KR20240055435A - Block chain based logistics order record device - Google Patents

Abstract

A blockchain-based logistics order recording device includes an order block generator that uniquely assigns an order identification code to each transaction order when a conversation according to a transaction order occurs and generates an order block encrypting the conversation, the order block. A blockchain list control unit that generates a blockchain list sequentially connected and allows access to the blockchain list through a shipper identification code uniquely assigned to the shipper, and identifies the shipper during the processing of logistics related to the transaction order. It includes an individual order confirmation unit that accesses the order block based on a code or the order identification code and confirms the order using the conversation content.

Description

Blockchain-based logistics order recording device {BLOCK CHAIN BASED LOGISTICS ORDER RECORD DEVICE}

The present invention relates to a blockchain-based logistics order recording device. More specifically, when a conversation according to a transaction order occurs, an order identification code is uniquely assigned to each transaction order and an order block encrypted with the conversation is generated. , creates a blockchain list that sequentially connects order blocks, allows access to the blockchain list through the shipper identification code uniquely assigned to the shipper, and identifies the shipper identification code or order during the processing of logistics related to the transaction order. It is about a blockchain-based logistics order recording device that accesses the order block based on a code and confirms the order through conversation content.

A forwarder is a multimodal transportation broker who can efficiently distribute and load cargo from shippers with relatively small capacity on the cargo ships of shipping companies (international carriers) that can ship large volumes of cargo at once or in the aircraft cargo of airlines. It may be a logistics company that acts as a broker and simultaneously handles various tasks such as customs clearance and insurance for the cargo it brokered.

In general, a shipper or forwarder performs logistics operations from an overseas port of arrival to the final destination in import/export logistics, using an overseas local logistics company that is an existing local partner or through an overseas local logistics company linked through another route. Requesting manipulation.

Conventionally, only limited services are provided by relying on overseas local logistics companies to carry out logistics in the import/export region, logistics costs are also determined by arbitrarily set rates, and transportation times and routes are also determined or changed by overseas local logistics companies. Disadvantages resulting from lack of information are causing economic losses.

In addition, in the case of imported logistics coming into the country from overseas, smooth communication with various transportation entities, including shippers, is essential for logistics processing, such as cargo unloading, customs declaration, and inland trucking. The efficiency of logistics management is very low due to the independent operation system among various players.

In addition, in some cases, logistics must be performed in accordance with various environments and situations, such as cargo must be transported quickly within a specific day or transported at the lowest logistics cost regardless of the date, but due to limitations in information collection, domestic shippers There is a problem that logistics is carried out regardless of the forwarder's will.

In addition, it is inconvenient for the shipper or forwarder to prepare documents related to one import/export logistics case separately even though they are similar in content, as well as manpower and other related costs, such as re-writing due to errors, processing time when defects occur, and re-delivery costs. There is a problem that costs increase.

Korean Patent Publication No. 2016-0034197 relates to a logistics service provision system and method, and provides logistics information including at least one of transportation schedule information for each airline and shipping company, transportation risk information, cargo transportation status information, and country-specific tariff information. Receives a request for information inquiry about at least one of cargo transportation schedule, transportation risk, cargo transportation status, and import/export tariff from the information collection unit, the logistics information storage unit that stores the collected logistics information, and the customer terminal, and receives the collected information from the customer terminal. It includes a logistics information provider that generates logistics service information corresponding to the inquiry request based on logistics information and provides it to the customer terminal.

Korean Patent Publication No. 2016-0034197 (2016.03.22)

One embodiment of the present invention provides a blockchain-based logistics order recording device that can uniquely assign an order identification code to each transaction order when a conversation according to a transaction order occurs and generate an order block encrypting the conversation content. I want to do it.

One embodiment of the present invention is a blockchain-based logistics order recording device that generates a blockchain list sequentially connecting order blocks and allows access to the blockchain list through a shipper identification code uniquely assigned to the shipper. We would like to provide.

One embodiment of the present invention provides a blockchain-based logistics order recording device that can access the order block based on the shipper identification code or order identification code in the process of processing logistics related to a transaction order and confirm the order through conversation content. I want to do it.

The blockchain-based logistics order recording device according to an embodiment of the present invention uniquely assigns an order identification code to each transaction order when a conversation according to a transaction order occurs and generates an order block encrypting the conversation. An order block generator, a blockchain list control unit that generates a blockchain list sequentially connecting the order blocks and allows access to the blockchain list through a shipper identification code uniquely assigned to the shipper, and a block chain associated with the transaction order. It includes an individual order confirmation unit that accesses the order block based on the shipper identification code or the order identification code during logistics processing and confirms the order using the conversation content.

