阅读说明：本技术 具气体监测的行动装置 (Mobile device with gas monitoring function ) 是由 莫皓然 黄启峰 韩永隆 陈宣恺 郭俊毅 于 2018-07-20 设计创作，主要内容包括：一种具气体监测的行动装置,包含：一本体；至少一气体监测模块,设置于该本体内,并包含一气体致动器、一气体传感器,透过该气体致动器控制气体导入由该气体传感器进行监测以产生监测资料；至少一微粒监测模块,设置于该本体内,并包含一微粒致动器及一微粒传感器,透过该微粒致动器控制气体导入由该微粒传感器监测气体中所含悬浮微粒的粒径及浓度；以及至少一净化气体模块,设置连通于于该本体内,并包含一净化致动器及一净化单元,透过该净化致动器控制气体导入由该净化单元净化气体,排出该本体外。(A mobile device with gas monitor function is composed of a main body , at least 0 gas monitor module in said main body and consisting of gas actuator and gas sensor for controlling the gas introduction via said actuator and monitoring by said sensor to generate monitor data, at least particle monitor module in said main body and consisting of particle actuator and particle sensor for controlling the gas introduction via said actuator and monitoring the particle size and concentration of suspended particles in gas via said sensor, and at least gas-cleaning module communicated with said main body and consisting of gas-cleaning actuator and gas-cleaning unit for controlling the gas introduction via said actuator and cleaning gas from said unit to be discharged out of said main body.)

1, A mobile device with gas monitoring function, comprising:

body comprising at least gas monitor inlet, at least gas monitor outlet, at least particle monitor inlet, at least particle monitor outlet, at least purge inlet, and at least purge outlet;

at least gas monitoring module, the gas monitoring module is set and connected between the gas monitoring inlet and the gas monitoring outlet, the gas monitoring module includes gas actuator and gas sensor, the gas actuator controls gas to be guided into the gas monitoring module from the gas monitoring inlet, and monitoring is carried out through the gas sensor to generate monitoring data;

at least particle monitoring module connected between the particle monitoring inlet and the particle monitoring outlet, the particle monitoring module including particle actuator and particle sensor, the particle actuator controlling gas to be introduced into the particle monitoring module from the particle monitoring inlet, and the particle sensor monitoring particle size and concentration of suspended particles in the gas, and

at least purge gas module, the purge gas module set up and communicate between this purge gas inlet and this purge gas vent, this purge gas module includes purification actuator and purification unit, this purification actuator control gas is led into this purge gas module inside from this purge gas inlet, sees through this purification unit purge gas, and the gas after the purification is discharged outside this body from this purge gas vent.

2. The mobile device with gas monitoring of claim 1, wherein the gas monitoring module comprises a th compartment body, the th compartment body is partitioned by a th gas passage partition into a gas inlet passage and a gas outlet passage, the gas inlet passage is connected to the gas monitoring inlet port, the gas sensor is disposed in the gas inlet passage, the gas outlet passage is connected to the gas monitoring outlet port, the gas actuator is disposed in the gas outlet passage and is located on the gas passage partition, and the gas passage partition is provided with a th gas passage connecting port to the gas inlet passage and the gas outlet passage.

3. The mobile device with gas monitoring of claim 1, wherein the gas sensor comprises at least one of an oxygen sensor, a carbon oxide sensor, and a carbon dioxide sensor or a combination thereof.

4. The mobile device with gas monitoring of claim 1, wherein the gas sensor comprises VOC sensors.

5. The mobile device of claim 1, wherein the gas sensor comprises at least of bacterial sensor, viral sensor, and microbial sensor.

6. The mobile device for gas monitoring of claim 1, wherein the particle monitoring module comprises a second compartment body, a load-bearing partition, 0a particle monitoring pedestal and 1a laser emitter, the second compartment body has an interior space divided by a monitoring inlet channel and a monitoring outlet channel, the monitoring inlet channel is correspondingly communicated with the particle monitoring inlet port, the monitoring outlet channel is correspondingly communicated with the particle monitoring outlet port, the load-bearing partition has a monitoring communication port for communicating the monitoring inlet channel and the monitoring outlet channel, the particle monitoring pedestal is disposed adjacent to the load-bearing partition and is contained in the monitoring inlet channel, the particle monitoring pedestal comprises a bearing groove, a monitoring channel, a beam channel and a containing chamber, the particle actuator is disposed on the bearing groove, the monitoring channel is disposed below the bearing groove, the containing chamber is disposed on the side of the monitoring channel a laser emitter positioned, the beam channel is communicated with the containing chamber and the monitoring channel, the monitoring channel is disposed vertically below the monitoring inlet port, the monitoring outlet channel directs the laser emitter to emit the monitoring particles through the monitoring outlet port, the monitoring outlet channel directs the monitoring laser emitter to direct the monitoring particles emitted from the monitoring outlet port, the monitoring laser emitter to control the particle monitor gas sensor, the laser emitter and the monitoring channel to direct emission of the monitoring particles emitted from the monitoring gas spot.

7. The mobile device with gas monitoring of claim 1, wherein the particle sensor is a PM2.5 sensor.

8. The mobile device with gas monitoring function of claim 1, wherein the purge gas module comprises a third compartment body, the third compartment body is provided with an air channel and a purge channel , the air channel is correspondingly connected to the purge inlet, the end of the purge channel is connected to the air channel, the end of the purge channel is connected to the purge outlet, the purge actuator is disposed in the purge channel, and the purge unit is disposed in the purge channel, and controls the introduction of gas into the purge channel by the purge actuator, and the purge gas is discharged from the body through the purge outlet by the purge unit.

