Decentralized coordinated control of continuous multi-zone objects
DOI:
https://doi.org/10.31548/energiya4(68).2023.101Abstract
Distributed continuous multi-zone objects are widespread both in production and in everyday life. Centralized and hierarchical control systems have a rigid relationship structure and are difficult to scale. This complicates their application to objects with frequent and rapid changes in its structure and requirements. The authors have proposed a new approach to the decentralized coordination of control of multi-zone thermal objects, however, the problem of coordination control of the state of continuous multi-zone distributed objects with a dynamic structure and variable requirements has not yet been effectively solved. The aim of the work is to generalize the approach to decentralized coordination of control of distributed systems with multi-zone objects of continuous type. The results of the work are based on the methods of the automatic control theory, heat engineering and simulation modeling. The methodology of decentralized coordination control, in particular the model of the distributed control system of a multi-zonal continuous object, the method of decentralized coordination based on the global-local criterion, the principle of close action, the approaches to active and passive identification of system parameters, the method of forecasting the state of the system based on analysis of spatial-time spectrum of object states were generalized in the work. Based on theoretical studies, a decentralized indoor microclimate control system was proposed. Further research is expected to be directed to the tasks of decentralized coordination by non-linear objects and to the expansion of the scope of practical application of decentralized coordination.
Key words: decentralized coordination, multi-zonal objects, principle of close action, local-global criterion
References
D. Blum, Z. Wang, C. Weyandt et al. (2022). Field demonstration and implementation analysis of model predictive control in an office HVAC system. Applied Energy, 318, Elsevier BV, Article ID 119104.
, X. Ge, Q.-L. Han, L. Ding, Y.-L. Wang, and X.-M. Zhang (2020). Dynamic event-triggered distributed coordination control and its applications: a survey of trends and techniques. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 50 (9), 3112–3125,
M. Vasak, A. Banjac, N. Hure, H. Novak, D. Marusic, V. Lesic (2021). Modular hierarchical model predictive control for coordinated and holistic energy management of buildings. IEEE Transactions on Energy Conversion, 36 (4), 2670–2682.
R. Yuan, H. Li (2017). A multidisciplinary coupling relationship coordination algorithm using the hierarchical control methods of complex systems and its application in multidisciplinary design optimization. Advances in MechanicalEngineering, 9 (1), SAGE Publications, Article ID 168781401668522.
S. Shrivastava, B. Subudhi (2020). Comprehensive review on hierarchical control of cyber-physical microgrid system. IET Generation, Transmission & Distribution, 14 (26), 6397–6416.
Y. Zhang, W. Wei (2020). Decentralized coordination control of PV generators, storage battery, hydrogen production unit and fuel cell in islanded DC microgrid. International Journal of Hydrogen Energy, 45 (15), 8243–8256.
P. Yang, Y. Xia, M. Yu, W. Wei, Y. Peng (2018). A decentralized coordination control method for parallel bidirectional power converters in a hybrid AC–DC microgrid. IEEE Transactions on Industrial Electronics, 65 (8), 6217–6228.
Dubovoi, V. M., Yukhymchuk, M. S. (2022). Detsentralizovane koordynatsiine keruvannia rozpodilenymy kiber-fizychnymy systemamy z neperervnymy ob’iektamy [Decentralized coordination control of distributed cyber-physical systems with continuous objects]. Vinnytsia : VNTU, 230.
Yukhymchuk M., Dubovoi V., Kovtun V. (2022). Decentralized Coordination of Temperature Control in Multiarea Premises. Complexity. ID 2588364, 18 pages, https://doi.org/10.1155/2022/2588364.
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