CN111947225A - Multifunctional heater control method and device, multifunctional heater and storage medium - Google Patents

Abstract

The application relates to a control method and device of a multifunctional heater, the multifunctional heater and a storage medium. The method comprises the following steps: acquiring the ambient temperature detected by a temperature detection module; when the ambient temperature meets the heating requirement, generating a first control instruction, and starting a heating module and a wind wheel module according to the first control instruction to heat; and when the ambient temperature meets the air supply requirement, generating a second control instruction and starting the flow guide module and the wind wheel module to supply air according to the second control instruction. By adopting the method, the use convenience of the multifunctional warmer can be improved.

Description

Multifunctional heater control method and device, multifunctional heater and storage medium

Technical Field

The application relates to the technical field of multi-heater control, in particular to a control method and device of a multifunctional heater, the multifunctional heater and a storage medium.

Background

With the increasing living standard of people, heating in winter and cooling in summer become the basic requirements of people's life. Therefore, the electric heater necessary in winter and the electric fan necessary in summer appear in the future.

However, both the electric heater and the electric fan only have a single heating or air supply function, and the user is required to manually control the electric heater and the electric fan, so that the use convenience is reduced.

Disclosure of Invention

The application aims at reducing the problem of convenience in use, and provides a control method and device of a multifunctional controller, the multifunctional controller and a storage medium.

A control method of a multifunctional warmer is characterized by comprising the following steps:

acquiring the ambient temperature detected by a temperature detection module;

when the ambient temperature meets the heating requirement, generating a first control instruction, and starting a heating module and a wind wheel module to heat according to the first control instruction;

and when the ambient temperature meets the air supply requirement, generating a second control instruction and starting the wind wheel module and the flow guide module to supply air according to the second control instruction.

In one embodiment, when the ambient temperature meets a heating requirement, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction includes:

when the ambient temperature meets the heating requirement, acquiring the current system time and the starting time of the last heating module starting;

comparing the current system time with the starting time, and determining a time difference value between the current system time and the starting time;

and when the time difference is larger than a preset difference threshold, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction.

In one embodiment, the method further comprises:

when the time difference is smaller than or equal to a preset difference threshold value, closing the temperature detection module to execute an active control mode;

and generating voice reminding information, and playing the voice reminding information to prompt a user to actively control.

In one embodiment, a method of determining whether the ambient temperature meets a heating requirement includes:

when a preset upper temperature threshold and a preset lower temperature threshold are obtained, comparing the environment temperature with the upper temperature threshold and the lower temperature threshold;

when the ambient temperature is less than the lower temperature threshold, determining that the ambient temperature meets the heating requirement;

and when the ambient temperature is greater than the upper limit of the temperature threshold value, determining that the ambient temperature meets the air supply requirement.

In one embodiment, after the generating the voice reminding message and playing the voice reminding message to prompt the user to actively control, the method further includes:

acquiring a control request of a user;

when the control request of the user is a heating instruction, generating a first control instruction and starting a heating module and a wind wheel module to heat according to the first control instruction;

and when the control request of the user is an air supply instruction, generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction.

In one embodiment, the method further comprises:

when the control instruction of the user is an automatic mode instruction, starting the temperature detection module to detect the ambient temperature;

and returning to the step of acquiring the ambient temperature detected by the temperature detection module.

A control device of a multifunctional warmer, the device comprising:

the acquisition module is used for acquiring the ambient temperature detected by the temperature detection module;

the heating control module is used for generating a first control instruction and starting the heating module and the wind wheel module to heat according to the first control instruction when the ambient temperature meets the heating requirement;

and the air supply control module is used for generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction when the ambient temperature meets the air supply requirement.

