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基于深度学习预测开裂位置的超高性能纤维增强混凝土抗拉强度估计

Tensile Strength Estimation of UHPFRC Based on Predicted Cracking Location Using Deep Learning.

作者信息

Luo Xin, Matsumoto Takashi

机构信息

Graduate School of Engineering, Hokkaido University, Sapporo 060-8628, Japan.

Faculty of Public Policy, Hokkaido University, Sapporo 060-0810, Japan.

出版信息

Materials (Basel). 2025 May 12;18(10):2237. doi: 10.3390/ma18102237.

DOI:10.3390/ma18102237
PMID:40428975
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12113348/
Abstract

Ultra-high-performance fiber-reinforced concrete (UHPFRC) exhibits exceptional tensile properties, but its tensile strength is highly dependent on fiber distribution, orientation, and count, making accurate strength estimation challenging. This study introduces a novel approach in which tensile strength estimation is achieved by analyzing fiber characteristics at predicted cracking locations using deep learning. Using X-ray computed tomography (CT) and image analysis techniques, the fiber orientation factor (μ) and average efficiency factor ((μ)) were determined at predicted cracking locations. A deep learning model (YOLOv11) was trained to identify regions with a defective distribution, achieving a mean Average Precision (mAP@0.5) of 0.87, demonstrating its high reliability in predicting cracking locations. The overall cracking location prediction success rate was 73% for strain-hardening specimens. The estimated tensile strength was then compared with uniaxial tensile test (UTT) results, revealing an average experiment-estimation error of 5.72% and an average theory-estimation error of 3.34% for strain-hardening specimens, whereas strain-softening specimens exhibited significantly higher errors, with an average experiment-estimation error of 43.09% and an average theory-estimation error of 15.73%. These findings highlight the strong correlation between fiber count, cracking behavior, and tensile strength in UHPFRC, offering a trustworthy, non-destructive framework for estimating tensile performance in UHPFRC elements.

摘要

超高性能纤维增强混凝土(UHPFRC)具有卓越的拉伸性能,但其拉伸强度高度依赖于纤维分布、取向和数量,这使得准确估计强度具有挑战性。本研究引入了一种新方法,即通过使用深度学习分析预测开裂位置处的纤维特性来实现拉伸强度估计。利用X射线计算机断层扫描(CT)和图像分析技术,在预测开裂位置确定了纤维取向因子(μ)和平均效率因子((μ))。训练了一个深度学习模型(YOLOv11)来识别分布有缺陷的区域,其平均精度均值(mAP@0.5)为0.87,表明其在预测开裂位置方面具有很高的可靠性。对于应变硬化试件,整体开裂位置预测成功率为73%。然后将估计的拉伸强度与单轴拉伸试验(UTT)结果进行比较,结果显示,对于应变硬化试件,平均实验估计误差为5.72%,平均理论估计误差为3.34%,而应变软化试件的误差明显更高,平均实验估计误差为43.09%,平均理论估计误差为15.73%。这些发现突出了UHPFRC中纤维数量、开裂行为和拉伸强度之间的强相关性,为估计UHPFRC构件的拉伸性能提供了一个可靠的无损框架。

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