KR20220000054A - System and method for power transaction intermediation bassed on block chain - Google Patents

Abstract

The present invention relates to a blockchain-based power transaction intermediation method which comprises the following steps: (a) enabling a predetermined prosumer to request a prediction of the amount of power to be generated from a power trading platform through a prosumer terminal; (b) predicting and transmitting, by the power trading platform, the amount of power generation to the prosumer terminal; (c) generating, by the prosumer, the power according to generation amount information predicted in the step (b) and selling the power to the power trading platform; (d) enabling any other prosumer requiring power among a plurality of prosumers to request a power purchase to the power trading platform through the prosumer terminal (100); (e) matching, by a power trading module (210) of the power trading platform, a prosumer who wants to sell power and a prosumer who wants to purchase power to conclude a transaction; (f) notifying, by the power trading platform, the prosumer who wants to sell power and the prosumer who wants to purchase power of conclusion of the power transaction; (g) when the prosumer who wants to sell power transmits power, enabling the prosumer who wants to purchase power to receive the power to perform the power transaction; and (h) storing, by the power trading platform, the power transactions between the prosumer who wants to sell power and the prosumer who wants to purchase power in the step (g) in a blockchain. Accordingly, forgery and falsification of weighing data can be prevented, thereby forming trust among members.

Description

SYSTEM AND METHOD FOR POWER TRANSACTION INTERMEDIATION BASSED ON BLOCK CHAIN

The present invention relates to a blockchain-based power transaction brokerage system and method, and more particularly, to receive meteorological data from the Meteorological Administration, predict the amount of power generation in advance with artificial intelligence, and efficiently collect small-scale distributed resources by using the blockchain. It relates to a blockchain-based power trading brokerage system and method that can trade power on an exchange.

Although there has been a small-scale electricity trading system in the past, there is a problem in that it is difficult for prosumers to predict how much power generation and usage will be in the future because there is no forecast data that intermediaries can refer to when bidding.

Above all, there is no small block chain-based power transaction brokerage system using block chain, so it is difficult to build trust among members in the amount of power generation and transaction volume, and there are problems in that it is vulnerable to forgery and falsification of metering data.

Republic of Korea Patent Publication No. 10-2085141 (2020.02.28)

In order to solve the above problems, the present invention collects past power generation data and weather data, pre-processes the collected data, and performs a selected deep learning algorithm to predict and provide the power to be produced by the seller, and provide power buyers and sellers The purpose is to provide a blockchain-based power transaction brokerage method that can mediate power transactions by matching.

In order to solve the above problems, a block chain-based power transaction brokerage method according to the present invention includes the steps of: (a) requesting a certain prosumer to predict the amount of power generation to be generated from a power trading platform through a prosumer terminal; (b) predicting the amount of power generation by the power trading platform and providing it to the prosumer terminal; (c) selling, by the prosumer, electricity to the electricity trading platform according to the generation amount information predicted and provided in step (b); (d) making a power purchase request to the power trading platform through the prosumer terminal 100 by any other prosumer requiring power among the plurality of prosumers; (e) the power trading module 210 of the power trading platform matches a prosumer who wants to sell power and a prosumer who wants to purchase power and concludes a transaction; (f) the power trading platform notifying the prosumer who wants to sell electricity and the prosumer who wants to purchase electricity that the power transaction has been concluded, respectively; (g) when the prosumer who wants to sell power transmits power, the prosumer who wants to purchase power receives the power and performs power transaction; (h) storing, by the power trading platform, power transactions between the prosumer who wants to sell power and the prosumer who wants to purchase power in the step (g); and (i) when the electricity transaction between the prosumer who wants to sell electricity and the prosumer who wants to purchase electricity in step (h) is completed, the electricity trading platform receives a notification of the completion of the electricity transaction from the prosumers doing the electricity transaction. and performing cost processing through a virtual currency transaction in which the held virtual currency is paid to the seller's account on the block chain.

