CN116608553A - Interconnection control method and device for air conditioner and humidity adjusting device and air conditioner - Google Patents

Abstract

The invention provides an interconnection control method and device of an air conditioner and a humidity adjusting device and the air conditioner. The interconnection control method of the air conditioner and the humidity adjusting device comprises the following steps: detecting an actual humidity in the second indoor environment; acquiring a first actual temperature of a first indoor environment and a second actual temperature of a second indoor environment under the condition that the actual humidity is greater than or equal to the preset humidity; determining the running state of the air conditioner according to the first actual temperature and the second actual temperature; and controlling the air conditioner to work according to the determined running state. According to the scheme, intelligent interconnection of the air conditioner and the humidity adjusting device can be realized, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved; according to actual conditions, the air conditioner and the humidity adjusting device are automatically adjusted, the situation that a user enters an environment with low temperature after the user has just washed is avoided, the comfort level and the physical health of the user are guaranteed, and the use experience of the user is improved.

Description

Interconnection control method and device for air conditioner and humidity adjusting device and air conditioner

Technical Field

The present invention relates to the field of intelligent control technologies, and in particular, to an interconnection control method and apparatus for an air conditioner and a humidity adjustment device, and an air conditioner.

Background

Along with the social development and the continuous improvement of the living standard of people, the requirements of people on the living quality are also higher. There is increasing emphasis on the comfort of living environments and the need for environment conditioning devices in everyday life or work is not limited to just traditional functions, but rather it is desirable that they can be adapted in various ways to the real-time needs of the user. The environment adjusting device can be a household appliance such as an air conditioner for adjusting the environment air parameters. Most of the current environmental conditioning devices do not well explain the concept of interconnection with other devices due to their own functional and structural limitations. For example, the current air conditioner and the humidity adjusting device in the indoor environment cannot be effectively interconnected, cannot be intelligently adjusted according to the actual states of the air conditioner and the humidity adjusting device, and the use experience of users is poor.

Disclosure of Invention

The intelligent interconnection device provided by the invention is used for realizing intelligent interconnection of the air conditioner and the humidity adjusting device, and effectively improving the intelligent degree.

A further object of the present invention is to automatically adjust the air conditioner and the humidity adjusting means according to the actual situation, thereby ensuring the comfort and physical health of the user.

In particular, the invention provides an interconnection control method of an air conditioner and a humidity adjusting device, wherein the air conditioner is arranged in a first indoor environment, the humidity adjusting device is arranged in a second indoor environment, and the method comprises the following steps: detecting an actual humidity in the second indoor environment; acquiring a first actual temperature of a first indoor environment and a second actual temperature of a second indoor environment under the condition that the actual humidity is greater than or equal to the preset humidity; determining the running state of the air conditioner according to the first actual temperature and the second actual temperature; and controlling the air conditioner to work according to the determined running state.

Optionally, before the step of obtaining the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment, further comprises: and controlling the humidity adjusting device to start a dehumidification function.

Optionally, the air conditioner is provided with a first temperature sensor configured to detect and obtain a first actual temperature; the humidity adjustment device is provided with a second temperature sensor configured to detect a second actual temperature and a humidity sensor configured to detect an actual humidity.

Optionally, the step of determining the operation state of the air conditioner according to the first actual temperature and the second actual temperature includes: calculating an actual temperature difference between the second actual temperature and the first actual temperature; judging whether the actual temperature difference is smaller than a preset temperature difference, wherein the preset temperature difference is a positive number; and if yes, determining that the current state of the air conditioner is unchanged.

Optionally, under the condition that the actual temperature difference value is greater than or equal to a preset temperature difference value, judging whether the air conditioner is started and operates in a refrigeration mode; and if so, controlling the air conditioner to close the refrigeration mode.

Optionally, when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is started and operates in an operation mode other than the refrigeration mode, and the current state of the air conditioner is controlled to be unchanged.

Optionally, when the actual temperature difference is greater than or equal to the preset temperature difference, judging whether the first actual temperature is less than the preset temperature or not under the condition that the air conditioner is closed; and if so, controlling the air conditioner to start a heating mode.

Optionally, when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is turned off, and the current state of the air conditioner is controlled to be unchanged under the condition that the first actual temperature is greater than or equal to the preset temperature.

