CN111457522A - Control method and device of superoxide atomization disinfection machine - Google Patents

Abstract

The invention provides a control method and a device of a superoxide atomization sterilizer, wherein the method comprises the following steps: receiving a touch control instruction input by a user; determining a current working mode according to the touch instruction; if the spray mode is direct spray mode, enter intoThe direct spray mode; if the first disinfection spraying mode is adopted, entering the first disinfection spraying mode; and if the second disinfection spray mode is adopted, entering the second disinfection spray mode. Through the three working modes, the spray, the ozone generator and the negative ion generator can be effectively controlled to work alternately, so that the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The allowed ozone concentration can effectively inhibit and eliminate viruses breeding in closed or semi-closed environments such as families, offices and the like. The defect that viruses bred in closed or semi-closed environments or dead corners of families, offices and the like cannot be inhibited and eliminated due to the fact that functions of humidifier products in the prior art are single is overcome.

Description

Control method and device of superoxide atomization disinfection machine

Technical Field

The invention relates to the technical field of household appliances and medical disinfection equipment, in particular to a control method and a control device of a superoxide atomization disinfection machine.

Background

Currently, the main function of the known humidifier products is to increase air humidity, and the functions are single. In small closed or semi-closed occasions such as families, offices and the like, viruses are easy to breed in closed or semi-closed environments, so that the health of people is affected. How to restrain and eliminate viruses bred in small-sized closed or semi-closed occasion environments such as families, offices and the like is a concern of people, most of the existing humidifiers are only used for simply and limitedly adjusting air humidity in the closed environments or are temporarily placed through a ventilation window box, and the viruses bred in the small-sized closed or semi-closed occasion environments such as the families, the offices and the like cannot be restrained and eliminated.

Disclosure of Invention

The technical problem to be solved by the embodiment of the invention is to provide a control method and a device of a superoxide atomization sterilizer with a sterilization function, aiming at the defects that humidifier products in the prior art have single functions and cannot inhibit and eliminate viruses bred in small-sized closed or semi-closed environments such as families, offices and the like.

In order to solve the technical problem, the embodiment of the invention provides a control method of a superoxide atomization disinfection machine, which comprises the following steps:

receiving a touch control instruction input by a user;

determining a current working mode according to the touch instruction, wherein the working mode comprises a direct spraying mode, a first disinfection spraying mode and a second disinfection spraying mode;

if the spray mode is the direct spray mode, the spray mode is entered, the ultrasonic wave energy conversion sheet and the negative ion generator are started, the high-frequency mechanical vibration generated by the ultrasonic wave energy conversion sheet drives the water to vibrate and atomize, and the atomized gas is directly sprayed and output through the fan;

if the water is in the first disinfection spraying mode, entering the first disinfection spraying mode, starting an ozone generator to generate ozone in a preset first time threshold while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, forming ozone or negative-ion vaporous gas and outputting the vaporous gas in a spraying manner, stopping generating the ozone after the expiration of the preset first time threshold by the ozone generator, and entering an independent spraying link;

if the water is in the second disinfection spraying mode, the water enters the second disinfection spraying mode, the ozone generator is started while the water is driven to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, the ozone generator can generate ozone within a preset working time threshold value between the first time threshold value and a preset second time threshold value to form ozone or negative-ion vaporous gas and spray and output the ozone, the ozone generator stops generating the ozone after the set working time threshold value, and the water enters an independent spraying link; wherein the second time domain value is greater than the first time domain value.

Further, the touch control instruction is a touch control instruction of an on-off key, and then the current working mode is determined to be a direct spraying mode according to the touch control instruction of the on-off key, and the direct spraying mode is entered.

Further, the touch control command is an on-off key and nano disinfection key combined touch control command, the current working mode is determined to be a first disinfection spray mode according to the on-off key and nano disinfection key combined touch control command, and the first disinfection spray mode is entered.

Further, the touch control command is a combined touch control command of an on-off key, a nanometer disinfection key and a timing key, the current working mode is determined to be a second disinfection spraying mode according to the combined command of the on-off key, the nanometer disinfection key and the timing key, and the link of the second disinfection spraying mode is entered.

Further, the preset first time threshold is 30 minutes, and the preset second time threshold is 120 minutes.

