TWI709103B - Health monitoring device - Google Patents

Abstract

A health monitoring device comprising a biological characteristic detecting module, a gas detecting module, a particle detecting module, a gas purifying module and a controlling module is provided. The biological characteristic detecting module provides a health data information. The gas detecting module provides a gas detecting data information. The particle detecting module provides a particle detecting data information. The gas purifying module provides a function of purifying the air. By utilizing the controlling module, the health data information, the gas detecting data information and the particle detecting data information are transmitted to an external connecting device for being saved, recorded and displayed.

Description

Health monitoring device

This case is about a health monitoring device, especially a portable device combined with gas monitoring.

As the pace of life accelerates and work pressure increases, more and more people begin to pay attention to fitness. As a result, wearable fitness tracking devices have become very popular. Many people begin to use such equipment for fitness or weight loss. These equipment can record fitness data and facilitate users to track fitness progress. Therefore, it is the main subject of the present invention to provide a device that can monitor health records anytime.

Although modern people can use the above-mentioned portable device for monitoring health records at any time to supplement exercise and fitness to maintain a healthy body, whether there is a good air quality environment to maintain health during exercise is a link that needs attention. Therefore, modern people pay more and more attention to the air quality requirements around their lives, especially such as carbon monoxide, carbon dioxide, volatile organic compounds (Volatile Organic Compound, VOC), PM 2.5, nitric oxide, sulfur monoxide and other gases, even gases The particles contained in it will be exposed in the environment to affect human health, and even endanger life seriously. Therefore, in order to maintain health and exercise, it is also necessary to understand the quality of the surrounding air, to stay away or take preventive measures, to achieve a goal that is truly suitable for healthy exercise, and how to monitor the surrounding air quality is a topic of current importance.

How to confirm the quality of the air, it is feasible to use a gas sensor to monitor the surrounding environment gas, if it can provide real-time monitoring information to warn people in the environment, so that they can immediately prevent or escape, and avoid exposure to the environment Exposure to the gas in the medium can cause human health effects and injuries. Using gas sensors to monitor the surrounding environment can be said to be a very good application; and portable devices are mobile devices that modern people will carry when they go out. Therefore, this case will monitor biometrics. The module combines a gas monitoring module, a particle monitoring module, and a purified gas module to be embedded in a portable device, especially when the current development trend of portable devices is light, thin, and high performance. How to provide a solution for making the health monitoring device thinner and assemble in a portable device for monitoring health records, monitoring the surrounding air quality and providing clean air at any time is an important issue developed in this case.

The main purpose of this case is to provide a health monitoring device that uses biometric monitoring modules to provide health data information, and combines gas monitoring modules and particulate monitoring modules to provide monitoring data information, and combines gas purification modules to provide air purification functions , And send the information to external connected devices for storage, recording and display, which can provide information in real time as a warning to inform people in the environment, so that it can prevent or escape in real time, and avoid exposure to gas in the environment to cause the human body Health impact and injury, to achieve the benefits of monitoring health records, monitoring the surrounding air quality and providing clean air at any time.

A broad implementation aspect of this case is a health monitoring device, including: a biometric monitoring module, including a photoelectric sensor, a pressure sensor, an impedance sensor, at least one light-emitting element, a blood pressure measuring device, and a health monitoring process And a substrate, wherein the blood pressure measuring device includes a gas-collecting actuator, an elastic medium and an array pressure sensor, the photoelectric sensor, the pressure sensor, and the impedance sensor are attached to the skin tissue of the user, and the The gas-collecting actuator of the blood pressure measuring device transmits gas to inflate the elastic medium to make the array pressure sensor elastically displace and resist the skin tissue of the user to generate and provide a detection signal to the health Monitoring processor, the health monitoring processor converts the detection signal into health data information and outputs; a gas monitoring module includes a gas sensor and a gas actuator, the gas actuator controls the gas to be introduced into the gas monitoring The inside of the module is monitored by the gas sensor to generate a gas monitoring data information; a particle monitoring module includes a particle actuator and a particle sensor, the particle actuator controls the gas to be introduced into the particle monitoring module Inside, 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 gas purification module includes a purification actuator and a purification unit, the purification actuator controls The gas is introduced into the purified gas module to enable the purification unit to purify the gas; a control module controls the activation of the biometric monitoring module, the gas monitoring module, the particle monitoring module and the purified gas module, And the information of the health data, the gas monitoring data and the particle monitoring data are transmitted and output.

Some typical embodiments embodying the features and advantages of this case will be described in detail in the following description. It should be understood that this case can have various changes in different aspects, all of which do not depart from the scope of the case, and the descriptions and illustrations therein are essentially for illustrative purposes, rather than limiting the case.

Please refer to Figure 1A to Figure 2. This case provides a health monitoring device 10, which mainly includes a biometric monitoring module 1, a gas monitoring module 2, a particle monitoring module 3, a purified gas module 4 and A control module 5, a biological feature monitoring module 1, a gas monitoring module 2, a particle monitoring module 3, a purified gas module 4, and a control module 5 can be placed in a body 7 to form a thin As a portable device, the appearance structure design needs to have the convenience of being easy to handle and not easy to drop and easy to carry. The appearance size of the main body 7 needs a thin design. Therefore, the appearance size design of the main body 7 in this case has a length L and a Width W and a height H, and according to the current biometric monitoring module 1, a gas monitoring module 2, a particle monitoring module 3, a purified gas module 4 and a control module 5 are arranged in the body 7 best The configuration design is to configure the length L of the body 7 to be 110~130 mm, 120 mm is the best, the width W is 110~130 mm, 120 mm is the best, and the height H is 15~25 mm. , 21 mm is the best. In addition, the body 7 has a chamber 71 inside, 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, the second air inlet The air inlet 73, the air outlet 74 and the monitoring area window 75 communicate with the chamber 71 respectively.

Please refer to Fig. 1F, Fig. 2 and Fig. 3, the above-mentioned biometric monitoring module 1 is disposed in the cavity 71 of the main body 7, and includes a photoelectric sensor 11, a pressure sensor 12, an impedance sensor 13, At least one light emitting element 14, blood pressure measuring device 15, a health monitoring processor 16 and a substrate 17. The photoelectric sensor 11, the pressure sensor 12, the impedance sensor 13, the light-emitting element 14, the blood pressure measuring device 15, and the health monitoring processor 16 are packaged and fixed on the substrate 17, and the substrate 17 is placed and positioned at the position of the window 75 of the monitoring area, and the photoelectric sensor 11 After fitting to the skin tissue of the user, the light 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 a detection signal is generated and provided to the health monitoring processor 16 to be converted into health data information output To the control module 5, 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 and an electrocardiogram data; after the pressure sensor is attached to the skin tissue of the user , The detection signal can be generated and supplied to the health monitoring processor 16 to be converted into health data information and output to the control module 5. The control module 5 transmits and outputs the health data information of the biometric monitoring module 1. The health data information is A breathing frequency data; after the impedance sensor 13 is attached to the skin tissue of the user, it can generate a detection signal and provide it to the health monitoring processor 16 to convert it into health data and output it to the control module 5. The control module 5 uses the biometric monitoring module The health data information of group 1 is transmitted and output, and this health data information is blood glucose data.

Please also refer to FIGS. 4A to 4D. The blood pressure measuring device 15 includes a gas collecting actuator 151, an elastic medium 152, an array pressure sensor 153, a base 154, a cavity plate 155 and A valve piece 156. The base 154 is built on the base plate 17 and is recessed with a receiving groove 154a, a lower gas collecting chamber 154b, and a lower pressure relief chamber 154c. There is a gas collecting through hole 154d between the receiving groove 154a and the lower gas collecting chamber 154b for communicating the receiving groove 154a and the lower gas collecting chamber 154b with each other. The lower gas collection chamber 154b and the lower pressure relief chamber 154c are spaced apart from each other on the same side of the base 154, and a communication channel 154e is provided between the lower gas collection chamber 154b and the lower pressure relief chamber 154c for The lower gas collection chamber 154b and the lower pressure relief chamber 154c communicate with each other. The lower pressure relief chamber 154c has a base protrusion 154f, and the center of the base protrusion 154f is provided with a pressure relief through hole 154g, which communicates with the lower pressure relief chamber 154c, and the elastic medium 152 is accommodated in the accommodation groove 154a In this case, the array pressure sensor 153 abuts against the elastic medium 152 to close the accommodating groove 154a, and the elastic medium 152 is in communication with the air collecting through hole 154d to be inflated and elastically displaced. The cavity plate 155 is placed on the base 154, and the surface of the corresponding base 154 is provided with a lower air collecting chamber 154b corresponding to each other, covering the upper air collecting chamber 155a and a lower pressure relief chamber 154c. Corresponding to the upper pressure relief chamber 155b of the cover, a cavity plate convex portion 155c is provided in the upper gas collection chamber 155a. In addition, the cavity plate 155 is recessed with a communication chamber 155d on the surface opposite to the upper gas collection chamber 155a and the upper pressure relief chamber 155b, and the gas collection actuator 151 is placed on the cavity plate 155 to cover the communication chamber 155d , And the communication chamber 155d penetrates at least one communication hole 155e, which is respectively communicated with the upper gas collection chamber 155a and the upper pressure relief chamber 155b. The valve plate 156 is disposed between the base 154 and the cavity plate 155, and the valve plate 156 abuts against the base protrusion 154f to close the pressure relief through hole 154g, and the valve plate 156 abuts the cavity plate protrusion 155c with a valve hole 156a. , And the valve hole 156a is closed due to abutting against the cavity plate protrusion 155c. The aforementioned elastic medium 152 may be an airbag structure.

