KR20230092411A - A maritime distress identification system - Google Patents

Abstract

A survivor identification system according to an embodiment of the present invention includes working clothes formed to be worn by a wearer and having a lifesaving function; a distress sending device mounted on the work clothes; and a distress identification device communicating with the distress sending device, wherein the distress sending device obtains a distress signal from the distress sending device and identifies the wearer's information and whether or not the wearer is in distress.

Description

Maritime Distress Identification System {A MARITIME DISTRESS IDENTIFICATION SYSTEM}

The present invention relates to a maritime survivor identification system, and more specifically, to a maritime survivor identification system including work clothes to which IoT technology is grafted in order to maximize survival probability in case of distress.

Maritime workers, such as fishermen, the navy, and the coast guard, often die of accidents at sea during work.

For prompt distress rescue activities, it is important that an inboard warning system such as a siren operates at the same time as a distress accident to notify colleagues on board and promptly identify the location of a person in distress.

In particular, life jackets that can increase buoyancy, maintain body temperature, and are convenient for everyday work are needed so that the survivors can survive on their own until rescue is performed.

Conventionally developed life jackets are mainly worn in the form of work clothes and vests, and there are various products for sending the location of a victim in distress, but there is a problem in that their use is not expanded because they are inconvenient to carry separately or to perform work due to their large size.

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

In particular, in preparation for a situation where it is impossible to respond in case of distress due to the aging of the working population and the increase in the number of single-person operators in coastal waters and coastal waters, simply connect your existing smartphone to the IoT Distress Identification Device and operate immediately even if you are in distress. It is configured to send a distress signal.

On the other hand, the following prior art documents are composed of a rope composed of a tension line having a loop fixed to the tension line in order to rescue a shipwrecked person at sea, and the rope is wrapped around the body of the shipwrecked person. However, the technical gist of the present invention is not disclosed.

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

A system for identifying a person at sea in accordance with an embodiment of the present invention aims at the following problems in order to solve the above problems.

In the event of a distress accident, it is a task to solve the problem of not missing the golden time for the rescue of the victim through the development of working clothes that can automatically transmit the distress signal and location and the identification system of the person in distress including the same.

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

A survivor identification system according to an embodiment of the present invention includes working clothes formed to be worn by a wearer and having a lifesaving function; a distress sending device mounted on the work clothes; and a distress identification device communicating with the distress sending device, wherein the distress sending device obtains a distress signal from the distress sending device and identifies the wearer's information and whether or not the wearer is in distress.

In the work clothes, at least one variable tightness tube accommodating an amount of air smaller than the maximum capacity is formed on the uppermost part of one side of the work clothes corresponding to the circumference of the wearer's body. As the air filled in the lower part rises upward by the upper part, it is preferable that the thickness of the upper part is changed to the thickness of the state in which the air is maximally accommodated therein and adheres to the circumference of the wearer's body.

The distress sending device may include a battery module; a water sensor for detecting whether the distress sending device is submerged; a GNSS receiver for generating coordinate information based on a received signal from a satellite; and a communication module provided for communication with the victim identification device.

When the communication module transmits a distress signal to the victim identification device at a preset first cycle based on the detection content of the water sensor, and receives a response signal corresponding to the distress signal from the victim identification device a preset number of times or more; Preferably, the communication module transmits a distress signal to the victim identification device at a predetermined second cycle, and the second cycle is shorter than the first cycle.

The distress sending device further includes a motion detection sensor for detecting a movement of the distress sending 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. It is preferable that the highest point is calculated based on the cycle of a storm or sea wave generated by using a detection value of the motion detection sensor.

The distress sending device may include an emergency button disposed to be manipulated by the wearer; a sound output means for outputting whether or not a distress signal has been transmitted by the communication module; It is preferable to further include; and a scintillation generating means provided to visually detect the wearer's position from the outside.

It is preferable to further include; an emergency power source for supplying power to at least one of a heating means provided inside the work clothes and the battery module.

