CN113739986A - Wearable equipment with blood pressure and gaseous detection function - Google Patents

Wearable equipment with blood pressure and gaseous detection function Download PDF

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Publication number
CN113739986A
CN113739986A CN202010475705.4A CN202010475705A CN113739986A CN 113739986 A CN113739986 A CN 113739986A CN 202010475705 A CN202010475705 A CN 202010475705A CN 113739986 A CN113739986 A CN 113739986A
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air
valve
gas
processor
heat dissipation
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CN113739986B (en
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王滨
彭日亮
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Huawei Technologies Co Ltd
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Huawei Technologies Co Ltd
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L19/00Details of, or accessories for, apparatus for measuring steady or quasi-steady pressure of a fluent medium insofar as such details or accessories are not special to particular types of pressure gauges
    • 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
    • A61B5/021Measuring pressure in heart or blood vessels
    • A61B5/022Measuring pressure in heart or blood vessels by applying pressure to close blood vessels, e.g. against the skin; Ophthalmodynamometers
    • 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
    • A61B5/021Measuring pressure in heart or blood vessels
    • A61B5/022Measuring pressure in heart or blood vessels by applying pressure to close blood vessels, e.g. against the skin; Ophthalmodynamometers
    • A61B5/02233Occluders specially adapted therefor
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L19/00Details of, or accessories for, apparatus for measuring steady or quasi-steady pressure of a fluent medium insofar as such details or accessories are not special to particular types of pressure gauges
    • G01L19/06Means for preventing overload or deleterious influence of the measured medium on the measuring device or vice versa
    • G01L19/0681Protection against excessive heat

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  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Physics & Mathematics (AREA)
  • Vascular Medicine (AREA)
  • Cardiology (AREA)
  • Engineering & Computer Science (AREA)
  • Public Health (AREA)
  • Ophthalmology & Optometry (AREA)
  • Biophysics (AREA)
  • Pathology (AREA)
  • General Physics & Mathematics (AREA)
  • Biomedical Technology (AREA)
  • Heart & Thoracic Surgery (AREA)
  • Medical Informatics (AREA)
  • Molecular Biology (AREA)
  • Surgery (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Physiology (AREA)
  • Veterinary Medicine (AREA)
  • Dentistry (AREA)
  • Measuring Pulse, Heart Rate, Blood Pressure Or Blood Flow (AREA)

Abstract

The embodiment of the application discloses wearable equipment with blood pressure and gaseous detection function belongs to health detection technical field. This wearable equipment includes equipment body, air cavity, gasbag, barometer, gas sensor, micropump and treater, wherein: the air cavity, the air bag, the barometer and the processor are all positioned in the equipment body, and the air sensor and the micropump are all positioned in the air cavity; the device body is provided with air vents, and the air vents are connected with the air cavity, the air cavity and the air bag, and the air bag and the barometer through air passages respectively; an air inlet valve is arranged on the air passage between the air vent and the air cavity, and an air bag valve is arranged on the air passage between the air cavity and the air bag; the wearable device measures blood pressure through a barometer and gas components through a gas sensor. By adopting the method and the device, the blood pressure can be measured, and the gas component measurement can be carried out on the gas exhaled by the user and the gas in the environment. Therefore, the wearable device has more using functions.

Description

Wearable equipment with blood pressure and gaseous detection function
Technical Field
The application relates to the technical field of health detection, in particular to a wearable device with blood pressure and gas detection functions.
Background
Along with the development of intelligent detection equipment, wearable equipment that can detect data such as blood pressure, electrocardio, rhythm of the heart is also more and more, for example, wrist formula sphygmomanometer, intelligent bracelet and intelligent wrist-watch are the more common wearable equipment that can carry out health detection promptly.
But most of the common wearable devices have single functions.
Disclosure of Invention
The embodiment of the application provides a wearable equipment with blood pressure and gaseous detection function, can overcome the comparatively single problem of wearable equipment majority function among the correlation technique, technical scheme is as follows:
in one aspect, a wearable device is provided, the wearable device comprising a device body, an air cavity, an air bladder, a barometer, a gas sensor, a micropump, and a processor, wherein:
the air cavity, the air bag, the barometer and the processor are all positioned in the equipment body, and the gas sensor and the micropump are all positioned in the air cavity;
the device body is provided with vent holes, and the vent holes are connected with the air cavity, the air cavity and the air bag, and the air bag and the barometer through air passages respectively;
an air inlet valve is arranged on an air passage between the air vent and the air cavity, and an air bag valve is arranged on the air passage between the air cavity and the air bag;
the processor is respectively electrically connected with the barometer, the gas sensor and the micropump, and is used for controlling the opening and closing of the air inlet valve and the air bag valve and controlling the starting and stopping of the micropump, using the barometer to measure blood pressure, controlling the starting and stopping of the micropump by controlling the opening and closing of the air inlet valve and the air bag valve, and controlling the starting and stopping of the gas sensor to measure gas components.
In one example, the gas cavity is used to house a micro-pump and a gas sensor for measuring the composition of the gas, e.g., the gas sensor may measure the composition of the gas located in the gas cavity. Barometers are used to measure blood pressure. The micro pump is used for pumping air into the air bag and the air cavity. The processor is used for controlling the barometer, the micropump, the gas sensor and each valve to work so as to realize blood pressure measurement and gas composition measurement.
In one example, the processor is used for measuring blood pressure by controlling the opening and closing of the air inlet valve and the air bag valve and controlling the starting and stopping of the micropump; the micro pump is used for controlling the starting and stopping of the micro pump and the starting and stopping of the gas sensor by controlling the opening and closing of the air inlet valve and the air bag valve so as to measure the gas components.
As an example, when blood pressure is measured, the air inlet valve and the air bag valve are opened, the micro pump is started, and air is pumped into the air bag. When the blood pressure measurement is finished, the micro pump is stopped, and the gas in the air bag is freely diffused and exhausted through the vent. When gas components are measured, the gas inlet valve and the airbag valve are opened, the micropump is started, residual gas in the gas cavity is discharged into the airbag, and when the gas cavity is filled with gas to be detected, the gas sensor is started to measure the gas components. After the gas component measurement is finished, the gas sensor is closed, and the gas inlet valve and the airbag valve are opened, so that the gas in the airbag and the gas cavity is freely diffused and exhausted through the vent hole.
Therefore, the wearable device can measure the blood pressure through the barometer, measure the gas composition of the gas exhaled by the user through the gas sensor, and measure the gas composition of the gas in the environment. Therefore, the wearable device has more functions and enriches the application scenes.
In addition, in the gas component measurement, the gas exhaled by the user can be measured, and the gas in the environment can also be measured, so that the use functions of the wearable device are further enriched.
In a possible embodiment, the processor is used for controlling the air inlet valve and the air bag valve to be opened when a signal for starting blood pressure measurement is detected, controlling the micro pump to start to work, receiving air pressure data collected by the barometer, calculating blood pressure data according to the air pressure data, controlling the micro pump to stop working when a signal for finishing blood pressure measurement is detected, and controlling the air inlet valve and the air bag valve to be closed after the air in the air bag is freely discharged from the air vent;
when a signal for starting gas component measurement is detected, the gas inlet valve and the airbag valve are controlled to be opened, the micro pump is controlled to start to work, residual gas in the gas cavity is discharged into the airbag, when the gas cavity is filled with gas to be measured, the micro pump is controlled to stop working, the gas inlet valve and the airbag valve are controlled to be closed, the gas sensor is controlled to start to work, gas data collected by the gas sensor is received, gas components are calculated according to the gas data, when a signal for finishing gas component measurement is detected, the gas sensor is controlled to stop working, the gas inlet valve and the airbag valve are controlled to be opened, and after the gas in the airbag is freely discharged from the vent, the gas inlet valve and the airbag valve are controlled to be closed.