Please also refer to FIGS. 5A to 5B. The above-mentioned gas collecting actuator 151 is a micropump 20. The micropump 20 consists of an inlet plate 201, a resonant sheet 202, a piezoelectric actuator 203, A first insulating sheet 204, a conductive sheet 205 and a second insulating sheet 206 are stacked in sequence. The inlet plate 201 has at least one inlet hole 201a, at least one busbar groove 201b, and a bus chamber 201c. The inlet hole 201a is for introducing gas. The inlet hole 201a corresponds to the busbar groove 201b, and the busbar groove 201b Confluence to the confluence chamber 201c, so that the gas introduced from the inlet 201a can be converged into the confluence chamber 201c. In this embodiment, the numbers of inlet holes 201a and busbar grooves 201b are the same, and the numbers of inlet holes 201a and busbar grooves 201b are 4, which are not limited to this. The 4 inlet holes 201a respectively penetrate through There are 4 busbar grooves 201b, and the 4 busbar grooves 201b merge to the busbar chamber 201c.

Please refer to Figures 5A, 5B, and 6A. The above-mentioned resonant sheet 202 is assembled on the inlet plate 201 by bonding, and the resonant sheet 202 has a hollow hole 202a, a movable portion 202b, and A fixed part 202c, the hollow hole 202a is located at the center of the resonance plate 202 and corresponds to the confluence chamber 201c of the inlet plate 201, and the movable part 202b is arranged around the hollow hole 202a and is opposite to the confluence chamber 201c, The fixing portion 202c is disposed on the outer peripheral edge portion of the resonant sheet 202 and adhered to the inlet plate 201.

Please continue to refer to FIGS. 5A, 5B and 6A. The piezoelectric actuator 203 described above includes a suspension plate 203a, an outer frame 203b, at least one bracket 203c, a piezoelectric element 203d, and at least one gap. 203e and a convex portion 203f. Among them, the suspension board 203a is a square shape. The reason why the suspension board 203a adopts a square shape is that compared with the design of the circular suspension board, the structure of the square suspension board 203a has obvious advantages in power saving, because it operates at the resonance frequency. For capacitive loads, the power consumption will increase as the frequency rises, and because the resonance frequency of the side-length square suspension plate 203a is significantly lower than that of the circular suspension plate, its relative power consumption is also significantly lower, which is the case used in this case The suspension board 203a of square design has the benefit of power saving; the outer frame 203b is arranged around the outer side of the suspension board 203a; at least one bracket 203c is connected between the suspension board 203a and the outer frame 203b to provide elastic support for the suspension board 203a Supporting force; and a piezoelectric element 203d has a side length that is less than or equal to a side length of the suspension plate 203a, and the piezoelectric element 203d is attached to a surface of the suspension plate 203a to be applied with a voltage to drive the suspension The plate 203a flexes and vibrates; and the suspension plate 203a, the outer frame 203b and the bracket 203c form at least a gap 203e for gas to pass through; the convex part 203f is arranged on the surface of the suspension plate 203a to which the piezoelectric element 203d is attached. On the other surface, the convex portion 203f in this embodiment can also be integrally formed through an etching process to form a convex structure on the opposite surface of the suspension plate 203a to which the piezoelectric element 203d is attached. .

Please continue to refer to Figures 5A, 5B and 6A, the above-mentioned inlet plate 201, resonance sheet 202, piezoelectric actuator 203, first insulating sheet 204, conductive sheet 205 and second insulating sheet 206 Stacked in sequence, where a cavity space 207 needs to be formed between the suspension plate 203a and the resonant plate 202. The cavity space 207 can be used to fill a gap between the resonant plate 202 and the outer frame 203b of the piezoelectric actuator 203 The material is formed, such as conductive glue, but not limited to it, so that a certain depth can be maintained between the resonance sheet 202 and the suspension plate 203a to form a chamber space 207, which can guide the gas to flow more quickly, and because of the suspension plate Keep a proper distance between 203a and the resonant sheet 202 to reduce the contact interference with each other, and promote the reduction of noise generation. Of course, in the embodiment, the height of the outer frame 203b of the piezoelectric actuator 203 can also be increased to reduce the resonance sheet 202 and pressure. The thickness of the conductive adhesive filled in the gap between the outer frame 203b of the electric actuator 203 can prevent the conductive adhesive from expanding and contracting with the hot pressing temperature and cooling temperature, which will affect the actual spacing of the cavity space 207 after molding, and reduce The hot pressing temperature and cooling temperature of the conductive adhesive have an indirect influence on the overall assembly structure of the micropump 20, but it is not limited to this. In addition, the chamber space 207 will affect the transmission effect of the micropump. Therefore, maintaining a fixed chamber space 207 is very important for the micropump to provide stable transmission efficiency.

Therefore, as shown in Fig. 6B, in other embodiments of the piezoelectric actuator 203, the suspension plate 203a can be formed by stamping to extend a distance outward, and its outward extension distance can be formed on the suspension plate 203a and the outside. At least one bracket 203c between the frames 203b is adjusted so that the surface of the convex portion 203f on the suspension plate 203a and the surface of the outer frame 203b form a non-coplanar surface, and a small amount is applied to the assembled surface of the outer frame 203b The filling material, such as conductive glue, is used to heat and press the piezoelectric actuator 203 to the fixing portion 202c of the resonant sheet 202, so that the piezoelectric actuator 203 can be assembled and combined with the resonant sheet 202 so as to directly penetrate The suspension plate 203a of the piezoelectric actuator 203 is improved by stamping and forming to form a cavity space 207. The required cavity space 207 can be adjusted by adjusting the stamping distance of the suspension plate 203a of the piezoelectric actuator 203. When completed, the structural design of the adjustment chamber space 207 is effectively simplified, and the advantages of simplifying the manufacturing process and shortening the manufacturing time are also achieved. In addition, the first insulating sheet 204, the conductive sheet 205, and the second insulating sheet 206 are all frame-shaped thin sheets, which are sequentially stacked on the piezoelectric actuator 203 to form the overall structure of the micropump 20.

In order to understand the output operation mode of the gas transmission provided by the above-mentioned micropump 20, please continue to refer to Figs. 6C to 6E. Please refer to Figure 6C first, the piezoelectric element 203d of the piezoelectric actuator 203 is deformed after the driving voltage is applied to drive the suspension plate 203a to move downwards. At this time, the volume of the chamber space 207 is increased, forming a shape in the chamber space 207 With the negative pressure, the gas in the confluence chamber 201c is drawn into the chamber space 207, and at the same time, the resonance plate 202 is synchronously displaced downward under the influence of the resonance principle, which in turn increases the volume of the confluence chamber 201c, and due to the confluence chamber The gas in 201c enters the chamber space 207, resulting in a negative pressure in the confluence chamber 201c, and the gas is sucked into the confluence chamber 201c through the inlet 201a and the bus groove 201b; please refer to section 6D again In the figure, the piezoelectric element 203d drives the levitation plate 203a to move upward, compressing the chamber space 207. Similarly, the resonant sheet 202 is displaced upward due to resonance with the levitation plate 203a, forcing the gas in the chamber space 207 to simultaneously push down through the gap. 203e is transmitted downward to achieve the effect of gas transmission; finally, please refer to Figure 6E. When the suspension plate 203a is driven downward, the resonance sheet 202 is also driven and displaced downward at the same time. At this time, the resonance sheet 202 will compress The gas in the chamber space 207 moves to the gap 203e and increases the volume in the confluence chamber 201c, so that the gas can continuously pass through the inlet 201a and the confluence groove 201b to converge in the confluence chamber 201c. By continuously repeating the steps of providing gas transmission by the micropump 20 shown in Figures 6C to 6E above, the micropump 20 can continuously enter the gas from the inlet 201a into the flow channel formed by the inlet plate 201 and the resonance plate 202 A pressure gradient is generated, and then it is transmitted downward from the gap 203e, so that the gas flows at a high speed to achieve the actuation operation of the micropump 20 to transmit the gas output.

