JP3879483B2 - Air conditioner control system and control method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air conditioner control system that performs an emergency apportionment calculation in a situation where normal apportionment is not possible when apportioning the amount of power used to charge the power charge for the air conditioner.
[0002]
[Prior art]
As an air conditioner control system provided with a power billing system for an air conditioner (hereinafter referred to as an air conditioner), for example, there are those disclosed in Japanese Patent Laid-Open Nos. 5-157336 and 5-196640.
[0003]
In Japanese Patent Application Laid-Open No. 5-157336, in order to calculate the air conditioning charges of a plurality of indoor units fairly according to the capacity of the indoor units, each indoor unit is calculated based on the opening and operation time of the electronic expansion valve of the indoor unit. The calculated capacity is calculated, and the air conditioning charges for the entire air conditioner are apportioned according to this capacity.
[0004]
FIG. 19 shows an electric power apportioning device disclosed in Japanese Patent Laid-Open No. 5-196640. The power apportioning apparatus in this figure includes a base load setting device 102 that sets a minimum amount of power that maintains the function of the air conditioner 101 at a minimum, an operation time detector 103 that detects the operation time of the air conditioner 101, and each air conditioner. An air conditioning capability setting unit 104 that presets the capability of 101, and a total electric energy proportionately determined by the ratio of the total operation time detected by the operation time detector 103 and the operation time of one air conditioner 101. Add the result of apportioning the minimum power amount by the ratio of the set total capacity of the air conditioner 101 and the capacity of one air conditioner 101 to the power consumption per operating time of each air conditioner 101. And a CPU 105 that calculates the power consumption of the air conditioner 101 for a certain period.
[0005]
As a result, information on the operation time and the capacity of the indoor units and outdoor units required for charging apportionment is collected, and the data of the air conditioning capacity setting unit 104 is used from the power consumption of the watt-hour meter (WHM) 106. Air conditioning charges for air conditioners are apportioned.
[0006]
[Problems to be solved by the invention]
Such a power charge system for an air conditioner corrects the air-conditioning charge without being able to apply the result of the air-conditioning charge based on the normal apportionment calculation when the air-conditioning operation data and the integrated data of the WHM 106 cannot be monitored normally. However, there is a problem that a great deal of labor and time are required.
[0007]
The present invention has been made to solve such a problem, and it is an object of the present invention to be able to quickly estimate an apportioned amount of power used for air conditioning when normal monitoring cannot be performed.
[0008]
[Means for Solving the Problems]
Multiple air conditioners,
A communication means for receiving operation information from a plurality of air conditioners;
A watt hour meter that measures the amount of power used by multiple air conditioners;
A monitoring means for monitoring the electric energy;
First power amount determination means for determining whether or not the power amount monitored by the monitoring means is within a predetermined range;
If the electric energy is within the range, the apportioning means for apportioning the electric energy based on the operation information to obtain the apportioned electric energy,
Storage means for storing apportioned electric energy and operation information;
If the electric energy is not within the range, the apportioned electric energy is estimated from the ratio of the operation information from the time of apportionment by the apportioning means to the current time and the operation information stored in the storage means and the apportioned electric energy stored in the storage means. Emergency apportioning means.
[0009]
In addition, if the power amount is not within the range, the monitoring unit repeats monitoring, and has a second power amount determination unit that determines whether the power amount is within a predetermined range,
If the power amount is within the range, the emergency apportioning means stores the ratio of the driving information from the time determined by the first power amount determining means to the current time and the driving information stored in the storage means and the storage means. The apportioned electric energy is estimated from the apportioned electric energy.
[0010]
Further, if the power amount is within the range, the processing interval is obtained from the time when the power amount is processed by the watt hour meter and the time when the power amount stored in the storage means is processed by the watt hour meter. If it is not within the predetermined range, it is stored in the storage means.
[0011]
Multiple air conditioners,
A communication means for receiving operation information from a plurality of air conditioners;
A watt hour meter that measures the amount of power used by multiple air conditioners;
A monitoring means for monitoring the electric energy;
First driving information determination means for determining whether the driving information monitored by the communication means is within a predetermined range;
If the operation information is within the range, the apportioning means for apportioning the electric energy based on the operation information to obtain the apportioned electric energy,
Storage means for storing apportioned electric energy and electric energy;
If the operation information is not within the range, the apportioned electric energy is estimated from the ratio of the electric energy from the time of apportionment by the apportioning means to the current time and the electric energy stored in the storage means and the apportioned electric energy stored in the storage means. Emergency apportioning means.
[0012]
In addition, if the driving information is not within the range, the monitoring means repeats monitoring, and has second driving information determination means for determining whether the driving information is within a predetermined range,
If the driving information is within the range, the emergency apportioning means is stored in the storage means and the ratio of the amount of power from the time determined by the first driving information determination means to the current time and the power amount stored in the storage means The apportioned electric energy is estimated from the apportioned electric energy.
[0013]
Further, if the driving information is within the range, a processing interval is obtained from the time when the driving information is processed by the communication means and the time when the driving information stored in the storage means is processed by the communication means, and the processing interval is determined in advance. If it is not within the specified range, it is stored in the storage means.
[0014]
A first step of monitoring the amount of power and determining whether the amount of power is within a predetermined range;
If the electric energy is within the range, the electric energy is apportioned based on the operation information to obtain the apportioned electric energy,
A second step of storing apportioned electric energy and operation information;
If the electric energy is not within the range, the apportioned electric energy is calculated from the ratio of the operation information from the time of apportionment by the apportioning means to the present time and the operation information stored in the storage means and the apportioned electric energy stored in the storage means. A third step of estimating.
[0015]
In addition, if the power amount is not within the range in the first step, the monitoring is repeated, and a fourth step is performed to determine whether the power amount is within a predetermined range,
If the electric energy is within the range, in the third step, the apportioned electric power is calculated from the ratio of the operation information from the determined time to the present time and the operation information stored in the storage means and the apportioned electric energy stored in the storage means. Having to estimate the quantity.
[0016]
Further, if the power amount is within the range in the first step, the processing interval from the time when the power amount is processed by the watt hour meter and the time when the power amount stored in the storage means is processed by the watt hour meter. A fifth step to find
And a sixth step of storing in the storage means if the processing interval is not within a predetermined range.
[0017]
A first step of monitoring driving information and determining whether the driving information is within a predetermined range;
If the operation information is within the range, a second step of apportioning the electric energy based on the operation information to obtain an apportioned electric energy and storing the apportioned electric energy and the electric energy;
If the operation information is not within the range, the apportioned electric energy is calculated from the ratio of the electric energy from the time of apportionment by the apportioning means to the present time and the apportioned electric energy stored in the storage means and the ratio of the electric energy stored in the storage means. A third step of estimating.
