CN107228454B - Method and device for air conditioner control - Google Patents

Abstract

The embodiment of the invention discloses a method for controlling an air conditioner, which comprises the following steps: acquiring the initial set temperature of air conditioners of a plurality of users in a cell; calculating an average value T of the air conditioner initial setting temperatures of the plurality of users; determining an air conditioning target temperature ti of the ith first-class user according to the average value T, wherein i is 1,2,3 …; and adjusting the air conditioner temperature of the ith first-class user to a target temperature ti. The air conditioner initial setting temperature of the first type of users in the community is automatically intervened and adjusted by utilizing the average value of the air conditioner initial setting temperatures of a plurality of users in the same community, so that the energy consumption corresponding to the adjusted target temperature is lower than that corresponding to the initial setting temperature. Therefore, the room temperature big data is effectively utilized to carry out more targeted and accurate adjustment on the room temperature of a specific user, the requirement of the user on the regulation and control of the room temperature can be met, and the user can be helped to reduce the energy consumption of the air conditioner. The invention also discloses a device for controlling the air conditioner.

Description

method and device for air conditioner control

Technical Field

The invention relates to the technical field of air conditioners, in particular to a method and a device for controlling an air conditioner.

Background

At present, the requirements of people on working, living and learning environments are continuously improved, and people always want to be in a comfortable environment no matter how the outside weather exists, so that the air conditioner is more and more widely applied and gradually becomes one of important devices which are indispensable in the life of people. However, the air conditioner brings about a great power consumption while improving and enhancing the quality of the office or residential environment, and therefore, the energy saving of the air conditioner is receiving more and more attention. In recent years, according to statistics, the power shortage occurs in nearly 20 provinces and cities, and some places even adopt power limiting measures, so that although the power consumption is saved to a certain extent, the function of the air conditioner is limited by the power limiting measures, different requirements of different users cannot be met, and the application of the air conditioner is hindered.

disclosure of Invention

the embodiment of the invention provides a method and a device for controlling an air conditioner, which can meet the requirement of a user on room temperature regulation and control and help the user to reduce the energy consumption of the air conditioner. 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 method for air conditioning control, including: acquiring the initial set temperature of air conditioners of a plurality of users in a cell; calculating an average value T of the air conditioner initial setting temperatures of the plurality of users; determining an air conditioning target temperature ti of the ith first-class user according to the average value T, wherein i is 1,2,3 …; and adjusting the air conditioner temperature of the ith first-class user to a target temperature ti. And the energy consumption corresponding to the adjusted target temperature ti is lower than the energy consumption corresponding to the initial set temperature of the ith first-class user. Wherein the ith first type user is a user in the cell.

Optionally, when the air conditioner operates in the heating mode, determining an air conditioner target temperature ti of the ith first class user according to the average value T, including: when the initial set temperature Ti of the ith first-class user is greater than or equal to the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as T; and when the initial set temperature of the ith first-class user is less than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

optionally, when the air conditioner operates in the cooling mode, determining an air conditioner target temperature ti of the ith first-class user according to the average value T, including: when the initial set temperature Ti of the ith first-class user is less than or equal to the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the average value T; and when the initial set temperature of the ith first-class user is greater than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

optionally, the determining an air conditioning target temperature ti of the ith user of the first class according to the average value T includes: calculating the difference value delta T between the initial set temperature Ti of the ith first-class user and the average value T; and determining the air-conditioning target temperature ti of the ith first-class user according to the difference delta T.

Optionally, when the air conditioner operates in the heating mode, determining an air conditioner target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; when the difference value delta T is smaller than the first set temperature value and larger than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; and when the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti. Wherein Δ t1 is greater than zero degrees and less than the first set temperature value.

optionally, when the air conditioner operates in the heating mode, determining an air conditioning target temperature ti of the ith first class user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; at 1 is greater than zero degrees and less than the first set temperature value and at 2 is less than zero degrees and greater than the second set temperature value.

Optionally, when the air conditioner operates in the cooling mode, determining an air conditioner target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is smaller than or equal to a second set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T2; when the difference value delta T is larger than the second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; and when the difference value delta T is greater than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti. Wherein Δ t2 is less than zero degrees and greater than the second set temperature value.

