Evolution, key technology, prospects, and applications of industrial network architecture

WANG Jian-quan; MA Zhang-chao; SUN Lei; ZHANG Chao-yi; LI Wei

doi:10.13374/j.issn2095-9389.2022.08.01.003

Volume 45 Issue 8

Aug. 2023

Turn off MathJax

Article Contents

Article Navigation > Chinese Journal of Engineering > 2023 > 45(8): 1376-1389

WANG Jian-quan, MA Zhang-chao, SUN Lei, ZHANG Chao-yi, LI Wei. Evolution, key technology, prospects, and applications of industrial network architecture[J]. Chinese Journal of Engineering, 2023, 45(8): 1376-1389. doi: 10.13374/j.issn2095-9389.2022.08.01.003

Citation:

WANG Jian-quan, MA Zhang-chao, SUN Lei, ZHANG Chao-yi, LI Wei. Evolution, key technology, prospects, and applications of industrial network architecture[J]. Chinese Journal of Engineering, 2023, 45(8): 1376-1389. doi: 10.13374/j.issn2095-9389.2022.08.01.003

Citation:

PDF( 2386 KB)

Evolution, key technology, prospects, and applications of industrial network architecture

doi: 10.13374/j.issn2095-9389.2022.08.01.003

1.
School of Automation and Electronic Engineering, University of Science and Technology Beijing, Beijing 100083, China
2.
School of Computer and Communication, University of Science and Technology Beijing, Beijing 100083, China

More Information

Corresponding author: E-mail: zhangchaoyi@ustb.edu.cn
Received Date: 2022-08-01
Available Online: 2023-04-14
Publish Date: 2023-08-25

Abstract

Abstract

Based on a summary of the characteristics of the industrial Internet, combined with the overall status of the existing industrial Internet, this paper analyzes the problems of the traditional industrial automation closed five-tier architecture and concludes that the current industrial Internet remains in a stage of technological development and maturation, which restricts the promotion and standardization of China’s intelligent manufacturing level to some extent. In the future, the industrial Internet will break the original data hierarchy structure, break the data barrier, and realize the development of intelligent manufacturing toward intelligent, flattening, lightweight, and green. First, this paper proposes a new industrial network collaboration architecture on the cloud side that supports efficient data flow. The proposed architecture is a flat, platform-based structure that realizes cloud-side collaboration and the integration of control, computing power, and network. Second, on the basis of the overall architecture of the industrial network, two key technologies are proposed to adapt the new industrial network infrastructure. One is 5G–time-sensitive networking (TSN) collaborative transmission technology. TSN realizes the interconnection and integration of heterogeneous networks in the industrial field based on the data link layer, and 5G–TSN collaborative transmission has become an important evolution trend of the intelligent factory network. Three key technical contents are introduced: 5G–TSN heterogeneous network convergence architecture, network clock adaptation mechanism, and software defined network (SDN)-based integration management and resource scheduling. The other key technology is cloud PLC technology based on a deterministic network, and the virtualization and cloud control system is the basis for breaking the original closed industrial control system. On the one hand, cloud-based hardware resources can be used to achieve one-to-many control, saving a large amount of industrial control equipment deployment investment costs. More importantly, the centralized control system can achieve unified control and optimization of global resources. This paper introduces the virtualization 5G cloud chemical industry control technology with two parts: technical content and technical route. Third, this paper proposes a cloud-based allocation of control resources and a cloud–network integration collaboration scenario and designs the 5G cloud-based programmable logic controller (PLC) and EtherCAT fusion system and the EtherCAT and TSN fusion system for real-time motion control. Through the testing of the end-to-end delay and cross-network time synchronization accuracy of the actual system, the current end-to-end delay of network transmission is less than 5 ms, the cross-network time synchronization error is between 100–400 us, and the accuracy is less than 100 ns These performance indicators reach the current industry-leading level. The test platform verifies the scientificalness and rationality of the new industrial network architecture. Finally, the integration problems and potential solutions of efficiency, reliability, and security are discussed in the future industrial automation system integrating network, control, and computing.
- industrial internet,
- intelligent manufacturing,
- time sensitive network,
- 5G,
- industrial control virtualization,
- auto-control,
- cloud programmable logic controller

FullText(HTML)

References(27)

