JP7209279B2 - Energy trading device, program - Google Patents

Description

The present invention relates to an energy trading device and a program.

In recent years, efforts have been proposed in light of the termination of the feed-in tariff system for renewable energy (hereinafter sometimes referred to as the "FIT system").
For example, the "Electricity Keeping Service (provisional name)" described in Non-Patent Document 1 allows you to keep surplus electricity even if there is no equipment such as a storage battery in a facility with a photovoltaic power generation facility (for example, a house). It is a service that can be regarded as a service that can be used when it is actually used.
In recent years, a non-fossil value trading market has also been created. This non-fossil value trading market reveals non-fossil value and enables transactions, thereby supporting the achievement of non-fossil power supply procurement targets of retail electricity companies and expanding the options for consumers. It is a new market that contributes to reducing the burden on the public through the FIT system.

TEPCO Energy Partner Co., Ltd., "Next-generation smart town project" utilizing energy and IoT technology, [searched on August 27, 2018], Internet, <URL: http://www.tepco.co.jp/ ep/notice/pressrelease/2018/1477419_8663.html>

Since people who do not use much electricity do not have many opportunities to use the entrusted electricity, the service described in Non-Patent Document 1 is preferable for those who own power generation facilities but do not use electricity much. Absent. Therefore, it is desired to construct a mechanism that is effective even for those who do not use much electric power.
Also, as the non-fossil value trading market was established, it is desired to expand the options for consumers who want to use non-fossil value electricity.
The present invention is an energy that can benefit even those who own power generation facilities but do not use much power, and can realize a system that expands the options of consumers who want to use non-fossil value power. The purpose is to provide a trading device.

The present invention, which has been completed for this purpose, includes a purchased power amount grasping unit for grasping the purchased power amount, which is the amount of electric power purchased from a power seller who has a power generation facility and generates power, and the power purchased amount grasped by the purchased power amount grasping unit. An energy trading device comprising: an emission credit calculation unit that calculates _CO2 emission credits according to the amount of power purchased; and a fuel amount calculation unit that calculates a fuel amount corresponding to the _CO2 emission credits calculated by the emission credit calculation unit. is.
Here, a notification unit may be further provided for notifying the specific consumer of at least part of the fuel quantity calculated by the fuel quantity calculation unit and the fuel quantity supplied to the specific consumer.
Further, the specific consumer may be a person having a power generation device that generates power using the supplied fuel.
In addition, the specific consumer is an electric vehicle that runs using electricity generated by a power generation device that generates electricity using the supplied fuel, and an electric vehicle that uses the supplied fuel to produce hydrogen and uses the produced hydrogen to generate electricity. It may be a fuel cell vehicle that runs on electricity supplied, or a vehicle equipped with an internal combustion engine or an external combustion engine that operates by burning supplied fuel.
Further, a notification unit for notifying the specific consumer of the electric power generated using at least part of the fuel amount calculated by the fuel amount calculation unit and supplied to the specific consumer. can be
Electric power generated by a power generation device that generates power using at least part of the fuel amount calculated by the fuel amount calculation unit may be supplied to the specific consumer.
Further, the electric power seller may generate electric power using renewable energy, and the specific consumer may be a consumer who intends to use RE100.
In addition, the present invention completed for this purpose provides a computer with a function of grasping the amount of power purchased, which is the amount of power purchased from a power seller that generates power with a power generation facility, and a CO ₂ emission credit, and a function of calculating the amount of fuel corresponding to the CO ₂ emission credit.

According to the present invention, it is possible to realize a system that allows even those who own power generation facilities but do not use much power to enjoy benefits and expands the options of consumers who want to use non-fossil value power. can.

BRIEF DESCRIPTION OF THE DRAWINGS It is the figure which illustrated schematic structure of the energy trading system which concerns on 1st Embodiment. It is the block diagram which illustrated the hardware constitutions of the energy trading apparatus. It is a block diagram which illustrated the functional composition of the energy trading device concerning a 1st embodiment. It is a flowchart which shows the trading process which the energy trading apparatus which concerns on 1st Embodiment performs. It is a flowchart which shows the notification process which the energy trading apparatus which concerns on 1st Embodiment performs. It is the figure which illustrated the schematic structure of the energy trading system which concerns on 2nd Embodiment. It is a block diagram which illustrated the functional composition of the energy trading device concerning a 2nd embodiment. It is the figure which illustrated the schematic structure of the energy trading system which concerns on 3rd Embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.
<First Embodiment>
FIG. 1 is a diagram illustrating a schematic configuration of an energy trading system 1 according to the first embodiment.
In the energy trading system 1 according to the first embodiment, a business operator who supplies electric power and gas (hereinafter sometimes referred to as “business operator B”) sells the power generated by itself (hereinafter, “seller”). Electric power supplier G”), and supply fuel in an amount corresponding to the CO ₂ emission rights corresponding to the amount of electric power purchased from the electric power seller G to a specific consumer. It is a system that supplies to a specific consumer S.

