Proximal Sensing of Density During Soil Compaction by Instrumented Roller

IF 0.3 Q4 ENGINEERING, GEOLOGICAL Australian Geomechanics Journal Pub Date : 2022-09-01 DOI:10.56295/agj5739
Amir Tophel, Jeffrey M. Walker, Ye Lu, J. Kodikara
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引用次数: 2

Abstract

The measurement of density or void ratio during the compaction of geomaterials (soils and unbound granular materials) in the field during road construction is essential for superior performance. The specifications adopted by the road authorities worldwide are exclusively based on density. However, estimating density evolution proximally or non-destructively is challenging. Conventional field-based density measurement techniques are hazardous, slow to use and are point-based measurements. This study developed a novel methodology to estimate the density of geomaterials non-destructively in real-time during the compaction process. The methodology included measuring the surface deformation using Light Detection and Ranging (LiDAR) systems attached to rollers and developing physics-based 1-Dimensional and machine learning (ML) based constitutive models to relate the measured parameters to the density. The developed methodology was validated in an indoor environment where a large soil box (dimensions: 7.5 m×4 m×0.8 m) was fabricated and a well-graded sand in 5 layers of 100 mm was compacted using a 1.5-tonne instrumented roller. The measurement of deformation provided an opportunity to estimate the density in real-time. The estimated density using 1-D model and a ML based classification model had an error of 20% and 16% respectively when compared to density measured from Nuclear Density Gauge (NDG). This novel instrumentation allowed the density to be measured during compaction with high accuracy, which presents an unprecedented advantage over other conventional approaches, which are intrusive and pointwise, thereby ensuring that the road will be constructed expediently and will function satisfactorily, minimising the occurrence of premature failures. The continual measurement of density during compaction will also facilitate maintaining uniformity of the density, thereby reducing the potential for excessive differential deformations.
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仪器压路机在土壤压实过程中密度的近端感知
在道路施工过程中,测量地质材料(土壤和未结合的颗粒材料)在现场的压实过程中的密度或空隙率对于取得优异的性能至关重要。世界范围内道路管理部门采用的规范完全基于密度。然而,近端或非破坏性地估计密度演变是具有挑战性的。传统的基于场的密度测量技术是危险的,使用速度慢,并且是基于点的测量。本研究提出了一种新的方法来实时无损地估计压实过程中岩土材料的密度。该方法包括使用连接在滚筒上的光探测和测距(LiDAR)系统测量表面变形,并开发基于物理的一维和基于机器学习(ML)的本构模型,将测量的参数与密度联系起来。开发的方法在室内环境中进行了验证,在室内环境中,制作了一个大型土箱(尺寸:7.5 m×4 m×0.8 m),并使用1.5吨的仪器滚轮压实了5层100 mm的分级良好的砂。变形的测量提供了一个实时估计密度的机会。与核密度计(NDG)测量的密度相比,使用1-D模型和基于ML的分类模型估计的密度分别有20%和16%的误差。这种新型仪器允许在压实过程中以高精度测量密度,这比其他传统方法具有前所未有的优势,这些方法是侵入式和点式的,从而确保道路建设方便,功能令人满意,最大限度地减少过早失效的发生。在压实过程中连续测量密度也将有助于保持密度的均匀性,从而减少过度微分变形的可能性。
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来源期刊
Australian Geomechanics Journal
Australian Geomechanics Journal ENGINEERING, GEOLOGICAL-
CiteScore
0.40
自引率
0.00%
发文量
1
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