CN116147177A

CN116147177A - Interconnection control method and device of air conditioner and smoke exhaust ventilator and air conditioner

Info

Publication number: CN116147177A
Application number: CN202310133389.6A
Authority: CN
Inventors: 张晓斌; 唐高明
Original assignee: Qingdao Haier Air Conditioner Gen Corp Ltd; Qingdao Haier Air Conditioning Electric Co Ltd; Haier Smart Home Co Ltd
Current assignee: Qingdao Haier Air Conditioner Gen Corp Ltd; Qingdao Haier Air Conditioning Electric Co Ltd; Haier Smart Home Co Ltd
Priority date: 2023-02-17
Filing date: 2023-02-17
Publication date: 2023-05-23

Abstract

The invention provides an interconnection control method and device of an air conditioner and a smoke exhaust ventilator and the air conditioner. The interconnection control method of the air conditioner and the smoke exhaust ventilator comprises the following steps: receiving a trigger signal of an air conditioner and a smoke exhaust ventilator in an interconnection starting mode; detecting a first humidity value of a first indoor environment and a second humidity value of a second indoor environment; determining the operation states of the air conditioner and the smoke exhaust ventilator according to the first humidity value and the second humidity value; and controlling the air conditioner and the smoke exhaust ventilator to work according to the determined running state. According to the scheme, intelligent interconnection of the air conditioner and the smoke exhaust ventilator can be realized, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved; according to the actual humidity conditions of the first indoor environment and the second indoor environment, the air conditioner and the smoke exhaust ventilator are automatically adjusted, the overall comfort level of the indoor environments is guaranteed, and the use experience of users is improved.

Description

Interconnection control method and device of air conditioner and smoke exhaust ventilator and air conditioner

Technical Field

The invention relates to the technical field of intelligent control, in particular to an interconnection control method and device of an air conditioner and a smoke exhaust ventilator and the 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, current air conditioners and range hoods in indoor environments cannot be effectively interconnected, cannot be intelligently adjusted according to actual states of the air conditioners and the range hoods, and 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 smoke exhaust ventilator, and effectively improving the intelligent degree.

A further object of the present invention is to automatically adjust the air conditioner and the range hood according to the actual humidity of the indoor environment, thereby ensuring the comfort of the indoor environment.

In particular, the invention provides an interconnection control method of an air conditioner and a smoke exhaust ventilator, wherein the air conditioner is arranged in a first indoor environment, the smoke exhaust ventilator is arranged in a second indoor environment, the first indoor environment is communicated with the second indoor environment, and the method comprises the following steps: receiving a trigger signal of an air conditioner and a smoke exhaust ventilator in an interconnection starting mode; detecting a first humidity value of a first indoor environment and a second humidity value of a second indoor environment; determining the operation states of the air conditioner and the smoke exhaust ventilator according to the first humidity value and the second humidity value; and controlling the air conditioner and the smoke exhaust ventilator to work according to the determined running state.

Optionally, the step of determining the operating states of the air conditioner and the range hood according to the first humidity value and the second humidity value includes: judging whether the first humidity value and the second humidity value are both greater than or equal to a preset humidity value; and if so, determining an air conditioner starting dehumidification mode, and starting the smoke exhaust ventilator.

Optionally, under the condition that the first humidity value and the second humidity value are smaller than the preset humidity value, determining that the air conditioner is closed to dehumidify the mode, and closing the range hood.

Optionally, under the condition that the first humidity value is greater than or equal to a preset humidity value and the second humidity value is less than the preset humidity value, determining that the air conditioner is in a dehumidification mode, and closing the smoke exhaust ventilator.

Optionally, under the condition that the second humidity value is greater than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value, determining that the air conditioner is in a closed dehumidification mode, and opening the smoke exhaust ventilator.

