KR20190118376A - Method for trading blockchain exchange based real electronic wallet and method for trading the same - Google Patents

Abstract

According to an embodiment of the present invention, a blockchain transaction processing method based on an actual transaction electronic wallet in cryptocurrency exchange comprises: an actual transaction electronic wallet providing process of allowing a cryptocurrency exchange server to generate an actual transaction electronic wallet for making a blockchain transaction to provide the same by members; a blockchain confirmation requesting process of allowing the cryptocurrency exchange server to add a blockchain transmission fee to cryptocurrency by each sale request from a seller and request blockchain confirmation to a blockchain network processing server in order to transfer cryptocurrency from an actual transaction electronic wallet of the seller to an actual transaction electronic wallet of a buyer if a trade including cryptocurrency sale and purchase is made between member terminals in the cryptocurrency exchange server; and a transaction fee processing process of allowing the cryptocurrency exchange server to process such that the seller and the buyer jointly pay a blockchain transaction transfer fee if blockchain transaction completion for the sale confirmation is received from the blockchain network processing server. According to the present invention, if a blockchain transaction happens through actual transaction electronic wallets of each member in an exchange, a transaction transfer fee for each member can be reduced.

Description

Method for trading blockchain exchange based real electronic wallet and method for trading the same}

The present invention relates to a blockchain transaction processing method, and a blockchain transaction processing method based on a real transaction electronic wallet in a cryptocurrency exchange.

Crypto-Currencies, represented by Bitcoin, have a common type of transaction ledger called Blockchain.

As an overview, an end user downloads a cryptocurrency wallet program to his computer and installs it on his computer, which then runs and synchronizes (matches) itself with the blockchain recorded on the network. Start with it. It usually takes three to seven days because the data reaches tens of gigabytes. After that sync, you can create your own address (the concept of an account at your bank) in your wallet and receive or send Bitcoin through that address (in Bitcoin, the address is 34 digits starting with 1 It is a combination of letters) and numbers, and the difficulty of this method is that there are many services in which the server having the entire node does not lower the node as the web wallet service (Blockchain Information, My Ethereum Wellet, Metamask, etc.).

Here, all crypto-currencies running on the blockchain system, including Bitcoin, are a pair of keys in the form of 'private key-public key (address)' between users. The private key corresponds to a password, which is a pair that only matches each other. For example, in the case of the Bitcoin QT program (user's personal wallet program), the user's password is encrypted and stored in the member computer. In the case of Bitcoin Exchange web wallet, the private key is encrypted and stored on the server using a user password or a server sort (SALT).

As such, the existing method is a method of storing the private key in the cryptocurrency exchange server 200 or in the member computer.

However, when using the cryptocurrency exchange server 200, the electronic wallet in each member's exchange is only a wallet operated based on a database (DB), not an actual electronic wallet on the blockchain. That is, when a member inquires his account using the cryptocurrency exchange server 200, the balance registered and stored in the server database DB is shown, but the actual balance existing in the address is meaningless to the member. In addition, there is a possibility that an insider related to cryptocurrency exchange security can secretly use the encrypted private key stored in the server.

Therefore, it is necessary to create and provide an electronic wallet of each member generated by the cryptocurrency exchange server 200 as a real transaction electronic wallet that can actually be traded on the blockchain, not an electronic wallet in a database form.

However, if the real transaction e-wallet is provided to registered members of the cryptocurrency exchange server 200, a fee is incurred each time a member makes a blockchain transaction through his or her real-time e-wallet, too much fee to the seller or the buyer. There is a problem that is burdened.

For example, when selling 10 Ethereum held by Seller A as shown in FIG. 1, when 10 Ethereum sold is bought as B1 Buyer 5 Ethereum, B2 Buyer 3 Ethereum, and B3 Buyer 2 Ethereum In this case, three transactions occur, and A seller pays 10 Ethereum and three transaction transmission fees in the city.

Therefore, when a blockchain transaction occurs through the real transaction e-wallet of each member in the exchange, a new method is needed to reduce the transaction transmission fee of each member.

Korean Patent Registration No. 10-1673073

An object of the present invention is to provide a means for reducing the transaction transmission fee when a blockchain transaction occurs through the real transaction electronic wallet of each member.

Embodiment of the present invention, the cryptocurrency exchange server, the real transaction e-wallet providing process for generating a real transaction e-wallet for blockchain transactions can be provided for each member; When a transaction including selling or buying cryptocurrency is made between member terminals in a cryptocurrency exchange server, the cryptocurrency exchange server encrypts the cryptocurrency transfer from the seller's real transaction e-wallet to the buyer's real transaction e-wallet, according to the seller's request to sell. A blockchain confirmation request process of requesting blockchain confirmation to a blockchain network processing server by adding a blockchain transmission fee to money; A transaction fee processing step of processing, by the cryptocurrency exchange server, the seller and the buyer jointly pay the transaction transmission fee of the blockchain when the blockchain transaction for the sell confirmation is received from the blockchain network processing server; can do.