Optionally, when the air conditioner operates in the cooling mode, determining an air conditioner target temperature ti of the ith first-class user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; at 1 is greater than zero degrees and less than the first set temperature value and at 2 is less than zero degrees and greater than the second set temperature value.

Optionally, determining the air-conditioning target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith user as the initial set temperature Ti; when the difference value Δ T is less than or equal to the second set temperature value, or when the difference value Δ T is greater than or equal to the first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti- Δ T/2. Wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

Optionally, the method for air conditioning control further includes: and generating an adjusting instruction according to the air conditioner target temperature ti of the ith first-class user, and sending the adjusting instruction to the air conditioner of the ith first-class user.

Optionally, the method for air conditioning control further includes: after an adjusting instruction is sent, detecting whether a user intervention instruction exists, wherein the user intervention instruction is an instruction for changing the adjusted set temperature by a user; updating a user intervention parameter when the user intervention instruction is detected, wherein the user intervention parameter is used for representing the number of times of detecting the user intervention instruction.

Optionally, the method for air conditioning control further includes: and when the user intervention parameter is greater than or equal to a preset threshold value, stopping adjusting the initial set temperature of the ith first-class user.

according to a second aspect of embodiments of the present invention, there is provided an apparatus for air conditioning control, including: the system comprises an acquisition module, a control module and a control module, wherein the acquisition module is used for acquiring the air conditioner initial setting temperature of a plurality of users in a cell; the calculation module is used for calculating the average value T of the air conditioner initial setting temperatures of the users; the processing module is used for determining the air-conditioning target temperature ti of the ith first-class user according to the average value T; 1,2,3 …; and the adjusting module is used for adjusting the air conditioner temperature of the ith first-class user to a target temperature ti. And the energy consumption corresponding to the adjusted target temperature ti is lower than the energy consumption corresponding to the initial set temperature of the ith first-class user. Wherein the ith first type user is a user in the cell.

Optionally, when the air conditioner operates in the heating mode, the processing module is configured to determine an air-conditioning target temperature Ti of the ith first-class user as T when the initial set temperature Ti of the ith first-class user is greater than or equal to the average value T; and when the initial set temperature of the ith first-class user is less than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

Optionally, when the air conditioner operates in a cooling mode, the processing module is configured to determine an air-conditioning target temperature Ti of the ith first-class user as T when the initial set temperature Ti of the ith first-class user is less than or equal to the average value T; and when the initial set temperature of the ith first-class user is greater than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

Optionally, the processing module includes: the calculation submodule is used for calculating the difference value delta T between the initial set temperature Ti of the ith first-class user and the average value T; and the processing submodule is used for determining the air-conditioning target temperature ti of the ith first-class user according to the difference delta T.

Optionally, when the air conditioner operates in the heating mode, the processing sub-module is configured to determine an air conditioner target temperature Ti of the ith first type of user to be Ti- Δ T1 when the difference Δ T is greater than or equal to a first set temperature value; when the difference value delta T is smaller than the first set temperature value and larger than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; when the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t1 is greater than zero degrees and less than the first set temperature value.

Optionally, when the air conditioner operates in the heating mode, the processing sub-module is configured to determine, when the difference Δ T is greater than a second set temperature value and smaller than a first set temperature value, an air conditioner target temperature Ti of the ith first-class user as the initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; at 1 is greater than zero degrees and less than the first set temperature value and at 2 is less than zero degrees and greater than the second set temperature value.

Optionally, when the air conditioner operates in a cooling mode, the processing sub-module is configured to determine that the air conditioner target temperature Ti of the ith first-class user is Ti- Δ T2 when the difference Δ T is less than or equal to a second set temperature value; when the difference value delta T is larger than the second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; when the difference value delta T is greater than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t2 is less than zero degrees and greater than the second set temperature value.

Optionally, when the air conditioner works in a cooling mode, the processing sub-module is configured to determine, when the difference Δ T is greater than a second set temperature value and smaller than a first set temperature value, an air conditioner target temperature Ti of the ith first-class user as the initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; at 1 is greater than zero degrees and less than the first set temperature value and at 2 is less than zero degrees and greater than the second set temperature value.

