TWI670045B - Health monitoring device - Google Patents

Abstract

A health monitoring device mainly comprises a biometric monitoring module, a gas monitoring module, a particle monitoring module, a purifying gas module and a control module, the biometric monitoring module provides health data information, and the gas monitoring module provides gas monitoring data. Information, the particle monitoring module provides particle monitoring data information, and the purification gas module provides air purification. The control module transmits health data information, gas monitoring data information and particle monitoring data information to an external connection device for storage, recording and display.

Description

Health monitoring device

The present invention relates to a health monitoring device, and more particularly to a portable device combined with a gas monitoring health monitoring device.

As the pace of life accelerates and work pressures increase, more and more people are paying attention to fitness. As a result, wearable fitness tracking devices have become very popular. Many people use this type of equipment for fitness or for weight loss. These devices can record fitness data so that users can track their fitness progress. Providing a device for monitoring health records at any time is the main subject of the present invention.

Although modern people can use the above-mentioned devices to monitor health records at any time to supplement exercise and fitness to maintain a healthy body, it is an important part of the gaze to maintain a healthy air quality environment to maintain health. Therefore, modern people pay more and more attention to the air quality requirements around life, such as carbon monoxide, carbon dioxide, volatile organic compounds (VOC), PM2.5, nitrogen monoxide, sulfur monoxide, etc., even gas. The particles contained in the environment will affect the human health in the environment, and even seriously endanger life. Therefore, in addition to maintaining health and sports, it is also necessary to understand the quality of the surrounding ambient air, to stay away from or to take precautions to achieve a purpose that can truly meet the health movement, and how to monitor the surrounding ambient air quality is a current priority.

How to confirm the quality of air quality, it is feasible to use a gas sensor to monitor the ambient gas. If it can provide monitoring information immediately, the person in the environment can be alerted. Preventing or escaping from exposure to environmental health effects and injuries from exposure to gases in the environment. Using gas sensors to monitor the surrounding environment is a very good application; portable devices are actions that modern people will carry out when they go out. Therefore, in this case, the biometrics monitoring module is integrated with the gas monitoring module, the particle monitoring module and the purified gas module in the portable device. In particular, the current development trend of the portable device is light, thin and necessary. In the case of high performance, how to thin the health monitoring device and set it in the portable device for the purpose of monitoring the health record, monitoring the ambient air quality and providing air purification solution at any time. Important topics developed.

The main purpose of the case is to provide a health monitoring device that uses the biometrics monitoring module to provide health data information, and provides monitoring data information in combination with the gas monitoring module and the particle monitoring module, and provides air purifying breathing in combination with the purifying gas module, and The information is transmitted to the external link device to store the record display, and the information can be immediately obtained as a warning to inform the person in the environment that the person can be immediately prevented or escaped, and the human health impact and injury caused by the exposure of the gas in the environment can be avoided. Monitor health records, monitor ambient air quality and provide clean air at any time.

A generalized embodiment of the present invention is a health monitoring device comprising: a body having a length of 110 to 130 mm, a width of 110 to 130 mm, a height of 15 to 25 mm, a chamber inside, and a first body An air inlet, a second air inlet, an air outlet and a monitoring area window are respectively connected to the chamber; a biometric monitoring module is disposed in the chamber of the body and positioned in the monitoring area window position The method includes a photoelectric sensor, a pressure sensor, an impedance sensor, at least one light emitting component, and a health monitoring processor. The photoelectric sensor, the pressure sensor and the impedance sensor are attached to the skin tissue of the user to generate a detection signal. For the health monitoring processor, the health monitoring processor will The detection signal is converted into a health data information output; a gas monitoring module is disposed in the chamber of the body and positioned at the first air inlet of the body, and includes a gas sensor and a gas actuator. The gas actuator controls the gas to be introduced into the gas monitoring module and is monitored by the gas sensor to generate a gas monitoring data information; a particle monitoring module is disposed in the chamber of the body and positioned corresponding to the Between the first air inlet and the air outlet, a particle actuator and a particle sensor are controlled, and the particle actuator controls the gas to be introduced into the particle monitoring module, and the particle sensor monitors the suspended particles contained in the gas. Particle size and concentration to generate a particle monitoring data information; a purge gas module disposed in the chamber of the body and positioned corresponding to the second air inlet and the air outlet, including a purification actuation And a purifying unit, the purifying actuator controls the gas to be introduced into the purifying gas module, so that the purifying unit purifies the gas; and a control module is arranged to be positioned Controlling the biometrics monitoring module, the gas monitoring module, the particle monitoring module and the purging gas module to operate, and the health data information, the gas monitoring data information and the particles Monitoring data information is transmitted and output.

