INDOOR AIR CLEANING SYSTEM

Description

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to Taiwan Patent Application No. 113106687, filed on Feb. 23, 2024. The entire contents of the above-mentioned patent application are incorporated herein by reference for all purposes.

FIELD OF THE INVENTION

The present disclosure relates to an indoor air cleaning system, and more particularly to an indoor air cleaning system having at least one air cleaning component and a gas detection module integrated into one piece and disposed in an indoor field for detecting, locating, circulating and filtering air pollution, to meet a clean room requirement of ZAPClean Room 1˜9.

BACKGROUND OF THE INVENTION

Suspended particles are defined as the solid particles or droplets contained in the air. Due to their extremely fine size, the suspended particles may enter the lungs of human body through the nasal hair in the nasal cavity easily, causing inflammation in the lungs, asthma or cardiovascular disease. If other pollutant compounds are attached to the suspended particles, it will further increase the harm to the respiratory system. In recent years, the issue of air pollution has been increasingly severe, especially with consistently high concentrations of suspended particles (e.g., PM2.5). Therefore, the monitoring to the concentration of the gas suspended particles is taken more and more seriously. However, the gas flows unstably due to the variable wind direction and the air volume, and the general gas-quality monitoring station is located in a fixed place. Under this circumstance, it is impossible for people to check the concentration of suspended particles in current environment.

Furthermore, in recent years, modern people are placing increasing importance on the quality of the air in their surroundings. For example, carbon monoxide, carbon dioxide, volatile organic compounds (VOC), PM2.5, nitric oxide, sulfur monoxide and even the suspended particles contained in the air are exposed in the environment to affect the human health, and even endanger the life seriously. Therefore, the quality of environmental air has attracted the attention of various countries. At present, how to detect the air quality and avoid the harm is a crucial issue that urgently needs to be solved.

In order to confirm the quality of the air, it is feasible to use a gas sensor to detect the air surrounding in the environment. If the detection information can be provided in real time to warn the people in the environment, it is helpful of avoiding the harm and facilitates the people to escape the hazard immediately, preventing the hazardous gas exposed in the environment from affecting the human health and causing the harm. Therefore, it is considered a valuable application to use a gas sensor detecting the air in the surrounding environment.

In addition, it is difficult to have the surveillance and control the indoor air quality. Besides the outdoor air quality, the indoor air-conditioning conditions and the pollution sources are the major factors affecting the indoor air quality. It is necessary to intelligently and quickly detect indoor air pollution sources in various indoor fields, effectively remove the indoor air pollution to form a clean and safe breathing gas state, and monitor indoor air quality in real time anytime, anywhere. Certainly, if the concentration of the suspended particles in the indoor space field is strictly controlled according to the “clean room” standard, it allows to avoid the introduction, generation and retention of suspended particles, and the temperature and humidity in the indoor space field are controlled within the required range. That is to say, the number of suspended particles in the air pollution of the indoor space field is used to distinguish their classifications, so that it allows the indoor space field to meet the clean room requirements for safe breathing.

At present, the air pollution detection of the indoor air purification system is implemented by the gas detector to transmit the air pollution information, and then the air pollution information is transmitted to the cloud computing service device through the Internet of Things communication, so that the air pollution information of the outdoor field and the indoor field is stored to form a big data database of air pollution data. Based on the intelligent calculation and comparison of the big data database of air pollution data, a control command is intelligently selected to be sent to the fan of the circulating filtering device to start the regulation operation. In that, an internal circulation directed airflow is continuously generated in the indoor field, and the air pollution is directed multiple times to be filtered and removed, so that the gas state in the indoor field has suspended particles meeting a clean room requirement of ZAPClean Room 1˜9. Therefore, how to regulate the above-mentioned cleaning devices in conjunction with the gas detection module is the main subject of the present disclosure.

SUMMARY OF THE INVENTION

One object of the present disclosure is to provide an indoor air cleaning system. An air cleaning device includes at least one air cleaning component and a gas detection module assembled into one piece, disposed in an indoor field for detecting, locating, circulating and filtering air pollution, and installed in the indoor field through a build-in or plug-in manner. The gas detection module implements air pollution detection to output air pollution data. Moreover, a networked cloud computing service device receives the air pollution data through the wireless communication or the wired communication. Since the communication transmission can be achieved by using the wireless communication or the wired communication, the dual methods of the wired communication and the wireless communication are selected to implement an operable transmission communication mechanism. The intelligent computing comparison based on the database of the air pollution data is performed to intelligently select and output the control command. Then, the control command is transmitted to the gas detection module to regulate the activation operation of the air cleaning device through an operable transmission communication mechanism of the wired communication and the wireless communication. In that, the air pollution processing operation of the air cleaning device is controlled. Thereby, a gas state of the air pollution in the indoor field reaches a clean room requirement of ZAPClean Room 1˜9.

In accordance with an aspect of the present disclosure, an indoor air cleaning system is provided, and includes at least one air cleaning device and a networked cloud computing service device. The air cleaning device includes at least one ventilation pipe, at least one gas cleaning component, at least one central control and regulation device, at least one communication module and least one gas detection module. The ventilation pipeline includes at least one gas guiding port, at least one gas inlet and at least one gas outlet, and the gas cleaning component and the gas detection module are disposed and integrated in the ventilation pipeline for detecting, locating, circulating and filtering air pollution in the indoor field. The gas detection module detects the air pollution to generate air pollution data and transmit the air pollution data to the communication module for networking output, and the central control and regulation device is connected to the gas detection module through wired communication for regulating operations of the gas detection module, so that the gas detection module is allowed controlling processing operations of the air cleaning component to filter the air pollution. The networked cloud computing service device receives the air pollution data through communication transmission. The air pollution data are received and stored to form a big data database of the air pollution, and a control command is intelligently selected to be send based on intelligent calculation and comparison of the air pollution data, and received and transmitted through the communication module to the gas detection module, so that the processing operations of the air cleaning component are controlled to filter the air pollution, and a gas state of the air pollution in the indoor field reaches a clean room requirement of ZAPClean Room 1˜9.

BRIEF DESCRIPTION OF THE DRAWINGS

The above contents of the present disclosure will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:

FIG. 1A is a schematic diagram illustrating a transmission relationship between gas detection modules of an indoor air cleaning system according to an embodiment of the present disclosure through wired communication or wireless communication;

FIG. 1B is a schematic view illustrating then indoor air cleaning system implemented in an indoor field according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram illustrating a regulation-device control circuit of the gas detection module in the indoor air cleaning system according to an embodiment of the present disclosure;

FIG. 3A is a schematic diagram illustrating the combination of the fan and filtering element of the air cleaning device of the present disclosure;

FIG. 3B is a schematic diagram illustrating the combination of the filtering elements of the air cleaning device of the present disclosure;

FIG. 3C is a schematic diagram illustrating the regulation operation of relative components of the air cleaning device according to the embodiment of the present disclosure;

FIG. 3D is a schematic diagram illustrating the regulation operation of the air cleaning device with an ultraviolet lamp component according to an embodiment of the present disclosure;

FIG. 4A is a schematic perspective view illustrating the gas detection module implemented in the outdoor field or the indoor field according to the embodiment of the present disclosure;

FIG. 4B is a schematic perspective view illustrating the gas detection module implemented in the outdoor field or the indoor field according to the embodiment of the present disclosure and taken from another perspective;

FIG. 4C is a schematic perspective view illustrating the gas detection module according to the embodiment of the present disclosure;

FIG. 5 is a schematic diagram of the architecture of the cloud computing service device according to the embodiment of the present disclosure; and

FIGS. 6A to 6F show cleanliness level comparison table of the gas state of the air pollution in the indoor field reaching the clean room requirement of ZAPClean Room 1˜9.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present disclosure will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only. It is not intended to be exhaustive or to be limited to the precise form disclosed.