Correspondingly, the invention also provides a control device of the superoxide atomization sterilizing machine, which comprises:

the receiving module is used for receiving a touch control instruction input by a user;

the working mode determining module is used for determining a current working mode according to the touch instruction received by the receiving module, wherein the working mode comprises a direct spraying mode, a first disinfection spraying mode and a second disinfection spraying mode;

the direct spraying module is used for entering the direct spraying mode when the working mode determining module determines that the current working mode is the direct spraying mode, starting the ultrasonic energy conversion sheet and the negative ion generator, driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, and directly spraying and outputting atomized gas through the fan;

the first disinfection spraying module is used for entering a first disinfection spraying mode when the working mode determining module determines that the current working mode is the first disinfection spraying mode, starting the ozone generator to generate ozone in a preset first time domain value while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, forming atomized gas of ozone or negative ions and outputting the atomized gas in a spraying manner, stopping generating the ozone after the expiration of the preset first time domain value by the ozone generator, and entering an independent spraying link;

the second disinfection spraying module is used for entering a second disinfection spraying mode when the working mode determining module determines that the current working mode is the second disinfection spraying mode, starting the ozone generator while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, wherein the ozone generator can generate ozone within a preset working time domain value between the first time domain value and a preset second time domain value to form ozone or mist gas of negative ions and spray and output the ozone, and the ozone generator stops generating the ozone after the set working time domain value and enters an independent spraying link; wherein the second time domain value is greater than the first time domain value.

Further, the touch control instruction is a touch control instruction of an on-off key, and then the current working mode is determined to be a direct spraying mode according to the touch control instruction of the on-off key, and the direct spraying mode is entered.

Further, the touch control command is an on-off key and nano disinfection key combined touch control command, the current working mode is determined to be a first disinfection spray mode according to the on-off key and nano disinfection key combined touch control command, and the first disinfection spray mode is entered.

Further, the touch control command is a combined touch control command of an on-off key, a nanometer disinfection key and a timing key, the current working mode is determined to be a second disinfection spraying mode according to the combined command of the on-off key, the nanometer disinfection key and the timing key, and the link of the second disinfection spraying mode is entered. .

Further, the preset first time threshold is 30 minutes, and the preset second time threshold is 120 minutes

According to the control method of the superoxide atomization disinfection machine, after a touch control instruction input by a user is received; determining a current working mode according to the touch instruction, entering the direct spraying mode if the current working mode is the direct spraying mode, starting the ultrasonic energy conversion sheet and the negative ion generator, driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, and directly spraying and outputting atomized gas through a fan; if the water is in the first disinfection spraying mode, entering the first disinfection spraying mode, starting an ozone generator to generate ozone in a preset first time threshold while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, forming ozone or negative-ion vaporous gas and outputting the vaporous gas in a spraying manner, stopping generating the ozone after the expiration of the preset first time threshold by the ozone generator, and entering an independent spraying link; if the water is in the second disinfection spray mode, the water enters the second disinfection spray mode, the ozone generator is started while the water is driven to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, the ozone generator can generate ozone within a preset working time threshold value between the first time threshold value and the preset second time threshold value to form ozone or negative-ion atomized gas and spray and output the ozone, the ozone generator stops generating the ozone after the set working time threshold value and enters an independent spray link, and therefore the spraying and ozone generator can be effectively controlled through the three working modesAnd the negative ion generator alternately work, so that the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The ozone generator can effectively inhibit and eliminate viruses bred in small-sized closed or semi-closed environments such as families, offices and the like while allowing the concentration of ozone, and solves the defects that the humidifier products in the prior art have single functions and cannot inhibit and eliminate the viruses bred in the small-sized closed or semi-closed environments such as the families, the offices and the like.

Drawings

FIG. 1 is a flow chart of a method for controlling a superoxide atomization sterilizer according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a control device of a superoxide atomization sterilizer provided by an embodiment of the invention.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects solved by the present invention more clearly apparent, the present invention is further described in 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 invention and are not intended to limit the invention.

Fig. 1 is a flow chart of a control method of a superoxide atomization disinfection machine according to an embodiment of the present invention. As shown in fig. 1, the method includes:

s101, receiving a touch control command input by a user.

Specifically, a user can input a touch instruction on a control panel of the superoxide atomization disinfection machine, and the control panel is used for realizing specific operations of the superoxide atomization disinfection machine: such as opening, closing, adjusting, timing or nano-disinfection, the control panel may be a control panel formed by collectively mounting a plurality of control buttons on a mounting plate, or may be a liquid crystal time-type control panel or any other panel capable of realizing a control function, and will not be described in detail herein.