10‧‧‧Health monitoring device

101‧‧‧ clothes

102‧‧‧ pants

103‧‧‧Retractable belt

1‧‧‧Biometric Monitoring Module

11‧‧‧Photoelectric sensor

12‧‧‧ Pressure sensor

13‧‧‧ Impedance sensor

14‧‧‧Lighting elements

15‧‧‧Health Monitoring Processor

2‧‧‧Gas Monitoring Module

21‧‧‧ compartment body

211‧‧‧ spacer

212‧‧‧First compartment

213‧‧‧ second compartment

214‧‧‧ gap

215‧‧‧ openings

216‧‧‧ Vents

217‧‧‧ accommodating slots

22‧‧‧ Carrier Board

221‧‧‧ vent

23‧‧‧ gas sensor

24‧‧‧ gas actuator

241‧‧‧ Intake plate

241a‧‧‧ Inlet

241b‧‧‧ busbar slot

241c‧‧‧ confluence chamber

242‧‧‧Resonance film

242a‧‧‧ hollow hole

242b‧‧‧movable department

242c‧‧‧Fixed Department

243‧‧‧ Piezoelectric Actuator

243a‧‧‧suspension plate

243b‧‧‧Front frame

243c‧‧‧ bracket

243d‧‧‧Piezoelectric components

243e‧‧‧ gap

243f‧‧‧ convex

244‧‧‧First insulation sheet

245‧‧‧Conductor

246‧‧‧Second insulation sheet

247‧‧‧chamber space

20‧‧‧Blowing box micropump

201‧‧‧jet film

201a‧‧‧Connecting parts

201b‧‧‧suspension tablets

201c‧‧‧ hollow holes

202‧‧‧ cavity frame

203‧‧‧Acoustic body

203a‧‧‧Piezo carrier

203b‧‧‧Adjusting the resonance plate

203c‧‧‧thin plate

204‧‧‧Insulation frame

205‧‧‧Electrical frame

206‧‧‧Resonance chamber

207‧‧‧Airflow chamber

3‧‧‧Particle Monitoring Module

31‧‧‧ Ventilation entrance

32‧‧‧ Ventilation exit

33‧‧‧Particle monitoring base

331‧‧‧ socket

332‧‧‧Monitoring channel

333‧‧‧beam channel

334‧‧‧ housing room

34‧‧‧ Carrying partition

341‧‧‧Connecting port

35‧‧‧Laser transmitter

36‧‧‧Particle actuators

37‧‧‧Particle sensor

38‧‧‧First compartment

39‧‧‧Second compartment

4‧‧‧Gas gas module

41‧‧‧ air inlet

42‧‧‧Air outlet

43‧‧‧ air guiding channel

44‧‧‧ Purification actuator

45‧‧‧purification unit

45a‧‧‧Filter

45b‧‧‧Photocatalyst

45c‧‧‧UV light

45d‧‧‧Nei light tube

45e‧‧‧electrode wire

45f‧‧‧ dust collecting board

45g‧‧‧Boost power supply

45h‧‧‧ electric field protection net

45i‧‧‧Adsorption filter

45j‧‧‧High voltage discharge electrode

45k‧‧‧ electric net protection net

5‧‧‧Control Module

51‧‧‧Microprocessor

52‧‧‧Communicator

52a‧‧‧Internet of Things communication components

52b‧‧‧Data communication components

53‧‧‧Global Positioning System Components

6‧‧‧Power supply module

7‧‧‧ Ontology

71‧‧‧ chamber

72‧‧‧First air inlet

73‧‧‧second air inlet

74‧‧‧ outlet

75‧‧‧Monitoring area window

8‧‧‧External power supply

9a‧‧‧Mobile communication device

9b‧‧‧ Network relay station

9c‧‧‧Cloud data processing device

9d‧‧‧ Notification Processing System

9e‧‧‧ Notification processing device

L‧‧‧ length

W‧‧‧Width

H‧‧‧ Height

A‧‧‧ airflow path

Figure 1A is a perspective view of the health monitoring device of the present invention.

Figure 1B is a front view of the health monitoring device of the present case.

Figure 1C is a schematic diagram of the front side of the health monitoring device of the present case.

Figure 1D is a schematic view of the right side of the health monitoring device of the present invention.

Figure 1E is a schematic view of the left side of the health monitoring device of the present invention.

Figure 1F is a schematic diagram of the underside of the health monitoring device of the present invention.

Fig. 2 is a schematic cross-sectional view taken along line A-A of Fig. 1B.

Fig. 3 is a perspective view showing the position of the components of the health monitoring device of the present case.

Figure 4A is a front view showing the front view of the components of the gas monitoring module of the health monitoring device of the present invention.

Figure 4B is a schematic view showing the appearance of the back side of the components of the gas monitoring module of the health monitoring device of the present invention.

Figure 4C is a schematic exploded view of the components of the gas monitoring module of the health monitoring device of the present invention.

The 4D is a three-dimensional view of the gas flow direction of the gas monitoring module of the health monitoring device of the present invention.

Figure 4E is a partially enlarged schematic view showing the gas flow direction of the gas monitoring module of the health monitoring device of the present invention.

Fig. 5A is a schematic exploded view of the gas monitoring module of the micro pump of the present invention.

Figure 5B is a schematic exploded view of the micropump gas monitoring module of the present invention from another angle.

Figure 6A is 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 is a schematic cross-sectional view of the particle monitoring module of the present invention.

Fig. 8A is a schematic cross-sectional view showing the first embodiment of the purification unit of the purge gas module of the present invention.

FIG. 8B is a schematic cross-sectional view showing a second embodiment of the purification unit of the purification gas module of the present invention.

8C is a cross-sectional view showing a third embodiment of the purification unit of the purification gas module of the present invention.

8D is a cross-sectional view showing a fourth embodiment of the purification unit of the purification gas module of the present invention.

8E is a cross-sectional view showing a fifth embodiment of the purification unit of the purge gas module of the present invention.

Figure 9 is a schematic exploded view of the relevant components of the blower box micropump in this case.

Fig. 10A to Fig. 10C are diagrams showing the operation of the blast furnace gas pump shown in Fig. 9.

Figure 11 is a schematic diagram of the control of the health monitoring device of the present case.

Figure 12 is a schematic view showing an embodiment of the health monitoring device of the present invention being placed on a garment.

Figure 13 is a schematic view showing an embodiment of the health monitoring device of the present invention positioned on the trousers.

Figure 14 is a schematic view showing an embodiment of the health monitoring device of the present invention combined with a telescopic belt.

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 embodiments, and is not intended to limit the scope of the invention.

Referring to FIG. 1A to FIG. 1F and FIG. 2 , the present invention provides a health monitoring device 10 mainly comprising a biometric monitoring module 1 , a gas monitoring module 2 , a particle monitoring module 3 , and a cleaning gas module . The group 4 and a control module 5, the biometrics monitoring module 1, a gas monitoring module 2, a particle monitoring module 3, a purge gas module 4, and a control module 5 can be disposed in a body 7. A thin portable device, so the appearance structure design needs to achieve the user's ability to have a good grip and is not easy to drop and carry the convenience, and the outer shape of the body 7 needs to be thinned, so that the appearance size of the body 7 has a length L, a width W, and a height H, and the current biometric monitoring module 1, a gas monitoring module 2, a particle monitoring module 3, a purge gas module 4, and a control module 5 are disposed on the body The optimized configuration in 7 is to configure the length L of the body 7 to be 110 mm to 130 mm, the length L to be 116 mm to 124 mm, the width W to be 110 mm to 130 mm, and the width W to be 116 mm to 124 mm. And height H is configured to be 15mm~25mm, height H is 20mm~22mm Best. Moreover, the body 7 has a chamber 71 therein, and is provided with a first air inlet 72, a second air inlet 73, an air outlet 74 and a monitoring area window 75, wherein the first air inlet 72 and the second The intake port 73, the air outlet 74, and the monitoring area window 75 are in communication with the chamber 71, respectively.

Referring to FIG. 1F, FIG. 2 and FIG. 3, the biometric monitoring module 1 is disposed in the chamber 71 of the body 7 and positioned at the monitoring area window 75, and includes a photoelectric sensor 11 and a The pressure sensor 12, an impedance sensor 13, at least one light-emitting element 14, and a health monitoring processor 15. After the photoelectric sensor 11 is applied to the skin tissue of the user, the light source emitted by the light-emitting element 14 is transmitted to the skin tissue, and the reflected light source is received by the photoelectric sensor 11, and the detection signal is generated and provided to the health monitoring processor 15 for conversion to health. The data information is output to the control module 5, and the control module 5 transmits and outputs the health data information of the biometric monitoring module 1, and the health data information may include a heart rate data, an electrocardiogram data, and a blood pressure data; After the sensor 12 is attached to the user's skin tissue, the detection signal is generated and provided to the health monitoring processor 15 for conversion to the health data information output to the control module 5, and the control module 5 outputs the health data information of the biometric monitoring module 1. Transmitted and outputted, the health data information is a respiratory frequency data; after the impedance sensor 13 is attached to the user's skin tissue, the detection signal is generated and provided to the health monitoring processor 15 for conversion to the health data information output to the control module 5, and the control The module 5 transmits and outputs the health data information of the biometrics monitoring module 1 According to the information, a blood sugar data.

Referring to FIG. 2, FIG. 3 and FIG. 4A to FIG. 4E, the gas monitoring module 2 includes a compartment body 21, a carrier 22, a gas sensor 23 and a gas actuator. twenty four. The compartment body 21 is disposed at a position below the first air inlet 72 of the body 7, and is separated by a spacer 211 to form a first compartment 212 and a second compartment 213. The spacer 211 has a notch 214 for The first compartment 212 and the second compartment 213 are connected to each other, and the first compartment 212 has an opening 215, the second compartment 213 has an air outlet 216, and the bottom of the compartment body 21 is provided with a receiving slot 217. The groove 217 is disposed for the carrier 22 to be positioned therein to close the bottom of the cavity body 21, and the carrier 22 is disposed under the cavity body 21 and is electrically and electrically connected to the gas sensor 23, and the gas sensor 23 is worn. Extending into the opening 215 and located in the first compartment 212, For detecting the gas in the first compartment 212, the carrier 22 is provided with a vent 221, such that the carrier 22 is disposed under the compartment body 21, and the vent 221 will correspond to the vent of the second compartment 213. 216, and the gas actuator 24 is disposed in the second compartment 213, and is isolated from the gas sensor 23 disposed in the first compartment 212, so that the heat source generated by the gas actuator 24 when actuated can be received by the spacer 211. The barrier does not affect the detection result of the gas sensor 23, and the gas actuator 24 closes the bottom of the second compartment 213 to control the actuation to generate a guiding airflow, so that the gas is introduced from the first air inlet 72 of the body 7. And monitored by the gas sensor 23, and then the gap 214 enters the second compartment 213 and passes through the air outlet 216, and is discharged through the vent 221 of the carrier 22 to the outside of the gas monitoring module 2, and is discharged from the body 7. The port 74 is discharged.

