KR102258700B1 - method and system of smart electronic contracting based on block chain - Google Patents

Abstract

In order to prevent forgery of the electronic contract in advance and improve information reliability and security, in the present invention, electronic contract data including contract information is input and converted into data through a contract creation terminal connected to the server unit, and the A first step of storing electronic contract data; A second step of communicating the electronic contract data stored in the server unit to at least one contract target terminal connected to the server unit; And when the electronic contract data is communicated from each of the terminals to the server unit, and it is determined whether the electronic contract data includes electronic signature information through each of the terminals, and the electronic signature information is included in the electronic contract data. It provides a block chain-based smart electronic contract signing method including a third step in which the electronic contract data is encrypted and blocked, and the generated block is stored in the server unit and each of the terminals, respectively.

Description

Method and system of smart electronic contracting based on block chain

The present invention relates to a method and system for signing a smart electronic contract based on a block chain, and more specifically, a method and system for signing a smart electronic contract based on a block chain that improves information reliability and security by preventing forgery and alteration of the electronic contract in advance. It is about.

When signing a labor contract, it is important to clarify the working conditions so that disputes between the parties can be prevented and workers can be protected, and the first step to this is to prepare a labor contract. However, only about 60% of the labor contracts are written in industrial sites.

In this situation, the electronic contract method based on the recent IT technology is attracting attention as a new means to increase the rate of writing labor contracts in that it is easy to write and preserve. However, in order to activate the electronic labor contract, it is necessary to secure the same level of stability and reliability as the written labor contract. Therefore, the government prepares and issues electronic labor contracts based on relevant laws such as the Labor Standards Act, the Electronic Documents and the Basic Act on Electronic Transactions. ㆍPreservation guidelines are in place.

In the conventional Korean Patent Publication (No. 10-2017-0022263)'Electronic Contract Execution System using the Internet', an electronic contract signing process in which a user who wishes to sign an electronic contract searches for a contract, writes a draft, discusses the contents of the contract, and signs the contract. And a terminal module that transmits and receives information related to the electronic contract signing process, and an interface module that provides a universal interface to transmit and receive requests from each terminal regardless of the type of each terminal module by being connected to the terminal module through the Internet. , A server module that processes the request of each terminal module transmitted from the interface module, wherein the server module includes a management module that manages the signing process of an electronic contract, a signature module that processes the signing procedure of the electronic contract, and the electronic contract. Disclosed is a security module that maintains security of a server module including a signing process, and a database in which data related to an electronic contract is stored.

In addition, since the electronic contract method is performed online, there are no restrictions on time and place, no tangible objects such as documents are required, and it is easy to store contract-related data.

However, the conventional electronic contract signing system has a problem that not only a user must install a separate software on his device to use the system, but also a service provider must develop a dedicated software for various use environments.

In addition, as the electronic contract signing process proceeds in the software installed in the user's device, it is difficult to guarantee reliability and there is a problem that security is weak. Moreover, since only some of the information related to the electronic contract, such as the final electronic contract, is stored, there is a problem that it is difficult to respond when a problem related to the contract occurs after the history management of the electronic contract is not performed.

In particular, in the electronic contract method, it is easy to forgery and falsify the electronic contract, it is difficult to verify that the party is the other party to the contract, and unauthorized access, modification, and duplication of the electronic contract is possible through hacking, so that information reliability and security are deteriorated. .

Korean Patent Application Publication No. 10-2017-0022263

In order to solve the above problems, the present invention aims to provide a block chain-based smart electronic contract signing method and system in which forgery and alteration of electronic contracts is prevented in advance and thus information reliability and security are improved.