The order block generator may generate the order identification code by deriving it from the identification code for the shipper requesting the transaction order. The order block generator may index the order block so that it can be accessed through the order identification code. The order block generator may encrypt the order block by generating an encryption key based on the order identification code and the shipper identification code.

The blockchain list control unit connects the order blocks in reverse serial order and can create an order lookup table so that they can be directly accessed through the order identification code. The blockchain list control unit can access the blockchain list for each shipper and create a shipper lookup table so that the order block can be accessed in reverse order.

The individual order confirmation unit may receive a contract confirmation request associated with the transaction order from the shipper during the logistics delivery process and generate a decryption key based on the shipper identification code and the order identification code. The individual order confirmation unit may decrypt the conversation content based on the decryption key and provide it to the shipper along with the order.

The disclosed technology can have the following effects. However, since it does not mean that a specific embodiment must include all of the following effects or only the following effects, the scope of rights of the disclosed technology should not be understood as being limited thereby.

The blockchain-based logistics order recording device according to an embodiment of the present invention can generate an order identification code by deriving it from the identification code for the shipper requesting a transaction order.

The blockchain-based logistics order recording device according to an embodiment of the present invention can encrypt an order block by generating an encryption key based on the order identification code and the shipper identification code.

The blockchain-based logistics order recording device according to an embodiment of the present invention connects order blocks in reverse serial order and can generate an order lookup table so that they can be directly accessed through the order identification code.

The blockchain-based logistics order recording device according to an embodiment of the present invention can access the blockchain list for each shipper and create a shipper lookup table so that order blocks can be accessed in reverse order.

The blockchain-based logistics order recording device according to an embodiment of the present invention can decrypt the conversation content based on the blockchain list decryption key and provide it to the shipper along with the order.

Figure 1 is a diagram illustrating a blockchain-based logistics order recording system according to an embodiment of the present invention.
FIG. 2 is a diagram explaining the configuration of the blockchain-based logistics order recording system in FIG. 1.
FIG. 3 is a diagram explaining the configuration of the blockchain-based logistics order recording device of FIG. 1.
FIG. 4 is a flowchart explaining the functional configuration of the blockchain-based logistics order recording device of FIG. 1.
Figure 5 is a diagram illustrating an embodiment of a blockchain-based logistics order recording device according to the present invention.
Figure 6 is a diagram illustrating an embodiment of a blockchain-based logistics order recording device according to the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text. In other words, since the embodiment can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea. In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

Meanwhile, the meaning of the terms described in this application should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, a first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is referred to as being “connected” to another component, it should be understood that it may be directly connected to the other component, but that other components may exist in between. On the other hand, when a component is said to be “directly connected” to another component, it should be understood that there are no other components in between. Meanwhile, other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly neighboring" should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as “comprise” or “have” refer to implemented features, numbers, steps, operations, components, parts, or them. It is intended to specify the existence of a combination, and should be understood as not excluding in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

For each step, identification codes (e.g., a, b, c, etc.) are used for convenience of explanation. The identification codes do not explain the order of each step, and each step clearly follows a specific order in context. Unless specified, events may occur differently from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the opposite order.

The present invention can be implemented as computer-readable code on a computer-readable recording medium, and the computer-readable recording medium includes all types of recording devices that store data that can be read by a computer system. . Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices. Additionally, the computer-readable recording medium can be distributed across computer systems connected to a network, so that computer-readable code can be stored and executed in a distributed manner.

All terms used herein, unless otherwise defined, have the same meaning as commonly understood by a person of ordinary skill in the field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present application.

Figure 1 is a diagram illustrating a blockchain-based logistics order recording system according to an embodiment of the present invention.

Referring to FIG. 1, the blockchain-based logistics order recording system 100 may include a user terminal 110, a forwarder terminal 111, a blockchain-based logistics order recording device 130, and a database 150. there is.

The user terminal 110 may correspond to a terminal device operated by a user. According to an embodiment of the present invention, there may be one or more users, and in the case of multiple users, they may be divided into one or more user groups. Each of one or more users may correspond to one or more user terminals 110 .

