WO2019242276A1 - Method, device and system for controlling air device, and computer storage medium - Google Patents

Abstract

A method for controlling an air device, relating to the technical field of smart home appliances. The method comprises: determining operating parameters of one or more air devices according to user information, wherein the user information comprises one or both among behavior information and location information (S101); and controlling the one or more air devices to operate in accordance with the operating parameters (S102). By employing the present technical solution, the air device may automatically adjust the operating state thereof according to different needs of a user, thereby fulfilling the changing needs of the user.

Description

Control method, device, system for air equipment and computer storage medium

This application is based on a Chinese patent application with an application number of 201810642203.9 and an application date of 2018.06.21, and claims the priority of the Chinese patent application. The entire content of the Chinese patent application is incorporated herein by reference.

Technical field

The present invention relates to the technical field of smart home appliances, and in particular, to a control method, device, system, and computer storage medium for air equipment.

Background technique

In the prior art, when the user turns on the air conditioner and sets the operating parameters of the air conditioner, the air conditioner continues to operate with the operating parameters, so that the indoor environment maintains a stable state. However, users in different locations and different activities have different needs for indoor environments, and the single operating state of air conditioners cannot meet the changing needs of users.

Summary of the Invention

An embodiment of the present invention provides a control method for an air device, which controls the air device according to the user's location information or behavior information, which can meet the changing needs of users.

In order to have a basic understanding of some aspects of the disclosed embodiments, a brief summary is given below. This summary is not a general overview, nor is it intended to identify key / important constituent elements or to describe the scope of protection of these embodiments. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

According to a first aspect of an embodiment of the present invention, a control method for an air device is provided.

In an optional embodiment, a control method for an air device includes:

Determining one or more operating parameters of the air equipment according to user information, wherein the user information includes one or both of behavior information and location information;

The operation of one or more air equipment is controlled according to said operating parameters.

In an optional embodiment, the control method is applied to a case where there are two or more users, and the operating parameter of the one or more air devices is determined according to the user information, including:

Determining two or more setting parameters of the air equipment according to two or more user information;

Obtain the operating parameters of one or more air devices from two or more set parameters according to the priority of user information, wherein the priority of the user information is a preset priority according to the user's ability to withstand ambient air .

In an optional embodiment, the one or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator, and an air purifier.

In an optional embodiment, before determining the operating parameters of one or more air devices according to user information, the method further includes:

User information is obtained through a linkage device, where the linkage device is a device that can provide user information.

According to a second aspect of the embodiments of the present invention, a control device for an air device is provided.

In an optional embodiment, the control device for an air device includes:

A first module is used to determine the operating parameters of one or more air devices according to user information, wherein the user information includes one or two of behavior information and location information;

The second module controls one or more air equipments to operate according to the operating parameters.

In an optional embodiment, the control device is applied to a case where there are two or more users, and the first module is specifically configured to determine two of the air equipment according to the information of the two or more users. Or one or more setting parameters; obtaining one or more operating parameters of the air equipment from two or more setting parameters according to the priority of user information, wherein the priority of the user information is Pre-set priorities for affordability, including the highest priority for special users.

In an optional embodiment, the one or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator, and an air purifier.

In an optional embodiment, the control device further includes: a tenth module, configured to obtain user information through a linkage device before determining operating parameters of one or more air devices according to the user information. The linkage device is a device that can provide user information.

According to a third aspect of the embodiments of the present invention, an air conditioning system is provided.

In an optional embodiment, the air conditioning system includes a plurality of air equipment and the above-mentioned control device for the air equipment.

According to a fourth aspect of the embodiments of the present invention, a computer storage medium is provided.

In an optional embodiment, the computer storage medium stores a computer program, and when the computer program is executed by a processor, the foregoing control method for an air device is implemented.

The beneficial effect of the embodiments of the present invention is that the air equipment can automatically adjust the operating state according to different needs of users, so as to meet the changing needs of users.

It should be understood that the above general description and the following detailed description are merely exemplary and explanatory, and should not limit the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings herein are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present invention, and together with the description serve to explain the principles of the present invention.

Fig. 1 is a schematic flowchart of a control method for an air device according to an exemplary embodiment;

Fig. 2 is a schematic flowchart of a control method for an air device according to an exemplary embodiment;

Fig. 3 is a schematic flowchart of a method for controlling an air device according to an exemplary embodiment;

Fig. 4 is a schematic flowchart of a control method for an air device according to an exemplary embodiment;

Fig. 5 is a schematic flowchart of obtaining operating parameters of an air device according to an exemplary embodiment;

Fig. 6 is a schematic flowchart of obtaining operating parameters of an air device according to an exemplary embodiment;

Fig. 7 is a schematic flowchart of a method for controlling an air device according to an exemplary embodiment;

Fig. 8 is a schematic flowchart of obtaining operating parameters of an air device according to an exemplary embodiment;

Fig. 9 is a schematic flowchart of obtaining operating parameters of an air device according to an exemplary embodiment;

Fig. 10 is a schematic block diagram of a control device for an air device according to an exemplary embodiment;

Fig. 11 is a schematic block diagram of a method for controlling an air device according to an exemplary embodiment;

Fig. 12 is a schematic block diagram of a method for controlling an air device according to an exemplary embodiment;

Fig. 13 is a schematic block diagram of a control method for an air device according to an exemplary embodiment.

detailed description

The following description and the drawings sufficiently illustrate specific embodiments of the present invention to enable those skilled in the art to practice them. The examples represent only possible variations. Unless explicitly required, individual components and functions are optional, and the order of operations may vary. Parts and features of some embodiments may be included in or replace parts and features of other embodiments. The scope of embodiments of the invention includes the entire scope of the claims, and all available equivalents of the claims. Herein, the embodiments may be individually or collectively represented by the term "invention", this is for convenience only, and if more than one invention is actually disclosed, it is not intended to automatically limit the scope of the application to any A single invention or inventive idea. In this article, relational terms such as first and second are used only to distinguish one entity or operation from another entity or operation, and do not require or imply any actual relationship between these entities or operations or order. Moreover, the terms "including," "including," or any other variation thereof are intended to encompass non-exclusive inclusion, such that a process, method, or device that includes a series of elements includes not only those elements, but also other elements not explicitly listed Elements. The embodiments in this document are described in a progressive manner. Each embodiment focuses on the differences from other embodiments. For the same and similar parts between the embodiments, refer to each other. As for the structures and products disclosed in the embodiments, since they correspond to the parts disclosed in the embodiments, the description is relatively simple, and the relevant parts can be referred to the description of the method.

The air conditioner mentioned in this article refers to all equipment that can directly provide treated air to an enclosed space, room or area. It mainly includes refrigeration systems for refrigeration and dehumidification, as well as air circulation and purification devices, and can also include heating and ventilation devices.

The humidifier mentioned in this article refers to all household appliances that can increase the humidity of a room, including, but not limited to, evaporative humidifiers, ultrasonic humidifiers, electric heating humidifiers, immersion electrode humidifiers, and cold mist humidifiers.

The dehumidifier mentioned in this article refers to all household appliances that can reduce the humidity of a room.

The air purifier mentioned in this article refers to all household and similar electrical appliances that can remove particulate matter, gaseous pollutants, microorganisms and other pollutants in the air.

The oxygen generator mentioned in this article refers to all electrical appliances that make oxygen.

The fresh air equipment mentioned in this article refers to all independent air treatment systems consisting of a supply air system and an exhaust air system, mainly including two types of ducted fresh air equipment and ductless fresh air equipment.

In the prior art, when the user turns on the air conditioner and sets the operating parameters of the air conditioner, the air conditioner continues to operate with the operating parameters, so that the indoor environment maintains a stable state. In the embodiment of the present invention, a control method using an air device is provided. When the control method is applied to an air conditioner, the operation of the air conditioner can be controlled according to the user's location information or behavior information. Since the user's location information or behavior information can reflect the user's actual needs, the control method can meet the changing needs of users.

According to a first aspect of an embodiment of the present invention, a control method for an air device is provided.

