Prediction of ultimate compressive strength for biopolymer-bound soil composites (BSC) using sliding wingtip crack analysis

Roedel Henning; Rosa Isamar; Allende Maria I; Lepech Michael D.; Loftus David J.; Garboczi Edward J.

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Prediction of ultimate compressive strength for biopolymer-bound soil composites (BSC) using sliding wingtip crack analysis

机译：使用滑动翼尖裂纹分析预测生物聚合物结合土复合材料（BSC）的最终抗压强度

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This paper introduces a damage-based model for determining the compressive strength of Biopolymer-bound Soil Composites (BSC), a novel class of bio-based construction composites that are produced through the mixture and desiccation of biopolymers with inorganic aggregates. A damage-based sliding wingtip crack model is used, in conjunction with experimental results from mechanical testing and X-ray micro-computed tomography image analysis, to predict the response of BSC materials under uniaxial compression. The model explores a range of mixture designs with varying biopolymer solution content. This methodology extends existing mixture design theory for BSC materials based on maximum bulk density of the soil phase.

机译：本文介绍了一种基于损伤的模型，用于确定生物聚合物结合土复合材料（BSC）的抗压强度，一种新型的生物基构造复合材料，其通过混合物和具有无机聚集体的生物聚合物的干燥产生。使用基于损坏的滑动翼尖裂纹模型，与机械测试和X射线微型计算机断层摄影图像分析结合使用实验结果，预测单轴压缩下BSC材料的响应。该模型探讨了一系列具有不同生物聚合物溶液含量的混合物设计。该方法基于土壤阶段的最大堆积密度扩展了BSC材料的现有混合设计理论。

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来源
《Engineering Fracture Mechanics》 |2019年第2019期|共12页
作者
Roedel Henning; Rosa Isamar; Allende Maria I; Lepech Michael D.; Loftus David J.; Garboczi Edward J.;
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作者单位

Stanford Univ Dept Civil &

Environm Engn Stanford CA 94305 USA;

Stanford Univ Dept Civil &

Environm Engn Stanford CA 94305 USA;

Stanford Univ Dept Civil &

Environm Engn Stanford CA 94305 USA;

Stanford Univ Dept Civil &

Environm Engn Stanford CA 94305 USA;

NASA Div Space Biosci Ames Res Ctr Mountain View CA USA;

NIST Appl Chem &

Mat Div Mat Measurement Lab Boulder CO USA;

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原文格式 PDF
正文语种 eng
中图分类工程力学;
关键词
Biomaterial; Biopolymer; Composite; Soil; Micro-computed tomography; Image segmentation; Wingtip crack;

机译：生物材料;生物聚合物;复合;土壤;微计算断层扫描;图像分割;翼尖裂缝;

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专利

1. Prediction of ultimate compressive strength for biopolymer-bound soil composites (BSC) using sliding wingtip crack analysis [J] . Roedel Henning, Rosa Isamar, Allende Maria I, Engineering Fracture Mechanics . 2019,第期

机译：使用滑动翼尖裂纹分析预测生物聚合物结合土复合材料（BSC）的最终抗压强度
2. Reliability analysis of ultimate compressive strength for stiffened composite panels [J] . Zhao Weitao, Liu Weihua, Yang Qijiao Journal of Reinforced Plastics and Composites . 2016,第11期

机译：加筋复合板极限抗压强度的可靠性分析
3. Prediction of cracking, yield and ultimate strengths based on the concrete three-phase micromechanics model [J] . Li Dongqi, Li Zongli, Yin Yueming, Construction and Building Materials . 2018,第DECa30期

机译：基于混凝土三相微力学模型的开裂，屈服和极限强度预测
4. Prediction of Ultimate Tensile Strength of Unidirectional Composites based on in-situ Fiber Strength Measurement [C] . Fang Ming ZHAO, Nobuo TAKEDA China-Japan conference on composites . 1999

机译：基于原位纤维强度测量的单向复合材料极限拉伸强度预测
5. Crack interactions and strength predictions in fibrous metal matrix composites. [D] . Zarzour, Joseph F. 1991

机译：纤维状金属基复合材料的裂纹相互作用和强度预测。
6. Flexural Strength Prediction Models for Soil–Cement from Unconfined Compressive Strength at Seven Days [O] . Alaitz Linares-Unamunzaga, Heriberto Pérez-Acebo, Marta Rojo, 2019

机译：基于7天无侧限抗压强度的水泥土抗弯强度预测模型
7. Effective Coefficient of Initial Deflection for Simple Prediction Method of Compressive Ultimate Strength of Rectangular Plate(Mechanics, Strength Structural Design) [O] . UEDA Yukio, NAKACHO Keiji, MORIYAMA Shuji 2013

机译：矩形板压缩极限强度简单预测方法的有效初始挠度系数（力学，强度和结构设计）

Prediction of ultimate compressive strength for biopolymer-bound soil composites (BSC) using sliding wingtip crack analysis

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