[0018]
In addition, if the driving information is not within the range in the first step, the monitoring step is repeated to determine whether the driving information is within a predetermined range,
If the operation information is within the range, in the third step, the apportioned electric power is calculated from the ratio of the electric energy from the determined time to the present time and the electric energy stored in the storage means and the apportioned electric energy stored in the storage means. Estimate the amount.
[0019]
Further, if the driving information is within the range in the first step, the processing interval is obtained from the time when the driving information is processed by the communication means and the time when the driving information stored in the storage means is processed by the communication means. The fifth step,
And a sixth step of storing in the storage means if the processing interval is not within a predetermined range.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
FIG. 1 is a configuration diagram of an air conditioner control system according to Embodiment 1 of the present invention. The air conditioner control system 1 consumes power and a power charge billing unit 2 that calculates a charge according to the amount of power. An air conditioner (air conditioner main body) 5 having the outdoor unit 3 and the indoor unit 4 and a watt-hour meter (WHM) 6 for measuring power consumption of the air conditioner main body 5 are provided.
[0021]
The electric power billing means 2 among them is the microcomputer 7 that controls the entire electric power billing means 2 and the operation status of each air conditioner in order to calculate the air conditioning charge from the air conditioner body 5 according to the command from the microcomputer 7. The communication means 8 for acquiring the operation information (described later) and the function as a monitoring means for monitoring the amount of power that is an integrated value of the power consumption of the air conditioner body 5 taken into the watt hour meter 6 An input means 9 for inputting operation settings of the air conditioner, and an output means 10 for outputting the result of inputting information such as the number of indoor units 4 required for charging, individual capacity data, and system configuration to the input means 9; The above-mentioned operation information, the operation capacity information indicating the air conditioning capacity and the amount of power consumption during the operation of the air conditioner main body 5, and the electric energy measured by the watt hour meter 6 are stored in the database 11 as storage means. A database input / output unit 12 for storing and reading, a distribution unit 13 for obtaining an apportioned electric energy from the operation information and the electric energy using the driving capability information read from the database 11 through the database input / output unit 12, and each In addition to the basic configuration such as the transmission line 14 for connecting the devices, the first power amount determination means 15 for determining whether or not the value of the power amount monitored by the input means 9 is normal, and the normal apportionment And emergency apportioning means 16 for apportioning instead.
[0022]
In the air conditioner control system 1 having such a configuration, an operation command is input from the input means 9 to the air conditioner main body 5, the individual air conditioners are operated, operation information of these air conditioners, and consumption of the air conditioner main body 5. Result of inputting information such as the electric energy of the watt hour meter 6 that is an integrated value of the consumed electric energy, the number of indoor units 4 that is a predetermined fixed value, individual capacity data, system configuration, etc. The distribution is calculated by the distribution means 13 from the information, and the distribution result is displayed on the output means 10 and stored in the database 11 via the database input / output means 12.
[0023]
There are several possible methods for apportioning air conditioning charges using such apportioning means. First, when the power consumption of the air conditioner is classified, it is divided into an outdoor unit 3 and an indoor unit 4. Of these, the amount of power used by the outdoor unit 3 is the amount of power used for the refrigerant, in other words, the amount of power consumed by the compressor and the fan. On the other hand, the amount of power used by the indoor unit 4 is the amount of power consumed by the operation of the blower FAN.
[0024]
The method of apportioning the amount of power used by the outdoor unit 3 of the air conditioner is as follows: (1) operating time x indoor functional force, (2) thermo-ON time x indoor functional force, and (3) integrated operating capacity x indoor functional force. , (4) Refrigerant amount integrated value x Indoor functional force, (5) Area ratio (method of always allocating power consumption at a fixed ratio), (6) Crankcase for preventing compressor from freezing while outdoor unit is stopped There may be a method in which the heater is turned on, the amount of power used is handled separately, and the amount of power is distributed to the indoor units using parameters.
[0025]
On the other hand, the method of apportioning the amount of electric power used by the indoor unit 4 may be (1) FAN operation time × FAN capacity, and (2) FAN operation capacity integrated value × FAN capacity. However, since the power consumption of FAN in the entire air conditioner is low, it is possible to ignore the power consumption of (3) FAN.
[0026]
Accordingly, the apportioned electric energy of a certain air conditioner is apportioned electric energy of the air conditioner = apportioned electric energy of the outdoor unit used electric energy + apportioned electric energy of the indoor unit used electric energy.
[0027]
Here, assuming that the apportionment unit is one day, the power consumption of the outdoor unit 3 and the indoor unit 4 is the apportioned power amount of the air conditioner = the used power amount of the WHM × the parameter of the indoor unit / WHM of all the indoor units connected to the indoor unit. Parameter total.
[0028]
For example, if the calculation of the amount of power used by the outdoor unit 3 is calculated according to (3) above,
Apportioned electric energy of the air conditioner = daily power consumption (outdoor unit only) x (operating capacity integrated value x indoor functional force) of a certain indoor unit / total (operating capacity integrated value x indoor functional force) of all indoor units It is expressed by the formula.
[0029]
This will be specifically described in association with each control means actually. The input means 9 inputs the capacity Qi of the indoor unit, the capacity Pfi of the indoor unit FAN, the capacity Pwi of the crankcase heater of the outdoor unit, and related information of the watt hour meter (information about the watt hour meter, the outdoor unit, and the indoor unit). Control means for monitoring the integrated value of the watt-hour meter, operating the indoor unit, and the like.
[0030]
Further, the apportioning means 13 includes information obtained from the outdoor unit 3 and the indoor unit 4 and the amount of electric power (integrated electric energy (on the day) Wi2 of the watt hour meter, operating capacity integrated time (on the day) Coi2 of the indoor unit 4, indoor unit 4 FAN operation integrated time (current day) Cii2, outdoor unit 3 crankcase heater operation integrated time (current day) Cci2), and the driving power information read from the database 11 and the integrated electric energy of the watt-hour meter 6 which is operating information (the previous day) ) Based on Wi1, the accumulated operating capacity of the indoor unit 4 (previous day) Coi1, the integrated FAN operating time of the indoor unit 4 (previous day) Cii1, and the accumulated crankcase heater operation time of the outdoor unit 3 (previous day) Cci1 The total power consumption Qi of the indoor unit 3 is apportioned according to each parameter.
[0031]
FIG. 2 is a flowchart showing a processing procedure for apportioning such air conditioning charges. When this flowchart is started, the watt hour meter integrated power amount Wi2 and the watt hour meter integrated power amount value Wi1 of the previous day are read from the database 11 (to be exact, the time at which the processing of the day is started).