Please refer to FIG. 1A, FIG. 1B and FIG. 2. The present disclosure provides an indoor air cleaning system, which mainly includes at least one air cleaning device 1 and a networked cloud computing service device 2. The at least one air cleaning device 1 is disposed in an indoor field A. The air cleaning device 1 includes at least one ventilation pipe 10, at least one gas cleaning component 11, at least one central control and regulation device 12, at least one communication module 13 and least one gas detection module S. The ventilation pipeline 10 includes at least one gas guiding port 10a, at least one gas inlet 10b, at least one gas outlet 10c and at least one vent 10d. A primary filtering element H is disposed in the gas guiding port 10a of the ventilation pipeline 10, so that outdoor air can be introduced through the air inlet 10a into the ventilation pipeline 10 to flow through the primary filtering element H for preliminarily filtering the air pollution contained in the gas. The gas cleaning component 11 and the gas detection module S are disposed and integrated in the ventilation pipeline 10 for detecting, locating, circulating and filtering air pollution in the indoor field A. The gas detection module S detects the air pollution to generate air pollution data and transmit the air pollution data to the communication module 13 for networking output. The central control and regulation device 12 is connected to the gas detection module S through wired communication for regulating operations of the gas detection module, so that the gas detection module S is allowed controlling processing operations of the air cleaning component 11 to filter the air pollution. The networked cloud computing service device 2 receives the air pollution data through communication transmission. The air pollution data are received and stored to form a big data database of the air pollution, and a control command is intelligently selected to be send based on intelligent calculation and comparison of the air pollution data, and received and transmitted through the communication module 13 to the gas detection module S, so that the processing operations of the air cleaning component 11 are controlled to filter the air pollution, and a gas state of the air pollution in the indoor field reaches a clean room requirement of ZAPClean Room 1˜9.

Please refer to FIG. 2. In the embodiment, the gas detection module S includes at least one power conversion component 31, at least one sensing component 32, at least one microcontroller (MCU) 33, at least one wireless communication component (WI-FI) 34 and at least one central control communication interface component 35. In the embodiment, an AC power is inputted into the power conversion component 31 and converted as a required DC power, the DC power is then outputted for the sensing component 32, the microcontroller 33, the wireless communication component 34 and the central control communication interface component 35. Preferably but not exclusively, an AC power is inputted into the power conversion component 11 and converted into a required DC voltage of 5 V and a required DC voltage of 3.3 V, respectively. The required DC voltage of 5 V is provided to the sensing component 32 and the central control communication interface component 35, and the required voltage of 3.3 V is provided to the sensing component 32, the microcontroller 33 and the wireless communication component 34, but the present disclosure is not limited thereto.

In the embodiment, the sensing component 32 includes a sensing element for detecting air pollution. Preferably but not exclusively, the sensing component 32 detects the air pollution, and outputs air pollution data for the microcontroller 33 calculating and processing. The microcontroller 33 outputs a plurality of regulation signals. Notably, in the embodiment, the air pollution is at least one selected from the group consisting of suspended particles, particulate matter, ozone, carbon monoxide, carbon dioxide, sulfur dioxide, nitrogen dioxide, acetaldehyde, acetamide, acetonitrile, acetophenone, 2-acetylaminofluorene, acrolein, acrylamide, acrylic acid, acrylonitrile, propylene chloride, 4-aminobiphenyl, aniline, o-anisidine, asbestos, benzene, benzidine, trichlorotoluene, benzyl chloride, biphenyl, di(2-ethylhexyl) phthalate (DEHP), dichloromethyl ether, tribromoform, 1-bromopropane, 1,3-butadiene, calcium cyanamide, caprolactam, captan, carbaryl, carbon disulfide, carbon tetrachloride, carbonyl sulfide, catechol, chloramben, chlordane, chlorine, chloroacetic acid, 2-chloroacetophenone, chlorobenzene, chlorobenzilate, chloroform, chloromethyl methyl ether, chloroprene, cresol/methanesulfonic acid (isomers and mixtures), o-cresol, m-cresol, p-cresol, cumene, 2,4-dichlorophenoxyacetic acid, salts and esters, dichlorodiphenyldichloroethylene (DDE), diazomethane, dibenzofuran, 1,2-dibromo-3-chloropropane, dibutyl phthalate, 1,4-dichlorobenzene, 3,3-dichlorobenzidine, dichloroethyl ether (bis(2-chloroethyl) ether), 1,3-dichloropropene, dichlorvos, diethanolamine, N,N-dimethylaniline, diethyl sulfate, 3,3-dimethoxybenzidine, dimethylaminoazobenzene, 3,3′-dimethylbenzidine, dimethylcarbamate chloride, dimethylformamide, 1,1-dimethylhydrazine, dimethyl phthalate, dimethyl sulfate, 4,6-dinitro-o-cresol and its salts, 2,4-dinitrophenol, 2,4-dinitrotoluene, 1,4-dioxane (1,4-ethylene dioxide), 1,2-diphenylhydrazine, epichlorohydrin (1-chloro-2,3-epoxy propane), 1,2-butylene oxide, ethyl acrylate, ethylbenzene, ethyl urethane (ethyl carbamate), ethyl chloride, dibromoethane, dichloroethane (1,2-dichloro ethane), ethylene glycol, ethyleneimine (azirine), ethylene oxide, ethylene thiourea, dichloroethane (1,1-dichloroethane), formaldehyde, hexachlorobenzene, hexachlorobutadiene, heptachlor, hexachlorocyclopentadiene, hexachloroethane, 1,6-hexamethylene diisocyanate, hexamethylphosphonamide, hexane, hydrazine, hydrochloric acid, hydrogen fluoride (hydrofluoric acid), hydrogen sulfide, hydroquinone, isophorone, lindane (all isomers), maleic anhydride, methanol, potassium chloride, methyl bromide (methyl bromide), methyl chloride (methyl chloride), methyl chloroform (1,1,1-trichloroethane), methyl ethyl ketone (2-butanone), methyl hydrazine, methyl iodide (methyl iodide), methyl isobutyl ketone (cyclohexanone), methyl isocyanate, methyl methacrylate, methyl tert-butyl ether, 4,4-methylenebis(2-chloroaniline), methylene chloride, methylene diphenyl diisocyanate (MDI), 4,4′-aminodiphenylmethane, naphthalene, nitrobenzene, 4-Nitrobiphenyl, 4-nitrophenol, 2-nitropropane, N-nitroso-N-methyl urea, N-nitroso dimethylamine, N-nitroso morpholine, Parathion, pentachloronitrobenzene (pentabenzene), pentachlorophenol, phenol, p-phenylenediamine, phosgene, phosphine, phosphorus, phthalic anhydride, polychlorinated biphenyls (Aroclors), 1,3-propane sultone, β-propiolactone, propionaldehyde, propoxur (Baigon), dichloropropane (1,2-dichloropropane), propylene oxide, 1,2-propylene imine (2-methylaziridine), quinoline, quinone, styrene, styrene oxide, 2,3,7,8-tetrachlorodibenzo-p-dioxin, 1,1,2,2-tetrachloroethane, tetrachloroethylene (perchloroethylene), titanium tetrachloride, toluene, 2,4-toluenediamine, 2,4-toluene diisocyanate, o-toluidine, toxaphene (camphene chloride), 1,2,4-trichlorobenzene, 1,1,2-trichloroethane, trichloroethylene, 2,4,5-trichlorophenol, 2,4,6-trichlorophenol, triethylamine, trifluralin, 2,2,4-trimethylpentane, vinyl acetate, bromine ethylene, vinyl chloride, vinylidene chloride (1,1-dichloroethylene), xylene, o-xylene, m-xylene, p-xylene, antimony compounds, arsenic compounds (inorganic, including arsine), beryllium compounds, cadmium compounds, chromium compounds, cobalt compounds, coke oven emissions, cyanide, glycol ethers, lead compounds, manganese compounds, mercury compounds, fine mineral fibers, nickel compounds, polycyclic organic compounds, radioactive nuclides (including radon), selenium compounds, bacteria, fungi, viruses and a combination thereof.

The sensing component 32 of the gas detection module S of the present disclosure not only detects the suspended particles in the gas, but also detects the characteristics of the introduced gas. Therefore, the sensing component 32 of the gas detection module S further includes a particle sensing element 32a, a temperature and humidity sensing element 32b and a gas sensing element 32c, or is expanded to include other sensing elements, such as a bacteria sensing element 32d, a fungus sensing element 32e and a virus sensing element 32f for detecting the introduced air pollution. Notably, in the embodiment, the sensing component 32 is a particle sensing element 32a for detecting the air pollution data of the suspended particles (PM1, PM2.5, PM10) contained in the gas and in particulate state. Preferably but not exclusively, the sensing component 32 is a temperature and humidity sensing element 32b for detecting the air pollution data of the temperature and humidity of the air. Preferably but not exclusively, the sensing component 32 is a gas sensing element 32c for detecting the air pollution data of gas molecules contained in the air. Preferably but not exclusively, the sensing component 32 includes a bacteria sensing element 32d for detecting the air pollution data of bacteria contained in the air. Preferably but not exclusively, the sensing component 32 includes a fungus sensing element 32e for detecting the air pollution data of fungus contained in the air. Preferably but not exclusively, the sensing component 32 includes a virus sensing element 32f for detecting the air pollution data of virus contained in the air. The present disclosure is not limited thereto.

