KR20170006850A

KR20170006850A - Wearable devices of Marine sos signal divergence and Health Care

Info

Publication number: KR20170006850A
Application number: KR1020150098145A
Authority: KR
Inventors: 김민주
Original assignee: 김민주
Priority date: 2015-07-10
Filing date: 2015-07-10
Publication date: 2017-01-18

Abstract

The present invention relates to a wearable device for generating a marine distress signal and providing health care to a sailor, which can be connected to a smart device of a sailor having boarded a ship. More specifically, the present invention relates to the wearable device for generating a marine distress signal and providing health care to a sailor, which enables information about health of a user having boarded a ship to be checked and which comprises a micro-computer (30M) adapted to transmit a signal to an application (A) of a data medium (D) when abnormality occurs in the user or the data medium (D) requires information about a current situation and adapted to be disposed in a housing (10) comprising a band part (11) disposed under the housing (10). The wearable device for generating a marine distress signal and providing health care to a sailor comprises: a circuit substrate (100) which includes a low-frequency transmitter (60) disposed on the circuit substrate (100), and which is disposed under a micro-computer (30M); a pressure sensor (12) which is disposed in an inner circumference of a band part (11); a heating plate (101) which is disposed under the circuit substrate (100); a battery unit (19) which is disposed in a housing (10); and a underwater ultrasonic sensor (70) which is connected to the micro-computer (30M), which is spaced apart from the micro-computer (30M), and which is disposed in an outer circumference of the housing (10) on one side of the housing (10). Accordingly, the wearable device checks various types of health states in order to enable a user having boarded a ship, in which the wearable device can be used, to wear safety gear, transmits a signal to the data medium (D), and automatically operates when abnormality occurs in a body of the user, thereby securing a life and identity of the user.

Description

[0001] The present invention relates to a marine sos signal divergence and health care device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wearable device that can be used in connection with a smart device of a seaman who is aboard a maritime vessel and more particularly to a wearable device capable of transmitting a rescue signal when a distress signal occurs at sea, The present invention relates to a multifunctional wearable device capable of maximizing the probability of survival while a crew member aboard a ship recognizes a state and a dangerous situation by themselves.

Recent developments of ICT (Information and Communications Technologies) technology As the US market has been activated, various technologies and documents have been recently released, and the application range and applied devices are continuously expanding due to various demands of consumers.

This technology is being developed not only to solve the purpose for the convenience of the user, but to provide a method of rescuing the user's life in the sea.

On the other hand, according to the statistics of the Korea Maritime Safety Tribunal, the applicant of the present case, there are 663 fishing vessel accidents per year for five years from 2010 to 2015, and many fishermen are missing or dead. The development of the technology is increasing.

The most recently disclosed ICT wearable technology for life saving purpose is a smart lifesaving vest system based on wireless wearing technology for an aquatic and underwater life structure and its operation method disclosed in Korean Patent Publication No. 10-2015-0041900, The technique includes a plurality of sensors mounted at predetermined positions of a life jacket worn by a user to acquire biometric information of the user and environmental information of an environment in which the user is located, A smart lifesaving vest system based on a wireless wear technology for an aquatic and underwater lifesaving system including an aggregator for collecting information, and a control server for monitoring an emergency situation of the user using information received from the collection device And a method of operating the same.

In this way, since ICT can be applied to the life-saving equipment that can be worn by the actual user, it is possible to apply the wearable which can be worn by the user directly to the user.

However, since the wearable using the life vest is not convenient for the operation due to the inconvenience of the life vest itself, the marine occupation personnel performing the service directly from the vessel such as fishermen are excellent in the performance of the life vest equipped with the distress signal Do not wear it.

Especially, in the case of the Ohryong Rokkasho in Russia, all crew members were killed or disappeared due to the use of complicated lifting gears. There was a problem that marine occupation workers facing the situation of safety insecurity could forget about the significance of use of lifejackets.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a safety device for a user, We are trying to obtain a seafloor rescue signal generation and healthcare wearable device that can operate directly to ensure the life and identity of the body.

In order to solve the above-described problems, the present invention is characterized in that a housing (10) provided with a band portion (11) at the lower end for mounting on a user's main body part arm is provided to check health information of a user on board a vessel, The microcomputer 30M is provided in the housing 10 so that the user can transmit a signal to the data medium D when an anomaly occurs or when the data medium D desires status information, The circuit board 100 is provided on the lower surface of the micom 30M.

A temperature sensor 120, a vibration sensor 130 and a low-frequency transmitter 60 are further provided on the upper surface of the circuit board 100 and the above-described configuration is provided for the microcomputer 30M To receive instructions and to operate or to transfer data to the data medium (D).

Since the microcomputer 30M further includes a read unit 40M, a boot gate 49M, a memory, a power control unit 99M and an instruction transfer unit 90M, And can transmit the data to the data medium (D) using the transmission / reception unit (110).

On the other hand, the above information is recorded in real time in the memory 60M, and when the user boots the application A of the data medium D and wants to confirm the information of the user, And the transmission / reception unit 110 can transmit information to the data medium D.

