CN113108438A - Air conditioner control method and device, storage medium and air conditioner - Google Patents

Abstract

The invention provides an air conditioner control method, an air conditioner control device, a storage medium and an air conditioner, wherein the method comprises the following steps: acquiring the current operation mode of the air conditioner and the current unit calculation load; acquiring matched initial comfort state data from a first database and/or a second database which are established in advance according to the acquired current operation mode and the current unit calculation load, wherein the initial comfort state data comprises: setting parameters and/or operating parameters; acquiring set parameters in the initial comfortable state data, and controlling the operation of the air conditioner according to the acquired set parameters; and establishing the first database or the second database based on the adjustment operation of the user on the air conditioner setting parameters during the operation of the air conditioner. The scheme provided by the invention can be combined with the user adjustment condition during the operation of the unit, and the user comfort level is defined according to the parameters before and after adjustment, so that the control optimization is carried out through different comfort levels.

Description

Air conditioner control method and device, storage medium and air conditioner

Technical Field

The invention relates to the field of control, in particular to an air conditioner control method and device, a storage medium and an air conditioner.

Background

At present, self-learning regulation of user habits is lacked for operation and control of an air conditioner such as a multi-split air conditioner, and no quantitative assessment is available between comfort conditions of unit operation and self-expected values of users.

Disclosure of Invention

The main purpose of the present invention is to overcome the above-mentioned drawbacks of the related art, and to provide an air conditioner control method, device, storage medium and air conditioner, so as to solve the problem in the related art that the operation and control of the air conditioner lack self-learning adjustment to the user's habits.

One aspect of the present invention provides an air conditioner control method, including: acquiring the current operation mode of the air conditioner and the current unit calculation load; acquiring matched initial comfort state data from a first database and/or a second database which are established in advance according to the acquired current operation mode and the current unit calculation load, wherein the initial comfort state data comprises: setting parameters and/or operating parameters; acquiring set parameters in the initial comfortable state data, and controlling the operation of the air conditioner according to the acquired set parameters; and establishing the first database or the second database based on the adjustment operation of the user on the air conditioner setting parameters during the operation of the air conditioner.

In some embodiments, further comprising: and if the matched initial comfort state data is not acquired from the pre-established first database or the pre-established second database, controlling the operation of the air conditioner according to the initial setting parameters.

In some embodiments, the establishing the first database based on the adjustment operation of the air conditioner setting parameter by the user when the air conditioner is running comprises: when the air conditioner is operated, judging whether the operation time of the air conditioner, in which the current setting parameters are not adjusted, reaches a preset time or not; if the running time reaches the preset time, acquiring the current running mode and the set parameters of the air conditioner, and acquiring the current running parameters of the air conditioner; respectively recording the acquired setting parameters and the acquired running parameters as a group of initial comfort state data corresponding to the corresponding running mode under the corresponding working condition, thereby establishing the first database; wherein, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

In some embodiments, the establishing the first database based on the setting parameters set by the user further includes: and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

In some embodiments, determining the comfort level of the corresponding initial comfort state according to the number of times that the setting parameter is changed and/or the change value before and after the setting parameter is changed in the initial comfort state data corresponding to different operation modes under different working conditions includes: for each group of initial comfort state data, determining a first comfort level corresponding to a corresponding set parameter according to the changed times of each set parameter, and/or for each group of initial comfort state data, determining a second comfort level corresponding to a corresponding set parameter according to the change value before and after each set parameter is changed; determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter; the different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels.

In some embodiments, establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user while the air conditioner is running comprises: acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level comprises at least one comfort level; and establishing the second database based on the obtained initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level.

In some embodiments, acquiring the setting parameters in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameters includes: if the number of the obtained initial comfortable state data is more than two groups, the obtained more than two groups of the initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time; the smaller the average total power per hour of the unit is, the higher the corresponding priority is; and acquiring the setting parameters in the initial comfort state data with the highest priority according to the priority sequencing result, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

In some embodiments, controlling the operation of the air conditioner according to the setting parameter in the initial comfort state data having the highest priority includes: performing parameter setting on the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority, wherein the set operation parameters comprise: compressor operating frequency and/or fan operating frequency.

In some embodiments, the establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user when the air conditioner is running further comprises: adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of an original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment; controlling the operation of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, further comprising: controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority; judging in proper order according to the parameter combination control of the compressor operating frequency and the fan operating frequency of more than two sets of difference after the adjustment the operation of air conditioner back, whether air conditioner running state satisfies user's demand, include: judging whether the set parameters are changed within preset time, if so, judging that the user requirements are not met; and if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency.

In some embodiments, obtaining the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load comprises: firstly, acquiring matched initial comfort state data from the second database according to the acquired current operation mode and the current unit calculation load, and if the matched initial comfort state data is not acquired from the second database, acquiring the matched initial comfort state data from the first database according to the acquired current operation mode and the current unit calculation load.

In some embodiments, obtaining the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load comprises: and searching the initial comfort state data which is the same as the current operation mode and the load section of the current unit calculation load from the first database or the second database.

Another aspect of the present invention provides an air conditioning control apparatus, including: the first acquisition unit is used for acquiring the current operation mode of the air conditioner and the current unit calculation load; a second obtaining unit, configured to obtain, according to the current operating mode and the current unit computational load obtained by the first obtaining unit, matched initial comfort state data from a first database and/or a second database established in advance, where the initial comfort state data includes: setting parameters and/or operating parameters; the control unit is used for acquiring set parameters in the initial comfortable state data and controlling the operation of the air conditioner according to the acquired set parameters; and establishing the first database or the second database based on the adjustment operation of the user on the air conditioner setting parameters during the operation of the air conditioner.

In some embodiments, further comprising: the control unit is further configured to: and if the second acquisition unit does not acquire the matched initial comfort state data from the pre-established first database or second database, controlling the operation of the air conditioner according to the initial setting parameters.

In some embodiments, the establishing the first database based on the adjustment operation of the air conditioner setting parameter by the user when the air conditioner is running comprises: when the air conditioner is operated, judging whether the operation time of the air conditioner, in which the current setting parameters are not adjusted, reaches a preset time or not; if the running time reaches the preset time, acquiring the current running mode and the set parameters of the air conditioner, and acquiring the current running parameters of the air conditioner; respectively recording the acquired setting parameters and the acquired running parameters as a group of initial comfort state data corresponding to the corresponding running mode under the corresponding working condition, thereby establishing the first database; wherein, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

In some embodiments, the establishing the first database based on the setting parameters set by the user further includes: and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

In some embodiments, determining the comfort level of the corresponding initial comfort state according to the number of times that the setting parameter is changed and/or the change value before and after the setting parameter is changed in the initial comfort state data corresponding to different operation modes under different working conditions includes: for each group of initial comfort state data, determining a first comfort level corresponding to a corresponding set parameter according to the changed times of each set parameter, and/or for each group of initial comfort state data, determining a second comfort level corresponding to a corresponding set parameter according to the change value before and after each set parameter is changed; determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter; the different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels.

In some embodiments, establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user while the air conditioner is running comprises: acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level comprises at least one comfort level; and establishing the second database based on the obtained initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level.

