KR20240034306A - Apparatus for emitting sonic sound for rescuing maritime distress - Google Patents

Abstract

The present invention includes a band portion 110 that is wrapped around and fixed to the user's specific body, a housing frame 121, a bobbin 122 that transmits vibration, and a sound wave signal in the audible frequency range that is coupled to the top of the bobbin 122. A sound wave generator 120 consisting of a diaphragm 123 with a watertight structure that transmits water underwater, a control module 125 that controls the application of current to the voice coil, a biometric sensor 130 that detects biological signals, and a diaphragm. Three or more seawater inlet holes 141 arranged at a certain distance apart in the border area of (123), a soluble barrier film 142 formed at the entrance of the seawater inlet hole 141, and seawater inflow exposed by dissolution of the barrier film 142. The control module 125, including a submersion detection unit 140 consisting of submersion sensors 143 that respectively detect seawater flowing into the hole 141, and a water pressure sensor 150 that detects water pressure, receives biological signals. By analyzing the user's normal situation and emergency situation, biometric information is generated, seawater flows into three or more seawater inflow holes (141) of the submersion sensor (143), continues for a certain period of time, and the water pressure sensor (150) Disclosed is a sound wave generator for maritime distress rescue that determines that the sound wave generator 120 is submerged when a certain water pressure is detected and transmits a sound wave signal containing biometric information underwater.

Description

Sound wave generator for maritime distress rescue {APPARATUS FOR EMITTING SONIC SOUND FOR RESCUING MARITIME DISTRESS}

The present invention collects the user's biometric signals to generate biometric information, determines whether the user is submerged without error using a submersion sensor and a water pressure sensor, and transmits a sound wave signal containing the biometric information into the water to provide rapid maritime disaster rescue. It relates to a sound wave generator for maritime distress rescue that can enable.

Normally, when a ship in operation runs aground or sinks, the crew and passengers on board the ship leave the ship and escape to the water, but as the ship is tilted due to the stranding or sinking, escape is not easy, so they must escape inside the ship, such as the cabin. You may become trapped in space.

In this way, floating survivors who escaped from the ship to the water can be visually identified by a rescue aircraft or rescue ship, allowing smooth rescue operations to be carried out in a short time. However, rescue operations are not easy for the crew and passengers trapped in the cabin. There is.

Meanwhile, in order to quickly rescue or salvage viable missing persons on a ship, the location of flooding in the sea area around the ship or the location of flooding within the ship must be more accurately identified.

Accordingly, technology is required to determine whether the crew and passengers are submerged and transmit sound wave signals underwater to enable rapid maritime disaster rescue.

Korean Patent Publication No. 10-2017-0077477 (Ship distress recognition device, 2017.07.06) Korean Patent Publication No. 10-2171300 (Underwater sound wave generation device and method, 2020.10.28)

The technical problem to be achieved by the idea of the present invention is to collect the user's biometric signals to generate biometric information, determine whether the user is submerged without error using an immersion sensor and a water pressure sensor, and transmit a sound wave signal containing the biometric information into the water. The purpose is to provide a sound wave generator for maritime distress rescue that can transmit sound waves to enable rapid maritime disaster rescue.

In order to achieve the above-described object, an embodiment of the present invention includes a band portion consisting of a strap whose length is adjustable and clamps formed at both ends of the strap, and wound around and fixed to a specific body of the user; A housing frame with a watertight structure attached and fixed to the outer surface of the strap, a bobbin formed inside the housing frame and inside a voice coil through which a current corresponding to sound information is conducted to transmit vibration, and the bobbin of the bobbin A sound wave generator consisting of a watertight diaphragm coupled to the top and transmitting sound wave signals in the audible frequency range underwater, and a control module for controlling the application of current to the voice coil; a biometric sensor that is attached and fixed to the inner surface of the strap and detects the user's biometric signals; It consists of three or more seawater inlet holes arranged at a certain distance apart in the border area of the diaphragm, a soluble barrier film formed at the entrance of the seawater inlet hole, and a submersion sensor that respectively detects seawater flowing into the seawater inlet hole exposed by dissolution of the barrier film. , flooding detection unit; and a water pressure sensor formed on a side of the sound wave generator to detect water pressure. Including, the control module generates biometric information by analyzing the biosignal to determine a normal situation and an emergency situation of the user, and the submersion sensor. When seawater flows into three or more seawater inflow holes and continues for more than a certain period of time, and a certain water pressure is detected by the water pressure sensor, the sound wave generator is determined to be submerged, and a sound wave signal containing the biometric information is transmitted underwater. Provides a sound wave generator for maritime distress rescue.