According to another aspect of the present invention, there is also provided an interconnection control device of an air conditioner and a humidity adjusting device, including: the air conditioner comprises a processor and a memory, wherein a control program is stored in the memory, and the control program is used for realizing the interconnection control method of the air conditioner and the humidity adjusting device when being executed by the processor.

According to still another aspect of the present invention, there is also provided an air conditioner having the interconnection control device of the air conditioner and the humidity adjusting device.

According to the interconnection control method and device for the air conditioner and the humidity adjusting device and the air conditioner, the air conditioner is arranged in the first indoor environment, the humidity adjusting device is arranged in the second indoor environment, the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment are obtained by detecting the actual humidity in the second indoor environment and under the condition that the actual humidity is greater than or equal to the preset humidity, the running state of the air conditioner is determined according to the first actual temperature and the second actual temperature, the air conditioner is controlled to work according to the determined running state, intelligent interconnection of the air conditioner and the humidity adjusting device can be achieved, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved.

Further, according to the interconnection control method and device for the air conditioner and the humidity adjusting device and the air conditioner, when the actual humidity is larger than or equal to the preset humidity, the humidity adjusting device is controlled to start a dehumidification function, a first actual temperature of a first indoor environment and a second actual temperature of a second indoor environment are obtained, an actual temperature difference value between the second actual temperature and the first actual temperature is calculated, and when the actual temperature difference value is smaller than the preset temperature difference value, it is determined that the current state of the air conditioner is unchanged; when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is controlled to be closed in a refrigeration mode under the condition that the air conditioner is opened and operates in the refrigeration mode; when the actual temperature difference value is larger than or equal to the preset temperature difference value, the air conditioner is controlled to keep the current state unchanged under the condition that the air conditioner is started and operates in an operation mode other than the refrigeration mode; when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is closed, and when the first actual temperature is less than the preset temperature, the air conditioner is controlled to start a heating mode; the air conditioner is controlled to keep the current state unchanged under the condition that the actual temperature difference value is greater than or equal to the preset temperature difference value and the air conditioner is closed, the air conditioner and the humidity adjusting device are automatically adjusted according to the actual condition, the situation that a user enters an environment with very low temperature after the user has just washed is avoided, the comfort level and the physical health of the user are guaranteed, and the use experience of the user is improved.

The above, as well as additional objectives, advantages, and features of the present invention will become apparent to those skilled in the art from the following detailed description of a specific embodiment of the present invention when read in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter by way of example and not by way of limitation with reference to the accompanying drawings. The same reference numbers will be used throughout the drawings to refer to the same or like parts or portions. It will be appreciated by those skilled in the art that the drawings are not necessarily drawn to scale. In the accompanying drawings:

fig. 1 is a schematic view illustrating an interconnection control method of an air conditioner and a humidity control apparatus according to an embodiment of the present invention;

fig. 2 is a detailed flowchart of an interconnection control method of an air conditioner and a humidity control apparatus according to an embodiment of the present invention;

fig. 3 is a schematic block diagram of an interconnection control apparatus of an air conditioner and a humidity control apparatus according to an embodiment of the present invention; and

fig. 4 is a schematic configuration diagram of an interconnection control device of an air conditioner and a humidity control device according to an embodiment of the present invention.

Detailed Description

The embodiment firstly provides an interconnection control method of an air conditioner and a humidity adjusting device, intelligent interconnection of the air conditioner and the humidity adjusting device can be achieved, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved. Fig. 1 is a schematic view illustrating an interconnection control method of an air conditioner and a humidity control apparatus according to an embodiment of the present invention. As shown in fig. 1, the interconnection control method of the air conditioner and the humidity control apparatus may include the steps of:

step S102, detecting the actual humidity in the second indoor environment;

step S104, acquiring a first actual temperature of a first indoor environment and a second actual temperature of a second indoor environment under the condition that the actual humidity is greater than or equal to a preset humidity;

step S106, determining the running state of the air conditioner according to the first actual temperature and the second actual temperature;

and step S108, controlling the air conditioner to work according to the determined running state.

It should be noted that, the method of this embodiment and the following embodiments are described from the side of the interconnection control device of the air conditioner and the humidity adjusting device, that is, the control device performs the relevant steps. Moreover, the precondition for realizing the embodiments and the following embodiments is that the air conditioner and the humidity adjusting device are interconnected, specifically, an interconnection control device of the air conditioner and the humidity adjusting device may be disposed between the air conditioner and the humidity adjusting device, and signals sent by the air conditioner and the humidity adjusting device may be received by the control device and may be sent to the air conditioner and the humidity adjusting device. The control device can be additionally and independently arranged and also can be arranged inside the air conditioner.

