KR20180083605A - Method for virtual electric power trading between microgrids and agent apparatus for the same - Google Patents

Abstract

The present invention relates to a method for virtual electric power trading between microgrids and an agent device for the same. The purpose of the present invention is to provide a method for virtual electric power trading between microgrids which enables the trading of electric power between microgrids in an environment in which various shapes of the microgrids exist, and the agent device for the same. According to a desirable embodiment of the present invention, the agent device for the virtual trading of electric power between microgrids includes: an information collection unit collecting electric power trading information from the multiple microgrids; and a relaying unit determining whether trading electric power between microgrids is concluded using the collected electric power trading information. According to the present invention, the method for virtual trading of electric power between microgrids enables the trading of electric power between microgrids to have a benefit between the microgrids wanting to sell electric power and the microgrids wanting to purchase the electric power.

Description

TECHNICAL FIELD [0001] The present invention relates to a virtual power trading method for a micro grid, and an agent apparatus for the virtual power trading method.

The present invention relates to a method of virtual power trading between microgrid and an agent apparatus therefor.

The US Department of Energy (DOE) defines the Micro Grid as:

It is a single controllable entity for the grid as a group of 'consumers' and 'Distributed Energy Resources' (DERs) interconnected in a clearly defined electrical range, and is connectable and independent from the grid.

In other words, the micro grid is a localized power grid that connects the distributed energy resources (DER) of the customer, wind power, and solar power, and operates independently of the entire power system (off-grid) ), And is a power grid that can operate on-grid as needed.

However, the microgrid in the present invention is interpreted in a broader sense.

In the present invention, the microgrid may be any one of the following: i) a load cluster formed only by a load connected to a common connection point; ii) a power generation cluster formed only by a power generation source; and iii) a cluster having both a power generation source and a load. That is, the microgrid of the present invention can be in various forms. The microgrid of the present invention may include a unit for performing control operations in the microgrid. In the micro grid of the present invention, the load may be at least one of a controllable load and an uncontrollable load. In the micro grid of the present invention, the power generation source may be at least one of an output controllable power generation source and an output controllable power generation source. And, the microgrid of the present invention can include an energy storage device. There is no limitation on the number of loads and power sources belonging to the micro grid of the present invention.

Such a micro grid can be operated independently or in conjunction with the power system with control mechanisms such as optimal control, economic dispatch, and the like. Alternatively, the microgrid can be operated independently or in conjunction with the power system due to the accident and recovery of the power system. Or, in the context of economic dispatch, electricity trading between the microgrid and the utility grid can take place.

Korean Patent Laid-Open No. 10-2011-0034888 (April 4, 2011) Korean Patent Laid-Open No. 10-2016-0010789 (2016.01.28)

In an environment in which various types of micro grids exist, the present invention aims to provide a virtual power trading method between a micro grid that enables power trading between micro grids and an agent apparatus therefor.

According to another aspect of the present invention, there is provided a micro-grid inter-virtual-currency trading agent device including an information collecting unit for collecting electric-power transaction information from a plurality of micro-grids; And a relay unit for determining whether or not the micro-grid power trading can be concluded using the collected power trading information.

Here, the power transaction information may be any one of a power sales condition and a power purchase condition.

The power selling condition may include a sales power amount and a selling price.

In addition, the power purchase condition may include a purchase power amount and a purchase price.

Also, the repeater may determine that the power trading can be concluded when the power sales condition and the power purchase condition are matched.

The microgrid system may further include an evidence data collection unit for collecting evidence data from the microgrid that can be used to determine whether or not the power exchange has been normally performed between the microgrid systems to which the power transaction is concluded, .

The information processing apparatus may further include an evidence data providing unit for transmitting the evidence data collected by the evidence data collecting unit to at least one of a power company and a power market operator.

The settlement unit may further include a settlement unit for settlement of the gain generated by the power sale condition and the power purchase condition when the power transaction is completed.

The settlement unit may settle at least one of a relay fee and a power grid fee.

According to another aspect of the present invention, there is provided a method for virtual-to-microgrid power trading, comprising: collecting power transaction information from a plurality of microgrid; And determining whether the micro-grid power trading can be concluded using the collected power trading information.

Here, the power transaction information may be any one of a power sales condition and a power purchase condition.

The power selling condition may include a sales power amount and a selling price.