Wti = Wi2-Wi1
The daily power amount Wti of the watt hour meter 6 is calculated from the subtraction formula (S201).
[0032]
Next, the crankcase heater operation integrated time Cci2 of the outdoor unit on the current day and the crankcase heater operation integrated time Cci1 of the outdoor unit on the previous day are read from the database 11,
Cci = Cci2-Cci1
The crankcase heater operating time Cci of the outdoor unit 3 for one day is calculated from the subtraction formula, and the crankcase heater capacity Pwi of the outdoor unit 3 is read from the database 11,
WSi = Pwi × Cci
From the multiplication formula, the amount of electric power used while the outdoor unit 3 is stopped (daily crankcase heater operating electric energy) WSi is calculated (S202).
[0033]
Next, the operation capacity integration time (current day) Coi2, the operation capacity integration time (previous day) Coi1, the FAN operation integration time (current day) Cii2, and the FAN operation integration time (previous day) Cii1 of the indoor unit 4 are read from the database 11.
Coi = Coi2-Coi1
Cii = Cii2-Cii1
From the subtraction formula, the daily operation capacity time Coi and the daily FAN operation time Cii of the indoor unit are calculated (S203).
[0034]
Next, it is determined based on information from the database 11 whether or not the watt-hour meter 6 is connected only to the outdoor unit 3 (S204). When connected to the outdoor unit 3, the sum of the used electric energy WSi during the outdoor unit stop of all the outdoor units 3 connected to the watt hour meter 6 and the daily electric energy Wti of the watt hour meter Compare and
Wti> ΣWSi
That is, whether the daily energy amount Wti of the watt-hour meter is greater than the total of the used power amount WSi during the outdoor unit stop of all the outdoor units 3 connected to the watt-hour meter 6 It is determined whether it is larger (S205).
[0035]
When the daily power amount Wti of the watt hour meter is larger, the power amount obtained by subtracting the total of the used power amount WSi while the outdoor unit is stopped from the daily power amount Wti of the watt hour meter and the indoor unit 1 Combined with the outdoor unit 3 connected to the watt hour meter 6 based on the daily driving capacity time Coi and the indoor unit capacity Pi, the power consumption of the outdoor unit for one day for each indoor unit constituting the air conditioner The quantity Qoi,
Qoi = (Wti−ΣWSi) · Coi · Pi / (ΣCoi · Pi) + WSi · Pi / (ΣPi)
The distribution is calculated by the following formula (S206).
[0036]
On the other hand, if the daily power amount Wti of the watt-hour meter is smaller in S205, the usage of each indoor unit connected to the outdoor unit is determined from the used power amount WSi while the outdoor unit is stopped and the capacity Pi of the indoor unit. Electricity amount Qoi
Qoi = WSi · Pi / (ΣPi)
The apportionment is calculated by the following formula (S207).
[0037]
When the power meter 6 is not connected to the outdoor unit 3 in S204, that is, when it is connected only to the indoor unit 4, the daily power amount Wti of the watt hour meter and the daily FAN operation time Cii. And the indoor unit power consumption Qii of each indoor unit connected to the watt hour meter from the FAN capacity Pfi of the indoor unit
Qii = Wti · Cii · Pfi / (ΣCii · Pfi)
The apportionment calculation is performed by the following formula (S208).
[0038]
Next, it is determined whether or not the apportioning calculation of Qoi or Qii has been completed for all the electric energy meters 6 by these processes (S209). If apportioning is calculated, apportioning is calculated in S206 or S207. Using the calculated Qoi and the Qii apportioned in S208, the daily power consumption of each indoor unit is calculated.
Qi = Qoi + Qii
(S210) and finishes.
[0039]
On the other hand, in S209, when it is not that the power consumption of all the watt-hour meters 6 is apportioned, the processing after S204 is repeated until the power consumption of all the watt-hour meters 6 is apportioned.
[0040]
In this embodiment, a normal apportioning process is performed by such a process.
[0041]
The above-described operation information is a general term for the operation capacity integration time of the indoor unit 4, the FAN operation integration time of the indoor unit 4, and the crankcase heater operation integration time of the outdoor unit 3.
[0042]
FIG. 3 shows a method in such an air conditioner control system 1 when a trouble occurs during the monitoring of the electric energy, and whether or not the monitored data is normal, and if it is not normal, the method of urgently apportioning. It is a flowchart to show.
[0043]
In this flowchart, when the process is started, in order to grasp the amount of power used for the apportionment calculation of the air-conditioning charge, the power amount of the watt hour meter 6 by the input means 9 is monitored in accordance with the monitor timing (S1). Next, in the first power amount determination means 15, it is determined whether or not the power amount is normal with respect to a predetermined power amount determination condition (S2). If it is determined to be normal, the power amount and the operation information and operation capability information of the air conditioner main body 5 stored in the database 11 are used for proportional distribution calculation (S3), and the distribution result is input / output to the database. It memorize | stores in the database 11 via the means 12 (S4), and complete | finishes.
[0044]
It should be noted that the electric energy determination condition is whether the electric energy meter 6 reads the electric energy consumed by the air conditioner body 5, and the value monitored by the input means 9 from the electric energy meter 6 is based on the operation information. This is based on the condition that it does not deviate from the predetermined first range.
[0045]
On the other hand, if it is determined in S2 that it is not normal, the ratio is calculated based on the previous day's operation information and the apportioned result, and the apportioned electric energy is calculated by the emergency apportioning means 16 from the current day's operation information (S5). The emergency apportioning result is stored in the database 11 via the database input / output means 12 (S6), and the process ends.
[0046]
At this time, the emergency apportioning calculation is
Apportioned electric energy for the current day = Operation information (for the day) / Operating information (for the previous day) x Apportioned electric energy (for the previous day)
It shall be performed by the formula.
[0047]
In this way, if a problem occurs during power monitoring, the data for the previous day can be used to calculate the air conditioning charges as soon as possible, which saves time and effort compared to manual calculation. Can be reduced.
[0048]
Further, in this embodiment, the configuration in which the watt-hour meter 6 monitors the power amount integrated value of the air conditioner body 5 is described. However, even if a pulse-type watt-hour meter is used, the pulse integrated value Thus, it is possible to identify the occurrence of a trouble and perform such an emergency apportionment calculation process.
[0049]
Furthermore, in this embodiment, the previous day's data is used as the data stored in the database 11 and used for the emergency apportionment calculation. However, the data on the day when the data can be normally monitored, the average data for the past week, the past It may be replaced with the average data for one month, the average data for the current month of the previous year, or the like, and the method of emergency apportionment calculation by the emergency apportioning means 16 may be used.