The user terminal 110 is a device that constitutes the blockchain-based logistics order recording system 100 and may correspond to a computing device operated by forwarders. For example, the user terminal 110 may include a terminal capable of operating while connected to the blockchain-based logistics order recording device 130, but is not limited to this and may be used by shippers participating in the logistics forwarding process of airlines, ships, etc. It may include a terminal operated by. Additionally, the user may include a forwarder, and the forwarder terminal 111 may include a terminal that operates while connected to the blockchain-based logistics order recording device 130. Additionally, the user terminal 110 may install and execute a dedicated program or application to interoperate with the blockchain-based logistics order recording device 130.

The blockchain-based logistics order recording device 130 may be implemented as a server corresponding to a computer or program that performs the blockchain-based logistics order recording system 100 according to the present invention. In addition, the blockchain-based logistics order recording device 130 can be connected to the user terminal 110 through a wired network or a wireless network such as Bluetooth, WiFi, LTE, etc., and transmits and transmits data to the user terminal 110 through the network. You can receive it.

In addition, the blockchain-based logistics order recording device 130 can provide the blockchain-based logistics order recording system 100 according to the present invention to the user terminal 110 through an independent platform. For example, the blockchain-based logistics order recording device 130 may provide a blockchain-based logistics order recording platform, and for this purpose, it may be implemented to operate by being connected to an independent external system (not shown in FIG. 1). You can.

The database 150 may correspond to a storage device that stores various information required during the operation of the blockchain-based logistics order recording device 130. For example, the database 150 may store information collected or processed in various forms during the process of recording logistics orders. Here, the logistics order may include cargo transportation tasks requested by the shipper, and may be stored in the database 150 in blockchain form.

In addition, in FIG. 1, the database 150 is shown as a device independent of the blockchain-based logistics order recording device 130, but is not necessarily limited thereto, and is a logical storage device and is a blockchain-based logistics order recording device. It can be implemented by being included in (130).

FIG. 2 is a diagram explaining the configuration of the blockchain-based logistics order recording system in FIG. 1.

Referring to FIG. 2, the blockchain-based logistics order recording device 130 may include a processor 210, a memory 230, a user input/output unit 250, and a network input/output unit 270.

The processor 210 can execute a blockchain-based logistics order system procedure according to an embodiment of the present invention, and manage the memory 230 that is read or written in this process, and can manage the volatile memory 230 in the memory 230. The synchronization time between memory and non-volatile memory can be scheduled. The processor 210 can control the overall operation of the blockchain-based logistics order recording device 130 and is electrically connected to the memory 230, the user input/output unit 250, and the network input/output unit 270. Data flow can be controlled. The processor 210 may be implemented as a CPU (Central Processing Unit) of the blockchain-based logistics order recording device 130.

The memory 230 is implemented as a non-volatile memory such as a solid state disk (SSD) or a hard disk drive (HDD) and is an auxiliary memory used to store all data required for the blockchain-based logistics order recording device 130. It may include a main memory implemented as volatile memory such as RAM (Random Access Memory). Additionally, the memory 230 can store a set of instructions for executing the blockchain-based order recording system 100 according to the present invention by being executed by the electrically connected processor 210.

The user input/output unit 250 includes an environment for receiving user input and an environment for outputting specific information to the user, and includes an input adapter such as, for example, a touch pad, a touch screen, an on-screen keyboard, or a pointing device. It may include an output device including a device and an adapter such as a monitor or touch screen. In one embodiment, the user input/output unit 250 may correspond to a computing device connected through a remote connection, and in such case, the blockchain-based logistics order recording device 130 may be performed as an independent server.

The network input/output unit 270 provides a communication environment for connection to the user terminal 110 through a network, for example, a local area network (LAN), a metropolitan area network (MAN), a wide area network (WAN), and It may include an adapter for communication such as VAN (Value Added Network). Additionally, the network input/output unit 270 may be implemented to provide short-range communication functions such as WiFi and Bluetooth or wireless communication functions of 4G or higher for wireless transmission of data.

FIG. 3 is a diagram explaining the configuration of the blockchain-based logistics order recording device of FIG. 1.

Referring to FIG. 3, the blockchain-based logistics order recording device 130 may include an order block generator 310, a blockchain list control unit 320, an individual order confirmation unit 330, and a control unit 340. there is.