Referring to FIG. 5A to FIG. 5B, the gas actuator 24 is a micro pump. The micro pump is composed of a current inlet plate 241, a resonance plate 242, a piezoelectric actuator 243, and a first The insulating sheet 244, a conductive sheet 245 and a second insulating sheet 246 are sequentially stacked. The inlet plate 241 has at least one inlet hole 241a, at least one bus bar groove 241b and a confluence chamber 241c. The inlet hole 241a is for introducing a gas, the inlet hole 241a is corresponding to the through bus bar groove 241b, and the bus bar groove 241b. The flow is merged into the confluence chamber 241c, so that the gas introduced into the inlet hole 241a is converged into the confluence chamber 241c. In the present embodiment, the number of the inlet holes 241a and the bus bar grooves 241b are the same, and the number of the inlet holes 241a and the bus bar grooves 241b are respectively four, which is not limited thereto, and the four inlet holes 241a are respectively penetrated. Four bus bar slots 241b, and four bus bar slots 241b merge into the sink chamber 241c.

Referring to FIGS. 5A, 5B, and 6A, the resonant plate 242 is assembled to the inflow plate 241 by a bonding method, and the resonant plate 242 has a hollow hole 242a and a movable portion 242b. a fixing portion 242c, the hollow hole 242a is located at the center of the resonance piece 242, and corresponds to the confluence chamber 241c of the inflow plate 241, and the movable portion 242b is disposed around the hollow hole 242a and The fixing portion 242c is provided on the outer peripheral portion of the resonance piece 242 and is attached to the inlet plate 241 in a region opposed to the manifold chamber 241c.

Continuing to refer to FIG. 5A, FIG. 5B and FIG. 6A, the piezoelectric actuator 243 includes a suspension plate 243a, an outer frame 243b, at least one bracket 243c, a piezoelectric element 243d, and at least one gap. 243e and a convex portion 243f. Wherein, the suspension plate 243a is in a square shape, and the suspension plate 243a adopts a square shape, which is compared with the design of the circular suspension plate. The structure of the square suspension plate 243a 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 243a 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 square design suspension plate 243a has the advantage of power saving advantage; the outer frame 243b is disposed around the outer side of the suspension plate 243a; at least one bracket 243c is connected between the suspension plate 243a and the outer frame 243b to provide elastic support for the suspension plate 243a. a supporting member; and a piezoelectric element 243d having a side length which is less than or equal to one side of the suspension plate 243a, and the piezoelectric element 243d is attached to a surface of the suspension plate 243a for applying a voltage to drive the suspension plate 243a bending vibration; and the suspension plate 243a, the outer frame 243b and the bracket 243c form at least one gap 243e for gas to pass through; the convex portion 243f is disposed on the suspension plate 243a The opposite surface of the surface of the piezoelectric element 243d, in the present embodiment, may be integrally formed by the squeezing process 243a by an etching process to protrude from the surface of the surface of the piezoelectric element 243d. 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 241, the resonance plate 242, the piezoelectric actuator 243, the first insulating sheet 244, the conductive sheet 245 and the second insulating sheet 246. The stacking assembly is sequentially arranged, wherein a cavity space 247 is formed between the suspension plate 243a and the resonant plate 242, and the cavity space 247 can be filled with a gap between the resonant plate 242 and the outer frame 243b of the piezoelectric actuator 243. Material formation, for example: conductive adhesive, but not limited to this, so that resonance A certain depth can be maintained between the sheet 242 and the suspension plate 243a to form the chamber space 247, thereby guiding the gas to flow more rapidly, and the suspension plate 243a and the resonator piece 242 are kept at an appropriate distance to reduce mutual contact interference, thereby promoting noise generation. It is reduced, of course, in the embodiment, the height of the frame 243b of the piezoelectric actuator 243 is raised to reduce the gap between the resonator piece 242 and the outer frame 243b of the piezoelectric actuator 243. The thickness of the micropump is not affected by the hot pressing temperature and the cooling temperature. The filling material of the conductive adhesive is affected by the thermal expansion and contraction factors, and the chamber space 247 is formed. Actual spacing, but not limited to this. In addition, the chamber space 247 will affect the transfer efficiency of the micropump, so maintaining a fixed chamber space 247 is important for providing a stable transfer efficiency for the micropump.

Therefore, in FIG. 6B, in other embodiments of the piezoelectric actuator 243, the suspension plate 243a may be press-formed to extend outwardly by a distance, and the outward extension distance may be formed by the at least one bracket 243c on the suspension plate. Between the 243a and the outer frame 243b, the surface of the convex portion 243f on the suspension plate 243a and the surface of the outer frame 243b are formed to be non-coplanar, and a small amount of filling material is applied to the surface of the outer frame 243b. For example, the conductive adhesive is used to bond the piezoelectric actuator 243 to the fixing portion 242c of the resonant piece 242 by heat pressing, so that the piezoelectric actuator 243 can be combined with the resonant piece 242, so that the above is directly transmitted. The suspension plate 243a of the piezoelectric actuator 243 is formed by press forming to form a chamber space 247, and the required chamber space 247 is completed by adjusting the press forming distance of the suspension plate 243a of the piezoelectric actuator 243. The structural design of the adjustment chamber space 247 is effectively simplified, and the advantages of simplifying the process and shortening the processing time are also achieved. In addition, the first insulating sheet 244, the conductive sheet 245, and the second insulating sheet 246 are all thin frame-shaped sheets, which are sequentially stacked on the piezoelectric actuator 243 to form a micropump integrated structure.

In order to understand the output operation mode of the above-mentioned micropump to provide gas transmission, please refer to FIG. 6C to FIG. 6E. Referring to FIG. 6C, the piezoelectric element 243d of the piezoelectric actuator 243 is applied with a driving voltage. The deformation causes the suspension plate 243a to be displaced downward. At this time, the volume of the chamber space 247 is increased, and a negative pressure is formed in the chamber space 247, so that the gas in the confluence chamber 241c is taken into the chamber space 247, and the resonance piece 242 is simultaneously. Under the influence of the resonance principle, the displacement is synchronously downward, and the volume of the confluence chamber 241c is increased, and the gas in the confluence chamber 241c enters the chamber space 247, so that the confluence chamber 241c is also in a negative pressure state. Further, the gas is sucked into the confluence chamber 241c through the inlet hole 241a and the bus bar groove 241b. Referring to FIG. 6D, the piezoelectric element 243d drives the suspension plate 243a to move upward, compressing the chamber space 247, and the same, the resonance piece. The 242 is displaced upward by the suspension plate 243a, forcing the gas in the synchronous pushing chamber space 247 to pass downward through the gap 243e to achieve the effect of transmitting gas; finally, refer to the 6E When the suspension plate 243a returns to the original position, the resonance piece 242 is still displaced downward by inertia, and the resonance piece 242 at this time will move the gas in the compression chamber space 247 to the gap 243e, and lift the inside of the confluence chamber 241c. The volume allows the gas to continuously converge in the confluence chamber 241c through the inlet hole 241a and the bus bar groove 241b, and the gas transmission operation step is provided by continuously repeating the micropumps shown in FIGS. 6C to 6E. The micropump enables the gas to continuously flow from the inlet hole 241a into the flow path formed by the inlet plate 241 and the resonator piece 242 to generate a pressure gradient, and then is transported downward by the gap 243e, so that the gas flows at a high speed to achieve the operation of the micropump transmission gas output. .