The humidity adjusting device in this embodiment has an intelligent characteristic, just because it can send signals to the control device and can also receive signals sent by the control device. Specifically, this may be achieved by providing a controller on the humidity control apparatus. Similarly, the air conditioner may be provided with its own controller, so that it is possible to send a signal to the control device and receive a signal issued by the control device.

The air conditioner in this embodiment may be disposed in a first indoor environment, and the humidity adjusting device may be disposed in a second indoor environment. In a specific embodiment, the first indoor environment may be a living room or a bedroom, i.e. the air conditioner may be disposed in the living room or the bedroom; the second indoor environment may be a bathroom, i.e. the humidity adjusting means may be provided in the bathroom. The humidity adjusting means may include various types such as an exhaust fan, a bathroom air conditioner, a bathroom warmer, an electric heater, and the like.

Among the above steps, step S102 detects an actual humidity in the second indoor environment, wherein the humidity adjustment device may be provided with a humidity sensor configured to detect the actual humidity. The humidity condition of the second indoor environment can be accurately known through the actual humidity detected by the humidity sensor of the humidity adjusting device. In a specific embodiment, before detecting the actual humidity in the second indoor environment in step S102, it is also possible to: and receiving a trigger signal for starting an interconnection mode of the air conditioner and the humidity adjusting device.

After the interconnection mode is started, the air conditioner can send a trigger signal to the control device for the control device to receive, so that interconnection between the air conditioner and the humidity adjusting device is realized, and the states of the humidity adjusting device and the air conditioner are adjusted. In a preferred embodiment, a trigger signal sent by a display device, a voice device, a remote control, or a mobile terminal bound to the air conditioner may be received. Wherein the mobile terminal may be a smart device, such as a smart phone, tablet computer, etc., that is convenient to move. Alternatively, in other embodiments, the air conditioner may remain interconnected with the humidity control apparatus at all times, thus eliminating the need to receive a trigger signal to turn on the interconnection mode of the air conditioner with the humidity control apparatus prior to detecting the actual humidity in the second indoor environment.

Step S104 obtains a first actual temperature of the first indoor environment and a second actual temperature of the second indoor environment when the actual humidity is greater than or equal to the preset humidity, where the actual humidity is greater than or equal to the preset humidity, which indicates that the humidity in the second indoor environment is higher, and the user may be bathing. At this time, the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment are obtained, so that the temperature conditions of the first indoor environment and the second indoor environment can be known, and the air conditioner can be adjusted appropriately later.

Temperature sensors may be provided in both the first indoor environment and the second indoor environment to detect respective temperature conditions. Specifically, the air conditioner may be provided with a first temperature sensor configured to detect a first actual temperature. The humidity adjustment device may be provided with a second temperature sensor configured to detect a second actual temperature. That is, the humidity and temperature of the second indoor environment can be known by the humidity adjusting means in the second indoor environment.

In a preferred embodiment, the step S104 may be further performed before acquiring the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment: and controlling the humidity adjusting device to start a dehumidification function. Under the precondition that the actual humidity is greater than or equal to the preset humidity, the humidity of the second indoor environment is higher, and the comfort level of a user can be possibly influenced, for example, the user can feel more choked, at the moment, the humidity adjusting device is controlled to start the dehumidification function, so that the humidity of the second indoor environment can be effectively reduced, and the use experience of the user is improved. As mentioned above, the humidity adjusting means in the second indoor environment may include various types such as an exhaust fan, a bathroom air conditioner, a bathroom heater, an electric heater, etc., but may have a function of detecting humidity, temperature, and performing dehumidification regardless of the type.

The temperature of the first indoor environment and the temperature of the second indoor environment are detected through the first temperature sensor and the second temperature sensor, so that the real and accurate temperature conditions of the first indoor environment and the second indoor environment can be known. More importantly, an actual temperature difference between the second actual temperature and the first actual temperature can be obtained, and the temperature difference between the second indoor environment and the first indoor environment can be known through the actual temperature difference. The larger the actual temperature difference value is, the higher the second actual temperature of the second indoor environment is, and the lower the first actual temperature of the first indoor environment is; the smaller the actual temperature difference, the lower the second actual temperature of the second indoor environment, and the higher the first actual temperature of the first indoor environment.

