WO2021025346A1 - Système de soin de santé pouvant être porté - Google Patents

Système de soin de santé pouvant être porté Download PDF

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Publication number
WO2021025346A1
WO2021025346A1 PCT/KR2020/009738 KR2020009738W WO2021025346A1 WO 2021025346 A1 WO2021025346 A1 WO 2021025346A1 KR 2020009738 W KR2020009738 W KR 2020009738W WO 2021025346 A1 WO2021025346 A1 WO 2021025346A1
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WO
WIPO (PCT)
Prior art keywords
user
unit
neckband
data
voice
Prior art date
Application number
PCT/KR2020/009738
Other languages
English (en)
Korean (ko)
Inventor
정성재
안유신
김동순
김병욱
오정아
Original Assignee
엘지전자 주식회사
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from KR1020190095510A external-priority patent/KR20190099154A/ko
Priority claimed from KR1020190095598A external-priority patent/KR102677427B1/ko
Application filed by 엘지전자 주식회사 filed Critical 엘지전자 주식회사
Publication of WO2021025346A1 publication Critical patent/WO2021025346A1/fr

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    • AHUMAN NECESSITIES
    • A41WEARING APPAREL
    • A41DOUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
    • A41D1/00Garments
    • AHUMAN NECESSITIES
    • A41WEARING APPAREL
    • A41DOUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
    • A41D13/00Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/01Measuring temperature of body parts ; Diagnostic temperature sensing, e.g. for malignant or inflamed tissue
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/02Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
    • A61B5/024Detecting, measuring or recording pulse rate or heart rate
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/08Detecting, measuring or recording devices for evaluating the respiratory organs
    • AHUMAN NECESSITIES
    • A62LIFE-SAVING; FIRE-FIGHTING
    • A62BDEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
    • A62B18/00Breathing masks or helmets, e.g. affording protection against chemical agents or for use at high altitudes or incorporating a pump or compressor for reducing the inhalation effort
    • AHUMAN NECESSITIES
    • A62LIFE-SAVING; FIRE-FIGHTING
    • A62BDEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
    • A62B18/00Breathing masks or helmets, e.g. affording protection against chemical agents or for use at high altitudes or incorporating a pump or compressor for reducing the inhalation effort
    • A62B18/02Masks
    • AHUMAN NECESSITIES
    • A62LIFE-SAVING; FIRE-FIGHTING
    • A62BDEVICES, APPARATUS OR METHODS FOR LIFE-SAVING
    • A62B18/00Breathing masks or helmets, e.g. affording protection against chemical agents or for use at high altitudes or incorporating a pump or compressor for reducing the inhalation effort
    • A62B18/08Component parts for gas-masks or gas-helmets, e.g. windows, straps, speech transmitters, signal-devices
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J7/00Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
    • H02J7/02Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from ac mains by converters
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04RLOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
    • H04R5/00Stereophonic arrangements
    • H04R5/033Headphones for stereophonic communication

Definitions

  • the present invention relates to a wearable healthcare system, and more particularly, to a wearable healthcare system capable of controlling a device worn by a user to an appropriate state by monitoring a change in a state of a user through outdoor activities.
  • health care devices worn by users include masks, earphones, and neckbands with speakers.
  • Masks are mainly worn to prevent users from inhaling contaminated air, and earphones and neckbands are worn by users to listen to sound regardless of location.
  • a user may wear a neckband that generates negative ions to inhale negative ions.
  • the user wears a heart rate signal measuring device on the body and transmits information on the measured heart rate to the server to determine whether the user is healthy.
  • the invention using a conventional healthcare device improves the user's health or convenience by using a healthcare device worn by the user, but does not effectively improve the user's health or convenience by interlocking a plurality of healthcare devices. There are difficulties.
  • the conventional health care device is mainly operated by a user's manipulation, and there is a point in that it is insufficient to automatically control the health care device to an optimal state by reflecting the user's state change through outdoor activities.
  • a mask is used to prevent inhalation of fine dust or yellow dust into the human body, but the mask interferes with breathing, so when wearing a mask and performing activities with a high amount of exercise, such as mountaineering, the user's If there is no separate manipulation, there is a problem that the physical ability cannot be properly exercised.
  • Korean Patent Registration No. 10-1785804 (hereinafter referred to as'priority document 1') discloses a'mask device'.
  • Prior Literature 1 is a body frame formed to cover the user's nose and mouth, a transparent window including a breathing chamber, an air inlet duct that introduces external air into the breathing chamber, and an air discharge that discharges the air in the breathing chamber to the outside. It includes multiple filters to purify ducts and air.
  • the mask device disclosed in Prior Document 1 has a disadvantage in that it is possible to provide purified air to the user, but cannot control the amount of air supplied to the user, and is supplied to the user when the user's exercise is increased and breathing is accelerated. There was a possibility that the amount of air was insufficient.
  • Korean Laid-Open Patent Publication No. 10-2017-0132188 (hereinafter referred to as'priority document 2') discloses a'respiratory mask, system and method'.
  • Prior Document 2 also relates to a respirator or a breathing air filter as a user wearable device.
  • the breathing mask disclosed in Prior Document 2 collects physiological and environmental data and shares them with external devices through a communication network.
  • the breathing mask disclosed in Prior Document 2 divides the step of supplying outdoor air to the user into a'simple pedestrian' mode, a'sports' mode, and the like, and the intake step of the fan is adjusted according to the divided mode.
  • Prior Document 2 operate only when the user selects through an input device, and when the user does not accurately grasp his or her physical state or amount of exercise, adequate air supply could not be performed.
  • Korean Patent Laid-Open Publication No. 10-2015-0063328 (hereinafter referred to as'priority document 3') discloses a'bluetooth built-in earphone for both necklaces'.
  • the Bluetooth built-in earphone for necklaces disclosed in Prior Document 3 can be wirelessly paired with a user's terminal, and is provided to transmit and receive voice without directly manipulating the terminal.
  • Korean Patent Publication No. 10-2018-0032829 (hereinafter referred to as'priority document 4') is attached to clothing to measure the user's heart rate, and transmits the measured heart rate to an external device that checks the user's health status.
  • a heart rate signal measuring device for clothing Disclosed is a heart rate signal measuring device for clothing.
  • Prior Document 4 generally discloses that the measured heart rate can be transmitted to an external device to check the user's health status, and specifically does not disclose a method of checking the health status using the heart rate.
  • the heart rate signal measuring device mounted on the user's body performs a function of transmitting heart rate data to an external device, but a plurality of devices are interlocked with each other without providing guidance in consideration of the user's health or operating for the user's convenience. Does not work.
  • One problem to be solved by the present invention is to solve the problem of the prior art in which a mask worn to purify pollutants in the air such as fine dust or yellow sand limits the amount of air supplied to the user.
  • Another problem to be solved by the present invention is to solve the inconvenience of the prior art in which the user had to wear earphones on the ear in a wearable healthcare device that is wirelessly paired with a terminal to transmit and receive voice.
  • Another problem to be solved by the present invention is that in a wearable healthcare device wirelessly paired with a terminal to transmit and receive voice, voice reception was possible only by wearing earphones in the ear, so that users can easily hear surrounding sounds. It is to solve the problems of the prior art that did not exist.
  • Another problem to be solved by the present invention is to solve the problem of the prior art in which it was difficult for a user to accurately detect a change in an amount of exercise or a change in a physical condition during outdoor activities.
  • Another problem to be solved by the present invention is to solve the problem of the prior art, in which several wearable healthcare devices must be separately operated in operating wearable healthcare devices worn on the user's body.
  • Another problem to be solved by the present invention is to solve the problem of the prior art, which was difficult to charge outdoors when one of the wearable healthcare devices worn by the user runs out of battery.
  • the mask while performing air purification and to prevent a shortage of purified air supplied to the user, the mask is Based on the data, the respiration volume suitable for the user's exercise volume is calculated and the amount of outside air supplied to the user is adjusted.
  • the first neckband communication unit and/or the second neckband communication unit of the neckband are provided so that the user can hear the sound signal output through the neckband without wearing earphones.
  • a sound output unit that is a directional speaker facing upward is provided.
  • the sound output through the neckband without wearing earphones so that the user can detect the noise generated from the outside while listening to the sound signal output through the neckband It is configured to be able to hear the signal.
  • information measured through a biometric signal meter and the terminal is stored or processed in the terminal so that the user can accurately recognize his or her physical state or amount of exercise during outdoor activities. Indicate.
  • wearable healthcare devices such as masks, neckbands, biometric signal measuring devices, manipulators, and terminals share data with each other through a network, so that one manipulator or one terminal without individual manipulation It is possible to control the connected wearable healthcare devices by manipulating the bay.
