WO2022183715A1

WO2022183715A1 - Control method for graphene lower air supply air conditioner, and graphene lower air supply air conditioner

Info

Publication number: WO2022183715A1
Application number: PCT/CN2021/119675
Authority: WO
Inventors: 李向凯; 郝本华; 矫立涛
Original assignee: 青岛海尔空调器有限总公司; 青岛海尔空调电子有限公司; 海尔智家股份有限公司
Priority date: 2021-03-03
Filing date: 2021-09-22
Publication date: 2022-09-09
Also published as: CN112944632A; CN112944632B

Abstract

The present application relates to the technical field of air conditioners, and provides a control method for a graphene lower air supply air conditioner, and a graphene lower air supply air conditioner. The method comprises: obtaining an actual near-floor temperature difference and an actual indoor temperature difference according to a near-floor temperature and an indoor temperature in a room; and according to the actual near-floor temperature difference and the actual indoor temperature difference, controlling to start a corresponding number of graphene heating films for heating, the actual near-floor temperature difference and the actual indoor temperature difference being positively correlated with the number of graphene heating films controlled to be started. According to the control method for a graphene lower air supply air conditioner provided by the present application, a heating layer and a radiating layer are arranged in each graphene heating film, and according to an actual near-floor temperature difference and an actual indoor temperature difference, a corresponding number of graphene heating films can be controlled to be started for heating, such that the graphene lower air supply air conditioner can change, depending on temperature change, the air supply temperature of the air conditioner for the lower space; in addition, the temperature of the lower space is rapidly increased by means of radiative heat transfer, thereby solving the problem that the temperature of the lower space of a room is too low during heating by a vertical air conditioner in winter.

Description

A kind of control method of graphene under-ventilation air conditioner and graphene under-ventilation air conditioner

CROSS-REFERENCE TO RELATED APPLICATIONS

This application requires the priority of the Chinese patent application with the application number of 202110235988.X submitted on March 03, 2021, and the invention title is "a control method of a graphene-based ventilating air conditioner and a graphene-based ventilating air conditioner", It is hereby incorporated by reference in its entirety.

technical field

The application relates to the technical field of air conditioners, and in particular, to a control method of a graphene down-flow air conditioner and a graphene down-flow air conditioner.

Background technique

With the improvement of people's living standards, air conditioners have become a must-use electrical appliance for modern people's homes and offices, especially in summer and winter, air conditioners are used for a long time. The air conditioner can cool in summer and heat in winter, and can adjust the indoor temperature to be warm in winter and cool in summer, providing users with a comfortable environment.

At present, most air conditioners have multiple modes such as cooling and heating. In the process of automatic control mode, they can automatically select cooling or heating according to the outdoor ambient temperature, and can automatically set the target temperature and temperature according to the indoor and outdoor temperatures. Fan speed, in order to achieve the purpose of indoor constant temperature as much as possible. However, during the heating process of the existing air conditioner, only the temperature sensor on the air conditioner is used to judge and control the heating process, and it is difficult to make the indoor temperature reach the set temperature. Especially when heating in winter, the cabinet air conditioner can easily cause the problem that the temperature at the bottom of the room is too low.

SUMMARY OF THE INVENTION

The embodiments of the present application provide a control method for a graphene under-ventilation air conditioner and a graphene under-ventilation air conditioner, so as to solve the problem that the temperature at the bottom of the room is too low when the cabinet air conditioner is heated in winter.