Step S106 determines the operation state of the air conditioner according to the first actual temperature and the second actual temperature, and in fact, in a specific embodiment, the operation state of the air conditioner may be determined according to the actual temperature difference between the second actual temperature and the first actual temperature. For example, the actual temperature difference may be compared with a preset temperature difference, wherein the preset temperature difference is a positive number.

When the actual temperature difference is greater than or equal to the preset temperature difference, the temperature difference between the second indoor environment and the first indoor environment is larger, and the second actual temperature of the second indoor environment is higher than the first actual temperature of the first indoor environment. The user may get to the first indoor environment with lower temperature after the second indoor environment is bathed, and symptoms of common cold, headache, fever and other uncomfortable symptoms may occur, so that important consideration is needed, and the running state of the air conditioner is properly adjusted, so that the temperature of the first indoor environment where the air conditioner is located can be raised or not too low, for example, the closed refrigeration mode, the open heating mode and the like of the air conditioner can be determined.

If the actual temperature difference between the second actual temperature and the first actual temperature is smaller than the preset temperature difference, the temperature difference between the second indoor environment and the first indoor environment is not large, or the first actual temperature is higher than the second actual temperature, the user can get to the first indoor environment after the second indoor environment is bathed, and the influence of discomfort on the user can not be caused. In this case, therefore, no additional adjustment of the air conditioner is necessary to keep the current state unchanged.

Step S110 controls the air conditioner to work according to the determined running state, so that the running state of the air conditioner accords with the current actual situation. Specifically, in the case where it is determined that the current state of the air conditioner remains unchanged, the air conditioner may be controlled to keep the current state unchanged. In the case where it is determined that the air conditioner is in the off cooling mode, the air conditioner may be controlled to be in the off cooling mode. In the case of determining the air conditioner on heating mode, the air conditioner on heating mode may be controlled.

In summary, according to the interconnection control method of the air conditioner and the humidity adjusting device, the air conditioner is arranged in a first indoor environment, the humidity adjusting device is arranged in a second indoor environment, the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment are obtained by detecting the actual humidity in the second indoor environment and under the condition that the actual humidity is greater than or equal to the preset humidity, the running state of the air conditioner is determined according to the first actual temperature and the second actual temperature, the air conditioner is controlled to work according to the determined running state, intelligent interconnection of the air conditioner and the humidity adjusting device can be achieved, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved.

In some alternative embodiments, the further optimization and configuration of the above steps may enable the interconnected air conditioner and humidity control device to achieve a higher technical effect, and the following description is given in detail of the interconnection control method of the air conditioner and humidity control device of this embodiment in conjunction with the description of an alternative execution flow of this embodiment, where this embodiment is merely illustrative of the execution flow, and when implemented, the execution sequence and operation conditions of some steps may be modified according to the specific implementation requirement. Fig. 2 is a detailed flowchart of an interconnection control method of an air conditioner and a humidity control apparatus according to an embodiment of the present invention, the interconnection control method of the air conditioner and the humidity control apparatus comprising the steps of:

step S202, detecting the actual humidity in the second indoor environment;

step S204, judging whether the actual humidity is greater than the preset humidity, if so, executing step S208, otherwise, executing step S206;

step S206, controlling the air conditioner to keep the current state unchanged;

step S208, controlling the humidity adjusting device to start a dehumidification function;

step S210, acquiring a first actual temperature of a first indoor environment and a second actual temperature of a second indoor environment;

step S212, calculating an actual temperature difference between the second actual temperature and the first actual temperature;

step S214, judging whether the actual temperature difference is smaller than the preset temperature difference, if so, executing step S216, otherwise, executing step S218;

step S216, determining that the current state of the air conditioner is unchanged, and executing step S206;

step S218, judging whether the air conditioner is started and operated in a refrigeration mode, if so, executing step S220, and if not, executing step S222;

step S220, controlling the air conditioner to close the refrigeration mode;

step S222, judging whether the air conditioner is started and operates in an operation mode other than the refrigeration mode, if so, executing step S206, otherwise, executing step S224;

step S224, judging whether the first actual temperature is less than the preset temperature, if yes, executing step S226, otherwise, executing step S206;

step S226, controlling the air conditioner to start the heating mode.

