Behaviour of Damaged B.F.I. Beam Repaired by CFRP Strips under Static or Fatigue Loads Using Finite Element Simulation
• 2019
معلومات البحث
المؤلفون
Hala M. Refat1 and Mohamed H. Makhlouf1*
الكلمات المفتاحية
Not Available
المجلة العلمية
Not Available
الناشر
Not Available
المجلد
Not Available
العدد
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الصفحات
12
publication.type
International
رابط البحث
Not Available
المواد المرفقة
Not Available
الملخص
steel Broad Flange I- beams section by single edge notched repaired with carbon fiber reinforced
polymer CFRP strips. The study is carried out using ANSYS classic modeling approach is
suggested to simulate the fatigue response of the beams, based on the cumulative damage theory
and strain life method. Experimental test results were compared with FE results obtained. A
parametric study was conducted using the validated model. The considered parameters were the
number of CFRP strip layers used in the repair, the applied load range, initial crack length at time of
strengthening and the thickness of CFRP strip. The numerical results indicated that the CFRP
increased the critical crack length at which fracture occurred, and the strengthening was more
effective at lower stress ranges. Moreover, the CFRP Strips can substantially delay failure and the
results demonstrate the possibility of technique and highlight the importance of early intervention
when repairing fatigue critical details. The ultimate load and ductility decreased substantially with
increasing initial crack length at the time of installing the strengthening layer. Furthermore,
increased capacity was achieved by increase the CFRP thickness and layers.
polymer CFRP strips. The study is carried out using ANSYS classic modeling approach is
suggested to simulate the fatigue response of the beams, based on the cumulative damage theory
and strain life method. Experimental test results were compared with FE results obtained. A
parametric study was conducted using the validated model. The considered parameters were the
number of CFRP strip layers used in the repair, the applied load range, initial crack length at time of
strengthening and the thickness of CFRP strip. The numerical results indicated that the CFRP
increased the critical crack length at which fracture occurred, and the strengthening was more
effective at lower stress ranges. Moreover, the CFRP Strips can substantially delay failure and the
results demonstrate the possibility of technique and highlight the importance of early intervention
when repairing fatigue critical details. The ultimate load and ductility decreased substantially with
increasing initial crack length at the time of installing the strengthening layer. Furthermore,
increased capacity was achieved by increase the CFRP thickness and layers.
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