The embodiment of the present application provides a control method for a graphene under-air air conditioner, wherein the graphene under-air air conditioner is provided with a plurality of temperature sensors and a multi-layer graphene heating film; each layer of the graphene heating film includes: heating layer for air heating and radiant layer for heating the bottom of the room;

The control method includes the following steps:

The temperature sensor detects the near ground temperature and the indoor temperature, and obtains the actual near ground temperature difference and the actual indoor temperature difference according to the set temperature, the near ground temperature and the indoor temperature;

According to the actual near-ground temperature difference and the actual indoor temperature difference, a corresponding number of the graphene heating films are controlled to start heating; wherein, the actual near-ground temperature difference and the actual indoor temperature difference are positively correlated with the number of the graphene heating films that are started by control.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, the step of controlling and starting a corresponding number of the graphene heating films to heat according to the actual near-ground temperature difference and the actual indoor temperature difference specifically includes:

If the actual near-earth temperature difference is within the first near-earth preset temperature interval, and when the actual indoor temperature difference is within the first near-earth preset temperature interval, control all the numbers corresponding to the first near-earth predetermined temperature interval and the first indoor predetermined temperature interval. The graphene heating film is heated.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is within the first near-ground preset temperature interval, and the actual indoor temperature difference is within the second indoor preset temperature interval, the control method corresponding to the first near-ground temperature A near-preset temperature interval and the number of the graphene heating films in the second indoor preset temperature interval are heated;

Wherein, the upper threshold value of the second indoor preset temperature interval is smaller than the lower threshold value of the first indoor preset temperature interval, and the number of the graphene heating films corresponding to the second indoor preset temperature interval is less than that of the first indoor preset temperature interval The corresponding number of the graphene heating films.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is within the second near-ground preset temperature range, and the actual indoor temperature difference is within the second indoor preset temperature range, the control method corresponding to the first Two near-ground preset temperature intervals and the number of described graphene heating films in the second indoor preset temperature interval are heated;

Wherein, the upper threshold value of the second near-earth preset temperature zone is smaller than the lower limit threshold of the first near-ground preset temperature interval, and the number of the graphene heating films corresponding to the second near-ground preset temperature zone is less than that of the first near-ground temperature zone The number of the graphene heating films corresponding to the preset temperature interval.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is within the second near-ground preset temperature interval, and the actual indoor temperature difference is within the third indoor preset temperature interval, the control method corresponding to the first Two near-ground preset temperature intervals and the number of described graphene heating films in the third indoor preset temperature interval are heated;

Wherein, the upper threshold value of the third indoor preset temperature interval is smaller than the lower threshold value of the second indoor preset temperature interval, and the number of the graphene heating films corresponding to the third indoor preset temperature interval is less than the second indoor preset temperature interval The corresponding number of the graphene heating films.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is within the third near-ground preset temperature interval, and the actual indoor temperature difference is within the third indoor preset temperature interval, the control method corresponding to the first Three near-ground preset temperature intervals and the third indoor preset temperature interval number of the graphene heating films are heated;

Wherein, the upper threshold of the third near-earth preset temperature interval is smaller than the lower threshold of the second near-earth preset temperature interval, and the number of the graphene heating films corresponding to the third near-earth preset temperature interval is less than that of the second near-earth preset temperature interval The number of the graphene heating films corresponding to the preset temperature interval.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is in the third near-ground preset temperature interval, and the actual indoor temperature difference is in the fourth indoor preset temperature interval, the control method corresponding to the first Three near-ground preset temperature intervals and the fourth indoor preset temperature interval number of the graphene heating films are heated;

Wherein, the upper threshold of the fourth indoor preset temperature interval is smaller than the lower threshold of the third indoor preset temperature interval, and the number of the graphene heating films corresponding to the fourth indoor preset temperature interval is less than the third indoor preset temperature interval The corresponding number of the graphene heating films.

According to the control method of the graphene down-air air conditioner provided by an embodiment of the present application, if the actual near-ground temperature difference is in the fourth near-ground preset temperature interval, and the actual indoor temperature difference is in the fourth indoor preset temperature interval, the control method corresponding to the first Four near-ground preset temperature intervals and the fourth indoor preset temperature interval number of the graphene heating films are heated;

Wherein, the upper limit threshold of the fourth near-earth preset temperature interval is smaller than the lower limit threshold of the third near-earth preset temperature interval, and the number of the graphene heating films corresponding to the fourth near-earth preset temperature interval is less than that of the third near-earth preset temperature interval The number of the graphene heating films corresponding to the preset temperature interval.

