CN113790501B - Plasma sterilization device and method - Google Patents

Abstract

The invention provides a plasma sterilization device and a method, the plasma sterilization device adopts plasma generated between electrodes to sterilize air, and the plasma sterilization device comprises: a plurality of pairs of electrodes, the inter-electrode spacing of the electrodes being adjustable; the detection device comprises one or more of an ozone concentration detection device, an air quality index detection device, a noise detection device and a distance measurement device and a control unit, and controls the electrode spacing of the electrodes to be adjusted to be optimal according to detection information acquired by the detection device. Has the advantages that: the plasma bacteria removing device and the method can achieve the effect that the inter-polar distance of the electrodes is in real-time dynamic adjustment, the inter-polar distance is always in the optimal value, so that the air quality index of the air subjected to bacteria removal through the plasma bacteria removing device is high, the ozone concentration is low, the noise generated by the electrodes is small, and the physical and mental health and the use experience of a user are not influenced.

Description

Plasma sterilization device and method

Technical Field

The invention relates to the field of air purification, in particular to a plasma sterilization device and a plasma sterilization method.

Background

Most of the current air conditioning systems are provided with a sterilizing device, a common sterilizing device is a plasma sterilizing device, wherein the plasma sterilizing device comprises two electrodes, a discharge electrode and a grounding electrode, the discharge electrode is connected with a high-voltage power supply, and plasma is generated between the discharge electrode and the grounding electrode under the condition of electrifying, so that air flowing between the two electrodes is sterilized through the plasma, and the sterilization and purification of the air are realized; however, the polar distance is too large, and the sterilization effect (which is directly reflected by the air quality index) is deteriorated, so how to control the polar distance, reduce noise and ensure the sterilization effect is a main research subject at present.

Disclosure of Invention

The invention solves the problems that the polar plate distance of the existing plasma sterilization device is close, noise and a large amount of ozone are generated in the sterilization process, the use experience of a user is influenced, or the polar distance is far, and the sterilization effect is poor.

To solve the above problems, it is an object of the present invention to provide a plasma sterilization apparatus.

The second purpose of the invention is to provide a plasma sterilization method.

In order to achieve the above object, a first aspect of the present invention provides a plasma sterilization apparatus for sterilizing air by generating plasma between electrodes, including:

a plurality of pairs of electrodes, the inter-electrode spacing of the electrodes being adjustable;

the detection device comprises any one or more of an ozone concentration detection device, an air quality index detection device, a noise detection device and a distance measurement device, wherein the ozone concentration detection device and the air quality index detection device are used for detecting the ozone concentration and the air quality index of airflow flowing out from a plurality of pairs of electrodes, the noise detection device is used for detecting the noise generated by the electrodes, and the distance measurement device is used for detecting the distance from a person to the electrodes; and

and the control unit controls the electrode distance to be adjusted to be optimal according to the detection information acquired by the detection device.

The plasma sterilization device provided by the embodiment of the invention adjusts the inter-polar distance of the electrodes to be optimal by detecting any one or more parameter information of four parameters, namely the ozone concentration and the air quality index of the air flow flowing out from the electrodes, the noise generated by the electrodes and the distance from a person to the electrodes in real time, namely the inter-polar distance of the electrodes is in real-time dynamic adjustment and is always in an optimal value, so that the air quality index of the air sterilized by the plasma sterilization device is high, the ozone concentration is low, the noise generated by the electrodes is low, and the physical and mental health and the use experience of a user are not influenced.

Further, the plasma sterilization device further comprises an air duct, the electrodes are arranged in the air duct, each pair of electrodes comprises a discharge electrode and a grounding electrode, the grounding electrodes are fixedly connected with the air duct, and the discharge electrodes can slide in the air duct to adjust the electrode spacing.

In the technical scheme, the air duct can be an air inlet channel of an air conditioner.

Furthermore, a rack is arranged on the discharge electrode along the direction of the inter-polar distance, a motor in transmission connection with the rack is arranged on the air duct, and the rack is driven by the motor to move along the direction of the inter-polar distance to adjust the inter-polar distance of the electrode.

In the technical scheme, the motor accurately regulates and controls the inter-polar distance of the electrodes under the control of the control unit.

Furthermore, a baffle is arranged on one side of the discharge electrode, which is far away from the grounding electrode, so that the air flow is prevented from flowing from one side of the discharge electrode, which is far away from the grounding electrode.

