降低LCOE的太阳能塔系统温度范围优化

SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems Pub Date : 2019-07-26 DOI:10.1063/1.5117522

R. Buck, S. Giuliano

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引用次数: 11

摘要

新的传热和存储介质为太阳能塔系统提供了更广泛的温度范围。更高的温度允许蒸汽动力循环与提高效率的集成。目前的研究评估了使用固体颗粒作为传热介质(HTM)的模块化太阳能塔式工厂，允许温度高达1000°C。在参数研究中，评价了热媒上下温度对平准化成本的影响。结果表明，热媒温度的选择对热媒温度的选择有显著影响，主要受热媒温差的影响。较高的温差会导致LCOE降低。最重要的因素是降低颗粒库存，存储容器和颗粒蒸汽发生器的成本。这种减少部分被定日镜和塔架成本的增加所抵消。结果表明，利用固体颗粒进行高效蒸汽动力循环具有独特的优势，因为固体颗粒的温度范围很宽。

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Solar tower system temperature range optimization for reduced LCOE

New heat transfer and storage media offer for solar tower systems a much broader temperature range. Higher temperatures allow the integration of steam power cycles with increased efficiency. The present study evaluates modular solar tower plants using solid particles as heat transfer medium (HTM), allowing temperatures up to 1000°C. In a parameter study the influence of upper and lower HTM temperature on levelized cost of electricity (LCOE) is evaluated. The results show a significant impact of the HTM temperature selection, mainly governed by the HTM temperature difference. A high temperature difference results in reduced LCOE. The most important factors for this reduction are the cost decrease of particle inventory, storage containment, and particle steam generator. This decrease is partially offset by an increase in heliostat field and tower cost. The results indicate that the use of solid particles for high efficiency steam power cycles offers unique advantages due to the wide temperature range of the particles.

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SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems

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