[0050]
Embodiment 2. FIG.
FIG. 4 is a configuration diagram of an air conditioner control system according to Embodiment 2 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1, the same number is attached | subjected and functional description is abbreviate | omitted.
[0051]
In FIG. 4, in addition to the basic configuration as described in the first embodiment, the power charge billing unit 2 determines whether the power value monitored by the input unit 9 is normal. Power apportioning means 15, emergency apportioning means 16 that apportions instead when normal apportioning is not possible, apportioning dividing unit 17 that corrects the apportioning result calculated by the emergency apportioning device 16 in apportionment units, and input unit 9 And a second power amount judging means 18 for judging whether or not the value of the power amount monitored by is normal.
[0052]
FIG. 5 shows whether in the air conditioner control system 1 having such a power billing means 2, when trouble occurs during power amount monitoring, whether or not the monitored data is normal, and if it is not normal, an emergency is given. It is a flowchart which shows the method of dividing proportionally in a proportional unit.
[0053]
In this flowchart, when the process is started, in order to grasp the amount of power used for the apportionment calculation of the air-conditioning charge, the power amount of the watt hour meter 6 by the input means 9 is monitored in accordance with the monitor timing (S11). Next, the first power amount determination means 15 determines whether or not the power amount is within a first range that is recognized as normal with respect to a predetermined reference power amount (S12). If it is determined to be normal, the power amount and the operation information and operation capacity information of the air conditioner main body 5 stored in the database 11 are used for proportional distribution calculation (S13), and the distribution result is input / output to the database. It memorize | stores in the database 11 via the means 12 (S14), and complete | finishes.
[0054]
On the other hand, if it is determined in S12 that it is not normal, it is considered that some failure has occurred. If this is the case, the restoration work is naturally performed, but in order to detect the completion of the restoration work, monitoring of the watt hour meter 6 by the input means 9 is performed at the next monitoring timing (S15), In the second power amount determination means 18, it is determined whether or not the power amount is within a second range that is recognized as normal with respect to a predetermined reference power amount (S16). As a result, if it is outside the range that can be regarded as normal, it is determined that the failure has not been recovered, and the process returns to S15 and monitoring is performed again.
[0055]
In addition, the process which judges that it has not recovered | restored and repeats the process of S15 again designates the frequency | count of monitoring in the 2nd electric energy determination means 18 previously.
Further, the first range predetermined for the first power amount determination means 15 and the second range predetermined for the second power amount determination means 18 can be set to the same range. It is also possible to set different ranges.
[0056]
On the other hand, if it is determined in S16 that the electric energy is within the range that can be regarded as normal and that it has been recovered from the failure, the monitoring failure of the electric energy meter 6 based on the electric energy of the electric energy meter 6 and the operation information of the air conditioner body 5 The apportioning calculation is performed by the emergency apportioning means 16 with the period as an apportioning unit (S17), and the calculated apportioning result is calculated by the apportioning dividing unit 17 so as to be divided into normal apportioning units (for example, one day unit) (S18). The apportioning result of the monitoring failure period of the watt-hour meter 6 is stored in the database 11 via the database input / output means 12 (S19), and the process ends.
[0057]
At this time, the emergency apportionment calculation of the monitoring failure period of the electricity meter 6 is
Apportioned electric energy for the required failure period = operation information (for the failure period) / operation information (for the normal operation period) x apportioned electric energy (for the normal operation period)
It shall be performed by the formula.
[0058]
In this way, if trouble occurs during power monitoring, the air conditioning charges during the failure period can be calculated on a prorated basis using data for the period of normal operation. This can save a lot of time and effort compared to manual calculation.
[0059]
Embodiment 3 FIG.
FIG. 6 is a configuration diagram of an air conditioner control system according to Embodiment 3 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1 and Embodiment 2, the same number is attached | subjected and description is abbreviate | omitted.
[0060]
In FIG. 6, in addition to the basic configuration as described in the first embodiment, the power charge billing unit 2 determines whether the power amount value monitored by the input unit 9 is normal. The power amount determination means 15, the emergency apportioning means 16 that apportions instead of when normal apportioning is not possible, the apportioning dividing means 17 that corrects the apportioning result calculated by the emergency apportioning means 16 into apportionment units, and the database 11. It has a power amount data comparison means 19 for comparing the stored power amount data with the power amount data monitored this time, and a failure period confirmation means 20 for checking whether or not a failure period is stored. .
[0061]
The input unit 9 has a function of inputting the amount of power during a period when trouble occurs and the amount of power is not monitored by the input unit 9 (hereinafter referred to as a failure period).
[0062]
FIGS. 7 and 8 show whether or not the monitored data is normal or the amount of electric power when the trouble occurs during the amount of electric power monitoring in the air conditioner control system 1 having such electric power billing means 2. It is a flowchart which shows whether it is normal compared with driving | running | working information, and the method of apportioning by the apportionment unit urgently when it is not normal.
[0063]
In the flowchart of FIG. 7, when the process is started, in order to grasp the amount of power used for the apportionment calculation of the air conditioning charge, the power amount of the watt hour meter 6 by the input means 9 is monitored in accordance with the monitor timing (S21). ). Next, the first power amount determination means 15 determines whether or not the power amount is within a range that is recognized as normal with respect to a predetermined amount of power (S22).
[0064]
When it is determined to be normal, the processing time in the watt hour meter 6 recorded in the current power amount data in the power amount data comparison means 19 and the latest power amount data stored in the database 11 Is compared with the processing time of the watt-hour meter 6 recorded in (1), and it is determined whether or not the interval matches (is normal) compared to a predetermined monitoring interval (S23). When it is determined that the power amount data comparison means 19 is normal, the power amount and the operation information and driving capability information of the air conditioner main body 5 stored in the database 11 are prorated and calculated (S24). The apportioned result is stored in the database 11 via the database input / output means 12 (S25), and the process ends.
[0065]
The amount of power used to apportion the air conditioning charges is the difference between the previously monitored integrated power amount and the currently monitored integrated power amount because the monitored power amount is an integrated value.
[0066]
On the other hand, if it is determined in S22 that the watt-hour meter 6 cannot be monitored, the watt-hour meter 6 in S21 is again monitored and the process is repeated.
[0067]
If it is determined in S23 that it is not normal because it does not match the predetermined monitoring interval, this period is regarded as a failure period of the watt hour meter 6 and stored in the database 11 via the database input / output means 12. (S26), the process ends.
[0068]
By doing so, in addition to knowing whether the monitored electric energy is normal and whether it has been recovered due to a failure, it is possible to store the period of the failure period.