Optionally, after determining the air conditioner off dehumidification mode and the range hood is opened, the method further comprises: the air conditioner is controlled to be closed in a dehumidification mode, and the smoke exhaust ventilator is controlled to be opened; detecting a third humidity value of the outdoor environment; judging whether the third humidity value is smaller than a preset humidity value or not; and if so, controlling the air conditioner to start a fresh air mode.

Optionally, under the condition that the third humidity value is greater than or equal to the preset humidity value, the air conditioner is controlled to keep the current state unchanged.

Optionally, the step of receiving a trigger signal for opening the interconnection mode of the air conditioner and the range hood comprises: and receiving a trigger signal sent by a display device, a voice device, a remote controller or a mobile terminal bound with the air conditioner.

According to another aspect of the present invention, there is also provided an interconnection control apparatus of an air conditioner and a range hood, comprising: the device 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 smoke exhaust ventilator when being executed by the processor.

According to still another aspect of the present invention, there is also provided an air conditioner having the above-mentioned interconnection control device of the air conditioner and the range hood.

According to the interconnection control method and device for the air conditioner and the smoke exhaust ventilator and the air conditioner, the air conditioner is arranged in the first indoor environment, the smoke exhaust ventilator is arranged in the second indoor environment, the first indoor environment is communicated with the second indoor environment, the first humidity value of the first indoor environment and the second humidity value of the second indoor environment are detected by receiving the trigger signal of the air conditioner and the smoke exhaust ventilator for starting an interconnection mode, the running states of the air conditioner and the smoke exhaust ventilator are determined according to the first humidity value and the second humidity value, the air conditioner and the smoke exhaust ventilator are controlled to work according to the determined running states, intelligent interconnection of the air conditioner and the smoke exhaust ventilator 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 of the air conditioner and the smoke exhaust ventilator and the air conditioner, the opening dehumidification mode of the air conditioner is determined and the smoke exhaust ventilator is opened under the condition that the first humidity value and the second humidity value are larger than or equal to the preset humidity value; under the condition that the first humidity value and the second humidity value are smaller than the preset humidity value, determining that the air conditioner is closed to dehumidify the mode, and closing the smoke exhaust ventilator; when the first humidity value is larger than or equal to the preset humidity value and the second humidity value is smaller than the preset humidity value, determining that the air conditioner is in a dehumidification mode, and closing the smoke exhaust ventilator; when the second humidity value is larger than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value, determining that the air conditioner is in a closed dehumidification mode, and opening the smoke exhaust ventilator; after the control air conditioner closes the dehumidification mode, and the smoke ventilator opens, detect the third humidity value of outdoor environment, under the condition that the third humidity value is less than preset humidity value, control air conditioner opens the new trend mode for indoor environment realizes malleation, promotes smoke ventilator's dehumidification efficiency, carries out automatically regulated to air conditioner and smoke ventilator according to the actual humidity condition of first indoor environment and second indoor environment, guarantees indoor environment's whole comfort level, promotes user's use experience.

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 of an interconnection control method of an air conditioner and a range hood 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 hood 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 hood according to an embodiment of the present invention; and

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

Detailed Description

The embodiment firstly provides an interconnection control method of an air conditioner and a smoke exhaust ventilator, intelligent interconnection of the air conditioner and the smoke exhaust ventilator can be achieved, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved. Fig. 1 is a schematic diagram of an interconnection control method of an air conditioner and a range hood according to an embodiment of the present invention. As shown in fig. 1, the method for controlling the interconnection between the air conditioner and the range hood may include the following steps:

step S102, receiving a trigger signal of an interconnection mode of an air conditioner and a smoke exhaust ventilator;

step S104, detecting a first humidity value of a first indoor environment and a second humidity value of a second indoor environment;

step S106, determining the operation states of the air conditioner and the smoke exhaust ventilator according to the first humidity value and the second humidity value;

and S108, controlling the air conditioner and the smoke exhaust ventilator to work according to the determined running state.