As an optional implementation manner, the touch control instruction is a touch instruction of an on-off key.

As an optional implementation manner, the touch control command is a combined touch control command of an on-off key and a nano disinfection key.

As an optional implementation manner, the touch control command is a combined touch control command of an on-off key, a nano disinfection key and a timing key.

S102, determining a current working mode according to the touch instruction, wherein the working mode comprises a direct spraying mode, a first disinfection spraying mode and a second disinfection spraying mode. The test mode may be manually input by the user, and if the test mode is the direct spray mode, the direct spray mode is entered, and step S103 is executed; if the first disinfection spray mode is adopted, entering the first disinfection spray mode, and executing the step S104; if the second sterilization spray mode is selected, the second sterilization spray mode is entered, and step S105 is executed.

S103, if the spray mode is the direct spray mode, entering the direct spray mode, starting the ultrasonic energy conversion sheet and the negative ion generator, driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, and directly spraying and outputting atomized gas through the fan.

Specifically, when the touch instruction received by the superoxide atomization disinfection machine is the touch instruction of an on-off key, the current working mode is determined to be the direct spraying mode according to the touch instruction of the on-off key, the direct spraying mode is entered, the ultrasonic energy conversion sheet and the anion generator are started, water is driven to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, and mist gas is directly sprayed and output through the fan, at the moment, the superoxide atomization disinfection machine only has a humidifying function, and the disinfection function of the superoxide atomization disinfection machine is not started.

In this embodiment, the water atomization part is mainly completed by the water tank, the ultrasonic transducer, the driving power supply and other components; the principle is as follows: after water is added into the water tank, the ultrasonic transducer is controlled and driven to generate high-frequency mechanical vibration, so that water is driven to vibrate and atomize, and the atomized gas is directly sprayed by the fan. The ozone generator module adopts positive electrons generated by direct current high voltage to be combined by oxygen ions in the air to form positive ions or negative ions.

S104, if the first disinfection spray mode is adopted, the first disinfection spray mode is entered, then the water is driven to vibrate and atomize through the high-frequency mechanical vibration generated by the ultrasonic energy conversion piece, meanwhile, the ozone generator is started to generate ozone in a preset first time domain value, ozone or negative-ion vaporific gas is formed and is output in a spraying mode, the ozone generator stops generating ozone after the preset first time domain value expires, and an independent spraying link is entered.

Specifically, when the touch control instruction received by the superoxide atomization disinfection machine is an on-off key and nanometer disinfection key combined touch instruction, the current working mode is determined to be a first disinfection spray mode according to the on-off key and nanometer disinfection key combined touch instruction, the first disinfection spray mode is entered, the ozone generator is started to generate ozone in a preset first time domain value while water is driven to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, atomized gas of ozone or negative ions is formed and sprayed and output, at the moment, ultrasonic atomization, ozone and negative ions of the superoxide atomization disinfection machine simultaneously work, atomized gas generates atomized gas containing ozone or negative ions after being disinfected by ozone and is sprayed, so that a disinfection function is realized, the ozone generator stops generating ozone after the expiration of the preset first time domain value, and (4) entering an independent spraying link, stopping producing ozone by the ozone generator at the moment, pausing the disinfection function, and only using high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet to drive water to vibrate and atomize and directly spray and output the vaporous gas through the fan. Because the ozone concentration requirement of the air products in China is 0.5-2mg/m at present³However, this requirement is easily met or exceeded in a closed environment, which causes adverse effect, therefore, this embodiment can effectively control the spray, the ozone generator and the negative ion generator to work alternately by controlling the ozone generator to generate ozone within a preset first time threshold value, so as to achieve the concentration of the discharged ozone far lower than the standard 0.15mg/m³The ozone concentration is allowed, and simultaneously, viruses bred in small-sized closed or semi-closed environments of families, offices and the like can be effectively inhibited and eliminated.

It should be noted that, in this embodiment, the preset first time threshold is 30 minutes, but this embodiment does not limit the first time threshold to be only preset for 30 minutes, and other times may be preset as needed.