In an optional embodiment, as shown in FIG. 1, a control method for controlling an air device includes:

S101. Determine operating parameters of one or more air devices according to user information, where the user information includes one or two of behavior information and location information.

Users in different states have different requirements for ambient air. For example, when the user is sleeping in the bedroom, the temperature of the ambient air in the bedroom needs to be high and air circulation is required. When the user is in motion, the indoor temperature needs to be reduced; When the user is in the bathroom, the fresh air function needs to be turned on; in S101, the behavior state of the current user can be inferred from the user's behavior information and location information, so as to determine the air equipment that meets the actual needs of the user in the behavior state. Operating parameters.

S102. Control the operation of one or more air equipment according to the operation parameters.

In this embodiment, the air equipment can automatically adjust the operating state according to different needs of users, so as to meet the changing needs of users. In some application scenarios, there is not only one type of user's needs. For example, users have requirements for the temperature and cleanliness of the ambient air. An air device (such as an air conditioner) with a temperature adjustment function and an air device (such as an air purifier) with a purification function are controlled at the same time. That is, controlling one air device operation or controlling multiple air device operations can be selected according to the specific needs of the user.

Regarding the needs of the user and the type of air equipment, in an optional embodiment, the one or more air equipment includes one of an air conditioner, a dehumidifier, a humidifier, a fresh air equipment, an oxygen generator, and an air purifier. Or more. Correspondingly, the conditioning effect of one or more air devices on the ambient air is mainly reflected in one or more of temperature, humidity, cleanliness, and freshness.

The user information in S101 is used to interact with the air equipment, and can reflect the user's needs. In the above embodiment, the user information includes one or both of behavior information and location information. It can be seen that in the above embodiment, the user interacts with the air device through the behavior information and location information. Of course, the user information is not limited to the above-mentioned behavior information and location information, and the user can also interact with the air device through other user information.

In the following scenario, when the user turns on the air conditioner, the air conditioner will run according to the parameters when it was last turned off by default. In some public places or homes, multiple users often use an air conditioner, but the needs of each user are different. When different users use the air conditioner, they need to reset the operating parameters of the air conditioner according to their own needs, which increases the complexity of use and results in poor user experience. Obviously, continuing to use the user's location information or behavior information as user information cannot solve the above problems.

Furthermore, an embodiment of the present invention provides a control method for an air device. When the control method is applied to an air conditioner, based on the user's user information, the appropriate operating parameters are automatically selected. When there are multiple users, In the information, appropriate operating parameters are determined according to the priority of multiple user information, which can meet the special needs of users. That is, the user information includes one or both of identity information and age information.

In an optional embodiment, as shown in FIG. 2, the control method for an air device includes:

S201. Determine operating parameters of one or more air devices according to user information, where the user information includes one or two of identity information and age information;

S202. Control the operation of one or more air devices according to the operating parameters.

In this embodiment, each user information corresponds to a setting parameter, and the setting parameter is a parameter set by a user in advance, or the setting parameter is a parameter determined after statistics of a user's operation behavior. The corresponding setting parameters can be matched by a certain user information. Each user has independent identity information. Before determining the operating parameters of one or more air equipment according to the user information, the identity information of the bound user is also included. Therefore, in this embodiment, the air equipment can automatically select appropriate operating parameters according to user information, which can meet different needs of different users.

In the following scenarios, different users have different perceptions of hot and cold, resulting in different needs of different users. Even the same user has different perceptions and needs for heat and cold in different time periods. In a method for controlling an air device provided by an embodiment of the present invention, by controlling the air device according to the user's physiological parameter information, the user's demand for ambient air can be automatically and real-timely met. When the air device is an air conditioner, the air conditioner is controlled according to the user's physiological parameter information, which can automatically meet the user's needs for temperature in real time and bring a better user experience.

In an optional embodiment, as shown in FIG. 3, the control method for an air device may be implemented as:

S301. Determine operating parameters of one or more air devices according to user information, where the user information is physiological parameter information of the user.

In S301, the user's physiological parameter information includes body surface temperature information, heart rate information, blood pressure information, blood glucose information, sleep information, blood oxygen content information, skin moisture information, respiratory rate information, brain activity information, female physiological period information, and fetal information. One or more of the heart rate information. The one or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator, and an air purifier.

S302. Control the operation of one or more air devices according to the operation parameters.

In this embodiment, the user's physiological parameter information can reflect the user's need for ambient air, and by controlling the air equipment according to the user's physiological parameter information, the user's need for ambient air can be automatically and real-timely met.

In an optional embodiment, the control method for an air device may be implemented as:

Determine the operating parameters of the air conditioner based on the body surface temperature information, and control the operation of the air conditioner according to the operating parameters; or,

Determine the operating parameters of the dehumidifier and / or humidifier according to the body surface temperature information, and control the operation of the dehumidifier and / or humidifier according to the operating parameters; or,

Determine the operating parameters of the air conditioner based on the heart rate information, and control the operation of the air conditioner according to the operating parameters; or,

Determine the operating parameters of the fresh air equipment according to the heart rate information, and control the operation of the fresh air equipment according to the operating parameters; or,

Determine the operating parameters of the air conditioner and / or fresh air equipment according to the body surface temperature information and heart rate information, and control the operation of the air conditioners and / or fresh air equipment according to the operating parameters; or,

Determine the operating parameters of the air conditioner based on the blood pressure information, and control the operation of the air conditioner according to the operating parameters; or,

Determine the operating parameters of the fresh air equipment according to the blood pressure information, and control the operation of the fresh air equipment according to the operating parameters; or,

Determine the operating parameters of the fresh air equipment based on the blood glucose information, and control the operation of the fresh air equipment according to the operating parameters; or,

Determine the operating parameters of the air conditioner based on the blood glucose information, and control the operation of the air conditioner according to the operating parameters; or,

Determine the operating parameters of the fresh air equipment based on the blood oxygen content information, and control the operation of the fresh air equipment according to the operating parameters; or,

Determine the operating parameters of the dehumidifier and / or humidifier according to the skin moisture information, and control the operation of the dehumidifier and / or humidifier according to the operating parameters; or,

Determine the operating parameters of the fresh air equipment and / or oxygen generator based on the breathing rate information, and control the operation of the fresh air equipment and / or oxygen generator according to the operating parameters; or,

The operating parameters of the fresh air equipment and / or the oxygen generator are determined according to the fetal heart rate information, and the operation of the fresh air equipment and / or the oxygen generator is controlled according to the operating parameters.

In addition, the combination between the user information and the air equipment is not limited to the above technical solution. Those skilled in the art can select the user information and the air equipment according to the actual situation, and use the user information to control the air equipment.

In an optional implementation manner, S101, S201, and S301 determine the operating parameters of one or more air equipment according to the user information, including: determining the setting parameters of one or more air equipment according to the user information, and The parameters and current environmental information determine the operating parameters of one or more air equipment. This technical solution is applicable to the technical solution for determining the operating parameters of one or more air devices according to the user information. For example, determining the operating parameters of the air conditioner according to the body surface temperature information and controlling the operation of the air conditioner according to the operating parameters may be implemented as: determining the setting parameters of the air conditioner according to the body surface temperature information, and determining the setting parameters according to the setting parameters and the current environmental information The operating parameters of the air conditioner are output, and the operation of the air conditioner is controlled according to the operating parameters.

In an optional implementation manner, S301 determines the operating parameters of one or more air devices according to user information, and may be implemented as:

When the first physiological parameter is within the range of the first set index and is not equal to the first optimal physiological parameter, and one or more air devices are in an operating state, based on the first operating parameters of the one or more air devices , Changing the first set value; wherein the user information includes a first physiological parameter, the first set index range is a normal range of the first physiological parameter, and the first optimal physiological parameter is a physiological parameter for which the user can obtain a comfortable experience; It is a fine-tuning operation of the air equipment at all times;

When the first physiological parameter is within the range of the first set index and is not equal to the first optimal physiological parameter, when one or more air devices are in a non-operating state, one or more is determined according to the set parameters corresponding to the user information. Operating parameters of multiple air equipment;

When the first physiological parameter is not within the range of the first set index, based on the first operating parameter of one or more air devices, change the second set value, or issue a reminder to the user, or, one or more The air device stops operating, wherein the second set value is greater than the first set value.

