CN110631220B - Control method, device and system for air equipment and computer storage medium - Google Patents

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

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Publication number
CN110631220B
CN110631220B CN201810642370.3A CN201810642370A CN110631220B CN 110631220 B CN110631220 B CN 110631220B CN 201810642370 A CN201810642370 A CN 201810642370A CN 110631220 B CN110631220 B CN 110631220B
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information
air
user
parameters
parameter
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CN110631220A (en
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于洋
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Qingdao Haier Air Conditioner Gen Corp Ltd
Haier Smart Home Co Ltd
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Qingdao Haier Air Conditioner Gen Corp Ltd
Haier Smart Home Co Ltd
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Priority to PCT/CN2018/123868 priority patent/WO2019242275A1/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/64Electronic processing using pre-stored data
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F2120/00Control inputs relating to users or occupants
    • F24F2120/10Occupancy

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  • Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Fuzzy Systems (AREA)
  • Mathematical Physics (AREA)
  • Air Conditioning Control Device (AREA)

Abstract

The embodiment of the invention discloses a control method for air equipment, and belongs to the technical field of intelligent household appliances. The method comprises the following steps: determining one or more operating parameters of the air equipment according to user information, wherein the user information is physiological parameter information of a user; the operation of one or more air devices is controlled based on the operating parameters. In the technical scheme, the air equipment is controlled according to the physiological parameter information of the user, so that the requirement of the user on the ambient air can be automatically met in real time. When the air equipment is an air conditioner, the requirement of a user on the temperature can be automatically met in real time, and better use experience is brought to the user. The embodiment of the invention also discloses a control device and a system for the air equipment and a computer storage medium.

Description

Control method, device and system for air equipment and computer storage medium
Technical Field
The invention relates to the technical field of intelligent household appliances, in particular to a control method, a control device, a control system and a computer storage medium for air equipment.
Background
With the development of technology, the requirements of people on the living standard are higher and higher. In daily life, different people have differences in the perception of cold and heat, resulting in differences in their needs. Even if the same person, the cold and hot perception and the demand of the person in different time periods can be different, therefore, a fixed operation mode is set by general intelligent control according to personnel information, the implementation demand of a user cannot be met, and the user manually adjusts the air conditioner at every time, which is very troublesome.
Disclosure of Invention
The embodiment of the invention provides a control method for air equipment, which is used for controlling the air equipment according to physiological parameter information of a user, and can automatically meet the temperature requirement of the user in real time when the air equipment is an air conditioner, so that better use experience is brought to the user.
The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview and is intended to neither identify key/critical elements nor delineate the scope of such 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 embodiments of the present invention, there is provided a control method for an air appliance.
In an alternative embodiment, the 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 is physiological parameter information of a user;
controlling operation of one or more air devices based on the operating parameter.
In an alternative embodiment, the obtaining one or more operating parameters of the air device according to the user information includes:
when the user information comprises two or more feature information conflicting with each other, acquiring two or more setting parameters of one or more air devices according to the two or more feature information; wherein the characteristic information is information characterizing a physiological characteristic of the user;
and determining the operation parameters of the one or more air devices in the two or more set parameters according to the priority of the two or more characteristic information.
In an optional embodiment, the determining, according to the priority of the two or more pieces of feature information, the operation parameter of the one or more air devices from the two or more setting parameters includes:
determining the priority of the two or more pieces of feature information according to the relative change rate of the two or more pieces of feature information;
and determining the operating parameters of the one or more air devices according to the first characteristic information with the highest priority.
In an alternative embodiment, the determining the operation parameters of the one or more air devices from the two or more setting parameters according to the priority of the two or more feature information includes:
acquiring two or more second sub-setting parameters related to second environment information in the two or more setting parameters, wherein the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information and oxygen content information;
and determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attributes of the two or more characteristic information.
According to a second aspect of embodiments of the present invention, there is provided a control apparatus for an air appliance.
In an alternative embodiment, the control device for an air apparatus includes:
the fifth module is used for determining one or more operating parameters of the air equipment according to user information, wherein the user information is physiological parameter information of a user;
a sixth module for controlling operation of one or more air devices based on the operating parameter.
In an alternative embodiment, the fifth module comprises:
the first unit is used for acquiring two or more setting parameters of one or more air devices according to two or more feature information when the user information comprises two or more feature information conflicting with each other; wherein the characteristic information is information characterizing a physiological characteristic of the user;
a second unit, configured to determine, according to the priority of the two or more pieces of feature information, an operation parameter of the one or more air devices among the two or more setting parameters.
In an optional embodiment, the second unit is specifically configured to determine the priority of the two or more pieces of feature information according to the relative change rate of the two or more pieces of feature information; and determining the operating parameters of the one or more air devices according to the first characteristic information with the highest priority.
In an optional embodiment, the second unit is specifically configured to acquire two or more second sub-setting parameters related to second environment information in the two or more setting parameters, where the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; and determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attributes of the two or more characteristic information.
According to a third aspect of embodiments of the present invention, there is provided an air conditioning system.
In an alternative embodiment, the air conditioning system comprises a plurality of air devices and the control device for the air devices.
According to a fourth aspect of embodiments of the present invention, there is provided a computer storage medium.
In an alternative embodiment, the computer storage medium stores a computer program which, when executed by a processor, implements the control method for an air device described above.
The embodiment of the invention has the beneficial effects that: the air equipment is controlled according to the physiological parameter information of the user, and the requirement of the user on the ambient air can be automatically met in real time. When the air equipment is an air conditioner, the requirement of a user on the temperature can be automatically met in real time, and better use experience is brought to the user.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.
Drawings
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.
FIG. 1 is a schematic flow diagram illustrating a control method for an air plant in accordance with an exemplary embodiment;
FIG. 2 is a flow chart diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 3 is a flow chart diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 4 is a flow chart diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 5 is a schematic flow diagram illustrating a process for obtaining operating parameters of an air plant in accordance with an exemplary embodiment;
FIG. 6 is a schematic flow diagram illustrating a process for obtaining operating parameters of an air plant in accordance with an exemplary embodiment;
FIG. 7 is a flow chart diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 8 is a schematic flow chart illustrating a method for obtaining operating parameters of an air plant in accordance with an exemplary embodiment;
FIG. 9 is a schematic flow diagram illustrating a process for obtaining operating parameters of an air plant in accordance with an exemplary embodiment;
FIG. 10 is a block schematic diagram illustrating a control apparatus for an air appliance in accordance with an exemplary embodiment;
FIG. 11 is a block schematic diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 12 is a block schematic diagram illustrating a control method for an air appliance in accordance with an exemplary embodiment;
FIG. 13 is a block schematic diagram illustrating a control method for an air appliance, according to an exemplary embodiment.
Detailed Description
The following description and the drawings sufficiently illustrate specific embodiments of the invention to enable those skilled in the art to practice them. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The scope of embodiments of the invention encompasses the full ambit of the claims, as well as all available equivalents of the claims. Embodiments may be referred to herein, individually or collectively, by the term "invention" merely for convenience and without intending to voluntarily limit the scope of this application to any single invention or inventive concept if more than one is in fact disclosed. Herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed. The embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. For the structures, products and the like disclosed by the embodiments, the description is relatively simple because the structures, the products and the like correspond to the parts disclosed by the embodiments, and the relevant parts can be just described by referring to the method part.
Air conditioners as referred to herein generally refer to all devices capable of providing treated air directly to an enclosed space, room or area. It mainly includes refrigerating system for refrigeration and dehumidification and air circulation and purification device, also can include heating and ventilation device.
The humidifier mentioned herein refers to all household appliances capable of increasing the humidity of a room, including but not limited to evaporation type humidifiers, ultrasonic humidifiers, electric heating type humidifiers, immersion type electrode humidifiers, cold mist humidifiers, etc.
The dehumidifier referred to herein generally refers to all household appliances that are capable of reducing the humidity of a room.