Business operator B purchases electric power from electric power seller G, and supplies specific consumer S with an amount of fuel corresponding to the amount of _CO2 emission credits corresponding to the amount of electric power purchased from electric power seller G. You own the energy trading device 100 that implements it.
Business operator B owns a power generation facility 11 that generates power and a fuel supply device 12 that supplies fuel to the power generation facility 11 .
The power generation equipment 11 uses the fuel supplied from the fuel supply device 12 to generate electric power through thermal power generation. The power generated by the power generation facility 11 is supplied to a power grid 60, which is a power system. The power supplied to the power grid 60 is supplied to the general consumer C. The fuel can be exemplified by city gas (main component: methane gas), LPG, and LNG.
The fuel supply device 12 supplies fuel to the power generation equipment 11 through the pipeline. Further, the fuel supply device 12 supplies fuel to the specific consumer S via, for example, a gas pipe network.

The power seller G is, for example, a natural person or a corporation that generates power by itself using renewable energy and sells the generated power.
Power generation using renewable energy performed by the power seller G can be exemplified by solar power generation. Moreover, wind power generation, hydraulic power generation, geothermal power generation, and biomass power generation may be used. The power generated by the power seller G is supplied to the power grid 60 .
The power seller G owns a power generation facility 21 that generates power using renewable energy, and a known power amount measuring device 22 that measures the amount of power and has a function of communicating with the energy trading device 100 .

The power generation equipment 21 can be exemplified as a photovoltaic power generation equipment (hereinafter sometimes referred to as “solar cell”). In addition, facilities for wind power generation, hydraulic power generation, geothermal power generation, and biomass power generation may be used. In addition, the power generation equipment 21 may not be a power generator using renewable energy, and may be a fuel cell power generator (hereinafter sometimes referred to as a "fuel cell") or the like. It may be equipment capable of generating power.
The power amount measuring device 22 measures the amount of power supplied (reverse power flow) to the power grid 60 (hereinafter sometimes referred to as "reverse power flow amount") out of the power generated by the power generation equipment 21. . Then, the power amount measuring device 22 transmits the measured reverse flow power amount to the energy trading apparatus 100 together with an ID stored in advance in association with the power seller G as information for identifying the power seller G. In addition, the power measuring device 22 measures the amount of power used by the power seller G, and transmits the measured amount of power used together with the ID of the power seller G to the energy trading apparatus 100 .
In addition, the power seller G may be singular or plural.

The specific consumer S is, for example, an RE100-oriented consumer, such as a company aiming to procure 100% renewable energy for its business operations.
The specific consumer S measures the amount of fuel supplied from the business operator B and communicates with the power generation device 31 that generates power using the fuel supplied from the business operator B's fuel supply device 12 and the energy trading device 100 . It possesses a known fuel amount measuring device 32 having a function.

The power generation device 31 is a well-known SOFC (solid oxide fuel cell) or PCFC that generates electric power through an electrochemical reaction between a fuel such as hydrocarbon (methane, propane, butane, etc.) or hydrogen and oxygen in the air. (Proton Conducting Solid Oxide Fuel Cell) or PEFC (Polymer Electrolyte Fuel Cell). Alternatively, the power generation device 31 may be a device that generates power with a gas engine or a gas cogeneration system. From the viewpoint of power generation efficiency, the power generation device 31 is most preferably SOFC or PCFC. In the first embodiment, the power generation device 31 uses gas supplied by the operator B as fuel.

The fuel amount measuring device 32 measures the amount of fuel supplied from the fuel supply device 12 of the operator B to the power generation device 31 . Then, the fuel amount measuring device 32 transmits the measured fuel amount to the energy trading apparatus 100 together with an ID stored in advance in association with the specific consumer S as information for identifying the specific consumer S.

At least part of the amount of fuel supplied from the fuel supply device 12 of the business operator B to the power generation device 31 is the amount of fuel corresponding to the CO ₂ emission rights corresponding to the amount of power purchased from the power seller G. The amount of fuel corresponding to the CO ₂ emission right is the amount of fuel predetermined between the business operator B and the specific consumer S. This fuel amount can be exemplified by being determined on a monthly basis or a yearly basis.
The specific consumer S consumes the power generated by the power generator 31 . Since at least part of the fuel amount supplied to the power generation device 31 is the fuel amount corresponding to the _CO2 emission credit, the power generated by the power generation device 31 is the power associated with the _CO2 emission credit. is. The manner in which the specific consumer S consumes the power generated by the power generator 31 is not particularly limited. For example, the specific consumer S may consume power to operate lighting fixtures, air conditioners, PCs, etc. necessary for business operations. Further, the specific consumer S may have an electric vehicle (EV), store electric power generated by the power generation device 31, and run using the stored electric power.
In this way, the specific consumer S differs from the general consumer C in that it receives a predetermined supply of fuel from the business operator B.

Further, the specific consumer S may be supplied with power from the power grid 60 when the amount of power consumed is greater than the amount of power generated by the power generator 31 . If the specific customer S receives power supply from the power grid 60, the specific customer S may also be the general customer C.
Note that the specific consumer S may be singular or plural.