  • the biosignal meter may be attached to a sixth coupling part provided in smart clothing to perform charging so that outdoor activities can be sustained for a long time even with a limited battery capacity.
  • the wearable healthcare system includes a mask, a neckband, a biometric signal meter, and a control unit.
  • the mask includes a body covering a user's mouth and nose, and a breathing unit provided in the body and supplying external air to the user's mouth and nose.
  • the neckband can be worn by the user by hanging it around the neck, measures the surrounding air quality, and can input and output sound signals.
  • the biometric signal meter is worn on the user's body to measure the user's biometric information.
  • the control unit adjusts the amount of outside air supplied to the user's mouth and nose through the breathing unit based on the user's biometric information collected through the biometric signal meter.
  • the breathing unit includes an inner wall, an outer wall, a filter, and a blower fan.
  • the inner wall forms at least a part of the inner surface of the main body and a ventilation hole is formed.
  • the outer wall forms at least a part of the outer surface of the main body and a ventilation hole is formed.
  • At least one of the filters is disposed between the inner wall and the outer wall.
  • the blower fan introduces outside air that has passed through the outer wall to the inside of the main body through the inner wall.
  • the rotational speed of the blowing fan is controlled through a control unit.
  • the rotational speed increases or decreases in proportion to the user's exercise amount derived through the user's biometric information measured through the biometric signal meter.
  • the neckband includes an anion generator. Anions are generated through the anion generating port.
  • the blower fan increases or decreases the rotational speed in proportion to the amount of negative ions generated through the negative ion generating port.
  • the neckband includes a first neckband communication unit, a second neckband communication unit, and a connection member.
  • the connecting member connects the first neckband communication unit and the second neckband communication unit and is made of a material capable of elastic deformation.
  • at least one of the first neckband communication unit and the second neckband communication unit includes an earphone, a sound output unit, an operation button, and a microphone.
  • the sound output unit is connected to at least one of the first neckband communication unit and the second neckband communication unit through a second extension member, and when a tensile force of more than a predetermined size is applied to the second extension member, the second extension unit is It includes a movement output unit that can be moved by extending the member.
  • the moving output unit may be attached to the mask.
  • An embodiment of the present invention further includes smart clothing.
  • Smart clothing is in the form of a strap or clothing worn on a part of the user's body, and a biometric signal meter is combined with smart clothing.
  • the biosignal meter includes a first coupling unit.
  • the first coupling portion includes a first magnetic body. Then, the first coupling portion is detached from the smart clothing through magnetic force.
  • the smart clothing includes a battery and a wireless charging device built-in, the bio-signal meter is formed to be detachable, and includes a second coupling unit for charging the bio-signal meter wirelessly when the bio-signal meter is attached.
  • the neckband includes a third coupling portion
  • the smart clothing includes a third coupling portion and a holder detachable through magnetic force.
  • the sound output unit which is a directional speaker in which the output direction of the sound signal is directed upward, is disposed on the third coupling part, and the holder is vertically above the sound output part when the third coupling part and the holder are combined. It includes a through hole to be opened.
  • the smart clothing includes a manipulator provided with a manipulation unit capable of operating at least one of a neckband, a mask, a neckband, or a terminal interlocked with the mask.
  • the user is connected to the mask, the neckband and the biosignal meter wirelessly, and includes a control unit for controlling the operation of at least one of the mask, the neckband and the biosignal meter,
  • the biometric information of is transmitted to the paired terminal.
  • the wearable healthcare system includes a mask, a neckband, a biometric signal meter, a control unit, and a manipulator.
  • the controller derives and stores the user's exercise state based on the GPS information collected by the terminal and the user's biometric information measured by the biometric signal meter.
  • the mask includes an acoustic signal input unit.
  • the wearable healthcare system according to an embodiment of the present invention can be worn on the user's neck, and a neckband sensor unit for measuring air pollution, and negative ions.
  • a server including a neckband including a generating negative ion generator, a storage unit for storing data, a determination unit for calculating control data for controlling an external device, and a server control unit for controlling the external device.
  • the server receives air pollution level data measured by the neckband sensor unit, calculates first anion control data to generate negative ions in proportion to the measured air pollution degree, and converts the first anion control data to the neckband. By transmitting, it is possible to control the amount of negative ions generated by the negative ion generator.
  • the server may include a voice unit including a voice conversion module for converting data into voice data, and convert the control data into voice data and transmit the sound output unit to output the voice data as voice.
  • a voice unit including a voice conversion module for converting data into voice data, and convert the control data into voice data and transmit the sound output unit to output the voice data as voice.
  • a breathing unit including at least one blood flow and an air purification means installed in the blood flow to allow air to pass through, and a first blowing means for controlling the amount of air entering and leaving the blood flow, and the amount of negative ions contained in the external air
  • a mask including a mask sensor unit, wherein the server receives the data on the amount of negative ions measured by the mask sensor unit, and controls the first blowing so that the amount of air introduced into the user's respiratory tract increases in proportion to the measured amount of negative ions. By calculating data, the first blowing means can be controlled.
  • the mask may include a directional speaker and a mask sound output unit that outputs sound to the user's ear.
  • a control unit that receives a command for controlling an external device, a display unit that displays symbols and images, and a manipulator control unit that controls the operation of the external device by transmitting control data about the command received through the control unit to the external device.
  • the operation unit includes a touch input means for receiving a command by a user's touch input and a voice input means for receiving a user's voice, and controls the operation of an external device by a command or voice input by a touch input. Can be controlled.
  • the neckband may be detachable to clothing by magnetic force
  • the mask sound output unit may be detachable to the mask by magnetic force
  • the server may be included in the mask, the neckband, the manipulator, or the terminal.
  • a wearable health care system for solving the above problem is a neckband that can be worn on the user's neck and includes a sound output unit that outputs sound to the user's ear by having a directional speaker.
  • a biometric signal meter that is mounted on the body to measure body information including heart rate and transmit and receive data, a storage unit that stores data, a determination unit that generates status data and recommendation data, and a voice that can convert data into voice data. It may include a server containing wealth.
  • the server generates data including the state data and the recommendation data based on the body information of the user measured and transmitted by the biometric signal meter, and includes the generated state data and the recommendation data.
  • the data is converted into voice data and transmitted to the neckband, and the neckband may output the voice data as voice to the sound output unit.
  • the state data may be data related to one or more of changes in exercise amount, exercise intensity, health, and physical strength of the user
  • the recommended data may be data related to any one or more of rest, medical treatment, exercise, and movement route.
  • the server controls the determination unit to control the external device.
  • the first blowing means may be controlled by calculating data and calculating second blowing control data so that the amount of air flowing into the user's respiratory tract increases in proportion to the user's heart rate measured and transmitted by the biometric signal meter.
  • it may include a manipulator capable of controlling an external device through a user's touch input or voice input.
  • the server may be included in the mask, the neckband, the manipulator, the terminal, or the biosignal measuring device.
  • the manipulator may be provided with a magnetic coupling means to allow attachment and detachment to the clothing by magnetic force.
  • FIG. 1 is an exemplary diagram of a wearable healthcare system control environment according to an embodiment of the present invention.
  • FIG. 2 is a block diagram showing a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 3 is a perspective view and a partial cross-sectional view illustrating a mask of a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 4 is a perspective view showing a neckband of a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 5 is a perspective view illustrating a state in which earphones are withdrawn from a neckband of a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 6 is a perspective view illustrating a state in which a movement output unit is withdrawn from a neckband of a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 7 and 8 are perspective views and cross-sectional views illustrating a state in which a neckband of a wearable healthcare system according to an embodiment of the present invention is coupled to a holder.
  • FIG. 9 is a perspective view showing a smart clothing and a bio-signal meter of a wearable healthcare system according to an embodiment of the present invention.
  • FIG. 10 is a perspective view showing a smart clothing and a manipulator of a wearable healthcare system according to an embodiment of the disclosed content.
  • FIG. 11 is a block diagram illustrating a wearable healthcare system according to another embodiment of the present invention.
  • FIG. 12 is a diagram showing an example of a mask constituting the wearable healthcare system of FIG. 11.
  • FIG. 13 is a view showing an example of the mask of FIG. 12 including a detachable mask sound output unit.
  • FIG. 14 is a block diagram illustrating a mask sensor unit of the mask of FIG. 12.
  • 15 is a block diagram showing a breathing part of the mask of FIG. 12.
  • FIG. 16 is a diagram showing an example of a neckband constituting the wearable healthcare system of FIG. 11.
