Near Critical Point Testing and Performance Results of a sCO2 Compressor for a 10MWe Brayton Cycle

Volume 9: Supercritical CO2 Pub Date : 2022-06-13 DOI:10.1115/gt2022-83503

Rob Pelton, Jonathan Bygrave, Karl D. Wygant, Jason C. Wilkes, Thomas Revak, K. Kim

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Abstract

Development and commercial acceptance of sCO2 Brayton cycles for power generation applications are growing rapidly as they offer performance advantages over other cycles. To maximize the cycle performance, the compressors are designed to operate near the critical point of the working fluid. At the critical point the fluid properties change rapidly with variations in inlet conditions. This makes it challenging to both accurately predict the performance and guarantee the operability of the compressor, as the behavior is affected by these slight variations in inlet conditions. A full scale 1st stage main compressor for a 10MWe-Class recompression Brayton cycle was built and tested to validate performance and operability in this unique operating range. The compressor was tested in a laboratory environment with additional instrumentation, beyond what is required by PTC-10, to minimize the uncertainty in the measured performance. Complete constant speed characteristics were collected at multiple supercritical points, operating at constant inlet conditions for each speed line covering a range of compressor inlet densities from 400 to 600 kg/m3. Variations in the compressor stage efficiency and choke margin were observed, and the overall operability and stability of the compressor in response to changes in operating condition were also monitored. The compressor was shown to have excellent performance that closely matched the original design prediction. The performance at various inlet conditions showed minimal change in isentropic head coefficient at the design flow, but did show some variation in efficiency and choke margin across the map. These changes in performance were observed to be minimal, and did not affect the stable operation of the compressor. The results demonstrate that a commercial scale sCO2 compressor can operate near the critical point and achieve the high levels of performance and stability required for power generation applications.

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10MWe布雷顿循环sCO2压缩机近临界点测试及性能结果

用于发电应用的sCO2布雷顿循环的开发和商业接受度正在迅速增长，因为它们比其他循环具有性能优势。为了最大限度地提高循环性能，压缩机被设计成在工作流体的临界点附近运行。在临界点处，流体性质随入口条件的变化而迅速变化。这使得准确预测性能和保证压缩机的可操作性变得具有挑战性，因为压缩机的行为会受到进口条件这些细微变化的影响。为10mwe级Brayton循环再压缩设计了一个全尺寸的一级主压缩机，并对其进行了测试，以验证其在这一独特工作范围内的性能和可操作性。除了PTC-10的要求外，压缩机在实验室环境中使用了额外的仪器进行测试，以尽量减少测量性能的不确定性。在多个超临界点收集了完整的恒速特性，在每个速度线的恒定进口条件下运行，覆盖了从400到600 kg/m3的压缩机进口密度范围。观察了压缩机级效率和节流裕度的变化，并监测了压缩机在运行条件变化下的整体可操作性和稳定性。结果表明，该压缩机具有良好的性能，与最初的设计预测非常吻合。在不同进口条件下的性能表明，在设计流量下等熵水头系数的变化很小，但在整个图中确实显示出效率和节流裕度的一些变化。这些性能变化被观察到是最小的，并且不影响压缩机的稳定运行。结果表明，商业规模的sCO2压缩机可以在临界点附近运行，并达到发电应用所需的高水平性能和稳定性。

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 9: Supercritical CO2

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