In the embodiment, the particle sensing element 32a is disposed in an indoor field A and configured to detect if the suspended particulate matter (PM1, PM2.5, PM10) and the concentration of suspended particles contained in the air pollution exceeds a pollution threshold safety value. When the microcontroller 33 receives that the air pollution data of suspend particles exceeds the pollution threshold safety value, a plurality of regulation signals are outputted. Preferably but not exclusively, the pollution threshold safety value of suspended particulate matter 2.5 (PM2.5) includes a concentration of suspended particulate matter 2.5 (PM2.5) less than 15 μg/m³. In the embodiment, the temperature and humidity sensing element 32b is configured to detect if the temperature and humidity of the air in the indoor field A exceeds a pollution threshold safety value. When the microcontroller 33 receives that the air pollution data of the temperature and humidity of the air exceeds the pollution threshold safety value, a plurality of regulation signals are outputted. Preferably but not exclusively, the pollution threshold safety value of temperature and humidity includes a temperature of 25° C.±3° C. and a humidity of 50%±10%. Preferably but not exclusively, the pollution threshold safety value of temperature and humidity is used to implement a temperature and humidity control in the indoor field A, and the temperature and humidity control is implemented to maintain a temperature of 25° C.±3° C. and a humidity of 50%±10% in the indoor field A. Preferably but not exclusively, the gas sensing element 32c is configured to detect if the air pollution data of carbon dioxide (CO₂) exceeds a threshold safety value. When the microcontroller 33 receives that the air pollution data of carbon dioxide (CO₂) exceeds the pollution threshold safety value, a plurality of regulation signals are outputted. Preferably but not exclusively, the air pollution data of carbon dioxide (CO₂) have to be maintained below the pollution threshold safety value of 800 ppm.

In the embodiment, the microcontroller 33 receives the air pollution data outputted by the sensing component 32, and calculates and processes the air pollution data to outputs the plurality of regulation signals. The air pollution data outputted by the sensing component 32 are transmitted to the microcontroller 33 through a serial communication (IIC) signal for receiving, calculating and processing. The regulation signal outputted by the microcontroller 33 includes a Universal Asynchronous Transceiver and Transceiver (UART) signal and a General Purpose Input and Output (GP I/O) signal. The Universal Asynchronous Transceiver and Transceiver (UART) signals are transmitted through electrical wires to the air cleaning component 11, the wireless communication component 34 and the central control communication interface component 35 for receiving. The General Purpose Input and Output (GP I/O) signals are transmitted through electrical wires to the air cleaning component 11 for receiving. Notably, as shown in FIG. 2 and FIG. 1A, the central control communication interface component 35 is connected to a communication control line and the central control and regulation device 12 for communication connection and transmission. Preferably but not exclusively, a wired communication transmission (the solid transmission line of the central control and regulation device 12 and the gas detection module S shown in FIG. 1A and FIG. 1B) under a RS485 communication protocol is used for communication connection and transmission.

Please refer to FIG. 4A and FIG. 4B, again. The gas detection module S can be composed of a type including an external power terminal, and the external power terminal is directly inserted into the power interface of the indoor field A or the outdoor field B (e.g., the gas detection module shown in FIG. 1B and represented by number S), so as to start operation of detecting the air pollution. Alternatively, as shown in FIG. 4C, the gas detection module doesn't include an external power terminal, and is directly disposed and integrated within the ventilation pipeline 10 of the air cleaning device 1 in electrical connection (e.g., the gas detection module S shown in FIG. 1B).

Please refer to FIG. 1A. In the embodiment, the air cleaning component 11 includes a purifier 11a, a cooler 11b and a full heat exchanger 11c integrated into one piece, the gas detection module S detects and locates the air pollution, the purifier 11a circulates and filters the air pollution, and the cooler 11b and the full heat exchanger 11c regulate temperature, humidity and ventilation of the indoor field A. In an embodiment, the air cleaning component 11 includes a purifier 11a and a cooler 11b integrated into one piece, the gas detection module S detects and locates the air pollution, the purifier 11a circulates and filters the air pollution, and the cooler 11b regulates temperature and humidity of the indoor field. In another embodiment, the air cleaning component 11 includes a purifier 11a and a full heat exchanger 11b integrated into one piece, the gas detection module S detects and locates the air pollution, the purifier 11a circulates and filters the air pollution, and the full heat exchanger 11c regulates ventilation of the indoor field. In other embodiments, the air cleaning component 11 includes a purifier 11a, the gas detection module S detects and locates the air pollution, and the purifier 11a circulates and filters the air pollution. Preferably but not exclusively, in some embodiments, the purifier 11a, the cooler 11b and the full heat exchanger 11c are arbitrarily integrated into one piece of the air cleaning component 11 according to the practical requirements for detecting, locating, circulating and filtering the air pollution, and regulating temperature, humidity and ventilation of the indoor field A.

Please refer to FIG. 1A, FIG. 1B, FIG. 3C and FIG. 3D. In the embodiment, the air cleaning device 11 includes the purifier 11a, the cooler 11b and the full heat exchanger 11c, which are arbitrarily integrated into one piece. The purifier 11a, the cooler 11b and the full heat exchanger 11c are controlled by the gas detection module S so as to control processing operation of filtering the air pollution. In the embodiment, the gas detection module S detects the air pollution to generate the air pollution data and transmit the air pollution data to the communication module 13 for networking output, and the central control and regulation device 12 is connected to central control communication interface components 35 of the gas detection module S through wired communication to receive the air pollution data for displaying. In the embodiment, the purifier 11a includes a fan 111 and at least one filtering element 112, and the gas detection module S is connected under handshake communication protocol of wired communication or wireless communication to receive an control command issued by the networked cloud computing service device 2, calculates, processes and outputs a plurality of regulation signals to a driving control component 113, so that activation operation of the fan 111 of the purifier 11a and a wind speed of the fan 111 of the purifier 11a are regulated, the fan 111 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration, the cooler 11b is controlled to start maintain temperature and humidity of the indoor field A, the full heat exchanger 11c is controlled to start maintain ventilation of the indoor filed A, and the gas state of the air pollution in the indoor field A reaches the clean room requirement of ZAPClean Room 1˜9.

In the embodiment, the gas detection module S is electrically connected to the fan 111 and the driving control component 113 (as shown in FIG. 3C). Please further refer to FIG. 2 and FIG. 3C. In the embodiment, the air cleaning component 11 further includes a relay 114 and a communication interface device 115. Preferably but not exclusively, the relay 114 is electrically connected to input the AC voltage outputted by the power conversion component 31 and cooperatively connected to the microcontroller (MCU) 33 to output the regulation signal (i.e., the General Purpose Input and Output (GP I/O) signal), so that the AC voltage is outputted and provided to a driving control component 113 for power control and regulation. Moreover, the communication interface device 115 is connected to input the required DC voltage of 5 V converted by the power conversion component 31, cooperating with the microcontroller (MCU) 33 to input the regulation signal (i.e., the Universal Asynchronous Transceiver and Transceiver (UART) signal) outputted therefrom, and connected to the driving control component 113 for communication connection and transmission through a communication control line to regulate a wind speed of a fan 111 of the air cleaning component 11, so that the fan 111 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration. Notably, in the embodiment, the communication control line of the air cleaning component 11 is used for outputting under a RS485 communication protocol. Notably, in the embodiment, it allows to implement a plurality of air cleaning components 11 in the present disclosure, each of the air cleaning component includes an address encoder (not shown) for connection with the wire outputting the regulation signal (i.e., the General Purpose Input and Output (GP I/O) signal), so that the plurality of air cleaning components 11 are serially connected for regulation.

Please refer to FIG. 1A and FIG. 2. In the embodiment, the communication module 13 of the air cleaning device 1 communities with the central control and regulation device 12 and the wireless communication component (WI-FI) 34 of the gas detection module S of the air cleaning component 11 through wireless communication to receive the air pollution data and then transmit to the networked cloud computing service device 2, and the air pollution information is received and stored by the networked cloud computing service device 2 to form the big data database of the air pollution. Notably, in the embodiment, the communication module 13 of the air cleaning device 1 is a router. Preferably but not exclusively, communication transmission of the communication module 13 is a wired communication transmission or a wireless communication transmission.

