农产品智慧供应链：内涵、关键技术与未来方向

doi:10.12133/j.smartag.SA202501006

Smart Agriculture

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农产品智慧供应链：内涵、关键技术与未来方向

韩佳伟¹^,²^,³(), 杨信廷¹^,²^,³()

^1.北京市农林科学院信息技术研究中心，北京 100097，中国
^2.农产品质量安全追溯技术及应用国家工程研究中心，北京 100097，中国
^3.农业农村部农产品冷链物流技术重点实验室，北京 100097，中国

收稿日期:2025-04-08 出版日期:2025-05-07
基金项目:
国家重点研发计划项目(2023YFD2001302;2022YFD2001804);宁夏回族自治区重点研发计划(2024BEG02031);北京市农林科学院科研创新平台建设项目(PT2025-24)
作者简介:韩佳伟，博士，副研究员，研究方向为智慧低碳冷链物流关键技术。E-mail：hanjw@nercita.org.cn
通信作者: 杨信廷，博士，研究员，研究方向为智慧低碳供应链关键技术。E-mail：yangxt@nercita.org.cn

Smart Supply Chains for Agricultural Products: Key Technologies, Research Progress and Future Direction

HAN Jiawei¹^,²^,³(), YANG Xinting¹^,²^,³()

^1.Research Center of information Technology, Beijing Academy of Agriculture and Forestry Sciences, Beijing 100097, China
^2.National Engineering Laboratory for Agri-product Quality Traceability, Beijing 100097, China
^3.Key Laboratory of Cold Chain Logistics Technology for Agro-product, Ministry of Agriculture and Rural Affairs, Beijing 100097, China

Received:2025-04-08 Online:2025-05-07
Foundation items:National Key Research and Development Program of China(2023YFD2001302;2022YFD2001804);Key Research and Development Program of Ningxia Hui Autonomous Region(2024BEG02031);Beijing Academy of Agriculture and Forestry Sciences Research Innovation Platform Construction Project(PT2025-24)
About author:HAN Jiawei, E-mail: hanjw@nercita.org.cn
Corresponding author:YANG Xinting, E-mail: yangxt@nercita.org.cn

摘要/Abstract

摘要：

目的/意义 农产品供应链智能化转型是破解传统环节信息断层、高物流成本与质量追溯难题的关键路径，对提升效率、保障质量安全及农业现代化意义重大。本文系统解析其内涵，梳理各环节技术进展并提出发展方向。［进展］本文详细梳理了农产品智慧供应链在生产、加工、仓储、运输、配送、销售等各环节的关键技术研究进展。生产环节集成物联网、人工智能（Artificial Intelligence, AI）与区块链技术，实现精准决策与病虫害防控；加工环节依托智能分拣、新型清洗减菌技术提升品质；仓储通过物联网监测与AI优化库存管理提高效率；运输聚焦冷链技术创新与智能调度系统优化配送时效；销售端运用大数据与AI技术驱动精准营销与库存管理，全链可溯源确保数据透明。［结论/ 展望未来需加速无人化运作与信息共享平台建设，通过技术赋能提升供应链韧性，并推进精细化管理以增强国际竞争力；产业模式上应深化低碳转型，推广清洁能源、绿色包装及智能物流，对接“双碳”目标。当前技术应用仍面临数据治理、标准化不足等挑战，需政策引导建立技术规范、加大研发投入，并强化跨领域协同创新，推动智能化升级，为农业可持续发展和全球粮食安全提供支撑。

关键词: 农产品, 智慧供应链, 物联网, 人工智能, 区块链

Abstract:

