Modelling and Experimental Validation of a Controllable Energy Harvester for Pressure Regulation

Y. Ko, Shi M. Yu, A. Bilton
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Abstract

A pico-scale Francis turbine (or energy harvester) was designed, fabricated and tested for pressure regulation and power generation application. The prototype energy harvester contains pivotable guide vanes and a controllable load to change the runner speed. This allows the simultaneous variation of the pressure drop and the output power. A computational fluid dynamics (CFD) model of the turbine was developed in ANSYS CFX 18.1 to evaluate the turbine’s sensitivity to geometric parameters such as the clearance gap size of the guide vane and its modularity. In conjunction to the CFD model, the electric generator’s characteristics were used to predict the turbine performance at varying guide vane angles. The turbine was prototyped and tested using a custom-built experimental set-up. The pico-scale turbine, with a runner diameter of 1.42 inches, was able to output up to 100 W of electrical power at its rated flowrate of 29 GPM. By varying the guide vane angles, the pressure drop and the hydraulic efficiency varied between 3–22 psi and up to 60% respectively. When validated against the experimental results, the CFD model showed a good agreement despite its low computational cost. The energy harvester’s initial characteristics demonstrate its potential as a game changer in the control valve market.
一种用于压力调节的可控能量采集器建模与实验验证
设计、制造并测试了用于压力调节和发电应用的微型混流式涡轮机(或能量采集器)。原型能量收集器包含可旋转的导叶和可控制的负载来改变转轮的速度。这样可以同时改变压降和输出功率。在ANSYS CFX 18.1中建立了涡轮的计算流体动力学(CFD)模型,以评估涡轮对导叶间隙大小及其模块化等几何参数的敏感性。结合CFD模型,利用发电机特性对不同导叶角度下的涡轮性能进行了预测。涡轮机的原型和测试使用定制的实验装置。这台微型涡轮机的转轮直径为1.42英寸,能够以29 GPM的额定流量输出高达100 W的电力。通过改变导叶角度,压降和液压效率分别在3-22 psi和高达60%之间变化。通过与实验结果的对比验证,计算成本较低的CFD模型具有较好的一致性。能量采集器的初始特性表明,它有可能改变控制阀市场的游戏规则。
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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