When conversation content according to a transaction order is generated, the order block generator 310 can uniquely assign an order identification code to each transaction order and generate an order block encrypting the conversation content. Here, the transaction order may correspond to a shipper requesting cargo transportation from the forwarder, and is not necessarily limited to this, and is performed through the user terminal 110 and the forwarder terminal ( 111) may further include conversations about cargo transportation between the parties. Here, the conversation content may include a request from a shipper requesting the performance of logistics forwarding work, but is not necessarily limited to this and may include the forwarder's response to the shipper's request and the overall message between the shipper and the forwarder. An order block may correspond to storing the contents of a conversation according to a transaction order as data in the form of a blockchain. It is not necessarily limited to this, and the contents of a conversation according to a transaction order are distributed to one or more terminals in a virtual data storage space in the form of a block. May include saved items. Here, the virtual data storage space in the form of a block may correspond to the database 150. Additionally, order blocks can be mapped using a hash code of a certain length and stored in the database 150 separately according to the shipper. In one embodiment, the order block generator 310 can divide order blocks by shipper and connect a plurality of blocks in the form of a chain, and can identify the order details of the shipper through the blocks connected in the chain form. In one embodiment, the order block generator 310 can distinguish order blocks of different shippers by generating a shipper identification code for one or more shippers and assigning it to each shipper. Here, the shipper identification code may correspond to information related to user identification such as e-mail information, social network ID, etc., but is not necessarily limited to this and is composed of random numbers including numbers and strings of a certain length to identify the shipper. It may correspond to a serial number and may be distributed and stored through one or more terminals in blockchain form. When generating a shipper identification code, the order block generator 310 may request a certificate from the shipper to distinguish between different shippers, and store the certificate received through the user terminal 110 in the database 150. . Here, the certificate may correspond to procedures such as electronic certificate, joint certificate including fingerprint recognition, and user authentication through login, and may be stored in different locations in the database 150 for each shipper. That is, the order block generator 310 generates a shipper identification code for each order block based on each shipper's certificate and stores it in different locations in the database 150, thereby generating conversation contents according to the shipper's transaction order. can be accessed.

In one embodiment, the order block generator 310 may generate an order identification code by deriving it from the identification code for the shipper requesting a transaction order. Here, the order identification code may correspond to information containing part or all of the information on user identification that constitutes the shipper identification code, but is not necessarily applicable to this and is a series of codes to distinguish one or more order blocks requested by the shipper. It may further include numbers, and the serial number may correspond to a random number containing numbers and strings of a certain length. For example, the order block generator 310 can distinguish each order block for one shipper through the order identification code generated using the shipper identification code. That is, the order block generator 310 generates an order identification code and assigns it to each order block, thereby confirming the details of the logistics forwarding task requested by the shipper. In addition, the order block generator 310 can provide the shipper's request details in time series through the user terminal 110, and this does not necessarily apply to the time, cost details, and origin/of items for the shipper's entire request. Forwarding information including destination and Incoterms rules used in the forwarding process can be provided in time series. Incoterms rules include Cost, Insurance And Freight (CIF), Carriage Paid To (CPT), Carriage And Insurance Paid To (CIP), Cost And Freight (CFR), Delivered At Terminal (DAT), Delivered At Place (DAP) and Export process Incoterms, including Delivered Duty Paid (DDP), and import process Incoterms, including EXW (Ex Works), FCA (Free Carrier), FAS (Free Alongside Ship), and FOB (Free On Board). and may be updated when new revisions are released.

Additionally, the order block generator 310 can generate order blocks for each shipper, classify the order blocks for each shipper, and connect them in the form of a chain. That is, the order block generator 310 stores the orders requested by each shipper in the database 150 in the form of a block, thereby distinguishing and accessing one or more orders requested by each shipper. For example, the order block generator 310 can access the shipper's transaction orders in time series order. Time series order may correspond to accessing forwarding information items including time, cost details, origin/destination of items, and Incoterms rules used in the forwarding process for the shipper's transaction order, but is not limited to this, and may be done in reverse series order. It is accessible.

In one embodiment, the order block generator 310 may index the order block so that it can be accessed through an order identification code. Here, the index may correspond to storing the order block location in the database 150, designating the order block storage location, and may include accessing the order block storage location. The order block generator 310 stores the order block in the database 150, and when the shipper requests access to the order block through the user terminal 110, the storage location of the order block stored in the database 150 is determined. It can be provided to the user terminal 110. That is, when the order block generator 310 receives a shipper's request by specifying and indexing the storage address of the order block, it accesses the order block, checks the order identification code, and uses the encryption key through the user terminal 110. By requesting to input , access of the user terminal 110 and the forwarder terminal 111 to the shipper's request details can be permitted.

