CN111271827A - Indoor air purification control method, device and system and mobile terminal - Google Patents

Abstract

The invention discloses an indoor air purification control method, device and system and a mobile terminal, wherein the method comprises the following steps: establishing a communication connection with a remote air purification device; receiving a mode selection signal from a user; analyzing the mode selection signal, and judging whether the mode selection signal is a disinfection mode selection signal; if the mode selection signal is a disinfection mode selection signal, generating unmanned prompt information according to the disinfection mode selection signal and pushing and displaying the unmanned prompt information; detecting whether unmanned confirmation information input by a user is received or not; if the unmanned confirmation information is received, generating a disinfection control signal and sending the disinfection control signal to a remote air purification device; whether a living body exists in the space to be detected is confirmed with the user again before the disinfection mode is executed, and the disinfection mode is started again under the condition that no living body exists, so that the safety of personnel and animals is ensured.

Description

Indoor air purification control method, device and system and mobile terminal

Technical Field

The invention relates to the field of air purification control, in particular to an indoor air purification control method, device and system and a mobile terminal.

Background

Indoor air purification products on the market at present are generally divided into two types, one type is to filter particulate matters in air by adopting a filtering mode; the other is to generate ozone and negative ions to purify air. A lot of current air purification devices possess the disinfection function, but the gaseous disinfection probably causes certain injury to the human body, and the security is poor.

Disclosure of Invention

The invention provides an indoor air purification control method, device and system and a mobile terminal, and aims to solve the problem that an existing ozone and negative ion purification device is poor in safety.

An indoor air purification control method, comprising:

establishing a communication connection with a remote air purification device;

receiving a mode selection signal from a user;

analyzing the mode selection signal, and judging whether the mode selection signal is a disinfection mode selection signal;

if the mode selection signal is a disinfection mode selection signal, generating unmanned prompt information according to the disinfection mode selection signal and pushing and displaying the unmanned prompt information;

detecting whether unmanned confirmation information input by a user is received or not;

and if the unmanned confirmation information is received, generating a disinfection control signal and sending the disinfection control signal to a remote air purification device.

Further, the mode selection signal comprises a first mode selection signal, a second mode selection signal, a third mode selection signal, a fourth mode selection signal and a sleep mode selection signal;

if the mode selection signal is a first mode selection signal, generating a first mode control signal according to the first mode selection signal and sending the first mode control signal to a remote air purification device;

if the mode selection signal is a second mode selection signal, generating a second mode control signal according to the second mode selection signal and sending the second mode control signal to a remote air purification device;

if the mode selection signal is a third mode selection signal, generating a third mode control signal according to the third mode selection signal and sending the third mode control signal to a remote air purification device;

if the mode selection signal is a fourth mode selection signal, generating a fourth mode control signal according to the fourth mode selection signal and sending the fourth mode control signal to a remote air purification device;

and if the mode selection signal is a sleep mode selection signal, generating a sleep mode control signal according to the sleep mode selection signal and sending the sleep mode control signal to a remote air purification device.

An indoor air purification control device comprising:

the communication module is used for establishing communication connection with the remote air purification device;

the signal receiving module is used for receiving a mode selection signal from a user;

the analysis module is used for analyzing the mode selection signal and judging whether the mode selection signal is a disinfection mode selection signal;

the prompting module is used for generating unmanned prompting information according to the disinfection mode selection signal and pushing and displaying the unmanned prompting information when the mode selection signal is the disinfection mode selection signal;

the confirmation module is used for detecting whether unmanned confirmation information input by a user is received or not;

and the sending module is used for generating a disinfection control signal and sending the disinfection control signal to the remote air purification device when the unmanned confirmation information is received.

A mobile terminal comprises a processor and a storage device, wherein the processor is connected with the storage device, the storage device stores a plurality of instructions, and the processor is used for reading the instructions and executing the indoor air purification control method.

