Optimization of the Energy Monitoring System for Continuous-Process Industrial Enterprises
https://doi.org/10.56225/ijgoia.v3i3.432
Keywords:
Energy Monitoring Systems, Continuous-Process Industries, Digital Twin Integration, Industrial Energy EfficiencyAbstract
In the context of growing demand for efficiency, resilience, and sustainability in industrial energy usage, optimizing monitoring systems has become a critical priority. This paper develops and tests a data-driven approach to enhance energy monitoring in continuous-process industries, with a case study of a large-scale water supply enterprise in the Khorezm region of Uzbekistan. The proposed methodology integrates statistical distribution analysis, correlation mapping, and logical process modeling to capture both quantitative relationships and the physical dynamics of operations. Unlike traditional systems that rely on isolated parameters or manual interpretation, the new model embeds process logic into digital platforms, thereby reducing human dependency, minimizing error, and improving response time. The results demonstrate that the modular framework enables more accurate identification of key parameter interdependencies, supports predictive forecasting of energy consumption, and allows for real-time adjustment through ensemble machine learning submodules. In the water supply case, the system successfully differentiated between operational and idle energy usage, optimized pump loads, and provided early detection of anomalies. These improvements translate into enhanced energy efficiency, reduced operational costs, and greater reliability of supply. The study concludes that integrating physical process logic with statistical modeling not only improves monitoring accuracy but also supports the deployment of digital twins and adaptive control systems aligned with Industry 4.0. Policy implications highlight the potential for broader adoption of such models across industrial sectors, particularly in contexts where energy sustainability and infrastructure resilience are national priorities. This approach offers a scalable pathway toward smarter, more sustainable industrial energy management.
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References
Alarcón, M., Martínez-García, F. M., & de León Hijes, F. C. G. (2021). Energy and maintenance management systems in the context of industry 4.0. Implementation in a real case. Renewable and Sustainable Energy Reviews, 142, 110841.
Bao, J., Guo, D., Li, J., & Zhang, J. (2019). The modelling and operations for the digital twin in the context of manufacturing. Enterprise Information Systems, 13(4), 534–556.
Embergenov, A. (2023). Enhancing enterprise energy management with iot-based monitoring systems. Eurasian Science Review An International Peer-Reviewed Multidisciplinary Journal, 1(1), 1–7. https://doi.org/10.63034/esr-16
Herce, C., Biele, E., Martini, C., Salvio, M., & Toro, C. (2021). Impact of energy monitoring and management systems on the implementation and planning of energy performance improved actions: An empirical analysis based on energy audits in Italy. Energies, 14(16), 4723.
Jiang, H., Qin, S., Fu, J., Zhang, J., & Ding, G. (2021). How to model and implement connections between physical and virtual models for digital twin application. Journal of Manufacturing Systems, 58, 36–51.
Kampelis, N., Papayiannis, G. I., Kolokotsa, D., Galanis, G. N., Isidori, D., Cristalli, C., & Yannacopoulos, A. N. (2020). An Integrated Energy Simulation Model for Buildings. Energies, 13(5), 11–70. https://doi.org/10.3390/en13051170
Madakam, S., Ramaswamy, R., & Tripathi, S. (2015). Internet of Things (IoT): A Literature Review. Journal of Computer and Communications, 03(05), 164–173. https://doi.org/10.4236/jcc.2015.35021
Meng, Y., Yang, Y., Chung, H., Lee, P.-H., & Shao, C. (2018). Enhancing sustainability and energy efficiency in smart factories: A review. Sustainability, 10(12), 4779.
Moreira, D. M., Ferreira, V., Resende, P. R., & Pinho, C. (2020). Determination of kinetic data through the fluidized bed combustion of chars made from vine and kiwi pruning wastes. Energy Reports, 6(9), 615–619. https://doi.org/10.1016/j.egyr.2019.09.035
Nota, G., Nota, F. D., Peluso, D., & Toro Lazo, A. (2020). Energy efficiency in Industry 4.0: The case of batch production processes. Sustainability, 12(16), 6631.
Prashar, A. (2019). Towards sustainable development in industrial small and Medium-sized Enterprises: An energy sustainability approach. Journal of Cleaner Production, 235, 977–996.
Rasheed, A., San, O., & Kvamsdal, T. (2020). Digital twin: Values, challenges and enablers from a modeling perspective. IEEE Access, 8, 21980–22012.
Rogge, M., van der Hurk, E., Larsen, A., & Sauer, D. U. (2018). Electric bus fleet size and mix problem with optimization of charging infrastructure. Applied Energy, 211(11), 282–295. https://doi.org/10.1016/j.apenergy.2017.11.051
Stary, C., Elstermann, M., Fleischmann, A., & Schmidt, W. (2022). Behavior-centered digital-twin design for dynamic cyber-physical system development. Complex Systems Informatics and Modeling Quarterly, 30, 31–52.
Tian, W., Han, X., Zuo, W., & Sohn, M. D. (2018). Building energy simulation coupled with CFD for indoor environment: A critical review and recent applications. Energy and Buildings, 165(1), 184–199. https://doi.org/10.1016/j.enbuild.2018.01.046
Van de Graaf, T. (2014). International Energy Agency. In Handbook of Governance and Security. Edward Elgar Publishing. https://doi.org/10.4337/9781781953174.00038
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