KR102075083B1 - Compensating method of electricity generation amount, charging method of electricity receiving amount and charging method of electricity transmitting amount - Google Patents

Abstract

In one embodiment, the method for charging the amount of renewable energy transmission between the power receiving device connected to the transmission line and the power generation device, the method comprising the steps of: checking the amount of power matching the power generation device from the power receiving device; Confirming a power transmission amount matched with the power receiving device from the power generation device; And charging a transmission network use amount to a cumulative transmission amount in which the transmission amount is accumulated during a first charging section, and in the charging of the transmission network use amount, proportional to the length of the transmission line and the cumulative transmission amount. It provides a renewable energy transmission amount billing method for determining the power grid utilization so that the mismatch cost determined penaltyally added to the amount of power (inconsistent power amount) corresponding to the difference between the amount of power transmission and the amount of power received in the power transmission cost determined to be. .

Description

Compensation method for renewable energy generation, charging method for charging power and charging method for transmitting power to promote generation by renewable energy

This embodiment relates to a technique for promoting power generation by renewable energy.

Efforts have been made to increase the proportion of renewable energy generation in order to solve problems such as energy shortage due to exhaustion of fossil fuels and global warming due to the use of fossil fuels.

A representative case is the Renewable Portfolio Standard (RPS) system, which allocates the amount of power generated by renewable energy to supply mandates. Here, the supply mandate is a business operator operating a capacity of a certain size or more, generally a power generation company that operates a large power plant commercially.

These supply mandates may build their own renewable energy plants to meet the RPS, but they may also meet the RPS by purchasing renewable energy generation from other renewable energy generators.

The latter is known as REC (Renewable Energy Certification). Renewable energy generators supply renewable energy generation on behalf of supply mandates and, in return, receive compensation from supply mandates.

Renewable energy generation incurs various costs such as site cost, power plant license fee, and power plant construction cost. With REC, supply mandates can meet RPS without paying the initial cost. Will be. In addition, renewable energy generators can supply renewable energy by using their own power generation sites and receive compensation in return. The mutual benefit combination facilitates the development of renewable energy.

On the other hand, the RPS system has a role of promoting the generation by renewable energy, but there is a certain limit to the increase of the RPS system because it is a system for forcibly allocating a supply mandate. In general, the quota of RPS is expected to increase by 1% per year. It is difficult to increase the quota unreasonably because of the burden of supply mandates.

In this respect, the introduction of other systems to promote power generation by renewable energy is urged. Newly introduced systems are encouraged to encourage private voluntary participation, not by compulsory government policies.

Against this background, it is an object of this embodiment to provide a technique for promoting power generation by renewable energy. The present embodiment provides a technique relating to a method for compensating the amount of generation of renewable energy, a technique for providing a method for charging the amount of renewable energy received, and a method for charging the amount of renewable energy transmitted. Its aim is to provide a description of

In order to achieve the above object, in one embodiment, in the method for charging the amount of renewable energy transmission between the power receiving device connected to the power transmission line and the power generation device, the amount of power reception matching the power generation device from the power receiving device is confirmed; Making; Confirming a power transmission amount matched with the power receiving device from the power generation device; And charging a transmission network use amount to a cumulative transmission amount in which the transmission amount is accumulated during a first charging section, and in the charging of the transmission network use amount, proportional to the length of the transmission line and the cumulative transmission amount. It provides a renewable energy transmission amount billing method for determining the power grid utilization so that the mismatch cost determined penaltyally added to the amount of power (inconsistent power amount) corresponding to the difference between the amount of power transmission and the amount of power received in the power transmission cost determined to be. .

The method may further include charging a power receiving cost to the cumulative excess power received by accumulating the amount of power exceeding the power transmission amount in the power receiving amount during the second charging period.

The method may further include providing a power sale to the cumulative excess transmission amount in which the amount of power exceeding the amount of power reception in the transmission amount during the third charging period is accumulated.

In this method, in the step of charging the power grid utilization, a penalty amount set in proportion to an absolute value of the amount of mismatched power at a time point may be accumulated during the first charging period to determine the mismatch cost.

In this method, in the step of charging the power grid utilization, the penalty amount may not be imposed on the power amount corresponding to a predetermined range from the power amount.

Another embodiment of the present invention is a method for charging the amount of power of a plurality of power generation devices connected to a power receiving device through a power transmission network, the method comprising the steps of: checking the total amount of power receiving from the power receiving device; Checking the amount of power transmission from each power generation apparatus; Determining a transmission cost for a cumulative transmission amount in which the transmission amount is accumulated for each power generation device during a first charging period; And determining an inconsistency cost for an amount of power (mismatched amount of power) corresponding to a difference between the total (total amount of power) and the total amount of power of each power generation device during the first charging period. In the step of determining, for each power generation device, provides a renewable energy transmission amount charging method for determining the transmission cost in proportion to the length of the transmission line to the power receiving device and the cumulative transmission amount.

