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11	Analysis of assumptions made in design of reinforcement in Slender Reinforced Concrete (Tilt-Up) panels with openings Schwabauer, Brandon January 1900 (has links) Master of Science / Department of Architectural Engineering and Construction Science / Kimberly W. Kramer / This report uses and references (Analysis of Vertical Reinforcement in Slender Reinforced Concrete (Tilt-up) Panels with Openings & Subject to Varying Wind Pressures) (Bartels, 2010) to investigate the design philosophy and assumptions used in Section 14.8 of the ACI 318-08 (ACI Committee 318, 2008). The design philosophy and assumptions are analyzed to determine the applicability and accuracy of Section 14.8 of the ACI 318-08 (ACI Committee 318, 2008) to the design and analysis of slender concrete panels with openings. Special emphasis is placed on identifying and quantifying the degree of effect that each assumption has on the final design of the panel. These topics include stress distribution around openings, the effect of varying stiffness of the member on the P-delta effect, stiffness variations due to workmanship and tolerances, and the effect of axial load on the stiffness of the member. This is accomplished through the use of specially designed computer analyses that isolate an assumption or effect to determine its impact on the final design. This study shows that two-way effects are almost non-existant, the portion of the panel above the opening has very little effect on the P-delta effects, the code specified reduction in bending stiffness due to workmanship and tolerances appear to be appropriate, and the effective area of reinforcement overestimates the stiffness of the panel. Tilt-up concrete panels Slender reinforced concrete panels Engineering, Civil (0543)
12	Buckling behavior of reinforced concrete plate models Seck, Abdoulaye Yaya January 2011 (has links) Typescript (photocopy). / Digitized by Kansas Correctional Industries Concrete panels--Testing Materials--Dynamic testing Buckling (Mechanics)
13	Seismic performance of precast concrete cladding systems. Baird, Andrew January 2014 (has links) Structural engineering is facing an extraordinarily challenging era. These challenges are driven by the increasing expectations of modern society to provide low-cost, architecturally appealing structures which can withstand large earthquakes. However, being able to avoid collapse in a large earthquake is no longer enough. A building must now be able to withstand a major seismic event with negligible damage so that it is immediately occupiable following such an event. As recent earthquakes have shown, the economic consequences of not achieving this level of performance are not acceptable. Technological solutions for low-damage structural systems are emerging. However, the goal of developing a low-damage building requires improving the performance of both the structural skeleton and the non-structural components. These non-structural components include items such as the claddings, partitions, ceilings and contents. Previous research has shown that damage to such items contributes a disproportionate amount to the overall economic losses in an earthquake. One such non-structural element that has a history of poor performance is the external cladding system, and this forms the focus of this research. Cladding systems are invariably complicated and provide a number of architectural functions. Therefore, it is important than when seeking to improve their seismic performance that these functions are not neglected. The seismic vulnerability of cladding systems are determined in this research through a desktop background study, literature review, and postearthquake reconnaissance survey of their performance in the 2010 – 2011 Canterbury earthquake sequence. This study identified that precast concrete claddings present a significant life-safety risk to pedestrians, and that the effect they have upon the primary structure is not well understood. The main objective of this research is consequently to better understand the performance of precast concrete cladding systems in earthquakes. This is achieved through an experimental campaign and numerical modelling of a range of precast concrete cladding systems. The experimental campaign consists of uni-directional, quasi static cyclic earthquake simulation on a test frame which represents a single-storey, single-bay portion of a reinforced concrete building. The test frame is clad with various precast concrete cladding panel configurations. A major focus is placed upon the influence the connection between the cladding panel and structural frame has upon seismic performance. A combination of experimental component testing, finite element modelling and analytical derivation is used to develop cladding models of the cladding systems investigated. The cyclic responses of the models are compared with the experimental data to evaluate their accuracy