A multi-function warmer, comprising:

a control module;

the temperature detection module is connected with the control module and used for detecting the ambient temperature;

the heating module is connected with the control module and used for heating;

the wind wheel module is connected with the control module and used for generating air volume;

the flow guide module is connected with the control module and used for reinforcing gas exchange;

the control module is used for starting the heating module and the wind wheel module to heat when the ambient temperature detected by the temperature detection module meets the heating requirement, and is also used for starting the diversion module and the wind wheel module to supply air when the ambient temperature detected by the temperature detection module meets the air supply requirement.

In one embodiment, the flow guide module comprises a wind wheel and a wind channel.

A computer-readable storage medium, on which a computer program is stored, which, when executed by a processor, implements the steps of the control method of a multifunctional warmer of any one of the above.

According to the control method and device of the multifunctional warmer, the multifunctional warmer and the storage medium, the temperature detection module is used for detecting the ambient temperature to judge whether the current environment meets the warming requirement or the air supply requirement, then, when the warming requirement is met, a first control instruction is generated to start the heating module and the wind wheel module to heat, and when the air supply requirement is met, a second control instruction is generated to start the wind wheel module and the flow guide module to supply air. The method adjusts the working mode of the multifunctional warmer in real time through the ambient temperature, not only realizes multiple purposes of one machine, but also automatically adjusts the working state through the ambient temperature, thereby improving the convenience of use. And when the air supply mode is controlled, the flow guide module is started at the same time, so that the convection of air is enhanced, and the air supply effect is improved.

Drawings

FIG. 1 is a flow chart illustrating a control method of the multifunctional warmer according to an embodiment;

FIG. 2 is a schematic flow chart illustrating a heating step of generating a first control command and activating a heating module and a wind wheel module according to the first control command when an ambient temperature meets a heating requirement according to an embodiment;

FIG. 3 is a schematic structural diagram of the multifunctional warmer in one embodiment;

fig. 4 is a block diagram of the control device of the multifunctional warmer in one embodiment.

Detailed Description

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

In one embodiment, as shown in fig. 1, a control method of a multifunctional warmer is provided, and the control method of the multifunctional warmer provided by the present application is executed in a control module of the multifunctional warmer. The method is applied to a control module of the multifunctional warmer for explanation by taking the example that the method comprises the following steps:

step S102, the ambient temperature detected by the temperature detection module is obtained.

The temperature detection module is used for detecting the ambient temperature of the surrounding environment where the multifunctional warmer is located, and can be understood as a temperature sensor. The ambient temperature is a temperature value of the ambient environment obtained by the temperature detection module through detection. It should be understood that the installation position of the temperature detection module needs to be determined according to the actual multifunctional warmer product form. However, in order to ensure that the temperature detected by the temperature detection module is the ambient temperature and not the temperature of the internal heating module of the multifunctional warmer, the temperature detection module is installed as far away from the heat generation source as possible. And, because the hot air is upward and the cold air is downward, the installation position of the temperature detection module can be as close to the bottom of the product as possible.

Specifically, when the multifunctional warmer is started and operated in an automatic mode, the temperature detection module is started to detect the temperature of the surrounding environment in real time. And then the ambient temperature detected by the temperature detection module is obtained.

And step S104, when the ambient temperature meets the heating requirement, generating a first control instruction, and starting the heating module and the wind wheel module to heat according to the first control instruction.

The ambient temperature satisfying the heating requirement means that the ambient temperature is a temperature suitable for heating. The first control command is a command for controlling a module for starting heating, and can be understood as a heating command. The module used for heating in the multifunctional warmer comprises a heating module and a wind wheel module.

Specifically, after the control module in the multifunctional warmer acquires the ambient temperature detected by the temperature detection module, the ambient temperature detected by the temperature detection module is compared with a set temperature threshold. It is determined whether the current ambient temperature meets the heating requirements or the supply air requirements. When the current environment temperature is determined to meet the heating requirement, the control module generates a first control instruction for controlling the heating module to start. And starting the heating module according to the first control instruction to heat, namely starting the heating module and the wind wheel module according to the first control instruction to start working. After the heating module and the wind wheel module are started, the passing airflow is transmitted to the outside of the multifunctional warmer through the heating module and the wind wheel module. And because the air current passes to the outside after heating through heating module to ambient temperature has been promoted and the purpose of heating has been reached. It can be understood that after the heating module of the multifunctional warmer is started, the multifunctional warmer is independently used as an electric heater.

