Spelling suggestions: "subject:"posttensioning"" "subject:"postensioning""
1 |
Análise experimental da punção em lajes de concreto armado e protendido / Experimental punching shear analysis of reinforced and prestressed concrete slabsMelges, José Luiz Pinheiro 29 March 2001 (has links)
As lajes lisas podem oferecer diversas vantagens quando comparadas ao sistema de lajes, vigas e pilares, sendo, em muitos casos, mais econômicas. O uso da protensão pode oferecer outras vantagens, tais como um melhor controle da fissuração e dos deslocamentos transversais da laje. Como a punção é um dos pontos fracos das lajes lisas protendidas, face à grande esbeltez destas lajes, apresentam-se resultados experimentais de ligações laje-pilar interno, com carregamento concêntrico, com e sem armadura de punção (conectores tipo-pino), com e sem protensão por pós-tração (cabos não aderentes). Os principais aspectos analisados foram as influências da armadura de punção e da protensão na resistência da ligação laje-pilar. Fez-se também uma análise envolvendo a previsão da resistência da ligação, dada por algumas normas e códigos. Observa-se que, de um modo aproximado, a armadura de punção eleva significativamente a resistência do modelo à punção, seja ele de concreto armado ou protendido. Observa-se ainda que, embora diminuindo a taxa de armadura dos modelos de concreto armado, para que se introduzissem as cordoalhas de protensão, os valores experimentais obtidos mostram que a presença da protensão aumentou a resistência da ligação. De um modo geral, a melhor norma que reflete o comportamento da ligação lajepilar é a Revisão da NB-1 (2000). Com relação aos modelos protendidos, o ACI poderia ter tido um bom desempenho, caso não houvesse uma restrição tão rígida com relação ao uso de armaduras de punção / The use of flat plates may offer some economical and aesthetic benefits when compared with other structural systems. The use of post-tensioned slabs may offer other advantages, as a better crack and deflection control and a thinner slab for the same span and load conditions. This work presents some experimental results and conclusions about the punching shear failure, as it is a critical problem for flat plate structures, post-tensioned or not. The main aspects analyzed are the influence of the shear reinforcement (studs) and of the post-tensioning with unbonded tendons on a slab internal column connection strength. A comparison between experimental results and those given by some standards is presented. This comparison aims to verify if the codes accurately predict the punching shear strength of the connection. It can be noted that, in an specific comparison, the studs enhance the punching shear strength of the slab-column connection. In spite of the use of less flexural reinforcement in the post-tensioned models, the punching shear strength of the connection had a higher value when compared with the reinforced ones. This fact is due to the presence of the prestressed strands
|
2 |
Análise experimental da punção em lajes de concreto armado e protendido / Experimental punching shear analysis of reinforced and prestressed concrete slabsJosé Luiz Pinheiro Melges 29 March 2001 (has links)
As lajes lisas podem oferecer diversas vantagens quando comparadas ao sistema de lajes, vigas e pilares, sendo, em muitos casos, mais econômicas. O uso da protensão pode oferecer outras vantagens, tais como um melhor controle da fissuração e dos deslocamentos transversais da laje. Como a punção é um dos pontos fracos das lajes lisas protendidas, face à grande esbeltez destas lajes, apresentam-se resultados experimentais de ligações laje-pilar interno, com carregamento concêntrico, com e sem armadura de punção (conectores tipo-pino), com e sem protensão por pós-tração (cabos não aderentes). Os principais aspectos analisados foram as influências da armadura de punção e da protensão na resistência da ligação laje-pilar. Fez-se também uma análise envolvendo a previsão da resistência da ligação, dada por algumas normas e códigos. Observa-se que, de um modo aproximado, a armadura de punção eleva significativamente a resistência do modelo à punção, seja ele de concreto armado ou protendido. Observa-se ainda que, embora diminuindo a taxa de armadura dos modelos de concreto armado, para que se introduzissem as cordoalhas de protensão, os valores experimentais obtidos mostram que a presença da protensão aumentou a resistência da ligação. De um modo geral, a melhor norma que reflete o comportamento da ligação lajepilar é a Revisão da NB-1 (2000). Com relação aos modelos protendidos, o ACI poderia ter tido um bom desempenho, caso não houvesse uma restrição tão rígida com relação ao uso de armaduras de punção / The use of flat plates may offer some economical and aesthetic benefits when compared with other structural systems. The use of post-tensioned slabs may offer other advantages, as a better crack and deflection control and a thinner slab for the same span and load conditions. This work presents some experimental results and conclusions about the punching shear failure, as it is a critical problem for flat plate structures, post-tensioned or not. The main aspects analyzed are the influence of the shear reinforcement (studs) and of the post-tensioning with unbonded tendons on a slab internal column connection strength. A comparison between experimental results and those given by some standards is presented. This comparison aims to verify if the codes accurately predict the punching shear strength of the connection. It can be noted that, in an specific comparison, the studs enhance the punching shear strength of the slab-column connection. In spite of the use of less flexural reinforcement in the post-tensioned models, the punching shear strength of the connection had a higher value when compared with the reinforced ones. This fact is due to the presence of the prestressed strands
|
3 |
Shear strength of structural elements in high performance fibre reinforced concrete (HPFRC)Moreillon, Lionel 19 March 2013 (has links) (PDF)
For members and flat slabs without shear reinforcement, the shear and punching shear strength are often the determining design criteria. These failure modes are characterized by a fragile behaviour implying possible partial or total collapse of the structure. Despite extensive research in this field, shear and punching shear in reinforced and prestressed concrete structures, remain complex phenomena so much that the current approach is often empirical or simplified. The ability of Steel Fibre Reinforced Concrete (SFRC) to reduce shear reinforcement in reinforced and prestressed concrete members and slabs,or even eliminate it, is supported by several experimental studies. However its practical application remains marginal mainly due to the lack of standard, procedures and rules adapted to its performance. The stationary processes in precast industry offer optimal possibilities for using high performance cementitious materials such as Self Compacting Concrete (SCC) and High Strength Concrete (HSC). For the author, the combination of High Performance Concrete and steel fibres is the following step in the development and the optimization of this industry. The High Performance Fibre Reinforced Concrete (HPFRC) stands between conventional SFRC and Ultra-High Performance Fibre Reinforced Concrete (UHPFRC). The HPFRC exhibiting a good strength/cost ratio is, thus, an alternative of UHPFRC for precast elements. The principal aim of this work was to analyse the shear and punching shear behaviour of HPFRC and UHPFRC structures without transversal reinforcement and to propose recommendations and design models adapted for practitioners. Several experimental studies on structural elements, i.e. beams and slabs, were undertaken for this purpose. Firstly, an original experimental campaign was performed on pre-tensioned members in HPFRC. A total number of six shear-critical beams of a 3.6 m span each, and two full scale beams of a 12 m span each, were tested in order to evaluate the shear and flexural strength. The principal parameter between the specimens was the fibres (...)
