CN215231706U - Air disinfection and purification device - Google Patents

Abstract

The application discloses air disinfection and purifier, including respiratory and at least one plasma electricity percussion generator. The breathing part is provided with a breathing cavity. The plasma electric firing generator is provided with an electric shock flow channel which is communicated with the breathing cavity and the external environment, and the plasma electric firing generator is configured to enable gas flowing through the electric shock flow channel to be disinfected and purified through electric shock. The device of this application portable, and can disinfect and purify gas according to the needs that the user breathed, automatic regulating function has, wherein, ambient air flows in plasma electricity percussion generator and is disinfected and purify, then carry and supply the user to inhale in the breathing portion, the gas of user's exhalation flows in plasma electricity percussion generator and is disinfected and purify, then carry to the environment in, the transmission chain disconnection to the fastest, user and user's peripheral crowd can not infected by virus and bacterium, thereby reduce the chance of cross infection and viral variant.

Description

Air disinfection and purification device

Technical Field

The present application relates to the field of air purification and disinfection, personal protective equipment, public health and respiratory assistance, and in particular to an air disinfection and purification device.

Background

Currently, there is an increasing population of air resistant bacteria, variant viruses and harmful organic compounds, particularly viruses with an increased variant rate. Neither drugs nor prophylactic vaccines can protect against this in time. Generally, virus infected people have no obvious symptoms in the latent period, but the air exhaled by the virus is possibly already provided with the virus, so that cross infection is caused.

SUMMERY OF THE UTILITY MODEL

The application provides an air disinfection and purification device, can reduce cross infection.

In a first aspect, embodiments of the present application provide an air disinfecting and purifying apparatus comprising a breathing portion and at least one plasma electrotransport generator. The breathing part is provided with a breathing cavity. The plasma electric firing generator is provided with an electric shock flow channel which is communicated with the breathing cavity and the external environment, and the plasma electric firing generator is configured to enable gas flowing through the electric shock flow channel to be disinfected and purified through electric shock.

In some of these embodiments, the air disinfecting and purifying apparatus includes a gas sensor for detecting an inspiratory volume and an expiratory volume of a user wearing a breathing portion for breathing, and a control module. The control module is connected with the gas sensor and the plasma electric-percussion generator, so that the control module controls the gas disinfection and purification amount of the plasma electric-percussion generator according to the detection information of the gas sensor.

In some of these embodiments, the plasma shock generator comprises at least a first plasma shock generator and at least a second plasma shock generator, the shock flow path of the first plasma shock generator and the shock flow path of the second plasma shock generator each communicating with the breathing chamber and the external environment, respectively. The air disinfecting and purifying device includes at least one intake air flow generating device configured to cause air flowing into the shock flow channel of the first plasma shock generator to flow toward the breathing chamber.

In some of these embodiments, the air disinfecting and purifying apparatus includes at least one outlet air flow generating device. The outlet gas flow generating means is arranged to cause gas flowing into the electrode flow channel of the second plasma shock generator to flow to the external environment.

In some of these embodiments, downstream of the second plasma shock generator, there may be a collection tank configured to collect moisture and spray.

In some of these embodiments, the gas sensor comprises a first gas sensor and a second gas sensor; the first gas sensor is configured to detect the inspiratory volume of a user wearing the breathing part for breathing; the second gas sensor is configured to detect an amount of exhalation that is breathed by the user wearing the breathing portion.

In some embodiments, the control module is connected to the first gas sensor, the second gas sensor, the first plasma shock generator and the second plasma shock generator, such that the control module controls the amount of gas sanitization by the first plasma shock generator and the amount of gas sanitization by the second plasma shock generator according to the detection information from the first gas sensor and the detection information from the second gas sensor.

In some embodiments, the control module is connected with the intake airflow generation device, so that the control module controls the intake air amount of the intake airflow generation device according to the detection information of the gas sensor.

In some embodiments, the control module is connected to the output airflow generating device, so that the control module controls the output of the output airflow generating device according to the detection information of the gas sensor.

In some of these embodiments, the air disinfecting and purifying device includes a battery configured to supply power to electrical components in the air disinfecting and purifying device.