In one example, in blood pressure measurement, the air is pumped into the air bag through the micro pump, the air pumping speed is high, the air bag can be filled with air rapidly, the air in the air bag can improve the measurement result of blood pressure under the condition of being sufficient, and the accuracy of blood pressure measurement of the wearable device is improved.
In the gas component measurement, the residual gas in the gas cavity is discharged into the air bag, and the gas sensor is started to measure the gas component after the residual gas in the gas cavity is discharged, so that the accuracy of the gas component measurement can be improved.
In a possible implementation mode, the equipment body is also provided with a heat dissipation outlet, and an air passage is connected between the air cavity and the heat dissipation outlet;
the air channel between the air cavity and the heat dissipation outlet is respectively contacted with a plurality of heating elements in the equipment body, and the plurality of heating elements dissipate heat through the air channel between the air cavity and the heat dissipation outlet;
an air outlet valve is arranged on the air passage between the air cavity and the heat dissipation outlet and close to the heat dissipation outlet, and a heat dissipation valve is arranged on the air passage between the air cavity and the heat dissipation outlet and close to the air cavity;
the processor is also used for controlling the air inlet valve, the air bag valve, the air outlet valve and the heat dissipation valve to be opened and closed and controlling the micro pump to be started and stopped so as to dissipate heat of a plurality of heating elements.
In one example, the heat dissipation outlet is used for exhausting gas in the air bag and the air cavity when heat is dissipated. In the heat dissipation process, the air inlet valve and the air bag valve are opened, the heat dissipation valve and the air outlet valve are closed, when the air bag and the air cavity are filled with air, the air inlet valve and the air bag valve are closed, the heat dissipation valve and the air outlet valve are opened, the air in the air bag and the air cavity flows to the heat dissipation outlet through the air passage, and the air can take away heat on the heating element in the flowing process of the air passage to dissipate heat of the heating element.
Therefore, the wearable device not only has the functions of measuring blood pressure and gas components, but also has the function of heat dissipation. This wearable equipment's heat dissipation function can avoid heating element to break down because of the high temperature, causes the fire incident even, and then can maintain heating element's normal work, prolongs its life, can also improve this wearable equipment's safety in utilization
In a possible embodiment, the processor is used for controlling the air outlet valve and the heat dissipation valve to be closed, controlling the air inlet valve and the air bag valve to be opened and controlling the micro pump to start to work when a signal for starting heat dissipation is detected;
when the air bag is filled with air, the micropump is controlled to stop working, the air inlet valve is controlled to be closed, the air bag valve, the air outlet valve and the heat dissipation valve are controlled to be opened, and the air flows in an air passage between the air cavity and the heat dissipation outlet to dissipate heat of the heating element;
when a signal of finishing heat dissipation is detected, the gas in the air bag is discharged from the heat dissipation outlet and then the air bag valve, the gas outlet valve and the heat dissipation valve are controlled to be closed.
In one example, in heat dissipation, the air bag and the air cavity are filled with air, and then the air in the air bag and the air cavity flows in the air passage and is discharged from the heat dissipation outlet, so that the heat of the heating element can be taken away by the air flowing in the air passage to dissipate the heat of the heating element.
The air bag and the air cavity are filled with air firstly, then the air flows in the air passage, the flow of the air can be increased in the heat dissipation process, a large amount of air flows in the air passage, the heat on the heating element passing through the air passage can be taken away quickly and effectively, and then the heat dissipation speed is improved for the heating element to dissipate heat quickly.
In a possible embodiment, the wearable device further comprises an air outlet valve control and a heat dissipation valve control, both of which are electrically connected to the processor;
the processor is used for controlling the air outlet valve to be opened and closed through the air outlet valve control part and controlling the heat dissipation valve to be opened and closed through the heat dissipation valve control part.
In one example, the processor controls the opening and closing of the outlet valve through the outlet valve control member, and controls the opening and closing of the heat dissipation valve through the heat dissipation valve control member.
The treater passes through the opening and closing of heat dissipation valve control piece control heat dissipation valve, controls the opening and closing of air outlet valve through air outlet valve control piece, realizes air outlet valve and heat dissipation valve's automated control, need not user manual control, can promote the user of this wearable equipment and use and experience.
In one possible embodiment, the wearable device further comprises a gas sensor control, a micropump control, an intake valve control, and an airbag valve control;
the gas sensor control element, the micropump control element, the air inlet valve control element and the airbag valve control element are all electrically connected with the processor;
the processor is used for controlling the gas sensor to start and stop through the gas sensor control piece, controlling the micropump to start and stop through the micropump control piece, controlling the air inlet valve to open and close through the air bag valve control piece, and controlling the air bag valve to open and close through the air bag valve control piece.
In one example, the processor controls the gas sensor to start and stop operation via the gas sensor control, controls the micro-pump to start and stop operation via the micro-pump control, controls the intake valve to open and close via the intake valve control, and controls the airbag valve to open and close via the airbag valve control.
The gas sensor is controlled to start and stop by the gas sensor control element, the micro pump is controlled to start and stop by the micro pump control element, the gas inlet valve is controlled to open and close by the gas inlet valve control element, the air bag valve is controlled to open and close by the air bag valve control element, the gas sensor and the micro pump are not required to be manually controlled to start and stop by a user, the gas inlet valve and the air bag valve are not required to be manually controlled to open and close by the user, certain convenience is brought to the use of the user, and the use experience of the user is enhanced.
In a possible embodiment, the wearable device further comprises a signal processing unit, and the signal processing unit is electrically connected with the barometer and the processor respectively;
the signal processing part is used for receiving the air pressure data collected by the barometer and sending the processed air pressure data to the processor.
In one example, the signal processing unit may be a digital-to-analog conversion unit, or may be a signal amplification unit, and may process blood pressure data collected by the barometer and send the processed blood pressure data to the processor.
Therefore, the data collected by the barometer are processed by the signal processing part and then sent to the processor, and the measurement accuracy of the blood pressure data can be improved.
In a possible implementation manner, the wearable device further includes a power chip, the power chip is electrically connected to the micro pump and the processor, and the processor is further configured to control the power chip to output a voltage to the micro pump.
In one example, the power chip is used for inputting voltage to the micro pump under the control of the processor, wherein the rotation speed of the micro pump can be related to the input voltage, and the higher the voltage is provided to the micro pump, the higher the rotation speed of the micro pump is, the faster the gas can be filled in the gas bag. The technician can set the gear of the micro pump according to the voltage provided to the micro pump, for example, the high gear of the micro pump, the power chip provides higher voltage to the micro pump, the middle gear of the micro pump, the power chip provides medium voltage to the micro pump, the low gear of the micro pump, the power chip provides lower voltage to the micro pump. In some applications, the processor may control the power chip to input a high-level voltage to the micro-pump, for example, in blood pressure measurements, and in other applications, the processor may control the power chip to input a low-level voltage to the micro-pump, for example, in gas composition measurements.
