TY - JOUR A1 - Yabuki, Nobuyoshi A1 - Yoshimura, Yutaka T1 - An Evaluation System for Steel Structures of Hydroelectric Power Stations based on Fault Tree Analysis and Performance Maps N2 - This paper presents an evaluation system for steel structures of hydroelectric power stations, including hydraulic gates and penstocks, based on Fault Tree Analyasis (FTA) and performance maps. This system consists of fault tree diagrams of FTA, performance maps, design and analysis systems, and engineerin databases. These four modules are integrated by appropriate hyperlinks so that the user of this system can use it easily and seamlessly. A well developed system was applied to some illustrative example cases, and they showed that the developed methodology and system worked well and the users found the system useful and effective for their maintenance tasks at powerstations. KW - Wissensmanagement KW - Stahlbau KW - Wasserkraftwerk Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-2564 ER - TY - JOUR A1 - Kicinger, Rafal A1 - Arciszewski, Tomasz A1 - De Jong, Kenneth T1 - Distributed Evolutionary Design: Island-Model-based Optimization of Steel Skeleton Structures in Tall Buildings N2 - This paper presents results of a study on distributed, or parallel, evolutionary computation in the topological design of steel structural systems in tall buildings. It describes results of extensive experimental research on various parallel evolutionary architectures applied to a complex structural design problem. The experiments were conducted using Inventor 2003, a networkbased evolutionary design support tool developed at George Mason University. First, a general introduction to evolutionary computation is provided with an emphasis on recent developments in parallel evolutionary architectures. Next, a discussion of conceptual design of steel structural systems in tall buildings is presented. Further, Inventor 2003 is briefly introduced as well as its design representation and evolutionary computation characteristics. Next, the results obtained from systematic design experiments conducted with Inventor 2003 are discussed. The objective of these experiments was to qualitatively and quantitatively investigate evolution of steel structural systems in tall buildings during a distributed evolutionary design process as well as to compare efficiency and effectiveness of various parallel evolutionary architectures with the traditional evolutionary design approaches. Two connectivity topologies (ring topology and fully-connected topology) have been investigated for four populations of structural designs evolving in parallel and using various migration strategies. Also, results of the initial sensitivity studies are reported in which two ways of initializing distributed evolutionary design processes were investigated, using either arbitrarily selected designs as initial parents or randomly generated ones. Finally, initial research conclusions are presented. KW - Mehragentensystem KW - Lernendes System KW - Stahlbau KW - Skelettbau KW - Optimierung Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-2195 ER - TY - JOUR A1 - Holtzhauer, Eric A1 - Saal, Helmut T1 - Product modelling in the steel construction domain N2 - The complexity of the relationships between the actors of a building project requires high efficiency in communication. Among other things, data sharing is crucial. The exchange of data is made possible by interfaces between expert programs, which rely on product models. The latter are neutral standards with formal definitions of building objects and their attributes. This paper deals with the state of the art and the research activities concerning product models in the steel construction domain and the advantages provided by this technology for the sector. KW - Produktmodell KW - Simulation KW - Bautechnik KW - Stahlbau Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-2415 ER - TY - THES A1 - Lehmkuhl, Hansjörg T1 - Zur praktischen Anwendung numerischer Analysemethoden für Stabilitätsprobleme T1 - The application of numerical methods to stability problems in practice N2 - In der täglichen Ingenieurpraxis werden in zunehmenden Maße numerische Analysen im Rahmen der Finite-Elemente-Methode auch zur Untersuchung stabilitätsgefährdeter Strukturen eingesetzt. Für die aktuelle Praxis, insbesondere im konstruktiven Stahlbau, ist jedoch festzustellen, dass zwischen der fortgeschrittenen Theorie und dem Niveau der praktischen Anwendung numerischer Stabilitätsanalysen eine große Kluft besteht. Aus praktischer Sicht erscheint es unumgänglich, die weiter wachsende Diskrepanz zwischen den umfangreichen theoretischen Möglichkeiten und der gegenwärtigen Praxis abzubauen. Damit steht der praktisch tätige Ingenieur vor der Aufgabe, sein Wissen auf dem Gebiet numerischer Stabilitätsanalysen zu vertiefen und bereits vorhandene FE-Programme um Berechnungsalgorithmen für umfassende numerische Stabilitätsanalysen zu erweitern. Dafür werden in der Arbeit die Grundlagen einer FEM- orientierten modernen Stabilitätstheorie einheitlich und aus Sicht einer praktischen Anwendung aufbereitet. Die Darstellung von realisierten programmtechnischen Umsetzungen für erweiterte Analysenmethoden wie Nachbeulanalysen, Pfadwechsel und Approximationen imperfekter Pfade ermöglicht eine Erweiterung des Methodenvorrates. Die innerhalb der Arbeit untersuchten Beispiele zeigen, dass durch die Anwendung der behandelten Verfahren das Tragverhalten einer stabilitätsgefährdeten Struktur wesentlich besser eingeschätzt werden kann als bei Beschränkung auf die herkömmlichen Analysemethoden. N2 - The daily engineering practice is characterized by an increasing use of numerical analyses also for structures influenced by stability problems. However it must be noticed that in practice, especially in steel construction, exists a large gap between the advanced stability theory and the level of practical applications of numerical stability analyses. From a practical point of view it seems be absolutely necessary to break up the continual growing discrepancy between comprehensive theoretical possibilities and current practice. Therefore practical engineers have to deepen their knowledge on the field of numerical stability analyses and have to expand existing finite element programs with special algorithms. For this purpose basics of a finite element orientated modern stability theory are presented from the view of practical application. Furthermore steps are shown for programming special methods like post-buckling analyses, path switching and approximations for load-deformation pathes including imperfections. The importance of the additional methods for a better understanding of the structures stability behaviour clearly comes out by the presentation of different examples of practical relevance. KW - Nichtlineare Stabilitätstheorie KW - Finite-Elemente-Methode KW - Stabilität KW - Stahlbau KW - Imperfektion KW - Nachbeulverhalten KW - Schale KW - Non-linear buckling KW - Finite Element Method KW - stability theory KW - post-buckling analysis KW - koiter approximation Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20051013-7102 ER -