  • FIG. 17 is a block diagram illustrating a neckband sensor unit constituting the neckband of FIG. 16.
  • FIG. 18 is a diagram illustrating an example of an electrocardiogram type bio-signal measuring device constituting the wearable healthcare system of FIG. 11.
  • FIG. 19 is a diagram illustrating an example of an optical type bio-signal measuring device constituting the wearable healthcare system of FIG. 11.
  • FIG. 20 is a diagram illustrating an example of a manipulator constituting the wearable healthcare system of FIG. 11.
  • 21 is a block diagram showing an operation unit of the manipulator of FIG. 20.
  • FIG. 22 is a block diagram illustrating a determination unit of a server constituting the wearable healthcare system of FIG. 21.
  • FIG. 23 is a block diagram showing a voice conversion module of a voice unit of a server constituting the wearable healthcare system of FIG. 21.
  • FIG. 24 is a block diagram illustrating a voice recognition module of a voice unit of a server constituting the wearable healthcare system of FIG. 21.
  • FIG. 25 is a block diagram illustrating an example of the operation of the wearable healthcare system of FIG. 11 when civil war occurs.
  • 26 is a block diagram illustrating an example of the operation of the wearable healthcare system of FIG. 11 during a phone call.
  • FIG. 1 is an exemplary diagram of a wearable healthcare system control environment according to an embodiment of the disclosure.
  • the wearable healthcare system control environment of the present invention includes a mask 100, a neckband 200, a biometric signal meter 300, a manipulator 400, smart clothing 500, 600, and a server ( 10) and some of the networks.
  • the mask 100, the neckband 200, the biometric signal measuring device 300, the manipulator 400, and the smart clothing 500 and 600 are wearable healthcare devices that can be worn on the user's body, respectively.
  • the mask 100, the neckband 200, the biometric signal measuring device 300, the manipulator 400, and the smart clothing 500, 600 are each provided to enable communication with the server 10, and data determined by the server 10 Can be transmitted, and also receive predetermined data from the server 10.
  • the server 10 may be provided separately from the terminal 20, and may be embedded in the terminal 20 according to an embodiment to which the present invention is applied. Alternatively, it may be installed on at least one of the mask 100, the neckband 200, the biometric signal meter 300, the manipulator 400, and the smart clothing 500 and 600.
  • the mask 100, the neckband 200, the biometric signal meter 300, the manipulator 400, the smart clothing 500 and 600, the terminal 20 and the server 10 wirelessly exchange data with each other.
  • Network can be formed.
  • the mask 100, the neckband 200, the biometric signal meter 300, the manipulator 400, and the smart clothing 500 and 600 may each include a communication unit, and a communication unit included in each Pairing that is placed in a state in which data can be exchanged with the terminal 20 or the server 10 specified through may be performed.
  • Such networks may include wireless networks such as wireless LANs, CDMA, Bluetooth, and satellite communication, but the scope of the disclosed contents is not limited thereto.
  • the network may transmit and receive information using short-range communication and/or long-distance communication.
  • short-range communication may include Bluetooth, radio frequency identification (RFID), infrared data association (IrDA), ultra-wideband (UWB), ZigBee, and wireless fidelity (Wi-Fi) technologies
  • Communication includes code division multiple access (CDMA), frequency division multiple access (FDMA), time division multiple access (TDMA), orthogonal frequency division multiple access (OFDMA), single carrier frequency division multiple access (SC-FDMA) technology. I can.
  • a network may include the connection of network elements such as hubs, bridges, routers, switches and gateways. Access to the network may be provided through one or more radio access networks. Furthermore, the network may support an Internet of Things (IoT) network and/or 5G communication that exchanges and processes information between distributed components such as objects.
  • IoT Internet of Things
  • FIG. 2 is a block diagram illustrating a wearable healthcare system according to an embodiment of the disclosure.
  • the wearable healthcare system may include a mask 100, a neckband 200, a biometric signal meter 300, and a control unit 30.
  • the mask 100 includes a main body 110 covering the user's mouth and nose, and a breathing unit 120 provided in the main body 110 and supplying external air to the user's mouth and nose.
  • the neckband 200 can be worn by the user by hanging it around the neck, measures the surrounding air quality, and inputs and outputs sound signals.
  • the biosignal measuring device 300 is worn on the user's body to measure the user's biometric information.
  • the control unit 30 adjusts the amount of outside air supplied to the user's mouth and nose through the breathing unit 120 based on the user's biometric information collected through the biometric signal meter 300.
  • control unit 30 may be additionally connected to the terminal 20 or the manipulator 400.
  • the control unit 30 is a kind of central processing unit and may control the operation of wearable healthcare devices connected to the control unit 30 by wire or wireless by driving a control program.
  • the controller 30 may be included in the terminal 20 or the server 10, or may be included in some of the wearable healthcare devices.
  • the controller 30 may include all kinds of devices capable of processing data, such as a processor.
  • the'processor' may refer to a data processing device embedded in hardware having a circuit physically structured to perform a function represented by a code or instruction included in a program.
  • a data processing device built into the hardware as described above a microprocessor, a central processing unit (CPU), a processor core, a multiprocessor, and an ASIC ( Processing devices such as an application-specific integrated circuit) and a field programmable gate array (FPGA) may be covered, but the scope of the disclosed content is not limited thereto.
  • FIG 3 is a perspective view and a partial cross-sectional view illustrating a mask 100 of a wearable healthcare system according to an embodiment of the disclosure.
  • the mask 100 includes a body 110 capable of covering a part of a user's face.
  • the body 110 may be curved on one side with a curvature similar to that of a human face.
  • the body 110 is formed to be in close contact with the user's face, in particular, the face portion where the nose and mouth are located.
  • the main body 110 is provided with a width that can cover the user's nose and mouth, and a space is formed so that a surface adjacent to the user's face does not contact the user's nose and mouth.
  • the body 110 has a breathing part 120 formed on a part thereof. At least one breathing unit 120 is provided, and is provided so that outside air can pass through the outer and inner surfaces of the body 110.
  • the breathing unit 120 has an outer wall 122, a first filter 124, a second filter 126, an inner wall 128, and a blowing fan as shown in the cross-sectional view A-A' of FIG. ).
  • the outer wall 122 and the inner wall 128 are each formed with a ventilation hole h through which air can pass, the outer wall 122 is on the outer surface of the main body 110, and the inner wall 128 is the inside of the main body 110. It is placed on the side.
  • a first filter 124 and a second filter 126 are provided between the outer wall 122 and the inner wall 128, and the first filter 124 and the second filter 126 can filter out specific particles, respectively. It may be a filter provided to be. At least one of the first filter 124 and the second filter 126 may be a high efficiency particulate air filter.
  • At least one filter may be included between the outer wall 122 and the inner wall 128 of the breathing unit 120, and a plurality of filters may be provided.
  • a plurality of filters may be provided.
  • Air introduced through the outer wall 122 passes through the first filter 124 and the second filter 126, and specific particles or substances mixed in the air in the process of passing the air pass through the first filter 124 and the second filter 126. It is filtered through 2 filter 126.
  • the air purified by passing through the first filter 124 and the second filter 126 is supplied to the mouth and nose of the user through a vent h formed in the inner wall 128.
  • a blowing fan f for flowing air is provided between the first filter 124 and the second filter 126.
  • the blower fan (f) creates a flow of air and flows the air in a specific direction.
  • the blowing fan f allows outside air to flow into the main body 110 through a ventilation hole h formed in the outer wall 122, and the outside air is the outer wall 122, the first filter 124, The second filter 126 and the inner wall 128 are sequentially passed to be supplied to the user.
  • the amount of outside air flowing into the main body 110 may be adjusted at the rotational speed of the blowing fan f.
  • the amount of outside air introduced into the main body 110 is adjusted in proportion to the rotational speed of the blowing fan f.
  • the breathing unit 120 may block the outside air from passing through the breathing unit 120 when the blowing fan f is stopped or through a separate blocking member.
  • the body 110 may be fitted with wearables 140 on both sides.
  • the wearing tool 140 may be a strap-shaped member, and is provided to bind a part of the user's body so that the body 110 maintains a state in contact with the user's face.
  • the wearing tool 140 may be implemented through various fastening means according to an embodiment to which the present invention is applied.
  • fourth coupling portions 130 may be formed in portions adjacent to both sides of the outer surface of the main body 110.
  • the fourth coupling part 130 is formed at a portion adjacent to the user's ear when the user wears the mask 100, and the surface direction of the coupling part may be toward the user's ear.