When this wearable equipment is carrying out blood pressure measurement, need take out gaseously with the gasbag fast, power chip can be to the great voltage of micropump input. When the wearable device detects the gas components, in order to improve the measurement speed, the power supply chip can input larger voltage to the micropump, so that the gas component measurement speed is improved. In the heat dissipation process, the gas flows slowly in the air passage to take away the heat generated by the heating element, and correspondingly, the power supply chip can input smaller voltage to the micropump. Therefore, the wearable device can control the power supply chip to provide proper voltage for the micro pump according to the specific executed function, the use flexibility of the wearable device can be improved, and the micro pump can be protected.
In one possible embodiment, the wearable device is a wrist device or a arm device, the device body includes a wearing body and a device body, the airbag is located in the wearing body, and the air chamber, the barometer and the processor are all located in the device body.
In one example, the wearable device is a wrist-type device or arm-type device, in which case the device body may include a donning body and a device body, the bladder may be located in the donning body, and the air chamber, the barometer, and the processor may all be located in the device body. Illustratively, the wearable device is a smart watch, the wearing body can be a watchband, and the device body can be a watch body.
The wearable device is wrist type or arm type, is small in size, small and exquisite, can be carried by a user, and can be used for measuring blood pressure and gas components at any time and any place.
Wherein, gas composition measurement can be to the gas of user's exhalation, also can measure the environment that the user is located, can promote this wearable equipment's application scene.
In another aspect, a method for using a wearable device is provided, where the wearable device is the wearable device described above, and the method includes:
when a signal for starting blood pressure measurement is detected, the air inlet valve and the air bag valve are opened, the micro pump is started to measure blood pressure, when a signal for finishing blood pressure measurement is detected, the micro pump is stopped, and after gas in the air bag is freely discharged from the vent, the air inlet valve and the air bag valve are closed;
when a signal for starting gas component measurement is detected, the gas inlet valve and the airbag valve are opened, the micro pump is started, residual gas in the gas cavity is discharged into the airbag, when the gas cavity is filled with gas to be measured, the micro pump is stopped, the gas inlet valve and the airbag valve are closed, the gas sensor is started to measure the gas component, when a signal for finishing gas component measurement is detected, the gas sensor is stopped, the gas inlet valve and the airbag valve are opened, and after the gas in the airbag is freely discharged from the vent, the gas inlet valve and the airbag valve are closed.
In the embodiment of the application, the wearable device comprises an air cavity, an air bag and a barometer which are positioned in a device body, and a micro pump and a gas sensor which are positioned in the air cavity, so that the wearable device can measure the blood pressure through the barometer, measure the gas components of the gas exhaled by a user through the gas sensor, and measure the gas components of the gas in the environment. Therefore, the wearable device has more functions and enriches the application scenes.
Drawings
Fig. 1 is a schematic structural diagram of a wearable device provided in an embodiment of the present application;
fig. 2 is a schematic structural diagram of a wearable device provided in an embodiment of the present application;
fig. 3 is a schematic structural diagram of a wearable device provided in an embodiment of the present application;
fig. 4 is a schematic flow chart of blood pressure measurement using a wearable device according to an embodiment of the present disclosure;
fig. 5 is a schematic view of a wearable device provided in an embodiment of the present application when air is pumped into an airbag;
fig. 6 is a schematic view of a wearable device according to an embodiment of the present disclosure, in which the wearable device exhausts air through a vent;
FIG. 7 is a schematic flow chart illustrating gas composition measurement using a wearable device according to an embodiment of the present disclosure;
FIG. 8 is a schematic diagram of a scenario for gas composition measurement in a gas cavity according to an embodiment of the present application;
fig. 9 is a schematic flow chart illustrating heat dissipation of a wearable device according to an embodiment of the present disclosure;
fig. 10 is a schematic view of a scene in which a wearable device provided in an embodiment of the present application dissipates heat;
fig. 11 is a schematic flow chart illustrating usage of a wearable device according to an embodiment of the present application.
Description of the figures
1. An apparatus body; 2. an air cavity; 3. an air bag; 4. a barometer; 5. a gas sensor; 6. a micropump; 7. a processor; 8. an airway; 9. an intake valve; 10. an air bag valve; 11. an air outlet valve; 12. a heat dissipation valve; 13. a signal processing part; 14. a power supply chip; 51. a gas sensor control; 61. a micro-pump control; 91. an intake valve control; 100. an airbag valve control; 101. a vent; 102. a heat dissipation outlet; 103. a wearing body; 104. an apparatus body; 111. an outlet valve control; 121. a heat dissipation valve control member.
Detailed Description
The embodiment of the application relates to a wearable device with blood pressure and gas detection functions, and the wearable device can be a wrist type device, for example, a smart watch, a smart bracelet and the like, and can also be a arm type device.
As shown in fig. 1, the wearable device includes a device body 1, an air chamber 2, an airbag 3, a barometer 4, a gas sensor 5, a micro pump 6, and a processor 7, wherein: the air cavity 2, the air bag 3, the barometer 4 and the processor 7 are all located in the equipment body 1, the gas sensor 5 and the micropump 6 are all located in the air cavity 2, and the processor 7 is electrically connected with the barometer 4, the gas sensor 5 and the micropump 6 respectively.
Among them, the barometer 4 is used to measure blood pressure, and the gas sensor 5 is used to measure gas components. The airbag 3 is used for containing gas, can be subjected to contraction change, and can be made of an elastic material.
Wherein the device body 1 is a main body portion of the wearable device for carrying the installation of other components in the wearable device, for example, the device body 1 serves as a carrier for the air chamber 2, the air bag 3, the barometer 4 and the processor 7, and the air chamber 2, the air bag 3, the barometer 4 and the processor 7 are all installed in the device body 1. This wearable equipment can supply the user to dress, and corresponding equipment body 1 still has the effect that supplies the user to dress.
Wherein, because this wearable equipment can supply the user to dress, it is corresponding, equipment body 1 can have skin-friendly nature, compliance and elasticity etc. in the material.
In one example, the shape of the device body 1 is related to the specific type of wearable device, for example, if the wearable device is a coat, the device body may have the appearance of a garment. The size can be divided according to the height and the weight of the user, and can comprise a large size, a medium size, a small size and the like.
As another example, the wearable device is a wrist-type device worn on a user's wrist or a wrist-type device worn on a user's arm. Accordingly, the device body 1 may include a wearing body 103 and a device body 104, the airbag 3 may be located in the wearing body 103, and the air chamber 2, the barometer 4, and the processor 7 may be located in the device body 104. Illustratively, the wearable device is a smart watch, the wearing body 103 may be a watch band, and the device body 104 may be a watch body.
The wearable device needs to be pumped when in use, correspondingly, the device body 1 can be provided with a vent 101, and the vent 101 is connected with the air cavity 2, the air cavity 2 is connected with the air bag 3, and the air bag 3 is connected with the barometer 4 through an air passage 8; an air inlet valve 9 is arranged on an air passage 8 between the air vent 101 and the air cavity 2, and an air bag valve 10 is arranged on the air passage 8 between the air cavity 2 and the air bag 3.