Embodiments of the present application also provide a graphene down-air air conditioner, comprising: a main control module, a warm air control module, a multilayer graphene heating film and a plurality of the temperature sensors;

The main control module, each of the graphene heating films and each of the temperature sensors are all connected with the heater control module circuit, and each of the temperature sensors is used to detect the near-ground temperature and the indoor temperature, so that the The warm air control module controls and starts a corresponding number of the graphene heating films to heat according to the actual near-ground temperature difference and the actual indoor temperature difference; wherein, the actual near-ground temperature difference and the actual indoor temperature difference and the warm air control module control and start The number of the graphene heating films is positively correlated.

According to the graphene down-flow air conditioner provided in an embodiment of the present application, the graphene down-flow air conditioner further includes: a WiFi control module, a mobile phone client and a cloud server; the main control module passes the WiFi control module, all the The cloud server is in communication connection with the mobile phone client.

The control method of the air-conditioning under the graphene provided by the application, a heating layer for air heating and a radiant layer for heating at the bottom of the room are arranged in the graphene heating film, according to the set temperature of the room, the near-ground temperature and the indoor temperature temperature, obtain the actual near-ground temperature difference and the actual indoor temperature difference, and can start the corresponding number of graphene heating films for heating according to the actual near-ground temperature difference and the actual indoor temperature difference, so that the graphene under-air air conditioner can change the bottom of the air conditioner according to the temperature change. At the same time, the temperature of the bottom of the room is quickly increased by means of radiation heat transfer, which solves the problem that the temperature of the bottom of the room is too low when the cabinet air conditioner is heated in winter.

Description of drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the following will briefly introduce the accompanying drawings used in the description of the embodiments or the prior art. Obviously, the accompanying drawings in the following description These are some embodiments of the present application. For those of ordinary skill in the art, other drawings can also be obtained based on these drawings without any creative effort.

Fig. 1 is the schematic flow sheet of the control method of the ventilation air conditioner under the graphene provided by the embodiment of the present application;

Fig. 2 is the structural representation of a kind of graphene down-air air conditioner provided in the embodiment of the present application;

Fig. 3 is the structural representation of another kind of graphene down-air air conditioner provided in the embodiment of the present application;

In the figure, 1. Temperature sensor; 11. Near ground temperature sensor; 12. Indoor temperature sensor; 2. Warm air control module; 3. Graphene heating film; 4. Main control module; 5. Cloud server; 6. Mobile phone customer 7. WiFi control module.

Detailed ways

In order to make the purposes, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be described clearly and completely below with reference to the drawings in the embodiments of the present application. Obviously, the described embodiments It is a part of the embodiments of the present application, but not all of the embodiments. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skill in the art without creative work fall within the protection scope of the present application.

The application provides a kind of control method of the air outlet air conditioner under the graphene, the following describes the control method of the air outlet air conditioner under the graphene provided by the embodiment of the present application in conjunction with Fig. 1 and Fig. 2, the air outlet air conditioner under the graphene is provided with a plurality of temperature A sensor 1 and a multilayer graphene heating film 3; each graphene heating film 3 includes a heating layer and a radiation layer. Among them, the heating layer is used for air heating, and the radiant layer is directly used for heating at the bottom of the room.

The control method of this graphene down-air air conditioner comprises the following steps:

Step S1: the temperature sensor detects the near-earth temperature and the indoor temperature, and obtains the actual near-earth temperature difference and the actual indoor temperature difference according to the set temperature, the near-earth temperature and the indoor temperature.

Step S2: controlling and starting a corresponding number of graphene heating films for heating according to the actual near-ground temperature difference and the actual indoor temperature difference; wherein, the actual near-ground temperature difference and the actual indoor temperature difference are positively correlated with the number of graphene heating films that are controlled to start.