And S106, when the ambient temperature meets the air supply requirement, generating a second control instruction, and starting the wind wheel module and the flow guide module to supply air according to the second control instruction.

The condition that the ambient temperature meets the air supply requirement means that the ambient temperature meets the air supply temperature. The second control instruction is an instruction for controlling a module for starting air supply, and can be understood as an air supply instruction. The module used for supplying air in the multifunctional warmer comprises a flow guide module and a wind wheel module.

Specifically, after the control module in the multifunctional warmer acquires the ambient temperature detected by the temperature detection module, the ambient temperature detected by the temperature detection module is compared with a set temperature threshold. It is determined whether the current ambient temperature meets the heating requirements or the supply air requirements. And when the current environment temperature is determined to meet the air supply requirement, the control module generates a second control instruction for controlling the start of the air supply module. And starting the air supply module to supply air according to the second control instruction, namely starting the diversion module and the wind wheel module to start working according to the second control instruction. At this moment, the diversion module and the wind wheel module inside the multifunctional heater are only started, and the heating module is not started. Therefore, the airflow transmitted to the outside through the diversion module and the wind wheel module is not heated by the heating module, and only convection is enhanced to realize air supply. It can be understood that after the heating module of the multifunctional warmer is turned off, the multifunctional warmer is independently used as an electric fan. Meanwhile, when the air-cooling fan is used as an electric fan, the exchange of air is enhanced by starting the diversion module, so that the air supply effect is further improved.

According to the control method of the multifunctional warmer, the ambient temperature is detected by the temperature detection module to judge whether the current environment meets the warming requirement or the air supply requirement, and then when the warming requirement is met, a first control instruction is generated to start the heating module and the wind wheel module to heat, and when the air supply requirement is met, a second control instruction is generated to start the wind wheel module and the flow guide module to supply air. The method adjusts the working mode of the multifunctional warmer in real time through the ambient temperature, not only realizes multiple purposes of one machine, but also improves the use convenience through automatic adjustment realized by the ambient temperature. And when the air supply mode is controlled, the flow guide module is started at the same time, so that the convection of air is enhanced, and the air supply effect is improved.

In one embodiment, as shown in fig. 2, step S104 includes:

step 202, when the ambient temperature meets the heating requirement, the current system time and the starting time of the last heating module starting are obtained.

Specifically, the current system time refers to the system time when the ambient temperature is determined to meet the heating requirement, for example, when the ambient temperature detected by the temperature detection module at 9:00 of 1/1990 determines that heating is needed at the moment, 9:00 of 1/1990 is the current system time. The start-up time of the last start-up of the heating module is understood as the time of the last determination that the heating requirement is met and the heating module (heating module and wind wheel module) is started, e.g. the time of the start-up of the over-heating module at 8:00 on 1/1990, so that 8:00 on 1/1990 is the start-up time of the last start-up.

Step 204, comparing the current system time with the starting time, and determining the time difference between the current system time and the starting time.

Specifically, after the current system time and the start time of the last start are acquired, a time interval between two times of satisfying the heating requirement is determined. And comparing the current system time with the starting time, and determining the time difference value between the current system time and the starting time. The time difference is understood to be the time interval between the two. For example, the current system time is 9:00 on 1/1990, and the start time is 8:00 on 1/1990, with a time difference of 1 hour (60 minutes). The current system time was 9:00 on month 2 of 1990 and the start time was 8:00 on month 1 of 1990, with a time difference of 25 hours.

And step S206, when the time difference is larger than a preset difference threshold, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction.

The minimum starting time interval between two preset starting heating times in the difference threshold value can be configured according to actual requirements.