Preferably, in order to solve the above-mentioned problem, step (b) of the block chain-based power transaction brokerage method according to the present invention includes: (b-1) the power trading platform collects past power generation data and weather data; (b-2) selecting, by the power trading platform, an algorithm for estimating the amount of power generation, and setting an execution environment of the selected algorithm; (b-3) calculating, by the power trading platform, the power amount prediction result by performing the algorithm selected in step (b-2); (b-4) determining the accuracy of the amount of electricity predicted by the power trading platform; (b-5) The power trading platform repeats the process after step (b-3) of selecting a prediction algorithm when the accuracy is less than or equal to the target value in step (b-4), and the result ( accuracy); (b-6) In the electric energy prediction environment set through the steps (b-1) to (b-5), the electric power trading platform collects weather forecast data, selects a deep learning algorithm, and sets an environment for performing the algorithm to do; and (b-7) performing, by the trading platform, the deep learning algorithm, and predicting the amount of power required accordingly.

The blockchain-based power transaction brokerage system and method according to the present invention can provide predictive data that can be helpful when a broker makes a bid by utilizing weather data and artificial intelligence, and the open source Ethereum blockchain can be used to build a power brokerage platform quickly and inexpensively.

In addition, the blockchain-based power transaction brokerage system and method according to the present invention can easily perform settlement of transactions by utilizing the virtual currency of the Ethereum blockchain, and the irreversible characteristics of the block chain prevent forgery and falsification of metering data. It is possible to build trust among members.

In addition, the block chain-based power transaction brokerage system and method according to the present invention can increase the participation rate in power trade because energy prosumers can receive forecast data that can know in advance the amount of power generation and usage in the future, and the brokerage service provider can predict You can use the information to receive solar power generation forecasting incentives from the power exchange.

Finally, the blockchain-based power transaction brokerage system and method according to the present invention may directly mediate power between a small-scale power producer and a consumer who needs power, or between a small-scale power producer and a power exchange. .

1 is a diagram of a blockchain-based power transaction brokerage system according to the present invention.
2 is a detailed diagram of a blockchain-based power transaction brokerage system according to the present invention.
3 is a diagram showing the form of a mediation result report of the blockchain-based power transaction mediation system according to the present invention.
4 is a flowchart of a block chain-based power transaction brokerage method according to the present invention.
5 is a detailed flowchart of a prediction room among the block chain-based power transaction brokerage methods according to the present invention.

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. Based on the principle that there is, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, so they can be substituted at the time of the present application It should be understood that various equivalents and modifications may exist.

Hereinafter, with reference to the accompanying drawings, a block chain-based power transaction brokerage system and method according to the present invention will be described in detail.

1 is a diagram of a blockchain-based power transaction brokerage system according to the present invention.

As shown in FIG. 1 , the blockchain-based power transaction brokerage system according to the present invention includes a plurality of prosumer terminals 100 , a power trading platform 200 , a meteorological agency server 300 , and a power exchange server 400 . do.

A plurality of energy prosumers consume energy and also play the role of energy producers by holding solar power generation facilities or ESS (Energy Storage System).

The prosumer terminal 100 is a terminal possessed by energy prosumers as described above, and is configured to access the power trading platform 200 to purchase necessary energy or to sell the remaining energy produced through a solar power generation facility.

The Meteorological Administration server 300 is connected to the power trading platform 200 to provide data related to weather data by date, ie, temperature, humidity, lightning, cloudiness, and the like.

The power exchange server 400 mediates small-scale power as a method for efficient use of small-scale distributed resources such as new and renewable energy and activation of a new energy industry.

In particular, the power exchange server 400 announces the power market price (SMP) circulated in the power market, and just as the price of a general product is determined according to demand and supply, the power demand curve and the supply curve of power generation companies participating in the bidding Set the electricity market price (SMP) at the intersection.

The power trading platform 200 is an artificial intelligence-based blockchain-based power trading platform to which the prosumer terminal 100 , the Korea Meteorological Administration server 300 , and the power exchange server 400 are connected.

That is, the electricity trading platform 200 is an intermediary operator that recruits the prosumers and sells small-scale electricity to the electricity exchange, and can directly broker electricity between small-scale electricity producers and consumers who need electricity, and with small-scale electricity producers. Power can also be brokered between power exchanges.

More specifically, the power trading platform 200 of the block chain-based power trading intermediary system according to the present invention will be described with reference to FIG. 2 .

As shown in FIG. 1 , the power trading platform 200 includes a power trading module 210 , a power generation prediction module 220 , and a block chain 230 .

The power trading module 210 is connected to the power exchange server 400 and the prosumer terminal 100 to request a power transaction from the power exchange or prosumer, or conversely, approve the power transaction request from the power exchange or prosumer, Settling the cost of electricity transaction.

