (a), the problem of deterioration of the activity of the wearer 10 does not occur, and the wearer 10 When falling into the water, part of the upper body of the wearer (10) can be raised above the water surface by the variable adhesion tube (140) formed along the upper circumference of the torso of the wearer (10), thereby providing psychological relief to the wearer (10) in the event of a drowning accident. It can provide a sense of stability.

The distress transmitting device 200 is mounted on the work clothes 100, and is preferably accommodated in a pocket created on the shoulder strap side of the work clothes 100, and details about this will be described later.

The distressed person identification device 300 is configured to be placed on the ship 20 and communicate with the distress transmitting device 200. The distressed person identification device 300 receives information about the wearer 10 from the distress transmitting device 200, It performs the function of receiving distress signals such as distress status and distress location, and transmitting them to the external control server (50) through the base station (40).

Hereinafter, the distress transmission device 200 will be described in more detail with reference to FIG. 5.

As shown in FIG. 5, the distress transmitting device 200 of the maritime distress identification system according to an embodiment of the present invention includes a battery module 210, a water sensor 220, a receiver 230, and a communication module 240. It is designed to include

The battery module 210 functions to supply power to various components included in the distress transmitting device 200, which will be described later, and is preferably made of a rechargeable lithium polymer battery.

The water sensor 220 is a component that performs a function of detecting whether the distress transmitting device 200 is submerged, and may be formed as a pair of conductive terminals for detecting whether the wearer 10 is in distress.

When water comes into contact with such a conductive terminal, the current flowing between the two terminals can be amplified to a voltage to determine whether or not there is flooding. Specifically, it can be configured to determine whether or not there is flooding by considering the characteristics between seawater and fresh water.

In particular, the water sensor 220 must be formed to be exposed to the outside for contact with external water, and can be formed integrally with the charging terminal for charging the battery module 210 described above, thereby providing the distress transmitting device 200 It is desirable to simplify and miniaturize the configuration.

The GNSS receiver 230 performs a function of generating coordinate information based on signals received from the satellite 30.

The communication module 240 is a component for communication with the above-described distress identification device 300, and based on the detection contents of the water sensor 220, the identification information of the wearer 10 and the wearer 10 are transmitted to the distress transmitting device 200. ) is configured to transmit location information and distress signals, etc. to the distress identification device 300, and considering the characteristics of the distress transmission device 200, it is desirable to adopt a LoRa communication module capable of low-power and high-performance communication. .

Meanwhile, considering the long-term distress situation of the wearer 10, it is desirable to minimize the power consumption of the battery module 210, and it is possible to transmit a distress signal to the distress transmitting device 200 for at least 72 hours after the distress situation occurs. It must be structured so that

To this end, the communication module 240 transmits a distress signal to the distress identification device 300 at a preset first cycle based on the detection contents of the water sensor 220, and transmits a distress signal corresponding to the distress signal from the distress identification device 300. When an ACK signal is received more than a preset number of times, the communication module 240 may be configured to transmit a distress signal to the distress identification device in a preset second cycle, where the second cycle is shorter than the first cycle. must be set to.

This is a battery save function to ensure the operation of the distress transmitting device 200 for at least 72 hours when the wearer 10 is in distress. For example, when the wearer 10 is in distress, the distress transmitting device 200 sends out a distress signal every 5 seconds for 5 minutes. It is transmitted to the distress identification device 300.

Afterwards, when the ACK signal indicating that the distress of the wearer 10 has been recognized is received from the distress identification device 300 more than 5 times, the communication module 240 transmits a distress signal such as location information of the wearer 10 at 1-minute intervals. It is configured to do so.

In addition, when the wearer 10 is distressed at sea, if the communication module 240 transmits a distress signal at the low point of the sea wave, loss of communication distance may occur, which may result in the distress transmitted from the distress transmitting device 200. The signal may not be transmitted smoothly to the distress identification device 300.

In order to prevent the above-described problem, the distress transmitting device 200 of the maritime distress identification system according to an embodiment of the present invention may further include a motion detection sensor 250 that detects the movement of the distress transmitting device 200. there is.

Here, the motion detection sensor 250 is preferably an acceleration sensor (G-Sensor) for detecting changes in the angular velocity of the distress transmission device 200 according to the rise and fall of sea waves.

The distress transmitting device 200 uses the motion detection sensor 250 to determine the highest point and cycle of the sea wave through changes in angular velocity in a situation where the sea wave repeatedly rises and falls, and then uses the communication module (240) when the highest point of the next sea wave is reached. ) to transmit a distress signal to the distress identification device 300, it is possible to overcome the problem of transmitting a distress signal at the low point of sea waves.

In addition, the distress transmitting device 200 may be configured to further include an emergency button 260, a sound output means 270, and a flash generating means 280.

The emergency button 260 is configured to allow the wearer 10 to directly operate the distress transmitting device 200 in a situation where a distress signal is not generated or transmitted due to a problem with the water sensor 220.

The sound output means 270 is configured to perform the function of outputting a buzzer sound when the communication module 240 transmits a distress signal, and the wearer 10 can confirm that the distress signal is being properly transmitted through the sound output means 270. By being able to recognize it, you can feel psychological stability.

The flash generating means 280 is a component that performs the function of outputting light. Through this, the location of the wearer 10 can be announced to the surroundings at night, and further, it can be utilized during rescue by marine aviation means such as a helicopter. .

In addition, the maritime distress identification system according to an embodiment of the present invention can prevent the body temperature of the wearer 10 from falling during distress by providing a heating means provided inside the work clothes 100, and power supply to this heating means. An emergency power source 400 may be provided for.

