CN116447730B - Automatic control method and system for air conditioner - Google Patents

Abstract

The invention relates to the technical field of air conditioner energy conservation, and discloses an automatic control method and system of an air conditioner, wherein the automatic control method comprises the following steps: and under the condition of the grading temperature control points and the target grading temperature control points, regulating and controlling the temperature in the related space field from the original temperature change to the testing energy consumption set of the target temperature change temperature, extracting the corresponding grading temperature control point of the testing energy consumption minimum value, taking the corresponding grading temperature control point as the target grading temperature control point, judging whether the testing energy consumption minimum value is reduced to the testing energy consumption minimum value, if not, returning to select the grading temperature control point, if so, summarizing the target grading temperature control point set, obtaining a temperature change gradient sequence, constructing a field temperature control schedule, inquiring the current space field according to the temperature change characteristics of the current field, inquiring the target temperature change gradient sequence according to the temperature of the current field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence. The invention mainly aims to solve the problem of higher energy consumption of an air conditioner in the process of regulating and controlling room temperature.

Description

Automatic control method and system for air conditioner

Technical Field

The invention relates to an automatic control method and system for an air conditioner, and belongs to the technical field of energy conservation of air conditioners.

Background

With the frequent occurrence of extreme weather, the installation amount and the use frequency of air conditioners begin to increase year by year. Since the air conditioning load is an important load in the power grid, air conditioning energy consumption is beginning to be a major component of residential and industrial electricity consumption.

The automatic control of the air conditioner is a technology for intelligently adjusting the internal temperature of the air conditioning system by utilizing an automatic control system. When the current air conditioner is started, a user can directly regulate the temperature to the required temperature, and the temperature regulation mode of the air conditioner can simply and efficiently regulate the room temperature to the temperature required by the user, but the temperature regulation mode directly takes the temperature required by the user as the target regulation temperature of the air conditioner, so that the current air conditioner has the phenomenon of higher energy consumption in the room temperature regulation process.

Disclosure of Invention

The invention provides an automatic control method and system of an air conditioner and a computer readable storage medium, and mainly aims to solve the problem that the energy consumption of the air conditioner is high in the process of regulating and controlling the room temperature.

In order to achieve the above object, the present invention provides an automatic control method for an air conditioner, comprising:

acquiring a required temperature change domain set of different space domains, and sequentially extracting the required temperature change domains from the required temperature change domain set;

Extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

sequentially selecting grading temperature control points in the required temperature change region, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set;

selecting a test energy consumption minimum value in the test energy consumption set, extracting a corresponding grading temperature control point of the test energy consumption minimum value, and taking the corresponding grading temperature control point as a target grading temperature control point;

judging whether the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption or not;

if the minimum value of the test energy consumption is not reduced to the minimum value of the test energy consumption, returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain;

if the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption, summarizing all the target grading temperature control points to obtain a target grading temperature control point set;

taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

Constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

acquiring a current field temperature change characteristic, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristic;

acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

Optionally, the acquiring the required temperature change domain set of different spatial domains includes:

acquiring an original temperature change temperature set and a target temperature change temperature set;

sequentially extracting the original temperature change temperature and the target temperature change temperature respectively in the original temperature change temperature set and the target temperature change temperature set;

constructing the required temperature change domain according to the original temperature change temperature and the target temperature change temperature;

summarizing all the required temperature change areas of the original temperature change temperature and the target temperature change temperature to obtain the required temperature change area set;

acquiring spaces with different space characteristics to obtain a space field set;

and constructing the corresponding relation between different spatial domains in the spatial domain set and the required temperature change domain set to obtain the required temperature change domain set of the different spatial domains.

Optionally, the sequentially selecting the graded temperature control points in the required temperature variation domain includes:

acquiring a temperature control point selection step length;

and selecting step length according to the original temperature change temperature and the temperature control points, and sequentially selecting graded temperature control points in the required temperature change area.

Optionally, selecting step sizes according to the original temperature change temperature and the temperature control points, and sequentially selecting the graded temperature control points in the required temperature change area includes:

taking the original temperature change temperature as a starting point, taking the temperature control point selection step length as a selection span, and sequentially selecting to-be-determined grading temperature control points in the required temperature change region;

judging whether the temperature difference between the to-be-determined grading temperature control point and the target temperature change is smaller than or equal to the temperature control point selection step length;

if the temperature difference between the to-be-determined grading temperature control point and the target temperature change point is not smaller than the temperature control point selection step length, returning to the step taking the original temperature change point as a starting point;

and if the temperature difference between the to-be-determined grading temperature control points and the target temperature change is smaller than or equal to the temperature control point selection step length, taking all the to-be-determined grading temperature control points as grading temperature control points.

Optionally, the determining, at different hierarchical temperature control points and target hierarchical temperature control points, the test energy consumption of regulating the temperature in the associated space field from the original temperature to the target temperature to obtain a test energy consumption set includes:

Sorting the different grading temperature control points and the target grading temperature control points from small to large to obtain a grading temperature control point sequence;

and regulating and controlling the temperature in the related space field from the original temperature to the target temperature by using the grading temperature control point sequence to obtain a test energy consumption set.

