JP4544968B2 - Air conditioning charge calculator - Google Patents

Description

  The present invention relates to an apparatus for calculating a charge of an air conditioner driven using a plurality of powers.

  Some air conditioners have a compressor driven by different types of power such as a GHP (Gas Engine Heat Pump) system and an EHP (Electric Heat Pump) system. Specifically, in the GHP system, the compressor is a gas engine, and a fan motor and the like are driven by electricity, and in the EHP system, the compressor and the fan motor are driven by three-phase power or single-phase power. In a building having air conditioning equipment in which various power sources are mixed in this way, various methods for apportioning the charge to each room can be considered.

  Patent Document 1 discloses an air-conditioning charge management apparatus that calculates a power usage fee for each air conditioner for each of the plurality of power units using a plurality of air conditioners that use a plurality of powers including electric power and gas. A power apportioning means for setting a plurality of power apportioning methods for measuring the total power consumption of the machine for each power and apportioning the measured power to each air conditioner; An air-conditioning charge management device is disclosed in which a distribution method is selected for each power from a method.

Japanese Patent No. 3480098

The objective of this invention is providing the air-conditioning charge calculation apparatus which apportions the charge of the several air-conditioning system driven by a different power source.
Another object of the present invention is to provide an air-conditioning charge calculation device that performs an appropriate distribution calculation by setting one distribution method for each air-conditioning indoor unit.
Still another object of the present invention is to provide an air-conditioning charge calculation device that enables apportionment calculations that are easy to understand and set for users (tenant building managers and tenant users).

  In the following, means for solving the problem will be described using the numbers used in [Best Mode for Carrying Out the Invention] in parentheses. These numbers are added to clarify the correspondence between the description of [Claims] and [Best Mode for Carrying Out the Invention]. However, these numbers should not be used to interpret the technical scope of the invention described in [Claims].

  The air-conditioning charge calculation apparatus according to the present invention includes a first meter (6) that transmits a first signal indicating a usage amount of a first power source (5) that drives a first air-conditioning system (2), and a first air-conditioning system ( 2) a second meter (8) that transmits a second signal indicating the amount of use of the second power source (7) that drives 2), a receiver (22) that receives the first signal and the second signal, and reception An air conditioning charge calculation unit (26) that calculates a usage charge for the first air conditioning system (2) using the first signal and the second signal received by the unit (22). The air conditioning charge calculation unit (26) includes a selection unit that accepts an input of a distribution method of the first air conditioning system (2) selected from among a plurality of distribution methods, and uses the first charge of the first power source (5). The usage fee of the two power sources (7) is calculated by a common apportionment method input to the selection unit.

  More preferably, the air-conditioning charge calculation apparatus according to the present invention includes a third meter (14) that transmits a third signal indicating the amount of use of the third power source (13) that drives the second air-conditioning system (4). ing. The receiving unit (22) receives the third signal. A selection part receives the input of the apportioning method selected independently with respect to each of a 1st air conditioning system (2) and a 2nd air conditioning system (4) from the some apportioning methods. The air conditioning fee calculation unit (26) calculates the usage fee of the second air conditioning system (4) using the third signal received by the receiving unit (22).

  Moreover, in the air-conditioning charge calculation apparatus by this invention, a 1st power source (5) is gas and a 2nd power source (7) is electric power. The first air conditioning system (2) is preferably air-conditioned by a GHP (Gas Engine Heat Pump) method.

  In the air conditioning charge calculation apparatus according to the present invention, the second power source (7) and the third power source (13) may be the same type of power source.

  More preferably, in the air-conditioning charge calculation apparatus according to the present invention, the third power source (13) for driving the second air conditioning system (4) is set to three-phase power, and the fourth power source (15 The second air conditioning system (4) of the EHP (Electric Heat Pump) system that is driven even if the above is used. The air conditioning charge calculation unit (26) combines the usage fee for the third power source (13) and the usage fee for the fourth power source (15) together with the second air conditioning system (4) input to the selection unit (22). ) Using the apportionment method.

  In the air conditioning charge calculation device according to the present invention, a plurality of air conditioning charge calculation units (26) may be provided. Each of the plurality of air conditioning charge calculation units can independently set a charge calculation formula corresponding to the apportionment method.

  The air conditioning system according to the present invention employs a configuration including the above-described air conditioning charge calculation device according to the present invention, the first air conditioning system (2), and the second air conditioning system (4).

