Preliminary and robust design analysis of a solar thermal power block

Science & Engineering Faculty Pub Date : 2016-06-13 DOI:10.1115/GT2016-57172

R. Persky, E. Sauret

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引用次数: 2

Abstract

Australia is endeavouring to expand the mix of power resources, and is investing heavily in the development of renewable generation methods such as concentrated solar thermal power. In these systems, the power block and turbine need to maintain high efficiency under non-ideal conditions away from the design point. Literature shows that there is a clear relationship between the selection of fluids, the design of the operating cycle, the fluctuation in operating conditions and changes in power block performance. It is thus important for innovative power block designs to consider the performance of the system as a whole rather than by component, mainly turbine design, cycle development and economic analysis. However, there are few works that consider the coupling of multidisciplinary design and robust design to turbine-fluid selection and economic analysis for realistic systems. Furthermore, existing methodologies for robust optimisation often do not consider the effects of high-density gas properties on the performance of the power block. It is also critical that a power generation system produces ideal economic outcomes that meet a number of key performance indicators including levelised cost of electricity. Therefore, this paper develops a preliminary multidisciplinary design and robust design applied to turbine-fluid selection and economic analysis of a solar-thermal power block. In this work, an Organic Rankine Cycle using novel working fluids for a solar thermal power system is developed. Integrating robust optimisation into the development of the power block is key to push efficiency further and guarantee power block feasibility when running at non-ideal conditions. A preliminary multidisciplinary optimisation is applied to design the complete power block concept such that the power block operates at peak performance across multiple analysis approaches. When using a multidisciplinary design approach, it is possible to perform robust optimisation on the whole power block where the target is on the economic outcomes rather than traditional targets such as efficiency, specific power generation capacity or size.

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太阳能热发电模块的初步稳健设计分析

澳大利亚正在努力扩大电力资源的组合，并正在大力投资发展可再生发电方法，如集中太阳能热发电。在这些系统中，动力块和涡轮机需要在远离设计点的非理想条件下保持高效率。文献表明，流体的选择、运行周期的设计、运行工况的波动与动力块性能的变化之间存在着明确的关系。因此，对于创新的动力块设计来说，将系统的性能作为一个整体而不是单个部件来考虑是很重要的，主要是涡轮设计、循环开发和经济分析。然而，将多学科设计和鲁棒性设计的耦合考虑到实际系统的涡轮流体选择和经济分析的工作很少。此外，现有的稳健优化方法通常没有考虑高密度气体特性对动力块性能的影响。同样重要的是，发电系统产生理想的经济结果，满足一些关键绩效指标，包括电力成本的平衡。因此，本文对太阳能热发电机组的涡轮流体选择和经济性分析进行了初步的多学科设计和稳健设计。在这项工作中，开发了一个使用新型工质的有机朗肯循环，用于太阳能热发电系统。将稳健的优化集成到动力块的开发中是进一步提高效率和保证动力块在非理想条件下运行可行性的关键。初步的多学科优化应用于设计完整的功率块概念，使功率块在多种分析方法的峰值性能下运行。当使用多学科设计方法时，可以在整个电力块上执行稳健的优化，其中目标是经济结果，而不是传统的目标，如效率，特定发电容量或规模。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Science & Engineering Faculty

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