In some embodiments, the controlling unit acquiring a setting parameter in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameter includes: if the number of the obtained initial comfortable state data is more than two groups, the obtained more than two groups of the initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time; the smaller the average total power of the unit in unit time is, the higher the corresponding priority is; and acquiring the setting parameters in the initial comfort state data with the highest priority according to the priority sequencing result, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

In some embodiments, the controlling unit controlling the operation of the air conditioner according to the setting parameter in the initial comfort state data having the highest priority, includes: performing parameter setting on the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority, wherein the set operation parameters comprise: compressor operating frequency and/or fan operating frequency.

In some embodiments, the establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user when the air conditioner is running further comprises: adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of an original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment; controlling the operation of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, further comprising: controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority; judging in proper order according to the parameter combination control of the compressor operating frequency and the fan operating frequency of more than two sets of difference after the adjustment the operation of air conditioner back, judge whether air conditioner running state satisfies user's demand, include: judging whether the set parameters are changed within preset time, if so, judging that the user requirements are not met; and if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency.

In some embodiments, the second obtaining unit obtains the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load, and includes: firstly, acquiring matched initial comfort state data from the second database according to the acquired current operation mode and the current unit calculation load, and if the matched initial comfort state data is not acquired from the second database, acquiring the matched initial comfort state data from the first database according to the acquired current operation mode and the current unit calculation load.

In some embodiments, the second obtaining unit obtains the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load, and includes: and searching the initial comfort state data which is the same as the current operation mode and the load section of the current unit calculation load from the first database or the second database.

A further aspect of the invention provides a storage medium having stored thereon a computer program which, when executed by a processor, carries out the steps of any of the methods described above.

Yet another aspect of the present invention provides an air conditioner comprising a processor, a memory, and a computer program stored on the memory and operable on the processor, wherein the processor implements the steps of any of the methods described above when executing the program.

In another aspect, the invention provides an air conditioner, which comprises the air conditioner control device.

According to the technical scheme of the invention, the user comfort level is defined according to the parameters before and after adjustment by combining the user adjustment condition during the operation of the unit, so that the control optimization is carried out through different comfort levels, and finally, the energy-saving control is achieved by comparing the average use power of the unit in different time periods.

By using the use data of the user and the transformation conditions of various indoor parameters, the unit analyzes and judges the comfort level of the unit based on user experience by using the average use power condition of the unit at different time intervals, and performs self-learning and self-optimization of the unit, thereby finally achieving the effects of meeting the user requirements and saving energy.

Real experience of the unit for a user during operation is judged in multiple directions through coupling of multi-dimensional parameters of the unit. The comfort condition of the unit based on the user experience is judged through the set adjustment of the user to the unit, and the comfort condition is divided. The set setting is intelligently adjusted through the use condition of the user and the power of the set, the set control is corrected, and the effect of man-machine interaction is achieved. Therefore, a certain energy-saving effect is achieved on the premise of meeting the comfort of the user.

The control of the unit is adjusted based on user experience, self-learning and self-correction of the unit are realized through a man-machine interaction method, the running condition of the unit and the user experience are related, and the user experience is optimized to a certain extent by the satisfaction degree of the user. Through the comparison of the average power of the units, the most energy-saving self-adaptive control is pushed, and the satisfaction and comfort of users can be achieved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic diagram of an embodiment of an air conditioner control method according to the present invention;

FIG. 2 is a flowchart illustrating one embodiment of the steps for creating the first database based on user adjustments to the air conditioner setting parameters while the air conditioner is running;

FIG. 3 is a flowchart illustrating one embodiment of the step of building the second database based on user adjustments to the air conditioner setting parameters while the air conditioner is running;

fig. 4 is a flowchart illustrating an embodiment of the steps of acquiring the setting parameter in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameter;

FIG. 5 is a schematic diagram of an embodiment of a method for controlling an air conditioner according to the present invention;

fig. 6 is a block diagram of an embodiment of an air conditioning control apparatus according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

At present, the self-learning regulation of the running and control lack of the multi-split air conditioner set on the user habit is embodied in the following aspects:

1. there is no way to quantify the examination between the comfort condition of the unit operation and the user's own desired value;

2. the comfort effect of the unit operation is not related to the behavior habits, work and rest, body feeling and the like of one or more users;

3. the control method for the unit operation is not corrected by the user, and artificial intelligence cannot be really realized.

The invention provides an air conditioner control method. The air conditioner control method is used for realizing an intelligent adjusting mode of the air conditioner.

Fig. 1 is a schematic method diagram of an embodiment of an air conditioner control method provided by the present invention.

As shown in fig. 1, according to an embodiment of the present invention, the air conditioner control method includes at least step S110, step S120, and step S130.

And step S110, acquiring the current operation mode of the air conditioner and the current unit calculation load.

Specifically, after the intelligent adjustment mode is started, the current operation mode of the air conditioner is obtained, and the current unit calculation load is calculated. In one embodiment, the current unit calculation load is calculated according to the current outdoor environment temperature, the setting parameters and the indoor unit capacity of the air conditioner. The unit can be corrected again according to factors such as comfort and output of the press to obtain the target heating capacity or refrigerating capacity of the unit, and each manufacturer can have a correction algorithm. The unit of load is kW.

And step S120, acquiring matched initial comfort state data from a first database and/or a second database which are established in advance according to the acquired current operation mode and the current unit calculation load.

The initial comfort state data may specifically include: setting parameters and/or operating parameters. Optionally, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: the unit calculates a load segment in which the load is located (for example, a load segment is defined from 0 load to zeta increase, for example, (0, zeta), (zeta, 2 zeta) are all load segments), at least one of the unit time average total power, the compressor operation frequency and the fan operation frequency.

Fig. 2 is a flowchart illustrating a specific embodiment of the step of establishing the first database based on the adjustment operation of the air conditioner setting parameter by the user when the air conditioner is running. As shown in fig. 2, specifically, the establishing of the first database based on the adjustment operation of the air conditioner setting parameter by the user during the operation of the air conditioner may include step S11, step S12, and step S13.

Step S11, when the air conditioner is running, it is determined whether the running time of the air conditioner, in which the current setting parameter is kept unadjusted, reaches a preset time.

Specifically, if the air conditioner keeps the running time of the current setting parameter, which is not adjusted, for a preset time, it may be said that the indoor environment meets the user's initial comfort state. That is to say, it is determined that the current setting parameter is not adjusted by the user, and whether the operation time of the air conditioner operating according to the current setting parameter reaches the preset time is determined, for example, under a certain working condition (e.g., a certain outdoor environment temperature section) and the unit is operating, if the setting parameter of the air conditioner is changed by X hours by the user, it is determined that the indoor air index satisfies the initial comfort state of the user.

And step S12, if the operation time reaches the preset time, acquiring the current operation mode and the setting parameters of the air conditioner, and acquiring the current operation parameters of the air conditioner.

Specifically, if the air conditioner keeps the current set parameter unadjusted operation time for a preset time, which may indicate that the indoor environment meets the user's initial comfort state, the current operation mode and the set parameter are obtained, and the current operation parameter of the air conditioner, that is, the operation parameter of the air conditioner when the air conditioner operates according to the current set parameter, is obtained.

Step S13, recording the setting parameters and the operating parameters obtained each time as a set of initial comfort state data corresponding to the corresponding operating mode under the corresponding working condition, respectively, thereby creating the first database.