ADVANTAGE OF THE INVENTION According to this invention, the air-conditioning charge calculation apparatus which apportions the charge of the several air conditioning system driven by a different power source is provided.
Furthermore, according to this invention, the air-conditioning charge calculation apparatus which performs an appropriate proportional distribution calculation by setting one proportional distribution system with respect to each air-conditioning indoor unit is provided.
Furthermore, according to the present invention, there is provided an air-conditioning charge calculation device that enables apportionment calculations that are easy to understand and set for users (tenant building managers and tenant users).

  Hereinafter, the best mode for carrying out an air-conditioning charge calculation apparatus according to the present invention will be described with reference to the drawings.

  Referring to FIG. 1, there is shown an air-conditioning charge calculation apparatus according to the present embodiment and an air conditioner system to which the air-conditioning charge calculation apparatus is applied (for example, a system that performs air conditioning of an entire tenant building). The air conditioner system according to the present embodiment includes a multi-type air conditioner GHP2 that employs the GHP method and a multi-type air conditioner EHP4 that employs the EHP method.

GHP2 is supplied with gas 5 and electricity 7 as a power source. The GHP 2 includes a gas flow meter 6 and an electric energy meter 8. Here, the gas flow rate meter 6, the gas, by delivering a pulse signal every time a predetermined amount (e.g., 1 m ³⁾ supply, and transmits to the central control unit 22 to be described later. The electric energy meter 8 transmits a pulse signal every time a predetermined amount (for example, 1 kWh) of electric power is supplied, and transmits the pulse signal to the central control device 22.
The GHP 2 includes at least one outdoor unit 10 and at least one indoor unit 12 corresponding to each outdoor unit 10. Each outdoor unit 10 constitutes an air conditioning system 2-1, 2-2 connected to one or more indoor units 12 by a refrigerant pipe (not shown).

The EHP 4 is supplied with three-phase electricity 13 and single-phase electricity 15 as power sources. More specifically, three-phase electricity 13 is supplied to the outdoor unit 18 and single-phase electricity 15 is supplied to the indoor unit 20 from the viewpoint of electricity.
The EHP 4 includes a three-phase energy meter 14 and a single-phase energy meter 16. Here, the three-phase electric energy meter 14 transmits a pulse signal every time the electric energy of the three-phase electricity 13 is supplied by a predetermined amount (for example, 1 kWh), and transmits the pulse signal to the centralized control device 22 described later. The single-phase electric energy meter 16 transmits a pulse signal every time the electric energy of the single-phase electricity 15 is supplied by a predetermined amount (for example, 1 kWh), and transmits the pulse signal to the centralized control device 22 described later.
The EHP 2 includes at least one outdoor unit 18 and at least one indoor unit 20 corresponding to each outdoor unit 18. Each outdoor unit 18 constitutes an air conditioning system 4-1, 4-2 connected to one or more indoor units 20 by a refrigerant pipe (not shown).

  GHP2 and EHP4 are used for air conditioning a plurality of sections (tenants) of a building. A tenant may use a mixture of indoor units 12 and 20 belonging to different types of outdoor units, such as three indoor units 12 belonging to GHP2 and one indoor unit 20 belonging to EHP4.

The central control device 22 includes a storage device 28. The central control device 22 further includes an arithmetic control device, an input device, an output device, and a communication device (not shown), and can be realized by a computer system such as a personal computer.
The central control device 22 receives pulse signals from the gas flow meter 6, the electric energy meter 8, the three-phase electric energy meter 14, and the single-phase electric energy meter 16. The centralized control device 22 accumulates (adds) the number of received pulse signals every predetermined time (for example, every 10 minutes, every hour, every day).

  In addition, the centralized control device 22 according to the present embodiment includes a USB (Universal Serial Bus) connector. The amount of operation for each air conditioning indoor unit calculated based on the selected apportioning method and the integrated value of the pulse signal for each predetermined time are stored in the USB memory 24 connected to the USB connector.

  The central control device 22 is connected to a control device that controls each of the indoor units 12 and 20 so as to allow information communication. Thereby, the centralized control device 22 can collect and store the operation amount for each air conditioner (information relating to the operation of each indoor unit 12, 20). Specifically, the collected information includes the operation time of each indoor unit 12, 20 within a predetermined time (for example, one day), the refrigerant flow rate (a numerical value corresponding to the indoor unit electronic expansion valve opening), the thermostat. The time of ON (at the time of air conditioning operation) is illustrated.

