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العنوان
Theoretical Evaluation of Uniaxial Flexural Behavior of Ultra High Performance Reinforced Concrete Members /
المؤلف
Abdel-Bary, Ahmed Abdel-Rahman Ibrahim.
هيئة الاعداد
باحث / أحمد عبد الرحمن إبراهيم عبد البارى
مشرف / أيمن حسين حسنى خليل
مشرف / وائل محمد منتصر
مناقش / وائل محمد منتصر
تاريخ النشر
2021.
عدد الصفحات
132p. :
اللغة
الإنجليزية
الدرجة
ماجستير
التخصص
الهندسة المدنية والإنشائية
تاريخ الإجازة
1/1/2021
مكان الإجازة
جامعة عين شمس - كلية الهندسة - الهندسة الانشائية
الفهرس
Only 14 pages are availabe for public view

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from 132

Abstract

Ultra high performance concrete (UHPC) is an advanced cementitious composite consisting of a dense high strength matrix and fibers. The use of UHPC is growing worldwide owing to its high performance so leading to be employed in a wide range of practical applications like nuclear waste containment structures, high rise structures, long span bridges and thin shells. Most studies on UHPC have focused on special concrete materials with characteristics that differ from those of conventional concrete at the material level. However, few researches are available on the uniaxial flexural capacity of UHPC beams at the structural level that can predict the overall performance. This thesis provides theoretical study on the structural behavior of UHPC beams. Several parameters were considered. The parameters are the reinforcement ratio, the concrete compressive strength, the eccentricity ratio (e/t) and the concrete cover. Eighteen finite element models were developed and analyzed in ANSYS software to investigate the effect of mentioned parameters on uniaxial flexural behavior of UHPC simple beams. The results showed that increasing the reinforcement ratio from 0.3 to 3 % led to increase in flexure capacity by 541 % and stiffness by 173 %. Increasing the concrete compressive strength from 115 to 215 MPa led to increase in the stiffness by 9.32 %. While, the flexure capacity wasn’t affected. Increasing the eccentricity ratio (e/t) from 0.50 to ∞ led to decrease in flexure capacity by 49.7 % and stiffness by 49.8 %. Increasing the concrete cover from 30 to 70 mm led to decrease in flexure capacity by 17.2 % and stiffness by 30.6 %. The FEM and results of this study provide valuable data that can be used in future studies on the development of computational models of uniaxial flexural behavior of UHPC.
Keywords—Ultra High Performance Concrete (UHPC), Structural, Uniaxial, ANSYS, Flexure capacity, Stiffness.