That is, each time it is determined that the operating time during which the current setting parameter of the air conditioner is not adjusted reaches the preset time, the acquired setting parameter and operating parameter are respectively recorded as a set of initial comfort state data corresponding to the corresponding operating mode under the corresponding working condition, so that multiple sets of initial comfort state data can be saved to establish the first database. Each set of initial comfort state data in the first database corresponds to an initial comfort state. Different initial comfort state data can be provided for different working conditions, different operation modes and different set parameters. The working conditions may specifically include outdoor ambient temperature and indoor unit capacity.

For example, the user initial comfort state M is defined as: under the condition that a unit operates in a certain outdoor environment temperature section (namely a temperature interval), if the indoor set parameters are not changed by a user for X hours, the indoor air indexes are judged to meet the initial comfortable state of the user, the set parameters and the operating parameters at the moment are recorded according to the format of the table 1, and the set parameters and the operating parameters are recorded into a first database according to the format. Each set of initial comfort state data corresponds to one initial comfort state, and may be respectively numbered, for example, the initial comfort state 1 shown in table 1, it should be understood that only one set of initial comfort state data is shown in table 1, but the initial comfort state data that may be included may be one set or more than two sets.

Optionally, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

TABLE 1

The unit factory program comprises a program for calculating the load value which needs to be output by the unit currently, and the unit of the load is kW. The load segment where the load is calculated by the unit is defined, for example, as one load segment every time ζ w increases from 0 load, for example, (0, ζ), (ζ, 2 ζ) are all one load segment.

Optionally, if the air conditioner is subjected to parameter setting according to a setting parameter in any initial comfort state data obtained from the first database (that is, set as the setting parameter of the air conditioner), if the user adjusts the setting parameter of the air conditioner within a preset time, the corresponding initial comfort state data is deleted from the first database, and/or the setting parameter and the corresponding operation parameter after the user adjustment are recorded as a set of initial comfort state data corresponding to the corresponding operation mode under the corresponding working condition, so as to update the first database.

For example, if a recording parameter included in a certain "initial comfort state" is extracted from the first database as a setting parameter, if the user changes the setting in the process, the "initial comfort state" record in the first database is deleted, and the setting parameter adjusted by the user and the adjusted operation parameter are recorded as a set of initial comfort state data corresponding to the corresponding operation mode under the corresponding working condition.

Optionally, if more than two sets of initial comfort state data with the same setting parameter exist in the recorded initial comfort state data corresponding to the same operation mode under the same working condition, one set of initial comfort state data with the minimum unit time average total power is reserved, and the rest are deleted. For example, if there is more than one set of records with the same setting parameters in the first database, only the record with the minimum average total power per hour of the unit is saved.

Optionally, the establishing the first database based on the setting parameters set by the user further includes: and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

Specifically, for each set of the initial comfort state data, a first comfort level corresponding to the corresponding setting parameter is determined according to the changed times (the times changed to the current value) of each setting parameter, and/or for each set of the initial comfort state data, a second comfort level corresponding to the corresponding setting parameter is determined according to the change values (the change values before and after changed to the current value) before and after the change of each setting parameter; and determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter. The different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels. Specifically, different times of changing each set parameter correspond to different first comfort levels, and different pre-change and post-change values of each set parameter correspond to different second comfort levels.

For example, the satisfactory comfort definition is made for the initial comfort state in the form of table 2. According to the format of table 2 when the user initial comfort state is judged to be satisfied each time, the comfort level of the corresponding initial comfort state is determined according to the number of times that the set parameter is changed (the number of times that the set parameter is changed to the current value) and/or the change value before and after the set parameter is changed (the change value before and after the set parameter is changed to the current value) in the initial comfort state data corresponding to the current operation mode under the current working condition, and the actual comfort of the user is defined.

For example, the operation mode is determined first, and then the current outdoor environment temperature (working condition) is determined, on the premise that this is the premise, the real comfort of the user is defined for the times of adjusting the setting parameters by the user under different operation modes and different setting parameters, and the change values before and after the user adjusts the setting parameters.

For example, the words defining comfort may be different levels of "very cold", "slightly cold", "comfort", "slightly hot", "very hot", and the like. For example, setting parameters including setting temperature and setting wind gear, the definition of the grade may utilize the following parameters: user-set temperature operation times C_T(i.e., the number of times the user changes the set temperature), the user-set temperature change amplitude f_T(i.e., the set temperature change value before and after the user changes the set temperature), the user sets the windshield change amplitude f_F(i.e. the user changes the wind gear (wind speed) change value before and after setting the wind gear), and the user sets the number of times of operation C of the windshield_F(i.e. the number of times the user changes the setting of the gear), these parameters have different value ranges, four parameters C_T、f_T、f_F、C_FUnder different combinations of ranges, different grades are defined.

For example, as shown in Table 2, can be C_T、f_T、f_F、C_FDifferent value sections are set, and each value section is a grade.

Such as C_TThe value section(s) is (are) grade A in (a, B), grade B in (c, d), and the like. Different user comfort levels may be defined according to different combinations of levels. For example, when all four parameters are a, comfort is defined as "comfort". The accuracy of comfort definition can be adjusted by taking value segments.

The words comfort definition may be "comfortable", "cooler", "very cold", etc.

TABLE 2

Different parameter value combinations can be provided under different working conditions, different operation modes and different setting conditions to define the user comfort. Each set of initial comfort state data corresponds to one initial comfort state, and may be respectively numbered, for example, the initial comfort state 1 shown in table 2, it should be understood that only one set of initial comfort state data is shown in table 2, but the initial comfort state data that may be included may be one set or more than two sets.

Fig. 3 is a flowchart illustrating a specific embodiment of the step of establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user when the air conditioner is running. As shown in fig. 3, specifically, the step of establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user during the operation of the air conditioner may include the step S21 and the step S22.

Step S21, acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level includes at least one comfort level.

Step S22, establishing the second database based on the obtained comfort level of the corresponding initial comfort state as the initial comfort state data of the preset level.

If the preset level is "comfortable", for example, acquiring initial comfort state data, of which the comfort level of the initial comfort state is "comfortable", corresponding to the first database, and establishing a second database based on the acquired initial comfort state data, of which the comfort level of the initial comfort state is "comfortable". Optionally, the preset level may also include more than two comfort levels. Optionally, the initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level is deleted from the first database.

For example, the initial comfort state data with the corresponding comfort level of the initial comfort state as "comfort" is obtained from the first database, and the data is entered into the second database according to the format of table 3 below, which is the energy-saving database that the user actually satisfies. This "initial comfort state" contains records (i.e. initial comfort state data) that are deleted in the first database.

TABLE 3

Optionally, the establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user when the air conditioner is running further includes: and adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of the original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment.