It should be noted that, the methods of the present embodiment and the following embodiments are described from the side of the interconnection control device of the air conditioner and the range hood, that is, the control device performs the relevant steps. In addition, the premise of realizing the embodiment and the following embodiment scheme is that the air conditioner and the smoke exhaust ventilator are interconnected, specifically, an interconnection control device of the air conditioner and the smoke exhaust ventilator can be arranged between the air conditioner and the smoke exhaust ventilator, and signals sent by the air conditioner and the smoke exhaust ventilator can be received through the control device and can be sent to the air conditioner and the smoke exhaust ventilator. The control device can be additionally and independently arranged and also can be arranged inside the air conditioner.

The range hood in this embodiment has the intelligent characteristic, just because it can send the signal to controlling means just as mentioned above, can receive the signal that controlling means issued again. Specifically, the control device can be realized by arranging a controller on the smoke exhaust ventilator. 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 range hood may be disposed in a second indoor environment. And the first indoor environment and the second indoor environment are communicated. Specifically, the first indoor environment and the second indoor environment may be directly communicated, or a door body may be disposed between the first indoor environment and the second indoor environment, and under the condition that the door body is opened, the first indoor environment and the second indoor environment are communicated. In a specific embodiment, the first indoor environment in which the air conditioner is located may be a living room, and the second indoor environment in which the range hood is located may be a kitchen. If the kitchen is an open kitchen, it may be in direct communication with the living room. Or a door body can be arranged between the kitchen and the living room, and the living room is communicated with the kitchen under the condition that the door body is opened.

In the above steps, step S102 receives a trigger signal for opening the interconnection mode of the air conditioner and the range hood, and after the interconnection mode is opened, the air conditioner may send the trigger signal to the control device for the control device to receive, thereby realizing interconnection of the air conditioner and the range hood, and adjusting the states of the range hood and the air conditioner. In a specific 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.

Step S104 detects a first humidity value of the first indoor environment and a second humidity value of the second indoor environment, where both the first indoor environment and the second indoor environment may be provided with humidity sensors to detect respective humidity conditions. Specifically, a humidity sensor of the first indoor environment may be disposed on the air conditioner for detecting a first humidity value. The humidity sensor of the second indoor environment may be disposed on the range hood for detecting a second humidity value. The humidity sensor is used for detecting the humidity of the first indoor environment and the second indoor environment, so that the real and accurate humidity conditions of the first indoor environment and the second indoor environment can be known.

Step S106 is to determine the operation states of the air conditioner and the smoke exhaust ventilator according to the first humidity value and the second humidity value, and in fact, the humidity conditions of the first indoor environment and the second indoor environment are judged without adjusting through the air conditioner and the smoke exhaust ventilator. In a specific embodiment, the determining, in step S106, the operation states of the air conditioner and the range hood according to the first humidity value and the second humidity value may specifically include: judging whether the first humidity value and the second humidity value are both greater than or equal to a preset humidity value, and determining that the air conditioner is started in a dehumidification mode and the smoke exhaust ventilator is started under the condition that the judgment result is yes, namely the first humidity value and the second humidity value are both greater than or equal to the preset humidity value.

The first humidity value and the second humidity value are both greater than or equal to the preset humidity value, so that the humidity of the first indoor environment and the humidity of the second indoor environment are higher, the humidity needs to be reduced in time, and therefore the dehumidification mode can be started through the air conditioner, and the range hood is started to reduce the humidity of the first indoor environment and the humidity of the second indoor environment. Specifically, the air conditioner is in a dehumidification mode, and at the moment, the fan of the indoor unit runs slowly, so that moisture in air is condensed into liquid to achieve the dehumidification effect, and the humidity of the first indoor environment is mainly reduced. The smoke ventilator is opened, so that moist air can be discharged outdoors, the indoor air pressure is low, and the outdoor air automatically enters to achieve the dehumidification effect, so that the humidity of a second indoor environment is mainly reduced.