After the user selects the heating function, the main control module 4 sends a signal to the heating control module 2. After receiving the signal, the heating control module 2 can control all the temperature sensors 1 to start measuring the temperature of the room at the same time, and each temperature sensor 1 can obtain the proximity of the room. The ground temperature and the indoor temperature, the actual near ground temperature difference is obtained according to the difference between the set temperature and the near ground temperature, and the actual indoor temperature difference is obtained according to the difference between the set temperature and the indoor temperature. The warm air control module 2 controls and activates a corresponding number of graphene heating films 3 for heating according to the actual near-ground temperature difference and the actual indoor temperature difference. The heating layer of the graphene heating film 3 can effectively heat the air, and the radiation layer of the graphene heating film 3 directly heats the bottom of the room.

According to the distribution characteristics of air temperature, in the absence of other factors, the air temperature at the bottom of the room decreases sequentially from top to bottom. It is necessary to maintain the stability of the overall temperature at the bottom and avoid the temperature at the bottom of the room from being too low. In the control process, the actual near-ground temperature difference and the actual indoor temperature difference are positively correlated with the number of graphene heating films 3 controlled and activated by the warm air control module 2 . For example, when the actual near-ground temperature difference and the actual indoor temperature difference increase, the number of graphene heating films 3 controlled by the warm air control module 2 to start working increases. When the actual near-ground temperature difference and the actual indoor temperature difference decrease, the number of graphene heating films 3 that are controlled by the warm air control module 2 to start working decreases.

It should be noted that the graphene down-air air conditioner can be used together with conventional air conditioners. Therefore, in the process of controlling heating, the graphene down-air air conditioner only needs to ensure the bottom temperature.

In this embodiment, as shown in FIG. 2 , the number of temperature sensors 1 is at least two, including: a proximity temperature sensor 11 and an indoor temperature sensor 12 . The near-earth temperature sensor 11 is used to measure the near-earth temperature. The indoor temperature sensor 12 is used to measure the indoor temperature.

When the heater control module 2 is in standby and power-on state, it can detect the temperature of the room at a height of 60cm above the ground through the near-ground temperature sensor 11, and feed it back to the display screen to prompt the temperature value. Green, and red when the temperature is higher than the set temperature. At the same time, the heater control module 2 can also detect the overall indoor temperature through the indoor temperature sensor 12, and can also feed back to the display screen to prompt the temperature value. The set temperature is displayed in red.

During the working process, the near-ground temperature sensor 11 detects the near-ground temperature, and the indoor temperature sensor 12 detects the indoor temperature. The actual near-ground temperature difference is calculated according to the difference between the set temperature and the near-ground temperature, and the actual indoor temperature difference is calculated according to the difference between the set temperature and the indoor temperature. In the heating process in winter, the indoor temperature is generally greater than or equal to the near-ground temperature, so during the whole process, the actual near-ground temperature difference is greater than or equal to the actual indoor temperature difference.

If the actual near-ground temperature difference is within the first near-ground preset temperature interval, and the actual indoor temperature difference is within the first near-ground predetermined temperature interval, the heater control module 2 controls the corresponding first near-ground predetermined temperature interval and the first indoor predetermined temperature The graphene heating film 3 in the number of intervals is heated.

If the actual near-ground temperature difference is within the first near-ground preset temperature interval, and the actual indoor temperature difference is within the second near-ground predetermined temperature interval, the heater control module 2 controls the corresponding first near-ground preset temperature interval and the second indoor preset temperature interval The graphene heating film 3 in the number of temperature intervals is heated.

Wherein, the upper threshold value of the second indoor preset temperature interval is smaller than the lower threshold value of the first indoor preset temperature interval, and the number of graphene heating films 3 corresponding to the second indoor preset temperature interval is less than that of the first indoor preset temperature interval. The number of graphene heating films 3.

If the actual near-earth temperature difference is within the second near-ground preset temperature interval, and the actual indoor temperature difference is within the second near-ground preset temperature interval, the heater control module 2 controls the corresponding second near-ground temperature interval and the second indoor preset temperature interval The graphene heating film 3 in the number of temperature intervals is heated.

