CN104833038B - Multi-gang air-conditioner centralized Control method and Centralized Controller - Google Patents

Abstract

The present invention provides a kind of multi-gang air-conditioner centralized Control method and Centralized Controller.Wherein method comprises the following steps：Save the setting of cycle and target energy conservation value to an at least indoor set for multi-gang air-conditioner, according to the target energy conservation value of setting, the operational factor of storage and the default operational factor of user's setting, computing is carried out within the energy-conservation cycle and draws the energy-saving run parameter after optimization, control multi-gang air-conditioner carries out energy-saving run.Its target energy conservation value that can be set according to multi-gang air-conditioner difference indoor set, the default operational factor of intelligence computation user setting, and default operational factor is optimized, multi-gang air-conditioner is reached the effect of energy-conservation；It had both met that user used comfort of air conditioner, allowed user's own experience to lift satisfaction of the user to product to the effect for reducing air-conditioning power consumption and operating cost again；It is applied to multi-gang air-conditioner, can carry out target energy conservation value setting to more indoor sets simultaneously, add the population proportion of energy-conservation.

Description

Multi-gang air-conditioner centralized Control method and Centralized Controller

Technical field

The present invention relates to air-conditioner field, more particularly to multi-gang air-conditioner centralized Control method and Centralized Controller.

Background technology

Existing multi-gang air-conditioner Centralized Controller is only capable of realizing central controlled basic function, i.e.,：Centralized Controller root Setup parameter according to user to separate unit indoor set（Including parameters such as pattern, design temperature, wind speed settings）, issue control command to Air-conditioning system, the parameter that indoor set is set according to user are run, and outdoor unit carries out the distribution of ability according to the setting demand of user.

By multi-gang air-conditioner towards user's composition of residents it is complicated, user runs and saved knowledge to multi-gang air-conditioner Understand seldom, easily cause energy waste from control source（Such as design temperature is too low during refrigeration, design temperature mistake during heating It is high, cause energy consumption to raise）, also influence air-conditioning the comfortable effect of use（Supercooling, the comfortable experience for crossing heat affecting user）, together When, also it is unfavorable for control of each user to energy consumption, does not reach preferable effects of energy saving and emission reduction, then increases for the user of household cost allocation The expense that user undertakes is added.

The content of the invention

The problem of it is poor to be controlled for existing multi-gang air-conditioner Centralized Controller energy consumption, and effects of energy saving and emission reduction is bad, this hair It is bright to provide a kind of energy-saving multi-gang air-conditioner centralized Control method and Centralized Controller.

To reach technical purpose, the embodiment of the present invention adopts the following technical scheme that：

The present invention provides a kind of multi-gang air-conditioner centralized Control method, comprises the following steps：

Save the setting of cycle and target energy conservation value to an at least indoor set for multi-gang air-conditioner；

According to the target energy conservation value of setting, the default operational factor of the operational factor of storage and user's setting, saving Computing is carried out in cycle, draws the energy-saving run parameter after optimization；

Control multi-gang air-conditioner is run by the energy-saving run parameter after optimization.

It is described to carry out computing within the energy-conservation cycle as a kind of embodiment, draw the energy-saving run parameter after optimization, control Multi-gang air-conditioner processed is run by the energy-saving run parameter after optimization, is comprised the following steps：

The operational factor of the default running temperature and database purchase in the default operational factor of user's setting is obtained, is carried out Computing, the first energy-conservation operational factor after optimization is drawn, control signal is sent and controls multi-gang air-conditioner by the first segment after optimization Can operational factor operation；

When multi-gang air-conditioner run time reaches the gap periods of setting, computing is carried out, draws the second section after optimization Energy operational factor, send control signal control multi-gang air-conditioner and run by the second energy-saving run parameter after optimization.

As a kind of embodiment, carry out saving cycle and target at least indoor set to multi-gang air-conditioner Before the setting of energy conservation value, also comprise the following steps：

The operational factor of the indoor set of multi-gang air-conditioner in the history energy-conservation cycle is stored；

Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history section Can the cycle；The unit in history energy-conservation cycle is day.