Specifically, after the time difference between the current system time and the last start time is obtained, the time difference is compared with a difference threshold value to determine whether the time difference is greater than the difference threshold value. And when the time difference is larger than the difference threshold value, the time interval between two times of heating starting meets the minimum starting time interval, and the heating can be started at this time. Then, the control module generates a first control instruction for controlling the heating module to start. And starting the heating module according to the first control instruction to heat, namely starting the heating module and the wind wheel module according to the first control instruction to start working.

In another embodiment, after step S204, the method further includes: when the time difference is smaller than or equal to a preset difference threshold value, closing the temperature detection module to execute an active control mode; and generating voice reminding information, and playing the voice reminding information to prompt a user to actively control.

Specifically, when the time difference is determined to be less than or equal to the preset difference threshold by comparing the time difference with the difference threshold, it indicates that the time interval between two start-ups does not satisfy the minimum start-up time interval. The control module closes the temperature detection module through a control instruction, and the temperature detection module does not detect the ambient temperature in real time until the temperature detection module is started. And after the control module closes the temperature detection module, the active control module is executed, namely the control authority of the multifunctional warmer is provided for the user. Therefore, the control module generates and plays the voice reminding information for prompting the user to actively control the multifunctional warmer to heat and supply air or enter an automatic mode.

In this embodiment, whether heating is started or not at this time is determined by comparing the difference threshold value used for indicating the minimum starting time interval with the time difference value of the secondary starting, so that the service life of a product is prevented from being reduced due to frequent opening and closing of the heating module.

In one embodiment, after step S206, the method further includes: acquiring a control request of a user; when the control request of the user is a heating instruction, generating a first control instruction and starting a heating module and a wind wheel module to heat according to the first control instruction; and when the control request of the user is an air supply instruction, generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction.

The control request is an instruction for issuing, and the control request may be issued by a user through operating a remote controller or issued by the user through operating an operation panel provided by the multifunctional warmer. For example, the user clicks a heating button, an air supply button, or an auto mode button on a remote controller or an operation panel to issue a corresponding control request.

Specifically, when a control request of a user is acquired, a corresponding control action is executed according to the control request. For example, when the control request is a request issued by clicking a heating button, the control request is a heating instruction, and the control module generates a first control instruction to control the heating module and the wind wheel module to be started for heating. And when the control request is a request issued by clicking an air supply button, the control request is an air supply instruction, and the control module generates a second control instruction to control the starting of the diversion module and the wind wheel module for air supply.

In one embodiment, when the control request is a request issued by clicking an automatic mode button, the control request is a command requesting for automatic control, and the control module generates a control command to control the start of the temperature detection module. Then, the flow proceeds to step S102, and the flow proceeds to active control. Namely, the control module obtains the ambient temperature detected by the temperature detection module, compares the ambient temperature with the upper limit of the temperature threshold and the lower limit of the temperature threshold to determine that the heating requirement is met, and generates a first control instruction to control the starting heating module and the wind wheel module to heat when the difference value between the system time for determining heating and the last time for starting heating is met. And when the environmental temperature is compared with the upper limit and the lower limit of the temperature threshold value to determine that the air supply requirement is met, the control module generates a second control instruction to control the flow guide module and the wind wheel module to supply air.

In the embodiment, after the multifunctional warmer enters the active mode, the control of the multifunctional warmer is realized by responding to the control request of the user.

In one embodiment, a method of determining whether an ambient temperature meets a heating requirement, comprises: when the upper limit and the lower limit of the preset temperature threshold are obtained, comparing the environmental temperature with the upper limit and the lower limit of the temperature threshold; when the ambient temperature is less than the lower limit of the temperature threshold, determining that the ambient temperature meets the heating requirement; and when the ambient temperature is greater than the upper limit of the temperature threshold, determining that the ambient temperature meets the air supply requirement.

