CN117553380B

CN117553380B - Multifunctional indoor air purification treatment control system

Info

Publication number: CN117553380B
Application number: CN202311848308.7A
Authority: CN
Inventors: 王轲; 郑琨; 蔡有杰; 沈芝榕
Original assignee: Qiqihar University
Current assignee: Qiqihar University
Priority date: 2023-12-29
Filing date: 2023-12-29
Publication date: 2024-04-09
Anticipated expiration: 2043-12-29
Also published as: CN117553380A

Abstract

The invention belongs to the technical field of air purification and treatment, and discloses a multifunctional indoor air purification treatment control system, which comprises the following components: the device comprises a processor shell, and an adjusting layer, a transition layer, a filtering and disinfecting layer, an air inlet detection layer and a mobile energy realizing layer which are arranged in the processor shell; the bottom of the movable energy realizing layer is provided with a driving steering unit; each layer is connected through a partition board, the partition board is provided with an air inlet, and the air outlet and the air inlet of the air inlet are provided with sensing detection units; the filter sterilizing layer is internally provided with a filter device and a sterilizing device, the transition layer is internally provided with an exhaust fan, and the regulating layer is provided with a temperature and humidity regulating device and a negative ion regulating device; a total control unit and a camera device are arranged outside the regulating layer; and the user terminal is in communication connection with the total control unit. The technical scheme of the invention can control the air temperature and humidity, can produce negative oxygen ions, is movable and can be remotely controlled by the user terminal.

Description

Multifunctional indoor air purification treatment control system

Technical Field

The invention belongs to the technical field of air purification and treatment, and particularly relates to a multifunctional indoor air purification treatment control system.

Background

With the promotion of industrialization, various pollution or natural or artificial pollution is inevitably generated in life. Such as various indoor household appliances, such as refrigerators, computers, televisions, etc., can produce toxic substances such as carbon tetrachloride, tetrachloroethylene, trichloroethylene, ethylbenzene, benzene, etc., which makes the pollution concentration of the closed indoor 5-10 times of the outdoor. The health care product is in a room with excessive pollutant concentration for a long time, is obviously unfavorable for the body of people, and can cause adverse phenomena such as cough, asthma, tiredness, headache, dizziness and the like. Moreover, with recent years of people's understanding of harmful viral hazards and routes of transmission, people are increasingly paying attention to household hygiene. These have led to a greater attention to the purification and treatment of air, satisfying the pursuit of healthy life itself.

The purification and treatment of air are related to more technologies, but the installation position is fixed, the movement function is not available, and the existing multifunctional requirements of air purification cannot be met.

Disclosure of Invention

The invention aims to provide a multifunctional indoor air purification treatment control system so as to solve the problems in the prior art.

In order to achieve the above object, the present invention provides a multifunctional indoor air purification treatment control system, comprising: the device comprises a processor shell, and an adjusting layer, a transition layer, a filtering and disinfecting layer, an air inlet detection layer and a mobile energy realizing layer which are arranged in the processor shell;

a plurality of partition boards are arranged in the processor shell, each partition board is fixedly connected with the processor shell at set intervals, so that a plurality of partition spaces are formed in the processor shell, and each partition space is sequentially used as an adjusting layer, a transition layer, a filtering and disinfecting layer, an air inlet detection layer and a mobile energy realizing layer from top to bottom in the processor shell;

the bottom of the movable energy realizing layer is provided with a driving steering unit;

the air inlet net is adopted by the side walls around the air inlet detection layer, and a first air inlet is formed in the middle of the partition plate between the air inlet detection layer and the filtering and sterilizing layer; an exhaust fan is arranged in the air inlet detection layer, and the exhaust fan is communicated with the first air inlet;

a second air inlet is formed in the middle of the partition plate between the transition layer and the filtering and sterilizing layer; a third air inlet is formed in the middle of the partition plate between the adjusting layer and the transition layer; sensing detection units are arranged at the air outlet and the air inlet of the first air inlet, the second air inlet and the third air inlet;