Air purifiers as referred to herein generally refer to all household and similar appliances that have a certain ability to remove one or more contaminants, such as particulate matter, gaseous contaminants, microorganisms, etc., from the air.
Oxygen generators as referred to herein generally refer to all electrical appliances that produce oxygen.
The fresh air equipment mentioned in the text refers to all independent air processing systems composed of an air supply system and an air exhaust system, and mainly comprises two types of pipeline type fresh air equipment and non-pipeline type fresh air equipment.
In the prior art, after a user turns on an air conditioner and sets an operation parameter of the air conditioner, the air conditioner may continuously operate at the operation parameter, so that an indoor environment maintains a stable state. In an embodiment of the present invention, a control method for an air conditioner is provided, which can control the operation of the air conditioner according to user location information or behavior information when the control method is applied to the air conditioner. The position information or the behavior information of the user can reflect the actual requirements of the user, so the control method can meet the variable requirements of the user.
According to a first aspect of embodiments of the present invention, there is provided a control method for an air apparatus.
In an alternative embodiment, as shown in fig. 1, a control method for controlling an air appliance includes:
s101, determining one or more operating parameters of the air equipment according to user information, wherein the user information comprises one or two of behavior information and position information.
Users in different states have different requirements for ambient air, for example, when the user is in a sleeping state in a bedroom, the temperature of the ambient air in the bedroom is required to be higher, and air circulation is required; when the user is in a motion state, the indoor temperature needs to be reduced; when a user is in a toilet, a fresh air function needs to be started; in S101, the current behavior state of the user can be inferred from the behavior information and the location information of the user, so as to determine the operating parameters of the air equipment that meet the actual needs of the user in the behavior state.
And S102, controlling one or more air devices to operate according to the operation parameters.
In this embodiment, the air device can automatically adjust the operation state according to different requirements of the user, thereby satisfying the changeable requirements of the user. In some application scenarios, the user's requirement is not only one, for example, the user has requirements on the temperature and cleanliness of the ambient air at the same time, and in order to meet the requirements of the user, one air device with temperature regulation and purification functions may be controlled, or one air device with temperature regulation function (for example, an air conditioner) and one air device with purification function (for example, an air purifier) may be controlled at the same time. That is, controlling the operation of one air device or controlling the operation of a plurality of air devices may be selected according to the specific needs of the user.
With respect to the needs of the user and the type of air device, in an alternative 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. Correspondingly, the conditioning effect of the one or more air devices on the ambient air is mainly reflected in: adjusting one or more of temperature, humidity, cleanliness, freshness.
The user information in S101 is information for interacting with the air device and reflecting the user' S needs. In the above embodiment, the user information includes one or both of the behavior information and the location information, and it can be seen that in the above embodiment, the user interacts with the air device through the behavior information and the location information. Of course, the user information is not limited to the behavior information and the location information, and the user may interact with the air device through other user information.
In the following scenes, after a user turns on the air conditioner, the air conditioner can operate according to the parameters of the air conditioner during the last shutdown by default, in some public places or families, a plurality of users often use one air conditioner, but the requirements of each user are different, when different users use the air conditioner, the operating parameters of the air conditioner need to be reset according to the requirements of the users, the use complexity is increased, and the user experience effect is poor. Obviously, it is impossible to solve the above problem by continuing to use the user information, such as the user location information or the user behavior information.
Furthermore, the embodiment of the invention provides a control method for air equipment, when the control method is applied to an air conditioner, on the basis of automatically selecting proper operation parameters according to user information of a user, when a plurality of user information exist, the proper operation parameters are determined according to priorities of the plurality of user information, and special requirements of the user can be met. That is, the user information includes one or both of identity information and age information.
In an alternative embodiment, as shown in fig. 2, a control method for an air appliance includes:
s201, determining one or more operating parameters of the air equipment according to user information, wherein the user information comprises one or two of identity information and age information;
and S202, controlling one or more air devices to operate according to the operation parameters.
In this embodiment, each piece of user information corresponds to a set parameter, and the set parameter is a parameter preset by a user, or the set parameter is a parameter determined after statistics of operation behaviors of the user is performed. The corresponding setting parameters can be matched through certain user information. Each user has independent identity information, and before determining one or more operating parameters of the air equipment according to the user information, the identity information of the bound user is also included. Therefore, in the embodiment, the air equipment can automatically select proper operation parameters according to the user information, and different requirements of different users can be met.
In the following scenario, different users have different perceptions of cold and heat, resulting in different needs of different users. Even the same user, the perception and demand for cold and heat at different time periods is different. In the control method for the air equipment provided by the embodiment of the invention, the air equipment is controlled according to the physiological parameter information of the user, so that the requirement of the user on the ambient air can be automatically met in real time. When the air equipment is the air conditioner, the air conditioner is controlled according to the physiological parameter information of the user, the requirement of the user on the temperature can be automatically met in real time, and better use experience is brought to the user.
In an alternative embodiment, as shown in fig. 3, the control method for the air device may be implemented as:
s301, determining one or more operating parameters of the air equipment according to user information, wherein the user information is physiological parameter information of a user.
In S301, the physiological parameter information of the user includes one or more of body surface temperature information, heart rate information, blood pressure information, blood sugar information, sleep information, blood oxygen content information, skin moisture information, respiration rate information, brain activity information, female physiological phase information, and fetal 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.
And S302, controlling the operation of one or more air devices according to the operation parameters.
In this embodiment, the physiological parameter information of the user can reflect the requirement of the user on the ambient air, and the air device is controlled according to the physiological parameter information of the user, so that the requirement of the user on the ambient air can be automatically met in real time.
In an alternative embodiment, the control method for an air device may be implemented as:
determining the operation parameters of the air conditioner according to the body surface temperature information, and controlling the air conditioner to operate according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the dehumidifier and/or humidifier according to the body surface temperature information, and controlling the operation of the dehumidifier and/or humidifier according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the air conditioner according to the heart rate information, and controlling the air conditioner to operate according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the fresh air equipment according to the heart rate information, and controlling the operation of the fresh air equipment according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the air conditioner and/or the fresh air equipment according to the body surface temperature information and the heart rate information, and controlling the operation of the air conditioner and/or the fresh air equipment according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the air conditioner according to the blood pressure information, and controlling the operation of the air conditioner according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the fresh air equipment according to the blood pressure information, and controlling the operation of the fresh air equipment according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the fresh air equipment according to the blood sugar information, and controlling the operation of the fresh air equipment according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the air conditioner according to the blood sugar information, and controlling the operation of the air conditioner according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the fresh air equipment according to the blood oxygen content information, and controlling the operation of the fresh air equipment according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the dehumidifier and/or humidifier according to the skin moisture information, and controlling the operation of the dehumidifier and/or humidifier according to the operation parameters; or the like, or, alternatively,
determining the operation parameters of the fresh air equipment and/or the oxygen generator according to the respiration rate information, and controlling the operation of the fresh air equipment and/or the oxygen generator according to the operation parameters; or the like, or, alternatively,
and determining the operation parameters of the fresh air equipment and/or the oxygen generator according to the fetal heart rate information, and controlling the operation of the fresh air equipment and/or the oxygen generator according to the operation parameters.
In addition, the combination between the user information and the air equipment is not limited to the above technical solutions, and a person 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 alternative embodiment, S101, S201, S301 determines one or more operating parameters of the air device according to the user information, including: and determining the set parameters of one or more air devices according to the user information, and determining the operating parameters of one or more air devices according to the set parameters and the current environment information. The technical scheme is suitable for the technical scheme of determining the operation parameters of one or more air devices according to the user information. For example, the operation parameters of the air conditioner are determined according to the body surface temperature information, and the operation of the air conditioner is controlled according to the operation parameters, which can be implemented as follows: and determining the set parameters of the air conditioner according to the body surface temperature information, determining the operating parameters of the air conditioner according to the set parameters and the current environment information, and controlling the air conditioner to operate according to the operating parameters.