An indoor air purification control system comprises the mobile terminal and an air purification device;

the air purification device is used for receiving the disinfection control signal and executing disinfection operation according to the disinfection control signal.

Further, the air purification device comprises a wireless communication module, a controller, a frequency conversion module and an ozone generation device, wherein the controller is connected with the frequency conversion module and the wireless communication module, and the frequency conversion module is connected with the ozone generation device;

the wireless communication module is used for receiving the disinfection control signal and sending the disinfection control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the ozone generation device to release ozone according to the disinfection control signal and stops after the disinfection control signal lasts for a first preset time.

Further, the air purification device further comprises a negative ion generation device, and the negative ion generation device is connected with the controller;

the wireless communication module is also used for receiving a first mode control signal sent by the mobile terminal and sending the first mode control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the ozone generation device to release ozone according to the first mode control signal and stop the ozone generation device after the ozone generation device continues for a second preset time, then driving the anion generation device to release anions for a third preset time, and circulating the anions after a fourth preset time interval; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the first mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a second preset time and then stops, the negative ion generating device releases negative ions and continues for a third preset time and then stops, and circulation is carried out after a fourth preset time is respectively spaced.

Further, the wireless communication module is further configured to receive a second mode control signal sent by the mobile terminal and send the second mode control signal to the controller, and the controller is configured to control the frequency conversion module to drive the ozone generating device to release ozone according to the second mode control signal and stop after the ozone generating device continues for a fifth preset time, then drive the negative ion generating device to release negative ions and continue for a sixth preset time, and circulate after a seventh preset time interval; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the second mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a fifth preset time and stops, the negative ion generating device releases negative ions and continues for a sixth preset time and stops, and circulation is carried out after the interval of the seventh preset time.

Further, the wireless communication module is further configured to receive a third mode control signal sent by the mobile terminal and send the third mode control signal to the controller, and the controller is configured to control the frequency conversion module to drive the ozone generating device to release ozone according to the third mode control signal and stop after the ozone generating device continues for an eighth preset time, then drive the negative ion generating device to release negative ions and continue for a ninth preset time, and circulate after a tenth preset time interval; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the third mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for the eighth preset time, the negative ion generating device releases negative ions and stops for the ninth preset time, and circulation is carried out after the tenth preset time is respectively spaced.

Further, the wireless communication module is further configured to receive a fourth mode control signal sent by the mobile terminal and send the fourth mode control signal to the controller, and the controller is configured to control the frequency conversion module to drive the ozone generating device to release ozone according to the fourth mode control signal and stop the ozone generating device after the ozone generating device continues for an eleventh preset time, then drive the negative ion generating device to release negative ions and continue for a twelfth preset time, and circulate after a thirteenth preset time interval; alternatively, the first and second electrodes may be,

the controller is used for controlling the frequency conversion module to drive the ozone generating device and the negative ion generating device to work simultaneously initially according to the fourth mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions at the same time, the ozone generating device releases ozone for an eleventh preset time and stops, the negative ion generating device releases negative ions for a twelfth preset time and stops, and circulation is performed after a thirteenth preset time interval;

the wireless communication module is further used for receiving a sleep mode control signal sent by the mobile terminal and sending the sleep mode control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the negative ion generating device to release negative ions according to the sleep mode control signal and stop after the negative ions continue for a fourteenth preset time.

The indoor air purification control method, the indoor air purification control device, the indoor air purification control system and the mobile terminal at least have the following beneficial effects:

(1) before the disinfection mode is executed, whether a living body exists in the space to be detected is confirmed with the user again, and the disinfection mode is started again under the condition that no living body exists, so that the safety of personnel and animals is ensured;

(2) the ozone generating device or the negative ion generating device can be controlled to work according to a preset mode according to a remote control signal, multiple modes can be selected, resources are saved to a certain extent, the ozone generating device or the negative ion generating device can be suitable for different scenes, and the ozone generating device or the negative ion generating device is high in applicability and good in purification effect; and can carry out remote operation, the convenience is high.