  • the fourth coupling part 130 may include at least one fourth magnetic body 132, and the fourth magnetic body 132 is made of a member having a magnetic force, and a component made of a material attached to the magnet may be detached.
  • the movement output units 254a and 254b of the neckband 200 to be described later may be detachable, and a third coupling portion 260a provided in the movement output units 254a and 254b is a fourth coupling unit 130 ) And magnetic force.
  • the rotational speed of the blowing fan f is controlled through the control unit 30.
  • the controller 30 predicts the user's exercise amount based on the user's biometric information measured through the biometric signal meter 300, and calculates the required respiration amount according to the user's exercise amount.
  • the control unit 30 controls the rotational speed of the blowing fan f so that sufficient air for breathing is supplied to the user based on the amount of respiration required according to the amount of exercise of the user.
  • the rotational speed of the blowing fan f controlled by the controller 30 may vary according to the amount of negative ions generated by the neckband 200 to be described later. For example, if the amount of negative ions generated through the neckband 200 is large, the rotational speed of the blowing fan f can be quickly controlled through the control unit 30, and if the amount of negative ions is small, the blowing fan f The rotation speed of can be controlled slowly through the control unit 30.
  • the rotational speed of the blowing fan f may vary according to the air quality sensed through the neckband 200. For example, when the amount of fine dust, yellow dust, or specific harmful substances detected through the neckband 200 is greater than or equal to a value that can be purified through the first filter 124 and the second filter 126, the first filter 124 ) And the rotational speed of the blowing fan f is controlled so as to introduce only air in the body 110 in an amount that can be sufficiently purified through the second filter 126.
  • the mask 100 may be provided with an acoustic signal input unit on its inner surface.
  • the sound signal input unit may receive a user's voice and transmit it to at least one of the terminal 20, the server 10, the control unit 30, or the neckband 200. This enables a user wearing the mask 100 to transmit a voice through the neckband 200 or the terminal 20 even when wearing the mask 100.
  • FIG. 4 is a perspective view showing a neckband 200 of a wearable healthcare system according to an embodiment of the disclosed content
  • FIG. 5 is a neckband 200 of a wearable healthcare system according to an embodiment of the disclosed content Is a perspective view showing a state in which the earphones 220a and 220b are withdrawn.
  • the neckband 200 includes a neckband communication unit and a connection member 280.
  • the neckband communication unit includes a first neckband communication unit 210a and a second neckband communication unit 210b.
  • the first neckband communication unit 210a and the second neckband communication unit 210b are connected to each other through a connection member 280, and the first neckband communication unit 210a, the connection member 280, and the second neckband communication unit ( 210b) has a shape that can be hung on the neck when combined with each other. Therefore, the neckband 200 to which the first neckband communication unit 210a, the connection member 280 and the second neckband communication unit 210b are connected can be worn around the user's neck, and the first neckband communication unit 210a ) And the second neckband communication unit 210b may be disposed on both sides of the user's neck, respectively.
  • connection member 280 may be made of a material capable of elastic deformation.
  • the neckband communication unit includes earphones 220a and 220b, negative ion generator 240a, sound output unit 250a, seventh coupling unit 258b, operation button 270a, and microphone 290a.
  • Earphones (220a, 220b), negative ion generator (240a), sound output unit (250a), seventh coupling unit (258b), operation button (270a) and microphone (290a) are respectively a first neckband communication unit (210a) and / Or disposed on the second neckband communication unit 210b.
  • the earphones 220a and 220b may be provided at the ends of the neckband communication unit, and are connected to the first neckband communication unit 210a and/or the second neckband communication unit 210b through the first extension members 230a and 230b. do.
  • the first extension members 230a and 230b extend when a tensile force of more than a predetermined size is applied, and when the applied tensile force is removed or an external force satisfying a predetermined condition is applied, the first neckband communication unit 210a and/or the second The length that was extended to the outside of the neckband communication unit 210b is shortened.
  • the negative ion generator 240a is formed in the first neckband communication unit 210a and/or the second neckband communication unit 210b, and from the first neckband communication unit 210a and/or the second neckband communication unit 210b. It is opened toward the top to discharge negative ions to the top of the first neckband communication unit 210a and/or the second neckband communication unit 210b.
  • FIG. 6 is a perspective view illustrating a state in which the movement output units 254a and 254b are withdrawn from the neckband 200 of the wearable healthcare system according to an embodiment of the disclosure.
  • the sound output unit 250a provided in the neckband 200 may include a fixed output unit 252a and moving output units 254a and 254b.
  • the sound output unit 250a may be formed of a directional speaker.
  • Directional Speakers have a directivity that radiates sound only in a targeted direction. Accordingly, the sound signal output through the sound output unit 250a may be set to face a predetermined direction. In an embodiment of the present invention, the sound output unit 250a is set so that the sound signal is directed upwards of the first neckband communication unit 210a and/or the second neckband communication unit 210b.
  • the fixed output unit 252a is disposed on the first neckband communication unit 210a and/or the second neckband communication unit 210b, and the moving output units 254a and 254b are the first neckband communication unit 210a and/or Alternatively, it is disposed at the end of the second neckband communication unit 210b and is connected to the first neckband communication unit 210a and/or the second neckband communication unit 210b through the second extension members 256a and 256b.
  • the length exposed to the outside of the first neckband communication unit 210a and/or the second neckband communication unit 210b increases, and the applied external force
  • the length exposed to the outside of the first neckband communication unit 210a and/or the second neckband communication unit 210b is shortened when removing or when an external force of a specific size or pattern acts.
  • the movement output units 254a and 254b connected to the second extension members 256a and 256b may be moved in position.
  • the moving output units 254a and 254b are provided with a third coupling portion 260a on one surface, and the third coupling portion 260a includes a third magnetic body 262a.
  • the movement output units 254a and 254b are moved in position as the lengths of the second extension members 256a and 256b are extended, and the fourth coupling unit 130 provided in the mask 100 as shown in FIG. ) Can be attached.
  • the direction in which the sound signals of the movement output units 254a and 254b are output is a direction in which the surface forming the fourth coupling unit 130 looks, and is directed toward the user's ears while the user wears the mask 100. .
  • the moving output units 254a and 254b extend the length of the second extension members 256a and 256b and attach them to the mask 100 according to the user's selection, or the second extension members 256a and 256b are attached to the first neck.
  • the band communication unit 210a and/or the second neckband communication unit 210b may be disposed on the first neckband communication unit 210a and/or the second neckband communication unit 210b in a hidden state.
  • the sound output unit 250a and the seventh coupling unit 258b are also provided in the first neckband communication unit 210a and/or the second neckband communication unit 210b, and the first neckband communication unit 210a and/or It is disposed toward the top of the two neckband communication unit (210b).
  • FIG. 7 and 8 are perspective views and cross-sectional views illustrating a state in which the neckband 200 of the wearable healthcare system according to an embodiment of the disclosure is coupled to the holder 610.
  • the seventh coupling portion 258b is made of a plurality of seventh magnetic bodies 259b.
  • the seventh magnetic body 259b is made of a material having magnetic force.
  • the fixed output unit 252a is disposed on the seventh coupling unit 258b.
  • the seventh coupling portion 258b may be coupled to the holder 610 to be described later.
  • the holder 610 is fixed to the smart clothing (500, 600), and when wearing the smart clothing (500, 600) and the neckband 200 together, the neckband 200 is placed in a predetermined position on the smart clothing (500, 600). Guide them to be aligned.
  • the second coupling portion 612 formed on the seventh coupling portion 258b and the holder 610 is a coupling force generated by the magnetic properties of the seventh magnetic body 259b and the second magnetic body 614 provided on each other. Through, it is detached. Therefore, when the holder 610 and the neckband 200 are detached, they are guided by magnetic force, so that the same coupling position can be maintained at all times.
  • the holder 610 may be coupled to the smart clothing (500, 600), and the neckband 200 is detached from the holder 610 in a state coupled to the smart clothing (500, 600), the neckband 200 and When the user wears the smart clothing 500 and 600 together, the position of the neckband 200 can be determined.
  • the holder 610 has a through hole 618 penetrating up and down at a position corresponding to the fixed output unit 252a.
  • the through hole 618 acts as a passage through which the sound signal output to the upper portion through the fixed output unit 252a can pass.
  • the periphery of the through hole 618 includes a protrusion 616 protruding from the second coupling part 612 to one side, and the protrusion 616 is a process in which the smart clothing 500 and 600 and the holder 610 are combined. In the holder 610 acts to be fixed to a predetermined position of the smart clothing (500, 600).
  • the microphone 290a may be provided in the first neckband communication unit 210a and/or the second neckband communication unit 210b as a configuration in which sound signals generated from the surroundings are input.