Please continue to refer to Fig. 6A. The inlet plate 201, resonance sheet 202, piezoelectric actuator 203, first insulating sheet 204, conductive sheet 205, and second insulating sheet 206 of the micro pump 20 can all pass through the micro-electromechanical surface The micro-processing technology process reduces the size of the micro-pump 20 to form a micro-electromechanical system micro-pump 20.

From the above description, the specific implementation of the blood pressure measuring device 15 in this case, as shown in Figures 4B to 4C, when the gas collection actuator 151 is controlled and driven to perform gas transmission, the gas is driven by the gas collection actuator 151 The external introduction is concentrated in the communicating chamber 155d, and then introduced from the communicating chamber 155d to the upper gas collecting chamber 155a and the upper pressure relief chamber 155b through the communicating hole 155e to push the valve plate 156 away from the cavity plate convex portion 155c. The valve plate 156 abuts against the base protrusion 154f to close the pressure relief through hole 154g. At the same time, the gas in the upper pressure relief chamber 155b also flows into the upper gas collecting chamber 155a through the communication channel 154e, so that the gas can pass through the valve of the valve plate 156 The hole 156a circulates into the air collecting chamber 154b under the base 154, and then is connected through the air collecting through hole 154d and filled in the elastic medium 152. The elastic medium 152 is inflated and swelled to elastically displace the array pressure sensor 153, such as the first As shown in FIG. 16, the array pressure sensor 153 is pressed against the skin tissue 501 of the user to compress the artery 502 between the skin tissue 501 and the bone 503 of the user. The array pressure sensor 153 measures the blood pressure data of the target artery 502 by pressing against the artery 502 of the user using applanation scan to generate and provide a detection signal to the health monitoring processor 16 to convert it into a health data information output to the control Module 5. The control module 5 transmits and outputs the health data information of the biometric monitoring module 1, and the health data information is blood pressure data.

Of course, when the blood pressure measuring device 15 in this case is stopped, as shown in Fig. 4D, the gas collecting actuator 151 stops the operation of transmitting gas. At this time, the gas pressure in the elastic medium 152 is greater than the gas pressure at the communicating chamber 155d. The gas in the elastic medium 152 pushes the valve plate 156 to displace, causing it to abut the cavity plate convex portion 155c, thereby closing the valve hole 156a. At the same time, the valve plate 156 will leave the convex portion 154f of the abutting base to open the pressure relief through hole 154g, and the gas in the elastic medium 152 will be led out into the pressure relief through hole 154g through the communication channel 154e, and then discharged to the blood pressure measuring device. 15 outside, and the array pressure sensor 153 retracts into the accommodating groove 154a to complete the pressure relief operation of the elastic medium 152.

Please refer to FIG. 2 and FIG. 7A to FIG. 7E again. The gas monitoring module 2 described above includes a compartment body 21, a carrier board 22, a gas sensor 23 and a gas actuator 24. The compartment body 21 is disposed at a position below the first air inlet 72 of the body 7, and the interior is divided by a partition 211 to form a first compartment 212 and a second compartment 213. The partition 211 has a gap 214 for the first compartment 212 and the second compartment 213 to communicate with each other, and the first compartment 212 has an opening 215, and the second compartment 213 has an air outlet 216. The bottom of the compartment main body 21 is provided with a containing groove 217, and the containing groove 217 allows the carrier board 22 to penetrate and be positioned in it to close the bottom of the compartment main body 21. The carrier board 22 is assembled under the compartment body 21 and encapsulated and electrically connected to the gas sensor 23, and the gas sensor 23 extends through the opening 215 and is disposed in the first compartment 212 for detecting the gas in the first compartment 212 Furthermore, the carrier board 22 is provided with a vent 221, so when the carrier board 22 is assembled under the compartment body 21, the vent 221 will correspond to the vent 216 of the second compartment 213. 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 it is actuated can be blocked by the diaphragm 211, and not As for influencing the detection result of the gas sensor 23, and the gas actuator 24 closes the bottom of the second compartment 213 and is controlled and actuated to generate a guiding airflow, so that the gas is introduced from the first air inlet 72 of the body 7 through The gas sensor 23 is monitored, and then enters the second compartment 213 through the notch 214, passes through the air outlet 216, and is discharged out of the gas monitoring module 2 through the air vent 221 of the carrier 22, and is discharged from the air outlet 74 of the body 7.

The above is a description of the characteristics of the gas monitoring module 2, and the gas actuator 24 is used as a gas transmission and can be a micro pump 20 structure. The structure and operation mode of the micropump 20 are the same as those described above, and will not be repeated here.

Therefore, please continue to refer to Figure 7D and Figure 7E. In order to facilitate the description of the gas flow direction of the gas monitoring module 2, the body 7 in the legend is hereby made transparent for description. When the gas monitoring module 2 is embedded in the cavity 71 of the main body 7, the first air inlet 72 of the main body 7 corresponds to the first compartment 212 of the compartment main body 21 and is not different from the first compartment 212 located in the first compartment 212. The inner gas sensor 23 directly corresponds, that is, the first air inlet 72 is not directly above the gas sensor 23, and the two are misaligned with each other. In this way, through the control action of the gas actuator 24, a negative pressure is formed in the second compartment 213, and the external air outside the body 7 can be drawn and introduced into the first compartment 212, so that the first The gas sensor 23 in the compartment 212 monitors the gas flowing over its surface to detect the quality of the gas introduced from the outside of the body 7. When the gas actuator 24 continues to operate, the monitored gas will be introduced into the second compartment 213 through the gap 214 on the spacer 211, and finally discharged into the compartment through the air outlet 216 and the vent 221 of the carrier 22 Outside of the main body 21, a one-way gas-conducting monitoring (in the direction of the air flow path B shown in the 7D icon) is formed.

The aforementioned gas sensor 23 includes at least one or a combination of an oxygen sensor, a carbon monoxide sensor, and a carbon dioxide sensor; or, the aforementioned gas sensor 23 includes one or a combination of a temperature sensor and a humidity sensor; or The above-mentioned gas sensor 23 includes a volatile organic compound sensor; or, the above-mentioned gas sensor 23 includes one or a combination of a bacteria sensor, a virus sensor, and a microorganism sensor.

It can be seen from the above description that the health monitoring device 10 provided in this case uses the gas monitoring module 2 to monitor the air quality around the user at any time, and uses the gas actuator 24 to quickly and stably introduce gas into the gas monitoring module 2 Not only improves the efficiency of the gas sensor 23, but also separates the gas actuator 24 and the gas sensor 23 from each other through the design of the first compartment 212 and the second compartment 213 of the compartment body 21, so that the gas sensor 23 monitors It can block and reduce the influence of the heat source of the gas actuator 24, thereby avoiding affecting the monitoring accuracy of the gas sensor 23. In addition, the gas sensor 23 can also be prevented from being affected by other components in the device. Therefore, the gas actuator 24 controls the gas to be introduced into the gas monitoring module 2 and monitored by the gas sensor 23. The detected gas monitoring data information is transmitted to the control module 5, and the control module 5 transfers the gas to the gas monitoring module 2 The gas monitoring data information is transmitted and output, so that the purpose of the health monitoring device 10 can be detected at any time and anywhere, and the monitoring effect can be fast and accurate.