Seller: In the case of a blockchain transaction of Buyer = 1: 1, the transaction fee processing process imposes the same amount as the Buyer's fee on the Buyer's fee to receive the deposit along with the Buying Amount, Exchange fee, and Buyer's fee. process; And a buyer fee distribution process of dividing the buyer fee transferred by the buyer by half and paying the same to the seller and the buyer.

Seller: Buyer = 1: N blockchain transaction, the transaction fee processing process imposes the same amount as the buyer's fee on N buyers as the buyer's fee, so that the purchase price, exchange fee, And receiving each transfer along with the buyer fee; Participants of the blockchain confirmation are paid [(N-1) × buyer fee] out of [N × buyer fee] received from N buyers and divide the other buyer fee by 1 / (N + 1) It may include a; buyer fee distribution process that pays the same to each seller and the buyer.

Seller: In the case of a blockchain transaction with Buyer = N: 1, the transaction fee processing process imposes the same amount as the blockchain transmission fee on the buyer per blockchain transaction as the buyer's fee, so that the purchase price, exchange fee, and buyer from the buyer The process of transferring each with a fee; It may include a buyer fee distribution process that divides the buyer fee received from the buyer into 1 / (N + 1) and pays the same to each seller and buyer who are parties to the blockchain confirmation.

In the case of a blockchain transaction with a seller: buyer = N: N, the transaction fee processing process imposes the same amount as the buyer's fee on N buyers as the buyer's fee, so that the purchase price, exchange fee, And receiving each transfer along with the buyer fee; Of the [N × buyer fee] received from N buyers, the amount corresponding to [(N-1) × buyer fee] is paid to the seller who paid the transaction transfer fee, and the other buyer fee is 1 / (N The purchaser fee distribution process of equally paying each seller and the buyer who are parties to the blockchain confirmation by dividing by × 2).

The buyer fee distribution process may be characterized by converting into a point form that can be used in the cryptocurrency exchange server and saving to the seller and the buyer, respectively.

The private key of the trading request member used in the blockchain confirmation request is encrypted and divided into a first divided private key and a second divided private key, and the first divided private key is stored in a cryptocurrency exchange server, and the second divided private key. Is stored in a trading request member terminal, and the blockchain confirmation request process receives a second split private key from a trading request member terminal at the time of the blockchain confirmation request, and receives the second split private key and a cryptocurrency. By using the first divided private key stored in the exchange server, the private key of the trade request member may be transmitted to the blockchain network processing server along with the transaction request information to request the transaction confirmation.

According to the embodiment of the present invention, when a blockchain transaction occurs through the real transaction electronic wallet of each member in the exchange, it is possible to reduce the transaction transmission fee of each member.

1 is a diagram showing a transaction fee is duplicated when a blockchain transaction through a real transaction electronic wallet.
2 is a block diagram of a blockchain transaction processing system based on a real wallet electronic wallet in a cryptocurrency exchange according to an embodiment of the present invention.
3 is a block diagram of a cryptocurrency exchange server according to an embodiment of the present invention.
4 is a block diagram illustrating a blockchain confirmation request using a split private key according to an embodiment of the present invention.
5 is a flowchart illustrating a blockchain transaction processing process based on a real transaction electronic wallet in a cryptocurrency exchange according to an embodiment of the present invention.
Figure 6 is an illustration of a 1: 1 blockchain transaction between the seller and the buyer in accordance with an embodiment of the present invention.
7 is an illustration of a 1: N blockchain transaction between a seller and a buyer in accordance with an embodiment of the present invention.
8 is an exemplary diagram in which a blockchain transaction of N: 1 is made between a seller and a buyer according to an embodiment of the present invention.
9 is an exemplary diagram in which a N: N blockchain transaction is made between a seller and a buyer in accordance with an embodiment of the present invention.
Figure 10 is an illustration of the fees when purchasing another cryptocurrency with a cryptocurrency other than the won according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and is provided to fully inform the scope of the invention to those skilled in the art. The invention is defined only by the scope of the claims. In addition, in the following description of the present invention, if it is determined that related related technologies and the like may obscure the gist of the present invention, detailed description thereof will be omitted.

2 is a block diagram of a blockchain transaction processing system based on a real transaction electronic wallet in a cryptocurrency exchange according to an embodiment of the present invention, and FIG. 3 is a block diagram of a cryptocurrency exchange server according to an embodiment of the present invention. 4 is a diagram illustrating a blockchain confirmation request using a split private key according to an embodiment of the present invention.