  • FIG. 9 is a perspective view showing smart clothes 500 and 600 of a wearable healthcare system and a biometric signal meter 300 according to an embodiment of the disclosed content
  • FIG. 10 is a wearable according to an embodiment of the disclosed content. It is a perspective view showing the smart clothing (500, 600) and the manipulator 400 of the health care system.
  • the biometric signal meter 300 may be detachable from the smart clothing 500 and 600.
  • the smart clothing 500 and 600 may be implemented as a first smart clothing 500 that can be worn by the user in a string form, and a second smart clothing 600 that can be worn by the user in a clothing form.
  • the first smart clothing 500 and the second smart clothing 600 are exemplary, and may be implemented in various types of clothing according to an embodiment to which the present invention is applied.
  • the biosignal measuring device 300 includes a first coupling unit 310.
  • the first coupling part 310 is provided with a first magnetic body 312, and the first magnetic body 312 is combined with the fifth magnetic body 512 of the fifth coupling part 510 provided in the smart clothing 500 and 600 Can be.
  • the biosignal measuring device 300 is attached to the smart clothing 500 and 600 to measure a user's biosignal.
  • the measured biological signal may be body temperature, heart rate, and the like.
  • the biometric signal meter 300 may be attached to the sixth coupling unit 602 provided in the smart clothing 500 and 600.
  • the sixth coupling unit 602 has a battery and a wireless charging device embedded therein, and charges the biosignal measuring device 300 attached to the sixth coupling unit 602 through the sixth magnetic body 604.
  • the biometric signal meter 300 may be attached to the sixth coupling unit 602 of the smart clothing 500 and 600 to perform charging.
  • the manipulator 400 may be attached to the smart clothing 500 and 600.
  • the manipulator 400 includes a display unit 410 and an operation unit 420.
  • the manipulator 400 is provided to enable communication with the mask 100, the neckband 200, the biosignal measuring device 300, the terminal 20, the control unit 30, the server 10, etc., and the manipulation unit 420
  • the user's signal input through the mask 100, the neckband 200, the biometric signal meter 300, the terminal 20, the control unit 30, the server 10 may be transmitted to at least one of.
  • the display unit 410 may display manipulation information such as a mask 100, a neckband 200, a biometric signal measuring device 300, a terminal 20, a server 10, etc. currently controlled through the manipulator 400. .
  • the user's biometric information measured through the biometric signal meter 300 may be transmitted to the terminal 20 paired with the wearable healthcare system according to an embodiment of the present invention, and the transmitted user's biometric information is transmitted to the terminal 20 ) Can be stored or processed to be used as user's exercise information.
  • the terminal 20, the server 10, and the control unit 30 may be implemented as a single configuration as described above, or may be implemented as different configurations according to an embodiment to which the present invention is applied.
  • the mask 100, the neckband 200, the biometric signal meter 300 and the manipulator 400 form a single network to share data. It can be manipulated under predetermined conditions based on mutually generated data.
  • the terminal (20) when the user's exercise amount derived from the user's biometric information measured through the biometric signal meter 300 meets a predetermined standard or an abnormality is detected in the user's physical condition derived through the user's biometric information, the terminal (20), it is possible to notify the user by generating an acoustic signal or vibration through a configuration such as the neckband 200.
  • FIG. 11 is a block diagram illustrating a wearable healthcare system according to another embodiment of the present invention.
  • a wearable healthcare system may be configured with a plurality of healthcare devices.
  • FIG. 12 is a diagram showing an example of a mask constituting the wearable healthcare system of FIG. 11.
  • the mask 100 can be worn on the user's face, and is formed to block the user's respiratory organs from outside air so that the user does not inhale contaminated air.
  • the mask 100 may be formed to cover a face other than the user's eyes, and may have two earring portions to be worn on the user's face by being worn on both ears of the user.
  • the mask 100 may include a mask communication unit 170, a mask sensor unit 150, a breathing unit 120, and a mask sound output unit 160.
  • the mask communication unit 170 includes a communication module, etc. so that the mask 100 and a device or a server external to the mask 100 (hereinafter, referred to as an external device) can transmit and receive data to and from each other.
  • Communication technologies such as RFID (Radio Frequency Identification), UWB (Ultra Wide Band), Bluetooth, and wireless sensor networks can be used to suit the requirements.
  • FIG. 14 is a block diagram illustrating a mask sensor unit of the mask of FIG. 12.
  • the mask sensor unit 150 is in contact with an anion measuring sensor 151 capable of measuring an amount of anion contained in air in contact with the mask 100, and the mask 100 It may include an air measurement sensor 152 that can measure the pollution degree, humidity, temperature, etc. of the air, a noise measurement sensor 153 that can measure noise, and a position measurement sensor 154 that can measure a position. have. Data measured by the mask sensor unit 150 may be used to control the wearable healthcare system of the present invention.
  • 15 is a block diagram showing a breathing part of the mask of FIG. 12.
  • the breathing unit 120 may be provided on the mask 100 so that the user's respiratory organs and external air communicate with each other so that the user can breathe.
  • the respirator 120 has a surface where the mask 100 and the user's face face to each other (hereinafter referred to as the inside of the mask) and a surface in which the mask 100 and external air contact (hereinafter, referred to as (Referred to as the outside of the mask), the air purification means (124, 126) for purifying the air that is installed in the blood flow to circulate air between the inside and the outside of the mask, and the air purification means It may include a first blowing means that is installed adjacent to be able to adjust the direction and amount of air flowing into or out of the mask.
  • a plurality of the breathing units 120 may be provided on the mask 100 so as to be symmetrical with respect to a direction in which the user faces when the user wears the mask 100.
  • the air purifying means 124 and 126 perform a function of purifying air when air outside the mask enters the mask in order to prevent the user from inhaling contaminated air containing fine dust, etc. It may be composed of a filter, such as a filter, a hepa filter, and an ultra-low penetration air filter.
  • the first blowing means performs a function of adjusting the blowing direction and amount of air, and may be composed of a blowing means f such as a conventional fan.
  • a blowing means f such as a conventional fan.
  • air can enter or exit the mask 100 inside or outside, By controlling the rotation speed of the fan, the amount of air entering or leaving the mask 100 may be adjusted.
  • one first blowing means rotates clockwise and the other first blowing means rotates counterclockwise, effectively to the user. It can supply air and expel the user's exhalation.
  • the mask sound output unit 160 performs a function of outputting sound so that a user can hear sound, and may be configured so that the user can effectively hear the sound.
  • the mask sound output unit 160 is provided with two symmetrical on the mask 100 so as to be close to both ears of the user, and includes a directional speaker using ultrasonic waves, and the directional speaker is It can have a directing angle to output sound in a direction.
  • the mask sound output unit 160 may be configured to be detachably attached to the mask 100.
  • the mask 100 includes a mask seat 162 including a magnet or a magnetic material
  • the mask sound output unit 160 includes the mask seat 162 and
  • the mask coupling unit 164 including a magnet or a magnetic material to be magnetically coupled the mask sound output unit 160 can be freely attached and detached to the mask 100.
  • FIG. 16 is a diagram showing an example of a neckband constituting the wearable healthcare system of FIG. 11.
  • the neckband 200 is worn on the user's neck to output sound that the user can hear, or to provide negative ions toward the user's neck or face. I can. Therefore, the neckband 200 may be formed in a structure that can be worn on the user's neck.
  • the neckband 200 may be formed in a necklace shape to be worn on the user's neck, or may be hung over the user's neck and formed in a necklace shape with one side open.
  • the neckband 200 may include a neckband communication unit 210, an audio output unit 250a, an anion generator 240a, a neckband sensor unit 240, and a neckband operation unit 250.
  • the neckband communication unit 210 includes a communication module, etc. so that the neckband 200 and an external device can transmit and receive data with each other, and to be suitable for data transmission/reception, RFID (Radio Frequency Identification), UWB (Ultra Wide Band) ), Bluetooth, wireless sensor network, and other communication technologies can be used.
  • RFID Radio Frequency Identification
  • UWB Ultra Wide Band
  • Bluetooth Wireless Sensor Network
  • the sound output unit 250a performs a function of outputting sound so that a user can hear sound, and may be configured so that the user can effectively hear the sound.
  • the sound output unit 250a when the neckband 200 is hung on the nape of the user's neck, two are symmetrical with respect to the direction in which the user faces the neckband 200. It is installed and includes a directional speaker using ultrasonic waves, and the directional speaker may have a directivity angle to output sound toward the user's ear.
  • the sound output unit 250a may be configured to be detachably attached to the neckband 200.
