CN208506006U - Gas-detecting device - Google Patents
Gas-detecting device Download PDFInfo
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- CN208506006U CN208506006U CN201820929715.9U CN201820929715U CN208506006U CN 208506006 U CN208506006 U CN 208506006U CN 201820929715 U CN201820929715 U CN 201820929715U CN 208506006 U CN208506006 U CN 208506006U
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Abstract
A kind of gas-detecting device includes: a casing ontology, is nested with tank and a monitoring chamber comprising one, this, which is nested with tank and is nested with for running gear, is combined into one;One gas detection module is mounted in the monitoring chamber of the casing ontology, includes an at least sensor and an at least actuator, actuator control gas imports inside the gas detection module, and is monitored by the sensor;One control module monitors starting running to control the driving signal of the gas detection module, and the monitoring data of the gas detection module are carried out to be converted into monitoring data storage, and can be sent to this action device and show and be uploaded to external device (ED) storage.
Description
Technical field
This case is about a kind of gas-detecting device, espespecially a kind of gas detection that is slim, portable, can carrying out gas-monitoring
Device.
Background technique
Modern more and more payes attention to the requirement of GAS QUALITY arround life, such as carbon monoxide, carbon dioxide, waves
Hair property organic matter (Volatile Organic Compound, VOC), PM2.5, nitric oxide, sulfur monoxide etc. gas, very
As for the particle contained in gas, can all expose in the environment influences human health, serious or even jeopardize life.Therefore ring
GAS QUALITY quality in border causes various countries to pay attention to one after another, and it is the project currently paid attention to that how urgent need, which will monitor, at present, which avoids separate,.
The quality for how confirming GAS QUALITY, monitored using a kind of gas sensor surrounding environmental gases be it is feasible,
If can provide monitoring information immediately again, the people at warning in the environment can prevent or flee from immediately, avoid by environment
Gas exposure causes Health Impact and injury, and ambient enviroment is monitored using gas sensor can say it is extraordinary answer
With.
However, portable apparatus is the outgoing running gear that can all carry of modern, therefore gas detection module is embedded
It is extremely to be taken seriously in portable apparatus, the development trend of especially current portable apparatus is light, thin and must have both
In high performance situation, how gas detection module to be thinned and is mounted on the application in portable apparatus, be provided with utilizing, be
The important topic that this case is researched and developed.
Utility model content
The main purpose of this case is to provide a kind of gas-detecting device, has can accommodate running gear to be nested with tank and appearance
The monitoring chamber for setting gas detection module can monitor user's ambient air quality using gas detection module at any time, and
Be able to quickly and stably introduce gas into gas detection module using actuator, not only promote sensor efficiency, but penetrate every
The compartment of chamber ontology designs, and actuator and sensor is spaced from each other, obstructing when sensor being enable to monitor reduces actuator
Heat source influence, be unlikely to influence sensor monitoring accuracy, also can not be by the other elements (control module) in device
Influence, and will test result immediately and be transmitted on running gear through connectivity port, reach can at any time, the mesh of detection gas everywhere
, and can have fast and accurately monitoring effect.
The one broad sense state sample implementation of this case is a kind of gas-detecting device, and include: a casing ontology is nested with tank comprising one
And a monitoring chamber, this, which is nested with tank and is nested with for running gear, is combined into one;One gas detection module is mounted on the casing sheet
It include an at least sensor and an at least actuator in the monitoring chamber of body, actuator control gas imports gas inspection
Inside modules are surveyed, and are monitored by the sensor;One control module, to control the driving signal of the gas detection module and
Monitoring starting running, and the monitoring data of the gas detection module are carried out to be converted into monitoring data storage, and can pass
It send to this action device and shows and be uploaded to external device (ED) storage.
Detailed description of the invention
Fig. 1 is the schematic diagram of this case gas-detecting device.
Fig. 2 is the diagrammatic cross-section of this case body detection device.
Fig. 3 A is the gas detection module associated components front appearance schematic diagram of this case gas-detecting device.
Fig. 3 B is the gas detection module associated components back appearance schematic diagram of this case gas-detecting device.
Fig. 3 C is the gas detection module associated components decomposition diagram of this case gas-detecting device.