As a kind of embodiment, the carry out computing, comprise the following steps：

A corresponding upper energy-conservation cycle and target energy conservation value were obtained from the operational factor of storage；

Read the user's design temperature and real time environment temperature of the indoor set of the multi-gang air-conditioner of upper energy-conservation cycle memory storage Degree；

Calculate the average value T of daily user's design temperature_saWith the average value T of daily real time environment temperature_ea；

According to formulaCalculate the power saving factor Δ T in an energy-conservation cycle；

Judge the absolute of the temperature difference of the default running temperature and current environmental temperature in the default operational factor of user's setting Whether value is in power saving factor Δ T；

If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, the energy-saving run ginseng after optimization is drawn Number is the default operational factor of user's setting and power saving factor Δ T difference, if the preset running mode of multi-gang air-conditioner is system During chill formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.

As a kind of embodiment, the default operational factor includes default running temperature, preset running mode and/or section Can the cycle；

The unit in the energy-conservation cycle is day, and the target energy conservation value is as a percentage；

The unit of the gap periods is hour or minute, the gap periods be program fixed value set in advance or Person is set by user and obtained.

The present invention also provides a kind of multi-gang air-conditioner Centralized Controller, including setting module and data processing module, wherein：

The setting module, for carrying out saving cycle and target energy conservation value to an at least indoor set for multi-gang air-conditioner Setting；

The data processing module, for the target energy conservation value according to setting, the operational factor of storage and user's setting Default operational factor, energy-conservation the cycle in carry out computing, draw optimization after energy-saving run parameter, control multi-gang air-conditioner press Energy-saving run parameter after optimization is run.

As a kind of embodiment, the data processing module includes first processing units and second processing unit；

The first processing units, the default running temperature and data in default operational factor for obtaining user's setting The operational factor of library storage, computing is carried out, draw the first energy-conservation operational factor after optimization, send control signal control multi-connected machine Air-conditioning is by the first energy-conservation operational factor operation after optimization；

The second processing unit, during gap periods for reaching setting when multi-gang air-conditioner run time, transported Calculate, draw the second energy-saving run parameter after optimization, send control signal control multi-gang air-conditioner by the second energy-conservation after optimization Operational factor is run.

As a kind of embodiment, the Centralized Controller includes database storage module；

The database storage module, for entering to the operational factor of the indoor set of multi-gang air-conditioner in the history energy-conservation cycle Row storage；

Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history section Can the cycle；The unit in history energy-conservation cycle is day.

As a kind of embodiment, the Centralized Controller also includes algoritic module；

The algoritic module includes acquiring unit, reads computing unit, power saving factor unit and draws energy-saving run parameter Unit, wherein：

The acquiring unit, for obtaining a corresponding upper energy-conservation cycle and target energy-conservation from the operational factor of storage Value；

The reading computing unit, the user of the indoor set of the multi-gang air-conditioner for reading upper energy-conservation cycle memory storage Design temperature and real time environment temperature, and calculate the average value T of daily user's design temperature_saWith daily real time environment temperature Average value T_ea；

The power saving factor unit, is used for and according to formulaCalculate an energy-conservation The power saving factor Δ T in cycle；

It is described to draw energy-saving run parameters unit, the default operation temperature in default operational factor for judging user's setting Whether the absolute value of the temperature difference of degree and current environmental temperature is in power saving factor Δ T；

If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, the energy-saving run ginseng after optimization is drawn Number is the default operational factor of user's setting and power saving factor Δ T difference, if the preset running mode of multi-gang air-conditioner is system During chill formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.

As a kind of embodiment, the default operational factor includes default running temperature, preset running mode and/or section Can the cycle；

The unit in the energy-conservation cycle is day, and the target energy conservation value is as a percentage；

The unit of the gap periods is hour or minute, the gap periods be program fixed value set in advance or Person is set by user and obtained.

Beneficial effects of the present invention：

The multi-gang air-conditioner centralized Control method and Centralized Controller of the present invention, can be according in multi-gang air-conditioner different chamber The target energy conservation value of machine setting, the default operational factor of intelligence computation user setting, and default operational factor is optimized, make Multi-gang air-conditioner reaches the effect of energy-conservation.This method makes user participate in energy-saving activity, met from user perspective While user uses comfort of air conditioner, own experience enhances user's to the effect for reducing air-conditioning power consumption and operating cost Experience sense, satisfaction of the lifting user to product.In addition, this method is applied to multi-gang air-conditioner, can be simultaneously to more indoor sets Target energy conservation value setting is carried out, adds the population proportion of energy-conservation, to reducing energy waste, user cost is reduced, saves the energy There is good effect.