and validity. The comparison shows that the cladding models developed provide an excellent representation of real-world cladding behaviour. The cladding models are subsequently applied to a ten-storey case-study building. The expected seismic performance is examined with and without the cladding taken into consideration. The numerical analyses of the case-study building include modal analyses, nonlinear adaptive pushover analyses, and non-linear dynamic seismic response (time history) analyses to different levels of seismic hazard. The clad frame models are compared to the bare frame model to investigate the effect the cladding has upon the structural behaviour. Both the structural performance and cladding performance are also assessed using qualitative damage states. The results show a poor performance of precast concrete cladding systems is expected when traditional connection typologies are used. This result confirms the misalignment of structural and cladding damage observed in recent earthquake events. Consequently, this research explores the potential of an innovative cladding connection. The outcomes from this research shows that the innovative cladding connection proposed here is able to achieve low-damage performance whilst also being cost comparable to a traditional cladding connection. It is also theoretically possible that the connection can provide a positive value to the seismic performance of the structure by adding addition strength, stiffness and damping. Finally, the losses associated with both the traditional and innovative cladding systems are compared in terms of tangible outcomes, namely: repair costs, repair time and casualties. The results confirm that the use of innovative cladding technology can substantially reduce the overall losses that result from cladding damage. Cladding Precast concrete panels Non-structural elements
14	Buckling behavior of reinforced concrete wall panel models Munoz, Arturo C January 2011 (has links) Typescript (photocopy). / Digitized by Kansas Correctional Industries Concrete panels Precast concrete Concrete--Testing Concrete--Fatigue
15	Research on the application of concrete/steel panels in a composite building construction system Szepesi, George Pal January 1978 (has links) Thesis. 1978. M.Arch.A.S.--Massachusetts Institute of Technology. Dept. of Architecture. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND ROTCH. / by George Szepesi. / M.Arch.A.S. Architecture Reinforced concrete construction Concrete panels Industrialized building
16	Documentation of the rapid replacement of four GDOT bridge decks Umphrey, Joshua Matthew, Ramey, George E. January 2006 (has links) (PDF) Thesis(M.S.)--Auburn University, 2006. / Abstract. Vita. Includes bibliographic references (p.200).
17	A cost study of an American precast panel system. Moghadam, Hamid Reza. January 1978 (has links) Thesis: M.S., Massachusetts Institute of Technology, Department of Civil Engineering, 1978 / Bibliography: p. 195-199. / M.S. / M.S. Massachusetts Institute of Technology, Department of Civil Engineering Civil Engineering Concrete panels. Dwellings Estimates.
18	Development of a Precast Concrete Supertile Roofing System for the Mitigation of Extreme Wind Events Mintz, Brandon L 03 July 2014 (has links) Residential roofs have traditionally formed the weakest part of the structure. The connections of roofs to the walls has lacked a clear load path with the result that the structure is weak at this point, leading to the compromise of the structure. Indeed roofs have multiple points of failure that lead to the weakness of the residential structure as a whole. Even if structural failure does not occur, compromise the roofing membrane can lead to high repair costs and property loss. The failure lies in the complex forming of the roof components as the roof aesthetics are placed to protect the underlayment and the underlayment protects the sheathing and trusses. However, the aesthetics, such as the roof tile, not being structural can be damaged easily and lead to the compromise of the roofing system as well as endangering surrounding structures. The shape of the roof tile lends itself well to structural design. The wave motion leads to structural redundancy and provides a significant ability to provide stiffness. Using the shape of the roof tile, a structure can be created to encapsulate the shape and provide structural strength. The aesthetics are already accounted for in the shape and the shape is strengthened according to necessity. A system has been devised for flexural strength and applicable connections to demonstrate the constructability and feasibility of creating and using such a system. Design concepts are accounted for, the components are tested and confirmed, and a full-scale test is carried out to demonstrate the concepts ability as a system. The outgrowth of this work is to produce design tables that allow the designer the ability to design for certain building conditions. Taking the concepts of flexural strength and wall to roof, panel to panel, and ridge connections, the design is broken down into appropriate design parameters. Tables are developed that allow the concept to be used under different structural conditions and geographical needs. The conclusion allows us to show specifically how the concept can be applied in specific geographical regions. Precast concrete panels Fiber-reinforced polymers (FRP) Residential roofing Wind mitigation Civil Engineering Structural Engineering