[0069]
Next, FIG. 8 will be described. In this flowchart, when the process is started, it is determined whether or not correction of the used power apportioning value for the failure period has been selected by the input means 9 (S31). If selected, the failure period is stored in the database 11. The failure confirmation means 20 determines whether or not a failure period exists (S32), and if a failure period exists, the database input / output means 12 is used to read the power amount from the database 11 and use the power amount other than the failure period and the failure period. The calculation result is displayed on the output means 10 (S33). The amount of power used during the failure period with reference to the amount of power other than the failure period and the failure period and the amount of power charged is input to the input means 9 (S34), and the operation information of the air conditioner read from the database 11 and the failure period The apportioning means 16 calculates the apportionment of the air-conditioning charge using the apportioning unit (S35). Using the calculated apportioning result, the apportioning dividing unit 17 performs calculation so as to divide into normal apportioning units (for example, one day unit) (S36), and the failure period calculated using the database input / output unit 12 is calculated. The distribution result is stored in the database 11 (S37), and the process is terminated.
[0070]
Note that if correction is not selected in S31, the process ends. If the failure period is not stored in the database 11 in S32, the process also ends.
[0071]
In this way, in order to apportion the air conditioning charges, even if troubles such as replacement of electricity meters occur, the air conditioning charges can be calculated for each failure period or prorated unit of the failure period. Can save time and labor compared to manual calculation.
[0072]
In this embodiment, a configuration is described in which the amount of power in the failure period is calculated and input based on the amount of power in the billing fee, the failure period, and the amount of power outside the failure period. It is also possible to use a method in which the ratio of values that become apportionment factors outside the failure period and the failure period is displayed from the operation information, and the electric energy for the failure period is obtained and input.
[0073]
Embodiment 4 FIG.
FIG. 9 is a configuration diagram of an air conditioner control system according to Embodiment 4 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1 thru | or Embodiment 3, the same number is attached | subjected and description is abbreviate | omitted.
[0074]
In FIG. 9, in addition to the basic configuration described in the first embodiment, the power billing unit 2 determines whether or not the operation information received by the communication unit 8 from the air conditioner body 5 is normal. First operation information determination means 21 is included.
[0075]
FIG. 10 determines whether or not the operation information from the air conditioner body 5 is normal in the air conditioner control system 1 having such a power billing means 2 and divides it into a normal case and a non-normal case. 5 is a flowchart showing a method for performing processing.
[0076]
In the flowchart of FIG. 10, when the process is started, the operation information of the air conditioner body 5 used for the apportionment calculation of the air conditioning charges is monitored by the communication means 8 (S41), and the first operation information determination means 21 performs the communication means 8 Whether or not the driving information can be normally monitored is determined using the driving information determination condition (S42). When the driving information satisfies the driving information determination condition and is considered to be normal, the operating information stored in the database 11 such as driving information, driving capability information, and monitoring value of the watt hour meter is used. The distribution calculation is performed (S43), and the distribution result calculated using the database input / output means 12 is stored in the database 11 (S44).
[0077]
On the other hand, when the driving information does not satisfy the driving information determination condition in S42 and is regarded as not normal, the emergency apportioning means 16 calculates the ratio based on the driving information of the previous day and the apportioned electric energy data, The apportioned electric energy is calculated from the amount urgently (S45), the database input / output means 12 is used to store the calculated urgent apportioning result in the database 11 (S46), and the process ends.
[0078]
At this time, the emergency apportioning calculation is
Apportioned electric energy for the current day = Electric energy (for the day) / Electric energy (for the previous day) x Apportioned electric energy (for the previous day)
It shall be performed by the formula.
[0079]
The operation information determination condition is that the communication unit 8 can monitor the operation information of the air conditioner body 5, and the value monitored by the communication unit 8 deviates from a predetermined range based on the operation information. This is based on the condition of whether or not
[0080]
In this way, even when troubles such as monitoring of outdoor unit or indoor unit information) data occur in order to apportion the air conditioning charges, the air conditioning charges can be promptly used using the previous day's data. Apportionment can be calculated, and labor and time can be greatly reduced compared to manual calculation.
[0081]
Moreover, in this embodiment, the data used for emergency apportionment calculation is the previous day's data, but the data of the day when normal monitoring was possible, the average data for the past week, the average data for the past month, It is also possible to use a method in which the apportioning means 16 performs an emergency apportionment calculation using average data or the like.
[0082]
Embodiment 5 FIG.
FIG. 11 is a configuration diagram of an air conditioner control system according to Embodiment 5 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1 thru | or Embodiment 4, the same number is attached | subjected and description is abbreviate | omitted.
[0083]
In FIG. 11, in addition to the basic configuration as described in the first embodiment, the power rate billing unit 2 determines whether or not the value of the operation information monitored by the communication unit 8 is normal. Driving information determining means 21, emergency apportioning means 16 that apportions instead when normal apportioning is not possible, and apportionment results calculated by the emergency apportioning means 16 are divided and corrected into apportionment units, for example, with one day as one unit. The distribution division means 17 and the second driving information determination means 22 for determining whether or not the value of the driving information monitored by the communication means 8 is normal are included.
[0084]
FIG. 12 shows whether in the air conditioner control system 1 having such a power billing means 2, when trouble occurs during monitoring of operation information, whether or not the monitored data is normal, and if it is not normal, an emergency is given. It is a flowchart which shows the method of dividing proportionally in a proportional unit.
[0085]
In this flowchart, when the process is started, the operation information of the air conditioner body 5 is monitored by the communication means 8 in order to grasp the operation information used for the apportionment calculation of the air conditioning charges (S51), and the first operation information determination means In step 21, it is determined whether or not the operation information can be normally monitored by the communication means 8 (S52). When the operation information can be monitored, the power consumption of the air conditioner body 5 is apportioned using data such as the operation information of the air conditioner body 5, the operation capacity information, and the monitoring value of the watt hour meter stored in the database 11. The calculation is performed (S53), and the distribution result calculated using the database input / output means 12 is stored in the database 11 (S54).
[0086]
On the other hand, if it is determined in S56 that it is not normal, it is considered that some failure has occurred. If this happens, the restoration work will naturally be performed, but in order to detect the completion of the restoration work, the monitoring of the air conditioner body 5 by the communication means 8 is performed in accordance with the next monitoring timing (S55). In the second driving information determination means 22, it is determined whether or not the driving information is within a range that is recognized as normal with respect to driving information that is a predetermined reference (S 56). As a result, if it is out of the range that can be regarded as normal, it is determined that the failure has not been recovered, and the process returns to S55 to perform monitoring again.
[0087]
In addition, the process which judges that it has not recovered | restored and repeats the process of S55 again designates the frequency | count of monitoring in the 2nd driving information determination means 22 previously.