This technical solution can not only monitor the user's health, but also ensure that the user gets a comfortable experience. In this technical solution, the first set index range and the optimal physiological parameter of users of different constitutions in different seasons are different. For example, when the user feels very comfortable in summer, the body surface temperature is 36 ° C, and when the user feels very comfortable in winter, the body surface temperature is 37 ° C. In winter, when the body surface temperature is 37 ° C, the cooling cannot be turned on. This control method is based on the change of its physiological characteristics. Specifically, real-time monitoring of the user's physiological indicators, each physiological indicator will have a relatively stable value over a period of time, such as body surface temperature during this time around 37 ℃, and physiological indicators sometimes change, such as relatively hot Changed to 38 ℃, at this time you can control the device to cool down until the surface temperature returns to 37 ℃. That is, the physiological characteristics are detected in real time. When the parameters are changed, the control module issues an instruction to adjust the device to change the current environment, thereby allowing the user's changed physiological characteristic values to return to normal parameters. For this time period, it can be set artificially, such as 10 hours or 10 days.

When the first physiological parameter body surface temperature information, heart rate information, blood pressure information, blood glucose information, skin moisture information, respiration rate information, and fetal heart rate information, all of the technical solutions can be adopted.

For example, when the first physiological parameter is body surface temperature information and the air device is an air conditioner, when the user's body surface temperature T is within T1 to T2, and T is not equal to T3, when the air conditioner is in an operating state, if T <T3 , Then increase the current set temperature by 0.5 ° C, or increase other first set values; if T> T3, lower the current set temperature by 0.5 ° C, or lower other first settings value. The difference between T and T3 is positively related to the first set value.

Or, when the user's body surface temperature T is within T1 ~ T2, and T is not equal to T3, and the air conditioner is in the running state, in the heating mode, if T <T3, the current set wind speed is increased by 1 level Or, increase the other first set value; if T> T3, reduce the current set wind speed by one level, or, lower the other first set value. In the cooling mode, if T <T3, reduce the current set wind speed by 1 level, or lower other first set values; if T> T3, increase the current set wind speed by 1 level, or , Increase the other first set value. The difference between T and T3 is positively related to the first set value. If the set wind speed is already the minimum wind speed or the maximum wind speed, the set temperature of the air conditioner is adjusted according to the body surface temperature T.

When the body surface temperature T of the user is within T1 to T2, and T is not equal to T3, and the air conditioner is in a non-operating state, if the room temperature needs to be increased, it needs to be adjusted in conjunction with the current room temperature. If the room temperature is lower than a certain value (such as 20 degrees) and the room temperature needs to be increased, the air conditioner is turned on and the heating mode defaults to the temperature value and wind speed corresponding to the user's body surface temperature T, such as 26 degrees, low wind, turned on After setting the time, fine-tune the air conditioner according to the above principles. If the room temperature is higher than 20 degrees and it is necessary to raise the room temperature, the air conditioner is not turned on, the control module sends a message (or voice broadcast) to the user to remind the user to add clothes.

When the body surface temperature T of the user is within T1 to T2, and T is not equal to T3, and the air conditioner is in a non-operating state, if the current room temperature needs to be reduced, the current room temperature adjustment needs to be adjusted. If the room temperature is higher than a certain value (for example, 23 degrees), the air conditioner operates and the cooling mode is set to a temperature value and a wind speed corresponding to the user's body surface temperature T, such as 22 degrees and low wind. After the air conditioner has run for a set time, fine-tune the air conditioner according to the above principles.

Another control method when the air conditioner is not turned on and the room temperature needs to be adjusted is: turn on the air conditioner, comfort mode (or smart mode), and the air conditioner selects the on mode and the set temperature according to the current room temperature.

Optionally, the set temperature and wind speed of the air conditioner are adjusted at the same time.

When the user's body surface temperature T is not between T1 and T2, if T <T1, the current set temperature is increased by 1 ° C, or 2 ° C, or 3 ° C, or other second set values, and turned on at the same time. Wind avoidance mode; if T> T2, lower the current setting by 1 ° C, or 2 ° C, or 3 ° C, or another second set value, and turn on wind avoidance mode.

In an application scenario, the operating parameters of the air conditioner and the fresh air equipment are determined according to the body surface temperature information and the heart rate information, and the operation of the air conditioner and the fresh air equipment is controlled according to the operating parameters. When the temperature needs to be increased, the temperature is increased. When the body surface temperature is too high and the heart rate is too low, the temperature is not increased and the air conditioning equipment is controlled according to the body surface temperature. When the body surface temperature is too high and the heart rate is too high When the body surface temperature is too low and the heart rate is too high, the temperature increase operation is performed on the air-conditioning equipment and the operation of increasing the air volume is performed on the fresh air equipment. If the device is not turned on, you need to make a judgment operation based on the current ambient temperature and the value of CO ₂ concentration. For example, when the CO ₂ concentration is greater than the set value (such as 1000ppm), the fresh air device is turned on and the wind speed is set (such as low Wind), after the fresh air equipment runs for a set time, fine-tune the fresh air equipment.

When the user information includes any one of blood pressure information, blood glucose information, blood oxygen content information, skin moisture information, respiration rate information, and fetal heart rate information, the specific adjustment method can refer to the adjustment of the air conditioner according to the body surface temperature information Flow; when the user information includes two or more of body surface temperature information, heart rate information, blood pressure information, blood glucose information, blood oxygen content information, skin moisture information, respiratory rate information, and fetal heart rate information, the specific adjustment method Refer to the adjustment process of air conditioners and fresh air equipment according to body surface temperature information and heart rate information.

In an optional implementation manner, S301 determines the operating parameters of one or more air devices according to user information, and may be implemented as:

The level at which the second physiological parameter is located is determined according to the preset index level, where the user information includes the second physiological parameter, and the preset index level is associated with two or more numerical ranges of the second physiological parameter and their corresponding levels;

The operating parameter of the one or more air devices is determined according to the level at which the second physiological parameter is located, wherein the operating parameter of the one or more air devices is associated with the level at which the second physiological parameter is located.

In this technical solution, the state of the user is divided into levels, and the air conditioning equipment is targeted to further ensure that the user is in a comfortable state.

In one application scenario, user information includes sleep information, and users with different sleep depths have different needs for temperature and air volume. The level at which the second sleep parameter is located is determined according to the preset sleep level, wherein the user information includes the second sleep parameter, and the preset sleep level is associated with two or more numerical ranges of the second sleep parameter and their corresponding levels. The operating parameter of the one or more air devices is determined according to the level at which the second sleep parameter is located, where the operating parameter of the one or more air devices is associated with the level at which the second sleep parameter is located. For example, the preset sleep level includes five sleep levels: X1, X2, X3, X4, X5. Correspondingly, the set temperature and air volume direction of the air device include five operating states: S1, S2, S3, S4, S5. Among them, 5 operating states are preset operating states. When the second sleep level is X3, the operating state of the air device is S3.

In one application scenario, user information includes information about the physiological period of women. Women should not be cold during the physiological period. The temperature should be appropriately raised, fresh air is needed, and fresh air should be turned on. The level of the second physiological period parameter is determined according to the preset physiological period level, wherein the user information includes the second physiological period parameter, the two or more numerical ranges associated with the second physiological period parameter in the preset physiological period level, and Corresponding level. The operating parameter of the one or more air equipment is determined according to the level at which the second physiological period parameter is located, wherein the operating parameter of the one or more air equipment is associated with the level at which the second physiological period parameter is located. For example, the preset physiological period level includes 5 physiological period levels, X1, X2, X3, X4, X5. Correspondingly, the combination between the set temperature and the freshness of the air device includes 5 operating states: S1, S2, S3, S4, S5. Among them, five operating states are preset operating states. In the preset operating states, the indoor temperature can be controlled to a set value, and the indoor CO ₂ concentration can be controlled to a set value, for example, less than 800 ppm. When the second physiological period level is X3, the operating state of the air device is S3. The second physiological period parameters of the user are obtained through the wearable device, and the operating parameters of the air conditioner and the fresh air device are determined according to the second physiological period parameters; the position of the user is obtained through the wearable device, and the air conditioner and the fresh air device are controlled to prevent the user from being located. Location was hairy.

