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Behaviour of GFRP Reinforced Concrete Columns under Combined Axial Load and FlexureTavassoli, Arjang 28 November 2013 (has links)
This study presents experimental results from nine large-scale circular concrete columns
reinforced with longitudinal and transverse glass fiber-reinforced polymer (GFRP) bars. These
specimens were tested under lateral cyclic quasi-static loading while simultaneously subjected
to constant axial load. Based on the measured hysteretic loops of moment vs. curvature and
shear vs. tip deflection relationships, a series of parameters related to ductility and flexural
strength are used to evaluate the seismic behavior of each column. The results showed that
concrete columns reinforced with GFRP bars have stable post-peak branches and can achieve
very high levels of deformability. Longitudinal GFRP bars maintained their stiffness at high
strains and transverse GFRP spirals provided increasing confinement for the entire duration of
the test without any spiral damage. The tests showed that, as an innovative material with
excellent corrosion resistance GFRP bars can be successfully used as internal reinforcement in
ductile concrete columns.
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Behaviour of GFRP Reinforced Concrete Columns under Combined Axial Load and FlexureTavassoli, Arjang 28 November 2013 (has links)
This study presents experimental results from nine large-scale circular concrete columns
reinforced with longitudinal and transverse glass fiber-reinforced polymer (GFRP) bars. These
specimens were tested under lateral cyclic quasi-static loading while simultaneously subjected
to constant axial load. Based on the measured hysteretic loops of moment vs. curvature and
shear vs. tip deflection relationships, a series of parameters related to ductility and flexural
strength are used to evaluate the seismic behavior of each column. The results showed that
concrete columns reinforced with GFRP bars have stable post-peak branches and can achieve
very high levels of deformability. Longitudinal GFRP bars maintained their stiffness at high
strains and transverse GFRP spirals provided increasing confinement for the entire duration of
the test without any spiral damage. The tests showed that, as an innovative material with
excellent corrosion resistance GFRP bars can be successfully used as internal reinforcement in
ductile concrete columns.
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Experimental Evaluation and Computer Analysis of Multi-Spiral Confinement in Reinforced Concrete ColumnsBrubaker, Briana January 1900 (has links)
Master of Science / Department of Civil Engineering / Asadollah Esmaeily / Bridge and building construction in areas that sustain frequent seismic activity require the use of heavy lateral steel reinforcement within concrete columns to handle the lateral loads. Multi-spiral lateral reinforcement has been recently introduced to the construction field to offer an alternative to the traditional hoop and tie reinforcement. This report evaluates the experimental data observed in multiple experimental studies done on different concrete specimens. These specimens include multiple rectilinear reinforcement and several multi-spiral configurations in both rectangular and oblong columns. Due to multi-spiral reinforcement being a relatively new design, traditional computer programs have yet to include design analysis for this type of reinforcement in computer programs. Dr. Asad Esmaeily developed the program KSU RC 2.0 that can implement multiple analytical models to evaluate different multi-spiral configurations, as well as traditional hoop and tie confinement, that may be compared with experimental data. This report illustrates the comparative data from several different reinforced concrete column models. The data clearly indicates that multi-spiral reinforced columns exhibit higher compressive strength in the axial direction as well as higher ductility capabilities when compared to traditional rectilinear reinforcement of similar lateral steel reinforcement ratios. The use of multi-spiral reinforcement is also shown to lower costs for both the work time needed to install the structures as well as lowering the required steel ratio; all while maintaining the structural integrity of the columns.