The emergency power source may include a fan that rotates by at least one of seawater or sea wind introduced from the outside; speed increasing means for increasing the rotation of the fan; generating means for generating electric power based on rotation of the gearbox; Power storage means for storing the power produced by the power generation means; and a power distribution means for distributing and supplying the electric power stored in the power storage means to at least one of the heating means and the battery module.

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

The survivor identification system according to an embodiment of the present invention eliminates the inconvenience of life jackets at sea and promotes rapid transmission and reception of distress signals in case of distress, thereby maximizing the survival probability of the survivors.

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

1 is a conceptual diagram of a maritime survivor identification system according to an embodiment of the present invention.
2 is a schematic diagram of work clothes during construction of a maritime survivor identification system according to an embodiment of the present invention.
3 is a side cross-sectional view of work clothes during construction of a maritime survivor identification system according to an embodiment of the present invention.
FIG. 4 is a diagram illustrating a state change of a variable tightness tube of work clothes during construction of a maritime victim identification system according to an embodiment of the present invention.
5 is a block diagram schematically showing the detailed configuration of a distress sending device among configurations of a maritime survivor identification system according to an embodiment of the present invention.
6 is a block diagram schematically showing the detailed configuration of an emergency power source among configurations of a maritime survivor identification system according to an embodiment of the present invention.

With reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail, but the same or similar components are assigned the same reference numerals regardless of reference numerals, and redundant description thereof will be omitted.

In addition, in describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description will be omitted. In addition, it should be noted that the accompanying drawings are only for easily understanding the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

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

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

The work clothes 100 are configured to be worn by the wearer 10 and have a lifesaving function, and are preferably made of two or more layers of fabric.

Here, the fabric used for the work clothes 100 may be a neoprene material having buoyancy, excellent waterproofness, heat insulation and elasticity, and easy repair, but the present invention is not limited thereto. In other words, any alternative material that satisfies the above functions can be used.

As shown in FIG. 2, the work clothes 100 include a body portion 110 formed to surround the body of the wearer 10 and extending downward from the body portion 110 to protect both legs of the wearer 10. A pair of lower limbs 120 formed to surround and both ends are coupled to the front and rear upper ends of the torso 110 and include shoulder straps 130 fastened to the wearer's shoulders.

In particular, as shown in FIG. 3, the work clothes 100 of the present invention have one side of the upper part of the torso 110 corresponding to the circumference of the upper part of the torso of the wearer 10 and each lower limb corresponding to the circumference of the lower part of the leg of the wearer 10. A variable tightness tube 140 accommodating a smaller amount of air than the maximum capacity may be formed inside one side of the lower end of the unit 120 .

The variable adhesion tube 140 is preferably formed to a thickness that can adhere to the wearer's body when maximum air is accommodated therein. It is preferable to be formed with a sufficient height so that the air corresponding to the maximum capacity can be filled at the upper end by floating.

Referring to FIG. 4, the variable tightness tube 140 will be examined in more detail. As shown in FIG. In normal times, it has a relatively thinner thickness than the thickness in a state where air is maximally accommodated therein.

When the wearer 10 enters the water due to a drowning accident, air filled in the lower part rises to the upper part due to the effect of the water pressure, which increases as the water pressure increases, as shown in FIG. 4(b). Accordingly, the thickness of the upper portion has the same thickness as the thickness of the state in which air is maximally accommodated therein.

That is, in the case of normal times, as shown in FIG. 4(a), the wearer 10 does not have a problem in which the activity of the wearer 10 is reduced by maintaining a separation state between the body of the wearer 10 and the variable adhesion tube 40, and the wearer 10 If you fall into water, a part of the upper body of the wearer 10 can be lifted to the surface of the water by the variable adhesion tube 140 formed along the circumference of the upper end of the torso of the wearer 10, thereby providing psychological protection to the wearer 10 in the event of a drowning accident. It can provide stability.

The distress sending device 200 is configured to be mounted on the work clothes 100, and is preferably accommodated in a pocket created on the shoulder strap side of the work clothes 100, which will be described in detail later.

