TWM608555U - Air purification circulation system with real-time monitoring function - Google Patents

Abstract

This model is an air purification circulation system with real-time monitoring function, which includes an air-conditioning device, a real-time biological sensing module, an air valve, a second air outlet pipe and a return air pipe; the air-conditioning device uses a dehumidification and sterilization The solution dehumidifies and sterilizes the outside air and discharges it. The real-time biosensing module measures and judges whether the discharged air meets the standard. If it does not, the discharged air is switched to the return air duct through the air valve to make the discharge The gas returns to the air-conditioning device through the return air duct and performs secondary sterilization until the real-time biosensing module determines that the exhaust air meets the standard; in this way, the real-time biosensing module controls the switching of the air valve, The discharged air is selectively discharged into the second air outlet duct or the return air duct to achieve the effect of real-time control of the sterilization ability according to the content of pathogens in the air.

Description

Air purification circulation system with real-time monitoring function

This model is an air purification circulation system, especially an air purification circulation system with real-time monitoring function.

Air sterilization ability is the main research and development and construction project of air-conditioning systems in various buildings after global climate abnormalities, especially in buildings where people gather, such as factories or office buildings, or like medical institutions. Or food processing plants that have special requirements for the number of pathogens in the air, and modern people are almost in a closed air-conditioned environment from morning to night, so a liquid dehumidification device is proposed to achieve the required sterilization function.

As shown in FIG. 5, a conventional wet air conditioner 90 includes an air inlet pipe 91, a water collection tank 92, a dehumidification and sterilization tank 93, a plurality of nozzles 94, an air outlet 95, a pump 96, and a water pipe. 97 and a dehumidification and sterilization solution 98, the air inlet pipe 91 receives an outside air and discharges it into the dehumidification and sterilization tank 93; the water collection tank 92 is arranged under the dehumidification and sterilization tank 93 and contains the dehumidification and sterilization solution 98 The pump 96 is connected to the water collection tank 92, and the dehumidification and sterilization solution 98 is pumped into the water pipe 97. The nozzles 94 are arranged at the outlet pipe 95 of the dehumidification and sterilization tank 93 and connected to the water pipe 97, In order to spray the dehumidification and sterilization solution 98 in the dehumidification and sterilization tank 83, the discharged air is sterilized in the dehumidification and sterilization tank 93 and the dehumidification and sterilization solution 98, and then the sterilized air is discharged into the outlet pipe 95 to achieve The effect of air sterilization.

However, the sterilization ability of the wet air conditioner 90 is based on preset parameters, such as the intensity of spraying the dehumidifying and sterilizing solution 98 by the nozzles 94, or the output pressure of the pump 96, which cannot be changed immediately according to the air, such as the sudden number of germs. Ascending to immediately strengthen the sterilization ability of the wet-type air-conditioning device 90, therefore, it is necessary to improve the existing wet-type air-conditioning device.

In view of the shortcomings of the above-mentioned wet air conditioner, the main purpose of the present invention is to provide a new air purification circulation system with real-time monitoring function to solve the above-mentioned problems.

The main technical means used to achieve the above-mentioned new purpose is to make the air purification circulation system of the real-time monitoring function include: an air-conditioning device, which includes an air inlet pipe, a first air outlet pipe and a dehumidification and sterilization tank. The air duct is connected to an air inlet end of the dehumidification and sterilization tank and receives an outside air. The first air outlet pipe is connected to a filter end of the dehumidification and sterilization tank and discharges the air sterilized by the dehumidification and sterilization tank. The dehumidification and sterilization tank contains a dehumidification and sterilization solution; a first real-time biosensing module is preset with a biological content standard range, and is set at the first air outlet pipe of the air conditioning device to measure and determine the Whether the biological content in the air discharged by the air conditioner exceeds the biological content standard range; an air valve is connected to the first air outlet pipe and electrically connected to the first real-time biological sensing module, and the first real-time biological The sensing module controls the switching of the air valve; a second air outlet pipe is connected to the air valve and selectively communicates with the first air outlet pipe through the air valve; and A return air pipe is connected to the air valve and the air inlet pipe, and selectively communicates with the first air outlet pipe through the air valve; wherein: when the first real-time biosensing module determines the air discharged from the air conditioner When the biological content in the air is lower than the standard range of biological content, the air valve is controlled to make the first air outlet pipe communicate with the second air outlet pipe, and the discharged air is discharged into the second air outlet pipe; and when the first air outlet The real-time biological sensing module determines that the biological content in the air discharged from the air conditioner is higher than the first biological content standard value, and controls the air valve to make the first air outlet pipe communicate with the return air pipe, and discharge the discharged air Enter the return air duct and send it back to the air-conditioning device for re-sterilization.

The advantage of the present invention is that the first real-time biological sensing module is arranged at the first air outlet pipe of the air-conditioning device, and the air valve is controlled by the biological sensing module, and the air valve is controlled by the first real-time biological sensing module. The sensing module measures and judges the result of the air discharged from the first air outlet pipe in real time, and selectively controls the air valve so that the discharged air that meets the standard is discharged from the second air outlet pipe or sent into the return flow The air duct is sterilized again by the air-conditioning device to achieve the effect of instant sterilization according to the content of pathogens in the air.

The main technical means used to achieve the above-mentioned new purpose is to make the air purification circulation system of the real-time monitoring function include: an air-conditioning device, which includes an air inlet pipe, a first air outlet pipe and a dehumidification and sterilization tank. The air duct is connected to an air inlet end of the dehumidification and sterilization tank and receives an outside air. The first air outlet pipe is connected to a filter end of the dehumidification and sterilization tank and discharges the air sterilized by the dehumidification and sterilization tank. The dehumidification and sterilization tank contains a dehumidification and sterilization solution; a first real-time biosensing module is preset with a biological content standard range, and is set at the first air outlet pipe of the air conditioning device to measure and determine the Whether the biological content in the air discharged from the air-conditioning device exceeds the biological content standard range; A second air outlet pipe is connected to the first air outlet pipe; and a first sterilization module is arranged between the first real-time biosensing module and the second air outlet pipe, and is electrically connected The first real-time biological sensing module is controlled by the first real-time biological sensing module to turn on or off the first sterilization module; wherein: when the first real-time biological sensing module determines the air discharged from the air conditioner When the biological content in the air conditioner is lower than the biological content standard range, the first sterilization module is turned off; and when the first real-time biosensing module determines that the biological content in the air discharged from the air conditioning device is higher than the biological content standard range, Turn on the first sterilization module to further sterilize the discharged air.

The advantage of the present invention is that the first real-time biosensing module is arranged at the first air outlet pipe of the air conditioning device, and the first real-time biosensing module controls the opening of the first sterilization module Or closed, when the first real-time biosensing module measures and judges that the air discharged by the first air outlet meets the standard, close the first sterilization module and open the air directly from the second air outlet; If it does not meet the requirements, turn on the first sterilization module to sterilize the discharged air again before discharging it into the second air outlet pipe, achieving the effect of instant sterilization according to the pathogen content in the air.