9. The mobile device for gas monitoring of claim 1, wherein the gas actuator, the particle actuator and the purge actuator are MEMS gas pumps.

10. The mobile device with gas monitoring of claim 1, wherein the gas actuator, the particle actuator and the purge actuator are gas pumps, the gas pumps comprising:

an air inlet plate having at least air inlet holes, at least bus bar holes and converging chamber, wherein the air inlet holes are used for introducing air flow, the bus bar holes are corresponding to the air inlet holes, and the air flow of the air inlet holes is guided to converge to the converging chamber;

resonator plate having hollow holes corresponding to the confluence chamber and movable part around the hollow holes, and

piezoelectric actuator corresponding to the resonator plate;

an cavity space is formed between the resonance sheet and the piezoelectric actuator, so that when the piezoelectric actuator is driven, airflow is guided in from the air inlet hole of the air inlet plate, is collected to the collecting chamber through the collecting hole, and then flows through the hollow hole of the resonance sheet, and resonance transmission airflow is generated by the piezoelectric actuator and the movable part of the resonance sheet.

11. The mobile device with gas monitoring of claim 1, wherein the gas actuator, the particle actuator and the purge actuator are blower box gas pumps, the blower box gas pumps comprising:

air jet hole plate, which comprises multiple connectors, suspension plate and hollow hole, wherein the suspension plate can be bent and vibrated, the connectors are adjacent to the periphery of the suspension plate, the hollow hole is formed at the center of the suspension plate, and is positioned through the connectors, and provides elastic support for the suspension plate, and makes air flow chamber be formed between the bottom surfaces of the air jet hole plate, and at least gap is formed between the connectors and the suspension plate;

cavity frame bearing and overlapping on the suspension plate;

actuating body bearing and superposed on the cavity frame to receive voltage and generate reciprocating bending vibration;

insulating frame bearing the actuator, and

conductive frame, bearing stack is set on the insulating frame;

an resonance chamber is formed among the actuating body, the cavity frame and the suspension plate, and the suspension plate of the air injection hole plate generates reciprocating vibration displacement by driving the actuating body to drive the air injection hole plate to generate resonance, so that air enters the air flow chamber through the gap and is exhausted, and the transmission and flow of the air are realized.

12. The mobile device with gas monitoring of claim 8, wherein the purge unit is an filter unit comprising a plurality of filters respectively disposed in the purge channel at a distance of , and the purge actuator controls the gas to be introduced into the purge channel and be filtered and purged by the plurality of filters.

13. The mobile device of claim 12, wherein the filter is at least one of an electrostatic filter, a activated carbon filter, and a high efficiency filter (HEPA) .

14. The mobile device with gas monitor of claim 8, wherein the purification unit is photo-catalyst unit, which comprises photo-catalyst and UV lamp, which are respectively disposed in the purification channel to maintain a distance of , the gas is controlled to be introduced into the purification channel by the purification actuator, and the photo-catalyst is irradiated by the UV lamp to decompose the purified gas.

15. The mobile device with gas monitor of claim 14, wherein the photo-catalyst unit comprises a plurality of filters respectively disposed in the purge channel at an interval of , and the purge actuator controls the gas to be introduced into the purge channel and be filtered and purged by the plurality of filters.

16. The mobile device of claim 15, wherein the filter is at least of electrostatic filter, activated carbon filter, and high efficiency filter (HEPA).

17. The mobile device with gas monitoring of claim 8, wherein the purification unit is an optical plasma unit comprising a nm light pipe disposed in the purification channel, the purification actuator controls the gas to be introduced into the purification channel, and the nm light pipe irradiates to decompose and purify the gas containing volatile formaldehyde, toluene and volatile organic compounds.

18. The mobile device of claim 17, wherein the optical plasma unit comprises a plurality of filters respectively disposed in the purge channel at an interval of , and the purge actuator controls the gas to be introduced into the purge channel and to be filtered and purged by the plurality of filters.

19. The mobile device of claim 18, wherein the filter is at least of electrostatic filter, activated carbon filter, and high efficiency filter (HEPA).

20. The mobile device with gas monitoring of claim 8, wherein the purification unit is an anion unit comprising at least electrode wires, at least dust-collecting plates and voltage-boosting power supply, the electrode wires and the dust-collecting plates are disposed in the purification channel, and the voltage-boosting power supply is disposed in the purification gas module for providing high-voltage discharge of the electrode wires, the dust-collecting plates have negative charges, the gas is guided into the purification channel through the purification actuator, and the high-voltage discharge of the electrode wires can positively charge particles contained in the gas, so as to attach the negatively charged dust-collecting plates for purification.

21. The mobile device of claim 20, wherein the anion unit comprises a plurality of filters respectively disposed in the purge channel at an interval of , and the purge actuator controls the gas to be introduced into the purge channel and filtered and purged by the plurality of filters.

22. The mobile device of claim 21, wherein the filter is at least one of an electrostatic filter, a activated carbon filter, and a high efficiency filter (HEPA) .

23. The mobile device with gas monitoring of claim 20, wherein the electrode wire is made of fiber bundle of fullerene material.