The survivor identification device 300 is disposed on the ship 20 and communicates with the distress sending device 200. It performs a function of receiving a distress signal such as whether there is a distress and a distress location, and transmitting it to the external control server 50 through the base station 40.

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

As shown in FIG. 5, the distress sending device 200 of the maritime survivor 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. configured to include

The battery module 210 is a component that performs a function of supplying power to various components included in the distress sending device 200 to be described later, and is preferably composed of a rechargeable lithium polymer battery.

The water sensor 220 is a component that performs a function of detecting whether the distress sending device 200 is submerged or not, and may be formed of a pair of conductive terminals for detecting whether or not the wearer 10 is in distress.

When water comes into contact with these conductive terminals, the current flowing between the two terminals can be amplified into a voltage to determine whether or not flooding occurs.

In particular, the water sensor 220 must be formed to be exposed to the outside for contact with external water, and can be integrally formed with the charging terminal for charging the battery module 210 described above, so that the distress sending device 200 It is desirable to achieve simplification and miniaturization of the configuration.

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

The communication module 240 is a component for communication with the above-mentioned person in 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 transmission device 200. ) is a configuration for transmitting location information and distress signals, etc. to the survivor identification device 300, and it is preferable to employ a LoRa communication module capable of low power and high performance communication in consideration of the characteristics of the distress sending device 200. .

On the other hand, it is desirable to minimize the power consumption of the battery module 210 in consideration of the distress situation of the wearer 10 for a long time, and it is possible to send a distress signal to the distress transmission device 200 for at least 72 hours after the distress situation occurs. It should be structured so that

To this end, the communication module 240 transmits a distress signal to the survivor identification device 300 at a preset first cycle based on the detection content of the water sensor 220, and the distress signal corresponding to the distress signal from the survivor identification device 300 When the response signal (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 victim identification device at a preset second cycle, wherein the second cycle is shorter than the first cycle. should be set.

This is a battery save function to ensure the operation of the distress sending device 200 for at least 72 hours when the wearer 10 is in distress. It is transmitted to the survivor identification device 300.

Thereafter, when the ACK signal indicating that the distress of the wearer 10 has been recognized is accumulated and received more than 5 times from the person in distress identification device 300, the communication module 240 transmits a distress signal such as location information of the wearer 10 at intervals of 1 minute is configured to

In addition, when the wearer 10 is in distress at sea, when the communication module 240 transmits a distress signal at the bottom of the sea wave, a loss of communication distance may occur, thereby causing distress transmitted from the distress sending device 200. The signal may not be smoothly transmitted to the victim identification device 300 .

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

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

The distress sending device 200 uses the motion detection sensor 250 in a situation where the sea wave rises and falls repeatedly to determine the highest point and period of the sea wave based on the change in angular velocity, and then, when reaching the highest point of the next sea wave, the communication module 240 ) to transmit the distress signal to the survivor identification device 300, it is possible to overcome the problem of transmitting the distress signal at the bottom of the sea wave.

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

The emergency button 260 is a component for the wearer 10 to directly operate the distress sending device 200 in a situation where a distress signal is not generated and transmitted due to an abnormality in the water sensor 220 .

The sound output means 270 is a component that performs a function of outputting a buzzer sound when the communication module 240 transmits a distress signal, and the wearer 10 confirms that the distress signal is 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 a function of outputting light, and through this, the location of the wearer 10 can be informed to the surroundings at night, and furthermore, it can be used in rescue by maritime air means such as a helicopter. .

In addition, the maritime survivor identification system according to an embodiment of the present invention can prevent the body temperature of the wearer 10 from dropping during distress by providing a heat generating means provided inside the work clothes 100, and power is supplied to the heat generating means. It may be provided with an emergency power source 400 for.

In particular, the emergency power source 400 may be configured to supply power not only to the heating means but also to the battery module 210 of the distress sending device 200 if necessary. Hereinafter, referring to FIG. 6, the emergency power source 400 ) to be explained in detail.

As shown in FIG. 6, the emergency power source 400 of the maritime victim 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. And it is configured to include a power distribution means (450).