  • the neckband 200 includes a coupling portion including a magnet or a magnetic material
  • the sound output unit 250a includes a coupling portion including a magnet or a magnetic material to be magnetically coupled with the coupling portion.
  • the sound output unit 250a may be freely attached and detached from the neckband 200.
  • the negative ion generator 240a generates negatively charged particles (hereinafter, referred to as negative ions) around the user's neck and face, and the generated negative ions are combined with positively charged dust to remove the heavy dust. Sit down to remove dust around the user's neck and face. In addition, the user can see a beneficial effect on the human body by inhaling the negative ions generated by the negative ion generating device (240a).
  • negative ions negatively charged particles
  • the negative ion generator 240a may be installed on the neckband 200 to effectively generate negative ions around the user's neck and face.
  • the negative ion generator 240a may be installed on the upper surface of the neckband 200 based on a direction perpendicular to the horizontal plane when the neckband 200 is over the nape of the user's neck.
  • two may be installed so as to be symmetrical based on the direction in which the user faces the front.
  • the negative ion generating port 240a may be provided with a second blowing means to blow air containing negative ions generated toward the user's face.
  • the second blowing means may be composed of a conventional fan, and the negative ions may be effectively transmitted to the user's face through adjustment of the rotation speed and installation angle of the fan. .
  • FIG. 17 is a block diagram illustrating a neckband sensor unit constituting the neckband of FIG. 16.
  • the neckband sensor unit 240 is an air measurement sensor 241 capable of measuring pollution degree, humidity, temperature, etc. of air in contact with the neckband 200, and noise is measured. It may include a noise measurement sensor 242 that can be, a position measurement sensor 243 that can measure the position. The data measured by the neckband sensor unit 240 may be used to control the wearable healthcare system of the present invention.
  • the neckband 200 may be provided with the neckband operation unit 250 to adjust the amount of sound output from the sound output unit 250a and the amount of negative ions generated from the negative ion generator 240a.
  • the neckband manipulation unit 250 may employ a conventional volume key that can control strength and weakness by rotation.
  • the neckband 200 may be configured to be detachable to clothing.
  • the neckband 200 may be configured to include a magnetic coupling means that can be attached to or detached from clothing by magnetic force.
  • the biosignal measuring device 300 is mounted on a user's body and performs a function of measuring data such as heart rate, body temperature, and blood pressure (hereinafter referred to as body data), and a measuring instrument communication unit 340 and a measuring instrument sensor unit ( 320), may include a measuring device operating unit 330.
  • the measuring instrument communication unit 340 is provided with a communication module, etc. so that the bio-signal measuring instrument 300 and an external device can transmit and receive data between each other, and to be suitable for data transmission/reception, RFID (Radio Frequency Identification), UWB (Ultra Wide Band) ), Bluetooth, wireless sensor network, and other communication technologies can be used.
  • RFID Radio Frequency Identification
  • UWB Ultra Wide Band
  • Bluetooth Wireless Sensor Network
  • the measuring device sensor unit 320 performs a function of measuring body data of a user, and a method of measuring the body data may be different.
  • the measuring device sensor unit 320 may measure the user's heart rate by a method such as an electrocardiogram method or an optical method.
  • FIG. 18 is a diagram showing an example of an electrocardiogram type biosignal meter constituting the wearable healthcare system of FIG. 11, and FIG. 19 is a view showing an example of an optical type biosignal meter constituting the wearable health care system of FIG. 11 It is a drawing.
  • the biosignal measuring device 300 in which the measuring device sensor unit 320 measures the heart rate in an electrocardiogram method measures an electrical change in the user's heart activity, so that electricity can be effectively conducted.
  • a chest strap 500 worn around a user's chest a fifth coupling portion 510 installed on the chest strap 500 to contact the user's body and formed of a conductor including a magnet or a magnetic material ,
  • an electrical signal of the user's cardiac activity may be measured.
  • the biosignal measuring device 300 in which the measuring device sensor unit 320 measures the heart rate in an optical method, irradiates light to the blood vessel 10 and reflects it from the blood vessel 10.
  • the heart rate is calculated by measuring the light.
  • the principle that the amount of reflected light decreases when the amount of blood flowing through the blood vessel 10 by the heart pumping out increases, and the amount of reflected light increases when the amount of blood flowing through the blood vessel 10 decreases.
  • the user when the user wears the biological signal measuring device 300 in the shape of a watch or wristband, the user from the measuring device sensor unit 320 that comes into contact with the user's skin
  • the heart rate may be calculated by irradiating and reflecting light into the blood vessel 10 inside the skin of the patient, and measuring the reflected light by the biosignal meter 300.
  • the measuring device sensor unit 300 may measure the user's body temperature.
  • the biosignal measuring device 300 may be configured to measure the user's body temperature by providing a known thermometer or the like at a portion in contact with or close to the user's body.
  • the measuring device control unit 330 may be configured to allow a user to control the power of the biological signal measuring device 300 or to operate to transmit the heart rate measured by the biological signal measuring device 300 to an external device.
  • the measuring device operating unit 330 can be operated by pressing or touching (hereinafter, referred to as touch input) with a predetermined force, and the biosignal measuring device 300 is the measuring device operating part 330 Power may be controlled according to the time or number of touch inputs, or the measured heart rate may be transmitted so that an external device or an external server can store it.
  • the manipulator 400 may transmit/receive data to/from an external device and operate the wearable healthcare system of the present invention by a user's manipulation.
  • the manipulator 400 may include a manipulator communication unit 430, a manipulator 420, a display unit 410, and a manipulator control unit 440.
  • the manipulator 400 may be configured to be detachably attached to the user's clothing.
  • one side of the manipulator 400 includes a magnet or a magnetic material, and a button including a magnet or a magnetic material is provided so as to be magnetically coupled to the side of the manipulator 400, When the button is coupled to the one side of the manipulator 400 through a button hole formed, the manipulator 400 may be configured to be attached to the user's clothing.
  • the manipulator communication unit 430 is provided with a communication module, etc. so that the manipulator 400 and an external device can transmit and receive data between each other, and to be suitable for data transmission and reception, RFID (Radio Frequency Identification), UWB (Ultra Wide Band), Communication technologies such as Bluetooth and wireless sensor networks can be used.
  • RFID Radio Frequency Identification
  • UWB Ultra Wide Band
  • Communication technologies such as Bluetooth and wireless sensor networks can be used.
  • FIG. 20 is a diagram illustrating an example of a manipulator constituting the wearable healthcare system of FIG. 11, and FIG. 21 is a block diagram showing an operation unit of the manipulator of FIG. 20.
  • the manipulation unit 420 includes a touch input means 422 for inputting a manipulation command by a user's touch input, and a voice input means for a user to input a manipulation command by voice. Includes (424).
  • the touch input means 422 may be composed of a button 422-1 or a touch panel 422-2, and the touch panel 422-2 is a touch input as well as a user touching and pushing a finger, etc. Includes functions that can be manipulated.
  • the voice input means 424 may be configured with a known microphone or the like.
  • the display unit 410 may display symbols such as letters and numbers, and images such as graphs and moving pictures. Therefore, the display unit 410 can effectively display a control value of the wearable healthcare system of the present invention, information to be transmitted to a user, a text transmitted from the terminal 20, and the like so that the user can recognize it.
  • the manipulator control unit 440 stores control data including control data according to an operation command input through the manipulation unit 420, control data transmitted from the server 10, etc. to constitute the wearable healthcare system of the present invention. It may be transmitted to the healthcare device to control the healthcare device.
  • the manipulator control unit 440 may transmit the control data using the manipulator communication unit 430.
  • the server 10 is a server capable of controlling and managing the wearable healthcare system of the present invention based on the received data, and will be described with reference to FIG. 1, the server communication unit 11, the storage unit 12, and the determination It may include a unit 13, an audio unit 14, and a server control unit 15.
  • the server 10 may be provided in an independent device, or included in the mask 100, the neckband 200, the biometric signal meter 300, the manipulator 400, and the terminal 20. have.
  • the server communication unit 11 includes a communication module, etc. so that the server 10 and an external device can transmit and receive data with each other, and to be suitable for data transmission/reception, RFID (Radio Frequency Identification), UWB (Ultra Wide Band), Communication technologies such as Bluetooth and wireless sensor networks can be used.
  • RFID Radio Frequency Identification
  • UWB Ultra Wide Band
  • Communication technologies such as Bluetooth and wireless sensor networks can be used.
  • the storage unit 12 may store data, and the data stored in the storage unit 12 include environmental data measured by the mask sensor unit 150, the neckband sensor unit 210, and the like, and the measuring device. Body data, music data, and image data of the user measured by the sensor unit 320 may be included.
