TWM576726U - Wearable health monitoring device - Google Patents

Abstract

A wearable health monitoring device includes: a monitoring body; a wearing part connected to the outside of the monitoring body; a biometric monitoring module disposed in the monitoring body, including a photoelectric sensor, a pressure sensor and a barometric blood pressure device, and the blood pressure device is embedded in Positioning in the embedded groove portion of the embedded seat body, comprising a gas collecting actuator and an elastic air bag, the gas collecting actuator is for supplying gas to the elastic air bag, and the elastic air bag is inflated and elastically displaced to protrude outside the monitoring body, Fits the skin tissue of the user and causes the pressure sensor to measure the vasoconstriction of the skin tissue to generate a detection signal and convert it into a health data information output. The health data information provides a monitoring and correction calculation of the photoelectric sensor to adjust the output precision. Health data information.

Description

Wearable health monitoring device

The present invention relates to a wearable device, and more particularly to a wearable health monitoring device having a biometric monitoring module for performing health measurement and capable of measuring blood pressure with an optical blood pressure measurement.

In today's society where rapid and personal pressure is growing, the awareness of the pursuit of personal health is gradually evolving. It is the general person who wants to constantly monitor or examine his or her health. In general, the traditional data measurement of human physiological health information is mainly through a fixed sphygmomanometer or a large measuring instrument. These testing instruments usually include a motor-type fluid pump, an airbag bag, a sensor, and a deflated air. Components such as valves, batteries, etc., in which a motor-type fluid pump is prone to frictional loss, and the components are bulky after assembly, and do not utilize frequent use, but if a small-sized motor type fluid pump is used , it will lose faster and consume more energy.

In order to facilitate the average person to regularly monitor their own health conditions and make the monitoring device easy to carry, the wearable health monitoring devices on the market are increasing day by day. However, in the case of the commonly-used wearable health monitoring device on the market, it is usually detected by optical detection. However, the accuracy of the optical detection method is not high, so the error value is often generated, and cannot be Effectively obtain trusted data, so that users can not obtain accurate data related to their own health, and it is easy to cause errors in judgment. Generally speaking, in order to sense the physiological information of a person to be tested, it is usually selected to monitor the position such as the head, the heart, the wrist or the ankle, which is the most sensitive pulse blood pressure in the human body and The location of information such as heartbeat is to quickly and effectively understand the physiological health information of the person to be tested by sensing at these locations. However, as mentioned above, if the wearable health monitoring device with optical detection is not accurate due to its low accuracy, it is difficult to identify the data detected by it. High blood pressure monitors or other measuring instruments are too small to be light, thin, and portable.

Therefore, how to develop a wearable health monitoring device that can improve the above-mentioned conventional technology and make the personal health monitoring device small, miniaturized, portable, power-saving, and highly accurate is urgently needed to be solved. problem.

The main purpose of this case is to provide a wearable health monitoring device, which implements health measurement by monitoring the body embedded in the biometrics monitoring module, and uses the photoelectric sensor to perform optical blood pressure measurement, and can be matched with a pneumatic blood pressure device and a pressure sensor. To implement the inflated blood pressure measurement, and use the inflatable blood pressure measurement to monitor the health data information as the basis for the correction of the optical blood pressure measurement before the measurement, to provide more reliable and accurate measurement at any time and anywhere, and further control The module transmits the health data information to the external link device for storage and recording for further analysis and statistics, so as to better understand the health situation of the wearer and the instant notification of the treatment or return of the ambulance treatment.

In order to achieve the above object, a broader aspect of the present invention provides a wearable health monitoring device, comprising: a monitoring body, comprising an embedded seat body, a monitoring area slot and a cover plate, the embedded seat body Having a recessed embedded groove portion, and a bottom portion of the embedded groove portion is connected to a venting groove and an exhaust flow passage, and the monitoring portion notch is disposed on a side adjacent to the embedded seat body, and the cover plate cover a venting opening is provided at a bottom of the embedding groove portion corresponding to the venting groove position, and a venting opening is provided corresponding to the exhaust gas flow path position, corresponding to the notch position of the monitoring area a light transmissive cover; a wearable member connected to the outside of the monitoring body; a biometric monitoring module disposed in the monitoring body, comprising a photoelectric sensor, a pressure sensor and a pneumatic blood pressure device, wherein the photoelectric sensor The pressure sensor is disposed at the notch of the monitoring area for monitoring, and the pneumatic blood pressure device is embedded in the embedding groove portion of the embedded seat body, and includes a gas collecting actuator and an elastic air bag, the elastic air bag Compression set The venting groove of the embedding groove portion and the notch of the cover plate, the gas collecting actuator supplies gas to the elastic air bag, and the elastic air bag is inflated and elastically displaced out of the cover plate to Fitting the user's skin tissue, and causing the pressure sensor to perform vasoconstriction pulsation measurement of the skin tissue to generate a detection signal to convert a health data information output, the health data information providing a monitoring correction calculation of the photoelectric sensor to adjust Output accurate health data information.

In order to achieve the above object, a broader aspect of the present invention provides a wearable health monitoring device, comprising: a monitoring body, comprising an embedded seat body, a monitoring area slot and a cover plate, the embedded seat body The recessed portion has a recessed groove portion, and a bottom portion of the inserting groove portion communicates with a venting groove and an exhaust flow passage, and a side of the inserting seat body is provided with an air bag passage for communicating with the venting groove, and the monitoring The slot is disposed adjacent to the side of the embedded seat, and the cover is capped at the bottom of the recessed slot, and a corresponding exhaust hole is provided corresponding to the position of the exhaust runner, corresponding to the monitoring a light-transmissive cover is disposed at a position of the slot; a wearable member is connected to the outside of the monitoring body, and an inner side of the wear member surrounds an elastic airbag, and the inlet end of the elastic airbag is embedded in the airbag channel of the embedded seat body for connection and positioning; a biometric monitoring module is disposed in the monitoring body, and includes a photoelectric sensor, a pressure sensor and a pneumatic blood pressure device, wherein the photoelectric sensor and the pressure sensor are disposed at a slot of the monitoring area for monitoring, and The pneumatic blood pressure device is embedded in the embedding groove portion of the embedded seat body, and includes a gas collecting actuator, a gas collecting valve seat, a cavity plate and a valve piece, and the gas collecting valve seat has an episode a gas trough corresponding to the venting groove connecting the embedded seat body and the air bag passage, and the gas collecting actuator supplies the gas through the venting groove through the venting groove, and the air bag channel gives the elastic air bag The elastic airbag is inflated and elastically displaced to protrude around the inner side of the wearing member to fit the skin tissue of the user, and the pressure sensor performs blood vessel contraction and pulsation measurement of the skin tissue to generate a detection signal conversion. Health data information output, the health data information provides monitoring and correction calculation of the photoelectric sensor to adjust the output of accurate health data information.