In addition, the power purchase condition may include a purchase power amount and a purchase price.

In addition, when the power sales condition and the power purchase condition are matched, it can be determined that the power trading can be concluded.

The method may further include the step of collecting, from the microgrid, evidence data for judging whether or not power trading has been normally performed between the microgrid in which the power trading is concluded, when it is determined that the power trading can be concluded.

The method may further include transmitting the collected evidence to at least one of a power company and a power market operator.

In addition, the method may further include the step of, when the power trading is completed, calculating a gain generated by the power sales condition and the power purchase condition.

In addition, at least one of the relay fee and the power grid fee may be settled in the settlement of the benefit amount.

The present invention enables power trading between micro grids to benefit between micro grids that desire to sell power and micro grids that desire to purchase power.

The present invention enables power trading between the microgrid in cooperation with the power trading market and the power grid.

1 is a schematic diagram of a micro-grid inter-virtual power trading system in accordance with a preferred embodiment of the present invention.
2 is a functional block diagram of the agent apparatus of FIG.
3 is a flow chart for a virtual power trading process performed by the agent device of FIG.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, .

On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention.

The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Hereinafter, a microgrid inter-virtual power trading system according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. 1 is a schematic diagram of a micro-grid inter-virtual power trading system in accordance with a preferred embodiment of the present invention. 2 is a functional block diagram of the agent apparatus of FIG.

1, a microgrid inter-virtual power trading system according to a preferred embodiment of the present invention includes a micro grid 100, a micro grid agent apparatus 200 (hereinafter referred to as "MG agent apparatus"), A power supplier 400, and a power trading market operator 500. The power supplier 400 may be a power supply company or a power supply company. The device on the micro grid 100, the MG agent device 200, the MG MI device 300, the power company 400 side device and the power trading market operator 500 (for example, the power exchange KPX) (Not shown). Here, the communication network may be any one of wired and wireless communication networks. And, the communication protocol may be unlimited. Various communication methods may be mixed. Also, a power line communication (PLC) scheme may be used. 1, at least one of the power company 400 and the power trading market operator 500 may be included in the microgrid inter-virtual power trading system of the present invention.

The microgrid 100 in FIG. 1 may be any of the following: i) a load cluster formed only by a load connected to a common connection point ii) a generator cluster formed by only a generator, and iii) a cluster with both a generator and a load. That is, the microgrid of the present invention can be in various forms. The microgrid of the present invention may include a unit for performing control operations in the microgrid. In the micro grid of the present invention, the load may be at least one of a controllable load and an uncontrollable load. Further, in the micro grid of the present invention, the power source may be at least one of an output controllable load and an output controllable load. And, the microgrid of the present invention can include an energy storage device. In the microgrid of the present invention, there may be no limitation on the number of loads and power sources belonging to the microgrid. In FIG. 1, each of the plurality of micro-grids 100 may be any one of various micro-grid shapes defined by the present invention described above. Each of the plurality of micro-grids 100 may be electrically connected through a power grid (not shown). The grid can be a utility grid. And, a plurality of microgrid may belong to different distribution planes. And, the operating subject of the different distribution view may be different.

Each of the plurality of micro grids 100 may include a control unit capable of managing the microgrid in conjunction with the MG agent apparatus.

The MG agent apparatus 200 can manage power transactions of at least one microgrid 100, which is a lower node in terms of a communication architecture. The MG agent apparatus 200 may be plural. When there are a plurality of MG agent apparatuses 200, the operating subjects may be different from each other. The plurality of microgrids managed by the MG agent apparatus 200 may belong to the same distribution scheme, respectively, or may be different from each other.

A plurality of MG agent apparatuses 200 are managed by the MG MI apparatus 300, and may perform a virtual power trading-related operation in cooperation with the MG MI apparatus 300.

The micro-grid power trading performed by the MG agent device 200 is a virtual power trading concept, and there may be no physical limitation in power trading. In other words, when power is exchanged between microgrid, existing power grid interconnecting multiple microgrids can be used as is.

In addition, the power transaction proof in the micro-grid inter-power transaction performed by the MG agent apparatus 200 may be a concept of measurement based proof rather than physical direct transaction.

The micro-grid power transaction performed by the MG agent apparatus 200 can be performed by the MG agent apparatus 200 under the power market mechanism without going through the existing power market.