[0088]
On the other hand, if it is determined in S56 that the operation information is within a range that can be regarded as normal and that the operation has been recovered from the failure, the emergency apportioning means is based on the monitoring failure period of the air conditioner body 5 based on the operation information of the air conditioner body 5 16 (S57), and the calculated apportioning result is calculated so as to be divided into normal apportioning units (for example, daily units) by the apportioning dividing unit 17 (S58). The apportioning result of the period is stored in the database 11 via the database input / output means 12 (S59), and the process ends.
[0089]
At this time, the emergency apportionment calculation of the monitoring failure period of the electricity meter 6 is
Apportioned electric energy for the required failure period = electric energy (for the failure period) / electric energy (for the normal operation period) x apportioned electric energy (for the normal operation period)
It shall be performed by the formula.
[0090]
In this way, in order to apportion the air conditioning charges, the air conditioning charges can be calculated for each normal apportionment unit even if the monitoring of the operation information of the air conditioner body 5 temporarily causes trouble. This can save a lot of time and effort compared to manual calculation.
[0091]
Embodiment 6 FIG.
FIG. 13 is a configuration diagram of an air conditioner control system according to Embodiment 6 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1 thru | or Embodiment 5, the same number is attached | subjected and description is abbreviate | omitted.
[0092]
In FIG. 13, in addition to the basic configuration described in the first embodiment, the power billing means 2 is a first operation for determining whether or not the operation information monitored by the communication means 8 is normal. The information determination means 21, the emergency apportioning means 16 that apportions instead of when normal apportioning is not possible, the apportioning dividing means 17 that corrects the apportioning results calculated by the emergency apportioning means 16 in apportionment units, and the database 11. Driving information data comparing means 23 for comparing the driving information data currently monitored and the driving information data monitored this time.
[0093]
The input unit 9 has a function of inputting the amount of power during a period when trouble occurs and the operation information is not monitored by the input unit 9 (hereinafter referred to as a failure period).
[0094]
FIG. 14 and FIG. 15 show whether or not the monitored data is normal when the trouble occurs when monitoring the operation information in the air conditioner control system 1 having such a power billing means 2 or whether the operation information is It is a flowchart which shows the method of apportioning by the apportionment unit urgently when it is normal and it is not normal.
[0095]
In the flowchart of FIG. 14, when the processing is started, monitoring of the operation information of the air conditioner body 5 by the communication means 8 is performed in accordance with the monitor timing in order to grasp the amount of power used for the apportionment calculation of the air conditioning charges (S61). ). Next, in the first driving information determination means 21, it is determined whether or not the driving information is within a range that is recognized as normal with respect to the driving information that is a predetermined reference (S62).
[0096]
When it is determined to be normal, the operation information data comparison means 23 records the current operation information data in the current operation information data in the air conditioner body 5 and the latest operation information data stored in the database 11. Is compared with the processing time of the air conditioner main body 5 recorded in the above, and it is determined whether or not the interval matches (is normal) compared to a predetermined monitoring interval (S63). When it is determined that the power amount data comparison means 23 is normal, or when it is determined that the power amount data comparison means 19 is normal, the power amount and the air conditioner main body stored in the database 11 Apportionment calculation using the operation information and operation capability information of 5 and the apportionment calculation using the operation information and operation capability information of the air conditioner main body 5 stored in the database 11 (S64). The data is stored in the database 11 via the input / output means 12 (S65), and the process ends.
[0097]
On the other hand, if it is determined in S62 that the operation information cannot be monitored, the air conditioner body 5 is monitored again in S61, and the process is repeated.
[0098]
Further, if it is determined in S63 that it is not normal because it does not match the predetermined monitoring interval, this period is regarded as a failure period of the air conditioner body 5 and stored in the database 11 via the database input / output means 12. (S66), the process ends.
[0099]
By doing so, in addition to knowing whether or not the monitored operation information is normal and whether or not the operation information has been recovered due to the failure, it is possible to store the period of the failure period.
[0100]
Next, FIG. 15 will be described. In this flowchart, when the process is started, it is determined whether or not the correction of the used power apportioning value for the failure period is selected by the input means 9 (S71). If it is selected, the failure period is stored in the database 11. The failure confirmation means 20 determines whether or not a failure period exists (S72), and if there is a failure period, the operation information is read from the database 11 using the database input / output means 12 to obtain operation information other than the failure period and the failure period. The calculated result is displayed on the output means 10 (S73). The failure period operation information with reference to the failure period and the operation information other than the failure period is input to the input means 9 (S74), and the apportionment of the air-conditioning charge is urgently performed with the electric energy read from the database 11 and the failure period as apportionment units. The apportioning means 16 calculates (S75). Using the calculated apportioning result, the apportioning dividing unit 17 performs calculation so as to divide into normal apportioning units (for example, daily units) (S76), and the failure period calculated using the database input / output unit 12 is calculated. The apportioning result is stored in the database 11 (S77), and the process ends.
[0101]
If correction is not selected in S71, the process ends. If the failure period is not stored in the database 11 in S72, the process ends.
[0102]
In this way, in order to apportion the air conditioning charges, even if troubles such as replacement of the outdoor unit or indoor unit occur, the air conditioning charges are calculated for each failure period or prorated unit of the failure period. This can save a lot of time and effort compared to manual calculation.
[0103]
Embodiment 7 FIG.
FIG. 16 is a configuration diagram of an air conditioner control system according to Embodiment 7 of the present invention. In addition, about the structure which has the same function as what was already demonstrated in Embodiment 1 thru | or Embodiment 6, the same number is attached | subjected and description is abbreviate | omitted.
[0104]
In FIG. 16, in addition to the basic configuration as described in the first embodiment, the power charge billing unit 2 determines whether or not the value of the electric energy monitored by the input unit 9 is normal. Power amount determining means 15, emergency apportioning means 16 that apportions instead when normal apportioning is not possible, and first that determines whether or not the operation information received by the communication means 8 from the air conditioner body 5 is normal. Driving information determination means 21, apportioning dividing means 17 for dividing and correcting the apportioning result calculated by the emergency apportioning means 16, tenant detecting means 24 for detecting whether the tenant setting content has been changed, The apportionment state confirmation means 25 for detecting the existence of apportionment execution units that have not been apportioned within the settlement period at the time, and the apportionment period detected by the apportionment state confirmation means 25 are apportioned and calculated as soon as possible. An emergency settlement means 26 for making an immediate settlement using the apportioned value and the apportioned value calculated by the apportioning means 13; an emergency settlement confirmation means 27 for detecting whether or not the emergency settlement has been carried out by the emergency settlement means 26; And an emergency fee settlement means 28 that settles the difference between the apportioned result of emergency settlement and the result of apportioned calculation at the time of recovery from a failure into the air conditioning fee for the next month.