And under the condition that the first humidity value and the second humidity value are smaller than the preset humidity value, the air conditioner can be determined to be closed in a dehumidification mode, and the smoke exhaust ventilator is closed. The first humidity value and the second humidity value are smaller than the preset humidity value, so that the humidity of the first indoor environment and the humidity of the second indoor environment are not high, the humidity is not required to be reduced, the air conditioner closing dehumidification mode can be determined, the smoke exhaust ventilator is closed, and electric energy is effectively saved.

And under the condition that the first humidity value is larger than or equal to the preset humidity value and the second humidity value is smaller than the preset humidity value, the air conditioner can be determined to be in a dehumidification mode, and the smoke exhaust ventilator is determined to be in a closed state. The first humidity value is larger than or equal to the preset humidity value, and the second humidity value is smaller than the preset humidity value, which indicates that the humidity of the first indoor environment is higher and needs to be reduced in time; the second indoor environment is not high in humidity, and the humidity does not need to be reduced. Therefore, the dehumidification mode can be started through the air conditioner, and the humidity of the first indoor environment is mainly reduced; the smoke ventilator is closed, need not to adjust the humidity of second indoor environment, effectively practices thrift the electric energy.

And under the condition that the second humidity value is larger than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value, the air conditioner can be determined to be in a closed dehumidification mode, and the smoke exhaust ventilator is opened. The second humidity value is larger than or equal to the preset humidity value, and the first humidity value is smaller than the preset humidity value, which indicates that the humidity of the first indoor environment is not high, and the humidity does not need to be reduced; the second indoor environment has higher humidity and needs to be timely reduced. Therefore, the range hood can be opened to mainly reduce the humidity of the second indoor environment; the air conditioner is turned off in the dehumidification mode without adjusting the humidity of the second indoor environment.

It should be noted that, the preset humidity value can be set according to actual conditions, and can be a humidity value that a user feels comfortable, and when the humidity of the indoor environment is greater than or equal to the preset humidity value, the humidity in the indoor environment can be considered to be higher, bacteria and mold are easy to grow in the humid environment, so that the physical health of the user is threatened, and the user easily feels difficult and suffocating to dissipate heat. Therefore, once the humidity of the indoor environment is larger than or equal to a preset humidity value, dehumidification can be performed in time, the humidity is reduced, and the comfort level and the physical health of a user are guaranteed.

In addition, because the first indoor environment is communicated with the second indoor environment, the first indoor environment is mainly reduced in humidity while the dehumidifying mode is started through the air conditioner, and a certain dehumidifying effect can be achieved on the second indoor environment in practice. Similarly, when the range hood is opened to mainly reduce the humidity of the second indoor environment, a certain dehumidification effect can be achieved on the first indoor environment. The humidity of two indoor environments is adjusted by the air conditioner or the smoke exhaust ventilator independently, and electric energy can be effectively saved.

Step S108, controlling the air conditioner and the smoke exhaust ventilator to work according to the determined running states, so that the running states of the air conditioner and the smoke exhaust ventilator accord with the current actual conditions of the first indoor environment and the second indoor environment. Specifically, when the air conditioner is determined to be in the on dehumidification mode and the smoke exhaust ventilator is determined to be in the on dehumidification mode, the air conditioner can be controlled to be in the on dehumidification mode and the smoke exhaust ventilator can be controlled to be in the on state. And under the condition that the air conditioner is determined to be in a closed dehumidification mode and the smoke exhaust ventilator is closed, the air conditioner can be controlled to be in the closed dehumidification mode, and the smoke exhaust ventilator is closed. And under the condition that the air conditioner is determined to be in a dehumidification mode and the smoke exhaust ventilator is determined to be in a closed state, the air conditioner can be controlled to be in the dehumidification mode, and the smoke exhaust ventilator is controlled to be in the closed state. And under the condition that the air conditioner is determined to be in a closed dehumidification mode and the smoke exhaust ventilator is opened, the air conditioner can be controlled to be in the closed dehumidification mode, and the smoke exhaust ventilator is opened.