Fig. 4 A is the actuator decomposition diagram of this case gas detection module.
Fig. 4 B is that another angle of actuator of this case gas detection module regards to obtain decomposition diagram.
Fig. 5 A is the actuator diagrammatic cross-section of this case gas detection module.
The actuator illustrative view of Fig. 5 B to Fig. 5 D this case gas detection module.
Fig. 6 is the gas detection module gas flow direction stereoscopic schematic diagram of this case gas-detecting device.
Fig. 7 is the gas detection module gas flow direction partial enlargement diagram of this case gas-detecting device.
Fig. 8 is the particulate matter monitoring module and control module appearance diagram of this case gas-detecting device.
Fig. 9 is the first embodiment block diagram of this case gas-detecting device.
Figure 10 is the second embodiment block diagram of this case gas-detecting device.
Description of symbols
1: casing ontology
11: being nested with tank
12: monitoring chamber
121: air inlet
122: gas outlet
13: connectivity port
2: gas detection module
21: compartment body
211: partition
212: first compartment
213: second compartment
214: notch
215: opening
216: venthole
217: accommodation groove
22: support plate
221: blow vent
222: connector
23: sensor
24: actuator
241: inlet plate
241a: air inlet
241b: confluence round
241c: confluence chamber
242: resonance plate
242a: hollow hole
242b: movable part
242c: fixed part
243: piezoelectric actuator
243a: suspension board
2431a: first surface
2432a: second surface
243b: outline border
2431b: surface is assembled
2432b: lower surface
243c: interconnecting piece
243d: piezoelectric element
243e: gap
243f: protrusion
2431f: boss surface
244: insulating trip
245: conductive sheet
246: cavity space
3: control module
31: processor
32: power supply module
4: running gear
5: external device (ED)
6: power supply unit
A: air flow path
G: chamber spacing
Specific embodiment
The some exemplary embodiments for embodying this case features and advantages will describe in detail in the explanation of back segment.It should be understood that
This case can have various variations in different aspects, all not depart from the range of this case, and explanation therein and diagram
It is illustrated as being used in itself, rather than to limit this case.
Fig. 1, Fig. 2 and Figure 10 are please referred to, this case provides a kind of gas-detecting device, comprising an at least casing ontology 1, at least
One gas detection module 2 and at least a control module 3, in order to avoid repeating, following embodiment explanation, casing ontology 1, gas
Detection module 2, control module 3 its quantity are given an example using one without exception, and but not limited to this.Casing ontology 1 has one
It is nested with tank 11, one and monitors chamber 12 and a connectivity port 13, be nested with tank 11 and be installed with wherein for a running gear 4, make casing
Ontology 1 is combined into one with Portable mobile device, and when running gear 4, which is located in, to be nested in tank 11, connectivity port 13 is supplied
To connect with running gear 4, running gear 4 is enable to provide electric energy to gas detection module 2 and control module 3;Gas detection
Module 2 is mounted in the monitoring chamber 12 of casing ontology 1, and gas detection module 2 is drawing gas into monitoring chamber 12
It is interior, and it is detected, and control module 3 is then connect with gas detection module 2, to control the driving of gas detection module 2
Signal and monitor starting running, and the monitoring data of gas detection module 2 be converted into monitoring data storage,
And it can transmit to set the display of running gear 4 and be uploaded to external device (ED) 5 and store;In addition, monitoring chamber 12 is further provided with an air inlet 121
An and gas outlet 122.