Since the actual transmission of a general cryptocurrency requires a plurality of confirmation processes, it is impossible to buy and sell frequently in a short time. In order to solve this problem, the trading system of the present invention generates an electronic wallet (hereinafter, referred to as a 'real trading electronic wallet') that can actually blockchain transactions on the exchange server, and uses a real trading electronic wallet for fast and stable blockchain trading. The action is made so that quick response is possible by real-time processing of order / contract.

To this end, the real-world electronic wallet-based trading system in the cryptocurrency exchange of the present invention, as shown in FIG. 2, a wired / wireless communication network (not shown), a member terminal 300, a cryptocurrency exchange server 200, and a blockchain network. It may include a processing server (100).

Hereinafter, a cryptocurrency is a concept including all of various digital cryptocurrencies such as Bitcoin, Bitcoin Cash, Ethereum, Litecoin, Namecoin, Dogecoin, Ripple, etc., which are traded on an exchange.

The wired / wireless communication network (not shown) provides wired or wireless communication between the member terminal 300 and the cryptocurrency exchange server 200 and between the cryptocurrency exchange server 200 and the blockchain network processing server 100. When such a wired / wireless communication network (not shown) is implemented as a wireless communication network, a wireless mobile communication network including a base transceiver station (BTS), a mobile switching center (MSC), and a home location register (HLR) Data communication can be performed using. In addition, when the wired / wireless communication network (not shown) is implemented as a wired communication network, it may be implemented as a network communication network, and data communication may be performed according to an Internet protocol such as Transmission Control Protocol / Internet Protocol (TCP / IP).

The member terminal 300 is a terminal used by a member registered to the cryptocurrency exchange server 200. In the drawings, a member phone 300 will be described as an example, but not only a smartphone but also a desktop PC and a tablet are described. A PC, a tablet PC, a notebook computer, and the like may be applicable. Of course, the terminal to which the present invention is applicable is not limited to the above-described type, and of course, may include all terminals capable of communicating with external devices.

Member terminal 300, the cryptocurrency trading app (APP; application) is installed, accesses the cryptocurrency exchange to display the cryptocurrency trading information, and also cryptocurrency trading (cryptocurrency) on the cryptocurrency exchange server 200 May be sold or bought).

For example, the member terminal 300 is equipped with a blockchain-based cryptocurrency trading app that transmits a transaction request signal including the price information of the cryptocurrency to be sold and the personal information of the trader to the cryptocurrency exchange server 200. Terminal. Here, the blockchain-based cryptocurrency trading app is an application program, which can be downloaded by accessing the app store through the member terminal 300 or directly connected to the blockchain-based digital cryptocurrency exchange server 200 to be downloaded and installed.

For reference, the cryptocurrency exchange server 200 requests the blockchain network processing server 100 for a blockchain confirmation according to a transaction request signal. Here, the blockchain confirmation is a message requesting to confirm and record a transaction including the price information of the cryptocurrency to be sold and the personal information of the trader on the blockchain, and the blockchain network processing server 100 Perform the requested blockchain confirmation.

In addition, the member terminal 300 displays a blockchain-based digital cryptocurrency transaction screen for inputting an amount of the digital cryptocurrency having a blockchain and selecting an instant messenger. The cryptocurrency transaction screen may include an amount display field for displaying the amount of the cryptocurrency having the blockchain.

In addition, the member terminal 300 may include a seller terminal 300a and a buyer terminal 300b. Hereinafter, a terminal for selling cryptocurrency is called a seller terminal 300a, and a terminal for buying cryptocurrency is a buyer terminal ( 300b).

When the blockchain transaction confirmation is requested from the cryptocurrency exchange server 200, the blockchain network processing server 100 propagates the blockchain transaction based on the transaction request information to an adjacent node to confirm the blockchain transaction confirmation (cicada authentication and recording). ), And notifies the cryptocurrency exchange server 200 of the completion of the blockchain trading confirmation. For example, the Bitcoin blockchain network processing server 100 performs a blockchain confirmation that exchanges 6 confirmations with an adjacent node per one blockchain transaction and completes the transaction.

To this end, the blockchain network processing server 100 performs a blockchain-based cryptocurrency transaction by verifying the transaction information for the cryptocurrency transaction having the blockchain transmitted when the transaction information for the cryptocurrency transaction having the blockchain is transmitted. A blockchain is installed which authenticates and records transaction information for cryptocurrency transactions having a blockchain in accordance with the authentication. Therefore, peer-topeer network (P2P) based on peer-topeer network (P2P) that performs cryptocurrency transactions with blockchain through confirmation (authentication and record) for cryptocurrency transactions with blockchain. Devices that make up a distributed blockchain network. In particular, in the present invention, the electronic wallet for each individual member operated by the cryptocurrency exchange corresponds to a member of one blockchain network processing server 100 in the configuration of the blockchain network processing server 100.