Some exemplary embodiments embodying the features and advantages of the present invention are described in detail in the following description. It is to be understood that the present invention is capable of various modifications in various aspects, and is not to be construed as a limitation.

Please refer to Figure 1, Figure 2A and Figure 2B. The wearable health monitoring device of this case can be worn by the user on the wrist for health monitoring. In this embodiment, the wearable health monitoring device includes a monitoring body 1, a wearing component 2, a biometric monitoring module 3, and a control module 4.

In this embodiment, the wearing part 2 can be a ring-shaped strip structure composed of a soft or rigid material, for example, a silicone material, a plastic material, a metal material, or other related materials, and is not The limit is mainly used to wrap around a specific part of the wearer, such as a wrist or an ankle, but not limited thereto. As for the connection manner of the two ends of the wearing part 2, the method of attaching the devil's felt can be adopted, or the fastening method of the convex and concave butt joints, or the buckle ring commonly used for the general wearable parts, or even the same can be integrated. The connection structure of the formed ring structure or the like may be changed according to the actual application situation, and is not limited thereto.

In this embodiment, the monitoring body 1 includes a screen 11, an embedded body 12, a monitoring area slot 13 and a cover 14 disposed on the upper surface of the monitoring body 1 for displaying health. Information, but not limited to this; in this embodiment, the screen 11 can be, but is not limited to, a touch screen, and the wearable user can touch the screen 11 to select the information to be displayed. The information system may include at least one of wearer's health information, time information, caller ID information, etc.; the embedded body 12 is disposed at the bottom of the monitoring body 1, has a recessed embedded groove portion 121, and is embedded The bottom of the groove portion 121 is connected to a venting groove 122 and an exhaust flow path 123; the monitoring area notch 13 is disposed at the bottom of the monitoring body 1 adjacent to the side of the embedded body 12; and the cover 14 is covered in the embedded groove The bottom portion of the portion 121 is provided with a communicating notch 141 corresponding to the position of the venting groove 122, and a communicating vent hole 142 corresponding to the position of the exhaust flow path 123, and corresponding to the position of the notch 13 of the monitoring area There is a cover transparent cover 143.

Continuing to refer to FIG. 2A, FIG. 2B and FIG. 3 , the biometric monitoring module 3 is disposed in the monitoring body 1 and includes a driving circuit board 31 , a photoelectric sensor 32 , a pressure sensor 33 , and a The impedance sensor 34, at least one light-emitting element 35, and a pneumatic blood pressure device 36. The driving circuit board 31 is positioned at the slot 13 of the monitoring area to position the photosensor 32, the pressure sensor 33, the impedance sensor 34, the at least one light emitting component 35, and provide the required electrical connection and drive control signals. The line conduction, and the driving circuit board 31 also provides electrical connection of the pneumatic blood pressure device 36 and control of the driving signal; the photoelectric sensor 32, the pressure sensor 33, the impedance sensor 34 and each of the light-emitting elements 35 are disposed on the driving circuit board 31. The lower side is used for monitoring purposes, and the transparent cover 143 of the cover 14 can cover the notch 13 of the monitoring area, so that the photosensor 32, the pressure sensor 33, the impedance sensor 34 and each of the light-emitting elements 35 are packaged under the driving circuit board 31. The cover module can be protected from dust and light, and can transparently detect the wearer's skin tissue 5, and receive the detection of the skin tissue 5 fold back light to generate the detection signal; further, the control module 4 is also packaged on the drive circuit board 31, and The photoelectricity, driving signal control and monitoring of the photoelectric sensor 32, the pressure sensor 33, the impedance sensor 34, each of the light-emitting elements 35 and the barometric blood pressure device 36 are provided. The information is received and outputted. After the photosensor 32 is attached to the user's skin tissue 5, the light source emitted by the light-emitting element 35 is transmitted to the skin tissue 5. The reflected light source is received by the photosensor 32, and a detection signal is generated. The control module 4 is converted into a health data information output, and the health data information may include a heart rate data, an electrocardiogram data, and a blood pressure data; the pressure sensor 33 is attached to the user's skin tissue 5 to generate a detection signal for providing control The module 4 is converted into a health data information output, the health data information is a respiratory frequency data and a blood pressure data; the impedance sensor 34 is attached to the user's skin tissue 5 to generate a detection signal for the control module 4 to be converted into a health Data information output, this health data information is a blood glucose data.

Referring again to FIGS. 2A and 2B and FIGS. 4A to 4D, the barometric blood pressure device 36 is embedded in the embedding groove portion 121 of the insertion seat body 12, and the barometric blood pressure device 36 includes a gas collection actuator. 361. A gas collecting valve seat 362, a cavity plate 363, a valve piece 364 and an elastic air bag 365. The gas collecting valve seat 362 is placed on the embedding groove portion 121, and a gas collecting groove 362a is concavely disposed on the lower surface corresponding to the ventilation groove 122, and the gas collecting valve seat 362 is provided with a lower gas collecting chamber on the upper surface. The chamber 362b and the lower pressure relief chamber 362c have a gas collecting through hole 362d between the gas collecting groove 362a and the lower gas collecting chamber 362b for allowing the gas collecting groove 362a and the lower gas collecting chamber 362b to communicate with each other. The air chamber 362b is spaced apart from the lower pressure relief chamber 362c at the upper surface of the gas collection valve seat 362, and a communication flow path 362e is provided between the lower gas collection chamber 362b and the lower pressure relief chamber 362c for the lower portion. The gas collection chamber 362b and the lower pressure relief chamber 362c communicate with each other, the lower pressure relief chamber 362c has a gas collection valve seat convex portion 362f, and the center of the gas collection valve seat convex portion 362f is provided with a pressure relief through hole 362g. The lower pressure relief chamber 362c is in communication with the venting opening 142 of the cover plate 14, and the elastic airbag 365 is fixed in the air collecting groove 362a to close the air collecting groove 362a. At the same time, the elastic air bag 365 is compressed and placed in the embedded groove portion 121. The venting groove 122, the notch 141 of the cover plate 14 and maintaining the same plane as the cover plate 14 without Exposed, and the elastic air bag 365 communicates with the air collecting groove 362a and the gas collecting through hole 362d, and is inflated and elastically displaced out of the cover plate 14, and the elastic end of the elastic air bag 365 has a pressing plate 365a; The gas collecting valve seat 362 is disposed on the upper surface of the gas collecting valve seat 362, and the upper and lower gas collecting chambers 362b are respectively disposed corresponding to the upper air collecting chamber 363a and the lower pressure reducing chamber 362c. Corresponding to the top pressure relief chamber 363b of the cover, and the upper air collection chamber 363a is provided with a cavity plate projection 363c, and the cavity plate 363 is recessed on the surface of the upper upper collection chamber 363a and the upper pressure relief chamber 363b. a communication chamber 363d, the gas collection actuator 361 is placed on the cavity plate 363 to cover the communication chamber 363d, and the communication chamber 363d passes through at least one communication hole 363e, respectively, and the upper air collection chamber 363a and the upper portion are unloaded The pressure chamber 363b is in communication; further, the valve piece 364 is disposed between the gas collection valve seat 362 and the cavity plate 363, and the valve piece 364 is in contact with the gas collection valve seat convex portion 362f to close the pressure relief through hole 362g, and the valve piece 364 A valve hole 364a is disposed at a position against the cavity plate convex portion 363c, and the valve hole 364a is blocked by the cavity plate convex portion 363c. Closed.

