JP2021026501A - Electric power charge management device and electric power charge management method - Google Patents

Abstract

To quantitatively evaluate an electric power charge reduction effect.SOLUTION: An electric power charge management device has a following program constitution. An electric power charge unit price setting part sets a basic charge unit price of an electric power charge and a meter-rate charge unit price per unit time at each time zone. A contract electric power amount input part inputs a contract electric power amount. An electric power use amount measurement part measures an electric power use amount per unit time. A total unit price calculation part calculates a total unit price per unit time on the basis of a first unit price per unit time based on the basic charge unit price, and a second unit price per unit time based on the meter-rate charge unit price at each time zone which are calculated by using the basic charge unit price, the contract electric power amount, and the electric power use amount per unit time. A time money-amount result creation part calculates an electric power charge per unit time, based on the total unit price and the electric power use amount per unit time of a time as an electric power charge calculation object. A display function processing part displays the electric power charge per unit time.SELECTED DRAWING: Figure 3

Description

The present invention relates to an electricity rate management device and an electricity rate management method.

Normally, the watt-hour meter measures the time when the electric power is used and the kWh integrated value in 1-hour units (30-minute units + 30-minute units). The electricity rate is calculated by multiplying the kWh integrated value measured by the electricity meter by the electricity rate unit price (yen / kWh) at the end of the month. The basic charge is set on a monthly basis (yen / contract power kWh / month), and is calculated at the end of each month regardless of the usage amount (kWh). Therefore, the invoice from the electric power company to the consumer includes a metered charge based on the monthly kWh integrated value for each season and each time, and a monthly basic charge based on the contracted electric power.

In addition, a management system such as BEMS (Building Energy Management System) that manages energy in a building collects the same kWh integrated value as the above-mentioned power meter online. When a consumer aims to reduce electricity charges, promoting energy saving (hereinafter referred to as energy saving) of equipment and reducing the amount of electricity used (kWh) will lead to reduction of electricity charges. However, it is not possible to easily grasp the amount of power cost reduction due to energy saving in a power charge system in which the unit price is different for each season and each hour only by referring to the power value (kWh integrated value) collected by BEMS. There is a limit to energy saving by shortening the usage time and reducing power consumption by equipment, and the effect of reducing electricity charges only for energy saving is being lost. As another means, there is energy saving (for example, peak shift) due to the operation of equipment, but the effect of reduction of electricity charges cannot be clearly verified.

Japanese Unexamined Patent Publication No. 2006-14533

In this way, when aiming to reduce electricity charges, there is a limit to the effectiveness of energy saving in equipment. In addition, it is not possible to evaluate the effects other than the energy saving rate for reducing electricity charges in the operation of equipment. If the purpose is to reduce electricity charges, there is no method to evaluate the effect of reducing electricity charges without saving electricity by using electricity with the same amount of electricity (kWh) and a low unit price. If the effect of reducing electricity charges cannot be evaluated quantitatively, the activity of proposing equipment sales is not realistic, and the target of operational improvement (for example, peak shift) cannot be set.

In the past, the electricity bill charged by the electric power company is known only at the end of the month, and the billed amount is calculated based on the unit price setting that differs depending on the operating time zone, and the basic charge that does not depend on the electricity usage (kWh) as a fixed cost. Therefore, it was difficult to quantitatively evaluate the effect of reducing electricity charges.

The present invention has been made in consideration of the above-mentioned circumstances, and an object of the present invention is to provide an electric power charge management device and an electric power charge management method capable of quantitatively evaluating an electric power charge reduction effect.