the filter sterilizing layer is internally provided with a filter device and a sterilizing device, the sterilizing device is arranged on the peripheral side wall in the filter sterilizing layer, and the filter device is arranged at the central position of the bottom partition plate of the filter sterilizing layer and is communicated with the first air inlet;

an exhaust fan is arranged at the center of the bottom partition plate of the transition layer, and the exhaust fan is communicated with the second air inlet;

a temperature and humidity adjusting device is arranged at the center of the bottom partition plate of the adjusting layer and is communicated with the third air inlet; negative ion adjusting devices are arranged in the side walls around the adjusting layer; a top air outlet is formed in the top of the adjusting layer, and a total control unit is arranged outside the side walls of the periphery of the adjusting layer; an image pickup device is arranged above the main control unit;

the camera device, the driving steering unit, the filtering device, the sterilizing device, the negative ion regulating device, the temperature and humidity regulating device and the sensing detection units are electrically connected with the main control unit;

and the user terminal is in communication connection with the total control unit.

Optionally, the total control unit comprises a data processing module, a humidification control module, a heating control module, a dehumidification control module, a filtration control module and a mobile control module;

each control module is connected with the data processing module; and each control module sends out a corresponding control signal to control the processor.

Optionally, the overall control unit further includes a communication module, and the data processing module is connected with the user terminal in a communication manner through the communication module.

Optionally, the communication module includes one or more of a LoRa module, a 2.5G communication module, a 3G communication module, a 4G communication module, and a 5G communication module.

Optionally, water tanks are further installed on two sides of the processor shell, and the installation height of each water tank is parallel to the installation height of the exhaust fan of the transition layer.

Optionally, the driving steering unit comprises a driving device and a steering device, and the driving device and the steering device are symmetrically arranged at two ends of the bottom of the movable layer.

Optionally, the driving device comprises a plurality of driving rollers which are sequentially arranged, and the steering device comprises a plurality of universal wheels which are sequentially arranged; the driving rollers and the universal wheels are symmetrically arranged in a one-to-one parallel mode.

Optionally, the sensing detection unit comprises a temperature sensor, a humidity sensor, a PM2.5 sensor and a valve core position sensor, and each sensor is electrically connected with the overall control unit.

Optionally, the air inlet net is provided with a plurality of air inlet holes.

Optionally, electric control baffles are installed above the first air inlet, the second air inlet and the third air inlet.

The invention has the technical effects that:

the multifunctional indoor air purification treatment control system provided by the invention can filter indoor air dust, can improve indoor air temperature, can reduce or improve indoor air humidity, can produce negative oxygen ions, can move to provide guarantee for the health of people aiming at specific space air, is additionally provided with network interconnection, can remotely control the start and stop of each functional module through a user terminal, can adjust the position of a processor through real-time images transmitted by a camera device by using a mobile phone, and is convenient for people to live.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

The accompanying drawings, which are included to provide a further understanding of the application, illustrate and explain the application and are not to be construed as limiting the application. In the drawings:

FIG. 1 is a schematic diagram of a front view of a multifunctional indoor air purifying processor according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the left-view internal structure of the multifunctional indoor air purifying processor according to the embodiment of the invention;

FIG. 3 is a system block diagram of the overall control system in an embodiment of the invention;

description of the reference numerals: the device comprises a 1-universal wheel, a 2-movable realization layer, a 3-air inlet hole, a 4-air inlet detection layer, a 5-first air inlet, a 6-filtration and disinfection layer, a 7-left water tank, an 8-transition layer, a 9-display screen, a 10-control switch, an 11-camera, a 12-right water tank, a 13-driving roller, a 14-first screw, a 15-filter cartridge, a 16-second air inlet, a 17-exhaust fan, a 18-second screw, a 19-third electric control baffle, a 20-heating wire, a 21-heat insulation pad, a 22-anion generator, a 23-top air outlet, a 24-fixed lamp buckle, a 25-ultraviolet lamp tube and a 26-lamp holder.