Please refer to Figure 8 again. The health monitoring device 10 provided in this case further has a particle monitoring module 3 for monitoring particles in the gas. The particle monitoring module 3 is disposed in the chamber 71 of the body 7 and includes a vent The inlet 31, a ventilation outlet 32, a particle monitoring base 33, a carrying partition 34, a laser transmitter 35, a particle actuator 36 and a particle sensor 37. The ventilation inlet 31 corresponds to the second air inlet 73 of the main body 7, and the ventilation outlet 32 corresponds to the air outlet 74 of the main body 7, so that gas enters the particle monitoring module 3 through the ventilation inlet 31 and is discharged from the ventilation outlet 32. The particle monitoring base 33 and the carrying partition 34 are arranged inside the particle monitoring module 3, so that the internal space of the particle monitoring module 3 defines a first compartment 38 and a second compartment 39 by the carrying partition 34, and carries The partition 34 has a communication port 341 to connect the first compartment 38 and the second compartment 39, wherein the second compartment 39 is in communication with the ventilation outlet 32. In addition, the particle monitoring base 33 is adjacent to the carrying partition 34 and is accommodated in the first compartment 38, and the particle monitoring base 33 has a receiving groove 331, a monitoring channel 332, a beam channel 333 and a Storage room 334. The receiving groove 331 corresponds vertically to the ventilation inlet 31, the monitoring channel 332 is connected between the receiving groove 331 and the communication opening 341 of the carrying partition 34, the receiving chamber 334 is arranged on the side of the monitoring channel 332, and the beam channel 333 is connected Between the accommodating chamber 334 and the monitoring channel 332, and the beam channel 333 crosses the monitoring channel 332 vertically. In this way, the inside of the particle monitoring module 3 is composed of the ventilation inlet 31, the receiving groove 331, the monitoring channel 332, the communication port 341, and the ventilation outlet 32 to form a gas channel for unidirectional gas transmission, that is, the path direction shown by the arrow in FIG. In addition, the laser transmitter 35 is disposed in the accommodating chamber 334, the particle actuator 36 is structured in the receiving groove 331 at one end of the monitoring channel 332, and the particle sensor 37 is electrically connected to the carrying partition 34 and located in the monitoring channel The other end of 332.

The above is a description of the characteristics of the particle monitoring module 3, and the particle actuator 36, as a gas transmission, can be a micropump 20 structure. The structure and operation of the micropump 20 are the same as those described above, and will not be repeated here.

It can be seen from the above that 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 transmitter 35 irradiates into the beam channel 333, and the beam channel 333 guides the laser beam to irradiate the monitoring channel In 332, the suspended particles in the gas in the monitoring channel 332 are irradiated. After the suspended particles are irradiated by the light beam, multiple light spots will be generated and projected on the surface of the particle sensor 37, so that the particle sensor 37 can sense the particle size and concentration of the suspended particles. , And transmit the detected particle monitoring data information to the control module 5, so that the control module 5 transmits and outputs the particle monitoring data information of the particle monitoring module 3.

In addition, the monitoring channel 332 of the particle monitoring module 3 in this case is vertically corresponding to the ventilation inlet 31, so that the monitoring channel 332 can directly conduct air without affecting the airflow introduction, and the particle actuator 36 is structured in the receiving groove 331, and can be sucked and combined. The external air of the ventilation inlet 31 is guided, so that the gas can enter the monitoring channel 332 more quickly for the particle sensor 37 to detect, so as to improve the efficiency of the particle sensor 37. The particle sensor in this embodiment is a PM2.5 sensor.

Please refer to Fig. 3 and Figs. 8A to 8E again. The health monitoring device 10 provided in this case further has a gas purification module 4 for gas purification. The purifying gas module 4 is disposed in the chamber 71 of the main body 7 and includes an air guiding inlet 41, an air guiding outlet 42, an air guiding channel 43, a purifying actuator 44 and a purifying unit 45. The air guide inlet 41 corresponds to the second air inlet 73 of the main body 7, the air guide outlet 42 corresponds to the air outlet 74 of the main body 7, and the air guide channel 43 is arranged between the air guide inlet 41 and the air outlet 42, and is clean The actuator 44 is disposed in the air guiding channel 43 to control the gas to be introduced into the air guiding channel 43, and the purification unit 45 is located in the air guiding channel 43.

The above-mentioned purification unit 45 may be a filter unit, as shown in Figure 8A, including a plurality of filter meshes 45a. In this embodiment, two filter meshes 45a are respectively arranged in the air guide channel 43 and kept at a distance so that The gas is controlled by the purifying actuator 44 to be introduced into the air guide passage 43. The two filters 45a absorb the chemical smoke, bacteria, dust particles and pollen contained in the gas to achieve the effect of purifying the gas. The filter 45a can be electrostatic Filter, activated carbon filter or high efficiency filter (HEPA).

The above-mentioned purification unit 45 can be a photocatalyst unit, as shown in Figure 8B, including a photocatalyst 45b and an ultraviolet lamp 45c, which are respectively arranged in the air guide channel 43 and maintained at a distance so that the gas can be controlled by the purification actuator 44 Introduced into the air guide channel 43, and the photocatalyst 45b is irradiated by the ultraviolet lamp 45c to convert light energy into chemical energy for decomposing harmful gases in the gas and sterilizing the gas to achieve the effect of purifying the gas. Of course, when the purification unit 45 is a photocatalyst unit, it can be arranged in the air guiding channel 43 with a filter 45a to enhance the effect of purifying the gas. The filter 45a can be an electrostatic filter, an activated carbon filter or a high-efficiency filter (HEPA). ).

The above-mentioned purification unit 45 can be a kind of optical plasma unit, as shown in Fig. 8C, including a nano-light tube 45d, which is arranged in the air guide channel 43 so that the gas is controlled to be introduced into the air guide channel 43 through the purification actuator 44, Through the 45d irradiation of the nanotube, the oxygen molecules and water molecules in the gas can be decomposed into a highly oxidizing light plasma that can destroy organic molecules. 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, when the purifying unit 45 is a light plasma unit, the filter 45a can also be installed in the air guiding channel 43 to enhance the effect of purifying the gas. 45a can be electrostatic filter, activated carbon filter or high efficiency filter (HEPA).

The aforementioned purification unit 45 may be a negative ion unit, as shown in Figure 8D, including at least one electrode wire 45e, at least one dust collecting plate 45f and a booster power supply 45g, each electrode wire 45e, each dust collecting plate 45f is arranged in the air guide channel 43, and the booster power supply 45g is arranged in the purification gas module 4 to provide high-voltage discharge of each electrode wire 45e, and each dust collecting plate 45f is negatively charged to allow the gas to pass through the purification actuator 44 is introduced into the air guide channel 43, through each electrode wire 45e high voltage discharge, so that the particles contained in the gas can be positively charged, and further attached to each negatively charged dust collecting plate 45f, so as to purify the gas. Effect, of course, when the purification unit 45 is a negative ion unit, it can also be combined with a filter 45a in the air duct 43 to enhance the effect of purifying the gas. The filter 45a can be an electrostatic filter, an activated carbon filter or a high-efficiency filter ( HEPA).

The aforementioned purification unit 45 may be a plasma ion unit, as shown in Figure 8E, including an electric field upper guard 45h, an adsorption filter 45i, a high-voltage discharge electrode 45j, an electric field lower guard 45k, and a booster The power supply 45g, in which the electric field upper protective net 45h, the adsorption filter 45i, the high-voltage discharge electrode 45j and the electric field lower protective net 45k are set in the air channel 43, and the adsorption filter 45i and the high-voltage discharge electrode 45j are clamped on the electric field upper protective Between the net 45h and the protective net 45k under the electric field, and the booster power supply 45g is arranged in the purified gas module 4 to provide a high-voltage discharge electrode 45j high-voltage discharge to generate a high-voltage plasma column with plasma ions, so that the gas can be purified through The actuator 44 is controlled to be introduced into the air guide channel 43, through plasma ions to ionize oxygen molecules and water molecules in the gas to generate cations (H ⁺ ) and anions (O ^2- ), and water molecules are attached to the surrounding ions. After attaching to the surface of viruses and bacteria, under the action of a chemical reaction, it will be converted into strong oxidizing reactive oxygen species (hydroxyl group, OH group), thereby taking away the hydrogen from the surface proteins of viruses and bacteria and decomposing them (oxidative decomposition) , In order to achieve the effect of purifying gas, of course, when the purifying unit 45 is a negative ion unit, it can also be equipped with a filter 45a in the air channel 43 to enhance the effect of purifying the gas. The filter 45a can be an electrostatic filter or an activated carbon filter. Net or high efficiency filter (HEPA).

The above is a description of the characteristics of the gas purification module 4, and the purification actuator 44 as a gas transmission can be a micropump 20 structure. The structure and operation of the micropump 20 are the same as those described above, and will not be repeated here.