An air disinfecting and purifying device provided according to an embodiment of the present application includes a breathing portion and at least one plasma electric fire generator. The breathing part is provided with a breathing cavity. The plasma electric firing generator is provided with an electric shock flow channel which is communicated with the breathing cavity and the external environment, and the plasma electric firing generator is configured to enable gas flowing through the electric shock flow channel to be disinfected and purified through electric shock.

The device of the application has the following beneficial effects:

1. first plasma electric shock generator and second plasma electric shock generator in the device of this application can destroy the gene of microorganism and virus in the air, also can decompose organic compound in the air, reach air-purifying's effect, the above-mentioned process is the use physical effect completely, do not use any chemical substance, the condition that can not have secondary pollution and virus to expand the property of medicine produces, and the above-mentioned process only needs the electric energy and does not need the assistance of other special environment, can produce effectual reaction to the material in the air, in addition, the air after the purification can supply the human direct suction, and can not have any side effect. The first plasma electric shock generator and the second plasma electric shock generator in the device are high in air disinfection and purification efficiency and low in energy consumption.

2. The device of this application makes ambient air flow into plasma electricity percussion generator disinfected and purifies, then carries to supply the user to inhale in the respiration portion, and the gas that the user expired flows into plasma electricity percussion generator and is disinfected and purify, then carries to the environment in, breaks off the transmission chain fastest, and user's peripheral crowd can not receive virus and bacterial infection to reduce the chance of cross infection and virus variation.

3. The device of the application is self-maintaining clean, and can be used for a long time and reused for many times.

4. The device of this application can disinfect and purify gas according to the needs that the user breathed, has the automatically regulated tolerance function for the user can comfortably move about in the environment (like hospital, subway) that the crowd concentrated, work etc. for example, when user's activity intensity increases, inspiratory capacity and expiratory volume increase, and at this moment, the gaseous disinfection purification volume of increase device guarantees that the user can not receive the infection, can not infect peripheral crowd yet.

5. The device of this application is through automatically regulated tolerance and suitable efficiency in order to avoid being in high energy consumption and extravagant state for a long time, has reduced the consumption of battery, has prolonged the life of battery, for example, when user's activity intensity reduces, inspiratory capacity and expiratory capacity reduce, at this moment, reduce the gaseous disinfection purification volume of device, guarantee the prerequisite that user and peripheral crowd can not cross infection, the electric quantity of battery has been saved, thereby make the device of this application portable.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural diagram of an apparatus in an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Currently, there is an increasing population of air resistant bacteria, variant viruses and harmful organic compounds, particularly viruses with an increased variant rate. Neither drugs nor prophylactic vaccines can protect against this in time. Generally, virus infected individuals have no obvious symptoms in the latent stage, but the air exhaled by them may already carry viruses. In order to break the transmission chain as quickly as possible, both inhaled and exhaled viruses must be killed. As long as humans are not infected, the chances of viral variants are reduced and the vaccine effect is exerted. In order to protect individuals and surrounding people, the user can inhale the disinfected and purified air and exhaust the gas exhaled by the user after disinfection and purification, so that the people around the user are prevented from being infected, and cross infection is reduced.

Referring to fig. 1, an embodiment of the present application provides an air disinfecting and purifying apparatus 1 including a breathing portion 10 and at least one plasma torch 20.

The breathing portion 10 has a breathing chamber. The breathing part 10 may be a breathing tube, in which case the space in the breathing tube is a breathing cavity. The breathing portion 10 may be a mask, in which case the space defined by the mask is a breathing chamber. The mask may be shaped to provide a snug fit to the face of the user. The mask is made of a material which can enable air to pass through and filter air, can also enable air not to pass through, and can be cleaned by using chemicals for multiple times.

The plasma electric fire generator 20 has an electric shock flow passage communicating the breathing chamber and the external environment, and the plasma electric fire generator 20 is configured such that the gas flowing through the electric shock flow passage is sterilized and purified by electric shock. Specifically, the plasma electric fire generator 20 is configured such that a plasma environment is formed in the electric shock flow channel, and positive and negative charges in the plasma environment generate an electric shock, so that the gas carries the positive and negative charges after flowing into the electric shock flow channel, and the gas is sterilized and purified as the positive and negative charges generate the electric shock.