Again refering to shown in Fig. 2, Fig. 3 A to Fig. 3 C, gas detection module 2 above-mentioned includes a compartment body 21, a support plate
22, an at least sensor 23 and at least an actuator 24.In following embodiment, sensor 23 and actuator 24 its quantity are without exception
It is given an example using one, but not limited to this, and sensor 23 and actuator 24 also can be multiple.Wherein compartment body 21 is set
It is placed in 121 lower section of air inlet of monitoring chamber 12, and inside is distinguished by a partition 211 and forms a first compartment 212 and one second
Compartment 213, partition 211 have one section of notch 214, are interconnected for first compartment 212 and second compartment 213, and first compartment
212 have an opening 215, and there is second compartment 213 venthole 216 and 21 bottom of compartment body to be equipped with an accommodation groove
217, accommodation groove 217 stretches through to be placed in for support plate 22 and wherein position, and to close the bottom of compartment body 21, and support plate 22 is equipped with one
Blow vent 221, and a sensor 23 is encapsulated and is electrically connected on support plate 22, such support plate 22 is mounted on 21 lower section of compartment body,
Blow vent 221 will correspond to the venthole 216 of second compartment 213, and sensor 23 stretches through into the opening 215 of first compartment 212
And setting in first compartment 212, to detect the gas in first compartment 212, and actuator 24 is then set to second compartment
In 213, completely cut off with the sensor 23 that is set in first compartment 212, enables generated heat source when actuation of actuator 24
Hard to bear partition 211 obstructs, and does not go the testing result for influencing sensor 23, and actuator 24 closes the bottom of second compartment 213, and
Control actuating generates a delivery air-flow, then is discharged by the venthole 216 of second compartment 213, by the blow vent 221 of support plate 22
Gas is discharged in outside compartment body 21.
Please continue to refer to Fig. 3 A to Fig. 3 C, above-mentioned support plate 22 can be a circuit board, and have a connector 222 thereon,
Connector 222 stretches through for a circuit soft board (not shown) into connection, provides the electric connection of support plate 22 and signal connection.
Fig. 4 A to Fig. 5 A is please referred to again, and it includes the inlet plate sequentially stacked that above-mentioned actuator 24, which is a gas pump,
241, a resonance plate 242, a piezoelectric actuator 243, an insulating trip 244, a conductive sheet 245.Inlet plate 241 have at least one into
Stomata 241a, at least one confluence round 241b and one confluence chamber 241c, above-mentioned air inlet 241a and confluence round 241b its
Quantity is identical, and in this present embodiment, air inlet 241a and confluence round 241b are given an example with quantity 4, not as
Limit;4 air inlet 241a penetrate through 4 confluence round 241b respectively, and 4 confluence round 241b are flowed to confluence chamber 241c.
Above-mentioned resonance plate 242, permeable laminating type are connected on inlet plate 241, and are had in one on resonance plate 242
Emptying aperture 242a, a movable part 242b and a fixed part 242c, hollow hole 242a are located at the center of resonance plate 242, and and air inlet
The confluence chamber 241c of plate 241 is corresponding, and is set to around hollow hole 242a and the region opposite with confluence chamber 241c is
Movable part 242b, and the outer peripheral edge portion for being set to resonance plate 242 is posted solid on inlet plate 241 then as fixed part 242c.
Above-mentioned piezoelectric actuator 243 includes a suspension board 243a, an outline border 243b, at least an interconnecting piece 243c, one
Piezoelectric element 243d, at least a gap 243e and a protrusion 243f;Wherein, suspension board 243a is a positive square suspension board, is had
A second surface 2432a of first surface 2431a and opposite first surface 2431a, outline border 243b surround and are set to suspension board
The periphery of 243a, and outline border 243b has one to assemble surface 2431b and a lower surface 2432b, and penetrates an at least interconnecting piece
243c is connected between suspension board 243a and outline border 243b, to provide the support force of resilient support suspension board 243a, wherein at least
Gap of the one gap 243e between suspension board 243a, outline border 243b and interconnecting piece 243c, to for gas to pass through.In addition, outstanding
The first surface 2431a of kickboard 243a have protrusion 243f, protrusion 243f be in this present embodiment by the periphery of protrusion 243f and
The junction of interconnecting piece 243c is adjacent to through etch process, keeps its recessed, to make the protrusion 243f of suspension board 243a be higher than the
One surface 2431a forms step structure.