  • the determination unit 13 may calculate data for controlling the wearable healthcare system of the present invention, and determine a user's physical condition and an action to be recommended to the user. For example, the determination unit 13 calculates the control data for controlling the wearable healthcare system of the present invention based on the environmental data or the body data, and based on the body data, the user's body
  • the state data may be generated by determining information related to the environment, and recommendation data may be generated based on the environmental data or the body data to determine a recommendation action for recommending a specific action to the user.
  • FIG. 22 is a block diagram illustrating a determination unit of a server constituting the wearable healthcare system of FIG. 21.
  • the determination unit 13 calculates the control data
  • the determination unit 13 measures the wind power of the first blowing means of the mask 100 and the second blowing means of the neckband 200. Blowing control data for control can be calculated.
  • the determination unit 13 is in proportion to the user's body temperature measured by the measuring instrument sensor unit 320 and transmitted, the user's heart rate, and the amount of negative ions measured by the mask sensor unit 150 and transmitted. 1 It is possible to calculate the first blowing control data so that the wind power of the blowing means becomes stronger. This is because when the user's body temperature rises or the heart rate increases, it is necessary to supply more oxygen to the user and circulate the wind to cool off the heat, and when there are more negative ions around the user's face, it is necessary to effectively inhale them.
  • the determination unit 13 may calculate the second blowing control data so that the wind power of the second blowing means increases in proportion to the temperature of the air measured by the neckband sensor unit 240 and transmitted. Since the diffusion rate of negative ions increases as the temperature increases, the amount of negative ions generated from the negative ion generating port 240a may decrease as the temperature increases. Therefore, in order to effectively supply near the user's neck or face, it is necessary to minimize the diffusion of negative ions generated from the negative ion generating port 240a by increasing the wind output from the second blowing means in proportion to the measured air temperature. Because there is.
  • the determination unit 13 is an anion control for controlling the amount of anions generated in the anion generating port 240a of the neckband 200 Data can be calculated.
  • the determination unit 13 has a large amount of negative ions generated in the negative ion generating port 240a in proportion to the degree of contamination of the air measured by the mask sensor unit 150 or the neckband sensor unit 240 and transmitted.
  • the first anion control data can be calculated to be This is because the negative ions generated in the negative ion generator 240a and the dust having positive ions in the air are effectively combined and removed by a load, so that the air around the user's neck or face can be kept clean.
  • the determination unit 13 is for controlling the volume of the sound output from the mask sound output unit 160 or the sound output unit 250a. Sound control data can be calculated.
  • the determination unit 13 is the mask sound output unit 160 or the sound output unit in proportion to the amount of noise measured and transmitted by the mask sensor unit 150 or the neckband sensor unit 240
  • First sound control data or second sound control data may be calculated so that the sound output from 250a is increased. This is because, when the user's surroundings are noisy, it is difficult to effectively hear the sound output from the mask sound output unit 160 or the sound output unit 250a.
  • the determination unit 13 may generate the state data by determining a state of a physical state such as a user's exercise amount, exercise intensity, health, and physical strength change. I can.
  • the determination unit 13 may determine the state of the user's exercise amount and exercise intensity based on the user's heart rate information measured and transmitted by the meter sensor unit 320.
  • the method of determining the amount of exercise may employ a method of calculating the amount of exercise using a conventional heart rate over time, and the method of determining the intensity of luck is to determine the intensity of exercise such as aerobic and tempo according to the current heart rate. The method can be adopted.
  • the state data may be generated based on the determination.
  • the determination unit 13 determines changes in the user's health and physical strength based on the user's heart rate and body temperature information measured and transmitted by the measuring instrument sensor unit 320, for example, if the user's heart rate is irregular, arrhythmia It can be determined that there are symptoms such as, and if the user's body temperature is outside the normal range, it can be determined that there is an abnormality in health.
  • the user's physical strength change may be determined by comparing the user's past maximum heart rate with the currently measured maximum heart rate. When a change in health and physical strength of the user is determined, the state data may be generated based on this.
  • the determination unit 13 may determine and recommend actions such as rest, medical treatment, exercise, and movement to be recommended to the user.
  • the determination unit 13 is measured and transmitted by the user's body temperature, the user's heart rate, the mask sensor unit 150 or the neckband sensor unit 240 measured and transmitted by the measuring instrument sensor unit 320
  • the recommendation data for recommending a specific action to a user may be generated based on the determined temperature, humidity, and air pollution level.
  • the recommendation data for recommending rest or treatment may be generated, and the recommended data for recommending exercise intensity having an appropriate heart rate to the user in consideration of temperature and humidity. Can be generated.
  • a conventional exercise intensity recommendation method according to a heart rate may be used based on the maximum heart rate information of the user stored in the storage unit 12.
  • the determination unit 13 generates the recommendation data for recommending a moving route to the user based on the location information of the user measured and transmitted by the mask sensor unit 150 or the neckband sensor unit 240 can do. For example, when a user wants to move to a specific location and inputs the specific location through the operation unit 420, the server 10 transmits the user's current location information and the input information on the specific location. Upon receiving, the determination unit 13 may generate the recommendation data for recommending a path for moving to the specific location using a conventional location guide program or the like.
  • the voice unit 14 converts data to be transmitted from the server 10 to an external device or an external server into voice data that can be output as voice, or recognizes a user's voice transmitted to the server 10, Based on the recognized voice, the server control unit 15 can control the wearable healthcare system of the present invention.
  • FIG. 23 is a block diagram showing a voice conversion module of a voice unit of a server constituting the wearable healthcare system of FIG. 21.
  • the voice unit 14 may include a voice conversion module to convert data into the voice data.
  • the voice conversion module converts the control data, the status data, the recommendation data, and the control data received from the manipulator 400 into the voice data calculated and determined by the determination unit 13. can do.
  • the voice conversion module may employ a conventional voice conversion program or the like.
  • the voice data converted by the voice unit 14 is transmitted to the mask 100 or the neckband 200 and is output as voice through the mask sound output unit 160 or the sound output unit 250a Can be.
  • FIG. 24 is a block diagram illustrating a voice recognition module of a voice unit of a server constituting the wearable healthcare system of FIG. 21.
  • the voice input means of the manipulator 400 When the voice input through 424 is transmitted to the server 10, the voice receiving means 14-1 receives the voice signal and transmits it to the voice signal processing means 14-2.
  • the voice signal processing means (14-2) detects a command for controlling the wearable healthcare system of the present invention based on the voice signal transmitted from the voice receiving means (14-1), and sends the control data to the server controller. Transfer to (15).
  • server control unit 15 transmits the control data transmitted from the voice signal processing unit 14-2 to the healthcare device constituting the wearable healthcare system of the present invention through the server communication unit 11 I can.
  • the server controller 15 may transmit data such as the control data, the status data, and the recommendation data to the healthcare device to control the healthcare device or provide information such as music and video to the user. .
  • the server control unit 15 transmits the state data and the recommendation data generated by the determination unit 13 and converted into the voice data through the voice unit 14 to the server communication unit 11.
  • the transmitted voice data may be output as voice through the mask sound output unit 160 or the sound output unit 250a so that the user can recognize it.
  • the server control unit 15 transmits the control data calculated by the determination unit 13 to the mask 100 and the neckband 200 through the server communication unit 11.
  • the server control unit 15 controls the healthcare device based on the control data calculated by the determination unit 13, the user's permission may be required. For example, when the server control unit 15 attempts to control the healthcare device, a voice inquiring for permission to control the healthcare device is sent to the mask sound output unit 160 or the sound output unit 250a. ) Can be configured to be output. In addition, the server controller 15 may be configured to control the healthcare device only when the user inputs a permission command through the manipulator 400 in response to a control permission inquiry of the healthcare device.
  • the terminal 20 is a device capable of being portable by a user and having a communication module to transmit and receive data such as phone calls and text messages.
  • the terminal 20 may include a smartphone, a tablet PC, and a mobile phone.
  • the terminal 20 may transmit civil war notification data to inform the server 10 or the manipulator 400 of a call (hereinafter referred to as civil war), and the server 10 and the manipulator 400 Call data may be transmitted and received with one or more of the health care devices 400, the mask 100, and the neckband 200.
  • civil war civil war notification data
  • the server 10 and the manipulator 400 Call data may be transmitted and received with one or more of the health care devices 400, the mask 100, and the neckband 200.
  • FIG. 25 is a block diagram illustrating an example of the operation of the wearable healthcare system of FIG. 11 when civil war occurs.
