Research on financial platform of railway freight supply chain based on blockchain

2.1.1 Financial development status of railway freight supply chain.

In August, 2011, China Railway Modern Logistics Technology Co., Ltd. and Shenzhen Development Bank reached a cooperation intention, realizing the formal connection between the online supply chain financial system of Shenzhen Development Bank and China Railway Modern Logistics Management System, representing the arrival of the era of real-time data exchange between the supply chain financial system and logistics supervision system of domestic commercial banks. In 2018, the total freight volume of China’s railways will be 4.026 billion tons. The intelligent railway supply chain will also promote the integration of trade and supply chain financial service systems directly related to the logistics service industry chain, and will obtain cross-border benefits through the integration of transportation, trade and finance. According to the long-term prospect in the Medium-and Long-Term Railway Network Planning, by 2030, internal and external interconnection, smooth inter-regional multi-channels, high-speed railway connectivity in provincial capitals, rapid access to cities and counties will be basically realized, and the largest railway logistics network in China will be formed. Therefore, the railway logistics and freight transportation industry will inevitably play a great role in supporting the factor endowment in the future railway supply chain ecology (Fengmao, 2020; Tian, 2020).

The “integration of transportation, trade and finance” led by the railway network aims at the upstream and downstream supply chain systems of all kinds of production/commerce industry chains, and uses the railway network, railway logistics base and controllable pick-up and delivery to “door-to-door” road freight enterprises, etc., forming an integrated system carrier of “transportation, storage and distribution”, as a “1” core enterprise and a closed control platform system in the “1+N + X” of supply chain finance, through systematic financial arrangements, we are deeply involved in various commercial enterprises and even production enterprises, forming an industrial chain ecology of “five flows in one” of business flow, information flow, capital flow, logistics and people flow, and using the blockchain and supply chain double-chain integration model. TOKEN is used to control the transportation/trade cycle within the tax cycle, helping upstream and downstream enterprises in the chain to obtain more reasonable value-added profits and further enhance the supply chain stability of the industrial chain ecological closed loop (Sixin and Jun, 2017; Geng, 2014).

2.1.2 Analysis of business entities and business activities of railway freight supply chain.

Based on the analysis of business entities and business activities in the supply chain of railway freight industry, we take railway coal transportation as an example to analyze business entities and business activities in the business chain:

• Background analysis of coal railway freight transportation business.

Construct the main business chain through three core enterprises: upstream coal production, midstream transportation and downstream coal consumption.

Core enterprises at different stages gather a number of small- and medium-sized enterprises with supply chains around them:

• Supply chain finance business scenario in coal railway freight transportation.

Small- and medium-sized enterprises around the supply chain of core enterprises at different stages include production, loading and unloading, transportation, warehousing and service.

For different types of small- and medium-sized enterprises, accounts receivable which can be used for financing are formed in the business dealings with core enterprises.

The supply chain finance business of railway freight industry will closely focus on all kinds of small-and medium-sized enterprises in the whole freight business chain and design corresponding business models to meet the financing needs of all kinds of enterprises.

2.2.1 Accounts receivable financing.

Taking the accounts receivable vouchers held by coal-producing enterprises as the subject matter (pledge or transfer), it provides enterprises with short-term financing business with a term not exceeding the aging of accounts receivable. In this business model, the responsibilities of the supply chain financial platform include: providing logistics and warehousing information services for banks and other funders and providing financing services for small- and medium-sized enterprises. For the credit line provided by banks and other funders, the supply chain financial platform provides online functions such as business management, process supervision and comprehensive information services.

2.2.2 Financing on behalf of procurement.

Supply chain financial platform provides financing services for coal consuming enterprises with purchasing needs and also provides logistics services such as purchasing, transportation, warehousing supervision and distribution.

2.2.3 Generation of sales financing.

Supply chain financial platform provides financing services for coal-producing enterprises with sales demand and also provides logistics services such as warehousing supervision, transportation and sales.

2.3.1 Analysis of the problems existing in the supply chain finance business of the railway freight industry.

To promote the financial industry to improve its service capacity and support the industrial transformation and upgrading, in recent years, various ministries and commissions have successively formulated a series of relevant policies to encourage the development of supply chain finance business in various industries. However, there are still many problems and challenges in the development of traditional supply chain finance business, which are summarized as follows:

• There is an information island in the supply chain: ERP systems among enterprises in the same supply chain are not interoperable, which leads to information fragmentation among enterprises, and it is difficult to integrate information in the whole chain. For financial institutions such as banks, the opaque information of enterprises means that risk control is more difficult, which is a huge obstacle to corporate financing and penetration of financial institutions.

• Core enterprise credit cannot be transferred: the information island problem leads to the indirect trade information between upstream suppliers and core enterprises cannot be proved, while the traditional supply chain financial instruments have limited ability to transfer core enterprise credit, which leads to the core enterprise credit can only be transferred to the first-level supplier level, but cannot be transferred across the whole supply chain.

• The performance risk cannot be effectively controlled: the payment and agreed settlement between the supplier and the buyer, the financier and the financial institution are limited by the contractual spirit and the willingness to perform, and there are many uncertain factors, which may lead to misappropriation of funds, malicious default or operational risks.