The plasma electric fire generator 20 may include an outer electrode, an inner electrode, a first fixed seat, and a second fixed seat. The outer electrode may be a hollow cylindrical shape. The inner electrode may have a columnar shape. The outer diameter of the inner electrode is smaller than the inner diameter of the outer electrode, so that the inner electrode can be inserted into the outer electrode along the axial direction of the inner electrode, and at the moment, the axis of the inner electrode can be coincident with the axis of the outer electrode. The first anchor may be connected to a first end of the external electrode and a first end of the internal electrode. The second anchor may be connected to the second end of the outer electrode and the second end of the inner electrode. The first and second holders are configured such that the inner electrode is held in the outer electrode, the inner and outer electrodes together defining an annular flow channel, both ends of the annular flow channel being respectively communicated with the external space. The annular flow channel described here is also the shock flow channel described above. When the plasma electric trigger 20 is operated, the outer electrode and the inner electrode are connected to a power supply, respectively. The plasma electric fire generator 20 is automatically started at the time of starting the air sterilizing and purifying device 1.

The plasma electric shock generator 20 may include at least one first plasma shock generator 21 and at least one second plasma shock generator 22. The shock flow path of the first plasma shock generator 21 and the shock flow path of the second plasma shock generator 22 may both communicate with the respiratory chamber and the external environment, respectively.

The air disinfecting and cleaning device 1 comprises at least one incoming air flow generating means 30 and at least one outgoing air flow generating means 40.

The intake air flow generating device 30 is configured to flow the air flowing into the shock flow path of the first plasma shock generator 21 toward the respiratory chamber. The intake airflow generating device 30 may include a first intake airflow generating device 31 and a second intake airflow generating device 32. The first intake airflow generating device 31 may be located downstream of the stun flow path of the first plasma stun generator 21. The second intake airflow generating device 32 may be located upstream of the stun flow path of the first plasma stun generator 21. The intake airflow generating device 30 may be a fan, or may be of other structures, which are not described in detail herein.

The outlet gas flow generating means 40 is arranged to cause gas flowing into the electrode flow channels of the second plasma shock generator 22 to flow to the external environment. The outlet gas flow generating means 40 may comprise a first outlet gas flow generating means 41 and a second outlet gas flow generating means 42. The first outlet gas flow generating means 41 may be located upstream of the stun flow path of the second plasma stun generator 22. A second outlet gas flow generating device 42 may be located downstream of the stun flow path of the second plasma stun generator 22. The outlet airflow generating device 40 may be a fan, or may be other structures, which are not described in detail herein. At this time, downstream of the second plasma shock generator 22, there may be a collection tank 100, the collection tank 100 being configured to collect moisture and spray. The collection box 100 may be located downstream of the second outgoing airflow generating device 42. The collection box 100 may be located at a position intermediate the second outlet gas flow generating device 42 and the second plasma shock generator 22.

The air disinfecting and purifying device 1 may further include a gas sensor 50 and a control module 70.

The gas sensor 50 is configured to detect an inspiratory volume and an expiratory volume of a user breathing with the breathing portion worn. The gas sensor 50 may include a first gas sensor 51 and a second gas sensor 52. The gas sensor 50 may be a pressure sensor, a wind speed sensor, or a flow sensor.

The first gas sensor 51 is configured to detect an inspiratory volume of a user breathing by wearing the breathing portion 10. The first gas sensor 51 may be a pressure sensor, a wind speed sensor, or a flow sensor. The first gas sensor 51 may be located downstream or upstream of the strike flow path of the first plasma shock generator 21. The first gas sensor 51 may be located on the intake airflow generating device 30. When the intake airflow generating device 30 includes the first intake airflow generating device 31 and the second intake airflow generating device 32, the first gas sensor 51 may be only located on the first intake airflow generating device 31 or the second intake airflow generating device 32, or may be distributed on the first intake airflow generating device 31 and the second intake airflow generating device 32.