More specifically, the power transaction module 210 includes a settlement unit 211 , a power transaction unit 212 , and a block chain interface unit 213 , wherein the settlement unit 211 is the power exchange server 400 . Alternatively, cash is exchanged for a dedicated coin required for power transaction between prosumer terminals 100, the price for power transaction is settled with a dedicated coin, and the remaining dedicated coin is exchanged for cash at the request of the power exchange or prosumer. can give

The power transaction unit 212 is connected to the prosumer terminal 100, and there is a request to sell the remaining energy after the prosumer consumes the energy produced by the prosumer while producing energy by holding a photovoltaic power generation facility or ESS. , or if there is a purchase request because consumption exceeds production, it is approved.

Similarly, the power trading unit 212 is connected to the power exchange servers 400 that broker power produced by small power producers to collect small-scale distributed resources and collect power data to purchase power produced by small-scale power producers. The power required by the power exchange may be provided by intermediary to them, or conversely, by receiving the power required by the power exchange from the prosumers.

The block chain interface unit 213 stores the transaction details of the power transaction unit 212 and the settlement details of the settlement unit 211 in the block chain 230 .

The generation amount prediction module 220 includes a data collection interface unit 221 , a prediction unit 222 , and a prediction result providing unit 223 .

The data collection interface unit 221 includes a photovoltaic power generation facility or ESS (Energy Storage System) from a prosumer that consumes energy and produces energy at the same time through the prosumer terminal 100. Alternatively, it collects data such as the amount of electricity generated by time, location, sunlight, temperature, and humidity.

In addition, the data collection interface unit 221 collects meteorological data, such as temperature, humidity, air volume, and cloud volume, provided by the Meteorological Agency server 300 .

The prediction unit 222 predicts the amount of power generation in advance using the data collected by the data collection interface unit 221 .

More specifically, the prediction unit 222 is internally equipped with a machine learning algorithm, and processes data collected for machine learning modeling.

That is, the prediction unit 222 performs data preprocessing to match data formats, complete or remove missing values, and remove outliers.

The prediction unit 222 matches the data format through characterization, numbering, or integerization of data, completes missing values in the data collection process, and determines whether the value is significantly larger or smaller among the collected data. Perform preprocessing to remove the corresponding outlier.

In particular, the prediction unit 222 may be removed when it is impossible to complete the missing values in the data collection process.

Next, when the data pre-processing process is completed as described above, the prediction unit 222 creates a modeling environment for learning the machine learning algorithm, such as epoch, sigma setting, learning data range setting, test data setting, prediction period setting, etc. set

The epoch is the number of learning times, and the epoch setting is simply to set the number of times, and the learning data is the weather forecast data such as date, cloud shape, lightning, wind volume, wind direction, cloud volume, precipitation, temperature, humidity, etc. The learning data range setting is the Korea Meteorological Administration It is to set the data provided by the system according to the forecast period, and the test data is the weather forecast data and the power generation forecast data by applying the weather forecast data to the model created by learning.

The forecast period refers to a period in which there is weather forecast data precisely on a daily basis.

When the modeling environment setting is completed, the prediction unit 222 performs a machine learning algorithm such as LSTM (Long Short Term Memory), regression analysis, and SVM (Support Vector Machine) in an environment set based on the processed data to generate power generation. predict

The prediction result providing unit 223 reports to the prosumer consuming and producing energy through the prosumer terminal 100 connected to the amount of power predicted by the prediction unit 222 in the form of a report as shown in FIG. 3 . can provide

The block chain 230 is equipped with an Ethereum-based smart contract for data storage, so a number of prosumer terminals 100 and power exchange servers 400 participating in electricity transactions are sold and purchased electricity of the electricity transaction unit 212 The data and the corresponding settlement history data of the settlement unit 211 are stored in a block, connected in a chain form, and copied and stored in a distributed manner in another power trading platform 200 at the same time.

The smart contract is a kind of program executed on the block chain, and is a digital contract method in which contract contents are executed when conditions are met.

As another embodiment, a block-chain-based power transaction brokerage method by a block-chain-based power transaction brokerage system according to the present invention having the above-described configuration will be described with reference to FIGS. 4 and 5 .