Further, in the above-described embodiment, the power generated by the power generation equipment 11 and the power not consumed in the power generated by the power generation equipment 21 are supplied to the power grid 60, which is the power system. It is not particularly limited to such an aspect. For example, it may be supplied to a privately owned transmission and distribution network separate from the power grid 60 maintained within a certain area.

The energy trading device 100 will be described in detail below.
FIG. 2 is a block diagram illustrating the hardware configuration of the energy trading device 100. As shown in FIG.
The energy trading device 100 has a computer capable of executing various types of information processing. The energy trading device 100 includes a control unit 101 that controls the entire device, a storage unit 102 that stores data and the like, a display unit 103 that displays operation reception screens and images, and receives user input operations. It has an operation unit 104 and a communication unit 105 used for communication with an external device.

The control unit 101 includes a CPU (Central Processing Unit) 101a, a ROM (Read Only Memory) 101b, and a RAM (Random Access Memory) 101c. The ROM 101b stores a basic program (operating system) executed by the CPU 101a, various settings, and the like. The CPU 101a uses the RAM 101c as a work area and executes application programs read from the ROM 101b or the storage unit 102. FIG. The function of each part of the energy trading device 100 is realized by the CPU 101a executing the program.

The storage unit 102 can be exemplified by a storage device such as a semiconductor memory. The storage unit 102 may be an HDD (Hard Disk Drive).
The display unit 103 is a display device that displays still images, moving images, and the like. The display unit 103 can be exemplified by a liquid crystal display or an organic EL (Electro Luminescence) display.
An operation unit 104 is an input device that receives an operation from a user. The operation unit 104 can be exemplified by buttons, switches, and a touch panel.

The communication unit 105 can be exemplified as a communication interface (communication I/F). The energy trading device 100 can communicate with the electricity seller G's power amount measuring device 22 and the specific consumer's S fuel amount measuring device 32 via a network. The network is not particularly limited as long as it is a communication network used for data communication between devices, and examples thereof include the Internet, WAN (Wide Area Network), and LAN (Local Area Network). The communication line used for data communication may be wired or wireless, and both may be used. Further, a relay device such as a gateway device or a router may be used to connect each device via a plurality of networks or communication lines.

The program executed by the CPU 101a is stored in a computer-readable recording medium such as a magnetic recording medium (magnetic tape, magnetic disk, etc.), an optical recording medium (optical disk, etc.), a magneto-optical recording medium, a semiconductor memory, or the like. can be provided with Moreover, you may make it download to the energy trading apparatus 100 using communication means, such as the internet.

FIG. 3 is a block diagram illustrating the functional configuration of the energy trading device 100 according to the first embodiment.
The energy trading device 100 includes a receiving unit 110 that receives information sent from the electric energy measuring device 22 of the power seller G or the fuel amount measuring device 32 of the specific consumer S via the communication unit 105. there is
The energy trading apparatus 100 also includes a reverse power flow grasping unit 120 that grasps the reverse power flow power amount measured by the power amount measuring device 22 based on the information received by the receiving unit 110 . The reverse power flow amount is the amount of power purchased by the business operator B from the power seller G. Therefore, the reverse power flow rate grasping unit 120 functions as a purchased power amount grasping unit that grasps the purchased power amount, which is the amount of power purchased from the power seller G.

The energy trading device 100 also includes an emission credit calculation unit 130 that calculates CO ₂ emission credits for the amount of reverse power flow (purchased power amount) grasped by the reverse power flow rate grasping unit 120 .
The energy trading device 100 also includes an emission credit corresponding fuel amount calculation unit 140 that calculates the fuel amount corresponding to the CO ₂ emission credit calculated by the emission credit calculation unit 130 .
The energy trading device 100 also includes a supply instruction unit 150 that instructs the fuel supply device 12 to supply the specific consumer S with fuel.
The energy trading device 100 also includes a supplied fuel amount grasping unit 160 that grasps the fuel amount measured by the fuel amount measuring device 32 of the specific consumer S based on the information received by the receiving unit 110 .
The energy trading device 100 also includes a notification unit 170 that notifies the specific consumer S of the amount of fuel supplied by the fuel supply device 12 .

The reverse power flow rate grasping unit 120 grasps the reverse power flow power amount of the power seller G when the receiving unit 110 receives the reverse power flow power amount sent from the power seller G's power amount measuring device 22. At the same time, the reverse flow power amount is stored in the storage unit 102 in association with the ID of the power seller G. FIG. The reverse power flow rate grasping unit 120 may grasp and store the reverse power flow power amount every time it is sent from the power amount measuring device 22, or for example, the reverse power flow power amount sent every 30 minutes. The cumulative value may be grasped and stored, for example, in units of days or months.