Again as shown in Figure 5A, the suspension board 243a of the present embodiment is adopted makes it to lower recess with stamping, distance of sinking
It can be formed between suspension board 243a and outline border 243b and be adjusted by an at least interconnecting piece 243c, made convex on suspension board 243a
Both surface 2431b that assembles of the boss surface 2431f and outline border 243b of portion 243f form non-co-planar, that is, protrusion 243f
What boss surface 2431f will be less than outline border 243b assembles surface 2431b, and the second surface 2432a of suspension board 243a is lower than outer
The lower surface 2432b of frame 243b, but piezoelectric element 243d is attached at the second surface 2432a of suspension board 243a, with protrusion 243f
It is oppositely arranged, piezoelectric element 243d is applied after driving voltage and generates deformation due to piezoelectric effect, and then drives suspension board
243a bending vibration;It is used in assembling for outline border 243b and is coated with a small amount of adhesive on the 2431b of surface, cause piezoelectricity with hot pressing mode
Dynamic device 243 fits in the fixed part 242c of resonance plate 242, so that piezoelectric actuator 243 is able to assemble knot with resonance plate 242
It closes.In addition, insulating trip 244 and conductive sheet 245 are all the slim sheet body of frame-type, sequentially it is stacked under piezoelectric actuator 243.Yu Ben
In embodiment, insulating trip 244 is attached at the lower surface 2432b of the outline border 243b of piezoelectric actuator 243.
Please continue to refer to Fig. 5 A, the inlet plate 241 of actuator 24, resonance plate 242, piezoelectric actuator 243, insulating trip 244,
After conductive sheet 245 sequentially stacks combination, a chamber wherein is formed between the first surface 2431a and resonance plate 242 of suspension board 243a
Room spacing g, chamber spacing g will will affect the laser propagation effect of actuator 24, therefore maintain a fixed chamber spacing g for actuator
The stable efficiency of transmission of 24 offers is particularly significant.The actuator 24 of this case to suspension board 243a use impact style, make its to
Lower recess allows both surface 2431b that assembles of the first surface 2431a and outline border 243b of suspension board 243a to be non-co-planar, also
That is what the first surface 2431a of suspension board 243a will be less than outline border 243b assembles surface 2431b, and the second table of suspension board 243a
Face 2432a is lower than the lower surface 2432b of outline border 243b, so that the suspension board 243a of piezoelectric actuator 243 is recessed to form a space
It obtains and constitutes an adjustable chamber spacing g with resonance plate 242, be directed through the suspension board 243a of above-mentioned piezoelectric actuator 243
The structural improvement that a cavity space 246 is constituted with shaped depression is adopted, in this way, which required chamber spacing g is able to through adjustment
The suspension board 243a shaped depression distance of piezoelectric actuator 243 is completed, and the structure for effectively simplifying adjustment chamber spacing g is set
The advantages that counting, while also reaching simplified processing procedure, shortening processing time.
Fig. 5 B to Fig. 5 D is the illustrative view of actuator 24 shown in Fig. 5 A, please referring initially to Fig. 5 B, piezoelectric actuator 243
Piezoelectric element 243d be applied after driving voltage and generate deformation and drive suspension board 243a to bottom offset, cavity space 246 at this time
Volume promoted, in foring negative pressure in cavity space 246, just draw confluence chamber 241c in air enter cavity space
In 246, while resonance plate 242 is influenced to be synchronized by resonance principle to bottom offset, related to increase confluence chamber 241c's
Volume, and because the air in confluence chamber 241c enters the relationship of cavity space 246, it causes equally to be negative in confluence chamber 241c
Pressure condition, and then entered in confluence chamber 241c by confluence round 241b, air inlet 241a come draw air;Referring again to figure
5C, piezoelectric element 243d drive suspension board 243a to shift up, and compression chamber space 246 forces the air in cavity space 246
It is transmitted downwards by an at least gap 243e, to achieve the effect that transmit air, the same to time, resonance plate 242 is equally suspended plate
243a is shifted up because of resonance, and the synchronous gas pushed in confluence chamber 241c is mobile toward cavity space 246;Finally please refer to
Fig. 5 D, when suspension board 243a is driven downwards, resonance plate 242 be also driven simultaneously and to bottom offset, resonance plate 242 at this time
It is mobile to an at least gap 243e will to make the gas in compression chamber space 246, and promotes the volume in confluence chamber 241c,
Gas can constantly be converged at by air inlet 241a, confluence round 241b in confluence chamber 241c, through constantly
It repeats the above steps, so that actuator 24 is continuously entered gas from air inlet 241a, then downward by an at least gap 243e
Transmission provides gas and senses to transfer meter 23 constantly to draw the entrance of the gas outside gas-detecting device, promotes sensing effect
Rate.
