TWI836330B - Fan for air pollution prevention - Google Patents

Abstract

A fan for air pollution prevention is disclosed and includes a main body, a blower, a filtering and cleaning assembly and an air detection module. The main body is configured to form a guiding path. The blower is disposed on the guiding path to direct the air for convection. The filtering and cleaning assembly is disposed on the guiding path and filters and cleans the air pollutant in the air guided by the blower. The air detection module is disposed on the guiding path, detects the air pollutant and transmits an air detection data.

Description

Air pollution prevention electric fan

The present invention relates to an electric fan with the function of filtering and detecting air pollution, and in particular to an electric fan for preventing and controlling air pollution.

As people pay more and more attention to the quality of the air around them, suspended particles (PM) such as PM ₁ , PM _2.5 , PM ₁₀ , carbon dioxide, total volatile organic compounds (Total Volatile Organic Compound, TVOC), formaldehyde... Such gases as well as the particles, aerosols, bacteria, viruses, etc. contained in the gas will affect human health when exposed to the environment, and even endanger life in severe cases.

At present, indoor air quality is not easy to control. In addition to outdoor air quality, indoor environmental conditions and pollution sources are the main factors affecting indoor air quality, especially dust, bacteria and viruses caused by poor indoor air circulation.

In view of this, in order to provide a purification solution that can instantly purify the indoor air quality and reduce the harmful gases breathed indoors, and can monitor the indoor air quality in real time anytime and anywhere, improve the indoor air quality, and quickly purify the indoor air, which is the main topic developed by this invention.

The main purpose of the present invention is to provide an air pollution prevention and control electric fan, which can detect the indoor air pollution quality through a gas detection module, and instantly understand the ambient air quality status. It can also use the air duct fan to divert the air pollution source, and filter the air pollution source in real time through the filter purification component. The microcontroller can also receive the data detected by the gas detection module to control the start of the air duct fan and adjust the diversion air volume, so as to enable the ambient air quality to be detected in real time and the air pollution source to be filtered and processed in real time.

To achieve the above-mentioned purpose, a more general implementation of the present invention is to provide an air pollution prevention and control electric fan, comprising: a main body, configured to form a flow guide path; a wind guide fan, configured on the flow guide path, to guide air convection; a filtering and purifying component, configured on the flow guide path, and filtering and purifying an air pollution source in the air convection guided by the wind guide fan 2; at least one gas detection module, configured on the flow guide path, to detect the air pollution source, and transmit a gas detection data.

In order to achieve the above purpose, another broader implementation aspect of this case is to provide an electric fan for preventing and controlling air pollution, which includes: a main body configured to form a diversion path; an air guide fan configured on the diversion path to guide air Convection; a filtering and cleaning component is arranged on the guide path, and filters and cleans an air pollution source in the air convection guided by the draft fan; at least one gas detection module is arranged on the guide path, detecting Detect the air pollution source and transmit a gas detection data; and a micro-control system device receives the gas detection data of the gas detection module through wireless transmission, intelligently compares the status of the monitoring mechanism, and issues driving instructions to Control the starting operation of the air guide fan and the adjustment of the air guide volume.

1: Subject

2: Air guide fan

3: Filter and purify components

31: Activated carbon

32: High efficiency filter

33: Zeolite Network

34: Photocatalyst unit

35: Photoplasma unit

36: Negative ion unit

37: Plasma ion unit

4: Gas detection module

41: Control circuit board

42: Gas detection subject

421: Base

4211: First surface

4212: Second surface

4213:Laser setting area

4214:Intake groove

4214a:Inlet vent

4214b: Translucent window

4215: Air guide component carrying area

4215a:Ventilation hole

4215b: Positioning bump

4216: Air outlet groove

4216a: Air outlet

4216b: First interval

4216c: Second interval

422: Piezoelectric actuator

4221: Air jet hole piece

4221a: Suspension sheet

4221b: Hollow hole

4221c:gap

4222: Cavity frame

4223: Actuator

4223a: Piezoelectric carrier plate

4223b: Adjust the resonance plate

4223c: Piezoelectric plate

4223d: Piezoelectric pin

4224: Insulation frame

4225: Conductive frame

4225a: Conductive pin

4225b: Conductive electrode

4226:Resonance Chamber

4227: Airflow chamber

423:Driver circuit board

424:Laser components

425:Particle sensor

426: Outer cover

4261: Side panels

4261a: Air intake frame

4261b: Air outlet frame opening

427:Gas sensor

43:Microprocessor

44:Communicator

5: Microcontroller

6: Air pollution treatment system

6a: Outdoor gas detection module

6b: Indoor gas detection module

6c: Gas exchange processing device

6d: Indoor cleaning and filtering device

6e: Intelligent control processing device

7: Cloud processing system

A:Indoors

B:Outdoor

L: diversion path

Figure 1A is a schematic diagram of the electric arm type air pollution prevention electric fan of the present invention.

Figure 1B is a schematic diagram of the centrifugal air pollution prevention electric fan of the present invention.

Figure 1C is a schematic diagram of the operation of a centrifugal air pollution prevention electric fan according to the present invention.

Figure 1D is a schematic diagram of the filtering and purifying assembly of the air pollution prevention and control electric fan of the present invention.

Figure 2A is a schematic diagram of the air pollution prevention and control electric fan connected to the cloud processing system of the present invention.

Figure 2B is a schematic diagram of the air pollution treatment system of the electric fan for air pollution prevention and control according to the present invention.

Figure 3 is a schematic diagram of the three-dimensional assembly of the gas detection module of the electric fan for preventing and controlling air pollution of the present invention.

Figure 4A is a schematic diagram of the three-dimensional assembly of the gas detection main body of the gas detection module of the present invention.

Figure 4B is a schematic diagram of the three-dimensional combination of the gas detection main body of the gas detection module of the present invention from another viewing angle.

Figure 4C is a three-dimensional exploded schematic diagram of the gas detection main body of the gas detection module of the present invention.

Figure 5A is a schematic three-dimensional view of the base of the gas detection body of the gas detection module of the present invention.