In order to solve the above problems, the electricity rate management device in the present embodiment includes an electricity rate unit price setting unit, a contracted electric energy input unit, an electric energy consumption measurement unit, a comprehensive unit price calculation unit, an hourly amount actual creation unit, and a display function. It has a processing unit. The electricity rate unit price setting unit sets the basic rate unit price of the electricity rate and the metered rate unit price per unit time for each time zone. The contracted electric energy input unit inputs the contracted electric energy. The power consumption measurement unit measures the power consumption per unit time. The total unit price calculation unit has a first unit price per unit time based on the basic charge unit price calculated by using the basic charge unit price, the contracted electric energy amount, and the electric power consumption per unit time, and a metered amount for each time zone. The total unit price per unit time is calculated based on the second unit price per unit time based on the unit price. The hourly amount record creation unit calculates the electricity charge per unit time based on the total unit price and the amount of electricity used per unit time for the time for which the electricity charge is to be calculated. The display function processing unit displays the electricity charge per unit time.

The figure which shows the whole structure of the electricity charge management system of this embodiment. The figure which shows the structure of the electricity charge management server in this embodiment. A block diagram showing a functional configuration realized by executing an electricity rate management program. The figure which shows an example of the electricity charge management data. A flowchart showing the electricity rate menu selection process by the electricity rate menu selection process unit. A flowchart showing the actual power consumption processing by the electric power usage actual processing unit. A flowchart showing display function processing by the display function processing unit. The figure which shows the display example of the total unit price graph in this embodiment. The figure which shows the display example of the time amount graph in this embodiment. The figure which shows the display example of the electricity charge integration counter in this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing an overall configuration of the electricity rate management system of the present embodiment. The electricity rate management system is configured by connecting a power rate management server 10 to a BEMS (Building Energy Management System) 14, a power meter 16, an electronic device 18, and the like via a network 12. Not limited to BEMS, systems such as FEMS (Factory Energy Management System) and HEMS (Home Energy Management System) that can monitor power consumption and transmit data indicating power consumption can be targeted.

The electricity charge management server 10 collects data on the electricity used or the amount of electricity used from the BEMS 14 or the electricity meter 16 for each consumer, and manages the electricity charge based on the amount of electricity used for each consumer. The electricity rate management server 10 in the present embodiment does not manage the electricity rate on a monthly basis and provide it to the customer, but uses the unit time by adding up the basic rate (fixed cost) and the metered rate (variable cost). Based on the total unit price rebated by the amount of electric power (kWh), the electric power charge can be managed for each unit time by multiplying the amount of electric power used measured for each unit time by the BEMS 14 or the electric power meter 16. In the following description, the unit time is, for example, one hour. The unit time can be managed by using another time such as 30 minutes, 3 hours, or 12 hours as a unit time.

The BEMS 14 or the power meter 16 detects the amount of power used in the power equipment, and transmits the data to the power charge management server 10 at predetermined time intervals (for example, 1 hour).

The network 12 is a communication network capable of data communication by wire priority or wireless, including the Internet and a public network.

The electronic device 18 is used by, for example, a consumer, and is used for inputting and setting information necessary for managing electricity charges and for referring to information on electricity charges provided by the electricity charge management server 10. Will be done. As the electronic device 18, a personal computer, a target terminal, a smartphone, or the like can be used. When the consumer refers to the information regarding his / her own electricity charge, he / she uses the electronic device 18 to connect to the electricity charge management server 10 via the network 12.

FIG. 2 is a diagram showing a configuration of the electricity rate management server 10 in the present embodiment. As the electricity rate management server 10, a normal server computer can be used. The electricity rate management server 10 is provided with a processor 10A that performs various data processing and calculations. The processor 10A is connected to the memory 10B, the display device 10C, the input device 10D, the communication device 10E, and the storage device 10F via the bus.

The processor 10A can access the memory 10B composed of ROM, RAM, etc., and also access other input / output circuits, etc. to perform various processes. The processor 10A realizes the function shown in FIG. 3 described later by executing the power charge management program 10F1 loaded in the memory 10B, manages the power charge for each consumer, and provides information on the power charge. Execute the processing for.

The processor 10A operates according to the system programs and data such as BIOS stored in the ROM of the memory 10B and the programs and data loaded from the storage device 10F into the RAM of the memory 10B. Various application programs including the OS (operating system) which is a basic program and the power charge management program 10F1 loaded from the power charge management server 10 are loaded in the RAM.