Drawings

Fig. 1 is a flowchart illustrating an indoor air purification control method according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of an embodiment of an indoor air purification control apparatus provided by the present invention.

Fig. 3 is a schematic structural diagram of an embodiment of a mobile terminal provided in the present invention.

Fig. 4 is a schematic structural diagram of an embodiment of an indoor air purification control system according to the present invention.

Detailed description of the preferred embodiments

In order to better understand the technical solution, the technical solution will be described in detail with reference to the drawings and the specific embodiments.

Example one

Referring to fig. 1, the present embodiment provides an indoor air purification control method, including:

step S101, establishing communication connection with a remote air purification device;

step S102, receiving a mode selection signal from a user;

step S103, analyzing the mode selection signal, and judging whether the mode selection signal is a disinfection mode selection signal;

step S104, if the mode selection signal is a disinfection mode selection signal, generating unmanned prompt information according to the disinfection mode selection signal and pushing and displaying the unmanned prompt information;

step S105, detecting whether unmanned confirmation information input by a user is received;

and step S106, if the unmanned confirmation information is received, generating a disinfection control signal and sending the disinfection control signal to a remote air purification device.

Specifically, step S101 is executed to establish a communication connection with a remote air purification device, specifically, a communication connection with a remote air purification device can be established through Wi-Fi or bluetooth.

Further, step S102 is executed to receive a mode selection signal from the user, and as a preferred embodiment, the user may send the mode selection signal by clicking the relevant icon.

Further, step S103 is executed to receive a mode selection signal from the user and analyze the mode selection signal.

The mode selection signal may be one of a sterilization mode selection signal, a first mode selection signal, a second mode selection signal, a third mode selection signal, a fourth mode selection signal, and a sleep mode selection signal.

And if the mode selection signal is a first mode selection signal, generating a first mode control signal according to the first mode selection signal and sending the first mode control signal to the remote air purification device, wherein the first mode control signal is used for controlling the remote air purification device to work in a first mode.

And if the mode selection signal is a second mode selection signal, generating a second mode control signal according to the second mode selection signal and sending the second mode control signal to the remote air purification device, wherein the second mode control signal is used for controlling the remote air purification device to work in a second mode.

And if the mode selection signal is a third mode selection signal, generating a third mode control signal according to the third mode selection signal and sending the third mode control signal to the remote air purification device, wherein the third mode control signal is used for controlling the remote air purification device to work in a third mode.

And if the mode selection signal is a fourth mode selection signal, generating a fourth mode control signal according to the fourth mode selection signal and sending the fourth mode control signal to the remote air purification device, wherein the fourth mode control signal is used for controlling the remote air purification device to work in a fourth mode.

And if the mode selection signal is a sleep mode selection signal, generating a sleep mode control signal according to the sleep mode selection signal and sending the sleep mode control signal to the remote air purification device, wherein the sleep mode control signal is used for controlling the remote air purification device to work in a sleep mode.

Further, step S104 is executed, if the mode selection signal is a disinfection mode selection signal, generating an unattended prompt message according to the disinfection mode selection signal, and pushing and displaying the unattended prompt message.

Specifically, the unmanned prompt message may be a dialog box, a corresponding determination icon is arranged on the dialog box, and after the user determines that the room to be disinfected has no living bodies (including people and animals), the user clicks the determination icon to send the unmanned confirmation message.

Further, step S105 and step S106 are executed, whether unmanned confirmation information input by the user is received is detected, and if the unmanned confirmation information is received, a disinfection control signal for controlling the remote air purification device to work in a disinfection mode is generated and sent to the remote air purification device.

In a preferred embodiment, in the disinfection mode, the air purification device releases ozone and stops after a first preset time.

Wherein the first preset time period is preferably 60 minutes, and the ozone releasing rate is 200 mg/h.