Similar to the previous embodiment, the air conditioner of the present embodiment may be disposed in a first indoor environment, and the humidity adjusting apparatus may be disposed in a second indoor environment. In a specific embodiment, the first indoor environment may be a living room or a bedroom, i.e. the air conditioner may be disposed in the living room or the bedroom; the second indoor environment may be a bathroom, i.e. the humidity adjusting means may be provided in the bathroom. The humidity adjusting means may include various types such as an exhaust fan, a bathroom air conditioner, a bathroom warmer, an electric heater, and the like.

In the above steps, step S202 is first performed to detect the actual humidity in the second indoor environment, and in a specific embodiment, the humidity adjustment device may be provided with a humidity sensor configured to detect the actual humidity. The humidity condition of the second indoor environment can be accurately known through the actual humidity detected by the humidity sensor of the humidity adjusting device.

Then step S204 may be executed to determine whether the actual humidity is greater than the preset humidity, and step S206 may be executed to control the air conditioner to maintain the current state unchanged if the determination result in step S204 is no, i.e., if the actual humidity is less than or equal to the preset humidity. The actual humidity is less than or equal to the preset humidity, which indicates that the humidity of the second indoor environment is lower, and the user does not bathe in the second indoor environment. Therefore, the user can go to the first indoor environment from the second indoor environment, the air conditioner in the first indoor environment is not required to be additionally regulated, and the current state of the air conditioner is controlled to be unchanged.

The air conditioner is controlled to keep the current state unchanged, for example, the air conditioner is in a closed state, and the air conditioner can be controlled to keep the closed state unchanged. For another example, if the air conditioner is in an on state and is operated in the heating mode, the air conditioner may be controlled to remain in an on state and be operated in the heating mode. That is, no adjustment action is made to the air conditioner regardless of the current state of the air conditioner, so that the current state is maintained unchanged.

If the determination result in step S204 is yes, that is, if the actual humidity is greater than the preset humidity, step S208 may be executed to control the humidity adjustment device to start the dehumidification function. The actual humidity is greater than or equal to the preset humidity, which indicates that the humidity in the second indoor environment is higher, and the user may be bathing. The humidity of the second indoor environment is higher, and the comfort level of the user can be possibly influenced, for example, the user can feel more choked, and at the moment, the humidity adjusting device is controlled to start the dehumidification function, so that the humidity of the second indoor environment can be effectively reduced, and the use experience of the user is improved.

After the humidity control apparatus is controlled to turn on the dehumidification function in step S208, step S210 may be performed to obtain a first actual temperature of the first indoor environment and a second actual temperature of the second indoor environment, and the temperature conditions of the first indoor environment and the second indoor environment may be known, so that the air conditioner may be appropriately adjusted subsequently. Temperature sensors may be provided in both the first indoor environment and the second indoor environment, so that respective temperature conditions may be detected.

Specifically, the air conditioner may be provided with a first temperature sensor configured to detect a first actual temperature. The humidity adjustment device may be provided with a second temperature sensor configured to detect a second actual temperature. As mentioned above, the humidity adjusting means in the second indoor environment may include various types such as an exhaust fan, a bathroom air conditioner, a bathroom heater, an electric heater, etc., but may have a function of detecting humidity, temperature, and performing dehumidification regardless of the type.

After the first actual temperature and the second actual temperature are obtained, step S212 and step S214 may be performed, an actual temperature difference between the second actual temperature and the first actual temperature is calculated, whether the actual temperature difference is smaller than a preset temperature difference is determined, and if the determination result in step S214 is yes, that is, if the actual temperature difference is smaller than the preset temperature difference, step S216 may be performed, it is determined that the current state of the air conditioner is kept unchanged, and step S206 is performed, to control the air conditioner to keep the current state unchanged.

Wherein the preset temperature difference is a positive number. The difference between the actual temperature of the second actual temperature and the actual temperature of the first actual temperature is smaller than the preset temperature difference, which means that the temperature difference between the second indoor environment and the first indoor environment is not large, or the first actual temperature is higher than the second actual temperature, so that the user can get to the first indoor environment after the second indoor environment is bathed, and the influence of discomfort on the user can not be caused. Therefore, in this case, the air conditioner can be controlled without additional adjustment, and the current state of the air conditioner is kept unchanged.

Step S218 may be executed to determine whether the air conditioner is turned on and operated in the cooling mode if the determination result of step S214 is no, i.e., if the actual temperature difference is greater than or equal to the preset temperature difference, and step S220 may be executed to control the air conditioner to be turned off in the cooling mode if the determination result of step S218 is yes, i.e., if the air conditioner is turned on and operated in the cooling mode.