References

[1]	亓晉, 王微, 陳孟璽, 等. 工業互聯網的概念、體系架構及關鍵技術. 物聯網學報, 2022, 6(2):38 Qi J, Wang W, Chen M X, et al. Concept, architecture and key technologies of industrial internet. Chin J Internet Things, 2022, 6(2): 38
[2]	Jagatheesaperumal S K, Rahouti M, Ahmad K, et al. The Duo of artificial intelligence and big data for industry 4.0: Applications, techniques, challenges, and future research directions. IEEE Internet Things J, 2022, 9(15): 12861
[3]	Javaid M, Haleem A, Singh R P, et al. Artificial intelligence applications for industry 4.0: A literature-based study. J Ind Intg Mgmt, 2022, 7(1): 83 doi: 10.1142/S2424862221300040
[4]	Yuan C X, Li G Y, Kamarthi S, et al. Trends in intelligent manufacturing research: A keyword co-occurrence network based review. J Intell Manuf, 2022, 33(2): 425 doi: 10.1007/s10845-021-01885-x
[5]	Wan J F, Tang S L, Shu Z G, et al. Software-defined industrial Internet of Things in the context of industry 4.0. IEEE Sens J, 2016, 16(20): 7373
[6]	馬南峰, 姚錫凡, 王柯賽. 面向未來互聯網的智慧制造研究現狀與展望. 中國科學:技術科學, 2022, 52(1):55 doi: 10.1360/SST-2021-0232 Ma N F, Yao X F, Wang K S. Current status and prospect of future internet-oriented wisdom manufacturing. Sci Sin (Technol), 2022, 52(1): 55 doi: 10.1360/SST-2021-0232
[7]	Wollschlaeger M, Sauter T, Jasperneite J. The future of industrial communication: Automation networks in the era of the internet of things and industry 4.0. IEEE Ind Electron Mag, 2017, 11(1): 17 doi: 10.1109/MIE.2017.2649104
[8]	Pop P, Zarrin B, Barzegaran M, et al. The FORA fog computing platform for industrial IoT. Inf Syst, 2021, 98: 101727 doi: 10.1016/j.is.2021.101727
[9]	孫雷, 王健全, 林尚靜, 等. 基于無線信道信息的5G與TSN聯合調度機制研究. 通信學報, 2021, 42(12):65 Sun L, Wang J Q, Lin S J, et al. Research on 5G–TSN joint scheduling mechanism based on radio channel information. J Commun, 2021, 42(12): 65
[10]	劉青, 邵鑫, 楊建平, 等. 煉鋼廠多尺度建模與協同制造. 工程科學學報, 2021, 43(12):1698 Liu Q, Shao X, Yang J P, et al. Multiscale modeling and collaborative manufacturing for steelmaking plants. Chin J Eng, 2021, 43(12): 1698
[11]	張麗. 5G網絡在鋼鐵行業設備數據快速接入平臺中的應用. 冶金自動化, 2021, 45(4):1 doi: 10.3969/j.issn.1000-7059.2021.04.001 Zhang L. Application of 5G network in iron and steel industry equipment data fast access platform. Metall Ind Autom, 2021, 45(4): 1 doi: 10.3969/j.issn.1000-7059.2021.04.001
[12]	Alonzo M, Baracca P, Khosravirad S R, et al. Cell-free and user-centric massive MIMO architectures for reliable communications in indoor factory environments. IEEE Open J Commun Soc, 2021, 2: 1390 doi: 10.1109/OJCOMS.2021.3089281
[13]	Briglauer W, Stocker V, Whalley J. Public policy targets in EU broadband markets: The role of technological neutrality. Telecommun Policy, 2020, 44(5): 101908 doi: 10.1016/j.telpol.2019.101908
[14]	Zhu P K, Yoshida Y, Kanno A, et al. High-fidelity indoor MIMO radio access for 5G and beyond based on legacy multimode fiber and real-time analog-to-digital-compression. Opt Express, 2021, 29(2): 1945 doi: 10.1364/OE.411144
[15]	李伯虎, 柴旭東, 劉陽, 等. 工業環境下信息通信類技術賦能智能制造研究. 中國工程科學, 2022, 24(2):75 Li B H, Chai X D, Liu Y, et al. Intelligent manufacturing enabled by information and communication technology in industrial environment. Strateg Study CAE, 2022, 24(2): 75
