Packing, compressibility, and crushability of rockfill materials with polydisperse particle size distributions and implications for dam engineering

IF 3.7 Q1 WATER RESOURCES
Chao-min Shen , Si-hong Liu , Liu-jiang Wang , Ji-du Yu , Hao Wei , Ping Wu
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引用次数: 2

Abstract

In rockfill dam engineering, particle breakage of rockfill materials is one of the major factors resulting in dam settlement. In this study, one-dimensional compression tests on a series of coarse granular materials with artificially-graded particle size distributions (PSDs) were carried out. The tests focused on understanding the role of initial PSDs in the dense packing density, compressibility and crushability of coarse granular materials. The effects of fractal dimension (D) and size polydispersity (θ) of PSDs were quantitatively analyzed. Two different loading stages were identified from the logarithms of the stress–strain relationships, with the turning point marked as the yield stress. A similar effect of initial PSDs was observed on the packing density and low-pressure modulus of coarse granular materials. The packing density and low-pressure modulus increased monotonically with θ, and their peak values were attained at a D value of approximately 2.2. However, there was no unique correspondence between the dense packing density and low-pressure modulus. The particle breakage was influenced differently by the initial PSDs, and it decreased with the values of D and θ. The emergence of the unique ultimate state was also identified from both the compression curves and PSDs of the samples after the tests. The potential implications of the test results in the design of both low and high rockfill dams were also demonstrated.

多分散粒径分布的堆石料的堆积性、可压缩性和可破碎性及其对大坝工程的影响
在堆石坝工程中,堆石料颗粒破碎是造成坝体沉降的主要因素之一。在本研究中,对一系列具有人工分级粒度分布(psd)的粗颗粒材料进行了一维压缩试验。试验的重点是了解初始psd对粗颗粒材料的致密堆积密度、可压缩性和可破碎性的作用。定量分析了分形维数(D)和粒径多分散度(θ)对psd的影响。根据应力应变关系的对数,确定了两个不同的加载阶段,并将拐点标记为屈服应力。初始psd对粗颗粒材料的堆积密度和低压模量也有类似的影响。填料密度和低压模量随θ单调增加,在D值约为2.2时达到峰值。然而,致密堆积密度与低压模量之间没有独特的对应关系。初始psd对颗粒破碎的影响不同,随着D和θ的增大而减小。试验后试样的压缩曲线和psd均出现了独特的极限状态。试验结果对高低堆石坝设计的潜在影响也进行了论证。
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来源期刊
CiteScore
6.60
自引率
5.00%
发文量
573
审稿时长
50 weeks
期刊介绍: Water Science and Engineering journal is an international, peer-reviewed research publication covering new concepts, theories, methods, and techniques related to water issues. The journal aims to publish research that helps advance the theoretical and practical understanding of water resources, aquatic environment, aquatic ecology, and water engineering, with emphases placed on the innovation and applicability of science and technology in large-scale hydropower project construction, large river and lake regulation, inter-basin water transfer, hydroelectric energy development, ecological restoration, the development of new materials, and sustainable utilization of water resources.
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