The cryptocurrency exchange server 200 generates a real transaction electronic wallet through which blockchain transactions can be made, and provides each member. In the past, the electronic wallet that can actually perform blockchain transactions can be managed as a database without creating each member, but the cryptocurrency exchange server 200 of the present invention generates an electronic wallet that can actually perform blockchain transactions for each member. to provide.

Therefore, the cryptocurrency exchange server 200 subtracts the amount of money sold from the blockchain-based cryptocurrency amount information held in the seller's actual transaction electronic wallet, and the blockchain-based cryptocurrency of the buyer's actual transaction electronic wallet by the deducted amount. To generate transaction information for digital cryptocurrency transactions consisting of transaction details accumulated in the amount information, it is spread to the blockchain network processing server (100).

In particular, the cryptocurrency exchange server 200 of the present invention, when the blockchain transaction for the sell confirmation is completed, the cryptocurrency exchange server 200 processes the seller and the buyer to jointly bear the transmission fee of the blockchain, It is possible to prevent excessive transfer charges in either side, which ultimately reduces blockchain transaction fees.

To this end, as shown in FIG. 3, the cryptocurrency exchange server 200 of the present invention includes a real transaction electronic wallet 210 for each member, and a blockchain transaction processing unit 220. In addition, it may further include a partitioned private key storage unit 230 in which the member's partitioned private key is stored. Although not shown in the figure, the blockchain-based cryptocurrency exchange server 200 is information registered when a user registers for a blockchain-based cryptocurrency transaction, and includes a member's ID, password, a telephone number including a communication terminal, Member information including the address includes a member list information DB (not shown) stored separately for each member.

The real transaction electronic wallet for each member 210 is an electronic wallet having blockchain-based cryptocurrency amount information so as to actually trade cryptocurrency on the blockchain, and is generated and assigned to each member. Therefore, when a blockchain transaction occurs, the blockchain transaction details are updated and stored in the real transaction electronic wallet of each member.

The blockchain transaction processing unit 220 requests a blockchain confirmation requested for sale to the blockchain network processing server 100 when there is a request for sale such as blockchain sale or purchase from a member.

When a transaction including selling or buying cryptocurrency is made between the member terminals 300 in the cryptocurrency exchange server 200, the cryptocurrency exchange server 200 transfers the cryptocurrency from the seller real transaction electronic wallet to the buyer real transaction electronic wallet. In addition, the blockchain transmission fee is added to the cryptocurrency for each seller's selling request so that the blockchain network processing server 100 requests a blockchain confirmation. When the blockchain transaction for the sell confirmation is received from the blockchain network processing server 100, the cryptocurrency exchange server 200 processes the seller and the buyer to jointly bear the transaction transmission fee of the blockchain. Detailed description of the processing of the transaction fee will be described with reference to FIGS. 5 to 10 to be described later.

On the other hand, in implementing the blockchain transaction processing based on the real transaction electronic wallet in the cryptocurrency exchange of the present invention, it is necessary to improve security and decentralized transactions. To this end, as shown in FIG. 4, the private key of the trading request member used in the blockchain confirmation request is encrypted and divided into a first divided private key and a second divided private key, and the first divided private key is converted into a cryptocurrency exchange server ( It is stored in the divided private key storage unit 230 of the 200, so that the second divided private key is stored in the trading request member terminal (300). When the blockchain confirmation request is received, the second split private key is received from the trading request member terminal 300 and the received split second private key and the divided private key storage unit 230 of the cryptocurrency exchange server 200 are received. The private key of the trade request member decrypted using the stored first split private key is restored and transmitted to the blockchain network processing server 100 together with the trade request information to request the trade confirmation.

For reference, referring to FIG. 4, a separate encryption security server 400 is in charge of splitting encryption into a first split private key and a second split private key. In addition, a separate security service server 500 may reissue the divided encryption key after authentication of member information to a member who has lost the divided encryption key.

FIG. 5 is a flowchart illustrating a blockchain transaction processing process based on a real transaction electronic wallet in a cryptocurrency exchange according to an embodiment of the present invention, and FIG. 6 is a 1: 1 blockchain between a seller and a buyer according to an embodiment of the present invention. 7 is an exemplary diagram in which a transaction is made, and FIG. 7 is an exemplary diagram in which a 1: N blockchain transaction is made between a seller and a buyer in accordance with an embodiment of the present invention, and FIG. 8 is a diagram of N: 1 between a seller and a buyer in accordance with an embodiment of the present invention. 9 is an exemplary diagram in which a blockchain transaction is made, and FIG. 9 is an exemplary diagram in which a N: N blockchain transaction is made between a seller and a buyer according to an embodiment of the present invention, and FIG. 10 is a cryptocurrency other than the won according to an embodiment of the present invention. This is an example of fees when purchasing cryptocurrency.