Detailed Description

In the following, a technical solution in the embodiments of the present invention will be clearly and completely described in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, but not all embodiments, based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts are within the scope of protection of the present invention.

In order that the invention may be readily understood, several embodiments of the invention will be described more fully hereinafter with reference to the accompanying drawings, in which, however, the invention may be embodied in many different forms and is not limited to the embodiments described herein, but instead is provided for the purpose of providing a more thorough and complete disclosure of the invention.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may also be present, and when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only;

as used herein, the terms "comprising," "including," "having," "containing," and the like are open ended terms, meaning including, but not limited to.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms used herein in this description of the invention are for the purpose of describing particular embodiments only and are not intended to be limiting of the invention, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Example 1

As shown in fig. 1 to 3, in this embodiment, there is provided a multifunctional indoor air purification process control system, including:

the device comprises a processor shell, and an adjusting layer, a transition layer 8, a filtration and disinfection layer 6, an air inlet detection layer 4 and a mobile energy realization layer 2 which are arranged in the processor shell;

a plurality of partition boards are arranged in the processor shell, each partition board is fixedly connected with the processor shell at set intervals, so that a plurality of partition spaces are formed in the processor shell, and each partition space is sequentially used as an adjusting layer, a transition layer 8, a filtration and disinfection layer 6, an air inlet detection layer 4 and a mobile energy realizing layer 2 from top to bottom in the processor shell;

the bottom of the movable energy realizing layer 2 is provided with a driving steering unit;

the side walls of the periphery of the air inlet detection layer 4 are all provided with air inlet nets, and a first air inlet is formed in the middle of a partition plate between the air inlet detection layer 4 and the filtering and sterilizing layer 6; an exhaust fan is arranged in the wind inlet detection layer 4 and communicated with the first air inlet;

a second air inlet is formed in the middle of the partition plate between the transition layer 8 and the filtering and sterilizing layer 6; a third air inlet is formed in the middle of the partition plate between the adjusting layer and the transition layer 8; sensing detection units are arranged at the air outlet and the air inlet of the first air inlet, the second air inlet and the third air inlet;

the inside of the filtering and sterilizing layer 6 is provided with a filtering device and a sterilizing device, the sterilizing device is arranged on the peripheral side wall in the filtering and sterilizing layer 6, and the filtering device is arranged at the central position of the bottom partition plate of the filtering and sterilizing layer 6 and is communicated with the first air inlet;

an exhaust fan is arranged at the central position of the bottom partition plate of the transition layer 8 and is communicated with the second air inlet;

according to the embodiment, indoor air dust can be filtered, indoor air temperature can be improved, indoor air humidity can be reduced or improved, negative oxygen ions can be produced, the negative oxygen ions can be moved to aim at specific space air, guarantee is provided for human health, network interconnection is added, starting and stopping of each functional module can be remotely controlled through a mobile phone, and the position of a processor can be adjusted through real-time images transmitted by a camera device by using the mobile phone, so that life of people is facilitated.

The box body is sequentially divided into a movable energy realizing layer 2, an air inlet detection layer 4, a filtration and disinfection layer 6 and an adjusting layer 8 from bottom to top.

The movement can realize that the layer 2 is arranged at the bottommost part, is provided with the idler wheels 13, the universal wheels 1 and the motor, and controls the processor to move by utilizing differential operation. The idler wheels are provided with two driving wheels and two universal wheels which are respectively and symmetrically distributed. The motor is a direct current miniature speed reducing motor. The universal wheel 1 and the exhaust fan 17 are fixed on the processor shell through screws;

the air inlet holes 3 of the air inlet detection layer 4 are uniformly distributed on the outer surface of the shell, and a temperature sensor, a humidity sensor and a PM2.5 detection sensor are arranged in the shell; an exhaust fan, a first air inlet 5 and a first electric control baffle are arranged between the air inlet detection layer and the filtering and sterilizing layer; an exhaust fan, a second air inlet and a second electric control baffle are arranged between the filtering and sterilizing layer and the adjusting layer;