Optionally, the step of using the hierarchical temperature control point sequence to regulate the temperature in the associated space field from the original temperature to the target temperature to obtain a test energy consumption set includes:

sequentially extracting stepwise hierarchical temperature control points in the hierarchical temperature control point sequence;

the temperature in the related space field is regulated and controlled from the original temperature change to the staged target temperature change by taking the staged temperature control point as the staged target temperature change, and the staged energy consumption is measured;

judging whether the staged grading temperature control point is the target temperature change;

if the staged approach temperature control point is not the target temperature change, returning to the step of sequentially extracting the staged hierarchical temperature control points in the hierarchical temperature control point sequence;

if the step grading temperature control point is the target temperature change, the target temperature change is taken as step target temperature change, the temperature in the related space field is regulated and controlled from the original temperature change to the target temperature change, and step energy consumption is measured;

Summarizing the energy consumption of all stages to obtain a stage energy consumption set, and calculating the total energy consumption of the stage energy consumption set to obtain a test energy consumption set.

Optionally, the adjusting the temperature in the associated space field from the original temperature to the staged target temperature by using the staged temperature control point as the staged target temperature change includes:

acquiring temperature regulation power corresponding to the staged grading temperature control point;

and regulating and controlling the temperature in the related space field from the original temperature to the staged target temperature according to the temperature regulating and controlling power.

Optionally, the acquiring the current field temperature change characteristic includes:

receiving a test instruction of the current field temperature change characteristic;

according to the test instruction, a preset test temperature control power is utilized to measure a current field temperature change characteristic curve;

and extracting the change characteristics of the current field temperature change characteristic curve to obtain the current field temperature change characteristics.

Optionally, the acquiring the current field temperature includes:

determining a current field temperature sequence by using a pre-built temperature sensor;

extracting the field temperature when the test instruction of the current field temperature change characteristic is received from the current field temperature sequence, and taking the field temperature when the test instruction of the current field temperature change characteristic is received as the current field temperature.

In order to solve the above problems, the present invention also provides an air conditioner automatic control system, the system comprising:

the system comprises a required temperature change domain and related space domain determining module, a storage module and a storage module, wherein the required temperature change domain and related space domain determining module is used for acquiring required temperature change domain sets of different space domains, and sequentially extracting the required temperature change domains in the required temperature change domain sets; extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

the grading regulation and control module is used for sequentially selecting grading temperature control points in the required temperature change area, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set; selecting a test energy consumption minimum value in the test energy consumption set, extracting corresponding grading temperature control points of the test energy consumption minimum value, taking the corresponding grading temperature control points as target grading temperature control points, and returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain until the test energy consumption minimum value is reduced to the test energy consumption minimum value, and summarizing all target grading temperature control points to obtain a target grading temperature control point set; taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

The field temperature control schedule constructing module is used for constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

the current field temperature regulation and control module is used for acquiring current field temperature change characteristics, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristics; acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

In order to solve the above-mentioned problems, the present invention also provides an electronic apparatus including:

at least one processor; the method comprises the steps of,

a memory communicatively coupled to the at least one processor; wherein,

the memory stores instructions executable by the at least one processor to implement the automatic control method of the air conditioner.

In order to solve the above-mentioned problems, the present invention also provides a computer-readable storage medium having stored therein at least one instruction that is executed by a processor in an electronic device to implement the above-mentioned air conditioner automatic control method.

Compared with the problems in the background art, the embodiment of the invention obtains a spatial scene of temperature test and a demand regulation temperature through collocation of a demand temperature change domain and an associated spatial domain corresponding to the demand temperature change domain, sequentially selects hierarchical temperature control points in the demand temperature change domain at the time of test energy consumption, measures the test energy consumption of regulating the temperature in the associated spatial domain from the original temperature change temperature to the target temperature change temperature at different hierarchical temperature control points, obtains a test energy consumption set, sequentially selects a test energy consumption minimum value in the test energy consumption set, extracts the corresponding hierarchical temperature control point of the test energy consumption minimum value, takes the corresponding hierarchical temperature control point as the target hierarchical temperature control point, obtains an acquisition mode of the target hierarchical temperature control point, judges whether the test energy consumption minimum value is reduced to the minimum value, and if the test energy consumption minimum value is not reduced to the minimum value, indicates that there is a space for reducing energy consumption, so that the current temperature of the corresponding hierarchical temperature control point is required to be sequentially selected in the demand temperature change domain, and the current temperature change domain is searched for a sequence, the current temperature change domain is searched for by using the current temperature change domain, the corresponding to the current temperature change domain, the gradient of the temperature change domain is searched for the current temperature change domain, and the current temperature change domain is searched for, and the gradient of the corresponding spatial temperature control domain is collected, and the current temperature domain is searched for, and the current temperature domain is used as the current temperature domain, and the corresponding hierarchical temperature control point is used as a target hierarchical temperature control point, and the target temperature control point is acquired, and acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence. Because the room temperature is adjusted by the way of succession pictures, the energy consumption is saved although the heating time is improved. Therefore, the automatic control method, the automatic control system, the electronic equipment and the computer readable storage medium of the air conditioner mainly aim to solve the problem that the energy consumption of the air conditioner is high in the process of regulating and controlling the room temperature.