  The air conditioning charge calculator 26 includes a storage device 27. The air-conditioning charge calculator 26 further includes an arithmetic control device, an input device, an output device, and a communication device (not shown), and can be realized by a computer system such as a personal computer. The air conditioning charge calculator 26 includes a USB connector. The air conditioning charge calculator 26 receives and stores data such as the operation amount for each air conditioner and the integrated value of the pulse signal for each predetermined time from the central control device 22 via the USB memory 24.

  FIG. 2 shows a table stored in the storage device 27 of the air conditioning charge calculator 26. More specifically, the storage device 27 stores a system definition table 30, a pulse definition table 32, a basic charge table 34, a unit price table 35, and a tenant configuration table 36. Data stored in these tables can be referred to by a display device provided in the air conditioning charge calculator 26 and can be rewritten by an input device.

  Since data transfer between the central control device 22 and the air conditioning charge calculator 26 is performed by a USB memory, wiring work between the central control device 22 and the air conditioning charge calculator 26 becomes unnecessary, and the installation of the apparatus becomes easy. .

  FIG. 3 shows a table stored in the storage device 28 of the central control device 22. The storage device 28 stores a distribution system / model capability table 60 and a billing time zone table 61. The data stored in these tables can be referred to by a display device provided in the central control device 22 and can be rewritten by an input device.

FIG. 4 shows the data configuration of the system definition table 30. The system definition table 30 includes an air conditioner ID 37, which is an identifier for identifying each air conditioning indoor unit, and to which pulse system each air conditioning indoor unit belongs, that is, a gas flow meter 6, a power meter 8, three-phase power. Stored in association with a system selection 38 indicating which meter is connected to the meter 14, the single-phase power meter 16, or the like.
Further, the pulse system associated with the air conditioning indoor unit is not limited to one, and a method of storing a plurality of system selections in association with each other, such as the air conditioner 1-06 or 1-07 shown in FIG. It is desirable to adopt.

FIG. 5 shows the data structure of the pulse definition table 32. The pulse definition table 32 stores a pulse system 39, a pulse constant 40, and a power / gas category 41 in association with each other. The pulse system 39 is an identifier for identifying a meter such as a gas meter or a power meter. The pulse constant 40 indicates a unit in which each meter transmits one pulse.
For example, the first line of the pulse definition table 32 shown in FIG. 5 specifies that the power / gas section 41 is electricity and the pulse constant 40 is 12.34. This indicates that one pulse signal is transmitted every time 12.34 kWh of power is consumed. Similarly, the second line specifies that the power / gas section 41 is gas and the pulse constant 40 is 42.45. This indicates that one pulse signal is transmitted every time 42.45 m ^{3 of} gas is consumed.

  FIG. 6 shows an electricity basic charge table 34-1 which is a part of the basic charge table 34. The electricity basic charge table 34-1 stores a tenant ID 43 that individually identifies each tenant and an electricity basic charge 44 (for example, monthly) of each tenant in association with each other.

  FIG. 7 shows a gas basic charge table 34-2 which is a part of the basic charge table 34. The gas basic charge table 34-2 stores the tenant ID 43 and the basic charge 50 (for example, monthly) of each air conditioner in association with each other.

  FIG. 8 shows the data structure of the unit price table 35. The unit price table 35 stores a pulse system 39, an intra-hour unit price 42, and an out-of-hour unit price 46 in association with each other. The in-hour unit price 42 indicates the unit price of electricity or gas within the time set to be within the time in the billing time zone table 61 as will be described later. The off-hour unit price 42 indicates the unit price of electricity or gas at a time other than the time set to be within the time.

  FIG. 9 shows the data configuration of the tenant configuration table 36. The tenant configuration table 36 stores a tenant ID 43 and a configuration air conditioner ID 45 that identifies the air conditioner indoor unit used for the tenant specified by the tenant ID 43 in association with each other.

  FIG. 10 shows the data structure of the apportionment method / model capability table 60. The apportioning method / model capability table 60 stores the air conditioner ID 37, the apportioning method 59, and the model capability 62 in association with each other. The apportionment method 59 indicates a type of a method for calculating a dimensionless operation amount for calculating a usage fee of the air conditioning indoor unit specified by the air conditioner ID 37. The model capability 62 indicates the capability of the air conditioner indoor unit specified by the air conditioner ID 37.