For example, referring to table 3, the operating frequency of the compressor and/or the operating frequency of the fan in a certain set of initial comfort state data are reduced and adjusted on the basis of the original value (the original parameter value corresponding to the initial comfort state of the user is satisfied), so as to obtain more than two different sets of parameter combinations of the operating frequency of the compressor and the operating frequency of the fan after adjustment. For example, the compressor operating frequency and the fan operating frequency in the parameter combination may be adjusted by only one or both of them, so as to obtain three different sets of parameter combinations of the compressor operating frequency and the fan operating frequency. For example, as shown in table 3, in the parameter combination with level 1, the compressor operating frequency and the fan operating frequency are the original values of the compressor operating frequency and the fan operating frequency in the initial comfort state data, and in the parameter combination with level 2, the compressor operating frequency is the original value, and the fan operating frequency is decreased by b on the basis of the original value; in the parameter combination with the level 3, c is subtracted from the compressor operating frequency on the basis of the original value, and the fan operating frequency is the original value; in the parameter combination with the level 4, the operating frequency of the compressor is decreased by d on the basis of the original value, and the operating frequency of the fan is decreased by e on the basis of the original value, wherein b, c, d and e are all adjustable positive numbers. The running frequency of the compressor or the running frequency of the fan is reduced on the basis of an original value, and the unit time average total power can be reduced theoretically, so that more energy-saving control is realized.

The "initial comfort state" in table 3 and the "initial comfort state" in table 1 are the same record. The 'operation mode', 'load section where the unit calculation load is located', 'user-set temperature', 'user-set windshield' are all parameters in the same recording state. It should be understood that only one set of initial comfort state data is shown in table 3, but that it may include one or more sets of initial comfort state data.

In some embodiments, the initial comfort state data that is the same as the current operation mode and that is the same as the load segment in which the current unit computing load is located is searched from the first database or the second database. More specifically, the initial comfort state data which is the same as the current working condition, the same as the current operation mode and the same as the load section of the current unit calculation load is searched from the first database or the second database. Preferably, the matched initial comfort state data is obtained from the second database according to the obtained current operating mode and the current unit calculation load, and if the matched initial comfort state data is not obtained from the second database, the matched initial comfort state data is obtained from the first database according to the obtained current operating mode and the current unit calculation load.

Step S130, obtaining a setting parameter in the initial comfort state data, and controlling the operation of the air conditioner according to the obtained setting parameter.

And if the obtained initial comfortable state data is a group, obtaining the set parameters in the group of initial comfortable state data, and controlling the operation of the air conditioner according to the obtained set parameters.

Fig. 4 is a flowchart illustrating an embodiment of the steps of acquiring the setting parameter in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameter. As shown in fig. 4, in a specific embodiment, step S130 includes step S131 and step S132.

Step S131, if the number of the obtained initial comfortable state data is more than two, the obtained more than two groups of initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time. The smaller the average total power of the unit time is, the higher the corresponding priority is.

Step S132, according to the priority ranking result, obtaining the setting parameters in the initial comfort state data with the highest priority, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

For example, more than two groups of initial comfort state data acquired from the first database or the second database are sorted according to the average total power per hour of the unit, the smaller the average total power per hour is, the higher the corresponding priority is, and the operation of the air conditioner is controlled according to the set parameters in the initial comfort state data with the highest priority.

In one embodiment, controlling the operation of the air conditioner according to the setting parameter in the initial comfort state data having the highest priority includes: and setting parameters of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority. The setting of the operating parameters comprises: compressor operating frequency and/or fan operating frequency.

Optionally, the controlling the operation of the air conditioner according to the setting parameter in the initial comfort state data with the highest priority further includes: controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority; and after the operation of the air conditioner is sequentially judged to be controlled according to the adjusted parameter combinations of the more than two groups of different compressor operation frequencies and fan operation frequencies, judging whether the operation state of the air conditioner meets the user requirements, and if the operation state of the air conditioner does not meet the user requirements, deleting the corresponding parameter combinations of the compressor operation frequencies and the fan operation frequencies.

Wherein, judge whether the air conditioner running state satisfies user's demand, include: and judging whether the set parameters are changed within the preset time, if so, judging that the user requirements are not met. That is, after the operation of the air conditioner is controlled according to the adjusted parameter combination of the two or more different sets of the compressor operation frequency and the fan operation frequency, which is obtained by adjusting the initial comfort state data with the highest priority on the basis of the original value, if the user does not change the parameter combination within the preset time, the adjusted parameter combination can meet the comfort of the user, the parameter combination can be retained, the compressor operation frequency or the fan operation frequency is reduced on the basis of the original value, the unit time average total power can be theoretically reduced, and therefore more energy-saving control is achieved, and therefore the parameter combination can be used as a more preferable parameter for controlling the operation of the air conditioner. If the user changes the set parameters within the preset time, it indicates that the adjusted parameter combination cannot meet the comfort of the user, that is, the user requirements are not met. And if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency. That is, if the adjusted parameter combination of the compressor operating frequency and the fan operating frequency cannot meet the requirement of the user, the parameter combination is deleted.

Further, if the matched initial comfort state data is not acquired from the pre-established first database and/or the pre-established second database, the operation of the air conditioner is controlled according to preset initial setting parameters. For example, first, according to the obtained current operation mode and the current unit calculation load, obtaining matched initial comfort state data from the second database, if the matched initial comfort state data is not obtained from the second database, obtaining the matched initial comfort state data from the first database according to the obtained current operation mode and the current unit calculation load, and if the matched initial comfort state data is not obtained from the first database, controlling the operation of the air conditioner according to an initial setting parameter, that is, controlling the operation of the air conditioner according to a default parameter. For example, the default value of the cooling mode is the set temperature T_0LDEG C, windshield-F_0L. The default values of the heating mode are as follows: set temperature T_0RDEG C, windshield-F_0R。

For clearly explaining the technical solution of the present invention, the following describes an execution flow of the air conditioner control method provided by the present invention with a specific embodiment.

Fig. 5 is a schematic method diagram of an embodiment of an air conditioner control method according to the present invention.

As shown in fig. 5, after the intelligent adjustment mode is started, an operation mode is obtained, a unit calculation load is calculated, a load segment where the load is located is determined, the same load segment in the same operation mode is matched in the second database, if the initial comfortable state data which is the same as the load segment where the unit calculation load is located exists in the second database, the set parameter in the initial comfortable state data with the highest priority is obtained for parameter setting, whether the set parameter is changed by the user when the initial satisfaction state of the user is reached is judged, if the set parameter is changed by the user, the corresponding record is deleted from the second database, and if the set parameter is not changed by the user, other record parameters under the set parameter are updated according to the unit data. If the initial comfortable state data which is the same as the load section of the unit calculation load is not matched in the second database, the same load section in the same operation mode is matched in the first database, if the initial comfortable state data which is the same as the load section of the unit calculation load exists in the first database, the set parameters in the initial comfortable state data with the highest priority are obtained for parameter setting, whether the set parameters are changed by the user when the initial satisfactory state of the user is achieved is judged, if the set parameters are changed by the user, the corresponding records are deleted from the first database, and if the set parameters are not changed by the user, the parameters are recorded according to the format of the table 1. If the initial comfortable state data which is the same as the load section where the unit calculation load is located is not matched in the first database, starting according to a default value, and recording parameters according to a form of a table 1 when the initial satisfied state of a user is achieved.

The invention also provides an air conditioner control device. The air conditioner control device is used for realizing an intelligent adjusting mode of the air conditioner.

Fig. 6 is a block diagram of an embodiment of an air conditioning control apparatus according to the present invention. As shown in fig. 6, the air conditioning control apparatus 100 includes: a first acquisition unit 110, a second acquisition unit 120, and a control unit 130.

