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References (30)
-
E. Barbieri, F. Melino, Mirko Morini (2012)
Influence of the thermal energy storage on the profitability of micro-CHP systems for residential building applicationsApplied Energy, 97
-
C. Andraka (2014)
Dish Stirling Advanced Latent Storage Feasibility.Energy Procedia, 49
-
S. Murugan, B. Horák (2016)
A review of micro combined heat and power systems for residential applicationsRenewable & Sustainable Energy Reviews, 64
-
R. Tol (1999)
The Marginal Costs of Greenhouse Gas EmissionsThe Energy Journal, 20
-
A. Carrillo, J. González-Aguilar, M. Romero, J. Coronado (2019)
Solar Energy on Demand: A Review on High Temperature Thermochemical Heat Storage Systems and Materials.Chemical reviews, 119 7
-
Shuang-Ying Wu, Lan Xiao, Yiding Cao, You-Rong Li (2010)
A parabolic dish/AMTEC solar thermal power system and its performance evaluationApplied Energy, 87
-
C. Amy, H. Seyf, M. Steiner, D. Friedman, A. Henry (2018)
Correction: Thermal energy grid storage using multi-junction photovoltaicsEnergy & Environmental Science
-
Alexander Limia, J. Ha, P. Kottke, Andrey Gunawan, A. Fedorov, Seung Lee, S. Yee (2017)
A dual-stage sodium thermal electrochemical converter (Na-TEC)Journal of Power Sources, 371
-
Maryam Maghanki, B. Ghobadian, G. Najafi, R. Galogah (2013)
Micro combined heat and power (MCHP) technologies and applicationsRenewable & Sustainable Energy Reviews, 28
-
G. Notton, V. Lazarov, L. Stoyanov (2010)
Optimal sizing of a grid-connected PV system for various PV module technologies and inclinations, inverter efficiency characteristics and locationsRenewable Energy, 35
-
N. Siegel (2012)
Thermal energy storage for solar power productionWiley Interdisciplinary Reviews: Energy and Environment, 1
-
T. Hunt, N. Weber, T. Cole (1981)
High efficiency thermoelectric conversion with beta″-alumina electrolytes, the sodium heat engineSolid State Ionics, 5
-
M. Abbas, Bousaad Boumeddane, N. Said, A. Chikouche (2011)
Dish Stirling technology: A 100 MW solar power plant using hydrogen for AlgeriaInternational Journal of Hydrogen Energy, 36
-
Alexander Limia, P. Kottke, A. Fedorov, S. Yee (2018)
Thermal modeling and efficiency of a dual-stage sodium heat engineApplied Thermal Engineering
-
Andrey Gunawan, R. Simmons, M. Haynes, Daniel Moreno, Akanksha Menon, M. Hatzell, S. Yee (2019)
Techno-Economics of Cogeneration Approaches for Combined Power and Desalination From Concentrated Solar PowerJournal of Solar Energy Engineering
-
(2016)
Renewable Sustainable Energy Rev -
S. Yee, S. LeBlanc, K. Goodson, C. Dames (2013)
$ per W metrics for thermoelectric power generation: beyond ZTEnergy and Environmental Science, 6
-
B. Brinkworth (1974)
Solar energyNature, 249
-
J. Mondol, Y. Yohanis, Brian Norton (2006)
Optimal sizing of array and inverter for grid-connected photovoltaic systemsSolar Energy, 80
-
S. Martinez, G. Michaux, P. Salagnac, Jean-Louis Bouvier (2017)
Micro-combined heat and power systems (micro-CHP) based on renewable energy sourcesEnergy Conversion and Management, 154
-
T. Cole (1983)
Thermoelectric Energy Conversion with Solid ElectrolytesScience, 221
-
M. Romero, J. González-Aguilar (2014)
Solar thermal CSP technologyWiley Interdisciplinary Reviews: Energy and Environment, 3
-
Caitlin Murphy, Yinong Sun, W. Cole, Galen Maclaurin, M. Mehos, C. Turchi (2019)
The Potential Role of Concentrating Solar Power within the Context of DOE's 2030 Solar Cost Targets -
Jonathan Rea, C. Oshman, Ashutosh Singh, J. Alleman, P. Parilla, C. Hardin, M. Olsen, N. Siegel, D. Ginley, E. Toberer, E. Toberer (2018)
Experimental demonstration of a dispatchable latent heat storage system with aluminum-silicon as a phase change materialApplied Energy
-
Lee Weinstein, J. Loomis, B. Bhatia, D. Bierman, E. Wang, Gang Chen (2015)
Concentrating Solar Power.Chemical reviews, 115 23
-
A. Henry, R. Prasher (2014)
The prospect of high temperature solid state energy conversion to reduce the cost of concentrated solar powerEnergy and Environmental Science, 7
-
Philipp Krüger, Augustin Landier, D. Thesmar (2011)
The WACC Fallacy: The Real Effects of Using a Unique Discount RateHEC Paris: Finance (Topic)
-
Kotaro Tanaka (2008)
Concept design of solar thermal receiver using alkali metal thermal to electric converter (AMTEC)Current Applied Physics, 10
-
C. Andraka (2018)
Sandia - CSP - Dish Technology Assessment. -
Abhishek Singh, Nick AuYeung, K. Randhir, Rishi Mishra, Kyle Allen, J. Petrasch, J. Klausner (2015)
Thermal Reduction of Iron Oxide under Reduced Pressure and Implications on Thermal Conversion Efficiency for Solar Thermochemical Fuel ProductionIndustrial & Engineering Chemistry Research, 54
- Publisher
- Wiley
- Copyright
- © 2020 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim
- eISSN
- 2366-7486
- DOI
- 10.1002/adsu.201900104
- Publisher site
- See Article on Publisher Site
Abstract
A sodium thermal electrochemical converter (Na‐TEC) generates electricity directly from heat through isothermal expansion of sodium ions across a beta″‐alumina solid‐electrolyte. This heat engine has been considered for use with conventional concentrating solar power (CSP) systems before. However, unlike previous single‐stage devices, the improved design uses two stages with an interstage reheat, allowing more economical and efficient conversion up to 29% at a hot side temperature of 850 °C. Herein, a cost‐performance analysis for this improved design assesses opportunities for distributed‐CSP in the context of micro‐combined heat and power systems. A high‐level techno‐economic analysis (TEA) is presented that explores four scenarios where a Na‐TEC is used as the heat engine for a distributed‐CSP system. Overnight capital cost and levelized cost of electricity (LCOE) are estimated for a system lifetime of 30 years, revealing that overnight capital costs in a range from $3.57 to $17.71 per We are feasible, which equate to LCOEs from 6.9 to 17.2 cents kWhe−1. This analysis makes a significant contribution by concurrently quantifying the efficiency and unit costs for a range of multistage configurations, and demonstrating that a Na‐TEC may be a promising alternative to Stirling engines for distributed‐CSP systems at residential scale of 1–5 kWe.
Journal
Advanced Sustainable Systems – Wiley
Published: Jun 1, 2020
Keywords: ; ; ; ;