The storage device 10F stores an OS program to be executed by the processor 10A, other programs including the power charge management program 10F1, and is appropriately read out and loaded into the RAM of the memory 10B. Further, the storage device 10F stores the power charge management data 10F2 processed based on the power charge management program 10F1. The power charge management data 10F2 includes basic charge unit price, weight charge unit price, data indicating contracted power set for each customer, and power usage measured every unit time (here, 1 hour) by BEMS 14 or watt-hour meter 16. Includes measurement data indicating the quantity. The measurement data indicating the amount of electric power consumption includes, for example, data of "24 hours x 365 days = 8760" as data for one year. Further, various data calculated based on the measured electric energy consumption are added to the electricity rate management data 10F2 in association with the measured data (see FIG. 4).

The display device 10C and the input device 10D are used by the administrator of the electricity rate management server 10. The display device 10C is a liquid crystal display or the like, and the input device 10D is a keyboard, a touch panel, a mouse or the like. The electric power charge management server 10 provides the electronic device 18 with information on the electric power charge via the network 12, but the information on the electric power charge can also be viewed on the display device 10C. The processor 10A displays information in the same manner as the information regarding the power charge provided to the electronic device 18 in response to the operation of the input device 10D, and also displays each data included in the power charge management data 10F2.

The communication device 10E executes control for communicating with the BEMS 14, the power meter 16, and the electronic device 18 via the network 12 under the control of the processor 10A.

FIG. 3 is a block diagram showing a functional configuration realized by the processor 10A executing the power charge management program 10F1.

The processor 10A realizes each function of the power charge menu selection processing unit 20, the display function processing unit 24, and the power usage record processing unit 26 based on the power charge management program 10F1.

The electricity charge menu selection processing unit 20 includes an electricity charge unit price setting unit 20A, a contract electric energy input unit 20B, a total unit price graph creation unit 20C, and a time amount graph creation unit 20D. Further, the display function processing unit 24 includes a total unit price / load factor / actual display unit 24A, an hour amount / load factor / actual display unit 24B, and a power charge integration counter display unit 24C. Further, the electric power consumption actual processing unit 26 includes an electric power consumption measurement unit 26A, a load factor calculation unit 26B, a total unit price calculation unit 26C, a total unit price actual creation unit 26D, and a time amount actual production unit 26E.

The electricity rate unit price setting unit 20A sets the basic rate unit price (¥ / kWh) of the electricity rate and the metered rate unit price (¥ / kWh) per unit time for each time zone. As the pay-as-you-go unit price, for example, different unit prices are set for each time zone of day time, night time, and heavy time.

The contracted electric energy input unit 20B inputs the contracted electric energy (kW).

The electricity rate unit price setting unit 20A and the contracted electric energy amount input unit 20B display, for example, the electricity rate menu screen and select the setting items provided on the electricity rate menu screen to select the basic rate unit price and the metered rate per unit time. The unit price and contracted electric energy can be set. The selection of the selection item may be executed, for example, by the operation of the electronic device 18 by the consumer, or by the operation of the input device 10D by the administrator of the electricity rate management server 10.

The total unit price graph creation unit 20C creates a total unit price graph showing the relationship between the load factor calculated by the load factor calculation unit 26B and the total unit price calculated by the total unit price calculation unit 26C. The calculation of the load factor will be described later.

The time amount graph creation unit 20D creates an hour amount graph showing the relationship between the load factor calculated by the load factor calculation unit 26B and the electricity charge per unit time.

The display function processing unit 24 is a process for displaying the power charge per unit time charged to the consumer based on the processing results of the power charge menu selection processing unit 20 and the power usage record processing unit 26. To execute. In addition to displaying on the display device 10C of the electricity rate management server 10, the display function processing unit 24 displays on the display device (not shown) of the electronic device 18 via the network 12 in response to a request from the electronic device 18.