the filtering and sterilizing layer 6 is provided with a filter cylinder 15, an exhaust fan 17, two ultraviolet lamp tubes 25 and a temperature and humidity sensor. The filter cartridge 15 comprises a filter core which is embedded in a filter cartridge 16, is an active carbon filter core, has a multi-layer fine filtering function, is positioned in the center of a bottom plate of the layer, and is provided with an opening at the bottom for air intake; the air supply unit comprises an exhaust fan 17 and a second air inlet 16; the sterilizing unit comprises an ultraviolet sterilizing lamp 25 and a shading and radiation protection housing. The ultraviolet disinfection lamp 25 is arranged on the lamp holder 26, and the upper end of the ultraviolet disinfection lamp 25 is fixed through the fixed lamp buckle 24; the exhaust fan 17 is an electronically commutated external rotor dc fan and is located on top of this layer. The ultraviolet lamp 25 is arranged at the ventilation channel outside the filter core and two opposite corners, so that the filter core can be disinfected and sterilized. The temperature and humidity sensor is used for detecting the temperature and humidity of the filtered air and is positioned at the position of entering the upper ventilation opening at the top of the layer. The shell is not provided with holes, so that the damage of ultraviolet rays to human bodies is avoided.

The adjusting layer 8 comprises a water tank 7, a negative ion generator 22, a humidifier, a heating wire 20, a compressor, a condenser, a third electric control baffle 1919, an air outlet 23, a display screen 9, a switch 10 and a camera 11. The heating unit comprises a heating wire 20 which is arranged at the center of the bottom plate at the bottom of the layer and is a round heating wire for heating the air for conveying and filtering. The negative ion generator 22 is composed of a high voltage generator, a negative electrode needle assembly, a fan and the like, is arranged on the inner surface of the shell, can eliminate smoke and dust, purify air, sterilize and purify formaldehyde, has a health care function after the negative oxygen ions are inhaled by a human body, has the action range of about 10 square meters, is divided into two parts, and can cover a whole room by utilizing the moving function of the embodiment. The humidification unit comprises an atomizer and a water tank 7, wherein the humidification module is a USB spray type humidification module and is matched with an atomization sheet for use, and the humidification unit is arranged on the water tank 7. The water tank 7 and the exhaust fan 17 of the transition layer are the same in height and are arranged on the outer side of the shell, so that water can be added or changed. The condensing unit includes a compressor and a condenser. The air outlet is positioned at the top of the processor and provides purified air for residents. The display screen 9 is a touch screen, is mounted on the outer shell, and is used for displaying detection values of the sensors. The camera 11 is arranged on the shell, the lens faces the outer side of the shell, and after the camera is started, the indoor position of the processor can be remotely determined in real time through a mobile phone, so that the processor can be conveniently remotely controlled to move. A control switch 10 is arranged on the outer shell and is used for controlling the start and stop of the purifying processor.

The control system of the processor is a closed-loop control system and comprises a controller, a driver, an actuator, a detection unit, a display screen, a control panel and a switch. The controller comprises a programmable controller; the driver comprises a motor driver; the actuator comprises an electric actuator; the detection unit comprises a temperature sensor, a humidity sensor, a PM2.5 sensor and a valve core position sensor and is used for acquiring parameters and inputting the parameters into the control system; the display screen includes a touch screen. The detection unit is positioned at the air outlet and the air inlet of each layer of ventilation channel; the display screen and the switch are positioned on the outer surface of the processor shell; the control system can control the start and stop of the motor and the rotating speed of the motor. The control system can control independent start-stop and independent movement of the functional layers of the humidifying unit, the condensing unit and the sterilizing unit; the control system can control the first air port fan and the second air port fan; the control system can control the first electric control baffle, the second electric control baffle fan and the third electric control baffle 19; the control system is provided with a filtering mode, a sterilizing mode, a heating mode, a humidity control mode and a negative oxygen mode; the modes set by the control system comprise single selection operation and simultaneous operation of multiple modes. The control system chip may be connected to the gateway. The control system can be remotely controlled through a mobile phone.