Referring to FIG. 5A to FIG. 5B , the gas collecting actuator 361 is a micro pump 10 , and the micro pump 10 includes a current inlet plate 101 , a resonant plate 102 , a piezoelectric actuator 103 , and a piezoelectric actuator 103 . A first insulating sheet 104, a conductive sheet 105 and a second insulating sheet 106 are sequentially stacked. The inlet plate 101 has at least one inlet hole 101a, at least one bus bar groove 101b, and a confluence chamber 101c. The inlet hole 101a is for introducing a gas, the inlet hole 101a is corresponding to the through bus groove 101b, and the bus bar groove 101b. The flow is merged into the confluence chamber 101c, and the gas introduced into the inlet hole 101a is converged into the confluence chamber 101c. In the present embodiment, the number of the inlet holes 101a and the bus bar grooves 101b are the same, and the number of the inlet holes 101a and the bus bar grooves 101b are respectively four, which is not limited thereto, and the four inlet holes 101a are respectively penetrated. Four bus bar slots 101b, and four bus bar slots 101b merge into the bustling chamber 101c.

Referring to FIG. 5A, FIG. 5B, and FIG. 6A, the resonant plate 102 is assembled to the inflow plate 101 by a bonding method, and the resonant plate 102 has a hollow hole 102a and a movable portion 102b. a fixing portion 102c, the hollow hole 102a is located at the center of the resonance piece 102, and corresponds to the confluence chamber 101c of the inlet plate 101, and the movable portion 102b is disposed around the hollow hole 102a and opposed to the confluence chamber 101c. The fixing portion 102c is provided on the outer peripheral edge portion of the resonator piece 102 and is attached to the inlet plate 101.

Continuing to refer to FIG. 5A, FIG. 5B and FIG. 6A, the piezoelectric actuator 103 includes a suspension plate 103a, an outer frame 103b, at least one bracket 103c, a piezoelectric element 103d, and at least one gap. 103e and a convex portion 103f. Wherein, the suspension plate 103a is in a square shape, and the suspension plate 103a adopts a square shape, which is compared with the design of the circular suspension plate. The structure of the square suspension plate 103a obviously has the advantage of power saving, and operates at the resonance frequency. Capacitive load, its power consumption will increase with the increase of frequency, and because the resonant frequency of the side-length square suspension plate 103a is significantly lower than that of the circular suspension plate, the relative power consumption is also significantly lower, that is, the case is adopted in this case. The floating plate 103a of the square design has the advantage of saving power; the outer frame 103b is disposed around the outer side of the suspension plate 103a; at least one bracket 103c is connected between the suspension plate 103a and the outer frame 103b to provide elastic support for the suspension plate 103a. a supporting member; and a piezoelectric element 103d having a side length which is less than or equal to one side of the suspension plate 103a, and the piezoelectric element 103d is attached to a surface of the suspension plate 103a for applying a voltage to drive the suspension The plate 103a is bent and vibrated; and the suspension plate 103a, the outer frame 103b and the bracket 103c form at least one gap 103e for gas to pass through; the convex portion 103f is disposed on the suspension plate 103a. The opposite surface of the surface of the piezoelectric element 103d is attached. In this embodiment, the convex portion 103f may be integrally formed by an etching process and protruded from the surface of the piezoelectric element 103d by the suspension plate 103a. A convex structure is formed on the other surface.

Please refer to FIG. 5A, FIG. 5B and FIG. 6A for the above-mentioned inlet plate 101, the resonance plate 102, the piezoelectric actuator 103, the first insulating sheet 104, the conductive sheet 105 and the second insulating sheet 106. The stacking assembly is sequentially arranged, wherein a cavity space 107 is formed between the suspension plate 103a and the resonant plate 102, and the cavity space 107 can be filled with a gap between the resonant plate 102 and the outer frame 103b of the piezoelectric actuator 103. The material is formed, for example, a conductive adhesive, but not limited thereto, so that a certain depth can be maintained between the resonant plate 102 and the suspension plate 103a to form the chamber space 107, thereby guiding the gas to flow more rapidly, and the suspension plate 103a maintains an appropriate distance from the resonator piece 102 to reduce mutual contact interference, and the noise generation can be reduced. Of course, in the embodiment, the resonance piece 102 and the pressure can also be reduced by increasing the height of the frame 103b of the piezoelectric actuator 103. The gap between the outer frame 103b of the electric actuator 103 is filled with the thickness of the conductive adhesive, so that the conductive rubber can be prevented from being thermally expanded and contracted with the hot pressing temperature and the cooling temperature, thereby affecting the actual spacing of the cavity space 107 after molding, and reducing Hot pressing temperature and cooling temperature of conductive adhesive Overall indirect impact of the assembled structure of the micro-pump 10, but is not limited thereto. In addition, the chamber space 107 will affect the transfer efficiency of the micropump, so maintaining a fixed chamber space 107 is important for providing stable transmission efficiency to the micropump 10.