Continuing to refer to FIG. 6A, the micropump inlet plate 241, the resonant plate 242, the piezoelectric actuator 243, the first insulating sheet 244, the conductive sheet 245, and the second insulating sheet 246 are all transparent to the micro-electromechanical surface. The processing technology process reduces the size of the micropump to form a micro-electromechanical system micropump.

Please continue to refer to FIG. 4D and FIG. 4E. When the gas monitoring module 2 is embedded in the chamber 71 of the body 7, the body 7 is illustrated in the figure for convenience of explaining the gas flow of the gas monitoring module 2. Therefore, the body 7 is hereby transparently illustrated in the drawings for illustration, and the first air inlet 72 of the body 7 corresponds to the first compartment 212 of the compartment body 21, and the first air inlet 72 of the body 7 is The gas sensors 23 located in the first compartment 212 do not directly correspond to each other, that is, the first air inlets 72 are not directly located above the gas sensor 23, and the two are offset from each other, so that the control of the gas actuator 24 is actuated. The negative pressure is started in the second compartment 213, and the external air outside the body 7 is started to be drawn into the first compartment 212, so that the gas sensor 23 in the first compartment 212 starts to flow on the gas flowing over the surface. Monitoring to detect the quality of the gas introduced from outside the body 7, while the gas actuator 24 is continuously actuated, the monitored gas will be introduced into the second compartment 213 through the notch 214 on the septum 211, and finally through the vent. The vent 221 of the 216 and the carrier 22 is discharged outside the compartment body 21 to constitute a one-way gas conduction monitoring (as indicated by the 4D icon, the direction of the airflow path A).

The gas sensor 23 includes at least one of an oxygen sensor, a carbon monoxide sensor, and a carbon dioxide sensor, or a combination thereof; or the gas sensor 23 includes one or a combination of a temperature sensor and a humidity sensor; or The gas sensor 23 includes a volatile organic substance sensor; or the gas sensor 23 includes one of a bacterial sensor, a virus sensor, and a microbial sensor, or a combination thereof.

It can be seen from the above description that the health monitoring device 10 provided in the present invention can monitor the ambient air quality of the user at any time by using the gas monitoring module 2, and can quickly and stably introduce the gas into the gas monitoring module 2 by using the gas actuator 24. In addition, not only the efficiency of the gas sensor 23 is enhanced, but also the design of the first compartment 212 and the second compartment 213 of the compartment body 21 separates the gas actuator 24 from the gas sensor 23 so that the gas sensor 23 is monitored. The ability to block the heat source of the gas actuator 24 can be prevented, thereby avoiding the monitoring accuracy of the gas sensor 23 and, in addition, the gas sensor 23 can be prevented from being affected by other components in the device. ring. Therefore, the gas actuator 24 controls the gas to be introduced into the gas monitoring module 2, and is monitored by the gas sensor 23, and the detected gas monitoring data information is transmitted to the control module 5, and the control module 5 controls the gas monitoring module 2 The gas monitoring data information is transmitted and output, so that the gas monitoring module 2 can achieve the purpose of detecting the gas at any time and any place, and can have a fast and accurate monitoring effect.

Referring to FIG. 7 again, the health monitoring device 10 provided in the present invention further has a particle monitoring module 3 for monitoring particles contained in the gas. The particle monitoring module 3 is disposed in the chamber 71 of the body 7, and the particle monitoring module The group 3 includes a ventilation inlet 31, a ventilation outlet 32, a particle monitoring base 33, a load-bearing partition 34, a laser emitter 35, a particle actuator 36 and a particle sensor 37, wherein the ventilation inlet 31 corresponds to The second air inlet 73 of the body 7 and the air outlet 32 correspond to the air outlet 74 of the body 7, so that the gas enters the interior of the particle monitoring module 3 from the ventilation inlet 31, and is discharged by the ventilation outlet 32, and the particle monitoring base 33 and The carrier baffle 34 is disposed inside the particle monitoring module 3, so that the inner space of the particle monitoring module 3 defines a first compartment 38 and a second compartment 39 by the carrying partition 34, and the carrying baffle 34 has a communication. The port 341 is configured to communicate the first compartment 38 with the second compartment 39, and the second compartment 39 is in communication with the venting outlet 32. The particle monitoring base 33 is adjacent to the carrying partition 34 and is received in the first partition. In the chamber 38, and the particle monitoring base 33 has a receiving groove 331, a monitoring a channel 332, a beam path 333 and an accommodating chamber 334, wherein the receiving groove 331 directly corresponds to the venting inlet 31, and the monitoring channel 332 is disposed below the receiving groove 331 and communicates with the communication port 341 of the carrying partition 34. The accommodating chamber 334 is disposed on the side of the monitoring channel 332, and the beam path 333 is connected between the accommodating chamber 334 and the monitoring channel 332, and the beam path 333 directly traverses the monitoring channel 332 vertically, so that the interior of the particle monitoring module 3 is ventilated. The inlet 31, the receiving groove 331, the monitoring channel 332, the communication port 341, and the venting port 32 constitute a gas passage for a single gas supply, that is, a path in the direction indicated by the arrow in FIG. Moreover, the laser emitter 35 is disposed in the accommodating chamber 334, and the particulate actuator 36 is disposed in the receiving slot 331. At one end of the monitoring channel 332, and the particle sensor 37 is electrically connected to the carrier baffle 34 and located at the other end of the monitoring channel 332.

Knowing the characteristics of the above-mentioned particle monitoring module 3, and the particle actuator 36 as a gas transmission, it can be a micro pump structure, and the structure and operation mode of the micro pump are as described above, and will not be described herein.

As can be seen from the above, the particle actuator 36 controls the gas to be introduced into the particle monitoring module 3, so that the laser beam emitted by the laser emitter 35 is irradiated into the beam path 333, and the beam channel 333 guides the laser beam to the monitoring channel. In 332, the suspended particles contained in the gas in the monitoring channel 332 are irradiated, and after the floating particles are irradiated by the light beam, a plurality of light spots are generated, and the projection is received on the surface of the particle sensor 37, so that the particle sensor 37 senses The particle size and concentration of the suspended particles, the detected particle monitoring data information is transmitted to the control module 5, and the control module 5 transmits and outputs the particle monitoring data information of the particle monitoring module 3.

Moreover, the monitoring channel 332 of the particle monitoring module 3 directly corresponds to the venting inlet 31 directly, so that the monitoring channel 332 can directly conduct air without affecting airflow introduction, and the particle actuator 36 is framed in the receiving slot 331 and the venting inlet 31 The external gas is guided into the suction, so that the gas is introduced into the monitoring channel 332 and detected by the particle sensor 37 to increase the efficiency of the particle sensor 37. The particle sensor 37 of this embodiment is a PM2.5 sensor.