In order to solve the above problems, the present invention provides a first step of inputting and converting electronic contract data including contract information through a contract creation-side terminal connected to the server unit, and storing the electronic contract data in the server unit; A second step of communicating the electronic contract data stored in the server unit to at least one contract target-side terminal connected to the server unit; And when the electronic contract data is communicated from each of the terminals to the server unit, and it is determined whether the electronic contract data includes electronic signature information through each of the terminals, and the electronic signature information is included in the electronic contract data. And a third step in which blocks generated by encrypting and blocking the electronic contract data are stored in the server unit and each of the terminals, respectively, wherein in the third step, the blocks are collected to form a tree structure. As a space created, a plurality of pieces are generated, including the electronic contract conclusion data generated for the electronic contract data to which the digital signature information, the key value for encryption, and the sequence number are assigned, and are chained and connected to each other, and the electronic contract is concluded. Data is encrypted data and blockchainized through a hash function including SHA-256 that consists of 256 bits and returns a 64-digit character string, and in the third step, the block including the electronic contract signing data includes a header and a body. Included, wherein the header stores hash values of adjacent blocks for preventing forgery and alteration in a hash tree structure, and in the body, the electronic contract conclusion data and the browsing history of the electronic contract conclusion data encrypted through a hash function are stored in a hash tree structure. Stored, and the third step further includes the step of extracting the block to a comparison unit to determine whether forgery or alteration has been performed, and selectively transmitting a forgery or alteration notification message to at least one of each of the terminals, wherein the third step is , A block for the electronic contract data to be verified, and a block stored in any one of the terminals are extracted to the comparison unit, respectively, and a block for the electronic contract data to be verified and a block stored in each of the terminals are The step of sequentially comparing each individual block to see if they coincide with each other, and when the hash value of the n-th block for the electronic contract data to be verified and the hash value of the n-th block stored in any one of the terminals do not match, each of the Blockchain-based smart communication, comprising the step of transmitting the forgery and alteration notification message to at least one of the terminals. Provides self-contract signing method

In addition, in the present invention, the electronic contract data including contract information is input, and the contract creation side terminal for mediating the authentication of the electronic signature information to the electronic contract data; A contract target-side terminal for mediating authentication of electronic signature information to the electronic contract data created from the contract-writing terminal; A block generator that determines whether the electronic contract data includes electronic signature information through each of the terminals, and when the electronic signature information is included, encrypts and converts the electronic contract data into a block chain to generate a plurality of blocks; A server unit in which an electronic contract template is previously stored, a key value and an order value for encryption are stored, and the electronic contract data and the block are stored; And a comparison unit that compares and determines whether or not the electronic contract data is forged or altered, and selectively transmits a forgery notification message to at least one of the terminals, wherein the block is a space in which the electronic contract conclusion data is aggregated to form a tree structure. , A plurality of digital signature information, including the electronic contract conclusion data generated for the electronic contract data to which the encryption key value and the sequence number are assigned, are chained to each other, and the electronic contract conclusion data is 256 Encrypted data and block chained through a hash function including SHA-256 that consists of bits and returns a 64-digit character string, and the block includes a header and a body, and the hash value of an adjacent block to prevent forgery is concatenated in the header. The electronic contract data and the browsing history of the electronic contract data encrypted through a hash function are stored in the body in a hash tree structure, and the comparison unit includes a block for the electronic contract data to be verified and each of the Each individual block is sequentially compared to see if the blocks stored in any of the terminals match each other, and the hash value of the n-th block for the electronic contract data to be verified and the hash value of the n-th block stored in any one of the terminals are Provides a blockchain-based smart electronic contract signing system, characterized in that the forgery and alteration notification message is selectively transmitted to at least one of the terminals when they do not match.

Through the above solution means, the blockchain-based smart electronic contract execution method and system according to the present invention provides the following effects.

First, as each terminal of the contract creation side and the contract target side is connected to the cloud-based server unit, it is possible to easily create and view electronic contract data for signing an electronic contract, and to register electronic signatures between the two parties. It can be improved.

Second, as the digital signature between both parties of the contract is entered into the electronic contract data, the agreement on the contract is concluded and the electronic contract data is stored in a block chain at the same time, so it is practically impossible to change the data on the contract contents. Since the data is listed and stored in the server unit, a notarization function can be provided.