The total unit price / load factor / performance display unit 24A displays the total unit price graph created by the total unit price graph creation unit 20C, and corresponds to the load factor according to the total unit price performance created by the total unit price performance creation unit 26D. Display the total unit price in the graph.

The time amount / load factor / result display unit 24B displays the time amount graph created by the time amount graph creation unit 20D, and corresponds to the load factor according to the time amount result created by the time amount result creation unit 26E. Display the electricity charge per hour in the graph.

The electricity rate integration counter display unit 24C displays the electricity rate integration counter including the integrated value of the electricity rate corresponding to each measurement data according to the time amount actual result created by the time amount record creation unit 26E. Not only the integrated value but also the numerical value set in the electricity charge menu selection processing unit 20 and the time amount actualizing unit 26E of the electric power usage amount actual processing unit 26 are obtained by the processing of each unit except the integrated value. Numerical values can be displayed.

The electric power consumption measuring unit 26A receives data indicating the electric power used in the customer's equipment from the BEMS 14 or the electronic device 18 through the communication device 10E, and measures the electric power consumption per unit time.

The load factor calculation unit 26B calculates the load factor based on the contracted power amount and the power consumption per unit time. The load factor represents the ratio of the maximum power to the average power in a certain period. For example, the annual average load factor, the daily average load factor, the hourly load factor, etc. are calculated for each period, and can be calculated by the following formula.

(Load factor%) = (Average power of period kWh / h) / (Maximum power of period kW) × 100
In the present embodiment, the time load factor for each hour is calculated in order to manage the unit time as one hour. In the calculation of the time load factor, (average power kWh / h during the period) is measured every hour (power consumption kWh per hour), and (maximum power kW during the period) is defined as (contract power kW) as follows. It can be calculated by the formula of.

(Time load factor%) = (1 hour power consumption kWh / h) / (contract power kW) x 100
In the following description, the time load factor will be used, and will be described simply as the load factor. Generally, the higher the load factor, the cheaper the electricity charge, and conversely, the lower the load factor, the higher the electricity charge. That is, if the same amount of electricity is used (if the equipment is to be subjected to the same amount of work (electric energy)), the electricity charge will be cheaper if the operation is performed so that the load factor is high.

The total unit price calculation unit 26C is based on the first unit price per unit time based on the basic charge unit price, the contracted power amount, and the power consumption per unit time, and the metered charge unit price for each time zone. The total unit price per unit time is calculated based on the second unit price per unit time. That is, the total unit price calculation unit 26C adds up the basic charge unit price (fixed cost) and the metered charge unit price (variable cost) for each customer and rebates the total unit price (yen) by the amount of electricity used per hour (kWh). / KWh) is calculated, and the total unit price is multiplied by the amount of electricity used measured in 1-hour units so that the hourly electricity rate can be calculated.

The total unit price calculation unit 26C calculates the total unit price based on, for example, the following formula.

Total unit price = (basic charge unit price (yen / kWh)) x (contract power (kW)) / (electricity usage per hour (kWh)) / (hours per month) + (time zone used Pay-as-you-go unit price (yen / kWh))
In the above formula, "(contract power (kW)) / (electricity consumption per hour (kWh)" corresponds to "1 / (time load factor)", and other numerical values are constant, so the total The unit price can be uniquely obtained by the load factor. Therefore, based on the load factor calculated by the load factor calculation unit 26B, the total unit price graph creation unit 20C creates the total unit price graph and the time amount graph creation unit. It is possible to create a time amount graph in 20D.

Based on the total unit price calculated by the total unit price calculation unit 26C, the total unit price actual creation unit 26D is the total unit price corresponding to the load factor of the time for which the electricity rate is calculated (the total according to the load factor of the time). Unit price) is created as the total unit price result.