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Influência da forma de seção transversal no confinamento de pilares de concreto armado encamisados com PRFC (polímero reforçado com fibras) / Influence of the cross section shape in the confinement of jacketed reinforced concrete columns with CFRP (carbon fiber reinforced polymer)Sudano, Alexandre Luis 31 May 2005 (has links)
O efeito de confinamento do concreto em pilares submetidos à compressão axial traz diversos benefícios ao seu comportamento estrutural, dentre os quais destacam-se o aumento na resistência à compressão axial do concreto pela ação das pressões laterais, e a melhoria da ductilidade do elemento estrutural. Em função destas vantagens, o confinamento é uma das principais técnicas de reforço de pilares de concreto. Porém, dependendo da forma da seção transversal, a eficiência do reforço pode ficar comprometida em função da distribuição da pressão de confinamento. No caso de pilares de seção circular, esta distribuição é uniforme. Já em pilares de seção quadrada e retangular, existe concentração de tensão nos cantos da seção transversal, o que, no caso de reforço por encamisamento com PRFC, pode causar a ruptura prematura da camisa, resultando num reforço ineficiente. Com o intuito de considerar as diferentes configurações da distribuição da pressão de confinamento, utiliza-se um coeficiente de forma, que em seções diferentes da circular (para a qual este coeficiente é igual à unidade), minora o valor da pressão de confinamento, o qual é utilizado na previsão da carga de ruptura do pilar reforçado. Este trabalho tem como objetivo central o estudo de vários tipos de seção transversal com o intuito de avaliar a sua influência na eficiência do reforço e da ductilidade do elemento estrutural. Para tal, foram realizadas simulações experimentais com pilares de seção transversal circular, quadrada e retangular com os cantos arredondados, elíptica e uma seção composta por semicírculos. Os resultados demonstram que uma forma de seção transversal adequada é essencial para um bom desempenho do pilar reforçado, sendo assim, as seções transversais que apresentaram os melhores resultados foram a circular, a elíptica e a composta por semicírculos / The effect of the concrete confinement in columns submitted to the axial compression brings many benefits to its structural behavior, amongst them the increase of the axial compressive strength due to the action of the lateral pressures and the improvement of the ductility. In function of these advantages, the confinement is one of the main techniques for strengthening of concrete columns. However, depending on the shape of the cross section, the efficiency of the reinforcement can be impaired by the non-uniformity of the confinement pressure distribution. In the case of circular cross section columns, this distribution is uniform. Otherwise, in square and rectangular cross section columns, there is a pressure concentration at the cross section corners. In case of CFRP jackets, the pressure concentration leads to a premature rupture of the jacket, resulting in an inefficient reinforcement. Intending to consider the different confinement pressure distributions, a shape coefficient is applied to cross sections with distinguished shape from the circular one (for which this coefficient is equal to the unit), to correct the confinement pressure value. The corrected pressure is applied in theoretical evaluations of the columns load carrying capacity. The main objective of work is to analyze the structural behavior of strengthened concrete columns with different shape cross-sections, evaluating the influences in the efficiency of the jacketing and in the ductility of the structural element. Experimental simulations were made in columns with the following cross section shapes: circular, square and rectangular with rounded corners, elliptical and a section composed by semicircles. The results demonstrated that an adequate shape of the cross-section is essential for a good performance of the strengthened columns. The cross sections that presented the best results were the circular, the elliptical and the one composed by semicircles
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Influência da forma de seção transversal no confinamento de pilares de concreto armado encamisados com PRFC (polímero reforçado com fibras) / Influence of the cross section shape in the confinement of jacketed reinforced concrete columns with CFRP (carbon fiber reinforced polymer)Alexandre Luis Sudano 31 May 2005 (has links)