Drawings

Fig. 1 is a schematic flow chart of an automatic control method of an air conditioner according to an embodiment of the application;

FIG. 2 is a detailed flow chart of one of the steps shown in FIG. 1;

FIG. 3 is a detailed flow chart of another step of FIG. 1;

FIG. 4 is a functional block diagram of an automatic air conditioner control system according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of an electronic device for implementing the automatic control method of an air conditioner according to an embodiment of the present application.

The achievement of the objects, functional features and advantages of the present application will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The embodiment of the application provides an automatic control method of an air conditioner. The execution main body of the air conditioner automatic control method comprises, but is not limited to, at least one of a server side, a terminal and the like which can be configured to execute the electronic equipment of the method provided by the embodiment of the application. In other words, the air conditioner automatic control method may be performed by software or hardware installed at a terminal device or a server device. The service end includes but is not limited to: a single server, a server cluster, a cloud server or a cloud server cluster, and the like.

Example 1:

referring to fig. 1, a flow chart of an automatic control method of an air conditioner according to an embodiment of the invention is shown. In this embodiment, the air conditioner automatic control method includes:

s1, acquiring a required temperature change domain set of different space domains, and sequentially extracting the required temperature change domains from the required temperature change domain set.

The spatial field is an interpretable field area having a certain spatial size, for example: supermarkets, classrooms, offices, etc. The required temperature change region refers to a temperature change region needing to be regulated and controlled, for example: the temperature of a certain supermarket is 15 ℃, and the temperature is required to be regulated to 25 ℃, and the required temperature change range is 15-25 ℃. The set of demand temperature change domains refers to a set of the demand temperature change domains.

In the embodiment of the present invention, the acquiring the required temperature change domain sets of different spatial domains includes:

acquiring an original temperature change temperature set and a target temperature change temperature set;

sequentially extracting the original temperature change temperature and the target temperature change temperature respectively in the original temperature change temperature set and the target temperature change temperature set;

constructing the required temperature change domain according to the original temperature change temperature and the target temperature change temperature;

summarizing all the required temperature change areas of the original temperature change temperature and the target temperature change temperature to obtain the required temperature change area set;

Acquiring spaces with different space characteristics to obtain a space field set;

and constructing the corresponding relation between different spatial domains in the spatial domain set and the required temperature change domain set to obtain the required temperature change domain set of the different spatial domains.

It should be appreciated that the raw temperature change set refers to a set of temperatures prior to temperature regulation, such as: the temperature of the supermarket before temperature regulation is 15 ℃, the temperature of the classroom before temperature regulation is 20 ℃, and the temperature of the office before temperature regulation is 18 ℃, so that the original temperature change set comprises 15, 20 and 18 ℃. The original temperature change temperature can be set according to actual conditions of different areas, for example, the perennial temperature of a certain area is between 0 and 30 ℃, then the original temperature change set is [0, 30] ℃, and the span can be 0.1 ℃, for example: 0.1, 0.2, 0.3, …, 30 degrees celsius.

It can be appreciated that the original temperature-change temperature and the target temperature-change temperature can be combined and matched differently, so that various required temperature-change areas can be provided.

Further, the spatial characteristics refer to temperature change characteristics of the room temperature in the spatial field along with the test temperature control power regulation of the air conditioner.

S2, extracting the original temperature change and the target temperature change of the required temperature change region, taking the target temperature change as a target grading temperature control point, and identifying an associated space field corresponding to the required temperature change region.

The initial temperature change temperature and the target temperature change temperature refer to the minimum temperature change temperature and the maximum temperature change temperature of the required temperature change region respectively. The target graded temperature control point refers to a temperature at which the temperature is regulated and controlled in stages, for example: the required temperature change range is 15-25 ℃, and the target grading temperature control point can be 25 ℃, namely the target temperature in the last stage of temperature regulation is 25 ℃. The associated spatial field refers to a spatial field corresponding to the required temperature change field. When the associated spatial field is an office, the target temperature change temperature may be an optimal temperature of a human body.

S3, sequentially selecting grading temperature control points in the required temperature change region, measuring test energy consumption of regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set.

It can be explained that, in order to extract the optimal graded temperature control points in the required temperature change domain, the graded temperature control points should be sequentially selected in the required temperature change domain to perform energy consumption test, for example: when the required temperature change area is 15-25 ℃, the grading temperature control points can be 15.1, 15.2, 15.3, … and 25 ℃, and different grading temperature control points correspond to different testing energy consumption.

In the embodiment of the present invention, the sequentially selecting the hierarchical temperature control points in the required temperature variation domain includes:

acquiring a temperature control point selection step length;

and selecting step length according to the original temperature change temperature and the temperature control points, and sequentially selecting graded temperature control points in the required temperature change area.

It can be understood that the temperature control point selection step length refers to selecting the interval size of the graded temperature control points, and when the graded temperature control points are 15.1, 15.2, 15.3, … and 25 ℃, the temperature control point selection step length is 0.1 ℃.