The temperature threshold is a requirement that is set in advance to be satisfied for determining the ambient temperature, and is understood to be a critical value for heating and blowing air. The temperature threshold can be set in real time according to requirements, for example, an initial temperature threshold is set when the multifunctional warmer leaves a factory. When the temperature-sensing device is used by a subsequent user, if the temperature-sensing device is not reset, the temperature threshold set by a factory is compared with the environmental temperature. And if the temperature threshold is reset in the using process of the user, replacing the temperature threshold set by the user with the temperature threshold set by the factory. Due to the difference of the area temperatures, the user can conveniently set the proper temperature threshold value according to the actual area condition by providing the autonomous setting temperature threshold value. In order to prevent the temperature threshold value from being set too extreme and affecting the determination, the temperature threshold value may be set in a temperature range comfortable for the human body, that is, the temperature threshold value needs to be set to have upper and lower limits. For example, the temperature threshold is 10 ℃ to 30 ℃, 10 ℃ is the lower temperature threshold, and 30 ℃ is the upper temperature threshold.

Specifically, when it is determined whether heating or ventilation is required according to the ambient temperature detected by the temperature detection module, the set upper temperature threshold and lower temperature threshold are acquired. And comparing the upper limit and the lower limit of the temperature threshold with the ambient temperature, and when the ambient temperature is greater than the upper limit of the temperature threshold, indicating that the current ambient temperature is too high, and determining that the air supply requirement is met. Otherwise, when the ambient temperature is smaller than the lower limit of the temperature threshold, the current ambient temperature is too low, and the heating requirement is determined to be met. For example, if the temperature threshold is 10 ℃ to 30 ℃, the air supply requirement is determined to be met when the current ambient temperature is greater than 30 ℃. And when the current ambient temperature is less than 10 ℃, determining that the heating requirement is met. It should be understood that when the ambient temperature is between 10 ℃ and 30 ℃ (including 10 ℃ and 30 ℃), the ambient temperature is comfortable and suitable for human body, so that heating or air supply is not needed. Namely, the control module does not control heating or air supply, so that the multifunctional warmer is in a standby state.

In this embodiment, confirm whether to satisfy heating or supply air through temperature threshold value upper limit and the lower limit that sets for according to user's demand, can also control according to user's demand when can be according to ambient temperature automatic control, improve user experience.

In one embodiment, as shown in FIG. 3, a multi-functional warmer is provided. The control method of the multifunctional warmer will be explained based on the multifunctional warmer shown in fig. 3.

Specifically, referring to fig. 3, the multifunctional warmer includes: the device comprises a control module 10, a temperature detection module 20 connected with the control module 10 and used for detecting the ambient temperature, a heating module 30 connected with the control module 10 and used for heating, a wind wheel module 40 connected with the control module 10 and used for generating wind volume, and a flow guide module 50 connected with the control module 10 and used for strengthening gas exchange.

Specifically, when the multifunctional warmer is started to work, the control module 10 acquires the ambient temperature detected by the temperature detection module 20. The control module 10 compares the ambient temperature detected by the temperature detection module 20 with a pre-configured upper temperature threshold and a pre-configured lower temperature threshold. When the ambient temperature is greater than the upper temperature threshold, the control module 10 determines that the air supply requirement is met. The control module 10 controls the start-up rotor module 40 and the deflector module 50.

When the ambient temperature is less than the lower temperature threshold, the control module 10 determines that the heating demand is satisfied. Then, the control module 10 obtains the starting time of the last heating starting and compares the starting time with the current system time, and when the time difference between the current system time and the starting time is determined to be greater than the difference threshold, the control module 10 controls the heating starting module 30 and the wind wheel module 40 to heat. If the ambient temperature is greater than or equal to the lower temperature threshold and less than or equal to the upper temperature threshold, the control module 10 does not control, and re-acquires the ambient temperature detected by the temperature detection module 20, and enters the next control process.

