Global ETD Search

51	放熱量最大化を目的とした非定常熱伝導場の形状最適化 AZEGAMI, Hideyuki, IWATA, Yutaro, KATAMINE, Eiji, 畔上, 秀幸, 岩田, 侑太朗, 片峯, 英次 07 1900 (has links) No description available. Traction Method Shape Optimization Heat Conduction Heat Transfer Design Numerical Analysis Finite Element Method Inverse Problem Optimum Design
52	複数荷重を考慮した線形弾性体の多目的形状最適化(平均コンプライアンス最小化問題を例として) 下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki 02 1900 (has links) No description available. Optimum Design Computational Mechanics Finite-Element Method Structural Analysis Domain Optimization Multiobjective Optimization Pareto Solution Traction Method Multiply Connected Domain
53	非定常熱伝導場における形状同定問題の解法片峯, 英次, Katamine, Eiji, 畔上, 秀幸, Azegami, Hideyuki, 松浦, 易広, Matsuura, Yasuhiro 01 1900 (has links) No description available. Inverse Problem Optimum Design Numerical Analysis Unsteady Heat-Conduction Finite-Element Method Domain Optimization Shape Identification Traction Method
54	複数荷重を考慮した線形弾性体の形状最適化 (力法による体積最小設計) 下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 井原, 久, Ihara, Hisashi, 桜井, 俊明, Sakurai, Toshiaki 07 1900 (has links) No description available. Optimum Design Computational Mechanics Finite-Element Method Structural Analysis Shape Optimization Minimum Volume Design Multiple Loading Traction Method Multiconstraint
55	Otimização de risco estrutural baseada em confiabilidade / Reliability-based structural risk optimization Camila Cardozo Verzenhassi 28 March 2008 (has links) Em um ambiente competitivo, sistemas estruturais devem ser projetados levando-se em conta, além da funcionalidade, o custo total de construção e operação da estrutura, bem como a sua capacidade de geração de lucro. Os custos estão diretamente ligados ao risco que a construção e operação da estrutura oferecem. O risco deve ser entendido como o produto de um custo esperado de falha pela probabilidade de que essa falha aconteça. A segurança da estrutura está diretamente relacionada com os coeficientes de segurança adotados em projeto. Verifica-se, portanto, que a minimização do custo total de um sistema estrutural passa, necessariamente, por uma otimização do nível de segurança para o qual o sistema é projetado. Diante desses fatos, neste trabalho realiza-se a busca do coeficiente de segurança parcial ótimo que minimiza o custo esperado total de sistemas estruturais: a chamada otimização de risco baseada em confiabilidade. Para tanto, foi desenvolvido um programa computacional em Fortran que encontra o coeficiente de segurança ótimo. Tal programa está acoplado a um programa de análise de confiabilidade estrutural desenvolvido na EESC/USP e a um programa comercial de elementos finitos. O trabalho inclui alguns estudos de caso, entre eles o de uma torre de telefonia sujeita a cargas de vento e de tornado. Esses estudos mostram que quando parcelas não estruturais dominam o custo, um projeto super-dimensionado não representa grande perda econômica, enquanto um projeto sub-dimensionado pode causar enormes prejuízos. O trabalho aponta que a confiabilidade ótima é altamente dependente das conseqüências e custos de falha. Mostra também que casualidades que possuem grande incerteza e grandes conseqüências de falha tendem a dominar o projeto. O estudo indica que, em situações de projeto diferentes (e.g., carregamentos diferentes), é razoável trabalhar-se com níveis de confiabilidade distintos. Além disso, mostra que a falta de percepção do risco pelas partes envolvidas em um projeto pode levar a contratos inadequados. Finalmente, o estudo revela que para uma estrutura submetida a carregamentos que variam com o tempo, como tornados, o custo e a confiabilidade ótimos são altamente dependentes da vida útil adotada para o projeto. / In a competitive environment, structural systems must be designed considering not only their function, but also their total costs of construction and operation and their ability to generate profit. The costs are directly linked to the risk resulting from construction and operation of the structure. Risk is defined as the product of failure cost by failure probability. The safety of the structure is directly related to safety coefficients adopted in design. Hence, the minimization of the total cost of a structural system