In the embodiment, the networked cloud computing service device 2 intelligently computes and compares based on the air pollution data. The control command is intelligently selected and issued through the communication module 13, transmitted to the gas detection module S of the air cleaning device 1 for receiving, then transmitted to the driving control component 113 to regulate the activation operation of the fan 111 and the wind speed of the fan 111. In that, the fan 111 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration, the cooler 11b is controlled to start maintain the temperature and humidity of the indoor field A at a temperature of 25° C.±3° C. and a humidity of 50%±10%, and the full heat exchanger 11c is controlled to start maintain the ventilation of the indoor filed A that the air pollution data of carbon dioxide (CO₂) in the indoor field A have to be maintained below the pollution threshold safety value of 800 ppm, therefore the gas state in the indoor field A is cleaned to meet the clean room requirement of ZAPClean Room 1˜9. Alternatively, in an embodiment, the networked cloud computing service device 2 intelligently computes and compares based on the air pollution data, the control command is intelligently selected and issued to the at least one central control and regulation device 12 through the communication module 13, and then the control command is transmitted to the gas detection module S through wired communication connection for receiving, and then transmitted to the driving control component 113 to regulate the activation operation of the fan 111 and the wind speed of the fan 111. In that, the fan 111 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration, the cooler 11b is controlled to start maintain the temperature and humidity of the indoor field A at a temperature of 25° C.±3° C. and a humidity of 50%±10%, and the full heat exchanger 11cis controlled to start maintain the ventilation of the indoor filed A that the air pollution data of carbon dioxide (CO₂) in the indoor field A have to be maintained below the pollution threshold safety value of 800 ppm, so that the gas state in the indoor field A is cleaned to meet the clean room requirement of ZAPClean Room 1˜9.

In the embodiment, the gas detection modules S are connected under handshake communication protocol of wired communication or wireless communication. When the wireless communication or the wired communication is disconnected, it allows to regulate and select an activation mechanism with the wired communication or the wireless communication that can operate transmission. The networked cloud computing service device 2 receives the air pollution data through the activation mechanism with the wired communication or the wireless communication that can operate the transmission, intelligently computes and compares based on the air pollution data, and then intelligently selects and issues the control command to be transmitted to the gas detection modules S for receiving under the connection of the activation mechanism with the wired communication or the wireless communication that can operate transmission, and then the control command is transmitted to the driving control component 113 to regulate the activation operation of the fan 111 and the wind speed of the fan 111. In that, the fan 111 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration, the full heat exchanger 11c is controlled to start maintain the ventilation of the indoor filed A that the air pollution data of carbon dioxide (CO₂) in the indoor field A have to be maintained below the pollution threshold safety value of 800 ppm, and then the gas state in the indoor field A is cleaned to meet the clean room requirement of ZAPClean Room 1˜9. Alternatively, when the gas detection modules S are connected under the handshake communication protocol of the wired communication or the wireless communication and the wireless communication and the wired communication are both disconnected, it allows to autonomously compute and compare the air pollution data outputted by the gas detection modules S based on the air pollution data, and then transmit the control command to the driving control component 113 to regulate the activation operation of the fan 111. The fan 11 is controlled to start guiding the air pollution passing through the filtering element 112 for filtration, and the full heat exchanger 11c is controlled to start maintain the ventilation of the indoor filed A that the air pollution data of carbon dioxide (CO₂) in the indoor field A have to be maintained below the pollution threshold safety value of 800 ppm, so that the gas state in the indoor field A is cleaned to meet the clean room requirement of ZAPClean Room 1˜9.

From the above, the specific implementation of the indoor air cleaning system in the indoor field A according to the present disclosure can be understood. The specific implementation of the plurality of air cleaning components 11 in the indoor field A will be described below. As shown in FIG. 1B, the air cleaning component 11 can be installed in the indoor field A through a build-in or plug-in manner. If the air cleaning component 11 is installed in the indoor field A through the build-in manner, at least one circulation back-flow channel C is disposed within the indoor field A. The at least one circulation back-flow channel C is surrounded and isolated by several partitions C1 to form on a side of the indoor field A, and includes a plurality of vents C2.

In addition, as shown in FIG. 1A and FIG. 1B, the air cleaning component 11 includes a purifier 11a, a cooler 11b and a full heat exchanger 11 arbitrarily integrated into one piece for detecting, locating, circulating and filtering air pollution in the indoor field A, and regulating temperature, humidity and ventilation of the indoor field A. Furthermore, at least one gas detection module S is disposed in the outdoor field B and at least one gas detection module S is disposed in the indoor field A for detecting the air pollution. The networked cloud computing service device 2 receives the air pollution data of the indoor field A and the outdoor field B for storing to form the big data database of the air pollution data, and intelligently computes and compares the air pollution data of the indoor field A and the outdoor field B. When the air pollution data of the indoor field A is greater than the air pollution data of the outdoor field B, the networked cloud computing service device 2 issues the control command to be transmitted to the full heat exchanger 11c through wireless communication or wired communication to regulate the activation operation for ventilation in the indoor field A. That is, the full heat exchanger 11c is controlled to start maintain the ventilation of the indoor filed A, and the gas in the outdoor field B is inhaled through the gas guiding port 10a and flows through the primary filtering element H to maintain the ventilation of the indoor field A. Preferably but not exclusively, the air pollution data of carbon dioxide (CO₂) in the indoor field A have to be maintained below the pollution threshold safety value of 800 ppm. The gas from outdoor field B is introduced into the indoor field A for ventilation Notably, the gas detection module S in the indoor field detects the air pollution data, the networked cloud computing service device 2 receives the air pollution data of the indoor field A through the wireless communication or the wired communication for storing to form the big data database of the air pollution data, and the intelligent computing comparison based on the database of the air pollution data is performed to intelligently select and output the control command to the fan 111 of the air cleaning component 11 for actuation and regulation operation. The air in the outdoor field B is inhaled from the gas inlet 10b by the fan 111, filtered by the filtering element 112, introduced into the ventilation pipeline 10, then flows into the circulation back-flow channel C and enters the indoor field A through the plurality of vents C2. Moreover, the air pollution in the indoor field A enters the ventilation pipeline 10 through the gas outlet 10b, flows through the full heat exchanger 11c, and be discharged the vents 10d. In this way, an internal circulation directional airflow is generated continuously by the air intake and exhaust operations in the indoor field A. It allows the indoor field A to be ventilated. The air pollution is introduced through the gas inlet 10b into the ventilation pipeline 10 of the gas cleaning component 11, and guided to pass through the filtering element 112 multiple times for filtration. 2, and the indoor field A gas circulates through the refrigerator 11b and the total heat exchanger 11c to regulate the temperature, humidity and ventilation of the passing gas. Moreover, the air in the indoor field A is circulated to flow through the cooler 11b and the full heat exchanger 11c to control the temperature, humidity and ventilation thereof. In addition, the networked cloud computing service device 2 intelligently computes the cleanliness according to the number of suspended particles passing through the indoor field A in real time, intelligently selects and issues the control command to be transmitted to the plurality of the air cleaning components 11 (the purifier 11a, the cooler 11b and the full heat exchanger 11c), and timely adjusts and controls the air cleaning components 11 for actuation, so as to randomly change and adjust the airflow volume and the actuation time period of the fan 111 of the purifier 11a based on the cleanliness of the number of suspended particles in real time. Whereby, the cleaning efficiency of the indoor field A is improved, the environmental noise of the indoor field A is reduced, the internal circulation directional airflow is generated in the indoor field A to generate, and the air pollution is guided to pass through the filtering element 112 multiple times for filtration, so that the gas state of the air pollution in the indoor reaches the clean room requirement of ZAPClean Room 1˜9.

Please refer to FIG. 3A and FIG. 3B. In the above embodiments, the fan 111 of the air cleaning component 11 is controlled and enabled to guide the air pollution to pass through the filtering element 112 for filtration. Preferably but not exclusively, in an embodiment, the filtering element 112 is an ultra-low particulate air (ULPA) filter, a high efficiency particulate air (HEPA) filter or a combination thereof, which is configured to absorb the chemical smoke, the bacteria, the dust particles and the pollen contained in the air pollution, so that the air pollution introduced into the filtering element 112 is filtered and purified to achieve the effect of filtering and purification.

