Wyniki wyszukiwania - BazTech

Ograniczanie wyników

Znaleziono wyników: 2

Liczba wyników na stronie

Wyniki wyszukiwania

Wyszukiwano:
w słowach kluczowych: deep beam

Sortuj według:

Ogranicz wyniki do:

Shear strengthening of deficient RC deep beams using NSM FRP system: Experimental and numerical investigation

Abadel Aref

Materials Science Poland

2024

Vol. 42, No. 1

140--157

It is essential to retrofit deep beams with shear inadequacies because these beams, although they have the same shear and flexural reinforcements as ordinary beams, are more susceptible to shear failure. Hence, it is of great significance to overcome the shear weaknesses in deep beams. This research paper aims to experimentally examine the effectiveness of near-surface mounted (NSM) carbon fiber reinforced polymer (CFRP) for retrofitting reinforced concrete (RC) deep beams subjected to shear forces. The study involved three different types of specimens. The first specimen was constructed with concrete throughout its span and included shear stirrups. The second specimen was divided into two halves, with one half lacking shear reinforcements and the other half having them. The third specimen had steel web reinforcement in one half of the span, while the other half was strengthened using NSM CFRP U-wrap strips and externally bonded horizontal CFRP strips. The proposed strengthening method significantly increased the shear strength of the deep beams, surpassing that provided by steel web reinforcement alone. Furthermore, the NSM CFRP strengthened specimen exhibited a change in failure mode from shear to flexural failure. In comparison to the control beam without stirrups, the beams strengthened with NSM CFRP U-wrap strips demonstrated an impressive 82% improvement in shear strength, while the beam with shear reinforcement showed a 23 % enhancement in load capacity. The proposed strengthened scheme is capable of enhancing the structural performance and load-carrying capacity effectively. A finite element model was generated utilizing ABAQUS software to simulate the behavior of the tested deep beams and verified against the experimental outcomes. The numerical models successfully predicted the behavior of the RC deep beams strengthened with NSM CFRP when compared to the experimental data.

Prognosis of dynamic behavior of reinforced concrete deep beams of very high strength materials

Cichorski Waldemar, Stolarski Adam

Archives of Civil Engineering

2020

Vol. 66, nr 1

257--279

An analysis of the dynamic load - carrying capacity of rectangular reinforced concrete deep beam considering the physical nonlinearities of structural materials: concrete and reinforcing steel, is the aim of the paper. The model of the elastic/visco-perfectly plastic material including dynamic yield criterion was applied for the reinforcing steel. The non-standard model of dynamic deformation, regarding the dynamic strength criterion and material softening was applied for the concrete. The method for description of deformation parameters of high strength concrete was included in the model. The method of structure effort analysis was developed using the finite element method. The comparative analyses of the obtained results for three different values of high strengths of concrete and one value of high yield stress for reinforcing steel were carried out in relation to the numerical results obtained for ordinary concrete and steel in case of dynamic loading. In these cases, the significant differences in behavior of reinforced concrete deep beams have been observed and described in detail. The effectiveness of the method analysis and computational algorithms for the problems of numerical simulation of reinforced concrete deep beam dynamic behavior was indicated in the paper.

W pracy przedstawiono prognozę zachowania prostokątnych tarcz żelbetowych wykonanych z betonów o bardzo wysokiej wytrzymałości obciążonych dynamicznie z uwzględnieniem fizycznych nieliniowości materiałów konstrukcyjnych: betonu i stali zbrojeniowej. Do opisu dynamicznych właściwości materiałów konstrukcyjnych dla betonu zastosowano niestandardowy model deformacji dynamicznej uwzględniający wytrzymałość dynamiczną betonu, osłabienie materiałowe, zarysowanie i miażdżenie betonu. W modelu opisującym dynamiczne zachowanie betonu dokonano modyfikacji paramentów materiału uwzględniających charakterystykę naprężeniowo-odkształceniową uwzgledniająca parametry betonu bardzo wysokiej wytrzymałości. Dla stali zbrojeniowej przyjęto model sprężysto/lepko-idealnie plastycznego materiału z uwzględnieniem efektu opóźniania plastycznego. Modelowanie procesów dynamicznego odkształcania płaskiego ustroju konstrukcyjnego- tarczy żelbetowej przeprowadzono przy użyciu własnych procedur numerycznych i programów obliczeniowych bazując na metodzie elementów skończonych.