In one embodiment, the order block generator 310 may generate an encryption key based on the order identification code and the shipper identification code to encrypt the order block. The encryption key may correspond to information about the certificate used in the order identification code and shipper identification code, and is not necessarily limited to this, and may correspond to a code generated by adding or subtracting the serial numbers of the shipper identification code and order identification code. there is. For example, the order block generator 310 can generate an encryption key and encrypt the order block using the result of adding and subtracting the order identification code and the shipper identification code. When accessing an order block stored in the database 150 through an order identification code, the order block generator 310 may request input of an encryption key through the user terminal 110. That is, the order block generator 310 can block access to the order block by anyone other than the shipper and forwarder by requesting input of an encryption key.

The blockchain list control unit 320 can create a blockchain list that sequentially connects order blocks and allow access to the blockchain list through the shipper identification code uniquely assigned to the shipper. Here, the blockchain list may correspond to a list of order blocks containing the request details of each shipper stored in the database 150. The blockchain list control unit 320 can access the order block corresponding to each shipper's request details through the shipper identification code, including time, cost details, origin/destination of the item, and Incoterms rules used in the forwarding process. Forwarding information can be accessed by item.

In one embodiment, the blockchain list control unit 320 connects order blocks in reverse serial order and creates an order lookup table so that they can be directly accessed through the order identification code. That is, the blockchain list control unit 320 defines and generates matching information between the order identification code and the order block as a lookup table, and can directly access the order block corresponding to the order identification code through the generated order lookup table. The order lookup table may correspond to a matching table corresponding to matching information between the order identification code and the order block. For example, the order lookup table may correspond to data stored by matching the shipper's order block stored in the database 150 by forwarding information item. This may correspond to storing not only order identification code and block matching information, but also matching information between forwarding information items and order blocks. When a request for order block confirmation from a shipper is received, the blockchain list control unit 320 determines a matching order block through an order lookup table based on the order identification code associated with the request, and sends the information stored in the order block to the corresponding order block. It can be provided to the shipper as a response to the request. In other words, the blockchain list control unit 320 can enable the forwarder to directly access the order contents by creating an order lookup table, and provides information about the order block to the forwarder who sent the order block confirmation request. can do.

In one embodiment, the blockchain list control unit 320 can access the blockchain list for each shipper and create a shipper lookup table so that order blocks can be accessed in reverse order. The shipper lookup table may correspond to a matching table corresponding to matching information between the shipper identification code and the order block. For example, it may correspond to data stored by matching the shipper's order block stored in the database 150 by shipper name. This may correspond to storing not only the shipper identification code and order block matching information, but also matching information between the shipper name and order block. For example, the blockchain list control unit 320 can confirm the overall process of logistics forwarding by accessing previously stored order blocks and checking the conversation contents in reverse order. In one embodiment, the blockchain list control unit 320 matches the order lookup table and the shipper lookup table, allowing the shipper and the forwarder to access the order block in both directions. For example, the blockchain list control unit 320 checks the order lookup table and the order block matching the shipper lookup table for the transaction orders of the shipper and the forwarder, and allows the shipper and the forwarder to simultaneously access the corresponding order block and place the transaction order. You can check the information. In other words, the blockchain list control unit 320 can access the designated storage location of the corresponding order block based on the order lookup table and the shipper lookup table, and allow simultaneous access to the order block requested by the shipper and forwarder.

The individual order confirmation unit 330 may access the order block based on the shipper identification code or order identification code during the processing of logistics related to the transaction order and confirm the order through conversation content. For example, the individual order confirmation unit 330 matches the order lookup table and the shipper lookup table generated by the blockchain list control unit 320 to access the order block requested by the shipper, thereby performing an index process for the order block requested by the shipper. You can access the order block corresponding to the shipper identification code or order identification code using index information for the stored order block. That is, during the logistics processing process, the individual order confirmation unit 330 can check the order between the shipper and the forwarder stored in the order block and perform logistics work based on the conversation content.