24. The mobile device with gas monitoring of claim 8, wherein the purification unit is an ion unit comprising a electric field upper guard net, a adsorption screen, a high voltage discharge electrode, a electric field lower guard net and a boost power supply, the electric field upper guard net, the adsorption screen, the high voltage discharge electrode and the electric field lower guard net are disposed in the purification channel, and the adsorption screen and the high voltage discharge electrode are disposed between the electric field upper guard net and the electric field lower guard net, and the boost power supply is disposed in the purification gas module to provide high voltage discharge of the high voltage discharge electrode to generate high voltage column carrying ions, so that gas is controlled to be introduced into the purification channel through the purification actuator, and purified gas is decomposed through the ions.

25. The mobile device of claim 24, wherein the plasma ion unit comprises a plurality of filters respectively disposed in the purge passage at an interval of , and the purge actuator controls the gas to be introduced into the purge passage and to be filtered and purged by the plurality of filters.

26. The mobile device of claim 25, wherein the filter is at least one of an electrostatic filter, a activated carbon filter, and a high efficiency filter (HEPA) .

27. The mobile device with gas monitor of claim 1, wherein the gas monitor inlet and the gas monitor outlet are respectively provided with protection films, and the protection films are waterproof and dustproof film structures capable of penetrating gas.

28. The mobile device with gas monitoring and actuation sensing module of claim 27, wherein the protection rating of the protection film is a rating of international protection rating certification IP 64.

29. The mobile device for monitoring gases of claim 27, wherein the protection rating of the protection film is a rating of international protection rating certification IP 68.

30, A mobile device with gas monitoring, comprising:

at least body comprising at least gas monitor inlet, at least gas monitor outlet, at least particle monitor inlet, at least particle monitor outlet, at least purge inlet, and at least purge outlet;

at least gas monitoring module, the gas monitoring module is set up and connected between the gas monitoring air inlet and the gas monitoring exhaust outlet, the gas monitoring module includes at least gas actuator and at least gas sensor, the gas actuator controls the gas to be led into the gas monitoring module from the gas monitoring air inlet, monitor through the gas sensor to produce the monitoring data;

at least particle monitoring module connected between the particle monitoring inlet and the particle monitoring outlet, the particle monitoring module including at least particle actuator and at least particle sensor, the particle actuator controlling gas to be introduced into the particle monitoring module from the particle monitoring inlet, and the particle sensor monitoring particle size and concentration of suspended particles in the gas, and

at least purge gas module, the purge gas module set up and communicate between this purge gas inlet and this purge gas vent, this purge gas module includes at least and purification unit, this purification actuator control gas is led into this purge gas module inside from this purge gas inlet, sees through this purification unit purge gas, the gas after the purification is discharged outside this body from this purge gas vent.

Technical Field

The present invention relates to mobile devices with gas monitoring function, and more particularly to mobile devices for gas monitoring applications.

Background

Modern people pay more and more attention to the requirements for the quality of gases around life, such as carbon oxide, carbon dioxide, Volatile Organic Compounds (VOC), PM2.5, nitrogen oxide, sulfur oxide and other gases, even particles contained in gases, are exposed in the environment and affect human health, and seriously even harm life.

How to confirm the quality of the gas is feasible by using gas sensors to monitor the gas in the surrounding environment, if the monitoring information can be provided in real time to warn people in the environment, the people can be prevented or escape in real time, the influence and harm to human health caused by the exposure of the gas in the environment are avoided, and the application of the gas sensors to monitor the surrounding environment is very good.

However, even if the air quality status can be immediately known, if the air quality status cannot be immediately improved, the air quality status will immediately affect the human health, so it is very important to embed the gas detection module and the air purification equipment in the portable device, especially, under the condition that the current development trend of the portable device is light, thin and high performance, how to make the gas detection module thin and assemble in the portable mobile device for use is an important subject developed by the present disclosure.

Disclosure of Invention

The main purpose of this scheme is to provide kinds of mobile devices with gas monitoring, assemble the gas monitoring module, particle monitoring module and purge gas module on the slim portable mobile device, utilize the gas monitoring module, particle monitoring module to carry on the gas monitoring, achieve the purpose that the gas monitoring device can be detected at any time, anywhere, can have fast accurate monitoring effect, in addition, particle monitoring module monitors the monitoring information that contains the particle concentration in the air of the surrounding environment, and can provide the monitoring information with the mobile device of this scheme and transmit to the external device, can obtain the information in time, in order to warn and tell the people in the environment can prevent or flee from in time, and the purge gas module of this apparatus provides the purge gas and discharges and uses, reduce the gas exposure in the environment and causes human health influence and injury.

The embodiment of the present application is type of mobile device with gas monitoring, comprising a body including at least gas monitoring inlet, at least gas monitoring outlet, at least particle monitoring inlet, at least particle monitoring outlet, at least purge inlet and at least purge outlet, at least gas monitoring module connected between the gas monitoring inlet and the gas monitoring outlet, the gas monitoring module including gas actuators and gas sensors, the gas actuators controlling gas introduction from the gas monitoring inlet into the gas monitoring module, monitoring through the gas sensors to generate monitoring data, and monitoring gas exhaust from the gas monitoring outlet, at least particle monitoring module connected between the particle monitoring inlet and the particle monitoring outlet, the particle monitoring module including particle actuators and particle sensors, the particle actuators controlling gas introduction from the inside of the particle monitoring module, the gas monitoring gas introduction from the particle monitoring inlet and the particle monitoring outlet, the particle monitoring module controlling particle concentration of the purge gas from the gas monitoring inlet to the particle monitoring outlet, the purge gas monitoring module, the purge gas introduction from the purge outlet to the particle monitoring inlet, the purge gas monitoring module, the purge gas monitoring outlet, the purge gas monitoring module including particle monitoring inlet, and purge gas exhaust from the purge gas monitoring outlet, the purge gas monitoring module, and the purge gas monitoring module including the purge gas monitoring gas exhaust unit.