The emission credit calculation unit 130 calculates the CO ₂ emission credit R (CO ₂ -kg) using, for example, the following calculation formula (1).
R=k×(1−x)×e (1)
Here, k is a CO ₂ reduction constant corresponding to the power plant 21, and the unit is CO ₂ -kg/kWh. When the power generation equipment 21 is a solar cell, k is a value determined annually by each electric power company. It is a numerical value that is decided as a publicly known value based on past results every year. If the power generation equipment 21 is a generator other than a solar cell, such as a fuel cell, k can be calculated using the following formula (2).
k=(E1−E2)×C (2)
Here, E1 is the power generation efficiency of the fuel cell, E2 is the power generation efficiency of the power plant, and C is the carbon dioxide intensity announced by a major power company. Note that E1 may be the total efficiency including heat utilization of the fuel cell.
Alternatively, k may be calculated by the following calculation formula (3).
k=E1×C1−E2×C2 (3)
Here, C1 is the carbon dioxide emission coefficient (CO ₂ -kg/kWh) of the fuel cell, and C2 is the carbon dioxide intensity announced by a major power company.

x in the above calculation formula (1) is emissions during manufacture of the power generation equipment 21, which is used when considering life cycle CO2 (LCCO2) (when calculating and evaluating _CO2 emissions per year of building life) is the _CO2 factor. x is a value (no unit) from 0 to 1, and is determined to be a larger value as more CO ₂ is emitted during construction of the power generation facility 21 . It is 0 if manufacturing emissions _CO2 are ignored.
e in the above calculation formula (1) is the amount of electric power (kWh) generated by the power generation equipment 21 .
It should be noted that the calculation formula is an example, and can be changed in accordance with the laws and regulations related to the electric power industry and its actual situation.

The emission credit corresponding fuel amount calculation unit 140 calculates the city gas (methane gas) amount M(m ³ ) corresponding to the CO ₂ emission credit R using the following calculation formula (4), for example.
M=R×12/44×V×l (4)
Here, V is a conversion coefficient to volume, and under standard conditions, V=0.224 (m ³ /mol). l is a correction factor due to gas composition. For example, when LPG is supplied, the composition is different from city gas, so a correction factor is used. For example, l is 1.

The supply instruction unit 150 instructs the fuel supply device 12 to supply the specific consumer S with fuel. For example, if (i) the monthly or yearly supply amount is determined between the business operator B and the specific consumer S, the supply instruction unit 150 determines the monthly or yearly supply amount. the recommended amount. Further, the supply instruction unit 150 may, for example, instruct (ii) to supply the amount of fuel used by the specific consumer S. In addition, the supply instruction unit 150, for example, (iii) instructs to supply the amount of fuel corresponding to the CO ₂ emission rights corresponding to the electricity purchased from the specific electricity seller G (there may be a plurality of electricity sellers). can be

When the receiving unit 110 receives the fuel amount sent from the fuel amount measuring device 32 of the specific consumer S, the supplied fuel amount grasping unit 160 determines the fuel amount supplied to the specific consumer S (supplied fuel amount ) is grasped, and the supplied fuel amount is stored in the storage unit 102 in association with the ID of the specific consumer S. The supplied fuel amount grasping unit 160 may grasp and store the supplied fuel amount each time it is sent from the fuel amount measuring device 32, or for example, the cumulative value of the supplied fuel amount sent every 30 minutes. may be grasped and stored, for example, in units of days or months.

The notification unit 170 notifies the specific consumer S of the amount of fuel supplied by the fuel supply device 12 (supplied fuel amount), and also informs the specific consumer S of the fuel amount corresponding to the CO ₂ emission credit R (emission credit corresponding fuel quantity) is also notified. The notification unit 170 notifies, for example, at a predetermined time on a predetermined day of every month or at a predetermined time on a predetermined day of a predetermined month every year. Hereinafter, these may be referred to as "notification time".

For example, in the case of (i) above, since the supply amount is predetermined, when the entire amount is supplied, the predetermined amount becomes the supply fuel amount. In the case of (ii) above, the supplied fuel amount is the amount measured by the fuel amount measuring device 32 . In both cases (i) and (ii) above, if the monthly or yearly amount of fuel for emission credits is determined in advance between business operator B and specific consumer S, The determined amount is the amount of fuel corresponding to emission rights. If the amount of electric power purchased by the business operator B from the power seller G is large and the amount of fuel supplied can be covered by the amount of fuel corresponding to emission rights, the amount of fuel corresponding to emission rights is the same as the amount of fuel supplied. On the other hand, if the amount of electricity purchased by business operator B from power seller G is not large enough to cover the amount of fuel supplied, the amount of fuel corresponding to emission rights is greater than the amount of fuel supplied. a small amount.
In addition, in the case of (iii) above, only the amount of fuel corresponding to the CO ₂ emission rights corresponding to the power purchased from the specific power seller G (may be more than one) is supplied to the specific consumer S. Therefore, the corresponding amount of fuel becomes the amount of fuel corresponding to emission rights and the amount of supplied fuel.

FIG. 4 is a flowchart showing calculation processing performed by the energy trading device 100 according to the first embodiment. The energy trading device 100 repeatedly executes this calculation process at predetermined intervals (for example, one minute).