In order to achieve the above object, a second aspect of the present invention provides a plasma sterilization method for sterilizing air by generating plasma between electrodes, including:

acquiring detection information, wherein the detection information comprises any one or more of ozone concentration N of airflow flowing out from between the electrodes, air quality index X of the airflow flowing out from between the electrodes, noise magnitude M of the electrodes and distance H from a person to the electrodes;

obtaining the optimal inter-polar distance D of the electrode according to the detection information_{Optimization of}；

If D is_min≤D_{Optimization of}≤D_maxAdjusting the inter-polar distance of the electrodes to D_{Optimization of}；

If D is_{Optimization of}＜D_minAdjusting the inter-polar distance of the electrodes to D_min；

If D is_{Optimization of}＞D_maxAdjusting the inter-polar distance of the electrodes to D_max。

According to the plasma sterilization method, the electrode distance of the electrodes is adjusted to be optimal through detecting any one or more parameter information of four parameters including the ozone concentration and the air quality index of airflow flowing out of the electrodes, the noise generated by the electrodes and the distance from a person to the electrodes in real time, namely the electrode distance of the electrodes is in real-time dynamic adjustment and is always in an optimal value, so that the air quality index of the air sterilized by the plasma sterilization device is high, the ozone concentration is low, the noise generated by the electrodes is low, and the physical and mental health and the use experience of a user are not influenced.

Further, the optimal inter-polar distance D of the electrodes is obtained according to the detection information_{Optimization of}The method comprises the following steps:

if the detection information is the distance H between the person and the electrode, and H₁≤H≤H₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}＝K₁H+C₁In the formula, H₁、H₂、K₁、C₁Are all constants;

if the detection information is the noise of the electrode, and M is₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}＝K₂M+C₂In the formula, M₁、M₂、K₂、C₂Are all constants;

if the detection information is the ozone concentration N of the airflow flowing out from the electrode, and N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}＝K₃N+C₃In the formula, N₁、N₂、K₃、C₃Are all constants;

if the detection information is an air quality index X of the air flow flowing out from between the electrodes, and X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Optimum 4}＝K₄X+C₄In the formula, X₁、X₂、K₄、C₄Are all constants;

if the detection information is the distance H between the person and the electrode and the noise magnitude M of the electrode, and H₁≤H≤H₂、M₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}；

If the detection information is the distance H between the person and the electrodes and the ozone concentration N of the airflow flowing out from the electrodes, and H₁≤H≤H₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 3}；

If the detection information is the distance H between the person and the electrode and the air quality index X of the air flow flowing out from the electrode, and H₁≤H≤H₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes and the ozone concentration N of the air flow flowing out from between the electrodes, and M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}；

If the detection information is the noise of the electrode M and the noise flowing out from the electrodeAir mass index X, and M of the air stream of (2)₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Optimum 4}；

If the detection information is the ozone concentration N and the air quality index X of the airflow flowing out from the electrode, and N is₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H from a person to the electrodes, the noise level M of the electrodes and the ozone concentration N of the airflow flowing out of the electrodes, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Best 3}；

If the detection information is the distance H between the human body and the electrode, the noise magnitude M of the electrode and the air quality index X of the air flow flowing out from the electrode, and H₁≤H≤H₂、M₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes, the ozone concentration N of the airflow flowing out from the electrodes and the air quality index X, and M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H between a person and the electrodes, the noise magnitude M of the electrodes, the ozone concentration N of the airflow flowing out of the electrodes and the air quality index X, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Best 3}+D_{Optimum 4}。

In the technical scheme, if the detection information is different, the corresponding calculation methods of the optimal inter-polar distance are also different.

Further, if H < H₁Then D is_{Best 1}＝K₁H₁+C₁If H > H₂Then D is_{Best 1}＝K₁H₂+C₁；

If M is less than M₁Then D is_{Best 2}＝K₂M₁+C₂If M > M₂Then D is_{Best 2}＝K₂M₂+C₂；

If N is less than N₁Then D is_{Best 3}＝K₃N₁+C₃If N > N₂Then D is_{Best 3}＝K₃N₂+C₃；

If X < X₁Then D is_{Optimum 4}＝K₄X₁+C₄If X > X₂Then D is_{Optimum 4}＝K₄X₂+C₄。

Has the advantages that: the utility model provides a plasma bacteria removing device and method are through the ozone concentration and the air quality index of real-time detection follow the air current that flows out between a plurality of pairs of electrodes, the noise size that the electrode produced, the interpolar distance that the electrode was adjusted to the arbitrary or multiple parameter information in these four parameters of distance of people to electrode is optimum, the interpolar distance of also being the electrode is in among the real-time dynamic adjustment, the interpolar distance is in the optimal value all the time, the air quality index of the air after like this through the degerming of plasma bacteria removing device is high, ozone concentration is low, the noise that the electrode produced is little, do not influence user's physical and mental health and use experience.

