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Reducing CO2 emissions in the copper smelting process by using high-temperature solar heat: Tecno-economic assessment

Cruz-Robles, Irving ORCID: https://orcid.org/0009-0006-5850-3024, Islas-Samperio, Jorge M., Alonso Romero, Elisa ORCID: https://orcid.org/0000-0001-9676-095X, Vázquez-Vaamonde, Alfonso J., Pérez-Rábago, Carlos A. and Estrada, Claudio A. ORCID: https://orcid.org/0000-0003-2767-3662 (2023). Reducing CO2 emissions in the copper smelting process by using high-temperature solar heat: Tecno-economic assessment. "Applied Thermal Engineering", v. 226 ; pp. 1-21. ISSN 1359-4311. https://doi.org/10.1016/j.applthermaleng.2023.120270.

Descripción

Título: Reducing CO2 emissions in the copper smelting process by using high-temperature solar heat: Tecno-economic assessment
Autor/es:
Tipo de Documento: Artículo
Título de Revista/Publicación: Applied Thermal Engineering
Fecha: 25 Mayo 2023
ISSN: 1359-4311
Volumen: 226
Materias:
ODS:
Palabras Clave Informales: Copper smelting process; Costs; CSP; CSP th Central Tower technology; Impact; Industrial heat process; model; power; separation; TECHNOLOGIES; THERMAL-ENERGY; tower; Carbon Dioxide; CO 2 emission; Copper smelting process; Cost Effectiveness; CSPth Central Tower technology; Energy Utilization; Heat process; Heat storage; High temperature air; Industrial Emissions; Industrial heat process; MATTE GRADE; Smelting process; Solar heating; Solar mining; Thermal Energy; Tower systems; Tower technology
Escuela: E.T.S.I. Industriales (UPM)
Departamento: Ingeniería Energética
Licencias Creative Commons: Ninguna

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Resumen

The work explores the idea of using high-temperature solar heat in the copper smelting process; a Hybrid Central Tower system is analyzed to supply the high-temperature air for this process. The methodology was built based on the equilibrium of the smelting reactions; therefore, this analysis only account for the reactions’ energy demand. Two process schemes (process with/without using high-temperature air) and five off-gas scenarios were evaluated. Using Hybrid Central Tower systems with 13 h of Thermal Energy Storage leads to significant reductions in the annual equivalent energy consumption of the reactions (up to 22.61 %) and in the CO2 emissions of the smelting process (up to 61.4 %). The scheme that doesn't use high-temperature air is the lower-cost option; however, with a 15 % reduction in the capital expenditure and using a discount rate of 5 %, the scheme that uses Hybrid Central Tower systems with 13 h of Thermal Energy Storage shows the similar present value costs. If a carbon price of 25 USD/tCO2e is included, the latter scheme represents the lower-cost option and the most cost-effective solution to avoid CO2 emissions. © 2023

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ID de Registro: 91483
Identificador DC: https://oa.upm.es/91483/
Identificador OAI: oai:oa.upm.es:91483
URL Portal Científico: https://portalcientifico.upm.es/es/ipublic/item/10111045
Identificador DOI: 10.1016/j.applthermaleng.2023.120270
URL Oficial: https://www.sciencedirect.com/science/article/pii/...
Depositado por: iMarina Portal Científico
Depositado el: 16 Oct 2025 10:01
Ultima Modificación: 16 Oct 2025 10:01

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