In an optional implementation manner, S301 determines the operating parameters of one or more air devices according to user information, and may be implemented as:

Adjust operating parameters of one or more air devices according to brain activity information, where the user information includes brain activity information.

With this technical solution, users can more conveniently adjust one or more air devices. In the prior art, the wearable device that detects the brain can detect some basic commands, and through these basic commands, basic operations such as turning on and off the air conditioner, increasing the temperature, lowering the temperature, increasing the air volume, and reducing the air volume can be implemented. For example, when the user wants to turn on the air conditioner, the brain wave signal is obtained through the wearable device, and the air conditioner is controlled to be turned on. In one application scenario, when a person feels cold, a first brain wave signal is generated, and when a person feels hot, a second brain wave signal is generated. The wearable device can detect the first brain wave signal and the second brain wave. Radio signal. The operating process of the air equipment is: when the first brain wave signal is detected, increase the airflow of the air conditioner, or increase the set temperature of the air conditioner; when the second brain wave signal is detected, reduce the air conditioner's Air volume, or, lower the set temperature of the air conditioner.

When there is multiple user information, as shown in FIG. 4, the foregoing control method for an air device may be implemented as:

S401. Determine two or more setting parameters of the air device according to two or more user information, where the user information includes one or two of identity information and age information, or the user information includes location information and behavior The information, or the user information, includes one or more of the user's physiological parameter information, or the user information includes one or more of identity information, age information, location information, behavior information, and user's physiological parameter information.

Each user information corresponds to a setting parameter. When multiple users use the air device at the same time, two or more user information and corresponding two or more setting parameters can be obtained. The setting parameter is a parameter preset by the user. Among them, the user preset parameter can be obtained through the mobile terminal, and the user information and the user preset parameter are stored in a database in a one-to-one correspondence manner. The database can be set On a local area network or on a cloud platform server. Among the parameters preset by the user, the user has set one or more of temperature, humidity, cleanliness, and freshness. The mobile terminal may be a terminal device such as a smart phone, a tablet computer, a Ultra-mobile Personal Computer (UMPC), a netbook, or a Personal Digital Assistant (PDA), and is not limited thereto.

Optionally, when the user does not set the setting parameter in advance, the user information and the operation behavior of the user are counted to determine the setting parameter. For example, when the user's information includes body surface temperature information, the user's normal body surface temperature is 37 ° C. At this time, the user's body surface temperature is 38 ° C. After 10 minutes, the user starts the air conditioner, selects cooling, and low wind. 26 ° C. The user has encountered this situation many times, and has set the air conditioner many times in the manner described above. For example, the above situation is repeated 3 times, or, 5 times, or, 10 times, or 20 times. Then, the following scenario: user information is body surface temperature information, and the normal body surface temperature is 37 ° C, and the current body surface temperature is 38 ° C, and the corresponding setting parameters are: cooling mode, low wind, 26 ° C (for air conditioners) Setting parameters). If the temperature of the user's body surface is 38 ° C, the operating parameters of the air conditioner are automatically determined according to the set parameters, that is, the operating state of the air conditioner is controlled to the cooling mode, low wind, 26 ° C.

S402. Obtain the operating parameters of one or more air devices from two or more set parameters according to the priorities of two or more user information. The priority of the user information is based on the user's ability to withstand ambient air. Pre-set priority.

Among them, the priority of the user information includes the highest priority of the special user. In the case where the user is a special user, for example, when the user has a cold, or when the user is taking care of a baby, at this time the user is difficult to bear the lower ambient temperature, the user information of the user has the highest priority, that is, as long as The user determines the operating parameters of one or more air devices according to the user's set parameters within the range that the air device can influence, which meets the needs of the special user.

It can be known in S401 that the user information corresponds to the setting parameters. In S402, the following process is included: the second user information with the highest priority is determined from the two or more user information, and the second user information corresponds to the second user information. The second set parameter obtains the operating parameters of one or more air equipment. Wherein, obtaining the operating parameters of one or more air equipment according to the second setting parameter corresponding to the second user information may be implemented as: obtaining current environmental information, and obtaining one or more air according to the second setting parameter and current environmental information The operating parameters of the device.

For example, when the user information includes body surface temperature information, when the body surface temperature is 37 ° C, the setting temperature in the setting parameter is 26 ° C, and when the body surface temperature is 38 ° C, the setting temperature in the setting parameter is 25 ° C When the body surface temperature is 30 ° C, the setting parameter in the set temperature is 23 ° C. When the body surface temperature is 30 ° C and the current indoor temperature is 16 ° C, the heating mode of the air conditioner is controlled to be turned on. The set temperature is 23 ° C, so that the room temperature is gradually increased and maintained at 23 ° C. When the body surface temperature is 37 ° C At ℃, the current indoor temperature is 30 ° C, then the air conditioner is controlled to turn on the cooling mode, the set temperature is 26 ° C, and the room temperature is gradually reduced and maintained at 26 ° C.

S403. Control the operation of one or more air devices according to the operating parameters.

In this embodiment, when there are multiple users, the air equipment can meet the special needs of special users.

In an optional embodiment, in S402, obtaining operating parameters of one or more air equipments from two or more setting parameters according to the priorities of two or more user information, including:

When the user information includes identity information, the first identity information with the highest priority is determined from the two or more identity information; and the operating parameters of one or more air equipment are determined according to the setting parameters corresponding to the first identity information. .

When the user information includes age information, the priority of the operating mode is determined according to the priority of the age information; the priority of the setting parameters is determined according to the priority of the operating mode; one or more of the setting parameters are determined according to the highest priority setting parameter. Operating parameters of an air device. Among them, the operation mode is set according to the age of the user, and the operation mode corresponds to the set parameters one by one. The priority of the operation mode is a priority set in advance according to the ability of different users to withstand ambient air. The operation modes include, but are not limited to, the pregnancy mode, child mode, normal mode, and elderly mode. The priority of the operation mode can be set from high to low: pregnancy mode, child mode, elderly mode, and normal mode. For example, when an unfamiliar person is recognized as an adult, the air device is operated in the normal mode; if both an adult and an infant are recognized, the air device is operated in the pregnant and infant mode. In the case where the user does not set parameters in advance, this embodiment can still ensure that the user obtains a better experience.

When the user information includes both identity information and age information, it is preferred to determine the operating parameters of one or more air equipment according to the setting parameters corresponding to the identity information.

When the user information includes behavior information and location information, the user status is determined according to the behavior information and location information; the priority of the setting parameter is determined according to the priority of the user status; and one or more of the setting parameters are determined according to the highest priority setting parameter. Operating parameters of air equipment. The user status refers to the user's activity status, including but not limited to: bathing status, exercise status, reading status, cleaning status, and entertainment status. The user status corresponds to the set parameters one by one, for example, the user is in a sports status The corresponding setting parameters are: temperature 24 ° C, humidity 40%, PM2.5 <50μg / m ³ , CO ₂ <800ppm, and oxygen content 21%, where PM2.5 is the aerodynamic equivalent diameter in the ambient air of less than Particles equal to 2.5 microns, also known as fine particles. Correspondingly, the operating parameters of the air equipment are: the air conditioner is in the cooling state, medium speed wind, 24 ° C, the air purifier is in intelligent mode, automatic wind, fresh air equipment medium speed wind The oxygen generator is turned on. The user is in an entertaining state. The corresponding setting parameters are: temperature 26 ℃, humidity 60%, PM2.5 <60μg / m ³ , CO2 <1000ppm, oxygen content 20.9%. Correspondingly, the operating parameters of the air equipment are: air conditioner The air conditioner outputs cooling state, low-speed wind, 26 ℃, air purifier is in intelligent mode, automatic wind; fresh air equipment is low-speed wind, oxygen generator is turned off. The priority of the user state is a preset priority according to the user's ability to withstand ambient air in different states. For example, the priority of the user state can be as follows: bathing state> exercise state> reading state> cleaning state> Entertainment status.

