Optimal demand response operation of electric boosting glass furnaces

•Develop physics-based model for an electric-boosting glass furnace.•Define demand response (DR) strategy balancing electricity and natural gas.•Optimal DR decisions for two case studies of practical interest are analyzed. The glass industry is highly energy-intensive, accounting for 1% of total ind...

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Bibliographic Details
Published in:Applied energy 2020-07, Vol.269, p.115077, Article 115077
Main Authors: Seo, Kyeongjun, Edgar, Thomas F., Baldea, Michael
Format: Article
Language:English
Subjects:
Demand response
Electric boosting
Glass furnace
Natural gas
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Summary:•Develop physics-based model for an electric-boosting glass furnace.•Define demand response (DR) strategy balancing electricity and natural gas.•Optimal DR decisions for two case studies of practical interest are analyzed. The glass industry is highly energy-intensive, accounting for 1% of total industrial energy consumption in the United States. Most of the energy consumption in the glass manufacturing process is attributable to the significant heat required to melt raw materials. An electric boosting system which can transfer extra heat (5%–20% of total energy) to the glass melt in addition to the energy from natural gas combustion can be implemented in a glass furnace. Electric boosting is thermally efficient, reduces direct pollutant emissions, and prolongs furnace superstructure lifespan. However, a high level of electric boost is not always economically desirable, considering the volatility of electricity prices. Balancing between natural gas and electricity consumption in a demand response strategy can reduce the energy cost and mitigate strain on the electrical grid. In this paper, a physics-based model is developed to describe the dynamic behavior of a prototype electric boosting glass furnace. We present a dynamic optimization strategy to optimally balance between using natural gas and electric power under electricity price fluctuations. Case studies on the effect of varying energy prices and emissions regulations are analyzed.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2020.115077