Drawings

FIG. 1A is a schematic diagram of the arrangement positions of the related components of the mobile device with gas monitoring according to the present disclosure.

FIG. 1B is a schematic cross-sectional view of a gas monitoring module in a mobile device with gas monitoring according to the present disclosure.

FIG. 1C is a schematic cross-sectional view of a particle monitoring module and a purge gas module in a mobile device with gas monitoring according to the present disclosure.

Fig. 2 is a schematic view of an operation section of the gas monitoring module.

FIG. 3 is a schematic cross-sectional view of a gas monitoring module in a mobile device with gas monitoring according to the present disclosure.

Fig. 4A and 4B are exploded schematic views of the gas pump according to the present invention.

Fig. 4C is a schematic cross-sectional view of the gas pump of the present invention.

Fig. 4D to 4F are schematic operation diagrams of the gas pump of the present invention.

Fig. 5A is an exploded view of the related components of the blower box gas pump.

Fig. 5B to 5D are schematic operation diagrams of the blower box gas pump of the present invention.

Fig. 6 is a schematic view of an operation section of the particle monitoring module.

Fig. 7A is a schematic cross-sectional view of an th embodiment of a purge unit of the purge gas module of the present disclosure.

Fig. 7B is a schematic cross-sectional view of a second embodiment of a purge unit of the purge gas module of the present disclosure.

Fig. 7C is a schematic cross-sectional view of a third embodiment of a purge unit of the purge gas module of the present disclosure.

Fig. 7D is a schematic cross-sectional view of a fourth embodiment of the purge unit of the purge gas module of the present disclosure.

Fig. 7E is a schematic cross-sectional view of a fifth embodiment of a purge unit of the purge gas module of the present disclosure.

Description of the reference numerals

10: body

10 a: gas monitoring gas inlet

10 b: gas monitoring exhaust port

10 c: particle monitoring air inlet

10 d: particle monitoring exhaust port

10 e: purifying air inlet

10 f: purification exhaust port

10 g: protective film

1 a: gas monitoring module

11: gas actuator

12: gas sensor

th diaphragm cavity body

14: air flue partition plate

141: airway communicating port

15: gas inlet channel

16: gas exhaust channel

2 a: particle monitoring module

21: particle actuator

22: particle sensor

23: second compartment body

24: bearing partition plate

241: monitoring communication port

25: monitoring an intake passage

26: monitoring exhaust gas passages

27: particle monitoring base

271: bearing groove

272: monitoring channel

273: light beam channel

274: accommodation chamber

28: laser transmitter

3 a: purge gas module

31: purge actuator

32: purification unit

32 a: filter screen

32 b: photocatalyst

32c, the ratio of: ultraviolet lamp

32 d: nano light pipe

32e, and (3): electrode wire

32 f: dust collecting plate

32 g: boosting power supply

32 h: electric field upper protective net

32 i: adsorption filter screen

32 j: high-voltage discharge electrode

32 k: protective net under electric field

33: third compartment body

34: air guide channel

35: purification channel

4: gas pump

41: air inlet plate

41 a: air intake

41 b: bus bar hole

41 c: confluence chamber

42: resonance sheet

42 a: hollow hole

42 b: movable part

42 c: fixing part

43: piezoelectric actuator

43 a: suspension plate

431a th surface

432 a: second surface

43 b: outer frame

431 b: matched surface

432 b: lower surface

43 c: connecting part

43 d: piezoelectric element

43 e: gap

43 f: convex part

431 f: surface of the convex part

44: insulating sheet

45: conductive sheet

46: chamber space

5: blast box gas pump

51: air injection hole sheet

51 a: connecting piece

51 b: suspension plate

51 c: hollow hole

52: cavity frame

53: actuating body

53 a: piezoelectric carrier plate

53 b: tuning the resonator plate

53 c: piezoelectric plate

54: insulating frame

55: conductive frame

56: resonance chamber

57: airflow chamber

g: chamber spacing

Detailed Description

While certain exemplary embodiments embodying features and advantages of the present invention will be described in detail in the following description, it will be understood that the invention is capable of numerous modifications of various forms without departing from the scope of the invention, and that the description and drawings are to be regarded as illustrative in nature, and not as restrictive.

Referring to fig. 1A, 1B and 1C, kinds of mobile devices with gas monitoring include at least main body 10, at least 0 gas monitoring module 1A, at least 1 particle monitoring module 2a and at least purge gas module 3a, wherein the main body 10 is a housing of the mobile device disposed outside and includes at least gas monitoring inlet 10a, at least gas monitoring outlet 10B, at least particle monitoring inlet 10C, at least particle monitoring outlet 10d, at least purge inlet 10e and at least purge outlet 10f, and a plurality of gas monitoring modules 1A, a plurality of particle monitoring modules 2a and a plurality of purge gas modules 3a may be disposed therein for monitoring gas and purge gas, for avoiding redundancy, the main body 10, the gas monitoring modules 1A, the particle monitoring modules 2a and the purge gas modules 3a are for illustration, but not limited thereto, the main body 10, the gas monitoring modules 1A, the particle monitoring modules 2a and the purge gas monitoring modules 10a may be disposed in the main body 10a, the purge gas monitoring modules 10C, and the purge gas monitoring modules 10C may be disposed in the main body 10a and the main body 10 a.