In one embodiment, the individual order confirmation unit 330 may receive a contract confirmation request associated with a transaction order from a shipper during the logistics delivery process and generate a decryption key based on the shipper identification code and order identification code. When receiving a contract confirmation request related to a transaction order between a shipper and a forwarder, the individual order confirmation unit 330 may provide a decryption key to the user terminal 110 and the forwarder terminal 111. The decryption key may correspond to the symmetry of the encryption key, but is not necessarily limited to this, and may correspond to a reversal of the encryption key generation process. That is, the individual order confirmation unit 330 can generate a decryption key by reversing the process of adding and subtracting the serial numbers of the order identification code and the shipper identification code used in the encryption key generation process.

The individual order confirmation unit 330 can reconfirm the contract contents to the shipper and forwarder by providing a decryption key to the shipper and forwarder whose contract has been confirmed for the order, and is not necessarily limited to this, but provides information on overall logistics forwarding. can do. For example, the individual order confirmation unit 330 can grant access to the order block by generating a decryption key based on the order lookup table and the shipper lookup table and providing it to the shipper and forwarder.

In one embodiment, the individual order confirmation unit 330 may decrypt the conversation content based on a decryption key and provide it to the shipper along with the order. The individual order confirmation unit 330 receives a decryption key request from the user terminal 110 and provides the decryption key itself, thereby confirming information about the transaction order on the user terminal 110 that received the decryption key. That is, the individual order confirmation unit 330 can reconfirm the content of the conversation about the request between the shipper and the forwarder by providing a decryption key to the shipper and forwarder for whom the contract has been completed. For example, the individual order confirmation unit 330 may provide information on contract fulfillment by providing a decryption key for one or more order blocks between the shipper and forwarder who performed the contract, but is not necessarily limited thereto, and may provide information on contract fulfillment according to the contract. Logistics information generated during the logistics execution process can be provided. Here, the logistics information may include, but is not necessarily limited to, the current location of the cargo and the numbers of airplanes and ships transporting the cargo. In one embodiment, the individual order confirmation unit 330 may update logistics information generated during the logistics execution process in real time.

The control unit 340 controls the overall operation of the blockchain-based logistics order recording device 130 and controls the control flow between the order block creation unit 310, the blockchain list control unit 320, and the individual order confirmation unit 330. Data flow can be managed.

FIG. 4 is a flowchart explaining the functional configuration of the blockchain-based logistics order recording device of FIG. 1.

Referring to FIG. 4, the blockchain-based logistics order recording device 130 can be implemented to execute the blockchain-based logistics order recording system 100 according to the present invention.

When conversation content according to a transaction order occurs, an order identification code is uniquely assigned to each transaction order and an order block encrypting the conversation content is created (S410). In one embodiment, the order block generator 310 can divide order blocks by shipper and connect a plurality of blocks in the form of a chain, and can identify the order details of the shipper through the blocks connected in the chain form. In addition, when generating a shipper identification code, the order block generator 310 may request a certificate from the shipper to distinguish between different shippers, and store the certificate received through the user terminal 110 in the database 150. You can. At this time, the order block generator 310 generates a shipper identification code for each order block based on each shipper's certificate and stores it in different locations in the database 150, thereby providing conversation content according to the shipper's transaction order. can be accessed.

In one embodiment, the order block generator 310 may generate an order identification code by deriving it from the identification code for the shipper requesting a transaction order. In addition, the order block generator 310 can provide the shipper's request details in time series through the user terminal 110, and this does not necessarily apply to the time, cost details, and origin/of items for the shipper's entire request. Forwarding information including destination and Incoterms rules used in the forwarding process can be provided in time series. The order block generator 310 stores the orders requested by each shipper in the database 150 in the form of blocks, so that one or more orders requested by each shipper can be distinguished and accessed through the order identification code. When receiving a shipper's request by indexing an order block, the user terminal (110) accesses the corresponding order block, checks the order identification code, and requests the user terminal (110) to enter an encryption key to confirm the shipper's request details. ) and access to the forwarder terminal 111 may be permitted.

A blockchain list that sequentially connects order blocks is created, and the blockchain list is accessed through the shipper identification code uniquely assigned to the shipper (S420). The blockchain list control unit 320 can access the order block corresponding to each shipper's request details through the shipper identification code, including time, cost details, origin/destination of the item, and Incoterms rules used in the forwarding process. Forwarding information can be accessed by item. At this time, the blockchain list control unit 320 connects the order blocks in reverse serial order and creates an order lookup table so that they can be accessed directly through the order identification code, and looks up matching information between the order identification code and the order block. You can define and create a table and directly access the order block corresponding to the order identification code through the created order lookup table. The blockchain list control unit 320 can access the blockchain list by shipper and create a shipper lookup table so that order blocks can be accessed in reverse order, and the corresponding order block based on the order lookup table and shipper lookup table. You can access the designated storage location and access the order block requested by the shipper and forwarder at the same time.