Referring to FIG. 3 and FIG. 8A to FIG. 8E , the health monitoring device 10 provided in the present invention further has a purge gas module 4 for purifying gas, and the purge gas module 4 is disposed in the chamber 71 of the body 7 . The air inlet 41, the air outlet 42 and the cleaning actuator 44 and the cleaning unit 45 are connected to the second air inlet 73 of the body 7. 42 corresponds to the air outlet 74 of the body 7, the air guiding passage 43 is disposed between the air guiding inlet 41 and the air guiding outlet 42, and the purifying actuator 44 is disposed in the air guiding passage 43 to control the gas introduction into the air guiding passage 43. The purification unit 45 is placed in the air guiding passage 43.

The cleaning unit 45 can be a filter unit. As shown in FIG. 8A, the filter unit 45 includes a plurality of screens 45a. In this embodiment, the two screens 45a are respectively disposed with a space in the air guiding passage 43 to allow gas to pass through. The purifying actuator 44 controls the chemical fumes, bacteria, dust particles and pollen contained in the gas adsorbed by the two screens 45a in the air guiding passage 43 to achieve the effect of purifying the gas, wherein the screen 45a can be an electrostatic filter. Activated carbon filter or high efficiency filter (HEPA).

The cleaning unit 45 can be a photocatalyst unit. As shown in FIG. 8B, a photocatalyst 45b and an ultraviolet lamp 45c are disposed, and a distance is maintained in the air guiding channel 43 to allow the gas to pass through the purification actuator 44 to control the introduction. In the air guiding channel 43, and the photocatalyst 45b is irradiated by the ultraviolet lamp 45c, the light energy can be converted into chemical energy to decompose the gas into the harmful gas and disinfected to achieve the effect of purifying the gas. Of course, the purifying unit 45 is a photocatalyst unit and can also be matched with the filter. 45a is in the air guiding passage 43 to enhance the effect of purifying the gas, wherein the screen 45a may be an electrostatic screen, an activated carbon screen or a high efficiency screen (HEPA).

The purifying unit 45 can be a photoplasma unit, as shown in FIG. 8C, including a nano tube 45d, and the gas guiding channel 43 is disposed, so that the gas is controlled to be introduced into the air guiding channel 43 through the purifying actuator 44. By irradiating through the nanometer tube 45d, the oxygen molecules and water molecules in the gas are decomposed into a highly oxidizing photo-plasma with an ion stream that destroys the organic molecules, and the gas contains volatile formaldehyde, toluene, and volatile organic gases (VOC). The gas molecules are decomposed into water and carbon dioxide to achieve the effect of purifying the gas. Of course, the purification unit 45 is a light plasma unit and can also cooperate with the filter 45a in the air guiding passage 43 to enhance the effect of purifying the gas. The filter 45a can be It is an electrostatic filter, activated carbon filter or high efficiency filter (HEPA).

The cleaning unit 45 can be an anion unit, as shown in FIG. 8D, comprising at least one electrode line 45e, at least one dust collecting plate 45f and a boosting power supply 45g, each electrode line 45e and each dust collecting plate. 45f is disposed in the air guiding passage 43, and the boosting power source 45g is disposed in the purge gas module 4 to provide high voltage discharge for each electrode line 45e, and each of the dust collecting plates 45f has a negative electric charge to make the gas The inlet into the gas guiding passage 43 is controlled by the purifying actuator 44, and the high-voltage discharge is performed through each of the electrode wires 45e, so that the particles contained in the gas are positively charged, and the positively-charged particles are attached to each of the negatively-charged dust collecting plates. 45f, in order to achieve the effect of purifying the gas, of course, the purification unit 45 is an anion unit can also cooperate with the filter 45a in the air guiding passage 43 to enhance the effect of purifying the gas, wherein the screen 45a can be an electrostatic screen, activated carbon Filter or high efficiency filter (HEPA).

The cleaning unit 45 can be a plasma ion unit, as shown in FIG. 8E, including an electric field upper protection net 45h, an adsorption filter 45i, a high voltage discharge electrode 45j, an electric field lower protection net 45k, and a boosting unit. The power source 45g, wherein the electric field upper protection net 45h, the adsorption filter net 45i, the high voltage discharge electrode 45j and the electric field lower protection net 45k are disposed in the air guiding passage 43, and the adsorption filter 45i and the high voltage discharge electrode 45j are disposed on the electric field. The protection net 45h and the electric field under the protection net 45k, and the boosting power supply 45g is disposed in the purification gas module 4 to provide a high-voltage discharge electrode 45j high-voltage discharge to generate a high-voltage plasma column with plasma ions to allow gas to pass through The purifying actuator 44 controls the introduction into the gas guiding passage 43 to permeate the plasma ions to ionize the oxygen molecules contained in the gas to form cations (H ⁺ ) and anions (O ₂ ^- ), and water molecules are attached around the ions. After the substance adheres to the surface of the virus and bacteria, it will be converted into strong oxidizing active oxygen (hydroxyl, OH group) under the action of chemical reaction, thereby taking away the hydrogen of the virus and bacterial surface proteins and decomposing it (oxidative decomposition). ), in order to achieve the effect of purifying the gas, when The cleaning unit 45 is an anion unit and can also cooperate with the screen 45a in the air guiding passage 43 to enhance the effect of purifying the gas. The screen 45a can be an electrostatic screen, an activated carbon screen or a high efficiency screen (HEPA).

The above description of the characteristics of the purge gas module 4, and the purification actuator 44 as a gas transmission, may be a micro-pump structure, the structure and operation of the micro-pump is the same as described above, and will not be described herein.

Of course, the gas actuator 24, the particulate actuator 36, and the purification actuator 44 of the present invention may be the structure and actuation of a blower box micropump 20, respectively, in addition to the micropump structure described above. The way to implement gas transmission. Referring to FIG. 9 , FIG. 10A to FIG. 10C , the blower box micropump 20 includes the sequentially disposed jet orifice sheet 201 , the cavity frame 202 , the actuating body 203 , the insulating frame 204 , and the conductive frame 205 ; The hole piece 201 includes a plurality of connecting pieces 201a, a suspension piece 201b and a hollow hole 201c. The suspension piece 201b can be flexed and vibrated, and the plurality of connecting pieces 201a are adjacent to the circumference of the suspension piece 201b. In this embodiment, the connecting piece 201a The number is four, respectively adjacent to the four corners of the suspension piece 201b, but not limited thereto, and the hollow hole 201c is formed at the center position of the suspension piece 201b; the cavity frame 202 is carried on the suspension piece 201b, resulting in The movable body 203 is stacked on the cavity frame 202 and includes a piezoelectric carrier 203a, an adjustment resonator plate 203b, and a piezoelectric plate 203c. The piezoelectric carrier 203a is stacked on the cavity frame 202. The adjustment resonator plate 203b is placed on the piezoelectric carrier 203a, and the piezoelectric plate 203c is placed on the adjustment resonator plate 203b for deformation after being applied to drive the piezoelectric carrier 203a and the adjustment resonator plate 203b. Reciprocating bending vibration; insulating frame 204 is Stacked on the piezoelectric carrier 203a of the actuating body 203, the conductive frame 205 is stacked on the insulating frame 204, wherein a resonant cavity is formed between the actuating body 203, the cavity frame 202 and the suspension piece 201b. 206.