1a, 1b, 1c, 1d, 1e, 1f: air purification circulation system

10, 10a, 10b, 10c: air conditioner

11: Inlet duct

110: Adjustable damper

12: The first air outlet

120: Windmill Module

13: Dehumidification and sterilization tank

131: intake end

132: filter end

14: Dehumidifying and sterilizing solution

14’: Dehumidification and sterilization solution

15: Sump

16: pump

17: Cooling device

171: The first water pipe

18: Nozzle

19: Bubble generating device

191: Bubble

20: The first real-time biosensing module

20’: The second real-time biosensing module

21: The first gaseous molecular pollutant detection module

21’: The second gaseous molecular pollutant detection module

22: The first particle detection module

22’: The second particle detection module

30: Air valve

40: The second air duct

41: The first extension duct

410: Indoor Space

42: Differential pressure gauge

43: The second extension duct

44: The third sterilization module

50: Return air duct

60: The first sterilization module

70: The second sterilization module

80: Regenerative device

81: Recycled water collection tank

82: Regenerative Pump

821: second water pipe

822: third water pipe

83: heating device

831: third water pipe

84: sprinkler

85: Regeneration tank

851: intake end

852: exhalation

86: Regenerative inlet pipe

87: Regenerative air duct

90: Wet air conditioner

91: Inlet pipe

92: Sump

93: Dehumidification and sterilization tank

94: Nozzle

95: Outlet pipe

96: Pump

97: water pipe

98: Dehumidifying and sterilizing solution

Fig. 1A: The functional block diagram of the first embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Fig. 1B: The functional block diagram of the second embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Fig. 1C: The functional block diagram of the third embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Fig. 1D: The functional block diagram of the fourth embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Fig. 2A: The functional block diagram of the fifth embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Fig. 2B: The functional block diagram of the sixth embodiment of the air purification circulation system with real-time monitoring function of the present invention.

Figure 3: Schematic diagram of the air purification circulation system with the new real-time monitoring function.

Fig. 4A: A schematic diagram of the first embodiment of the new air conditioner.

Fig. 4B: A schematic diagram of the second embodiment of the new air conditioner.

Fig. 4C: A schematic diagram of the third embodiment of the new air conditioner.

Fig. 4D: A schematic diagram of the fourth embodiment of the new air conditioner.

Figure 5: A schematic diagram of a wet air conditioner in the prior art.

The present invention proposes a new air purification circulation system with real-time monitoring function. The following is a detailed description of the technology of the present invention with a number of embodiments and figures.

First, please refer to FIG. 1A, which is the first embodiment of the air purification circulation system 1a with real-time monitoring function of the present invention, which includes an air-conditioning device 10, a first real-time biological sensing module 20, an air valve 30, and a second outlet The air duct 40 and a return air duct 50, wherein the air-conditioning device 10 is connected to the air valve 30, the The first real-time biosensing module 20 is arranged between the air conditioner 10 and the air valve 30, and is electrically connected to the air valve 30, so that the air valve 30 is selectively connected to the second air outlet pipe 40 or the return flow The wind pipe 50.

The air conditioner 10 includes an air inlet pipe 11, a first air outlet pipe 12, and a dehumidification and sterilization tank 13. In this embodiment, please refer to FIG. 4A. The air conditioner 10 includes a dehumidification and sterilization solution 14. The air inlet pipe 11 is connected to an inlet end 131 of the dehumidification and sterilization tank 13, and the outside air is introduced into the dehumidification and sterilization tank 13, and the dehumidification and sterilization solution 14 in the dehumidification and sterilization tank 13 is dehumidified and sterilized. The first air outlet pipe 12 is connected to a filter end 132 of the dehumidification and sterilization tank 13 to discharge the air sterilized by the dehumidification and sterilization tank 13; in this embodiment, the dehumidification and sterilization solution 14 is an absorbent with a viscosity between 0.1 cps and 100 cps; Preferably, the dehumidifying and sterilizing solution 14 is an absorbent with a viscosity ranging from 0.5 cps to 50 cps.

The above-mentioned absorbent can be a salt liquid or an ionic liquid, as long as it has the functions of dehumidification, sterilization, dust removal (including PM10 and PM2.5), and removal of airborne molecular contamination (AMC, Airborne Molecular Contamination). The agent can be used as the dehumidifying and sterilizing solution 14 of this new type.

The first real-time biosensing module 20 is arranged at the first air outlet 12 of the air-conditioning system 10, and a biological content standard range is preset; in this embodiment, the first real-time biosensing module 20 is to measure and determine whether the air in the first air outlet pipe 12 exceeds the biological content standard range; preferably, the first real-time biosensing module 20 uses optical sensing to determine the size of particles in the air (size 0.5 μm to 30 μm) and the number of particles, and further use different wavelengths of light to determine whether the particles are microorganisms and the types of microorganisms.

In another embodiment, the air purification circulation system 1a with the real-time monitoring function of the present invention can be further provided with a first gaseous molecular pollutant detection module 21 or a first particle detection module 22, which is also provided in the air conditioning system 10 At the first air outlet pipe 12, the first gaseous molecular pollutant detection module Group 21 is preset with a pollutant content standard range, wherein the first gaseous molecular pollutant detection module 21 measures and determines whether the air in the first air outlet pipe 12 exceeds the pollutant content standard range; A particle detection module 22 is preset with a particle content standard range, wherein the first particle detection module 22 measures and determines whether the air in the first air outlet duct 12 exceeds the particle content standard range; For example, the first gaseous molecular pollutant detection module 21 and the first particle detection module 22 are installed at the first air outlet pipe 12 of the air conditioning system 10 at the same time, and the first air outlet pipe 12 is measured and judged at the same time. Whether the air in the air duct 12 exceeds the standard range of the pollutant content and the standard range of the particulate content.

The air valve 30 is connected to the first air outlet pipe 12 and electrically connected to the first real-time biological sensing module 20; in this embodiment, the air valve is controlled by the first real-time biological sensing module 20 30 switch; in another embodiment, the gas valve 30 is further electrically connected to the first gaseous molecular pollutant detection module 21 or the first particle detection module 22, and further by the first gaseous molecule The pollutant detection module 21 or the first particle detection module 22 controls the switching of the gas valve 30; in another embodiment, the gas valve 30 is electrically connected to the first gaseous molecular pollutant detection module 21 and The first particle detection module 22 is further controlled by the first gaseous molecular pollutant detection module 21 and the first particle detection module 22 to control the switching of the gas valve 30.

The second air outlet pipe 40 is connected to the air valve 30; in this embodiment, when the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioning device 10 is lower than the biological content standard range , That is, the air valve 30 is switched so that the first air outlet pipe 12 is connected with the second air outlet pipe 40, and the discharged air is discharged into the second air outlet pipe 40; in another embodiment, it is further based on the first air outlet pipe 40 A gaseous molecular pollutant detection module 21 or the first particle detection module 22 determines that the pollutant content in the air discharged from the air conditioning device 10 is lower than the pollutant content standard range or the particulate content is lower than the particulate content standard range , That is, the air valve 30 is switched to make the first air outlet pipe 12 communicate with the second air outlet pipe 40, and the discharged air is discharged into The second air outlet pipe 40; in another embodiment, it is further based on the first gaseous molecular pollutant detection module 21 and the first particle detection module 22 to determine the pollutants in the air discharged from the air conditioning device 10 The content is lower than the standard range of the pollutant content and the particle content is lower than the standard range of the particle content, that is, the air valve 30 is switched so that the first air outlet pipe 12 and the second air outlet pipe 40 are connected, and the discharged air is discharged into The second air outlet pipe 40.