Drawings

FIG. 1 is a first schematic diagram of a plasma sterilization apparatus according to an embodiment of the present invention;

FIG. 2 is a second schematic diagram of a plasma sterilization apparatus according to an embodiment of the present invention;

fig. 3 is an enlarged view of a portion a in fig. 2.

The reference numbers are as follows:

1. an air duct; 2. a ground electrode; 3. a discharge electrode; 4. a baffle plate; 5. a motor; 6. a rack; 7. a through groove.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

The invention provides a plasma sterilization device which adopts plasma generated between electrodes to sterilize air, for example, the plasma sterilization device is arranged in an air inlet or an air inlet channel of an indoor unit of an air conditioner to sterilize and purify the air entering the indoor unit.

In an embodiment of the invention, the plasma sterilization device comprises a plurality of pairs of electrodes, a detection device and a control unit, the plurality of pairs of electrodes are arranged along the flowing direction of air, the air flow can sequentially pass through the plurality of pairs of electrodes, the passing of the air flow through one pair of electrodes means that the air flow passes through between the pair of electrodes, for example, one pair of electrodes comprises a discharge electrode 3 and a grounding electrode 2, the passing of the air flow through one pair of electrodes means that the air flow passes through between the discharge electrode 3 and the grounding electrode 2, the sequentially passing of the air flow through the plurality of pairs of electrodes means that the air flow sequentially passes through the discharge electrode 3 and the grounding electrode 2 of the plurality of pairs of electrodes, and the electrode spacing between the electrodes is adjustable;

the detection device comprises any one or more of an ozone concentration detection device, an air quality index detection device, a noise detection device and a distance measurement device, wherein the ozone concentration detection device and the air quality index detection device are used for detecting the ozone concentration and the air quality index of airflow flowing out of a plurality of pairs of electrodes, namely detecting the ozone concentration and the air quality index of air sterilized by the plasma sterilization device; the distance measuring device is used for detecting the distance from a person to the electrode, and certainly, if the plasma sterilization device is applied to the air-conditioning indoor unit, the distance measuring device can also be used for detecting the distance from the person to the air-conditioning indoor unit, so that the distance from the person to the electrode or the air-conditioning indoor unit is detected to protect the health of the person and prevent the person from approaching the air-conditioning indoor unit or the electrode from being influenced by noise and ozone generated by the electrode;

the control unit comprises a controller and a processor, wherein the processor is used for analyzing and processing the detection information acquired by the detection device, then sending a control instruction to the controller, and controlling the electrode spacing of the electrodes to be adjusted by the controller so as to ensure that the electrode spacing of the electrodes is always in the optimal level.

The plasma sterilization device provided by the embodiment of the invention adjusts the inter-polar distance of the electrodes to be optimal by detecting any one or more parameter information of four parameters, namely the ozone concentration and the air quality index of the air flow flowing out from the electrodes, the noise generated by the electrodes and the distance from a person to the electrodes in real time, namely the inter-polar distance of the electrodes is in real-time dynamic adjustment and is always in an optimal value, so that the air quality index of the air sterilized by the plasma sterilization device is high, the ozone concentration is low, the noise generated by the electrodes is low, and the physical and mental health and the use experience of a user are not influenced.

In this embodiment, ozone concentration detection instrument can be chooseed for use to ozone concentration detection device, air quality index detection instrument can be chooseed for use to air quality index detection device, noise level meter can be chooseed for use to noise detection device, infrared distancer can be chooseed for use to range unit.