The embodiment provides an air processor and a total control system, which are a PLC control system, can operate a touch screen operation mode, and can be remotely connected with a system by utilizing a mobile phone APP to set the operation mode of the processor. And displaying parameters and output states on the touch screen/mobile phone. The processor and the control system thereof are also internally provided with a temperature sensor, a humidity sensor and a PM2.5 detection sensor. The acquisition parameters are input to a PLC control system, and the PLC control system controls a moving function, a sterilizing function, a filtering function, a heating function, a humidity control function and a video function, and specifically comprises an atomizer start/stop, a condenser start/stop, an ultraviolet lamp start/stop, a heating wire start/stop, a moving motor, a fan motor, a motor variable-frequency speed regulation and a camera start/stop. The signals of the camera are remotely projected onto the mobile phone through the network, so that a user can determine the position of the processor in real time, and mobile operation is facilitated.

When the warm and humid air processor and the total control system are specifically used,

1. the temperature, the humidity and the PM2.5 are the basis for the control of the PLC control system, and the loading and unloading of each functional part are carried out according to the parameter value set by the customer and the actually measured parameter value.

2. The PLC control system can set the required temperature, humidity and PM2.5. The touch screen/mobile phone displays the running speed, temperature, humidifying humidity atomizer, electric heating wire, ultraviolet lamp, condenser, atomizer and compressor working state of the fan under the current parameters,

3. and (3) electric heating: when the fed-back temperature is smaller than the set temperature, starting the electric heating wire assembly; and stopping heating when the fed-back temperature is higher than the set temperature.

4. Humidifying: and when the fed-back humidity is less than the set temperature, starting the electrospray humidifying component to increase the humidity. And when the fed-back humidity is greater than the set humidity, opening the condenser assembly to reduce the humidity.

5. Sterilizing: when PM2.5 is detected to be larger than a set value, an ultraviolet lamp is started to kill; when PM2.5 is detected to be smaller than a set value, the ultraviolet lamp is turned off;

6. remote mobile control: the mobile phone is remotely connected with the processor, the camera is started, and the position of the processor in a room is obtained in real time.

7. The PLC system can make mode selections based on the desired selections.

8. In the warm and humid air processor and the control system thereof, room air is sucked through the air inlet hole 3 by using the exhaust fan, and detected by the temperature sensor, the humidity sensor and the PM2.5 detection sensor which are arranged in the shell, the detected result is transmitted to the mobile phone/touch screen for display, and a user selects a proper mode.

In the case where the functions are fully turned off in the initial state, a specific implementation of each mode will be described:

the control system arrangement comprises: a filtering mode, a sterilizing mode, a heating mode, a humidity control mode and a negative oxygen mode; each mode can independently select operation and simultaneously operate in multiple modes;

(1) in the filtering mode, the exhaust fan A is started, air enters the processor, the first electric control baffle is moved away, the first air inlet is opened, the second air inlet is kept closed, the air enters the filter cylinder 15 of the filtering device, and after being filtered by the filter element, the air is discharged into a room through the top air outlet 23.

(2) In the disinfection mode, an air outlet fan of the top air outlet 23 is started, air enters the processor, the ultraviolet lamp is started, and the air disinfected by the ultraviolet lamp is discharged into a room through the top air outlet 23.

(3) In a heating mode, an exhaust fan A is started, a first electric control baffle is moved away, and air enters a processor; the first air inlet is opened, and air enters the filter cylinder 15 of the filtering device; the exhaust fan B is started, the second electric control baffle is moved away, and air enters the heating unit; the air outlet fan of the top air outlet 23 is started and air is discharged into the room through the top air outlet 23. The residence time of the air in the treatment is controlled by adjusting the rotating speed of the fan, and the heating efficiency of the air is controlled by adjusting and increasing the power of the heating wire.