Among the plurality of prosumers, a first prosumer requesting the power trading platform 200 connected through the prosumer terminal 100 to predict the amount of power to be generated is performed (S100).

For reference, the following second prosumers, including the first prosumer, and all prosumers are prosumers that have already been registered as members and signed a contract before power transaction according to the present invention.

In response to the request in S100, the power generation amount prediction module 220 of the power trading platform 200 executes a deep learning algorithm with the collected information to predict the generation amount and provide it to the prosumer terminal 100 ( S200).

The step S200 of predicting the amount of power generation will be described in more detail with reference to FIG. 5 .

First, the power trading platform 200 performs a step of collecting past power generation data and weather data (S210).

That is, the power trading platform 200 collects data, such as the amount of power generation, location, sunlight, temperature, humidity, etc. for each distributed resource by the past daily or hour, from the plurality of prosumers through the data collection interface 221 .

In addition, the data collection interface unit 221 collects meteorological data such as temperature, humidity, air volume, and cloud volume provided by the Meteorological Agency server 300 .

Next, the power trading platform 200 selects an algorithm for predicting the amount of power generation, and performs the steps of setting the execution environment of the selected algorithm (S220).

That is, in step S220, the power trading platform 200 selects an algorithm suitable for predicting power generation among various machine learning algorithms, such as LSTM (Long Short Term Memory), regression analysis, and SVM (Support Vector Machine), and generates power of the selected algorithm. Set up the execution environment to increase the accuracy of prediction.

The power trading platform 200 performs the step of calculating the power amount prediction result by performing the algorithm selected in step S220 (S230).

Thereafter, the power trading platform 200 repeats the process after step S200 of selecting a prediction algorithm when the accuracy is less than or equal to the target value through the step (S240) of determining the accuracy of the predicted power amount, and when the accuracy is greater than the target value A step of checking the result (accuracy) is performed (S250).

As described above, in the power amount prediction environment set through steps S210 to S250, the power trading platform 200 performs a step (S260) of collecting weather forecast data, selects a deep learning algorithm, and selects an environment for performing the algorithm A setting step is performed (S270).

In the step S270, if there is no special variable, it is preferable to set the environment by selecting the algorithm selected in S220 as it is.

Then, the trading platform 200 performs the deep learning algorithm, and performs the step of estimating the amount of power required accordingly (S280).

The first prosumer generates power according to the generation amount information predicted in step S200 and sells power to the power trading platform 200 (S300).

In this case, it is preferable that the first prosumer, who owns the power resource, check the expected power generation amount and the power generation amount possessed, and register the power generation amount and unit price to be sold.

Thereafter, any other second prosumer requiring power among the plurality of prosumers makes a power purchase request to the power trading platform 200 connected through the prosumer terminal 100 ( S400 ).

At this time, it is preferable that the first prosumer, the purchaser, selects and requests the transaction after checking the power generation amount and unit price among the transactions registered for sale in the electricity trading platform 200 in step S300.

In response to the power purchase request in step S400, the power trading module 210 of the power trading platform 200 matches the prosumer who wants to sell power and the prosumer who wants to purchase power and concludes a transaction (S500). ).

Then, the power trading platform 200 performs a step of notifying the prosumer who wants to sell power and the prosumer who wants to purchase power, respectively, that the power transaction has been concluded ( S600 ).

In step S600, when the first prosumer, the seller, who has received the notification of the conclusion of the loan transaction, transmits power, the second prosumer, the buyer, receives the power transmitted by the first prosumer, thereby conducting a power transaction between the first prosumer and the second prosumer. The performing step is performed (S700).

At the same time, the power trading platform 200 parallelly stores the power transaction record between the first and second prosumers in the block chain 230 (S700`).

As described above, the block chain 230 stores power transaction records between prosumers in preparation for disputes and issues certificates upon request by members.

When the power transaction between the first prosumer and the second prosumer is completed in step S700, the power trading platform 200 receives a notification of completion of the power transaction from the first prosumer terminal 100 and the second prosumer terminal 100'. A step of performing cost processing through a virtual currency transaction in which the virtual currency held in the buyer's account is paid to the seller's account on the block chain 230 is performed (S800).

In this case, it is preferable to purchase the cryptocurrency required for power transaction from the operator by paying cash in advance before the power transaction.

On the other hand, as the second prosumer, the buyer, transmits the Ethereum cryptocurrency to the first prosumer, the seller, the cost processing in step S800 is performed.