In a word, according to the interconnection control method of the air conditioner and the smoke exhaust ventilator, through receiving the trigger signal of the opening interconnection mode of the air conditioner and the smoke exhaust ventilator, the first humidity value of the first indoor environment and the second humidity value of the second indoor environment are detected, the running states of the air conditioner and the smoke exhaust ventilator are determined according to the first humidity value and the second humidity value, the air conditioner and the smoke exhaust ventilator are controlled to work according to the determined running states, intelligent interconnection of the air conditioner and the smoke exhaust ventilator can be achieved, an intelligent household appliance interconnection scene is provided, and the intelligent degree is effectively improved.

In some optional embodiments, the further optimization and configuration of the above steps may enable the interconnected air conditioner and smoke ventilator to achieve a higher technical effect, and the following description is given in detail on the interconnection control method of the air conditioner and smoke ventilator of this embodiment in combination with the description of an optional execution flow of this embodiment, where this embodiment is merely illustrative of the execution flow, and when implementing, the execution sequence and the operation condition 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 range hood according to an embodiment of the present invention, the interconnection control method of the air conditioner and the range hood comprising the steps of:

step S202, receiving a trigger signal for starting an interconnection mode sent by a display device, a voice device, a remote controller or a mobile terminal bound with the air conditioner of the air conditioner;

step S204, detecting a first humidity value of a first indoor environment and a second humidity value of a second indoor environment;

step S206, judging whether the first humidity value and the second humidity value are both greater than or equal to a preset humidity value, if so, executing step S208, otherwise, executing step S212;

step S208, determining a dehumidifying mode of an air conditioner, and starting a smoke exhaust ventilator;

step S210, controlling the air conditioner to start a dehumidification mode, and starting the smoke exhaust ventilator;

step S212, judging whether the first humidity value and the second humidity value are smaller than the preset humidity value, if yes, executing step S214, otherwise, executing step S218;

step S214, determining a dehumidifying mode of closing the air conditioner, and closing the smoke exhaust ventilator;

step S216, controlling the air conditioner to close a dehumidification mode, and closing the smoke exhaust ventilator;

step S218, judging whether the first humidity value is larger than or equal to a preset humidity value and the second humidity value is smaller than the preset humidity value, if yes, executing step S220, and if not, executing step S224;

step S220, determining an air conditioner on dehumidification mode, and closing a smoke exhaust ventilator;

step S222, controlling the air conditioner to start a dehumidification mode, and closing the smoke exhaust ventilator;

step S224, determining a dehumidifying mode of the air conditioner, and opening the smoke exhaust ventilator;

step S226, controlling the air conditioner to be closed in a dehumidification mode, and opening the smoke exhaust ventilator;

step S228, detecting a third humidity value of the outdoor environment;

step S230, judging whether the third humidity value is smaller than the preset humidity value, if yes, executing step S232, otherwise, executing step S234;

step S232, controlling an air conditioner to start a fresh air mode;

in step S234, the air conditioner is controlled to maintain the current state unchanged.

Similar to the previous embodiment, the air conditioner in this embodiment may be disposed in a first indoor environment, and the range hood may be disposed in a second indoor environment. And the first indoor environment and the second indoor environment are communicated. Specifically, the first indoor environment and the second indoor environment may be directly communicated, or a door body may be disposed between the first indoor environment and the second indoor environment, and under the condition that the door body is opened, the first indoor environment and the second indoor environment are communicated.

In the above steps, step S202 and step S204 are first executed, a trigger signal for turning on an interconnection mode sent by a display device, a voice device, a remote controller or a mobile terminal bound to the air conditioner is received, and a first humidity value of a first indoor environment and a second humidity value of a second indoor environment are detected. Humidity sensors can be arranged in the first indoor environment and the second indoor environment to detect and obtain a first humidity value of the first indoor environment and a second humidity value of the second indoor environment.