  • the pronation is displayed on the display unit 410 of the manipulator 400, or the mask sound output unit 160 or the sound output
  • the civil war notification data may be transmitted to the mask 100, the neckband 200, the manipulator 400, or the server 10 so that the civil war notification data is output as sound by the unit 250a.
  • the civil war notification data is transmitted to the server 10
  • the civil war notification data is converted into civil war voice data and transmitted to the mask sound output unit 160 or the sound output unit 250a to notify the civil war by voice. I can.
  • the manipulator 400 transmits reception control data through the manipulator communication unit 430 to the terminal ( 20).
  • 26 is a block diagram illustrating an example of the operation of the wearable healthcare system of FIG. 11 during a phone call.
  • the terminal 20 receiving the reception control data receives a phone call, receives the voice input through the operation unit 420, and receives the mask sound output unit 160 or the sound Voice can be transmitted (hereinafter referred to as transmission/reception of call data) so that voice is output through the output unit 250a.
  • a transmission command voice can be transmitted to the server 10 through the manipulator communication unit 430.
  • the server 10 receiving the transmission command voice may detect the command through the voice unit 14 and transmit transmission control data to the server control unit 15.
  • the server control unit 15 transmits the transmission control data to the terminal 20
  • the terminal 20 can initiate a call by making a phone call to a specific person.
  • the server 10 When the amount of negative ions, air quality, noise, and location information measured by the mask sensor unit 150 or the neckband sensor unit 240 and the body data measured by the biosignal meter 300 are transmitted to the server 10 It may be stored in the storage unit 12.
  • the determination unit 13 is based on the data stored in the storage unit 12, the first blowing means wind power, the second blowing means wind power, the negative ion generation amount of the negative ion generator 240a, the mask sound output section ( 160) Alternatively, the control data for controlling the volume of the output sound of the sound output unit 250a may be calculated. In addition, the determination unit 13 may generate the recommendation data for recommending a specific action to the user based on the data stored in the storage unit 12.
  • the calculated control value of the control data and the recommended action of the generated recommendation data may be converted into the voice data by the voice unit 14 so that the user can receive information by voice.
  • the server 10 transmits the calculated control data to determine the amount of air blown by the mask 100 or the neckband 200, the amount of anion generated by the anion generator 240a, and the mask 100 or the neckband.
  • the volume of the sound output from 200 can be controlled.
  • the mask sound output unit 160 or the sound output unit 250a can be used to output the control value and the recommended action as a voice through the mask sound output unit 160 or the sound output unit 250a so that the user can easily recognize the control value and the recommended action. have.
  • body data such as the user's heart rate and body temperature measured by the biometric signal meter 300
  • the determination unit 13 is based on the user's heart rate.
  • the state data may be generated by determining changes in exercise amount, exercise intensity, health, and physical strength, and the state data may be generated by determining health based on the user's body temperature.
  • the generated state data related to the user's physical condition may be converted into the voice data by the voice unit 14.
  • the generated state data is transmitted and output as a voice through the mask sound output unit 160 or the sound output unit 250a, or is displayed as text using the display unit 410, and the user's body state Information about can be delivered to the user.
  • the control data related to the command through the manipulator control unit 440 is transmitted to the health care. It can be transmitted to the device to control the healthcare device.
  • the neckband ( 200) to control the operation of the neckband 200 by transmitting the control data for controlling the output sound volume, the amount of negative ions generated, and the wind power of the blowing means, and the power to the biosignal meter 300, the measured heart rate data
  • the operation of the biosignal measuring device 300 may be controlled by transmitting the control data for controlling transmission or not.
  • control data may be transmitted to the server 10.
  • the command is transmitted to the server 10 and the determination unit 13 and the voice unit 14
  • Information on the user's current exercise intensity is generated as the voice data, and the generated voice data may be transmitted to the neckband 200 and output as voice through the sound output unit 250a.
  • control data may be transmitted to the terminal 20 to receive or make a call by manipulating the manipulator 400.
  • the manipulator 400 transmits the reception control data to the terminal 20 to make a call It is possible to control the terminal 20 to receive.
  • the transmission control data is transmitted to the terminal 20 through the voice unit 14 of the server 10
  • the terminal 20 can be controlled to make a call to a specific person.
  • the wearable health care system of the present invention provides an effect of effectively taking care of the user's health by allowing the user to effectively inhale negative ions or oxygen depending on the situation.
  • the sound output unit of the health care device constituting the wearable health care system is equipped with a directional speaker so that sound can be effectively transmitted to the user, and a phone call can be made without carrying a phone with simple operation. Provides an effect of enhancing user convenience.
  • a health care device comprising a mask and a neckband is controlled to operate effectively according to a situation, thereby providing an effect of remarkably improving the health and convenience of a user.
  • a wearable healthcare system composed of healthcare devices provides an effect of remarkably improving the user's health and convenience by operating in consideration of the user's physical condition and surrounding environment.
  • the wearable healthcare system can be controlled by the user's voice, the user can easily manipulate the healthcare device.
  • the server can recommend actions necessary for the user in the current situation, providing an effect of allowing the user to know the actions necessary for health and safety.
  • first filter 126 second filter
  • 210a, 210b first neckband communication unit, second neckband communication unit
  • neckband sensor unit 240a negative ion generator
  • 250 neckband control unit 250a: sound output unit
  • 252a fixed output unit 254a
  • 254b moving output unit
  • biosignal measuring device 310 first coupling unit
  • first magnetic body 320 measuring instrument sensor unit
  • measuring instrument operation unit 340 measuring instrument communication unit
  • manipulator control unit 500 first smart clothing
  • the wearable health care system provides an effect of effectively taking care of the user's health by allowing the user to effectively inhale negative ions or oxygen depending on the situation.
  • the sound output unit of the health care device constituting the wearable health care system is equipped with a directional speaker so that sound can be effectively transmitted to the user, and a phone call can be made without carrying a phone with simple operation. Provides an effect of enhancing user convenience.
  • a health care device comprising a mask and a neckband is controlled to operate effectively according to a situation, thereby providing an effect of remarkably improving the health and convenience of a user.
  • a wearable healthcare system composed of healthcare devices provides an effect of remarkably improving the user's health and convenience by operating in consideration of the user's physical condition and surrounding environment.
  • the wearable healthcare system can be controlled by the user's voice, the user can easily manipulate the healthcare device.
  • the server can recommend actions necessary for the user in the current situation, providing an effect of allowing the user to know the actions necessary for health and safety.

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Abstract

Dans un système de soins de santé pouvant être porté, selon un mode de réalisation de la présente invention, un masque calcule la quantité de respiration appropriée pour la quantité d'exercice d'un utilisateur sur la base des données de biosignal de l'utilisateur mesurées par l'intermédiaire d'un dispositif de mesure de biosignal et ajuste la quantité d'air extérieur fourni à l'utilisateur, de manière à purifier l'air et à empêcher également l'air purifié fourni à l'utilisateur d'être insuffisant.
PCT/KR2020/009738 2019-08-06 2020-07-23 Système de soin de santé pouvant être porté WO2021025346A1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
KR1020190095510A KR20190099154A (ko) 2019-08-06 2019-08-06 헬스 케어 시스템
KR10-2019-0095598 2019-08-06
KR10-2019-0095510 2019-08-06
KR1020190095598A KR102677427B1 (ko) 2019-08-06 2019-08-06 웨어러블 시스템

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CN114432607A (zh) * 2021-12-30 2022-05-06 安徽上造智能设备科技有限公司 配备智能穿戴设备的防护服及其工作方法
EP4389232A1 (fr) * 2022-12-19 2024-06-26 Honeywell International Inc. Appareils et procédés pour fournir des dispositifs de protection respiratoire avec des écouteurs amovibles et pouvant être passés outre

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KR20170031956A (ko) * 2015-09-14 2017-03-22 유제빈 넥밴드형 음이온 발생장치
KR101881775B1 (ko) * 2016-10-12 2018-07-27 (주)텍스트무브 웨어러블형 휴대용 에어 블로워 및 이를 이용한 대기오염 모니터링 시스템
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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114432607A (zh) * 2021-12-30 2022-05-06 安徽上造智能设备科技有限公司 配备智能穿戴设备的防护服及其工作方法
CN114432607B (zh) * 2021-12-30 2022-09-13 安徽上造智能设备科技有限公司 配备智能穿戴设备的防护服及其工作方法
EP4389232A1 (fr) * 2022-12-19 2024-06-26 Honeywell International Inc. Appareils et procédés pour fournir des dispositifs de protection respiratoire avec des écouteurs amovibles et pouvant être passés outre

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