[0105]
An actual charging process of the system having such a configuration will be described. In addition to this billing process, as shown in FIG. 17, there is a process for recording that a tenant where a plurality of air conditioners managed by this system are installed. In this process, The tenant detection means 24 detects whether or not the tenant has been changed (S91). If the tenant has been changed, the tenant change date is set to the database 11 via the database input / output means 12 as the tenant change date. Store (S92), and if not changed, end without storing.
[0106]
FIG. 18 shows whether or not the monitored data is normal when trouble occurs in the air conditioner control system 1 having such a power billing means 2, and if it is not normal, it is urgently distributed in units. It is a flowchart which shows the method of performing until apportionment and charge settlement.
[0107]
In this flowchart, when processing is started, in order to grasp the amount of electric power used in apportionment of the air conditioning charges and the operation information, monitoring of the electric energy of the watt hour meter 6 by the input means 9 and the main body of the air conditioner by the communication means 8 The monitoring of the driving information 5 is performed in accordance with the monitoring timing (S91). Next, it is determined whether or not the power amount and the operation information can be normally monitored by the first power amount determination unit 15 and the first operation information determination unit 21 (S92). When the electric energy and the operation information are normal, the apportioning means 13 apportionably calculates the electric energy used by the air conditioner body 5 by using data such as the electric energy and the operation information and driving ability information stored in the database 11. (S93), the distribution result calculated using the database input / output means 12 is stored in the database 11 (S94), and the process ends.
[0108]
On the other hand, if it is determined in S92 that the monitoring of the electric energy or the operation information is not normal, it is determined whether or not the processing day corresponds to the settlement date set by the input means 9 using the apportionment status confirmation means 25. If it is judged (S95) and it falls on the settlement date, there is an unprorated apportionment unit for the settlement period, and one week from the operation information after the tenant change and apportionment result value with reference to the modification date stored in the database 11 The air-conditioning charge apportioning value is calculated by calculating the air-conditioning charge apportioning value for the failure period up to the settlement date by the emergency settlement means 26 (S96). And the apportioned value stored in the database 11 are used to calculate the emergency charge for the total air conditioning charge during the checkout period (S97), and monitor the electric energy and operation information at the next monitoring timing. S98).
[0109]
On the other hand, if it is determined in S95 that it is not a settlement date, the emergency apportioning calculation is not performed and monitoring is performed in S98.
[0110]
Next, it is determined again whether the power amount and the operation information have been normally monitored using the first power amount determination unit 15 and the first operation information determination unit 21, that is, whether the operation has been recovered (S <b> 99). When it is determined to be normal, the apportionment calculation of the air-conditioning charge is performed by using the emergency apportioning means 16 based on the monitored electric energy and operation information and the data of the failure period stored in the database 11. (S100), using the apportionment result calculated by the apportionment dividing unit 17, correction calculation is performed in a normal apportionment unit (eg, daily unit) (S101).
[0111]
On the other hand, if it is determined that the power is not normal, the monitoring function of the electric energy of the wattmeter 6 and the operation information of the air conditioner main body 5 has not been restored, so the processing from S95 is repeated again.
[0112]
Next, it is determined whether or not the emergency checkout has been made between the time when the emergency checkout confirmation means 27 determines that it is not normal at S92 and the time when it is determined that it is normal at S99 (S102). If there is, the emergency charge settlement means 28 compares the result of the temporary distribution calculated in S96 with the distribution result calculated in S100, and reflects the difference in the adjustment of the air conditioning charge in the next month. The difference is included in the apportioned value of, and settlement is performed (S103) and stored in the database 11 by the database input / output means 12 (S104).
[0113]
On the other hand, when the settlement is not performed in S102, the distribution result corrected in the distribution unit calculated in S101 is stored in the database 11 by the database input / output means 12.
[0114]
By doing in this way, it is possible to make adjustments by including the corresponding period in the total air conditioning charges on the settlement day, so that the air conditioning charges during the failure period when a temporary monitor trouble has occurred are not biased to the next day. There is an effect that it can be settled. In addition, since the air-conditioning charge for the month in which the failure has been recovered can be automatically adjusted by adjusting the difference from the last month's emergency settlement result, it is possible to significantly reduce labor and time compared to manual calculation. In addition, since a means for detecting a change in tenant is provided, an emergency apportioning using the tenant usage record data can be performed, and the air conditioning charge can be calculated in a form close to the tenant use record.
[0115]
In this embodiment, the data used for the emergency apportionment calculation is configured to use the apportionment value of the weekly average after the tenant change. Needless to say, the emergency apportionment calculation means 18 can use the average apportionment calculation means 18 using the average data of the month, the current month average data of one year ago, and the like.
[0116]
【The invention's effect】
Since the present invention is configured as described above, the following effects can be obtained. Even if the operation information of the air conditioner or the monitoring of the electric energy of the watt hour meter cannot be performed normally, it can be apportioned immediately using the previous data, and the individual air conditioning charges can be calculated.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an air conditioning control system according to Embodiment 1 of the present invention.
FIG. 2 is a flowchart of the air conditioning control system according to Embodiment 1 of the present invention.
FIG. 3 is a flowchart of an air conditioning control system in Embodiment 2 of the present invention.
FIG. 4 is a configuration diagram of an air conditioning control system in Embodiment 2 of the present invention.
FIG. 5 is a flowchart of an air conditioning control system in Embodiment 2 of the present invention.
FIG. 6 is a configuration diagram of an air conditioning control system according to Embodiment 3 of the present invention.
FIG. 7 is a flowchart of an air conditioning control system in Embodiment 3 of the present invention.
FIG. 8 is a flowchart of an air conditioning control system in Embodiment 3 of the present invention.
FIG. 9 is a configuration diagram of an air conditioning control system according to Embodiment 4 of the present invention.
FIG. 10 is a flowchart of an air conditioning control system in Embodiment 4 of the present invention.
FIG. 11 is a configuration diagram of an air conditioning control system according to Embodiment 5 of the present invention.
FIG. 12 is a flowchart of an air conditioning control system in Embodiment 5 of the present invention.
FIG. 13 is a configuration diagram of an air conditioning control system according to Embodiment 6 of the present invention.
FIG. 14 is a flowchart of an air conditioning control system in Embodiment 6 of the present invention.
FIG. 15 is a flowchart of an air conditioning control system in a sixth embodiment of the present invention.
FIG. 16 is a configuration diagram of an air conditioning control system according to a seventh embodiment of the present invention.