Wherein, the upper threshold value of the second near-earth preset temperature zone is smaller than the lower limit threshold of the first near-ground preset temperature interval, and the number of graphene heating films 3 corresponding to the second near-ground preset temperature zone is less than that of the first near-ground preset temperature zone. Set the number of graphene heating films 3 corresponding to the temperature range.

If the actual near-ground temperature difference is within the second near-ground preset temperature interval, and the actual indoor temperature difference is within the third near-ground predetermined temperature interval, the heater control module 2 controls the corresponding second near-ground predetermined temperature interval and the third indoor preset temperature interval The graphene heating film 3 in the number of temperature intervals is heated.

Wherein, the upper threshold value of the third indoor preset temperature interval is smaller than the lower threshold value of the second indoor preset temperature interval, and the number of graphene heating films 3 corresponding to the third indoor preset temperature interval is less than that of the second indoor preset temperature interval. The number of graphene heating films 3.

If the actual near-ground temperature difference is within the third near-ground preset temperature interval, and the actual indoor temperature difference is within the third near-ground preset temperature interval, the heater control module 2 controls the corresponding third near-ground preset temperature interval and the third indoor preset temperature interval The graphene heating film 3 of the number of temperature intervals is heated.

Wherein, the upper limit threshold of the third near-earth preset temperature interval is smaller than the lower limit threshold of the second near-earth preset temperature interval, and the number of graphene heating films 3 corresponding to the third near-earth preset temperature interval is less than that of the second near-earth preset temperature interval. Set the number of graphene heating films 3 corresponding to the temperature range.

If the actual near-ground temperature difference is within the third near-ground preset temperature interval, and the actual indoor temperature difference is within the fourth near-ground predetermined temperature interval, the heater control module 2 controls the corresponding third near-ground preset temperature interval and the fourth indoor preset temperature interval The graphene heating film 3 of the number of temperature intervals is heated.

The upper threshold of the fourth indoor preset temperature interval is smaller than the lower threshold of the third indoor preset temperature interval, and the number of graphene heating films 3 corresponding to the fourth indoor preset temperature interval is less than that of the third indoor preset temperature interval. The number of graphene heating films 3.

If the actual near-ground temperature difference is within the fourth near-ground preset temperature interval, and the actual indoor temperature difference is within the fourth near-ground preset temperature interval, the heater control module 2 controls the corresponding fourth near-ground preset temperature interval and the fourth indoor preset temperature interval The graphene heating film 3 in the number of temperature intervals is heated.

Wherein, the upper limit threshold of the fourth near-earth preset temperature interval is smaller than the lower limit threshold of the third near-earth preset temperature interval, and the number of graphene heating films 3 corresponding to the fourth near-earth preset temperature interval is less than the third near-earth predetermined temperature interval. Set the number of graphene heating films 3 corresponding to the temperature range.

When the air conditioner is turned on or off, the heating function can operate simultaneously or independently. After the user selects the heating function, the main control module 4 sends a signal to the heating control module 2. After receiving the signal, the heating control module 2 can control all the temperature sensors 1 to start measuring the temperature of the room at the same time, and each temperature sensor 1 can obtain the proximity of the room. The ground temperature and the indoor temperature, the actual near ground temperature difference is obtained according to the difference between the set temperature and the near ground temperature, and the actual indoor temperature difference is obtained according to the difference between the set temperature and the indoor temperature. The warm air control module 2 controls and activates a corresponding number of graphene heating films 3 for heating according to the actual near-ground temperature difference and the actual indoor temperature difference.

In a specific embodiment, the ground temperature sensor 11 is used to detect the near ground temperature first, and the indoor temperature sensor 12 detects the indoor temperature. The actual near-ground temperature difference is calculated according to the difference between the set temperature and the near-ground temperature, and the actual indoor temperature difference is calculated according to the difference between the set temperature and the indoor temperature.