Figure 5B is a three-dimensional schematic diagram of the base of the gas detection body of the gas detection module of the present invention from another viewing angle.

Figure 6 is a schematic three-dimensional view of the base of the gas detection body of the gas detection module of the present invention combined with the laser component.

Figure 7A is a three-dimensional schematic diagram of the piezoelectric actuator and base of the gas detection body of the gas detection module of the present invention.

Figure 7B is a three-dimensional schematic diagram of the piezoelectric actuator and base assembly of the gas detection body of the gas detection module of the present invention.

Figure 8A is a three-dimensional exploded schematic diagram of the piezoelectric actuator of the gas detection body of the gas detection module of the present invention.

Figure 8B is a three-dimensional exploded schematic diagram of the piezoelectric actuator of the gas detection body of the gas detection module of the present invention from another perspective.

Figure 9A is a schematic cross-sectional view of the piezoelectric actuator of the gas detection body of the gas detection module of the present invention.

Figure 9B is a cross-sectional schematic diagram of the piezoelectric actuator of the gas detection body of the gas detection module of the present invention in action.

Figure 9C is a cross-sectional schematic diagram of the second operation of the piezoelectric actuator of the gas detection body of the gas detection module of the present invention.

Figure 10A is a schematic cross-sectional view of the gas inlet of the gas detection body of the gas detection module of the present invention.

Figure 10B is a schematic cross-sectional view of the gas detection body of the gas detection module of the present invention.

Figure 10C is a schematic cross-sectional view of the gas discharge of the gas detection body of the gas detection module of the present invention.

The embodiments that embody the features of the present invention will be described in detail in the following description. It should be understood that the present invention can have various variations in different forms, all of which do not deviate from the scope of the present invention, and the descriptions and illustrations therein are essentially for illustrative purposes rather than for limiting the present invention.

Please refer to FIG. 1A , FIG. 1B and FIG. 1C . The present invention provides an air pollution prevention and control electric fan, which includes a main body 1 , an air guide fan 2 , a filtering and purifying component 3 , at least one gas detection module 4 and a micro-control system 5 . The main body 1 is configured to form a flow path L; the air guide fan 2 is configured on the flow path L to guide air convection; the filtering and purifying component 3 is configured on the flow path L to filter and purify the air pollution source in the air convection guided by the air guide fan 2; at least one gas detection module 4 is configured on the flow path L to detect the air pollution source and transmit the gas detection data; the microcontroller system 5 receives the gas detection data of the gas detection module 4 in a wireless transmission mode, performs intelligent comparison of the monitoring mechanism status, and issues a driving command to control the startup operation of the air guide fan 2 and the adjustment of the air guide volume. Among them, the monitoring mechanism status is defined as the gas detection data detected by the gas detection module 4 at the air pollution source exceeding the safety detection value.

It is worth noting that the above-mentioned air duct 2 can be an example of an air pollution prevention and control fan with an armature type air duct 2 as an embodiment, or an example of an air pollution prevention and control fan with a centrifugal type air duct 2 as an embodiment as shown in Figure 1A or Figure 1C, but it is not limited to this. Any air duct 2 that can generate air flow and fluid flow is an extension of the embodiment of this case. In addition, it is worth noting that the filter purification component 3 is placed after the gas detection module 4 (as shown in Figure 1A) or the gas detection module 4 is placed after the filter purification component 3 (as shown in Figure 1C) is protected by this case. In addition, it is worth noting that after the microcontroller 5 receives the gas detection data detected by the gas detection module 4 in a wireless manner, it intelligently judges and issues a driving command to control the start-up of the air duct fan 2 or adjust the air volume. That is, as the gas detection data is greater than the safety detection value, the air volume of the air duct fan 2 is adjusted to be larger, and as the gas detection data is closer to the safety detection value, the air volume of the air duct fan 2 is adjusted to be smaller.

Please refer to Figures 3 to 9A. The gas detection module 4 mentioned above includes: a control circuit board 41, a gas detection body 42, a microprocessor 43 and a communicator 44. Among them, the gas detection body 42, the microprocessor 43 and the communicator 44 are packaged on the control circuit board 41 to form an integral body and are electrically connected to each other. And the microprocessor 43 controls the detection operation of the gas detection main body 42. The gas detection main body 42 detects the air pollution source and outputs a detection signal. The microprocessor 43 receives the detection signal and calculates and processes the output to promote the gas detection module. The microprocessor 43 of group 4 forms gas detection data and provides it to the communicator 44 for external communication and transmission. The external communication transmission of the above-mentioned communicator 44 can be a wired two-way communication transmission, such as USB, mini-USB, micro-USB, or a wireless two-way communication transmission, such as a Wi-Fi module, a Bluetooth module, Radio frequency identification modules, near field communication modules, etc. The microcontroller 5 receives the gas detection data transmitted by the communicator 44 through wireless transmission.

The gas detection body 42 includes a base 421, a piezoelectric actuator 422, a driving circuit board 423, a laser assembly 424, a particle sensor 425, an outer cover 426 and a gas sensor 427. The base 421 has a first surface 4211, a second surface 4212, a laser setting area 4213, an air inlet groove 4214, a gas guide assembly carrying area 4215 and an air outlet groove 4216. The first surface 4211 and the second surface 4212 are two surfaces arranged opposite to each other. The laser assembly 424 is hollowed out from the first surface 4211 toward the second surface 4212. In addition, the outer cover 426 covers the base 421 and has a side plate 4261, and the side plate 4261 has an air inlet frame 4261a and an air outlet frame 4261b. The air inlet groove 4214 is formed by being recessed from the second surface 4212 and is adjacent to the laser setting area 4213. The air inlet groove 4214 has an air inlet opening 4214a, which is connected to the outside of the base 421 and corresponds to the air inlet frame 4261a of the outer cover 426, and the two side walls of the air inlet groove 4214 have penetrating light-transmitting windows 4214b, which are connected to the laser setting area 4213. Therefore, the first surface 4211 of the base 421 is covered by the outer cover 426, and the second surface 4212 is covered by the driving circuit board 423, so that the air intake groove 4214 defines an air intake path.