The hourly amount actual result creation unit 26E is based on the total unit price calculated by the total unit price calculation unit 26C and the amount of electricity used per unit time for which the electricity rate is calculated, and the unit time corresponding to the load factor. Create an electricity rate (electricity rate paid by the consumer per hour) as a time record. The hourly amount record creation unit 26E calculates the electricity charge per unit time (1 hour) (electricity charge (yen) per hour at that time) by "total unit price x (electricity consumption kWh per hour)". To do.

FIG. 4 is a diagram showing an example of the electricity rate management data 10F2. The electricity rate management data 10F2 is continuously recorded for 24 hours throughout the year (365 days), distinguishing each consumer. FIG. 4 shows a part of one year's worth of data recorded for one consumer.

In the electric energy charge management data 10F2, time item 30 (yyy / mm / dd / h: year / month / day / hour, week: day, year: year, month: month, day: day, how: time), electric energy item 32 (KWh / h: Electric energy 32a, kW: Contract power 32b), Load factor 36 (Lodratio: Load factor%), Unit price setting item 38 (¥ / kWh: Basic charge unit price 38a, ¥ / kWh: Pay-as-you-go unit price 38b ), Total unit price item 42 (¥ / kWh / h: basic charge per hour 42a, ¥ / kW / h / kWh: total unit price of basic charge 42b), display amount item 46 (User kWh yen / h: 1 hour) Pay-as-you-go charge amount 46a, User yen / h / kWh: Total unit price (total unit price according to the load factor at that time) 46b, User total yen / h: Electric energy charge paid by the consumer per hour 46c) Is done.

The electric energy 32a of the electric energy item 32 is stored by the electric energy measuring unit 26A, and the contracted electric energy 32b is stored by the contracted electric energy input unit 20B. The load factor 36 is stored by the load factor calculation unit 26B based on the data of the electric energy item 32. The basic charge unit price 38a and the metered charge unit price 38b of the unit price setting item 38 are stored by the electricity charge unit price setting unit 20A. The basic charge 42a per hour of the total unit price item 42 and the total unit price 42b of the basic charge are stored by the total unit price calculation unit 26C. The metered rate amount 46a per hour of the displayed amount item 46, the total unit price (total unit price according to the load factor of the time) 46b, and the electricity charge 46c paid by the consumer per hour are the total unit price actual creation unit 26D or It is stored by the time amount record creation unit 26E.

Next, the operation of the electricity rate management server 10 in this embodiment will be described.

FIG. 5 is a flowchart showing the electricity charge menu selection process by the electricity charge menu selection processing unit 20, FIG. 6 is a flowchart showing the electricity usage actual processing by the electric power usage actual processing unit 26, and FIG. 7 is a display function processing unit. It is a flowchart which shows the display function processing by 24.

In order to manage the electricity charges of the consumer, the electricity charge management server 10 manages the electricity charges of the customer in advance with respect to the basic charge unit price (¥ / kW) of the electricity charge and the metered amount per unit time for each time zone. Set the unit price (¥ / kWh) and the contracted power amount. For example, the processor 10A displays the power charge menu screen according to the access from the electronic device 18, and selects the setting items provided on the power charge menu screen to select the basic charge unit price and the metered charge per unit time. Set the unit price and contracted electric energy (steps A1 and A2). As the metered rate unit price, different unit prices are set for each time zone such as day time, night time, and heavy time.

After that, the processor 10A additionally stores the set basic charge unit price, the metered charge unit price per unit time, and the contracted electric energy in the electric power charge management data 10F2 corresponding to the customer.

After the information necessary for managing the power charge is set, the power charge management server 10 reaches the measurement time set for each preset unit time (here, 1 hour) (FIG. 6, steps B1, Yes). ), Receives data indicating the amount of power consumption measured from the BEMS 14 or the power meter 16 provided in the customer's equipment. That is, the processor 10A measures the power consumption per unit time by the power consumption measurement unit 26A (step B2).