The method may further include charging a power receiving cost to a cumulative excess power amount accumulated in the total power amount exceeding the total power amount in the total power amount during the second charging period.

In the determining of the mismatch cost, the method may accumulate a penalty amount set in proportion to an absolute value of the amount of mismatched power at the time point during the first charging period to determine the mismatch cost.

Another embodiment is a method for compensating for the amount of power generation of a power generation device for transmitting renewable energy to a power receiving device through a power transmission line, the method comprising the steps of: confirming the amount of power matching the power generation device from the power receiving device; Confirming a power transmission amount matched with the power receiving device from the power generation device; Determining a Renewable Energy (RE) compensation amount for a cumulative amount of power that accumulates the amount of power (amount of suitable power) not exceeding the amount of power received during the charging period; Determining a cumulative power transmission amount in which the power transmission amount is accumulated during the charging period or a power transmission cost for the cumulative power consumption; Determining an inconsistency cost for a cumulative unmatched amount of power that accumulates the amount of power (unmatched amount of power) corresponding to the difference between the amount of power transmission and the amount of power received during the charging period; exceeding the amount of power received in the amount of power transmission during the charging period. Determining a power sale amount for a cumulative excess transmission amount in which the amount of electricity (excess transmission amount) is accumulated; And determining a power generation compensation amount so that the RE compensation amount and the electric power sales amount are added and the power transmission cost and the mismatch cost are subtracted.

In this method, in the determining of the mismatch cost, a penalty amount, which is set in proportion to the absolute value of the mismatched power amount, may be accumulated during the charging period to determine the mismatch cost.

In this method, in the determining of the mismatch cost, the penalty amount (negative penalty amount) when the power transmission amount is smaller than the power reception amount is greater than the penalty amount (plus penalty amount) when the power transmission amount is larger than the power reception amount. Can be.

In this method, the unit price of the RE compensation amount may be set higher than the unit price of the power sale amount.

In still another embodiment, there is provided a method for charging a power receiving amount of a power receiving device for receiving renewable energy from a plurality of power generation devices through a power transmission network, the method comprising: checking a total power reception amount from the power receiving device; Checking the amount of power transmission from each power generation apparatus; Determining a Renewable Energy (RE) cost for a cumulative amount of power that accumulates an amount of electricity (amount of suitable power) that does not exceed the total (total amount of electricity) of each power generation device in the total power amount during the charging period; Determining a general faucet cost for a cumulative excess faucet that has accumulated an amount of electricity (excess faucet) exceeding the total transmission amount from the total faucet amount during the charging period; Determining an inconsistency compensation amount by accumulating a deficit compensation amount set in proportion to the excess faucet amount during the charging period; And charging the faucet cost such that the RE faucet cost and the general faucet cost are added, and the mismatch compensation is subtracted.

The method may further include dividing the total amount of power received into a plurality of amounts of power received, matching the received amount of power for each power generating device, and transmitting the received amount of power to each power generating device.

The method further includes the step of receiving a power supply amount from each power generation device, and in the step of transmitting the power reception amount, the power reception amount can be determined in proportion to the power transmission amount received from each power generation device. .

The method further includes the step of calculating a cumulative unmatched power amount accumulated for each power generating device for each power generation device, the accumulated amount of power (unmatched power amount) corresponding to the difference between the power reception amount and the power transmission amount during the charging period, and transmitting the power reception amount. In the step of, the cumulative mismatched power amount for each power generation device can decrease the occupancy of the power receiving amount.

As described above, according to the present embodiment, there is an effect of promoting power generation by renewable energy.

1 is a configuration diagram of a general RE100 system.
2 is a configuration diagram of a system to which embodiments of the present specification can be applied.
3 is a conceptual diagram of a system according to a first embodiment.
4 is a flowchart illustrating a method of processing a renewable energy generation amount according to the first embodiment.
5 is a hardware configuration diagram of a system according to the first embodiment.
6 is a conceptual diagram of a system according to a second embodiment.
7 is a flowchart of a transmission amount charging method according to a second embodiment.
8 is a graph showing occurrence of mismatch costs according to the amount of power received and the amount of power transmitted in the second embodiment.
9 is a graph showing the power generation unit cost according to the power transmission distance in the second embodiment.
10 is a graph showing power generation costs according to power generation amount in the second embodiment.
11 is a hardware configuration diagram according to the second embodiment.
12 is a flowchart of a transmission amount charging method according to a third embodiment.
13 is a hardware configuration diagram according to the fourth embodiment.
14 is a flowchart of a power generation compensation method according to the fourth embodiment.
15 is a flowchart of a power receiving amount charging method according to a fourth embodiment.
16 is a flowchart of a method of matching the total amount of power received by each power generation device in the fourth embodiment.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected to or connected to that other component, but there may be another configuration between each component. It is to be understood that the elements may be "connected", "coupled" or "connected".

