Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage

Nathan P. Siegel; Jonathan E. Rea; Christopher J. Oshman; Michele L. Olsen; Corey L. Hardin; Greg C. Glatzmaier; Philip A. Parilla; David S. Ginley; Eric S. Toberer

doi:10.1016/j.apenergy.2018.02.067

Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage

Nathan P. Siegel, Jonathan E. Rea, Christopher J. Oshman, Michele L. Olsen, Corey L. Hardin, Greg C. Glatzmaier, Philip A. Parilla, David S. Ginley, Eric S. Toberer

Bucknell University

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper, we present performance simulations and techno-economic analysis of a modular dispatchable solar power tower. Using a heliostat field and power block three orders of magnitude smaller than conventional solar power towers, our unique configuration locates thermal storage and a power block directly on a tower receiver. To make the system dispatchable, a valved thermosyphon controls heat flow from a latent heat thermal storage tank to a Stirling engine. The modular design results in minimal balance of system costs and enables high deployment rates with a rapid realization of economies of scale. In this new analysis, we combine performance simulations with techno-economic analysis to evaluate levelized cost of electricity, and find that the system has potential for cost-competitiveness with natural gas peaking plants and alternative dispatchable renewables.

Original language	American English
Journal	Default journal
Volume	217
DOIs	https://doi.org/10.1016/j.apenergy.2018.02.067
State	Published - Jan 1 2018

Keywords

Solar
Tower
Storage
Aluminum

Disciplines

Energy Systems

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10.1016/j.apenergy.2018.02.067License: CC BY

https://doi.org/10.1016/j.apenergy.2018.02.067

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title = "Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage",

abstract = " In this paper, we present performance simulations and techno-economic analysis of a modular dispatchable solar power tower. Using a heliostat field and power block three orders of magnitude smaller than conventional solar power towers, our unique configuration locates thermal storage and a power block directly on a tower receiver. To make the system dispatchable, a valved thermosyphon controls heat flow from a latent heat thermal storage tank to a Stirling engine. The modular design results in minimal balance of system costs and enables high deployment rates with a rapid realization of economies of scale. In this new analysis, we combine performance simulations with techno-economic analysis to evaluate levelized cost of electricity, and find that the system has potential for cost-competitiveness with natural gas peaking plants and alternative dispatchable renewables.",

keywords = "Solar, Tower, Storage, Aluminum",

author = "Siegel, \{Nathan P.\} and Rea, \{Jonathan E.\} and Oshman, \{Christopher J.\} and Olsen, \{Michele L.\} and Hardin, \{Corey L.\} and Glatzmaier, \{Greg C.\} and Parilla, \{Philip A.\} and Ginley, \{David S.\} and Toberer, \{Eric S.\}",

note = "Rea, Jonathan E., Christopher J. Oshman, Michele L. Olsen, Corey L. Hardin, Greg C. Glatzmaier, Nathan P. Siegel, Philip A. Parilla, David S. Ginley, and Eric S. Toberer. {"}Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage.{"} Applied energy 217 (2018): 143-152.",

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doi = "10.1016/j.apenergy.2018.02.067",

language = "American English",

volume = "217",

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TY - JOUR

T1 - Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage

AU - Siegel, Nathan P.

AU - Rea, Jonathan E.

AU - Oshman, Christopher J.

AU - Olsen, Michele L.

AU - Hardin, Corey L.

AU - Glatzmaier, Greg C.

AU - Parilla, Philip A.

AU - Ginley, David S.

AU - Toberer, Eric S.

N1 - Rea, Jonathan E., Christopher J. Oshman, Michele L. Olsen, Corey L. Hardin, Greg C. Glatzmaier, Nathan P. Siegel, Philip A. Parilla, David S. Ginley, and Eric S. Toberer. "Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage." Applied energy 217 (2018): 143-152.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - In this paper, we present performance simulations and techno-economic analysis of a modular dispatchable solar power tower. Using a heliostat field and power block three orders of magnitude smaller than conventional solar power towers, our unique configuration locates thermal storage and a power block directly on a tower receiver. To make the system dispatchable, a valved thermosyphon controls heat flow from a latent heat thermal storage tank to a Stirling engine. The modular design results in minimal balance of system costs and enables high deployment rates with a rapid realization of economies of scale. In this new analysis, we combine performance simulations with techno-economic analysis to evaluate levelized cost of electricity, and find that the system has potential for cost-competitiveness with natural gas peaking plants and alternative dispatchable renewables.

AB - In this paper, we present performance simulations and techno-economic analysis of a modular dispatchable solar power tower. Using a heliostat field and power block three orders of magnitude smaller than conventional solar power towers, our unique configuration locates thermal storage and a power block directly on a tower receiver. To make the system dispatchable, a valved thermosyphon controls heat flow from a latent heat thermal storage tank to a Stirling engine. The modular design results in minimal balance of system costs and enables high deployment rates with a rapid realization of economies of scale. In this new analysis, we combine performance simulations with techno-economic analysis to evaluate levelized cost of electricity, and find that the system has potential for cost-competitiveness with natural gas peaking plants and alternative dispatchable renewables.

KW - Solar

KW - Tower

KW - Storage

KW - Aluminum

UR - https://digitalcommons.bucknell.edu/fac_journ/1555

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M3 - Article

VL - 217

JO - Default journal

JF - Default journal

ER -

Performance modeling and techno-economic analysis of a modular concentrated solar power tower with latent heat storage

Abstract

Keywords

Disciplines

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