Second gas sensor 52 is configured to detect the amount of exhalation that is breathed by the user wearing respiratory portion 10. The second gas sensor 52 may be a pressure sensor, a wind speed sensor, or a flow sensor. The second gas sensor 52 may be located upstream or downstream of the strike flow path of the second plasma shock generator 22. Second gas sensor 52 may be located on exhaust gas flow generating device 40. When the output airflow generating device 40 includes the first output airflow generating device 41 and the second output airflow generating device 42, the second gas sensor 52 may be only located on the first output airflow generating device 41 or the second output airflow generating device 42, or may be distributed on the first output airflow generating device 41 and the second output airflow generating device 42.

The control module 70 is connected with the gas sensor and the plasma electric-fire generator 20, so that the control module 70 controls the gas disinfection and purification amount of the plasma electric-fire generator 20 according to the detection information of the gas sensor. When the plasma electric shock generator 20 includes the first plasma shock generator 21 and the second plasma shock generator 22, the control module 70 may be connected to both the first plasma shock generator 21 and the second plasma shock generator 22. The gas sensors include a first gas sensor 51 and a second gas sensor 52, and the control module 70 may be connected to both the first gas sensor 51 and the second gas sensor 52.

In addition, when the air sterilizing and purifying device 1 includes the inlet air flow generating device 30 and the outlet air flow generating device 40, the control module 70 may be connected to the inlet air flow generating device 30 and the outlet air flow generating device 40, so that the control module 70 controls the inlet air amount of the inlet air flow generating device 30 and the outlet air amount of the outlet air flow generating device 40 according to the detection information of the gas sensor. When the intake airflow generating device 30 includes the first intake airflow generating device 31 and the second intake airflow generating device 32, the control module 70 may be connected to both the first intake airflow generating device 31 and the second intake airflow generating device 32. When the output airflow generating device 40 includes the first output airflow generating device 41 and the second output airflow generating device 42, the control module 70 may be connected to both the first output airflow generating device 41 and the second output airflow generating device 42.

The air disinfecting and purifying device 1 may include an inlet duct 80, an outlet duct 90.

The air inlet duct 80 communicates with the shock flow path and the breathing chamber of the first plasma shock generator 21. The position of the communication position of the air inlet pipe 80 and the breathing cavity can enable the user to wear the breathing part 10 to breathe, and the communication position is located between the mouth and the nose of the user. The orientation of the communication portion may be such that the user does not experience a noticeable impact after wearing the breathing portion 10 to breathe. The first intake airflow generating device 31 may be located upstream of the intake duct 80. The first gas sensor 51 may be located upstream of the first intake airflow generation device 31.

The outlet conduit 90 communicates with the stun flow channel and the breathing chamber of the second plasma stun generator 22. The position of the communication position of the air outlet pipeline 90 and the breathing cavity can enable the user to wear the breathing part 10 to breathe, and the communication position is located between the mouth and the nose of the user. The orientation of the communication may be such that the user does not experience a noticeable pulling sensation after wearing the breathing portion 10 to breathe. First outlet gas flow generating device 41 may be located downstream of outlet pipe 90. Second gas sensor 52 may be located downstream of first gas stream generating device 41.

The device may comprise a battery. The battery is configured to supply power to electrical components in the air disinfection and purification apparatus. Wherein the battery may be integrated with the control module 70. The device may not include a battery, and supplies power to the electric device of the air disinfecting and purifying device by means of an external power supply, which is not described herein.

In addition, the device may further include a base 60, the base 60 being configured to carry electrical components in the air disinfection and purification device. The device may be provided without any valve.

An embodiment of the present application provides a control method of an air disinfecting and purifying apparatus 1, including the steps of: an air disinfecting and purifying device is provided. The air disinfecting and purifying device is activated so that the user inhales the disinfected and purified air, and the air exhaled by the user is discharged after disinfection and purification.

Alternatively, the breathing part 10 is controlled to intake air after the breathing part 10 is worn by the user to inhale air. After the breathing part 10 worn by the user is sensed to exhale, the breathing part 10 is controlled to outgas.

Specifically, after the user wears the breathing part 10 to inhale, the intake airflow generating device 30 is controlled to start. After the exhalation of the user wearing the breathing part 10 is sensed, the exhaust gas flow generating device 40 is controlled to be started.