necessarily involves an optimization of the safety level for which the system is designed. Based on these facts, the present study investigates the partial safety factor which minimizes the total expected cost of specific structural systems. This is referred to as reliability-based risk optimization. A Fortran computer code is developed to find the optimum safety factor. This code works together with a structural reliability analysis program developed at EESC/USP and with a commercial finite element program. Some case studies are presented, including the design of a steel frame communications tower, subjected to extreme storm and tornado wind loads. These studies show that when non-structural terms dominate the cost function, it is not too costly to over-design, but an under-designed project can cause huge money losses. The study shows that optimum reliability is strongly dependant on limit state exceedance consequences. It also shows that events with high uncertainty and high failure consequences generally dominate the design, and that for different design situations (e.g., multiple hazards) it is reasonable to work with different reliability levels. Moreover, it shows that when risk is not properly understood, it is also not properly dealt with by the parties involved, leading to inadequate contracts. Finally, the study shows that for structures under time-varying loads, such as tornados, the optimum reliability is strongly dependent on the selected design life. Confiabilidade estrutural Minimização de custo Otimização Projeto ótimo Risco Minimum design cost Optimum design Reliability-based risk optimization Structural reliability
56	Optimum design of one way concrete slabs cast against Textile Reinforced Concrete Stay-in-Place Formwork Elements Papantoniou, Ioannis, Papanicolaou, Catherine, Triantafillou, Thanasis 03 June 2009 (has links) This study presents a conceptual design process for one-way reinforced concrete slabs cast over Textile Reinforced Concrete (TRC) Stay-in-Place (SiP) formwork elements, aiming at the minimization of the composite slab cost satisfying Ultimate Limit State (ULS) and Serviceability Limit State (SLS) design criteria. The thin-walled TRC element is considered to participate in the structural behaviour of the composite slab. This distinct function of the TRC element (as formwork and as a part of a composite element) distinguishes the design procedure into two States: a Temporary and a Permanent one. Design parameters such as the type of the textile reinforcement (material), the geometry of the TRC cross-section, the flexural strength of the fine-grained concrete in the TRC element and the compressive strength of the cast in-situ concrete are considered as the main optimization variables. info:eu-repo/classification/ddc/620 ddc:620
57	位相最適化と形状最適化の統合による多目的構造物の形状設計(均質化法と力法によるアプローチ) 井原, 久, Ihara, Hisashi, 下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki 04 1900 (has links) No description available. Optimum Design Computational Mechanics Structural Analysis Finite-Element Method Shape Optimization Topology Optimization Traction Method Homogenization Method Multiobjective Optimization Multiobjective Structure
58	応力分布を規定した連続体の境界形状決定下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki 10 1900 (has links) No description available. Optimum Design Computational Mechanics Finite-Element Method Shape Identification Shape Optimization Stress Control Traction Method Adjoint Method von Mises Stress Uniform Stress Material Derivative
59	ホモロガス変形を目的とする連続体の形状決定下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki 12 1900 (has links) No description available. Optimum Design Computational Mechanics Finite-Element Method Structural Analysis Shape Identification Shape Optimization Homologous Deformation Homology Design Displacement Control Traction Method Adjoint Variable Method Material Derivative
60	固有振動問題における領域最適化解析　(質量最小化問題) 呉, 志強, WU, Zhi Chang, 畔上, 秀幸, Azegami, Hideyuki, 下田, 昌利, Shimoda, Masatoshi, 桜井, 俊明, Sakurai, Toshiaki 07 1900 (has links) No description available. Optimum Design Computer-Aided Design Finite-Element Method Vibration of Continuous System Modal Analysis Demain Optimization Speed Method Gradient Method Traction Method

Search results