The actual temperature difference is greater than or equal to the preset temperature difference, which means that the temperature difference between the second indoor environment and the first indoor environment is greater, and the second actual temperature of the second indoor environment is higher than the first actual temperature of the first indoor environment. The user may get to the first indoor environment with lower temperature after having washed the second indoor environment, and symptoms such as cold, headache, fever, etc. may occur. At this time, the current state of the air conditioner needs to be further considered, and the air conditioner can be controlled to be in a closed refrigeration mode under the condition that the air conditioner is opened and operates in the refrigeration mode, so that the air conditioner stops providing cold energy to the first indoor environment, and the temperature of the first indoor environment can be raised or not too low.

If the determination result in step S218 is no, step S222 may be executed to further determine whether the air conditioner is turned on and operates in an operation mode other than the cooling mode, and if the determination result in step S222 is yes, that is, if the air conditioner is turned on and operates in an operation mode other than the cooling mode, step S206 may be executed to control the air conditioner to keep the current state unchanged.

Under the precondition that the actual temperature difference is greater than or equal to the preset temperature difference, the user finishes bathing and goes from the second indoor environment with higher temperature to the first indoor environment with lower temperature, and symptoms of common cold, headache, fever and the like can possibly appear. At this time, the current state of the air conditioner needs to be further considered, and in the case that the air conditioner is turned on and operates in an operation mode other than the cooling mode, the air conditioner cannot provide cooling capacity for the first indoor environment, for example, the air conditioner may only operate in the fresh air mode to improve the air quality of the first indoor environment, or the air conditioner may operate in the heating mode to heat the first indoor environment, that is, the current state of the air conditioner cannot reduce the temperature of the first indoor environment, so that the air conditioner can be controlled to keep the current state unchanged.

Since the air conditioner is either turned off or turned on, and is either operated in the cooling mode or in an operation mode other than the cooling mode, that is, the air conditioner is only in three states of being turned on and operated in the cooling mode, being turned on and operated in the operation mode other than the cooling mode, being turned off, according to the step execution sequence shown in fig. 2, in the case that the determination result of step S222 is no, it is possible to unambiguously determine that the air conditioner is turned off, and to execute step S224, and to determine whether the first actual temperature is less than the preset temperature, in the case that the determination result of step S224 is yes, that is, the first actual temperature is less than the preset temperature, to execute step S224, and to control the air conditioner to turn on the heating mode.

Under the precondition that the actual temperature difference is greater than or equal to the preset temperature difference, the user finishes bathing and goes from the second indoor environment with higher temperature to the first indoor environment with lower temperature, and symptoms of common cold, headache, fever and the like can possibly appear. At this time, the current state of the air conditioner needs to be further considered, the air conditioner is closed, and the first actual temperature is lower than the condition of the preset temperature, the first indoor environment is colder, and the air conditioner can be controlled to be opened to a heating mode at this time, so that the air conditioner can provide heat for the first indoor environment, the temperature of the first indoor environment is effectively improved, and the comfort level and the physical health of a user are guaranteed.

If the determination result in step S224 is no, that is, if the first actual temperature is greater than or equal to the preset temperature, step S206 is executed to control the air conditioner to keep the current state unchanged. Under the precondition that the actual temperature difference is greater than or equal to the preset temperature difference, the user finishes bathing and goes from the second indoor environment with higher temperature to the first indoor environment with lower temperature, and symptoms of common cold, headache, fever and the like can possibly appear. At this time, the current state of the air conditioner needs to be further considered, when the air conditioner is turned off and the first actual temperature is greater than or equal to the preset temperature, the first indoor environment is only reduced compared with the second indoor environment, but is not too cold, so that no additional adjustment is needed to be made to the air conditioner, and the air conditioner is controlled to keep the current state unchanged.

It should be noted that, although step S206 is executed after step S216 and step S222 are both yes and step S224 is no, the current status of the corresponding air conditioner may not be the same. For example, the current state of the air conditioner in step S216 may be any state, for example, off, on, and on may be any operation mode.

If the determination result in step S222 is yes, the current state of the air conditioner is the operation mode in which the air conditioner is turned on and operates outside the cooling mode, and then the air conditioner is controlled to keep the current state unchanged, i.e. the air conditioner is controlled to keep the air conditioner turned on and operate outside the cooling mode. If the result of the step S224 is no, the current state of the air conditioner is that the air conditioner is turned off, and then the air conditioner is controlled to keep the current state unchanged, i.e. the air conditioner is controlled to keep turned off.