Blockchain transaction processing method based on the real transaction electronic wallet in the cryptocurrency exchange of the present invention, as shown in Figure 5, the real transaction electronic wallet providing process (S510), blockchain confirmation request process (S520), and transaction fee processing process ( S530) may be included.

The real transaction electronic wallet providing process (S510) is a process in which the cryptocurrency exchange server 200 generates a real transaction electronic wallet for blockchain transactions and provides each member. The member-specific real transaction electronic wallet 210 becomes a blockchain component that can participate in the blockchain network and confirm blockchain (authentication and recording).

In the blockchain confirmation request process (S520), when a transaction including selling or buying cryptocurrency is made between member terminals 300 in the cryptocurrency exchange server 200, the cryptocurrency exchange server 200 is executed by the seller's real transaction electronic wallet. It is a process of requesting blockchain confirmation to the blockchain network processing server 100 by adding a blockchain transmission fee to the cryptocurrency for each seller's selling request so that the cryptocurrency transfer is made to the buyer. For example, when the seller sells 1 Ethereum cryptocurrency as shown in Fig. 6, the block chain network processing server 100 generates 0.000441ETH, which is a 1ETH selling transmission fee, and blocks the entire 1.0.000441ETHH. A chain confirm request is issued.

When the transaction fee processing process (S530) is received from the blockchain network processing server 100 to complete the blockchain transaction for the sell confirmation, the cryptocurrency exchange server 200 performs the transaction of the blockchain jointly by the seller and the buyer. Process to bear the transmission fee.

For example, when selling 10 Ethereum held by Seller A as shown in FIG. 1, when 10 Ethereum sold is bought as B1 Buyer 5 Ethereum, B2 Buyer 3 Ethereum, and B3 Buyer 2 Ethereum In this case, three transactions occur, and Seller A pays 10 transaction fees for 10 Ethereum.

In order to solve this problem, the present invention is to deal with the seller and the buyer to jointly bear the transaction transmission fee of the blockchain.

The co-payment method of the transaction transmission fee may be performed in various forms such as 1: 1 transaction (FIG. 6), 1: N transaction (FIG. 7), N: 1 transaction (FIG. 8), N: N transaction (FIG. 9). have. This will be described in detail below.

1) 1: 1 transaction (Figure 6)

As shown in FIG. 6, in the case of a blockchain transaction of a seller: buyer = 1: 1, the transaction fee processing step S530 of the cryptocurrency exchange server 200 uses the same amount as the buyer's fee as the buyer's fee. Depositing, along with the purchase amount, exchange fee, and buyer fee, and thereafter distributing the buyer fee equally to the seller and the buyer by dividing the buyer fee transferred from the buyer by half. can do.

For example, as shown in FIG. 6, it is assumed that an A1 seller requests to sell 1 ETH, which is 1 Ethereum, and a B1 buyer requests to buy 1 ETH.

In addition to the 1ETH to be sold, the transaction transaction fee 0.000441ETH is added to the A1 seller's actual electronic wallet, and the blockchain network processing server is required to confirm blockchain selling.

B1 purchaser deposits 661 won, which is equivalent to transaction transfer fee 0.000441ETH, to the cryptocurrency exchange, in addition to the purchase amount of 1ETH of 1ETH and KRW 2,250 of the brokerage brokerage fee.

After completion of the blockchain confirmation, the blockchain network processing server deposits 1ETH from the seller's 1.0.000441ETHH minus the transaction transfer fee 0.000441ETH into the B1 buyer's real transaction electronic wallet.

When the transaction is completed, the cryptocurrency exchange server 200 pays the A1 seller and the B1 buyer 330.5 won which is divided into 1/2 of the buyer fee 661 won additionally deposited from the B1 buyer.

In the form of payment, it can be converted to the form of points that can be used in the cryptocurrency exchange server 200, and earned to the seller and the buyer, respectively, if a certain amount or more can be refunded and paid in cash, gift certificates, and the like.

2) 1: N transaction (Figure 7)

As shown in FIG. 7, in the case of a blockchain transaction of a seller: buyer = 1: N, the transaction fee processing step S530 of the cryptocurrency exchange server 200 uses the same amount as the buyer's fee as the buyer's fee. ((N-1) × Buyer Fee among the N × Buyer Fees], which are imposed on each buyer and received from N buyers together with the purchase price, exchange fee, and buyer fee, respectively, and [N × Buyer Fee] deposited from N buyers. ] May be paid to the seller, and the remaining one buyer fee may be divided by 1 / (N + 1) to include the seller fee distribution process that equally pays each seller and buyer who is a party to the blockchain confirmation.