When the user information includes identity information, age information, behavior information, and location information, the highest priority is given to the baby-to-baby mode, that is, when a baby is detected indoors, one or Operating parameters of multiple air equipment. When there are no babies in the room, the bathing state is the highest priority, that is, the user is in the bathing state. When the user returns to the room, the operating parameters of one or more indoor air devices are determined according to the setting parameters corresponding to the bathing state.

This embodiment can meet the special needs of special users.

In this embodiment, if it is recognized that the priorities of the two users before and after are the same, then one or more operating parameters of the air device are determined according to the setting parameters of the previous user, or one is determined according to the setting parameters of the next user Or operating parameters of multiple air equipment.

In one application scenario, the user is in motion and the user is running on a treadmill. The treadmill is a linkage device. The user can obtain the user's running speed and the user's exercise intensity through the treadmill. When the air equipment operates according to the setting parameters corresponding to the first motion state, for example: the air conditioner is in the cooling state, the medium-speed wind, the temperature is 24 ° C; the air purifier is in the intelligent mode, the automatic wind; the fresh air equipment is the high-speed wind, the system The oxygen machine is turned on. When the speed of the treadmill is greater than 10km / h, the air equipment operates according to the set parameters corresponding to the second motion state, for example: the air conditioner is in the cooling state, the medium speed wind, and the temperature is 24 ° C; the air purifier is in the intelligent mode and automatically Wind; fresh air equipment is high-speed wind, oxygen generator is turned on. If the user's running speed is increased from 9km / h to 11km / h, the air device automatically switches from the first running state to the second running state.

In an optional embodiment, in S402, one or more operating parameters of the air equipment are obtained from two or more setting parameters according to the priorities of two or more user information, including:

For the first air device, determining the first user information with the highest priority;

An operating parameter of the first air device is determined according to a setting parameter corresponding to the first user information.

Repeat the above steps until all operating parameters of the air equipment are determined. In the above technical solution, for the same air device, different user information has different priorities, and for the same user information, different air devices have different priorities. Adopting this technical solution can meet the most important needs of multiple users. For example, the third user has a higher requirement for the temperature of the ambient air. If the user is more afraid of cold, then the third user has the highest priority in the control of the air conditioner; the fourth user has the cleanliness of the ambient air. The requirements are relatively high, so the fourth user has the highest priority in controlling the air purifier. When the air equipment is running, the air cleaner operates according to the setting parameters corresponding to the user information of the third user, and the air purifier operates according to the setting parameters corresponding to the user information of the fourth user. Therefore, the third user and the The main needs of the fourth user.

In an optional embodiment, in S402, obtaining operating parameters of one or more air equipments from two or more setting parameters according to the priorities of two or more user information, including:

Determine the priority of two or more user information according to the relative change rate of two or more user information, and determine one or more air devices in two or more setting parameters according to the highest priority user information Operating parameters.

For the convenience of recording, the relative change rate of two or more user information is divided into levels. The higher the level, the greater the relative change rate, and the greater the degree of change of the user information.

For example, when the user information includes body surface temperature information and heart rate information, the body surface temperature change level of the fifth user is 2, the heart rate change level is 1, the body surface temperature change level of the sixth user is 2, and the heart rate change level is 3. . Among the changes of the above-mentioned various user information, the degree of the greatest change is the heart rate information of the sixth user, and one or more operating parameters of the air equipment are determined according to the setting parameters corresponding to the relative change rate of the heart rate information of the sixth user.

In an optional embodiment, as shown in FIG. 5, in S402, one or more operating parameters of the air equipment are obtained from two or more setting parameters according to the priorities of two or more user information. include:

S501. Obtain two or more first sub-setting parameters related to first environmental information among two or more setting parameters, where the first environmental information is temperature information, humidity information, cleanliness information, and freshness information. , Any of the oxygen content information.

Optionally, one setting parameter may include one or more of a sub-setting parameter about temperature, a sub-setting parameter about humidity, a sub-setting parameter about cleanliness, and a sub-setting parameter about freshness. .

S502. Determine a first sub-operation parameter among two or more first sub-setting parameters according to the attribute of the first environment information.

The attribute of the first environment information refers to a correspondence between changes in the first environment information and changes in user comfort, and includes that when the first environment information becomes larger, the user comfort becomes worse, or the user comfort It becomes better; when the first environment information becomes smaller, the user comfort becomes worse, or the user comfort becomes better. For example, the higher the cleanliness, the better the user's comfort; the higher the freshness, the better the user's comfort. For a plurality of first sub-setting parameters that represent the first environment information, the better the user comfort, the higher the priority of the first sub-setting parameter, and the first sub-setting parameter with the highest priority is used to determine the first sub-setting parameter. First child operating parameters.

Perform S501 and S502 multiple times to obtain multiple sub-operational parameters, and combine the multiple sub-operational parameters to obtain the operating parameters of one or more air equipment. Controlling the air equipment according to the operating parameters obtained by the above technical solution can ensure that users in the ambient air have a better experience.

When the first environmental information is temperature information, humidity information, cleanliness information, and freshness information, the specific implementation of the foregoing technical solution is as follows:

When the first environmental information is temperature information, two or more first sub-setting parameters related to temperature information among the two or more setting parameters are acquired, and determined in the two or more first sub-setting parameters. The highest set value is used as the first sub-operation parameter;

When the first environmental information is humidity information, two or more first sub-setting parameters related to humidity information among two or more setting parameters are acquired, and an average of the two or more first sub-setting parameters is obtained. Value as the first sub-run parameter;

When the first environment information is cleanliness information, two or more first sub-setting parameters related to cleanliness information among two or more setting parameters are acquired, and the two or more first sub-setting parameters are obtained. The lowest set value is determined as the first sub-operation parameter;

When the first environment information is freshness information, two or more first sub-setting parameters related to freshness information among the two or more setting parameters are acquired, and the two or more first sub-setting parameters are obtained. The lowest set value is determined as the first sub-operation parameter.

The above technical solution is executed once to obtain a sub-operation parameter about an environmental information, and the number of times the above technical solution is executed is the same as the number of sub-setting parameters included in the setting parameters. After the last technical solution is executed, the obtained sub-operation parameters are combined as the operation parameters of one or more air equipment.

For example, the setting parameter of the first user is "refrigeration 26 ° C, humidity 40%, PM2.5> 100μg / m ³ turns on purification, CO ₂ > 1500ppm turns on fresh air", and the setting parameter of the second user is "cooling 23 ° C" , Humidity 60%, PM2.5> 150μg / m ³ turn on purification, CO ₂ > 1000ppm turn on fresh air ". When it is detected that only the first user is indoors, determine the operating parameters of one or more air equipment according to the set parameters of the first user. Turn on the air conditioner and set it to 26 ° C. When the humidity is greater than 40%, turn on the dehumidification Machine, control the humidity at 40%, when the humidity is less than 40%, turn on the humidifier, control the humidity at 40%, when PM2.5> 100μg / m ³ turn on the air purifier or the air conditioning purification function, when the CO ₂ concentration When it is greater than 1500ppm, turn on the fresh air equipment or turn on the fresh air function of the air conditioner; when it is detected that both the first user and the second user are indoors, among the setting parameters of the first user, the sub-setting parameter about the temperature information is "cooling 26 ℃ ", Among the setting parameters of the second user, the sub-setting parameter regarding temperature information is" refrigeration 23 ° C ", and" refrigeration 26 ° C "is selected as a sub-operation parameter of the operating parameter; regarding the humidity information, the first user's setting The sub-setting parameter in the setting parameter is "humidity 40%", the sub-setting parameter in the setting parameter of the second user is "humidity 60%", and the average value of the two is "humidity 50%" as a sub-operation parameter. ; In cleanliness information, user setting parameters in the first sub-set parameter "PM2.5> 100μg / m ³ Open purification", the second user setting parameters set in the sub-parameter "of PM2.5 ＞ 150μg / m ³ start purification ", select" PM2.5 ＞ 100μg / m ³ start purification "as a sub-operation parameter; regarding the freshness information, the sub-setting parameter in the setting parameter of the first user is" CO ₂ ＞ 1500ppm open fresh air ", the sub-setting parameter in the second user's setting parameter is" CO ₂ ＞ 1000ppm open fresh air ", and select" CO ₂ ＞ 1000ppm open fresh air "as a sub-operation parameter. The above four sub-operating parameters are combined, and the obtained operating parameters are "refrigeration 26 ° C, humidity 50%, PM2.5> 100μg / m ³ start purification, CO ₂ > 1000ppm start fresh air".