The vent hole 101 may be used as an air inlet or an air outlet, for example, in blood pressure measurement and gas composition measurement, air is drawn into the air bag 3 and the air chamber 2 through the vent hole 101, and after the blood pressure measurement and the gas composition measurement are completed, the air in the air bag 3 and the air chamber 2 is exhausted through the vent hole 101.
The air passage 8 is a pipe through which air flows, and may be referred to as an air passage.
In one example, micro-pump 6 is used to draw gas into gas cavity 2 and bladder 3, and micro-pump 6 is activated and deactivated under the direction of processor 7. For example, as shown in fig. 2, the wearable device may further include a micro-pump controller 61, the micro-pump controller 61 is electrically connected to the micro-pump 6 and the processor 7, and the processor 7 may control the micro-pump 6 to start and stop by the micro-pump controller 61. Illustratively, the processor 7 may send a start command and a stop command to the micro-pump control unit 61, and when the micro-pump control unit 61 receives the start command, the micro-pump control unit 61 may control the micro-pump 6 to start to pump gas into the gas cavity 2 and the gas bag 3 for blood pressure measurement, gas composition measurement, heat dissipation, or the like, and when the micro-pump control unit 61 receives the stop command, the micro-pump 6 may be controlled to stop working.
This wearable equipment is in blood pressure measurement, through micropump 6 to bleeding in gasbag 3, it is fast to bleed, can be full of gas fast in the gasbag 3, and the gas in the gasbag 3 can improve the measuring result of blood pressure under comparatively sufficient circumstances, improves this wearable equipment's blood pressure measurement's accuracy.
As shown in fig. 2, the wearable device may further include a power chip 14, the power chip 14 is electrically connected to the micro pump 6 and the processor 7, respectively, and the processor 7 may control the power chip 14 to output a voltage to the micro pump 6. Wherein the rotation speed of the micro pump 6 can be related to the input voltage, and the higher the voltage provided to the micro pump 6, the higher the rotation speed of the micro pump 6, so as to enable the gas to fill the air bag 3 faster. The technician can set the gear of the micro pump 6 according to the voltage supplied to the micro pump 6, for example, the high gear of the micro pump 6, the power chip 14 supplies a higher voltage to the micro pump 6, the middle gear of the micro pump 6, the power chip 14 supplies a medium voltage to the micro pump 6, the low gear of the micro pump 6, and the power chip 14 supplies a lower voltage to the micro pump. In some applications, for example in blood pressure measurements, the processor 7 may control the power chip 14 to input a high-level voltage to the micro-pump 6, and in other applications, for example in gas composition measurements, the processor 7 may control the power chip 14 to input a low-level voltage to the micro-pump 6.
In one example, the gas sensor 5 is used to measure the components contained in the gas located in the gas chamber 2 and the content of each component, and the gas sensor 5 is activated and deactivated under the instruction of the processor 7. For example, as shown in fig. 2, the wearable device may further include a gas sensor control 51, the gas sensor control 51 is electrically connected to the gas sensor 5 and the processor 7, and the processor 7 may control the gas sensor 5 to start and stop operating through the gas sensor control 51. For example, the processor 7 may send a start command and a stop command to the gas sensor control 51, and the gas sensor control 51 may control the gas sensor 5 to start to operate for gas composition measurement when receiving the start command, and the gas sensor control 51 may control the gas sensor 5 to stop operating when receiving the stop command.
The gas sensor 5 is used for measuring the components contained in the gas chamber 2 and the content of each component, and for example, can be used for measuring the components contained in the gas exhaled by the user and the content of each component, so that the gas sensor can be used as an index for detecting the digestive function of the user and can also be used as an index for judging the oral hygiene. For another example, the gas sensor 5 may be used to measure the components contained in the gas in the environment and the content of each component, thereby being used as a basis for determining the environmental condition. The present embodiment does not limit the specific application scenario of the gas sensor 5.
In one example, the intake valve 9 is opened and closed under the instruction of the processor 7, for example, as shown in fig. 2, the wearable device may further include an intake valve control member 91, the intake valve control member 91 is electrically connected to the intake valve 9 and the processor 7, respectively, and the processor 7 may control the intake valve 9 to be opened and closed through the intake valve control member 91. For example, the processor 7 may send an opening instruction and a closing instruction to the intake valve controller 91, the intake valve controller 91 controls the intake valve 9 to open after receiving the opening instruction, so that the gas enters the apparatus body 1 through the vent 101 under the driving of the micro pump 6, and the intake valve controller 91 controls the intake valve 9 to close after receiving the closing instruction.
In one example, the airbag valve 10 is opened and closed under the instruction of the processor 7, for example, as shown in fig. 2, the wearable device may further include an airbag valve control 100, the airbag valve control 100 is electrically connected to the airbag valve 10 and the processor 7, respectively, and the processor 7 may control the airbag valve 10 to be opened and closed through the airbag valve control 100. For example, the processor 7 may send an opening command and a closing command to the airbag valve control 100, and the airbag valve control 100 receives the opening command and controls the airbag valve 10 to open so as to allow the gas to enter the airbag 3.
In one example, processor 7 may take a blood pressure measurement with barometer 4, for example, one way may be that barometer 4 may send collected air pressure data to processor 7, processor 7 calculates the received air pressure data to obtain blood pressure data, the wearable device has a display through which the user views the blood pressure data. For another example, the barometer 4 may send the collected air pressure data to the processor 7, and after the processor 7 receives the air pressure data and performs some processing, the processed air pressure data may be sent to a processing device connected to the wearable device, so that the processing device calculates the air pressure data to obtain blood pressure data, and the user views the blood pressure data through a display of the processing device. For another example, the barometer 4 may send the collected air pressure data to the processor 7, after the processor 7 receives the air pressure data and performs some processing, the processed air pressure data may be sent to a server, the server calculates the air pressure data to obtain blood pressure data, and sends the blood pressure data to a terminal associated with the wearable device, and the user may view the blood pressure data through an application installed on the terminal.
The present embodiment does not limit the specific way of calculating the blood pressure data from the air pressure data, and the following may be exemplified in the first way in describing the blood pressure measurement.
In an example, as shown in fig. 2, the wearable device may further include a signal processing unit 13, where the signal processing unit 13 is electrically connected to the barometer 4 and the processor 7, respectively, and the signal processing unit 13 may process the received air pressure data collected by the barometer 4 and send the processed air pressure data to the processor 7. For example, the signal processing unit 13 may convert a received analog signal into a digital signal, may perform noise reduction processing on the received air pressure data, may perform amplification processing on the received air pressure data, and the like.
Based on a similar procedure as described above for obtaining blood pressure data, the processor 7 may perform gas composition measurements via the gas sensor 5, for example, one way may be that the gas sensor 5 may send the collected gas data to the processor 7, the processor 7 calculates the received gas data to obtain gas composition data, the wearable device has a display through which the user views the gas composition data. For another example, the gas sensor 5 may send the collected gas data to the processor 7, and after receiving the gas data and performing some processing, the processor 7 may send the processed gas data to a processing device connected to the wearable device, so that the processing device calculates the gas data to obtain gas composition data, and the user views the gas composition data through the processing device. For another example, the gas sensor 5 may send the collected gas data to the processor 7, after the processor 7 receives the gas data and performs some processing on the gas data, the processor may send the processed gas data to a server, the server calculates the gas data to obtain gas composition data, and sends the gas composition data to a terminal associated with the wearable device, and the user may view the gas composition data through an application installed on the terminal. Wherein, the gas component data comprises gas components and the content of each gas component.
