Please use this identifier to cite or link to this item: http://hdl.handle.net/1942/42717
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dc.contributor.authorENGELEN, Tine-
dc.contributor.authorCASASOLA PAESA, Marta-
dc.contributor.authorDAENEN, Michael-
dc.contributor.authorVANDOREN, Bram-
dc.date.accessioned2024-03-27T14:06:39Z-
dc.date.available2024-03-27T14:06:39Z-
dc.date.issued2023-
dc.date.submitted2024-03-20T13:07:43Z-
dc.identifier.citation18th Advanced Building Skins Conference & Expo, Bern, Switzerland, 30-31 October 2023-
dc.identifier.isbn978-3-9524883-9-3-
dc.identifier.urihttp://hdl.handle.net/1942/42717-
dc.description.abstractThere is an increase in interest in timber as a material for the design of the load-bearing system of a building. At the same time, large glass façades are often desired in modern buildings. Additionally, the production of green energy is an increasingly important design principle for buildings. These three requirements can be combined in a structural timber-glass façade with integrated photovoltaics, which is the topic of this contribution. However, there is a lack of design rules for these systems. The timber-glass connection design is developed in this work to exploit the in-plane stiffness of the glass panel and increase the horizontal stability of the underlying timber structure. A detailed numerical model is validated with experimental tensile and shear tests on the connections. Additionally, the glass/glass photovoltaic elements are studied with a numerical model that predicts stresses and strains in the glass and the solar cells under various loading conditions. Experimental in-and out-of-plane bending tests are performed on glass/glass photovoltaic (PV) modules to validate the numerical results. With this combined numerical-experimental approach, reliable models are made that can be used for designing structural timber-glass façade elements with integrated photovoltaics.-
dc.language.isoen-
dc.rights© Copyright: Advanced Building Skins GmbH-
dc.subject.otherGlass-
dc.subject.otherPhotovoltaics-
dc.subject.otherTimber-
dc.subject.otherComposite-
dc.subject.otherFEM-
dc.subject.otherExperimental-
dc.titleDevelopment and analysis of structural timber-glass façade systems with integrated photovoltaics-
dc.typeConference Material-
local.bibliographicCitation.authorsAdvanced Buildin Skins Gmbh-
local.bibliographicCitation.conferencedate30-31 October 2023-
local.bibliographicCitation.conferencename18th Advanced Building Skins Conference & Expo-
local.bibliographicCitation.conferenceplaceBern, Switzerland-
local.bibliographicCitation.jcatC2-
dc.relation.references[1] W. Hochhauser, “Ein Beitrag zur Berechnung und Bemessung von geklebten und geklotzten Holz-Glas-Verbundscheiben,” TU wien, 2011. [2] W. Winter, W. Hochhauser, and K. Kreher, “Load bearing and stiffening timber-glass-composites (TGC),” 11th World Conference on Timber Engineering 2010, WCTE 2010, vol. 1, no. December, pp. 147–155, 2010. [3] F. Konstruktiver Glasbau eV, “Structural Silicone Sealants in Structural Glass Systems,” 2021. [Online]. Available: www.glas-fkg.org [4] V. Rosliakova, F. Nicklisch, and B. Weller, “A review of possibilities to integrate photovoltaic in a load ‐ bearing timber ‐ glass façade,” Conference: Advanced Building Skins, no. November, pp. 1–10, 2015, doi: 10.13140/RG.2.1.2920.9681. [5] N. Perković, V. Rajčić, C. Bedon, J. Barbalić, and R. Žarnić, “Basis of Guidelines for Structural Design and Thermal Assessment of Buildings with Hybrid CLT-Glass Elements,” International Journal of Structural Glass and Advanced Materials Research, vol. 4, no. 1, pp. 97–113, 2020, doi: 10.3844/sgamrsp.2020.97.113. [6] M. Feldmann and R. Kasper, “Guidance for European Structural Design of Glass Components,” 2014. doi: 10.2788/5523. [7] E. Gutiérrez, S. Dimova, and A. Pinto, “Purpose and Justification for New Design Standards Regarding the Use of Glass in Civil Engineering Works,” 2007. [8] M. Kozłowski, M. Dorn, and E. Serrano, “Experimental testing of load-bearing timber–glass composite shear walls and beams,” Wood Mater Sci Eng, vol. 10, no. 3, pp. 276–286, 2015. [9] B. Ber, M. Premrov, A. Štrukelj, and M. Kuhta, “Experimental investigations of timber-glass composite wall panels,” Constr Build Mater, vol. 66, pp. 235–246, 2014, doi: 10.1016/j.conbuildmat.2014.05.044. [10] P. Nivelle and M. Daenen, “Thermal monitoring in laminate structures Europe Patent EP20175245,” 2020 [11] P. Nivelle, L. Maes, J. Poortmans, and M. Daenen, “In situ quantification of temperature and strain within photovoltaic modules through optical sensing,” Progress in Photovoltaics: Research and Applications, 2022, doi: 10.1002/pip.3622.-
local.type.refereedNon-Refereed-
local.type.specifiedConference Material-
local.provider.typePdf-
local.bibliographicCitation.btitle18th Advanced Buildin Skins Conference & Expo-
local.uhasselt.internationalno-
item.accessRightsRestricted Access-
item.fullcitationENGELEN, Tine; CASASOLA PAESA, Marta; DAENEN, Michael & VANDOREN, Bram (2023) Development and analysis of structural timber-glass façade systems with integrated photovoltaics. In: 18th Advanced Building Skins Conference & Expo, Bern, Switzerland, 30-31 October 2023.-
item.fulltextWith Fulltext-
item.contributorENGELEN, Tine-
item.contributorCASASOLA PAESA, Marta-
item.contributorDAENEN, Michael-
item.contributorVANDOREN, Bram-
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