haldimann matthias (9 resultados)

Softcover. 215 S. Ehem. Bibliotheksexemplar mit Signatur und Stempel. GUTER Zustand, ein paar Gebrauchsspuren. Ex-library with stamp and library-signature. GOOD condition, some traces of use. w15085 9783857481192 Sprache: Englisch Gewicht in Gramm: 550.

Paperback. Condición: Brand New. 215 pages. 9.40x6.70x0.60 inches. In Stock.

Taschenbuch. Condición: Neu. Neuware -For centuries, the use of glass in buildings was essentially restricted to functions such as windows and glazing. Recent technological developments have now brought about unprecedented opportunities. Glass elements can today carry substantial loads and therefore achieve a structural role. The structural design of such elements, however, remains problematic. The lack of confidence in ¿advanced¿ glass models and the absence of a generally agreed design method result in frequent time-consuming and expensive laboratory testing and in inadequately designed structural glass elements. The present thesis endeavours to improve this situation. After outlining the fundamental aspects of the use of glass as a building material, an analysis of present knowledge was conducted. Then a lifetime prediction model for structural glass elements, which offers significant advantages over currently used models, was established based on fracture mechanics and the theory of probability. Laboratory tests were performed and testing procedures improved in order to provide more reliable and accurate model input. Finally, recommendations for structural design and testing were developed.Books on Demand GmbH, Überseering 33, 22297 Hamburg 224 pp. Deutsch.

Paperback. Condición: Brand New. 215 pages. 9.40x6.70x0.60 inches. In Stock.

Gr.-8°. 215 S. m. einigen Fig., OKart., ausgeschied. Bibl.-Expl. mit den üblichen Kennzeichnungen. ISBN 9783857481192.

24 x 17 cm. 215 Seiten mit einigen Abbildungen. Original-Karton. Besitzeintrag auf hinterem Deckel innen, sonst gut und sauber. (Structural Engineering Documents Band 10). Sprache: englisch.

Taschenbuch. Condición: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -For centuries, the use of glass in buildings was essentially restricted to functions such as windows and glazing. Recent technological developments have now brought about unprecedented opportunities. Glass elements can today carry substantial loads and therefore achieve a structural role. The structural design of such elements, however, remains problematic. The lack of confidence in 'advanced' glass models and the absence of a generally agreed design method result in frequent time-consuming and expensive laboratory testing and in inadequately designed structural glass elements. The present thesis endeavours to improve this situation. After outlining the fundamental aspects of the use of glass as a building material, an analysis of present knowledge was conducted. Then a lifetime prediction model for structural glass elements, which offers significant advantages over currently used models, was established based on fracture mechanics and the theory of probability. Laboratory tests were performed and testing procedures improved in order to provide more reliable and accurate model input. Finally, recommendations for structural design and testing were developed. 224 pp. Deutsch.

Condición: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. For centuries, the use of glass in buildings was essentially restricted to functions such as windows and glazing. Recent technological developments have now brought about unprecedented opportunities. Glass elements can today carry substantial loads and ther.

Taschenbuch. Condición: Neu. nach der Bestellung gedruckt Neuware - Printed after ordering - For centuries, the use of glass in buildings was essentially restricted to functions such as windows and glazing. Recent technological developments have now brought about unprecedented opportunities. Glass elements can today carry substantial loads and therefore achieve a structural role. The structural design of such elements, however, remains problematic. The lack of confidence in 'advanced' glass models and the absence of a generally agreed design method result in frequent time-consuming and expensive laboratory testing and in inadequately designed structural glass elements. The present thesis endeavours to improve this situation. After outlining the fundamental aspects of the use of glass as a building material, an analysis of present knowledge was conducted. Then a lifetime prediction model for structural glass elements, which offers significant advantages over currently used models, was established based on fracture mechanics and the theory of probability. Laboratory tests were performed and testing procedures improved in order to provide more reliable and accurate model input. Finally, recommendations for structural design and testing were developed.