RE100 means that all energy required for the production of the product is supplied from renewable energy. Companies pursuing RE100 can enhance the product image or corporate image by advertising that the product is produced through renewable energy, and consumers can promote the production of products by renewable energy by consuming products by RE100.

1 is a configuration diagram of a general RE100 system.

Referring to FIG. 1, the RE100 system may include a power generator 10, a power transmission line 20, and a power receiver 30.

The generator 10 is a device that generates power using renewable energy, and may include a photovoltaic device and a wind power generator. In addition, according to the embodiment, the power generation device 10 may further include an energy storage system (ESS) device.

In the concept of the conventional RE100 system, a company pursuing RE100 constructs the power generation device 10 in the vicinity of the power receiving device 30 and receives the power consumed by the power receiving device 30 from the power generation device 10. An ESS device may be further included in the power generation device 10 to compensate for a mismatch between the power reception amount of the power reception device 30 and the power generation amount of the power generation device 10.

On the other hand, in order to introduce such a power generation device 10, a power generation site is required, and an initial construction cost is required, and it is not easy to provide a large power generation site in the vicinity of the power receiving device 30. Due to the nature of the enterprise, it is not easy to inject a large amount of initial construction cost for the power generation device (10).

Due to these problems, the conventional RE100 system is not activated well. The present embodiment provides a system in which a power generation device and a power receiving device are separated to solve this problem.

2 is a configuration diagram of a system to which embodiments of the present specification can be applied.

Referring to FIG. 2, the system 100 may include a power generator 110, a power transmission line 120, and a power receiver 130.

Here, the transmission line 120 is different from the transmission line described with reference to FIG. 1 (see 20 in FIG. 1). The power transmission line described with reference to FIG. 1 (see 20 in FIG. 1) may be understood as an internal power grid of an enterprise. In contrast, the transmission line 120 described with reference to FIG. 2 may be understood as an external power grid. The external power grid is, for example, a commercial power grid owned by a power company, and in order to use such an external power grid, it is necessary to obtain permission from the power company, so that the generator 110 arbitrarily generates power from the power transmission line 120. And the power receiver 130 cannot arbitrarily receive power from the power transmission line 120.

The power generator 110, the power transmission line 120, and the power receiver 130 constituting the system 100 may be operated by different entities. For example, the power generation device 110 may be operated by a renewable energy generator, the power transmission line 120 may be operated by a power transmission operator, and the power reception device 130 may be operated by a power reception provider.

Conceptually, the power generator 110 and the power receiver 130 are spatially separated, and the power generated by the power generator 110 may be transmitted to the power receiver 130 through the power transmission line 120. For example, a power receiving cost may be charged to a subject operating the power receiving device 130, and a power generation compensation may be given to a subject operating the power generating device 110.

On the other hand, the generator 110 is to use the transmission line 120 in the process of transmitting the generated power, in this case, it is possible to pay the transmission cost to the operating entity of the transmission line 120 for the amount of power transmitted.

As a result, the main body of the power receiving device 130 can produce a product with renewable energy while paying the cost corresponding to the power receiving cost, the main body of the power generating device 110 generates the power generation profit by subtracting the transmission cost from the power compensation compensation. It is possible to create, the subject of the transmission line 120 can generate a transmission revenue as much as the transmission cost.

The system 100 may be configured in such a way that the interests of the three subjects are in harmony with each other.

On the other hand, when all of the power produced by the power generator 110 is transmitted to the power receiver 130 or all the power consumed in the power receiver 130 is derived from the power generator 110, the system 100 operates efficiently If the power generation amount of the power generation device 110 and the power reception amount of the power receiving device 130 are inconsistent, a problem may occur as the voltage or current of the power transmission line 120 is disturbed.

In order to prevent the disturbance of the transmission line 120, the system 100 may limit the amount of power generation of the power generation device 110 exceeding the amount of power reception of the power reception device 130 to be input to the transmission line 120.

3 is a conceptual diagram of a system according to a first embodiment.

Referring to FIG. 3, the system 300 may include a power generator 310, a power transmission line 320, a power receiver 330, and a storage device 340.

The power receiving device 330 measures the amount of power receiving A received through the power transmission line 320, and transmits the power receiving amount A to another device, for example, the power generation device 310, in real time. have.

The power generation device 310 checks the power reception amount A of the power reception device 330, and the amount of power corresponding to the power reception amount A or less of the power generation amount is transmitted to the power transmission line 320, and the power reception amount A exceeds. The excess power generation (B) may be stored in the storage device 340 connected to the internal power grid.

4 is a flowchart illustrating a method of processing a renewable energy generation amount according to the first embodiment.

