Numerical simulation of open channel basaltic lava flow through topographical bends

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
Dale R. Cusack , David K. Muchiri , James N. Hewett , Mathieu Sellier , Ben Kennedy , Miguel Moyers-Gonzalez
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Abstract

In this study, we utilised computational fluid dynamics to investigate the behaviour of open-channel basaltic lava flows navigating bends on shield volcanoes. Our focus was on understanding the relationship between flow velocity, rheology, and bend geometry. Employing a simple Force Balance Model (FBM), which considers the equilibrium between hydrostatic pressure and centrifugal force, we accurately approximated the changes in the height of the lava’s free surface through various bend geometries. Our analysis includes examining the influence of channel depth, width, and bend radius on the flow, revealing that variations in these parameters significantly affect the flow’s vertical displacement. Additionally, the bend sector angle emerged as a critical factor, indicating a minimum angle necessary for the flow to fully develop before exiting the bend.
Further, we assessed the applicability of the Shallow Water Equations (SWE) for modelling the inertial displacement of the lava flow in bends, finding a good fit. The study extended to comparing the FBM’s predictions of the tilt angle of the flow’s free surface with the SWE results, showing notable agreement under specific conditions, particularly at a bend angle of 90 degrees. The impact of fluid density was also considered, revealing that density is a contributing factor to the development of the wetted line in the bend, a factor that is not captured by the simple FBM model. Finally, we explored different rheologies akin to natural lava flows, such as viscoplastic flow, and determined that factors like yield stress, consistency index, and power law index have a small impact on the flow behaviour in a steady-state condition within a bend.
明渠玄武岩熔岩流穿越地形弯道的数值模拟
在这项研究中,我们利用计算流体动力学研究了明渠玄武岩熔岩流在盾构火山弯道中的行为。我们的重点是了解流速、流变学和弯道几何形状之间的关系。我们采用简单的力平衡模型(FBM)(该模型考虑了静水压力和离心力之间的平衡),精确地近似分析了熔岩自由表面高度在各种弯曲几何形状下的变化。我们的分析包括研究通道深度、宽度和弯曲半径对熔岩流的影响,结果表明,这些参数的变化会显著影响熔岩流的垂直位移。此外,弯道扇形角也是一个关键因素,它表明了熔岩流在流出弯道之前充分发展所需的最小角度。此外,我们还评估了浅水方程(SWE)在模拟熔岩流在弯道中的惯性位移时的适用性,发现其拟合效果良好。研究还将熔岩流自由表面倾斜角的预测结果与 SWE 结果进行了比较,结果表明在特定条件下,尤其是在弯曲角度为 90 度时,两者的预测结果是一致的。我们还考虑了流体密度的影响,结果表明密度是导致弯道湿润线发展的一个因素,而简单的 FBM 模型并没有捕捉到这一因素。最后,我们探讨了与天然熔岩流类似的不同流变学,如粘塑性流动,并确定屈服应力、稠度指数和幂律指数等因素对弯道内稳态条件下的流动行为影响较小。
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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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
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审稿时长
68 days
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