In addition, power exchange between various micro-grids can be performed through power exchange between the micro-grids performed by the MG agent device 200, and economical efficiency of each micro-grid object can be maximized through various micro-grid power transactions.

The MG agent device 200 may integrate microgrid resources to allow the microgrid to participate in the power market through a power market intermediary (MG MI device in the present invention).

The economical efficiency of each microgrid object can be maximized through various microgrid power trading by scheduling of the MG agent apparatus 200.

In addition, microgrid resources can be integrated and the microgrid can participate in the power market through power market intermediaries (MG MI devices in the present invention).

Here, the power trading between the micro grid and the power market through the micro grid-based power trading and the MG agent apparatus 200 / MG MI apparatus 300 may be the concept of the metering amount-based power transaction proof.

A relay fee and a power grid fee may be added to the profit generating portion according to the power trading intervention through the MG agent apparatus 200. [

The MG agent apparatus 200 can contribute to the weight and efficiency of the EMS (Energy Management System) in the microgrid 100 through the historical data management proxy of the microgrid 100 to be managed.

In the present invention, the MG MI 300 may play an integrated role in the power market transactions of the MG agent devices 200.

The MG MI device 300 may be operated singularly or plural. Rather than managing all the micro grids connected to the power network with one MG MI device 300, the integrated management of the MG MI device 300 through the plurality of MG agent devices 200 is efficient and new business area expansion and It is easy to develop. When the distribution business network is divided, it is preferable to manage it by a plurality of MG agent apparatuses 200.

The MG MI device 300 of the present invention can store the transaction proof data of the MG agent device 200 that is interlocked with the MG MI device 300 and provide transaction proof data to the electric power company 400 and the power transaction market operator 500 .

The MG MI device 300 of the present invention can assist in the settlement of electric power charges of the micro grid through proof of the power transaction in cooperation with the utility charge settlement system.

The MG MI device 300 of the present invention can relay the power trading market and the micro grid through the interworking with the MG agent device 200 and relay the demand response market and the micro grid.

The MG MI 300 of the present invention develops a power bill system through historical data of micro grid resources managed by the MG agent apparatus 200 through interworking with the MG agent apparatus 200, A reaction system can be developed.

The MG MI device 300 of the present invention can perform virtual power trading among the microgrid 100, virtual power trading between the MG agent devices 200, power trading of the microgrid 100, Settlement of accounts, and settlement of charges. The MG MI device 300 collects the transaction proof data from the MG agent device 200 and provides it to the electric utility charge settlement system that cooperates with the MG MI device 300. The electric utility charge settlement system reflects the transaction proof data in the electric charge settlement . ≪ / RTI > The MG MI device 300 may provide the same day and real time power trading market information to the MG agent device 200. The MG MI 300 device may then provide the MG agent device 200 with the power trading market information the next day or after a predetermined time.

2, the MG agent apparatus 200 includes an information collecting unit 210, a relay unit 220, a proof data collection unit 230, a settlement unit 240, and a proof data providing unit 250 .

The information collecting unit 210 can collect the power transaction information from the micro grid 100 interlocked with each other. Here, the electric power transaction information may be any one of electric power sales information and electric power purchase information. The information collecting unit 210 may collect power purchase information from a micro grid that is intended to purchase electric power sales information as power transaction information from a micro grid to sell electric power. The power sale information may include power sale conditions (e.g., sales power, sales price, etc.). The power purchase information may include power purchase conditions (purchased power, sales price, etc.).

The relay unit 220 can determine whether the power trading can be concluded by referring to the power trading information. When the power purchase condition and the power sale condition match, the relay unit 220 can determine that the power transaction between the micro grid providing the power sale condition and the micro grid providing the power purchase condition can be concluded. If the power purchase condition and the power sale condition do not match, the relay unit 220 can determine that the power purchase contract is incomplete between the micro grid providing the power sale condition and the micro grid providing the power purchase condition. Convergence may mean that all of the mutual power trading conditions are met. For example, if the purchase price is equal to or greater than the selling price, it can be regarded as a match. If the price is matched but the amount of electricity purchased is larger than the amount of electricity sold, it can be regarded as a sum of the amount of electricity sold (that is, electricity trading is established).