In one embodiment, the deflector module 50 includes a wind wheel and a wind tunnel. It is understood that the deflector module 50 is a wind turbine duct assembly. Convection is further enhanced by the addition of the flow guide module 50, which can enhance the effect of convection compared to natural convection.

It should be understood that although the various steps in the flow charts of fig. 1-2 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 1-2 may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed in turn or alternately with other steps or at least some of the other steps.

In one embodiment, as shown in fig. 4, there is provided a control device of a multifunctional warmer, including: an acquisition module 402, a heating control module 404, and an air supply control module 406, wherein:

an obtaining module 402, configured to obtain an ambient temperature detected by the temperature detecting module;

the heating control module 404 is configured to generate a first control instruction and start the heating module and the wind wheel module to heat according to the first control instruction when the ambient temperature meets the heating requirement;

and the air supply control module 406 is used for generating a second control instruction and starting the flow guide module and the wind wheel module to supply air according to the second control instruction when the ambient temperature meets the air supply requirement.

In one embodiment, the heating control module 404 is further configured to, when the ambient temperature meets the heating requirement, obtain a current system time and a start time for starting the heating module last time; comparing the current system time with the starting time, and determining the time difference between the current system time and the starting time; and when the time difference is larger than a preset difference threshold, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction.

In one embodiment, the heating control module 404 is further configured to turn off the temperature detection module to perform the active control mode when the time difference is less than or equal to a preset difference threshold; and generating voice reminding information, and playing the voice reminding information to prompt the user to actively control.

In one embodiment, the control device of the multifunctional warmer further comprises a comparison module, configured to compare the ambient temperature with an upper temperature threshold and a lower temperature threshold when acquiring a preset upper temperature threshold and a preset lower temperature threshold; when the ambient temperature is less than the lower limit of the temperature threshold, determining that the ambient temperature meets the heating requirement; and when the ambient temperature is greater than the upper limit of the temperature threshold, determining that the ambient temperature meets the air supply requirement.

In one embodiment, the obtaining module 402 is further configured to obtain a control request of a user.

The heating control module 404 is further configured to generate a first control instruction and start the heating module and the wind wheel module to heat according to the first control instruction when the control request of the user is a heating instruction.

The air supply control module 406 is further configured to generate a second control instruction and start the airflow guide module and the wind wheel module to supply air according to the second control instruction when the control request of the user is an air supply instruction.

In one embodiment, the control device of the multifunctional warmer further comprises a sensor control module, which is used for starting the temperature detection module to detect the ambient temperature when the control instruction of the user is an automatic mode instruction.

The specific definition of the control device of the multifunctional warmer can be referred to the definition of the control method of the multifunctional warmer in the above, and the detailed description is omitted here. All or part of each module in the control device of the multifunctional warmer can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of:

acquiring the ambient temperature detected by a temperature detection module;

when the ambient temperature meets the heating requirement, generating a first control instruction, and starting a heating module and a wind wheel module according to the first control instruction to heat;

and when the ambient temperature meets the air supply requirement, generating a second control instruction and starting the flow guide module and the wind wheel module to supply air according to the second control instruction.

In one embodiment, the computer program when executed by the processor further performs the steps of: when the ambient temperature meets the heating requirement, acquiring the current system time and the starting time of the last heating module starting; comparing the current system time with the starting time, and determining the time difference between the current system time and the starting time; and when the time difference is larger than a preset difference threshold, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction.

In one embodiment, the computer program when executed by the processor further performs the steps of: when the time difference is smaller than or equal to a preset difference threshold value, closing the temperature detection module to execute an active control mode; and generating voice reminding information, and playing the voice reminding information to prompt the user to actively control.

In one embodiment, the computer program when executed by the processor further performs the steps of: when the upper limit and the lower limit of the preset temperature threshold are obtained, comparing the environmental temperature with the upper limit and the lower limit of the temperature threshold; when the ambient temperature is less than the lower limit of the temperature threshold, determining that the ambient temperature meets the heating requirement; and when the ambient temperature is greater than the upper limit of the temperature threshold, determining that the ambient temperature meets the air supply requirement.