In an alternative embodiment, S301 determines one or more operating parameters of the air device according to the user information, and may be implemented as:
when the first physiological parameter is within the first set index range and is not equal to the first optimal physiological parameter and the one or more air devices are in the running state, changing a first set value on the basis of the first running parameter of the one or more air devices; the user information comprises 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 which can be used by a user for obtaining comfortable experience; at the moment, fine adjustment operation is carried out on the air equipment;
when the first physiological parameter is within a first set index range and is not equal to the first optimal physiological parameter and the one or more air devices are in a non-running state, determining the running parameters of the one or more air devices according to the set parameters corresponding to the user information;
and when the first physiological parameter is not in the first set index range, changing a second set value on the basis of the first operation parameter of the one or more air equipment, or sending a prompt to a user, or stopping the operation of the one or more air equipment, wherein the second set value is larger than the first set value.
The technical scheme can monitor the health condition of the user and ensure that the user obtains comfortable experience. In the technical scheme, the first set index range and the optimal physiological parameter of users with different constitutions are different in different seasons. If the user feels a very comfortable state in summer when the body surface temperature is 36 ℃, and feels a very comfortable state in winter when the body surface temperature is 37 ℃, the refrigeration cannot be started when the body surface temperature is 37 ℃ in winter. The control mode is controlled according to the change rule of the physiological characteristics. Specifically, the physiological indexes of the user are monitored in real time, each physiological index has a relatively stable value within a period of time, for example, the period of time of the body surface temperature is about 37 ℃, and the physiological indexes are changed sometimes, for example, the temperature is changed to 38 ℃ due to heat, and at this time, the device can be controlled to cool until the body surface temperature returns to 37 ℃ again. That is, the physiological characteristic is detected in real time, and when the parameter changes, the control module issues an instruction to change the current environment by adjusting the device, so that the changed physiological characteristic value of the user returns to the normal parameter. For this period of time, it can be set manually, for example, 10 hours, or 10 days.
When first physiological parameter body surface temperature information, heart rate information, blood pressure information, blood sugar information, skin moisture information, respiratory rate information and fetal heart rate information, all can adopt this technical scheme.
For example, when the first physiological parameter is body surface temperature information and the air equipment is an air conditioner, when the body surface temperature T of the user is within T1-T2 and T is not equal to T3, and the air conditioner is in an operating state, if T is less than T3, the current set temperature is increased by 0.5 ℃, or other first set values are increased; if T is more than T3, the current set temperature is adjusted to be lower by 0.5 ℃, or other first set values are adjusted to be lower. Wherein the difference between T and T3 is positively correlated with the first set value.
Or, when the body surface temperature T of the user is within T1-T2, T is not equal to T3, and the air conditioner is in the running state, under the heating mode, if T is less than T3, the current set wind speed is increased by 1 level, or other first set values are increased; if T > T3, the current set wind speed is reduced by 1 level, or other first set value. In the cooling mode, if T is less than T3, reducing the current set wind speed by 1 level, or reducing other first set values; if T > T3, the current set wind speed is increased by 1 level, or other first set value. Wherein the difference between T and T3 is positively correlated with the first set value. And if the set wind speed is the lowest wind speed or the highest wind speed, adjusting the set temperature of the air conditioner according to the body surface temperature T.
When the body surface temperature T of the user is within T1-T2, T is not equal to T3, and the air conditioner is in a non-operation state, if the room temperature needs to be raised, the current room temperature needs to be adjusted. 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 started in a heating mode, a temperature value and a wind speed corresponding to the body surface temperature T of the user are defaulted, such as 26 degrees and low wind, and the air conditioner is finely adjusted according to the principle after the air conditioner is started for a set time. If the room temperature is higher than 20 ℃, and the room temperature needs to be raised, the air conditioner is not started, and 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-T2, T is not equal to T3, and the air conditioner is in a non-operation state, if the current room temperature needs to be reduced, the current room temperature needs to be combined for adjustment. If the room temperature is higher than a certain value (such as 23 degrees), the air conditioner operates in a cooling mode, and a temperature value and a wind speed corresponding to the body surface temperature T of the user are set, such as 22 degrees and low wind. And after the air conditioner runs for a set time, finely adjusting the air conditioner according to the principle.
The other control mode when the air conditioner is not started and the room temperature needs to be adjusted is as follows: and starting the air conditioner, selecting a comfortable mode (or an intelligent mode) by the air conditioner, and selecting the starting mode and the set temperature by the air conditioner according to the current room temperature.
Optionally, the set temperature and the wind speed of the air conditioner are adjusted simultaneously.
When the body surface temperature T of the user is not between T1 and T2, if T is less than T1, the current set temperature is increased by 1 ℃, or 2 ℃, or 3 ℃, or other second set values, and a wind-avoiding mode is started; if T is more than T2, the current set temperature is adjusted to be lower by 1 ℃, or 2 ℃, or 3 ℃, or other second set values, and the wind-avoiding blowing mode is started.
In an application scene, determine the operating parameter of air conditioner and new trend equipment according to body surface temperature information and rhythm of the heart information, according to the operation of operating parameter control air conditioner and new trend equipment, can use as: if the body surface temperature is too low and the heart rate is too low, and the temperature needs to be increased, the operation of increasing the temperature is carried out; 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, the temperature is reduced; when the body surface temperature is too low and the heart rate is too high, the temperature is increased for the air conditioning equipment, and the air quantity is increased for the fresh air equipment. If the device is not on, then the current ambient temperature and CO need to be combined2The value of the concentration is judged, for example, when CO2At a concentration greater thanAnd (3) starting the fresh air equipment when the wind speed is in a set state (such as low wind) if the wind speed is set to be 1000ppm, and finely adjusting the fresh air equipment after the fresh air equipment runs for a set time.
When the user information comprises any one of blood pressure information, blood sugar information, blood oxygen content information, skin moisture information, respiratory rate information and fetal heart rate information, the specific adjusting mode can refer to the adjusting process of the air conditioner according to the body surface temperature information; when the user information comprises two or more of body surface temperature information, heart rate information, blood pressure information, blood sugar information, blood oxygen content information, skin moisture information, respiration rate information and fetal heart rate information, the specific adjusting mode can refer to the adjusting flow of the air conditioner and the fresh air equipment according to the body surface temperature information and the heart rate information.
In an alternative embodiment, S301 determines one or more operating parameters of the air device according to the user information, and may be implemented as:
determining the level of the second physiological parameter according to the preset index level, wherein the user information comprises the second physiological parameter, and two or more numerical value ranges and corresponding levels of the two or more numerical value ranges which are related to the second physiological parameter in the preset index level;
and determining one or more operating parameters of the air equipment according to the level of the second physiological parameter, wherein the one or more operating parameters of the air equipment are associated with the level of the second physiological parameter.
According to the technical scheme, the state of the user is classified, the air conditioning equipment is pertinently adjusted, and the user is further ensured to be in a comfortable state.
In an application scenario, the user information includes sleep information, and users with different sleep depths have different requirements on temperature and air volume. And determining the level of the second sleep parameter according to the preset sleep level, wherein the user information comprises the second sleep parameter, and two or more numerical value ranges and corresponding levels of the second sleep parameter in the preset sleep level. And determining the operating parameters of one or more air devices according to the level of the second sleep parameter, wherein the operating parameters of one or more air devices are associated with the level of the second sleep parameter. For example, the preset sleep levels include 5 sleep levels: x1, X2, X3, X4, and X5, and correspondingly, the set temperature and the air volume and the air direction of the air equipment include 5 operating states: s1, S2, S3, S4 and S5. Wherein, 5 operating states are preset operating states. When the second sleep level is X3, the operation state of the air appliance is S3.