Optionally, the processing sub-module is configured to determine, when the difference Δ T is greater than a second set temperature value and smaller than a first set temperature value, an air-conditioning target temperature Ti of the ith user as the initial set temperature Ti; when the difference value delta T is smaller than or equal to the second set temperature value, or when the difference value delta T is larger than or equal to the first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti-delta T/2; wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

Optionally, the apparatus for air conditioning control further includes: the generating module is used for generating an adjusting instruction according to the air-conditioning target temperature ti of the ith first-class user; and the sending module is used for sending an adjusting instruction to the air conditioner of the ith first-class user.

Optionally, the apparatus for air conditioning control further includes: the detection module is used for detecting whether a user intervention instruction exists after the sending module sends the adjusting instruction, and the user intervention instruction is an instruction for changing the adjusted set temperature by a user; and the counting module is used for updating a user intervention parameter when the detection module detects the user intervention instruction, wherein the user intervention parameter is used for representing the number of times of detecting the user intervention instruction.

Optionally, the adjusting module is further configured to stop adjusting the ith first-class user initial set temperature when the user intervention parameter is greater than or equal to a preset threshold.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

The method comprises the steps of obtaining air conditioner initial setting temperatures of a plurality of users in a community, and automatically adjusting the air conditioner initial setting temperatures of the first class of users in the community by combining with an average value T of the air conditioner initial setting temperatures of the plurality of users in the same community, so that energy consumption corresponding to an adjusted target temperature is lower than energy consumption corresponding to the initial setting temperature. Therefore, the room temperature big data is effectively utilized to carry out more targeted and accurate adjustment on the room temperature of a specific user, the requirement of the user on the regulation and control of the room temperature can be met, and the user can be helped to reduce the energy consumption of the air conditioner.

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 flow diagram illustrating a method for air conditioning control according to an exemplary embodiment;

FIG. 2 is a graph of statistics of a day of use of a user's air conditioner in accordance with an embodiment of the present invention;

FIG. 3 is a graph illustrating statistics of usage of a user's air conditioner for another day according to an embodiment of the present invention;

Fig. 4 is a block diagram illustrating an apparatus for air conditioning control 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.

Fig. 1 is a flowchart illustrating a method for air conditioning control according to an exemplary embodiment, including:

Step 101, acquiring air conditioner initial set temperatures of a plurality of users in a cell.

the air conditioner initial setting temperature of a plurality of users is the temperature which is expected to be reached by the air conditioner and set by the users according to the self requirements and habits, and the user requirements are reflected.

And 102, calculating an average value T of the air conditioner initial setting temperatures of the plurality of users.

And 103, determining the air conditioning target temperature T of the ith first-class user according to the average value T, wherein i is 1,2 and 3 ….

wherein, the first type of users are users who accept intervention adjustment, and in some embodiments, the users can send an acceptance control instruction through a remote controller to indicate that the intervention control is accepted. In other embodiments, the user may select an accept control option, indicating acceptance of the intervention control, via the control panel of the air conditioner.

Because the air conditioner initial setting temperature reflects the user requirements, the air conditioner initial setting temperature of each user may be different, and the energy consumption of the air conditioner is increased when the air conditioner initial setting temperature of the user is too high or too low. The average value T of the air conditioner initial setting temperatures of a plurality of users is calculated, the average requirements of the plurality of users can be reflected, the target temperature of each user is determined according to the average value T and the air conditioner initial setting temperature of each user, and the target temperature of each user is determined, namely the target temperature corresponding to the ith user is ti, so that the energy consumption of the air conditioner is reduced while the self requirements of each user are considered.

And 104, adjusting the air conditioner temperature of the ith first-class user to a target temperature ti.