In the embodiment, the filtering element 112 of the present disclosure is further combined with physical or chemical materials to provide a sterilization effect on the air pollution, and the airflow of the fan 111 flows in the path indicated by the arrow. As shown in FIG. 3B, in the embodiment, the filtering element 112 includes a decomposition layer coated thereon to sterilize in chemical means. Preferably but not exclusively, the decomposition layer includes an activated carbon 222a configured to remove organic and inorganic substances in air pollution, and remove colored and odorous substances. Preferably but not exclusively, the decomposition layer includes a cleansing factor containing chlorine dioxide layer 112b configured to inhibit viruses, bacteria, fungi, influenza A, influenza B, enterovirus and norovirus in the air pollution, and the inhibition ratio can reach 99% and more, thereby reducing the cross-infection of viruses. Preferably but not exclusively, the decomposition layer includes an herbal protective layer 112c extracted from ginkgo and Japanese Rhus chinensis configured to resist allergy effectively and destroy a surface protein of influenza virus (such as H1N1 influenza virus) passing therethrough. Preferably but not exclusively, the decomposition layer includes a silver ion 112d configured to inhibit viruses, bacteria and fungi contained in the air pollution. Preferably but not exclusively, the decomposition layer includes a zeolite 112e configured to remove ammonia nitrogen, heavy metals, organic pollutants, Escherichia coli, phenol, chloroform and anionic surfactants.

Furthermore, in some embodiments, the filtering element 112 is combined with a light irradiation element to sterilize in chemical means. Preferably but not exclusively, the light irradiation element is a photo-catalyst unit including a photo catalyst 112f and an ultraviolet lamp 112g. When the photo catalyst 112f is irradiated by the ultraviolet lamp 112g, the light energy is converted into the chemical energy, thereby decomposes harmful gases and disinfects bacteria contained in the air pollution, so as to achieve the effects of filtering and purifying. Preferably but not exclusively, the light irradiation element is a photo-plasma unit including a nanometer irradiation tube 112h. When the introduced air pollution is irradiated by the nanometer irradiation tube 112h, the oxygen molecules and water molecules contained in the air pollution are decomposed into high oxidizing photo-plasma, and an ion flow capable of destroying organic molecules is generated. In that, volatile formaldehyde, volatile toluene and volatile organic compounds (VOC) contained in the air pollution are decomposed into water and carbon dioxide, so as to achieve the effects of filtering and purifying. Notably, in the embodiment, as shown in FIG. 3D, the air cleaning component 11 further comprises an ultraviolet lamp component 116, the ultraviolet lamp component 116 includes a relay 116a, and the relay 116a is connected to input an AC voltage outputted from the power conversion component 31 and cooperatively connected to the microcontroller 33 to output the regulation signal((i.e., the General Purpose Input and Output (GP I/O) signal)), so that the AC voltage is outputted and provided to a power switch 26b, and the power switch 116b is connected to control starting and regulation of the ultraviolet lamp 112g. Preferably but not exclusively, the ultraviolet lamp 112g is arranged on one side of the filtering element 112 for sterilizing the air pollution.

Moreover, in some embodiments, the filtering element 112 is combined with a decomposition unit to sterilize in chemical means. Preferably but not exclusively, the decomposition unit is a negative ion unit 112i with a dust collecting plate. It makes the suspended particles in the air pollution to carry with positive charge and adhered to the dust collecting plate carry with negative charges, so as to achieve the effects of filtering and purifying. Preferably but not exclusively, the decomposition unit is a plasma ion unit 112j. The oxygen molecules and water molecules contained in the air pollution are decomposed into positive hydrogen ions (H⁺) and negative oxygen ions (O²⁻) by the plasma ion. The substances attached with water around the ions are adhered on the surface of viruses and bacteria and converted into OH radicals with extremely strong oxidizing power, thereby removing hydrogen (H) from the protein on the surface of viruses and bacteria, and thus decomposing (oxidizing) the protein, so as to filter the introduced air pollution and achieve the effects of filtering and purifying.

Please refer to FIG. 5. In the above embodiments, the networked cloud computing service device 2 includes a wireless network cloud computing service module 21, a cloud control service unit 22, a device management unit 23 and an application program unit 24. The wireless network cloud computing service module 21 receives the information of the air pollution data from the gas detection module S disposed in the outdoor field B, receives the information of the air pollution data from the gas detection module S disposed in the indoor field A, receives the communication information of the air pollution data from the gas detection modules S disposed within the plurality of air cleaning components 11 and transmits the control commands. Moreover, the wireless network cloud computing service module 21 receives the information of the air pollution data of the indoor field A and the outdoor field B and transmits the information to the cloud control service unit 22 to store and form the big data database of the air pollution data. An artificial intelligence calculation is implemented to determine the location of the air pollution through the air pollution database comparison, so that the control command is transmitted to the wireless network cloud computing service module 21, and then transmitted to the air cleaning component 11 to control the actuation operation through the wireless network cloud computing service module 21. The device management unit 23 receives the communication information of the plurality of air cleaning components 11 through the wireless network cloud computing service module 21 to manage the user login and device binding. The device management information can be provided to the application program unit 24 for system control and management, and the application program unit 24 can also display and inform the air pollution information obtained by the cloud control service unit 22. The user can know the real-time status of air pollution removal through the mobile phone or the communication device. Moreover, the user can control the operation of the indoor air cleaning system through the application program unit 24 of the mobile phone or the communication device. Certainly, the air cleaning system of the present disclosure includes a control drive software built into the central control and regulation device 12 and a mobile device. The control command is transmitted to the gas detection module S for receiving, so that the gas detection module S is allowed controlling the processing operations of the air cleaning component 11 to filter the air pollution. The mobile device issues the control command through wireless communication, the application program unit 24 of the networked computing service device 2 receives and then transmits the control command to the communication module 13 of the air cleaning device 1 for receiving, and the communication module 13 transmits the control command to the gas detection module S for receiving through wireless communication or wired communication, so that the processing operations of the air cleaning component 11 are controlled to filter the air pollution, and the gas state of the air pollution in the indoor field A reaches a clean room requirement of ZAPClean Room 1˜9.

Moreover, in the indoor air cleaning system of the present disclosure, the networked cloud computing service device 2 receives the air pollution data of the indoor field A and the outdoor field B through the wireless communication or the wired communication for storing to form the big data database of the air pollution data. The intelligent computing comparison based on the database of the air pollution data is performed to intelligently select and output the control command to the air cleaning component 11 for actuation and regulation operation. Whereby, the fan 111 of the air cleaning component 11 generates an internal circulation directional airflow continuously in the indoor field A, and the air pollution is guided to pass through the filtering element 112 multiple times for filtration. In other words, the networked cloud computing service device 2 intelligently computes the cleanliness according to the number of suspended particles passing through the indoor field A in real time, intelligently selects and issues the control command to be transmitted to the plurality of the air cleaning component 11, and timely adjusts and controls the air cleaning component 11 for actuation, so as to randomly change and adjust the airflow volume and the actuation time period of the fan 11 of the purifier 11a based on the cleanliness of the number of suspended particles in real time. Whereby, the cleaning efficiency of the indoor field A is improved, the environmental noise of the indoor field A is reduced, the internal circulation directional airflow is generated in the indoor field A to generate, and the air pollution is guided to pass through the filtering element 112 multiple times for filtration, so that the gas state of the air pollution in the indoor reaches the air pollution data targeted according to a cumulative number of PM2.5 detected by the plurality of gas detection modules S in 24 hours and a required space of the indoor field A for one air cleaning component 11, to meet a clean room requirement of ZAPClean Room 1˜9.

The above clean room requirement allows to reach a cleanliness of ZAPClean Room 1˜9, which is similar to the ISO standard clean room ISO 1˜9. However, the cleanliness of ZAPClean Room 1˜9 is a technical structure different from the traditional clean room ISO 1˜9, but able to achieve the same indoor air cleanliness as the traditional clean room ISO 1˜9. Generally, the cleanliness of the traditional clean room ISO 1˜9 is not equipped with sensors for real-time detection around the clock, so the system need to be operated in a 24-hour accumulation and high-speed mode. This way of operating will result in a large amount of energy loss and a high-noise environment. Such a system cannot be used in ordinary indoor home life.