The energy trading device 100 determines whether or not the receiving unit 110 has received the reverse flow power amount from the power seller G's power amount measuring device 22 (S401). This is a process determined by the reverse flow rate grasping unit 120 . Then, when the receiving unit 110 receives the reverse flow power amount (Yes in S401), the energy trading device 100 grasps the reverse power flow power amount of the power seller G, associates it with the ID of the power seller G, and The power flow amount is stored in the storage unit 102 (S402). After that, the energy trading device 100 calculates the CO ₂ emission right R according to the reverse flow power amount (purchased power amount) grasped in S402 (S403). This is a process performed by the emission credit calculation unit 130 using the above calculation formula (1). After that, the energy trading device 100 calculates a city gas (methane gas) amount M (m ³ ) corresponding to the CO ₂ emission credit R calculated in S403 (S404). This is a process of calculation by the emission credit corresponding fuel amount calculation unit 140 using the above calculation formula (4).
In S401, if the receiving unit 110 has not received the reverse power flow amount (No in S401), this process is terminated.

FIG. 5 is a flowchart showing notification processing performed by the energy trading device 100 according to the first embodiment. The energy trading device 100 repeatedly executes this notification process at predetermined intervals (for example, one minute). Note that the notification processing illustrated in FIG. 5 is processing in the case of (ii) above, that is, when the amount of supplied fuel is the amount measured by the fuel amount measuring device 32 .
The energy trading device 100 determines whether or not the receiving unit 110 has received the supplied fuel amount from the fuel amount measuring device 32 of the specific consumer S (S501). This is a process determined by the supplied fuel amount grasping unit 160 . Then, when the receiving unit 110 receives the supplied fuel amount (Yes in S501), the supplied fuel amount grasping unit 160 grasps the supplied fuel amount to the specific consumer S and associates it with the ID of the specific consumer S. The supplied fuel amount is stored in the storage unit 102 (S502).
After that, the notification unit 170 determines whether or not the above-described notification time at which the specific consumer S should be notified has come (S503). Then, when the notification time has come (Yes in S503), the energy trading device 100 notifies the specific consumer S of the supplied fuel amount and the emission credit corresponding fuel amount (S504). On the other hand, if the notification time has not come (No in S503), the notification process is terminated.
Further, in S501, if the receiving unit 110 has not received the supplied fuel amount (No in S501), the process proceeds to S503.
In addition, if the fuel amount measuring device 32 is a device that also has a function to measure the amount of fuel returned from the specific consumer S to the business operator B, from the supplied fuel amount measured by the fuel amount measuring device 32 Alternatively, the amount obtained by subtracting the returned fuel amount measured by the fuel amount measuring device 32 may be notified as the final supplied fuel amount. Alternatively, if a device for measuring the amount of fuel returned from the specific consumer S to the business operator B is provided separately from the fuel amount measuring device 32, the returned fuel amount received from the device is measured by the fuel amount measuring device 32. The amount obtained by subtracting from the supplied fuel amount measured in 1. may be notified as the final supplied fuel amount. In such a case, for example, when the above notification time comes, fuel supply for a certain period (one month if the notification time is set at a predetermined time on a predetermined day of every month) The amount obtained by subtracting the returned fuel amount for a certain period from the amount may be notified as the final supplied fuel amount.

According to the energy trading system 1 configured as described above, it is possible to receive the following benefits.
When the feed-in tariff system (FIT system) for renewable energy ends, for example, surplus power generated by photovoltaic power generation can be stored in storage batteries or hydrogen storage tanks for self-consumption. However, since the storage battery and the hydrogen storage tank are expensive, the purchase of the storage battery and the hydrogen storage tank is a burden on the owner of the photovoltaic power generation facility (for example, the electricity seller G). In addition, for example, since a storage battery involves a charge/discharge loss of about 10%, for example, when the storage battery is charged with surplus power, the owner of the photovoltaic power generation facility (for example, the power seller G) can only use 90% of the surplus power. Unable to use.
On the other hand, in the energy trading system 1, since the business operator B supplies the fuel (for example, city gas) corresponding to the surplus power, it is possible to suppress the conversion loss in the system as a whole.

Moreover, if the owner of the photovoltaic power generation facility (for example, the power seller G) does not use much power, there is no need to store the surplus power.
In the energy trading system 1, since the business operator B purchases surplus power even after the FIT system ends, there is a possibility that the power generated by the power generation equipment 21 will be restricted from being supplied to the power grid 60. can be reduced. Therefore, even if the power seller G owns the power generation equipment 21 for photovoltaic power generation but does not use the power very much, he or she can enjoy the benefits. In addition, it becomes possible for business operator B to procure "non-fossil value" that is difficult to procure (because there is no power supply designation) in transactions on exchanges.

In addition, according to the energy trading system 1, since the specific consumer S who is interested in RE100 acquires fuel through emission trading, gas (for example, city gas) can be used as substantial CO2 _- free methane. Therefore, it is possible to stably generate electric power compared to the case where the specific consumer S owns solar power generation equipment or wind power generation equipment that generates electric power using renewable energy and generates electric power.
Moreover, when producing CO ₂ -free methane, H ₂ is usually produced by electrolysis technology or the like using surplus electricity and reacted with CO ₂ , but the problem is that the conversion efficiency is low. On the other hand, according to the energy trading system 1, the conversion efficiency is equivalent to the amount of power generation, and can be 100% because the conversion is actually performed without the conversion reaction.