The processor 10A calculates the load factor by the load factor calculation unit 26B (step B3), calculates the total unit price by the total unit price calculation unit 26C (step B4), and creates the total unit price result according to the reception of the data indicating the power consumption. Calculation of the total unit price (total unit price according to the load factor at that time) by the unit 26D (step B5), calculation of the electricity charge per unit time corresponding to the load factor by the time amount actual creation unit 26E (step B5) Step B6) is executed, and each data is associated with each other and added to the electricity charge management data 10F2 as shown in FIG. 4 (step B7).

Less than. Similarly, each time the measurement time is reached, the power charge management server 10 receives data from the BEMS 14 or the power meter 16 (steps B1 and B2), and executes the same processing as described above (steps B3 to B7). ).

On the other hand, the processor 10A uses the total unit price graph showing the relationship between the load factor calculated by the load factor calculation unit 26B and the total unit price calculated by the total unit price calculation unit 26C by the total unit price graph creation unit 20C. It is created according to the total unit price calculated based on the data of the quantity 32a (step A3). Here, a total unit price graph corresponding to each of the different pay-as-you-go unit prices set for each of the day time, night time, and heavy time is created.

Further, the processor 10A also displays a time amount graph showing the relationship between the load factor calculated by the load factor calculation unit 26B by the time amount graph creation unit 20D and the power charge per unit time, and data of the power consumption 32a. It is created according to the time amount (electricity charge per hour) calculated in (step A4). The hourly amount graph shall also be created corresponding to each of the different pay-as-you-go unit prices set for each time zone.

Next, the processing of the display function processing unit 24 by the processor 10A will be described (FIG. 17).

The processor 10A provides information for managing the electricity charge based on the power charge management data 10F2, for example, in response to a request from the electronic device 18. In the present embodiment, for example, a total unit price graph (total unit price display) showing the relationship between the load factor and the total unit price, an hour amount graph (hour amount display) showing the relationship between the load factor and the electricity rate per unit time, and electric power. Any one of the electricity charge integration counters including the charge integration value can be arbitrarily selected and displayed.

When the electronic device 18 requests the total unit price display (steps C1, Yes), the processor 10A has the total unit price graph created by the total unit price graph creation unit 20C and the total unit price of the power charge management data 10F2 (load for that time). Based on the total unit price (total unit price according to the rate) 46b, the total unit price graph is displayed on the electronic device 18 via the network 12 (step C2).

FIG. 8 shows a display example of the total unit price graph 50 in this embodiment. In the total unit price graph 50 shown in FIG. 8, the vertical axis shows the total unit price (yen / kWh), the horizontal axis shows the load factor (%), and ◯: 1 hourly power usage points.

In FIG. 8, the first graph A (total daytime unit price curve) corresponding to the daytime (day time), the second graph (total nighttime unit price curve) corresponding to the nighttime (night time), and the peak time (heavy time) are shown for each time zone. The third graph C (peak time total unit price curve) corresponding to) is displayed, and the total unit price corresponding to the power usage point of the power charge management data 10F2 is displayed on the graphs of the first to third graphs A, B, and C. The graph shown is displayed at the position associated with the load factor.

The plot (power usage point) displayed on the total unit price graph 50 is displayed corresponding to the data of "24 hours x 365 days = 8760", which is data for one year, for example. However, the number of plots to be displayed can be changed by selecting an arbitrary period (1 month, several months, any period specified by the date, multiple years, etc.) from the electronic device 18 by the operation of the consumer. You may be able to do it.

As shown in FIG. 8, in the total unit price graph 50, a total unit price curve with the load factor as the horizontal axis is displayed, and which load factor of the total unit price curve (graph) the target demand occupies, the load factor and the total It becomes possible to easily grasp the correlation of unit prices.

For example, in the case of a customer with a high load factor, the plots are concentrated at the position of the high load factor (for example, 80% or more) in each of the first to third graphs A, B, and C. Conversely, in the case of consumers with a low load factor, the plots are concentrated on the part where the total unit price is high (the load factor is low). For example, in the third graph C corresponding to the peak time (heavy time), if the plots are concentrated in the portion where the total unit price is high (the load factor is low), the load factor at the peak time is in another time zone (daytime). It can be easily recognized that it is lower than (at night), and it can be understood that the total unit price can be lowered by changing the power consumption during peak hours and increasing the load factor. That is, it is possible to quantitatively evaluate the effect of reducing electricity charges based on the total unit price graph 50.