The method provided by the embodiment obtains the air conditioner initial setting temperatures of a plurality of users in a cell, and automatically intervenes and adjusts the air conditioner initial setting temperatures of the first class of users in the cell by combining the average value T of the air conditioner initial setting temperatures of the plurality of users in the same cell, so that the energy consumption corresponding to the adjusted target temperature is lower than the energy consumption corresponding to the initial setting temperature. Therefore, the room temperature big data is effectively utilized to carry out more targeted and accurate adjustment on the room temperature of a specific user, the requirement of the user on the regulation and control of the room temperature can be met, and the user can be helped to reduce the energy consumption of the air conditioner.

In some embodiments, the air conditioner initial set temperature is the temperature expected to be reached by the air conditioner set by the user according to the user's own needs and habits, and thus the user needs are reflected. When the air conditioner is started, the adjusting condition is not reached immediately, so that the starting time of the air conditioner can be recorded, and the air conditioner temperature of the ith first-class user is adjusted to the target temperature ti when the preset time interval is formed between the current time and the starting time. The preset time duration can be obtained through data statistics, and the time required by the air conditioner to reach the indoor temperature meeting the preset condition from the initial indoor temperature at the starting time is used for determining the preset time duration.

In the practical application process of the air conditioner, due to the difference of the external environment, people have different requirements on the functions of the air conditioner. For example, in winter, the user turns on the heating mode of the air conditioner, the user turns on the air conditioner to the set temperature at first, the distribution of the set temperature is relatively discrete, and the ratio of each temperature such as 30 degrees, 26 degrees, 28 degrees is set to be high. For example, in order to obtain the setting habit of the user on the air conditioner set temperature, statistics is carried out on user data of the southern non-heating city in the heating season from 12 months to 2 months in the next year, and the statistical result of the big data shows that the set usage duration ratio of 30 degrees is the highest, the usage ratio of 26 degrees is the second, and the usage ratio of 28 degrees is the third. However, the difference of the wearing habits of the user is large, when the user is at home in winter, the wearing of short sleeves, home clothes, cotton clothes and the like is possible, the wearing of the clothes is strongly related to the set temperature, sometimes, the user directly sets the set temperature to 30 degrees firstly, but after the indoor temperature rises, the user can accept lower set temperature, but at the moment, the user often forgets to adjust the set temperature of the air conditioner again, and therefore energy consumption is wasted.

In the heating season, user data are randomly selected for statistics, the selected data comprise indoor temperature, outdoor temperature, set temperature and the like of an area where the user is located, the user air conditioner runs for 79 days in the heating season, the time length of the set temperature is greater than 26 degrees accounts for 97.6%, the statistical results are obtained through curve data shown in fig. 2 and fig. 3, the users are randomly extracted through the same method, the data statistics is carried out to obtain basically the same results, and meanwhile, the fact that even if the users are intensively set at 30 degrees, the 27 degrees can be accepted is found. Therefore, a higher set temperature is set when the user powers on, and a lower set temperature is acceptable after the indoor temperature rises.

in the graph of fig. 2, air conditioner usage data for any day of the month of january for randomly selected users is shown, which relates to the change in set temperature, indoor temperature, power and outdoor temperature of the air conditioner over time, which varies from 19:40 to 23: 52 data was recorded every 8 minutes. The 4 curves in fig. 2 are set temperature, indoor temperature, outdoor temperature and power in sequence from top to bottom according to the leftmost position. The set temperature, namely the initial set temperature is 30 degrees, the straight line indoor temperature with a turn in the middle is a curve which is increased from 15 degrees and finally approaches to the set temperature, the recorded outdoor temperature initial temperature is a curve with a small change amplitude slightly lower than the indoor temperature, the power is displayed on the lowest part of the graph 2, and when the user initial set temperature is reduced, the power is reduced.

In the graph shown in fig. 3, which shows the air conditioner usage data of the user on another day in fig. 2, the related parameters are the same as the categories of the parameters in fig. 2, and the 4 curves in fig. 3 are the set temperature, the indoor temperature, the power, and the outdoor temperature in order from the top to the bottom according to the leftmost position. In fig. 3, the conditions of use of the air conditioner from 21:24 to 22:15 on the next day are recorded, the set temperature is a straight line with an initial set temperature of 30 degrees, the indoor temperature is a curve that rises first and then falls, and a part of the time period coincides with the user initial set temperature, the power is a curve that is negatively correlated with the indoor temperature, and the outdoor temperature is the lowest curve in fig. 3.