The relay unit 220 can determine whether the power trading can be concluded by the power sales condition or the power purchase condition when the micro grid having the power sales condition and the micro grid providing the power purchase condition have a plurality of have. At this time, it may be determined whether or not the power trading can be concluded according to a predetermined priority (for example, a power trading information providing procedure).

According to the relay of the relay 220, the evidence data collection unit 230 can collect evidence from the microgrid that can determine whether the power transaction has been normally performed between the microgrid with which the power transaction is concluded. For example, the evidence may be a metric corresponding to the amount of electricity sold on the micro grid side to supply power according to the established power trading conditions. When the amount of sales power included in the established power trading condition and the amount of power supplied to the power grid by the micro grid to sell the power are equal, it is determined that the power trading according to the power trading condition is normally completed .

If it is determined that the power transaction is completed in the proof data collection unit 230, the settlement unit 240 can settle the gain generated by the power purchase condition and the power sale condition. The gain can be set based on the amount of profits the microgrid that sold the power receives. Or may be set based on the amount of profit received by the microgrid that purchased the power. Or may be set based on the benefit amount of both. For example, if the purchase price in the sales condition is 100 won and the purchase price in the purchasing condition is 150, if the conditions are matched and the power transaction is concluded, the gain amount according to the power transaction may be 50 won.

The settlement unit 240 may set a predetermined portion of the revenues as a relay commission. On the other hand, a fee that is proportional to the amount of electricity sold, regardless of the gain, can be a relay fee. Then, the predetermined portion of the revenues can be used as a power grid fee. On the other hand, a fee that is proportional to the amount of power purchased, regardless of the gain, can be a relay fee. And, regardless of the gain, the cost that is proportional to the amount of electricity purchased can be the electricity cost of the grid. The settlement unit 240 can perform settlement of the utility fee with the electric power company 400. The settlement unit 240 can perform settlement of the relay fee according to the set contract condition with at least one of the micro grid that sold the power and the micro grid that purchased the power.

The evidence data providing unit 250 may provide the electric power company 400 or the power trading market operator 500 with proof of the fact that the electricity trading is normally performed. Here, the evidence may include the sales power of the microgrid that sold the power. Alternatively, the evidence may include the amount of power purchased by the microgrid that purchased the power. Alternatively, the evidence may include power trading parties (microgrid) information between the microgrid. Based on this evidence, the utilities can estimate the electricity price of the power buyer. For example, the electricity price may be calculated by subtracting the amount of power supplied by another power source from the other micro grid from the total amount of power supplied by the power buyer through the power grid. The evidence may be transmitted via the MG MI device 300.

Hereinafter, a micro-grid inter-virtual power trading method according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. 3 is a flow chart for a virtual power trading process performed by the agent device of FIG.

First, the information collecting unit 210 may collect the power transaction information from the micro grid 100 that interlocks with the power trading information (S31). Here, the electric power transaction information may be any one of electric power sales information and electric power purchase information. The information collecting unit 210 may collect power purchase information from a micro grid that is intended to purchase electric power sales information as power transaction information from a micro grid to sell electric power. The power sale information may include power sale conditions (e.g., sales power, sales price, etc.). The power purchase information may include purchase conditions (purchased power, sales price, etc.).

The relay unit 220 can determine whether the power trading can be concluded by referring to the power trading information (S32). When the power purchase condition and the power sale condition match, the relay unit 220 can determine that the power transaction between the micro grid providing the power sale condition and the micro grid providing the power purchase condition can be concluded. If the power purchase condition and the power sale condition do not match, the relay unit 220 can determine that the power purchase contract is incomplete between the micro grid providing the power sale condition and the micro grid providing the power purchase condition ( S33). The relay unit 220 can determine whether the power trading can be concluded by the power sales condition or the power purchase condition when the micro grid having the power sales condition and the micro grid providing the power purchase condition have a plurality of have. At this time, it may be determined whether or not the power trading can be concluded according to a predetermined priority (for example, a power trading information providing procedure).

According to the relay of the relay 220, the evidence data collecting unit 230 can collect evidence from the microgrid to determine whether the power transaction has been normally performed between the microgrid with which the power transaction is concluded (S34). For example, the evidence may be a metric corresponding to the amount of electricity sold on the micro grid side to supply power according to the established power trading conditions. When the amount of sales power included in the established power trading condition and the amount of power supplied to the power grid by the micro grid to sell the power are equal, it is determined that the power trading according to the power trading condition is normally completed .