Of course, in this case, the gas gathering actuator 151, the gas actuator 24, the particle actuator 36, and the purification actuator 44 can be in addition to the above-mentioned micro pump 20 structure, and they can also be a blower box micro pump 30 respectively. The structure and operation method of the gas transmission. Please refer to Figure 10 and Figures 11A to 11C. The blower box micropump 30 includes an air jet orifice sheet 301, a cavity frame 302, an actuating body 303, an insulating frame 304, and a conductive frame 305 which are sequentially stacked; The perforated piece 301 includes a plurality of connecting pieces 301a, a suspension piece 301b and a hollow hole 301c. The suspension piece 301b can be bent and vibrated. The plural connecting pieces 301a are adjacent to the periphery of the suspension piece 301b. In this embodiment, the connecting piece 301a is The number is 4, which are respectively adjacent to the 4 corners of the suspension piece 301b, but not limited to this; the hollow hole 301c is formed at the center of the suspension piece 301b; the cavity frame 302 is carried and stacked on the suspension piece 301b; the actuating body The 303 carrier is stacked on the cavity frame 302, and includes a piezoelectric carrier 303a, an adjusting resonance plate 303b, and a piezoelectric plate 303c, wherein the piezoelectric carrier 303a is stacked on the cavity frame 302, The adjustment resonant plate 303b is loaded and stacked on the piezoelectric carrier 303a, and the piezoelectric plate 303c is loaded and stacked on the adjustment resonant plate 303b for deformation after voltage is applied to drive the piezoelectric carrier 303a and the adjustment resonant plate 303b to perform reciprocating Bending vibration; the insulating frame 304 is carried and stacked on the piezoelectric carrier 303a of the actuating body 303, and the conductive frame 305 is carried and stacked on the insulating frame 304, wherein the actuating body 303, the cavity frame 302 and the suspension sheet A resonance cavity 306 is formed between 301b.

Please refer to FIGS. 11A to 11C again, which are schematic diagrams of the operation of the blower box micropump 30 in this case. Please refer to Figure 10 and Figure 11A first, the blower box micropump 30 is fixedly arranged through a plurality of connecting pieces 301a, and the bottom of the jet orifice plate 301 forms an air flow chamber 307; please refer to Figure 11B again, when the voltage is applied When the piezoelectric plate 303c of the moving body 303, the piezoelectric plate 303c begins to deform due to the piezoelectric effect and synchronously drives the adjustment resonant plate 303b and the piezoelectric carrier plate 303a. At this time, the jet hole plate 301 will resonate due to Helmholtz ( Helmholtz resonance principle is driven together, so that the actuating body 303 moves upward. Due to the upward displacement of the actuating body 303, the volume of the air flow chamber 307 on the bottom surface of the air jet orifice sheet 301 increases, and its internal air pressure forms a negative pressure. The gas outside the blower box micropump 30 will be caused by the air jet hole sheet 301 due to the pressure gradient. The gap of the connecting piece 301a enters the air flow chamber 307 and collects the pressure; finally, referring to Figure 11C, the gas continuously enters the air flow chamber 307, so that the air pressure in the air flow chamber 307 forms a positive pressure. At this time, the actuation The body 303 is driven by voltage to move downwards, compresses the volume of the airflow chamber 307, and pushes the gas in the airflow chamber 307, so that the gas enters the blower box micropump 30 and then pushes and discharges to realize the gas transmission and flow.

Of course, the blower box micropump 30 in this case can also be a microelectromechanical system gas pump manufactured by a microelectromechanical manufacturing process. Among them, the jet orifice plate 301, the cavity frame 302, the actuator body 303, the insulating frame 304 and The conductive frame 305 can be made by surface micromachining technology to reduce the volume of the blower box micropump 30.

Please also refer to Figures 3 and 12. The health monitoring device 10 in this case further includes a power supply module 6 for storing and outputting electrical energy. The power supply module 6 can be a battery module that provides electrical energy output for biological characteristics. 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 the power supplied by an external power supply device 8 It can be stored, that is, it can be used as a wired transmission interface of at least one of a USB, a mini-USB, and a micro-USB to connect the external power supply device 8 and the power supply module 6 to store and output electrical energy, or the power supply module The group 6 receives and stores the electric energy supplied by an external power supply device 8 through wireless transmission, that is, it can use the wireless transmission interface as a wireless charging component to connect the external power supply device 8 and the power supply module 6 to store and output electric energy, and The external power supply device 8 can be at least one of a charger and a mobile power supply.

Please refer to FIGS. 3 and 12 again, the control module 5 includes a microprocessor 51, a communicator 52, and a global positioning system component 53. The communicator 52 includes an IoT communication element 52a and a data communication element 52b. The IoT communication element 52a receives the health data information of the biometric monitoring module 1 and the gas monitoring data information of the gas monitoring module 2 and the particulate monitoring module The 3 particles monitor data information, and transmit the information to an external connection device for storage, recording, and display, and the IoT communication component 52a is a narrowband IoT device that transmits and sends signals using narrowband radio communication technology. The external connection device includes a network relay station 9b and a cloud data processing device 9c. The IoT communication component 52a transmits the information to the cloud data processing device 9c through the network relay station 9b for storage, recording and display; and the data communication component 52b Receives the health data information of the biometric 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 transmits the information to the external connection device for storage, recording and Display, and the data communication component 52b transmits the information through a wired communication transmission interface, 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 is wireless The communication transmission interface transmits the 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 data communication components 52b transmits and sends the information to an external connection device. The external connection device includes a mobile communication connection device 9a. The mobile communication connection device 9a receives the information transmitted by the data communication component 52b and stores, records and displays the information. The communication link device 9a can be at least one of a mobile phone device, a smart watch, or a smart bracelet; or, the data communication element 52b transmits and sends the information to an external link device, which includes a mobile communication link device 9a, A network relay station 9b and a cloud data processing device 9c. The mobile communication link device 9a receives the information, and then sends the information to the cloud data processing device 9c through the network relay station 9b for storage, recording and display, and this mobile communication The connecting device 9a can be at least one of a mobile phone device, a notebook computer, and a tablet computer.

Furthermore, the aforementioned mobile communication connection device 9a can be connected to a notification processing system 9d. After the mobile communication link 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, it can generate alarm information, and transmit the alarm information to the notification processing system 9d to activate the air Quality notification mechanism. The air quality notification mechanism is to notify users to wear masks for protective notifications, and the air quality notification mechanism is to provide users with real-time air quality maps and remind users to avoid notification measures.

The aforementioned mobile communication connection device 9a can also be connected to a notification processing device 9e. After the mobile communication link 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, it can generate alarm information, and transmit the alarm information to the notification processing device 9e to start Air quality treatment. The notification processing device 9e can be at least one smart home appliance, and the smart home appliance can be an air purifier, a dehumidifier, an exhaust fan, an electric door, an electric window, an automatic cleaning robot, an air conditioner, etc., but not Limit this. Improve the air quality by operating one or more smart home appliances at the same time, for example, closing the electric doors and electric windows at the same time, and starting the air purifier to improve aerosols or fine aerosols. By the activation of the notification processing device 9e, the air quality around the user can be improved in time, and when the air quality around the user improves, the notification processing device 9e can receive the air quality information provided by the mobile communication link device 9a. Stop acting immediately.

In addition, the health monitoring device 10 of this case may further include a display (not shown). The health data information of the biometric monitoring module 1 transmitted by the control module 5, 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 displayed on this display.

Of course, the health monitoring device 10 of this case can be combined with clothing to form a smart clothing that can monitor health records, monitor the surrounding air quality, and provide air purification functions. As shown in Figure 13, the health monitoring device 10 can be hung and positioned on a piece of clothing 401 for implementation. As shown in Figure 14, the health monitoring device 10 can be hung and positioned on a pair of pants 402 for implementation. Alternatively, the health monitoring device 10 can be directly worn on the user to form a device capable of monitoring health records, monitoring the surrounding air quality, and providing air purification functions at any time. As shown in Figure 15, the health monitoring device 10 combines a retractable The belt 403 is implemented to be worn on the user's body.

In summary, this case provides a health monitoring device that uses biometric monitoring modules to provide health data information, and combines gas monitoring modules and particle monitoring modules to provide gas and particle monitoring data information, and provides clean gas modules The air purifies and breathes, and the information is sent to an external connection device for storage, recording and display. The information can be obtained in real time to warn people in the environment. It can prevent or escape in real time and avoid exposure to gas in the environment. Human health impact and injury, to achieve the benefits of monitoring health records at any time, monitoring the surrounding air quality, and providing purified air breathing.