Further, in this embodiment, the plasma sterilization apparatus further includes an air duct 1, as shown in fig. 1 and fig. 2, the air duct 1 may be an air inlet channel of an air conditioner, the electrodes are disposed in the air duct 1, each pair of electrodes includes a discharge electrode 3 and a ground electrode 2, the ground electrode 2 is fixedly connected to the air duct 1, the discharge electrode 3 can slide up and down in the air duct 1 to adjust a polar distance, the method of driving the discharge electrode 3 to slide up and down includes direct driving by a linear motor 5, driving by a linear actuator such as an air cylinder and a hydraulic cylinder, driving by a transmission belt and a transmission chain, and the like, in other embodiments, a rack 6 and a gear may be used for driving, for example, as shown in fig. 2 and fig. 3, the rack 6 is disposed on the discharge electrode 3 along a polar distance direction, a motor 5 drivingly connected to the rack 6 is disposed on the air duct 1, a gear engaged with the rack 6 is disposed on an output shaft of the motor 5, the rack 6 is driven by the motor 5 to move along the inter-polar distance direction to adjust the inter-polar distance of the electrodes, and in fig. 3, a through groove 7 for the rack 6 to pass through is arranged on the air duct 1.

Furthermore, as shown in fig. 1 and 2, a baffle 4 is disposed on a side of the discharge electrode 3 facing away from the ground electrode 2, the baffle 4 is slidably inserted into the air duct 1, and the baffle 4 functions to block the airflow from flowing from the side of the discharge electrode 3 facing away from the ground electrode 2 (i.e., the upper side of the discharge electrode 3 in fig. 1 and 2), so as to ensure that the airflow completely flows between the discharge electrode 3 and the ground electrode 2.

In order to achieve the above object, a second aspect of the present invention provides a plasma sterilization method for sterilizing air by generating plasma between electrodes, including:

s1, acquiring detection information, wherein the detection information comprises any one or more of ozone concentration N of the airflow flowing out from the electrode, air quality index X of the airflow flowing out from the electrode, noise magnitude M of the electrode and distance H from a person to the electrode;

s2, obtaining the optimal inter-polar distance D of the electrode according to the detection information_{Optimization of}；

If D is_min≤D_{Optimization of}≤D_maxAdjusting the inter-polar distance of the electrodes to D_{Optimization of}The electrode spacing may not be infinite or infinitesimal during practical use, and has a range, and the corresponding specific D is usually set according to the specific application environment of the plasma sterilization device_minAnd D_maxValues of (2), e.g. application of plasma sterilization devices in the field of air-conditioning indoor units, D_minIs 20mm, D_maxIs 30 mm;

if D is_{Optimization of}＜D_minThen only the inter-polar distance of the electrodes can be adjusted to D_min；

If D is_{Optimization of}＞D_maxThen onlyCan adjust the inter-polar distance of the electrodes to D_max。

According to the plasma sterilization method, the electrode distance of the electrodes is adjusted to be optimal through detecting any one or more parameter information of four parameters including the ozone concentration N and the air quality index X of air flow flowing out of a plurality of pairs of electrodes, the noise generated by the electrodes M and the distance H from a person to the electrodes in real time, namely the electrode distance of the electrodes is in real-time dynamic adjustment and is always in an optimal value, so that the air quality index of air sterilized by the plasma sterilization device is high, the ozone concentration is low, the noise generated by the electrodes is small, and the physical and mental health and the use experience of a user are not influenced.

Further, S2 obtains the optimal inter-polar distance D of the electrode according to the detection information_{Optimization of}The method comprises the following steps:

if the detection information is the distance H between the person and the electrode, and H₁≤H≤H₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}＝K₁H+C₁In the formula, H₁、H₂、K₁、C₁Are constant, and the specific value is related to the specific application environment of the plasma sterilization apparatus, such as the application of the plasma sterilization apparatus in the field of indoor unit of air conditioner, and H₁0.5m, H₂Is 2.5m, K₁Is-5, C₁Is 32.5, of course, if the detected distance H < H from the electrode₁Then D is_{Best 1}＝K₁H₁+C₁If H > H₂Then D is_{Best 1}＝K₁H₂+C₁；

If the detection information is the noise of the electrode, and M is₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}＝K₂M+C₂In the formula, M₁、M₂、K₂、C₂Are constant, and the specific value is related to the specific application environment of the plasma sterilization apparatus, such as the application of the plasma sterilization apparatus in the field of indoor unit of air conditioner, then M₁Is 30dB, M₂Is 65dB, K₂Is-2/7, C₂270/7, of course, if the noise level M < M of the electrode is detected₁Then D is_{Best 2}＝K₂M₁+C₂If M > M₂Then D is_{Best 2}＝K₂M₂+C₂；