Accordingly, the same problem exists in the cooling season, i.e., when the user needs air conditioning cooling in summer. Generally, when the air conditioner is turned on, a user will first set a lower set temperature, and after the indoor temperature is reduced, the user can also accept a higher set temperature.

different user initial set temperatures correspond to different adjustments. The user initial setting temperature is set by the user, so that the use habit of the user is reflected, the habit of the user is also considered in the adjusting process and the air conditioner adjusting process, and different adjusting strategies are indicated according to the habit.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, determining the air conditioning target temperature ti of the ith first type user according to the average value T includes: when the initial set temperature Ti of the ith first-class user is greater than or equal to the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as T; and when the initial set temperature of the ith first-class user is less than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

optionally, in some embodiments, when the air conditioner operates in the cooling mode, determining the air conditioning target temperature ti of the ith first type user according to the average value T includes: when the initial set temperature Ti of the ith first-class user is less than or equal to the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the average value T; and when the initial set temperature of the ith first-class user is greater than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

Optionally, in some embodiments, the determining the air conditioning target temperature ti of the ith first type user according to the average value T includes: calculating the difference value delta T between the initial set temperature Ti and the average value T of the ith first-class user; and determining the air conditioning target temperature ti of the ith first-class user according to the difference value delta T.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, determining the air conditioner target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; when the difference value delta T is smaller than a first set temperature value and larger than zero, determining the air-conditioning target temperature ti of the ith first-class user as an average value T; and when the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti. Wherein Δ t1 is greater than zero degrees and less than the first set temperature value.

Optionally, the first set temperature value is 1 ℃,2 ℃,3 ℃ or 4 ℃.

Alternatively,. DELTA.t 1 is 0.5 ℃, 1 ℃ or 1.5 ℃.

optionally, in some embodiments, when the air conditioner operates in the cooling mode, determining the air conditioner target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T2; when the difference value delta T is larger than a second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as an average value T; and when the difference value delta T is greater than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti. Wherein Δ t2 is less than zero degrees and greater than a second set temperature value.

Optionally, the second set temperature value is-1 ℃, -2 ℃, -3 ℃, or-4 ℃.

Alternatively,. DELTA.t 2 is-0.5 deg.C, -1 deg.C, or-1.5 deg.C.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, determining the air conditioning target temperature ti of the ith first type user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user as an initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; Δ t1 is greater than zero and less than a first set temperature value, and Δ t2 is less than zero and greater than a second set temperature value.

Optionally, in some embodiments, when the air conditioner operates in the cooling mode, determining the air conditioner target temperature ti of the ith first type user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; Δ t1 is greater than zero and less than a first set temperature value, and Δ t2 is less than zero and greater than a second set temperature value.

Optionally, in some embodiments, determining the air conditioning target temperature ti of the ith user according to the difference Δ T includes: when the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith user as an initial set temperature Ti; and when the difference value delta T is smaller than or equal to the second set temperature value, or when the difference value delta T is larger than or equal to the first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti-delta T/2. Wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

Optionally, the first set temperature value is 1 ℃,2 ℃,3 ℃ or 4 ℃.

Optionally, the second set temperature value is-1 ℃, -2 ℃, -3 ℃, or-4 ℃.

Alternatively,. DELTA.t 1 is 0.5 ℃, 1 ℃ or 1.5 ℃.

Alternatively,. DELTA.t 2 is-0.5 deg.C, -1 deg.C, or-1.5 deg.C.