Referring again to FIGS. 10A to 10C, a schematic diagram of the operation of the blower box micropump 20 of the present embodiment is shown. Referring to FIG. 9 and FIG. 10A, the blower box micropump 20 is fixedly disposed through a plurality of connecting members 201a, and an air flow chamber 207 is formed at the bottom of the air venting aperture 201; please refer to FIG. 10B, when voltage is applied When the piezoelectric plate 203c of the movable body 203 is pressed, the piezoelectric plate 203c starts to deform due to the piezoelectric effect and simultaneously drives the adjustment resonance plate 203b and the piezoelectric carrier plate 203a. At this time, the air ejection orifice 201 is affected by Helmholtz resonance ( The Helmholtz resonance principle is driven together, so that the actuating body 203 moves upward, and the displacement of the actuating body 203 is upward, so that the volume of the airflow chamber 207 on the bottom surface of the gas jet orifice 201 increases, and the internal air pressure forms a negative pressure in the blower box. The gas outside the micropump 20 will enter the airflow chamber by the gap of the connecting piece 201a of the air vent sheet 201 due to the pressure gradient. The chamber 207 is subjected to pressure collection; finally, referring to FIG. 10C, the gas continuously enters the gas flow chamber 207 to form a positive pressure of the gas pressure in the gas flow chamber 207. At this time, the actuating body 203 is driven to move downward by the voltage. The volume of the air flow chamber 207 will be compressed, and the gas in the air flow chamber 207 will be pushed, and the gas will be pushed into the blower box micropump 20 to be pushed out to realize the gas transport flow.

Of course, the blower box micropump 20 of the present invention can also be a microelectromechanical system gas pump produced by a microelectromechanical process, wherein the air vent sheet 201, the cavity frame 202, the actuating body 203, the insulating frame 204, and The conductive frame 205 can be made through a surface micromachining technique to reduce the volume of the blower box micropump 20.

Referring to FIG. 3 and FIG. 11 , the health monitoring device 10 further includes a power supply module 6 for storing electrical energy and outputting electrical energy. The power supply module 6 can be a battery module to provide electrical energy output to the biometric feature. The electrical operation of the monitoring module 1, the gas monitoring module 2, the particle monitoring module 3, the purified gas module 4 and the control module 5, and the power supply module 6 can be wired to receive an external power supply device 8 for supplying electrical energy The electric energy is stored, that is, the storage power and the output power can be provided between the external power supply device 8 and the power supply module 6 by using at least one of a wired transmission interface of a USB, a mini-USB, and a micro-USB, or The power supply module 6 wirelessly transmits and receives power from an external power supply device 8 to store electrical energy, that is, the wireless power transmission interface of a wireless charging component can be used to connect the external power supply device 8 and the power supply module 6 to store stored energy. The electrical energy is output, and the external power supply device 8 can be at least one of a charger and a mobile power source.

Referring to FIGS. 3 and 11 , the control module 5 includes a microprocessor 51 , a communicator 52 , and a global positioning system component 53 . The communicator 52 includes an Internet of Things communication component 52a and a data communication component 52b. The IoT communication component 52a receives the health data information of the biometrics monitoring module 1 and the gas monitoring data information and the particle monitoring module of the gas monitoring module 2. 3 particles monitor data information and transmit and send the information to an external link device The record shows that the Internet of Things communication component 52a is a narrowband IoT device that transmits signals transmitted by narrowband radio communication technology. The external connection device includes a network relay station 9b and a cloud data processing device 9c. The Internet of Things communication component 52a transmits the information to the cloud data processing device 9c through the network relay station 9b to store and store the record display. The data communication component 52b Receiving the health data information of the biometrics monitoring module 1 and the gas monitoring data information of the gas monitoring module 2 and the particle monitoring data information of the particle monitoring module 3, and transmitting and transmitting the information to the external linking device to store the record display, and The data communication component 52b transmits the information through a wired communication transmission, and the wired communication transmission interface is at least one of a USB, a mini-USB, and a micro-USB; or the data communication component 52b transmits the wireless communication transmission. Information, and the wireless communication transmission interface is at least one of a Wi-Fi module, a Bluetooth module, a radio frequency identification module and a near field communication module, and the data communication component 52b transmits and transmits the wireless communication interface Information to the external connection device, the external connection device includes a mobile communication connection device 9a, mobile communication connection 9a receiving the data communication component transmits and transmits the information to store the record display, and the mobile communication connection device 9a can be at least one of a mobile phone device, a smart watch, and a smart bracelet; or the data communication component 52b transmits and transmits the data. The information is connected to the external connection device. The external connection device includes a mobile communication connection device 9a, a network relay station 9b and a cloud data processing device 9c. The mobile communication connection device 9a receives the information and transmits the information through the network relay station 9b. The transfer to the cloud data processing device 9c stores the record display, and the mobile communication device 9a can be at least one of a mobile phone device, a notebook computer, and a tablet computer.

The mobile communication connection device 9a can be connected to a notification processing system 9d. The mobile communication connection device 9a receives the gas monitoring data information of the gas monitoring module 2 and the particle monitoring data information of the particle monitoring module 3 can be notified by the alarm information. Sending an alarm message to the notification processing system 9d to activate an air quality notification mechanism, the air quality notification mechanism is Provide users with protective notices for wearing masks, and an air quality notification mechanism to provide an instant air quality map to the user and remind them to take measures to avoid them.

The mobile communication connection device 9a can also be connected to a notification processing device 9e. The mobile communication connection device 9a receives the gas monitoring data information of the gas monitoring module 2 and the particle monitoring data information of the particle monitoring module 3 can be sent to the alarm information. The notification device 9e can be used to activate the air quality processing, and the notification processing device 9e can be at least one smart home appliance, and the smart home appliance can be an air cleaner, a dehumidifier, a row of fans, an electric door, and a Power window, an automatic cleaning robot, an air conditioner, etc., but not limited to this, through one or more smart appliances to improve the air quality at the same time, for example: simultaneously closing the electric door and the electric window, and The air cleaner is activated to improve suspended particles or fine aerosols, etc., by the activation of the notification processing device 9e, the air quality around the user can be improved in time, and when the ambient air quality of the user is improved, the notification processing device 9e receives After the air quality information of the mobile communication device 9a is transmitted, the operation can be stopped immediately.

In addition, the health monitoring device 10 of the present invention may further include a display (not shown), and the control module 5 transmits the health data information of the biometric monitoring module 1 and the gas monitoring data information and particle monitoring of the gas monitoring module 2 The particle monitoring data information of the module 3 is displayed by the display.

Of course, the health monitoring device 10 of the present invention can be integrated into the garment to form a smart garment with a health record that can be monitored at any time, monitor the ambient air quality, and provide clean air. The health monitoring device 10 shown in FIG. 12 can be The positioning is performed on a garment 101. As shown in Fig. 13, the health monitoring device 10 can be positioned and positioned on a pair of pants 102. Alternatively, the health monitoring device 10 is directly worn on the user to form a device having a health record that can be monitored at any time, monitoring the ambient air quality, and providing clean air. The health monitoring device 10 shown in FIG. 14 is combined with a telescopic belt 103 to Implemented on the wearer.

In summary, the present invention provides a health monitoring device that provides health data information using a biometric monitoring module, and provides gas and particle monitoring data information in combination with a gas monitoring module and a particle monitoring module, and is provided in combination with a purge gas module. The air purifies the breath, and the information is transmitted to the external link device to store the record display, and the information can be immediately obtained as a warning to inform the person in the environment that the person can be immediately prevented or escaped, and the human body is prevented from being exposed to the environment. Impact and injury, to achieve health monitoring, monitoring the ambient air quality and providing air purification.