For example, assume that the seller A applies for selling 13ETH, the buyer B1 buys 6ETH, the buyer B2 buys 4ETH, and the buyer B3 buys 3ETH, as shown in FIG. Then at Seller: Buyer = 1: N, N becomes '3'.

In addition to the 13ETH to be sold, the transaction price of 0.000441ETH due to blockchain confirmation between B1 buyers, transaction fee of 0.000441ETH due to blockchain confirmation between B2 buyers, and blockchain confirmation between B3 buyers. A transmission fee of 0.000441ETH is added, resulting in a total transaction fee of 3 × 0.000441ETH.

In addition to the purchase price of 6ETH and the exchange brokerage fee, the B1 purchaser deposits 661 won, which is a transaction transfer fee of 0.000441ETH, on the cryptocurrency exchange in addition to the purchase price of 6ETH.

Similarly, the B2 buyer, in addition to the purchase amount of 4ETH and the exchange brokerage fee, adds 661 won corresponding to the transaction transfer fee 0.000441ETH to the cryptocurrency exchange at the time of application for purchase.

Similarly, the B2 buyer, in addition to the purchase amount of 3ETH and the exchange brokerage fee, adds 661 won corresponding to the transaction transfer fee 0.000441ETH to the cryptocurrency exchange at the time of application for purchase.

After completion of the blockchain confirmation, the blockchain network processing server deposits ETH deducting the transaction transfer fee 0.000441ETH into the actual transaction electronic wallet of B1, B2, and B3 buyers. That is, 6ETH is deposited in the B1 buyer's real transaction e-wallet, 4ETH is deposited in the B2 buyer's real transaction e-wallet, and 3ETH is deposited in the B3 buyer's real transaction e-wallet.

When the transaction is completed, the cryptocurrency exchange server 200 sends the seller [2 × 661] which is [(N-1) × buyer fee] out of the buyer fee 3 × 661 which is additionally deposited from the B1, B2, and B3 buyers. Pay as a cashback. In addition, [661 won / 4] won, which is divided into a quarter of 661 won, the remaining buyer fee after cashback payment, is paid equally to A seller, B1 buyer, B2 buyer, and B3 buyer.

Similarly, in the form of payment, it can be converted to the form of points that can be used in the cryptocurrency exchange server 200 to be credited to the seller and the buyer, respectively, if a certain amount or more can be paid back in cash, gift certificates, and the like.

3) N: 1 trading (Figure 8)

As shown in FIG. 8, in the case of a blockchain transaction with a seller: buyer = N: 1, the transaction fee processing process S530 imposes the same amount as the blockchain transmission fee on the buyer for each blockchain transaction as a buyer fee, The process of receiving the transfer with the purchase amount, exchange fee, and buyer fee from the buyer, and the buyer fee received from the buyer are divided into 1 / (N + 1) to each seller and buyer who are parties to the blockchain confirmation. Have a buyer's commission distribution process.

For example, suppose that A1 seller applies for selling 3ETH, A2 seller applies for selling 5ETH, A3 seller applies for selling 2ETH, and B buyer applies for buying 10ETH, as shown in FIG. . Then at Seller: Buyer = N: 1, N becomes '3'.

In addition to the 3ETH to be sold, the transaction transfer fee 0.000441ETH is incurred by the blockchain confirmation between B buyers. Similarly, in transactional electronic wallets of A2 sellers, a transaction transfer fee of 0.000441ETH is incurred due to blockchain confirmation between B buyers in addition to 5ETH to be sold, and in addition to 2ETHs to sell in A3 sellers, blockchain confirmation between B buyers A transaction transfer fee of 0.000441ETH is incurred.

In addition to the purchase price of 10ETH and the exchange brokerage fee, the buyer B deposits 661 won corresponding to the transaction transfer fee of 0.000441ETH to the cryptocurrency exchange in addition to the purchase price of 10ETH.

After completion of the blockchain confirmation, the blockchain network processing server deposits ETH, deducting a transaction transfer fee of 0.000441ETH, into each buyer's real transaction electronic wallet.

When the transaction is completed, the cryptocurrency exchange server 200 divides the [661 won / 4] won, which is divided into one quarter of 661 won from the buyer B, into A1 seller, A2 seller, A3 seller, and B buyer. Pay the same.

Similarly, in the form of payment, it can be converted to the form of points that can be used in the cryptocurrency exchange server 200 to be credited to the seller and the buyer, respectively, if a certain amount or more can be paid back in cash, gift certificates, and the like.

4) N: N trading (Figure 9)

As shown in FIG. 9, in the case of a blockchain transaction of Seller: Buyer = N: N, the transaction fee processing step (S530) imposes the same amount as the Buyer's fee on N buyers as the Buyer's fee, respectively, The amount of money transferred from N buyers together with the purchase amount, exchange fee, and buyer fee, and the amount corresponding to [(N-1) × Buyer Fee] among [N × Buyer Fee] received from N Buyers, Pay the transaction forwarder to the seller who paid the additional fee. In addition, the remaining one buyer fee is divided by 1 / (N × 2) and the buyer fee distribution process pays the same to each seller and buyer who are parties to the blockchain confirmation.