Third, the digital signature information and the electronic contract conclusion data generated for the electronic contract data to which the key value and sequence number for encryption are assigned are encrypted data and blockchainized through a hash function such as SHA-256, and are stored in a plurality of blocks. Accordingly, since forgery and alteration of electronic contracts is practically impossible, security can be remarkably improved.

Fourth, information of electronic contract data that is communicated for electronic contracts made online because it is quickly determined whether the electronic contract data is forged or altered through comparison and comparison between blocks of electronic contract data to be verified and encrypted data and blocks previously stored in a block chain. Reliability and legitimacy can be guaranteed

1 is a flow chart showing a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention.
Figure 2 is a flow chart showing a block chain-based encryption and block chaining process in a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention.
3 is a flowchart showing a process of determining forgery and alteration of encrypted and block-chained electronic contract data based on a block chain in a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention.
Figure 4 is a block diagram showing a block chain-based smart electronic contract execution system according to an embodiment of the present invention.

Hereinafter, a method and system for signing a smart electronic contract based on a blockchain according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart showing a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention, and FIG. 2 is a block chain based smart electronic contract signing method based on a block chain according to an embodiment of the present invention. It is a flow chart showing the process of encryption and blockchainization. And, Figure 3 is a flow chart showing a forgery determination process of encrypted and block-chained electronic contract data based on a block chain in a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention. A block diagram showing a smart electronic contract execution system based on a block chain according to an embodiment.

As shown in Figs. 1 to 4, the method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention includes input and storage of electronic contract data in the server unit (s10), and the electronic contract data stored in the server unit. A communication to the contract target side terminal (s20), determining whether the electronic contract data contains electronic signature information, and a series of steps such as block generation (s30) by encrypting and blocking the electronic contract data.

In addition, the blockchain-based smart electronic contract execution system 100 according to an embodiment of the present invention includes a contract creation terminal 10A, a contract target terminal 10B, a server unit 20, and a block generation unit 21 ), and a comparison unit 22.

Here, it is preferable that the contract preparation terminal 10A inputs electronic contract data including contract information, and is provided to mediate authentication of electronic signature information to the electronic contract data.

In addition, it is preferable that the contract target-side terminal 10B is provided with at least one to mediate the authentication of the electronic signature information to the electronic contract data created from the contract-writing-side terminal 10A.

Hereinafter, it is preferable to understand that each of the terminals 10A and 10B is used as a concept including the contract creation side terminal 10A and the contract target side terminal 10B.

In addition, the block generator 21 determines whether the electronic contract data includes the electronic signature information through each of the terminals 10A and 10B, and when the electronic signature information is included, the electronic contract data is It is preferable to be provided to generate a plurality of blocks by encryption and block chaining.

In addition, the server unit 20 is provided on a cloud basis, so that an electronic contract template is previously stored, a key value and an order value set for encryption are stored, and generated through the electronic contract data and the block generation unit 21 It is preferable that the block is stored.

In addition, the comparison unit 22 is preferably provided to compare and determine whether the electronic contract data is forged or altered, and selectively transmit a forgery notification message to at least one of the terminals 10A and 10B.

Hereinafter, a method of signing a smart electronic contract based on a block chain according to an embodiment of the present invention will be described in detail.

Meanwhile, at least one electronic contract data including contract information is input and converted into data through the contract writing terminal 20A connected to the server unit 20, and the electronic contract data is stored in the server unit 20. It is stored (s10).

In detail, it is preferable that the contract writing-side terminal 10A is connected to the server unit 20 through the Internet or the like. At this time, it is preferable to understand that the server unit 20 is provided on a cloud basis and is connected to an internet site that mediates the conclusion of an electronic contract between the contract creation terminal 10A and the contract target terminal 10B. .

In addition, it is preferable that at least one electronic contract template pre-stored in the server unit 20 is extracted to the contract writing terminal 10A, and at least one electronic contract data including contract information is input and converted into data.

