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基于深度学习和钻孔图像岩体RQD智能计算OA

Intelligent computing of rock mass rock quality designation based on deep learning and borehole image analysis

中文摘要英文摘要

岩石质量指标(RQD)是岩土工程中公认的并广泛运用的反映岩石完整性的重要指标,常用于岩石质量分类,同时也是评级系统的重要输入参数.传统的RQD确定方法依赖于人工岩心测井,但通常费时费力,且易受钻进工艺、取心质量的影响,往往不能客观获得RQD值.基于深度学习算法YOLOv5 提出了一种新方法,无需采集岩心,能够直接从钻孔井下电视获得的原位钻孔图像中自动识别和定位结构面,从而避免岩心取样过程中的破坏性影响,并实现RQD的智能计算.该方法首先对钻孔原始图像进行预处理构建一个具有代表性的数据集,然后采用深度学习算法训练模型,最后结合图像分析方法自动计算RQD.为了验证该方法的准确性,选取了中国湖南省永州市某隧道工程,通过对比zk04 钻孔得到的RQD智能计算值和RQD人工测量值,发现根据钻孔图像智能计算的RQD值相较现场人工对于岩心盒的实测值平均偏高 20%,平均绝对误差为 9.82%.提出的方法能够避免钻进和取心过程对实际RQD造成的影响,提高了RQD数据的准确性,体现了其可靠性和有效性.

[Purpose]Rock quality designation(RQD)is widely recognized as a fundamental index in geotechnical engineering for evaluating rock mass integrity.It is extensively applied in rock mass classification systems and serves as a key input parameter for engineering rating systems.Conventionally,RQD determination relies on manual logging of recovered drill cores.However,this approach is labor-intensive,time-consuming,and highly sensitive to drilling techniques and core quality,making it difficult to obtain objective and reliable RQD values.[Method]To address these challenges,this study proposed a novel,non-destructive approach based on the deep learning algorithm YOLOv5(You Only Look Once,version 5)to detect and localize discontinuities directly from borehole televiewer images.It eliminated the disturbances and bias introduced during physical core extraction,enabling intelligent RQD computing.First,raw televiewer images were preprocessed,annotated,and augmented to build a representative dataset that highlighted natural fractures,bedding planes,and other geological discontinuities.Then,a YOLOv5 detector was trained on this dataset to recognize and segment discontinuities with high spatial accuracy.Finally,the model output was post-processed to compute RQD automatically by quantifying the proportion of intact rock segments exceeding the standard 10 cm threshold.[Results]To assess the method's performance,a case study was conducted on borehole zk04,part of a tunnel project in Yongzhou City,Hunan Province,China.Intelligent RQD values derived from the televiewer images were compared with conventional RQD measurements obtained from core boxes in the field.The results indicated that the automated approach tended to overestimate RQD by around 20%relative to manual measurements,with a mean absolute error of 9.82%.Despite this systematic bias,the spatial trend of RQD variation identified by the intelligent method closely matched that of in-situ wave velocity profiles,suggesting that the technique accurately captured relative changes in rock mass properties along the borehole.[Conclusion]Overall,the proposed YOLOv5-based workflow effectively reduces the influence of drilling-induced biases and core extraction artifacts on RQD estimation.By enabling rapid,repeatable,and objective computation of RQD directly from borehole images,the method enhances both efficiency and reliability of rock quality assessment.Future work will explore calibration strategies to correct systematic deviations and integrate complementary geophysical datasets.This approach demonstrates significant potential to digitalize geotechnical investigation processes,streamline tunnel engineering workflows,and advance rock mass characterization in a more robust and data-driven manner.

李东黎;刘兴宇;张占荣;葛云峰;李炜;张子龙

中铁第四勘察设计院集团有限公司,武汉 430063中国地质大学(武汉)工程学院,武汉 430074中铁第四勘察设计院集团有限公司,武汉 430063中国地质大学(武汉)工程学院,武汉 430074||新疆工业学院自然资源科技学院,新疆 和田 848000中铁第四勘察设计院集团有限公司,武汉 430063中国地质大学(武汉)工程学院,武汉 430074

建筑与水利

岩体质量岩石质量指标(RQD)井下电视深度学习单阶段目标检测(YOLO)智能计算

rock mass qualityrock quality designation(RQD)downhole videodeep learningYou Only Look Once(YOLO)intelligent computing

《地质科技通报》 2026 (3)

17-29,13

中国铁建股份有限公司科技重大专项(2022-A02)中国铁建股份有限公司科技重大专项(2024-W01)

10.19509/j.cnki.dzkq.tb20250114

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