Brief description of the drawings

Fig. 1 is the schematic flow sheet of an embodiment of the multi-gang air-conditioner centralized Control method of the present invention；

Fig. 2 is the idiographic flow schematic diagram of step S200 corresponding to a Fig. 1 embodiment；

Fig. 3 is the idiographic flow schematic diagram of step S300 corresponding to a Fig. 1 embodiment；

Fig. 4 is the step schematic diagram of the progress computing of the multi-gang air-conditioner centralized Control method of the present invention；

Fig. 5 is the structural representation of an embodiment of the multi-gang air-conditioner Centralized Controller of the present invention.

Embodiment

In order to make the purpose , technical scheme and advantage of the present invention be clearer, below in conjunction with drawings and Examples pair Multi-gang air-conditioner centralized Control method of the present invention and Centralized Controller are further elaborated.It should be appreciated that this place is retouched The specific embodiment stated only to explain the present invention, is not intended to limit the present invention.

Embodiment one

The embodiment of the present invention provides a kind of multi-gang air-conditioner centralized Control method, shown in Figure 1, comprises the following steps：

S100, the setting of cycle and target energy conservation value save to an at least indoor set for multi-gang air-conditioner；

According to the target energy conservation value of setting, the default operational factor of the operational factor of storage and user's setting, saving Computing is carried out in cycle, draws the energy-saving run parameter after optimization;

Control multi-gang air-conditioner is run by the energy-saving run parameter after optimization.

The multi-gang air-conditioner centralized Control method of the present invention, one or more indoor sets of multi-gang air-conditioner are selected first Save the setting of cycle and target energy conservation value, week is saved according to the history stored in the target energy conservation value and database of setting The operational factor of multi-gang air-conditioner indoor set in phase, carries out certain computing, draws the energy-saving run parameter of optimization, energy-conservation fortune Energy-saving run parameter when row parameter is the indoor set actual motion selected by multi-gang air-conditioner.Using of the present invention multi-joint Air conditioner centralized Control method, the target energy conservation value that can be set according to different indoor set users, intelligence computation user setting Default operational factor, and default operational factor is optimized, energy-saving run parameter is obtained, is handed down to the interior of multi-gang air-conditioner Machine controls its operation, can reach the effect of energy-conservation.

The present invention makes user participate in energy-saving activity, is meeting that it is empty that users'comfort uses from user perspective While tune, own experience to the effect for reducing air-conditioning power consumption and operating cost, enhancing user experience, consumer products are lifted Satisfaction.In addition, the present invention is applied to multi-gang air-conditioner, it can carry out energy-conservation setting to more indoor sets simultaneously, add section The population proportion of energy, to reducing energy waste, user cost is reduced, saving the energy has good effect.

It is described to carry out computing within the energy-conservation cycle referring to shown in Fig. 2, Fig. 3 as a kind of embodiment, draw optimization Energy-saving run parameter afterwards, control multi-gang air-conditioner are run by the energy-saving run parameter after optimization, comprised the following steps：

S200, obtain the operation ginseng of the default running temperature and database purchase in the default operational factor of user's setting Number, computing is carried out, draw the first energy-conservation operational factor T after optimization_sn1, send control signal and control multi-gang air-conditioner by optimization The first energy-conservation operational factor T afterwards_sn1Operation；

S300, when multi-gang air-conditioner run time reaches the gap periods T of setting_oWhen, computing is carried out, after drawing optimization Second energy-saving run parameter T_sn2, send control signal and control multi-gang air-conditioner by the second energy-saving run parameter T after optimization_sn2Fortune OK.

After multi-gang air-conditioner obtain energy-conservation cycle and target energy conservation value, run according to step S200, then further according to step S300 is run, and step S200 optimizes to the default operational factor that user sets according to certain algorithm, by the section after optimization Energy operational factor is handed down to multi-gang air-conditioner and controls it to be run, and it is run according to energy-saving run parameter, reaches energy-conservation Effect；Step S300 is according to the gap periods T of setting_o, often reach gap periods T_oWhen, once-through operation is just carried out, is drawn after calculating New energy-saving run parameter, and be handed down to multi-gang air-conditioner and control it to carry out energy-saving run, reach the effect of energy-conservation.