It should be noted that, in this embodiment, the ozone and negative ion generator is generated by a special module, and the principle is to separate oxygen molecules in air by using high voltage electric shock; ozone is an active oxidant, which is much more oxidizing than oxygen, mainly because it has delocalized pi-bonds, which can generate oxygen radicals. And for this reason it is a polar molecule. Ozone is strong in oxidizing property, has pungent odor when exceeding a certain concentration, has the international safety concentration of 0.1ppm but also has the characteristic that ozone is an allotrope of oxygen, is decomposed into oxygen and has no residues, so that the ozone is used for sterilization in the fields of pure water sterilization, high-end swimming pools, space sterilization GMP and the like, and the ozone is very active in chemical property, so that the decomposition is fast.

S105, if the second disinfection spray mode is adopted, the second disinfection spray mode is entered, then the high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet drives the water to vibrate and atomize, and simultaneously the ozone generator is started, the ozone generator can generate ozone within a working time domain value set at will between the first time domain value and a preset second time domain value to form ozone or negative ion mist gas and spray and output, the ozone generator stops generating ozone after the set working time domain value, and the independent spray link is entered; wherein the second time domain value is greater than the first time domain value.

Specifically, when the touch control instruction received by the superoxide atomization disinfection machine is a combined touch instruction of an on-off key, a nanometer disinfection key and a timing key, determining that the current working mode is a second disinfection spray mode according to the combined instruction of the on-off key, the nanometer disinfection key and the timing key, entering a link of the second disinfection spray mode, starting an ozone generator while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, wherein the ozone generator can generate ozone within a working time domain value which is arbitrarily set between a first time domain value and a preset second time domain value,form the fog gas of ozone or anion and spray and export, at this moment, the ultrasonic atomization of the super oxygen atomization sterilizer, ozone and anion generation work at the same time within the maximum control duration, the gas after the atomization produces the fog gas containing ozone or anion to spray out after the ozone sterilization, thus realize the disinfection function, the ozone generator stops generating ozone after the set working time threshold, enter the independent spraying link, at this moment, the ozone generator stops producing ozone, its disinfection function is suspended, only the high-frequency mechanical vibration that the ultrasonic transducer piece produces drives the water vibration atomization and directly sprays the fog gas and exports through the fan, this embodiment produces ozone within the preset working time threshold through controlling the ozone generator, can control the spray, the ozone generator and the anion generator to work at the same time within the maximum control duration effectively, thereby achieving the purpose that the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The ozone concentration is allowed, and simultaneously, viruses bred in small-sized closed or semi-closed environments such as families, offices and the like can be effectively inhibited and eliminated.

It should be noted that, in this embodiment, the second time domain value is greater than the first time domain value.

It should be noted that, in this embodiment, the preset second time threshold is 120 minutes, but this embodiment does not limit that the second time threshold is only preset to be 120 minutes, and other times may also be preset as needed, as long as it is ensured that the second time threshold is greater than the first time threshold.

It should be noted that, compared with the conventional ozone air sterilization, the present embodiment: 1. after ultrasonic atomization and ozone gas premixing are fused, the product is discharged without nitrogen oxide (with authority department certification and detection data); 2. the embodiment can effectively solve the problem of ionic activity and oxidized pollutant sedimentation of the traditional ozone generator which is difficult to control in the air by adding ozone through ultrasonic atomization.

According to the control method of the superoxide atomization disinfection machine provided by the embodiment of the invention, after a touch control instruction input by a user is received; according to the touch fingerDetermining a current working mode, if the current working mode is a direct spraying mode, entering the direct spraying mode, and if the current working mode is a first disinfection spraying mode, entering the first disinfection spraying mode; if the ozone generator is in the second disinfection spraying mode, the second disinfection spraying mode is entered, thus, the spraying, the ozone generator and the negative ion generator can be effectively controlled to alternately work through the three working modes, and the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The ozone generator can effectively inhibit and eliminate viruses bred in small-sized closed or semi-closed environments such as families, offices and the like while allowing the concentration of ozone, and overcomes the defects that the functions of humidifier products in the prior art are single and the viruses bred in the small-sized closed or semi-closed environments such as the families, the offices and the like cannot be inhibited and eliminated.