Referring to FIG. 4, the power generation apparatus may perform power generation by renewable energy (S400).

In addition, the power generation apparatus may check the power receiving amount of the power receiving device in real time (S401).

In addition, the power generation apparatus may check whether the amount of power generation exceeds the amount of power reception A (S402), and if the amount of power reception amount A does not exceed (YES in S402), the power generation amount may be transmitted to the transmission line (S404).

In addition, when the power generation amount exceeds the amount of power A (NO in S402), the power generation device may store the amount of power exceeding the amount of power A in a storage device or consume it through a load connected to an internal power grid (S410). ).

5 is a hardware configuration diagram of a system according to the first embodiment.

Referring to FIG. 5, the system 500 may include a power generator 310, a power transmission line 320, a power receiver 330, and a storage device 340, and may further include a central device 550.

The power generation device 310 may include a generator 512, a power transmission meter 514, a power transmission controller 516, and the like. The power reception device 330 includes a load 532, a power reception meter 534, and a power reception controller 536. ) May be included.

The power receiving device 330 may receive power consumed by the load 532 from the power transmission line 320, and the amount of power received by the load 532 may be measured by the power receiving meter 534.

The faucet controller 536 may check the amount of power received through the faucet meter 534, and may transmit the amount of received power to the power transmission controller 516 of the generator 310 or to the central apparatus 550.

When the amount of power received is transmitted to the central unit 550, the central unit 550 may recalculate the amount of power received to fit the generator 310, and then transmit the received amount of power to the generator 310. For example, a plurality of power generating devices 310 may supply power to one power receiving device 330. In this configuration, the central unit 550 may be configured to match the amount of power receiving to each of the power generating devices 310 (sub). ), And the (sub) power reception amount can be transmitted to the power transmission controller 516 of each power generator 310.

The power transmission controller 516 checks the received amount of power or (sub) power, and transmits the amount of power corresponding to the amount of power received or less than the (sub) power of the generator 512 to the power transmission line 320. The amount of power exceeding this may be stored in the storage device 340.

In addition, the power transmission controller 516 may transmit the power transmission amount checked through the power transmission meter 514 to the central device 550, and the power transmission device and the power reception device identified from the power generation device 310. By comparing the amount of power received from 330 can be confirmed whether the power transmission is properly made.

The first embodiment relates to blocking the transmission of excess power from the power generation apparatus to the power transmission line in hardware, and the system can prevent excessive inconsistency in the power transmission line through cost.

6 is a conceptual diagram of a system according to a second embodiment.

Referring to FIG. 6, the system 600 may include a power generator 610, a power transmission line 620, and a power receiver 630.

The power receiving device 630 measures the power receiving amount A received through the power transmission line 620 and transmits the power receiving amount A in real time to another device, for example, the power generation device 610. have.

The power generation device 610 may check the power receiving amount A of the power receiving device 630, and may try to transmit the amount of power corresponding to the amount or less of the power generation amount A to the power transmission line 620, but the amount of power receiving amount of the power generation device 630 is sufficient. Some amount of power B exceeding (A) may be transmitted to the transmission line 620.

At this time, the charging subject may charge the power receiving cost corresponding to the amount of power A to the main body of the power receiving device 630, and may charge the power transmission cost corresponding to the amount of power transmission to the main body of the power generating device 610. In addition, the charging subject may additionally charge the power generator 610 with an inconsistency cost that is determined to be penalty on the amount of power (mismatched amount of power) corresponding to the difference between the amount of power transmission and the amount of power receiving.

Here, the billing subject can be understood as a kind of server. In addition, the billing act of the billing subject may be understood as the server determining the billing amount, or further, the server notifying the subject of the power generation device 610 or the subject of the power receiving device 630 electronically.

According to such a charging system, since the power generation device 610 has to pay additional mismatch costs, the power generation device 610 performs the control so that the power transmission amount and the power reception amount coincide with each other.

7 is a flowchart of a transmission amount charging method according to a second embodiment.

Referring to FIG. 7, the apparatus for charging the amount of power transmitted from the power transmission line (hereinafter referred to as the 'charging device') may check the amount of power received from the power receiving device to be matched with the power generator (S700). The total amount of power received by the power receiving device can be matched and divided for each power generation device, and the charging device can check the amount of power matching by each power generation device based on the total amount of power received from the power receiving device. For example, if the total amount of power received is equally divided for each power generation device, the charging device can check the total amount of power received from the power supply device, and divide the total amount of power supply by the number of power generation devices to check the amount of power matching each power generation device. have. Alternatively, when a predetermined ratio is pre-assigned for each power generating device, the charging device may check the amount of power receiving for each power generating device by multiplying the total power received from the power receiving device by the ratio of each power generating device.