The default operational factor that operating procedure S200 is set to user optimizes, the energy-saving run parameter after being optimized For the first energy-conservation operational factor T_sn1, the default operational factor that operating procedure S300 is set to user optimizes, after obtaining optimization Energy-saving run parameter be the second energy-saving run parameter T_sn2。

The the first energy-conservation operational factor and the second energy-saving run parameter that multi-gang air-conditioner is drawn by step S200, S300 are run Afterwards, judge multi-gang air-conditioner run time whether reached user setting the energy-conservation cycle, when running between reach energy-conservation During the cycle, the optimization of the default operational factor in next energy-conservation cycle is carried out, target energy conservation value and energy-conservation cycle is reset, makes Multi-gang air-conditioner is run by the energy-saving run parameter after optimization, reaches the effect of energy-conservation；When the not up to energy-conservation cycle, multi-connected machine Air-conditioning continues the optimization of the default operational factor in the current energy-conservation cycle, makes multi-gang air-conditioner energy-saving run.

As a kind of embodiment, carry out saving cycle and mesh at least indoor set to multi-gang air-conditioner Before the setting for marking energy conservation value, also comprise the following steps：

The operational factor of the indoor set of multi-gang air-conditioner in the history energy-conservation cycle is stored；

Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history section Can the cycle；The unit in history energy-conservation cycle is day.

Operational factor in the history energy-conservation cycle is stored in database, can facilitate multi-connected machine in the query history energy-conservation cycle The operational factor of air-conditioning（Including user's design temperature, real time environment temperature and history energy-conservation cycle）, can be from when carrying out computing The data parameters of needs are obtained in the data of database purchase（User's design temperature in a such as corresponding upper energy-conservation cycle, in real time Environment temperature and it is upper one energy-conservation cycle T '）, make computing trouble-free operation.

It is shown in Figure 4 as a kind of embodiment, the carry out computing, comprise the following steps：

Step A, obtained from the operational factor of storage corresponding upper energy-conservation cycle T ' with target energy conservation value P；

Step B, read it is upper one save cycle T ' memory storage multi-gang air-conditioner indoor set user's design temperature T_sAnd Real time environment temperature T_e；

Step C, calculate the average value T of daily user's design temperature_saWith the average value T of daily real time environment temperature_ea；

Step D, according to formulaCalculate the power saving factor Δ in an energy-conservation cycle T；

Step E, judge the default running temperature T in the default operational factor of user's setting_soWith current environmental temperature T_ec's Whether the absolute value of the temperature difference is in power saving factor Δ T；

If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, the energy-saving run ginseng after optimization is drawn Number is the default operational factor of user's setting and power saving factor Δ T difference, if the preset running mode of multi-gang air-conditioner is system During chill formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.

Above-mentioned steps are to carry out the embodiment of computing, obtain first corresponding upper energy-conservation cycle T ' and use The target energy conservation value P of family setting, energy-conservation cycle T and upper energy-conservation cycle T ' in units of day, target energy conservation value P is with percentage table Show；Then the operational factor in a upper energy-conservation cycle for the indoor set of storage, including user's design temperature were read from database T_sAnd real time environment temperature T_e, user's design temperature reads user's design temperature of wherein one day, is designated as in units of day T_s1,T_s2,T_s3…T_si, corresponding real time environment temperature is designated as T_e1,T_e2,T_e3…T_ei, according to user's design temperature of reading In being calculated daily with real time environment temperature, the average value T of user's design temperature_saWith the average value T with real time environment temperature_ea, Wherein：The formula of average value for calculating user's design temperature is：Calculate the average value of real time environment temperature Formula is：

Wherein, i is positive integer（i=1、2、3…n）, n is the quantity of same day user's design temperature and real time environment temperature；Root According to the average value T of daily user's design temperature_saWith the average value Tea of daily real time environment temperature, formula is utilizedPower saving factor Δ T is calculated, P is target energy conservation value in formula, and T' is multi-gang air-conditioner In a upper energy-conservation cycle corresponding to the energy saving in running cycle, i is positive integer（i=1、2、3…T'）；Drawn power saving factor Δ T, when with Default running temperature T in the default operational factor of family setting_soWith current environmental temperature T_ecThe temperature difference absolute value be more than energy-conservation During factor Δ T, i.e., | T_ec-T_so| ＞ Δ T, when preset running mode is heating mode in default operational factor, the section that is optimized Can operational factor T_sn=T_so- Δ T, when preset running mode is refrigeration mode in default operational factor, the energy-conservation fortune that is optimized Row parameter T_sn=T_so+ΔT；Default running temperature T in the default operational factor of user's setting_soWith current environmental temperature T_ec's The absolute value of the temperature difference is less than or equal to power saving factor Δ T, i.e., | T_ec-T_so|≤Δ T, obtained energy-saving run parameter T_snSet for user Fixed default operational factor T_so。