Therefore, as shown in FIG. 6B, in other embodiments of the piezoelectric actuator 103, the suspension plate 103a may be press-formed to extend outwardly a distance, and the outward extension distance may be formed on the suspension plate 103a and the outside. At least one bracket 103c between the frames 103b is adjusted such that the surface of the convex portion 103f on the suspension plate 103a and the surface of the outer frame 103b form a non-coplanar surface, and a small amount is applied to the surface of the outer frame 103b. The filling material, for example, a conductive adhesive, is used to heat-press the piezoelectric actuator 103 to the fixing portion 102c of the resonant sheet 102, so that the piezoelectric actuator 103 can be combined with the resonant sheet 102, so that the direct transmission is performed. The suspension plate 103a of the piezoelectric actuator 103 is modified by a press forming to form a chamber space 107, and the required chamber space 107 is adjusted by the adjustment of the suspension plate 103a of the piezoelectric actuator 103. The completion of the structure of the adjustment chamber space 107 is effectively simplified, and the advantages of simplifying the process and shortening the process time are also achieved. In addition, the first insulating sheet 104, the conductive sheet 105, and the second insulating sheet 106 are all thin frame-shaped sheets, and are sequentially stacked on the piezoelectric actuator 103 to form an overall structure of the micropump 10.

In order to understand the output operation mode of the above-mentioned micropump 10 for gas transmission, please continue to refer to Figs. 6C to 6E. Referring to FIG. 6C, after the piezoelectric element 103d of the piezoelectric actuator 103 is applied with a driving voltage, the deformation causes the suspension plate 103a to be displaced downward. At this time, the volume of the chamber space 107 is increased to form in the chamber space 107. With the negative pressure, the gas in the confluence chamber 101c is taken into the chamber space 107, and the resonator piece 102 is synchronously displaced downward by the resonance principle, which increases the volume of the confluence chamber 101c, and the confluence chamber The relationship between the gas entering the chamber space 107 in the chamber 101c causes the same pressure in the confluence chamber 101c, and the gas is sucked into the confluence chamber 101c through the inlet hole 101a and the bus bar groove 101b; please refer to the 6D. The piezoelectric element 103d drives the suspension plate 103a upward to compress the chamber space 107. Similarly, the resonator piece 102 is displaced upward by resonance with the suspension plate 103a, forcing the gas in the chamber space 107 to pass through the gap synchronously. 103e is transmitted downward to achieve the effect of transmitting gas; finally, referring to FIG. 6E, when the suspension plate 103a is driven downward, the resonator piece 102 is also driven to be displaced downward, and the resonance piece 102 at this time The space within the compression chamber 107 moves to the gas gap 103e, and enhance the volume within the chamber 101c of the bus, so that gas can continue to flow through the inlet orifice 101a, 101b to bus slots converge in a manifold chamber 101c. The micropump 10 is continuously provided by the micropump 10 shown in FIGS. 6C to 6E to provide a gas transport operation step, so that the micropump 10 can continuously flow the gas from the inlet hole 101a into the flow path of the inlet plate 101 and the resonator plate 102. A pressure gradient is generated, which is then transmitted downward by the gap 103e to allow the gas to flow at a high speed to achieve the operation of the micropump 10 to transmit the gas output.

Continuing to refer to FIG. 6A, the inlet plate 101, the resonator plate 102, the piezoelectric actuator 103, the first insulating sheet 104, the conductive sheet 105, and the second insulating sheet 106 of the micropump 10 are all permeable to the microelectromechanical surface. The micromachining process reduces the volume of the micropump 10 to form a microelectromechanical system micropump 10.

As can be seen from the above description, in the specific embodiment, as shown in FIGS. 4B to 4C, when the gas gathering actuator 361 is controlled to drive the gas transmission, the gas is external to the gas collecting actuator 361. The introduction into the communication chamber 363d is concentrated, and then the communication chamber 363d is introduced into the upper collection chamber 363a and the upper pressure relief chamber 363b through the communication hole 363e to push the valve piece 364 away from the cavity plate projection 363c, and the valve piece 364 abuts the gas collection valve seat convex portion 362f to close the pressure relief through hole 362g, and the gas in the upper pressure relief chamber 363b also flows into the upper gas collection chamber 363a through the communication flow path 362e, so that the gas can pass through the valve of the valve piece 364. The hole 364a flows into the gas collecting chamber 362b under the gas collecting valve seat 362, and then communicates through the gas collecting through hole 362d and concentrates on the elastic air bag 365, so that the elastic air bag 365 is inflated and elastically displaced, of course, in the present case. After a period of inflation of the blood pressure blood pressure device 36, as shown in Fig. 7, the pressure plate 365a of the elastic air bag 365 will abut against the skin tissue 5 of the user to press the user between the skin tissue 5 and the bone 6. Blood vessels 7 prevent blood flow, at this time, In the present case, after the inflation time of the pneumatic blood pressure device 36 is stopped, as shown in FIG. 4D, the gas collecting actuator 361 stops the gas transmission operation, and the gas pressure in the elastic air bag 365 is larger than the gas in the communication chamber 363d. At the air pressure, the gas in the elastic airbag 365 will push the valve piece 364 to displace to abut the cavity protrusion 363c to close the valve hole 364a, and the valve piece 364 will move away from the contact valve seat protrusion 362f, thereby opening the pressure relief through hole. At 362 g, the gas in the elastic bladder 365 is led out from the communication passage 362e to the pressure relief through hole 362g, and is discharged to the outside of the pneumatic blood pressure device 36 to complete the pressure relief operation of the elastic bladder 365. During the pressure relief process, the pressure of the blood vessel 7 is gradually reduced. At this time, after the scanning and monitoring by the pressure sensor 33, the pressure pulse measurement can be used to measure the blood vessel pulsation, thereby completing an inflatable blood pressure monitoring operation, although it is a kind. There is a sense of blood pressure measurement, but can get a more accurate blood pressure data measurement.

Of course, the wearable health monitoring device of the present invention can also use the photoelectric sensor 32 to receive the detection signal generated by the light source reflected by the light source emitted from the light-emitting element 35 and reflected back to the skin tissue, thereby achieving a photoelectric volume pulse wave tracing (PPG) measurement principle. Provided to the control module 4 for conversion to health data information output, and the health data information may include a heart rate data, an electrocardiogram data, and blood pressure data, and the optical measurement is also a way to achieve blood pressure measurement, although at any time The measurement is performed every second, but the health data obtained by the monitoring is obtained through the algorithm adjustment. It is not directly measured by the inflatable measurement method, so the accuracy is not enough. In view of this, the wearable health monitoring device of the present case is specially provided. The miniaturization is suitable for the pneumatic blood pressure device 36 implemented on the wearable device and the pressure sensor 33 to implement the inflation blood pressure measurement method, and obtain accurate blood pressure measurement value, which can be used as the initial correction of the photoelectric measurement blood pressure. , Auxiliary confirmation of Heart Rate Variability (HRV), Atrial Fibrillation (AF); When the first measurement is started, the sensor 32 first implements the pneumatic blood pressure measurement method with the pressure blood pressure device 36 and the pressure sensor 33, and the obtained health data information is used as the calculation basis of the photoelectric sensor 32 measurement correction, so that the photoelectric sensor 32 can be compensated after each measurement to achieve a more accurate measurement of health data information output. In addition, when the wearer has a condition, such as a fall detection or blood sugar or blood oxygen abnormality, the pneumatic blood pressure device 36 of the wearable health monitoring device of the present invention can be used with the pressure sensor 33 to implement the inflation blood pressure measurement method. Providing a more reliable data reference to understand the user's health information in the event of a situation, and to be able to immediately report the treatment or return to the rescue treatment, which is of great value.

