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Benchmarking thermal energy storage cost for industrial process heat

Author

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  • Wikoff, Hope M.
  • Garfield, David
  • Hwang, Shannon
  • Ribo, Macarena Mendez
  • Ruth, Mark
  • Reese, Samantha B.

Abstract

Process heat accounts for roughly half of industrial energy demand, and currently 95 % of process heat is derived from the combustion of natural gas, oil, and coal. Electrification of industrial heating could be an alternative, potentially expanding locations suitable for manufacturing; however, industrial facility owners may desire energy storage to stabilize energy costs. In this work, the economic benefits of pairing thermal storage with electrified process heat to reduce the average price paid for energy are analyzed. Cost savings focus on energy arbitrage, or leveraging flexible energy pricing schemes, alone. The cost of natural gas combustion across decades (2019–2060) is compared to the costs of electricity and thermal energy storage in four United States Independent System Operator (ISO) regions. Systems installed today may not yield positive net present value (NPV) compared to the use of natural gas. However, using estimated electricity prices, systems installed in 2030 using arbitrage alone could be profitable when compared to natural gas in some regions of the U.S. Furthermore, if capital expenditures could be reduced by 50 % for sensible thermal storage systems by 2030, profitable systems are found across all regions. This implies that electrification of industrial process heat, when paired with inexpensive thermal energy storage systems, could be less expensive than brownfield natural gas systems, using arbitrage as the only source of revenue and without a dependency on any future policy drivers such as pricing externalities that could further incentivize the electrification of industrial process heat.

Suggested Citation

  • Wikoff, Hope M. & Garfield, David & Hwang, Shannon & Ribo, Macarena Mendez & Ruth, Mark & Reese, Samantha B., 2025. "Benchmarking thermal energy storage cost for industrial process heat," Applied Energy, Elsevier, vol. 402(PA).
    • Handle: RePEc:eee:appene:v:402:y:2025:i:pa:s0306261925016034
    DOI: 10.1016/j.apenergy.2025.126873
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    References listed on IDEAS

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    1. Stack, Daniel C. & Curtis, Daniel & Forsberg, Charles, 2019. "Performance of firebrick resistance-heated energy storage for industrial heat applications and round-trip electricity storage," Applied Energy, Elsevier, vol. 242(C), pages 782-796.
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