Please continue to refer to Fig. 5 A, its another embodiment of actuator 24 is a MEMS gas pump, wherein inlet plate
241, resonance plate 242, piezoelectric actuator 243, insulating trip 244, conductive sheet 245 all can pass through face type micro-processing technology and be made, with
Reduce the volume of actuator 24.
Please continue to refer to Fig. 6 and Fig. 7, when gas detection module 2 is embedded in the chamber of ontology 1, this ontology 1 is in legend
In gas detection module 2 for convenience of description gas flow direction, ontology 1 is given into transparency process in legend hereby, with
Just illustrate, and the air inlet 121 of ontology 1 correspond to compartment body 21 first compartment 212, the air inlet 121 of ontology 1 be located at
Both sensors 23 in first compartment 212 are not directly corresponding, that is, air inlet 121 is not positioned immediately on the top of sensor 23,
The two mutual dislocation so penetrates the control actuation of actuator 24, allows in second compartment 213 and initially forms negative pressure, starts to draw
Extraneous gas outside ontology 1, and import in first compartment 212, so that the sensor 23 in first compartment 212 starts for flowing through
Gas in its surface is monitored, with the GAS QUALITY outside detection body 1, and actuator 24 constantly actuation when, monitored
Gas will import second compartment 213 by the notch 214 on partition 211, finally by the ventilation of venthole 216, support plate 22
221 discharge of mouth is except compartment body 21, to constitute unidirectional gas delivery monitoring (such as Fig. 6 mark signified air flow path side A
To).
Above-mentioned sensor 23 can be gas sensor, include an oxygen sensor, a carbon monoxide transducer, a dioxy
Change at least one or its of carbon sensor, a temperature sensor, an ozone sensor and a volatile organic matter sensor
Combination;Or, above-mentioned sensor 23 can for bacterium sensor, viral sensor or microbiological sensor at least one or
A combination thereof.
As shown in the above description, gas-detecting device provided by this case, can be monitored at any time using gas detection module 2 is made
User's ambient air quality, and be able to quickly and stably introduce gas into gas detection module 2 using actuator 24,
23 efficiency of sensor is not only promoted, and penetrates the design of the first compartment 212 and second compartment 213 of compartment body 21, will be activated
Device 24 is spaced from each other with sensor 23, and sensor 23 is enable to obstruct the heat source influence for reducing actuator 24 when monitoring, unlikely
In the monitoring accuracy for influencing sensor 23, it is further possible to not influenced by the other elements in device, reach gas detection dress
The purpose that can be detected at any time, everywhere is set, and can have fast and accurately monitoring effect.
It is please referred to shown in Fig. 8 and Fig. 9 again again, the control module 3 of this case includes a processor 31, and processor 31 connects gas
Detection module 2 and connectivity port 13 make processor 31 be controlled the starting of actuator 24, and to 23 testing results of sensor
It is carried out being converted into monitoring data storage, and running gear 4 can be sent to show, and be uploaded to external device (ED) 5
Storage or display.External device (ED) 5 can for cloud system, portable apparatus, computer system, display device etc. one of them, with
Show monitoring data and notification warning.Wherein can pass through be wirelessly transmitted to external device (ED) 5, such as: Wi-Fi module, bluetooth module,
The radio interface of one of radio frequency identification module, a near field communication module etc. externally transmits.
Referring to Fig. 10, control module 3 further comprises a power supply module 32, to provide storage electric energy, output electric energy, and
Can arrange in pairs or groups an external power supply unit 6 stores to conduct electric energy and receive electric energy, so that electric energy is supplied to processor 31, makes processor
31 can be supplied to the electrical property and driving signal of gas detection module 2.Wherein power supply unit 6 is able to wired conduction pattern or wireless biography
The mode of leading conveys the electric energy and gives the storage of power supply module 32, and power supply module 52 further includes an at least rechargeable battery.In addition, power supply
Device 6 can also be received with wire transmission mode or wireless transmission method, export electric energy.Above-mentioned external device (ED) 5 can be a cloud
System, a portable apparatus, a computer system etc. at least one.