The power generation efficiency of fuel cells is higher than the power generation efficiency of thermal power generation, and the power generation efficiency of thermal power generation is about 50% in the case of improved combined cycle power generation (AAC). In the case of , the power generation efficiency is, for example, about 70%. Therefore, when the SOFC or PCFC is used as the power generator 31, the power generation efficiency of the power generator 31 is approximately 1.4 times that of thermal power generation. Therefore, in the service described in Non-Patent Document 1, compared to generating power using low-efficiency thermal power generation to return the deposited power amount, the energy trading system 1 generates power with higher efficiency. Since power is generated using the device 31, 1.4 times the power can be obtained.

From the above, according to the energy trading system 1, the specific consumer S uses more power associated with CO ₂ emission rights than purchasing power generated using renewable energy as it is. can do. As a result, even if the specific consumer S uses the same amount of power, it is possible to increase the ratio of the amount of power associated with the CO ₂ emission rights to the amount of power. That is, according to the energy trading system 1, it is possible to meet the needs of the specific consumer S who wants to use more non-fossil value electric power, and to expand the options of the specific consumer S.

As described above, the energy trading device 100 is an example of a power purchase amount grasping unit that grasps the power purchase amount (reverse power flow power amount), which is the amount of power purchased from the power seller G that has the power generation equipment 21 and generates power. A reverse power flow rate grasping unit 120 and an emission credit calculation unit 130 that calculates a CO ₂ emission credit R according to the power purchase amount grasped by the reverse power flow rate grasping unit 120 are provided. In addition, the energy trading device 100 is an emission credit corresponding fuel amount calculation unit as an example of a fuel amount calculation unit that calculates a fuel amount corresponding to the CO ₂ emission credit R calculated by the emission credit calculation unit 130 (emission credit corresponding fuel amount). A portion 140 is provided. As a result, the energy trading device 100 can accurately grasp the amount of electric power purchased from the electric power seller G, and also accurately calculate the fuel amount corresponding to the CO ₂ emission rights R corresponding to the purchased electric amount. be able to. As a result, even if the power seller G owns the power generation facility 21 but does not use much power, it is possible to enjoy the benefits, and at the same time, the option of the specific consumer S who wants to use power of non-fossil value is given. An expanding system can be realized.

In addition, the energy trading device 100 supplies at least part of the emission credit corresponding fuel amount calculated by the emission credit corresponding fuel amount calculation unit 140 to the specific consumer S as the emission credit corresponding fuel amount supplied to the specific consumer S A notification unit 170 for notifying S is further provided. The notification unit 170 notifies the specific consumer S of the amount of fuel corresponding to emission credits, so that the specific consumer S can grasp the amount of electric power associated with the CO ₂ emission credit. As a result, the specific consumer S can know the ratio of the amount of power associated with the CO ₂ emission credit to the amount of power used.

<Second embodiment>
FIG. 6 is a diagram illustrating a schematic configuration of an energy trading system 2 according to the second embodiment.
The energy trading system 2 according to the second embodiment differs from the energy trading system 1 according to the first embodiment in the owner of the power generator 31 . Differences from the energy trading system 1 according to the first embodiment will be described below. Elements having the same functions in the energy trading system 1 according to the first embodiment and the energy trading system 2 according to the second embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.

In the energy trading system 2 according to the second embodiment, the business operator B owns the power generator 31 and supplies power generated using the power generator 31 to the specific consumer S.
Further, the specific consumer S owns, instead of the fuel amount measuring device 32 , a known power amount measuring device 33 having a function of measuring the power amount and communicating with the energy trading device 100 .

FIG. 7 is a block diagram illustrating the functional configuration of an energy trading device 200 according to the second embodiment.
As with the energy trading device 100 according to the first embodiment, the energy trading device 200 according to the second embodiment includes a receiving unit 110, a reverse flow rate grasping unit 120, an emission credit calculation unit 130, an emission credit corresponding fuel and a quantity calculator 140 .

Then, the energy trading device 200, based on the information received by the supply instruction unit 250 that instructs the specific consumer S to supply the power generated by the power generation device 31 and the receiving unit 110, the specific consumer S and a power amount grasping unit 260 for grasping the power amount measured by the power amount measuring device 33 .
The energy trading device 200 also includes a notification unit 270 that notifies the specific consumer S of the amount of power supplied.

The supply instruction unit 250 instructs the specific consumer S to supply power. For example, if (i) the monthly or yearly supply amount is determined between the business operator B and the specific consumer S, the supply instruction unit 250 determines the monthly or yearly supply amount. the recommended amount. Further, the supply instruction unit 250 may, for example, instruct (ii) to supply the amount of electric power used by the specific consumer S. In addition, the supply instruction unit 250, for example, (iii) supplies the power generated using the amount of fuel corresponding to the CO ₂ emission rights corresponding to the power purchased from the specific power seller G (there may be a plurality of power sellers). You can order it to be supplied.