|
4 |
Shear strength of structural elements in high performance fibre reinforced concrete (HPFRC) / Comportement au cisaillement d'éléments de structures en béton fibré à hautes performances (BFHP)Moreillon, Lionel 19 March 2013 (has links)
Pour les poutres et les dalles ne comportant pas d'armatures de cisaillement, la résistance à l'effort tranchant ou au poinçonnement est souvent un critère important de dimensionnement. Ce type de rupture est caractérisé par un comportement fragile pouvant conduire à l'effondrement partiel voir total de la structure. Malgré de nombreuse recherche dans ce domaine, la résistance à l'effort tranchant et au poinçonnement des structure en béton armé ou précontraint demeure un phénomène complexe et dont l'approche normative est souvent empirique est simplifiée. La capacité des bétons renforcés de fibres métalliques à réduire voir à remplacer totalement les armatures de cisaillement des structures en béton armé et précontraint a été mis en évidence par plusieurs études expérimentales. Cependant, et malgré ses nombreux atouts, l'application à l'échelle industrielle des bétons de fibres est restée marginal, principalement due au manques d'un cadre normatif cohérent et reconnu. Les processus fixes d'une usine de préfabrication d'éléments en béton offre des possibilités optimales pour utiliser des matériaux cimentaires à hautes performances tel que les bétons autoplaçant, les bétons à hautes résistances, etc. Du point de vue de l'auteur, l'utilisation de bétons à hautes performances renforcés de fibres métalliques est le pas de développement et d'optimisation pour cette industrie. Les Bétons Fibrés à Hautes Performances (BFHP) reprennent une matrice similaire aux Bétons à Hautes Performances (BHP) auxquels est ajouté une certaine quantité de fibres métalliques conférant au matériau un comportement au niveau de la structure exploitable dans le dimensionnement. Les BFHP présentent un ratio résistances/coûts intéressant ainsi qu'une alternative au Béton Fibré Ultra-Performants (BFUP). L'objectif principal de ce travail est d'analyser le comportement au cisaillement et au poinçonnement d'éléments de structures en BFHP et en BFUP sans armatures de cisaillement et proposé des recommandations et des règles de dimensionnement adaptées aux ingénieurs de la pratique (…) / For members and flat slabs without shear reinforcement, the shear and punching shear strength are often the determining design criteria. These failure modes are characterized by a fragile behaviour implying possible partial or total collapse of the structure. Despite extensive research in this field, shear and punching shear in reinforced and prestressed concrete structures, remain complex phenomena so much that the current approach is often empirical or simplified. The ability of Steel Fibre Reinforced Concrete (SFRC) to reduce shear reinforcement in reinforced and prestressed concrete members and slabs,or even eliminate it, is supported by several experimental studies. However its practical application remains marginal mainly due to the lack of standard, procedures and rules adapted to its performance. The stationary processes in precast industry offer optimal possibilities for using high performance cementitious materials such as Self Compacting Concrete (SCC) and High Strength Concrete (HSC). For the author, the combination of High Performance Concrete and steel fibres is the following step in the development and the optimization of this industry. The High Performance Fibre Reinforced Concrete (HPFRC) stands between conventional SFRC and Ultra-High Performance Fibre Reinforced Concrete (UHPFRC). The HPFRC exhibiting a good strength/cost ratio is, thus, an alternative of UHPFRC for precast elements. The principal aim of this work was to analyse the shear and punching shear behaviour of HPFRC and UHPFRC structures without transversal reinforcement and to propose recommendations and design models adapted for practitioners. Several experimental studies on structural elements, i.e. beams and slabs, were undertaken for this purpose. Firstly, an original experimental campaign was performed on pre-tensioned members in HPFRC. A total number of six shear-critical beams of a 3.6 m span each, and two full scale beams of a 12 m span each, were tested in order to evaluate the shear and flexural strength. The principal parameter between the specimens was the fibres (…)
|
Page generated in 0.0958 seconds