FIG. 17 is a flowchart of an air conditioning control system in a seventh embodiment of the present invention.
FIG. 18 is a flowchart of an air conditioning control system in a seventh embodiment of the present invention.
FIG. 19 is a configuration diagram of a conventional air conditioning control system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Air conditioner control system, 2 Electricity charge billing means, 3 Outdoor unit, 4 Indoor unit, 5 Air conditioner main body, 6 Electricity meter, 7 Microcomputer, 8 Communication means, 9 Input means, 10 Output means, 11 Database, 12 Database Input / output means, 13 apportioning means, 14 transmission line, 15 first power amount judging means, 16 emergency apportioning means, 17 apportioning dividing means, 18 second power amount judging means, 19 power amount data comparing means, 20 failure check Means, 21 first driving information determination means, 22 second driving information determination means, 23 driving information data comparison means, 24 tenant detection means, 25 apportionment state confirmation means, 26 emergency settlement means, 27 emergency settlement confirmation means, 28 First aid fee settlement means.

Claims (12)

Multiple air conditioners,
Communication means for receiving operation information from the plurality of air conditioners;
A watt hour meter for measuring the amount of power used by the plurality of air conditioners;
Monitoring means for monitoring the amount of power;
First power amount determination means for determining whether or not the power amount monitored by the monitoring means is within a predetermined range;
If the power amount is within the range, apportioning means for apportioning the electric energy based on the operation information to obtain an apportioned electric energy;
Storage means for storing the apportioned electric energy and the operation information;
If the electric energy is not within the range, the apportioned electric energy stored in the storage means and the ratio of the operation information from the time of apportionment by the apportioning means to the current operation information stored in the storage means And an emergency apportioning means for estimating apportioned electric energy from the air conditioner control system. If the amount of power is not within the range, the monitoring unit repeats monitoring, and has a second power amount determination unit that determines whether the amount of power is within a predetermined range,
If the electric energy is within the range, the emergency apportioning means is a ratio of the operation information from the time point determined by the first electric energy determination means to the present time and the operation information stored in the storage means, and the storage means The air conditioner control system according to claim 1, wherein the apportioned electric energy is estimated from the apportioned electric energy stored in the computer. If the power amount is within the range, a processing interval is obtained from the time when the power amount is processed by the watt hour meter and the time when the power amount stored in the storage means is processed by the watt hour meter, and the processing interval 3. The air conditioner control system according to claim 1, wherein the storage unit stores the air conditioner that is not within a predetermined range. 4. Multiple air conditioners,
Communication means for receiving operation information from the plurality of air conditioners;
A watt hour meter for measuring the amount of power used by the plurality of air conditioners;
Monitoring means for monitoring the amount of power;
First driving information determination means for determining whether or not the driving information monitored by the communication means is within a predetermined range;
If the operation information is within the range, apportioning means for apportioning the electric energy based on the operation information to obtain an apportioned electric energy;
Storage means for storing the apportioned electric energy and the electric energy;
If the operation information is not within the range, the apportioned electric energy stored in the storage unit and the ratio of the electric energy from the time of apportioning by the apportioning unit to the current amount and the electric energy stored in the storage unit And an emergency apportioning means for estimating apportioned electric energy from the air conditioner control system. If the driving information is not within the range, the monitoring means repeats monitoring and has second driving information determination means for determining whether the driving information is within a predetermined range,
The emergency apportioning means, if the driving information is within the range, the ratio of the amount of electric power from the time determined by the first driving information determining means to the present time and the electric energy stored in the storage means and the storage means 5. The air conditioner control system according to claim 4, wherein the apportioned electric energy is estimated from the apportioned electric energy stored in the storage. If the driving information is within the above range, a processing interval is obtained from the time when the driving information is processed by the communication means and the time when the driving information stored in the storage means is processed by the communication means. The air conditioner control system according to any one of claims 4 and 5, wherein if it is not within a predetermined range, it is stored in the storage means. In a control method of an air conditioner control system having a plurality of air conditioners, and a control means that apportions the amount of power used by the plurality of air conditioners from the amount of power used by the plurality of air conditioners and operation information.
Monitoring a power amount and determining whether the power amount is within a predetermined range; and
If the amount of electric power is within the range, a second step of apportioning the amount of electric power based on the operation information to obtain an apportioned electric energy and storing the apportioned electric energy and the operation information;
If the amount of electric power is not within the range, the apportioned power stored in the storage unit and the ratio of the operation information from the time of apportioning by the apportioning unit to the present time and the operation information stored in the storage unit And a third step of estimating the apportioned electric energy from the amount, a control method for an air conditioner control system. If the amount of electric power is not within the range in the first step, it has a fourth step of repeating the monitoring to determine whether the amount of electric power is within a predetermined range,
If the amount of electric power is within the range, in the third step, the apportioned electric energy stored in the storage unit and the ratio of the operation information from the determined time to the current time and the operation information stored in the storage unit The method of controlling an air conditioner control system according to claim 7, further comprising: estimating apportioned electric energy from If the power amount is within the range in the first step, the processing interval is determined from the time when the power amount is processed by the watt hour meter and the time when the power amount stored in the storage means is processed by the watt hour meter. A fifth step to seek,
9. The control method for an air conditioner control system according to claim 7, further comprising: a sixth step of storing in the storage means if the processing interval is not within a predetermined range. In a control method of an air conditioner control system having a plurality of air conditioners, and a control means for receiving electric energy and operation information used by the plurality of air conditioners,
Monitoring the driving information and determining whether the driving information is within a predetermined range; and
If the operation information is within the range, a second step of apportioning the electric energy based on the operation information to obtain an apportioned electric energy and storing the apportioned electric energy and the electric energy;
If the operation information is not within the range, the apportioned electric power stored in the storage unit and the ratio of the electric energy from the time of apportioning by the apportioning unit to the present time and the electric energy stored in the storage unit And a third step of estimating the apportioned electric energy from the amount, a control method for an air conditioner control system. If the driving information is not within the range in the first step, there is a fourth step in which monitoring is repeated to determine whether the driving information is within a predetermined range,
If the operation information is within the range, in the third step, the apportioned power stored in the storage means and the ratio of the amount of power from the determined time to the current time and the amount of power stored in the storage means The control method for an air conditioner control system according to claim 10, wherein the apportioned electric energy is estimated from the amount. If the driving information is within the range in the first step, the processing interval is obtained from the time when the driving information is processed by the communication means and the time when the driving information stored in the storage means is processed by the communication means. The fifth step,
12. The control method for an air conditioner control system according to claim 10, further comprising: a sixth step of storing in the storage means if the processing interval is not within a predetermined range.

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