The seller, the first prosumer, can exchange the cryptocurrency received through the power sale for cash through the prosumer terminal 100 . The above-described power transaction describes a transaction between prosumers.

Hereinafter, a method of trading electricity through the power exchange of the prosumer will be briefly described.

First, the power trading platform 200 may perform power trading by registering as an intermediary operator through member registration and contract with the power exchange.

The power trading platform 200 collects and manages data for each distributed resource. In the process of collecting and managing the data, the power trading platform 200 checks and informs the data transmission/reception error, and checks the actual power generation compared to the expected power generation.

The power trading platform 200 submits the expected power generation amount to the power exchange server 400 , stores data in the block chain 230 in preparation for a dispute, and issues a certificate upon request by members.

In the above, the technical idea of the present invention has been described along with the accompanying drawings, but this is an exemplary description of a preferred embodiment of the present invention and does not limit the present invention. In addition, it is clear that various modifications and imitations are possible without departing from the scope of the technical spirit of the present invention by anyone having ordinary knowledge in the technical field to which the present invention pertains.

100: prosumer terminal
200: power trading platform
210: power trading module
211: settlement department
212: power trading department
213: block chain interface unit
220: power generation prediction module
230: Blockchain
300: Meteorological Agency Server
400: power exchange server

Claims (5)

(a) requesting, by a certain prosumer, a prediction of the amount of power to be generated from the power trading platform through the prosumer terminal;
(b) predicting the amount of power generation by the power trading platform and providing it to the prosumer terminal;
(c) selling, by the prosumer, electricity to the electricity trading platform according to the generation amount information predicted in step (b);
(d) making a power purchase request to the power trading platform through the prosumer terminal 100 by any other prosumer requiring power among the plurality of prosumers;
(e) the power trading module 210 of the power trading platform matches the prosumer who wants to sell power and the prosumer who wants to purchase power and concludes a transaction;
(f) the power trading platform notifying the prosumer who wants to sell electricity and the prosumer who wants to purchase electricity that the power transaction has been concluded;
(g) when the prosumer who wants to sell power transmits power, the prosumer who wants to purchase power receives the power and performs power transaction; and
(h) storing, by the power trading platform, power transactions between the prosumer who wants to sell power and the prosumer who wants to purchase power in step (g) in a block chain; How to broker a trade.
The method of claim 1,
(i) When the electricity transaction between the prosumer who wants to sell electricity and the prosumer who wants to purchase electricity in step (h) is completed, the electricity trading platform that receives the notification of completion of the electricity transaction from the prosumers who trade electricity holds in the buyer's account A block chain-based power transaction brokerage method, characterized in that it further comprises; performing cost processing through a virtual currency transaction in which the virtual currency is paid to the seller's account on the block chain.
3. The method of claim 2,
Step (b) is
(b-1) collecting, by the power trading platform, past power generation data and weather data;
(b-2) selecting, by the power trading platform, an algorithm for predicting power generation, and setting an environment for performing the selected algorithm;
(b-3) calculating, by the power trading platform, the power amount prediction result by performing the algorithm selected in step (b-2);
(b-4) determining the accuracy of the amount of power predicted by the power trading platform;
(b-5) The power trading platform repeats the process after step (b-3) of selecting a prediction algorithm when the accuracy is below the target value in step (b-4), and results when the accuracy is above the target value ( accuracy);
(b-6) In the power amount prediction environment set through steps (b-1) to (b-5), the power trading platform collects weather forecast data, selects a deep learning algorithm, and sets an environment for performing the algorithm to do; and
(b-7) the transaction platform performing the deep learning algorithm, and estimating the amount of power required according to it;
4. The method of claim 3,
The power trading platform is
Before the step (b-2), the data types collected in the step (b-1) are characterized, numbered, or integerized to match the data format, and the missing values in the data collection process are completed or removed. , a block-chain-based power transaction brokerage method, characterized in that a pre-processing step of removing outliers corresponding to a significantly larger or smaller value among the collected data is performed.
5. The method of claim 4,
The power trading platform is
A block chain-based power transaction brokerage method, characterized in that the power transaction details of the prosumer to sell and the prosumer to purchase stored in the block chain so that it cannot be forged or tampered with in step (i) are issued as a certificate upon request.

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