The first obtaining unit 110 is configured to obtain a current operation mode of the air conditioner and a current unit calculation load.

Specifically, after the intelligent adjustment mode is started, the current operation mode of the air conditioner is obtained, and the current unit calculation load is calculated. In one embodiment, the current unit calculation load is calculated according to the current outdoor environment temperature, the setting parameters and the indoor unit capacity of the air conditioner. The unit can be corrected again according to factors such as comfort and output of the press to obtain the target heating capacity or refrigerating capacity of the unit, and each manufacturer can have a correction algorithm. The unit of load is kW.

The second obtaining unit 120 is configured to obtain the matched initial comfort state data from the pre-established first database and/or second database according to the current operating mode and the current unit computational load obtained by the first obtaining unit 110.

The initial comfort state data may specifically include: setting parameters and/or operating parameters. Optionally, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: and the unit calculates a load segment in which the load is positioned (for example, defining that each time zeta w is increased from 0 load as a load segment, for example, (0, zeta) and (zeta, 2 zeta) are all load segments), at least one of the unit time average total power, the compressor operation frequency and the fan operation frequency.

Fig. 2 is a flowchart illustrating a specific embodiment of the step of establishing the first database based on the adjustment operation of the air conditioner setting parameter by the user when the air conditioner is running. As shown in fig. 2, specifically, the establishing of the first database based on the adjustment operation of the air conditioner setting parameter by the user during the operation of the air conditioner may include step S11, step S12, and step S13.

Step S11, when the air conditioner is running, it is determined whether the running time of the air conditioner, in which the current setting parameter is kept unadjusted, reaches a preset time.

Specifically, if the air conditioner keeps the running time of the current setting parameter, which is not adjusted, for a preset time, it may be said that the indoor environment meets the user's initial comfort state. That is to say, it is determined that the current setting parameter is not adjusted by the user, and whether the operation time of the air conditioner operating according to the current setting parameter reaches the preset time is determined, for example, under a certain working condition (e.g., a certain outdoor environment temperature section) and the unit is operating, if the setting parameter of the air conditioner is changed by X hours by the user, it is determined that the indoor air index satisfies the initial comfort state of the user.

And step S12, if the operation time reaches the preset time, acquiring the current operation mode and the setting parameters of the air conditioner, and acquiring the current operation parameters of the air conditioner.

Specifically, if the air conditioner keeps the current set parameter unadjusted operation time for a preset time, which may indicate that the indoor environment meets the user's initial comfort state, the current operation mode and the set parameter are obtained, and the current operation parameter of the air conditioner, that is, the operation parameter of the air conditioner when the air conditioner operates according to the current set parameter, is obtained.

Step S13, recording the setting parameters and the operating parameters obtained each time as a set of initial comfort state data corresponding to the corresponding operating mode under the corresponding working condition, respectively, thereby creating the first database.

That is, each time it is determined that the operating time during which the current setting parameter of the air conditioner is not adjusted reaches the preset time, the acquired setting parameter and operating parameter are respectively recorded as a set of initial comfort state data corresponding to the corresponding operating mode under the corresponding working condition, so that multiple sets of initial comfort state data can be saved to establish the first database. Each set of initial comfort state data in the first database corresponds to an initial comfort state. Different initial comfort state data can be provided for different working conditions, different operation modes and different set parameters. The working conditions may specifically include outdoor ambient temperature and indoor unit capacity.

For example, the user initial comfort state M is defined as: under the condition that a unit operates in a certain outdoor environment temperature section (namely a temperature interval), if the indoor set parameters are not changed by a user for X hours, the indoor air indexes are judged to meet the initial comfortable state of the user, the set parameters and the operating parameters at the moment are recorded according to the format of the table 1, and the set parameters and the operating parameters are recorded into a first database according to the format. Each set of initial comfort state data corresponds to one initial comfort state, and may be respectively numbered, for example, the initial comfort state 1 shown in table 1, it should be understood that only one set of initial comfort state data is shown in table 1, but the initial comfort state data that may be included may be one set or more than two sets.

Optionally, the setting parameters include: setting a temperature and/or setting a wind speed; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

TABLE 1

The unit factory program comprises a program for calculating the load value which needs to be output by the unit currently, and the unit of the load is kW. The load segment where the load is calculated by the unit is defined, for example, as one load segment every time ζ w increases from 0 load, for example, (0, ζ), (ζ, 2 ζ) are all one load segment.

Optionally, if the air conditioner is subjected to parameter setting according to a setting parameter in any initial comfort state data obtained from the first database (that is, set as the setting parameter of the air conditioner), if the user adjusts the setting parameter of the air conditioner within a preset time, the corresponding initial comfort state data is deleted from the first database, and/or the setting parameter and the corresponding operation parameter after the user adjustment are recorded as a set of initial comfort state data corresponding to the corresponding operation mode under the corresponding working condition, so as to update the first database.

For example, if a recording parameter included in a certain "initial comfort state" is extracted from the first database as a setting parameter, if the user changes the setting in the process, the "initial comfort state" record in the first database is deleted, and the setting parameter adjusted by the user and the adjusted operation parameter are recorded as a set of initial comfort state data corresponding to the corresponding operation mode under the corresponding working condition.

Optionally, if more than two sets of initial comfort state data with the same setting parameter exist in the recorded initial comfort state data corresponding to the same operation mode under the same working condition, one set of initial comfort state data with the minimum unit time average total power is reserved, and the rest are deleted. For example, if there is more than one set of records with the same setting parameters in the first database, only the record with the minimum average total power per hour of the unit is saved.

Optionally, the establishing the first database based on the setting parameters set by the user further includes: and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

Specifically, for each set of the initial comfort state data, a first comfort level corresponding to the corresponding setting parameter is determined according to the changed times (the times changed to the current value) of each setting parameter, and/or for each set of the initial comfort state data, a second comfort level corresponding to the corresponding setting parameter is determined according to the change values (the change values before and after changed to the current value) before and after the change of each setting parameter; and determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter. The different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels. Specifically, different times of changing each set parameter correspond to different first comfort levels, and different pre-change and post-change values of each set parameter correspond to different second comfort levels.

For example, the satisfactory comfort definition is made for the initial comfort state in the form of table 2. According to the format of table 2 when the user initial comfort state is judged to be satisfied each time, the comfort level of the corresponding initial comfort state is determined according to the number of times that the set parameter is changed (the number of times that the set parameter is changed to the current value) and/or the change value before and after the set parameter is changed (the change value before and after the set parameter is changed to the current value) in the initial comfort state data corresponding to the current operation mode under the current working condition, and the actual comfort of the user is defined.

For example, the operation mode is determined first, and then the current outdoor environment temperature (working condition) is determined, on the premise that this is the premise, the real comfort of the user is defined for the times of adjusting the setting parameters by the user under different operation modes and different setting parameters, and the change values before and after the user adjusts the setting parameters.