O efeito de confinamento do concreto em pilares submetidos à compressão axial traz diversos benefícios ao seu comportamento estrutural, dentre os quais destacam-se o aumento na resistência à compressão axial do concreto pela ação das pressões laterais, e a melhoria da ductilidade do elemento estrutural. Em função destas vantagens, o confinamento é uma das principais técnicas de reforço de pilares de concreto. Porém, dependendo da forma da seção transversal, a eficiência do reforço pode ficar comprometida em função da distribuição da pressão de confinamento. No caso de pilares de seção circular, esta distribuição é uniforme. Já em pilares de seção quadrada e retangular, existe concentração de tensão nos cantos da seção transversal, o que, no caso de reforço por encamisamento com PRFC, pode causar a ruptura prematura da camisa, resultando num reforço ineficiente. Com o intuito de considerar as diferentes configurações da distribuição da pressão de confinamento, utiliza-se um coeficiente de forma, que em seções diferentes da circular (para a qual este coeficiente é igual à unidade), minora o valor da pressão de confinamento, o qual é utilizado na previsão da carga de ruptura do pilar reforçado. Este trabalho tem como objetivo central o estudo de vários tipos de seção transversal com o intuito de avaliar a sua influência na eficiência do reforço e da ductilidade do elemento estrutural. Para tal, foram realizadas simulações experimentais com pilares de seção transversal circular, quadrada e retangular com os cantos arredondados, elíptica e uma seção composta por semicírculos. Os resultados demonstram que uma forma de seção transversal adequada é essencial para um bom desempenho do pilar reforçado, sendo assim, as seções transversais que apresentaram os melhores resultados foram a circular, a elíptica e a composta por semicírculos / The effect of the concrete confinement in columns submitted to the axial compression brings many benefits to its structural behavior, amongst them the increase of the axial compressive strength due to the action of the lateral pressures and the improvement of the ductility. In function of these advantages, the confinement is one of the main techniques for strengthening of concrete columns. However, depending on the shape of the cross section, the efficiency of the reinforcement can be impaired by the non-uniformity of the confinement pressure distribution. In the case of circular cross section columns, this distribution is uniform. Otherwise, in square and rectangular cross section columns, there is a pressure concentration at the cross section corners. In case of CFRP jackets, the pressure concentration leads to a premature rupture of the jacket, resulting in an inefficient reinforcement. Intending to consider the different confinement pressure distributions, a shape coefficient is applied to cross sections with distinguished shape from the circular one (for which this coefficient is equal to the unit), to correct the confinement pressure value. The corrected pressure is applied in theoretical evaluations of the columns load carrying capacity. The main objective of work is to analyze the structural behavior of strengthened concrete columns with different shape cross-sections, evaluating the influences in the efficiency of the jacketing and in the ductility of the structural element. Experimental simulations were made in columns with the following cross section shapes: circular, square and rectangular with rounded corners, elliptical and a section composed by semicircles. The results demonstrated that an adequate shape of the cross-section is essential for a good performance of the strengthened columns. The cross sections that presented the best results were the circular, the elliptical and the one composed by semicircles
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Safety Assessment Of R/c Columns Against Explosive Attacks By Vehicle Or Human From ExteriorAltunlu, Kartal 01 February 2008 (has links) (PDF)
Reinforced concrete structures may be subjected to blast loads together with static loads during their service life. Important buildings may be attacked by using explosives as a part of increasing global terrorist activities. Evaluation of blast phenomena for economically and strategically significant buildings is especially important, in order to analyze and design their structural members subjected to air blast loading. Understanding nature of explosions, which are loading characteristics and relation to selected parameters such as explosive type, quantity, and distance, were studied in this thesis. Earlier studies found in the literature survey on explosives, blast, and behavior of structural elements were investigated. Behavior of structures under blast load was described in terms of pressure magnitude, distribution, and reflection phenomena. Simple design, assessment guidelines, and useful charts were developed. A computer program was generated using MATLAB programming language, which automatically generates the air blast pressure versus time data resulting from an air explosion in addition to finite element model formation and dynamic time stepping analysis of a reinforced concrete column. The shear and moment capacities can be calculated and compared against dynamically calculated demand under known axial column force / therefore, vulnerability of a column under blast loading is evaluated. The results of the numerical analyses indicated that failure mechanism of columns is mostly shear failure instead of moment (i.e., plastic hinge and mechanism formation).