When multi-gang air-conditioner just brings into operation, if multi-gang air-conditioner preset running mode is heating mode, work as front ring Border temperature T_ecTypically all than relatively low, default running temperature T_soIt is higher than that current environmental temperature is a lot, i.e., its poor absolute value is general Power saving factor Δ T is greater than, the first energy-conservation operational factor for now obtaining multi-gang air-conditioner is T_sn1=T_so- Δ T, multi-connected machine are empty Adjust according to the first energy-conservation operational factor T now_sn1Operation, the energy is saved than being run according to default operational factor, reduce energy wave Take, according to the gap periods T of setting_o, per interval cycle T_oWhen, and default operational factor and current environmental temperature T_ecTemperature Poor absolute value just carries out once predetermined algorithm computing, draws the second new energy-saving run parameter still greater than power saving factor Δ T T_sn2, now T_sn2Still it is T_sn2=T_so- Δ T, if when certain reaches gap periods, judge default operational factor and current environment temperature The temperature difference absolute value of degree is less than or equal to power saving factor, then the second operational factor T obtained using above-mentioned algorithm_sn2=T_so, in repetition Step is stated, until energy-conservation cycle T terminates.If multi-gang air-conditioner preset running mode is refrigeration mode, its run with it is above-mentioned It is similar, the difference is that the second energy-saving run parameter T drawn_sn2=T_so+ Δ T, when reaching gap periods at certain, judge current The temperature difference absolute value of environment temperature and default operational factor is less than or equal to power saving factor, then carries out the second operation ginseng that computing obtains Number T_sn2=T_so, other similar steps, here is omitted.

As a kind of embodiment, the default operational factor includes default running temperature T_so, preset running mode and/ Or energy-conservation cycle T；

The unit of the energy-conservation cycle T is day, and the target energy conservation value P is as a percentage；

The gap periods T_oUnit be hour or minute, the gap periods T_oFor program fixation set in advance Value sets acquisition by user.

This embodiment is that the parameter being applied in above-mentioned centralized Control method is further elaborated, people convenient to carry out It is more clearly understood that, is not intended to limit the present invention.

Embodiment two

Based on same inventive concept, present invention also offers a kind of multi-gang air-conditioner Centralized Controller, due to this concentration control The principle that device processed solves problem is similar to a kind of foregoing multi-gang air-conditioner centralized Control method, therefore the implementation of the Centralized Controller The implementation of preceding method is may refer to, part is repeated and repeats no more.

Multi-gang air-conditioner Centralized Controller provided in an embodiment of the present invention, it is shown in Figure 5, including the He of setting module 120 Data processing module 130, wherein：

The setting module 120, for carrying out saving cycle and target section to an at least indoor set for multi-gang air-conditioner The setting that can be worth；

The data processing module 130, for the target energy conservation value according to setting, the operational factor of storage and user set Fixed default operational factor, computing is carried out within the energy-conservation cycle, draw the energy-saving run parameter after optimization, control multi-gang air-conditioner Run by the energy-saving run parameter after optimization.

Centralized Controller 100 is the human-computer interaction interface of multi-gang air-conditioner, including at least user interface and display circle There are mechanical key board, touch key-press or touch-screen in face, wherein user interface, are easy to number of the user to multi-gang air-conditioner It is configured according to parameter；Display interface is generally LCDs, for showing the work of indoor set list and multi-gang air-conditioner Operational factor.

As a kind of embodiment, the data processing module 130 includes first processing units 131 and second processing list Member 132；

The first processing units 131, for obtain user setting default operational factor in default running temperature and The operational factor of database purchase, computing is carried out, draw the first energy-conservation operational factor T after optimization_sn1, send control signal control Multi-gang air-conditioner processed is by the first energy-conservation operational factor T after optimization_sn1Operation；

The second processing unit 132, during gap periods for reaching setting when multi-gang air-conditioner run time, carry out Computing, draw the second energy-saving run parameter T after optimization_sn2, send control signal and control multi-gang air-conditioner by second after optimization Energy-saving run parameter T_sn2Operation.