In the embodiment of the present invention, the selecting step length according to the original temperature change temperature and the temperature control point sequentially selects the graded temperature control points in the required temperature change area, including:

taking the original temperature change temperature as a starting point, taking the temperature control point selection step length as a selection span, and sequentially selecting to-be-determined grading temperature control points in the required temperature change region;

judging whether the temperature difference between the to-be-determined grading temperature control point and the target temperature change is smaller than or equal to the temperature control point selection step length;

if the temperature difference between the to-be-determined grading temperature control point and the target temperature change point is not smaller than the temperature control point selection step length, returning to the step taking the original temperature change point as a starting point;

And if the temperature difference between the to-be-determined grading temperature control points and the target temperature change is smaller than or equal to the temperature control point selection step length, taking all the to-be-determined grading temperature control points as grading temperature control points.

It can be appreciated that the pending step temperature control point may be equal to the target temperature change, or the difference between the pending step temperature control point and the target temperature change is smaller than the step size of the temperature control point selection, at which time the selection of the step temperature control point is stopped.

In the embodiment of the present invention, the determining, at different hierarchical temperature control points and target hierarchical temperature control points, the test energy consumption of adjusting and controlling the temperature in the associated space field from the original temperature to the target temperature to obtain the test energy consumption set includes:

sorting the different grading temperature control points and the target grading temperature control points from small to large to obtain a grading temperature control point sequence;

and regulating and controlling the temperature in the related space field from the original temperature to the target temperature by using the grading temperature control point sequence to obtain a test energy consumption set.

It is understood that the temperature in the associated spatial field may be obtained for a terminal thermometer in the associated spatial field.

In the embodiment of the present invention, the step of using the hierarchical temperature control point sequence to regulate the temperature in the associated space field from the original temperature to the target temperature to obtain a test energy consumption set includes:

sequentially extracting stepwise hierarchical temperature control points in the hierarchical temperature control point sequence;

the temperature in the related space field is regulated and controlled from the original temperature change to the staged target temperature change by taking the staged temperature control point as the staged target temperature change, and the staged energy consumption is measured;

judging whether the staged grading temperature control point is the target temperature change;

if the staged approach temperature control point is not the target temperature change, returning to the step of sequentially extracting the staged hierarchical temperature control points in the hierarchical temperature control point sequence;

if the step grading temperature control point is the target temperature change, the target temperature change is taken as step target temperature change, the temperature in the related space field is regulated and controlled from the original temperature change to the target temperature change, and step energy consumption is measured;

summarizing the energy consumption of all stages to obtain a stage energy consumption set, and calculating the total energy consumption of the stage energy consumption set to obtain a test energy consumption set.

In the embodiment of the present invention, the adjusting the temperature in the associated space field from the original temperature change to the staged target temperature change with the staged temperature control point as the staged target temperature change includes:

acquiring temperature regulation power corresponding to the staged grading temperature control point;

and regulating and controlling the temperature in the related space field from the original temperature to the staged target temperature according to the temperature regulating and controlling power.

S4, selecting a test energy consumption minimum value in the test energy consumption set, extracting a corresponding grading temperature control point of the test energy consumption minimum value, and taking the corresponding grading temperature control point as a target grading temperature control point.

It is understood that the minimum value of the test energy consumption refers to the minimum value of the test energy consumption set.

In the embodiment of the invention, besides the test of the minimum energy consumption value by using the temperature, the air quantity of the air outlet can be added.

S5, judging whether the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption.

It should be understood that the test energy consumption minimum refers to the minimum energy consumption required by the associated spatial field to be regulated from the original temperature to the target temperature under the regulation of the target hierarchical temperature control point.

It can be explained that after the test energy consumption minimum value is selected from the test energy consumption set, the step temperature control points are selected in the required temperature change area in turn, and then the test energy consumption minimum value is calculated, and when the last test energy consumption minimum value is larger than the last test energy consumption minimum value, the last test energy consumption minimum value is reduced to the test energy consumption minimum value.

And if the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption, executing S6, and summarizing all the target grading temperature control points to obtain a target grading temperature control point set.

And S7, taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain.

In detail, participating in fig. 2, the taking the target hierarchical temperature control point set as the temperature gradient sequence of the required temperature change domain and the associated space domain includes:

s71, sorting the target hierarchical temperature control points in the target hierarchical temperature control point set from small to large to obtain a target hierarchical temperature control point sequence;

s72, taking the target grading temperature control point sequence as the temperature change gradient sequence of the required temperature change domain and the related space domain.

S8, constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field.

The field temperature control schedule is a data table for recording the corresponding relation between the temperature change gradient sequence, the required temperature change field and the associated space field.

S9, acquiring the temperature change characteristics of the current field, and inquiring the current space field by utilizing a pre-constructed field space-temperature change response table according to the temperature change characteristics of the current field.

It can be understood that the current field temperature change characteristic refers to a room temperature change curve characteristic of the current space field when the current space field is debugged along with the test temperature control power, for example: slope of the room temperature change curve, acceleration per unit time, etc.

In detail, referring to fig. 3, the acquiring the current field temperature change characteristic includes:

s91, receiving a test instruction of the current field temperature change characteristic;

s92, according to the test instruction, determining a current field temperature change characteristic curve by utilizing a preset test temperature control power;

s93, extracting the change characteristics of the current field temperature change characteristic curve to obtain the current field temperature change characteristics.