When the receiving unit 110 receives the power amount sent from the power amount measuring device 33 of the specific consumer S, the power amount grasping unit 260 grasps the power amount supplied to the specific consumer S, The supplied power is stored in the storage unit 102 in association with the ID of the specific consumer S. The power amount grasping unit 260 may grasp and store the amount of power supply each time it is sent from the power measuring device 33, or may calculate the cumulative value of the amount of power supply sent every 30 minutes, for example. , for example, may be grasped and stored in units of days or months.

The notification unit 270 notifies the specific consumer S of the supplied power amount (supplied power amount), and uses the fuel amount corresponding to the CO ₂ emission credit R (emission credit corresponding fuel amount) in the supplied power amount. It also notifies the amount of electric power generated by The notification unit 270 can, for example, notify at the notification time described above.

For example, in the case of (i) above, since the supply amount is predetermined, when the entire amount is supplied, the predetermined amount becomes the supply power amount. In the case of (ii) above, the amount of power supplied is the amount measured by the power amount measuring device 33 . In both cases of (i) and (ii) above, the amount of fuel corresponding to emission credits or the amount of fuel corresponding to emission credits is used on a monthly or yearly basis between business operator B and specific consumer S. If the amount of electric power to be supplied from the electric power generated by Reported as power consumption. If the amount of electric power purchased by the business operator B from the power seller G is large and the amount of electric power supplied can be covered by the amount of electric power corresponding to emission rights, the amount of electric power corresponding to emission rights will be the same as the amount of electric power supplied. On the other hand, if the amount of electric power purchased by business operator B from electric power seller G is not so large that the amount of electric power supplied can be covered by the amount of electric power corresponding to emission rights, the amount of electric power corresponding to emission rights is higher than the amount of electric power supplied. a small amount.
In addition, in the case of (iii) above, specify the amount of power generated using the fuel corresponding to the CO ₂ emission rights corresponding to the power purchased from the specific power seller G (there may be more than one). Since it is supplied to the consumer S, the amount of electric power corresponding to that amount becomes the amount of electric power corresponding to emission credits and the amount of electric power to be supplied.

Even with such a configuration, in the energy trading system 2, the business operator B uses the fuel corresponding to the surplus power and uses the power generation device 31 that generates power at a power generation efficiency higher than that of the power generation equipment 11. Since the generated power is supplied to the specific consumer S, it is possible to suppress the conversion loss in the system as a whole. Also, in the energy trading system 2, since the business operator B purchases surplus power after the FIT system ends, there is a possibility that the power generated by the power generation equipment 21 will be restricted from being supplied to the power grid 60. can be reduced. Therefore, even if the power seller G owns the power generation equipment 21 for photovoltaic power generation but does not use the power very much, he or she can enjoy the benefits. In addition, business operator B can procure "non-fossil value" that is difficult to procure through transactions on exchanges. In addition, the specific consumer S can use more power tied to the CO ₂ emission credit than purchasing power generated using renewable energy as it is, and the same amount of power was used. , it is possible to increase the ratio of the amount of electric power associated with CO ₂ emission rights to the amount of electric power.

In addition, the energy trading device 200 of the energy trading system 2 according to the second embodiment calculates the reverse power flow rate grasping unit 120 and the CO ₂ emission rights R corresponding to the power purchase amount grasped by the reverse power flow rate grasping unit 120. It has an emission credit calculation unit 130 and an emission credit corresponding fuel amount calculation unit 140 . In addition, the energy trading device 200 is the power generated using at least a part of the emission-compatible fuel amount calculated by the emission-compatible fuel amount calculation unit 140, and the amount of power supplied to the specific consumer S ( A notification unit 270 is provided for notifying the specific consumer S of the amount of electric power corresponding to emission credits. The notification unit 270 notifies the specific consumer S of the electric energy corresponding to the emission credit, so that the specific consumer S can grasp the electric energy associated with the CO ₂ emission credit. As a result, the specific consumer S can know the ratio of the amount of power associated with the CO ₂ emission credit to the amount of power used.

<Third Embodiment>
FIG. 8 is a diagram illustrating a schematic configuration of an energy trading system 3 according to the third embodiment.
The energy trading system 3 according to the third embodiment differs from the energy trading system 1 according to the first embodiment in that the specific consumer S has a hydrogen station 34 and a fuel cell vehicle 35. different. Differences from the energy trading system 1 according to the first embodiment will be described below. Elements having the same functions in the energy trading system 1 according to the first embodiment and the energy trading system 3 according to the third embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.

The hydrogen station 34 includes a hydrogen production device that produces hydrogen from the fuel supplied from the fuel supply device 12 of the operator B, a compressor that compresses hydrogen, a pressure accumulator that stores the compressed hydrogen, and a fuel cell vehicle 35. It is an on-site facility with a dispenser that fills the fuel tank with hydrogen.
The fuel cell vehicle 35 is a known fuel cell vehicle that runs by driving a motor with electric power generated by a mounted fuel cell.