As a kind of embodiment, the Centralized Controller 100 includes database storage module 110；

The database storage module 110, join for the operation to the indoor set of multi-gang air-conditioner in the history energy-conservation cycle Number is stored；

Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history section Can the cycle；The unit in history energy-conservation cycle is day.

As a kind of embodiment, the Centralized Controller 100 also includes algoritic module 140；

The algoritic module 140 includes acquiring unit 141, reads computing unit 142, power saving factor unit 143 and draws Energy-saving run parameters unit 144, wherein：

The acquiring unit 141, for obtained from the operational factor of storage corresponding upper one save cycle T ' and target Energy conservation value P；

The reading computing unit 142, the indoor set of the multi-gang air-conditioner for reading upper energy-conservation cycle memory storage User's design temperature T_sAnd real time environment temperature T_e, and calculate the average value T of daily user's design temperature_saWith daily real-time ring The average value T of border temperature_ea；

The power saving factor unit 143, is used for and according to formulaCalculate one Save the power saving factor Δ T in cycle；

It is described to draw energy-saving run parameters unit 144, the default fortune in default operational factor for judging user's setting Trip temperature T_snWith current environmental temperature T_ecThe temperature difference absolute value whether in power saving factor Δ T；

If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, the energy-saving run ginseng after optimization is drawn Number is the default operational factor of user's setting and power saving factor Δ T difference, if the preset running mode of multi-gang air-conditioner is system During chill formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.

As a kind of embodiment, the default operational factor includes default running temperature T_so, preset running mode and/ Or energy-conservation cycle T；

The unit of the energy-conservation cycle T is day, and the target energy conservation value P is as a percentage；

The gap periods T_oUnit be hour or minute, the gap periods T_oFor program fixation set in advance Value sets acquisition by user.

Embodiment described above only expresses the several embodiments of the present invention, and its description is more specific and detailed, but simultaneously Therefore the limitation to the scope of the claims of the present invention can not be interpreted as.It should be pointed out that for one of ordinary skill in the art For, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to the guarantor of the present invention Protect scope.Therefore, the protection domain of patent of the present invention should be determined by the appended claims.

Claims (10)

1. A kind of 1. multi-gang air-conditioner centralized Control method, it is characterised in that comprise the following steps：

   Save the setting of cycle and target energy conservation value to an at least indoor set for multi-gang air-conditioner；

   According to the target energy conservation value of setting, the default operational factor of the operational factor of storage and user's setting, in the energy-conservation cycle Interior carry out difference operation, draw the energy-saving run parameter after optimization；

   Control multi-gang air-conditioner is run by the energy-saving run parameter after optimization.
2. 2. multi-gang air-conditioner centralized Control method according to claim 1, it is characterised in that transported within the energy-conservation cycle To calculate, draw the energy-saving run parameter after optimization, control multi-gang air-conditioner is run by the energy-saving run parameter after optimization, including Following steps：

   The operational factor of the default running temperature and database purchase in the default operational factor of user's setting is obtained, is transported Calculate, draw the first energy-conservation operational factor after optimization, send control signal control multi-gang air-conditioner by the first energy-conservation after optimization Operational factor is run；

   When multi-gang air-conditioner run time reaches the gap periods of setting, computing is carried out, draws the second energy-conservation fortune after optimization Row parameter, send control signal control multi-gang air-conditioner and run by the second energy-saving run parameter after optimization, the gap periods Less than the energy-conservation cycle.
3. 3. multi-gang air-conditioner centralized Control method according to claim 1, it is characterised in that described to multi-gang air-conditioner An at least indoor set save the setting of cycle and target energy conservation value before, also comprise the following steps：

   The operational factor of the indoor set of multi-gang air-conditioner in the history energy-conservation cycle is stored；

   Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history energy-conservation week Phase；The unit in history energy-conservation cycle is day.
4. 4. multi-gang air-conditioner centralized Control method according to claim 2, it is characterised in that the carry out computing, including Following steps：

   A corresponding upper energy-conservation cycle and target energy conservation value were obtained from the operational factor of storage；

   Read the user's design temperature and real time environment temperature of the indoor set of the multi-gang air-conditioner of upper energy-conservation cycle memory storage；

   Calculate the average value T of daily user's design temperature_saWith the average value T of daily real time environment temperature_ea；

   According to formulaPower saving factor the Δ T, wherein P for calculating an energy-conservation cycle are institute Target energy conservation value is stated, T' was upper one energy-conservation cycle；

