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access icon openaccess Industrial multi-energy and production management scheme in cyber-physical environments: a case study in a battery manufacturing plant

This is an open access article published by the IET under the Creative Commons Attribution -NonCommercial License (http://creativecommons.org/licenses/by-nc/3.0/)
Received 28/02/2018, Accepted 27/09/2018, Revised 22/06/2018, Published 03/10/2018

Among the various electricity consumer sectors, the consumption level of the industrial sector is often considered as the largest portion of electricity consumption, highlighting the urgent need to implement demand response (DR) energy management. However, implementation of DR for the industrial sector requires a more sophisticated and different scheme compared to the residential and commercial sector. This study explores all the elastic segments of plant multi-energy production, conversion, and consumption. We then construct a real-time industrial facilities management problem as an optimal dispatch model to enclose these elastic segments and production constraints in cyber-physical environments. Moreover, a model predictive-based centralised dispatch scheme is proposed to address the uncertainties of real-time price and renewable energy forecasting while considering the sequence of the production process. Numerical results demonstrate that the proposed scheme can enhance energy efficiency and economics of lithium battery manufacturing plant through responding to the real-time price whilst ensuring the completion of production tasks.

Inspec keywords: renewable energy sources; power generation dispatch; pricing; production management; energy conservation; energy management systems; power consumption

Other keywords: cyber-physical environments; production management scheme; electricity consumption; production tasks; sophisticated scheme; case study; lithium battery manufacturing plant; renewable energy forecasting; energy efficiency; consumption level; residential sector; real-time price; largest portion; electricity consumer sectors; industrial sector; real-time industrial facilities management problem; demand response energy management; industrial multienergy; centralised dispatch scheme; commercial sector; production constraints; different scheme; optimal dispatch model; plant multienergy production; production process; elastic segments

Subjects: Other topics in statistics; Power system management, operation and economics; Optimisation techniques

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