盘式开槽脉冲水射流流场结构及硬岩侵蚀势的数值模拟与分析

Q3 Physics and Astronomy
Zhaohui Lu, Yiyu Lu, M. Hood, Pan Linhua, Pei He
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引用次数: 5

摘要

由于水锤压力、超高速横向喷射和脉冲动载荷等特殊的加载方式,圆盘缝脉冲水射流是一种有潜力的破岩工具。针对射流流场的研究,基于流体体积(VOF)模型和动态网格理论,建立了与间断水射流产生装置的几何形状和运动相匹配的两相流瞬态计算模型,模拟了100 mm间隙内单次脉动的动态演变和特性。结果表明,在脉冲射流的头部形成偏转的段塞结构,这与高速摄影实验结果一致。段塞头速度低于射流出口速度,射流湍流主要分布在射流与空气的边界层和偏转侧。在脉冲形成过程中产生了瓦片状的立体结构。冲击目标时呈现非轴对称流型,与硬岩破碎实验得到的不规则冲蚀空腔相一致。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical simulation and analysis on the flow field structure and hard rock erosion potential of a disc-slotted pulse water jet
A disc-slotted pulse water jet is a potential tool to break hard rock due to its special loading styles, such as the water hammer pressure, ultra-speed lateral jetting and pulse dynamic load etc. Aiming at investigating the flow filed of the jet, a two-phase-flow transient computational model, matching with the geometry and motion of the interrupted water jet generating device, was established to simulate the dynamic evolution and characteristics of a single pulsation within 100 mm standoff based on the volume of fluid (VOF) model and dynamic mesh theory. The results show that at the head of the pulsed jet forms a deflective slug structure which is consistent with the result from high-speed photography experiments. The slug head velocity is lower than that at the jet outlet and the jet turbulence is mainly distributed over boundary layers between jet and air and at the deflective side. Tile-shaped stereo-structure is yielded during the pulse formation process. It presents non-axisymmetric flow pattern when impacting target, which consists with the irregular erosion cavity obtained by hard rock fragmentation experiments.
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来源期刊
振动与冲击
振动与冲击 Physics and Astronomy-Acoustics and Ultrasonics
CiteScore
1.60
自引率
0.00%
发文量
14597
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