For example, the words defining comfort may be different levels of "very cold", "slightly cold", "comfort", "slightly hot", "very hot", and the like. For example, setting parameters including setting temperature and setting wind gear, the definition of the grade may utilize the following parameters: user-set temperature operation times C_T(i.e., the number of times the user changes the set temperature), the user-set temperature change amplitude f_T(i.e., the set temperature change value before and after the user changes the set temperature), the user sets the windshield change amplitude f_F(i.e. the user changes the wind gear (wind speed) change value before and after setting the wind gear), and the user sets the number of times of operation C of the windshield_F(i.e. the number of times the user changes the setting of the gear), these parameters have different value ranges, four parameters C_T、f_T、f_F、C_FUnder different combinations of ranges, different grades are defined.

For example, as shown in Table 2, can be C_T、f_T、f_F、C_FDifferent value sections are set, and each value section is a grade.

Such as C_TThe value section(s) is (are) grade A in (a, B), grade B in (c, d), and the like. Different user comfort levels may be defined according to different combinations of levels. For example, when all four parameters are a, comfort is defined as "comfort". The definition of comfort canTo adjust by taking value segments. The words comfort definition may be "comfortable", "cooler", "very cold", etc.

TABLE 2

Different parameter value combinations can be provided under different working conditions, different operation modes and different setting conditions to define the user comfort. Each set of initial comfort state data corresponds to an initial comfort state, and may be respectively numbered, for example, the initial comfort state 1 shown in table 2. It should be understood that only one set of initial comfort state data is shown in table 2, but that it may include one or more sets of initial comfort state data.

Fig. 3 is a flowchart illustrating a specific embodiment of the step of establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user when the air conditioner is running. As shown in fig. 3, specifically, the step of establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user during the operation of the air conditioner may include the step S21 and the step S22.

Step S21, acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level comprises at least one comfort level;

step S22, establishing the second database based on the obtained comfort level of the corresponding initial comfort state as the initial comfort state data of the preset level.

If the preset level is "comfortable", for example, acquiring initial comfort state data, of which the comfort level of the initial comfort state is "comfortable", corresponding to the first database, and establishing a second database based on the acquired initial comfort state data, of which the comfort level of the initial comfort state is "comfortable". Optionally, the preset level may also include more than two comfort levels. Optionally, the initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level is deleted from the first database.

For example, the initial comfort state data with the corresponding comfort level of the initial comfort state as "comfort" is obtained from the first database, and the data is entered into the second database according to the format of table 3 below, which is the energy-saving database that the user actually satisfies. This "initial comfort state" contains records (i.e. initial comfort state data) that are deleted in the first database.

TABLE 3

Optionally, the establishing the second database based on the adjustment of the setting parameter of the air conditioner by the user when the air conditioner is running further includes: and adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of the original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment.

For example, referring to table 3, the operating frequency of the compressor and/or the operating frequency of the fan in a certain set of initial comfort state data are reduced and adjusted on the basis of the original value (the original parameter value corresponding to the initial comfort state of the user is satisfied), so as to obtain more than two different sets of parameter combinations of the operating frequency of the compressor and the operating frequency of the fan after adjustment. For example, the compressor operating frequency and the fan operating frequency in the parameter combination may be adjusted by only one or both of them, so as to obtain three different sets of parameter combinations of the compressor operating frequency and the fan operating frequency. For example, as shown in table 3, in the parameter combination with level 1, the compressor operating frequency and the fan operating frequency are the original values of the compressor operating frequency and the fan operating frequency in the initial comfort state data, and in the parameter combination with level 2, the compressor operating frequency is the original value, and the fan operating frequency is decreased by b on the basis of the original value; in the parameter combination with the level 3, c is subtracted from the compressor operating frequency on the basis of the original value, and the fan operating frequency is the original value; in the parameter combination with the level 4, the operating frequency of the compressor is decreased by d on the basis of the original value, and the operating frequency of the fan is decreased by e on the basis of the original value, wherein b, c, d and e are all adjustable positive numbers. The running frequency of the compressor or the running frequency of the fan is reduced on the basis of an original value, and the unit time average total power can be reduced theoretically, so that more energy-saving control is realized.

The "initial comfort state" in table 3 and the "initial comfort state" in table 1 are the same record. The 'operation mode', 'load section where the unit calculation load is located', 'user-set temperature', 'user-set windshield' are all parameters in the same recording state. It should be understood that only one set of initial comfort state data is shown in table 3, but that it may include one or more sets of initial comfort state data.

The control unit 130 is configured to obtain a setting parameter in the initial comfort state data, and control the operation of the air conditioner according to the obtained setting parameter.

In some embodiments, the second obtaining unit 120 searches the first database or the second database for the initial comfort state data that is the same as the current operation mode and the same as the load segment of the current unit computational load. More specifically, the initial comfort state data which is the same as the current working condition, the same as the current operation mode and the same as the load section of the current unit calculation load is searched from the first database or the second database. Preferably, the second obtaining unit 120 obtains the matched initial comfort state data from the second database according to the obtained current operating mode and the current unit computing load, and if the matched initial comfort state data is not obtained from the second database, obtains the matched initial comfort state data from the first database according to the obtained current operating mode and the current unit computing load.

If the initial comfort state data acquired by the second acquiring unit 120 is a set, the control unit 130 acquires the setting parameters in the set of initial comfort state data, and controls the operation of the air conditioner according to the acquired setting parameters.

If the initial comfort state data acquired by the second acquiring unit 120 is more than two groups, the controlling unit 130 acquires the setting parameters in the initial comfort state data, and controls the operation of the air conditioner according to the acquired setting parameters, including: if the number of the obtained initial comfortable state data is more than two groups, the obtained more than two groups of the initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time; the smaller the average total power of the unit in unit time is, the higher the corresponding priority is; and acquiring the setting parameters in the initial comfort state data with the highest priority according to the priority sequencing result, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

For example, more than two groups of initial comfort state data acquired from the first database or the second database are sorted according to the average total power per hour of the unit, the smaller the average total power per hour is, the higher the corresponding priority is, and the operation of the air conditioner is controlled according to the set parameters in the initial comfort state data with the highest priority.

In one embodiment, the control unit 130 controls the operation of the air conditioner according to the setting parameter in the initial comfort state data with the highest priority, including: and setting parameters of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority. The setting of the operating parameters comprises: compressor operating frequency and/or fan operating frequency.

Optionally, the controlling unit 130 controls the operation of the air conditioner according to the setting parameter in the initial comfort state data with the highest priority, and further includes: controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority; and after the operation of the air conditioner is sequentially judged to be controlled according to the adjusted parameter combinations of the more than two groups of different compressor operation frequencies and fan operation frequencies, judging whether the operation state of the air conditioner meets the user requirements, and if the operation state of the air conditioner does not meet the user requirements, deleting the corresponding parameter combinations of the compressor operation frequencies and the fan operation frequencies.

Wherein, judge whether the air conditioner running state satisfies user's demand, include: and judging whether the set parameters are changed within the preset time, if so, judging that the user requirements are not met. That is, after the operation of the air conditioner is controlled according to the adjusted parameter combination of the two or more different sets of the compressor operation frequency and the fan operation frequency, which is obtained by adjusting the initial comfort state data with the highest priority on the basis of the original value, if the user does not change the parameter combination within the preset time, the adjusted parameter combination can meet the comfort of the user, the parameter combination can be retained, the compressor operation frequency or the fan operation frequency is reduced on the basis of the original value, the unit time average total power can be theoretically reduced, and therefore more energy-saving control is achieved, and therefore the parameter combination can be used as a more preferable parameter for controlling the operation of the air conditioner. If the user changes the set parameters within the preset time, it indicates that the adjusted parameter combination cannot meet the comfort of the user, that is, the user requirements are not met. And if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency. That is, if the adjusted parameter combination of the compressor operating frequency and the fan operating frequency cannot meet the requirement of the user, the parameter combination is deleted.