Here, the band portion is wrapped and fixed to cover the user's arms, legs, neck, or chest, and the biometric sensor is in close contact with the user's skin and can measure biometric signals such as body temperature, pulse, heart rate, movement, or number of steps. there is.

In addition, the submersion sensor measures the salinity concentration of seawater flowing into the seawater inlet hole, and when a salinity concentration above a certain concentration is detected, the control module may determine that the sound wave generator is submerged.

In addition, the submersion sensor measures the flow rate or weight of seawater flowing into the seawater inlet hole, and when a flow rate above a certain water level or seawater exceeding a certain weight is detected, the control module may determine that the sound wave generator is submerged.

In addition, the submersion sensor includes a first air bag that is contracted by seawater flowing into the seawater inlet hole, and a second air bag that communicates with the first air bag and expands by air exhausted by contraction of the first air bag. It includes an air bladder and a limit switch operated by expansion of the second air bladder, and whether or not the sound wave generator is submerged can be identified depending on whether the limit switch is in contact.

Additionally, the control module may analyze the biometric signals to determine the user's level of emergency or survival, generate the biometric information, and generate a sound wave signal including the biometric information.

Additionally, the barrier film may include starch of a certain thickness.

In addition, the sound wave generator includes GPS, and in a flood situation, the control module can convert location information about the current location using the GPS into sound waves and include it in the sound wave information.

In addition, the sound wave generator includes an LED module, and optical fibers that emit light guided from the LED modules are formed on both sides of the strap. When the control module determines that the situation is submerged, the optical fibers can be made to emit light. .

In addition, the sound wave generator includes a beacon module, and when the control module determines that the situation is flooded, it can transmit a beacon signal through the beacon module.

According to the present invention, biometric information is generated by collecting the user's biometric signals, and the user's submergence is determined without error using a submersion sensor and water pressure sensor, and a sound wave signal containing the biometric information is transmitted underwater to provide rapid resolution. It has the effect of making disaster relief possible.

Figure 1 shows a schematic configuration diagram of a sound wave generator for maritime distress rescue according to an embodiment of the present invention.
Figure 2 is an implementation of the sound wave generator for maritime distress rescue of Figure 1.
Figure 3 illustrates the planar structure and cross-sectional structure of the sound wave generator of the sound wave generator for maritime distress rescue of Figure 1.
FIG. 4 shows the submersion sensor of the sound wave generator of the sound wave generator for maritime distress rescue of FIG. 1 separated.
Figure 5 illustrates the submersion sensor of the sound wave generator for maritime distress rescue of Figure 1.
Figure 6 illustrates the operation of the beacon module of the sound wave generator for maritime distress rescue of Figure 1.

Hereinafter, embodiments of the present invention having the above-described features will be described in more detail with reference to the attached drawings.

