Failure Mechanism of Rock Pillar Containing Two Edge Notches: Experimental Test and Numerical Simulation
محل انتشار: مجله معدن و محیط زیست، دوره: 14، شماره: 3
سال انتشار: 1402
نوع سند: مقاله ژورنالی
زبان: انگلیسی
مشاهده: 182
فایل این مقاله در 11 صفحه با فرمت PDF قابل دریافت می باشد
- صدور گواهی نمایه سازی
- من نویسنده این مقاله هستم
استخراج به نرم افزارهای پژوهشی:
شناسه ملی سند علمی:
JR_JMAE-14-3_015
تاریخ نمایه سازی: 27 تیر 1402
چکیده مقاله:
Non-persistent joints are geologic occurrences in rocks that weaken pillars because they are present within them. Using practical tests and numerical models, it has been determined how edge notches affect the way pillars break. Gypsum samples that are notched and have dimensions of ۷۰ mm by ۷۰ mm by ۵۰ mm are created. Gypsum's Young modulus, Poisson ratio, compressive strength, and tensile strength are ۵.۵ GPa, ۰.۲۷, ۸ MPa, and ۱.۱ MPa, respectively. ۱۰-, ۲۰-, and ۳۰-degree notch angles are used. The model receives an axial stress at a rate of ۰.۰۵ mm/min. On a rock pillar, numerical simulation is carried out concurrently with an experimental test. The findings indicate that the joint angle is mostly responsible for the failure process. The fracture pattern and failure mechanism of the pillars are connected to the compressive strengths of the specimens. At the notch points, two significant splitting tensile fractures spread vertically until coalescing with the top and lower boundaries of the models. On the left and right sides of the pillar, two rock columns are also taken out. The overall number of cracks rises as sample loading increases. The model's deformation at the start of loading reflect a linear elastic behavior, and the number of fractures steadily grows. When the number of cracks increases, the curve becomes non-linear, and the force being applied peaks. When the sample can no longer tolerate the applied force, a dramatic stress decrease occurs. The macro-failure over the whole model is what leads to the greater stress decrease following the peak load. In actuality, the reduced stress reduction is accompanied by more overall fractures. Similar findings are shown in both the experimental testing and numerical modeling.
کلیدواژه ها:
نویسندگان
Amir Rezaei
Department of Mining Engineering, Hamedan University of Technology, Hamedan, Iran
Vahab Sarfarazi
Department of Mining Engineering, Hamedan University of Technology, Hamedan, Iran
Nima Babanouri
Department of Mining Engineering, Hamedan University of Technology, Hamedan, Iran
Mohammad Omidi manesh
Department of Mining Engineering, Hamedan University of Technology, Hamedan, Iran
Shirin Jahanmiri
Department of Mining Engineering, Hamedan University of Technology, Hamedan, Iran
مراجع و منابع این مقاله:
لیست زیر مراجع و منابع استفاده شده در این مقاله را نمایش می دهد. این مراجع به صورت کاملا ماشینی و بر اساس هوش مصنوعی استخراج شده اند و لذا ممکن است دارای اشکالاتی باشند که به مرور زمان دقت استخراج این محتوا افزایش می یابد. مراجعی که مقالات مربوط به آنها در سیویلیکا نمایه شده و پیدا شده اند، به خود مقاله لینک شده اند :