The present embodiment does not limit the specific manner of calculating the gas composition data from the gas data, and the following description may be given in the first manner in describing the measurement of the gas composition.
As described above, the processor 7 can perform blood pressure measurement by the barometer 4 and gas component measurement by the gas sensor 5. For example, the processor 7 may perform blood pressure measurements by controlling the opening and closing of the intake valve 9 and the bladder valve 10, as well as controlling the start and stop of the micro-pump 6; the gas composition measurement can be performed by controlling the opening and closing of the intake valve 9 and the bag valve 10, controlling the start and stop of the micro pump 6, and controlling the start and stop of the gas sensor 5.
As an example, in performing a blood pressure measurement, when the processor 7 detects a signal to initiate a blood pressure measurement, the air inlet valve 9 and the air bladder valve 10 are controlled to open, e.g., the air inlet valve 9 is controlled to open by the air inlet valve control 91 and the air bladder valve 10 is controlled to open by the air bladder valve control 100. Then, the processor 7 may control the micro pump 6 to start, for example, the processor 7 may control the micro pump 6 to start through the micro pump control element 61, and control the power chip 14 to provide a voltage of a certain gear to the micro pump 6, so that the processor 7 may receive the air pressure data collected by the barometer 4, and then the processor 7 may calculate the blood pressure data according to the air pressure data. When the processor 7 detects a signal to end the blood pressure measurement, the micro pump 6 is controlled to stop, for example, the processor 7 may control the micro pump 6 to stop by the micro pump control 61. After the micro-pump 6 stops working, the gas in the air bag 3 and the air chamber 2 can be freely diffused and exhausted through the vent 101, and then the processor 7 can control the air inlet valve 9 and the air bag valve 10 to be closed again, for example, the processor 7 controls the air inlet valve 9 to be closed through the air inlet valve control member 91 and controls the air bag valve 10 to be closed through the air bag valve control member 100.
Wherein, the air in the air bag 3 and the air chamber 2 is freely diffused and exhausted through the vent 101, the processor 7 can determine the time for controlling the closing of the air inlet valve 9 and the air bag valve 10 through the time length, for example, the processor 7 starts to time from the stop moment of the micro pump 6, and sends a closing instruction to the air inlet valve control member 91 and the air bag valve control member 100 when reaching a first time length, wherein the first time length can be a time length calculated by a technician through factors such as the volume of the air bag 3, the volume of the air chamber 2, the free diffusion speed of the air and the like, or a time length obtained by the technician through simulation software. Alternatively, the processor 7 may control the closing time of the intake valve 9 and the airbag valve 10 according to the received command, for example, the wearable device has a valve closing button, and after the user performs a valve closing operation, the processor 7 may receive a closing command of the intake valve 9 and the airbag valve 10, and further send a closing command to the intake valve control member 91 and the airbag valve control member 100.
As an example, in performing a gas composition measurement, when the processor 7 detects a signal to initiate a gas composition measurement, the inlet valve 9 and the airbag valve 10 are controlled to open, e.g., the inlet valve 9 is controlled to open by inlet valve control 91 and the airbag valve 10 is controlled to open by airbag valve control 100. Then, the processor 7 may control the micro pump 6 to start, for example, the processor 7 may control the micro pump 6 to start through the micro pump control 61, and control the power chip 14 to provide a voltage of a certain gear to the micro pump 6. When all the residual gas in the gas chamber 2 enters the gas bag 3 and the gas chamber 2 is filled with the gas to be measured, the processor 7 can control the micro pump 6 to stop working, for example, the micro pump 6 is controlled to stop working by the micro pump control part 61. Thereafter, processor 7 controls intake valve 9 and airbag valve 10 to close, e.g., controls intake valve 9 to close via intake valve control 91 and airbag valve 10 to close via airbag valve control 100. After that, the processor 7 may control the gas sensor 5 to start operation, for example, by controlling the gas sensor control 51 to control the gas sensor 5 to start operation. The processor 7 may then receive the gas data collected by the gas sensor 5 and calculate the gas composition from the gas data. When a signal to end the gas component measurement is detected, the gas sensor 5 is controlled to stop operating, for example, the gas sensor 5 is controlled to stop operating by the gas sensor control member 51. The intake valve 9 and the airbag valve 10 are controlled to open, for example, the intake valve 9 is controlled to open by the intake valve control 91 and the airbag valve 10 is controlled to open by the airbag valve control 100. After the gas in the airbag 3 is freely diffused and exhausted through the vent 101, the air inlet valve 9 and the airbag valve 10 are controlled to be closed, for example, the air inlet valve 9 and the airbag valve 10 may be triggered to be closed by the first time period described above, or the air inlet valve 9 and the airbag valve 10 may be triggered to be closed by the valve closing operation of the user.
The processor 7 can judge that residual gas in the air cavity 2 enters the air bag 3 through time length, and the air cavity 2 is filled with gas to be detected, for example, the processor 7 starts timing at the working moment of the self-starting micropump 6, and when the time length reaching the second time length is detected, the residual gas in the air cavity 2 can be determined to enter the air bag 3, and the air cavity 2 is filled with the gas to be detected. The second duration may be a duration calculated by a technician through factors such as the volume of the airbag 3, the volume of the air cavity 2, the free diffusion speed of the gas, and the like, or a duration obtained by the technician through simulation software.
In the gas component measurement, the residual gas in the gas cavity 2 is discharged into the air bag 3, and the gas sensor 5 is started to measure the gas component after the residual gas in the gas cavity 2 is discharged, so that the accuracy of the gas component measurement can be improved.
By the above, the wearable device can be used for measuring the blood pressure data of the user, measuring the gas component data of the gas exhaled by the user, measuring the gas component data of the gas in the environment, improving the use function of the wearable device and enriching the application scene of the wearable device.
In one example, the wearable device further has a heat dissipation function, and correspondingly, as shown in fig. 3, the device body 1 further has a heat dissipation outlet 102, and an air channel 8 is connected between the air cavity 2 and the heat dissipation outlet 102; the air passage 8 between the air cavity 2 and the heat dissipation outlet 102 is respectively contacted with a plurality of heating elements in the equipment body 1, and the plurality of heating elements dissipate heat through the air passage 8 between the air cavity 2 and the heat dissipation outlet 102; an air outlet valve 11 is arranged on the air passage 8 between the air cavity 2 and the heat dissipation outlet 102 at a position close to the heat dissipation outlet 102, and a heat dissipation valve 12 is arranged on the air passage 8 between the air cavity 2 and the heat dissipation outlet 102 at a position close to the air cavity 2.
The processor 7 is used for controlling the opening and closing of the air inlet valve 9, the air bag valve 10, the air outlet valve 11 and the heat dissipation valve 12 and controlling the starting and stopping of the micro pump 6 to dissipate heat of a plurality of heating components.
The heating element may include a signal processing element 13, a power chip 14, a processor 7, an airbag valve control element 100, a micropump control element 61, a gas sensor control element 51, an intake valve control element 91, and the like.