According to the energy trading system 3 according to the third embodiment configured as described above, similarly to the energy trading system 1 according to the first embodiment, the operator B supplies fuel equivalent to the surplus electricity. Therefore, the conversion loss can be suppressed in the system as a whole. In addition, in the energy trading system 3 as well, since the business operator B purchases surplus power after the FIT system ends, there is a possibility that the power generated by the power generation equipment 21 will be restricted from being supplied to the power grid 60. can be reduced. Therefore, even if the power seller G owns the power generation equipment 21 for photovoltaic power generation but does not use much power, he or she can enjoy the benefits. In addition, business operator B can procure "non-fossil value" that is difficult to procure through transactions on exchanges. In addition, the specific consumer S can use more power associated with the CO ₂ emission credits than, for example, owning an electric vehicle that runs on power generated using renewable energy. As a result, even if the specific consumer S uses the same amount of power, it is possible to increase the ratio of the amount of power associated with the CO ₂ emission rights to the amount of power.

Moreover, the energy trading system 3 according to the third embodiment includes an energy trading device 100 similar to the energy trading system 1 according to the first embodiment. The energy trading device 100 can accurately grasp the amount of power purchased from the power seller G, and can also accurately calculate the amount of fuel corresponding to the CO ₂ emission rights R corresponding to the purchased amount of power. . In addition, the notification unit 170 notifies the specific consumer S of the fuel amount corresponding to the emission credit, so that the specific consumer S can grasp the amount of electric power associated with the CO ₂ emission credit. As a result, the specific consumer S can know the ratio of the amount of power associated with the CO ₂ emission credit to the amount of power used.

In addition, in the energy trading system 3 according to the third embodiment, the specific consumer S has the fuel cell vehicle 35, but the present invention is not particularly limited to this aspect. For example, the specific consumer S uses the fuel supplied from the fuel supply device 12 of the business operator B as an automobile equipped with an internal combustion engine that operates with combustion gas that is burned inside the engine, or a combustion that is burned outside the engine. The vehicle may have an external combustion engine, such as a steam engine powered by steam generated using gas. Note that the fuel supplied from the business operator B is not limited to the fuel supplied from the fuel supply device 12 . For example, the fuel may be supplied from business operator B to specific consumer S in a container.

DESCRIPTION OF SYMBOLS 1,2,3... Energy trading system, 11... Power generation equipment, 12... Fuel supply device, 21... Power generation equipment, 22... Electricity measuring equipment, 31... Power generating equipment, 32... Fuel amount measuring equipment, 60... Power grid, DESCRIPTION OF SYMBOLS 100... Energy trading apparatus 120... Reverse flow rate grasping part 130... Emission credit calculation part 140... Emission credit corresponding fuel amount calculation part 170, 270... Notification part

Claims (8)

a purchased power amount grasping unit that grasps the amount of purchased power, which is the amount of power purchased from a power seller that has a power generation facility and generates power;
an emission credit calculation unit that calculates CO2 emission credits according to the power purchase amount grasped by the power purchase amount grasping unit;
a fuel amount calculation unit that calculates a fuel amount corresponding to the CO2 emission credit calculated by the emission credit calculation unit;
a notification unit that notifies the specific consumer of at least part of the fuel amount calculated by the fuel amount calculation unit and that is supplied to the specific consumer;
energy trading device. 2. The energy trading device according to claim 1 , wherein said specific consumer has a power generation device that generates power using the supplied fuel. The specific consumer is an electric vehicle that runs on electricity generated by a power generation device that generates electricity using the supplied fuel, and an electric vehicle that produces hydrogen using the supplied fuel and electricity that is generated using the produced hydrogen. 2. The energy trading device according to claim 1 , wherein the vehicle is a fuel cell vehicle that runs on a fuel cell, or a vehicle equipped with an internal combustion engine or an external combustion engine that operates by burning supplied fuel. a purchased power amount grasping unit that grasps the amount of purchased power, which is the amount of power purchased from a power seller that has a power generation facility and generates power;
an emission credit calculation unit that calculates CO2 emission credits according to the power purchase amount grasped by the power purchase amount grasping unit;
a fuel amount calculation unit that calculates a fuel amount corresponding to the CO2 emission credit calculated by the emission credit calculation unit;
a notification unit for notifying a specific consumer of the amount of power generated using at least part of the fuel amount calculated by the fuel amount calculation unit and supplied to the specific consumer ;
energy trading device. 5. The energy trading device according to claim 4 , wherein power generated by a power generation device that generates power using at least part of the fuel amount calculated by the fuel amount calculation unit is supplied to the specific consumer. The power seller generates power using renewable energy,
The energy trading device according to any one of claims 1 to 5 , wherein the specific consumer is a consumer who intends to use RE100. to the computer,
A function to grasp the amount of power purchased, which is the amount of power purchased from a power seller who has a power generation facility and generates power,
a function of calculating CO2 emission rights according to the amount of power purchased;
a function of calculating a fuel amount corresponding to the CO2 emission credit;
a function of notifying the specific consumer of at least a part of the fuel quantity supplied to the specific consumer;
program to realize to the computer,
A function to grasp the amount of power purchased, which is the amount of power purchased from a power seller who has a power generation facility and generates power,
a function of calculating CO2 emission rights according to the amount of power purchased;
a function of calculating a fuel amount corresponding to the CO2 emission credit;
A function of notifying a specific consumer of the amount of power generated using at least part of the fuel amount and supplied to the specific consumer;
program to realize

Images