In detail, the field space-temperature change response table refers to a data table for recording the characteristic relation between field spaces with different sizes and room temperature change under temperature control test power.

In detail, the querying the current spatial field by using the pre-constructed field space-temperature change response table according to the current field temperature change characteristic includes:

Acquiring a spatial field Wen Biante collection;

extracting a temperature change characteristic value set from the current field temperature change characteristic curve according to a preset temperature change characteristic element set;

judging whether the spatial field temperature change characteristic set has the spatial field temperature change characteristic matched with the temperature change characteristic value set or not;

if the space field temperature change characteristic set does not have the space field temperature change characteristic matched with the temperature change characteristic value set, returning to the step of extracting the temperature change characteristic value set from the current field temperature change characteristic curve according to the preset temperature change characteristic element set;

and if the spatial field temperature change characteristics matched with the temperature change characteristic value set exist in the spatial field temperature change characteristic set, acquiring a characteristic spatial field corresponding to the spatial field temperature change characteristics, and taking the characteristic spatial field as the current spatial field.

It can be explained that relying on the temperature change feature value set for a short time may not be sufficient to extract a matching spatial field temperature change feature at the spatial field temperature change feature set, so the test duration for testing the temperature control power may be prolonged to obtain a sufficiently detailed temperature change feature value set.

It is appreciated that different volumes of space may be used to obtain the spatial field Wen Biante collection, each corresponding to a unique spatial field temperature change characteristic at the test temperature control power.

S10, acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

The current field temperature refers to a space field which needs to be controlled by an air conditioner at present.

In an embodiment of the present invention, the obtaining the current field temperature includes:

determining a current field temperature sequence by using a pre-built temperature sensor;

extracting the field temperature when the test instruction of the current field temperature change characteristic is received from the current field temperature sequence, and taking the field temperature when the test instruction of the current field temperature change characteristic is received as the current field temperature.

Compared with the problems in the background art, the embodiment of the invention obtains a spatial scene of temperature test and a demand regulation temperature through collocation of a demand temperature change domain and an associated spatial domain corresponding to the demand temperature change domain, sequentially selects hierarchical temperature control points in the demand temperature change domain at the time of test energy consumption, measures the test energy consumption of regulating the temperature in the associated spatial domain from the original temperature change temperature to the target temperature change temperature at different hierarchical temperature control points, obtains a test energy consumption set, sequentially selects a test energy consumption minimum value in the test energy consumption set, extracts the corresponding hierarchical temperature control point of the test energy consumption minimum value, takes the corresponding hierarchical temperature control point as the target hierarchical temperature control point, obtains an acquisition mode of the target hierarchical temperature control point, judges whether the test energy consumption minimum value is reduced to the minimum value, and if the test energy consumption minimum value is not reduced to the minimum value, indicates that there is a space for reducing energy consumption, so that the current temperature of the corresponding hierarchical temperature control point is required to be sequentially selected in the demand temperature change domain, and the current temperature change domain is searched for a sequence, the current temperature change domain is searched for by using the current temperature change domain, the corresponding to the current temperature change domain, the gradient of the temperature change domain is searched for the current temperature change domain, and the current temperature change domain is searched for, and the gradient of the corresponding spatial temperature control domain is collected, and the current temperature domain is searched for, and the current temperature domain is used as the current temperature domain, and the corresponding hierarchical temperature control point is used as a target hierarchical temperature control point, and the target temperature control point is acquired, and acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence. Because the room temperature is adjusted by the way of succession pictures, the energy consumption is saved although the heating time is improved. Therefore, the automatic control method, the automatic control system, the electronic equipment and the computer readable storage medium of the air conditioner mainly aim to solve the problem that the energy consumption of the air conditioner is high in the process of regulating and controlling the room temperature.

Example 2:

fig. 4 is a functional block diagram of an automatic air conditioner control system according to an embodiment of the present invention.

The automatic air conditioner control system 100 of the present invention may be installed in an electronic device. Depending on the implementation, the automatic air conditioner control system 100 may include a required temperature change domain and associated space domain determining module 101, a hierarchical regulation module 102, a domain temperature control schedule constructing module 103, and a current domain temperature regulation module 104. The module of the invention, which may also be referred to as a unit, refers to a series of computer program segments, which are stored in the memory of the electronic device, capable of being executed by the processor of the electronic device and of performing a fixed function.

The required temperature change domain and related space domain determining module 101 is configured to obtain a required temperature change domain set of different space domains, and sequentially extract required temperature change domains in the required temperature change domain set; extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

the grading regulation and control module 102 is configured to sequentially select grading temperature control points in the required temperature variation domain, measure test energy consumption for regulating and controlling the temperature in the associated space field from the original temperature variation to the target temperature variation temperature at different grading temperature control points and at the target grading temperature control points, and obtain a test energy consumption set; selecting a test energy consumption minimum value in the test energy consumption set, extracting corresponding grading temperature control points of the test energy consumption minimum value, taking the corresponding grading temperature control points as target grading temperature control points, and returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain until the test energy consumption minimum value is reduced to the test energy consumption minimum value, and summarizing all target grading temperature control points to obtain a target grading temperature control point set; taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

The field temperature control schedule constructing module 103 is configured to construct a field temperature control schedule according to the corresponding relationship between the temperature change gradient sequence and the required temperature change field and the associated spatial field;

the current field temperature regulation module 104 is configured to obtain a current field temperature change characteristic, and query a current spatial field by using a pre-constructed field spatial-temperature change response table according to the current field temperature change characteristic; acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

In detail, the modules in the automatic air conditioner control system 100 in the embodiment of the present invention use the same technical means as the automatic air conditioner control method described in fig. 1, and can produce the same technical effects, which are not described herein.