Here, the electronic contract template refers to a common form required when creating a contract document, and may be provided in various preset forms and stored in the server unit 20. In this case, the electronic contract template may be previously stored and provided in the server unit 20, and may be stored in the server unit 20 as it is input and modified through the contract writing-side terminal 10A.

In addition, the contract information is preferably understood as the details of the conclusion of the electronic contract created through the contract preparation terminal 10A based on the electronic contract template. Of course, the contract information may be input through the contract preparation terminal 10A without the electronic contract template.

Subsequently, when the electronic contract template is extracted through the contract creation side terminal 10A and input of electronic contract data including contract information is completed, the electronic contract data is stored and converted into data and stored in the server unit 20. It is desirable to be.

In addition, the electronic contract data created based on the electronic contract template through the contract writing terminal 10A and stored in the server unit 20 may be viewed through the expert terminal to be verified through a legal consultation process. .

Here, the electronic contract data may be reviewed and corrected by the expert terminal connected to the server unit 20. Subsequently, the electronic contract data corrected through the expert's terminal may be communicated and stored to the server unit 20.

Accordingly, the electronic contract data can be reviewed and corrected by the expert terminal connected to the server unit 20 before it is confirmed that the electronic contract data is encrypted and blockchained so that it cannot be modified or forged. The expertise and fairness of the company can be improved.

In addition, the contact information of the contract target side and the expert side may be input and converted into data through the contract writing terminal 10A and stored in the server unit 20. In this case, it is preferable that the contact information includes information such as a phone number, an email address, and an address.

Here, a notification message may be transmitted to the expert based on the contact information of the expert before the electronic contract data created through the contract writing side terminal 10A is read by the contract target side terminal 10B. have. To this end, it may be set to automatically transmit a notification message to an expert through the contract creation terminal 10A on the Internet that mediates an electronic contract.

Accordingly, when the notification message is transmitted to the expert based on contact information such as e-mail, the expert's terminal is connected to the server unit 20 by the expert, and the electronic contract data may be reviewed and corrected.

Meanwhile, the electronic contract data stored in the server unit 20 is communicated to the at least one contract target-side terminal 10B connected to the server unit 20 (s20).

Here, when the creation of the electronic contract data is completed through the contract writing terminal 10A, it is preferable that communication is performed so that the electronic contract data can be viewed through the contract target terminal 10B.

At this time, the above-described communication means that the electronic contract data is transmitted/received through means such as the Internet, and the electronic contract data stored in the server unit 20 is selectively transmitted through each of the terminals 10A and 10B. It is desirable to understand that it encompasses the meaning of being prepared to be read.

In addition, when the creation of the electronic contract data stored in the server unit 20 is completed, a notification message may be transmitted to the contract target party based on the contact information. In this case, it is preferable that the contact information of the contract target party includes information such as phone number, email address, and address.

Here, it may be set so that a notification message is transmitted to the contract target party through the contract writing terminal 10A on the Internet that mediates the electronic contract. Accordingly, when the notification message is transmitted to the contract target party based on contact information such as e-mail, the contract target terminal 10B is connected to the server unit 20 by the contract target party to view the electronic contract data. Can be.

On the other hand, the electronic contract data is communicated to the server unit 20 from each of the terminals 10A and 10B, and it is determined whether the electronic contract data includes electronic signature information through each of the terminals 10A and 10B. , When the electronic contract data includes the electronic signature information, the block generated by encrypting and blocking the electronic contract data is stored in the server unit 20 and each of the terminals 10A and 10B, respectively (s30). .

In detail, when the electronic contract data is communicated from each of the terminals 10A and 10B to the server unit 20, the electronic signature information is added to the electronic contract data by at least one of the terminals 10A and 10B. It is preferable that is entered.