In this embodiment, as shown in FIG. 8, the control module 4 of the wearable health monitoring device of the present invention comprises a microprocessor 41, a communicator 42 and a global positioning system component 43. The microprocessor 41 converts the photoelectric sensor 32, the pressure sensor 33, and the impedance sensor 34 to generate a detection signal to be converted into a health data information output, and the output is directly displayed on the screen 11 or output to the communicator 42, and the communicator 42 includes An Internet of Things communication component 42a and a data communication component 42b, the Internet of Things communication component 42a receives the health data information of the biometrics monitoring module 1 and transmits and transmits the health data information to an external linking device for storage and recording for further analysis. Statistics, in order to better understand the health situation of the wearable user, and the Internet of Things communication component 42a is a narrowband IoT device that transmits a signal transmitted by a narrowband radio communication technology; and the external connection device includes a network relay station 8a and a cloud data processing The device 8b, the Internet of Things communication component 42a transmits the health data information to the cloud data processing device 8b through the network relay station 8a for storage and recording for further analysis and statistics, so as to better understand the health situation of the wearable user; and the data communication component 42b Receiving health data of biometric monitoring module 1 And transmitting the health data information to the external link device for storage, recording and display, and the data communication component 42b transmits the health data information through the wireless communication transmission interface, and the wireless communication transmission interface is a Wi-Fi module, a Bluetooth module a group, a radio frequency identification module (RFID) and a near field communication module (NFC), and the data communication component 42b transmits and transmits health data information to the external connection device. The external connection device includes a mobile communication connection device 8c. The mobile communication connection device 8c receives the data communication component 42b for transmitting and transmitting health data information, and stores and records for further analysis and statistics, so as to better understand the health situation of the wearer. The mobile communication device 8c can be at least one of a mobile phone device, a notebook computer, and a tablet computer; or the data communication component 42b transmits and transmits health data information to the external connection device, and the external connection device includes a mobile communication link. Device 8c, a network relay station 8a and a cloud The end data processing device 8b, the mobile communication connection device 8c receives the health data information, and then transmits the health data information to the cloud data processing device 8b via the network relay station 8a for storage and recording for further analysis and statistics, so as to better understand the wear and use. The mobile communication device 8c can be at least one of a mobile phone device, a notebook computer, and a tablet computer.

In addition, as shown in FIG. 9 to FIG. 10 and FIG. 11 , the elastic airbag 365 of the wearable health monitoring device of the present invention can also be arranged in another embodiment, and the elastic airbag 365 can also be disposed on the inner side of the wearing member 2 to be embedded. One side of the seat body 12 is provided with an air bag passage 124 for communicating with the venting groove 122, and the inlet end of the elastic air bag 365 is embedded in the air bag passage 124, and the notch 141 of the cover plate 14 is unset, and the cover plate 14 is disposed. A cover portion 144 is a cover venting groove 122 and a bottom portion of the air bag passage 124, so that the venting groove 122 and the air bag passage 124 form a passage connecting the elastic air bag 365, so that the pneumatic blood pressure device 36 can transmit gas through the venting groove 122 to make the elastic air bag 365. The elastic displacement is inflated and bulged around the inner side of the wearing member 2, thereby abutting against the wrist portion of the user. As shown in Fig. 7, the blood vessel 7 is pressed against the blood vessel 7 between the skin tissue 5 and the bone 6 to prevent blood flow. The pressure sensor 33 is then used to perform an inflation blood pressure measurement method for health monitoring.

In summary, the wearable health monitoring device provided in the present invention mainly implements health measurement by monitoring the body embedded in the biometrics monitoring module, and uses the photoelectric sensor to perform optical blood pressure measurement, and can utilize the blood pressure blood pressure device and The pressure sensor is used to implement the inflated blood pressure measurement, and the inflated blood pressure measurement monitoring health data information is used as the basis for the correction of the optical blood pressure measurement before the measurement, thereby providing more reliable and accurate measurement at any time and anywhere, and further The control module transmits the health data information to the external link device for storage and recording for further analysis and statistics, so as to better understand the health situation of the wearable user, and can immediately report the treatment measures for processing or returning the ambulance, which is highly utilized by the industry. Value, 提出 apply in accordance with the law.

Even though the present invention has been described in detail by the above-described embodiments, it can be modified by those skilled in the art, and is not intended to be protected as claimed.