In an optional embodiment, as shown in FIG. 6, it is applied to a case where there are two or more air devices having the same function. In S402, according to the priority of two or more user information, two or more air devices are used. Obtain the operating parameters of one or more air equipment from multiple setting parameters, including:

S601. Determine the comprehensive setting parameter among two or more setting parameters according to the priority of the user information.

In this embodiment, there are two or more air devices having the same function. For example, in the case of humidification, when there is an ultrasonic humidifier and an electric heating humidifier, there are two or more air devices having the same function. For the condition of the equipment, the comprehensive setting parameter in S501 refers to the effect achieved by the function of two or more air equipment having the same function, for example, the comprehensive setting parameter "humidity 50%". The control method mentioned in the foregoing is equivalent to directly determining the operating parameters of one or more air equipment according to the comprehensive set parameters.

S602. Obtain two or more operating parameters of two or more air devices having the same function according to the comprehensive setting parameters, where the operating parameters include the operating power of each air device.

In the case where the comprehensive setting parameter is determined, two or more air devices having the same function have two or more combined forms in order to achieve the effect determined by the comprehensive setting parameter. For example, the parameter "cooling power 1000W" is comprehensively set, and there are two indoor cooling devices: the first air conditioner and the second air conditioner, where the power of the first air conditioner is 1500W and the power of the second air conditioner is 3000W. The operating parameters include three types. The first operating parameter: only the first air conditioner is activated, which can meet the comprehensive setting parameters; the second operating parameter: only the second air conditioner is activated, which can meet the comprehensive setting parameters; the third operating parameter : Start the first air conditioner and the second air conditioner at the same time, which can meet the comprehensive setting parameters.

S603. Determine a first operating parameter with a minimum total power among two or more operating parameters.

Among the above three operating parameters, the total power required by the first operating parameter is 1500W, the total power required by the second operating parameter is 3000W, and the total power required by the third operating parameter is 4500W. Obviously, the The total power required by one operating parameter is less than the total power required by the second and third operating parameters. Therefore, the first operating parameter is selected as the first operating parameter.

Further, when there are two or more first operating parameters that satisfy the minimum power, a second operating parameter that involves the least number of air equipment is determined among the two or more first operating parameters. For example, comprehensively set the parameter "cooling power 3000W", and there are three indoor cooling equipment: the first air conditioner, the second air conditioner and the third air conditioner, where the power of the first air conditioner is 1500W and the power of the second air conditioner is 1500W , The power of the third air conditioner is 3000W, then, the first operating parameter includes two types, the first type of first operating parameter: the first and second air conditioners are started at the same time; the second type of first operating parameter: only the third air conditioner is started . In the first first operating parameter, two air devices are involved, and in the second first operating parameter, one air device is involved. Therefore, the second first operating device is selected as the second operating parameter.

In this embodiment, while ensuring that the conditioning effect of the air equipment on the indoor air achieves the expected effect, it can also save energy to the greatest extent.

In the foregoing, when one operating parameter of an air device determined according to one user information conflicts with another operating parameter of an air device determined according to another user information, A running parameter sets different priorities to avoid conflicts between the two.

However, a user information often includes a variety of different information, such as identity information, age information, behavior information, location information, body surface temperature information, heart rate information, and so on. One operating parameter of the air equipment is determined according to one type of information included in the user information, and another operating parameter of the air equipment is determined according to another type of information included in the user information. The operating parameters of the above-mentioned air equipment will inevitably occur conflict.

When the user information includes two or more conflicting feature information, obtaining the operating parameters of one or more air equipment according to the user information includes:

Obtaining two or more setting parameters of one or more air equipment according to two or more characteristic information;

According to the priority of the two or more characteristic information, one or more operating parameters of the air equipment are determined among the two or more setting parameters.

If there is no two or more conflicting feature information in the user information, all the operating parameters of the one or more air devices determined according to the user information are executed.

On this basis, as shown in FIG. 7, the foregoing control method for air equipment can be implemented as:

S701. Obtain two or more setting parameters of one or more air devices according to two or more characteristic information.

The feature information is conflicting information included in the user information. Two or more feature information conflict with each other, which means that two or more operations of the same air device can be determined based on the two or more feature information. Parameters, and an air device can only operate according to one operating parameter, so two or more operating parameters conflict.

Optionally, the two or more characteristic information includes identity information, age information, behavior information, location information, body surface temperature information, heart rate information, blood pressure information, blood glucose information, sleep information, blood oxygen content information, skin moisture information, One or more of respiratory rate information, brain activity information, female physiological period information, and fetal heart rate information.

S702. Determine operating parameters of one or more air devices among two or more setting parameters according to the priorities of the two or more characteristic information.

S703. Control the operation of one or more air devices according to the operation parameters.

In an optional embodiment, as shown in FIG. 8, according to the priority of two or more characteristic information, one or more operating parameters of the air equipment are determined from two or more setting parameters, specifically for:

S801. Determine the priority of the two or more characteristic information according to a relative change rate of the two or more characteristic information.

The relative change rate reflects the degree to which the characteristic information changes. The larger the relative change rate, the greater the degree of change in the characteristic information, and the smaller the relative change rate, the smaller the degree of change in the characteristic information. Optionally, the relative change rate is divided into change levels.

S802. Determine operating parameters of one or more air devices according to the first characteristic information having the highest priority.

For example, if the surface temperature change level is 2 and the heart rate change level is 1, the operating parameters of one or more air devices are determined according to the body surface temperature.

This embodiment can meet the main needs of users.

In an optional embodiment, the operating parameters of one or more air equipment are determined from the two or more setting parameters according to the priorities of the two or more characteristic information, which are specifically:

The priority of the two or more characteristic information is determined according to the type of the air conditioning regulating device; the operating parameter of the one or more air devices is determined according to the characteristic information with the highest priority. For example, when the air device is an air conditioner, body surface temperature information> blood pressure information> heart rate information, and when the air device is fresh air device, blood oxygen information> heart rate information> blood pressure information.

In an optional embodiment, as shown in FIG. 9, one or more operating parameters of the air equipment are determined from the two or more setting parameters according to the priorities of the two or more characteristic information, including:

S901. Obtain two or more second sub-setting parameters regarding the second environment information from the two or more setting parameters according to the two or more characteristic information, wherein the second environment information is temperature information and humidity information. , Cleanliness information, freshness information, and oxygen content information;

S902. Determine a second sub-operation parameter among two or more second sub-setting parameters according to the attribute of the second environment information.