In summary, in the interconnection control method of the air conditioner and the humidity control device of the embodiment, when the actual humidity is greater than or equal to the preset humidity, the humidity control device is controlled to start the dehumidification function, the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment are obtained, the actual temperature difference between the second actual temperature and the first actual temperature is calculated, and when the actual temperature difference is smaller than the preset temperature difference, it is determined that the current state of the air conditioner is kept unchanged; when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is controlled to be closed in a refrigeration mode under the condition that the air conditioner is opened and operates in the refrigeration mode; when the actual temperature difference value is larger than or equal to the preset temperature difference value, the air conditioner is controlled to keep the current state unchanged under the condition that the air conditioner is started and operates in an operation mode other than the refrigeration mode; when the actual temperature difference is greater than or equal to the preset temperature difference, the air conditioner is closed, and when the first actual temperature is less than the preset temperature, the air conditioner is controlled to start a heating mode; the air conditioner is controlled to keep the current state unchanged under the condition that the actual temperature difference value is greater than or equal to the preset temperature difference value and the air conditioner is closed, the air conditioner and the humidity adjusting device are automatically adjusted according to the actual condition, the situation that a user enters an environment with very low temperature after the user has just washed is avoided, the comfort level and the physical health of the user are guaranteed, and the use experience of the user is improved.

The present embodiment also provides an interconnection control device for an air conditioner and a humidity control apparatus, fig. 3 is a schematic block diagram of an interconnection control device 300 for an air conditioner and a humidity control apparatus according to an embodiment of the present invention, and fig. 4 is a schematic block diagram of an interconnection control device 300 for an air conditioner and a humidity control apparatus according to an embodiment of the present invention. As shown in fig. 3, the control device 300 may include: the processor 310 and the memory 320, the memory 320 stores a control program 321, and the control program 321 is used for implementing any of the interconnection control methods of the air conditioner and the humidity control device when executed by the processor 310.

As mentioned above, the interconnection control method of the air conditioner and the humidity control apparatus according to any of the above embodiments is described from the control apparatus 300 side, that is, the control apparatus 300 performs the relevant steps. In a specific embodiment, the control device 300 is in data connection with the air conditioner 100 and the humidity adjusting device 200, and may arrange a server, a cloud end, and other network side devices, acquire various data of a set space through a network, and remotely send instructions to the air conditioner 100 and the humidity adjusting device 200 to realize related adjustment.

The control device 300 may be various kinds of centralized control equipment, and is disposed in a set space and controls the air conditioner 100 and the humidity control device 200. The data connection manner of the control device 300 and the air conditioner 100 and the humidity adjusting device 200 includes, but is not limited to, wireless transmission, infrared transmission, ultrasonic transmission, and the like. In some embodiments, the control device 300 may also be disposed inside the air conditioner 100 as a part of the air conditioner 100, and be in data connection with a controller of the air conditioner 100, for example, the air conditioner 100 is internally provided with a dedicated control device 300, and cooperates with a controller dedicated to performing component control.

The processor 310 may be a central processing unit (central processing unit, CPU for short), or a digital processing unit, or the like. The processor 310 transmits and receives data through a communication interface. The memory 320 is used to store programs executed by the processor 310. Memory 320 is any medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer, and may be a combination of multiple memories 320. The control program 321 described above may be downloaded from a computer readable storage medium to a corresponding computing/processing device or downloaded via a network (e.g., the internet, a local area network, a wide area network, and/or a wireless network) and installed to the control apparatus 300.

The present embodiment also provides an air conditioner 100, which may have the interconnection control device 300 of the air conditioner and the humidity adjusting device of the above embodiment. That is, the control device 300 may not be provided outside the air conditioner 100, but may be provided on the air conditioner 100. The control device 300 and the controller of the air conditioner 100 may be the same component, i.e. the control device 300 is used for controlling the operation of the air conditioner 100 itself, and also for receiving the signal of the humidity control device 200 and sending the signal to the humidity control device 200.

Alternatively, the controller 300 and the controller of the air conditioner 100 may be different components, that is, the controller is used to control the operation of the air conditioner 100, and the controller 300 is used to receive the signal of the humidity control apparatus 200 and send the signal to the humidity control apparatus 200. The control device 300 also communicates with the controller to receive signals from and send signals to the controller of the air conditioner 100 itself.