The charging device may check the amount of power received for each power generation device through the calculation as described above, or may receive and check the amount of power received that matches each power generation device from the power receiving device.

Then, the charging device may check the power transmission amount matched to each power receiving device from the power generation device (S702). The power generation apparatus may match the total transmission amount by dividing the plurality of power receiving apparatuses, and the matching may be performed by the charging apparatus or may be performed by the power generation apparatus.

The charging device may receive the total power amount from the power generator and match the total power amount for each power receiver. Here, matching the total amount of power transmission by each power receiving device may be substantially the same method as matching the total amount of power transmission by each power generation device in the above description. For example, the charging device may check the power transmission amount matched by each power reception device by dividing the total power transmission by the number of power reception devices, and if a predetermined ratio is pre-assigned for each power reception device, the charging device is determined from the power generation device. The total amount of power transmitted can be confirmed by multiplying the ratio of each power supply device by the ratio of each power supply device.

As described above, the charging device may check the amount of power transmission for each power receiving device through calculation, or may receive and confirm the amount of power transmission that matches each power receiving device from the power generation device.

In addition, the charging device may charge the power transmission network use amount to the cumulative transmission amount accumulated in the transmission amount during the first charging section (S704).

In the transmission network utilization charging step (S704), the charging device can determine the transmission cost in proportion to the length of the transmission line and the cumulative transmission amount. In addition, the charging device may penalize the cost of the mismatch in the amount of mismatched power corresponding to the difference between the amount of power transmission and the amount of power received. In addition, the charging device may determine the transmission network use so that the mismatch cost is added to the transmission cost.

8 is a graph showing occurrence of mismatch costs according to the amount of power received and the amount of power transmitted in the second embodiment.

Referring to FIG. 8, the amount of power received 810 may vary with time. In this case, the power generation apparatus may control the power transmission amount 820 to follow the power reception amount 810. However, the power transmission amount 820 may not accurately follow the power reception amount 810 due to control dynamics in the power generation device or a communication delay between the power generation device and the power reception device. As another example, when the generator does not consume or store the generated power, the power generator may transmit such power to the power transmission line, such that the power transmission amount 820 may be inconsistent with the power reception amount 810.

The apparatus for charging the power grid utilization (billing apparatus) charges the mismatch cost to the amount of power (mismatched power) corresponding to the mismatch between the amount of power transmission 820 and the amount of power receiving 810 to induce the generator to perform more sophisticated control. Can be.

The charging device may determine the inconsistency cost by accumulating a penalty amount that is set in proportion to the absolute value of the inconsistency power amount at each time point during the first charging period.

In consideration of the controllable limitation, the charging device may not charge a penalty amount for the amount of power transmission (the amount of power transmission between the upper limit and the lower limit in FIG. 8) from the amount of power reception. In addition, the charging device may charge a mismatch cost for the mismatched power amount 830 that deviates from the predetermined range.

On the other hand, the penalty amount (negative penalty amount) when the amount of power transmission is smaller than the amount of power receiving may be greater than the penalty amount (plus penalty amount) when the amount of power transmission is larger than the amount of power receiving. If the amount of power transmission is less than the amount of power receiving, the power receiving device may not meet RE100, and the negative penalty amount may be set larger than the positive penalty amount in consideration of such damage of the power receiving device.

In addition, the charging device may charge the faucet cost to the cumulative excess power received by accumulating the amount of power exceeding the transmission amount in the power received during the second charging section. Since the cumulative excess power is actually not the power generated by the generator, but the power input to the transmission line by another device, the charging device may charge separately for the accumulated excess power. Here, the second billing section may be the same as or different from the first billing section.

In addition, the charging device may provide the power sales money to the cumulative excess transmission amount in which the amount of power exceeding the amount of power reception in the transmission amount during the third charging section is accumulated. The cumulative excess transmission is not actually the amount of power consumed by the power receiving device, but is the amount of power consumed by another device connected to the transmission line. Can be provided.

According to this second embodiment, the power generation device can be disposed at an appropriate distance from the power receiving device to prevent the excessive use of the power transmission line, and to prevent the disturbance of the power transmission line resulting from a mismatch between the power transmission amount and the power reception amount.

9 is a graph showing the power generation unit cost according to the power transmission distance in the second embodiment.

Referring to FIG. 9, as the power transmission distance indicating the distance between the power generator and the power receiver increases, the power generation cost may increase.

In the second embodiment, the power transmission cost may be determined in proportion to the length (power transmission distance) of the power transmission line. When reflecting the characteristics of the power transmission cost, the power generation unit 910 of the power generation device may exhibit a curve that increases in proportion to the power transmission distance.

If the power generation cost is higher than the power compensation price, power generation does not occur. Therefore, the power generation device is not installed in accordance with the principle of the market. The unit price will be installed at a distance shorter than the distance (L).