Here, in the case where only one of the contract creation side and the contract target side is requested for electronic signature information in the content of the electronic contract, only one electronic signature information is included in the electronic contract data by any one of the terminals 10A and 10B. Can be entered. Hereinafter, a case in which electronic signature information of both the contract creation side and the contract target side is required in the blockchain-based smart electronic contract conclusion method according to an embodiment of the present invention will be described as an example.

In addition, the electronic signature information is preferably understood as information data to prove the identity of the person, and may be provided as an identity authentication means such as an accredited certificate. In this case, the electronic signature information may be input to the electronic contract data as each of the terminals 10A and 10B provided with a PC or a mobile device is connected to an Internet site that mediates the conclusion of an electronic contract.

In addition, the digital signature information of the contract creation side may be input immediately after the step of creating the electronic contract data through the contract creation side terminal 10A connected to the server unit 20, and the server unit 20 It may be input after the electronic contract data is viewed and confirmed by the contract target side through the contract target side terminal 10B connected to the contract target side terminal 10B. In addition, the electronic signature information of the contract target side may be input through the contract target side terminal 10B connected to the server unit 20.

Subsequently, it is preferable to determine whether the electronic contract data includes electronic signature information through the terminals 10A and 10B through an operation processing device of the server unit 20 or the like. At this time, the case where the electronic contract data does not include the electronic signature information of both the contract creator and the contract target party, unless only the electronic signature information of either the contract creation party or the contract target party is required, will be described later. The electronic contract signing process is not in progress.

On the other hand, when the electronic contract data includes electronic signature information of both the contract creation side and the contract target side, the electronic contract data is encrypted and blocked to generate a block, and the block is the server unit 20 and each of the It is stored in the terminals 10A and 10B, respectively.

At this time, the contract is signed by the contract creation party and the contract target party in the electronic contract data, and the contract is concluded with the electronic signature information included, that is, a state in which there is no room for modification of the electronic contract is the contract creation party and the contract. It is preferable to understand that the electronic contract data is encrypted and blocked so that modification and forgery of the electronic contract data are prevented after an agreement between both parties to the target party.

Of course, so that the electronic contract data created by the contract creation-side terminal 10A connected to the server unit 20 is not modified or forged through the contract target-side terminal 10B, the contract is added to the electronic contract data. It may be encrypted and blocked before the creation-side electronic signature information is input and the electronic contract data is communicated to the contract target-side terminal 10B connected to the server unit 20.

In addition, the block is generated in a plurality, including the digital signature information and the electronic contract execution data generated for the electronic contract data to which the key value and sequence number set for encryption are assigned, and the electronic contract execution data is SHA- It is preferable to use a hash function such as 256 to convert it into cryptographic data and to block chain.

Here, SHA (Secure Hash Algorithm) is a standard hash algorithm published by the National Institute of Standards and Technology (NIST) and is most widely used worldwide in the software market. SHA-1 and SHA-2 series are currently mainly used, and SHA-2 is divided into SHA-224, SHA-256, SHA-384, and SHA-512 in detail. SHA-256 is the most used. And, SHA-256 consists of 256 bits and returns a 64-digit string. For example, the string "Contract" can be converted to 64 digits of data such as "875C2FD188350......1877005365BA2" through SHA-256.

In addition, the electronic contract execution data is preferably stored in the body of the block, and preferably includes the electronic contract data and electronic signature information of the contract creation side and the contract target side. Here, the block includes a header and a body, and the hash value, block version, Merkle Root, Nonce value, etc. of adjacent blocks are stored in the header, and a hash function is stored in the body. It is preferable that the electronic contract signing data and the browsing history of the electronic contract signing data encrypted through are stored in a hash tree structure.

In this case, the hash function refers to a function that converts certain data of an arbitrary length into certain data of a certain length, and the block refers to a space in which the electronic contract signing data is aggregated to form a tree structure.

These blocks are generated one by one at preset time intervals and spread throughout the network, and each block is chained and connected to each other to prove the integrity of the n-1th block through a hash tree structure. For example, as a hash value equal to the hash value of the n-1 th block exists in the header of the n th block, it can be verified that the n-1 th block is not modulated.