In particular, the emergency power source 400 may be configured to supply power not only to the heat generating means but also to the battery module 210 of the distress transmission device 200, if necessary. Hereinafter, with reference to FIG. 6, the emergency power source 400 ) will be explained in detail.

The emergency power source 400 of the maritime distress identification system according to an embodiment of the present invention includes a fan 410, a speed increasing means 420, a power generation means 430, and a power storage means 440, as shown in FIG. and a power distribution means 450.

The fan 410 has a plurality of blades and functions to rotate by at least one of seawater or sea breeze flowing in from the outside, and the speed increasing means 420 functions to increase the rotation of the fan 410.

The power generation means 430 performs the function of producing electric power by converting the rotational force of the gearbox into electric power, and the power storage means 440 performs the function of storing the power generated by the power generation means 430.

The power distribution means 450 performs the function of distributing and supplying the power stored in the power storage means 440 to at least one of the heating means disposed inside the work clothes 100 and the battery module 210 of the distress transmitting device 200. do.

In particular, the power distribution means 450 is configured to distribute and supply power based on the body temperature of the wearer 10 and the charging rate of the battery module 210. At this time, a body temperature sensor for sensing the body temperature of the wearer 10 is used in the work clothes. It is desirable to have it at (100).

When explaining an embodiment of power distribution of the power distribution means 450, first, in the first embodiment, the body temperature of the wearer 10 is above a preset temperature and the charging rate of the battery module 210 is above a preset value. In this case, the power distribution means 450 does not supply all of the power stored in the power storage means 440 to the heat generation means and the battery module 210, and as a result, the power generated by the power generation means 430 is supplied to the power storage means ( 440).

The second embodiment is a case where the body temperature of the wearer 10 is below the preset temperature and the charging rate of the battery module 210 is above the preset value, and the power distribution means 450 stores the power stored in the power storage means 440. is supplied preferentially to the heat generating means.

The third embodiment is a case where the body temperature of the wearer 10 is above the preset temperature and the charging rate of the battery module 210 is below the preset value, and the power distribution means 450 stores the power stored in the power storage means 440. is preferentially supplied to the battery module 210.

The fourth embodiment is a case where the body temperature of the wearer 10 is less than a preset temperature and the charging rate of the battery module 210 is less than a preset value, and the power distribution means 450 operates the heat generation means and the battery module ( 210), supply power alternately.

Meanwhile, the first to fourth embodiments are premised on the case where sufficient power is stored in the power storage means 440, and if the charging rate of the power storage means 440 is less than a preset value, power distribution The means 450 must supply power to the heating means and the battery module 210, taking into account the power generation amount of the power generation means 430, the body temperature of the wearer 10, and the charging rate of the battery module 210.

This is not a problem if the power production of the power generation means 430 is sufficient, such as when a strong sea breeze blows or sea water flows strongly, but the power production of the power generation means 430 is not large, and furthermore, the body temperature of the wearer 10 is not set in advance. When the temperature is below and the charging rate of the battery module 210 is below a preset value, the power storage means 440 performs a first step of blocking power supply, a second step of supplying power to the battery module 210, and power supply. The third step of blocking and the fourth step of supplying power to the heating means can be performed sequentially.

The progress time for each stage may be set differently by comprehensively considering the amount of power generation, body temperature of the wearer 10, and charging rate of the battery module 210, and may change in real time depending on the situation.

Above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to the specific embodiments and should be interpreted in accordance with the appended claims. Additionally, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

100: work clothes
200: Distress transmitting device
300: Distress identification device
400: Emergency power source

Claims (5)

Work clothes that are designed to be worn by the wearer and have life-saving functions;
A distress transmitting device mounted on the work clothes; and
A distress identification device that communicates with the distress transmitting device;
Including,
The distress identification device obtains a distress signal from the distress transmitting device and determines the wearer's information and whether he or she is in distress,
The distress transmitting device,
battery module;
A water sensor that detects whether the distress transmitting device is submerged;
A GNSS receiver that generates coordinate information based on signals received from satellites;
A communication module provided for communication with the victim identification device; and
An acceleration sensor for detecting changes in the angular velocity of the distress transmission device according to the rise and fall of sea waves;
Including,
The distress transmitting device extracts the change in angular velocity of the distress transmitting device using the acceleration sensor in a situation where sea waves repeatedly rise and fall, determines the highest point and cycle of the sea wave, and then communicates when the highest point of the next sea wave is reached. A maritime distress identification system characterized in that the module transmits the distress signal to a distress identification device.
The method of claim 1, wherein the work clothes are:
At least one variable tight tube that accommodates a smaller amount of air than the maximum capacity is formed at the uppermost part of one side of the workwear corresponding to the wearer's body circumference,
When the variable adhesion tube is introduced into the water, the air filled in the lower part rises to the upper part due to water pressure, and the thickness of the upper part is changed to the thickness in a state where the air is maximally accommodated inside, so that it adheres closely to the wearer's body. A maritime casualty identification system.
delete In claim 1,
The communication module transmits a distress signal to the distress identification device at a preset first cycle based on the detection contents of the water sensor,
When a response signal corresponding to a distress signal is received from the distress identification device more than a preset number of times, the communication module transmits a distress signal to the distress identification device at a preset second cycle,
A maritime distress identification system, characterized in that the second cycle is shorter than the first cycle.
The method of claim 1, wherein the distress transmitting device,
An emergency button arranged to be operated by the wearer;
Sound output means for outputting sound whether a distress signal is transmitted from the communication module; and
Flash generating means provided to visually determine the location of the wearer from the outside;
A maritime distress identification system further comprising:

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