(4) In the humidity control mode, an air outlet fan of the top air outlet 23 is started, and air enters the processor through the air inlet hole 3; because the first air inlet electric control baffle is in a closed state at this time, air flows upwards from the outer side of the filter cylinder 15 of the filter device through the ultraviolet lamp and enters the space where the humidity control function of the water tank 7 is located, and in one case, the humidity is lower than a set value, and when the humidity needs to be increased, the atomizer is started to increase the air humidity. In one case, when the humidity is higher than a set value and the humidity needs to be reduced, the condenser is started to reduce the air humidity. As the third electric control baffle 19 is closed, the treated air is discharged from the outer side of the heating wire 20 into the room through the top air outlet 23;

(5) in the negative oxygen mode, an air outlet fan of the top air outlet 23 is started, and air enters the processor through the air inlet hole 3; the first air inlet electric control baffle, the second air inlet electric control baffle and the third electric control baffle 19 are in a closed state at the moment, air flows from the outer side of the filter cylinder 15 of the filtering device to the upper layer, the negative ion regulating device starts to treat the air, and the treated air is discharged into a room through the top air outlet 23.

Obviously, the modes in the above 5 can be freely combined to meet different requirements of people.

A composite mode implementation. A combination of a filtering mode, a sanitizing mode, and a warming mode is selected.

Starting a first fan, moving a first electric control baffle, and enabling air to enter the processor; the first air inlet is opened, and air enters the filter cylinder 15; the first fan is closed, the second electric control baffle is closed, the second air inlet is closed, air is filtered by the filter element of the filter cartridge 15, reaches the outer side of the filter cartridge 15, and the ultraviolet lamp 25 is turned on to kill the air; the fan at the air outlet 23 is opened, the third electric control baffle 19 is opened, and the filtered and killed air enters the internal space of the heating wire 20 to heat; the filtered, sterilized and warmed air is discharged into the indoor space through the top air outlet 23.

The foregoing is merely a preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any changes or substitutions easily contemplated by those skilled in the art within the technical scope of the present application should be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. A multifunctional indoor air purification treatment control system, comprising:

the device comprises a processor shell, and an adjusting layer, a transition layer (8), a filtration and disinfection layer (6), an air inlet detection layer (4) and a mobile energy realization layer (2) which are arranged in the processor shell;

a plurality of partition boards are arranged in the processor shell, each partition board is fixedly connected with the processor shell at set intervals, so that a plurality of partition spaces are formed in the processor shell, and each partition space is sequentially used as an adjusting layer, a transition layer (8), a filtering and disinfecting layer (6), an air inlet detection layer (4) and a mobile energy realizing layer (2) from top to bottom in the processor shell;

the bottom of the movable energy realizing layer (2) is provided with a driving steering unit;

the air inlet net is adopted on the side walls around the air inlet detection layer (4), and a first air inlet is formed in the middle of a partition plate between the air inlet detection layer (4) and the filtering and sterilizing layer (6); an exhaust fan A is arranged in the air inlet detection layer (4), and the exhaust fan A is communicated with the first air inlet;

a second air inlet is formed in the middle of the partition plate between the transition layer (8) and the filtering and sterilizing layer (6); a third air inlet is formed in the middle of the partition plate between the adjusting layer and the transition layer (8); sensing detection units are arranged at the air outlet and the air inlet of the first air inlet, the second air inlet and the third air inlet;

a filtering device and a sterilizing device are arranged in the filtering and sterilizing layer (6), and the sterilizing device comprises two ultraviolet lamps which are diagonally arranged;

the disinfection device is arranged on the peripheral side wall in the filtration disinfection layer (6), and the filtration device is arranged at the central position of the bottom partition plate of the filtration disinfection layer (6) and is communicated with the first air inlet;

an exhaust fan B is arranged at the central position of the bottom partition plate of the transition layer (8), and the exhaust fan B is communicated with the second air inlet;

the regulating layer comprises a humidifying unit, and the humidifying unit comprises an atomizer and a water tank;