Under the disinfection mode, ozone concentration is higher, before opening the disinfection mode, confirms again with the user whether have the live body in the space of treating the disinfection, confirms after not having the live body, opens the disinfection mode again, ensures safety.

The indoor air purification control method provided by the embodiment confirms whether a living body exists in the space to be detected with the user again before executing the disinfection mode, and starts the disinfection mode again under the condition of confirming no living body, so that the safety of personnel and animals is ensured.

Example two

Referring to fig. 2, the present embodiment provides an indoor air purification control apparatus, including:

a communication module 201 for establishing a communication connection with a remote air purification device;

a signal receiving module 202, configured to receive a mode selection signal from a user;

the analysis module 203 is used for analyzing the mode selection signal and judging whether the mode selection signal is a disinfection mode selection signal;

the prompt module 204 is configured to generate an unmanned prompt message according to the disinfection mode selection signal and push the unmanned prompt message for display when the mode selection signal is the disinfection mode selection signal;

a confirmation module 205, configured to detect whether unmanned confirmation information input by a user is received;

a sending module 206, configured to generate a disinfection control signal and send the disinfection control signal to the remote air purification apparatus when the unmanned confirmation information is received.

Specifically, the communication module 201 may be a Wi-Fi module or a bluetooth module.

The analysis module 203 analyzes the mode selection signal, which may be one of a disinfection mode selection signal, a first mode selection signal, a second mode selection signal, a third mode selection signal, a fourth mode selection signal, and a sleep mode selection signal.

The prompt module 204 may generate the unmanned prompt message as a dialog box, the dialog box is provided with a corresponding determination icon, and after the user determines that the room to be disinfected has no living bodies (including people and animals), the user clicks the determination icon to send the unmanned confirmation message.

The indoor air purification control device that this embodiment provided confirms again with the user before carrying out the disinfection mode whether to have the live body in waiting to detect the space, confirms to open the disinfection mode again under the condition of no live body, guarantees personnel and animal's safety.

EXAMPLE III

Referring to fig. 3, the present embodiment provides a mobile terminal, which includes a processor 301 and a storage device 302, wherein the processor 301 is connected to the storage device 302, the storage device 302 stores a plurality of instructions, and the processor 301 is configured to read the instructions and execute the indoor air purification control method.

Specifically, the mobile terminal described in this embodiment may be a mobile phone, a tablet computer, and the like.

Example four

Referring to fig. 4, the present embodiment provides an indoor air purification control system, including a mobile terminal 401 according to the third embodiment, and further including an air purification device 402;

the air cleaning device 402 is used for receiving the disinfection control signal and executing disinfection operation according to the disinfection control signal.

Further, the air purification device 402 comprises a wireless communication module 4021, a controller 4022, a frequency conversion module 4023 and an ozone generation device 4024, the controller 4022 is connected with the frequency conversion module 4023 and the wireless communication module 4021, and the frequency conversion module 4023 is connected with the ozone generation device 4024;

the wireless communication module 4021 is configured to receive the disinfection control signal and send the disinfection control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the ozone generator 4024 to release ozone according to the disinfection control signal, and stop after the first preset duration.

In the disinfection mode, the ozone generator 4024 releases ozone at a rate of 200mg/h, and the first preset time period is preferably 60 minutes.

Further, the air purification device in this embodiment further includes a negative ion generator 4025, and the negative ion generator 4025 is connected to the controller 4022;

the wireless communication module 4021 is further configured to receive a first mode control signal sent by the mobile terminal and send the first mode control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the ozone generation device 4024 to release ozone according to the first mode control signal and stop the ozone after the ozone generation device lasts for a second preset duration, then drive the negative ion generation device 4025 to release negative ions and continue for a third preset duration, and circulate after a fourth preset duration is separated; alternatively, the first and second electrodes may be,

the ozone generating device and the negative ion generating device work simultaneously initially, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a second preset time and then stops, the negative ion generating device releases negative ions and continues for a third preset time and then stops, and circulation is carried out after a fourth preset time is respectively spaced.