Example 3:

fig. 5 is a schematic structural diagram of an electronic device for implementing an automatic control method of an air conditioner according to an embodiment of the present invention.

The electronic device 1 may comprise a processor 10, a memory 11, a bus 12 and a communication interface 13, and may further comprise a computer program, such as an air conditioner automatic control program, stored in the memory 11 and executable on the processor 10.

The memory 11 includes at least one type of readable storage medium, including flash memory, a mobile hard disk, a multimedia card, a card memory (e.g., SD or DX memory, etc.), a magnetic memory, a magnetic disk, an optical disk, etc. The memory 11 may in some embodiments be an internal storage unit of the electronic device 1, such as a removable hard disk of the electronic device 1. The memory 11 may in other embodiments also be an external storage device of the electronic device 1, such as a plug-in mobile hard disk, a smart memory card (SmartMediaCard, SMC), a secure digital (SecureDigital, SD) card, a flash card (FlashCard) or the like, provided on the electronic device 1. Further, the memory 11 may also include both an internal storage unit and an external storage device of the electronic device 1. The memory 11 may be used not only for storing application software installed in the electronic device 1 and various types of data, such as codes of an air conditioner automatic control program, etc., but also for temporarily storing data that has been output or is to be output.

The processor 10 may be comprised of integrated circuits in some embodiments, for example, a single packaged integrated circuit, or may be comprised of multiple integrated circuits packaged with the same or different functions, including one or more central processing units (CentralProcessingunit, CPU), microprocessors, digital processing chips, graphics processors, a combination of various control chips, and the like. The processor 10 is a control unit (control unit) of the electronic device, connects respective parts of the entire electronic device using various interfaces and lines, and executes various functions of the electronic device 1 and processes data by running or executing programs or modules (e.g., an air conditioner automatic control program, etc.) stored in the memory 11, and calling data stored in the memory 11.

The bus may be an Peripheral Component Interconnect (PCI) bus, an Extended Industry Standard Architecture (EISA) bus, or the like. The bus may be classified as an address bus, a data bus, a control bus, etc. The bus is arranged to enable a connection communication between the memory 11 and at least one processor 10 etc.

Fig. 5 shows only an electronic device with components, it being understood by a person skilled in the art that the structure shown in fig. 5 does not constitute a limitation of the electronic device 1, and may comprise fewer or more components than shown, or may combine certain components, or may be arranged in different components.

For example, although not shown, the electronic device 1 may further include a power source (such as a battery) for supplying power to the respective components, and preferably, the power source may be logically connected to the at least one processor 10 through a power management system, so as to perform functions of charge management, discharge management, and power consumption management through the power management system. The power supply may also include one or more of any of a direct current or alternating current power supply, a recharging system, a power failure detection circuit, a power converter or inverter, a power status indicator, and the like. The electronic device 1 may further include various sensors, bluetooth modules, wi-Fi modules, etc., which will not be described herein.

Further, the electronic device 1 may also comprise a network interface, optionally the network interface may comprise a wired interface and/or a wireless interface (e.g. WI-FI interface, bluetooth interface, etc.), typically used for establishing a communication connection between the electronic device 1 and other electronic devices.

The electronic device 1 may optionally further comprise a user interface, which may be a Display, an input unit, such as a Keyboard (Keyboard), or a standard wired interface, a wireless interface. Alternatively, in some embodiments, the display may be an LED display, a liquid crystal display, a touch-sensitive liquid crystal display, an OLED (organic light-emitting diode) touch, or the like. The display may also be referred to as a display screen or display unit, as appropriate, for displaying information processed in the electronic device 1 and for displaying a visual user interface.

It should be understood that the embodiments described are for illustrative purposes only and are not limited to this configuration in the scope of the patent application.

The automatic air conditioner control program stored in the memory 11 of the electronic device 1 is a combination of a plurality of instructions, and when executed in the processor 10, can realize:

Acquiring a required temperature change domain set of different space domains, and sequentially extracting the required temperature change domains from the required temperature change domain set;

extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

sequentially selecting grading temperature control points in the required temperature change region, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set;

selecting a test energy consumption minimum value in the test energy consumption set, extracting a corresponding grading temperature control point of the test energy consumption minimum value, and taking the corresponding grading temperature control point as a target grading temperature control point;

judging whether the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption or not;

if the minimum value of the test energy consumption is not reduced to the minimum value of the test energy consumption, returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain;

if the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption, summarizing all the target grading temperature control points to obtain a target grading temperature control point set;

Taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

acquiring a current field temperature change characteristic, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristic;

acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

Specifically, the specific implementation method of the above instruction by the processor 10 may refer to descriptions of related steps in the corresponding embodiments of fig. 1 to 4, which are not repeated herein.