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Evaluation Of Performance Based Displacement Limits For Reinforced Concrete Columns Under FlexureSolmaz, Taylan 01 September 2010 (has links) (PDF)
Reinforced concrete frame buildings are the most common type of constructions in Turkey which are exposed to various types of forces during their lifetime. Seismic performance of reinforced concrete frame buildings is dominated by columns which can be classified as primary members of these structures. When current codes are considered, all of them contain several provisions in order to implement reliable seismic performances of reinforced concrete columns. In order to evaluate the accuracy of these provisions, analytical and parametric studies are carried out for flexure critical reinforced concrete columns. In these studies, total numbers of 30 flexure critical columns are extracted from PEER database (2005) and analytically investigated. Once the seismic responses obtained from analytical investigations are close enough to experimental seismic responses, performance based displacement limits are pointed out according to TEC (2007), FEMA 356 (2000), Eurocode 8 (2003), and ASCE/SEI 41 Update (2009). In addition to this, total numbers of 144 flexure critical columns are generated in parametric studies to present the effects of various parameters such as column geometry, concrete strength, axial load ratio, transverse reinforcement ratio, and yielding strength of longitudinal reinforcement on performance based displacement limits. Performance based displacement limits proposed by TEC (2007), FEMA 356 (2000), Eurocode 8 (2003), and ASCE/SEI 41 Update (2009) are found very conservative compared to limits obtained from both experimental and analytical behavior. On the other hand, performance based displacement limits given in Eurocode 8 (2003) and ASCE/SEI 41 Update (2009) predict the experimental behavior more accurate than TEC (2007) and FEMA 356 (2000). Improvements on these limits are proposed.
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Effect of load pattern and history on performance of reinforced concrete columnsShirmohammadi, Fatemeh January 1900 (has links)
Doctor of Philosophy / Civil Engineering / Asadollah Esmaeily / Accurate and realistic assessment of the performance of columns in general, and those in critical locations that may cause progressive failure of the entire structure, in particular, is significantly important. This performance is affected by the load history, pattern, and intensity. Current design code does not consider the effect of load pattern on the load and displacement capacity of columns. A primary research sponsored by Kansas Department of Transportation (KDOT) was conducted as the initial step of the present study (No. K-TRAN: KSU-11-5). The main goals of the KDOT project were: (1) investigation of new KDOT requirements in terms of the column design procedure and detailing and their consistency with AASHTO provisions; (2) verification of the KDOT assumptions for the plastic hinge regions for columns and bridge piers, (3) provide assessment of the load capacity of the existing columns and bridge piers in the light of the new specifications and using the new load demand as in the new provisions; and finally recommendations for columns and bridge piers that do not meet the new requirements. A conclusion was drawn that there is a need for conducting more studies on the realistic performance of Reinforced Concrete (RC) sections and columns. The studies should have included performance of RC members under various loading scenarios, assessment of columns capacity considering confinement effect provided by lateral reinforcement, and investigation on performance of various monotonic and cyclic material models applied to simulate the realistic performance.
In the study reported here, monotonic material models, cyclic rules, and plastic hinge models have been utilized in a fiber-based analytical procedure, and validated against experimental data to simulate behavior of RC section under various loading scenarios. Comparison of the analytical predictions and experimental data, through moment–curvature and force–deflection analyses, confirmed the accuracy and validity of the analytical algorithm and models. The performance of RC columns under various axial and lateral loading patterns was assessed in terms of flexural strength and energy dissipation.
FRP application to enhance ductility, flexural strength, and shear capacity of existing deficient concrete structures has increased during the last two decades. Therefore, various aspects of FRP-confined concrete members, specifically monotonic and cyclic behavior of concrete members confined and reinforced by FRP, have been studied in many research programs, suggesting various monotonic models for concrete confined by only FRP. Exploration of existing model performances for predicting the behavior of several tested specimens shows a need for improvement of existing algorithms. The model proposed in the current study is a step in this direction. FRP wrapping is typically used to confine existing concrete members containing conventional lateral steel reinforcement (tie/spiral). The confining effect of lateral steel reinforcement in analytical studies has been uniquely considered in various models. Most models consider confinement due to FRP and ignore the effect of conventional lateral steel reinforcement. Exploration of existing model performances for predicting the behavior of several tested specimens confined by both FRP and lateral steel shows a need for improvement of existing algorithms. A model was proposed in this study which is a step in this direction. Performance of the proposed model and four other representative models from literature was compared to experimental data from four independent databases.