As shown in fig. 1B and 2, the gas monitoring module 1a is disposed in communication between the gas monitoring inlet 10a and the gas monitoring outlet 10B, and the gas monitoring module 1a includes at least a gas actuator 11, and at least a gas sensor 12, a -th compartment body 13, wherein the -th compartment body 13 is internally partitioned by a -th gas partition 14 into -th gas inlet passage 15 and -th gas outlet passage 16, the gas inlet passage 15 is correspondingly communicated with the gas monitoring inlet 10a, and the gas sensor 12 is disposed in the gas inlet passage 15, and the gas outlet passage 16 is correspondingly communicated with the gas monitoring outlet 10B, and the gas actuator 11 is disposed in the gas outlet passage 16 and positioned on the gas partition 14, and the gas partition 14 is provided with a -th gas passage communication port 141 for communicating the gas inlet passage 15 and gas outlet passage 16, such that the gas sensor 12 is disposed in the gas inlet passage 15 and is kept isolated from the gas actuator 11 by the gas partition 14, and thus the gas sensor 14 is prevented from affecting the sensitivity of the gas sensor 12, and the gas sensor 12 is not illustrated as a combined with the gas monitoring inlet and gas sensor 11 for monitoring outlet 10B.

The gas sensor 12 may be at least one of oxygen sensor, carbon oxide sensor, carbon dioxide sensor, temperature sensor, ozone sensor and volatile organic compound sensor, or the gas sensor 12 may be at least one of bacteria sensor, virus sensor or microorganism sensor, or a combination thereof, all of which are not limited thereto.

Referring to fig. 4A, 4B and 4C, the gas actuator 11 of the present invention is an gas pump 4, which includes a gas inlet plate 41, a resonator plate 42, a piezoelectric actuator 43, a insulating plate 44 and a conductive plate 45 stacked in sequence, wherein the gas inlet plate 41 has at least gas inlet holes 41a, at least bus holes 41B and a bus chamber 41C, the number of the gas inlet holes 41a is the same as that of the bus holes 41B, in this embodiment, the number of the gas inlet holes 41a and the number of the bus holes 41B are 4 by way of example, but not limited thereto, the 4 gas inlet holes 41a respectively penetrate through the 4 bus holes 41B, and the 4 bus holes 41B are converged to the bus chamber 41C.

The above-mentioned resonator plate 42 is assembled to the air inlet plate 41 by means of bonding, and the resonator plate 42 has hollow holes 42a, movable portions 42b and fixing portions 42c, the hollow hole 42a is located at the center of the resonator plate 42 and corresponds to the confluence chamber 41c of the air inlet plate 41, the area which is disposed around the hollow hole 42a and is opposite to the confluence chamber 41c is the movable portion 42b, and the outer peripheral edge portion of the resonator plate 42 is bonded to the air inlet plate 41 and is the fixing portion 42 c.

The piezoelectric actuator 43 includes a suspension plate 43a, a frame 43b, at least 0 connecting portions 43c, a 1 piezoelectric element 43d, at least 2 gap 43e and a 3 protrusion 43f, wherein the suspension plate 43a is a 4 square suspension plate having a 5 th surface 431a and a second surface 432a opposite to the th surface 431a, the frame 43b is disposed around the periphery of the suspension plate 43a, the frame 43b has assembling surfaces 431b and lower surface 432b and is connected between the suspension plate 43a and the frame 43b through at least connecting portions 43c to provide a supporting force for elastically supporting the suspension plate 43a, wherein at least gap 43e is a gap between the suspension plate 43a, the frame 43b and the connecting portions 43c for gas to pass through, the th surface 431a of the suspension plate 43a has 43f, the protrusion 43f is adjacent to the periphery of the protrusion 43c, and the protrusion 43f is etched to form a step-shaped protrusion structure .

As shown in fig. 4C, the suspension plate 43a of the present embodiment is formed by stamping to be recessed downward, and the sinking distance thereof can be adjusted by at least connecting portions 43C formed between the suspension plate 43a and the outer frame 43b, such that the convex surface 431f of the convex portion 43f on the suspension plate 43a and the assembly surface 431b of the outer frame 43b form a non-coplanar surface, i.e., the convex surface 431f of the convex portion 43f is lower than the assembly surface 431b of the outer frame 43b, and the second surface 432a of the suspension plate 43a is lower than the lower surface 432b of the outer frame 43b, and the piezoelectric element 43d is attached to the second surface 432a of the suspension plate 43a and disposed opposite to the convex portion 43f, and the piezoelectric element 43d is deformed due to the piezoelectric effect after being applied with a driving voltage, thereby driving the suspension plate 43a to vibrate in a bending manner, and a small amount of adhesive is applied to the assembly surface 431b of the outer frame 43b, such that the piezoelectric actuator 43 is attached to the fixing portion 42C of the resonator plate 42 in a thin type piezoelectric actuator 43b, such that the piezoelectric actuator 43 can be combined with the resonator plate 42, and the piezoelectric actuator 43b is sequentially stacked on the lower surface 43 b.