The air guide component carrying area 4215 is formed by the second surface 4212 being recessed and connected to the air inlet groove 4214, and a vent hole 4215a is passed through the bottom surface, and the four corners of the air guide component carrying area 4215 are respectively provided with a positioning bump 4215b. The above-mentioned air outlet groove 4216 is provided with an air outlet port 4216a, and the air outlet port 4216a is arranged corresponding to the air outlet frame port 4261b of the outer cover 426. The air outlet groove 4216 includes a first section 4216b formed by a depression of the vertical projection area of the first surface 4211 with respect to the air guide component carrying area 4215, and an area extending from the vertical projection area of the non-air guide component carrying area 4215, and a second section 4216c formed by hollowing out from the first surface 4211 to the second surface 4212, wherein the first section 4216b is connected to the second section 4216c to form a step difference, and the first section 4216b of the air outlet groove 4216 is communicated with the air vent 4215a of the air guide component carrying area 4215, and the second section 4216c of the air outlet groove 4216 is communicated with the air outlet port 4216a. Therefore, when the first surface 4211 of the base 421 is covered by the outer cover 426 and the second surface 4212 is covered by the driving circuit board 423, the air outlet groove 4216 and the driving circuit board 423 together define an air outlet path.

Furthermore, the above-mentioned laser component 424 and particle sensor 425 are both installed on the drive circuit board 423 and located in the base 421. In order to clearly illustrate the positions of the laser component 424, particle sensor 425 and the base 421, they are deliberately omitted. Driving circuit board 423, in which the laser component 424 is housed in the laser setting area 4213 of the base 421, and the particle sensor 425 is housed in the air inlet groove of the base 421 into slot 4214 and aligned with laser assembly 424. In addition, the laser component 424 corresponds to the light-transmitting window 4214b, and the light-transmitting window 4214b allows the laser light emitted by the laser component 424 to pass through, so that the laser light irradiates the air inlet groove 4214. The path of the beam emitted by the laser component 424 passes through the light-transmitting window 4214b and forms an orthogonal direction to the air inlet groove 4214. The laser component 424 emits a beam of light and enters the air inlet groove 4214 through the light-transmitting window 4214b. The gas in the air inlet groove 4214 is irradiated. When the light beam contacts the suspended particles in the gas, it will be scattered and produce a projected light spot, causing the The particle sensor 425 is located at its orthogonal position and receives the projected light points generated by scattering and performs calculations to obtain gas detection data. In addition, the gas sensor 427 is positioned on the drive circuit board 423 and is electrically connected to the drive circuit board 423, and is accommodated in the gas outlet groove 4216 for detecting gas pollution introduced into the gas outlet groove 4216. In a preferred implementation of the present invention In this example, the particle sensor 425 detects suspended particulate information, and the gas sensor 427 is a volatile organic compound sensor that detects carbon dioxide or total volatile organic compound gas information; or it is a formaldehyde sensor that detects formaldehyde gas information; or it is a formaldehyde sensor that detects formaldehyde gas information. A bacterial sensor detects bacterial information and fungal information; or a virus sensor detects virus gas information; or a temperature and humidity sensor detects gas temperature and humidity information.

And, the piezoelectric actuator 422 is accommodated in the square gas guide component carrying area 4215 of the base 421. In addition, the gas guide component carrying area 4215 is connected to the air inlet groove 4214. When the piezoelectric actuator 422 is actuated, the gas in the air inlet groove 4214 is drawn into the piezoelectric actuator 422, and the gas passes through the vent hole 4215a of the gas guide component carrying area 4215 and enters the air outlet groove 4216. And, the driving circuit board 423 is sealed on the second surface 4212 of the base 421. The laser component 424 is disposed on the driving circuit board 423 and is electrically connected. The particle sensor 425 is also disposed on the driving circuit board 423 and is electrically connected. When the outer cover 426 is covered on the base 421, the air inlet frame opening 4261a corresponds to the air inlet vent 4214a of the base 421, and the air outlet frame opening 4261b corresponds to the air outlet vent 4216a of the base 421.

And, the piezoelectric actuator 422 includes an air jet plate 4221, a cavity frame 4222, an actuator 4223, an insulating frame 4224 and a conductive frame 4225. The air jet plate 4221 is a flexible material and has a suspension plate 4221a and a hollow hole 4221b. The suspension plate 4221a is a bending and vibrating sheet structure, and its shape and size correspond to the inner edge of the air guide component bearing area 4215, and the hollow hole 4221b passes through the center of the suspension plate 4221a for gas circulation. In the preferred embodiment of the present invention, the shape of the suspension plate 4221a can be one of square, graphic, elliptical, triangular or polygonal.

Furthermore, the cavity frame 4222 is stacked on the air hole sheet 4221, and its appearance corresponds to the air hole sheet 4221. The actuator 4223 is stacked on the cavity frame 4222, and defines a resonance chamber 4226 between the actuator 4223, the air hole sheet 4221, and the suspension sheet 4221a. The insulation frame 4224 is stacked on the actuator 4223, and its appearance is similar to the cavity frame 4222. The conductive frame 4225 is stacked on the insulating frame 4224, and its appearance is similar to the insulating frame 4224. The conductive frame 4225 has a conductive pin 4225a and a conductive electrode 4225b, wherein the conductive pin 4225a extends outward from the outer source of the conductive frame 4225, and the conductive electrode 4225b extends inward from the inner edge of the conductive frame 4225.