The indoor air cleaning system of the present disclosure allows to reach the cleanliness of ZAPClean Room 1˜9. The indoor air cleaning system of the present disclosure utilizes the plurality of air cleaning components 11 with the gas detection module S and the networked cloud computing service device 2 disposed therein to form an intelligent linkage system. The external and build-in gas detection modules S are used to detect PM2.5 concentration/particle number, carbon dioxide (CO₂), carbon monoxide (CO), formaldehyde, methane, toluene, volatile organic compounds (TVOC), ozone (O₃), nitric oxide (NO), nitrogen dioxide (NO₂), sulfur dioxide (SO₂), radon (Rn-222), bacteria and fungi. It allows connecting to the networked cloud computing service device 2 through wired communication or wireless communication for intelligently computing and selecting so that the control instruction signals are provided for the gas detection modules S in the plurality of air cleaning components 11 regulating the activation operations, the air volume and the noise level of the fan 111, thereby achieving the ZAPClean room system that operates silently and efficiently.

In specific examples of the present disclosure, as shown in FIG. 6A to FIG. 6F, the air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 500,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 0.7 pings (i.e., 2.4 square meters, 25.6 square feet) for one air cleaning device 1, and include detection of suspended particulate matter PM 2.5≤0.02 μg/m³, detection of suspended particulate matter PM 10≤0.03 μμg/m³, detection of bacteria and fungi ≤2 CFU/m³, detection of formaldehyde≤0.032 ppm, detection of volatile organic compounds (TVOC)≤0.24 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide ≤4 ppm, detection of ozone≤0.020 ppm, detection of methane≤9 ppm, detection of toluene≤43 ppm, detection of nitric oxide and nitrogen dioxide≤0.043 ppm, detection of sulfur dioxide≤0.032 ppm, detection of radon≤40 Bq/m³, detection of ammonia≤9 ppm, detection of chlorine≤0.43 ppm, detection of hydrogen cyanide≤4 ppm, detection of hydrogen sulfide≤4 ppm, detection of propane bromide≤0.04 ppm, detect acetaldehyde≤40 ppm, detection of mercury and its compounds≤0.004 mg/m³, detection of dioxin≤0.43 ng-TEQ/Nm³, detection of acrolein≤0.04 ppm, detection of dichloropropane≤30 ppm, detection of Dichloromethane≤19 ppm, detection of acrylonitrile≤0.86 ppm, detection of 1,3-dichloropropene≤0.43 ppm, detection of nickel compounds≤0.43 mg/m3, detection of organic arsenic compounds≤0.22 ppm, detection of dichloroethylene≤84 ppm, detection of polychlorinated biphenyls≤0.004 mg/m³, detection of benzene≤0.43 ppm, detect ethylene oxide≤0.43 ppm, detection of polycyclic organic matter≤0.43 ppm, detection of beryllium and its compounds≤0.0009 mg/m³, detection of quinoline≤0.0004 ppm, detection of 1,3-butadiene≤2.15 ppm, detection of hexachlorobenzene≤0.43 ppm, detection of 1,1,2,2-tetrachloroethane≤0.43 ppm, detection of cadmium and its compounds≤0.022 mg/m³, detection of hydrazine≤0.04 ppm, detection of tetrachlorethylene≤19 ppm, detection of chloroform≤2 ppm, detection of lead and its inorganic compounds≤0.022 mg/m³, detection of trichlorethylene≤19 ppm, detection of chromium compounds≤0.22 mg/m³, detection of manganese and its inorganic compounds≤2.15 mg/m³, and detection of vinyl chloride≤0.43 ppm, for meeting the clean room requirement of ZAPClean Room 1.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 1,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 1 ping (i.e., 3.4 square meters, 36.6 square feet) for one air cleaning device 1, and include detection of suspended particulates PM 2.5≤0.04 μg/m³, detection of suspended particulates PM 10≤0.06 μg/m³, detection of bacteria and fungi≤5 CFU/m³, detection of formaldehyde≤0.038 ppm, detection of volatile organic compounds (TVOC)≤0.27 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤4 ppm, detection of ozone≤0.025 ppm, detection of methane≤10 ppm, detection of toluene≤48 ppm, detection of nitric oxide and nitrogen dioxide≤0.048 ppm, detection of sulfur dioxide≤0.036 ppm, detection of radon≤45 Bq/m³, detection of ammonia≤9 ppm, detection of chlorine≤0.48 ppm, detection of hydrogen cyanide≤5 ppm, detection of hydrogen sulfide≤5 ppm, detection of propane bromide≤0.05 ppm, detect acetaldehyde≤45 ppm, detect mercury and its compounds≤0.005 mg (mg/m³), detection of dioxin≤0.48 ng-TEQ/Nm³, detection of acrolein≤0.05 ppm, detection of dichloropropane≤34 ppm, detection of dichloromethane≤22 ppm, detection of acrylonitrile≤0.96 ppm, detection of 1,3-dichloropropene≤0.48 ppm, detection of nickel compounds≤0.48 mg/m³, detection of organic arsenic compounds≤0.24 ppm, detection of dichloroethylene≤94 ppm, detection of polychlorinated biphenyls≤0.005 mg/m³, detection of benzene≤0.48 ppm, detection of ethylene oxide≤0.48 ppm, detection of polycyclic organic matter≤0.48 ppm, detection of beryllium and its compound≤0.0010 mg/m³, detection of quinoline≤0.0005 ppm, detection of 1,3-butadiene≤2.39 ppm, detection of hexachlorobenzene≤0.48 ppm, detection of 1,1,2,2-tetrachloroethane≤0.48ppm, detection of cadmium and its compounds S 0.024 mg/m³, detection of hydrazine ≤0.05 ppm, detection of tetrachlorethylene≤22ppm, detection of chloroform≤3 ppm, detection of lead and its inorganic compounds≤0.024 mg/m3, detection of trichlorethylene≤22 ppm, detection of chromium compounds≤0.24 mg/m³, detection of manganese and its inorganic compounds≤2.39 mg/m³, detection of vinyl chloride≤0.48 ppm, for meeting the clean room requirement of ZAPClean Room 2.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 2,500,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 1.5 pings (i.e., 4.9 square meters, 52.3 square feet) for one air cleaning device 1, and include detection of suspended particulate matter PM 2.5≤0.11 μg/m³, detection of suspended particulate matter PM 10≤0.16 μg/m3, detection of bacteria and fungi≤10 CFU/m³, detection of formaldehyde≤0.044 ppm, detection of volatile organic compounds (TVOC)≤0.30 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤5 ppm, detection of ozone≤0.030 ppm, detection of methane≤11 ppm, detection of toluene≤53 ppm, detection of nitric oxide and nitrogen dioxide≤0.053 ppm, detection of sulfur dioxide≤0.040 ppm, detection of radon≤51 Bq/m³, detection of ammonia≤12 ppm, detection of chlorine≤0.53 ppm, detection of hydrogen cyanide≤5 ppm, detection of hydrogen sulfide≤5 ppm, detection of propane bromide≤0.05 ppm, detection of acetaldehyde≤51 ppm, detection of mercury and its compounds≤0.005 mg/m³, detection of dioxin≤0.53 ng-TEQ/Nm³, detection of acrolein≤0.05 ppm, detection of dichloropropane≤38 ppm, detection of dichloromethane≤25 ppm, detection of acrylonitrile≤1.06ppm, detection of 1,3-dichloropropene≤0.53 ppm, detection of nickel compounds≤0.53 mg/m³, detection of organic arsenic compounds≤0.27 ppm, detection of dichloroethylene≤105 ppm, detection of polychlorinated biphenyls≤0.005 mg/m³, detection of benzene≤0.53 ppm, detection of ethylene oxide≤0.53 ppm, detection of polycyclic organic matter≤0.53 ppm, detection of beryllium and its compounds≤0.0011 mg/m³, detection of quinoline≤0.0005 ppm, detection of 1,3-butadiene≤2.66 ppm, detection of hexachlorobenzene≤0.53 ppm, detection of 1,1,2,2-tetrachloroethane≤0.53 ppm, detection of cadmium and its compounds≤0.027 mg/m³, detection of hydrazine≤0.05 ppm, detection of tetrachlorethylene≤25 ppm, detection of chloroform≤4 ppm, detection of lead and its inorganic compounds≤0.027 mg/m³, detection of trichlorethylene≤25 ppm, detection of chromium compounds≤0.27 mg/m³, detection of manganese and its inorganic compounds≤2.66 mg/m³, detection of vinyl chloride≤0.53 ppm, for meeting the clean room requirement of ZAPClean Room 3.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 5,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 1 pings (i.e., 6.9 square meters, 74.7 square feet) for one air cleaning device 2, and include detection of suspended particulate matter PM 2.5≤0.20 μg/m³, detection of suspended particulate matter PM 10≤0.32 μg/m³, detection of bacteria and fungi≤30 CFU/m³, detection of formaldehyde≤0.05 ppm, detection of volatile organic compounds (TVOC)≤0.33 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤5 ppm, detection of ozone≤0.035 ppm, detection of methane≤12 ppm, detection of toluene≤59 ppm, detection of nitric oxide and nitrogen dioxide≤0.059 ppm, detection of sulfur dioxide≤0.044 ppm, detection of radon≤57 Bq/m³, detection of ammonia≤14 ppm, detection of chlorine≤0.59 ppm, detection of hydrogen cyanide≤6 ppm, detection of hydrogen sulfide≤6 ppm, detection of bromopropane≤0.06 ppm, detection of acetaldehyde≤57 ppm, detection of mercury and its compounds≤0.006 mg/m³, detection of dioxin≤0.59 ng-TEQ/Nm³, detection of acrolein≤0.06 ppm, detection of dichloropropane≤43 ppm, detection of dichloromethane≤28 ppm, detection of acrylonitrile≤1.18 ppm, detection of 1,3-dichloropropene≤0.59 ppm, detection of nickel compounds≤0.59 mg/m³, detection of organic arsenic compounds≤0.59 ppm, detection of dichloroethylene≤117 ppm, detection of polychlorinated biphenyls≤0.006 mg/m³, detection of benzene≤0.59 ppm, detection of ethylene oxide ≤0.59 ppm, detection of polycyclic organic matter≤0.59 ppm, detection of beryllium and its compounds≤0.0012 mg/m³, detection of quinoline≤0.0006 ppm, detection of 1,3-butadiene≤2.95 ppm, detection of hexachlorobenzene≤0.59 pm, detection of 1,1,2,2-tetrachloroethane≤0.59p pm, detection of cadmium and its compounds≤0.030 mg/m³, detection of hydrazine≤0.06 ppm, detection of tetrachlorethylene≤28 ppm, detection of chloroform≤5 ppm, detection of lead and its inorganic compounds≤0.030 mg/m³, detection of trichlorethylene≤28 ppm, detection of chromium compounds≤0.30mg/m³, detection of manganese and its inorganic compounds≤2.95 mg/m³, detection of vinyl chloride≤0.59 ppm, for the clean room requirement of ZAPClean Room 4.