  FIG. 11 shows the data structure of the billing time zone table 61. The unit price of electricity and gas may differ between a predetermined time of the day and other time zones. The billing time zone table 61 stores the start time and end time of the predetermined time. However, the data structure of the billing time zone table 61 is not limited to the configuration shown in FIG. 11, and not only the time zone according to the unit price of power, but also the hourly unit price other than a fixed working hour zone can be In order to obtain a desired setting, a configuration in which association with a plurality of time zones may be performed.

  In FIG. 12, the calculation flow of the air-conditioning charge calculation apparatus in this Embodiment is shown.

  Step S2: The central control device 22 receives operation data for calculating the operation amount for each air conditioning indoor unit. The central control apparatus 22 reads the apportioning method 59 and the model capability 62 set for each air conditioning indoor unit with reference to the apportioning method / model capability table 60. The central control device 22 calculates the operation amount for each air conditioner (the operation amount of each air conditioning indoor unit) based on the read apportionment method 59. The operation amount for each air conditioner is made dimensionless by being multiplied by a constant set in advance and stored in the storage device 28.

  The centralized control device 22 refers to the billing time zone table 61 and calculates the integrated value of the operating amount for each air conditioner within the set time and the integrated value of the operating amount for each air conditioner outside the set time.

  The apportionment method 59 includes (1) the operating time of each air conditioning indoor unit × model capacity 62, (2) the air conditioning load of each air conditioning indoor unit (refrigerant flow rate; a numerical value corresponding to the opening of the indoor unit electronic expansion valve), ( 3) It is selected from methods such as thermo-ON (air-conditioning operation) time x model capability 62.

  According to the data structure of the apportionment method / model capability table 60, the apportionment method 59 is set for each air conditioning indoor unit 37. Therefore, for example, in the case of the indoor unit 12 of GHP2, a common distribution method is set for gas and electricity. In the case of the EHP4 indoor unit 20, a common distribution method is set for the three-phase electricity 13 and the single-phase electricity 15.

  The method of setting the apportionment method corresponding to the air conditioning indoor unit is more user (building manager, tenant user) than the method of setting apportionment method for each power source (gas, three-phase electricity, single-phase electricity, etc.) ) Is easy to understand and it is easy to set up a distribution method that suits user needs.

  Step S4: Each meter (including the gas flow meter 6, the electric energy meter 8, the three-phase electric energy meter 14, and the single-phase electric energy meter 16) transmits a pulse signal according to the usage amount of each power source, A call is sent to the central control device 22. The central control device receives a pulse signal.

  The central control device 22 refers to the billing time zone table 61 and calculates the integrated value of the pulse signal received within the set time and the integrated value of the pulse signal received outside the time.

  Step S6: The centralized control device 22 stores the operation amount for each air conditioner calculated in Step S2 and the integrated value of the pulse signal calculated in Step S4 (both are calculated separately within the time and outside the time). To do. The stored operating amount for each air conditioner and the integrated value of the pulse signal are transferred to the air conditioning charge calculator 26 via the USB memory 24 at predetermined time intervals (for example, every day).

  Step S8: The air conditioning charge calculator 26 refers to the pulse definition table 32 and multiplies the integrated value of the pulse signal recorded in step S6 by the pulse constant for each pulse system 39. Thereby, the total number of air conditioners belonging to each pulse system (more precisely, the air conditioner indoor units specified by the air conditioner ID 37 in which the system selection 38 corresponding to each pulse system 39 is set in the system definition table 30). Consumption is obtained. This total consumption amount is calculated separately for in-hours and out-of-hours.

Step S10: The air conditioning charge calculator 26 calculates the consumption amount for each air conditioning indoor unit by the following formula:
Air conditioning unit consumption (within / outside) = total consumption (within / outside) x operation amount of the corresponding air conditioner (inside / outside) ÷ total amount of operation of the air conditioner belonging to the meter (within time) / Outside).

Even if a plurality of air conditioning indoor units belonging to the same pulse system are set to different apportioning systems because the operation amount for each air conditioner is made dimensionless in step S2, as shown in the above equation, The total consumption of each power source calculated from the pulse constant can be apportioned to each air conditioning indoor unit by the ratio of the operation amount for each air conditioner.