Meanwhile, referring to FIG. 2, the process of encryption and block chaining of the block is as follows. First, the electronic contract data including contract information is communicated to each of the terminals 10A and 10B, and the electronic signature information is input to the electronic contract data through each of the terminals 10A and 10B, and the electronic contract conclusion data It is preferable that is prepared.

Subsequently, it is preferable that the electronic contract data including electronic signature information, that is, the electronic contract conclusion data, is converted into encrypted data through a hash function by the block generator 21 to generate the n-th block among the blocks (s31. ).

In addition, it is preferable to determine whether the electronic contract data includes the electronic signature information to check the existence of the contract subject through an operation processing device of the server unit 20 (s32).

Here, if the digital signature information is not included in the electronic contract data, the block is stored in the server unit 20 and each of the terminals 10A and 10B, respectively, and the encrypted key value in the server unit 20 and It is preferable that the sequence number is stored (s33).

At this time, the block may be stored in the server unit 20 and each of the terminals 10A, 10B, or, each terminal connected to the server unit 20 is stored only in the server unit 20 The identity verification step of (10A.10B) may be added.

On the other hand, if the digital signature information is included in the electronic contract data, it is preferable that an n+1 th block is generated and the hash value of the n+1 th block is stored in the header of the n th block to form a blockchain (s34). . For example, a second block may be generated and a hash value of the second block may be stored in the header of the first block. In this case, it is preferable to understand that the electronic contract data including electronic signature information is included in the body of each block including the nth and n+1th.

In addition, it is preferable that the block is stored in the server unit 20 and each of the terminals 10A and 10B, and the encrypted key value and the sequence number are stored in the server unit 20 (s35). Subsequently, it is preferable that a plurality of blocks, which are mutually block-chained, are repeatedly generated for the process shown in s31, s32, s33, s34, and s35 of FIG. 2 (s36), that is, each of the blocks generated by being block-chained into a plurality The electronic contract signing data is stored in the body, and hash values of blocks adjacent to the head of the block are sequentially stored.

Accordingly, the electronic contract conclusion data generated for the electronic contract data to which the digital signature information and the encryption key value and sequence number are assigned is converted into cryptographic data and block chained through a hash function such as SHA-256, and stored in a plurality of blocks. As a result, forgery and alteration of electronic contracts is practically impossible, so security can be remarkably improved.

In addition, in some cases, when encryption and blockchainization of the electronic contract data including the electronic signature information is completed, a contract completion message may be transmitted to at least one of the contract creation party and the contract target party based on the contact information. .

On the other hand, referring to FIG. 3, it is preferable that the block is extracted by the comparison unit 22 to compare and determine whether or not forgery or alteration is performed, and a forgery notification message is selectively transmitted to at least one of the terminals 10A and 10B. Do. In detail, the process of determining forgery and alteration of electronic contract data encrypted and block-chained based on blockchain is as follows.

First, it is preferable that the n-th block for the electronic contract data to be verified and the n-th block stored in any one of the terminals 10A and 10B are extracted by the comparison unit 22, respectively (s41).

At this time, the block stored in any one of the terminals 10A and 10B may be extracted by the comparison unit 22, but if the block is stored only in the server unit 20, the block is stored in the server unit 20 After any one of the terminals 10A and 10B is connected to further proceed with the identity authentication step, the block may be extracted from the server unit 20 to the comparison unit 22.

Here, the verification target electronic contract data is data in a state in which forgery or alteration has not been determined, and the verification target electronic contract data in a state that is not encrypted and block-chained is extracted from the server unit 20, and the encrypted key value and sequence number are calculated. After encryption and block chaining, it may be extracted to the comparison unit 22.

In addition, it is preferable that the block for the electronic contract data to be verified and the block stored in each of the terminals 10A and 10B are sequentially compared for each individual block by the comparison unit 22 to see if they match each other (s42). ).

