Title:
Multi-Step Slotting Method for Evaluating In-Place Stress in Concrete
Author(s):
Zhao-Dong Xu, Yi Zhang, Jin-Bao Li, Xing-Huai Huang, and Ying-Qing Guo
Publication:
Materials Journal
Volume:
120
Issue:
5
Appears on pages(s):
101-110
Keywords:
experimental study; in-place stress; numerical analysis; slotting method; stress measurement
DOI:
10.14359/51738893
Date:
9/1/2023
Abstract:
The slotting method is a nondestructive detection method based on the stress release principle to evaluate in-place stress in concrete. By measuring the change in strain of the slotting area using a strain gauge, the in-place stress within the concrete member can be calculated by elastic theory. This paper proposes a multi-step slotting method that combines experimental strain measurements with numerical simulation results. For concrete specimens under unidirectional stress, the effects of compressive stress, slotting spacing, slotting length, and slotting depth on the degree of stress release were analyzed using finite element analysis, and a normalized fitting equation was proposed that can be quickly and accurately applied in engineering detection. The excellent agreement between the experimental results and the numerical simulation (fitted equation) results shows that the slotting method can facilitate the accurate evaluation of the in-place stress in concrete, and the relative error can be reduced to less than 10% when it is calculated using the optimized multi-step experimental data.