As shown in fig. 4C, after the gas inlet plate 41, the resonator plate 42, the piezoelectric actuator 43, the insulating sheet 44 and the conductive sheet 45 of the gas pump 4 are sequentially stacked and combined, wherein a chamber gap g is formed between the suspension plate 43a and the resonator plate 42, and the chamber gap g will affect the transmission effect of the gas actuator 11, so that it is very important to maintain a fixed chamber gap g for providing stable transmission efficiency for the gas pump 4. the gas pump 4 of the present invention uses a stamping method for the suspension plate 43a to recess downward, so that the surface 431a of the of the suspension plate 43a and the assembly surface 431b of the outer frame 43b are both non-coplanar, that is, the surface 431a of the of the suspension plate 43a is lower than the assembly surface 431b of the outer frame 43b, and the second surface 432a of the suspension plate 43a is lower than the lower surface 432b of the outer frame 43b, so that the recess space of the suspension plate 43a of the piezoelectric actuator 43 can be adjusted to form a space with the resonator plate 3942, and the chamber gap g formed by adjusting the resonator plate 43a, thereby achieving the advantages of simplifying the cavity gap 4643 g formed by adjusting the piezoelectric actuator 43 a.

Fig. 4D to 4F are schematic diagrams illustrating the operation of the gas pump 4 shown in fig. 4C, first referring to fig. 4D, the piezoelectric element 43D of the piezoelectric actuator 43 is deformed to drive the floating plate 43a to move downward after being applied with a driving voltage, at the same time, the volume of the chamber space 46 is increased to form a negative pressure in the chamber space 46, so as to draw air in the bus chamber 41C into the chamber space 46, the resonator 42 is synchronously moved downward under the influence of the resonance principle, the volume of the bus chamber 41C is increased, and the air in the bus chamber 41C is also in a negative pressure state due to the air entering the chamber space 46, so as to draw air into the bus chamber 41C through the bus holes 41b and the air inlet hole 41a, and then referring to fig. 4E, the piezoelectric element 43D drives the floating plate 43a to move upward to compress the chamber space 46, so that the air in the chamber space 46 is forced to pass through the gap 43E to be transferred downward, and the effect of transferring air is achieved, and at least the resonator 42a is continuously moved downward by the gas suction hole 41C through the bus hole 41b and the gas inlet hole 41C, and the gas is pushed by the resonance plate 43a, so that the gas is continuously pushed to the gas is pushed downward by the gas suction hole 41C, and the gas is continuously pushed to be transferred to the chamber 41C, and the gas suction hole 41C, and the gas is continuously transferred to the gas pump 41C, and the gas is transferred to the gas inlet hole 41C, and the gas sensing device, and the gas is continuously transferred to be transferred to the gas inlet hole 3542 b, and the gas inlet hole 41C.

Referring to fig. 4C, the gas actuator 11 is gas pump 4, and the gas pump 4 can also be a mems gas pump manufactured by a mems process, wherein the gas inlet plate 41, the resonator plate 42, the piezoelectric actuator 43, the insulating plate 44, and the conductive plate 45 can be manufactured by a surface micromachining technique to reduce the volume of the whole pump.

Referring to fig. 5A, 5B to 5D, the gas actuator 11 may also be a BLOWER gas PUMP 5(BLOWER PUMP), and includes a plurality of blowing hole sheets 51, a cavity frame 52, an actuating body 53, an insulating frame 54 and a conductive frame 55 stacked in sequence, the blowing hole sheet 51 includes a plurality of connecting members 51a, suspension sheets 51B and hollow holes 51c, the suspension sheets 51B are capable of bending and vibrating, the connecting members 51a are adjacent to the periphery of the suspension sheets 51B, in the embodiment, the number of the connecting members 51a is 4, the hollow holes 51c are respectively adjacent to 4 corners of the suspension sheets 51B, but not limited thereto, the hollow holes 51c are formed at the center of the suspension sheets 51B, the cavity frame 52 is stacked on the suspension sheets 51B, the actuating body 53 is stacked on the cavity frame 52, and includes piezoelectric carrier plates 53a, 56 tuning resonance plates 53B, 39 c, 53a is stacked on the cavity frame 52, the piezoelectric tuning resonance plates 53B is disposed on the piezoelectric carrier plates 53B, the piezoelectric carrier plates 53a is disposed on the piezoelectric tuning resonance frame 52, the piezoelectric carrier plates 53B is disposed on the piezoelectric carrier plates 53a, the piezoelectric tuning piezoelectric carrier plates 53B, the piezoelectric carrier plates 53B is disposed on the piezoelectric carrier plates 53B, the piezoelectric carrier plates 53a, the piezoelectric carrier plates 53B, the piezoelectric carrier plates.