During the heat dissipation process, the gas enters the gas cavity 2 and the air bag 3 through the vent 101 and is discharged through the heat dissipation outlet 102.
In an example, the air outlet valve 11 is opened and closed under the instruction of the processor 7, for example, as shown in fig. 3, the wearable device may further include an air outlet valve control part 111, the air outlet valve control part 111 is electrically connected to the air outlet valve 11 and the processor 7, the processor 7 may send an opening instruction and a closing instruction to the air outlet valve control part 111, and the air outlet valve control part 111 may control the air outlet valve 111 to open after receiving the opening instruction, so that the air in the air bag 3 and the air chamber 2 may be exhausted from the air passage 8 between the air chamber 2 and the heat dissipation outlet 102, and the air may take away heat generated on the heat generating component during flowing in the air passage 8 to dissipate heat of the heat generating component. The outlet valve controller 111 may control the outlet valve 11 to close after receiving the closing command.
Based on a similar process, the heat dissipation valve 12 is also opened and closed under the instruction of the processor 7, for example, as shown in fig. 3, the wearable device may further include a heat dissipation valve control member 121, the heat dissipation valve control member 121 is electrically connected to the heat dissipation valve 12 and the processor 7, respectively, and the processor 7 may control the heat dissipation valve to open and close through the heat dissipation valve control member 121. For example, the processor 7 may send an opening command and a closing command to the heat dissipation valve control element 121, and the heat dissipation valve control element 121 may control the heat dissipation valve 12 to open after receiving the opening command, so that the gas in the airbag 3 and the air cavity 2 may flow in the air duct 8 through the heat dissipation valve 12 to the heat dissipation outlet 102 to dissipate heat for the heat generating component. The heat dissipation valve controller 121 may control the heat dissipation valve 12 to close after receiving the closing command.
As described above, the processor 7 may be configured to control the opening and closing of the air inlet valve 9, the air bag valve 10, the air outlet valve 11, and the heat dissipation valve 12, and control the start and stop of the micro pump 6, so as to dissipate heat of the plurality of heat generating components.
Wherein, let the air flue 8 between air cavity 2 and heat dissipation export 102 pass as many heating element and part as possible, in passing, can take away the heat that produces on the heating element and part, and then for the heating element and part heat dissipation.
In one example, the processor 7 may control the air chamber 2 and the air bag 3 to be filled with air, and then control the air in the air chamber 2 and the air bag 3 to flow in the air passage 8. For example, when the processor 7 detects a signal for starting heat dissipation, the air outlet valve 11 and the heat dissipation valve 12 may be controlled to close and the air inlet valve 9 and the air bag valve 10 may be controlled to open, for example, the processor 7 may control the air outlet valve 11 to close through the air outlet valve control member 11, the heat dissipation valve 12 to close through the heat dissipation valve control member 121, the air inlet valve 9 to open through the air inlet valve control member 91, and the air bag valve 10 to open through the air bag valve control member 100. After processor 7 has completed each valve control, processor 7 may control micro-pump 6 to start, for example, micro-pump 6 via micro-pump control 61. When the processor 7 detects that the gas bag 3 is full of gas, the micro pump 6 is controlled to stop working, for example, the micro pump 6 is controlled to stop working by the micro pump control 61. Then, the processor 7 may control the air inlet valve 9 to close, and control the air bag valve 10, the air outlet valve 11 and the heat dissipation valve 12 to open, for example, the processor 7 may control the air inlet valve 9 to close through the air inlet valve control member 91, control the air bag valve 10 to open through the air bag valve control member 100, control the air outlet valve 11 to open through the air outlet valve control member 11, and control the heat dissipation valve 12 to open through the heat dissipation valve control member 121, so that the gas in the air bag 3 flows in the air passage 8 to dissipate heat for the heat generating component. When the processor 7 detects a signal of ending heat dissipation, the gas in the airbag 3 can be freely diffused and exhausted from the heat dissipation outlet 102, and then the processor 7 can control the airbag valve 10, the air outlet valve 11 and the heat dissipation valve 12 to be closed, for example, the processor 7 can control the airbag valve 10 to be closed through the airbag valve control member 100, the air outlet valve 11 to be closed through the air outlet valve control member 11, and the heat dissipation valve 12 to be closed through the heat dissipation valve control member 121.
The processor 7 may detect whether the air bag 3 is full of gas or not through a preset time period, for example, the processor 7 starts to time from the time when the micro pump 6 starts to operate, and when the third time period is detected, it may be determined that the air bag 3 is full of gas, that is, the third time period is a time period required for the air bag 3 to be full of gas. The third time period is similar to the first time period and the second time period, and may also be a time period calculated by a technician through factors such as the volume of the airbag 3, the volume of the air cavity 2, the free diffusion speed of the gas and the like, or a time period obtained by the technician through simulation software.
The processor 7 may use the temperature collected by the temperature sensor as a signal for determining the end of heat dissipation, for example, at least one temperature sensor is installed in the device body 1, and when the processor 7 detects that the temperature collected by the temperature sensor is lower than a temperature threshold, it may be determined that heat dissipation is ended. For another example, a temperature sensor is installed at each heating component, and when the temperature collected by these temperature sensors is lower than a temperature threshold, it may be determined that heat dissipation is finished. For another example, a temperature sensor is installed at several heating components that generate relatively large heat, and when the temperatures collected by these temperature sensors are all lower than a temperature threshold, it can be determined that heat dissipation is finished. For another example, the processor 7 may determine whether the heat dissipation is finished by the time length. The present embodiment does not limit the condition for determining the end of heat dissipation.
During the process of freely diffusing and discharging the gas in the airbag 3 through the heat dissipation outlet 102, the processor 7 may use a time duration as a condition for determining the end, for example, the processor 7 may start timing from the opening time of the gas outlet valve 11, when the fourth time duration is reached, it may be determined that the freely diffusing and discharging the gas in the airbag 3 through the heat dissipation outlet 102 is ended, and then, the gas outlet valve 11 is controlled to be closed. The fourth time period is similar to the first time period, and may also be a time period calculated by a technician through factors such as the volume of the airbag 3, the volume of the air cavity 2, the free diffusion speed of the gas, and the like, or a time period obtained by the technician through simulation software.
Wherein, this wearable equipment is full of gas earlier in the heat dissipation and is full of gasbag 3 and air cavity 2, then lets gas flow in air flue 8 again, can increase gaseous flow like this at the heat dissipation in-process, and a large amount of gas flow in air flue 8, can be fast effectual take away the heat on the heating element that air flue 8 passed, and then dispel the heat for heating element is quick, improve the radiating rate.
By the above, the wearable device can be used for measuring the blood pressure data of the user, measuring the gas component data of the gas exhaled by the user, measuring the gas component data of the gas in the environment, improving the use function of the wearable device and enriching the application scene of the wearable device.
Moreover, this wearable equipment still possesses from the heat dissipation function, flows in the air flue through gas, for the heating element and part heat dissipation that contacts with the air flue, avoids the heat to gather and influence wearable equipment's normal use.
In the embodiment of the application, the wearable device comprises an air cavity, an air bag and a barometer which are positioned in a device body, and a micro pump and a gas sensor which are positioned in the air cavity, so that the wearable device can measure the blood pressure through the barometer, measure the gas components of the gas exhaled by a user through the gas sensor, and measure the gas components of the gas in the environment. Therefore, the wearable device has more functions and enriches the application scenes.