Next, when the electronic device 18 instructs the processor 10A to end the display of the total unit price graph 50 (steps C3, Yes) and the time amount display is requested (steps C4, Yes), the time amount graph creation unit 20D causes the processor 10A. Based on the created time amount graph and the electricity charge 46c paid by the consumer per hour of the power charge management data 10F2, the time amount graph is displayed on the electronic device 18 via the network 12 (step C5).

FIG. 9 shows a display example of the time amount graph 52 in this embodiment. In the time amount graph 52 shown in FIG. 9, the vertical axis indicates the power charge (yen) per hour, the horizontal axis: the load factor (%), and ◯: the power usage point for each hour.

In FIG. 9, the first graph A (daytime metered rate gradient line) corresponding to day time, the second graph (night metered rate gradient line) corresponding to night time, and peak hours (daytime metered rate gradient line) are shown for each time zone. The third graph C (peak time metered rate gradient straight line) corresponding to (heavy time) is displayed, and corresponds to the power usage point of the power rate management data 10F2 on the graphs A, B, and C of the first to third graphs A, B, and C. A graph showing the hourly electricity rate is displayed at the position associated with the load factor. In the time amount graph 52, the lowest values of the first to third graphs A, B, and C represent the magnitude (basic charge) of the contracted power.

The correlation between the load factor and the total unit price can be grasped by the above-mentioned total unit price graph 50, but in order to verify the reduction effect as the (annual) total power cost (total cost), the load factor and the total cost unit price (1) The correlation between the basic charge per hour and the unit price, which is the sum of the metered charges) is represented by the hourly amount graph 52.

As the load factor increases, the amount of electricity used increases, so the total cost unit price also increases linearly in proportion. This proportional coefficient appears as the slope of graphs A, B, and C in the first to third graphs. For example, if the power consumption decreases due to energy saving, the slope of the graph becomes gentle, and if the contracted power decreases by increasing the load factor, The slope of the graph does not change, but the whole is shifted downward, and the total cost can be reduced.

Here, if the load factor can be increased and the graph can be moved horizontally to the right, more power can be used at the same cost, and if the load factor is the same, the graph can be shifted vertically downward. It is possible to verify the "shift effect" that can reduce the total cost. That is, it is possible to quantitatively evaluate the effect of reducing the electricity rate based on the time amount graph 52.

Next, when the electronic device 18 instructs the end of the display of the time amount graph 52 (step C6, Yes) and the integration counter display is requested (step C7, Yes), the processor 10A powers the processor 10A via the network 12. The charge integration counter is displayed on the electronic device 18 (step C8).

FIG. 10 shows a display example of the electricity rate integration counter 56 in this embodiment. The electricity rate integration counter 56 is displayed together with the total unit price graph 54, for example, as shown in FIG. The electric power charge integration counter 56 displays the integrated value of the electric power charge for each data of the electric power usage amount 32a of the electric power charge management data 10F2. In the electricity charge integration counter 56 shown in FIG. 10, each data related to the hourly electricity charge integrated into the integrated value of the electricity charge, that is, the date time, the load factor, the total unit price, the power consumption, and the like. Display contract power and contract unit price data. As a result, each data related to the hourly power charge accumulated in the integrated value of the power charge can be easily confirmed.

As described above, the data to be integrated at the electricity rate integration counter 56 may be data for one year, or may be operated by the consumer from the electronic device 18 for an arbitrary period (one month, several months, etc.). It may be possible to change it by selecting an arbitrary period by specifying the date, multiple years, etc.).