After detecting the first humidity value of the first indoor environment and the second humidity value of the second indoor environment in step S204, step S206 may be executed to determine whether the first humidity value and the second humidity value are both greater than or equal to the preset humidity value, and if yes in step S206, that is, if the first humidity value and the second humidity value are both greater than or equal to the preset humidity value, step S208 is executed to determine that the air conditioner is turned on to dehumidify the air conditioner, and then step S210 is executed to control the air conditioner to turn on to dehumidify the air conditioner and turn on the air extractor.

If the determination result in step S206 is no, step S212 is executed to further determine whether the first humidity value and the second humidity value are both less than the preset humidity value, and if the determination result in step S212 is yes, that is, if the first humidity value and the second humidity value are both less than the preset humidity value, step S214 is executed to determine that the air conditioner is turned off in the dehumidification mode, and then step S216 is executed to control the air conditioner to be turned off in the dehumidification mode and the range hood to be turned off.

The first humidity value and the second humidity value are smaller than the preset humidity value, so that the humidity of the first indoor environment and the humidity of the second indoor environment are not high, the humidity is not required to be reduced, the air conditioner can be controlled to be closed, the dehumidifying mode of the smoke exhaust ventilator can be controlled, and electric energy is effectively saved.

If the determination result in step S212 is no, step S218 is executed to further determine whether the first humidity value is greater than or equal to the preset humidity value and the second humidity value is less than the preset humidity value, and if the determination result in step S218 is yes, that is, if the first humidity value is greater than or equal to the preset humidity value and the second humidity value is less than the preset humidity value, step S220 is executed to determine that the air conditioner is turned on and the range hood is turned off, and then step S222 is executed to control the air conditioner to turn on and the range hood to be turned off.

The first humidity value is larger than or equal to the preset humidity value, and the second humidity value is smaller than the preset humidity value, which indicates that the humidity of the first indoor environment is higher and needs to be reduced in time; the second indoor environment is not high in humidity, and the humidity does not need to be reduced. Therefore, the dehumidification mode can be started through the air conditioner, and the humidity of the first indoor environment is mainly reduced; the smoke ventilator is closed, need not to adjust the humidity of second indoor environment, effectively practices thrift the electric energy.

Because the first humidity value, the second humidity value and the preset humidity value are relatively large, the following four conditions exist: the first humidity value and the second humidity value are both larger than or equal to a preset humidity value, the first humidity value and the second humidity value are both smaller than the preset humidity value, the first humidity value is larger than or equal to the preset humidity value and the second humidity value is smaller than the preset humidity value, the second humidity value is larger than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value. Therefore, according to the execution sequence of the steps shown in fig. 2, when the determination result in step S218 is no, it can be accurately determined that the second humidity value is greater than or equal to the preset humidity value and the first humidity value is less than the preset humidity value, and step S224 is performed to determine that the air conditioner is turned off and the range hood is turned on, and then step S226 is performed to control the air conditioner to be turned off and the range hood to be turned on.

The second humidity value is larger than or equal to the preset humidity value, and the first humidity value is smaller than the preset humidity value, which indicates that the humidity of the first indoor environment is not high, and the humidity does not need to be reduced; the second indoor environment has higher humidity and needs to be timely reduced. Therefore, the range hood can be opened to mainly reduce the humidity of the second indoor environment; the air conditioner is turned off in the dehumidification mode without adjusting the humidity of the second indoor environment.

It should be noted that, because the first indoor environment is communicated with the second indoor environment, when the dehumidification mode is started by the air conditioner to mainly reduce the humidity of the first indoor environment, a certain dehumidification effect can be actually achieved on the second indoor environment. Similarly, when the range hood is opened to mainly reduce the humidity of the second indoor environment, a certain dehumidification effect can be achieved on the first indoor environment. The humidity of two indoor environments is adjusted by the air conditioner or the smoke exhaust ventilator independently, and electric energy can be effectively saved.