For example, as shown in FIG. 9, A1 seller applies for selling 10ETH, A2 seller applies for selling 1ETH, A3 seller applies for selling 2ETH, B1 buyer applies for buying 5ETH, and B2 buyer buys Suppose you want to buy 3ETH and B3 buys 5ETH. Then N = 3 in Seller: Buyer = N: N.

In addition to the 10ETH to be sold in the A1 seller's electronic wallet, the transaction transfer fee 0.000441ETH for 5ETH transactions between B1 buyers, the transaction transfer fee 0.000441ETH for 3ETH transactions between B2 buyers, and the transaction transfer fee 0.000441ETH for 5ETH transactions between B3 buyers A total of 3 x 0.000441 ETH transaction transfer fees are incurred.

In addition to 1ETH to be sold in A2 seller's real transaction electronic wallet, transaction transfer fee 0.000441ETH is incurred once.

In addition to the purchase price of 5ETH and the exchange brokerage fee, B1 purchaser deposits 661 won, which is equivalent to the blockchain transaction transfer fee of 0.000441ETH, to the cryptocurrency exchange as a buyer fee.

In addition to the purchase price of 3ETH and the exchange brokerage fee, B2 purchaser shall deposit 661 won, which is equivalent to 0.000441ETH of blockchain transaction transfer fee, to the cryptocurrency exchange in addition to the purchase price of 3ETH.

In addition to the purchase price of 5ETH and the exchange brokerage fee, B3 buyer shall deposit 661 won, which is equivalent to 0.000441ETH of blockchain transaction transfer fee, to the cryptocurrency exchange in addition to the purchase price of 5ETH.

After completion of the blockchain confirmation, the blockchain network processing server deposits ETH deducting the transaction transfer fee 0.000441ETH into each buyer's real transaction electronic wallet. That is, 5ETH is deposited in the B1 buyer's real transaction e-wallet, 3ETH is deposited in the B2 buyer's real transaction e-wallet and 5ETH is deposited in the B3 buyer's real transaction e-wallet.

When the transaction is completed, the cryptocurrency exchange server 200 trades [2 × 661], which is [(N-1) × Buyer's Fee], among 3 × 661 buyer's fees additionally deposited from B1, B2, and B3 buyers. It is paid as a cashback to the A1 seller who paid the additional fee.

Cash back to the A1 seller and the remaining one buyer fee, 661 won, is divided by 1 / (N × 2) = 1 / (3 × 2) = 1/6 and each of A1, A2, The same shall be paid to A3 Seller and B1, B2, B3 Buyer.

Similarly, in the form of payment, it can be converted to the form of points that can be used in the cryptocurrency exchange server 200 to be credited to the seller and the buyer, respectively, if a certain amount or more can be paid back in cash, gift certificates, and the like.

On the other hand, the above description has described an example of buying cryptocurrencies using the won (KRW), but transactions using electronic money rather than the won (KRW) transaction may occur. That is, there may be a case where the seller A buys the second cryptocurrency at the amount sold by selling the first cryptocurrency in the real transaction electronic wallet.

Even in this case, A receives a commission for each sale and purchase, and cashback processing and earning points are processed. That is, as shown in FIG. 10, when member A requests a transaction to exchange 10 Bitcoin (BTC) for 20 Ethereum (ETH), a transaction transmission fee is generated in each 10 Bitcoin market, and 20 Ethereum At the time of purchase, a purchase fee corresponding to the transaction transfer fee is incurred. For A, there will be two transfer charges (transaction transfer fee in Bitcoin city + buyer fee at the time of Ethereum purchase), but the remaining fee can be earned points.

In other words, cashback payment (661 won × 2) to Bitcoin sold A and the remaining buyer fee 661 won divided by 1/4 to earn points to A, B1, B2, B3. In addition, A and C earn the points to A and C by dividing the buyer's fee provided by A when purchasing Ethereum.

On the other hand, the private key of the trading request member used in the blockchain confirmation request is encrypted and divided into a first divided private key and a second divided private key, and the first divided private key is stored in the cryptocurrency exchange server 200. The second split private key may be stored in the trading request member terminal 300.

In this case, the blockchain confirmation request process, upon requesting the blockchain confirmation, receives the second split private key from the trading request member terminal 300, and receives the received second split private key and the cryptocurrency exchange server 200. The private key of the trade request member decrypted using the stored first divided private key may be transmitted to the blockchain network processing server 100 together with the transaction request information to request a transaction confirmation.