Further, in the total unit price graph 54, in the power charge integration counter 56, according to the corresponding data related to the electricity charge per hour accumulated in the integrated value of the electricity charge, the first is performed in the same manner as in the total unit price graph 50. In any of the graphs A, B, and C of the third graph, the plot D showing the total unit price is displayed at the position associated with the load factor.

The processor 10A sequentially updates the data to be displayed in the power charge management data 10F2 (steps C9, Yes), and updates the display of the power charge integration counter 56 in the same manner as described above according to the updated data (step C9, Yes). Step C8). Further, the processor 10A updates the display position of the plot D indicating the total unit price according to the updated data. As a result, it is possible to confirm the update of the electricity charge integration counter 56 and the integrated value in association with the change in the total unit price in the total unit price graph 54.

Next, when the electronic device 18 instructs the processor 10A to end the display of the electricity rate integration counter 56 (steps C10, Yes), the processor 10A is in a state of waiting for an instruction from the electronic device 18 as described below.

In the above description, the power charge integration counter 56 is displayed based on the data set in the power charge management data 10F2, but it is displayed according to the latest data received from, for example, the BEMS 14 or the electronic device 18. You may do so. That is, it can also be used for real-time monitoring of power usage in consumer equipment.

In this way, the power charge management server 10 in the present embodiment displays the total unit price and the power charge per unit time based on the data received from the BEMS 14 or the electronic device 18, so that the power charge reduction effect is quantitative. Can be evaluated.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 ... Electricity rate management server, 10A ... Processor, 10B ... Memory, 10C ... Display device, 10D ... Input device, 10E ... Communication device, 10F ... Storage device, 10F1 ... Electricity rate management program, 10F2 ... Electricity rate management data, 12 ... network, 14 ... BEMS, 16 ... electricity meter, 18 ... electronic equipment.

Claims (6)

Electricity rate unit price setting unit that sets the basic rate unit price of electricity rate and the metered rate unit price per unit time for each time zone,
The contracted electric energy input section for inputting the contracted electric energy and
The power consumption measurement unit that measures the power consumption per unit time,
The first unit price per unit time based on the basic charge unit price calculated by using the basic charge unit price, the contracted electric energy amount, and the power consumption per unit time, and the unit time based on the metered charge unit price for each time zone. The total unit price calculation unit that calculates the total unit price per unit time based on the second unit price per unit,
Based on the amount of electricity used per unit time for the time for which the total unit price and the electricity rate are to be calculated, the time amount actual creation unit that calculates the electricity rate per unit time, and
An electric power charge management device having a display function processing unit for displaying the electric power charge per unit time. The power charge management device according to claim 1, wherein the display function processing unit displays the power charge per unit time of each time to be calculated for each time zone. A load factor calculation unit that calculates a load factor based on the contracted power amount and the power consumption per unit time,
It also has a total unit price graph creation unit that creates a total unit price graph showing the relationship between the load factor and the total unit price.
The electricity rate management device according to claim 1, wherein the display function processing unit displays the total unit price graph. The power charge management device according to claim 3, wherein the display function processing unit displays the power charge per unit time in the total unit price graph. A load factor calculation unit that calculates a load factor based on the contracted power amount and the power consumption per unit time,
It also has a time amount graph creating unit that creates a time amount graph showing the relationship between the load factor and the electricity rate per unit time.
The electricity rate management device according to claim 1, wherein the display function processing unit displays the time amount graph. Set the basic unit price of electricity charges and the metered unit price per unit time for each time zone,
Enter the contracted electric energy and
Measure the amount of electricity used per unit time,
The first unit price per unit time based on the basic charge unit price calculated by using the basic charge unit price, the contracted electric energy amount, and the power consumption per unit time, and the unit time based on the metered charge unit price for each time zone. Calculate the total unit price per unit time based on the second unit price per unit,
The electricity charge per unit time is calculated based on the amount of electricity used per unit time for the time for which the total unit price and the electricity charge are to be calculated.
An electricity rate management method for displaying the electricity rate per unit time.