In addition, the actuating body 4223 further includes a piezoelectric carrier plate 4223a, an adjusting resonance plate 4223b and a piezoelectric plate 4223c. Among them, the piezoelectric carrier plate 4223a is stacked on the cavity frame 4222. The adjusted resonance plate 4223b is stacked on the piezoelectric carrier plate 4223a. The piezoelectric plate 4223c is stacked on the adjusted resonance plate 4223b. The adjusting resonance plate 4223b and the piezoelectric plate 4223c are accommodated in the insulating frame 4224. The piezoelectric plate 4223c is electrically connected to the conductive electrode 4225b of the conductive frame 4225. Among them, in the preferred embodiment of the present invention, the piezoelectric carrier plate 4223a and the adjustable resonance plate 4223b are both made of conductive materials. The piezoelectric carrier board 4223a has a piezoelectric pin 4223d, and the piezoelectric pin 4223d and the conductive pin 4225a are connected to the driving circuit (not shown) on the driving circuit board 423 to receive the driving signal (which can be the driving frequency and driving frequency). voltage), the driving signal can be transmitted from the piezoelectric pin 4223d, the piezoelectric carrier plate 4223a, the adjustable resonance plate 4223b, the piezoelectric plate 4223c, the conductive electrode 4225b, the conductive frame 4225 and the conductive The electrical pins 4225a form a loop, and the insulating frame 4224 blocks the conductive frame 4225 from the actuating body 4223 to avoid short circuit, so that the driving signal can be transmitted to the piezoelectric plate 4223c. After receiving the driving signal, the piezoelectric plate 4223c deforms due to the piezoelectric effect, further driving the piezoelectric carrier plate 4223a and adjusting the resonance plate 4223b to generate reciprocating bending vibration.

To further explain, the tuning resonance plate 4223b is located between the piezoelectric plate 4223c and the piezoelectric carrier plate 4223a, and acts as a buffer between the two to adjust the vibration frequency of the piezoelectric carrier plate 4223a. Basically, the thickness of the tuning resonance plate 4223b is greater than that of the piezoelectric carrier plate 4223a, and the vibration frequency of the actuator 4223 is adjusted by changing the thickness of the tuning resonance plate 4223b. The air jet hole sheet 4221, the cavity frame 4222, the actuator 4223, the insulating frame 4224 and the conductive frame 4225 are stacked and positioned in sequence in the air guide component support area 4215, so that the piezoelectric actuator 422 is positioned in the air guide component support area 4215. The piezoelectric actuator 422 defines a gap 4221c between the suspension sheet 4221a and the inner edge of the air guide component support area 4215 for gas flow.

An airflow chamber 4227 is formed between the air jet plate 4221 and the bottom surface of the air guide component carrying area 4215. The airflow chamber 4227 is connected to the resonant chamber 4226 between the actuator 4223, the cavity frame 4222 and the suspension plate 4221a through the hollow hole 4221b in the air jet plate 4221. The vibration frequency of the gas in the resonant chamber 4226 is made close to the vibration frequency of the suspension plate 4221a, so that the resonant chamber 4226 and the suspension plate 4221a can generate a Helmholtz resonance effect, thereby improving the transmission efficiency of the gas. When the piezoelectric plate 4223c moves away from the bottom surface of the air-conducting component carrying area 4215, the piezoelectric plate 4223c drives the suspended plate 4221a of the air-jet hole plate 4221 to move away from the bottom surface of the air-conducting component carrying area 4215, so that the volume of the airflow chamber 4227 expands rapidly, the internal pressure drops to produce negative pressure, and the gas outside the piezoelectric actuator 422 is attracted to flow in from the gap 4221c and enter the resonance chamber 4226 through the hollow hole 4221b, thereby increasing the air pressure in the resonance chamber 4226 and generating a pressure gradient. When the piezoelectric plate 4223c drives the suspended plate 4221a of the air jet hole plate 4221 to move toward the bottom surface of the air guide component support area 4215, the gas in the resonance chamber 4226 flows out quickly through the hollow hole 4221b, squeezes the gas in the air flow chamber 4227, and makes the converged gas quickly and in large quantities through the vent hole 4215a of the air guide component support area 4215 in an ideal gas state close to Bernoulli's law.

By repeating the actions shown in Figure 9B and Figure 9C, the piezoelectric plate 4223c vibrates reciprocatingly. According to the inertia principle, the internal air pressure of the resonance chamber 4226 after exhaust is lower than the equilibrium air pressure, which will guide the gas to enter the resonance chamber 4226 again. In this way, the vibration frequency of the gas in the resonance chamber 4226 is controlled to be the same as the vibration frequency of the piezoelectric plate 4223c, so as to generate the Helmholtz resonance effect and realize high-speed and large-volume transmission of gas.

Please refer to Figures 10A to 10C. The gas enters from the air inlet frame 4261a of the outer cover 426, enters the air inlet groove 4214 of the base 421 through the air inlet port 4214a, and flows to the position of the particle sensor 425. Furthermore, the piezoelectric actuator 422 is continuously driven to absorb the gas in the air inlet path, so that the external gas is quickly introduced and circulated stably, and passes through the top of the particle sensor 425. At this time, the laser component 424 emits a light beam through the light-transmitting window 4214b into the air inlet groove 4214. The air inlet groove 4214 passes through the top of the particle sensor 425. When the light beam of the particle sensor 425 irradiates the suspended particles in the gas, the gas inlet groove 4214 is discharged. When suspended particles are present, scattering and projected light spots will be generated. When the particle sensor 425 receives the projected light spots generated by the scattering, it calculates to obtain relevant information such as the particle size and quantity of the suspended particles contained in the gas. In addition, the gas above the particle sensor 425 is continuously driven by the piezoelectric actuator 422 to be introduced into the vent hole 4215a of the gas guide component carrying area 4215 and enter the gas outlet groove 4216. Finally, after the gas enters the gas outlet groove 4216, since the piezoelectric actuator 422 continuously transports the gas into the gas outlet groove 4216, the gas in the gas outlet groove 4216 will be pushed and discharged to the outside through the gas outlet port 4216a and the gas outlet frame port 4261b.