Here, if the hash value of the n-th block for the electronic contract data to be verified and the hash value of the n-th block stored in any one of the terminals 10A and 10B do not match, among the terminals 10A and 10B It is preferable that the forgery and alteration notification message is selectively transmitted to at least one of them (s44).

On the other hand, if the hash value of the n-th block for the electronic contract data to be verified and the hash value of the n-th block stored in any one of the terminals 10A and 10B match, n+ for the electronic contract data to be verified. It is preferable that it is determined by the comparison unit 22 whether the first block exists (s43).

Here, if the n+1 th block for the verification target electronic contract data does not exist, the hash value of the n th block for the verification target electronic contract data and the n th stored in any one of the terminals 10A and 10B It is determined that the hash values of the blocks match, and it is determined that the electronic contract data to be verified has not been forged (s45).

On the other hand, when the n+1th block for the electronic contract data to be verified exists, a plurality of blocks including the n+1th for the process shown in s41, s42, s43, s44, s45 of FIG. It is preferable that the matching operation is repeatedly performed (s36).

That is, when comparing whether the block stored in any one of the terminals 10A and 10B and the block for the electronic contract data to be verified match each other, it is preferable that each block is individually compared and compared.

Accordingly, the electronic contract data that is communicated for electronic contracts made online is quickly determined through comparison and comparison between the blocks of the electronic contract data to be verified and the blocks of the electronic contract data to be verified and the blocks previously stored in the block chain. Reliability and legitimacy of information can be guaranteed

Therefore, as each of the terminals 10A and 10B of the contract creation side and the contract target side are connected to the cloud-based server unit 20, creation and viewing of electronic contract data for the conclusion of an electronic contract, and electronic signature registration between the two parties Since this can be performed easily, the usability can be remarkably improved.

In addition, the contracted electronic contract data is preferably listed and stored in the server unit 20, and can be viewed through each of the terminals 10A and 10B connected to the server unit 20. Accordingly, as the electronic signature between the two parties of the contract is entered into the electronic contract data, the agreement on the contract is reached and the electronic contract data is stored in a block chain at the same time, so it is practically impossible to change the data on the contract contents. Since contract data is listed and stored in the server unit, a notarization function can be provided.

Terms such as "comprise", "comprise" or "include" described above mean that the corresponding component can be present unless otherwise stated, so excluding other components Rather, it should be interpreted as being able to further include other components. All terms, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art, unless otherwise defined. Terms generally used, such as terms defined in the dictionary, should be interpreted as being consistent with the meaning of the context of the related technology, and are not interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

As described above, the present invention is not limited to each of the above-described embodiments, and it is possible to be modified and implemented by those of ordinary skill in the art without departing from the scope claimed in the claims of the present invention. And, these modifications are within the scope of the present invention.

100: Blockchain-based smart electronic contract signing system
10A: Terminal for contract preparation 10B: Terminal for contract
20: server unit 21: block generation unit
22: comparison unit

Claims (10)