In conclusion gas-detecting device provided by this case, accommodates running gear using casing ontology, then with connecting pin
Mouth connect running gear with control module, so that gas detection module can monitor user's ambient air quality at any time,
Air quality information is transferred on running gear in time, is able to achieve the purpose that detect air quality anywhere or anytime, and not
User be will increase in order to learn air quality, the burden for separately carrying air quality sensor is also needed, in addition, utilizing actuator
Be able to quickly and stably introduce gas into gas detection module, not only promote sensor efficiency, but penetrate compartment body every
Room design, actuator and sensor are spaced from each other, and the heat source influence for reducing actuator is obstructed when sensor being enable to monitor,
It is unlikely to influence the monitoring accuracy of sensor, can not be also influenced by the other elements (control module) in device, reach gas
The purpose that body detection device can detect at any time, everywhere, and can have fast and accurately monitoring effect, finally, can be mentioned in this case
Power supply module is arranged in its casing ontology of the hollow body detection device of confession, and power supply module can provide electric power to gas detection module and row
Dynamic device mitigates user instantly and gos out and need to carry the burden of multiple electronic products to charge to running gear.
This case appointed as person familiar with the technology apply craftsman think and be it is all as modify, it is so neither de- such as attached claim
Be intended to Protector.
Claims (20)
1. a kind of gas-detecting device, characterized by comprising:
One casing ontology is nested with tank and a monitoring chamber comprising one, this is nested with tank and is nested with for a running gear and is combined into one
Body;
One gas detection module is mounted in the monitoring chamber of the casing ontology, comprising an at least sensor and at least consistent
Dynamic device, at least actuator control gas imports inside the gas detection module, and at least a sensor is supervised by this
It surveys;And
One control module monitors starting running to control the driving signal of the gas detection module, and by the gas detection mould
The monitoring data of block are carried out being converted into monitoring data storage, and are sent to this action device and are shown and be uploaded to outside one
Device storage.
2. gas-detecting device as described in claim 1, which is characterized in that the casing ontology is equipped with a connectivity port, is provided with
This action device is connected, this action device is promoted to provide electric energy to the gas detection module and the electrical property of the control module.
3. gas-detecting device as described in claim 1, which is characterized in that the monitoring chamber is equipped with an air inlet and an outlet
Mouthful.
4. gas-detecting device as claimed in claim 3, which is characterized in that the gas detection module include a compartment body and
One support plate, the compartment body are set to below the air inlet, and are distinguished inside by a partition and formed a first compartment and one second
There is a notch to be interconnected for the first compartment and the second compartment for compartment, the partition, and the first compartment has an opening,
The second compartment has a venthole, and the support plate is mounted below the compartment body and encapsulates and be electrically connected at least one biography
Sensor, an and at least sensor stretches through the opening setting in the first compartment, and this at least an actuator is mounted on this
Completely cut off in second compartment with an at least sensor, and at least actuator control gas is imported by the air inlet, and is penetrated
At least a sensor is monitored for this, then the venthole through the compartment body is discharged except the monitoring chamber.
5. gas-detecting device as described in claim 1, which is characterized in that an at least sensor for the gas detection module
Comprising an oxygen sensor, a carbon monoxide transducer and a carbon dioxide sensor at least one or combinations thereof.
6. gas-detecting device as described in claim 1, which is characterized in that an at least sensor for the gas detection module
Include a volatile organic matter sensor.
7. gas-detecting device as described in claim 1, which is characterized in that an at least sensor for the gas detection module
Comprising bacterium sensor, viral sensor or microbiological sensor at least one or combinations thereof.
8. gas-detecting device as described in claim 1, which is characterized in that an at least actuator for the gas detection module
For a MEMS gas pump.