Referring to fig. 5B to 5D, an operation diagram of the blower box gas pump 5 of the present disclosure is shown, first, referring to fig. 5B, the blower box gas pump 5 is positioned through a plurality of connectors 51a, such that the blower box gas pump 5 is disposed in the gas exhaust passage 16, the air injection hole piece 51 and the bottom surface of the gas exhaust passage 16 are disposed at an interval, and an air flow chamber 57 is formed therebetween, referring to fig. 5C, when a voltage is applied to the piezoelectric plate 53C of the actuating body 53, the piezoelectric plate 53C starts to deform due to a piezoelectric effect and synchronously drives the tuning resonance plate 53B and the piezoelectric carrier plate 53a, at this time, the air injection hole piece 51 is driven by a Helmholtz resonance (Helmholtz resonance) principle , such that the actuating body 53 moves upward, such that a volume of the air flow chamber 57 increases, an internal air pressure forms a negative pressure, air outside the blower box gas pump 5 is driven by a positive pressure gradient through the connectors 51a plurality of connectors and a side wall of the air flow chamber 57 and moves into the air flow chamber 57, such that the air flow sensor compresses the air flow chamber 57, and the air flow sensor 5C compresses the air flow is configured to detect the air flow chamber 57, and the air flow chamber 57.

Of course, the blower box gas pump 5 of the present invention can also be a mems gas pump manufactured by a mems process, wherein the gas injection hole plate 51, the cavity frame 52, the actuator 53, the insulating frame 54 and the conductive frame 55 can be manufactured by a surface micromachining technique to reduce the overall volume of the pump.

In the embodiment shown in fig. 3, the gas monitoring inlet 10a and the gas monitoring outlet 10b are respectively provided with protective films 10g for sealing, the protective films 10g are waterproof, dustproof and gas penetrable films, the protective films 10g have the International Protection certification (IEC 60529) IP64, that is, the dustproof rating is 6 (completely dustproof, dust can not enter), the waterproof rating is 4 (anti-splashing, water splashes onto the equipment from any angle without negative effect), but not limited thereto, the protective rating of the protective films 10g can also be the International certification IP68, that is, the International certification is the International certification of the waterproof rating is 6, that is, the dustproof rating is 6, water splashes onto the equipment from any angle without negative effect, and the waterproof rating is also not limited to water immersion.

As shown in fig. 1C and 6, the particle monitoring module 2b is disposed in communication between the particle monitoring inlet 10C and the particle monitoring outlet 10d, the particle monitoring module 2b includes at least particle actuator 21, at least particle sensor 22 and 0 second compartment body 23, carrying partition 24, particle monitoring base 27 and 3 laser emitter 28, the inner space of the second compartment body 23 defines monitoring inlet channel 25 and 5 monitoring outlet channel 26 by the carrying partition 24, the monitoring inlet channel 25 is correspondingly communicated with the particle monitoring inlet 10C, the monitoring outlet channel 26 is correspondingly communicated with the particle monitoring outlet 10d, the carrying partition 24 also has a monitoring communication port 241 for communicating the monitoring inlet channel 25 with the monitoring outlet channel 26, and the particle monitoring base 27 is disposed adjacent to the carrying partition 24 and is accommodated in the monitoring inlet channel 25, the inlet channel 271 has a receiving slot 271, monitoring channels 272, beam channels 273 and receiving chamber 274, the actuator 271 is disposed on the receiving slot 272, the receiving slot 272 and is disposed on the receiving slot 272 for receiving the particle monitoring channel 272, the particle monitoring gas sensor 272, the particle monitoring channel 272, the particle monitoring device 272 is disposed on the receiving slot 272, and the receiving laser emitter and monitoring channel 272, the receiving laser emitter is disposed to receive particle monitoring device 272, the laser emission information from the laser emitter and from the laser emitter 34, the laser emitter and from the laser emitter to monitor emitter 34, the monitoring device 272, the laser emitter to monitor particle monitoring device 272, the monitoring outlet 20, the particle monitoring channel 272, the particle monitoring device is disposed to provide information for monitoring device 272, the particle monitoring device for monitoring device 272, the particle monitoring device 272 for monitoring device 272, the particle monitoring device for.

The particle actuator 21 of the particle monitoring module 2a may be gas pump 4 or bellows gas pump 5, the gas pump 4 is positioned above the supporting groove 271 of the particle monitoring base 27 for implementing gas transmission, the bellows gas pump 5 is positioned above the supporting groove 271 of the particle monitoring base 27 for implementing gas transmission through a plurality of connectors 51a, and the structure and operation of the pump are as described above for the gas pump 4 and the bellows gas pump 5, which are not described herein.

Referring to fig. 1C and fig. 7A to 7E, the above-mentioned purge gas module 3a is disposed in communication between the purge inlet 10E and the purge outlet 10f, the purge gas module 3a includes at least a purge actuator 31, at least a purge unit 32 and a third compartment body 33, the third compartment body 33 is provided with an air guide channel 34 and a a purge channel 35, the air guide channel 34 is correspondingly communicated with the purge inlet 10E, an end of the purge channel 35 is communicated with the air guide channel 34, an end of the is communicated with the purge outlet 10f, the purge actuator 31 is disposed in the purge channel 35, the purge unit 32 is disposed in the purge channel 35, the purge actuator 31 controls the introduction of the gas from the purge inlet 10E to the air guide channel 34, the purge gas is purified by the purge channel 35 through the purge unit 32, and the purge gas is exhausted from the purge outlet 10 f.

As shown in fig. 7A, which is a cross-sectional view of an th embodiment of the purge unit 32 of the purge gas module 3a, the purge unit 32 may be a kinds of filter units, which include a plurality of filters 32a, in this embodiment, two filters 32a are respectively disposed in the purge channel 35 to maintain a spacing, so that the gas is guided into the purge channel 35 by the purge actuator 31 to be adsorbed by the two filters 32a, so as to achieve the effect of purging the gas, wherein the filters 32a may be an electrostatic filter, an activated carbon filter, or a high efficiency filter (HEPA).