In an application scenario, the user information includes information of a female physiological period, the female is not suitable for catching a cold in the physiological period, the temperature should be properly increased, fresh air is needed, and fresh air should be started. And determining the level of the second physiological period parameter according to the preset physiological period level, wherein the user information comprises the second physiological period parameter, and two or more numerical value ranges and corresponding levels of the second physiological period parameter in the preset physiological period level. And determining one or more operating parameters of the air equipment according to the level of the second physiological period parameter, wherein the one or more operating parameters of the air equipment are associated with the level of the second physiological period parameter. For example, the preset physiological period levels include 5 physiological period levels, X1, X2, X3, X4, and X5, and correspondingly, the combination between the set temperature and the set freshness of the air device includes 5 operating states: s1, S2, S3, S4 and S5. Wherein, 5 operating states are preset operating states, in which the indoor temperature can be controlled to be a set value and indoor CO can be controlled2The concentration is a set value, for example below 800 ppm. When the second physiological period level is X3, the operation state of the air device is S3. Acquiring a second physiological period parameter of the user through the wearable device, and determining operation parameters of the air conditioner and the fresh air device according to the second physiological period parameter; the position of the user is obtained through the wearable device, and the air conditioner and the fresh air device are controlled not to blow air to the position where the user is located.
In an alternative embodiment, S301 determines one or more operating parameters of the air device according to the user information, and may be implemented as:
adjusting one or more operating parameters of the air device based on the brain activity information, wherein the user information includes the brain activity information.
By adopting the technical scheme, a user can adjust one or more air devices more conveniently and rapidly. In the prior art, a wearable device detecting the brain can detect basic commands, and basic operations such as switching on and off the air conditioner, increasing the temperature, reducing the temperature, increasing the air volume, reducing the air volume and the like can be realized through the basic commands. For example, when the user wants to turn on the air conditioner, the wearable device acquires the brain wave signal to control the air conditioner to be turned on. In one application scenario, a person may generate a first brain wave signal when feeling cold, and a second brain wave signal when feeling hot, and the wearable device may detect the first brain wave signal and the second brain wave signal. The operation flow of the air equipment is as follows: when the first brain wave signal is detected, increasing the air output of the air conditioner or increasing the set temperature of the air conditioner; when the second brain wave signal is detected, the air output of the air conditioner is reduced, or the set temperature of the air conditioner is lowered.
When there are a plurality of user information, as shown in fig. 4, the aforementioned control method for the air appliance may be implemented as:
s401, determining two or more set parameters of the air equipment according to two or more pieces of user information, wherein the user information comprises one or two of identity information and age information, or the user information comprises position information and behavior information, or the user information comprises one or more of physiological parameter information of the user, or the user information comprises one or more of identity information, age information, position information, behavior information and physiological parameter information of the user.
Each user information corresponds to one setting parameter, and when a plurality of users use the air equipment at the same time, two or more user information and two or more corresponding setting parameters can be obtained. The set parameters are parameters preset by a user, wherein the parameters preset by the user can be acquired through the mobile terminal, user information and the parameters preset by the user are stored in a database in a one-to-one correspondence mode, and the database can be arranged in a local area network or on a cloud platform server. Among the parameters preset by the user, the user sets 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, an Ultra-mobile Personal Computer (UMPC), a netbook, a Personal Digital assistant (pda) (Personal Digital assistant), and the like, but is not limited thereto.
Optionally, when the user does not preset the setting parameter, the user information and the operation behavior of the user are counted to determine the setting parameter. For example, when the user information includes the body surface temperature information, the normal body surface temperature of the user is 37 ℃, the body surface temperature of the user is 38 ℃, and after 10 minutes, the user starts the air conditioner to select refrigeration, low wind and 26 ℃. The user encounters this situation a number of times and sets the air conditioner in the manner described above a number of times. For example, the above is repeated 3 times, or 5 times, or 10 times, or 20 times. Then, the following scenario: the user information is body surface temperature information, the normal body surface temperature is 37 ℃, the current body surface temperature is 38 ℃, and the corresponding setting parameters are as follows: cooling mode, low wind, 26 ℃ (setting parameters for air conditioner). If the body surface temperature of the user is 38 ℃, the operation parameters of the air conditioner are automatically determined according to the set parameters, namely the operation state of the air conditioner is controlled to be a refrigeration mode, low wind and 26 ℃.
S402, acquiring one or more operating parameters of the air equipment from two or more set parameters according to the priority of two or more pieces of user information, wherein the priority of the user information is preset according to the bearing capacity of the user to the ambient air.
Wherein the priority of the user information comprises the highest priority of the particular user. In the case where the user is a special user, for example, when the user is catching a cold or when the user is caring for an infant, and the user is not likely to be subjected to ambient air at a lower temperature, the user information of the user has the highest priority, that is, as long as the user is within the range that can be affected by the air equipment, the operating parameters of one or more air equipments are determined according to the setting parameters of the user, so that the requirements of the special user are met.
In S401, the user information corresponds to the setting parameter, and in S402, the following procedure is included: and determining second user information with the highest priority in the two or more pieces of user information, and acquiring the operating parameters of one or more pieces of air equipment according to second set parameters corresponding to the second user information. The obtaining of the operating parameters of the one or more air devices according to the second setting parameter corresponding to the second user information may be implemented as: and acquiring current environment information, and acquiring the operating parameters of one or more air devices according to the second set parameters and the current environment information.
For example, when the user information includes the body surface temperature information, the set temperature of the setting parameters is 26 ℃ when the body surface temperature is 37 ℃, the set temperature of the setting parameters is 25 ℃ when the body surface temperature is 38 ℃, and the set parameter of the setting parameters is 23 ℃ when the body surface temperature is 30 ℃. When the body surface temperature is 30 ℃ and the current indoor temperature is 16 ℃, controlling to start the heating mode of the air conditioner, setting the temperature to be 23 ℃, and gradually increasing the room temperature and keeping the room temperature at 23 ℃; when the body surface temperature is 37 ℃ and the current indoor temperature is 30 ℃, controlling the air conditioner to start the refrigeration mode, setting the temperature to be 26 ℃, and gradually reducing and keeping the room temperature at 26 ℃.
And S403, controlling one or more air devices to operate according to the operation parameters.
In this embodiment, when there are multiple users, the air device can meet the special needs of the particular user.
In an alternative embodiment, the step S402 of obtaining the operation parameters of the one or more air devices from the two or more setting parameters according to the priority of the two or more user information includes:
when the user information comprises identity information, determining first identity information with the highest priority in the two or more identity information; and determining the operating parameters of one or more air devices according to the set parameters corresponding to the first identity information.
When the user information comprises age information, determining the priority of the operation mode according to the priority of the age information; determining the priority of the set parameters according to the priority of the operation mode; and determining the operating parameters of one or more air devices according to the set parameters with the highest priority. The operation modes are set according to the ages of users, the operation modes correspond to the set parameters one by one, and the priority of the operation modes is preset according to the bearing capacity of different users on the ambient air. The operating modes include, but are not limited to: the operation mode comprises a pregnant baby mode, a child mode, a common mode and an old man mode, wherein the priority of the operation mode can be set from high to low as: pregnant infant mode > child mode > geriatric mode > general mode. For example, when an unfamiliar person is an adult, the air device is operated in a normal mode; if both adults and infants are identified, the air device is operated in a pregnant mode. Under the condition that the user does not preset the parameters, the embodiment can still ensure that the user obtains better experience.
When the user information simultaneously comprises identity information and age information, preferentially selecting to determine the operating parameters of one or more air devices according to the set parameters corresponding to the identity information.