The above-mentioned return air pipe 50 is connected to the air valve 30 and the air inlet pipe 11; in this embodiment, when the first real-time biological sensing module 20 determines that the biological content in the air discharged from the air conditioning device 10 is higher than that of the biological The content standard range, that is, the air valve 30 is controlled to switch the first air outlet pipe 12 to communicate with the return air pipe 50, and the discharged air is discharged into the return air pipe 50 and sent back to the air conditioner 10 to be sterilized again; In an embodiment, it is further determined according to the first gaseous molecular pollutant detection module 21 or the first particle detection module 22 that the pollutant content in the air discharged from the air conditioning device 10 is higher than the pollutant content standard range or particulates The content is higher than the standard range of particle content, that is, the air valve 30 is controlled to make the first air outlet pipe 12 communicate with the return air pipe 50, and the discharged air is sent back to the air conditioner 10 through the return air pipe 50, and removed again Pollutants or particulate removal; in another embodiment, it is further determined based on the first gaseous molecular pollutant detection module 21 and the first particulate detection module 22 that the pollutant content in the air discharged from the air conditioning device 10 is high When the pollutant content standard range and the particulate content are higher than the particulate content standard range, the air valve 30 is switched to connect the first air outlet pipe 12 with the return air pipe 50, and the discharged air passes through the return air pipe 50 Return to the air conditioner 10 to remove pollutants and particles again.

It can be seen from the above description that the air purification circulation system 1a with real-time monitoring function of the present invention is to install the first real-time biological sensing module 20 at the first air outlet pipe 12 of the air-conditioning device 10, and according to the A real-time biosensing module 20 measures and judges the result of the air discharged from the first air outlet pipe 12, and selectively controls the air valve 30 so that the air valve 30 discharges the discharged air into the second air outlet Tube 40, Or make the air valve 30 discharge the exhausted air into the return air duct 50, and send it back to the air conditioning device for re-sterilization, so as to achieve the effect of instantly controlling the sterilization ability according to the pathogen content in the air; or further set the first A gaseous molecular pollutant detection module 21 or the first particle detection module 22 is located at the first air outlet pipe 12 of the air-conditioning device 10, according to the first gaseous molecular pollutant detection module 21 or the first air outlet pipe 12 A particle detection module 22 measures and judges the result of the air discharged from the first air outlet pipe 12, and selectively controls the air valve 30 so that the air valve 30 discharges the discharged air into the second air outlet pipe 40 , Or make the air valve 30 discharge the exhausted air into the return air duct 50, and send it back to the air conditioning device to remove pollutants or particulates again, and further achieve immediate control based on the pollutant content or particulate content in the air The effect of the ability to remove pollutants or particles; or at the same time provide the first gaseous molecular pollutant detection module 21 and the first particle detection module 22 at the first air outlet pipe 12 of the air conditioning system 10 , And according to the first gaseous molecular pollutant detection module 21 and the first particle detection module 22 to determine the results of measuring and judging the air discharged from the first air outlet pipe 12, the air valve 30 is selectively controlled , Make the air valve 30 discharge the discharged air into the second air outlet pipe 40, or make the air valve 30 discharge the discharged air into the return air pipe 50, and send it back to the air conditioner to remove pollutants again And particles, to achieve the effect of real-time control of the ability to remove pollutants and particles according to the content of pollutants and particles in the air.

Please refer to Figure 1B, which is the second embodiment of the air purification circulation system 1b with the new real-time monitoring function; the air circulation purification system 1b of this embodiment is roughly the same as the air circulation purification system 1a shown in Figure 1A, but the A first sterilization module 60 is further provided between the air valve 30 and the second air outlet pipe 40, and is electrically connected to the first real-time biosensing module 20, which is controlled by the first real-time biosensing module 20 The first sterilization module 60 is turned on or off; in this embodiment, the biological content standard range preset by the first real-time biosensing module 20 includes a first standard value and a second standard value, the second standard The value is greater than the first standard value; preferably, the first sterilization module 60 is an ultraviolet sterilization module.

When the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioner 10 is lower than the first standard value, the first sterilization module 60 is closed and the air valve 30 is controlled so that the first The air outlet pipe 12 communicates with the second air outlet pipe 40, and discharges the exhausted air into the second air outlet pipe 40; when the first real-time biological sensing module 20 determines the biological content in the air discharged from the air conditioner 10 The content is between the first standard value and the second standard value, that is, the first sterilization module 60 is turned on and the air valve 30 is controlled to make the first air outlet pipe 12 communicate with the second air outlet pipe 40, The discharged air is further sterilized by the first sterilization module 60 and then discharged into the second air outlet pipe 40; when the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioner 10 is higher than For the second standard value, close the first sterilization module 60 and control the air valve 30 to connect the first air outlet pipe 12 with the return air pipe 50, and send the discharged air back to the air conditioner 10 for re-sterilization; In addition, the first gaseous molecular pollutant detection module 21 or the first particle detection module 22 that is the same as the air purification circulation system 1a can be further provided at the first air outlet pipe 12 of the air conditioning system 10; That.

It can be seen from the above description that the air purification circulation system 1b with real-time monitoring function of the present invention is further provided with the first sterilization module 60 between the air valve 30 and the second air outlet pipe 40, so that the first air outlet The air discharged from the pipe 12 can be discharged into the second air outlet pipe 40 after further sterilization, instead of being discharged into the return air pipe 50 to be sterilized in the air conditioner 10 again, reducing the sterilization time and increasing energy usage.

Please refer to FIG. 1C, which is the third embodiment of the air purification circulation system 1c with the real-time monitoring function of the present invention; the air circulation purification system 1c of this embodiment is roughly the same as the air circulation purification system 1a shown in FIG. A second sterilization module 70 is further provided between the air valve 30 and the return air duct 50, and is electrically connected to the first real-time biological sensing module 20, and the second real-time biological sensing module 20 is controlled by the second sterilization module 70. The sterilization module 70 is turned on or off; in this embodiment, the first real-time biosensing module 20 is preset The standard range of the biological content includes a first standard value and a second standard value, and the second standard value is greater than the first standard value; preferably, the second sterilization module 70 is an ultraviolet sterilization module.

When the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioner 10 is lower than the first standard value, the second sterilization module 70 is closed and the air valve 30 is controlled so that the first The air outlet pipe 12 communicates with the second air outlet pipe 40, and discharges the exhausted air into the second air outlet pipe 40; when the first real-time biological sensing module 20 determines the biological content in the air discharged from the air conditioner 10 The content is between the first standard value and the second standard value, the air valve 30 is controlled to make the first air outlet pipe 12 communicate with the return air pipe 50, and the discharged air is sent back to the air conditioner 10 for another Sterilization; when the first real-time biological sensing module 20 determines that the biological content in the air discharged from the air conditioning device 10 is higher than the second standard value, the second sterilization module 70 is turned on and the air valve 30 is controlled to make the first An outlet pipe 12 is connected to the return air pipe 50, and the discharged air is further sterilized by the second sterilization module 70 and then sent back to the air-conditioning device for re-sterilization; in addition, it can be further sterilized in the first air-conditioning system 10 The air outlet pipe 12 is provided with the first gaseous molecular pollutant detection module 21 or the first particle detection module 22 that is the same as the air purification circulation system 1a, and the pollutant content standard range and the particulate content standard range are also It can be the same as the biological content standard range, and further include multiple standard values.

