The Profile Loss of Additive Manufactured Blades for Organic Rankine Cycle Turbines

IF 1.3 Q2 ENGINEERING, AEROSPACE

International Journal of Turbomachinery, Propulsion and Power Pub Date : 2022-03-21 DOI:10.3390/ijtpp7010011

L. Hake, Felix Reinker, R. Wagner, S. aus der Wiesche, M. Schatz

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引用次数: 3

Abstract

Results from an experimental profile loss study are presented of an additive manufactured linear turbine cascade placed in the test section of a closed-loop organic vapor wind tunnel. This test facility at Muenster University of Applied Sciences allows the investigation of high subsonic and transonic organic vapor flows under ORC turbine flow conditions at elevated pressure and temperature levels. An airfoil from the open literature was chosen for the cascade, and the organic vapor was Novec 649TM. Pitot probes measured the flow field upstream and downstream of the cascade. The inflow turbulence level was 0.5%. The roughness parameters of the metal-printed blades were determined, and the first set of flow measurements was performed. Then, the blade surfaces were further finished, and the impact of roughness on profile losses was assessed in the second flow measurement set. Although the Reynolds number level was relatively high, further surface treatment reduces the profile loss noticeably in organic vapor flows through the printed cascade.

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有机朗肯循环涡轮机添加剂制造叶片的型面损失

将添加制造的线性涡轮叶栅放置在闭环有机蒸汽风洞的试验段中，给出了实验剖面损失研究的结果。明斯特应用科学大学的这一测试设施允许研究ORC涡轮机在高压和高温条件下的高亚音速和跨音速有机蒸汽流。叶栅选用了公开文献中的翼型，有机蒸汽为Novec 649TM。皮托管探头测量了叶栅上游和下游的流场。流入湍流水平为0.5%。确定了金属印刷叶片的粗糙度参数，并进行了第一组流量测量。然后，对叶片表面进行进一步精加工，并在第二组流量测量中评估粗糙度对轮廓损失的影响。尽管雷诺数水平相对较高，但进一步的表面处理显著降低了通过印刷级联的有机蒸汽流中的剖面损失。

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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