MinWaterCSP大型冷却系统测试设施中24英尺直径风扇性能的初步评估

Volume 1: Aircraft Engine; Fans and Blowers; Marine; Wind Energy; Scholar Lecture Pub Date : 2021-06-07 DOI:10.1115/gt2021-59130

S. V. D. Spuy, D. Els, L. Tieghi, G. Delibra, A. Corsini, Francois G. Louw, Albert Zapke, C. Meyer

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引用次数: 1

摘要

MinWaterCSP项目的目的是减少聚光太阳能发电厂的冷却系统用水量和辅助电力消耗。随后，在位于Stellenbosch大学的Min WaterCSP冷却系统测试设施中安装了一个直径为24英尺(7.315米)的全尺寸m型风扇模型。测试设备配备了直列扭矩臂和速度传感器，用于测量传递到风扇转子的功率，以及风扇转子上游的一组旋转叶片风速计，用于测量通过风扇的风量流量。将测量结果与在直径1.542 m的ISO 5801测试设备上使用风扇缩放定律获得的结果进行比较。对比表明，风机功率值与小型风机的相关系数在+/ - 7%范围内，但全尺寸风机的叶片设置角高1°。为了与预期的风机静压上升相关，研究人员对直径为24英尺(7.315米)的风机进行了CFD分析。通过CFD分析预测的风机静压上升值与在1.542 m ISO测试设备上测量的结果进行了比较。仿真采用执行器盘模型来表示风机的影响。结果表明，安装的24 ft (7.315 m)直径风机的风机静压上升预测结果与1.542 m直径风机在其设计流量下的预测结果密切相关(差异小于1%)，但同样是在叶片设置角高约1°时。

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Preliminary Evaluation of the 24 Ft. Diameter Fan Performance In the MinWaterCSP Large Cooling Systems Test Facility

The MinWaterCSP project was defined with the aim of reducing the cooling system water consumption and auxiliary power consumption of concentrating solar power (CSP) plants. A full-scale, 24 ft (7.315 m) diameter model of the M-fan was subsequently installed in the Min WaterCSP cooling system test facility, located at Stellenbosch University. The test facility was equipped with an in-line torque arm and speed transducer to measure the power transferred to the fan rotor, as well as a set of rotating vane anemometers upstream of the fan rotor to measure the air volume flow rate passing through the fan. The measured results were compared to those obtained on the 1.542 m diameter ISO 5801 test facility using the fan scaling laws. The comparison showed that the fan power values correlated within +/− 7% to those of the small-scale fan, but at a 1° higher blade setting angle for the full-scale fan. To correlate the expected fan static pressure rise, a CFD analysis of the 24 ft (7.315 m) diameter fan installation was performed. The predicted fan static pressure rise values from the CFD analysis were compared to those measured on the 1.542 m ISO test facility, for the same fan. The simulation made use of an actuator disc model to represent the effect of the fan. The results showed that the predicted results for fan static pressure rise of the installed 24 ft (7.315 m) diameter fan correlated closely (smaller than 1% difference) to those of the 1.542 m diameter fan at its design flowrate but, once again, at approximately 1° higher blade setting angle.

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Volume 1: Aircraft Engine; Fans and Blowers; Marine; Wind Energy; Scholar Lecture

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