Please refer to Figure 1D. The above-mentioned filtering and cleaning component 3 can be a combination of various implementation forms. In some specific embodiments, the filtering and cleaning component 3 can be an activated carbon 31, or the filtering and cleaning component 3 can be a high-efficiency filter. (High-Efficiency Particulate Air,HEPA)32, Or the filtering and cleaning component 3 can be composed of an activated carbon 31, a high-efficiency filter 32 and a zeolite mesh 33. Of course, the above-mentioned activated carbon 31 or high-efficiency filter 32 can be coated with a layer of chlorine dioxide as a cleaning factor to inhibit viruses, bacteria, and fungi in air pollution sources; the above-mentioned high-efficiency filter 32 can be coated with a layer of chlorine dioxide as a cleaning factor. Factor, the inhibition rate of viruses, bacteria, fungi, influenza A virus, influenza B virus, enterovirus, and norovirus in the gas pollution of the filter purification component 3 is over 99%, reducing cross-infection of viruses; the above-mentioned activated carbon 31 Or the high-efficiency filter 32 can also be coated with a layer of herbal protective coating extracted from ginkgo and Japanese salt bark to form a herbal protective anti-allergic filter, which can effectively resist allergies and destroy influenza virus surface proteins that pass through the high-efficiency filter 32 ( For example: H1N1); the above-mentioned activated carbon 31 or high-efficiency filter 32 can also be coated with silver ions to inhibit viruses, bacteria, and fungi in air pollution sources.

The above-mentioned activated carbon 31 is used to filter and adsorb suspended particulate matter 2.5 (PM _2.5 ), the zeolite mesh 33 is used to filter and adsorb volatile organic compounds (Volatile Organic Compound, VOC), and the high-efficiency filter 32 is used to adsorb chemical smog contained in the gas. Bacteria, dust particles and pollen pollute the gas introduced into the filtering and purifying component 3, thereby achieving the effect of filtering and purifying.

In some embodiments, the filtering and cleaning component 3 can also be composed of activated carbon 31, high-efficiency filter 32, zeolite mesh 33 and a photocatalyst unit 34, so that outdoor air pollution can be introduced into the filtering and cleaning component 3 through the photocatalyst. Unit 34 converts light energy into electrical energy, decomposes harmful substances in the gas and performs disinfection and sterilization to achieve the effects of filtering and purifying the gas.

In some embodiments, the filter purification component 3 may also be composed of activated carbon 31, a high-efficiency filter 32, a zeolite mesh 33 and a photoplasma unit 35. The photoplasma unit 35 includes a nanotube, which irradiates the gas pollution introduced by the filter purification component 3 through the nanotube, thereby promoting the decomposition and purification of volatile organic gases contained in the gas pollution. When the filter purification component 3 introduces gas pollution, the nano-light tube irradiates the introduced gas, decomposing the oxygen molecules and water molecules in the gas into highly oxidizing photoplasmas, forming an ion gas flow that destroys organic molecules, and decomposing gas molecules such as volatile formaldehyde, toluene, and volatile organic compounds (VOC) in the gas into water and carbon dioxide, achieving the effect of filtering and purifying the gas.

In some embodiments, the filter purification component 3 may also be composed of activated carbon 31, high-efficiency filter 32, zeolite mesh 33 and negative ion unit 36, and the negative ion unit 36 includes a dust inlet plate. The filter purification component 3 discharges the gaseous pollution introduced from the outdoor B with high voltage, and attaches the particles contained in the gaseous pollution with positive charge to the negatively charged dust inlet plate, thereby achieving the effect of filtering and purifying the introduced gaseous pollution.

In some embodiments, the filtration and cleaning component 3 can also be composed of activated carbon 31, high-efficiency filter 32, zeolite mesh 33 and a plasma ion unit 37. The plasma ion unit 37 generates a high-voltage plasma column. The plasma ions in the high-voltage plasma column are decomposed into the filtering and cleaning component 3 to remove viruses and bacteria in the gas pollution introduced from outdoor B, and through the plasma ions, the oxygen molecules and water molecules contained in the gas are ionized to generate cations (H ⁺ ) and anions (O ₂ ^- ), with water molecules attached around the ions attached to the surface of viruses and bacteria. Under the action of chemical reactions, they will be converted into highly oxidizing active oxygen (hydroxyl, OH groups), thus It takes away the hydrogen from the surface proteins of viruses and bacteria and oxidizes and decomposes them to achieve the effect of filtering and purifying the introduced gas.

In some embodiments, the filtration and cleaning component 3 can only have a high-efficiency filter 32; or the high-efficiency filter 32 can be combined with any one of the photocatalyst unit 34, the photoplasma unit 35, the negative ion unit 36, and the plasma ion unit 37; or The high-efficiency filter 32 is matched with a combination of any two units of the photocatalyst unit 34, the photoplasma unit 35, the negative ion unit 36, and the plasma ion unit 37; or the high-efficiency filter 32 is matched with the photocatalyst unit 34, the photoplasma unit 35, and the negative ion unit 36. , any three-unit combination of the plasma ion unit 37; or all combinations of the high-efficiency filter 32 with the photocatalyst unit 34, the photo-plasma unit 35, the negative ion unit 36, and the plasma ion unit 37.

In short, in some specific embodiments, the filtering and cleaning component 3 can be one of activated carbon 31, high-efficiency filter 32, zeolite mesh 33, photocatalyst unit 34, photoplasma unit 35, negative ion unit 36, and plasma ion unit 37. one or a combination thereof.

The air pollution source in this case refers to one or a combination of suspended particles, carbon monoxide, carbon dioxide, ozone, sulfur dioxide, nitrogen dioxide, lead, total volatile organic compounds, formaldehyde, bacteria, fungi and viruses.

The above-mentioned micro-control system 5 receives the gas detection data of the gas detection module 4 through wireless transmission, and intelligently compares the status of the monitoring mechanism. The status of the monitoring mechanism is detected by the gas detection module 4 at the air pollution source. The gas detection data exceeds the safe detection value. In some embodiments, the safety detection value means that the number of suspended particles 2.5 is less than 35 μg/m ³ , the carbon dioxide concentration is less than 1000 ppm, the total volatile organic matter concentration is less than 0.56 ppm, the formaldehyde concentration is less than 0.08 ppm, and the bacterial count is less than 1500 CFU/ m ³ , the number of fungi is less than 1000CFU/m ³ , the sulfur dioxide concentration is less than 0.075ppm, the nitrogen dioxide concentration is less than 0.1ppm, the carbon monoxide concentration is less than 9ppm, the ozone concentration is less than 0.06ppm or the lead concentration is less than 0.15μg/m ³ .