1‧‧‧Monitoring ontology

11‧‧‧ screen

12‧‧‧ embedded body

121‧‧‧ embedded trough

122‧‧‧Ventilation slot

123‧‧‧Exhaust runner

124‧‧‧Airbag access

13‧‧‧ Monitoring area notch

14‧‧‧ Cover

141‧‧‧ notch

142‧‧‧ venting holes

143‧‧‧Transparent cover

144‧‧‧ Covering Department

2‧‧‧ wearing parts

3‧‧‧Biometric Monitoring Module

31‧‧‧Drive Circuit Board

32‧‧‧Photoelectric sensor

33‧‧‧ Pressure sensor

34‧‧‧impedance sensor

35‧‧‧Lighting elements

36‧‧‧Pneumatic blood pressure device

361‧‧‧Gas actuator

362‧‧‧Gas valve seat

362a‧‧‧gas collecting trough

362b‧‧‧ lower gas collection chamber

362c‧‧‧lower pressure relief chamber

362d‧‧‧ gas collecting through hole

362e‧‧‧Connected runners

362f‧‧‧Gas valve seat projection

362g‧‧‧Relief through hole

363‧‧‧ cavity plate

363a‧‧‧Upper gas collection chamber

363b‧‧‧Upper pressure relief chamber

363c‧‧‧ cavity plate convex

363d‧‧‧Connecting chamber

363e‧‧‧Connected holes

364‧‧‧ valve

364a‧‧‧ valve hole

365‧‧‧elastic bladder

365a‧‧‧Plate

4‧‧‧Control Module

41‧‧‧Microprocessor

42‧‧‧Communicator

42a‧‧‧Internet of Things communication components

42b‧‧‧Data communication components

43‧‧‧Global Positioning System Components

5‧‧‧Skin tissue

6‧‧‧ bones

7‧‧‧Vascular

8a‧‧‧ Network relay station

8b‧‧‧Cloud data processing device

8c‧‧‧Mobile communication device

10‧‧‧Micropump

101‧‧‧Intake plate

101a‧‧‧ Inlet

101b‧‧‧ busbar slot

101c‧‧ ‧ confluence chamber

102‧‧‧Resonance film

102a‧‧‧ hollow hole

102b‧‧‧movable department

102c‧‧‧ fixed department

103‧‧‧ Piezoelectric Actuator

103a‧‧‧suspension plate

103b‧‧‧Front frame

103c‧‧‧ bracket

103d‧‧‧Piezoelectric components

103e‧‧‧ gap

103f‧‧‧ convex

104‧‧‧First insulation sheet

105‧‧‧Conductor

106‧‧‧Second insulation sheet

107‧‧‧Case space

Figure 1 is a schematic view showing the appearance of the wearable health monitoring device of the present invention. FIG. 2A is a schematic cross-sectional view showing the assembled biometrics monitoring module in the wearable health monitoring device of the present invention. FIG. 2B is a schematic view showing the back of the monitoring body of the wearable health monitoring device of the present invention. Figure 3 shows a wear level measurement diagram of the wearable health monitoring device of the present invention. Fig. 4A is a schematic cross-sectional view showing the pneumatic blood pressure device of the present invention. Fig. 4B to Fig. 4C are schematic views showing the inflation operation of the barometric blood pressure device shown in Fig. 4A. Fig. 4D is a schematic view showing the pressure relief operation of the barometric blood pressure device shown in Fig. 4A. Figure 5A shows a schematic exploded view of the micropump of the present invention. Fig. 5B is a schematic exploded view showing the micropump of the present invention from another angle. Figure 6A shows a schematic cross-sectional view of the micropump of the present invention. Fig. 6B is a schematic cross-sectional view showing another preferred embodiment of the micropump of the present invention. 6C to 6E are schematic views showing the operation of the micropump shown in Fig. 6A. Figure 7 shows a schematic diagram of the measurement of the blood pressure device on the human body. Figure 8 is a schematic diagram showing the connection transmission of the control module of the wearable health monitoring device of the present invention. FIG. 9 is a schematic cross-sectional view showing another embodiment of the elastic airbag of the wearable health monitoring device of the present invention. FIG. 10 is a schematic view showing another embodiment of the elastic airbag of the wearable health monitoring device of the present invention assembled on the wearing member. FIG. 11 is a schematic view showing another embodiment of the elastic airbag of the wearable health monitoring device of the present invention assembled on the wearing member.

Claims (29)