The attribute of the two or more feature information refers to a correspondence between a change in the two or more feature information and a change in user comfort, including when the feature information becomes larger, the user comfort becomes worse, or , User comfort becomes better; when feature information becomes smaller, user comfort becomes worse, or user comfort becomes better. Among the two or more second sub-setting parameters for setting the second environment information, the better the user comfort, the higher the priority of the second sub-setting parameter, according to the second The sub-setting parameter determines the second sub-operation parameter. For example, in a plurality of set temperatures, a sub-operation parameter is determined according to a sub-setting parameter with a high temperature; in a plurality of set freshnesses, a sub-operation parameter is determined according to a sub-setting parameter with a lowest CO ₂ concentration. . For example, during the physiological period of a woman, the temperature is required to be 28 ° C, and the CO _{2 is} below 1000 ppm. At this time, the required temperature for heart rate changes is 26 ° C, and the CO _{2 is} within 800 ppm. At this time, the temperature is compared and set to 28 ° C; the CO ₂ concentration requirements are compared, and the CO ₂ is controlled to be within 800 ppm.

Perform S901 and S902 multiple times to obtain multiple sub-operational parameters, and combine the multiple sub-operational parameters to obtain the operating parameters of one or more air equipment. Controlling the air equipment according to the operating parameters obtained by the above technical solution can ensure that users in the ambient air have a better experience.

Optionally, before S101, S201, S301, or S401, the method further includes: acquiring user information;

When the user identity information is behavior information or location information, obtaining the user's identity information may be implemented as: obtaining user information through a linkage device, where the linkage device is a device that can provide user information.

Among them, the linkage device refers to an electrical device that provides necessary functions to maintain a normal life in the daily life of the user. Linked devices include, but are not limited to, range hoods, induction cookers, gas stoves, electric ovens, rice cookers, bathroom water heaters, washing machines, smart toilet covers, televisions, projectors, computers, and treadmills. The setting position of the linkage equipment in home life is generally fixed, for example: the treadmill is set in the exercise and fitness room; the range hood, the electromagnetic range, and the gas range are set in the kitchen; the bathroom water heater and the intelligent toilet cover are set in the toilet. Therefore, the location information of the user can be determined according to the activation of a certain linkage device. In addition, different linkage devices have different functions, for example: a treadmill is used for exercising, a range hood, an electromagnetic range or a gas range is used for cooking, and a bathroom water heater is used for bathing. Therefore, the behavior information of the user can be determined according to the running time of the linked device and the combined running status of two or more linked devices. By linking the devices, the user's behavior information and location information can be determined more accurately. Obtaining user information may also be implemented as: obtaining user behavior information through a camera or an infrared sensor, and obtaining position information through radio frequency identification technology (Radio Frequency Identification). Optionally, acquiring the behavior information of the user includes: determining the behavior of the user through a camera or an infrared sensor, and acquiring and determining the intensity of the user's behavior through a linkage device.

When the user information is the user's physiological parameter information, obtaining the identity information of the user may be implemented as: obtaining the user information through a linkage device, where the linkage device is a device that can provide user information. Linked devices include, but are not limited to, smart bracelets, smart watches, smart helmets, smart skin patches, smart armbands, and the like.

When the user information is identity information or age information, obtaining user information may be implemented as: obtaining a user's face image through a camera, and determining the user's identity information based on the user's face image, or, age information, or, identity information and age information ; Among them, the camera may be any one of an airborne camera, a dedicated camera, and a security camera. Obtaining the user's identity information can also be implemented as: obtaining the user's identity information through RFID.

After obtaining the user identity information, S401 may optionally be implemented as: sending the identity information to a database, and matching the setting parameters corresponding to the identity information in the database. The database communicates with the air equipment, or with the air equipment and the linkage equipment. The database can be optionally set on a local area network (such as a smart home system), and can be optionally set on a cloud platform server.

When the setting parameters of the air device cannot be determined through the identity information, that is, when the setting parameters cannot be obtained according to the identity information, the operating mode is determined according to the age information, wherein the operating mode corresponds to the setting parameters one-to-one.

According to a second aspect of the embodiments of the present invention, a control device for an air device is provided.

In an optional embodiment, as shown in FIG. 10, the control device for the air equipment includes:

The first module 10 is configured to determine operating parameters of one or more air devices according to user information, where the user information includes one or two of behavior information and location information;

The second module 20 is configured to control the operation of one or more air equipments according to operating parameters.

In an optional embodiment, as shown in FIG. 11, the control device for the air equipment includes:

A third module 30 is configured to determine one or more operating parameters of the air equipment according to user information, where the user information includes one or two of identity information and age information;

The fourth module 40 is configured to control the operation of one or more air equipment according to the operation parameters.

In an optional embodiment, as shown in FIG. 12, the control device for the air equipment includes:

A fifth module 50 is configured to determine operating parameters of one or more air devices according to user information, where the user information is physiological parameter information of the user;

The user's physiological parameter information includes body surface temperature information, heart rate information, blood pressure information, blood glucose information, sleep information, blood oxygen content information, skin moisture information, respiratory rate information, brain activity information, female physiological period information, and fetal heart rate information. One or more. One or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator, and an air purifier;

A sixth module 60 is configured to control the operation of one or more air equipment according to the operating parameters.

In an optional embodiment, the first module, the third module, or the fifth module is specifically configured to determine the setting parameters of one or more air devices according to user information, and determine the setting parameters according to the setting parameters and current environmental information. Operating parameters of one or more air equipment.

In an optional implementation manner, the fifth module is specifically configured to: when the first physiological parameter is within a range of the first set index and is not equal to the first optimal physiological parameter, one or more air devices are in an operating state When changing the first set value based on the first operating parameter of one or more air equipment; wherein the user information includes the first physiological parameter, and the first set index range is a normal range of the first physiological parameter, The first optimal physiological parameter is a physiological parameter in which the user can obtain a comfortable experience; when the first physiological parameter is within the range of the first set index and is not equal to the first optimal physiological parameter, one or more air devices are in a non-operation state The operating parameters of one or more air devices are determined according to the setting parameters corresponding to the user information; when the first physiological parameter is not within the first set index range, the first operating parameter of the one or more air devices On the basis of changing the second setting value, or issuing a reminder to the user, or stopping one or more air devices, the second setting value is greater than the first setting value.

In an optional implementation manner, the fifth module is specifically configured to determine a level at which the second physiological parameter is located according to a preset index level, and determine the operation of one or more air devices according to the level at which the second physiological parameter is located. Parameters, wherein the user information includes a second physiological parameter, two or more numerical ranges associated with the second physiological parameter and their corresponding levels in the preset index level, one or more operating parameters of the air device and the second physiological parameter Associated with the level.

In an optional implementation manner, the fifth module is specifically configured to adjust operating parameters of one or more air devices according to brain activity information, wherein the user information includes brain activity information.

In an optional embodiment, as shown in FIG. 13, the control device for an air device includes:

A seventh module 70 is configured to determine two or more setting parameters of the air device according to two or more user information, wherein the user information includes one or two of identity information and age information, or user information Including location information and behavior information, or user information including user's physiological parameter information, or user information including one or more of identity information, age information, location information, behavior information, and user's physiological parameter information;

An eighth module 80 is configured to obtain one or more operating parameters of the air equipment from two or more setting parameters according to the priorities of the two or more user information, wherein the priority of the user information is Ambient air carrying capacity has a preset priority;

The ninth module 90 is configured to control the operation of one or more air devices according to the operating parameters.

In an optional implementation manner, the seventh module is further configured to count user information and user operation behaviors to determine set parameters.

In an optional implementation manner, the eighth module is specifically configured to determine the second user information having the highest priority among the two or more user information, and obtain the second user information according to the second setting parameter corresponding to the second user information. Operating parameters of one or more air equipment. Wherein, obtaining the operating parameters of one or more air equipment according to the second setting parameter corresponding to the second user information may be implemented as: obtaining current environmental information, and obtaining one or more air according to the second setting parameter and current environmental information The operating parameters of the device.

In an optional embodiment, the eighth module is specifically configured to determine the first priority information with the highest priority among two or more pieces of identity information when the user information includes the identity information; The corresponding setting parameters determine the operating parameters of one or more air equipment. When the user information includes age information, the priority of the operating mode is determined according to the priority of the age information; the priority of the setting parameters is determined according to the priority of the operating mode; one or more of the setting parameters are determined according to the highest priority setting parameter. Operating parameters of an air device. When the user information includes both identity information and age information, it is preferred to determine the operating parameters of one or more air equipment according to the setting parameters corresponding to the identity information. When the user information includes behavior information and location information, the user status is determined according to the behavior information and location information; the priority of the setting parameter is determined according to the priority of the user status; and one or more of the setting parameters are determined according to the highest priority setting parameter. Operating parameters of air equipment. When the user information includes identity information, age information, behavior information, and location information, the pregnancy and baby mode is the highest priority.