In a preferred embodiment, the second predetermined period is 20 minutes, the third predetermined period is 60 minutes, and the fourth predetermined period is 240 minutes.

In the first preset mode, the ozone generating device stops after releasing ozone for 20 minutes, the negative ion generating device immediately releases negative ions for 60 minutes, and then circulation is performed after 240 minutes, so that the ozone generating device and the negative ion generating device work separately, the circulation time is prolonged, and the service life of each part can be effectively prolonged. In addition, the ozone generating device and the negative ion generating device can work simultaneously initially, the ozone generating device releases ozone for 20 minutes and then stops, the ozone generating device circulates after 240 minutes, the negative ion generating device releases negative ions for 60 minutes and then circulates after 240 minutes, and the mode that the ozone generating device and the negative ion generating device work simultaneously initially is adopted, so that the circulation time is shorter, and the purification effect is better. The first preset mode can be configured according to actual requirements.

In the first mode, the ozone generating device releases ozone at a rate of 50mg/h, and the negative ion generating device releases negative ions at a release rate of 800 ten thousand/cm³The frequency conversion module can be controlled to control the ozone generating device and the negative ion generating device to be turned on and off, and the rate of ozone released by the ozone generating device and the release amount of negative ions released by the negative ion generating device.

The first mode is suitable for the space with the area smaller than 10 square meters, and the first mode is adopted for the space smaller than 10 square meters, so that the energy is saved, and meanwhile, a better purification effect is achieved.

Further, the wireless communication module 4021 is further configured to receive a second mode control signal sent by the mobile terminal and send the second mode control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the ozone generating device 4024 to release ozone according to the second mode control signal and stop the ozone for a fifth preset time, and then drive the negative ion generating device 4025 to release negative ions for a sixth preset time, and circulate after a seventh preset time interval; alternatively, the first and second electrodes may be,

the ozone generating device and the negative ion generating device work simultaneously initially, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a fifth preset time and then stops, the negative ion generating device releases negative ions and continues for a sixth preset time and then stops, and circulation is carried out after the interval of the seventh preset time.

In a preferred embodiment, the fifth preset time period is 30 minutes, the sixth preset time period is 60 minutes, and the seventh preset time period is 180 minutes.

In the second preset mode, the ozone generating device stops after releasing ozone for 30 minutes, the negative ion generating device immediately releases negative ions for 60 minutes, and then circulation is carried out after 180 minutes, so that the ozone generating device and the negative ion generating device work separately, the circulation time is prolonged, and the service life of each part can be effectively prolonged. In addition, the ozone generating device and the negative ion generating device can work simultaneously initially, the ozone generating device releases ozone for 30 minutes and then stops, the ozone generating device circulates after 180 minutes, the negative ion generating device releases negative ions for 60 minutes and then circulates after 180 minutes, and the mode that the ozone generating device and the negative ion generating device work simultaneously initially is adopted, so that the circulation time is shorter, and the purification effect is better. The second preset mode can be configured according to actual requirements.

In the second mode, the ozone generating device releases ozone at a rate of 80mg/h, and the negative ion generating device releases negative ions at a release rate of 800 ten thousand/cm³The frequency conversion module can be controlled to control the ozone generating device and the negative ion generating device to be turned on and off, and the rate of ozone released by the ozone generating device and the release amount of negative ions released by the negative ion generating device.

The second mode is suitable for the space with the area more than or equal to 10 square meters and less than 20 square meters, and the second mode is adopted for the space within the range, so that the energy is saved, and meanwhile, a better purification effect is achieved.