The application also provides a use method of the wearable device, wherein the wearable device is the wearable device.
As mentioned above, the method can be used to perform blood pressure measurement, and the method can perform the blood pressure measurement process according to the flow shown in fig. 4:
when a signal for starting blood pressure measurement is detected, step 401 is executed, in step 401, the air inlet valve 9 and the air bag valve 10 are opened, the micro pump 6 is started, and blood pressure measurement is carried out.
Wherein the start signal of blood pressure measurement may be triggered by the user clicking a button on the wearable device for measuring blood pressure.
In one example, processor 7 may control micro pump 6 to start via micro pump control 61, and then may control power chip 14 to input a voltage corresponding to the high gear to micro pump 6.
In step 402, when a signal to end the blood pressure measurement is detected, the micro pump 6 is stopped, wherein gas is freely diffused out of the vent 101.
In step 403, it is determined whether the gas in the airbag 3 has finished diffusing and discharging freely.
If not, continuing the air exhaust, and if so, going to step 404.
In one example, whether or not the gas in the airbag 3 completes the free diffusion exhaust may be judged by the period of time for which the gas is exhausted, for example, the exhaust period reaches the first period of time to complete the free diffusion exhaust.
In step 404, the intake valve 9 and the airbag valve 10 are closed. The blood pressure measurement is ended.
Wherein closing the inlet valve 9 and the airbag valve 10 is also triggered by the user by closing the button in step 404, in which case it may not be necessary to judge whether the gas in the airbag 3 has finished diffusing out freely.
In an example, a scene application diagram of the wearable device for blood pressure measurement may be referred to as shown in fig. 5 and fig. 6, where arrows in fig. 5 and fig. 6 indicate a flow direction of gas in the airway 8. Fig. 5 is a schematic view of a scene of air suction into the air bag 3 in a blood pressure measurement process, in fig. 5, the heat dissipation valve and the air outlet valve are in a closed state, and the air inlet valve and the air bag valve are in an open state. Fig. 6 is a schematic view showing a situation in which the gas in the air bag 3 is freely diffused and exhausted in the air passage 8 after the blood pressure measurement is completed, and in fig. 6, the heat dissipation valve and the air outlet valve are in a closed state, and the air inlet valve and the air bag valve are in an open state. Wherein an "x" in fig. 5 and 6 indicates that the valve on the air duct 8 is in a closed state.
Where intake valve 9 may be opened and closed by processor 7 by controlling intake valve control 91, and airbag valve 10 may be opened and closed by processor 7 by controlling airbag valve control 100. Micro-pump 6 may be a processor 7 that controls micro-pump control 61 to start and stop operation.
As described above, the method may be used to perform gas composition measurement, and the method may perform a gas composition measurement process according to the flow shown in fig. 7:
when a signal to start the measurement of the gas composition is detected, step 701 is executed, and in step 701, the intake valve 9 and the airbag valve 10 are opened to start the micro pump 6.
Wherein the initiation signal of the gas composition measurement may be triggered by the user clicking a button on the wearable device for measuring the gas composition.
In step 702, it is determined whether the air chamber 2 is filled with the gas to be measured.
If not, the micro pump 6 continues to pump air into the air cavity 2, and if yes, the process goes to step 703.
In one example, whether the air cavity 2 is filled with the gas to be measured can be determined by the time length of the gas entering the air cavity 2, for example, if the time length of the gas entering the air cavity 2 reaches the second time length, the residual gas in the air cavity 2 is completely removed, and the gas to be measured is filled.
In step 703, the micro pump 6 is stopped, the intake valve 9 and the air bag valve 10 are closed, and the gas sensor 5 is activated to perform gas composition measurement.
In step 704, when a signal to end the gas composition measurement is detected, the gas sensor 5 is stopped, the intake valve 9 and the airbag valve 10 are opened, and the gas in the airbag 3 is freely diffused and exhausted through the vent 101.
In step 705, it is determined whether the gas in the airbag 3 has finished diffusing and discharging freely.
If not, the exhaust is continued, and if so, the process goes to step 706.
In one example, whether or not the gas in the airbag 3 completes the free diffusion exhaust may be judged by the period of time for which the gas is exhausted, for example, the exhaust period reaches the first period of time to complete the free diffusion exhaust.
In step 706, the intake valve 9 and the airbag valve 10 are closed. The gas composition measurement is ended.
In one example, the wearable device is used in a gas composition measurement scenario, in which air is pumped into the air chamber 3 to drive off residual gas in the air chamber, so that the air chamber is filled with the gas to be measured, which is schematically shown in fig. 5. Referring to fig. 8, an arrow in fig. 8 indicates a flowing direction of the gas in the gas passage 8, and all the valves are in a closed state, that is, the intake valve, the airbag valve, the exhaust valve, and the heat dissipation valve are in a closed state. A schematic diagram of the free diffusion venting of gas from the bladder and air cavity after the gas composition measurement is completed can be seen with reference to fig. 6.
Where intake valve 9 may be opened and closed by processor 7 by controlling intake valve control 91, and airbag valve 10 may be opened and closed by processor 7 by controlling airbag valve control 100. Micro-pump 6 may be a processor 7 that controls micro-pump control 61 to start and stop operation. The gas sensor 5 may be activated and deactivated by the processor 7 by controlling the gas sensor control 51.
As described above, the method may be used to dissipate heat of an internal heat-generating component, and the method may perform a heat dissipation process according to the flow shown in fig. 9:
when a signal for starting heat dissipation is detected, step 901 is executed, in step 901, the air outlet valve 11 and the heat dissipation valve 12 are closed, the air inlet valve 9 and the airbag valve 10 are opened, and the micro pump 6 is started.
In step 902, it is determined whether the airbag 3 is filled with gas.
If not, continuing to pump air into the airbag 3, and if so, turning to step 903.
In step 903, the micro pump 6 stops working, the air inlet valve 9 is closed, the airbag valve 10, the air outlet valve 11 and the heat dissipation valve 12 are opened, and the gas in the airbag 3 flows in the air passage 8 between the air cavity 2 and the heat dissipation outlet 102 to dissipate heat of the heating element.
In step 904, it is determined whether heat dissipation is complete.
If not, go to step 901, continue to execute the above steps, if yes, execute step 905.
In step 905, it is judged whether or not the gas in the airbag 3 has finished the free diffusion discharge.
If not, continue exhausting through the heat dissipation outlet 102, if yes, go to step 906.
In step 906, the airbag valve 10, the vent valve 11, and the heat dissipation valve 12 are closed. And finishing heat dissipation.
In an example, in a scene application of the wearable device for heat dissipation, a schematic view of a scene of pumping air into the airbag can be shown with reference to fig. 5. For a schematic view of a scene of heat dissipation of a heat generating component, as shown in fig. 10, arrows in fig. 10 indicate a flowing direction of gas in the air duct 8, in fig. 10, only the air inlet valve is in a closed state, other valves are all in an open state, that is, the air inlet valve 9 is in a closed state, and the air bag valve 10, the air outlet valve 11, and the heat dissipation valve 12 are all in an open state.