From the above description, the present invention provides an electric fan for preventing and controlling air pollution, which detects the quality of indoor air pollution through the gas detection module 4 and understands the ambient air quality status in real time. It can also use the air guide 2 to divert the source of air pollution and filter it through The purifying component 3 instantly filters air pollution, and can also use the microcontroller 5 to receive the data detected by the gas detection module 4 to control the start of the air guide fan 2 and adjust the air guide volume, achieving an autonomous detection mode for prevention and control. The air pollution electric fan enables real-time detection of ambient air quality and real-time filtering of air pollution sources.

Please refer to Figure 2A. In some specific embodiments, the air pollution prevention electric fan provided by the present invention can be combined with a cloud processing system 7. The microcontroller 5 transmits the gas detection data detected by the gas detection module 4 of the air pollution prevention electric fan to the cloud processing system 7 via wireless transmission. The microcontroller 5 transmits the gas detection data detected by the gas detection module 4 of the air pollution prevention electric fan to the cloud processing system 7. The microcontroller 5 receives the information transmitted by the cloud processing system 7 to issue a driving command to control the start-up operation of the air duct 2 and the adjustment of the air flow volume.

It is worth noting that in the embodiment of Figure 2A, the air pollution prevention and control electric fan is not limited to the armature type. The centrifugal air pollution prevention and control electric fan can also be bidirectionally transmitted to the cloud for processing through the micro-control system device 5 through wireless transmission. System 7 transmits the gas detection data detected by the gas detection module 4 to the cloud processing system 7, and receives the information transmitted by the cloud processing system 7 to issue driving instructions to control the starting operation of the air guide fan 2 and the adjustment of the air guide volume. . In addition, it is worth noting that the start-up of the air guide fan 2 or the size of the air guide volume can be directly controlled manually through the micro-control system 5, or the size of the air guide volume can be automatically adjusted through artificial intelligence of the cloud processing system 7, and a drive command is issued to adjust the guide volume. The air guide volume of fan 2; that is, as the gas detection data is greater than the safety detection value, the adjustment of the air guide volume of fan 2 is greater, and the closer the gas detection data is to the safety detection value, the air guide volume of fan 2 is The smaller the adjustment of the air guide volume. In addition, it is worth noting that if multiple sets of the air pollution prevention and control electric fans described in this case are placed in the same indoor space, the cloud processing system 7 can also detect the gas detection modules 4 of the air pollution prevention and control electric fans at different locations. Based on different gas detection data, the cloud processing system 7 will also transmit control signals to the corresponding air pollution prevention and control electric fans according to different levels of air quality conditions. The microcontroller 5 will control the starting operation of the air guide fan 2 and the air guide volume. Adjust.

Please refer to Figure 2B. In some specific embodiments, the air pollution prevention and control electric fan provided by the present invention can be combined with the indoor air pollution treatment system 6. The microcontroller 5 transmits bidirectional transmission to the air pollution treatment system 6 through wireless transmission. The micro-control system device 5 transmits the gas detection data detected by the gas detection module 4 of the air pollution prevention and control electric fan to the air pollution treatment system 6, or the micro-control system device 5 can receive the information transmitted by the air pollution treatment system 6 , to issue a driving command to control the starting operation of the air guide fan 2 and the adjustment of the air guide volume.

The above-mentioned air pollution treatment system 6 includes: at least one outdoor gas detection module 6a, at least one indoor gas detection module 6b, at least one gas exchange processing device 6c, at least one indoor cleaning and filtering device 6d, and an intelligent control process Device 6e.

The above-mentioned at least one outdoor gas detection module 6a is installed outside B, detects the air pollution source outside B, and transmits outdoor gas detection data. And at least one indoor gas detection module 6b is installed in indoor A to detect air pollution sources in indoor A and transmit indoor gas detection data. It is worth noting that the start-up of the air guide fan 2 or the size of the air guide volume can be directly controlled manually through the micro-control system 5, or the air guide volume can be automatically adjusted through artificial intelligence of the air pollution treatment system 6, and a drive command is issued to adjust the air guide fan. 2. Air guide volume. The outdoor gas detection module 6a is installed in outdoor B, and detects the air quality in outdoor B, and outputs outdoor gas detection data; while the indoor gas detection module 6b is installed in indoor A, and detects the air in indoor A. Quality, output indoor gas detection data. The outdoor gas detection module 6a or the indoor gas detection module 6b can be, for example, a gas detection module 4 that detects air quality and outputs gas detection data.

At least one gas exchange processing device 6c controls whether the external gas from outdoor B is introduced into the space of indoor A, so as to filter and exchange the air pollution source of indoor A. At least one indoor purification filter device 6d activates the air pollution source of indoor A. The intelligent control processing device 6e receives and compares the outdoor gas detection data and the indoor gas detection data, and provides intelligent selection of the gas exchange processing device 6c to operate the introduction or non-introduction of the external gas from outdoor B.

After receiving and comparing the outdoor gas detection data and the indoor gas detection data, the intelligent control processing device 6e provides the intelligent selection gas exchange processing device 6c to operate the introduction or non-introduction of the external gas to the outdoor B, and the intelligent control processing device 6e instantly controls at least one indoor purification filter device 6d to filter and purify, so that the air pollution source in the indoor A can be filtered and exchanged to form a fresh air. It is worth noting that the indoor purification filter device 6d can be an air conditioner, a range hood, an exhaust fan, a purifier, a vacuum cleaner, a hair dryer, etc. Each indoor clean filter device 6d is equipped with an indoor gas detection module 6b to detect the air pollution source in room A and control the startup and operation of the indoor clean filter device 6d.

Therefore, after the intelligent control processing device 6e receives and compares the outdoor gas detection data and the indoor gas detection data, when it determines that the indoor gas detection data is inferior to the outdoor gas detection data, it sends a control signal to the gas exchange processing device 6c, and introduces the external gas into the indoor space A, and sends a control to start at least one indoor purification filter device 6d for filtering and purification, but it is not limited to this.