When the user information comprises behavior information and position information, determining the user state according to the behavior information and the position information; determining the priority of the set parameters according to the priority of the user state; and determining the operating parameters of one or more air devices according to the set parameters with the highest priority. Wherein, the user state refers to the activity state of the user, including but not limited to: bathing state, motion state, reading state, cleaning health state, entertainment state, user state and setting parameter one-to-one correspondence, for example, the user is in the motion state, and the corresponding setting parameter is: temperature 24 deg.C, humidity 40%, PM2.5 less than 50 μ g/m3, CO2Less than 800ppm and an oxygen content of 21%, wherein PM2.5 is particles with an aerodynamic equivalent diameter of less than or equal to 2.5 microns in ambient air, also called fine particles; correspondingly, the operating parameters of the air equipment are as follows: the air conditioner is in a refrigeration state, the air purifier is in an intelligent mode at 24 ℃ with medium-speed wind, the automatic wind is generated, the fresh air equipment is with medium-speed wind, and the oxygen generator is started. The user is in an entertainment state, and the corresponding setting parameters are as follows: the temperature is 26 ℃, the humidity is 60 percent, and the PM2.5 is less than 60 mu g/m3CO2 < 1000ppm, oxygen contentAmount 20.9%; correspondingly, the operating parameters of the air plant are: the air conditioner outputs refrigeration state, low-speed air, 26 ℃, and the air purifier is in an intelligent mode and automatically blows air; the fresh air equipment is used for blowing air at a low speed, and the oxygen generator is closed. The priority of the user state is a priority preset according to the air bearing capacity of the user in different states to the environment, for example, the priority of the user state from high to low may be: bathing state, moving state, reading state, cleaning state and entertainment state.
When the user information simultaneously comprises identity information, age information, behavior information and position information, the pregnancy-infant mode is taken as the highest priority, namely when the infant is detected to exist indoors, the operation parameters of one or more air devices are determined according to the set parameters corresponding to the pregnancy-infant mode. And when the user returns to the room, determining the operating parameters of one or more indoor air devices according to the set parameters corresponding to the bathing state.
The embodiment can meet the special requirements of special users.
In this embodiment, if it is recognized that the priorities of the front and rear users are the same, the operation parameters of one or more air devices are determined according to the setting parameters of the front user, or the operation parameters of one or more air devices are determined according to the setting parameters of the rear user.
In an application scenario, a user is in a motion state, the user runs on a treadmill, the treadmill is a linkage device, the running speed of the user can be obtained through the treadmill, the motion intensity of the user is obtained, and when the speed of the treadmill is less than 10km/h, the air device operates according to set parameters corresponding to a first motion state, for example: the air conditioner is in a refrigeration state, and the temperature is 24 ℃ at medium speed wind; the air purifier is in an intelligent mode and automatically blows wind; the fresh air equipment is high-speed wind, and the oxygen generator is started. 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 a refrigeration state, and the temperature is 24 ℃ at medium speed wind; the air purifier is in an intelligent mode and automatically blows wind; the fresh air equipment is high-speed wind, and the oxygen generator is started. If the running speed of the user is increased from 9km/h to 11km/h, the air equipment is automatically switched from the first running state to the second running state.
In an alternative embodiment, the step S402 of obtaining the operation parameter of the one or more air devices from the two or more setting parameters according to the priority of the two or more pieces of user information includes:
determining first user information with the highest priority aiming at the first air equipment;
and determining the operating parameters of the first air equipment according to the set parameters corresponding to the first user information.
And repeating the steps until the operation parameters of all the air equipment are determined. In the technical scheme, different user information has different priorities for the same air equipment, and different air equipment has different priorities for the same user information. The technical scheme can meet the most main requirements of a plurality of users. For example, if the temperature requirement of the third user for the ambient air is relatively high, such as the user is relatively afraid of cooling, then the third user has the highest priority in controlling the air conditioner; the cleanliness requirement of the ambient air by the fourth user is relatively high, and the fourth user has the highest priority in terms of control of the air purifier. When the air equipment operates, the air purifier operates according to the set parameters corresponding to the user information of the third user, and the air purifier operates according to the set parameters corresponding to the user information of the fourth user, so that the most main requirements of the third user and the fourth user are met at the same time.
In an alternative embodiment, the step S402 of obtaining the operation parameters of the one or more air devices from the two or more setting parameters according to the priority of the two or more user information includes:
determining the priority of the two or more pieces of user information according to the relative change rate of the two or more pieces of user information, and determining the operating parameters of one or more pieces of air equipment in two or more set parameters according to the user information with the highest priority.
For recording convenience, the relative change rates of two or more pieces of user information are ranked, wherein the higher the ranking, 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 variation level of the fifth user is 2, the heart rate variation level is 1, the body surface temperature variation level of the sixth user is 2, and the heart rate variation level is 3. In the change of the user information, the maximum change degree is the heart rate information of the sixth user, and the operation parameters of one or more air devices are determined according to the set parameters corresponding to the relative change rate of the heart rate information of the sixth user.
In an alternative embodiment, as shown in fig. 5, the step S402 of obtaining the operation parameter of the one or more air devices from the two or more setting parameters according to the priority of the two or more pieces of user information includes:
s501, acquiring two or more first sub-setting parameters related to first environment information in the two or more setting parameters, wherein the first environment information is any one of temperature information, humidity information, cleanliness information, freshness information and oxygen content information.
Alternatively, one setting parameter may include one or more of a sub-setting parameter regarding temperature, a sub-setting parameter regarding humidity, a sub-setting parameter regarding cleanliness, and a sub-setting parameter regarding freshness.
S502, determining a first sub-operation parameter from 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 corresponding relation between the change of the first environment information and the change of the user comfort level, and the corresponding relation comprises that the user comfort level is poor or the user comfort level is good when the first environment information is large; when the first environment information becomes small, the user comfort level becomes poor, or the user comfort level becomes good. For example, the higher the cleanliness, the better the user comfort; the higher the freshness, the better the user comfort. For a plurality of first sub-setting parameters representing first environment information, the comfort level of a user is better, the priority of the first sub-setting parameters is higher, and the first sub-operation parameters are determined according to the first sub-setting parameters with the highest priority.
And executing the steps S501 and S502 for multiple times to obtain a plurality of sub-operation parameters, and combining the plurality of sub-operation parameters to obtain the operation parameters of one or more air devices. The air equipment is controlled according to the operation parameters acquired by the technical scheme, and users can be guaranteed to have better experience in the ambient air.
When the first environment information is temperature information, humidity information, cleanliness information, and freshness information, respectively, the specific implementation of the above technical scheme is as follows:
when the first environment information is temperature information, acquiring two or more first sub-setting parameters related to the temperature information in the two or more setting parameters, and determining the highest setting value in the two or more first sub-setting parameters as a first sub-operation parameter;
when the first environment information is humidity information, acquiring two or more first sub-set parameters related to the humidity information in the two or more set parameters, and taking an average value of the two or more first sub-set parameters as a first sub-operation parameter;
when the first environmental information is cleanliness information, acquiring two or more first sub-set parameters related to the cleanliness information in the two or more set parameters, and determining the lowest set value in the two or more first sub-set parameters as a first sub-operation parameter;
when the first environment information is freshness information, two or more first sub-setting parameters related to the freshness information in the two or more setting parameters are obtained, and the lowest setting value in the two or more first sub-setting parameters is determined as a first sub-operation parameter.
The technical scheme is executed once, a sub-operation parameter related to the environment information is obtained, and the number of times of executing the technical scheme is the same as the number of sub-setting parameters contained in the setting parameters. After the last technical scheme is executed, the obtained plurality of sub-operation parameters are combined to be used as the operation parameters of one or more air devices.