When the set temperature - the near-ground temperature = the actual near-ground temperature difference ≥ 15° C., the actual near-ground temperature difference corresponds to the three-layer graphene heating film 3 . Set temperature - indoor temperature = when the actual indoor temperature difference is ≥ 15°C, the actual indoor temperature difference corresponds to the 3-layer graphene heating film 3 . The warm air control module 2 controls the 6-layer graphene heating film 3 to heat.

When the actual near-ground temperature difference is greater than or equal to 15°C, the actual near-ground temperature difference corresponds to 3 layers of graphene heating film 3. When 10°C ≤ actual indoor temperature difference <15°C, the actual indoor temperature difference corresponds to 2 layers of graphene heating film 3. The warm air control module 2 controls the 5-layer graphene heating film 3 to heat.

When 10℃≤actual near-ground temperature difference<15℃, the actual near-ground temperature difference corresponds to 2 layers of graphene heating film 3. When 10℃≤actual indoor temperature difference<15℃, the actual indoor temperature difference corresponds to 2 layers of graphene heating film 3. The warm air control module 2 controls the 4-layer graphene heating film 3 to heat.

When 10℃≤actual near-ground temperature difference<15℃, the actual near-ground temperature difference corresponds to 2 layers of graphene heating film 3. When 5℃≤actual indoor temperature difference<10℃, the actual indoor temperature difference corresponds to 1 layer of graphene heating film 3. The warm air control module 2 controls the three-layer graphene heating film 3 to be heated.

When 5°C≤actual near-ground temperature difference<10°C, the actual near-ground temperature difference corresponds to 1 layer of graphene heating film3. When 5°C≤actual indoor temperature difference<10°C, the actual indoor temperature difference corresponds to 1 layer of graphene heating film at this time 3. The warm air control module 2 controls the two-layer graphene heating film 3 to heat.

When 5℃≤actual near-ground temperature difference<10℃, the actual near-ground temperature difference corresponds to 1 layer of graphene heating film 3. When 0℃≤actual indoor temperature difference<5℃, the actual indoor temperature difference corresponds to 0 layers of graphene heating film at this time 3. The warm air control module 2 controls a layer of graphene heating film 3 to be heated.

When 0℃≤actual near-ground temperature difference<5℃, the actual near-ground temperature difference corresponds to 0 layers of graphene heating film 3. When 0℃≤actual indoor temperature difference<5℃, the actual indoor temperature difference corresponds to 0-layer graphene heating film at this time 3. The warm air control module 2 controls the 0-layer graphene heating film 3 to heat.

In addition, if the air conditioner has a warm air forced mode, after the user selects, the near-ground temperature sensor 11 and the indoor temperature sensor 12 can be shielded, and the user can manually select the number of openings of the graphene heating film 3. For example, the 1st gear corresponds to 3 layers of graphene heating film 3, the 2nd gear corresponds to 5 layers of graphene heating film 3, and the 3rd gear corresponds to 8 layers of graphene heating film 3. It can be set according to the specific parameters of the graphene heating film 3 .

The present application also provides a graphene air outlet air conditioner, as shown in FIG. 2 , the graphene air outlet air conditioner includes: a main control module 4, a warm air control module 2, a multilayer graphene heating film 3 and a plurality of temperature Sensor 1. The main control module 4, each graphene heating film 3 and each temperature sensor 1 are all connected in circuit with the warm air control module 2, and each temperature sensor 1 is used to detect the near-ground temperature and the indoor temperature respectively, so that the warm air control module 2 is based on the actual The near ground temperature difference and the actual indoor temperature difference are controlled to start the corresponding number of graphene heating films 3 for heating; wherein, the actual near ground temperature difference and the actual indoor temperature difference are positively correlated with the number of graphene heating films 3 controlled and started by the warm air control module 2.

