论文信息 - Advances in solar tower technology

Advances in solar tower technology

This article begins with a short introduction and continues with a presentation of solar tower power plants around the world. The focus is set on the developments of the last five years and in the near future of the most important components of a central receiver system (CRS). For each of the components, a description of each technology, its applicability, and the advantages and disadvantages is presented. The chapter also includes a state of the art review for almost each system and points out the Research and Development (R&D) needs. A further issue is the choice of the heat-transfer fluid (HTF) as well as the improvement of new solar tower power plant cycle systems. The paper introduces recent R&D activities, with the majority occurring in Europe and the United States, as has been presented in international journals and conferences by scientific personnel. It also reflects opinions of experts who specialized in the planning and erection of solar power plants and carrying out CRS research projects. The future effort of R&D in these fields should improve efficiencies, increase durability and reliability, and reduce investment and Operation & Maintenance (O&M) costs. Nowadays, and in this decade, the most advances in CRS occur in the United States, in Europe, and in China. Furthermore, a great interest, especially for add-ons to existing research platforms as well as the construction of new ones, can be observed for the last years for countries in the Middle East & North Africa region, such as Morocco as well as India, Australia, and South Africa. WIREs Energy Environ 2017, 6:e217. doi: 10.1002/wene.217 For further resources related to this article, please visit the WIREs website.

Bernhard Hoffschmidt | Spiros Alexopoulos | S. Alexopoulos | B. Hoffschmidt

[1] Ricardo Chacartegui,et al. Alternative cycles based on carbon dioxide for central receiver solar power plants , 2011 .

[2] Bernhard Hoffschmidt,et al. 3.18 – Concentrating Solar Power , 2012 .

[3] Antonio L. Avila-Marin,et al. Volumetric receivers in Solar Thermal Power Plants with Central Receiver System technology: A review , 2011 .

[4] Bernhard Hoffschmidt,et al. Concentrating Receiver Systems (Solar Power Tower) , 2021, Encyclopedia of Sustainability Science and Technology.

[5] Robert Pitz-Paal,et al. Solarthermische Kraftwerke-Schlüsselbausteine für die DESERTEC-Pläne , 2011 .

[6] Steve Schell,et al. Design and evaluation of esolar's heliostat fields , 2011 .

[7] Abdallah Khellaf,et al. A review of studies on central receiver solar thermal power plants , 2013 .

[8] Reiner Buck,et al. Analysis Of Solar Thermal Power Plants With Thermal Energy Storage And Solar-Hybrid Operation Strategy , 2011 .

[9] Yitung Chen,et al. Review of study on solid particle solar receivers , 2010 .

[10] Peter Schwarzbözl,et al. Biomass and central receiver system (CRS) hybridization: Volumetric air CRS and integration of a biomass waste direct burning boiler on steam cycle☆ , 2012 .

[11] Anton Meier,et al. A predictive CFD model for a falling particle receiver/reactor exposed to concentrated sunlight , 1999 .

[12] Bernhard Hoffschmidt,et al. Simulation of Hybrid Solar Tower Power Plants , 2011 .