Alternatively, the intake air amount of the breathing portion 10 is controlled to reach the breathing demand of the user. The exhalation quantity of the breathing portion 10 is controlled to the breathing demand of the user. That is, the amount of intake air of the breathing portion 10 is controlled to reach the user's inhalation amount. The air output of the breathing part 10 is controlled to the air output of the user. Alternatively, the intake air amount of the breathing portion 10 is controlled to reach the set intake air amount. The air output of the breathing part 10 is controlled to reach the set air output.

Specifically, the air input of the inlet airflow generating device 30 is controlled to reach the inhalation volume of the user, and the air output of the outlet airflow generating device 40 is controlled to reach the exhalation volume of the user. Alternatively, the intake air amount of the intake air flow generator 30 is controlled to reach the set intake air amount, and the exhaust air amount of the exhaust air flow generator 40 is controlled to reach the set exhaust air amount.

Alternatively, the amount of air supplied to the control respiratory portion 10 increases as the respiratory demand of the user increases and decreases as the respiratory demand of the user decreases, and the amount of air supplied to the control respiratory portion 10 increases as the respiratory demand of the user increases and decreases as the respiratory demand of the user decreases. That is, the amount of air taken to control the breathing part 10 increases as the amount of inhalation of the user increases and decreases as the amount of inhalation of the user decreases, and the amount of air taken to control the breathing part 10 increases as the amount of exhalation of the user increases and decreases as the amount of exhalation of the user decreases.

Specifically, after the air inflow of the inlet airflow generating device 30 is controlled to reach the inhalation amount of the user, the air outflow of the outlet airflow generating device 40 is controlled to reach the exhalation amount of the user, or the air inflow of the inlet airflow generating device 30 is controlled to reach the set air inflow, and the air outflow of the outlet airflow generating device 40 is controlled to reach the set air outflow, if the inhalation amount of the user is increased, the air inflow of the inlet airflow generating device 30 is controlled to be increased. If the user's intake air amount decreases, the intake air amount of the intake airflow generation device 30 is controlled to decrease. If the user's exhalation volume increases, the control air flow generating device 40 controls the exhalation volume to increase. If the exhalation volume of the user decreases, the air output of the air output flow generating device 40 is controlled to decrease.

Alternatively, the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to the respiration requirement of the user, and the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to the respiration requirement of the user. That is, the gas sterilizing and purifying amount of the first plasma shock generator 21 is controlled to the inhalation air amount of the user, and the gas sterilizing and purifying amount of the second plasma shock generator 22 is controlled to the exhalation air amount of the user. Alternatively, the gas sterilizing and purifying amount of the first plasma shock generator 21 is controlled to a first set gas sterilizing and purifying amount, and the gas sterilizing and purifying amount of the second plasma shock generator 22 is controlled to a second set gas sterilizing and purifying amount.

Alternatively, the amount of gas sterilization purge to control the first plasma shock generator 21 increases as the user's respiratory demand increases and decreases as the user's respiratory demand decreases. The amount of sanitization of gas that controls the second plasma shock generator 22 increases as the user's respiratory demand increases and decreases as the user's respiratory demand decreases. That is, the sterilization purge amount of gas controlling the first plasma shock generator 21 increases as the user's inhalation amount increases, and decreases as the user's inhalation amount decreases. The amount of sanitization of gas that controls the second plasma shock generator 22 increases as the amount of exhalation by the user increases and decreases as the amount of exhalation by the user decreases.

Specifically, after the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to reach the inhalation air amount of the user, the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to reach the exhalation air amount of the user, or the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to reach the first set gas sterilization and purification amount, and the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to reach the second set gas sterilization and purification amount, if the inhalation air amount of the user increases, the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to increase, and if the inhalation air amount of the user decreases, the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to decrease. If the user's breath volume increases, the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to increase, and if the user's breath volume decreases, the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to decrease.

Alternatively, the amount of gas sanitization by which the second plasma shock generator 22 is controlled decreases as the amount of gas sanitization by the first plasma shock generator 21 increases and increases as the amount of gas sanitization by the first plasma shock generator 21 decreases. The amount of gas disinfection decontamination by the first plasma shock generator 21 is controlled to decrease as the amount of gas disinfection decontamination by the second plasma shock generator 22 increases and to increase as the amount of gas disinfection decontamination by the second plasma shock generator 22 decreases.