In addition, after the air conditioner is controlled to be turned off and the dehumidification mode is controlled in step S226, step S228 and step S230 may be performed to detect a third humidity value of the outdoor environment and determine whether the third humidity value is smaller than a preset humidity value, and if the third humidity value is smaller than the preset humidity value in step S230, step S232 is performed to control the air conditioner to be turned on in a fresh air mode.

Under the precondition that the air conditioner is closed for dehumidifying mode and the smoke ventilator is opened, if the third humidity value of the outdoor environment is smaller than the preset humidity value, the humidity of the outdoor environment is lower, the fresh air mode can be opened by controlling the air conditioner, so that positive pressure is realized for the first indoor environment and the second indoor environment communicated with the first indoor environment, the smoke ventilator is accelerated to discharge indoor air, more outdoor air with lower humidity is promoted to enter the indoor environment, the humidity of the indoor environment, especially the second indoor environment, is reduced, and the dehumidifying efficiency of the smoke ventilator is improved.

If the determination result in step S230 is no, that is, if the third humidity value is greater than or equal to the preset humidity value, step S234 is performed to control the air conditioner to keep the current state unchanged, that is, especially, without making additional adjustment to the dehumidification mode of the air conditioner. Under the precondition that the air conditioner is closed for dehumidifying mode and the smoke exhaust ventilator is opened, if the third humidity value of the outdoor environment is larger than or equal to the preset humidity value, the humidity of the outdoor environment is higher, and the humidity of the indoor environment cannot be reduced by introducing more outdoor air, so that the indoor positive pressure is realized without additionally controlling the air conditioner to open a fresh air mode. At this time, the air conditioner is not required to be additionally adjusted, so that the current state of the air conditioner is kept unchanged. The control of the air conditioner to keep the current state unchanged mainly means that the air conditioner is not controlled to additionally start a fresh air mode.

In summary, in the interconnection control method of the air conditioner and the smoke exhaust ventilator of the embodiment, under the condition that the first humidity value and the second humidity value are both greater than or equal to the preset humidity value, the opening dehumidification mode of the air conditioner is determined, and the smoke exhaust ventilator is opened; under the condition that the first humidity value and the second humidity value are smaller than the preset humidity value, determining that the air conditioner is closed to dehumidify the mode, and closing the smoke exhaust ventilator; when the first humidity value is larger than or equal to the preset humidity value and the second humidity value is smaller than the preset humidity value, determining that the air conditioner is in a dehumidification mode, and closing the smoke exhaust ventilator; when the second humidity value is larger than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value, determining that the air conditioner is in a closed dehumidification mode, and opening the smoke exhaust ventilator; after the control air conditioner closes the dehumidification mode, and the smoke ventilator opens, detect the third humidity value of outdoor environment, under the condition that the third humidity value is less than preset humidity value, control air conditioner opens the new trend mode for indoor environment realizes malleation, promotes smoke ventilator's dehumidification efficiency, carries out automatically regulated to air conditioner and smoke ventilator according to the actual humidity condition of first indoor environment and second indoor environment, guarantees indoor environment's whole comfort level, promotes user's use experience.

The present embodiment also provides an interconnection control device for an air conditioner and a range hood, fig. 3 is a schematic block diagram of an interconnection control device 300 for an air conditioner and a range hood 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 range hood 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 smoke exhaust ventilator when executed by the processor 310.

As mentioned above, the interconnection control method of the air conditioner and the range hood according to any of the above embodiments is described from the side of the control device 300, that is, the control device 300 performs the relevant steps. In a specific embodiment, the control device 300 is in data connection with the air conditioner 100 and the range hood 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 range hood 200 to realize relevant adjustment.