2.3.2 Integration needs of blockchain technology and supply chain finance.

The business pain point in the traditional supply chain finance scenario is the advantage of blockchain, a new technology. Blockchain is a fusion technology in many fields, such as point-to-point communication, digital encryption, distributed ledger, multi-party collaborative consensus algorithm, etc. It has the characteristics of unchangeable and traceable data on the chain, and is very suitable for multi-party supply chain financial business scenarios. Through blockchain technology, it can ensure data credibility and mutual recognition, transfer core enterprise credit, prevent performance risks, improve operational efficiency and reduce business costs. The application of blockchain in the field of supply chain finance can finally satisfy the mutual confirmation and matching of multiple information sources in the supply chain, and solve the pain point that the funder distrusts the transaction data (Xingxiong et al., 2018). Specific instructions are as follows:

• Transaction confirmation based on encrypted data.

Intangible assets that are difficult to supervise and protect under the network environment, blockchain is based on timestamp technology and difficult to tamper with, which has become a new method of intellectual property protection under the virtual environment. In recent years, it has begun to show important application value in the field of asset management, which promotes the real-time confirmation, authorization and transaction supervision of various assets. For tangible assets, such as certificates of deposit, accounts receivable and digital intelligent assets, real-world asset transactions can be realized under virtual environment, such as asset authorization and use control, product traceability and other applications. Blockchain realizes the automatic confirmation of movable property rights for all participants in the supply chain, forms an unalterable rights account book, and solves the pain points in the existing rights registration and rights realization:

• Proof of transaction authenticity based on deposit certificate.

The proof of transaction authenticity needs to be recorded in the creditor's rights information in the virtual world, and the consistency between the virtual information and the real information must be guaranteed, which is the basis of financial services and risk control. Supply chain finance needs to ensure that participants, transaction results and documents are based on real asset transactions. The authenticity of transaction is verified by manual means, which has some disadvantages such as high cost and low efficiency. To solve one of the core problems of supply chain finance, that is, the authenticity of transactions, it is necessary to obtain all kinds of information dynamically and in real time from the trading network under the virtual environment, and to carry out “cross-validation” of information to test the authenticity of transactions, which has become one of the key technologies of supply chain finance at present. Blockchain can solve this problem to a certain extent through digital signature, encryption and decryption technology and various offline operations:

• Credit disassembly based on shared ledger.

The goal of supply chain finance is to fully cover the financing of small and medium-sized enterprises. However, the financing needs of a large number of second-level and third-level suppliers/distributors are still difficult to meet. How to provide financial services for a large number of non-first-level suppliers and distributors in core enterprises needs to be focused on. Blockchain technology can disassemble the credit of core enterprises and pass it on to suppliers and distributors in the whole chain through shared books. Core enterprises can register their creditor's rights and debts with suppliers on the blockchain platform, and transfer relevant accounting vouchers step by step. The original debtor of the accounting voucher is the core enterprise, so in the financing scenario of the bank or factoring company, the process of reviewing the trade background can be seen at a glance on the platform. The problem of credit transmission can be solved with the help of blockchain technology:

• Automatic execution based on intelligent contract.

Intelligent contract provides an automatic operation tool for the implementation of supply chain financial business, and relying on efficient, accurate and automatic contract execution, it can alleviate the problem of difficult contract execution in reality. Taking real right financing as an example, after delivery, payment instructions can be sent to banks through smart contracts, thereby automatically completing fund payment, liquidation and financial reconciliation, improving business operation efficiency and reducing potential risks and losses caused by human operations to a certain extent. At present, the intelligent contract development platforms mainly include: Hyperledger (Linux), Corda intelligent contract platform (R3 Alliance), Ethereum intelligent contract platform, etc. Hyperledger (Linux) is widely used in commercial projects.

2.3.3 Integration framework of blockchain and supply chain finance.

The overall structure based on the integration of blockchain and supply chain financial business is shown in Figure 2.

Among them, the supply chain financial platform is the platform to be built by the railway freight logistics industry; Other partner systems are the systems of relevant external partners. The blockchain platform is built with Hyperledger-based Fabric technology. Each module inside the blockchain platform is described as follows.

API+SDK: External business systems access various resources in the blockchain platform network through SDK packaged into API interface, including account books, transactions, chain codes, events, rights management, etc., especially the installation, instantiation, upgrade and call of chain codes.

Account book: it is the core structure, which is responsible for recording application information, and the application records data in the account book by initiating transactions; Transaction: the logic of execution is carried by chain code; Events: Events occurring in the whole network operation can be accessed by applications to trigger external processes and even other systems; Chain code: relying on container, state machine and other technologies. User chain code provides state processing logic based on blockchain distributed ledger, which is written in Go/Java language and runs in Docker container.

Books and transactions depend on core technologies such as blockchain structure, database and consensus mechanism. Sorting service: All transactions in the sending network need to be sorted globally by sorting service before being verified and accepted by Committer, which provides atomic broadcast sorting function.