Further, the control unit 130 is further configured to: if the second obtaining unit 120 does not obtain the matched initial comfort state data from the pre-established first database and/or the second database, the control unit 130 controls the operation of the air conditioner according to preset initial setting parameters. For example, the second obtaining unit 120 first obtains the matched initial comfort state data from the second database according to the obtained current operation mode and the current unit calculation load, and if the matched initial comfort state data is not obtained from the second databaseIf the second obtaining unit 120 does not obtain the matched initial comfort state data from the first database, the control unit 130 controls the operation of the air conditioner according to the initial setting parameters, that is, controls the operation of the air conditioner according to the default parameters. For example, the default value of the cooling mode is the set temperature T_0LDEG C, windshield-F_0L. The default values of the heating mode are as follows: set temperature T_0RDEG C, windshield-F_0R。

The present invention also provides a storage medium corresponding to the air conditioning control method, having a computer program stored thereon, which when executed by a processor, performs the steps of any of the aforementioned methods.

The invention also provides an air conditioner corresponding to the air conditioner control method, which comprises a processor, a memory and a computer program which is stored on the memory and can run on the processor, wherein the processor realizes the steps of any one of the methods when executing the program.

The invention also provides an air conditioner corresponding to the air conditioner control device, which comprises the air conditioner control device.

Therefore, according to the scheme provided by the invention, the user comfort levels are defined according to the parameters before and after adjustment by combining the user adjustment condition during the operation of the unit, so that the control optimization is carried out through different comfort levels, and finally, the energy-saving control is achieved by comparing the average use power of the unit in different time periods.

By using the use data of the user and the transformation conditions of various indoor parameters, the unit analyzes and judges the comfort level of the unit based on user experience by using the average use power condition of the unit at different time intervals, and performs self-learning and self-optimization of the unit, thereby finally achieving the effects of meeting the user requirements and saving energy.

Real experience of the unit for a user during operation is judged in multiple directions through coupling of multi-dimensional parameters of the unit. The comfort condition of the unit based on the user experience is judged through the set adjustment of the user to the unit, and the comfort condition is divided. The set setting is intelligently adjusted through the use condition of the user and the power of the set, the set control is corrected, and the effect of man-machine interaction is achieved. Therefore, a certain energy-saving effect is achieved on the premise of meeting the comfort of the user.

The control of the unit is adjusted based on user experience, self-learning and self-correction of the unit are realized through a man-machine interaction method, the running condition of the unit and the user experience are related, and the user experience is optimized to a certain extent by the satisfaction degree of the user. Through the comparison of the average power of the units, the most energy-saving self-adaptive control is pushed, and the satisfaction and comfort of users can be achieved.

The functions described herein may be implemented in hardware, software executed by a processor, firmware, or any combination thereof. If implemented in software executed by a processor, the functions may be stored on or transmitted over as one or more instructions or code on a computer-readable medium. Other examples and implementations are within the scope and spirit of the invention and the following claims. For example, due to the nature of software, the functions described above may be implemented using software executed by a processor, hardware, firmware, hardwired, or a combination of any of these. In addition, each functional unit may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In the embodiments provided in the present application, it should be understood that the disclosed technology can be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units may be a logical division, and in actual implementation, there may be another division, for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, units or modules, and may be in an electrical or other form.

The units described as separate parts may or may not be physically separate, and the parts serving as the control device may or may not be physical units, may be located in one place, or may be distributed on a plurality of units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a removable hard disk, a magnetic or optical disk, and other various media capable of storing program codes.

The above description is only an example of the present invention, and is not intended to limit the present invention, and it is obvious to those skilled in the art that various modifications and variations can be made in the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (24)

1. An air conditioner control method, comprising:

acquiring the current operation mode of the air conditioner and the current unit calculation load;

acquiring matched initial comfort state data from a first database and/or a second database which are established in advance according to the acquired current operation mode and the current unit calculation load, wherein the initial comfort state data comprises: setting parameters;

acquiring set parameters in the initial comfortable state data, and controlling the operation of the air conditioner according to the acquired set parameters;

and establishing the first database or the second database based on the adjustment operation of the user on the air conditioner setting parameters during the operation of the air conditioner.

2. The method of claim 1, further comprising:

and if the matched initial comfort state data is not acquired from the pre-established first database or the pre-established second database, controlling the operation of the air conditioner according to the initial setting parameters.

3. The method according to claim 1 or 2, wherein the establishing of the first database based on the adjustment operation of the air conditioner setting parameter by the user when the air conditioner is running comprises:

when the air conditioner is operated, judging whether the operation time of the air conditioner, in which the current setting parameters are not adjusted, reaches a preset time or not;

if the running time reaches the preset time, acquiring the current running mode and the set parameters of the air conditioner, and acquiring the current running parameters of the air conditioner;

respectively recording the acquired setting parameters and the acquired running parameters as a group of initial comfort state data corresponding to the corresponding running mode under the corresponding working condition, thereby establishing the first database;

wherein, the setting parameters include: setting a temperature and/or setting a wind speed;

the initial comfort state data further comprises: operating parameters; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

4. The method of claim 3, wherein establishing the first database based on setting parameters set by a user further comprises:

and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

5. The method according to claim 4, wherein the determining the comfort level of the corresponding initial comfort state according to the number of times the setting parameter is changed and/or the change value before and after the setting parameter is changed in the initial comfort state data corresponding to different operation modes under different working conditions comprises:

for each group of initial comfort state data, determining a first comfort level corresponding to a corresponding set parameter according to the changed times of each set parameter, and/or for each group of initial comfort state data, determining a second comfort level corresponding to a corresponding set parameter according to the change value before and after each set parameter is changed;

determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter;

the different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels.

6. The method of claim 4 or 5, wherein establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user while the air conditioner is running comprises:

acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level comprises at least one comfort level;

and establishing the second database based on the obtained initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level.

7. The method of claim 6, wherein acquiring the setting parameter in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameter comprises:

if the number of the obtained initial comfortable state data is more than two groups, the obtained more than two groups of the initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time; the smaller the average total power of the unit in unit time is, the higher the corresponding priority is;

and acquiring the setting parameters in the initial comfort state data with the highest priority according to the priority sequencing result, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

8. The method as claimed in claim 7, wherein controlling the operation of the air conditioner according to the setting parameter in the initial comfort state data having the highest priority level comprises:

performing parameter setting on the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority, wherein the set operation parameters comprise: compressor operating frequency and/or fan operating frequency.

9. The method according to any one of claims 6 to 8, wherein establishing the second database based on the adjustment of the setting parameters of the air conditioner by the user while the air conditioner is running further comprises:

adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of an original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment;

controlling the operation of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, further comprising:

controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority;

judging in proper order according to the parameter combination control of the compressor operating frequency and the fan operating frequency of more than two sets of difference after the adjustment the operation of air conditioner back, whether air conditioner running state satisfies user's demand, include: judging whether the set parameters are changed within preset time, if so, judging that the user requirements are not met;

and if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency.