In addition, as shown in FIG. 3 , the graphene down-air air conditioner also includes: a WiFi control module 7 , a mobile phone client 6 and a cloud server 5 . The main control module 4 is connected in communication with the mobile phone client 6 through the WiFi control module 7 and the cloud server 5 . The heating function of the graphene under-air air conditioner can be turned on through the mobile phone client 6. The temperature sensor 1 can detect the temperature within 60cm at the bottom of the room in the standby and power-on state, and feed back to the mobile phone client 6 including the numerical value and the prompt color, such as blue temperature is low, green is suitable, and red temperature is high. The user can select display functions such as warm air through the operation interface of the mobile phone client 6 , and the mobile phone client 6 sends a signal to the cloud server 5 to the main control module 4 . In addition, the mobile phone client 6 comes with a one-key setting function. After the user chooses to turn it on, the graphene down-air air conditioner can automatically determine the indoor temperature and automatically turn on the heater.

In the graphene down-air air conditioner provided in this application, a heating layer for air heating and a radiant layer for heating at the bottom of the room are arranged in the graphene heating film, and according to the set temperature of the room, the near-ground temperature and the indoor temperature, obtain The actual near-ground temperature difference and the actual indoor temperature difference can be controlled to start a corresponding number of graphene heating films for heating according to the actual near-ground temperature difference and the actual indoor temperature difference, so that the graphene under-air air conditioner can change the air supply temperature at the bottom of the air conditioner according to the temperature change, At the same time, the method of radiation heat transfer is used to quickly increase the temperature of the bottom, so as to solve the problem that the temperature of the bottom of the room is too low when the cabinet air conditioner is heated in winter.

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present application, but not to limit them; although the present application has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that: it can still be The technical solutions described in the foregoing embodiments are modified, or some technical features thereof are equivalently replaced; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions in the embodiments of the present application.

Claims

A control method for a graphene under-ventilation air conditioner, characterized in that the graphene under-ventilation air conditioner is provided with a plurality of temperature sensors and a multi-layer graphene heating film; and each layer of the graphene heating film comprises: Heating layer for air heating and radiant layer for heating the bottom of the room;

The control method includes the following steps:

The temperature sensor detects the near-ground temperature and the indoor temperature, and obtains the actual near-ground temperature difference and the actual indoor temperature difference according to the set temperature, the near-ground temperature and the indoor temperature;

According to the actual near-ground temperature difference and the actual indoor temperature difference, a corresponding number of the graphene heating films are controlled to start heating; wherein, the actual near-ground temperature difference and the actual indoor temperature difference are positively correlated with the number of the graphene heating films that are started by control.
The control method of the graphene air-outlet air conditioner according to claim 1, wherein the step of controlling and starting a corresponding number of the graphene heating films to heat according to the actual near-ground temperature difference and the actual indoor temperature difference specifically includes:

If the actual near-earth temperature difference is within the first near-earth preset temperature interval, and when the actual indoor temperature difference is within the first near-earth preset temperature interval, control all the numbers corresponding to the first near-earth predetermined temperature interval and the first indoor predetermined temperature interval. The graphene heating film is heated.
The control method of the graphene-based air outlet air conditioner according to claim 2, wherein, if the actual near-ground temperature difference is in the first near-ground preset temperature interval, and the actual indoor temperature difference is in the second indoor preset temperature interval, Controlling the graphene heating film corresponding to the first near-ground preset temperature interval and the number of the second indoor preset temperature interval to heat;

Wherein, the upper threshold value of the second indoor preset temperature interval is smaller than the lower threshold value of the first indoor preset temperature interval, and the number of the graphene heating films corresponding to the second indoor preset temperature interval is less than that of the first indoor preset temperature interval The corresponding number of the graphene heating films.
The method for controlling the air-conditioning under graphene outlet according to claim 3, wherein, if the actual near-ground temperature difference is within the second near-ground preset temperature interval, and when the actual indoor temperature difference is within the second indoor preset temperature interval, Controlling the graphene heating film corresponding to the second near-ground preset temperature interval and the number of the second indoor preset temperature interval to heat;