Step S12: The air conditioning charge calculator 26 refers to the system definition table 30 to search which pulse system each air conditioning indoor unit belongs to. The air conditioning charge calculator 26 refers to the unit price table 35 and searches for the in-hour unit price 42 and the overtime unit price 46 corresponding to the searched pulse system 39. The air conditioning fee calculator 26 calculates the usage fee for each air conditioning indoor unit according to the following formula:
Charge for each air conditioner = consumption per air conditioner (within hours) x unit price within hours + consumption per air conditioner (outside hours) x unit price over time.

Step S14: The air conditioning charge calculator 26 refers to the basic charge table 34 and searches for the electric basic charge 44 and the gas use charge 50 corresponding to each tenant ID 43. The air conditioning fee calculator 26 refers to the tenant configuration table 36 and refers to the configuration air conditioner 45 corresponding to each tenant ID 43.
Specifically, the air conditioning fee calculator 26 performs processing for calculating the air conditioning fee for each tenant according to the following equation.

First, a case where the power source is electricity will be described.
Air conditioning charge per tenant (electricity) = basic charge (electricity) + Σ (charge per use of air conditioner of the air conditioner constituting the tenant)
here,
Charge for each air conditioner (electricity) = power consumption of pulse system 1 × pulse system 1 unit price + pulse system 2 power consumption × pulse system 2 unit price +... + Pulse system 8 power consumption × pulse system 8 Unit price The air-conditioning charge calculator 26 calculates and adds the calculation processing based on these formulas in each of the hours and after hours while referring to various tables. In the calculation process, the consumption amount of the pulse system in which the corresponding air conditioning indoor unit is not registered in the system definition table 30 is zero. Further, when the power / gas classification 41 of the pulse definition table 32 is gas, the consumption amount is 0 and is not added.

Next, a case where gas is used as a power source will be described.
Air conditioning charge per tenant (gas) = basic charge (gas) + Σ (use charge per air conditioner of the air conditioner constituting the tenant)
here,
Charge for each air conditioner (gas) = gas consumption of pulse system 1 x pulse system 1 unit price + gas consumption of pulse system 2 x pulse system 2 unit price + gas consumption of pulse system 8 x pulse system 8 unit price Air conditioning charge calculator 26 calculates and adds the calculation processes based on these formulas within and outside of the time with reference to various tables. In the calculation process, the consumption amount of the pulse system in which the corresponding air conditioning indoor unit is not registered in the system definition table 30 is zero. Further, when the power / gas classification 41 of the pulse definition table 32 is electricity, the consumption amount is 0 and is not added.
In addition, the calculation can be simplified by setting the unit price table 35 not only for each pulse system but only for the unit price of gas and electricity within and outside hours.

  The fee calculated by the above flow has the following characteristics.

  The gas flow meter and watt-hour meter in GHP adopt the same distribution method. An independent apportioning system is used for the watt-hour meter in GHP and the watt-hour meter in EHP. That is, different distribution methods can be set for a plurality of systems, that is, GHP and EHP in the present embodiment. In addition, a plurality of powers in the same system, in this embodiment, the GHP power system and gas system are set in the same apportioning system. For example, a proportional distribution method based on the refrigerant flow rate (air conditioning load) can be selected for GHP, and a proportional distribution method based on operation time can be selected for EHP.

  As a modification of the present embodiment, a configuration is possible in which the central control device 22 and the air conditioning charge calculator 26 are connected by a LAN, and data transfer is performed by a LAN instead of a USB memory. In that case, the LAN can be configured to include a plurality of air conditioning charge calculators 26 each capable of independently selecting a charge calculation formula. According to the air conditioning charge calculation apparatus having such a configuration, energy calculation according to the purpose is facilitated, and energy management can be performed with higher convenience.

  Furthermore, as another example of the apportionment method, it is also preferable to adopt a method that apportions the charge in proportion to “the operation time of the indoor fan motor that is the main energy consumption source of the indoor unit × the fan motor rotation speed × the model capability”. . By using such a proportional distribution method, it is possible to calculate the energy consumption with higher accuracy.

FIG. 1 shows the configuration of an air conditioner and an air conditioning charge calculator. FIG. 2 shows a table stored in the air conditioning charge calculator. FIG. 3 shows a table stored in the central control apparatus. FIG. 4 shows a system definition table. FIG. 5 shows a pulse definition table. FIG. 6 shows a basic electricity charge table. FIG. 7 shows a gas basic charge table. FIG. 8 shows a unit price table. FIG. 9 shows a tenant configuration table. FIG. 10 shows a distribution method / model capability table. FIG. 11 shows a billing time zone table. FIG. 12 is a flowchart showing a fee calculation procedure.