This case can be modified in many ways by those who are familiar with this technology, but none of them deviates from the protection of the scope of the patent application. Symbol Description】

1: Biometrics monitoring module 11: Photoelectric sensor 12: Pressure sensor 13: Impedance sensor 14: Light-emitting element 15: Blood pressure measuring device 151: Gas gathering actuator 152: Elastic medium 153: Array pressure sensor 154: Base 154a: accommodating groove 154b: lower gas collecting chamber 154c: lower pressure relief chamber 154d: gas collecting through hole 154e: communicating flow passage 154f: base convex part 154g: pressure relief through hole 155: cavity plate 155a: upper part Gas collecting chamber 155b: upper pressure relief chamber 155c: cavity plate convex part 155d: communicating chamber 155e: communicating hole 156: valve disc 156a: valve hole 16: health monitoring processor 17: substrate 2: gas monitoring module 21 : Compartment body 211: Separator 212: First compartment 213: Second compartment 214: Gap 215: Opening 216: Outlet hole 217: Receptacle 22: Carrier plate 221: Vent 23: Gas sensor 24: Gas Actuator 3: Particle Monitoring Module 31: Ventilation Inlet 32: Ventilation Outlet 33: Particle Monitoring Base 331: Retaining Slot 332: Monitoring Channel 333: Beam Channel 334: Receptacle 34: Carrier Partition 341: Connecting Port 35: Laser Transmitter 36: Particle Actuator 37: Particle Sensor 38: First Compartment 39: Second Compartment 4: Purification Gas Module 41: Air Inlet 42: Air Outlet 43: Air Channel 44 : Purification actuator 45: Purification unit 45a: Filter 45b: Photocatalyst 45c: Ultraviolet lamp 45d: Nanotube 45e: Electrode wire 45f: Dust collecting plate 45g: Boost power supply 45h: Electric field protection net 45i: Adsorption filter Net 45j: high-voltage discharge electrode 45k: electric field protection net 5: control module 51: microprocessor 52: communicator 52a: IoT communication component 52b: data communication component 53: global positioning system component 6: power supply module 7: Body 71: chamber 72: first air inlet 73: second air inlet 74: air outlet 75: monitoring area window 8: external power supply device 9a: mobile communication connection device 9b: networked relay station 9c: cloud data processing device 9d: Notification processing system 9e: Notification processing device 10: Health monitoring device 20: Micro pump 201: Inflow plate 201a: Inflow hole 201b: Busbar groove 201c: Confluence chamber 202: Resonant sheet 202a: Hollow hole 202b: Movable Part 202c: fixed part 203: piezoelectric actuator 203a: suspension plate 203b: outer frame 203c: bracket 203d: piezoelectric element 203e: gap 203f: convex part 204: first insulating sheet 205: conductive sheet 206: second insulation Sheet 207: chamber space 30: blower box micropump 301: jet orifice sheet 301a: connecting piece 301b: suspension sheet 301c: hollow hole 302: cavity frame 303: actuating body 303a: piezoelectric carrier plate 303b: adjusting resonance Plate 303c: piezoelectric plate 304: insulating frame 305: conductive frame 306: resonance chamber 401: clothing Clothes 402: Pants 403: Stretching belt 501: Skin tissue 502: Artery 503: Bone L: Length W: Width H: Height A-A’: Tangent B: Airflow path

Figure 1A is a three-dimensional schematic diagram of the health monitoring device in this case. Figure 1B is a front view of the health monitoring device in this case. Figure 1C is a schematic diagram of the front side of the health monitoring device in this case. Figure 1D is a schematic diagram of the right side of the health monitoring device in this case. Figure 1E is a schematic diagram of the left side of the health monitoring device in this case. Figure 1F is a schematic diagram of the back of the health monitoring device in this case. Figure 2 is a schematic cross-sectional view taken from the line A-A' shown in Figure 1B. Figure 3 is a three-dimensional schematic diagram of the assembly position of the relevant components of the health monitoring device in this case. Figure 4A is a schematic diagram of the cross-sectional appearance of the relevant components of the blood pressure measuring device of the health monitoring device of the present invention. Figures 4B to 4C are schematic diagrams of the inflation action of the blood pressure measuring device shown in Figure 4A. Figure 4D is a schematic diagram of the pressure relief operation of the blood pressure measuring device shown in Figure 4A. Figure 5A is an exploded schematic diagram of the micro pump in this case. Figure 5B is an exploded schematic view of the micropump in this case from another angle. Figure 6A is a schematic cross-sectional view of the micro-pump in this case. Figure 6B is a schematic cross-sectional view of another preferred embodiment of the micropump of the present invention. Figures 6C to 6E are schematic diagrams of the operation of the micropump shown in Figure 6A. Figure 7A is a schematic diagram of the front appearance of the relevant components of the gas monitoring module of the health monitoring device of this case. Figure 7B is a schematic diagram of the back appearance of the related components of the gas monitoring module of the health monitoring device of this case. Figure 7C is an exploded schematic diagram of the relevant components of the gas monitoring module of the health monitoring device in this case. Figure 7D is a three-dimensional schematic diagram of the gas flow direction of the gas monitoring module of the health monitoring device in this case. Figure 7E is a partial enlarged schematic diagram of the gas flow direction of the gas monitoring module of the health monitoring device in this case. Figure 8 is a schematic cross-sectional view of the particle monitoring module of the project. Figure 9A is a schematic cross-sectional view of the first embodiment of the purification unit of the gas purification module of the present invention. Figure 9B is a schematic cross-sectional view of the second embodiment of the purification unit of the gas purification module of the present invention. Figure 9C is a schematic cross-sectional view of the third embodiment of the purification unit of the gas purification module of the present invention. Figure 9D is a schematic cross-sectional view of the fourth embodiment of the purification unit of the gas purification module of the present invention. Figure 9E is a schematic cross-sectional view of the fifth embodiment of the purification unit of the gas purification module of the present invention. Figure 10 shows the exploded schematic diagram of the relevant components of the blower box mini pump in this case. Figures 11A to 11C show schematic diagrams of the operation of the blower box gas pump shown in Figure 10. Figure 12 is a schematic diagram of the control action of the health monitoring device in this case. Figure 13 is a schematic diagram of an embodiment of the present health monitoring device being hung and positioned on clothes. Figure 14 is a schematic diagram of an embodiment of the present health monitoring device being hung and positioned on the pants. Figure 15 is a schematic diagram of an embodiment of the health monitoring device combined with a retractable belt. Figure 16 is a schematic diagram of blood pressure measurement of the blood pressure measuring device in this case.

1: Biometric monitoring module

2: Gas monitoring module

3: Particle monitoring module

4: Purifying gas module

5: Control module

51: Microprocessor

52: Communicator

52a: IoT communication components

52b: Data communication components

53: Global Positioning System Components

6: Power supply module

7: body

8: External power supply device

9a: Mobile communication link device

9b: Connected relay station

9c: Cloud data processing device

9d: Notification processing system

9e: Notification processing device

Claims (44)