10 is a graph showing power generation costs according to power generation amount in the second embodiment.

Referring to FIG. 10, the power generation cost 1010 is the lowest when the power generation amount A is the same, and as the difference with the power reception amount A increases, the power generation cost may also increase.

In the second embodiment, the mismatch cost can be determined proportionally to the amount of mismatched power. When reflecting the characteristics of such a mismatch cost, the generation cost 1010 of the power generation device is the lowest when the same as the amount of power received (A), the power generation cost may increase as the difference with the amount of power received (A) increases. .

If the power generation cost is higher than the power compensation price, power generation does not occur. Therefore, the power generation device is not installed according to the principle of the market. The amount of transmission is controlled to be equal.

11 is a hardware configuration diagram according to the second embodiment.

Referring to FIG. 11, the system 1100 may include a power generator 610, a power transmission line 620, a power receiver 630, a storage device 640, and a charging device 1150.

The generator 610 may include a generator 1112, a power transmitter 1114, a power transmitter 1116, and the like. The power receiver 630 includes a load 1132, a power receiver 1134, a power receiver controller 1136. ) May be included.

The power receiving device 630 may receive power consumed by the load 1132 from the power transmission line 620, and the total amount of power supplied to the load 1132 may be measured by the power receiving meter 1134.

The faucet controller 1136 checks the total amount of received power through the faucet meter 1134 and transmits the received amount of power received by dividing the total received amount to match each of the generators 610 to the power transmission controller 1116 of the generator 610. Or to the charging device 1150. On the other hand, the faucet controller 1136 transmits the total amount of power to the charging device 1150, checks the amount of power received by the charging device 1150 to divide the total amount of power to match each of the power generation devices 610, The confirmed amount of power may be transmitted to each power generator 610.

The generator 610 may transmit power generated by the generator 1112 to the power transmission line 620, and the total amount of power transmitted to the power transmission line 620 may be measured by the power transmission meter 1114.

The power transmission controller 1116 checks the total power transmission amount through the power transmission meter 1114 and transmits the power transmission amount obtained by dividing the total power transmission amount to match each power reception device 630 to the power reception controller 1136 of the power reception device 630. Or to the charging device 1150. On the other hand, the power transmission controller 1116 transmits the total power amount to the charging device 1150, checks the power amount divided by the charging device 1150 to match the total power amount to each power receiving device 630, The confirmed power transmission amount can be transmitted to each power receiving device 630.

The power transmission controller 1116 checks the amount of power received by the power receiving device 630 and transmits the amount of power corresponding to the amount of power less than the amount of power received from the power generator 1112 to the power transmission line 620, and stores the amount of power exceeding this. ) Can be controlled.

Meanwhile, the charging device may charge the inconsistency cost for each power generation device, but may charge the inconsistency cost for the entire power generation device that transmits to one power receiving device.

12 is a flowchart of a transmission amount charging method according to a third embodiment.

Referring to FIG. 12, the charging device may check the total amount of power received from the power receiving device (S1200).

Then, the charging device can check the power transmission amount that matches the power receiving device from each power generator (S1202).

In addition, the charging device may determine the transmission cost for the cumulative transmission amount in which the transmission amount is accumulated for each power generation device during the first charging period (S1204).

In step S1204 of determining the power transmission cost, the charging device may determine the power transmission cost in proportion to the length of the power transmission line leading to the power receiving device and the cumulative power transmission amount for each power generation device.

In addition, the charging device may determine an inconsistency cost for the amount of power (mismatched power) corresponding to the difference between the total (total amount of power) and the total amount of power of each power generation device during the first charging period (S1206).

In the step S1206 of determining such inconsistency cost, the charging apparatus may determine the inconsistency cost by accumulating a penalty amount set in proportion to the absolute value of the amount of inconsistency power at the time point during the first charging period.

In addition, the charging apparatus may set the mismatch cost according to the mismatch contribution rate of each power generating apparatus, and charge the power transmission network use by adding the mismatching cost settled on the transmission cost for each power generating apparatus (S1208).

Here, the inconsistency contribution rate may be determined as a ratio of the cumulative unmatched power amount accumulated for each power generation device.

In the above-described embodiment, the transmission network use fee may be charged separately for each power generation device. In addition, each power generation device may generate power generation profit by subtracting the power transmission network use money from power generation compensation money obtained by supplying renewable energy to the power receiving device.

The power generation compensation can be handled by the relay system, which can facilitate the overall cost handling by managing the power transmission network utilization along with the power generation compensation.

13 is a hardware configuration diagram according to the fourth embodiment.

Referring to FIG. 13, the system 1300 may include a power generation device 1310, a power transmission line 1320, a power receiving device 1330, a storage device 1340, and an intermediary device 1350.