In an actual implementation process, the method for controlling the air conditioner, which is provided by the invention, can instruct the air conditioner to execute through the cloud platform server, and can also execute through the air conditioner.

with reference to the method flow shown in fig. 1, a cloud platform server obtains a plurality of user initial set temperatures reported by an air conditioner, determines a target temperature of an ith first-class user with reference to the ith first-class user initial set temperature and an average value T of the air conditioner initial set temperatures of the plurality of users, generates an adjustment instruction, includes the target temperature ti of the ith first-class user, and sends the adjustment instruction to the air conditioner, so that the air conditioner adjusts the set temperature of the air conditioner of the user according to the adjusted set temperature in the adjustment instruction after receiving the adjustment instruction. With reference to the above description, the air-conditioning target temperature ti may be an air-conditioning initial set temperature, or may be a temperature after the air-conditioning initial set temperature is turned down or turned up. And the first set temperature value, the second set temperature value and the preset value related in the adjusting process are stored in the cloud platform server in advance.

in some embodiments, the cloud platform server may further record a starting time reported by the air conditioner, and send an adjustment instruction to the air conditioner after a preset time interval from the starting time.

optionally, in some implementations, the cloud platform server may further detect the number of times of the user intervention instruction acquired by the air conditioner, and if the adjusted air conditioner receives the user intervention instruction, that is, an instruction for the user to change the adjusted set temperature, it indicates that the adjusted set temperature is not a result expected by the user. Further, recording a user intervention parameter, and stopping the adjustment of the air conditioner when the user intervention parameter is greater than or equal to a preset threshold value.

Optionally, in some embodiments, in order to better improve the user experience and the feedback of the user on the air conditioner adjustment, the air conditioner is adjusted only once during one turn-on process. If the energy-saving intervention is carried out in the daytime, the energy-saving intervention can still be carried out at night, and the calculation is once.

Fig. 4 is a block diagram illustrating an apparatus for air conditioning control according to an exemplary embodiment, including: an acquisition module 401, a calculation module 402, a processing module 403 and an adjustment module 404.

The acquiring module 401 is configured to acquire air conditioner initial set temperatures of a plurality of users in a cell, the calculating module 402 is configured to calculate an average value T of the air conditioner initial set temperatures of the plurality of users, and the processing module 403 is configured to determine an air conditioner target temperature ti of an ith first-class user according to the average value T, where i is 1,2, and 3 …; the adjusting module 404 is configured to adjust the air conditioner temperature of the ith user of the first category to a target temperature ti. And the energy consumption corresponding to the adjusted target temperature ti is lower than the energy consumption corresponding to the initial set temperature of the ith first-class user. Wherein the ith first type user is a user in the cell.

The device provided by this embodiment performs automatic intervention and adjustment on the air-conditioning initial set temperatures of the first type of users in the cell by acquiring the air-conditioning initial set temperatures of the plurality of users in the cell and combining with the average value T of the air-conditioning initial set temperatures of the plurality of users in the same cell, so that the energy consumption corresponding to the adjusted target temperature is lower than the energy consumption corresponding to the initial set temperature. Therefore, the room temperature big data is effectively utilized to carry out more targeted and accurate adjustment on the room temperature of a specific user, the requirement of the user on the regulation and control of the room temperature can be met, and the user can be helped to reduce the energy consumption of the air conditioner.

The apparatus shown in fig. 4 is used for implementing the method flow shown in fig. 1, and related contents are described the same, which are not described herein again.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, the processing module 403 is configured to determine the air conditioner target temperature Ti of the ith first-class user as T when the initial setting temperature Ti of the ith first-class user is greater than or equal to the average value T; and when the initial set temperature of the ith first-class user is less than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

Optionally, in some embodiments, when the air conditioner operates in the cooling mode, the processing module 403 is configured to determine the air-conditioning target temperature Ti of the ith first-class user as T when the initial setting temperature Ti of the ith first-class user is less than or equal to the average value T; and when the initial set temperature of the ith first-class user is greater than the average value T, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti.

optionally, in some embodiments, the processing module 403 includes a computation submodule and a processing submodule. The calculating submodule is used for calculating a difference value delta T between the initial set temperature Ti and the average value T of the ith first-class user, and the processing submodule is used for determining the air-conditioning target temperature Ti of the ith first-class user according to the difference value delta T.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, the processing sub-module is configured to determine the air conditioner target temperature Ti of the ith first type of user to be Ti- Δ T1 when the difference Δ T is greater than or equal to the first set temperature value; when the difference value delta T is smaller than a first set temperature value and larger than zero, determining the air-conditioning target temperature ti of the ith first-class user as an average value T; when the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t1 is greater than zero degrees and less than a first set temperature value.