Explanation of symbols

2 ... GHP (Gas Heat Pump)
2-1, 2-2 ... Air conditioning system 4 ... EHP (Electric Heat Pump)
4-1, 4-2 ... air conditioning system 5 ... gas 6 ... gas flow meter 7 ... electricity 8 ... electricity meter 10 ... outdoor unit 12 ... indoor unit 13 ... three-phase electricity 14 ... three-phase electricity meter 15 ... single phase Electricity 16 ... Single-phase energy meter 18 ... Outdoor unit 20 ... Indoor unit 22 ... Centralized control device 24 ... USB memory 26 ... Air conditioning charge calculator 27 ... Storage device 28 ... Storage device 30 ... System definition table 32 ... Pulse definition table 34 ... Basic charge table 34-1 ... Electric basic charge table 34-2 ... Gas basic charge table 35 ... Unit price table 36 ... Tenant configuration table 37 ... Air conditioner ID
38 ... System selection 39 ... Pulse system 40 ... Pulse constant 41 ... Power / gas classification 42 ... In-hour unit price 43 ... Tenant ID
44 ... Electric basic charge 45 ... Configuration air conditioner ID
46: Overtime unit price 50: Gas basic charge 52 ... Gas charge 54 ... Electricity charge 59 ... Prorated system 60 ... Prorated system / model capability table 61 ... Billing time zone table 62 ... Model capability

Claims (8)

An air-conditioning charge calculation device for calculating a charge for a first air-conditioning system and a second air-conditioning system used to air-condition a plurality of sections of a building,
Each of the plurality of indoor units arranged in the plurality of sections is included in one of the first air conditioning system and the second air conditioning system,
The first air conditioning system uses a plurality of power sources,
A first meter for transmitting a first signal indicating the amount of the first power source used to drive the first air conditioning system;
A second meter for transmitting a second signal indicating the amount of the second power source used to drive the first air conditioning system;
A receiving unit for receiving the first signal and the second signal;
An air-conditioning charge calculation unit that calculates a use charge of the first air-conditioning system using the first signal and the second signal received by the receiving unit;
The air-conditioning charge calculation unit includes a selection unit that receives an input of a distribution method of the first air-conditioning system that is selected for each indoor unit from among a plurality of distribution methods, and the usage fee of the first power source and the second Air-conditioning charge calculation apparatus characterized by calculating for each indoor unit by a common proportional division scheme input for each indoor unit and charge for the power source to the selection unit. An air-conditioning charge calculation device according to claim 1,
And a third meter for transmitting a third signal indicating the amount of the third power source used to drive the second air conditioning system.
The receiving unit receives the third signal;
The selection unit accepts an input of a distribution method that is independently selected for each of the first air conditioning system and the second air conditioning system from among a plurality of distribution systems.
The air-conditioning charge calculation unit calculates the use charge of the second air-conditioning system using the third signal received by the receiving unit. The air conditioning charge calculation device according to claim 1 or 2,
The first power source is gas, the second power source is electric power, and the first air conditioning system performs air conditioning by a GHP (Gas Engine Heat Pump) system. An air-conditioning charge calculation device according to claim 3,
The air conditioning charge calculation apparatus according to claim 1, wherein the second power source and the third power source are the same type of power source. The air-conditioning charge calculation device according to claim 3 or 4,
The third power source that drives the second air conditioning system is three-phase power,
The second air conditioning system is an EHP (Electric Heat Pump) system that is driven even when a fourth power source that is single-phase power is used.
The air conditioning fee calculation unit calculates both the usage fee of the third power source and the usage fee of the fourth power source using the apportioning system of the second air conditioning system input to the selection unit. An air-conditioning charge calculation device. An air-conditioning charge calculation device according to any one of claims 1 to 5,
There are a plurality of air conditioning charge calculators,
Each of the plurality of air-conditioning charge calculation units can independently set a charge calculation formula corresponding to a distribution method. The air-conditioning charge calculation device according to any one of claims 1 to 6,
The air conditioning charge calculation unit uses the first air conditioning system using the first power source usage and the second power source usage, which are dimensionlessly multiplied by a prestored constant. Air conditioning charge calculator that calculates charges. An air-conditioning charge calculation device according to any one of claims 1 to 7,
The first air conditioning system;
The second air conditioning system;
An air conditioning system comprising:

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