A generalized prediction model for complete performance investigation of pump operated as turbine in microhydro applications using novel approach for improving sustainability
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引用次数: 0
Abstract
Centrifugal pumps operated in reverse mode (popularly called pump as turbines (PATs)) are well-established as green energy converters, mainly used in microhydro applications due to their lower capital cost. However, the appropriate selection of the pump for reverse-mode application is a critical issue due to the unavailability of its characteristic curve in turbine mode. Therefore, various researchers have proposed models to predict PAT parameters from pump characteristics based on diverse approaches. Still, researchers are striving to develop a prediction model, which can predict the head and flow rates for the PAT with less than ±20 % deviation for both. This work proposed a novel approach to predict the characteristics of PAT with the integration of ensemble regression modelling for Best Efficiency Point (BEP) and from it, by polynomial equations complete characteristics curve. The data from in-house experiments and open literature are used to develop the proposed model excluding the data of four pumps, which are typically used for validation of it. The predicted parameters of PAT from pump characteristics show good agreement for four selected PATs with <10 % maximum deviation. Compared to the literature prediction models, it shows a lower deviation for the same four PATs. A case study based on the field data is carried out to justify the applicability of the proposed model. By using this model selected pump when operated in PAT will produce higher power and generate more revenue compared to literature models, resulting in the economical utilization of resources and improving sustainability. Though the savings are lower, it will be significant for a large number of PAT applications.
以反向模式运行的离心泵(俗称 "泵汽轮机"(PATs))是一种成熟的绿色能源转换器,由于其资本成本较低,主要用于微水电应用。然而,由于无法获得水泵在涡轮模式下的特性曲线,如何为反向模式应用选择合适的水泵是一个关键问题。因此,不同的研究人员根据不同的方法提出了根据泵特性预测 PAT 参数的模型。不过,研究人员仍在努力开发一种预测模型,能够预测 PAT 的扬程和流量,且两者的偏差均小于 ±20%。这项工作提出了一种预测 PAT 特性的新方法,它整合了最佳效率点(BEP)的集合回归模型,并在此基础上通过多项式方程得出完整的特性曲线。内部实验和公开文献中的数据被用于开发拟议模型,但不包括通常用于验证的四台泵的数据。根据泵特性预测的 PAT 参数与所选的四种 PAT 显示出良好的一致性,最大偏差为 10%。与文献预测模型相比,该模型对相同的四种 PAT 的偏差较小。基于现场数据的案例研究证明了所提模型的适用性。与文献模型相比,通过使用该模型,选定的水泵在 PAT 运行时将产生更高的功率和更多的收入,从而实现资源的经济利用并提高可持续性。虽然节省的费用较低,但对于大量的 PAT 应用来说意义重大。
期刊介绍:
Published on behalf of the International Energy Initiative, Energy for Sustainable Development is the journal for decision makers, managers, consultants, policy makers, planners and researchers in both government and non-government organizations. It publishes original research and reviews about energy in developing countries, sustainable development, energy resources, technologies, policies and interactions.