Optionally, in some embodiments, when the air conditioner operates in the heating mode, the processing sub-module is configured to determine the air conditioner target temperature Ti of the ith first-class user as the initial set temperature Ti when the difference Δ T is greater than the second set temperature value and less than the first set temperature value; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; Δ t1 is greater than zero and less than a first set temperature value, and Δ t2 is less than zero and greater than a second set temperature value.

Optionally, in some embodiments, when the air conditioner is operating in the cooling mode, the processing sub-module is configured to determine the air conditioner target temperature Ti of the ith first-class user to be Ti- Δ T2 when the difference Δ T is less than or equal to the second set temperature value; when the difference value delta T is larger than a second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as an average value T; when the difference value delta T is greater than or equal to zero, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t2 is less than zero degrees and greater than a second set temperature value.

Optionally, in some embodiments, when the air conditioner operates in the cooling mode, the processing sub-module is configured to determine the air conditioner target temperature Ti of the ith first-class user as the initial set temperature Ti when the difference Δ T is greater than the second set temperature value and less than the first set temperature value; when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1; and when the difference value delta T is smaller than or equal to the second set temperature value, determining the air-conditioning target temperature Ti of the first type of users as Ti-delta T2. The second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree; Δ t1 is greater than zero and less than a first set temperature value, and Δ t2 is less than zero and greater than a second set temperature value.

Optionally, in some embodiments, the processing sub-module is configured to determine the air-conditioning target temperature Ti of the ith user as the initial set temperature Ti when the difference Δ T is greater than the second set temperature value and less than the first set temperature value; when the difference value delta T is smaller than or equal to a second set temperature value, or when the difference value delta T is larger than or equal to a first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti-delta T/2; wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

Optionally, the first set temperature value is 1 ℃,2 ℃,3 ℃ or 4 ℃.

optionally, the second set temperature value is-1 ℃, -2 ℃, -3 ℃, or-4 ℃.

Alternatively,. DELTA.t 1 is 0.5 ℃, 1 ℃ or 1.5 ℃.

Alternatively,. DELTA.t 2 is-0.5 deg.C, -1 deg.C, or-1.5 deg.C.

In some embodiments, the adjusting module 404 includes a generating sub-module configured to generate an adjusting instruction according to the air conditioner target temperature ti of the ith first-class user, and a sending sub-module configured to send the adjusting instruction to the air conditioner of the ith first-class user.

in some embodiments, further comprising: and the recording module is used for recording the starting time of the air conditioner. After the self-starting time interval is preset, the adjusting module 404 sends an adjusting instruction to the air conditioner.

In other embodiments, the apparatus for air conditioning control further includes: and the detection intervention module is used for detecting whether a user intervention instruction exists or not after the adjustment instruction is sent to the air conditioner. The user intervention instruction is an instruction for changing the adjusted set temperature by the user. And the counting module is used for updating the user intervention parameters when the user intervention instruction is detected. Wherein the user intervention parameter is used to indicate the number of times the user intervention instruction is detected.

The detection intervention module and the counting module can be configured in an air conditioner or a cloud platform server. The detection intervention module detects whether a user intervention instruction input by a user exists when the detection intervention module is configured on the air conditioner, and detects whether the user intervention instruction reported by the air conditioner exists when the detection intervention module is configured on the cloud platform server.

The air conditioner control device can also stop adjusting the initial set temperature of the user when the user intervention parameter is larger than or equal to the preset threshold value.