Further, the wireless communication module 4021 is further configured to receive a third mode control signal sent by the mobile terminal and send the third mode control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the ozone generating device 4024 to release ozone according to the third mode control signal and stop the ozone for an eighth preset time, and then drive the negative ion generating device 4025 to release negative ions for a ninth preset time, and circulate after a tenth preset time interval; alternatively, the first and second electrodes may be,

the ozone generating device and the negative ion generating device work simultaneously initially, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for the eighth preset time and then stops, the negative ion generating device releases negative ions and continues for the ninth preset time and then stops, and circulation is carried out after the tenth preset time is respectively spaced.

In a preferred embodiment, the eighth preset time period is 60 minutes, the ninth preset time period is 60 minutes, and the tenth preset time period is 120 minutes.

In the third preset mode, the ozone generating device stops after releasing ozone for 60 minutes, the negative ion generating device immediately releases negative ions for 60 minutes, and then circulation is carried out after 120 minutes, so that the ozone generating device and the negative ion generating device work separately, the circulation time is prolonged, and the service life of each part can be effectively prolonged. In addition, the ozone generating device and the negative ion generating device can work simultaneously initially, the ozone generating device stops after releasing ozone for 60 minutes, the ozone generating device circulates after 120 minutes, the negative ion generating device releases negative ions for 60 minutes and then circulates after 120 minutes, and the mode that the ozone generating device and the negative ion generating device work simultaneously initially is adopted, so that the circulation time is shorter, and the purification effect is better. The third preset mode can be configured according to actual requirements.

In the third mode, the ozone generating device releases ozone at a rate of 100mg/h, and the negative ion generating device releases negative ions at a release rate of 800 ten thousand/cm³The frequency conversion module can be controlled to control the ozone generating device and the negative ion generating device to be turned on and off, and the rate of ozone released by the ozone generating device and the release amount of negative ions released by the negative ion generating device.

The third mode is suitable for the space with the area more than or equal to 20 square meters and less than 30 square meters, and the third mode is adopted for the space within the range, so that the energy is saved, and meanwhile, a better purification effect is achieved.

Further, the wireless communication module 4021 is further configured to receive a fourth mode control signal sent by the mobile terminal and send the fourth mode control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the ozone generating device 4024 to release ozone for an eleventh preset time period and then stop the ozone for the eleventh preset time period, and then drive the negative ion generating device 40 to release negative ions for a twelfth preset time period and circulate after a thirteenth preset time period; alternatively, the first and second electrodes may be,

the ozone generating device and the negative ion generating device work simultaneously initially, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for the eleventh preset time and stops, the negative ion generating device releases negative ions for the twelfth preset time and stops, and circulation is carried out after the thirteenth preset time is respectively spaced.

In a preferred embodiment, the eleventh preset time period is 20 minutes, the twelfth preset time period is 20 minutes, and the thirteenth preset time period is 60 minutes.

In the fourth preset mode, the ozone generating device stops after releasing ozone for 20 minutes, the negative ion generating device immediately releases negative ions for 20 minutes, and then circulation is carried out after 60 minutes, so that the ozone generating device and the negative ion generating device work separately, the circulation time is prolonged, and the service life of each part can be effectively prolonged. In addition, the ozone generating device and the negative ion generating device can work simultaneously initially, the ozone generating device stops after releasing ozone for 20 minutes, the ozone generating device circulates after 60 minutes, the negative ion generating device releases negative ions for 20 minutes and then circulates after 60 minutes, and the mode that the ozone generating device and the negative ion generating device work simultaneously initially is adopted, so that the circulation time is shorter, and the purification effect is better. The fourth preset mode can be configured according to actual requirements.

In the fourth mode, the ozone generating device releases ozone at a rate of 80mg/h, and the negative ion generating device releases negative ions at a release rate of 800 ten thousand/cm³The frequency conversion module can be controlled to control the ozone generating device and the negative ion generating device to be turned on and off, and the rate of ozone released by the ozone generating device and the release amount of negative ions released by the negative ion generating device.

