Dry granular flow in a vane shear cell: flow characteristics and rheological laws

IF 4.2 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL
Mohsen Kamali Zarch, Limin Zhang, S. Mohsen Haeri, Zhengdan Xu
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引用次数: 0

Abstract

The flow dynamics of dry granular flows is significantly affected by a prominent feature of a granular mass known as dilatancy. Although their rheological behaviour has been characterised via friction and dynamic dilatancy laws, the role of dilatancy in a granular flow has not been much appreciated. In this study, using a vane rheometer, an experimental investigation was conducted on uniform glass beads of (d = 3 mm) at different initial relative densities (15 ≤ D r ≤ 66%) and shear rates that span over four orders of magnitude. The flow characteristics in terms of effective friction, volume change, and velocity field were obtained and evaluated. The effective friction shows a descending-ascending pattern corresponding to a transitional behaviour from a velocity-weakening solid-like to a velocity-strengthening liquid-like behaviour. The volume-change measurements show that all specimens dilate and reach almost the same density at each shear rate. The velocity field follows a Gaussian pattern characterized by the slipping velocity at the boundary, the interlayer slippage between particles, and the interlayer disorder of the particles. A new non-monotonic friction law and a dynamic dilatancy law are presented as governing rheological laws based on the inertial number and by introducing an effective dilation coefficient. This effective dilation coefficient successfully captures the role of dilation-induced secondary vortex flows in the dry granular flows.
叶片式剪切箱中的干粒状流:流动特性和流变规律
干粒状流的流动动力学受到粒状体的一个显著特征的显著影响,即膨胀。虽然它们的流变行为已经通过摩擦和动态剪胀定律来表征,但剪胀在颗粒流动中的作用还没有得到很好的认识。在本研究中,使用叶片流变仪对不同初始相对密度(15≤d r≤66%)和剪切速率跨度超过四个数量级的均匀玻璃微珠(d = 3mm)进行了实验研究。得到了有效摩擦、体积变化和速度场的流动特性,并对其进行了评价。有效摩擦呈下降-上升模式,对应于从速度减弱的类固体到速度增强的类液体的过渡行为。体积变化测量表明,在每一种剪切速率下,所有试样都发生了膨胀,并达到了几乎相同的密度。速度场服从高斯模式,其特征是边界处的滑动速度、粒子间的层间滑移和粒子间的层间无序。在惯性数的基础上,引入有效膨胀系数,提出了新的非单调摩擦定律和动态膨胀定律作为控制流变的定律。这一有效膨胀系数成功地反映了膨胀诱导的二次涡在干颗粒流中的作用。
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
Geotechnique
Geotechnique 工程技术-地球科学综合
CiteScore
9.80
自引率
10.30%
发文量
168
审稿时长
7 months
期刊介绍: Established in 1948, Géotechnique is the world''s premier geotechnics journal, publishing research of the highest quality on all aspects of geotechnical engineering. Géotechnique provides access to rigorously refereed, current, innovative and authoritative research and practical papers, across the fields of soil and rock mechanics, engineering geology and environmental geotechnics.
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