A first step of inputting and converting electronic contract data including contract information through a contract writing-side terminal connected to the server unit, and storing the electronic contract data in the server unit;
A second step of communicating the electronic contract data stored in the server unit to at least one contract target-side terminal connected to the server unit; And
When the electronic contract data is communicated from each of the terminals to the server unit, it is determined whether the electronic contract data includes electronic signature information through each terminal, and the electronic signature information is included in the electronic contract data. Including a third step of storing the generated block by encrypting and blocking the electronic contract data in the server unit and each of the terminals, respectively,
In the third step, the block is a space in which electronic contract signing data is collected to form a tree structure, and the electronic contract signing generated for the electronic contract data to which the electronic signature information, a key value for encryption, and an order value are assigned. It is generated in plural, including data, and is chained and connected, and the electronic contract data is encrypted data and blockchainized through a hash function including SHA-256, which consists of 256 bits and returns a 64-digit character string,
In the third step, the block including the electronic contract signing data includes a header and a body, wherein hash values of adjacent blocks for preventing forgery and alteration are sequentially stored in the header, and in the body through a hash function. The encrypted electronic contract signing data and the browsing history of the electronic contract signing data are stored in a hash tree structure,
The third step further includes the step of extracting the block to a comparison unit to compare and determine whether or not forgery or alteration, and selectively transmitting a forgery or alteration notification message to at least one of each of the terminals,
In the third step, a block for the electronic contract data to be verified and a block stored in any one of the terminals are extracted to the comparison unit, respectively, and any one of the block for the electronic contract data to be verified and each of the terminals. The step of sequentially comparing each individual block to see if the blocks stored in one match each other, and the hash value of the n-th block of the electronic contract data to be verified and the hash value of the n-th block stored in any one of the terminals are identical. If not, the method for signing a smart electronic contract based on a blockchain comprising the step of transmitting the forgery and alteration notification message to at least one of the terminals. delete delete The method of claim 1,
The third step,
The electronic contract data including contract information is communicated to each of the terminals, and the electronic signature information is input to the electronic contract data through each of the terminals;
Generating the block by converting the electronic contract data including the electronic signature information into encrypted data through a hash function; and
And storing the block in the server unit and each of the terminals, and storing an encrypted key value and an order value in the server unit. The method of claim 4,
The third step,
Checking whether the electronic signature information is included in the electronic contract data so as to check the existence of a contract subject;
Blockchain-based smart electronic contract comprising the step of creating an n+1th block in the presence of the contract subject and storing the hash value of the n+1th block in the header of the nth block and converting it into a blockchain. Fastening method. delete delete The method of claim 1,
In the first step, at least one electronic contract template pre-stored in the server unit is extracted in the contract creation terminal, and electronic contract data including contract information is input and converted into data,
The electronic contract data created based on the electronic contract template and stored in the server unit is communicated to the expert's terminal through the contract creation terminal, and the corrected electronic contract data is transmitted to the server unit through the expert's terminal. And it further comprises the step of storing,
The second step further includes the step of communicating the electronic contract data stored in the server unit to each of the terminals, inputting the electronic signature information to the electronic contract data through each of the terminals, and storing the electronic signature information in the server unit. Blockchain-based smart electronic contract signing method, characterized in that. A contract creation terminal for inputting electronic contract data including contract information and for mediating authentication of electronic signature information to the electronic contract data;
A contract target-side terminal for mediating authentication of electronic signature information to the electronic contract data created from the contract-writing terminal;
A block generator that determines whether the electronic contract data includes electronic signature information through each of the terminals, and when the electronic signature information is included, encrypts and converts the electronic contract data into a block chain to generate a plurality of blocks;
A server unit in which an electronic contract template is previously stored, a key value and an order value for encryption are stored, and the electronic contract data and the block are stored; And
Comprising a comparison unit for comparing and determining whether the electronic contract data is forged or altered, and selectively transmitting a forgery notification message to at least one of the terminals,
The block is a space in which the electronic contract execution data is aggregated to form a tree structure, and includes the electronic contract execution data generated for the electronic contract data to which the electronic signature information, a key value for encryption, and an order value are assigned. It is generated, chained to each other, and the electronic contract signing data is encrypted data and blockchainized through a hash function including SHA-256 that consists of 256 bits and returns a 64-digit character string,
The block includes a header and a body, wherein hash values of adjacent blocks for preventing forgery are stored in a chain in the header, and the electronic contract conclusion data and the electronic contract conclusion data encrypted through a hash function are stored in the body. The browsing history is saved in a hash tree structure,
The comparison unit sequentially compares for each individual block whether the block for the electronic contract data to be verified and the block stored in each of the terminals coincide with each other, and the hash value of the n-th block for the electronic contract data to be verified and each When the hash value of the n-th block stored in any one of the terminals does not match, the forgery and alteration notification message is selectively transmitted to at least one of each of the terminals. delete

Images