基于CT探测技术的不良地质构造三维网格模型重构方法

doi:10.13722/j.cnki.jrme.2018.1232

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摘要不良地质条件下的岩土体稳定性在地下空间工程中引起了广泛关注。针对不良地质条件下的岩土体稳定性，为建立可靠的分析模型对其进行分析与预测，提出基于CT探测技术的不良地质构造三维网格模型重构方法。该方法通过进行弹性波CT仿真并进行区块化Kriging插值获得弹性波速度构造三维可视化模型，利用峰值法进行材料阈值分割，同时利用三维网格构建和材料属性映射，形成目标区域的三维网格模型。结果表明：通过对重构的三维网格模型与初始模型进行对比分析，重构模型的仿真度高达91.44%，体积分数的绝对误差为3.33%；在此基础上，针对桥梁基础落位区开展弹性波CT探测现场试验，重构该区域三维网格模型并进行取芯验证，其仿真度大于84.31%，体积分数的绝对误差小于2.45%。该方法具有较高的建模精度，能够精确地反映不良地质体的空间分布状态，对评价不良地质稳定性具有重要科学意义。

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	王启明
	车爱兰

关键词 ：岩土工程, 不良地质, 弹性波CT, 三维网格模型, 重构方法, 仿真度

Abstract：The stability of rock and soil under unfavorable geological conditions has attracted wide attention in underground space engineering. A 3D mesh model reconstruction method of unfavorable geological structure based on CT detection technology was proposed to establish a reliable analysis model for evaluating the stability of rock and mass. In this method，a 3D visualization model of the elastic-wave velocity was obtained by performing numerical simulation of elastic-wave CT detection and block Kriging interpolation. The peak value formula is used for material threshold segmentation，and the 3D mesh construction and material property mapping are used to form a 3D grid model in the target region. Comparison between the reconstructed 3D grid model and the original model shows that the simulation degree of the reconstructed model is as high as 91.44% and the absolute error of the volume fraction is 3.33%. Field test of elastic-wave CT detection was carried out for the bridge foundation location area，and the 3D mesh model of the region was reconstructed and verified by coring. The simulation degree is greater than 84.31%，and the absolute error of the volume fraction is less than 2.45%. The method has high modeling accuracy and can accurately reflect the spatial distribution state of bad geological bodies，and hence，has important scientific significance for evaluating the stability of poor geological structure.

Key words： geotechnical engineering unfavorable geology elastic wave CT 3D element mesh model reconstruction method simulation

引用本文:

王启明，车爱兰. 基于CT探测技术的不良地质构造三维网格模型重构方法[J]. 岩石力学与工程学报, 2019, 38(6): 1222-1232.
WANG Qiming，CHE Ailan. A 3D element mesh model reconstruction method for unfavorable#br# geological structure based on CT technology. , 2019, 38(6): 1222-1232.

链接本文:

http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2018.1232 或 http://www.rockmech.org/CN/Y2019/V38/I6/1222

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