A health monitoring device includes: a biometric monitoring module, including a photoelectric sensor, a pressure sensor, an impedance sensor, at least one light-emitting element, a blood pressure measuring device, a health monitoring processor and a substrate, wherein the blood pressure The measuring device includes a gas collecting actuator, an elastic medium and an array pressure sensor. After the photoelectric sensor, the pressure sensor and the impedance sensor are attached to the skin tissue of the user, the gas collecting of the blood pressure measuring device The actuator transmits gas to inflate the elastic medium to make the array pressure sensor elastically displace and press against the skin tissue of the user to generate and provide a detection signal for the health monitoring processor to convert into health data Information and output; a gas monitoring module, including a gas sensor and a gas actuator, the gas actuator controls the gas to be introduced into the gas monitoring module, and monitored by the gas sensor to generate a gas monitoring data Information; a particle monitoring module, including a particle actuator and a particle sensor, the particle actuator controls the introduction of gas into the particle monitoring module, the particle sensor detects the particle size and concentration of suspended particles contained in the gas , To generate a particle monitoring data information; a purified gas module, including a purification actuator and a purification unit, the purification actuator controls the gas to be introduced into the purification gas module, so that the purification unit purifies the gas; and a The control module controls the activation and operation of the biometric monitoring module, the gas monitoring module, the particle monitoring module, and the purified gas module, and combines the health data information, the gas monitoring data information, and the particle monitoring data Information is transmitted and output. The health monitoring device described in item 1 of the scope of patent application further includes a Body, the body has a chamber inside, the biological feature monitoring module, the gas monitoring module, the particle monitoring module, the purified gas module and the control module are arranged in the chamber, and the body is provided There is a first air inlet, a second air 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 cavity The chambers are connected, and the photoelectric sensor, the pressure sensor, the impedance sensor, the light-emitting element, the blood pressure measuring device, and the health monitoring processor package of the biometric monitoring module are fixed on the substrate, and the substrate is positioned and positioned At the window position of the monitoring area. The health monitoring device described in item 2 of the scope of patent application, wherein after the photoelectric sensor is attached to the skin tissue of the user, the photoelectric sensor receives the light source emitted by the light-emitting element transmitted to the skin tissue and then reflected back, and generates The detection signal is provided to the health monitoring processor and converted into the health data information output. For the health monitoring device described in item 3 of the scope of patent application, the health data information is heart rate data. For the health monitoring device described in item 3 of the scope of patent application, the health data information is an electrocardiogram data. Such as the health monitoring device described in item 2 of the scope of patent application, wherein after the pressure sensor of the biometric monitoring module is attached to the skin tissue of the user, the detection signal is generated and provided to the health monitoring processor to be converted into the health The data information is output, and the health data information is respiratory rate data. For example, the health monitoring device described in item 2 of the scope of patent application, wherein after the impedance sensor is attached to the skin tissue of the user, the detection signal is generated and provided to the health monitoring processor to be converted into the health data information output, and the health data The information is blood glucose data. The health monitoring device described in item 2 of the scope of patent application, wherein the blood pressure measurement After the device is attached to the skin tissue of the user, the detection signal is generated and provided to the health monitoring processor to be converted into the health data information output, and the health data information is blood pressure data. For the health monitoring device described in item 8 of the scope of patent application, the blood pressure measuring device further includes: a base framed on the base plate, and recessed with a receiving groove, a lower air collecting chamber, and a lower Part pressure relief chamber, there is a gas collecting through hole between the containing groove and the lower gas collecting chamber for communicating with each other, and the lower gas collecting chamber and the lower pressure releasing chamber are on the base The lower air-collecting chamber and the lower pressure relief chamber are provided with a communication channel for communicating with each other, and the lower pressure relief chamber has a base protrusion, A pressure relief through hole is provided in the center of the convex portion of the base, the pressure relief through hole communicates with the lower pressure relief chamber, and the elastic medium is accommodated in the accommodating groove, and the array pressure sensor abuts against the pressure relief cavity. The elastic medium closes the accommodating groove, and the elastic medium communicates with the air-collecting through hole to be inflated and elastically displaced; and a cavity plate is placed on the base and corresponds to the surface of the base. An upper gas collecting chamber with corresponding caps to the lower gas collecting chamber and an upper pressure releasing chamber with corresponding caps to the lower pressure releasing chamber are provided, and the upper gas collecting chamber is provided with a The cavity plate convex portion, and the cavity plate is concavely provided with a communicating cavity on the surface opposite to the upper gas collecting chamber and the upper pressure relief chamber, the gas collecting actuator is placed on the cavity plate to cover the Communicating chamber, and the communicating chamber passes through at least one communicating hole, respectively communicating with the upper gas collecting chamber and the upper pressure relief chamber; a valve plate is arranged between the base and the chamber plate, the valve The plate abuts against the convex portion of the base to close the pressure relief through hole, the valve plate is provided with a valve hole at a position where the valve plate abuts against the convex portion of the cavity plate, and the valve hole is closed due to the convex portion of the cavity plate; Thereby, the gas gathering actuator is controlled and driven to provide gas transmission, so that the gas is introduced into the communication chamber to concentrate, and the gas is introduced from the communication chamber to the upper gas gathering chamber and the upper pressure relief chamber through the communication hole In the chamber, the valve disc is pushed away from the convex portion of the cavity plate, and the valve disc is pushed against the convex portion of the base to close the pressure relief through hole, and at the same time, the gas in the upper pressure relief chamber is introduced into the upper part from the communication channel In the gas collecting chamber, the gas is introduced into the valve hole of the valve plate and continues to be introduced into the lower gas collecting chamber of the base, and the gas is concentrated to the gas collecting through hole and communicated through the gas collecting through hole It is filled in the elastic medium, and the elastic medium is inflated to elastically displace the array pressure sensor against the skin tissue of the user. The array pressure sensor uses applanation scanning to measure the blood pressure data of the target artery. The health monitoring device described in item 9 of the scope of patent application, wherein the gas collecting actuator stops the operation of transmitting gas. At this time, the gas pressure in the elastic medium is greater than the gas pressure at the communicating chamber, and the elastic medium collects The gas pushes the valve plate to move against the convex part of the cavity plate to close the valve hole, while the gas pushes the valve plate away from the convex part of the base to open the pressure relief through hole. The gas collected in the elastic medium is free from The communicating flow channel is led out into the pressure relief through hole, so that the gas is discharged outside the blood pressure measuring device, and the array pressure sensor is retracted into the containing groove to complete the pressure relief operation of the elastic medium. For the health monitoring device described in item 2 of the scope of patent application, wherein the gas monitoring module includes a compartment body and a carrier plate, the compartment body is arranged at the first air inlet position of the body and is A partition divides the inside to form a first compartment and a second compartment, the partition 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, the carrier board is assembled under the compartment body and encapsulates and electrically connects to the gas sensor, and the carrier board is provided with a vent hole corresponding to the second compartment Vent Hole, the gas sensor penetrates the opening and is disposed in the first compartment, the gas actuator is assembled in the second compartment, and the gas actuator is connected to the gas sensor in the first compartment Isolated, the gas actuator controls the external air to be introduced from the first air inlet into the gas sensor of the first compartment for monitoring, the gas from the first compartment is introduced into the second compartment through the gap, the first The gas of the two compartments is introduced into the vent hole to the vent of the carrier board to be discharged outside the gas monitoring module, and the gas outside the gas monitoring module is discharged from the gas outlet of the body. According to the health monitoring device described in claim 1, wherein the gas sensor includes one or a combination of an oxygen sensor, a carbon monoxide sensor, and a carbon dioxide sensor. According to the health monitoring device described in claim 1, wherein the gas sensor includes one or a combination of a temperature sensor and a humidity sensor. According to the health monitoring device described in claim 1, wherein the gas sensor comprises a volatile organic compound sensor. According to the health monitoring device described in claim 1, wherein the gas sensor includes one or a combination of a bacteria sensor, a virus sensor, and a microorganism sensor. The health monitoring device described in item 2 of the scope of patent application, wherein the particle monitoring module includes a ventilation inlet, a ventilation outlet, a bearing partition, a particle monitoring base and a laser transmitter, and the ventilation inlet is opposite to The second air inlet of the main body is arranged, and the air outlet is arranged corresponding to the air outlet of the main body. The internal space of the particle monitoring module defines a first compartment and a second compartment by the carrier partition, The load-bearing partition has a communication port which communicates with the first compartment and the second compartment, the first compartment is connected with the ventilation inlet, the second compartment is connected with the ventilation outlet, and the particle monitoring The base is adjacent to the bearing partition, and the particle monitoring The base is accommodated in the first compartment, and the particle monitoring base has a holding groove, a monitoring channel, a beam channel, and a holding chamber. The holding groove corresponds vertically to the ventilation inlet. The particle actuator It is arranged on the receiving groove and is located at one end of the monitoring channel. The accommodating chamber is arranged on one side of the monitoring channel to accommodate and position the laser transmitter, and the beam channel is connected to the accommodating room and the monitoring channel Between and vertically across the monitoring channel, and guide a laser beam emitted by the laser transmitter to irradiate the monitoring channel, the particle sensor is arranged at the other end of the monitoring channel, the particle actuator The control gas is introduced into the holding groove from the ventilation inlet, the gas of the holding groove is introduced into the monitoring channel, the gas of the monitoring channel is irradiated by the laser beam emitted by the laser transmitter, and the monitoring channel is The gas irradiated by the laser beam projects a spot of light in the gas to the surface of the particle sensor to monitor the particle size and concentration of the suspended particles contained in the gas. The monitored gas is introduced into the communicating port to the ventilation outlet and discharged out of the particle monitoring module , The gas outside the gas monitoring module is discharged from the gas outlet of the body. According to the health monitoring device described in item 1 of the scope of patent application, the particle sensor is a PM2.5 sensor. The health monitoring