It can be seen from the above description that the air purification circulation system 1c with real-time monitoring function of the present invention is further provided with the second sterilization module 70 between the air valve 30 and the return air duct 50 to further strengthen the air of the real-time monitoring function. Purify the sterilization ability of the circulation system 1c and reduce the number of backflows.

Please refer to Figure 1D, which is the fourth embodiment of the air purification circulation system 1d with the new real-time monitoring function; the air circulation purification system 1d of this embodiment is roughly the same as the air circulation purification system 1b shown in Figure 1B, but the A second sterilization module 70 is further provided between the air valve 30 and the return air duct 50, and is electrically connected to the first real-time biosensing module 20, which is controlled by the first real-time biosensing module 20 The second sterilization module 70 is turned on or off; in this embodiment, the biological content standard range preset by the first real-time biosensing module 20 further includes a third standard value, the third standard value being greater than the The second standard value.

When the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioner 10 is higher than the third standard value, the second sterilization module 70 is turned on and the air valve 30 is controlled so that the first outlet The air duct 12 is in communication with the return air duct 50, and the discharged air is further sterilized by the second sterilization module 70 and then sent back to the air-conditioning device 10 for re-sterilization; in addition, it can be further sterilized in the first outlet of the air-conditioning system 10 The air pipe 12 is provided with the first gaseous molecular pollutant detection module 21 or the first particle detection module 22 which is the same as the air purification circulation system 1a.

From the above description, it can be seen that the air purification circulation system 1d with real-time monitoring function of the present invention is equipped with the first sterilization module 60 and the second sterilization module 70 at the same time, so that it can reduce the sterilization time and increase the energy usage. The effect of reducing the number of reflows.

Please refer to FIG. 2A, which is a fifth embodiment of the air purification circulation system 1e with real-time monitoring function of the present invention, which includes an air-conditioning device 10, a first real-time biosensing module 20, a first sterilization module 60, and A second air outlet pipe 40, in which the air-conditioning device 10 and the first real-time biosensing module 20 are substantially the same as the first embodiment of the air purification circulation system 1a with real-time monitoring function of the present invention.

The second air outlet pipe 40 is connected to the first air outlet pipe 12; the first sterilization module 60 is arranged between the first real-time biosensing module 20 and the second air outlet pipe 40, and is electrically connected Connected to the first real-time biosensing module 20, the first real-time biosensing module 20 controls the opening or closing of the first sterilization module 60; preferably, the first sterilization module 60 is an ultraviolet sterilization Module.

When the first real-time biosensing module 20 determines that the biological content in the air discharged from the air conditioner 10 is lower than the biological content standard range, the first sterilization module 60 is closed to make the first air outlet pipe 12 The discharged air is discharged into the second air outlet pipe 40; when the first real-time biological sensing module 20 determines that the biological content in the air discharged from the air conditioning device 10 is higher than the biological content standard range, the first A sterilization module 60, the air discharged from the first air outlet pipe 12 is further sterilized by the first sterilization module 60 and then discharged into the second air outlet pipe 40; in addition, it can be further used in the first air outlet pipe 40 of the air conditioning system 10 The air outlet pipe 12 is provided with the first gaseous molecular pollutant detection module 21 or the first particle detection module 22 that is the same as the air purification circulation system 1 a.

It can be seen from the above description that the air purification circulation system 1e with real-time monitoring function of the present invention is provided with the first sterilization module 60 between the first real-time biosensing module 20 and the second air outlet pipe 40, and According to the result of measuring and judging the air discharged by the first air outlet pipe 12 by the first real-time biosensing module 20, the first sterilization module 60 is controlled to be turned on or off, so as to realize real-time detection according to the content of pathogens in the air. The effect of controlling the sterilization ability, and compared with the air purification circulation system 1a of the new type real-time monitoring function, the reflux process is omitted.

Please refer to FIG. 2B, which is the sixth embodiment of the air purification circulation system 1f with the new real-time monitoring function; the air circulation purification system 1f of this embodiment is substantially the same as the air circulation purification system 1d shown in FIG. The air valve 30 is provided in the first real-time biological sensing module 20; in addition, the first air outlet pipe 12 of the air conditioning system 10 can be further provided with the same first gas as the air purification circulation system 1a The sex molecule pollutant detection module 21 or the first particle detection module 22.

It can be seen from the above description that the air purification circulation system 1f with real-time monitoring function of the present invention sets the air valve 30 in the first real-time biosensing module 20, which simplifies the pipeline design of the air purification circulation system 1f and enables The air purification circulation system 1f can be applied more flexibly in terms of use design.

In use, as shown in FIG. 3, taking the air purification circulation system 1e with real-time monitoring function as an example, the second air outlet pipe 40 is connected to a first extension air pipe 41, and the first extension air pipe 41 can be for Installed in an indoor space 410, or an original ventilation pipe of the indoor space 410, exhausts air into the indoor space 410, and a second real-time biosensing module 20' is installed in the indoor space 410. A second extended air duct 43 is provided between the indoor space 410 and the air inlet pipe 11 of the air conditioner 10, and the second extended air duct 43 is directly connected to the ventilation pipe or to the indoor space 410, and is connected to The second extension duct 43 is provided with a third sterilization module 44, wherein the second real-time biosensing module 20' and the first real-time biosensing module of the first air outlet 12 of the air conditioning system 10 The test modules 20 are the same; in this embodiment, the second extension duct 43 is connected to the indoor space 410, and the third sterilization module 44 is an ultraviolet sterilization module.

The above-mentioned second real-time biosensing module 20' presets a sterilization module biological standard range, and is electrically connected to the third sterilization module 44; when the second real-time biosensing module 20' determines the indoor space 410 When the biological content in the air in the indoor space 410 is lower than the biological standard range of the sterilization module, the third sterilization module 44 is closed; when the indoor real-time biological sensing module 20' determines that the biological content in the air in the indoor space 410 is higher than The biological standard range of the sterilization module is to turn on the third sterilization module 44 to sterilize the air in the second extension air duct 43 to reduce the content of microorganisms discharged into the air conditioner 10.

In addition, in another embodiment, as shown in FIG. 3, an adjustable damper 110 is further provided on the air inlet pipe 11 of the air purification circulation system 1e, and the first real-time biosensing module 20 and the first real-time biosensing module 20 are further provided with an adjustable damper 110. A windmill module 120 is arranged between the two air outlet pipes 40; in this embodiment, the windmill module 120 can be arranged between the first real-time biosensing module 20 and the first sterilization module 60, and The indoor space 410 is provided with a differential pressure gauge 42; in this embodiment, the windmill module 120 is a variable frequency windmill module, and the adjustable damper 110 selectively controls the external air and the second extended air duct 43 to input The proportion of the air inlet pipe 11.