If the detection information is the ozone concentration N of the air flow flowing out from between the electrodes, and N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}＝K₃N+C₃In the formula, N₁、N₂、K₃、C₃Are constant, and the specific value is related to the specific application environment of the plasma sterilization apparatus, such as the application of the plasma sterilization apparatus in the field of indoor unit of air conditioner, and N₁0.15ppm, N₂0.3ppm, K₃Is-200/3, C₃Is 40, of course, if N < N₁Then D is_{Best 3}＝K₃N₁+C₃If N > N₂Then D is_{Best 3}＝K₃N₂+C₃；

If the detection information is an air quality index X of the air flow flowing out from between the electrodes, and X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Optimum 4}＝K₄X+C₄In the formula, X₁、X₂、K₄、C₄Are constant, and the specific value is related to the specific application environment of the plasma sterilization apparatus, such as the application of the plasma sterilization apparatus in the field of indoor unit of air conditioner, then X₁Is 30, X₂Is 300, K₄Is 1/27, C₄170/9, of course, if X < X₁Then D is_{Optimum 4}＝K₄X₁+C₄If X > X₂Then D is_{Optimum 4}＝K₄X₂+C₄；

If the detection information is the distance H between the person and the electrode and the noise magnitude M of the electrode, and H₁≤H≤H₂、M₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}；

If the detection information is the distance H between the person and the electrodes and the ozone concentration N of the airflow flowing out from the electrodes, and H₁≤H≤H₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 3}；

If the detection information is the distance H between the person and the electrode and the air quality index X of the air flow flowing out from the electrode, and H₁≤H≤H₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes and the ozone concentration N of the air flow flowing out from between the electrodes, and M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}；

If the detection information is the noise level M of the electrodes and the air quality index X of the air flow flowing out from between the electrodes, and M is₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Optimum 4}；

If the detection information is the ozone concentration N and the air quality index X of the airflow flowing out from the electrode, and N is₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H between a person and the electrodes, the noise level M of the electrodes and the ozone concentration N of the airflow flowing out from the electrodes, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Best 3}；

If the detection information is the distance H from the person to the electrode and the noise of the electrodeM and the air mass index X of the gas flow flowing out from between the electrodes, and H₁≤H≤H₂、M₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes, the ozone concentration N of the airflow flowing out from the electrodes and the air quality index X, and M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H between a person and the electrodes, the noise magnitude M of the electrodes, the ozone concentration N of the airflow flowing out from the electrodes and the air quality index X, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Best 3}+D _{Optimization of}4。

Therefore, in the technical scheme, if the detection information is different, the corresponding calculation method of the optimal inter-polar distance is also different.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (9)

1. A plasma sterilization method for sterilizing air by generating plasma between electrodes, comprising:

acquiring detection information, wherein the detection information comprises any one or more of ozone concentration N of airflow flowing out from between the electrodes, air quality index X of the airflow flowing out from between the electrodes, noise magnitude M of the electrodes and distance H from a person to the electrodes;

obtaining the optimal inter-polar distance D of the electrode according to the detection information_{Optimization of}；

If D is_min≤D_{Optimization of}≤D_maxAdjusting the inter-polar distance of the electrodes to D_{Optimization of}；

If D is_{Optimization of}＜D_minAdjusting the inter-polar distance of the electrodes to D_min；

If D is_{Optimization of}＞D_maxAdjusting the inter-polar distance of the electrodes to D_max；

Wherein the optimal inter-polar distance D of the electrodes is obtained according to the detection information_{Optimization of}The method comprises the following steps:

if the detection information is the distance H between the person and the electrode, and H₁≤H≤H₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}＝K₁H+C₁In the formula, H₁、H₂、K₁、C₁Are all constants;

if the detection information is the noise of the electrode, and M is₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}＝K₂M+C₂In the formula, M₁、M₂、K₂、C₂Are all constants;

if the detection information is the ozone concentration N of the air flow flowing out from between the electrodes, and N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}＝K₃N+C₃In the formula, N₁、N₂、K₃、C₃Are all constants;

if the detection information is an air quality index X of the air flow flowing out from between the electrodes, and X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Optimum 4}＝K₄X+C₄In the formula, X₁、X₂、K₄、C₄Are all constants;

if the detection information is the distance H between the person and the electrode and the noise level M of the electrode,and H₁≤H≤H₂、M₁≤M≤M₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}；