For example, the first user has set parameters of "refrigeration 26 ℃, humidity 40%, PM2.5 > 100 μ g/m3Start purification, CO2The fresh air is started at the concentration of more than 1500ppm, and the set parameters of a second user are refrigeration 23 ℃, humidity 60 percent and PM2.5 more than 150 mu g/m3Start purification, CO2Fresh air is turned on at 1000 ppm. When only a first user is detected to be indoors, determining one or more operation parameters of the air equipment according to the set parameters of the first user, starting the air conditioner, setting the temperature to be 26 ℃, starting the dehumidifier when the humidity is more than 40%, controlling the humidity to be 40%, starting the humidifier when the humidity is less than 40%, controlling the humidity to be 40%, and when PM2.5 is more than 100 mu g/m3Starting air purifier or air conditioner purification function when CO is in use2When the concentration is more than 1500ppm, starting fresh air equipment or starting the fresh air function of an air conditioner; when the first user and the second user are detected to be both indoors, in the set parameters of the first user, the sub-set parameter related to the temperature information is refrigeration 26 ℃, in the set parameters of the second user, the sub-set parameter related to the temperature information is refrigeration 23 ℃, and refrigeration 26 ℃ is selected as one sub-operation parameter of the operation parameter; regarding the humidity information, a sub-setting parameter in the setting parameters of the first user is "humidity 40%", a sub-setting parameter in the setting parameters of the second user is "humidity 60%", and the average value of the two is "humidity 50%" to be taken as a sub-operation parameter; regarding the cleanliness information, the sub-setting parameters of the first user are ' PM2.5 > 100 μ g/m3 start purge ', and the sub-setting parameters of the second user are ' PM2.5 > 150 μ g/m3Starting purification, selecting PM2.5 > 100 μ g/m3Opening purge as a sub-operational parameter; regarding the freshness information, a sub-setting parameter among the setting parameters of the first user is "CO2If the fresh air is started at the speed of more than 1500ppm, the sub-setting parameter in the setting parameters of the second user is' CO2If the fresh air is more than 1000ppm, selecting' CO2Opening fresh air more than 1000ppm is taken as a sub-operation parameter. Combining the above four sub-operation parametersThe operation parameters are refrigeration 26 ℃, humidity 50 percent and PM2.5 more than 100 mu g/m3Start purification, CO2Fresh air is turned on at 1000 ppm.
In an alternative embodiment, as shown in fig. 6, when there are two or more air devices having the same function, the obtaining of the operation parameter of one or more air devices from the two or more setting parameters according to the priority of the two or more user information in S402 includes:
s601, determining a comprehensive setting parameter from two or more setting parameters according to the priority of the user information.
In this embodiment, when two or more air devices having the same function exist, for example, in the case where an ultrasonic humidifier or a humidifier during electric heating exists simultaneously in the humidification aspect, that is, in the case where two or more air devices having the same function exist, the comprehensive setting parameter in S501 refers to an effect achieved by the functions of the two or more air devices having the same function, for example, the comprehensive setting parameter "humidity 50%". The control method mentioned in the foregoing is equivalent to determining one or more operating parameters of the air plant directly from the integrated set-point parameters.
And S602, acquiring two or more operation parameters of two or more air devices with the same function according to the comprehensive set parameters, wherein the operation parameters comprise the operation power of each air device.
In the case of the determination of the overall setting parameters, two or more air devices having the same function have two or more combinations in order to achieve the effect determined by the overall setting parameters. For example, the overall setting parameter "cooling power 1000W", and there are two indoor devices for cooling: the air conditioner comprises a first air conditioner and a second air conditioner, wherein the power of the first air conditioner is 1500W, the power of the second air conditioner is 3000W, and at the moment, the operation parameters comprise three types, namely: only the first air conditioner is started, so that comprehensive set parameters can be met; second operating parameters: only the second air conditioner is started, so that comprehensive set parameters can be met; third operating parameters: and the first air conditioner and the second air conditioner are started simultaneously, so that comprehensive set parameters can be met.
And S603, determining a first operation parameter with the minimum total power in the two or more operation parameters.
Of the three operating parameters described above, the total power required for the first operating parameter is 1500W, the total power required for the second operating parameter is 3000W, and the total power required for the third operating parameter is 4500W, and it is apparent that the total power required for the first operating parameter is less than the total power required for the second operating parameter and the third operating parameter, and therefore, the first operating parameter is selected as the first operating parameter.
Further, when there are two or more first operating parameters satisfying the minimum power, the second operating parameter relating to the minimum number of air devices is determined among the two or more first operating parameters. For example, the overall setting parameter "cooling power 3000W", and there are three devices for cooling indoors: the power of the first air conditioner is 1500W, the power of the second air conditioner is 1500W, and the power of the third air conditioner is 3000W, so the first operation parameter includes two kinds, the first operation parameter: starting the first air conditioner and the second air conditioner simultaneously; second first operating parameter: only the third air conditioner is started. In a first operating parameter, two air systems are involved, and in a second first operating parameter, one air system is involved, so that the second first operating parameter is selected as the second operating parameter.
The embodiment can also save energy to the maximum extent while ensuring that the adjusting effect of the air equipment on the indoor air achieves the expected effect of the effect.
In the foregoing, when one operation parameter of the air equipment determined according to one piece of user information conflicts with another operation parameter of the air equipment determined according to another piece of user information, by setting different priorities for the one operation parameter and the another operation parameter, the conflict between the two is avoided.
However, one 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 the like. The method comprises the steps of determining one operation parameter of the air equipment according to one information included in user information, determining another operation parameter of the air equipment according to another information included in the user information, wherein the operation parameters of the air equipment inevitably generate conflict.
When the user information includes two or more feature information conflicting with each other, acquiring one or more operating parameters of the air equipment according to the user information, including:
acquiring two or more setting parameters of one or more air devices according to the two or more characteristic information;
and determining one or more operating parameters of the air equipment from the two or more set parameters according to the priority of the two or more characteristic information.
And if two or more pieces of feature information which conflict with each other do not exist in the user information, executing all the operation parameters of one or more air devices determined according to the user information.
On this basis, as shown in fig. 7, the aforementioned control method for the air apparatus may be implemented as follows:
and S701, acquiring two or more setting parameters of one or more air devices according to the two or more characteristic information.
The characteristic information is information included in the user information and conflicts with each other, and the two or more characteristic information means that two or more operation parameters of the same air equipment can be determined according to the two or more characteristic information, and one air equipment can only operate according to one operation parameter, so that the two or more operation parameters conflict.
Optionally, the two or more characteristic information includes one or more of 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 hydration information, respiration rate information, brain activity information, female circadian phase information, and fetal heart rate information.
S702, determining one or more operating parameters of the air equipment in two or more set parameters according to the priority of the two or more pieces of characteristic information.
And S703, controlling the operation of one or more air devices according to the operation parameters.
In an alternative embodiment, as shown in fig. 8, the operation parameters of one or more air devices are determined from two or more setting parameters according to the priorities of two or more pieces of characteristic information, specifically:
s801, determining the priority of two or more pieces of feature information according to the relative change rate of the two or more pieces of feature information.
The relative change rate reflects the degree of change of the feature information, and the greater the relative change rate, the greater the degree of change of the feature information, and the smaller the relative change rate, the smaller the degree of change of the feature information. Optionally, the relative rate of change is divided into change levels.
S802, determining one or more operating parameters of the air equipment according to the first characteristic information with the highest priority.
For example, if the body surface temperature variation level is 2 and the heart rate variation level is 1, the operating parameters of one or more air devices are determined according to the body surface temperature.
The embodiment can meet the most important requirements of users.
In an alternative embodiment, the operation parameter of one or more air devices is determined from two or more setting parameters according to the priority of two or more pieces of characteristic information, specifically:
determining the priority of two or more pieces of characteristic information according to the type of the air conditioner adjusting equipment; and determining one or more operating parameters of the air equipment according to the characteristic information with the highest priority. For example, when the air device is an air conditioner, the body surface temperature information > the blood pressure information > the heart rate information, and when the air device is a fresh air device, the blood oxygen information > the heart rate information > the blood pressure information.
In an alternative embodiment, as shown in fig. 9, the determining one or more operating parameters of the air plant from the two or more setting parameters according to the priority of the two or more characteristic information includes:
s901, acquiring two or more second sub-setting parameters related to second environment information in two or more setting parameters according to the two or more characteristic information, wherein the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information and oxygen content information;
s902, determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attribute of the second environment information.
The attribute of the two or more pieces of feature information refers to a corresponding relation between the change of the two or more pieces of feature information and the change of the user comfort level, and includes that the user comfort level is poor or the user comfort level is good when the feature information is large; when the feature information becomes small, the user comfort level becomes poor, or the user comfort level becomes good. And determining a second sub-operation parameter according to the second sub-setting parameter with the highest priority, wherein the comfort level of a user is better in the two or more second sub-setting parameters for setting the second environment information, and the priority of the second sub-setting parameter is higher. For example, in a plurality of set temperatures, a sub-operation parameter is determined according to a sub-set parameter with a high temperature; among the plurality of set freshness degrees, CO is set according to the setting2The sub-setting parameter with the lowest concentration determines the sub-operation parameter. If the temperature is 28 ℃ during the female physiological period, CO is required2Below 1000 ppm; when the heart rate changes, the temperature is 26 ℃ and CO is required2Within 800 ppm. At this time, the temperature was compared and set to 28 ℃; to CO2The concentration requirements are compared, and CO is controlled2Within 800 ppm.