Wherein, the upper threshold value of the second near-earth preset temperature zone is smaller than the lower limit threshold of the first near-ground preset temperature interval, and the number of the graphene heating films corresponding to the second near-ground preset temperature zone is less than that of the first near-ground temperature zone. The number of the graphene heating films corresponding to the preset temperature interval.
The method for controlling the air-conditioning under graphene outlet according to claim 4, wherein, if the actual near-ground temperature difference is in the second near-ground preset temperature interval, and the actual indoor temperature difference is in the third indoor preset temperature interval, Controlling the graphene heating film corresponding to the second near-ground preset temperature interval and the number of the third indoor preset temperature interval to heat;

Wherein, the upper threshold of the third indoor preset temperature interval is smaller than the lower threshold of the second indoor preset temperature interval, and the number of the graphene heating films corresponding to the third indoor preset temperature interval is less than the second indoor preset temperature interval The corresponding number of the graphene heating films.
The method for controlling the air-conditioning under graphene outlet according to claim 5, wherein if the actual near-ground temperature difference is in the third near-ground preset temperature interval, and the actual indoor temperature difference is in the third indoor preset temperature interval, Controlling the graphene heating film corresponding to the third near-ground preset temperature interval and the number of the third indoor preset temperature interval to heat;

Wherein, the upper threshold of the third near-earth preset temperature interval is smaller than the lower threshold of the second near-earth preset temperature interval, and the number of the graphene heating films corresponding to the third near-earth preset temperature interval is less than that of the second near-earth preset temperature interval The number of the graphene heating films corresponding to the preset temperature interval.
The method for controlling the air-conditioning under graphene outlet according to claim 6, wherein, if the actual near-ground temperature difference is in the third near-ground preset temperature interval, and the actual indoor temperature difference is in the fourth indoor preset temperature interval, Controlling the graphene heating film corresponding to the third near-ground preset temperature interval and the number of the fourth indoor preset temperature interval to heat;

Wherein, the upper threshold of the fourth indoor preset temperature interval is smaller than the lower threshold of the third indoor preset temperature interval, and the number of the graphene heating films corresponding to the fourth indoor preset temperature interval is less than the third indoor preset temperature interval The corresponding number of the graphene heating films.
The method for controlling the air-conditioning under graphene outlet according to claim 7, wherein, if the actual near-ground temperature difference is in the fourth near-ground preset temperature interval, and the actual indoor temperature difference is in the fourth indoor preset temperature interval, Controlling the graphene heating film corresponding to the number of the fourth near-ground preset temperature interval and the fourth indoor preset temperature interval to heat;

Wherein, the upper limit threshold of the fourth near-earth preset temperature interval is smaller than the lower limit threshold of the third near-earth preset temperature interval, and the number of the graphene heating films corresponding to the fourth near-earth preset temperature interval is less than that of the third near-earth preset temperature interval The number of the graphene heating films corresponding to the preset temperature interval.
A kind of graphene down-air air conditioner for carrying out the control method according to any one of claims 1-8, it is characterized in that, comprising:

a main control module, a warm air control module, a multilayered graphene heating film and a plurality of the temperature sensors;

The main control module, each of the graphene heating films and each of the temperature sensors are all connected with the heater control module circuit, and each of the temperature sensors is used to detect the near-ground temperature and the indoor temperature, so that the The warm air control module controls and starts a corresponding number of the graphene heating films to heat according to the actual near-ground temperature difference and the actual indoor temperature difference; wherein, the actual near-ground temperature difference and the actual indoor temperature difference and the warm air control module control to start The number of the graphene heating films is positively correlated.
The graphene under-ventilation air conditioner according to claim 9, wherein the graphene under-ventilation air conditioner further comprises: a WiFi control module, a mobile phone client and a cloud server; the main control module is controlled by the WiFi The module, the cloud server and the mobile phone client are connected in communication.