Of course, after receiving the outdoor gas detection data and the indoor gas detection data, the intelligent control processing device 6e can intelligently select and send information control instructions to at least one indoor purification filter device 6d after comparison. It can also intelligently select and send information control instructions to the micro-control system 5 of the air pollution prevention and control electric fan to start the operation, so that the micro-control system 5 can issue a driving instruction to control the start-up operation of the air guide fan 2 and the adjustment of the air guide volume, so as to enable the air pollution source in the room A to be filtered to form a fresh air.

In the embodiment of Figure 2B, at least three indoor gas detection modules 6b are used, and the intelligent control processing device 6e receives and compares the indoor gas detection data detected by at least three indoor gas detection modules 6b to implement intelligent control. Calculation is used to find the location of the air pollution source area in indoor space A, and intelligently selects and controls the activation of the gas exchange processing device 6c or the indoor cleaning and filtering device 6d near the air pollution source to accelerate the guidance of the air pollution source. Keep the attraction from spreading; and the intelligent control processing device 6e receives and compares the indoor gas detection data detected by at least three indoor gas detection modules 6b to perform intelligent calculations to find out the air pollution in the indoor space A. In the source area, the gas exchange processing device 6c or the indoor purifying and filtering device 6d near the air pollution source is activated first. At the same time, the intelligent control processing device 6e can use artificial intelligence calculations to activate the remaining indoor purifying and filtering devices 6d to form an air flow. The air pollution source is guided to the indoor cleaning filter device 6d near the air pollution source for rapid filtration.

In summary, the present invention is an air pollution prevention and control electric fan, which detects indoor air quality through a gas detection module, and instantly understands the state of ambient air quality. It can also use a duct fan to drain air pollution sources, and filter air pollution instantly through a filter purification component. It can also use a microcontroller to receive data detected by the gas detection module to control the start of the duct fan and adjust the diversion air volume, so that the ambient air quality can be detected instantly and the air pollution source can be filtered and processed instantly. It not only has the ability to detect ambient air quality autonomously, but also can be connected to a cloud processing system or an indoor air pollution treatment system mode to form a complete instant processing system, which is extremely valuable for industrial use.

1:Subject

2: Air guide fan

3: Filter and purify components

4: Gas detection module

5: Microcontroller system

L: diversion path

Claims (25)