In an optional embodiment, the eighth module is specifically configured to determine the first user information with the highest priority for the first air device; and determine the first air device according to a setting parameter corresponding to the first user information. Operating parameters.

In an optional embodiment, the eighth module is specifically configured to determine the priority of the two or more user information according to a relative change rate of the two or more user information. Among the one or more setting parameters, one or more operating parameters of the air equipment are determined.

In an optional embodiment, the eighth module is specifically configured to acquire two or more first sub-setting parameters related to the first environment information among the two or more setting parameters, where the first environment The information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; a first is determined from two or more first sub-setting parameters according to the attributes of the first environmental information. Sub-run parameters.

In an optional embodiment, the eighth module is specifically configured to determine the comprehensive setting parameter among the two or more setting parameters according to the priority of the user information, and obtain two or more according to the comprehensive setting parameter. Two or more operating parameters of an air device having the same function, wherein the operating parameters include the operating power of each air device, and the first operating parameter having the smallest total power is determined from the two or more operating parameters.

In an optional embodiment, the fifth module includes:

A first unit, configured to obtain two or more setting parameters of one or more air devices according to the two or more characteristic information when the user information includes two or more conflicting characteristic information;

A second unit, configured to determine one or more operating parameters of the air equipment among the two or more setting parameters according to the priorities of the two or more characteristic information;

The third unit is configured to execute all operating parameters of one or more air devices determined according to the user information if there are no two or more conflicting feature information in the user information.

In an optional implementation manner, the second unit is specifically configured to determine the priority of the two or more characteristic information according to a relative change rate of the two or more characteristic information, and according to the first characteristic information having the highest priority Determine the operating parameters of one or more air equipment. The relative change rate reflects the degree to which the characteristic information changes. The larger the relative change rate, the greater the degree of change in the characteristic information, and the smaller the relative change rate, the smaller the degree of change in the characteristic information. Optionally, the relative change rate is divided into change levels.

In an optional implementation manner, the second unit is specifically configured to acquire two or more second sub-settings of the second environment information in the two or more setting parameters according to the two or more characteristic information. Parameters, wherein the second environmental information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; and is set in two or more second sub-items according to the attributes of the second environmental information The second sub-operation parameter is determined from the parameters.

In an optional embodiment, the control device for an air device further includes:

A tenth module is configured to obtain user information before determining operating parameters of one or more air equipment according to the user information.

In an optional implementation manner, the tenth module is specifically configured to obtain user information through a linkage device, where the linkage device is a device that can provide user information.

In an optional implementation manner, the tenth module is specifically configured to obtain user behavior information through a camera or an infrared sensor and position information through RFID, wherein acquiring the user's behavior information includes: determining the user through the camera or infrared sensor Behavioral action, which determines the intensity of the user's behavior through linkage with the device.

In an optional implementation manner, the tenth module is specifically configured to obtain user information through a linkage device when the user information is physiological parameter information of the user, where the linkage device is a device that can provide user information. Linked devices include, but are not limited to, smart bracelets, smart watches, smart helmets, smart skin patches, smart armbands, and the like.

Optionally, the tenth module is specifically configured to obtain a user's face image through a camera when the user information is identity information or age information, and determine the user's identity information, or age information, or identity information based on the user's face image. And age information; among them, the camera may be any one of an airborne camera, a dedicated camera, and a security camera.

Optionally, the tenth module is specifically configured to obtain user's identity information through RFID.

In an optional embodiment, the control device for an air device includes:

processor;

Memory for storing processor-executable instructions;

The processor is configured to:

Determine two or more setting parameters of the air device according to two or more user information, wherein the user information includes one or two of identity information and age information, or the user information includes location information and behavior information, Or, the user information includes user's physiological parameter information, or the user information includes one or more of identity information, age information, location information, behavior information, and user's physiological parameter information;

Obtain the operating parameters of one or more air devices from two or more set parameters according to the priority of two or more user information, wherein the priority of the user information is set in advance according to the user's ability to withstand ambient air Priority

Controls the operation of one or more air equipment based on operating parameters.

Optionally, the foregoing control method and device for an air device may be implemented in a network-side server, or in a mobile terminal, or in a dedicated control device.

According to a third aspect of the embodiments of the present invention, an air conditioning system is provided.

In some alternative embodiments, the air conditioning system includes a plurality of air equipment and the above-mentioned control device for the air equipment.

In an optional embodiment, a computer storage medium is provided, on which a computer program is stored, and the foregoing method is implemented when the computer program is executed by a processor. The computer storage medium includes a read only memory (Read Only Memory), a random access memory (RAM), a magnetic tape, an optical storage device, and the like.

Those of ordinary skill in the art may realize that the units and algorithm steps of each example described in combination with the embodiments disclosed herein can be implemented by electronic hardware, or a combination of computer software and electronic hardware. Whether these functions are performed in hardware or software depends on the specific application and design constraints of the technical solution. Those skilled in the art can use different methods to implement the described functions for each specific application, but such implementation should not be considered to be outside the scope of the present invention. Those skilled in the art can clearly understand that for the convenience and brevity of the description, the specific working process of the system and device described above can refer to the corresponding process in the foregoing method embodiments, and will not be repeated here.

It should be understood that the present invention is not limited to the processes and structures that have been described above and shown in the drawings, and various modifications and changes can be made without departing from the scope thereof. The scope of the invention is only limited by the appended claims.

Claims (10)

1. A control method for air equipment, comprising:

   Determining one or more operating parameters of the air equipment according to user information, wherein the user information includes one or both of behavior information and location information;

   The operation of one or more air equipment is controlled according to said operating parameters.
2. The control method according to claim 1, wherein the control method is applied to a case where there are two or more users, and the determining the operating parameters of the one or more air devices according to the user information comprises:

   Determining two or more setting parameters of the air equipment according to two or more user information;

   Obtain the operating parameters of one or more air devices from two or more set parameters according to the priority of user information, wherein the priority of the user information is a preset priority according to the user's ability to withstand ambient air .
3. The control method according to claim 1 or 2, wherein the one or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator, and an air purifier. Each.
4. The control method according to claim 1 or 2, wherein before determining the operating parameters of one or more air equipment based on user information, the method further comprises:

   User information is obtained through a linkage device, where the linkage device is a device that can provide user information.
5. A control device for air equipment, comprising:

   A first module is used to determine the operating parameters of one or more air devices according to user information, wherein the user information includes one or two of behavior information and location information;

   The second module controls one or more air equipments to operate according to the operating parameters.
6. The control device according to claim 5, wherein the control device is applied to a case where there are two or more users, and the first module is specifically configured to determine the air according to the information of the two or more users. Two or more setting parameters of the device; one or more operating parameters of the air device are obtained from the two or more setting parameters according to the priority of the user information, wherein the priority of the user information is based on the user Pre-set priorities for the ability to withstand ambient air, including the highest priority for special users.
7. The control device according to claim 5 or 6, wherein the one or more air devices include one or more of an air conditioner, a dehumidifier, a humidifier, a fresh air device, an oxygen generator and an air purifier. Each.
8. The control device according to claim 5 or 6, further comprising: a tenth module, configured to obtain user information through a linkage device before determining operating parameters of one or more air devices according to the user information, wherein The linkage device is a device that can provide user information.
9. An air conditioning system includes a plurality of air equipment, wherein the air conditioning system further comprises a control device for an air equipment according to any one of claims 5 to 8.
10. A computer-readable storage medium having stored thereon a computer program, characterized in that when the computer program is executed by a processor, the control method for an air device according to any one of claims 1 to 4 is implemented.

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