The fourth mode is applicable to smoking rooms, pet houses, toilets and the like, and under the application scene, the floating dust and bacteria in the air are more, so that the ozone generating device and the negative ion generating device work alternately, the interval time is short, and a large amount of floating dust and bacteria in the air can be effectively purified.

Further, the wireless communication module 4021 is further configured to receive a sleep mode control signal sent by the mobile terminal and send the sleep mode control signal to the controller 4022, and the controller 4022 is configured to control the frequency conversion module 4023 to drive the negative ion generating device to release negative ions according to the sleep mode control signal and stop after a fourteenth preset time duration.

In the sleep mode, only the negative ion generating device is operated, and as a preferred embodiment, the fourteenth preset time period is 12 hours, that is, the negative ion generating device is stopped after continuously operating for 12 hours. The sustained-release negative ions can play the roles of calming and relaxing emotion, and are helpful for improving the sleep quality of the user. The release amount of the negative ions released by the negative ion generating device is 800 ten thousand/cm³The opening and closing of the negative ion generating device and the releasing amount of negative ions released by the negative ion generating device can be controlled by controlling the frequency conversion module.

The indoor air purification control system provided by the embodiment can control the ozone generating device or the negative ion generating device to work according to a preset mode according to a remote control signal, multiple modes can be selected, resources are saved to a certain extent, the indoor air purification control system is suitable for different scenes, and is high in applicability and good in purification effect; and can carry out remote operation, the convenience is high.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the invention. It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. An indoor air purification control method, characterized by comprising:

establishing a communication connection with a remote air purification device;

receiving a mode selection signal from a user;

analyzing the mode selection signal, and judging whether the mode selection signal is a disinfection mode selection signal;

if the mode selection signal is a disinfection mode selection signal, generating unmanned prompt information according to the disinfection mode selection signal and pushing and displaying the unmanned prompt information;

detecting whether unmanned confirmation information input by a user is received or not;

and if the unmanned confirmation information is received, generating a disinfection control signal and sending the disinfection control signal to a remote air purification device.

2. The indoor air purification control method according to claim 1, wherein the mode selection signal further includes a first mode selection signal, a second mode selection signal, a third mode selection signal, a fourth mode selection signal, and a sleep mode selection signal;

if the mode selection signal is a first mode selection signal, generating a first mode control signal according to the first mode selection signal and sending the first mode control signal to a remote air purification device;

if the mode selection signal is a second mode selection signal, generating a second mode control signal according to the second mode selection signal and sending the second mode control signal to a remote air purification device;

if the mode selection signal is a third mode selection signal, generating a third mode control signal according to the third mode selection signal and sending the third mode control signal to a remote air purification device;

if the mode selection signal is a fourth mode selection signal, generating a fourth mode control signal according to the fourth mode selection signal and sending the fourth mode control signal to a remote air purification device;

and if the mode selection signal is a sleep mode selection signal, generating a sleep mode control signal according to the sleep mode selection signal and sending the sleep mode control signal to a remote air purification device.

3. An indoor air purification control device, comprising:

the communication module is used for establishing communication connection with the remote air purification device;

the signal receiving module is used for receiving a mode selection signal from a user;

the analysis module is used for analyzing the mode selection signal and judging whether the mode selection signal is a disinfection mode selection signal;

the prompting module is used for generating unmanned prompting information according to the disinfection mode selection signal and pushing and displaying the unmanned prompting information when the mode selection signal is the disinfection mode selection signal;

the confirmation module is used for detecting whether unmanned confirmation information input by a user is received or not;

and the sending module is used for generating a disinfection control signal and sending the disinfection control signal to the remote air purification device when the unmanned confirmation information is received.

4. A mobile terminal, comprising a processor and a storage device, wherein the processor is connected to the storage device, the storage device stores a plurality of instructions, and the processor is configured to read the instructions and execute the indoor air purification control method according to claim 1 or 2.