[16]	田輝, 賀碩, 林尚靜, 等. 工業互聯網感知通信控制協同融合技術研究綜述. 通信學報, 2021, 42(10):211 Tian H, He S, Lin S J, et al. Survey on cooperative fusion technologies with perception, communication and control coupled in industrial Internet. J Commun, 2021, 42(10): 211
[17]	任磊, 賈子翟, 賴李媛君, 等. 數據驅動的工業智能: 現狀與展望. 計算機集成制造系統, 2022, 28(7):1913 Ren L, Jia Z Z, Lai L Y J, et al. Data-driven industrial intelligence: Current status and future directions. Comput Integr Manuf Syst, 2022, 28(7): 1913
[18]	蔡岳平, 姚宗辰, 李天馳. 時間敏感網絡標準與研究綜述. 計算機學報, 2021, 44(7):1378 doi: 10.11897/SP.J.1016.2020.01378 Cai Y P, Yao Z C, Li T C. A survey on time-sensitive networking: Standards and state-of-the-art. Chin J Comput, 2021, 44(7): 1378 doi: 10.11897/SP.J.1016.2020.01378
[19]	柴天佑, 劉強, 丁進良, 等. 工業互聯網驅動的流程工業智能優化制造新模式研究展望. 中國科學:技術科學, 2022, 52(1):14 doi: 10.1360/SST-2021-0405 Chai T Y, Liu Q, Ding J L, et al. Perspectives on industrial-internet-driven intelligent optimized manufacturing mode for process industries. Sci Sin (Technol), 2022, 52(1): 14 doi: 10.1360/SST-2021-0405
[20]	安夢越, 王興艷. 以智能制造助力中國鋼鐵行業高質量發展. 冶金經濟與管理, 2022(2):30 An M Y, Wang X Y. Boosting the high-quality development of China’s steel industry with intelligent manufacturing. Metall Economy Manag, 2022(2): 30
[21]	張斌, 王法中, 許立前. 我國工業互聯網平臺標準化現狀及需求淺析. 中國質量與標準導報, 2022(1):59 Zhang B, Wang F Z, Xu L Q. Brief analysis on the current situation and demand of standardization of industrial Internet platform in China. China Qual Stand Rev, 2022(1): 59
[22]	臧冀原, 劉宇飛, 王柏村, 等. 面向2035的智能制造技術預見和路線圖研究. 機械工程學報, 2022, 58(4):285 Zang J Y, Liu Y F, Wang B C, et al. Technology forecasting and roadmapping of intelligent manufacturing by 2035. J Mech Eng, 2022, 58(4): 285
[23]	工業互聯網產業聯盟. 工業互聯網體系架構(版本2.0)[R/OL]. 在線報告(2020-04) [2022-08-01]. http://www.aii-alliance.org/upload/202004/0430_162140_875.pdf Industrial Internet Industry Alliance. Industrial internet architecture (2.0) [R/OL]. Report Online (2020-04) [2022-08-01]. http://www.aii-alliance.org/upload/202004/0430_162140_875.pdf
[24]	工業互聯網產業聯盟. 工業智能白皮書 [R/OL]. 在線報告(2020-04) [2022-08-01]. https://tech.sina.com.cn/roll/2020-07-06/doc-iircuyvk2170592.shtml Industrial Internet Industry Alliance. Industrial intelligence white paper [R/OL]. Report Online (2020-04) [2022-08-01]. https://tech.sina.com.cn/roll/2020-07-06/doc-iircuyvk2170592.shtml
[25]	Zheng Z, Zhang K T, Gao X Q. Human-cyber-physical system for production and operation decision optimization in smart steel plants. Sci China Technol Sci, 2022, 65(2): 247 doi: 10.1007/s11431-020-1838-6
[26]	5G Alliance for Connected Industries and Automation. Integration of 5G with time-sensitive networking for industrial communications [EB/OL]. Report Online (2021-01-19) [2022-08-01]. https://5g-acia.org/whitepapers/integration-of-5g-with-time-sensitive-networking-for-industrial-communications/
[27]	張啟明, 鄭興明, 張壽勇. 5G TSN技術的創新研究. 中興通訊技術, 2022, 28(3):78 Zhang Q M, Zheng X M, Zhang S Y. 5G TSN technologies and innovation. ZTE Technol J, 2022, 28(3): 78