Glass Failure Prediction Model for Out-of-Plane Bending of Waterjet- Drilled Holes
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Détails bibliographiques
Auteur(s): |
Joshua Schultz
(Gonzaga University, Spokane WA, USA)
John Knowles (Stutzki Engineering, Milwaukee WI, USA) Stephen Morse (Texas Tech University, Lubbock TX, USA) |
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Médium: | papier de conférence | ||||
Langue(s): | anglais | ||||
Conférence: | IABSE Symposium: Engineering the Future, Vancouver, Canada, 21-23 September 2017 | ||||
Publié dans: | IABSE Symposium Vancouver 2017 | ||||
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Page(s): | 2362-2369 | ||||
Nombre total de pages (du PDF): | 8 | ||||
Année: | 2017 | ||||
DOI: | 10.2749/vancouver.2017.2362 | ||||
Abstrait: |
Use of fully tempered (FT), point-supported glass (PSG) as structural elements has become increasingly common. However, current US glass design charts and analytical methods found in ASTM E1300 are only applicable to rectangular lites with continuous line supports along one or more edges. As a result, practitioners use finite element analysis to determine maximum principle stress that dictates glass thickness. However, sole reliance on the single largest maximum principle tensile stress (SLMPTS) may not always be representative of actual performance as surface flaws often precipitate failure at lower stresses and different locations from the SLMPTS. This paper analyzes the experimental data for 10 FT specimens with waterjet holes subject to out-of-plane bending. Experimental time histories are converted to the to 3-second failure loads for determination of best fit m- and k- values for use with the glass failure prediction model to determine stresses for a probability of breakage of 1 in 1,000 and 8 in 1,000 lites. |