5. An indoor air purification control system comprising the mobile terminal according to claim 4, further comprising an air purification device;

the air purification device is used for receiving the disinfection control signal and executing disinfection operation according to the disinfection control signal.

6. The indoor air purification control system according to claim 5, wherein the air purification device comprises a wireless communication module, a controller, a frequency conversion module and an ozone generation device, the controller is connected with the frequency conversion module and the wireless communication module, and the frequency conversion module is connected with the ozone generation device;

the wireless communication module is used for receiving the disinfection control signal and sending the disinfection control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the ozone generation device to release ozone according to the disinfection control signal and stops after the disinfection control signal lasts for a first preset time.

7. An indoor air purification control system according to claim 6, wherein the air purification apparatus further comprises a negative ion generation apparatus, the negative ion generation apparatus being connected to the controller;

the wireless communication module is also used for receiving a first mode control signal sent by the mobile terminal and sending the first mode control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the ozone generation device to release ozone according to the first mode control signal and stop the ozone generation device after the ozone generation device continues for a second preset time, then driving the anion generation device to release anions for a third preset time, and circulating the anions after a fourth preset time interval; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the first mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a second preset time and then stops, the negative ion generating device releases negative ions and continues for a third preset time and then stops, and circulation is carried out after a fourth preset time is respectively spaced.

8. The indoor air purification control system according to claim 6, wherein the wireless communication module is further configured to receive a second mode control signal sent by the mobile terminal and send the second mode control signal to the controller, and the controller is configured to control the frequency conversion module according to the second mode control signal to drive the ozone generation device to release ozone for a fifth preset duration and then stop, drive the anion generation device to release anions for a sixth preset duration, and circulate after a seventh preset duration; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the second mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for a fifth preset time and stops, the negative ion generating device releases negative ions and continues for a sixth preset time and stops, and circulation is carried out after the interval of the seventh preset time.

9. The indoor air purification control system according to claim 6, wherein the wireless communication module is further configured to receive a third mode control signal sent by the mobile terminal and send the third mode control signal to the controller, and the controller is configured to control the frequency conversion module according to the third mode control signal to drive the ozone generation device to release ozone and stop after an eighth preset time, then drive the anion generation device to release anions and continue for a ninth preset time, and circulate after an interval of a tenth preset time; alternatively, the first and second electrodes may be,

the controller is used for driving the ozone generating device and the negative ion generating device to work simultaneously initially according to the third mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions simultaneously, the ozone generating device releases ozone for the eighth preset time, the negative ion generating device releases negative ions and stops for the ninth preset time, and circulation is carried out after the tenth preset time is respectively spaced.

10. The indoor air purification control system according to claim 6, wherein the wireless communication module is further configured to receive a fourth mode control signal sent by the mobile terminal and send the fourth mode control signal to the controller, and the controller is configured to control the frequency conversion module according to the fourth mode control signal to drive the ozone generation device to release ozone for an eleventh preset duration and then stop the ozone generation device, drive the anion generation device to release anions for a twelfth preset duration, and circulate after an interval of a thirteenth preset duration; alternatively, the first and second electrodes may be,

the controller is used for controlling the frequency conversion module to drive the ozone generating device and the negative ion generating device to work simultaneously initially according to the fourth mode control signal, the ozone generating device releases ozone, the negative ion generating device releases negative ions at the same time, the ozone generating device releases ozone for an eleventh preset time and stops, the negative ion generating device releases negative ions for a twelfth preset time and stops, and circulation is performed after a thirteenth preset time interval;

the wireless communication module is further used for receiving a sleep mode control signal sent by the mobile terminal and sending the sleep mode control signal to the controller, and the controller is used for controlling the frequency conversion module to drive the negative ion generating device to release negative ions according to the sleep mode control signal and stop after the negative ions continue for a fourteenth preset time.

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