Analysis of Solar-Thermal Power Plants With Thermal Energy Storage and Solar-Hybrid Operation Strategy-Reference-Cited by-同舟云学术

Analysis of Solar-Thermal Power Plants With Thermal Energy Storage and Solar-Hybrid Operation Strategy

Published:2011-07-25 Issue:3 Volume:133 Page:
ISSN:0199-6231
Container-title:Journal of Solar Energy Engineering
language:en
Short-container-title:

Author:

Giuliano Stefano,Buck Reiner¹,Eguiguren Santiago²

Affiliation:

1. German Aerospace Centre (DLR), Institute of Technical Thermodynamics, Pfaffenwaldring 38-40, 70569 Stuttgart, Germany

2. Siemens AG, Energy Sector, Renewable Energy Division, E R STE, Hugo-Junkers-Str. 15-17, 90411 Nuremberg, Germany

Abstract

Selected solar-hybrid power plants for operation in base-load as well as midload were analyzed regarding supply security (dispatchable power due to hybridization with fossil fuel) and low CO2 emissions (due to integration of thermal energy storage). The power plants were modeled with different sizes of solar fields and different storage capacities and analyzed on an annual basis. The results were compared to each other and to a conventional fossil-fired combined cycle in terms of technical, economical, and ecological figures. The results of this study show that in comparison to a conventional fossil-fired combined cycle, the potential to reduce the CO2 emissions is high for solar-thermal power plants operated in base-load, especially with large solar fields and high storage capacities. However, for dispatchable power generation and supply security it is obvious that in any case a certain amount of additional fossil fuel is required. No analyzed solar-hybrid power plant shows at the same time advantages in terms of low CO2 emissions and low levelized electricity cost (LEC). While power plants with solar-hybrid combined cycle (SHCC®, Particle-Tower) show interesting LEC, the power plants with steam turbine (Salt-Tower, Parabolic Trough, CO2-Tower) have low CO2 emissions.

Publisher

ASME International

Subject

Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment

Link

http://asmedigitalcollection.asme.org/solarenergyengineering/article-pdf/doi/10.1115/1.4004246/5595474/031007_1.pdf

Reference9 articles.

1. Design and Operational Aspects of Gas and Steam Turbines for the Novel Solar Hybrid Combined Cycle SHCC®;Heide

2. Sugarmen, C., Tellez, F., Buck, R., Medina, J. R., Altwegg, P., Ring, A., 2005, “SOLGATE: Solar Hybrid Gas Turbine Electric Power System,” Final Report, European Commission, Brussels, EUR 21615; http:\\ec.europa.eu/research/energy/pdf/solgate_en.pdf.

3. Zavoico, A. B., 2001, “Solar Power Tower - Design Basis Document, Revision 0,” Sandia National Laboratories, Albuquerque, NM, SAND2001-2100.

4. Marquardt, R., Hoffmann, S., Pazzi, S., Klafki, M., and Zunft, S., 2008, “AA-CAES - Opportunities and Challenges of Advanced Adiabatic Compressed Air Energy Storage Technology as a Balancing Tool in Interconnected Grids,” Dresden ed., 40 Kraftwerkstechnisches Kolloquium, Technische Universität, Oct. 14–15, Vol. 2.

5. Schwarzbözl, P., Schmitz, M., and Pitz-Paal, R., 2009, “Visual hflcal – A Software Tool for Layout and Optimization of Heliostat Fields,” 15 International SolarPACES Symposium, Berlin.

Cited by 43 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Accumulating Thermal Energy and Conversion into Electrical Energy;2023 15th Electrical Engineering Faculty Conference (BulEF);2023-09-16

2. Study on the Periodic Collapse of Suspended Sandstone Interlayer under Coupled Thermo–Hydro–Mechanical Environment;International Journal of Geomechanics;2023-08

3. Performance optimization of solar‐powered heat engine using a multiobjective accelerated algorithm;Heat Transfer;2023-06-14

4. High-Efficiency Power Cycles for Particle-Based Concentrating Solar Power Plants: Thermodynamic Optimization and Critical Comparison;Energies;2022-11-16

5. Classification of solar receivers;Solar Receivers for Thermal Power Generation;2022