The power generation device 1310 may include a generator 1312, a power transmission meter 1314, a power transmission controller 1316, and the like. The power reception device 1330 includes a load 1332, a power reception meter 1334, and a power reception controller 1336. ) May be included.

The power receiver 1330 may receive power consumed by the load 1332 from the power transmission line 1320, and the total amount of power supplied to the load 1332 may be measured by the power receiver meter 1334.

The faucet controller 1336 checks the total amount of received power through the faucet meter 1334, and transmits the received amount of power received by dividing the total received amount to match each of the generators 1310 to the power transmission controller 1316 of the generator 1310. Or to the intermediary device 1350. On the other hand, the faucet controller 1336 transmits the total amount of power to the relay device 1350, checks the amount of power received by the relay device 1350 so as to match the total amount of power to each of the power generation devices 1310, The confirmed amount of power can be transmitted to each of the generators 1310.

The generator 1310 may transmit power generated by the generator 1312 to the transmission line 1320, and the total transmission amount transmitted to the transmission line 1320 may be measured by the transmission meter 1314.

The power transmission controller 1316 checks the total power transmission amount through the power transmission meter 1314 and transmits the power transmission amount obtained by dividing the total power transmission amount to match each power reception device 1330 to the power reception controller 1336 of the power reception device 1330. Or to the intermediary device 1350. On the other hand, the power transmission controller 1316 sends the total power amount to the intermediary device 1350, and checks the power amount divided by the intermediary device 1350 so as to match the total power amount to each power receiver 1330, The confirmed power transmission amount can be transmitted to each power reception device 1330.

The power transmission controller 1316 checks the amount of power received by the power receiving device 1330, and transmits the amount of power less than the amount of power received from the generator 1312 to the power transmission line 1320, and stores the amount of power exceeding this in the storage device 1340. ) Can be controlled.

The intermediary device 1350 may settle and charge the costs incurred in this process and provide power generation compensation to the power generation device 1310.

14 is a flowchart of a power generation compensation method according to the fourth embodiment.

Referring to FIG. 14, the intermediary device may check the amount of power reception that matches the power generation device from the power reception device (S1400). The intermediary device receives the total amount of power received from the power receiving device, and can check the amount of power received that matches each power generation device from the total amount of received power. In addition, the intermediary device may receive a power reception amount matched with each power generation device from the power reception device.

The intermediary device may check the transmission amount matched to the power receiving device from the power generation device (S1402).

The intermediary device may determine the RE (Renewable Energy) compensation for the cumulative amount of power that accumulated the amount of power (suitable power) that does not exceed the amount of power received during the charging period (S1404). RE compensation may be determined by the contract price, which may be the contract price between the operator of the power receiving device and the operator of the generator. The intermediary device stores the contract price in advance, and can determine the RE compensation amount by applying the contract price to the accumulated power.

The intermediary device may determine the transmission cost for the cumulative transmission amount or the cumulative power consumption that accumulated the transmission amount during the charging section (S1406).

The intermediary device may determine the inconsistency cost for the cumulative unmatched power amount accumulated in the amount of power (unmatched power amount) corresponding to the difference between the amount of transmission and the amount of power received during the charging period (S1408).

In the step of determining the mismatch cost (S1408), the intermediary device may determine the mismatch cost by accumulating a penalty amount set in proportion to the absolute value of the mismatched power amount during the charging period. In step S1408, the mediation apparatus determines that the penalty amount (negative penalty amount) when the amount of power transmission is smaller than the amount of power receiving is greater than the penalty amount (plus penalty amount) when the amount of power transmission is larger than the amount of power receiving. Can be set.

The intermediary device may determine the electric power sales amount for the cumulative excess transmission amount in which the amount of power exceeding the amount of power in the amount of power transmission (the excess amount of transmission) during the charging section is accumulated (S1410). In this case, the unit price of the RE compensation amount may be set higher than the unit price of the power sale amount. For example, the RE compensation may be set in such a manner that a certain additional compensation is added to the electricity sales, where the additional compensation may be equal to or larger than a general REC compensation.

The intermediary device may determine the power generation compensation so that RE compensation and power sales are added, and transmission and mismatch costs are subtracted (S1412).

15 is a flowchart of a power receiving amount charging method according to a fourth embodiment.

Referring to FIG. 15, the intermediary device may check the total amount of power received from the power receiving device (S1500).

Then, the intermediary device can check the power transmission amount from each power generation device (S1502).

In addition, the intermediary device determines the RE (Renewable Energy) power cost for the cumulative integrated power that accumulates the amount of power (suitable power) that does not exceed the total (total power) of each generator in the total power received during the charging period. It may be (S1504).

In addition, the intermediary device may determine the general faucet cost for the cumulative excess faucet accumulated in the total amount of power exceeding the total amount of transmission (excess power) during the charging period (S1506).