Authority management: responsible for access control in the whole process, solving the problem of who allows an operation in a certain scenario and using existing public key infrastructure system, digital certificate, encryption and decryption algorithm and other security technologies.

The bottom layer is composed of multiple nodes in peer-to-peer network, which communicates among different components through google remote procedure call channel, and uses Gossip protocol to provide message transmission, block distribution and state synchronization among nodes.

3.2.1 Risk identification and analysis.

Typical risks faced by railway freight transport industry in developing supply chain finance business include the following:

• Fraud risk. This risk is reflected in the authenticity of the basic transactions on which the supply chain financial business depends, including possible fraudulent behaviors such as constructing false transactions between buyers and sellers, or enterprises that do not have financing conditions pretending to be enterprises of the supply chain financial transaction parties to apply for financing, or using false information such as enterprises and transactions to apply for financing.

• Credit risk. According to the historical transaction records and business habits of enterprises participating in supply chain finance business, check the repayment performance of financing entities and repayment enterprises, and check the bad records of the entities through third parties (such as national tax, courts, etc.), so as to comprehensively judge the credit status of the participants in supply chain finance business, thus providing good basic data support for risk management and control.

• Risks such as price fluctuation of pledge. For the financing of goods, we should pay attention to the risks of the pledge itself, especially the position risk of the price fluctuation of the pledge after lending. The market price of the pledge may be affected by many factors and fluctuate. Therefore, the risks brought by the price fluctuation of pledge will be the key risks of the supply chain finance business of goods rights.

3.2.2 Design of wind control model.

Compared with traditional financial business, the risk control management of supply chain financial business should pay attention to not only the risks of financing subjects but also the final repayment sources, so as to control the risks of financing business in all directions. The wind control management model given in this study is shown in Figure 4:

• Risk control management is divided into three stages, namely, paying attention to the preliminary screening and review of basic transactions and assets in the pre-lending stage, paying attention to the rating credit and use of financing entities and related participants in the middle lending stage, paying attention to the repayment of various financing businesses after lending, monitoring related parties and collecting due claims.

• Risk control information focuses on three dimensions and six aspects of information, namely, enterprise basic information, enterprise shareholder information and enterprise operation information, and six aspects, namely, enterprise basic static information, enterprise financial status, legal person basic information, major shareholder information, enterprise exchange information and internal and external dynamic information. By collecting information about different dimensions and aspects of financing entities and final repayment entities, we can determine the credit line basis of enterprises, judge the current state of enterprises and predict the future dynamic information of enterprises, so as to better manage risk control.

• Multi-dimensional and multi-factor weighted risk control model algorithm, which classifies various types of risk control information for risk control management, gives different weights to different types of information in calculation, and can customize the risk factors and the scores of each factor under various types of information. The enterprise information that meets the requirements of risk factor data can finally get the total score of the enterprise under this model through this model algorithm.

The overall model is described as follows:

• Multi-dimensional model division and weight setting of each dimension. Support the establishment of multiple wind control models. Different dimensions can be set for a certain wind control model, and different dimensions are allowed to set their own risk factors. The model adopts a 100-point system, assuming that the weight of a certain dimension m in the model is n, the model has k dimensions, and the weight of each dimension is 100%. Therefore, the calculation algorithm of the first-level dimension framework of the model is described as follows:

Total score of model

For example, for the P model, three dimensions of enterprise basic information A, enterprise shareholder information B and enterprise management information C are set, and the full score of each dimension is 100 points. The weights of A, B and C are set to 30%, 30% and 40% respectively. It is necessary to calculate the scores of A, B and C, respectively, and the overall score is: A according to the first-level dimension framework.

• Setting multiple risk factors in each dimension. Set the risk factors included in each dimension of a wind control model and their weights under this dimension. Take the previous example: for example, dimension A includes two risk factors A and B (each with a weight of 50%), Dimension B includes four risk factors C, D, E and F (each with a weight of 25%), and Dimension C includes five risk factors G, H, I, J and K (each with a weight of 20%). So far, a basic risk control model system with three dimensions and eleven risk factors has been established.

• Preparation of business data input. According to all kinds of information of y enterprise in three dimensions of a, b and c, the business data required by eleven risk factors (i.e., a, b, c, d, e, f, g, h, I, j and k) required by the risk control model are extracted, so as to facilitate the calculation through the risk control model.

• Operational processing of wind control model. According to the data of eleven risk factors that Y enterprise meets the requirements, input the data into the wind control model, and calculate the final score of each risk factor according to the rules corresponding to different data scores specified in different risk factors in the model, and give the final scores of each dimension after the model operation. To take the above example: the input data based on eleven risk factors (i.e., A, B, C, D, E, F, G, H, I, J, K) and the operation and judgment process of risk control model judgment rules are shown in the following table: (Table 1).

• Wind control score output. Y enterprise score calculation is as follows:

Y total score of enterprise model =

= A * 30% + B * 30% + C * 40%

=70 * 30% + 60 * 30% + 80 * 40%

= 71

According to the final risk control score of enterprise Y, 71 points will be scored, and then follow-up business management activities such as credit rating and quota management related to supply chain finance business will be carried out.