And executing the steps S901 and S902 for multiple times to obtain a plurality of sub-operation parameters, and combining the plurality of sub-operation parameters to obtain the operation parameters of one or more air devices. The air equipment is controlled according to the operation parameters acquired by the technical scheme, and users can be guaranteed to have better experience in the ambient air.
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, acquiring the user identity information may be implemented as: and acquiring the user information through the linkage equipment, wherein the linkage equipment is equipment capable of providing the user information.
The linkage device is an electrical device which provides necessary functions to maintain normal life in daily life of a user. Linkage devices include, but are not limited to: a range hood, an electromagnetic stove, a gas stove, an electric oven, an electric cooker, a bathroom water heater, a washing machine, an intelligent toilet lid, a television, a projector, a computer and a treadmill. The setting position of the linkage equipment in the household life is generally fixed, for example: the treadmill is arranged in the sports fitness room; the range hood, the electromagnetic range and the gas range are arranged in a kitchen; the bathroom water heater and the intelligent toilet cover are arranged in a toilet. Therefore, the position information of the user can be determined according to the starting condition of one linkage device. In addition, different linkages have different functions, such as: the treadmill is used for exercising the body, the range hood, the electromagnetic stove or the gas stove are used for cooking, and the bathroom water heater is used for bathing and the like. Therefore, the behavior information of the user can be determined according to the running time of the linkage equipment and the combined running condition of two or more linkage equipment. The behavior information and the position information of the user can be more accurately determined through the linkage equipment. Obtaining user information may also be implemented as: behavior information of a user is acquired through a camera or an infrared sensor, and position information is acquired through a Radio Frequency Identification (RFID) technology. Optionally, the acquiring the behavior information of the user includes: the behavior action of the user is determined through the camera or the infrared sensor, and the behavior intensity of the user is determined through the linkage equipment.
When the user information is physiological parameter information of the user, acquiring the identity information of the user may be implemented as: and acquiring the user information through the linkage equipment, wherein the linkage equipment is equipment capable of providing the user information. The linkage devices include, but are not limited to, smart bracelets, smart watches, smart helmets, smart skin patches, smart armrings, and the like.
When the user information is identity information or age information, the obtaining of the user information may be implemented as: acquiring a facial image of a user through a camera, and determining identity information, or age information, or identity information and age information of the user according to the facial image of the user; the camera can be any one of a self-contained camera, a special camera and a security camera of the air equipment. The method for acquiring the identity information of the user can also be implemented as follows: and acquiring the identity information of the user through the RFID.
After obtaining the user identity information, S401 may be implemented as: and sending the identity information to a database, and matching the set parameters corresponding to the identity information in the database. The database is communicated with the air equipment or the air equipment and the linkage equipment, and the database can be optionally arranged on a local area network (such as an intelligent home system) and can be optionally arranged on a cloud platform server.
When the setting parameters of the air equipment can not be determined through the identity information, namely when the setting parameters can not be obtained according to the identity information, the running mode is determined according to the age information, wherein the running mode corresponds to the setting parameters one to one.
According to a second aspect of embodiments of the present invention, there is provided a control apparatus for an air appliance.
In an alternative embodiment, as shown in fig. 10, a control apparatus for an air appliance includes:
the system comprises a first module 10, a second module and a third module, wherein the first module is used for determining one or more operating parameters of the air equipment according to user information, and the user information comprises one or two of behavior information and position information;
a second module 20 for controlling the operation of one or more air devices based on the operating parameters.
In an alternative embodiment, as shown in fig. 11, a control apparatus for an air appliance includes:
a third module 30, configured to determine one or more operating parameters of the air device according to user information, where the user information includes one or both of identity information and age information;
a fourth module 40 for controlling operation of the one or more air devices based on the operating parameters.
In an alternative embodiment, as shown in fig. 12, a control apparatus for an air appliance includes:
a fifth module 50, configured to determine one or more operating parameters of the air device according to user information, where the user information is physiological parameter information of a user;
the physiological parameter information of the user comprises one or more of body surface temperature information, heart rate information, blood pressure information, blood sugar information, sleep information, blood oxygen content information, skin moisture information, respiration rate information, brain activity information, female physiological period information and fetal heart rate information. The one or more air devices comprise 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 for controlling operation of the one or more air devices based on the operating parameter.
In an optional embodiment, the first module, the third module, or the fifth module is specifically configured to determine a setting parameter of one or more air devices according to the user information, and determine an operating parameter of the one or more air devices according to the setting parameter and the current environment information.
In an optional implementation manner, the fifth module is specifically configured to: when the first physiological parameter is within the first set index range and is not equal to the first optimal physiological parameter and the one or more air devices are in the running state, changing a first set value on the basis of the first running parameter of the one or more air devices; the user information comprises 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 which can be used by a user for obtaining comfortable experience; when the first physiological parameter is within a first set index range and is not equal to the first optimal physiological parameter and the one or more air devices are in a non-running state, determining the running parameters of the one or more air devices according to the set parameters corresponding to the user information; and when the first physiological parameter is not in the first set index range, changing a second set value on the basis of the first operation parameter of the one or more air equipment, or sending a prompt to a user, or stopping the operation of the one or more air equipment, wherein the second set value is larger than the first set value.
In an optional implementation manner, the fifth module is specifically configured to determine a level of the second physiological parameter according to a preset index level; and determining the operation parameters of one or more air devices according to the level of the second physiological parameter, wherein the user information comprises the second physiological parameter, two or more numerical value ranges which are related to the second physiological parameter in the preset index level and the corresponding levels thereof, and the operation parameters of one or more air devices are related to the level of the second physiological parameter.
In an alternative embodiment, the fifth module is specifically configured to adjust the operating parameters of the one or more air devices based on brain activity information, wherein the user information includes the brain activity information.
In an alternative embodiment, as shown in fig. 13, the control device for an air apparatus includes:
a seventh module 70, configured to determine two or more setting parameters of the air device according to two or more pieces of 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 information, or the user information includes physiological parameter information of the user, or the user information includes one or more of identity information, age information, location information, behavior information, and physiological parameter information of the user;
an eighth module 80, configured to obtain, from the two or more setting parameters, an operating parameter of one or more air devices according to priorities of two or more pieces of user information, where the priority of the user information is a priority preset according to a user's ability to bear ambient air;
a ninth module 90 for controlling operation of one or more air devices based on the operating parameters.
In an optional implementation manner, the seventh module is further configured to count user information and an operation behavior of the user to determine the setting parameter.
In an optional implementation manner, the eighth module is specifically configured to determine second user information with a highest priority from among the two or more pieces of user information, and obtain the operating parameters of the one or more air devices according to second setting parameters corresponding to the second user information. The obtaining of the operating parameters of the one or more air devices according to the second setting parameter corresponding to the second user information may be implemented as: and acquiring current environment information, and acquiring the operating parameters of one or more air devices according to the second set parameters and the current environment information.
In an optional embodiment, the eighth module is specifically configured to determine, when the user information includes identity information, first identity information with a highest priority among the two or more identity information; and determining the operating parameters of one or more air devices according to the set parameters corresponding to the first identity information. When the user information comprises age information, determining the priority of the operation mode according to the priority of the age information; determining the priority of the set parameters according to the priority of the operation mode; and determining the operating parameters of one or more air devices according to the set parameters with the highest priority. When the user information simultaneously comprises identity information and age information, preferentially selecting to determine the operating parameters of one or more air devices according to the set parameters corresponding to the identity information. When the user information comprises behavior information and position information, determining the user state according to the behavior information and the position information; determining the priority of the set parameters according to the priority of the user state; and determining the operating parameters of one or more air devices according to the set parameters with the highest priority. When the user information simultaneously comprises identity information, age information, behavior information and position information, the pregnant baby mode is taken as the highest priority.