10. Method according to any of claims 1-9, wherein retrieving matching initial comfort state data from a pre-established first database and/or second database based on the retrieved current operation mode and the current crew computational load comprises:

firstly, acquiring matched initial comfort state data from the second database according to the acquired current operation mode and the current unit calculation load, and if the matched initial comfort state data is not acquired from the second database, acquiring the matched initial comfort state data from the first database according to the acquired current operation mode and the current unit calculation load.

11. Method according to any of claims 1-10, wherein retrieving matching initial comfort state data from a pre-established first database and/or second database based on the retrieved current operation mode and the current crew computational load comprises:

and searching the initial comfort state data which is the same as the current operation mode and the load section of the current unit calculation load from the first database or the second database.

12. An air conditioning control device, characterized by comprising:

the first acquisition unit is used for acquiring the current operation mode of the air conditioner and the current unit calculation load;

a second obtaining unit, configured to obtain, according to the current operating mode and the current unit computational load obtained by the first obtaining unit, matched initial comfort state data from a first database and/or a second database established in advance, where the initial comfort state data includes: setting parameters;

the control unit is used for acquiring set parameters in the initial comfortable state data and controlling the operation of the air conditioner according to the acquired set parameters;

and establishing the first database or the second database based on the adjustment operation of the user on the air conditioner setting parameters during the operation of the air conditioner.

13. The apparatus of claim 12, further comprising:

the control unit is further configured to: and if the second acquisition unit does not acquire the matched initial comfort state data from the pre-established first database or second database, controlling the operation of the air conditioner according to the initial setting parameters.

14. The apparatus according to claim 12 or 13, wherein the establishing of the first database based on the adjustment operation of the air conditioner setting parameter by the user while the air conditioner is running comprises:

when the air conditioner is operated, judging whether the operation time of the air conditioner, in which the current setting parameters are not adjusted, reaches a preset time or not;

if the running time reaches the preset time, acquiring the current running mode and the set parameters of the air conditioner, and acquiring the current running parameters of the air conditioner;

respectively recording the acquired setting parameters and the acquired running parameters as a group of initial comfort state data corresponding to the corresponding running mode under the corresponding working condition, thereby establishing the first database;

wherein, the setting parameters include: setting a temperature and/or setting a wind speed;

the initial comfort state data further comprises: operating parameters; the operating parameters include: and the unit calculates at least one of a load section where the load is located, unit time average total power, compressor operation frequency and fan operation frequency.

15. The apparatus of claim 14, wherein the first database is established based on setting parameters set by a user, and further comprising:

and determining the comfort level of the corresponding initial comfort state according to the number of times of changing the set parameters and/or the change values of the set parameters before and after changing in the initial comfort state data corresponding to different operation modes under different working conditions.

16. The apparatus according to claim 15, wherein the determining the comfort level of the corresponding initial comfort state according to the number of times the setting parameter is changed and/or the change value before and after the setting parameter is changed in the initial comfort state data corresponding to different operation modes under different working conditions comprises:

for each group of initial comfort state data, determining a first comfort level corresponding to a corresponding set parameter according to the changed times of each set parameter, and/or for each group of initial comfort state data, determining a second comfort level corresponding to a corresponding set parameter according to the change value before and after each set parameter is changed;

determining the comfort level of the corresponding initial comfort state according to the first comfort level and/or the second comfort level corresponding to each determined setting parameter;

the different changed times of different setting parameters respectively correspond to different first comfort levels, and/or different pre-change and post-change values of different setting parameters correspond to different second comfort levels.

17. The apparatus of claim 15 or 16, wherein the second database is established based on the adjustment of the setting parameters of the air conditioner by the user when the air conditioner is operated, and comprises:

acquiring initial comfort state data with the comfort level of the corresponding initial comfort state in the first database as a preset level; the preset level comprises at least one comfort level;

and establishing the second database based on the obtained initial comfort state data with the comfort level of the corresponding initial comfort state as a preset level.

18. The apparatus as claimed in any one of claims 12 to 17, wherein the control unit, acquiring the setting parameter in the initial comfort state data and controlling the operation of the air conditioner according to the acquired setting parameter, comprises:

if the number of the obtained initial comfortable state data is more than two groups, the obtained more than two groups of the initial comfortable state data are subjected to priority sequencing according to the average total power of the unit in unit time; the smaller the average total power of the unit in unit time is, the higher the corresponding priority is;

and acquiring the setting parameters in the initial comfort state data with the highest priority according to the priority sequencing result, so as to control the operation of the air conditioner according to the setting parameters in the initial comfort state data with the highest priority.

19. The apparatus of claim 18, wherein the control unit controls the operation of the air conditioner according to the setting parameter in the initial comfort state data having the highest priority, comprising:

performing parameter setting on the air conditioner according to the set parameters in the initial comfort state data with the highest priority, and controlling the air conditioner to operate according to the set operation parameters in the initial comfort state data with the highest priority, wherein the set operation parameters comprise: compressor operating frequency and/or fan operating frequency.

20. The apparatus of any one of claims 17-19, wherein the second database is established based on user adjustments to setting parameters of the air conditioner while the air conditioner is operating, further comprising:

adjusting the compressor operating frequency and/or the fan operating frequency in each set of the obtained initial comfort state data on the basis of an original value to obtain more than two sets of different parameter combinations of the compressor operating frequency and the fan operating frequency after adjustment;

controlling the operation of the air conditioner according to the set parameters in the initial comfort state data with the highest priority, further comprising:

controlling the operation of the air conditioner according to the parameter combination of more than two groups of different adjusted compressor operation frequencies and fan operation frequencies obtained by adjusting on the basis of the original value in the initial comfort state data with the highest priority;

judging in proper order according to the parameter combination control of the compressor operating frequency and the fan operating frequency of more than two sets of difference after the adjustment the operation of air conditioner back, judge whether air conditioner running state satisfies user's demand, include: judging whether the set parameters are changed within preset time, if so, judging that the user requirements are not met;

and if the air conditioner running state is judged not to meet the user requirements, deleting the corresponding parameter combination of the compressor running frequency and the fan running frequency.

21. The apparatus according to any one of claims 12 to 20, wherein the second obtaining unit obtains the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load, and comprises:

firstly, acquiring matched initial comfort state data from the second database according to the acquired current operation mode and the current unit calculation load, and if the matched initial comfort state data is not acquired from the second database, acquiring the matched initial comfort state data from the first database according to the acquired current operation mode and the current unit calculation load.

22. The apparatus according to any one of claims 12 to 21, wherein the second obtaining unit obtains the matched initial comfort state data from the pre-established first database and/or second database according to the obtained current operation mode and the current unit calculation load, and comprises:

and searching the initial comfort state data which is the same as the current operation mode and the load section of the current unit calculation load from the first database or the second database.

23. A storage medium, having stored thereon a computer program which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 11.

24. An air conditioner comprising a processor, a memory, and a computer program stored on the memory and operable on the processor, the processor implementing the steps of the method of any one of claims 1 to 11 when executing the program, or comprising the air conditioning control apparatus of any one of claims 12 to 22.

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