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 10,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 3 pings (i.e., 9.9 square meters, 106.8 square feet) for one air cleaning device 1, and include detection of suspended particles PM 2.5≤0.4 μg/m³, detection of suspended particles PM 10≤0.64 μg/m³, detection of bacteria≤80 CFU/m³, detection of fungi≤60 CFU/m³, detection of formaldehyde≤0.05 ppm, detection of volatile organic compounds (TVOC)≤0.33 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤5 ppm, detection of ozone≤0.035 ppm, detection of methane≤12 ppm, detection of toluene≤59 ppm, detection of nitric oxide and nitrogen dioxide≤0.043 ppm, detection of sulfur dioxide≤0.059 ppm, detection of radon≤64 Bq/m³, detection of ammonia≤16 ppm, detection of chlorine≤0.66 ppm, detection of hydrogen cyanide detection≤7 ppm, detection of hydrogen sulfide detection≤7p pm, detection of bromopropane≤0.07 ppm, detection of acetaldehyde≤64 ppm, detection of mercury and its compounds≤0.007 mg/m³, detection of dioxin≤0.66 ng-TEQ/Nm³, detection of acrolein≤0.07 ppm, detection of dichloropropane≤48 ppm, detection of methylene chloride≤32ppm, detection of acrylonitrile≤1.31 ppm, detection of 1,3-dichloropropene 0.66 ppm, detection of nickel compounds≤0.66 mg/m³, detection of organic arsenic compounds≤0.33 ppm, detection of dichloroethylene≤130ppm, detection of polychlorinated biphenyls≤0.007 mg/m³, detection of benzene≤0.66 ppm, detection of ethylene oxide≤0.66 ppm, detection of polycyclic organic matter≤0.66 ppm, detection of beryllium and its compounds≤0.0013 mg/m³, detection of quinoline≤0.0007 ppm, detection of 1,3-butadiene≤3.28 ppm, detection of hexachlorobenzene≤0.66 ppm, detection of 1,1,2,2-tetrachloroethane≤0.66 ppm, detection of cadmium and its compounds≤0.033 mg/m³, detection of hydrazine≤0.07 ppm, detection of tetrachlorethylene≤32 ppm, detection of chloroform≤6 ppm, detection of lead and its inorganic compounds≤0.033 mg/m³, detection of trichlorethylene≤32 ppm, detection of chromium compounds≤0.33 mg/m³, detection of manganese and its inorganic compounds≤3.28 mg/m³, detection of vinyl chloride≤0.66 ppm, for the clean room requirement of ZAPClean Room 5.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 25,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 5 pings (i.e., 16.5 square meters, 177.9 square feet) for one air cleaning device 1, and include detection of suspended particles PM 2.5≤1.0 μg/m³, detection of suspended particles PM 10≤1.6 g/m³, detection of bacteria≤200 CFU/m³, detection of fungi≤150 CFU/m³, detection of formaldehyde≤0.056 ppm, detection of volatile organic compounds (TVOC)≤0.37 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤6 ppm, detection of ozone≤0.040 ppm, detection of methane≤13 ppm, detection of toluene≤66 ppm, detection of nitric oxide and nitrogen dioxide≤0.066 ppm, detection of sulfur dioxide (SO2)≤0.049 ppm, detection of radon≤72 Bq/m³, detection of ammonia≤18 ppm, detection of chlorine≤0.73 ppm, detection of hydrogen cyanide≤7 ppm, detection of sulfide hydrogen≤7 ppm, detection of bromopropane≤0.07 ppm, detection of acetaldehyde≤72 ppm, detection of mercury and its compounds≤0.007 mg/m³, detection of dioxin≤0.73 ng-TEQ/Nm³, detection of acrolein≤0.07 ppm, detection of dichloropropane≤54 ppm, detection of dichloromethane≤36 ppm, detection of acrylonitrile≤1.46 ppm, detection of 1,3-dichloropropene≤0.73 ppm, detection of nickel compounds≤0.73 mg/m³, detection of organic arsenic compound≤0.36 ppm, detection of ethylene dichloride≤145 ppm, detection of polychlorinated biphenyls≤0.007 mg/m³, detection of benzene≤0.73 ppm, detection of ethylene oxide≤0.73 ppm, detection of polycyclic organic matter≤0.73 ppm, detection of beryllium and its compounds≤0.0013 mg/m³, detection of quinoline≤0.0007 ppm, detection of 1,3-butadiene≤3.65 ppm, detection of hexachlorobenzene≤0.73 ppm, detection of 1,1,2,2-tetrachloroethane≤0.73 ppm, detection of cadmium and its compounds≤0.036 mg/m³, detection of hydrazine≤0.07 ppm, detection of tetrachlorethylene≤36 ppm, detection of chloroform≤7 ppm, detection of lead and its inorganic compounds≤0.036 mg/m³, detection of trichlorethylene≤36 ppm, detection of chromium compounds≤0.36 mg/m³, detection of manganese and its inorganic compounds≤3.65 mg/m³, detection of vinyl chloride≤0.73 ppm, for the clean room requirement of ZAPClean Room 6.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 50,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 7 pings (i.e., 23.6 square meters, 254.2 square feet) for one air cleaning device 1, and include detection of suspended particles PM 2.5≤2.1 μg/m³, detection of suspended particles PM 10≤3.2 μg/m³, detection of bacteria ≤500 CFU/m3, detection of fungi≤350 CFU/m³, detect formaldehyde≤0.068 ppm, detection of volatile organic compounds (TVOC)≤0.45 ppm, detection of carbon dioxide≤800 ppm, detection of carbon monoxide≤7 ppm, detection of ozone≤0.050 ppm, detection of methane≤16 ppm, detection of toluene≤81 ppm, detection of nitric oxide and nitrogen dioxide≤0.081 ppm, detection of sulfur dioxide≤0.061 ppm, detection of radon≤81 Bq/m³, detection of ammonia≤20 ppm, detection of chlorine≤0.81 ppm, detection of hydrogen cyanide≤8 ppm, detection of hydrogen sulfide≤8 ppm, detection of bromopropane≤0.08 ppm, detection of acetaldehyde≤81 ppm, detection of mercury and its compounds≤0.008 mg/m³, detection of dioxin≤0.81 ng-TEQ/Nm³, detection of acrolein≤0.08 ppm, detection of dichloropropane≤60.75 ppm, detection of methylene chloride≤40.5 ppm, detection of acrylonitrile≤1.62ppm, detection of 1,3-dichloropropene≤0.81 ppm, detection of nickel compounds≤0.81 mg/m³, detection of organic arsenic compound≤0.41 ppm, detection of dichloroethylene≤162 ppm, detection of polychlorinated biphenyls≤0.08 mg/m³, detection of benzene≤0.81 ppm, detection of ethylene oxide≤0.81 ppm, detection of polycyclic organic matter≤0.81 ppm, detection of beryllium and its compounds≤0.0016mg/m³, detection of quinoline≤0.0008 ppm, detection of 1,3-butadiene≤4.05 ppm, detection of hexachlorobenzene≤0.81 ppm, detect 1,1,2,2-tetrachloroethane≤0.81 ppm, detection of cadmium and its compounds ≤0.041 mg/m³, detection of hydrazine≤0.08 ppm, detection of tetrachlorethylene≤40.5 ppm, detection of chloroform≤8.1 ppm, detection of lead and its inorganic compounds≤0.041 mg/m³, detection of trichlorethylene≤40.5 ppm, detecting chromium compounds≤0.41 mg/m3, detection of manganese and its inorganic compounds≤4.05 mg/m³, detection of vinyl chloride≤0.81 ppm, for the clean room requirement of ZAPClean Room 7.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 100,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 10 pings (i.e., 33.7 square meters, 363.1 square feet) for one air cleaning device 1, and include detection of suspended particles PM 2.5≤4.2 μg/m³, detection of suspended particles PM 10≤6.4 μg/m³, detection of bacteria≤1000 CFU/m³, detection of fungi≤750 CFU/m³, detection of formaldehyde≤0.08 ppm, detection of volatile organic compounds (TVOC)≤0.56 ppm, detection of carbon dioxide≤1000 ppm, detection of carbon monoxide≤8 ppm, detection of ozone≤0.055 ppm, detection of methane≤18 ppm, detection of toluene≤90 ppm, detection of nitric oxide and nitrogen dioxide≤0.090 ppm, detection of sulfur dioxide (SO2)≤0.068 ppm, detection of radon≤90 Bq/m³, detection of ammonia≤23 ppm, detection of chlorine≤0.90 ppm, detection of hydrogen cyanide≤9 ppm, detection of sulfide hydrogen≤9 ppm, detection of bromopropane≤0.09 ppm, detection of acetaldehyde≤90 ppm, detection of mercury and its compounds≤0.009 mg/m³, detection of dioxin≤0.9 0ng-TEQ/Nm³, detection of acrolein≤0.09 ppm, detection of dichloropropane≤67.5 ppm, detection of dichloromethane≤45 ppm, detection of acrylonitrile≤1.80 ppm, detection of 1,3-dichloropropene≤0.90 ppm, detection of nickel compounds≤0.90 mg/m³, detection of organic arsenic compounds≤0.45 ppm, detection of dichloroethylene ≤180 ppm, detection of polychlorinated biphenyls≤0.009 mg/m³, detection of benzene≤0.90 ppm, detection of ethylene oxide≤0.90 ppm, detection of polycyclic organic compounds≤0.90 ppm, detection of beryllium and its compounds≤0.0018 mg/m³, detection of quinoline≤0.0009 ppm, detection of 1,3-butadiene≤4.50 ppm, detection of hexachlorobenzene≤0.90 ppm, detect 1,1,2,2-tetrachloroethane≤0.90 ppm, detection of cadmium and its compounds≤0.045 mg/m³, detection of hydrazine≤0.09 ppm, detection of tetrachlorethylene≤45 ppm, detection of chloroform≤9 ppm, detection of lead and its inorganic compounds≤0.045 mg/m³, detection of trichlorethylene≤45 ppm, detection of chromium compounds≤0.45 mg/m³, detection of manganese and its inorganic compounds≤4.50 mg/m³, detection of vinyl chloride≤0.90 ppm, for the clean room requirement of ZAPClean Room 8.