As shown in fig. 4, the air conditioner 100 may be disposed in a first indoor environment, and the humidity adjusting apparatus 200 may be disposed in a second indoor environment. In a specific embodiment, the first indoor environment may be a living room or a bedroom, i.e., the air conditioner 100 may be disposed in the living room or the bedroom; the second indoor environment may be a bathroom, i.e., the humidity adjusting apparatus 200 may be provided in the bathroom. The humidity adjustment device 200 may include various types such as an exhaust fan, a bathroom air conditioner, a bathroom warmer, an electric heater, and the like.

The air conditioner 100 may be provided with a first temperature sensor configured to detect a first actual temperature of the first indoor environment. The humidity adjustment device 200 may be provided with a second temperature sensor configured to detect a second actual temperature of the second indoor environment and a humidity sensor configured to detect an actual humidity of the second indoor environment. That is, the humidity control apparatus 200 may have a function of detecting humidity and temperature, and the humidity control apparatus 200 may perform dehumidification.

The air conditioner 100 of the embodiment can realize intelligent interconnection with the humidity adjusting device 200, provides a scene of intelligent household electrical appliance interconnection, and effectively improves the intelligent degree; according to the actual conditions, the air conditioner 100 and the humidity adjusting device 200 are automatically adjusted, so that the situation that a user enters an environment with low temperature after the user has just washed is avoided, the comfort level and the physical health of the user are guaranteed, and the use experience of the user is improved.

In the description of the present embodiment, a description referring to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

By now it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been shown and described herein in detail, many other variations or modifications of the invention consistent with the principles of the invention may be directly ascertained or inferred from the present disclosure without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and deemed to cover all such other variations or modifications.

Claims (10)

1. An interconnection control method of an air conditioner and a humidity control device, wherein the air conditioner is arranged in a first indoor environment, the humidity control device is arranged in a second indoor environment, and the method comprises:

detecting an actual humidity in the second indoor environment;

acquiring a first actual temperature of the first indoor environment and a second actual temperature of the second indoor environment under the condition that the actual humidity is greater than or equal to a preset humidity;

determining an operating state of the air conditioner according to the first actual temperature and the second actual temperature; and

and controlling the air conditioner to work according to the determined running state.

2. The method of claim 1, wherein prior to the step of obtaining the first actual temperature of the first indoor environment and the second actual temperature of the second indoor environment further comprises:

and controlling the humidity adjusting device to start a dehumidification function.

3. The method of claim 1, wherein,

the air conditioner is provided with a first temperature sensor configured to detect the first actual temperature;

the humidity adjustment device is provided with a second temperature sensor configured to detect the second actual temperature and a humidity sensor configured to detect the actual humidity.

4. The method of claim 1, wherein determining the operating state of the air conditioner based on the first actual temperature and the second actual temperature comprises:

calculating an actual temperature difference between the second actual temperature and the first actual temperature;

judging whether the actual temperature difference is smaller than a preset temperature difference, wherein the preset temperature difference is a positive number; and

if yes, determining that the current state of the air conditioner is unchanged.

5. The method of claim 4, wherein,

judging whether the air conditioner is started and operates in a refrigeration mode under the condition that the actual temperature difference value is larger than or equal to the preset temperature difference value; and

if yes, the air conditioner is controlled to be closed in the refrigeration mode.

6. The method of claim 5, wherein,

and under the condition that the actual temperature difference value is larger than or equal to the preset temperature difference value and the air conditioner is started and operates in an operation mode other than the refrigeration mode, controlling the air conditioner to keep the current state unchanged.

7. The method of claim 6, wherein,

judging whether the first actual temperature is smaller than a preset temperature or not under the condition that the actual temperature difference is larger than or equal to the preset temperature difference and the air conditioner is closed; and

if yes, controlling the air conditioner to start a heating mode.

8. The method of claim 7, wherein,

and when the actual temperature difference value is greater than or equal to the preset temperature difference value, the air conditioner is closed, and the first actual temperature is greater than or equal to the preset temperature, and the air conditioner is controlled to keep the current state unchanged.

9. An interconnection control device of an air conditioner and a humidity adjusting device, comprising: a processor and a memory, wherein the memory stores a control program, and the control program is used for realizing the interconnection control method of the air conditioner and the humidity control device according to any one of claims 1 to 8 when executed by the processor.

10. An air conditioner having the interconnection control device of the air conditioner and the humidity control device according to claim 9.