The second real-time biosensing module 20' further presets a windmill biological standard range and is electrically connected to the windmill module 120; the micro differential pressure gauge 42 is electrically connected to the adjustable damper 110; when the second real-time The biosensing module 20' determines that the biological content in the air in the indoor space 410 is lower than the windmill biological standard range, and turns off the windmill module 120; when the second real-time biosensing module 20' determines the indoor space 410 The biological content in the air is higher than the biological standard range of the windmill, and the windmill module 120 is turned on to speed up the air circulation; at the same time, when the windmill module 120 is turned on, the amount of air delivered to the indoor space 410 increases, and the slight difference The pressure gauge 42 senses the change in air pressure. At this time, the differential pressure gauge 42 controls the adjustable damper 110 to increase the proportion of air discharged into the inlet pipe 11 by the second extended air duct 43, thereby reducing the The air pressure of the indoor space 410 keeps the air pressure of the indoor space 410 unchanged; in another embodiment, the third sterilization module 44 may be further provided.

In addition, a second gaseous molecular pollutant detection module 21' and a second particle detection module 22' can also be further provided, or the second gaseous molecular pollutant detection module 21' and the second gaseous molecular pollutant detection module 21' can be provided at the same time. The particle detection module 22' in the indoor space 410 achieves the effect of real-time control of pollutant removal and particle removal capabilities according to the pollutant content or particle content in the indoor space 410; in this embodiment, the second gaseous property The molecular pollutant detection module 21' is the same as the first gaseous molecular pollutant detection module 21 provided in the first air outlet pipe 12 of the air conditioning system 10, and the second particulate detection module 22' is the same as that provided in The first particle detection module 22 of the first air outlet pipe 12 of the air conditioning system 10 is the same.

The above method of use can also be applied to the air purification circulation systems 1a, 1b, 1c, 1d, and 1f with the real-time monitoring function.

The above is the system introduction of the new air purification circulation system, and the detailed structure of the air-conditioning device 10 will be further described below.

Please refer to FIG. 4A, which is a first embodiment of the new air conditioner 10, which includes an air inlet pipe 11, a first air outlet pipe 12, a dehumidification and sterilization tank 13, a dehumidification and sterilization solution 14, and a water collection tank 15. A pump 16, a cooling device 17 and a plurality of nozzles 18, wherein the water collection tank 15 is connected to the dehumidification and sterilization tank 13, the pump 16 and the cooling device 17 are arranged outside the dehumidification and sterilization tank 13, the The nozzles 18 are arranged in the dehumidification and sterilization tank 13.

The above-mentioned air inlet pipe 11, first air outlet pipe 12, dehumidification and sterilization tank 13, and dehumidification and sterilization solution 14 are the same as the first embodiment of the air purification circulation system 1a with real-time monitoring function of the present invention, and will not be repeated.

The water collection tank 15 is arranged below the dehumidification and sterilization tank 13, and is used to contain the dehumidification and sterilization solution 14.

The above-mentioned pump 16 is connected to the water collection tank 15 and pumps the dehumidifying and sterilizing solution 14 contained in the water collection tank 15 into a first water pipe 171.

The above-mentioned cooling device 17 is arranged at the first water pipe 171 to cool the dehumidifying and sterilizing solution 14 pumped into the first water pipe 171 by the pump 16; in this embodiment, the cooling device 17 is preset to a cooling temperature , The temperature of the dehumidifying and sterilizing solution 14 is lowered to the cooling temperature.

The above-mentioned multiple spray heads 18 are arranged near the first air outlet pipe 12, and are connected to the first water pipe 171 to spray the dehumidifying and sterilizing solution 14 driven by the pump 16; in this embodiment, the spray heads 18 The dehumidification and sterilization solution 14 is atomized and sprayed on the dehumidification and sterilization tank 13, and the water collection tank 15 is used to spread the dehumidification and sterilization solution 14; preferably, the atomization method can be a single pressure atomization, super Sonic atomization or two-fluid method.

It can be seen from the above description that the air-conditioning device 10 of the present invention uses the nozzles 18 to atomize the dehumidification and sterilization solution 14 and spray it on the dehumidification and sterilization tank 13, and the air inlet pipe 11 is connected in a gas-liquid exchange manner. The collected external air is sterilized, and the temperature of the air discharged from the first air outlet pipe 12 can be indirectly controlled by controlling the temperature of the dehumidifying and sterilizing solution 14 to achieve the effects of sterilization and temperature adjustment.

In another embodiment, please refer to FIG. 4A. The air-conditioning device 10 further includes a dehumidifying and sterilizing solution regeneration device 80, which is connected to the pump 16 of the air-conditioning device 10 by a second water pipe 821 to obtain The dehumidifying and sterilizing solution 14 ′ to be regenerated in the sump 15 is sent back to the sump 15 through a third water pipe 822.

The regeneration device 80 includes a regeneration water collection tank 81, a regeneration pump 82, a heating device 83, a plurality of nozzles 84 and a regeneration tank 85, wherein the regeneration water collection tank 81 is connected to the regeneration tank 85, and the regeneration pump 82 The heating device 83 is installed outside the regeneration tank 85, and the nozzles 84 are installed inside the regeneration tank 85.

The above-mentioned regeneration water collection tank 81 is connected to the second water pipe 821 to receive and contain the dehumidifying and sterilizing solution 14' to be regenerated.

The regeneration pump 82 is connected to the regeneration water collection tank 81, and the dehumidification and sterilization solution 14' contained in the regeneration water collection tank 81 is pumped into a fourth water pipe 831.

The heating device 83 is set at the fourth water pipe 831 to heat the dehumidifying solution 14' that the regeneration pump 82 drives into the fourth water pipe 831; in this embodiment, the heating device 83 is preset with a heating Temperature, the dehumidifying and sterilizing solution 14' is heated to the heating temperature.

The above-mentioned nozzles 84 are connected to the fourth water pipe 831 to spray the dehumidification and sterilization solution 14' driven by the regeneration pump 82; in this embodiment, the nozzles 84 are after atomizing the dehumidification and sterilization solution 14' Sprayed in the regeneration tank 85; preferably, the atomization method can be a single pressure atomization, ultrasonic atomization or a two-fluid method.

The regeneration tank 85 includes a regeneration inlet pipe 86 and a regeneration outlet pipe 87; in this embodiment, the regeneration inlet pipe 86 is connected to an inlet end 851 of the regeneration tank 85 and receives an outside air. The regeneration air duct 87 is connected to an air outlet 852 of the regeneration tank 85 and discharges the air passing through the regeneration tank 83, wherein the nozzles 84 are arranged near the regeneration air duct 87 to spray the dehumidifying and sterilizing solution 14' .