An electric fan for air pollution prevention and control, including: a main body configured to form a flow diversion path; an air guide fan disposed on the flow diversion path to guide air convection; a filtering and cleaning component disposed on the flow diversion path, And filter and clean an air pollution source in the air convection guided by the air guide fan; at least one gas detection module is configured on the flow guide path to detect the air pollution source and transmit a gas detection data; And a micro-control system device receives the gas detection data of the gas detection module through wireless transmission, makes an intelligent comparison of the status of the monitoring mechanism, and issues a drive command to control the starting operation and air guide volume of the air guide fan. Adjustment, wherein the micro-control system transmits bidirectional transmission to an air pollution treatment system through wireless transmission, wherein the gas detection data detected by the gas detection module of the air pollution prevention electric fan is transmitted to the air pollution treatment system , and receive a piece of information transmitted by the air pollution treatment system to issue the drive command to control the starting operation of the air guide fan and the adjustment of the air guide volume. An electric fan for air pollution prevention and control as described in claim 1, wherein the air pollution source refers to suspended particles, carbon monoxide, carbon dioxide, ozone, sulfur dioxide, nitrogen dioxide, lead, total volatile organic compounds, formaldehyde, bacteria, fungi and viruses. one or a combination thereof. The electric fan for air pollution prevention and control as described in claim 1, wherein the status of the monitoring mechanism is when the gas detection data detected by the gas detection module at the air pollution source exceeds a safe detection value. For the air pollution prevention and control electric fan as described in claim 3, the safety detection value refers to the suspended particulate matter 2.5 amount less than 35μg/ ^m3 , the carbon dioxide concentration value less than 1000ppm, the total volatile organic matter concentration value less than 0.56ppm, the formaldehyde concentration value less than 0.08ppm, the bacteria amount less than 1500CFU/ ^m3 , the fungus amount less than 1000CFU/ ^m3 , the sulfur dioxide concentration value less than 0.075ppm, the nitrogen dioxide concentration value less than 0.1ppm, the carbon monoxide concentration value less than 9ppm, the ozone concentration value less than 0.06ppm or the lead concentration value less than 0.15μg / ^m3 . As described in claim 1, the air pollution prevention and control electric fan, wherein the gas detection module comprises a control circuit board, a gas detection body, a microprocessor and a communicator, wherein the gas detection body, the microprocessor and the communicator are packaged on the control circuit board to form a whole and are electrically connected, and the microprocessor controls the detection operation of the gas detection body, the gas detection body detects the air pollution source and outputs a detection signal, the microprocessor receives the detection signal and calculates and processes the output, prompting the microprocessor of the gas detection module to form the gas detection data and provide it to the communicator for external communication transmission. The air pollution prevention and control electric fan as described in claim 5, wherein the microcontroller receives the gas detection data transmitted by the communicator via wireless transmission. The air pollution prevention electric fan according to claim 5, wherein the gas detection body includes: a base having: a first surface; a second surface, relative to the first surface; and a laser setting area, It is hollowed out from the first surface toward the second surface; an air inlet groove is formed recessed from the second surface and is adjacent to the laser setting area. The air inlet groove is provided with an air inlet opening and two The side walls respectively pass through a light-transmitting window and are connected with the laser setting area; an air guide component carrying area is recessed from the second surface and connected with the air inlet groove, and has a vent hole on a bottom surface; and an air outlet The groove is recessed from the first surface corresponding to the bottom surface of the air guide component carrying area, and is hollowed out from the first surface toward the second surface in the area of the first surface that does not correspond to the air guide component carrying area. Formed, connected to the vent hole, and provided with an air outlet; a piezoelectric actuator accommodated in the air guide component carrying area; a driving circuit board with a cover attached to the second surface of the base; a laser component positioned on the driving circuit board and electrically connected to it and correspondingly accommodated in the laser setting area, and An emitted beam path passes through the light-transmitting window and forms an orthogonal direction to the air inlet groove; a particle sensor is positioned on the drive circuit board and is electrically connected to it, and is correspondingly accommodated in the air inlet The groove is located at an orthogonal direction to the path of the beam projected by the laser component, for detecting particles contained in the air pollution source that pass through the air inlet trench and are irradiated by the beam projected by the laser component. Detection; a gas sensor positioned on the drive circuit board and electrically connected thereto, and accommodated in the air outlet trench for detecting the air pollution source introduced into the air outlet trench; and an outer cover , the cover is covered on the base and has a side plate. The side plate is provided with an air inlet frame opening and an air outlet frame opening. The air inlet frame opening corresponds to the air inlet opening of the base, and the air outlet frame opening corresponds to the air inlet opening of the base. The air outlet of the base; wherein, the outer cover covers the base, and the drive circuit board is attached to the second surface so that the air inlet groove defines an air inlet path, and the air outlet groove defines Create an air outlet path to drive the piezoelectric actuator to accelerate and guide the air source outside the air inlet vent of the base into the air inlet defined by the air inlet groove from the air inlet frame opening The particle sensor detects the particle concentration of the particles contained in the air pollution source through the path, and the air pollution source is then discharged from the vent hole into the air outlet trench through the gas sensor for detection. Measure, and finally discharge from the air outlet of the base to the air outlet frame. The air pollution prevention electric fan as described in claim 7, wherein the particle sensor is used to detect suspended particle information. The air pollution prevention electric fan as described in claim 7, wherein the gas sensor contains a volatile Organic matter sensor detects carbon dioxide or total volatile organic matter gas information. As described in claim 7, the air pollution prevention electric fan, wherein the gas sensor includes a formaldehyde sensor to detect formaldehyde gas information. The air pollution prevention electric fan described in claim 7, wherein the gas sensor includes a bacteria sensor to detect bacteria or fungi information. As described in claim 7, the air pollution prevention electric fan, wherein the gas sensor includes a virus sensor to detect virus gas information. The air pollution prevention electric fan described in claim 7, wherein the gas sensor includes a temperature and humidity sensor to detect the temperature and humidity information of the gas. The air pollution prevention and control electric fan described in claim 1, wherein the micro-control system device bidirectionally transmits to a cloud processing system through wireless transmission, wherein the gas detection module of the air pollution prevention and control electric fan transmits the gas detected by the air pollution prevention and control electric fan. The gas detection data is sent to the cloud processing system, and the information transmitted by the cloud processing system is received to issue the drive command to control the starting operation of the air guide fan and the adjustment of the air guide volume. The air pollution prevention and control electric fan as described in claim 1, wherein the air pollution treatment system comprises: at least one outdoor gas detection module and at least one indoor gas detection module, at least one outdoor gas detection module is arranged outdoors to detect the air pollution source outdoors and transmit an outdoor gas detection data, and at least one indoor gas detection module is arranged indoors to detect the air pollution source indoors and transmit an indoor gas detection data; at least one gas exchange processing device is used to control whether an external gas outdoors is introduced into the indoors. The space is used to filter and exchange the indoor air pollution source; at least one indoor clean filter device is used to start filtering and exchanging the indoor air pollution source; an intelligent control processing device receives and compares the outdoor gas detection data and the indoor gas detection data, and provides intelligent selection of the gas exchange processing device to operate or not to introduce the external gas outdoors, and the intelligent control processing device controls at least one indoor clean filter device in real time to filter and purify, so that the indoor air pollution source can be filtered and exchanged to form fresh air. The electric fan for air pollution prevention and control as described in claim 15, wherein the intelligent control processing device receives the outdoor gas detection data and the indoor gas detection data and intelligently selects and sends a control instruction of the information to the prevention and control device through comparison. The micro-control system of the air pollution electric fan starts operation, so that the micro-control system sends the drive command to control the start-up operation of the air guide fan and the adjustment of the air guide volume, so that the air pollution source in the room can be filtered and formed. Another breath of fresh air. As described in claim 15, the air pollution prevention electric fan, wherein the intelligent control processing device receives and compares the indoor gas detection data detected by at least three indoor gas detection modules to implement intelligent calculations to find the location of the air pollution source area in the indoor space, and intelligently selects and controls the gas exchange processing device or the indoor purification filter device near the air pollution source to start, so as to accelerate and guide the air pollution source to maintain attraction without diffusion. The air pollution prevention electric fan as described in claim 15, wherein the intelligent control processing device receives and compares the indoor gas detection data detected by at least three of the indoor gas detection modules to perform intelligent calculations for In order to find the location of the air pollution source area in the indoor space, the gas exchange processing device or the indoor purification and filtration device near the air pollution source is activated first, and at the same time, the intelligent control processing device can use artificial intelligence calculations to filter out the remaining air pollution sources. A plurality of the indoor cleaning and filtering devices are activated to form an airflow to guide the air pollution source to the indoor cleaning and filtering devices near the air pollution source for rapid filtration. The air pollution prevention and control electric fan as described in claim 1, wherein the filtering and cleaning component is an activated carbon. The electric fan for preventing and controlling air pollution as described in claim 1, wherein the filtering and cleaning component is a high-efficiency filter. The electric fan for air pollution prevention and control as described in claim 1, wherein the filtering and cleaning component is composed of an activated carbon, a high-efficiency filter and a zeolite mesh. The air pollution prevention electric fan as described in claim 1, wherein the filter cleaning component is coated with a layer of The cleaning factor of chlorine dioxide inhibits viruses and bacteria in air pollution sources. As described in claim 1, the air pollution prevention electric fan, wherein the filter purification component is coated with a layer of herbal protective coating extracted from ginkgo and Japanese saltwort, forming a herbal protective anti-allergic filter. The electric fan for preventing and controlling air pollution as described in claim 1, wherein the filter cleaning component is coated with a silver ion to inhibit viruses and bacteria in the air pollution source. The electric fan for air pollution prevention and control as described in claim 21, wherein the filtering and cleaning component is activated carbon, the high-efficiency filter, the zeolite mesh, a photocatalyst unit, a photoplasma unit, a negative ion unit, and a plasma ion unit one of them or a combination thereof.

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