9. gas-detecting device as described in claim 1, which is characterized in that an at least actuator for the gas detection module
For a gas pump, it includes:
One inlet plate has an at least air inlet, at least one confluence round and a confluence chamber, and wherein an at least air inlet supplies
Air-flow is imported, which corresponds to an at least air inlet, and the air-flow of an at least air inlet is guided to converge into
The confluence chamber;
There is one resonance plate a hollow hole to correspond to the confluence chamber, and be a movable part around the hollow hole;And
One piezoelectric actuator, setting corresponding with the resonance plate;
Wherein, between the resonance plate and the piezoelectric actuator there is a cavity space to make when so that the piezoelectric actuator being driven
Air-flow is imported by an at least air inlet for the inlet plate, is collected to the confluence chamber through at least one confluence round, is passed through
The hollow hole of the resonance plate generates resonance transfer air-flow by the movable part of the piezoelectric actuator and the resonance plate.
10. gas-detecting device as claimed in claim 9, which is characterized in that the piezoelectric actuator includes:
One suspension board, has a first surface and a second surface, which has a protrusion;
One outline border around the outside for being set to the suspension board, and has one to assemble surface;
An at least bracket is connected between the suspension board and the outline border, flexibly supports the suspension board to provide;And
One piezoelectric element is attached on the second surface of the suspension board, to apply voltage to drive the suspension plate benging to shake
It is dynamic;
Wherein, an at least stent forming is between the suspension board and the outline border, and makes the first surface of the suspension board and be somebody's turn to do
This of outline border assembles surface and is formed as non-co-planar structure, and the first surface of the suspension board and the sounding board is made to keep a chamber
Room spacing.
11. gas-detecting device as claimed in claim 9, which is characterized in that the gas pump includes that a conductive sheet and one are exhausted
Embolium, wherein the inlet plate, the resonance plate, the piezoelectric actuator, the conductive sheet and the insulating trip sequentially stack setting.
12. gas-detecting device as described in claim 1, which is characterized in that the control module includes a power supply module, is mentioned
For storage electric energy, output electric energy, electric energy is enable to be supplied to the electrical property of the gas detection module.
13. gas-detecting device as claimed in claim 12, which is characterized in that the power supply module is received with wire transmission and stored
Electric energy.
14. gas-detecting device as claimed in claim 12, which is characterized in that the power supply module exports electricity with wire transmission
Energy.
15. gas-detecting device as claimed in claim 12, which is characterized in that the power supply module is stored with radio transceiver
Electric energy.
16. gas-detecting device as claimed in claim 12, which is characterized in that the power supply module is to be wirelessly transferred output electricity
Energy.
17. gas-detecting device as claimed in claim 12, which is characterized in that the power supply module includes at least one charging electricity
Pond, to store electric energy, output electric energy.
18. gas-detecting device as claimed in claim 2, which is characterized in that the control module includes a processor, with control
An at least sensor for the gas detection module, this at least the driving signal of an actuator and start, and to this at least one pass
Sensor and particle sensor institute testing result carry out being converted into a monitoring data, which links by the connectivity port
This action device shows and is uploaded to external device (ED) storage.
19. gas-detecting device as claimed in claim 18, which is characterized in that the external device (ED) is a cloud system, one can
Portable device, a computer system etc. at least one.
20. a kind of gas-detecting device, characterized by comprising:
An at least casing ontology is nested with tank and at least one monitoring chamber comprising at least one, this at least one is nested with tank at least
One running gear, which is nested with, to be combined into one;
An at least gas detection module is mounted in at least one monitoring chamber of an at least casing ontology, includes at least one
Sensor and at least an actuator, at least actuator control gas imports inside an at least gas detection module, and passes through
Crossing this, at least a sensor is monitored;And
An at least control module, with control this at least the driving signal of a gas detection module and monitor starting running, and should
The monitoring data of an at least gas detection module be converted into an at least monitoring data storage, and be sent to this at least one
Running gear shows and is uploaded to the storage of an at least external device (ED).
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CN201820929715.9U CN208506006U (en) | 2018-06-15 | 2018-06-15 | Gas-detecting device |
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CN201820929715.9U CN208506006U (en) | 2018-06-15 | 2018-06-15 | Gas-detecting device |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20240011958A1 (en) * | 2022-07-05 | 2024-01-11 | Gus Hammond | Portable gas sensing device |
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2018
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20240011958A1 (en) * | 2022-07-05 | 2024-01-11 | Gus Hammond | Portable gas sensing device |
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