Therefore, the dehumidifying and sterilizing solution 14' is heated by the heating device 83 to increase the surface vapor pressure, and sprayed into the regeneration tank 85 through the nozzles 84 to contact the air discharged from the regeneration inlet duct 86 for gas-liquid exchange. The excess water vapor and temperature are converted to the discharged air, and the air that has absorbed the water vapor and temperature is discharged by the regeneration outlet duct 87, the dehumidification and sterilization solution 14' is regenerated, and the regeneration water collection tank 81 is used to contain the The regenerated dehumidifying and sterilizing solution 14 is driven by the regeneration pump 82 into the third water pipe 822 and sent back to the water collecting tank 15 of the air conditioner 10.

It can be seen from the above description that the air conditioner 10 of the present invention can regenerate the dehumidification and sterilization solution 14 by the regeneration device 80 of the dehumidification and sterilization solution, thereby prolonging the use time of the dehumidification and sterilization solution 14; 80 is to regenerate the dehumidification and sterilization solution 14' by heating. Compared with the regeneration method of traditional air conditioner which removes the moisture of a dehumidification solution by condensation, traditional air conditioner needs additional reheating device to warm the dehumidification solution. Therefore, the regeneration device 80 of the present invention does not require additional heating steps, and achieves the effect of energy saving.

Please refer to FIG. 4B, which is a second embodiment of the new air conditioner 10a; the air conditioner 10a of this embodiment is roughly the same as the air conditioner 10 shown in FIG. 4A, but further includes a bubble generating device 19, wherein the bubble The generating device 19 is installed outside the dehumidification and sterilization tank 13.

The above-mentioned bubble generating device 19 is further connected to a gas source; in this embodiment, the bubble generating device 19 is connected to the water collection tank 15 and generates a plurality of bubbles 191 in the water collection tank 15 In the dehumidifying and sterilizing solution 14; in another embodiment, the bubble generating device 19 is connected to the first water pipe 171, and generates the bubbles 191 in the dehumidifying and sterilizing solution 14 in the first water pipe 171; In one embodiment, the bubble generating device 19 is connected to the water collection tank 15 and the first water pipe 171 at the same time, and generates the bubbles 191 in the dehumidification and sterilization solution 14 of the water collection tank 15 and the first water pipe 171 at the same time; Preferably, the gas source includes air, nitrogen or ozone, and the bubbles 191 are a micron bubble or a nano bubble; in addition, the regeneration device 80 can be further provided to extend the use time of the dehumidifying and sterilizing solution 14.

From the above description, it can be seen that the air-conditioning device 10a of the present invention generates the bubbles 191 in the dehumidifying and sterilizing solution 14. The volume of the dehumidifying and sterilizing solution 14 is increased to increase the gas-liquid exchange area and enhance the dehumidifying and sterilizing effect of the air-conditioning device 10a; In addition, the gas source can be provided with different gases as the source of the bubbles 191 according to requirements, which increases the applicability of the air-conditioning device 10a.

Please refer to FIG. 4C, which is a third embodiment of the new air conditioner 10b; the air conditioner 10b of this embodiment is substantially the same as the air conditioner 10a shown in FIG. 4B, except that the bubble generating device 19 is integrated in the pump 16; In addition, the regeneration device 80 can be further provided to extend the use time of the dehumidifying and sterilizing solution 14

From the above description, it can be seen that the air-conditioning device 10b of the present invention integrates the bubble generating device 19 into the pump 16, reducing the overall size of the air-conditioning device 10b, so that the air-conditioning device 10b can be used more flexibly in design. .

Please refer to FIG. 4D, which is a fourth embodiment of the new air conditioner 10c; the air conditioner 10c of this embodiment is substantially the same as the air conditioner 10 shown in FIG. 4A, but further includes a bubble generating device 19, wherein the bubble The generating device 19 is installed at the air inlet 131 of the dehumidifying and sterilizing tank 13.

The above-mentioned bubble generating device 19 is connected to the air inlet pipe 11 and the water collecting tank 15, and after the outside air received by the air inlet pipe 11 is converted into bubbles 191, it is input into the dehumidifying and sterilizing solution 14 of the water collecting tank 15 for sterilization; Preferably, the bubble 191 is a micron bubble or a nano bubble; in addition, the regeneration device 80 can be further provided to extend the use time of the dehumidifying and sterilizing solution 14.

It can be seen from the above description that the air-conditioning device 10c of the present invention uses the bubble generating device 19 to convert the external air received by the air inlet pipe 11 into bubbles 191 and input into the dehumidifying and sterilizing solution 14 in the sump 15, adding The gas-liquid exchange area enhances the dehumidification and sterilization effect of the air conditioner 10c.

In summary, the air-conditioning system with real-time monitoring function of the present invention sets the first real-time biological sensing module at the first air outlet pipe of the air-conditioning device, and presets the biological content standard range, and the real-time quantity Measure and determine whether the air discharged by the air conditioner meets the standard, and control the air valve, the first sterilization module, and the second sterilization module to achieve the effect of real-time control of the sterilization ability according to the bacteria content in the air; and The gaseous molecular pollutant detection module and the particle detection are further provided to further achieve the effect of real-time control of the pollutant removal and particle removal ability according to the pollutant content and particle content in the air; the air conditioning device can also be further equipped with the dehumidification The regenerating device of the sterilizing solution can prolong the use time of the dehumidifying and sterilizing solution; or the bubble generating device is further provided to generate the bubbles to increase the gas-liquid exchange area and enhance the sterilizing effect of the air conditioner.

The above are only the embodiments of the present invention, and do not limit the present invention in any form. Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention. Anyone with ordinary knowledge in the relevant technical field, Without departing from the scope of the technical solution of the present invention, when the technical content disclosed above can be used to make slight changes or modification into equivalent embodiments with equivalent changes, but any content that does not deviate from the technical solution of the present invention is based on the technical essence of the present invention. Anything done to the above embodiment Simple modifications, equivalent changes and modifications are still within the scope of the new technical solution.

1a: Air purification circulation system

10: Air conditioner

11: Inlet duct

12: The first air outlet

13: Dehumidification and sterilization tank

20: The first real-time biosensing module

21: The first gaseous molecular pollutant detection module

22: The first particle detection module

30: Air valve

40: The second air duct

50: Return air duct

Claims (32)