   Judging the absolute value of the temperature difference of the default running temperature and current environmental temperature in the default operational factor of user's setting is It is no in power saving factor Δ T；

   If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

   Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, show that the energy-saving run parameter after optimization is The default operational factor and power saving factor Δ T difference of user's setting, if the preset running mode of multi-gang air-conditioner is refrigeration mould During formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.
5. 5. the multi-gang air-conditioner centralized Control method according to claim 2 or 4, it is characterised in that the default operation ginseng Number includes default running temperature, preset running mode and/or energy-conservation cycle；

   The unit in the energy-conservation cycle is day, and the target energy conservation value is as a percentage；

   The unit of the gap periods is hour or minute, and the gap periods are program fixed value set in advance or led to Cross user and set acquisition.
6. A kind of 6. multi-gang air-conditioner Centralized Controller, it is characterised in that including setting module and data processing module, wherein：

   The setting module, for carrying out saving setting for cycle and target energy conservation value to an at least indoor set for multi-gang air-conditioner It is fixed；

   The data processing module, for the target energy conservation value according to setting, the operational factor of storage and user setting it is pre- If operational factor, difference operation is carried out within the energy-conservation cycle, draws the energy-saving run parameter after optimization, control multi-gang air-conditioner is pressed Energy-saving run parameter after optimization is run.
7. 7. multi-gang air-conditioner Centralized Controller according to claim 6, it is characterised in that the data processing module includes First processing units and second processing unit；

   The first processing units, default running temperature and the data stock in default operational factor for obtaining user's setting The operational factor of storage, computing is carried out, draw the first energy-conservation operational factor after optimization, send control signal control multi-gang air-conditioner By the first energy-conservation operational factor operation after optimization；

   The second processing unit, during gap periods for reaching setting when multi-gang air-conditioner run time, computing is carried out, is obtained The the second energy-saving run parameter gone out after optimization, send control signal control multi-gang air-conditioner and join by the second energy-saving run after optimization Number operation, the gap periods are less than the energy-conservation cycle.
8. 8. multi-gang air-conditioner Centralized Controller according to claim 6, it is characterised in that the Centralized Controller includes number According to library storage module；

   The database storage module, for being deposited to the operational factor of the indoor set of multi-gang air-conditioner in the history energy-conservation cycle Storage；

   Operational factor in the history energy-conservation cycle includes user's design temperature, real time environment temperature and/or history energy-conservation week Phase；The unit in history energy-conservation cycle is day.
9. 9. multi-gang air-conditioner Centralized Controller according to claim 7, it is characterised in that the Centralized Controller also includes Algoritic module；

   The algoritic module includes acquiring unit, reads computing unit, power saving factor unit and draws energy-saving run parameters unit, Wherein：

   The acquiring unit, for obtaining a corresponding upper energy-conservation cycle and target energy conservation value from the operational factor of storage；

   The reading computing unit, user's setting of the indoor set of the multi-gang air-conditioner for reading upper energy-conservation cycle memory storage Temperature and real time environment temperature, and calculate the average value T of daily user's design temperature_saWith being averaged for daily real time environment temperature Value T_ea；

   The power saving factor unit, is used for and according to formulaCalculate an energy-conservation cycle Power saving factor Δ T, wherein P be the target energy conservation value, T' was upper one energy-conservation cycle；

   It is described to draw energy-saving run parameters unit, for judge user setting default operational factor in default running temperature and Whether the absolute value of the temperature difference of current environmental temperature is in power saving factor Δ T；

   If so, then draw the default operational factor that the energy-saving run parameter after optimization is user's setting；

   Otherwise, if the preset running mode of multi-gang air-conditioner is heating mode, show that the energy-saving run parameter after optimization is The default operational factor and power saving factor Δ T difference of user's setting, if the preset running mode of multi-gang air-conditioner is refrigeration mould During formula, draw the energy-saving run parameter after optimization for user's setting default operational factor and power saving factor Δ T's and.
10. 10. the multi-gang air-conditioner Centralized Controller according to claim 7 or 9, it is characterised in that the default operational factor Including presetting running temperature, preset running mode and/or energy-conservation cycle；

    The unit in the energy-conservation cycle is day, and the target energy conservation value is as a percentage；

    The unit of the gap periods is hour or minute, and the gap periods are program fixed value set in advance or led to Cross user and set acquisition.