The air pollution data for the gas state of the air pollution in the indoor field A is targeted according to a cumulative number of 200,000,000 of PM2.5 inhaled suspended particles detected in 24 hours and a required indoor field space of 15 pings (i.e., 48.2 square meters, 518.7 square feet) for one air cleaning device 1, and include detection of suspended particles PM 2.5≤8.5 μg/m3, detection of suspended particles PM 10≤12.7 g/m³, detection of bacteria≤1500 CFU/m³, detection of fungi≤1000 CFU/m³, detection of formaldehyde≤0.08 ppm, detection of volatile organic compounds (TVOC)≤0.56 ppm, detection of carbon dioxide≤1000 ppm, detection of carbon monoxide≤9 detection of, detect ozone≤0.06 ppm, detection of methane≤20 ppm, detection of toluene≤100 ppm, detection of nitric oxide and nitrogen dioxide≤0.100 ppm, detection of sulfur dioxide≤0.075 ppm, detection of radon≤100 Bq/m³, detection of ammonia≤25 ppm, detection of chlorine≤1.00 ppm, detection of hydrogen cyanide≤10 ppm, detection of hydrogen sulfide≤10 ppm, detection of bromopropane≤0.1 ppm, detection of acetaldehyde≤100 ppm, detection of mercury and its compounds≤0.01 mg/m³, detection of dioxin ≤1 ng-TEQ/Nm³, detection of acrolein≤0.1 ppm, detection of dichloropropane≤75 ppm, detection of dichloromethane≤50 ppm, detection of acrylonitrile≤2 ppm, detection of 1,3-dichloropropene≤1 ppm, detection of nickel compounds≤1 mg/m³, detection of organic arsenic compounds≤0.5 ppm, detection of dichloroethylene≤200 ppm, detection of polychlorinated biphenyls≤0.01 mg/m³, detection of benzene≤1 ppm, detection of ethylene oxide≤1 ppm, detection of polycyclic organic matter≤1 ppm, detection of beryllium and its compounds≤0.002 mg/m³, detection of quinoline≤0.001 ppm, detection of 1,3-butadiene≤5 ppm, detection of hexachlorobenzene≤1 ppm, detection of 1,1,2,2-tetrachloroethane≤1 ppm, detection of cadmium and its compounds≤0.05 mg/m³, detection of hydrazine≤0.1 ppm, detection of tetrachlorethylene≤50 ppm, detection of chloroform≤10 ppm, detection of lead and its inorganic compounds≤0.05 mg/m³, detection of trichlorethylene≤50 ppm, detection of chromium compounds≤0.5 mg/m³, detection of manganese and its inorganic compounds≤5 mg/m³, detection of vinyl chloride≤1 ppm, for the clean room requirement of ZAPClean Room 9.

In summary, the present disclosure provides an indoor air cleaning system. An air cleaning device includes at least one air cleaning component and a gas detection module assembled into one piece, disposed in an indoor field for detecting, locating, circulating and filtering air pollution, and installed in the indoor field through a build-in or plug-in manner. The gas detection module implements air pollution detection to output air pollution data. Moreover, a networked cloud computing service device receives the air pollution data through the wireless communication or the wired communication. Since the communication transmission can be achieved by using the wireless communication or the wired communication, the dual methods of the wired communication and the wireless communication are selected to implement an operable transmission communication mechanism. The intelligent computing comparison based on the database of the air pollution data is performed to intelligently select and output the control command. Then, the control command is transmitted to the gas detection module to regulate the activation operation of the air cleaning device through an operable transmission communication mechanism of the wired communication and the wireless communication. In that, the air pollution processing operation of the air cleaning device is controlled. Thereby, a gas state of the air pollution in the indoor field reaches a clean room requirement of ZAPClean Room 1˜9. It avoids being exposed to hazardous gas in the environment that may cause the human health impacts and injuries. The present disclosure includes the industrial applicability and the inventive steps.