In an optional embodiment, the eighth module is specifically configured to determine, for the first air device, first user information with a highest priority; and determining the operating parameters of the first air equipment according to the set parameters corresponding to the first user information.
In an optional embodiment, the eighth module is specifically configured to determine priorities of two or more pieces of user information according to relative change rates of the two or more pieces of user information, and determine one or more operating parameters of the air equipment from among the two or more set parameters according to the user information with the highest priority.
In an optional embodiment, the eighth module is specifically configured to acquire two or more first sub-setting parameters related to first environment information in the two or more setting parameters, where the first environment information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; and determining a first sub-operation parameter from the two or more first sub-setting parameters according to the attribute of the first environment information.
In an optional embodiment, the eighth module is specifically configured to determine, according to the priority of the user information, a comprehensive setting parameter among the two or more setting parameters, and obtain, according to the comprehensive setting parameter, two or more operation parameters of the two or more air devices having the same function, where the operation parameters include an operation power of each air device, and determine, among the two or more operation parameters, a first operation parameter having a minimum total power.
In an alternative embodiment, the fifth module comprises:
the first unit is used for acquiring two or more setting parameters of one or more air devices according to two or more feature information when the user information comprises two or more feature information conflicting with each other;
a second unit, configured to determine, from the two or more setting parameters, an operating parameter of the one or more air devices according to the priority of the two or more pieces of feature information;
and the third unit is used for executing all the operation parameters of one or more air devices determined according to the user information if two or more feature information conflicting with each other do not exist in the user information.
In an optional embodiment, the second unit is specifically configured to determine priorities of the two or more pieces of feature information according to relative change rates of the two or more pieces of feature information, and determine the operating parameters of the one or more air devices according to the first piece of feature information with the highest priority. The relative change rate reflects the degree of change of the feature information, and the greater the relative change rate, the greater the degree of change of the feature information, and the smaller the relative change rate, the smaller the degree of change of the feature information. Optionally, the relative rate of change is divided into change levels.
In an optional embodiment, the second unit is specifically configured to obtain two or more second sub-setting parameters related to second environment information in the two or more setting parameters according to the two or more characteristic information, where the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; and determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attribute of the second environment information.
In an alternative embodiment, the control device for an air apparatus further comprises:
a tenth module for obtaining the user information before determining the operating parameters of the one or more air devices based on the user information.
In an optional implementation manner, the tenth module is specifically configured to acquire the user information through a linkage device, where the linkage device is a device that can provide the user information.
In an optional implementation manner, the tenth module is specifically configured to acquire behavior information of a user through a camera or an infrared sensor, and acquire location information through an RFID, where acquiring the behavior information of the user includes: the behavior action of the user is determined through the camera or the infrared sensor, and the behavior intensity of the user is determined through the linkage equipment.
In an optional implementation manner, the tenth module is specifically configured to, when the user information is physiological parameter information of the user, acquire the user information through a linkage device, where the linkage device is a device that can provide the user information. The linkage devices include, but are not limited to, smart bracelets, smart watches, smart helmets, smart skin patches, smart armrings, and the like.
Optionally, the tenth module is specifically configured to, when the user information is identity information or age information, obtain a facial image of the user through the camera, and determine the identity information, or the age information, or the identity information and the age information of the user according to the facial image of the user; the camera can be any one of a self-contained camera, a special camera and a security camera of the air equipment.
Optionally, the tenth module is specifically configured to acquire the identity information of the user through an RFID.
In an alternative embodiment, a control apparatus for an air appliance includes:
a processor;
a memory for storing processor-executable instructions;
wherein the processor is configured to:
determining two or more set parameters of the air equipment according to two or more pieces of user information, wherein the user information comprises one or two of identity information and age information, or the user information comprises position information and behavior information, or the user information comprises physiological parameter information of a user, or the user information comprises one or more of identity information, age information, position information, behavior information and physiological parameter information of the user;
acquiring one or more operating parameters of the air equipment from two or more set parameters according to the priority of two or more pieces of user information, wherein the priority of the user information is preset according to the bearing capacity of a user on the ambient air;
one or more air devices are controlled to operate based on the operating parameters.
Alternatively, the foregoing control method and apparatus for air devices may be implemented in a network-side server, or implemented in a mobile terminal, or implemented in a dedicated control device.
According to a third aspect of embodiments of the present invention, there is provided an air conditioning system.
In some alternative embodiments, the air conditioning system comprises a plurality of air devices and the control device for air devices described above.
In an alternative embodiment, a computer storage medium is provided, on which a computer program is stored which, when being executed by a processor, carries out the method of the preceding paragraph. The computer storage medium includes a read Only memory rom (read Only memory), a random Access memory ram (random Access memory), a magnetic tape, an optical storage device, and the like.
Those of ordinary skill in the art will appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention. It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the system and the apparatus described above may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.
It is to be understood that the present invention is not limited to the procedures and structures described above and shown in the drawings, and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (6)

1. A control method for an air appliance, comprising:
determining one or more operating parameters of the air equipment according to user information, wherein the user information is physiological parameter information of a user;
controlling operation of one or more air devices according to the operating parameters;
wherein, the obtaining of the operating parameters of one or more air devices according to the user information comprises: when the user information comprises two or more feature information conflicting with each other, acquiring two or more setting parameters of one or more air devices according to the two or more feature information; wherein the characteristic information is information characterizing a physiological characteristic of the user; determining the operating parameters of the one or more air devices in the two or more set parameters according to the priorities of the two or more characteristic information;
the determining, according to the priorities of the two or more pieces of feature information, the operation parameters of the one or more pieces of air equipment among the two or more set parameters specifically includes: determining the priority of the two or more pieces of feature information according to the relative change rate of the two or more pieces of feature information;
and determining the operating parameters of the one or more air devices according to the first characteristic information with the highest priority.
2. The control method of claim 1, wherein determining the operating parameter of the one or more air devices from the two or more setting parameters based on the priority of the two or more characteristic information comprises:
acquiring two or more second sub-setting parameters related to second environment information in the two or more setting parameters, wherein the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information and oxygen content information;
and determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attributes of the two or more characteristic information.
3. A control device for an air appliance, comprising:
the fifth module is used for determining one or more operating parameters of the air equipment according to user information, wherein the user information is physiological parameter information of a user;
a sixth module for controlling operation of one or more air devices based on the operating parameter;
wherein the fifth module comprises:
the first unit is used for acquiring two or more setting parameters of one or more air devices according to two or more feature information when the user information comprises two or more feature information conflicting with each other; wherein the characteristic information is information characterizing a physiological characteristic of the user;
a second unit, configured to determine, according to priorities of the two or more pieces of feature information, an operation parameter of the one or more pieces of air equipment among the two or more setting parameters;
the second unit is specifically configured to determine priorities of the two or more pieces of feature information according to relative change rates of the two or more pieces of feature information; and determining the operating parameters of the one or more air devices according to the first characteristic information with the highest priority.
4. The control device according to claim 3, wherein the second unit is specifically configured to acquire two or more second sub-setting parameters related to second environment information from the two or more setting parameters, wherein the second environment information is any one of temperature information, humidity information, cleanliness information, freshness information, and oxygen content information; and determining a second sub-operation parameter from the two or more second sub-setting parameters according to the attributes of the two or more characteristic information.
5. An air-conditioning system comprising a plurality of air-conditioning apparatuses, characterized in that the air-conditioning system further comprises a control device for air-conditioning apparatuses as claimed in claim 3 or 4.
6. A computer storage medium on which a computer program is stored, characterized in that the computer program realizes the control method for an air appliance according to claim 1 or 2 when executed by a processor.
CN201810642370.3A 2018-06-21 2018-06-21 Control method, device and system for air equipment and computer storage medium Active CN110631220B (en)

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