As described above, it is possible to manage the state of the user's body through various applications such as the application A installed in the data medium D. However, when a problem arises in the identity of the user who boarded the ship, The structure signal can be immediately transmitted through the low frequency transmitter 60 provided on the upper surface of the substrate 100.

On the other hand, when the user's vessel overturns and the source of the vessel is confined inside the vessel or the user dies inside the vessel, the user is able to check the harmfulness of the distressed user or the dead user in the water, And the ultrasonic sensor 70 is further separated from the microcomputer 30M.

The wearable device having the functions described above prevents water leakage due to seawater so that the waterproof panel 20 is applied to the upper surface of the housing 10 so that the user can use the device smoothly even at sea, The housing cover 15 is provided on the upper surface of the housing cover 15 so as to solve the problems faced by the apparatus according to the present invention.

As described above, according to the present invention, various health states are checked and mounted on a data medium so that users aboard a ship to use the apparatus can wear the safety gear, and when an abnormality occurs in the user's body, Can be guaranteed.

FIG. 1 is a partial exploded view showing details of the entire external configuration of the present invention in a preferred embodiment of the present invention.
Fig. 2 is a partial view showing a state in which a configuration of the present invention is paired to a data medium D, in a preferred embodiment of the present invention; Fig.
3 is a perspective view showing the outer shape of the present invention in detail in a preferred embodiment of the present invention.
FIG. 4 is a simplified wiring diagram showing an operation example of the microcomputer 30M and its adjacent elements in a preferred embodiment of the present invention. FIG.
FIG. 5 is a partial perspective view of a preferred embodiment of the present invention in which a specific heat is generated in a part of a user's body by a heat plate 101; FIG.

Hereinafter, the present invention will be described more specifically based on the drawings and embodiments.

As shown in FIGS. 1 to 3, the present invention includes a housing 10 having a band portion 11 at the lower end thereof for mounting on an arm, which is a main body part of a user, so as to check health information of a user So that the microcomputer 30M is provided inside the housing 10 so that the user can transmit a signal to the data medium D when an abnormality occurs or when the data medium D wants the current status information And the circuit board 100 is provided on the lower surface of the microcomputer 30M.

4, the microcomputer 30M further includes a read unit 40M, a boot gate 49M, a memory 60M, a power control unit 99M, and an instruction transfer unit 90M It is possible to store the record of the device at predetermined intervals and to transmit it to the data medium D using the Bluetooth transmitting / receiving unit 110. [

The temperature sensing sensor 120 and the vibration sensing sensor 130 are provided to detect a user's body temperature and heart pulse as shown in FIG. 2, The microcomputer 30M is activated by allowing the reading unit 40M to transmit the operation signal to the boot gate 49M while the detection sensor 120 and the vibration detection sensor 130 are to be operated simultaneously for a predetermined period of time, So that the user's information is recorded on the monitor 60M and the health state can be checked in real time.

At this time, in order to activate the microcomputer 30M through the temperature sensor 120, the reader 40M must be able to transmit an operation signal although it should sense an appropriate temperature (Celsius) within a certain range. The range is preferably 26 to 33 degrees, which is the average optimum surface temperature of the wearer's arm.

On the other hand, when the temperature detection sensor 120 detects the temperature below the minimum value of the appropriate temperature range for a certain period of time, and the vibration detection sensor 130 continuously detects the pulse of the user, (30M).

The details of the above method are as follows. When the temperature sensing sensor 120 transmits to the reading unit the fact that the temperature of the user's arm is lowered to 25 degrees or less, the reading unit 40M notifies the generation signal And the microcomputer 30M operates the heat plate 101 provided at the lower end of the circuit board 100 through the command transmission unit 90M.

At this time, it is preferable that the operation temperature of the heat plate 101 generates a specific heat of 2 to 3 degrees from the detected user's arm temperature, thereby preventing the user from having a health problem due to hypothermia as shown in FIG.

The pressure sensor 12 provided on the inner circumferential surface of the band portion 11 may also transmit the blood pressure information of the user to the data medium D by transmitting the user's body blood pressure to the microcomputer 30M .

At this time, in order to prevent a rapid loss of power, the user's blood pressure meter probe detects the temperature sensor 120 and the vibration sensor 130. The microcomputer 30M recognizes that the user has installed the device, Lt; RTI ID = 0.0 > (D). &Lt; / RTI >

At this time, the low-frequency transmitter 60 is enabled to output a rescue signal through a radio frequency identification (RFID) at a radius of 15 km from an accident site.

At this time, while the RFID stores the information to be transmitted, it can transmit / receive information of various objects such as foods, animals, and objects through wireless transmission. Therefore, when the RFID is applied to the present invention, It is also possible to transmit the identification information together with the occurrence of the situation.