The fan 410 has a plurality of blades and performs a function of rotating by at least one of seawater or sea wind introduced from the outside, and the speed increasing unit 420 functions to increase the rotation of the fan 410 .

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

The power distribution means 450 performs a function of distributing and supplying the electric power stored in the power storage means 440 to at least one of the heat generating means disposed inside the work clothes 100 and the battery module 210 of the distress sending 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, and at this time, a body temperature sensor for sensing the body temperature of the wearer 10 is used in work clothes. It is preferable to be provided in (100).

Describing 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 charge rate of the battery module 210 is above a preset value. In this case, the power distribution means 450 does not supply the power stored in the power storage means 440 to both the heating means and the battery module 210, and thus the power generated by the power generation means 430 is the power storage means ( 440) is stored continuously.

The second embodiment is a case where the body temperature of the wearer 10 is less than a preset temperature and the charge rate of the battery module 210 is equal to or greater than a preset value, and the power distribution means 450 uses the power stored in the power storage means 440. is preferentially supplied to the heating means.

The third embodiment is a case where the body temperature of the wearer 10 is higher than a preset temperature and the charging rate of the battery module 210 is lower than a preset value, and the power distribution unit 450 stores the power stored in the power storage unit 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 is a heating means and a battery module ( 210) is alternately supplied with power.

On the other hand, the first to fourth embodiments are based on the premise that power is sufficiently 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 is performed. The unit 450 should supply power to the heating unit and the battery module 210 in consideration of the amount of power generated by the power generation unit 430, the body temperature of the wearer 10, and the charging rate of the battery module 210.

It is not a problem when the power generation means 430 is sufficient when the power generation means 430 is sufficient, such as strong sea breeze blowing or strong inflow of sea water. When the temperature is lower than the temperature and the charge rate of the battery module 210 is lower than the preset value, the power storage means 440 performs a first step of cutting off the power supply, a second step of supplying power to the battery module 210, and supplying power. The third step of blocking the and the fourth step of supplying power to the heating means may be sequentially performed.

The progress time for each step may be set differently by comprehensively considering the amount of power generation, the body temperature of the wearer 10, and the charging rate of the battery module 210, and may be changed in real time according to circumstances.

In the above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted according to the appended claims. In addition, 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 sending device
300: castaway identification device
400: emergency power source

Claims (5)

Work clothes formed to be worn by the wearer and equipped with a lifesaving function;
a distress sending device mounted on the work clothes; and
a distress identification device communicating with the distress transmission device;
including,
The maritime survivor identification system according to claim 1 , wherein the distress identification device obtains a distress signal from the distress transmission device and identifies the wearer's information and whether or not the person is in distress.
The method according to claim 1, wherein the work clothes,
At least one variable tightness tube accommodating an amount of air less than the maximum capacity is formed on the uppermost part of one side of the work clothes corresponding to the circumference of the wearer's body,
When the variable adhesion tube is introduced into water, the air filled in the lower end rises upward by water pressure, and the thickness of the upper end is changed to the thickness of the state in which the air is maximally accommodated therein, and is in close contact with the circumference of the wearer's body. maritime castaway identification system.
The method according to claim 1, wherein the distress sending device,
battery module;
a water sensor for detecting whether the distress sending device is submerged;
a GNSS receiver for generating coordinate information based on a received signal from a satellite; and
a communication module provided for communication with the victim identification device;
A maritime castaway identification system comprising a.
The method of claim 3,
The communication module transmits a distress signal to the victim identification device at a predetermined first cycle based on the detection contents of the water sensor,
When a response signal corresponding to a distress signal is received from the survivor identification device a preset number of times or more, the communication module transmits a distress signal to the survivor identification device at a preset second cycle;
The second period is shorter than the first period.
The method according to claim 3, wherein the distress sending device,
an emergency button disposed to be operated by the wearer;
a sound output means for outputting whether or not a distress signal has been transmitted by the communication module; and
Flash generation means provided to visually determine the location of the wearer from the outside;
The maritime castaway identification system further comprising a.

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