Referring to fig. 2, a structure diagram of a control device of a superoxide atomization disinfection machine according to an embodiment of the present invention is shown in fig. 2, where the control device 100 of the superoxide atomization disinfection machine includes: a receiving module 110, an operation mode determining module 120, a direct spray module 130, a first disinfection spray module 140, and a second disinfection spray module 150, wherein,

a receiving module 110, configured to receive a touch control instruction input by a user;

a working mode determining module 120, configured to determine a current working mode according to the touch instruction received by the receiving module 110, where the working mode includes a direct spraying mode, a first disinfection spraying mode, and a second disinfection spraying mode;

a direct spraying module 130, configured to enter the direct spraying mode when the working mode determining module 120 determines that the current working mode is the direct spraying mode, start the ultrasonic transducer and the anion generator, drive water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic transducer, and directly spray and output atomized gas through a fan;

a first disinfection spraying module 130, configured to enter a first disinfection spraying mode when the working mode determining module 120 determines that the current working mode is the first disinfection spraying mode, start an ozone generator to generate ozone within a preset first time threshold while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, form ozone or mist-like gas of negative ions and output the gas in a spraying manner, stop generating ozone after the expiration of the preset first time threshold, and enter an individual spraying link;

a second disinfection spray module 140, configured to enter a second disinfection spray mode when the working mode determining module 120 determines that the current working mode is the second disinfection spray mode, and start an ozone generator while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, where the ozone generator may generate ozone within a preset working time threshold between the first time threshold and a preset second time threshold, so as to form an ozone or negative-ion mist gas and spray the gas, and the ozone generator stops generating ozone after the preset working time threshold, and enters an individual spray link; wherein the second time domain value is greater than the first time domain value.

In this embodiment, the receiving module 110 receives a touch control command input by a user; the working mode determining module 120 determines the current working mode according to the touch instruction received by the receiving module 110, if the current working mode is the direct spraying mode, the direct spraying module 130 is entered, if the current working mode is the first disinfection spraying mode, the first disinfection spraying module 140 is entered, and if the current working mode is the second disinfection spraying mode, the first disinfection spraying module 150 is entered, so that the spraying, the ozone generator and the negative ion generator can be effectively controlled to work alternately through the three working modes, and the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The ozone concentration is allowed, and simultaneously, viruses bred in small-sized closed or semi-closed environments of families, offices and the like can be effectively inhibited and eliminated.

Further, the touch control instruction is a touch control instruction of an on-off key, and then the current working mode is determined to be a direct spraying mode according to the touch control instruction of the on-off key, and the direct spraying mode is entered.

Further, the touch control command is an on-off key and nano disinfection key combined touch control command, the current working mode is determined to be a first disinfection spray mode according to the on-off key and nano disinfection key combined touch control command, and the first disinfection spray mode is entered.

Further, the touch control command is a combined touch control command of an on-off key, a nanometer disinfection key and a timing key, the current working mode is determined to be a second disinfection spraying mode according to the combined command of the on-off key, the nanometer disinfection key and the timing key, and the link of the second disinfection spraying mode is entered. .

Further, the preset first time threshold is 30 minutes, and the preset second time threshold is 120 minutes.

According to the control method and the control device of the superoxide atomization disinfection machine, provided by the embodiment of the invention, after a touch control instruction input by a user is received; determining a current working mode according to the touch instruction, entering the direct spraying mode if the current working mode is the direct spraying mode, and entering the first disinfection spraying mode if the current working mode is the first disinfection spraying mode; if the ozone generator is in the second disinfection spraying mode, the second disinfection spraying mode is entered, thus, the spraying, the ozone generator and the negative ion generator can be effectively controlled to alternately work through the three working modes, and the concentration of the discharged ozone is far lower than the standard 0.15mg/m³The ozone generator can effectively inhibit and eliminate viruses bred in small-sized closed or semi-closed environments such as families, offices and the like while allowing the concentration of ozone, and solves the defects that the humidifier products in the prior art have single functions and cannot inhibit and eliminate the viruses bred in the small-sized closed or semi-closed environments such as the families, the offices and the like.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A control method of a superoxide atomization sterilizer is characterized by comprising the following steps:

receiving a touch control instruction input by a user;

determining a current working mode according to the touch instruction, wherein the working mode comprises a direct spraying mode, a first disinfection spraying mode and a second disinfection spraying mode;

if the spray mode is the direct spray mode, the spray mode is entered, the ultrasonic wave energy conversion sheet and the negative ion generator are started, the high-frequency mechanical vibration generated by the ultrasonic wave energy conversion sheet drives the water to vibrate and atomize, and the atomized gas is directly sprayed and output through the fan;