Wherein, the air inlet valve 9 may be opened and closed by the processor 7 by controlling the air inlet valve control member 91, the air bag valve 10 may be opened and closed by the processor 7 by controlling the air bag valve control member 100, the air outlet valve 11 may be opened and closed by the processor 7 by controlling the air outlet valve control member 111, and the heat dissipation valve 12 may be opened and closed by the processor 7 by controlling the heat dissipation valve control member 121. Micro-pump 6 may be a processor 7 that controls micro-pump control 61 to start and stop operation.
Based on the above, as shown in fig. 11, after the wearable device starts the health data monitoring function, it may first determine the function to be performed, and if it is to perform blood pressure measurement, perform the process from step 401 to step 404, if it is to perform gas component measurement, perform the process from step 701 to step 706, and if it is to perform heat dissipation, perform the process from step 901 to step 906. The processes of the steps have been described in detail above, and reference may be made to the above contents, which are not described in detail herein.
In the embodiment of the application, the wearable device can be used for measuring the blood pressure of a user, measuring the gas component of gas exhaled by the user, and measuring the gas component of gas in the environment. Therefore, the wearable device has more use functions and enriches the application scenes.
The above description is only one embodiment of the present application and should not be taken as limiting the present application, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A wearable device with blood pressure and gas detection functions, characterized in that the wearable device comprises a device body, an air cavity, an air bag, a barometer, a gas sensor, a micropump and a processor, wherein:
the air cavity, the air bag, the barometer and the processor are all positioned in the equipment body, and the gas sensor and the micropump are all positioned in the air cavity;
the device body is provided with vent holes, and the vent holes are connected with the air cavity, the air cavity and the air bag, and the air bag and the barometer through air passages respectively;
an air inlet valve is arranged on an air passage between the air vent and the air cavity, and an air bag valve is arranged on the air passage between the air cavity and the air bag;
the processor is respectively electrically connected with the barometer, the gas sensor and the micropump, and is used for controlling the opening and closing of the air inlet valve and the air bag valve and controlling the starting and stopping of the micropump, using the barometer to measure blood pressure, controlling the starting and stopping of the micropump by controlling the opening and closing of the air inlet valve and the air bag valve, and controlling the starting and stopping of the gas sensor to measure gas components.
2. The wearable device according to claim 1, wherein the processor is configured to control the air inlet valve and the air bag valve to open when a signal for starting blood pressure measurement is detected, control the micro pump to start operation, receive air pressure data collected by the air pressure gauge, calculate blood pressure data according to the air pressure data, control the micro pump to stop operation when a signal for ending blood pressure measurement is detected, and control the air inlet valve and the air bag valve to close after the air in the air bag is freely discharged from the vent;
when a signal for starting gas component measurement is detected, the gas inlet valve and the airbag valve are controlled to be opened, the micro pump is controlled to start to work, residual gas in the gas cavity is discharged into the airbag, when the gas cavity is filled with gas to be measured, the micro pump is controlled to stop working, the gas inlet valve and the airbag valve are controlled to be closed, the gas sensor is controlled to start to work, gas data collected by the gas sensor is received, gas components are calculated according to the gas data, when a signal for finishing gas component measurement is detected, the gas sensor is controlled to stop working, the gas inlet valve and the airbag valve are controlled to be opened, and after the gas in the airbag is freely discharged from the vent, the gas inlet valve and the airbag valve are controlled to be closed.
3. The wearable device according to claim 1 or 2, wherein the device body is further provided with a heat dissipation outlet, and an air channel is connected between the air cavity and the heat dissipation outlet;
the air channel between the air cavity and the heat dissipation outlet is respectively contacted with a plurality of heating elements in the equipment body, and the plurality of heating elements dissipate heat through the air channel between the air cavity and the heat dissipation outlet;
an air outlet valve is arranged on the air passage between the air cavity and the heat dissipation outlet and close to the heat dissipation outlet, and a heat dissipation valve is arranged on the air passage between the air cavity and the heat dissipation outlet and close to the air cavity;
the processor is also used for controlling the air inlet valve, the air bag valve, the air outlet valve and the heat dissipation valve to be opened and closed and controlling the micro pump to be started and stopped so as to dissipate heat of a plurality of heating elements.
4. The wearable device according to claim 3, wherein the processor is configured to control the air outlet valve and the heat dissipation valve to close, control the air inlet valve and the air bag valve to open, and control the micro pump to start operation when a signal for starting heat dissipation is detected;
when the air bag is filled with air, the micropump is controlled to stop working, the air inlet valve is controlled to be closed, the air bag valve, the air outlet valve and the heat dissipation valve are controlled to be opened, and the air flows in an air passage between the air cavity and the heat dissipation outlet to dissipate heat of the heating element;
when a signal of finishing heat dissipation is detected, the gas in the air bag is discharged from the heat dissipation outlet and then the air bag valve, the gas outlet valve and the heat dissipation valve are controlled to be closed.
5. The wearable device of claim 4, further comprising an exhaust valve control and a heat dissipation valve control, both electrically connected to the processor;
the processor is used for controlling the air outlet valve to be opened and closed through the air outlet valve control part and controlling the heat dissipation valve to be opened and closed through the heat dissipation valve control part.
6. The wearable device according to any of claims 1 to 5, further comprising a gas sensor control, a micropump control, an intake valve control, and an airbag valve control;
the gas sensor control element, the micropump control element, the air inlet valve control element and the airbag valve control element are all electrically connected with the processor;
the processor is used for controlling the gas sensor to start and stop through the gas sensor control piece, controlling the micropump to start and stop through the micropump control piece, controlling the air inlet valve to open and close through the air bag valve control piece, and controlling the air bag valve to open and close through the air bag valve control piece.
7. The wearable device according to any of claims 1 to 6, further comprising a signal processing element, the signal processing element being electrically connected to the barometer and the processor, respectively;
the signal processing part is used for receiving the air pressure data collected by the barometer and sending the processed air pressure data to the processor.
8. The wearable device according to any of claims 1 to 7, further comprising a power chip electrically connected to the micro pump and the processor, respectively, wherein the processor is further configured to control the power chip to output a voltage to the micro pump.
9. The wearable device according to any of claims 1 to 8, wherein the wearable device is a wrist-type device or a arm-type device, wherein the device body comprises a wearing body and a device body, wherein the air chamber, the barometer and the processor are located in the device body.
10. A method for using a wearable device, wherein the wearable device is the wearable device of any of claims 1 to 9, the method comprising:
when a signal for starting blood pressure measurement is detected, the air inlet valve and the air bag valve are opened, the micro pump is started to measure blood pressure, when a signal for finishing blood pressure measurement is detected, the micro pump is stopped, and after gas in the air bag is freely discharged from the vent, the air inlet valve and the air bag valve are closed;
when a signal for starting gas component measurement is detected, the gas inlet valve and the airbag valve are opened, the micro pump is started, residual gas in the gas cavity is discharged into the airbag, when the gas cavity is filled with gas to be measured, the micro pump is stopped, the gas inlet valve and the airbag valve are closed, the gas sensor is started to measure the gas component, when a signal for finishing gas component measurement is detected, the gas sensor is stopped, the gas inlet valve and the airbag valve are opened, and after the gas in the airbag is freely discharged from the vent, the gas inlet valve and the airbag valve are closed.
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