This case has been modified by people who are familiar with the technology, but it is not intended to be protected by the scope of the patent application.

Claims (47)

A health monitoring device comprises: a body having a length of 110 to 130 mm, a width of 110 to 130 mm, a height of 15 to 25 mm, a chamber inside, and a first air inlet and a second inlet a gas inlet, an air outlet and a monitoring area window, wherein the first air inlet, the second air inlet, the air outlet and the monitoring area window are respectively connected to the chamber; a biometric monitoring module is disposed on Positioned in the monitoring area window, the body of the body includes a photoelectric sensor, a pressure sensor, an impedance sensor, at least one light emitting component, and a health monitoring processor, the photoelectric sensor, the pressure sensor and the impedance sensor After the user's skin tissue is attached, a detection signal is generated for the health monitoring processor, and the health monitoring processor converts the detection signal into a health data information output; a gas monitoring module is disposed on the body Positioned in the first inlet port of the body, including a gas sensor and a gas actuator, the gas actuator controls gas introduction into the gas The inside of the body monitoring module is monitored by the gas sensor to generate a gas monitoring data information; a particle monitoring module is disposed in the chamber of the body and positioned corresponding to the first air inlet and the air outlet In between, a particle actuator and a particle sensor are controlled, and the particle actuator controls gas to be introduced into the particle monitoring module, and the particle sensor monitors the particle size and concentration of the suspended particles contained in the gas to generate a particle. Monitoring data information; a purge gas module disposed in the chamber of the body and positioned corresponding to the second air inlet and the air outlet, comprising a purification actuator and a purification unit, the purification The control gas is introduced into the clean gas module to enable the purification unit to purify the gas; and a control module is disposed in the chamber of the body to control the biometric monitoring module, the gas monitoring module, and the The particle monitoring module and the startup operation of the purge gas module, and the health data information, the gas monitoring data information and the particle monitoring data information are given Transfer output. The health monitoring device of claim 1, wherein the gas monitoring module comprises a compartment body and a carrier plate, wherein the compartment body is disposed at the first air inlet position of the body, and a spacer forms a first compartment and a second compartment, the spacer has a gap for the first compartment and the second compartment to communicate with each other, and the first compartment has an opening. The second compartment has an air outlet, and the carrier is disposed under the compartment body and encapsulates and electrically connects the gas sensor, and the carrier is provided with a vent corresponding to the second compartment. An air outlet, wherein the gas sensor penetrates into the opening and is disposed in the first compartment, the gas actuator is disposed in the second compartment, and is isolated from the gas sensor disposed in the first compartment Controlling gas is introduced from the first air inlet by the gas actuator, and is monitored by the gas sensor, and then the gap enters the second compartment and passes through the air outlet, and passes through the carrier The vent is discharged outside the gas monitoring module, and The air outlet of the body is discharged. The health monitoring device of claim 1, wherein the gas sensor comprises one or a combination of an oxygen sensor, a carbon monoxide sensor, and a carbon dioxide sensor. The health monitoring device of claim 1, wherein the gas sensor comprises one of a temperature sensor and a humidity sensor or a combination thereof. The health monitoring device of claim 1, wherein the gas sensor comprises a volatile organic sensor. The health monitoring device of claim 1, wherein the gas sensor comprises one of a bacterial sensor, a virus sensor, and a microbial sensor, or a combination thereof. The health monitoring device of claim 1, wherein the particle monitoring module comprises a ventilation inlet, a ventilation outlet, a load-bearing partition, a particle monitoring base and a laser emitter, wherein the ventilation inlet corresponds to Positioned at the second air inlet of the body, and the air is vented The port corresponds to the position of the air outlet of the body, and the inner space of the particle monitoring module defines a first compartment and a second compartment by the carrying partition, and the carrying partition has a communication port. Connecting the first compartment and the second compartment, and the first compartment is in communication with the ventilation inlet, the second compartment is in communication with the ventilation outlet, and the particle monitoring base is adjacent to the carrier partition And accommodating in the first compartment, having a receiving slot, a monitoring channel, a beam path and an accommodating chamber, the receiving slot directly corresponding to the venting inlet, and the particle actuator is disposed The receiving slot is located at one end of the monitoring channel, and the receiving chamber is disposed on the side of the monitoring channel to position the laser emitter, and the beam path is connected between the receiving chamber and the monitoring channel And directly perpendicular to the monitoring channel, guiding the laser beam emitted by the laser emitter to be irradiated into the monitoring channel, and the particle sensor is disposed at the other end of the monitoring channel, and the particle actuator controls the gas Entering the receiving groove from the venting inlet And introducing into the monitoring channel, and being irradiated by the laser beam emitted by the laser emitter to project a light spot in the gas to the particle sensor surface to detect the particle size and concentration of the suspended particles contained in the gas, and the monitored gas passes through the The venting outlet is discharged from the air outlet of the body. The health monitoring device of claim 1, wherein the particle sensor is a PM2.5 sensor. The health monitoring device of claim 1, wherein the purification gas module is adjacent to the particle monitoring module, and includes a gas guiding inlet, an air guiding outlet and a gas guiding passage, and the air guiding inlet Corresponding to the second air inlet position of the body, the air outlet corresponding to the air outlet position of the body, and the air guiding channel is disposed between the air guiding inlet and the air guiding outlet, and the a purifying actuator and the purifying unit are disposed in the air guiding channel, wherein the purifying actuator controls gas to enter from the second air inlet of the body and is introduced into the air guiding channel, so that the passing gas is received by the purifying unit Purification, and then discharged through the air outlet of the body through the air outlet. The health monitoring device of claim 1, wherein the gas actuator, the micro The granule actuator and the purifying actuator are respectively a micropump, the micropump comprising: a flow inlet plate having at least one inlet hole, at least one bus bar groove and a confluence chamber, wherein the inlet hole is provided Introducing a gas, the inlet hole correspondingly passes through the bus bar groove, and the bus bar groove merges into the confluence chamber, so that the gas introduced into the inlet hole can be merged into the confluence chamber; a resonance piece is coupled to the gas The air inlet plate has a hollow hole, a movable portion and a fixing portion, and the hollow hole is located at a center of the resonance plate and corresponds to the confluence chamber of the inflow plate, and the movable portion is disposed in the hollow hole a region surrounding the confluence chamber, wherein the fixing portion is disposed on the outer peripheral portion of the resonator piece and attached to the inflow plate; and a piezoelectric actuator coupled to the resonating plate and correspondingly disposed Wherein the resonator piece and the piezoelectric actuator have a chamber space for driving the piezoelectric actuator to be introduced from the inlet hole of the inlet plate through the confluence The trough is collected into the confluence chamber and flows through the resonator Pores, made of the piezoelectric actuator with the resonant plate of the movable portion of the transport gas resonance. The health monitoring device of claim 10, wherein the piezoelectric actuator comprises: a suspension plate having a square shape for bending vibration; and 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 which is less than or equal to one side length of the suspension plate, and the pressure An electrical component is attached to a surface of the suspension plate for applying a voltage to drive the suspension plate to flex vibration. The health monitoring device of claim 10, wherein the micro pump further comprises a first insulating sheet, a conductive sheet and a second insulating sheet, wherein the current plate, the resonant sheet, and the piezoelectric The first insulating sheet, the conductive sheet and the second insulating sheet are sequentially stacked and combined. The 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 health monitoring device according to claim 13, wherein the convex portion is formed by an etching process integrally forming a convex structure protruding from the opposite surface of the surface of the suspension plate to which the piezoelectric element is attached. The health monitoring device of claim 10, wherein the piezoelectric actuator comprises: a suspension plate having a square shape for bending vibration; and an outer frame disposed around the outer side of 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 