An air purification circulation system with real-time monitoring function includes: an air conditioner, including an air inlet pipe, a first air outlet pipe, and a dehumidification and sterilization tank; the inlet pipe is connected to an air inlet of the dehumidification and sterilization tank The first air outlet pipe is connected to a filter end of the dehumidification and sterilization tank, and discharges the air sterilized by the dehumidification and sterilization tank, wherein the dehumidification and sterilization tank contains a dehumidification and sterilization solution; A real-time biosensing module is preset with a standard range of biological content and is set at the first air outlet pipe of the air-conditioning device to measure and determine whether the biological content in the air discharged by the air-conditioning device exceeds the The biological content standard range; a gas valve connected to the first air outlet pipe and electrically connected to the first real-time biosensing module, and the first real-time biosensing module controls the switching of the gas valve; The second air outlet pipe is connected to the air valve and selectively communicates with the first air outlet pipe through the air valve; and a return air pipe is connected to the air valve and the air inlet pipe, and is selected through the air valve Ground is connected with the first air outlet pipe; wherein: when the first real-time biological sensing module determines that the biological content in the air discharged by the air conditioning device is lower than the biological content standard range, the air valve is controlled to make the first air outlet The air duct is connected with the second air outlet pipe to discharge the exhausted air into the second air outlet pipe; and when the first real-time biological sensing module determines that the biological content in the air discharged from the air conditioner is higher than that of the biological Within the content standard range, the air valve is controlled to make the first air outlet pipe communicate with the return air pipe, and the discharged air is discharged into the return air pipe and sent back to the air conditioner for re-sterilization. The air purification circulation system according to claim 1, further comprising a first sterilization module, wherein the first sterilization module is disposed between the air valve and the second air outlet pipe, and is electrically connected to the first sterilization module. A real-time biosensing module, the first real-time biosensing module controls the first sterilization module to turn on or off; the biological content standard range preset by the first real-time biosensing module includes a first Standard value and a second standard value, the second standard value is greater than the first standard value; wherein: when the first real-time biological sensing module determines that the biological content in the air discharged from the air conditioning device is lower than the first standard value Standard value, close the first sterilization module and control the air valve to make the first air outlet pipe communicate with the second air outlet pipe, and discharge the exhausted air into the second air outlet pipe; when the first instant biological The sensing module determines that the biological content in the air discharged from the air conditioner is between the first standard value and the second standard value, turns on the first sterilization module and controls the air valve to make the first air outlet pipe Connected with the second air outlet pipe, the discharged air is further sterilized by the first sterilization module and then discharged into the second air outlet pipe; and when the first real-time biosensing module determines the air discharged from the air conditioner If the biological content is higher than the second standard value, close the first sterilization module and control the air valve so that the first air outlet pipe is connected to the return air pipe, and the discharged air is sent back to the air conditioner for re-sterilization . The air purification circulation system according to claim 1, further comprising a second sterilization module, wherein the second sterilization module is disposed between the air valve and the return air duct, and is electrically connected to the first instant The biological sensing module is controlled by the first real-time biological sensing module to turn on or off the second sterilization module; the biological content standard range preset by the first real-time biological sensing module includes a first standard value And a second standard value, the second standard value is greater than the first standard value; where: When the first real-time biosensing module determines that the biological content in the air discharged from the air conditioning device is lower than the first standard value, the second sterilization module is closed and the air valve is controlled so that the first air outlet pipe and the The second air outlet pipe is connected to discharge the discharged air into the second air outlet pipe; when the first real-time biosensing module determines that the biological content in the air discharged from the air conditioner is between the first standard value and the Between the second standard value, the air valve is controlled to connect the first air outlet pipe with the return air pipe, and the discharged air is sent back to the air conditioner for re-sterilization; and when the first real-time biosensing module determines The biological content in the air discharged by the air conditioner is higher than the second standard value, the second sterilization module is turned on and the air valve is controlled so that the first air outlet pipe is connected to the return air pipe, and the discharged air is further removed by After the second sterilization module is sterilized, it is sent back to the air-conditioning device for re-sterilization. The air purification circulation system according to claim 2, further comprising a second sterilization module, wherein the second sterilization module is disposed between the air valve and the return air duct, and is electrically connected to the first instant The biological sensing module is controlled by the first real-time biological sensing module to turn on or off the second sterilization module; the biological content standard value preset by the first real-time biological sensing module further includes a third Standard value, the third standard value is greater than the second standard value; wherein: when the first real-time biosensing module determines that the biological content in the air discharged by the air conditioner is higher than the third standard value, the first standard value is turned on The second sterilization module controls the air valve to make the first air outlet pipe communicate with the return air pipe, and further sterilizes the discharged air by the second sterilization module and sends it back to the air conditioner for re-sterilization. The air purification circulation system according to any one of claim 2, 3 or 4, wherein the first sterilization module is an ultraviolet sterilization module. The air purification circulation system according to claim 3 or 4, wherein the second sterilization module is an ultraviolet sterilization module. The air purification circulation system according to any one of claims 1 to 4, further comprising a first gaseous molecular pollutant detection module, a first particle detection module or the first gaseous molecular pollutant detection module Module and the first particle detection module, wherein the first gaseous molecular pollutant detection module, the first particle detection module, or the first gaseous molecular pollutant detection module and the first particle detection module The group system is arranged at the first air outlet pipe of the air-conditioning device. The air purification circulation system according to claim 7, further comprising: a first extension air pipe connected to the second air outlet pipe; a second extension air pipe connected to the air inlet pipe of the air conditioner; A third sterilization module is arranged between the second extension air duct and the air inlet pipe; and a second real-time biosensing module is electrically connected to the third sterilization module and controls the third The sterilization module is turned on or off, and the second real-time biosensing module presets a sterilization module biological standard value. The air purification circulation system according to claim 7, further comprising: a first extension air pipe connected to the second air outlet pipe; a second extension air pipe connected to the air inlet pipe of the air conditioner; An adjustable damper is set at the air inlet pipe of the air conditioner; a micro differential pressure gauge is electrically connected to the adjustable damper and controls the adjustable damper to adjust the outside air entering the air inlet pipe The ratio of is to the ratio of the air discharged from the second extension air duct; a windmill module is arranged between the first real-time biosensing module and the second air outlet duct; and A second real-time biosensing module is electrically connected to the windmill module and controls the windmill module to be turned on or off, wherein the second real-time biosensing module presets a windmill biological standard value. The air purification circulation system according to claim 8, wherein the third sterilization module is an ultraviolet sterilization module. The air purification circulation system according to claim 7, wherein the dehumidifying and sterilizing solution is an absorbent with a viscosity ranging from 0.1 cps to 100 cps. The air purification circulation system according to claim 11, wherein the dehumidifying and sterilizing solution is an absorbent with a viscosity of 0.5 cps to 50 cps. The air purification circulation system according to claim 7, wherein the air-conditioning device further comprises: a water collection tank, which is arranged below the dehumidification and sterilization tank, and contains the dehumidification and sterilization solution; and a pump is connected to the water collection tank and The dehumidification and sterilization solution in the sump is pumped into a first water pipe; a cooling device is arranged at the first water pipe to cool the dehumidification and sterilization solution in the first water pipe; and a plurality of nozzles are arranged at The inside of the dehumidification and sterilization tank is close to the position of the first air outlet pipe, and is connected to the first water pipe to spray the dehumidification and sterilization solution driven by the pump. The air purification circulation system as described in claim 13, further comprising a regeneration device for dehumidification and sterilization solution, the regeneration device is connected to the pump by a second water pipe, and connected to the water collection tank by a third water pipe. The pump and the second water pipe obtain the dehumidification and sterilization