优化 90° 弯曲水平管道中浓浆流动的压降:响应面方法论

IF 2.3 4区 工程技术 Q2 ENGINEERING, MECHANICAL
Ram Krishna, Pankaj Kumar Gupta
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引用次数: 0

摘要

通过管道高效运输矿物和固体材料需要非常复杂的参数和条件。本研究调查了不同流动参数和管道设计元素之间的相关性,以预测弯道压降--一个表明管道直段和弯道可能发生侵蚀的因素。本研究采用响应面方法,在保持最小弯道压降的同时,确定了效果最佳的材料输送条件。研究表明,泥浆浓度、速度、颗粒直径、颗粒浓度和管道直径对弯管压降有显著影响。事实证明,输送速度是影响弯管截面的主要变量,而在水平管道部分,管道直径变得更加重要。本研究论文对控制物料输送的因素进行了深入研究,旨在将水平管道内浓浆流的弯管压降降低 15%。本研究报告了相关成果,包括混合物入口速度、固体体积浓度、粒度、管道直径和弯曲率的正确设计值为 1.787 m/s、8.82、450 μm、466.442 mm 和 1.2 的参数结果。在这些条件下,响应参数弯管压降为 49.7 Pa。这项研究为优化物料输送提供了有价值的见解,通过了解和操纵这些关键参数,可将水平管道内高密度浆料流的弯曲压降降低达 15%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimizing pressure drop in 90° bend horizontal pipelines for dense slurry flow: A response surface methodology approach
Efficient transportation of minerals and solid materials through pipelines requires very complex parameters and conditions. This research investigates the correlations between different flow parameters and pipe design elements to predict bend pressure drop—a factor that indicates the possibility of erosion both in the straight pipeline sections and in the bends. Adopting a response surface methodology approach, this study identifies material conveyance conditions with best results while maintaining minimal bend pressure drop. The research shows the significant influence of slurry concentration, velocity, particle diameter, particle concentration, and pipe diameter on bend pressure drop. The speed of conveyance turns out to be the main variable that affects the bend section, whereas in the horizontal pipe portions, the pipe diameter becomes more important. This research paper gives critical consideration of the factors controlling material conveyance with the aim of reducing bend pressure drop by up to 15% for dense slurry flow inside horizontal pipelines. This study reports the outcomes, including the results of the right design values for the parameters as 1.787 m/s, 8.82, 450 μm, 466.442 mm, and 1.2 for inlet velocity of the mixture, solid volume concentration, particle size, pipe diameter, and bend ratio. The response parameter bend pressure drop was 49.7 Pa at such conditions. This study provides valuable insights into optimizing material conveyance by understanding and manipulating these key parameters to reduce bend pressure drop by up to 15% in dense slurry flow within horizontal pipelines.
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来源期刊
CiteScore
3.80
自引率
16.70%
发文量
370
审稿时长
6 months
期刊介绍: The Journal of Process Mechanical Engineering publishes high-quality, peer-reviewed papers covering a broad area of mechanical engineering activities associated with the design and operation of process equipment.
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