a surface of the suspension plate and a surface of the outer frame are formed into a non-coplanar structure, and the One surface of the suspension plate and the resonance plate maintain a chamber space; and a piezoelectric element having a side length which is less than or equal to one side length of the suspension plate, and the piezoelectric element is attached to the suspension plate On one surface, a voltage is applied to drive the suspension plate to bend and vibrate. The health monitoring device of claim 1, wherein the gas actuator, the particulate actuator, and the purification actuator are respectively a blower box micropump, and the blower box micropump comprises: The air vent sheet comprises a plurality of connecting members, a suspension piece and a hollow hole, the suspension piece is bendable and vibrating, the plurality of connecting pieces are adjacent to a circumference of the suspension piece, and the hollow hole is formed at a center position of the suspension piece, The plurality of connecting members are fixedly disposed and provide elastic support for the suspension piece, and an air flow chamber is formed between the bottom portions of the air venting piece, and at least one gap is formed between the plurality of connecting members and the floating piece; a cavity frame Carrying a stack on the suspension sheet; a movable body stacked on the cavity frame to receive a voltage to generate reciprocating bending vibration; an insulating frame carrying the stack on the actuating body; a conductive frame is disposed on the insulating frame; wherein a resonant cavity is formed between the actuating body, the cavity frame and the floating piece, and the actuating body is driven to drive the air vent to generate resonance The suspension piece of the gas orifice sheet is reciprocally vibrated to cause the gas to enter the gas flow chamber through the at least one gap and then discharged, thereby realizing the gas transport flow. The health monitoring device of claim 16, wherein the actuating body comprises: a piezoelectric carrier, the carrier is stacked on the cavity frame; and an adjustment resonant plate is stacked on the piezoelectric carrier. And a piezoelectric plate stacked on the adjusting resonance plate to receive the voltage to drive the piezoelectric carrier and the adjusting resonant plate to generate reciprocating bending vibration. The health monitoring device of claim 1, wherein the gas actuator, the particulate actuator, and the purification actuator are respectively a microelectromechanical system gas pump. The health monitoring device of claim 1, further comprising a power supply module for providing stored energy and outputting electrical energy, the electrical energy output to the biometric monitoring module, the gas monitoring module, and the particle monitoring module The purification gas module and the control module are electrically operated. The health monitoring device of claim 19, wherein the power supply module receives the power supplied by an external power supply device by wire transmission to store electrical energy. The health monitoring device of claim 19, wherein the power supply module receives wirelessly transmitted power from an external power supply device to store electrical energy. The health monitoring device of claim 1, wherein the control module comprises a microprocessor, a communicator and a global positioning system component, wherein the communicator comprises an internet of things communication component and a data communication component . The health monitoring device of claim 22, wherein the Internet of Things communication component receives the health data information, the gas monitoring data information, and the particle monitoring data information, and transmits and transmits the health data information, the gas monitoring data Information and information on the particle monitoring data to An external linking device stores the record display. The health monitoring device of claim 23, wherein the Internet of Things communication component is a narrowband IoT device that transmits a transmission signal by using a narrowband radio communication technology. The health monitoring device of claim 23, wherein the external connection device comprises a network relay station and a cloud data processing device, and the Internet of Things communication component transmits the health data information through the network relay station, and the gas monitoring device The data information and the particle monitoring data information are sent to the cloud data processing device to store and store the record display. The health monitoring device of claim 22, wherein the data communication component receives the health data information, the gas monitoring data information, and the particle monitoring data information, and transmits and transmits the health data information, the gas monitoring data information And the particle monitoring data information is sent to an external linking device to store the record display. The health monitoring device of claim 26, wherein the data communication component transmits the health data information, the gas monitoring data information, and the particle monitoring data information through a wired communication transmission, the wired communication transmission interface is a USB, At least one of a mini-USB and a micro-USB. The health monitoring device of claim 26, wherein the data communication component transmits the health data information, the gas monitoring data information, and the particle monitoring data information through wireless communication, and the wireless communication transmission interface is a Wi- At least one of a Fi module, a Bluetooth module, a radio frequency identification module, and a near field communication module. The health monitoring device of claim 26, wherein the external connection device comprises a mobile communication connection device, and the mobile communication connection device receives the data communication component to transmit the health data information, the gas monitoring data information, and the The particle monitoring data information is stored and recorded. The health monitoring device of claim 29, wherein the mobile communication connecting device is at least one of a mobile phone device, a smart watch, and a smart bracelet. The health monitoring device of claim 26, wherein the external connection device comprises a mobile communication connection device, a network relay station and a cloud data processing device, the mobile communication connection device receives the health data information, and the gas monitoring device The data information and the particle monitoring data information are transmitted, and the health data information, the gas monitoring data information and the particle monitoring data information are forwarded to the cloud data processing device through the network relay station to store a record display. The health monitoring device of claim 31, wherein the mobile communication connection device is at least one of a mobile phone device, a notebook computer, and a tablet computer. The health monitoring device of claim 29 or 31, wherein the mobile communication connection device is coupled to a notification processing system, and the mobile communication connection device receives the gas monitoring data information and the particle monitoring data information is transmitted to the alarm information. To transmit the notification message to the notification processing system to initiate an air quality notification mechanism. The health monitoring device of claim 29, wherein the mobile communication device is coupled to a notification processing device, and the mobile communication device receives the gas monitoring data information and the particle monitoring data information is transmitted to the alarm information. And transmitting the notification information to the notification processing device to initiate air quality processing. The health monitoring device of claim 1, further comprising a display, wherein the control module transmits the health data information, the gas monitoring data information, and the particle monitoring data information is displayed by the display. The health monitoring device of claim 1, wherein the photosensor is attached to the skin tissue of the user, and the light source transmitted through the light source and transmitted back to the skin tissue is received by the photoelectric sensor, and The detection signal is generated and converted to the health monitoring processor for conversion to the health data information output. The health monitoring device of claim 36, wherein the health data information is a heart rate data. The health monitoring device of claim 36, wherein the health data information is an electrocardiogram data. The health monitoring device of claim 36, wherein the health data information is blood pressure data. The health monitoring device of claim 1, wherein the pressure sensor is applied to the skin tissue of the user to generate the detection signal for the health monitoring processor to convert to the health data information output. The health data information is a respiratory frequency data. The health monitoring device of claim 1, wherein the impedance sensor is applied to the skin tissue of the user to generate the detection signal for the health monitoring processor to convert to the health data information output. Health data information is a blood glucose data. The health monitoring device according to claim 1, wherein the body has a length of 116 mm to 124 mm. The health monitoring device according to claim 1, wherein the body has a width of 116 mm to 124 mm. The health monitoring device according to claim 1, wherein the height of the body is preferably 20 mm to 22 mm. The health monitoring device of claim 1, wherein the health monitoring device is mountable on a garment. The health monitoring device of claim 1, wherein the health monitoring device can be positioned and positioned on a pair of pants. The health monitoring device according to claim 1, wherein the health monitoring device is combined with a telescopic belt to be worn on a wearer.