The sound wave generator for maritime distress rescue according to an embodiment of the present invention includes a band portion 110 that is wrapped around and fixed to a specific body of the user, a housing frame 121, a bobbin 122 that transmits vibration, and the bobbin 122. A sound wave generator 120 consisting of a watertight diaphragm 123 that is coupled to the top and transmits sound wave signals in the audible frequency range underwater, and a control module 125 that controls the application of current to the voice coil, and a biological signal A biometric sensor 130 that detects, three or more seawater inlet holes 141 arranged at a certain distance apart in the border area of the diaphragm 123, and a soluble barrier film 142 formed at the entrance of the seawater inlet hole 141. , a submersion detection unit 140 consisting of a submersion sensor 143 that respectively detects seawater flowing into the seawater inlet hole 141 exposed by dissolution of the barrier film 142, and a water pressure sensor 150 that detects water pressure. Therefore, the control module 125 analyzes the biometric signals and determines the user's normal situation and emergency situation to generate biometric information, and seawater flows into three or more seawater inlet holes 141 of the submersion sensor 143. If it continues for more than a certain time and a certain water pressure is detected by the water pressure sensor 150, the sound wave generator 120 is determined to be submerged and transmits a sound wave signal containing biometric information into the water.

Hereinafter, with reference to the drawings, the sound wave generator for maritime distress rescue of the above-described configuration will be described in detail as follows.

First, referring to Figure 2, the band portion 110 is composed of an elastic strap 111 whose length is adjustable and a clamp 112 that is formed at both ends of the strap 111 and can be fastened to each other, so that the user's specific It is wrapped around the body so that it is fixed.

Next, the sound wave generator 120 is a component that transmits a sound wave signal when submerged underwater. Referring to Figures 2 and 3, the bottom surface is attached to the outer surface of the strap 111 and fixed to the watertight housing frame 121. ) and a bobbin 122 that is formed inside the housing frame 121 and is formed inside the voice coil through which current corresponding to sound information is conducted and transmits vibration, and is coupled to the top of the bobbin 122 to cover the audible frequency range. It consists of a watertight diaphragm 123 that transmits sound wave signals underwater, and a control module 125 that controls the application of current to the voice coil.

Here, the diaphragm 123 is coupled to the housing frame 121 in a watertight structure, but when in contact with seawater, water particles of seawater do not flow inside, and only sound wave signals in the audible frequency range pass through and are transmitted underwater. For example, a plurality of through holes 124 of 2000㎛ or less may be formed in the diaphragm 123, or it may be made of waterproof fabric with a water pressure of 10000mm or more.

Here, the control module 125 analyzes the biometric signals collected by the biometric sensor 130, determines the user's normal situation, degree of emergency, or survival, generates biometric information, and generates sound waves containing the biometric information. By generating a signal, it is possible to inform not only the user's location but also the degree of emergency or survival, so that maritime disaster rescue can be performed in response.

In addition, the sound wave generator 120 includes GPS, and in a flood situation, the control module 125 converts location information about the current location by GPS into sound waves and includes it in the sound wave information, so that accurate location information can be identified. You can do it as well.

In addition, the sound wave generator 120 includes an LED module 126, and optical fibers 113 that emit light guided from the LED module 126 are formed on both sides of the strap 111, and the control module 125 Judging by this submerged situation, the optical fiber 113 may be made to emit light to make visual identification easier when approaching the sound wave generator 120 by underwater rescue.

In addition, the sound wave generator 120 includes a beacon module 127 capable of short-distance communication, and when the control module 125 determines that the situation is submerged, it transmits a beacon signal through the beacon module 127, so that the underwater rescuer can use the sound wave. It is possible to approach a sunken ship through the sound wave signal from the generator 120, and by following the last beacon signal, the transmitting location within the ship, such as the bow, stern, and number of floors, can be accurately recognized and approached.

Next, the biometric sensor 130 is attached and fixed to the inner surface of the strap 111 opposite the attachment position of the sound wave generator 120, detects the user's biometric signal, and transmits it to the control module 125.

Meanwhile, the band portion 110 is wrapped and fixed to cover the user's arms, legs, neck, or chest, and the biometric sensor 130 is in close contact with the user's skin to detect biometric signals such as body temperature, pulse, heart rate, movement, or number of steps. can be measured, and the control module 125 can analyze body temperature, pulse, heart rate, movement, or number of steps to determine whether the user is in a normal situation or an emergency situation.