Specifically, when the gas sterilization and purification amount of the first plasma shock generator 21 is controlled to be increased, the gas sterilization and purification amount of the second plasma shock generator 22 is controlled to be decreased. When the gas sterilizing and purifying amount of the first plasma shock generator 21 is controlled to be decreased, the gas sterilizing and purifying amount of the second plasma shock generator 22 is controlled to be increased. When the amount of gas sterilization and purification by the second plasma shock generator 22 is controlled to increase, the amount of gas sterilization and purification by the first plasma shock generator 21 is controlled to decrease. When the gas sterilizing and purifying amount of the second plasma shock generator 22 is controlled to be decreased, the gas sterilizing and purifying amount of the first plasma shock generator 21 is controlled to be increased.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components. In the description of the present application, it should be understood that if there are terms such as "upper", "lower", "left", "right", etc., indicating orientations or positional relationships based on the orientations or positional relationships shown in the drawings, it is only for convenience of describing the present application and simplifying the description, but it is not intended to indicate or imply that the device 1 or the element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationships in the drawings are only used for illustrative purposes and are not to be construed as limiting the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. An air disinfecting and purifying device, comprising:

a breathing portion having a breathing cavity;

at least one plasma electric firing generator having an electric shock flow channel communicating the breathing chamber and an external environment, the plasma electric firing generator being configured such that gas flowing through the electric shock flow channel is disinfected and purified by electric shock.

2. An air disinfecting and purifying device as claimed in claim 1 which comprises:

the gas sensor is used for detecting the inspiration amount and the expiration amount of the user wearing the breathing part to breathe;

and the control module is connected with the gas sensor and the plasma electric-percussion generator, so that the control module controls the gas disinfection and purification amount of the plasma electric-percussion generator according to the detection information of the gas sensor.

3. Air disinfecting and purifying device as claimed in claim 2,

the plasma electric shock generator comprises at least one first plasma electric shock generator and at least one second plasma electric shock generator, and an electric shock flow channel of the first plasma electric shock generator and an electric shock flow channel of the second plasma electric shock generator are respectively communicated with the respiratory cavity and the external environment;

the air sterilizing and purifying apparatus includes:

at least one intake gas flow generating device configured to cause gas flowing into the strike flow channel of the first plasma shock generator to flow toward the breathing chamber.

4. An air disinfecting and purifying device as claimed in claim 3 which comprises:

at least one outlet gas flow generating device configured to cause gas flowing into the electrode flow channel of the second plasma shock generator to flow to the external environment.

5. Air disinfecting and purifying device as claimed in claim 3,

downstream of the second plasma shock generator there may be a collection tank configured to collect moisture and spray.

6. An air disinfecting and purifying device as recited in claim 3,

the gas sensor comprises a first gas sensor and a second gas sensor; the first gas sensor is configured to detect an inspiratory volume of a user breathing by wearing the breathing portion; the second gas sensor is configured to detect an amount of exhalation that is breathed by a user wearing the respiratory portion.

7. Air disinfecting and purifying device as recited in claim 6,

the control module is connected with the first gas sensor, the second gas sensor, the first plasma electric shock generator and the second plasma electric shock generator, so that the control module controls the gas disinfection and purification amount of the first plasma electric shock generator and the gas disinfection and purification amount of the second plasma electric shock generator according to the detection information of the first gas sensor and the detection information of the second gas sensor.

8. An air disinfecting and purifying device as recited in claim 3,

the control module is connected with the intake airflow generating device, so that the control module controls the air intake amount of the intake airflow generating device according to the detection information of the gas sensor.

9. Air disinfecting and purifying device as recited in claim 4,

the control module is connected with the gas outlet flow generating device, so that the control module controls the gas outlet amount of the gas outlet flow generating device according to the detection information of the gas sensor.

10. An air disinfecting and purifying device as recited in claim 1, comprising:

a battery configured to supply power to electrical devices in the air disinfecting and purifying apparatus.

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