A wearable health monitoring device includes: a monitoring body, comprising an embedded seat body, a monitoring area slot and a cover plate, the embedded seat body has a recessed embedded groove portion, and the embedded groove portion The bottom portion is connected to a venting groove and an exhausting flow channel, and the monitoring area notch is disposed adjacent to the side of the embedded seat body, and the cover plate is closed at the bottom of the embedded groove portion, and corresponds to the venting groove position a communication slot is provided, and a corresponding exhaust hole is disposed corresponding to the exhaust flow path position, and a transparent cover is disposed corresponding to the notch position of the monitoring area; and a wearing member is connected to the outside of the monitoring body And a biometric monitoring module disposed in the monitoring body, comprising a photoelectric sensor, a pressure sensor and a pneumatic blood pressure device, wherein the photoelectric sensor and the pressure sensor are disposed at the notch of the monitoring area for monitoring, and The pneumatic blood pressure device is embedded in the embedding groove portion of the embedded seat body, and includes a gas collecting actuator and an elastic air bag, and the elastic air bag compresses the ventilation groove disposed in the embedding groove portion and the The slot of the cover The gas collecting actuator supplies a gas to the elastic airbag, and the elastic airbag is inflated and elastically displaced out of the cover plate to fit the skin tissue of the user, and the pressure sensor performs the skin tissue. The lower vasoconstriction pulsation measurement is used to generate a detection signal and is converted into a health data information output, and the health data information provides a monitoring correction calculation of the photoelectric sensor to adjust the output of the health data information. The wearable health monitoring device of claim 1, wherein the biometric monitoring module further comprises a driving circuit board, an impedance sensor and at least one light emitting component, wherein the driving circuit board structure is positioned in the monitoring area At the notch, the photosensor, the pressure sensor, the impedance sensor, and the light emitting device package are positioned under the driving circuit board and connected to the driving circuit board to obtain the required electrical and driving control signals, and The monitoring device should be used for monitoring, and the pneumatic blood pressure device is electrically connected to the driving circuit board, and the driving circuit board provides a driving signal, and the transparent cover of the cover plate covers the monitoring area slot And the photoelectric sensor, the pressure sensor, the impedance sensor and the light-emitting element can be protected from dust by the cover, and can transparently detect the skin tissue of the wearer. The wearable health monitoring device of claim 2, wherein the photoelectric sensor of the biometric monitoring module transmits the light source emitted by the light emitting element to the skin tissue, and the reflected light source is received by the photoelectric sensor. The detection signal is generated and converted into a health data information output, the health data information includes a heart rate data, an electrocardiogram data, and a blood pressure data. The wearable health monitoring device of the second aspect of the invention, wherein the pressure sensor of the biometric monitoring module fits the skin tissue of the user to generate a detection signal and converts it into a health data information output. The health data information includes a respiratory frequency data and a blood pressure data. The wearable health monitoring device of claim 2, wherein the impedance sensor of the biometric monitoring module fits the skin tissue of the user to generate a detection signal and converts it into a health data information output. Health data information contains a blood glucose data. The wearable health monitoring device of claim 1, wherein the pneumatic blood pressure device further comprises a gas collection valve seat, a cavity plate and a valve piece, wherein the gas collection valve seat frame is placed in the insertion a gas collecting groove is disposed on the groove portion corresponding to the venting groove position on the lower surface, and the gas collecting valve seat is provided with a lower collecting chamber and a lower pressure reducing chamber on the upper surface, the gas collecting groove and the collecting groove a gas collecting through hole between the lower collecting chambers for communicating the gas collecting groove and the lower collecting chamber, wherein the lower collecting chamber and the lower pressure reducing chamber are at the gas collecting seat The upper surface is spaced apart, and the lower gas collecting chamber and the lower pressure reducing chamber A communication flow path is provided between the lower gas collection chamber and the lower pressure relief chamber, wherein the lower pressure relief chamber has a gas valve seat protrusion, and the gas collection valve seat is convex a pressure relief through hole is communicated with the lower pressure relief chamber and the vent hole of the cover plate, and the elastic air bag is connected to the gas collection groove and the gas collection through hole, and The cavity plate is disposed on the gas collecting valve seat, and a surface of the upper surface of the gas collecting valve seat corresponding to the lower gas collecting chamber is respectively corresponding to the upper gas collecting chamber of the upper cover, and the lower portion is unloaded The pressure chambers correspond to the upper pressure relief chambers of the cover, and the upper gas collection chamber is provided with a cavity plate protrusion, and the cavity plate is opposite to the upper gas collection chamber and the upper pressure relief chamber. The other surface is recessed with a communication chamber, and the gas collection actuator is disposed on the cavity plate to cover the communication chamber, and the communication chamber passes through at least one communication hole, respectively, and the upper gas collection chamber And the upper pressure relief chamber is in communication, and the valve piece is disposed between the gas collection valve seat and the cavity plate to resist the convex portion of the gas gathering valve seat Closing the pressure relief through hole, and the positions of the convex portion of the conflict chamber plate provided with a valve bore, the valve hole by inconsistent projection portion of the cavity plate is closed. The wearable health monitoring device of claim 6, wherein the gas collection actuator is controlled to drive to provide gas transmission, the gas is introduced into the communication chamber and concentrated, and the communication chamber passes through the communication hole. Introducing into the upper collecting chamber and the upper pressure releasing chamber to push the valve piece away from the cavity plate protrusion, and pushing the valve piece against the gas collecting valve seat convex portion to close the pressure releasing through hole, At the same time, the gas in the upper pressure-reducing chamber is introduced into the upper gas collecting chamber from the connecting flow channel, and the gas is continuously introduced into the lower gas collecting chamber through the valve hole of the valve piece, and the gas passes through the set. The air through hole is concentrated to the air collecting groove, and then inflated in the elastic air bag, and the elastic air bag is inflated and elastically displaced to protrude outside the cover plate to fit the skin tissue of the user. The wearable health monitoring device of claim 7, wherein the elastic end of the elastic bladder has a pressure plate for abutting against the skin tissue of the user. The wearable health monitoring device of claim 7, wherein when the gas collecting actuator stops transmitting gas, the gas pressure of the gas collecting gas in the elastic airbag is greater than the gas pressure at the communicating chamber, the elasticity The gas collected in the airbag pushes the valve plate to displace against the convex portion of the cavity plate to close the valve hole, and the gas pushes the valve plate to move away from the convex portion of the gas collecting valve seat to open the pressure relief through hole. The gas of the inner gas is discharged from the communication channel to the pressure relief through hole, and then discharged outside the pressure blood pressure device to complete the elastic balloon pressure relief operation. The wearable health monitoring device of claim 1, wherein the gas collection actuator is a micro pump comprising: a flow plate having at least one inlet hole and at least one bus groove And a manifold chamber, wherein the inlet hole is configured to introduce a fluid, the inlet hole correspondingly penetrates the busbar slot, and the busbar slot merges into the manifold chamber, so that the fluid introduced by the inlet hole can be merged into the inlet a resonating plate, coupled to the inflow plate, having a hollow hole, a movable portion and a fixing portion, the hollow hole being located at a center of the resonance piece and the confluence chamber of the inflow plate Corresponding to the chamber, the movable portion is disposed around the hollow hole and facing the confluence chamber, and the fixing portion is disposed on the outer peripheral portion of the resonator to be adhered to the inflow plate; and a piezoelectric An actuator is coupled to the resonant plate to be disposed correspondingly; wherein the resonant plate has a chamber space between the piezoelectric actuator and the piezoelectric actuator to enable the fluid to be driven by the piezoelectric actuator The inlet hole of the flow plate is introduced, and is collected through the bus groove And flowing into the hollow hole of the resonance piece to the confluence chamber, and the piezoelectric actuator and the movable portion of the resonance piece generate a resonance transmission fluid. The wearable health monitoring device of claim 10, wherein the piezoelectric actuator comprises: a suspension plate in a square shape, which is bendable and vibrating; An outer frame disposed around the outer side of the suspension plate; at least one bracket connected between the suspension plate and the outer frame to provide elastic support of the suspension plate; and a piezoelectric element having a side length that is long It is less than or equal to one side of the suspension plate, and the piezoelectric element is attached to one surface of the suspension plate for applying a voltage to drive the suspension plate to bend and vibrate. The wearable health monitoring device of claim 10, wherein the micropump comprises a first insulating sheet, a conductive sheet and a second insulating sheet, wherein the current plate, the resonant sheet, the piezoelectric The actuator, the first insulating sheet, the conductive sheet and the second insulating sheet are sequentially stacked and combined. The