A Supercritical CO2 Brayton Cycle Micro Turbine for Waste Heat Conversion: Optimization Layout in Cogenerative Applications

Volume 6: Ceramics and Ceramic Composites; Coal, Biomass, Hydrogen, and Alternative Fuels; Microturbines, Turbochargers, and Small Turbomachines Pub Date : 2021-06-07 DOI:10.1115/gt2021-59654

F. Reale, Raniero Sannino, R. Tuccillo

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Abstract

Waste heat recovery (WHR) can represent a good solution to increase overall performance of energy systems, even more in case of small systems. The exhaust gas at the outlet of micro gas turbines (MGTs) has still a large amount of thermal energy that can be converted into mechanical energy, because of its satisfactory temperature levels, even though the typical MGT layouts perform a recuperated cycle. In recent studies, supercritical CO2 Brayton Cycle (sCO2 GT) turbines were studied as WHR systems whose thermal source was the exhausts from gas turbines. In particular, subject of this study is the 100 kW MGT Turbec T100. In this paper, the authors analyze innovative layouts, with comparison in terms of performance variations and cogenerative indices. The study was carried out through the adoption of a commercial software, Thermoflex, for the thermodynamic analysis of the layouts. The MGT model was validated in previous papers while the characteristic parameters of the bottoming sCO2 GT were taken from the literature. The combined cycle layouts include simple and recompression sCO2 bottoming cycles and different fuel energy sources like conventional natural gas and syngases derived by biomasses gasification. A further option of bottoming cycle was also considered, namely an organic Rankine cycle (ORC) system for the final conversion of waste heat from sCO2 cycle into additional mechanical energy. Finally, the proposed plants have been compared, and the improvement in terms of flexibility and operating range have been highlighted.

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用于余热转换的超临界CO2布雷顿循环微型汽轮机:热电联产应用中的优化布局

废热回收(WHR)可以代表一个很好的解决方案，以提高能源系统的整体性能，甚至在小型系统的情况下。微型燃气轮机(MGT)出口的废气仍然有大量的热能，可以转化为机械能，因为它的温度水平令人满意，即使典型的MGT布局执行一个回收循环。近年来，超临界CO2布雷顿循环(sCO2 GT)汽轮机作为WHR系统进行了研究，其热源为燃气轮机废气。特别地，本研究的对象是100千瓦MGT Turbec T100。在本文中，作者分析了创新布局，并在性能变化和协同生成指标方面进行了比较。该研究是通过采用商业软件Thermoflex对布局进行热力学分析进行的。MGT模型已在前人的文献中得到验证，而sCO2 GT的底端特征参数则取自文献。联合循环布局包括简单的和再压缩的sCO2底循环，以及不同的燃料能源，如传统天然气和生物质气化产生的合成气。还考虑了底部循环的另一种选择，即有机朗肯循环(ORC)系统，用于将sCO2循环的废热最终转化为额外的机械能。最后，对建议的装置进行了比较，并强调了在灵活性和操作范围方面的改进。

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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Volume 6: Ceramics and Ceramic Composites; Coal, Biomass, Hydrogen, and Alternative Fuels; Microturbines, Turbochargers, and Small Turbomachines

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