19	Análise estrutural de painéis de concreto pré-moldado considerando a interação com a estrutura principal / Structural analysis of precast concrete panels considering the interaction with the main frame Castilho, Vanessa Cristina de 25 September 1998 (has links) No presente trabalho trata-se de um estudo da contribuição de painéis pré-moldados de fechamento no enrijecimento da estrutura principal, com relação às ações laterais. Inicialmente são apontados os critérios correntes de dimensionamento dos painéis pré-moldados de fechamento sem a consideração da interação destes com a estrutura principal. Em seguida, são desenvolvidas simulações numéricas em três exemplos com o objetivo de avaliar tal efeito. Estes exemplos englobam as seguintes situações: painel isolado, estrutura de um pavimento e uma estrutura de vários pavimentos. Os principias parâmetros analisados são os deslocamentos na estrutura principal, os esforços nas ligações e as tensões nos painéis. Os resultados obtidos mostram a importância da contribuição dos painéis no enrijecimento da estrutura principal. Na estrutura de um único pavimento analisada, a consideração de interação possibilita a passagem de situação em que os efeitos globais de segunda ordem são relevantes para aquela em que tais efeitos são desprezíveis. Para a estrutura analisada de vários pavimentos, a consideração de interação resulta em significativas economias de materiais apontando para economia da ordem de 20% na estrutura principal. Com base nos resultados, conclui-se que os painéis de fechamento pode ser incorporados numa estratégia de projeto, possibilitando economia na estrutura principal. / This work presents a study of the precast panels contribution in the main frame stiffness, subjected to lateral loads. At first, currents criteria of panels design are analyzed, without considering the interaction with the main frame. After that, three examples are calculated using numerical simulation to evaluate this effect. These examples include the following situations: a single panel, an one-story frame and a multi-story frame. The parameters are: the frame displacements, the connections efforts and the panels tensions. The results show the magnitude of the panels contribution. In fact, to the one-story frame, it was possible to pass from a flexible structure where the second-order effects must be taken into account to an other one where this effects could be neglected. For the multi-story frame analysis, the panels contribution produced an effective material economy of about 20% (and consequent cost reduction). Basing on these results, one can conclude that the infill panels can be included in the design strategy with economy for the structural system. Connections deformability Deformabilidades das ligações Interaction of the infill with the frame Painéis pré-moldados Precast concrete panels
20	Controlling cracking in precast prestressed concrete panels Azimov, Umid 29 October 2012 (has links) Precast, prestressed concrete panels (PCPs) have been widely used in Texas as stay-in-place formwork in bridge deck construction. Although PCPs are widely popular and extensively used, Texas is experiencing problems with collinear cracks (cracks along the strands) in panels. One reason for the formation of collinear cracks is thought to be the required level of initial prestress. Currently, PCPs are designed assuming a 45-ksi, lump-sum prestress loss. If the prestress losses are demonstrated to be lower than this value, this could justify the use of a lower initial prestress, probably resulting in fewer collinear cracks. For this purpose, 20 precast, prestressed panels were cast at two different plants. Half of those 20 panels were fabricated with the current TxDOT-required prestress of 16.1 kips per strand, and the other half were fabricated with a lower prestress of 14.4 kips per strand based on initially observed prestress losses of 25 ksi or less. Thirteen of those panels were instrumented with strain gages and monitored over their life time. Observed losses stabilized after five months, and are found to be about 24.4 ksi. Even with the reduced initial prestress, the remaining prestress in all panels exceeds the value now assumed by TxDOT for design. / text Precast panels Bridge deck panels Precast prestressed concrete panels Prestressed panels PCP Prestress loss Panel cracking Collinear cracking Crack control

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