Further, the modules/units integrated in the electronic device 1 may be stored in a computer readable storage medium if implemented in the form of software functional units and sold or used as separate products. The computer readable storage medium may be volatile or nonvolatile. For example, the computer readable medium may include: any entity or system capable of carrying the computer program code, a recording medium, a U disk, a removable hard disk, a magnetic disk, an optical disk, a computer memory, a Read-only memory (ROM).

The present invention also provides a computer readable storage medium storing a computer program which, when executed by a processor of an electronic device, can implement:

acquiring a required temperature change domain set of different space domains, and sequentially extracting the required temperature change domains from the required temperature change domain set;

extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

sequentially selecting grading temperature control points in the required temperature change region, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set;

selecting a test energy consumption minimum value in the test energy consumption set, extracting a corresponding grading temperature control point of the test energy consumption minimum value, and taking the corresponding grading temperature control point as a target grading temperature control point;

judging whether the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption or not;

if the minimum value of the test energy consumption is not reduced to the minimum value of the test energy consumption, returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain;

If the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption, summarizing all the target grading temperature control points to obtain a target grading temperature control point set;

taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

acquiring a current field temperature change characteristic, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristic;

acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence.

The modules described as separate components may or may not be physically separate, and components shown as modules may or may not be physical units, may be located in one place, or may be distributed over multiple network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional module in the embodiments of the present invention may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units can be realized in a form of hardware or a form of hardware and a form of software functional modules.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

Finally, it should be noted that the above-mentioned embodiments are merely for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention.

Claims (8)

1. An automatic control method of an air conditioner, comprising:

acquiring a required temperature change domain set of different space domains, and sequentially extracting the required temperature change domains from the required temperature change domain set;

Extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

sequentially selecting grading temperature control points in the required temperature change region, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set;

selecting a test energy consumption minimum value in the test energy consumption set, extracting a corresponding grading temperature control point of the test energy consumption minimum value, and taking the corresponding grading temperature control point as a target grading temperature control point;

judging whether the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption or not;

if the minimum value of the test energy consumption is not reduced to the minimum value of the test energy consumption, returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain;

if the minimum value of the test energy consumption is reduced to the minimum value of the test energy consumption, summarizing all the target grading temperature control points to obtain a target grading temperature control point set;

taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

Constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

acquiring a current field temperature change characteristic, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristic;

acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence;

the measuring is carried out under different grading temperature control points and target grading temperature control points, the temperature in the related space field is regulated and controlled from the original temperature to the target temperature, and a test energy consumption set is obtained, and the measuring comprises the following steps:

sorting the different grading temperature control points and the target grading temperature control points from small to large to obtain a grading temperature control point sequence;

regulating and controlling the temperature in the related space field from the original temperature to the target temperature by using the grading temperature control point sequence to obtain a test energy consumption set;

the step of utilizing the hierarchical temperature control point sequence to regulate and control the temperature in the related space field from the original temperature to the target temperature to obtain a test energy consumption set, comprising the following steps:

Sequentially extracting stepwise hierarchical temperature control points in the hierarchical temperature control point sequence;

the temperature in the related space field is regulated and controlled from the original temperature change to the staged target temperature change by taking the staged temperature control point as the staged target temperature change, and the staged energy consumption is measured;

judging whether the staged grading temperature control point is the target temperature change;

if the staged approach temperature control point is not the target temperature change, returning to the step of sequentially extracting the staged hierarchical temperature control points in the hierarchical temperature control point sequence;

if the step grading temperature control point is the target temperature change, the target temperature change is taken as step target temperature change, the temperature in the related space field is regulated and controlled from the original temperature change to the target temperature change, and step energy consumption is measured;

summarizing the energy consumption of all stages to obtain a stage energy consumption set, and calculating the total energy consumption of the stage energy consumption set to obtain a test energy consumption set.

2. The automatic control method of air conditioner as claimed in claim 1, wherein the acquiring the required temperature change domain sets of different spatial domains comprises:

Acquiring an original temperature change temperature set and a target temperature change temperature set;

sequentially extracting the original temperature change temperature and the target temperature change temperature respectively in the original temperature change temperature set and the target temperature change temperature set;

constructing the required temperature change domain according to the original temperature change temperature and the target temperature change temperature;

summarizing all the required temperature change areas of the original temperature change temperature and the target temperature change temperature to obtain the required temperature change area set;

acquiring spaces with different space characteristics to obtain a space field set;

and constructing the corresponding relation between different spatial domains in the spatial domain set and the required temperature change domain set to obtain the required temperature change domain set of the different spatial domains.

3. The automatic control method of an air conditioner according to claim 2, wherein sequentially selecting the hierarchical temperature control points in the required temperature variation region comprises:

acquiring a temperature control point selection step length;

and selecting step length according to the original temperature change temperature and the temperature control points, and sequentially selecting graded temperature control points in the required temperature change area.