It will be clear to those skilled in the art that, for convenience and simplicity of description, the foregoing division of the functional modules is merely used as an example, and in practical applications, the above function distribution may be performed by different functional modules according to needs, that is, the internal structure of the device is divided into different functional modules to perform all or part of the above described functions. For the specific working processes of the system, the apparatus, and the module described above, reference may be made to the corresponding processes in the foregoing method embodiments, which 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 method for air conditioning control, comprising:

acquiring the initial set temperature of air conditioners of a plurality of users in a cell;

Calculating an average value T of the air conditioner initial setting temperatures of the plurality of users;

Determining the air-conditioning target temperature ti of the ith first-class user according to the average value T, wherein the step of determining the air-conditioning target temperature ti of the ith first-class user comprises the following steps: calculating the difference value delta T between the initial set temperature Ti of the ith first-class user and the average value T;

Determining the air-conditioning target temperature ti of the ith first-class user according to the difference delta T; wherein i is 1,2,3 …;

Adjusting the air conditioner temperature of the ith first type user to a target temperature ti;

The determining the air-conditioning target temperature ti of the ith user according to the difference value Δ T includes:

When the difference value delta T is larger than a second set temperature value and smaller than a first set temperature value, determining the air-conditioning target temperature Ti of the ith user as the initial set temperature Ti;

When the difference value delta T is smaller than or equal to the second set temperature value, or when the difference value delta T is larger than or equal to the first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti-delta T/2;

wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

2. The method as claimed in claim 1, wherein determining an air-conditioning target temperature ti of the ith user according to the difference Δ T when the air conditioner is operated in a heating mode comprises:

when the difference value delta T is larger than or equal to a first set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T1;

When the difference value delta T is smaller than the first set temperature value and larger than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T;

When the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti;

Wherein Δ t1 is greater than zero degrees and less than the first set temperature value.

3. the method as claimed in claim 1, wherein determining the air-conditioning target temperature ti of the ith user according to the difference Δ T when the air conditioner is operated in a cooling mode comprises:

When the difference value delta T is smaller than or equal to a second set temperature value, determining the air-conditioning target temperature Ti of the ith first-class user to be Ti-delta T2;

When the difference value delta T is larger than the second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T;

When the difference value delta T is greater than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti;

Wherein Δ t2 is less than zero degrees and greater than the second set temperature value.

4. An apparatus for air conditioning control, comprising:

The system comprises an acquisition module, a control module and a control module, wherein the acquisition module is used for acquiring the air conditioner initial setting temperature of a plurality of users in a cell;

The calculation module is used for calculating the average value T of the air conditioner initial setting temperatures of the users;

The processing module is used for determining the air-conditioning target temperature ti of the ith first-class user according to the average value T; 1,2,3 …;

The adjusting module is used for adjusting the air conditioner temperature of the ith first-class user to a target temperature ti;

the processing module comprises:

The calculation submodule is used for calculating the difference value delta T between the initial set temperature Ti of the ith first-class user and the average value T; and the combination of (a) and (b),

The processing submodule is used for determining the air-conditioning target temperature ti of the ith first-class user according to the difference value delta T;

The processing submodule is used for determining the air-conditioning target temperature Ti of the ith user as the initial set temperature Ti when the difference value delta T is greater than a second set temperature value and less than a first set temperature value; when the difference value delta T is smaller than or equal to the second set temperature value, or when the difference value delta T is larger than or equal to the first set temperature value, determining that the air-conditioning target temperature Ti of the ith user is Ti-delta T/2; wherein, the second set temperature value is less than zero degree, and the first set temperature value is greater than zero degree.

5. The apparatus of claim 4, wherein when said air conditioner is operating in a heating mode, said processing sub-module is configured to determine an air conditioning target temperature Ti for said ith first type of user as Ti- Δ T1 when said difference Δ T is greater than or equal to a first set temperature value; when the difference value delta T is smaller than the first set temperature value and larger than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; when the difference value delta T is less than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t1 is greater than zero degrees and less than the first set temperature value.

6. The apparatus as claimed in claim 4, wherein when the air conditioner is operating in a cooling mode, the processing sub-module is configured to determine the air-conditioning target temperature Ti of the ith first-type user to be Ti- Δ T2 when the difference Δ T is less than or equal to a second set temperature value; when the difference value delta T is larger than the second set temperature value and smaller than zero degree, determining the air-conditioning target temperature ti of the ith first-class user as the average value T; when the difference value delta T is greater than or equal to zero degree, determining the air-conditioning target temperature Ti of the ith first-class user as the initial set temperature Ti; wherein Δ t2 is less than zero degrees and greater than the second set temperature value.