wearable health monitoring device of claim 11, wherein the suspension plate comprises a convex portion disposed on the opposite surface of the surface of the suspension plate to which the piezoelectric element is attached. The wearable health monitoring device of claim 13, wherein the convex portion is integrally formed by an etching process, and the opposite surface of the floating plate is attached to the opposite surface of the piezoelectric element to form a surface. Convex structure. The wearable health monitoring device of claim 11, wherein the piezoelectric actuator comprises: a suspension plate in a square shape, which is bendable and vibrating; and an outer frame disposed around the suspension plate At least one bracket is formed between the suspension plate and the outer frame to provide elastic support of the suspension plate, and one surface of the suspension plate and one surface of the outer frame are formed into a non-coplanar structure, and One surface of the suspension plate maintains a chamber space with the resonance plate; A piezoelectric element having a length that is less than or equal to one side of the suspension plate, and the piezoelectric element is attached to a surface of the suspension plate for applying a voltage to drive the suspension plate to bend and vibrate. The wearable health monitoring device of claim 10, wherein the micropump is a microelectromechanical system micropump. The wearable health monitoring device of claim 1, wherein the monitoring body further comprises a screen. The wearable health monitoring device of claim 2, further comprising a control module, the control module comprising a microprocessor, a communicator and a global positioning system component, wherein the microprocessor The detection signals generated by the photoelectric sensor, the pressure sensor and the impedance sensor are respectively converted into a health data information output, and the communicator includes an Internet of Things communication component and a data communication component. The wearable health monitoring device of claim 18, wherein the Internet of Things communication component receives the data of the property monitoring module, and transmits and transmits the data to an external connection device for storage and recording. Further analysis and statistics are carried out to better understand the health situation of the wearer. The wearable health monitoring device of claim 19, wherein the Internet of Things communication component is a narrowband Internet of Things device that transmits a signal by a narrowband radio communication technology. The wearable health monitoring device of claim 19, wherein the external connection device comprises a network relay station and a cloud data processing device, and the network communication component transmits the health data information to the data processing device through the network relay station. Store and record for further analysis and statistics to better understand the health of the wearer. The wearable health monitoring device of claim 18, wherein the data communication component receives the health data information of the physical feature monitoring module, and transmits and transmits the health data The information is stored and recorded by the external link device for further analysis and statistics to better understand the health situation of the wearable user, and the communication component transmits the health data information through the wireless communication transmission interface. The wearable health monitoring device of claim 22, wherein the wireless communication interface is a Wi-Fi module, a Bluetooth module, a radio frequency identification module, and a near field communication module. At least one of them. The wearable health monitoring device of claim 22, wherein the external connection device comprises a mobile communication connection device, a network relay station and a cloud data processing device, and the mobile communication connection device receives the health data information, and then The health data is sent to the cloud data processing device for storage and recording through the network relay station for further analysis and statistics, so as to better understand the health situation of the wearer. The wearable health monitoring device of claim 24, wherein the mobile communication connection device is at least one of a mobile phone device, a notebook computer and a tablet computer. A wearable health monitoring device includes: a monitoring body, comprising an embedded seat body, a monitoring area slot and a cover plate, the embedded seat body has a recessed embedded groove portion, and the embedded groove portion The bottom portion is connected to a venting groove and an exhaust flow channel, and an air bag channel is disposed on a side of the embedded seat body for communicating with the venting groove, and the monitoring area notch is disposed adjacent to the side of the embedded seat body, and The cover plate is disposed at the bottom of the embedding groove portion, and is provided with a communicating exhaust hole corresponding to the position of the exhaust gas flow path, and a light transmissive cover is disposed corresponding to the notch position of the monitoring area; The inner side of the wearable member is surrounded by an elastic airbag, and the inlet end of the elastic airbag is embedded in the airbag channel of the embedded seat body for connection and positioning; A biometric monitoring module is disposed in the monitoring body, and includes a photoelectric sensor, a pressure sensor and a pneumatic blood pressure device, wherein the photoelectric sensor and the pressure sensor are disposed at a slot of the monitoring area for monitoring, and the air pressure is monitored. The blood pressure device is embedded in the embedding groove portion of the embedded seat body, and comprises a gas collecting actuator, a gas collecting valve seat, a cavity plate and a valve piece, wherein the gas collecting valve seat has a gas gathering a sump corresponding to the venting groove and the air bag passage connecting the embedded seat body, and the gas collecting actuator supplies the gas through the venting groove and the air bag passage to the elastic air bag. The elastic airbag is inflated and elastically displaced to protrude around the inner side of the wearing member to fit the skin tissue of the user, and the pressure sensor performs a blood vessel contraction pulsation measurement of the skin tissue to generate a detection signal and convert it into A health data information output, the health data information provides a monitoring correction calculation of the photoelectric sensor to adjust the output of the health data information. The wearable health monitoring device of claim 26, wherein the gas collecting valve seat frame is disposed on the embedding groove portion, and the gas collecting groove is recessed on the lower surface corresponding to the position of the venting groove. And the gas collecting valve seat is provided with a lower gas collecting chamber and a lower pressure reducing chamber on the upper surface, and a gas collecting through hole is formed between the gas collecting groove and the lower gas collecting chamber for the gas collecting groove And the lower collecting chamber communicates with each other, the lower collecting chamber and the lower pressure reducing chamber are disposed apart from an upper surface of the collecting valve seat, and the lower collecting chamber and the lower pressure reducing chamber are a communication flow path is provided between the lower gas collection chamber and the lower pressure relief chamber, wherein the lower pressure relief chamber has a gas valve seat protrusion and the gas collection valve seat convex portion The center is provided with a pressure relief through hole, communicates with the lower pressure relief chamber, and communicates with the air outlet of the cover plate, and the cavity plate is placed on the gas collection valve seat, and corresponds to the gas collection valve seat The upper surface is respectively provided with a gas collecting chamber corresponding to the lower gas collecting chamber corresponding to the upper cover, and a Relief chamber unit corresponding to one another of the upper cover relief chamber, and the upper plenum chamber is provided with a projecting plate portion cavity, and the cavity plate relative to the upper plenum chamber and the upper portion The other surface of the pressure relief chamber is recessed with a communication chamber, and the gas collection actuator is placed on the cavity plate to cover the communication chamber, and the communication chamber passes through at least one communication hole, respectively The upper collecting chamber is connected to the upper pressure reducing chamber, and the valve plate is disposed between the gas collecting valve seat and the cavity plate to block the pressure releasing through hole against the convex portion of the gas collecting valve seat, and A valve hole is formed at a position against the convex portion of the cavity plate, and the valve hole is closed by being in contact with the convex portion of the cavity plate. The wearable health monitoring device of claim 27, wherein the gas collection actuator is controlled to drive to provide gas transmission, the gas is introduced into the communication chamber, and the communication chamber passes through the communication hole. Introducing into the upper collecting chamber and the upper pressure releasing chamber to push the valve piece away from the cavity plate protrusion, and pushing the valve piece against the gas collecting valve seat convex portion to close the pressure releasing through hole, At the same time, the gas in the upper pressure-reducing chamber is introduced into the upper gas collecting chamber from the connecting flow channel, and the gas is continuously introduced into the lower gas collecting chamber through the valve hole of the valve piece, and the gas passes through the set. The air through hole is concentrated in the air collecting groove, and is inflated in the elastic air bag through the air venting groove and the air bag channel, and the elastic air bag is inflated and elastically displaced to protrude around the inner side of the wearing member for fitting The skin tissue of the person. The wearable health monitoring device of claim 27, wherein when the gas collecting actuator stops transmitting gas, the gas pressure of the gas collecting gas in the elastic airbag is greater than the gas pressure at the communicating chamber, the elasticity The gas trapped in the airbag passes through the air bag passage and the venting groove to pass through the air collecting groove to push the valve plate to displace against the convex portion of the cavity plate to close the valve hole, and the gas pushes the valve plate away from the set The gas valve seat convex portion opens the pressure relief through hole, and the gas collected in the elastic airbag is led out from the communication flow passage to the pressure relief through hole, and then discharged outside the pneumatic blood pressure device to complete the elastic airbag pressure relief operation.