The antenna unit 40 can be spaced apart from the micom 30M which is further provided on the inner surface of the housing 10 for transmitting information through the low frequency transmitter 60. [

Therefore, the microcomputer 30M can read and convert the signal, and transmit the low frequency wave through the antenna unit 40 at a radius of 15 km.

At this time, the operation of the low-frequency transmitter 60 is exposed to the upper surface of the housing 10 in order to be performed when the user is in an emergency, The user can operate the low frequency transmitter 60 by inputting the macro 61M designated and recorded in the memory 60M via the button 17. The above method is effective for preventing the malfunction of the device .

On the other hand, the underwater ultrasonic sensor 70 can not be operated through the operation button 17 described above. Instead, the moisture sensor 79 is attached to the outer circumferential surface of one side of the housing 10 corresponding to the underwater ultrasonic sensor 70, So that the underwater ultrasonic sensor is operated when information of moisture is continuously input to the moisture sensor 79 for a predetermined time.

The detailed reading of the moisture sensor 79 is also performed by reading through the reading unit 40M and when the reading unit 40M confirms continuous moisture detection of the moisture sensor 79, And transmits the frequency output signal to the command transmission section 90M in the frequency gate 79M so that the command transmission section 90M transmits the frequency output signal to the underwater ultrasonic sensor 70M ) To operate.

The wearable device having the functions described above prevents water leakage due to seawater so that the waterproof panel 20 is applied to the upper surface of the housing 10 so that the user can use the device smoothly even at sea, A housing cover 15 is provided to apply a waterproof panel.

The waterproof panel 20 to be used at this time is made of a resilient material so as to block the inflow of seawater by preventing it from being formed in the lower surface of the housing cover 15 so as to form a long slot. .

On the other hand, the housing base cover 21 is provided on the lower surface of the waterproof panel 20 so that the above-described waterproof panel 20 receives an appropriate force and does not form a slot with the lower surface of the housing cover 15.

The above-described housing base cover 21 also has an effect of protecting all the structures provided on the inner surface of the housing 10 from damage from external impacts.

Therefore, the battery unit 19 is further provided on the inner surface of the housing 10 to continuously drive the above-described apparatus.

Users of the device aboard the ship through the above-described devices can continuously confirm basic health information such as blood pressure, pulse and heart rate from the data medium D. When an emergency occurs, the low frequency transmitter 60 or underwater ultrasound May request a rescue via the sensor 70, and may be able to sustain life from hypothermia for a long time.

Therefore, the scope of the claims is to be construed to cover all apparatus or systems capable of deriving the facts obvious from the gist of the present invention or implementing similar implementations.

10: housing 11: band portion
12: Pressure sensor 15: Housing cover
17: Operation button 19: Battery part
20: Waterproof panel 21: Foundation cover
40: Antenna section 60: Low frequency transmitter
70: Underwater ultrasonic sensor 79: Moisture sensor
100: circuit board 101:
110: Bluetooth transmitting / receiving unit 120: Temperature sensor
130: Vibration sensor
D: Data medium A: Application
30M: Microcomputer 40M:
49M: Boot Gate 60M: Memory
61M: Macro 79M: Frequency Gate
90M: command transmission unit 99M: power control unit

Claims

(30M) capable of sending a signal to the application (A) of the data medium (D) when an abnormality occurs to the user or when the data medium (D) ) Of the housing 10 provided with the band portion 11 at the lower end of the housing 10, in constructing the source water rescue signal generation and health care wearable device,
A circuit board 100 having a low frequency transmitter 60 on its upper surface is provided on the lower surface of the microcomputer 30M,
A pressure sensor 12 on the inner peripheral surface of the band portion 11,
A heat plate 101 at the lower end of the circuit board 100,
A battery unit 19 is further provided on the inner surface of the housing 10,
And an ultrasonic sensor (70) is provided on an outer circumferential surface of one side of the housing (10) so as to be spaced apart from the microcomputer (30M).

The method according to claim 1,
A Bluetooth transceiver 110, a temperature sensor 120, and a vibration sensor 130 are further provided on the upper surface of the circuit board 100,
Wherein the micom 30M further includes a read unit 40M, a boot gate 49M and a memory 60M, a power control unit 99M and an instruction transfer unit 90M. Occurrence and healthcare wearable devices.

The method according to claim 1,
Wherein the antenna unit (40) is further provided on an inner surface of the housing (10) so as to be spaced apart from the microcomputer (30M).

3. The method according to claim 1 or 2,
An operation button 17 which is exposed to the upper surface of the housing 10 and is spaced apart from the microcomputer 30M,
And the low frequency transmitter (60) is driven by a user inputting a macro (61M) designated and recorded in the memory (60M) through the operation button (17).

The method according to claim 1,
Wherein the moisture sensor (79) is further separated from the micom (30M) on the outer circumferential surface of one side of the housing (10) corresponding to the underwater ultrasonic sensor (70).

The method according to claim 1,
A waterproof panel 20 provided with a base cover 21 on a lower surface thereof is applied to the upper surface of the housing 10,
And a housing cover (15) is further provided on an upper surface of the waterproof panel (20).