solution in the sump, heat the dehumidification and sterilization solution to restore its concentration, and then send it back to the sump through the third water pipe. The air purification circulation system according to claim 14, wherein the pump system further includes a bubble generating device for generating bubbles in the dehumidifying and sterilizing solution, the bubble generating device is connected to a gas source, and the gas source contains air , Nitrogen or Ozone. The air purification circulation system according to claim 14, wherein the air-conditioning device further includes a bubble generating device connected to the first water pipe or the sump to generate bubbles in the dehumidifying and sterilizing solution in the first water pipe or In the dehumidifying and sterilizing solution of the sump; wherein the bubble generating device is connected to a gas source, and the gas source contains air, nitrogen or ozone. The air purification circulation system according to claim 14, wherein the air-conditioning device further includes a bubble generating device connected between the air inlet pipe and the sump to convert the external air into bubbles and pass into the collection In the sink. An air purification circulation system with real-time monitoring function includes: an air conditioner, including an air inlet pipe, a first air outlet pipe, and a dehumidification and sterilization tank; the inlet pipe is connected to an air inlet of the dehumidification and sterilization tank The first air outlet pipe is connected to a filter end of the dehumidification and sterilization tank, and discharges the air sterilized by the dehumidification and sterilization tank, wherein the dehumidification and sterilization tank contains a dehumidification and sterilization solution; A real-time biosensing module is preset with a standard range of biological content and is set at the first air outlet pipe of the air-conditioning device to measure and determine whether the biological content in the air discharged by the air-conditioning device exceeds the Standard range of biological content; a second air outlet pipe connected to the first air outlet pipe; and a first sterilization module set between the first real-time biosensing module and the second air outlet pipe And electrically connected to the first real-time biosensing module, and the first real-time biosensing module controls the first sterilization module to turn on or off; When the first real-time biosensing module determines that the biological content in the air discharged from the air conditioner is below the standard range of the biological content, the first sterilization module is turned off; and when the first real-time biological sensing module determines that the The biological content in the air discharged by the air conditioner is higher than the biological content standard range, and the first sterilization module is turned on to further sterilize the discharged air. The air purification circulation system according to claim 18, further comprising: an air valve, which is arranged in the first real-time biosensing module, connects the first air outlet pipe and the second air outlet pipe, and Electrically connected to the first real-time biological sensing module, wherein the air valve is controlled by the first real-time biological sensing module to switch the air valve to selectively connect the first air outlet pipe and the second air outlet pipe ; A return air pipe, which connects the air valve and the air inlet pipe, selectively communicates with the first air outlet pipe through the air valve; a second sterilization module, is arranged on the air valve and the return air pipe Between, and electrically connected to the first real-time biosensing module, the first real-time biosensing module controls the second sterilization module to turn on or off; the first real-time biosensing module is preset The biological content standard range includes a first standard value, a second standard value, and a third standard value, the first standard value is smaller than the second standard value, and the second standard value is smaller than the third standard value; Wherein: when the first real-time biosensing module determines that the biological content in the air discharged from the air conditioner is lower than the first standard value, the first sterilization module and the second sterilization module are closed and the air valve is controlled Connect the first air outlet pipe with the second air outlet pipe, and discharge the discharged air into the second air outlet pipe; when the first real-time biosensing module determines the biological content in the air discharged from the air conditioner Between the first standard value and the second standard value, turn on the first sterilization module and control the air valve so that the first An air outlet pipe is connected to the second air outlet pipe, and the discharged air is further sterilized by the first sterilization module and then discharged into the second air outlet pipe; when the first real-time biosensing module determines that the air conditioner The biological content in the discharged air is between the second standard value and the third standard value. The first sterilization module is closed and the air valve is controlled to make the first air outlet pipe communicate with the return air pipe. The discharged air is sent back to the air-conditioning device for re-sterilization; and when the first real-time biosensing module determines that the biological content in the air discharged from the air-conditioning device is higher than the third standard value, the second sterilization module is turned on and The air valve is controlled to make the first air outlet pipe communicate with the return air pipe, and the discharged air is further sterilized by the second sterilization module and then sent back to the air conditioner for re-sterilization. The air purification circulation system according to claim 18, wherein the first sterilization module is an ultraviolet sterilization module. The air purification circulation system according to claim 19, wherein the second sterilization module is an ultraviolet sterilization module. The air purification circulation system according to claim 18 or 19, further comprising a first gaseous molecular pollutant detection module, a first particle detection module, or the gaseous pollutant detection module and the first particle The detection module, wherein the first gaseous molecular pollutant detection module, the first particle detection module, or the first gaseous molecular pollutant detection module and the first particle detection module are installed in the air conditioner At the first outlet duct. The air purification circulation system according to claim 22, further comprising: a first extension air pipe connected to the second air outlet pipe; a second extension air pipe connected to the air inlet pipe of the air conditioner; A third sterilization module is arranged between the second extension air duct and the air inlet pipe; and a second real-time biosensing module is electrically connected to the third sterilization module and controls the third The sterilization module is turned on or off, and the second real-time biosensing module presets a sterilization module biological standard value. The air purification circulation system according to claim 22, further comprising: a first extension air pipe connected to the second air outlet pipe; a second extension air pipe connected to the air inlet pipe of the air conditioner; An adjustable damper is set at the air inlet pipe of the air conditioner; a micro differential pressure gauge is electrically connected to the adjustable damper and controls the adjustable damper to adjust the outside air entering the air inlet pipe The ratio of, and the ratio of the air discharged from the second extension duct; a windmill module, which is arranged between the first real-time biosensing module and the first sterilization module; and a second real-time biosensing The module is electrically connected to the windmill module and controls the windmill module to be turned on or off, wherein the second real-time biological sensing module presets a windmill biological standard value. The air purification circulation system according to claim 23, wherein the third sterilization module is an ultraviolet sterilization module. The air purification circulation system according to claim 22, wherein the dehumidifying solution is an absorbent with a viscosity ranging from 0.1 cps to 100 cps. The air purification circulation system according to claim 26, wherein the dehumidifying solution is an absorbent with a viscosity ranging from 0.5 cps to 50 cps. The air purification circulation system according to claim 22, wherein the air-conditioning device further comprises: a water collection tank, which is arranged under the dehumidification and sterilization tank, and contains the dehumidification and sterilization solution; A pump is connected to the sump and pumps the dehumidification and sterilization solution in the sump into a first water pipe; a cooling device is arranged at the first water pipe to cool the dehumidification in the first water pipe Sterilizing solution; and a plurality of spray heads are arranged inside the dehumidifying and sterilizing tank near the first air outlet position, and connected to the first water pipe to spray the dehumidifying and sterilizing solution driven by the pump. The air purification circulation system described in claim 28 further includes a regeneration device for dehumidification and sterilization solution, and the regeneration device is connected to the pump by a second water pipe, and connected to the water collecting tank by a third water pipe. The pump and the second water pipe obtain the dehumidification and sterilization solution in the sump, heat the dehumidification and sterilization solution to restore its concentration, and then send it back to the sump through the third water pipe. The air purification circulation system according to claim 29, wherein the pump system further comprises a bubble generating device for generating bubbles in the dehumidifying and sterilizing solution, the bubble generating device is connected to a gas source, and the gas source contains air , Nitrogen or Ozone. The air purification circulation system according to claim 29, wherein the air-conditioning device further includes a bubble generating device connected to the first water pipe or the sump to generate bubbles in the dehumidifying and sterilizing solution in the first water pipe or In the dehumidifying and sterilizing solution of the sump; wherein the bubble generating device is connected to a gas source, and the gas source contains air, nitrogen or ozone. The air purification circulation system according to claim 29, wherein the air-conditioning device further includes a bubble generating device connected between the air inlet pipe and the sump to convert the external air into bubbles and pass them into the collection tank. In the sink.

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