device described in item 2 of the scope of patent application, wherein the purified gas module is arranged adjacent to one side of the particle monitoring module, and the purified gas module includes a gas inlet, a gas outlet, and a gas A channel, the air guide inlet is positioned corresponding to the second air inlet of the body, the air guide outlet is arranged corresponding to the air outlet of the body, and the air guide channel is arranged between the air guide inlet and the air outlet, The purification actuator and the purification unit are arranged in the air guide passage, and the purification actuator controls gas to be introduced into the air guide passage from the second air inlet of the body, so that the gas passing through the air guide passage is The purification unit purifies and is discharged from the purified gas module through the gas guiding outlet, and the gas outside the purified gas module is discharged from the air outlet of the body. According to the health monitoring device described in claim 1, wherein the gas collection actuator, the gas actuator, the particle actuator and the purification actuator are each a micropump, and the micropump includes: An inlet plate having at least one inlet hole, at least one busbar groove and a bus chamber, wherein the inlet hole is for introducing gas, the inlet hole correspondingly penetrates the busbar groove, and the busbar groove flows to The confluence chamber allows the gas introduced by the inlet hole to flow into the confluence chamber; a resonant sheet is attached to the inlet plate and has a hollow hole, a movable part and a fixed part. The hollow The hole is located at the center of the resonance plate and corresponds to the confluence chamber of the inlet plate, and the movable part is arranged around the hollow hole and opposite to the confluence chamber, and the fixed part is arranged on the resonance plate And a piezoelectric actuator, which is connected to the resonant sheet and correspondingly arranged; wherein there is a cavity space between the resonant sheet and the piezoelectric actuator , So that when the piezoelectric actuator is driven, the gas is introduced from the inlet hole of the inlet plate, collected into the confluence chamber through the bus bar groove, and then flows through the hollow hole of the resonance plate , The piezoelectric actuator and the movable part of the resonant sheet generate resonance to transmit gas. The health monitoring device described in item 19 of the scope of patent application, wherein the piezoelectric actuator includes: a suspension plate having a square shape, which can be bent and vibrated; an outer frame arranged around the outer side of the suspension plate; At least one bracket is connected between the suspension board and the outer frame to provide elastic support for the suspension board; and a piezoelectric element having a side length that is less than or equal to the side length of the suspension board, and the pressure Electrical components are attached to one surface of the suspension board for application Voltage to drive the flexural vibration of the suspension plate. For the health monitoring device described in item 19 of the scope of application, the micropump further includes a first insulating sheet, a conductive sheet and a second insulating sheet, wherein the inlet plate, the resonance sheet, and the piezoelectric actuator The actuator, the first insulating sheet, the conductive sheet and the second insulating sheet are sequentially stacked and combined. According to the health monitoring device described in claim 20, the floating board includes a convex portion, and the convex portion is disposed on the opposite surface of the floating board attached to the piezoelectric element. According to the health monitoring device described in item 22 of the scope of patent application, the protrusion is formed by an etching process to form an integrally formed convex structure protruding from the surface on which the suspension plate is attached to the piezoelectric element. The health monitoring device described in item 19 of the scope of patent application, wherein the piezoelectric actuator includes: a suspension plate having a square shape, which can be bent and vibrated; an outer frame arranged around the outer side of the suspension plate; At least one bracket is connected and formed between the suspension board and the outer frame to provide elastic support for the suspension board, and make a surface of the suspension board and a surface of the outer frame form a non-coplanar structure, and make the A surface of the suspension plate and the resonance plate maintain a cavity space; and a piezoelectric element having a side length that is less than or equal to the length of one side of the suspension plate, and the piezoelectric element is attached to the suspension plate On a surface, a voltage is applied to drive the suspension plate to bend and vibrate. The health monitoring device described in the first item of the scope of patent application, wherein the gas collection actuator, the gas actuator, the particle actuator, and the purification actuator are respectively a blower box micropump, and the drum The bellows mini pump contains: An air jet hole sheet comprising a plurality of connecting members, a suspension sheet and a hollow hole, the suspension sheet can be flexurally vibrated, the plurality of connecting members are adjacent to the periphery of the suspension sheet, and the hollow hole is formed at the center of the suspension sheet, The plurality of connecting pieces are fixedly arranged to provide elastic support for the suspension sheet, and an air flow chamber is formed between the bottom of the air jet orifice sheet, and at least one gap is formed between the plurality of connecting pieces and the suspension sheet; a cavity A frame with a load-bearing superimposed on the suspension sheet; an actuator, a load-bearing superimposed on the cavity frame to receive voltage to generate reciprocating bending vibration; an insulating frame, a load-bearing superimposed on the actuating body; A conductive frame is stacked on the insulating frame; wherein a resonance chamber is formed between the actuating body, the cavity frame and the suspension plate, and the actuating body is driven to drive the air jet orifice plate to generate resonance, The suspension sheet of the air jet orifice sheet is reciprocally vibrated and displaced, so that the gas enters the air flow chamber through the at least one gap and then is discharged to realize the transmission and flow of the gas. The health monitoring device according to item 25 of the scope of patent application, wherein the actuating body includes: a piezoelectric carrier plate on which the carrier is stacked on the cavity frame; and an adjusting resonance plate on which the carrier is stacked on the piezoelectric carrier On the board; and a piezoelectric plate, which is loaded and stacked on the adjusting resonance plate to receive voltage to drive the piezoelectric carrier plate and the adjusting resonance plate to produce reciprocating bending vibration. According to the health monitoring device described in item 1 of the scope of patent application, the gas collection actuator, the gas actuator, the particle actuator and the purification actuator are respectively a MEMS gas pump. The health monitoring device described in item 1 of the scope of patent application further includes a supply The electrical module provides stored electrical energy and output electrical energy. The electrical energy is output to the electrical operation of the biometric monitoring module, the gas monitoring module, the particle monitoring module, the purified gas module, and the control module. Such as the health monitoring device described in item 28 of the scope of patent application, wherein the power supply module uses wired transmission to receive electric energy supplied by an external power supply device to store electric energy. For example, in the health monitoring device described in item 28 of the scope of patent application, the power supply module uses wireless transmission to receive electric energy supplied by an external power supply device to store electric energy. Such as the health monitoring device described in claim 1, wherein the control module includes a microprocessor, a communicator and a global positioning system component, and the communicator includes an IoT communication component and a data communication component . Such as the health monitoring device described in item 31 of the scope of patent application, wherein the IoT communication component receives the health data information of the biometric monitoring module, the gas monitoring data information and the particle monitoring data information, and transmits and sends the health data The information, the gas monitoring data information and the particulate monitoring data information are stored, recorded and displayed on an external connection device. The health monitoring device described in item 31 of the scope of patent application, wherein the Internet of Things communication component is a narrowband Internet of Things device that transmits signals through narrowband radio communication technology. Such as the health monitoring device described in item 32 of the scope of patent application, wherein the external connection device includes a network relay station and a cloud data processing device, and the Internet of Things communication component transmits the health data information and the gas monitoring through the network relay station The data information and the particle monitoring data information are stored, recorded and displayed in a cloud data processing device. For example, the health monitoring device described in item 31 of the scope of patent application, wherein the data communication element receives the health data information of the biometric monitoring module and the gas monitoring data According to the information and the particle monitoring data information, the health data information, the gas monitoring data information and the particle monitoring data information are transmitted to an external connection device for storage, recording and display. For example, the health monitoring device described in item 35 of the scope of patent application, wherein the data communication element transmits the health data information, the gas monitoring data information and the particle monitoring data information through wired communication transmission, and the wired communication transmission interface is a USB, At least one of a mini-USB and a micro-USB. For example, the health monitoring device described in item 35 of the scope of patent application, wherein the data communication element transmits the health data information, the gas monitoring data information and the particle monitoring data information through wireless communication transmission, and the wireless communication transmission interface is a Wi-Fi At least one of Fi module, a Bluetooth module, a radio frequency identification module and a near field communication module. For example, the health monitoring device described in item 35 of the scope of patent application, wherein the external connection device includes a mobile communication connection device, and the mobile communication connection device receives the data communication element to transmit the health data information, the gas monitoring data information and the The particle monitoring data information is stored, recorded and displayed. The health monitoring device described in item 38 of the scope of patent application, wherein the mobile communication connection device is at least one of a mobile phone device, a smart watch, and a smart bracelet. Such as the health monitoring device described in item 35 of the scope of patent application, wherein the external connection device includes 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 the gas monitoring The data information and the particle monitoring data information, and then 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 for storage, recording and display. Such as the health monitoring device described in item 40 of the scope of patent application, wherein the mobile communication connection device is at least one of a mobile phone device, a notebook computer and a tablet computer. Such as the health monitoring device described in item 38 or 40 of the scope of patent application, wherein the mobile communication link device is connected to a notification processing system, and the mobile communication link device receives the gas monitoring data information and the particulate monitoring data information to generate an alarm indication Information to transmit the notification information to the notification processing system to activate the air quality notification mechanism. Such as the health monitoring device described in item 38 or 40 of the scope of patent application, wherein the mobile communication connection device is connected to a notification processing device, and the mobile communication connection device receives the gas monitoring data information and the particulate monitoring data information to generate a notification The warning information is transmitted to the notification processing device to activate the air quality processing. For example, the health monitoring device described in item 1 of the scope of patent application further includes a display, and the control module transmits the health data information of the biometric monitoring module, the gas monitoring data information, and the particle monitoring data information from the display display.

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