The control device 300 may be various centralized control devices, and is disposed in a set space and controls the air conditioner 100 and the range hood 200. The data connection manner of the control device 300 and the air conditioner 100 and the range hood 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 range hood 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 can be the same component, i.e. the control device 300 is used for controlling the operation of the air conditioner 100, and is also used for receiving the signal of the smoke exhaust ventilator 200 and sending the signal to the smoke exhaust ventilator 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 range hood 200 and send the signal to the range hood 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 hood 200 may be disposed in a second indoor environment. And the first indoor environment and the second indoor environment are communicated. Specifically, the first indoor environment and the second indoor environment may be directly communicated, or a door body may be disposed between the first indoor environment and the second indoor environment, and under the condition that the door body is opened, the first indoor environment and the second indoor environment are communicated. Fig. 4 shows a case where a door body is provided between a first indoor environment and a second indoor environment, and communication is achieved by opening the door body.

In a specific embodiment, the first indoor environment in which the air conditioner 100 is located may be a living room, and the second indoor environment in which the hood 200 is located may be a kitchen. If the kitchen is an open kitchen, it may be in direct communication with the living room. Or a door body can be arranged between the kitchen and the living room, and the living room is communicated with the kitchen under the condition that the door body is opened. According to the actual humidity conditions of the first indoor environment and the second indoor environment, the air conditioner 100 and the smoke exhaust ventilator 200 are automatically adjusted, the overall comfort level of the indoor environments is guaranteed, and the use experience of a 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

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

receiving a trigger signal of the air conditioner and the smoke exhaust ventilator in an interconnection starting mode;

detecting a first humidity value of the first indoor environment and a second humidity value of the second indoor environment;

determining the operating states of the air conditioner and the smoke exhaust ventilator according to the first humidity value and the second humidity value; and

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

2. The method of claim 1, wherein determining the operating conditions of the air conditioner and the range hood from the first humidity value and the second humidity value comprises:

judging whether the first humidity value and the second humidity value are both greater than or equal to a preset humidity value; and

if yes, determining the opening dehumidification mode of the air conditioner, and opening the smoke exhaust ventilator.

3. The method of claim 2, wherein,

and under the condition that the first humidity value and the second humidity value are smaller than the preset humidity value, determining that the air conditioner is closed in the dehumidification mode, and closing the smoke exhaust ventilator.

4. The method of claim 2, wherein,

and under the condition that the first humidity value is larger than or equal to the preset humidity value and the second humidity value is smaller than the preset humidity value, determining that the air conditioner is started in the dehumidification mode, and closing the smoke exhaust ventilator.

5. The method of claim 2, wherein,

and under the condition that the second humidity value is larger than or equal to the preset humidity value and the first humidity value is smaller than the preset humidity value, determining that the air conditioner is closed in the dehumidification mode, and opening the smoke exhaust ventilator.

6. The method of claim 5, wherein after determining that the air conditioner is off the dehumidification mode, the range hood is on further comprising:

controlling the air conditioner to close the dehumidification mode, and opening the smoke exhaust ventilator;

detecting a third humidity value of the outdoor environment;

judging whether the third humidity value is smaller than the preset humidity value or not; and

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

7. The method of claim 6, wherein,

and under the condition that the third humidity value is larger than or equal to the preset humidity value, controlling the air conditioner to keep the current state unchanged.

8. The method of claim 1, wherein the step of receiving a trigger signal to turn on an interconnection mode of the air conditioner and the range hood comprises:

and receiving the trigger signal sent by the display device, the voice device, the remote controller or the mobile terminal bound with the air conditioner.

9. An interconnection control device of an air conditioner and a smoke exhaust ventilator, 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 smoke exhaust ventilator according to any one of claims 1 to 8 when executed by the processor.

10. An air conditioner having the interconnection control device of an air conditioner and a range hood according to claim 9.