If the detection information is the distance H between the person and the electrodes and the ozone concentration N of the airflow flowing out from the electrodes, and H₁≤H≤H₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 3}；

If the detection information is the distance H between the person and the electrode and the air quality index X of the air flow flowing out from the electrode, and H₁≤H≤H₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes and the ozone concentration N of the air flow flowing out from the space between the electrodes, and M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}；

If the detection information is the noise level M of the electrodes and the air quality index X of the air flow flowing out from between the electrodes, and M is₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Optimum 4}；

If the detection information is the ozone concentration N and the air quality index X of the airflow flowing out from the space between the electrodes, and N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H from a person to the electrodes, the noise level M of the electrodes and the ozone concentration N of the airflow flowing out of the electrodes, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Optimization of2}+D_{Best 3}；

If the detection information is the distance H between the human body and the electrode, the noise magnitude M of the electrode and the air quality index X of the air flow flowing out from the electrode, and H₁≤H≤H₂、M₁≤M≤M₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Optimum 4}；

If the detection information is the noise level M of the electrodes, the ozone concentration N of the airflow flowing out from the electrodes and the air quality index X, and M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 2}+D_{Best 3}+D_{Optimum 4}；

If the detection information is the distance H between a person and the electrodes, the noise magnitude M of the electrodes, the ozone concentration N of the airflow flowing out of the electrodes and the air quality index X, and H₁≤H≤H₂、M₁≤M≤M₂、N₁≤N≤N₂、X₁≤X≤X₂Then the optimum inter-polar distance D of the electrodes_{Optimization of}＝D_{Best 1}+D_{Best 2}+D_{Best 3}+D_{Optimum 4}。

2. The plasma sterilization method of claim 1, wherein if H < H₁Then D is_{Best 1}＝K₁H₁+C₁If H > H₂Then D is_{Best 1}＝K₁H₂+C₁。

3. The plasma sterilization method of claim 1, wherein if M < M₁Then D is_{Best 2}＝K₂M₁+C₂If M > M₂Then D is_{Best 2}＝K₂M₂+C₂。

4. The method of claim 1Plasma sterilization method, characterized in that if N < N₁Then D is_{Best 3}＝K₃N₁+C₃If N > N₂Then D is_{Best 3}＝K₃N₂+C₃。

5. The plasma sterilization method of claim 1, wherein if X < X₁Then D is_{Optimum 4}＝K₄X₁+C₄If X > X₂Then D is_{Optimum 4}＝K₄X₂+C₄。

6. A plasma sterilization apparatus for sterilizing air by generating plasma between electrodes, characterized in that the plasma sterilization method according to any one of claims 1 to 5 is used, the apparatus comprising:

a plurality of pairs of electrodes, the inter-electrode spacing of the electrodes being adjustable;

the detection device comprises any one or more of an ozone concentration detection device, an air quality index detection device, a noise detection device and a distance measurement device, wherein the ozone concentration detection device and the air quality index detection device are used for detecting the ozone concentration and the air quality index of airflow flowing out of a plurality of pairs of electrodes, the noise detection device is used for detecting the noise generated by the electrodes, and the distance measurement device is used for detecting the distance from a person to the electrodes; and

and the control unit controls the electrode distance to be adjusted to be optimal according to the detection information acquired by the detection device.

7. The plasma sterilization apparatus as recited in claim 6, further comprising an air duct, wherein said electrodes are disposed in said air duct, each pair of electrodes comprises a discharge electrode and a ground electrode, said ground electrode is fixedly connected to said air duct, and said discharge electrode is slidable within said air duct to adjust the distance between said electrodes.

8. The plasma sterilization apparatus as claimed in claim 7, wherein the discharge electrode is provided with a rack along the inter-polar distance direction, the air duct is provided with a motor in transmission connection with the rack, and the inter-polar distance of the discharge electrode is adjusted by moving the rack along the inter-polar distance direction by the motor.

9. The plasma sterilization apparatus as recited in claim 7, wherein a side of said discharge electrode facing away from said ground electrode is provided with a baffle to block the flow of air from the side of said discharge electrode facing away from said ground electrode.

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