In the process of processing logistics related to a transaction order, the order block is accessed based on the shipper identification code or order identification code and the order is confirmed through the conversation (S430). The individual order confirmation unit 330 may receive a contract confirmation request related to a transaction order from the shipper during the logistics delivery process and generate a decryption key based on the shipper identification code and order identification code. When the individual order confirmation unit 330 receives a contract confirmation request associated with a transaction order between a shipper and a forwarder, the user terminal 110 and the forwarder terminal 111 receive a contract confirmation request associated with a transaction order between a shipper and a forwarder. ) can provide the decryption key. The individual order confirmation unit 330 can provide information about contract details and overall logistics forwarding to the shipper and forwarder by providing the shipper with a decryption key.

Figure 5 is a diagram explaining an embodiment of a blockchain-based logistics order recording device according to the present invention.

Referring to FIG. 5, when each shipper requests one or more orders from the forwarder, the order block generator 310 assigns a shipper identification code to each shipper and generates one or more order blocks for the shipper identification code. You can. Here, one or more orders created by the shipper can be divided by shipper and connected in a chain form, and the shipper's order details can be identified by accessing blocks connected in the chain form, and the shipper's order can be checked through the user terminal 110. Details can be provided. In addition, the order block generator 310 generates each order identification code for one or more order blocks, such as time, cost details, origin/destination of items, and Incoterms rules used in the forwarding process for the shipper's entire request. Forwarding information including can be provided in time series.

Figure 6 is a diagram explaining an embodiment of a blockchain-based logistics order recording device according to the present invention.

Referring to FIG. 6, the individual order confirmation unit 330 can allow access to the order block by providing a decryption key to the shipper and forwarder with whom the contract has been established, and can confirm the order by providing conversation details to the shipper and forwarder. It can be re-confirmed. That is, the individual order confirmation unit 330 indexes order blocks based on the order lookup table and shipper lookup table generated by the blockchain list control unit 320, and provides a decryption key for each order block to enable the shipper and forwarder. Real-time access to information on contract performance and logistics information generated in the process of performing logistics according to the contract may be permitted.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

100: Blockchain-based logistics order recording system
110: user terminal
111: forwarder terminal
130: Blockchain-based logistics order recording device
150: database
310: Order block generation unit
320: Blockchain list control unit
330: Individual order confirmation unit
340: control unit

Claims (8)

When conversation content according to a transaction order occurs, an order block generator that uniquely assigns an order identification code to each transaction order and generates an order block encrypting the conversation content;
A blockchain list control unit that generates a blockchain list sequentially connecting the order blocks and allows access to the blockchain list through a shipper identification code uniquely assigned to the shipper; and
In the process of processing logistics related to the transaction order, a blockchain-based logistics order record including an individual order confirmation unit that accesses the order block based on the shipper identification code or the order identification code and confirms the order with the conversation content. Device.
The method of claim 1, wherein the order block generator
A blockchain-based logistics order recording device that generates the order identification code by deriving it from the identification code of the shipper requesting the transaction order.
The method of claim 2, wherein the order block generator
A blockchain-based logistics order recording device characterized by indexing the order block so that it can be accessed through the order identification code.
The method of claim 1, wherein the order block generator
A blockchain-based logistics order recording device characterized in that the order block is encrypted by generating an encryption key based on the order identification code and the shipper identification code.
The method of claim 1, wherein the blockchain list control unit
A blockchain-based logistics order recording device that connects the order blocks in reverse serial order and generates an order lookup table so that they can be directly accessed through the order identification code.
The method of claim 5, wherein the blockchain list control unit
A blockchain-based logistics order recording device that generates a shipper lookup table so that the block chain list can be accessed by shipper and the order block can be accessed in reverse order.
The method of claim 1, wherein the individual order confirmation unit
A blockchain-based logistics order recording device that receives a contract confirmation request related to the transaction order from the shipper during the logistics delivery process and generates a decryption key based on the shipper identification code and the order identification code.
The method of claim 7, wherein the individual order confirmation unit
A blockchain-based logistics order recording device that decrypts the conversation content based on the decryption key and provides it to the shipper along with the order.