Then, the intermediary device may accumulate the deficit compensation amount set in proportion to the amount of excess power during the charging period to determine the mismatch compensation amount (S1508).

In addition, the intermediary device may charge the faucet cost so that the RE faucet cost and the general faucet cost are added, and a mismatch compensation is subtracted (S1510).

16 is a flowchart of a method of matching the total amount of power received by each power generation device in the fourth embodiment.

Referring to FIG. 16, the intermediary device may receive a power transmission capacity from each power generation device (S1600).

In addition, the intermediary device may calculate the cumulative mismatched power amount accumulated for each generation device by accumulating the amount of power (inconsistent power amount) corresponding to the difference between the amount of power reception and the amount of power transmission during the charging period (S1604).

In addition, the intermediary device may divide the total power reception amount of the power reception device into a plurality of power reception amounts, match the power reception amount of each power generation device, and transmit the power reception device to each power generation device (S1604). The amount of power received can be determined in proportion to the amount of power available received from the device, and the occupancy rate of the power received can be reduced as the amount of accumulated mismatched power increases for each power generating device.

The terms "comprise", "comprise" or "having" described above mean that a corresponding component may be included unless specifically stated otherwise, and thus, other components are not excluded. It should be construed that it may further include other components. All terms, including technical and scientific terms, have the same meanings as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms commonly used, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be construed in an ideal or excessively formal sense unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (16)

In the method of charging by the charging device to the amount of renewable energy transmission between the power receiving device and the power generating device connected to the power transmission line,
Checking a power receiving amount matched with the power generation device from the power receiving device;
Confirming a power transmission amount matched with the power receiving device from the power generation device; And
Charging the transmission network use amount to a cumulative transmission amount in which the transmission amount is accumulated during a first charging period;
In the step of charging the power grid utilization,
The power transmission network is used so that a mismatch cost determined in a penalty amount is added to the amount of power (mismatched power amount) corresponding to the difference between the amount of power transmission and the amount of power received from the power transmission cost determined proportionally to the length of the power transmission line and the cumulative amount of power transmission. Determine the gold,
The discrepancy cost is determined by accumulating a penalty amount set in proportion to an absolute value of the discrepancy power amount at each time point during the first charging period, and the penalty amount (minor penalty amount) when the power transmission amount is smaller than the power receiving amount. ) Is greater than the penalty amount (plus penalty amount) when the power transmission amount is larger than the power reception amount,
Calculating a cumulative mismatched power amount in which the mismatched power amount is accumulated for the power generation device, and decreasing the occupancy rate of the power receiving amount matched with the power generation device as the cumulative mismatched power amount increases. The method of claim 1,
And charging a faucet cost to a cumulative excess faucet that accumulates an amount of power exceeding the amount of transmission in the faucet amount during a second billing period. The method of claim 1,
And providing a power sale to a cumulative excess transmission amount in which the amount of power exceeding the reception amount in the transmission amount during the third charging period is further included. delete The method of claim 1,
In the step of charging the power grid utilization,
The method of claim 1, wherein the penalty amount is not imposed on the amount of power transmitted within a predetermined range from the amount of power received. delete delete delete In the method for compensating the amount of power generated by the intermediary device, the power generation device for transmitting renewable energy to the power receiving device through the transmission line,
Checking a power receiving amount matched with the power generation device from the power receiving device;
Confirming a power transmission amount matched with the power receiving device from the power generation device;
Determining a Renewable Energy (RE) compensation amount for a cumulative amount of power that accumulates the amount of power (amount of suitable power) not exceeding the amount of power received during the charging period;
Determining a cumulative power transmission amount in which the power transmission amount is accumulated during the charging period or a power transmission cost for the cumulative power consumption;
Determining an inconsistency cost with respect to a cumulative mismatched power amount accumulated in an amount of power (mismatched power amount) corresponding to a difference between the power transmission amount and the power reception amount during the charging period;
Determining a power sale amount for a cumulative excess transmission amount in which the amount of power exceeding the reception amount (excess transmission amount) is accumulated in the transmission amount during the charging period; And
Determining the power generation compensation money so that the RE compensation money and the power sales money are added and the power transmission cost and the mismatch cost are subtracted,
The mismatch cost is determined by accumulating a penalty amount set in proportion to an absolute value of the mismatched power amount at the time point during the charging period, and the penalty amount (minus penalty amount) when the power transmission amount is smaller than the power receiving amount. It is larger than the penalty amount (plus penalty amount) when the power transmission amount is larger than the power reception amount,
Calculating a cumulative mismatched power amount in which the mismatched power amount is accumulated for the power generation device, and as the cumulative mismatched power amount increases, the share of the power receiving amount matched to the power generation device is reduced. delete delete The method of claim 9,
Renewable energy generation amount compensation method wherein the unit price of the RE compensation is set higher than the unit price of the electricity sales. delete delete delete delete

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