4. The automatic control method of air conditioner as claimed in claim 3, wherein the selecting step according to the original temperature and the temperature control point sequentially selects the hierarchical temperature control points within the required temperature variation region, comprises:

Taking the original temperature change temperature as a starting point, taking the temperature control point selection step length as a selection span, and sequentially selecting to-be-determined grading temperature control points in the required temperature change region;

judging whether the temperature difference between the to-be-determined grading temperature control point and the target temperature change is smaller than or equal to the temperature control point selection step length;

if the temperature difference between the to-be-determined grading temperature control point and the target temperature change point is not smaller than the temperature control point selection step length, returning to the step taking the original temperature change point as a starting point;

and if the temperature difference between the to-be-determined grading temperature control points and the target temperature change is smaller than or equal to the temperature control point selection step length, taking all the to-be-determined grading temperature control points as grading temperature control points.

5. The automatic control method of an air conditioner according to claim 4, wherein the adjusting the temperature in the associated space field from the original temperature change to the stepwise target temperature change with the stepwise temperature control point as the stepwise target temperature change includes:

acquiring temperature regulation power corresponding to the staged grading temperature control point;

and regulating and controlling the temperature in the related space field from the original temperature to the staged target temperature according to the temperature regulating and controlling power.

6. The automatic control method of an air conditioner as claimed in claim 1, wherein the acquiring the current field temperature change characteristic includes:

receiving a test instruction of the current field temperature change characteristic;

according to the test instruction, a preset test temperature control power is utilized to measure a current field temperature change characteristic curve;

and extracting the change characteristics of the current field temperature change characteristic curve to obtain the current field temperature change characteristics.

7. The automatic control method of an air conditioner as claimed in claim 1, wherein the acquiring the current field temperature includes:

determining a current field temperature sequence by using a pre-built temperature sensor;

extracting the field temperature when the test instruction of the current field temperature change characteristic is received from the current field temperature sequence, and taking the field temperature when the test instruction of the current field temperature change characteristic is received as the current field temperature.

8. An automatic control system for an air conditioner, the system comprising:

the system comprises a required temperature change domain and related space domain determining module, a storage module and a storage module, wherein the required temperature change domain and related space domain determining module is used for acquiring required temperature change domain sets of different space domains, and sequentially extracting the required temperature change domains in the required temperature change domain sets; extracting an original temperature change and a target temperature change of the required temperature change domain, taking the target temperature change as a target grading temperature control point, and identifying an associated space domain corresponding to the required temperature change domain;

The grading regulation and control module is used for sequentially selecting grading temperature control points in the required temperature change area, measuring test energy consumption for regulating and controlling the temperature in the related space field from the original temperature change to the target temperature change temperature under different grading temperature control points and target grading temperature control points, and obtaining a test energy consumption set; selecting a test energy consumption minimum value in the test energy consumption set, extracting corresponding grading temperature control points of the test energy consumption minimum value, taking the corresponding grading temperature control points as target grading temperature control points, and returning to the step of sequentially selecting the grading temperature control points in the required temperature variation domain until the test energy consumption minimum value is reduced to the test energy consumption minimum value, and summarizing all target grading temperature control points to obtain a target grading temperature control point set; taking the target grading temperature control point set as a temperature change gradient sequence of the required temperature change domain and the related space domain;

the field temperature control schedule constructing module is used for constructing a field temperature control schedule according to the corresponding relation between the temperature change gradient sequence and the required temperature change field and the associated space field;

the current field temperature regulation and control module is used for acquiring current field temperature change characteristics, and inquiring a current space field by utilizing a pre-constructed field space-temperature change response table according to the current field temperature change characteristics; acquiring the current field temperature, inquiring a target temperature change gradient sequence in the field temperature control schedule according to the current field temperature and the current space field, and regulating and controlling the temperature in the current space field according to the target temperature gradient sequence;

The measuring is carried out under different grading temperature control points and target grading temperature control points, the temperature in the related space field is regulated and controlled from the original temperature to the target temperature, and a test energy consumption set is obtained, and the measuring comprises the following steps:

sorting the different grading temperature control points and the target grading temperature control points from small to large to obtain a grading temperature control point sequence;

regulating and controlling the temperature in the related space field from the original temperature to the target temperature by using the grading temperature control point sequence to obtain a test energy consumption set;

the step of utilizing the hierarchical temperature control point sequence to regulate and control the temperature in the related space field from the original temperature to the target temperature to obtain a test energy consumption set, comprising the following steps:

sequentially extracting stepwise hierarchical temperature control points in the hierarchical temperature control point sequence;

the temperature in the related space field is regulated and controlled from the original temperature change to the staged target temperature change by taking the staged temperature control point as the staged target temperature change, and the staged energy consumption is measured;

judging whether the staged grading temperature control point is the target temperature change;

If the staged approach temperature control point is not the target temperature change, returning to the step of sequentially extracting the staged hierarchical temperature control points in the hierarchical temperature control point sequence;

if the step grading temperature control point is the target temperature change, the target temperature change is taken as step target temperature change, the temperature in the related space field is regulated and controlled from the original temperature change to the target temperature change, and step energy consumption is measured;

summarizing the energy consumption of all stages to obtain a stage energy consumption set, and calculating the total energy consumption of the stage energy consumption set to obtain a test energy consumption set.