Next, the submersion detection unit 140 is a component that detects whether the sound wave generator 120 is submerged and detects whether the user is submerged because the vessel on which the user is aboard, such as a cruise ship, fishing boat, or cargo ship, is stranded or sinks. Specifically, Referring to Figures 3 and 4, three or more seawater inlet holes 141 arranged at a certain distance apart in the border area of the diaphragm 123, a soluble barrier film 142 formed at the entrance of the seawater inlet hole 141, and It consists of submersion sensors 143 that each detect seawater flowing into the seawater inlet hole 141 exposed by the dissolution of the barrier film 142.

For example, in a flooding situation, when the soluble barrier film 142 is in contact with seawater for a certain period of time, it is dissolved and seawater flows into the seawater inlet hole 141, and the submersion sensor 143 detects the inflowing seawater to allow the user to Flooding can be detected, and three or more seawater inlet holes (141) are arranged radially spaced apart, so that the control module (125) only detects when seawater flows into all three or more seawater inlet holes (141). It is judged based on the situation.

Meanwhile, the barrier film 142 contains starch of a certain thickness, so that upon contact with seawater, it decomposes without polluting the marine environment, exposing the seawater inlet hole 141.

In addition, the submersion sensor 143 measures the salinity concentration of seawater flowing into the seawater inlet hole 141, and when a salinity concentration above a certain level is detected, the control module 125 determines that the sound wave generator 120 is submerged. You may.

In addition, the submersion sensor 143 measures the flow rate or weight of seawater flowing into the seawater inlet hole 141, and when the flow rate above a certain water level or seawater above a certain weight is detected, the control module 125 detects the sound wave generator 120. may be judged to have been flooded.

In addition, as illustrated in FIG. 5, the submersion sensor 143 communicates with the first air bladder 143a, which is contracted by seawater flowing into the seawater inlet hole 141, and the first air bladder 143a, It includes a second air bag (143b) that is expanded by air exhausted by contraction of the first air bag (143a), and a limit switch (143c) that is operated by expansion of the second air bag (143b), and limits Whether or not the sound wave generator 120 is submerged can be identified depending on whether the switch 143c is in contact.

Next, the water pressure sensor 150 is a component that determines whether or not it is flooded, separately from the flood detection unit 140, and is formed on the side of the sound wave generator 120 to detect water pressure, so that the control module 125 Depending on the detected water pressure, the user's flooded situation can be identified.

Accordingly, the control module 125 generates sound waves when all seawater flows into the three or more seawater inlet holes 141 of the submersion sensor 143 and continues for more than a certain period of time, and a certain water pressure is detected by the water pressure sensor 150. It is determined that the generator 120 is submerged, and a sound wave signal containing biometric information is transmitted underwater, thereby responding to a rescue request signal through a sonar that identifies the direction, location, and distance of the target using sound waves even at a distance. By detecting the corresponding sound wave signal, maritime distress rescue can be made possible.

In addition, the sound wave generator 120 further includes a water temperature sensor 129, and the control module 125 determines a flooded situation when it detects a water temperature below a certain temperature, and the flooded sensor 143 and the water pressure sensor 150 By integrating and analyzing information from the water temperature sensor 129, it is possible to accurately determine whether the user is submerged without error.

Meanwhile, the sound wave generator 120 includes an oxygen concentration sensor 128, and the control module 125 converts information related to oxygen concentration into sound waves and transmits them to survivors in the air pocket formed in the sunken or stranded ship. It can also be used to identify situations.

In addition, the submersion sensor 143 includes a laser light-emitting module and a laser light-receiving module formed opposite the seawater inlet hole 141, and the control module 125 is a refractive index of the laser due to the seawater flowing into the seawater inlet hole 141. It is also possible to determine whether the sound wave generator 120 is submerged by detecting changes.

In addition, the sound wave generator 120 is illustrated as generating sound waves by being composed of the voice coil, bobbin, and diaphragm mentioned above, but it is composed of piezoelectric ceramic and repeats contraction and expansion by transmitting a voltage of a certain frequency to be underwater. Sound waves can also be generated by applying pressure.