the adjusting layer comprises a heating unit, the heating unit comprises a heating wire (20), and the heating wire (20) is arranged in the center of the bottom plate of the adjusting layer; negative ion adjusting devices are arranged in the side walls around the adjusting layer; a top air outlet is formed in the top of the adjusting layer, and a total control unit is arranged outside the side walls of the periphery of the adjusting layer; an image pickup device is arranged above the main control unit;

the user terminal is in communication connection with the master control unit;

an electric control baffle is arranged above the first air inlet, the second air inlet and the third air inlet;

the control system is provided with a filtering mode, a sterilizing mode, a heating mode, a humidity control mode and a negative oxygen mode; each mode can independently select operation and simultaneously operate in multiple modes;

in the filtering mode, the exhaust fan A is started, air enters the processor, the first electric control baffle is moved away, the first air inlet is opened, the second air inlet is kept closed, the air enters a filter cylinder (15) of the filtering device, and after being filtered by the filter core, the air is discharged into a room through the top air outlet (23);

in the disinfection mode, an air outlet fan of a top air outlet (23) is started, air enters the processor, an ultraviolet lamp is started, and the air disinfected by the ultraviolet lamp is discharged into a room through the top air outlet (23);

in a heating mode, an exhaust fan A is started, a first electric control baffle is moved away, and air enters a processor; the first air inlet is opened, and air enters a filter cylinder (15) of the filtering device; the exhaust fan B is started, the second electric control baffle is moved away, and air enters the heating unit; an air outlet fan of the top air outlet (23) is started, and air is discharged into a room through the top air outlet (23);

in the humidity control mode, an air outlet fan of the top air outlet (23) is started, and air enters the processor through the air inlet hole (3); because the first air inlet electric control baffle is in a closed state at the moment, air flows upwards from the outer side of a filter cylinder (15) of the filtering device through an ultraviolet lamp and enters a space where a humidity control function of the water tank (7) is located, and because the third electric control baffle (19) is closed, the treated air is discharged indoors through a top air outlet (23) from the outer side of a heating wire (20);

in the negative oxygen mode, an air outlet fan of the top air outlet (23) is started, and air enters the processor through the air inlet hole (3); the first air inlet electric control baffle, the second air inlet electric control baffle and the third electric control baffle (19) are in a closed state at the moment, air flows upwards from the outer side of a filter cylinder (15) of the filtering device, the negative ion regulating device is started to treat the air, and the treated air is discharged into a room through the top air outlet (23).

2. The system of claim 1, wherein the overall control unit comprises a data processing module, a humidification control module, a heating control module, a dehumidification control module, a filtration control module, and a movement control module;

3. The multifunctional indoor air purification treatment control system according to claim 2, wherein the overall control unit further comprises a communication module, and the data processing module is communicatively connected to the user terminal through the communication module.

4. A multifunctional indoor air purification treatment control system according to claim 3, wherein the communication module comprises one or more of a LoRa module, a 2.5G communication module, a 3G communication module, a 4G communication module, and a 5G communication module.

5. A multifunctional indoor air purification treatment control system according to claim 1, characterized in that the two sides of the processor housing are also provided with water tanks, the installation height of each water tank being parallel to the installation height of the suction fan of the transition layer (8).

6. The multifunctional indoor air purification treatment control system according to claim 1, wherein the driving and steering unit comprises a driving device and a steering device, and the driving device and the steering device are symmetrically arranged at two ends of the bottom of the mobile energy realizing layer (2).

7. A multifunctional indoor air purification treatment control system according to claim 6, characterized in that said driving means comprises a number of driving rollers (13) arranged in sequence, said steering means comprises a number of universal wheels (1) arranged in sequence; the driving rollers (13) and the universal wheels (1) are symmetrically arranged in a one-to-one parallel mode.

8. The system of claim 1, wherein the sensing unit comprises a temperature sensor, a humidity sensor, a PM2.5 sensor, and a spool position sensor, each electrically connected to the overall control unit.

9. The multifunctional indoor air purification treatment control system according to claim 1, wherein the air inlet net is provided with a plurality of air inlet holes (3).