Therefore, in the blockchain transaction processing based on the real transaction electronic wallet in the cryptocurrency exchange of the present invention, security can be improved and decentralized transactions can be made.

The embodiments in the above description of the present invention are presented by selecting the most preferred examples to help those skilled in the art from the various possible examples, and the technical spirit of the present invention is not necessarily limited or limited only by the embodiments. However, various changes, modifications, and other equivalent embodiments may be made without departing from the technical spirit of the present invention.

100: blockchain network processing server
200: Cryptocurrency exchange server
300: member terminal

Claims (7)

A process for providing a real transaction electronic wallet, which the cryptocurrency exchange server generates and provides a real transaction electronic wallet in which blockchain transactions can be made;
When a transaction including selling or buying cryptocurrency is made between member terminals in a cryptocurrency exchange server, the cryptocurrency exchange server encrypts the cryptocurrency transfer from the seller's real transaction e-wallet to the buyer's real transaction e-wallet, according to the seller's request to sell. A blockchain confirmation request process of requesting blockchain confirmation to a blockchain network processing server by adding a blockchain transmission fee to money;
A transaction fee processing step of processing, by the cryptocurrency exchange server, the seller and the buyer to jointly bear the transaction transmission fee of the blockchain when the blockchain transaction for the sell confirmation is received from the blockchain network processing server;
Blockchain transaction processing method based on real transaction electronic wallet in cryptocurrency exchange comprising a.
The transaction fee processing process according to claim 1, wherein in the case of a blockchain transaction of a seller: buyer = 1: 1,
Charging the buyer with the same amount as the blockchain transmission fee as a buyer's fee, and receiving the deposit along with the purchase amount, the exchange fee, and the buyer's fee;
A buyer fee distribution process of dividing the buyer's fee transferred from the buyer by half and paying the seller and the buyer equally;
Transfer processing method based on real transaction electronic wallet in cryptocurrency exchange comprising a.
The transaction fee processing process according to claim 1, wherein in the case of a blockchain transaction of Seller: Buyer = 1: N,
Charging each of the N buyers the same amount as the blockchain transmission fee as a buyer fee, and transferring each of the N buyers together with the purchase amount, the exchange fee, and the buyer fee;
Of [N × buyer fee] received from N buyers, [(N-1) × buyer fee] is paid to the seller, and the remaining one buyer fee is divided by 1 / (N + 1) to the parties in the blockchain confirmation A buyer fee distribution process that equally pays each seller and buyer;
Blockchain transaction processing method based on real transaction electronic wallet in cryptocurrency exchange comprising a.
. The transaction fee processing process according to claim 1, wherein in the case of a blockchain transaction in which the seller: buyer = N: 1,
Imposing the same amount as the blockchain transmission fee on the buyer for each blockchain transaction as a buyer fee, and receiving the transfer amount from the buyer together with the purchase amount, the exchange fee, and the buyer fee;
A buyer fee distribution process of dividing the buyer fee received from the buyer into 1 / (N + 1) and paying equally to each seller and the buyer who are parties to the blockchain confirmation;
Blockchain transaction processing method based on real transaction electronic wallet in cryptocurrency exchange comprising a.
. The transaction fee processing process according to claim 1, wherein in the case of a blockchain transaction in which the seller: buyer = N: N,
Charging each of the N buyers the same amount as the blockchain transmission fee as a buyer fee, and transferring each of the N buyers together with the purchase amount, the exchange fee, and the buyer fee;
Of the [N × buyer fee] received from N buyers, the amount corresponding to [(N-1) × buyer fee] is paid to the seller who paid the transaction transfer fee, and the other buyer fee is 1 / (N A process of distributing a buyer fee, which is divided by × 2) and paid equally to each seller and buyer who are parties to the blockchain confirmation;
Blockchain transaction processing method based on real transaction electronic wallet in cryptocurrency exchange comprising a.
The method of claim 2, 3, 4, 5, wherein the buyer fee distribution process,
A method for processing a blockchain transaction based on a real wallet electronic wallet in a cryptocurrency exchange, which is converted into a point form that can be used on a cryptocurrency exchange server and earned to the seller and the buyer.
The method according to any one of claims 2, 3, 4, 5,
The private key of the transaction request member used in the blockchain confirmation request is encrypted and divided into a first divided private key and a second divided private key, and the first divided private key is stored in a cryptocurrency exchange server, and a second divided private key. Is stored in the member request terminal for sale,
The blockchain confirmation request process,
When the blockchain confirmation request is made, the request of the sale request member decrypted using the received second split private key and the first split private key stored in the cryptocurrency exchange server. A method of processing a blockchain transaction based on a real wallet electronic wallet in a cryptocurrency exchange by sending a private key along with the transaction request information to a blockchain network processing server.

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