In order to fulfill the need for a simple, yet accurate analytical tool for performance assessment of RC columns, a computer program was developed that uses relatively simple analytical methods and material models to accurately predict the performance of RC structures under various loading conditions, including cyclic lateral displacement under a non-proportionally variable axial load (Esmaeily and Xiao 2005, Esmaeily and Peterman 2007). However, it was limited to circular, rectangular, and hollow circular/rectangular sections and uniaxial lateral curvature or displacement.
In this regards, a computer program was developed which is the next generation of the aforesaid program with additional functionality and options. Triangulation of the section allows opportunity for cross-sectional geometry. Biaxial lateral curvature/displacement/force combined with any sequence of axial load provides opportunity to analyze the performance of a reinforced concrete column under any load and displacement path. Use of unconventional reinforcement, such as FRP, in lateral as well as longitudinal direction is another feature of this application.
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COLLAPSE MODELING OF REINFORCED CONCRETE FRAMES UNDER SEISMIC LOADINGEldawie, Alaaldeen Hassan January 2020 (has links)
No description available.
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Eccentric compression behavior of Steel-FRP composite bars RC columns under coupling action of chloride corrosion and loadGe, W., Zhang, S., Zhang, Z., Guan, Z., Ashour, Ashraf, Sun, C., Lu, W., Cao, D. 02 November 2023 (has links)
No / In order to investigate the eccentric compression behaviors of steel-FRP composite bar (SFCB) reinforced concrete (RC) columns subjected to chloride corrosion, the mechanical experiments of chloride corroded SFCBs and SFCBs RC eccentric compression columns were conducted. The effect of reinforcement type and ratio, eccentricity, slenderness, stress level and corrosion duration on bearing capacity, deformation, crack and failure pattern were investigated. The results showed that the strength retention ratio of reinforcement decreases with the increase of corrosion duration, the ultimate strengths of steel rebar, SFCB and FRP rebar decreased by 12.2%, 9.9% and 3.6%, respectively, when compared with those of uncorroded counterparts. With the increase of steel content of reinforcement, the load bearing capacity of eccentric compression RC column increases while the deformation decreases gradually. The load bearing capacity of corroded steel, SFCB and FRP RC columns maximally decreased by 16.6%, 12.4% and 7.2%, respectively, when compared with those of uncorroded counterparts. Based on the simplified materials constitutive relations and reasonable basic assumptions, formulae for discriminate failure mode, moment magnification factor and bearing capacity were developed. The predicted failure pattern, moment magnification factor and bearing capacity are in good agreement with the test results, confirming the validity of the proposed formulae, the results can be used as a reference for engineering application. / High-End Foreign Experts Project of Ministry of Science and Technology, China (G2022014054L), the Natural Science Foundation of Jiangsu Province, China (BK20201436), the Science and Technology Project of Jiangsu Construction System (2018ZD047, 2021ZD06), the Science and Technology Project of Gansu Construction System (JK2021-19), the Opening Foundation of Jiangsu Province Engineering Research Center of PrefabricatedBuilding and Intelligent Construction (2021), the Science and Technology Cooperation Fund Project of Yangzhou City and Yangzhou University (YZ2022194, YZU212105), the Science and Technology Project of Yangzhou Construction System (2022ZD03, 202204), the Nantong Jianghai (226) talents project, the Blue Project Youth Academic Leader of Colleges and Universities in Jiangsu Province (2020).
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