Therefore, by the configuration of the sound wave generator for maritime distress rescue as described above, biometric information is generated by collecting the user's biosignals, and the user's submergence is determined without error by the submersion sensor and water pressure sensor, and the biometric information is generated. It is possible to enable rapid maritime disaster rescue by transmitting sound wave signals underwater.

The embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so various equivalents may be substituted for them at the time of filing the present application. It should be understood that variations and variations may exist.

110: Band portion 111: Strap
112: clamp 113: optical fiber
120: Sound wave generator 121: Housing frame
122: Bobbin 123: Vibration plate
124: Through hole 125: Control module
126: LED module 127: Beacon module
128: oxygen concentration sensor 129: water temperature sensor
130: Biometric sensor 140: Flood detection unit
141: Seawater inlet hole 142: Blocking membrane
143: submersion sensor 150: water pressure sensor

Claims (10)

A band portion consisting of a strap whose length is adjustable and clamps formed at both ends of the strap, and wrapped around and fixed to a specific body of the user;
A housing frame of a watertight structure attached and fixed to the outer surface of the strap, a bobbin formed inside the housing frame and inside a voice coil through which a current corresponding to sound information is conducted to transmit vibration, and the bobbin of the bobbin A sound wave generator consisting of a watertight diaphragm coupled to the top and transmitting sound wave signals in the audible frequency range underwater, and a control module that controls the application of current to the voice coil;
a biometric sensor that is attached and fixed to the inner surface of the strap and detects the user's biometric signals;
It consists of three or more seawater inlet holes arranged at a certain distance apart in the border area of the diaphragm, a soluble barrier film formed at the entrance of the seawater inlet hole, and a submersion sensor that respectively detects seawater flowing into the seawater inlet hole exposed by dissolution of the barrier film. , flooding detection unit; and
Including a water pressure sensor formed on the side of the sound wave generator to detect water pressure,
The control module analyzes the biological signals to determine the user's normal situation and emergency situation to generate biometric information, seawater flows into three or more seawater inlet holes of the submersion sensor and continues for a certain period of time, and the water pressure sensor When a certain water pressure is detected, the sound wave generator is determined to be submerged and transmits a sound wave signal containing the biometric information into the water.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The band portion is wound and fixed to cover the user's arms, legs, neck, or chest,
The biometric sensor is in close contact with the user's skin and measures biosignals such as body temperature, pulse, heart rate, movement, or number of steps.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The submersion sensor measures the salinity concentration of seawater flowing into the seawater inlet hole, and when a salinity concentration above a certain concentration is detected, the control module determines that the sound wave generator is submerged.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The submersion sensor measures the flow rate or weight of seawater flowing into the seawater inlet hole, and when the flow rate above a certain water level or seawater above a certain weight is detected, the control module determines that the sound wave generator is flooded.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The submersion sensor includes a first air bag that is contracted by seawater flowing into the seawater inlet hole, and a second air bag that communicates with the first air bag and expands by air exhausted by contraction of the first air bag. And, comprising a limit switch operated by expansion of the second air bag, characterized in that it identifies whether the sound wave generator is submerged depending on whether the limit switch is in contact.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The control module analyzes the biometric signals to determine the user's level of emergency or survival, generates the biometric information, and generates a sound wave signal containing the biometric information.
Sound wave generator for maritime distress rescue.
According to clause 6,
The barrier film is characterized in that it contains starch of a certain thickness,
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The sound wave generator includes GPS, and in a flood situation, the control module converts location information about the current location by the GPS into sound waves and includes it in the sound wave information,
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The sound wave generator includes an LED module, and optical fibers are formed on both sides of the strap to emit light guided from the LED module,
Characterized in that when the control module determines that the situation is flooded, the optical fiber emits light.
Sound wave generator for maritime distress rescue.
According to paragraph 1,
The sound wave generator includes a beacon module, and when the control module determines that the situation is flooded, it transmits a beacon signal through the beacon module.
Sound wave generator for maritime distress rescue.

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