Significance The intelligent transformation of agricultural product supply chains is an essential solution to the challenges faced by traditional supply chains, such as information asymmetry, high logistics costs, and difficulties in quality traceability. This transformation also serves as a vital pathway to modernize agriculture and enhance industrial competitiveness. By integrating technologies such as the Internet of Things (IoT), big data, and artificial intelligence (AI), intelligent supply chains facilitate precise production and processing, efficient logistics distribution, and transparent quality supervision. As a result, they improve circulation efficiency, ensure product safety, increase farmers' incomes, and promote sustainable agricultural development. Furthermore, in light of global shifts in agricultural trade, this transformation bolsters the international competitiveness of China's agricultural products and propels the agricultural industrial chain toward higher value-added segments. This paper systematically examines the conceptual framework, technological applications, and future trends of intelligent supply chains, aiming to provide a theoretical foundation for industry practices and insights for policymaking and technological innovation. Progress In the production phase, IoT and remote sensing technologies enable real-time monitoring of crop growth conditions, including soil moisture, temperature, and pest infestation, facilitating precision irrigation, fertilization, and pest management. Big data analysis, coupled with AI algorithms, helps in predicting crop yields, optimizing resource allocation, and minimizing waste. Additionally, AI-driven smart pest control systems can dynamically adjust pesticide application, reducing chemical usage and environmental impact. The processing stage leverages advanced technologies for efficient sorting, grading, cleaning, and packaging. Computer vision and hyperspectral imaging technologies enhance the sorting efficiency and quality inspection of agricultural products, ensuring only high-quality products proceed to the next stage. Novel cleaning techniques, such as ultrasonic and nanobubble cleaning, effectively remove surface contaminants and reduce microbial loads without compromising product quality. Moreover, AI-integrated systems optimize processing lines, reducing downtime and enhancing overall throughput. Warehousing employs IoT sensors to monitor environmental conditions like temperature, humidity, and gas concentrations, ensuring optimal storage conditions for diverse agricultural products. AI algorithms predict inventory demand, optimizing stock levels to minimize waste and maximize freshness. Robotics and automation in warehouses improve picking, packing, and palletizing efficiency, reducing labor costs and enhancing accuracy. The transportation sector focuses on cold chain innovations to maintain product quality during transit. IoT-enabled temperature-controlled containers and AI-driven scheduling systems ensure timely and efficient delivery. Additionally, the integration of blockchain technology provides immutable records of product handling and conditions, enhancing transparency and trust. The adoption of new energy vehicles, such as electric and hydrogen-powered trucks, further reduces carbon footprints and operating costs. In the distribution and sales stages, big data analytics optimize delivery routes, reducing transportation time and costs. AI-powered demand forecasting enables precise inventory management, minimizing stockouts and excess inventories. Moreover, AI and machine learning algorithms personalize marketing efforts, improving customer engagement and satisfaction. Blockchain technology ensures product authenticity and traceability, enhancing consumer trust. Conclusions and Prospects As technological advancements and societal demands continue to evolve, the intelligent transformation of agricultural product supply chains has become increasingly urgent. Future development should prioritize unmanned operations to alleviate labor shortages and enhance product quality and safety. Establishing information-sharing platforms and implementing refined management practices will be crucial for optimizing resource allocation, improving operational efficiency, and enhancing international competitiveness. Additionally, aligning with the "dual-carbon" strategy by promoting clean energy adoption, optimizing transportation methods, and advocating for sustainable packaging will drive the supply chain toward greater sustainability. However, the application of emerging technologies in agricultural supply chains faces challenges such as data governance, technical adaptability, and standardization. Addressing these issues requires policy guidance, technological innovation, and cross-disciplinary collaboration. By overcoming these challenges, the comprehensive intelligent upgrade of agricultural product supply chains can be achieved, ultimately contributing to the modernization and sustainable development of the agricultural sector.

Key words: agricultural products, intelligent supply chain, IoT, AI, blockchain

中图分类号:

F326.6

韩佳伟, 杨信廷. 农产品智慧供应链：内涵、关键技术与未来方向[J]. 智慧农业(中英文), doi: 10.12133/j.smartag.SA202501006.

HAN Jiawei, YANG Xinting. Smart Supply Chains for Agricultural Products: Key Technologies, Research Progress and Future Direction[J]. Smart Agriculture, doi: 10.12133/j.smartag.SA202501006.

图/表 4

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农产品智慧供应链：内涵、关键技术与未来方向

Smart Supply Chains for Agricultural Products: Key Technologies, Research Progress and Future Direction

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