if the water is in the first disinfection spraying mode, entering the first disinfection spraying mode, starting an ozone generator to generate ozone in a preset first time threshold while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, forming ozone or negative-ion vaporous gas and outputting the vaporous gas in a spraying manner, stopping generating the ozone after the expiration of the preset first time threshold by the ozone generator, and entering an independent spraying link;

if the water is in the second disinfection spraying mode, the water enters the second disinfection spraying mode, the ozone generator is started while the water is driven to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, the ozone generator can generate ozone within a preset working time threshold value between the first time threshold value and a preset second time threshold value to form ozone or negative-ion vaporous gas and spray and output the ozone, the ozone generator stops generating the ozone after the set working time threshold value, and the water enters an independent spraying link; wherein the second time domain value is greater than the first time domain value.

2. The method for controlling the superoxide atomizing sterilizer of claim 1,

and if the touch control instruction is a touch control instruction of an on-off key, determining that the current working mode is a direct spraying mode according to the touch control instruction of the on-off key, and entering a link of the direct spraying mode.

3. The method for controlling the superoxide atomizing sterilizer of claim 1,

and if the touch control command is an on-off key and nano disinfection key combined touch control command, determining that the current working mode is a first disinfection spraying mode according to the on-off key and nano disinfection key combined touch control command, and entering a first disinfection spraying mode link.

4. The method for controlling the superoxide atomizing sterilizer of claim 1,

and the touch control command is a combined touch control command of an on-off key, a nanometer disinfection key and a timing key, the current working mode is determined to be a second disinfection spraying mode according to the combined command of the on-off key, the nanometer disinfection key and the timing key, and the link of the second disinfection spraying mode is entered.

5. The method of claim 1, wherein the first predetermined time threshold is 30 minutes and the second predetermined time threshold is 120 minutes.

6. A control device of a superoxide atomization disinfection machine is characterized by comprising:

the receiving module is used for receiving a touch control instruction input by a user;

the working mode determining module is used for determining a current working mode according to the touch instruction received by the receiving module, wherein the working mode comprises a direct spraying mode, a first disinfection spraying mode and a second disinfection spraying mode;

the direct spraying module is used for entering the direct spraying mode when the working mode determining module determines that the current working mode is the direct spraying mode, starting the ultrasonic energy conversion sheet and the negative ion generator, driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, and directly spraying and outputting atomized gas through the fan;

the first disinfection spraying module is used for entering a first disinfection spraying mode when the working mode determining module determines that the current working mode is the first disinfection spraying mode, starting the ozone generator to generate ozone in a preset first time domain value while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, forming atomized gas of ozone or negative ions and outputting the atomized gas in a spraying manner, stopping generating the ozone after the expiration of the preset first time domain value by the ozone generator, and entering an independent spraying link;

the second disinfection spraying module is used for entering a second disinfection spraying mode when the working mode determining module determines that the current working mode is the second disinfection spraying mode, starting the ozone generator while driving water to vibrate and atomize through high-frequency mechanical vibration generated by the ultrasonic energy conversion sheet, wherein the ozone generator can generate ozone within a preset working time domain value between the first time domain value and a preset second time domain value to form ozone or mist gas of negative ions and spray and output the ozone, and the ozone generator stops generating the ozone after the set working time domain value and enters an independent spraying link; wherein the second time domain value is greater than the first time domain value.

7. The control device of the superoxide atomization sterilizer as claimed in claim 6,

and if the touch control instruction is a touch control instruction of an on-off key, determining that the current working mode is a direct spraying mode according to the touch control instruction of the on-off key, and entering a link of the direct spraying mode.

8. The control device of the superoxide atomization sterilizer as claimed in claim 6,

and if the touch control command is an on-off key and nano disinfection key combined touch control command, determining that the current working mode is a first disinfection spraying mode according to the on-off key and nano disinfection key combined touch control command, and entering a first disinfection spraying mode link.

9. The control device of the superoxide atomization sterilizer as claimed in claim 6,

and the touch control command is a combined touch control command of an on-off key, a nanometer disinfection key and a timing key, the current working mode is determined to be a second disinfection spraying mode according to the combined command of the on-off key, the nanometer disinfection key and the timing key, and the link of the second disinfection spraying mode is entered.

10. The control device for the superoxide atomizing sterilizer of claim 6, wherein the preset first time threshold is 30 minutes and the preset second time threshold is 120 minutes.

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