As shown in fig. 7B, which is a schematic cross-sectional view of a second embodiment of the purification unit 32 of the purification module 3a, the purification unit 32 may be kinds of photocatalyst units, which include photocatalyst 32B and ultraviolet lamp 32c, respectively, disposed in the purification channel 35 to maintain a spacing, so that the gas is guided into the purification channel 35 under the control of the purification actuator 31, and the photocatalyst 32B is irradiated by the ultraviolet lamp 32c to convert light energy into chemical energy to decompose harmful gas and sterilize the gas, so as to achieve the effect of purifying the gas.

As shown in fig. 7C, which is a schematic cross-sectional view of a second embodiment of the purifying unit 32 of the purifying gas module 3a, the purifying unit 32 may be kinds of optical plasma units, including d nano-light tubes, disposed in the purifying channel 35, so that the gas is guided into the purifying channel 35 through the control of the purifying actuator 31, and irradiated through the nano-light tubes 32d, so as to decompose oxygen molecules and water molecules in the gas into an ion flow with high oxidizing optical plasma that can destroy organic molecules, and decompose gas molecules containing volatile formaldehyde, toluene, volatile organic gas (VOC), etc. into water and carbon dioxide, so as to achieve the effect of purifying gas.

As shown in fig. 7D, a schematic cross-sectional view of a second embodiment of a purification unit 32 for purifying a gas module 3a, the purification unit 32 may be types of anion units, including at least types of electrode wires 32e, at least types of dust collecting plates 32f and type of boost power supply 32g, each of the electrode wires 32e and each of the dust collecting plates 32f are disposed in the purification module 3a for providing high voltage discharge to each of the electrode wires 32e, each of the dust collecting plates 32f is negatively charged, so that the gas is guided into the purification channel 35 through the purification actuator 31, and the high voltage discharge is performed through each of the electrode wires 32e, so as to positively charge particles contained in the gas and attach the positively charged particles to each of the negatively charged dust collecting plates 32f, thereby achieving the effect of purifying gas, the electrode wires 32e are made of a fiber bundle of a fullerene material, the fiber bundle of types of electrical material manufactured by applying nanotechnology, which is type of a material close to zero, which generates strong resonance effect when passing through the ionized particles, and is very much more effective for purifying carbon dioxide ions, and the carbon dioxide ions generated by a conventional purification unit 32a filter screen, which can not only needs a filter screen 32a filter screen for generating strong electrostatic discharge of carbon dioxide ion, but also can generate strong electrostatic discharge, a carbon fiber filter screen, which is made of carbon fiber ion, and which can generate a filter screen for purifying the environment (or a) and which can generate strong electrostatic purification unit 32a carbon fiber filter screen for generating strong electrostatic purification of carbon fiber ion, and which can generate strong electrostatic purification unit which can generate strong electrostatic purification effect, and which can generate strong.

As shown in fig. 7E, a schematic cross-sectional view of a second embodiment of the purifying unit 32 of the purifying gas module 3a, the purifying unit 32 may be plasma ion units, which include electric field upper guard nets 32H, adsorption filter nets 32i, high-voltage discharge electrodes 32j, electric field lower guard nets 32k and boost power supply 32g, wherein the electric field upper guard net 32H, the adsorption filter net 32i, the high-voltage discharge electrodes 32j and the electric field lower guard nets 32k are disposed in the purifying channel 35, and the adsorption filter net 32i, the high-voltage discharge electrodes 32j are disposed between the electric field upper guard net 32H and the electric field lower guard nets 32k, and the boost power supply 32g is disposed in the purifying gas module 3a to provide high-voltage discharge of the high-voltage discharge electrodes 32j to generate high-voltage plasma columns with plasma ions, so that the gas is guided into the purifying channel 35 through the purifying actuator 31, the oxygen molecules contained in the gas are ionized to generate cations (H +) and anions (O5-), and the water molecules are attached to the surfaces of the bacteria, and the bacteria are converted into the purifying gas by the purifying unit, and the purifying unit may be converted into the purifying unit by the hydrogen ion removing unit, the hydrogen ion units (H, the hydrogen ion removing unit) by the hydrogen ion removing unit) and the filter nets 32 a) with the hydrogen ion removing effect of course, the hydrogen ion removing effect of the hydrogen ion units (H and the hydrogen ion generating the filter nets).

The purge actuator 31 of the purge gas module 3a may be gas pump 4 or a bellows gas pump 5, the gas pump 4 is positioned above the purge channel 35 for implementation, the bellows gas pump 5 is positioned above the purge channel 35 for implementation through a plurality of connectors 51a, and the structure and operation of the bellows gas pump are as described above for the gas pump 4 and the bellows gas pump 5, which are not described herein.

In summary, the mobile devices with gas monitoring function provided by the present disclosure combine a gas monitoring module, a particle monitoring module and a purge gas module on a thin portable mobile device, and use the gas monitoring module and the particle monitoring module to monitor gas, so as to achieve the purpose of detecting the gas monitoring device at any time and anywhere, and have a fast and accurate monitoring effect.

Various modifications may be made by those skilled in the art without departing from the scope of the invention as defined by the appended claims.