In one embodiment, the computer program when executed by the processor further performs the steps of: acquiring a control request of a user; when the control request of the user is a heating instruction, generating a first control instruction and starting a heating module and a wind wheel module to heat according to the first control instruction; and when the control request of the user is an air supply instruction, generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction.

In one embodiment, the computer program when executed by the processor further performs the steps of: when the control instruction of the user is an automatic mode instruction, starting a temperature detection module to detect the ambient temperature; and returning to the step of acquiring the ambient temperature detected by the temperature detection module.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A control method of a multifunctional warmer is characterized by comprising the following steps:

acquiring the ambient temperature detected by a temperature detection module;

when the ambient temperature meets the heating requirement, generating a first control instruction, and starting a heating module and a wind wheel module to heat according to the first control instruction;

and when the ambient temperature meets the air supply requirement, generating a second control instruction and starting the wind wheel module and the flow guide module to supply air according to the second control instruction.

2. The method according to claim 1, wherein when the ambient temperature meets a heating requirement, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction comprises:

when the ambient temperature meets the heating requirement, acquiring the current system time and the starting time of the last heating module starting;

comparing the current system time with the starting time, and determining a time difference value between the current system time and the starting time;

and when the time difference is larger than a preset difference threshold, generating a first control instruction and starting a corresponding heating module to heat according to the first control instruction.

3. The method of claim 2, further comprising:

when the time difference is smaller than or equal to a preset difference threshold value, closing the temperature detection module to execute an active control mode;

and generating voice reminding information, and playing the voice reminding information to prompt a user to actively control.

4. The method of claim 1, wherein the method of determining whether the ambient temperature meets a heating requirement comprises:

when a preset upper temperature threshold and a preset lower temperature threshold are obtained, comparing the environment temperature with the upper temperature threshold and the lower temperature threshold;

when the ambient temperature is less than the lower temperature threshold, determining that the ambient temperature meets the heating requirement;

and when the ambient temperature is greater than the upper limit of the temperature threshold value, determining that the ambient temperature meets the air supply requirement.

5. The method of claim 3, wherein after generating the voice alert message and playing the voice alert message to prompt the user for active control, further comprising:

acquiring a control request of a user;

when the control request of the user is a heating instruction, generating a first control instruction and starting a heating module and a wind wheel module to heat according to the first control instruction;

and when the control request of the user is an air supply instruction, generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction.

6. The method of claim 5, further comprising:

when the control instruction of the user is an automatic mode instruction, starting the temperature detection module to detect the ambient temperature;

and returning to the step of acquiring the ambient temperature detected by the temperature detection module.

7. A control device of a multifunctional warmer, characterized in that the device comprises:

the acquisition module is used for acquiring the ambient temperature detected by the temperature detection module;

the heating control module is used for generating a first control instruction and starting the heating module and the wind wheel module to heat according to the first control instruction when the ambient temperature meets the heating requirement;

and the air supply control module is used for generating a second control instruction and starting the diversion module and the wind wheel module to supply air according to the second control instruction when the ambient temperature meets the air supply requirement.

8. A multifunctional warmer is characterized by comprising:

a control module;

the temperature detection module is connected with the control module and used for detecting the ambient temperature;

the heating module is connected with the control module and used for heating;

the wind wheel module is connected with the control module and used for generating air volume;

the flow guide module is connected with the control module and used for reinforcing gas exchange;

the control module is used for starting the heating module and the wind wheel module to heat when the ambient temperature detected by the temperature detection module meets the heating requirement, and is also used for starting the diversion module and the wind wheel module to supply air when the ambient temperature detected by the temperature detection module meets the air supply requirement.

9. The multifunctional warmer of claim 8, wherein the flow guide module comprises a wind wheel and a wind tunnel.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 5.

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