If it is determined that the power transaction is completed in the proof data collection unit 230, the settlement unit 240 can settle the completed power transaction (S35). For example, the settlement unit 240 can settle the gain amount generated by the purchase condition and the sales condition. The gain can be set based on the amount of profits the microgrid that sold the power receives. Or may be set based on the amount of profit received by the microgrid that purchased the power. Or may be set based on the benefit amount of both. For example, if the purchase price in the sales condition is 100 won and the purchase price in the purchasing condition is 150, if the conditions are matched and the power transaction is concluded, the gain amount according to the power transaction may be 50 won.

The settlement unit 240 may set a predetermined portion of the revenues as a relay commission. On the other hand, a fee that is proportional to the amount of electricity sold, regardless of the gain, can be a relay fee. Then, the predetermined portion of the revenues can be used as a power grid fee. On the other hand, a fee that is proportional to the amount of power purchased, regardless of the gain, can be a relay fee. And, regardless of the gain, the cost that is proportional to the amount of electricity purchased can be the electricity cost of the grid.

The evidence data providing unit 250 may provide at least one of the electric power company 400 and the power trading market operator 500 with proof of the fact that the electricity trading is normally performed at step S36. Here, the evidence may include the sales power of the microgrid that sold the power. Alternatively, the evidence may include the amount of power purchased by the microgrid that purchased the power. Alternatively, the evidence may include power trading parties (microgrid) information between the microgrid. Based on this evidence, the utilities can estimate the electricity price of the power buyer. For example, the electricity price may be calculated by subtracting the amount of power supplied by another power source from the other micro grid from the total amount of power supplied by the power buyer through the power grid. The evidence may be transmitted via the MG MI device 300.

S35 and S36 may be performed in the order different or concurrently.

100: microgrid
200: MG agent device
300: MG MI device
400: Power company
500: Power Market Operator

Claims (18)

An information collecting unit collecting power transaction information from a plurality of micro grids; And
And a relay unit for determining whether or not the power trading can be concluded between the micro-grid using the collected power trading information. The method according to claim 1,
Wherein the power transaction information is one of a power sale condition and a power purchase condition. The method according to claim 1,
Wherein the power sales condition includes a sales power amount and a selling price. The method according to claim 1,
Wherein the power purchase condition includes a purchase power amount and a purchase price. The method according to claim 1,
Wherein the relay unit determines that the power trading can be concluded when the power sales condition and the power purchase condition are matched. The method according to claim 1,
And a proof data collecting unit for collecting proof data from the micro grid to judge whether or not the power exchange is normally performed between the micro grids in which the power trading is concluded when it is determined that the power trading can be concluded by the relay unit To-micro-grid virtual power trading agent device. The method according to claim 6,
Further comprising a proof data providing unit for transmitting the evidence data collected by the proof data collecting unit to at least one of a power company and a power market operator. 3. The method of claim 2,
Further comprising a settlement unit for calculating a gain generated by the power sales condition and the power purchase condition when the power transaction is completed. 9. The method of claim 8,
Wherein the settlement unit calculates at least one of a relay fee and a power grid fee. Collecting power transaction information from a plurality of micro-grids; And
And determining whether a power transaction can be concluded between the micro-grid using the collected power transaction information. 11. The method of claim 10,
Wherein the power transaction information is one of a power sale condition and a power purchase condition. 11. The method of claim 10,
Wherein the power sales condition includes a sales power amount and a selling price. 11. The method of claim 10,
Wherein the power purchase condition includes a purchase power amount and a purchase price. 11. The method of claim 10,
And determines that the power trading can be executed when the power sales condition and the power purchase condition are matched. 11. The method of claim 10,
Further comprising the step of collecting, from the micro grid, evidence from the microgrid that it is possible to determine whether a power transaction has been normally made between the microgrid with which the power transaction is concluded, How to trade. 16. The method of claim 15,
And transmitting the collected evidence to at least one of a power company and a power market operator. 12. The method of claim 11,
Further comprising the step of: if the power transaction is completed, calculating a gain generated by the power sales condition and the power purchase condition. 18. The method of claim 17,
Wherein at least one of a relay fee and a power grid fee is settled in the step of calculating the benefit amount.

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