Design of Composite Skin Panels with Solar Panels on the Roof

Authors

  • Serhiy Shkirenko

  • Volodymyr Muravlov

  • Oleksandr Zyma

How to Cite

Shkirenko, S., Muravlov, V., & Zyma, O. (2018). Design of Composite Skin Panels with Solar Panels on the Roof. International Journal of Engineering and Technology, 7(3.2), 398-400. https://doi.org/10.14419/ijet.v7i3.2.14560

Received date: June 23, 2018

Accepted date: June 23, 2018

Published date: June 20, 2018

DOI:

https://doi.org/10.14419/ijet.v7i3.2.14560

Keywords:

solar panels, roof members, two-sided composite skin panel, design of building constructions.

Abstract

An example of typical two-sided composite (timber and plywood) skin panel design to be used as a roof member with solar panels.

 

References

  1. [1] APA (1990), Design and fabrication of plywood stressed-skin panels, Supplement 3, Form No. U813L.Tacoma,Washington,USA

    [2] Arons, D. M. (2000), Properties and applications of double-skin building facades. Thesis (S.M.),MassachusettsInstitute ofTechnology,Boston.

    [3] APA (2014), Plywood design specification. design and fabrication of plywood stressed-skin panels, Supplement 3–12, Form No. U813M.Tacoma,Washington,USA.

    [4] .Raadschelders JGM, Blass HJ (1995), Stressed skin panels. STEP 1. Timber engineering. Basis of design, material properties, structural components and joints. Lecture B10, Centrum Hout, Netherland.

    [5] Gagnon S, Popovski M (2011), Structural design of cross-laminated timber elements, CLT handbook, Chapter 3, FP innovations Special Publication SP-528E,Quebec,Canada

    [6] Blass H, Fellmoser P (2004), Design of solid wood panels with cross layers, In: Proceedings of the 8th world conference on timber engineering (WCTE), vol 2,Lahti,Finland, pp 543–548.

    [7] EOTA (2000), Test methods for light composite wood-based beams and columns. TR002, European Organization for Technical Assessment,Brussels,Belgium.

    [8] EOTA (2005), Calculation models for prefabricated wood-based load-bearing stressed skin panels for use in roofs, TR019, European Organization for Technical Assessment,Brussels,Belgium.

    [9] Forest Products Laboratory (2010), Wood handbook: wood as an engineering material, chap. 5.USDAForest Service, Madison.

    [10] Gaspar F, Cruz H, Gomes A (2008) Evaluation of glued laminated timber structures—core extraction and shear testing. In: Proceedings of the world conference on timber engineering (WCTE),Miyazaki,Japan, pp 255–262.

    [11] Werner Weiss, Solar heating systems for houses: a design handbook for solar combisystems,London: James & James, (2003).

    [12] Munari Probst MC, Roecker C (2012), Innovative solar products for building integration, Solar energy and Architecture T.41.A.6 of IEA SHC 41.

    [13] Roberts S, Guariento N, (2009). Building integrated photovoltaics: a handbook,Basel, Walter de Gruyter.

    [14] Munari Probst MC, Roecker C (2014), Designing solar thermal systems for architectural integration, Solar energy and Architecture, Deliverable T.41. A.3 of IEA SHC 41.

    [15] https://unirac.com/

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How to Cite

Shkirenko, S., Muravlov, V., & Zyma, O. (2018). Design of Composite Skin Panels with Solar Panels on the Roof. International Journal of Engineering and Technology, 7(3.2), 398-400. https://doi.org/10.14419/ijet.v7i3.2.14560

Received date: June 23, 2018

Accepted date: June 23, 2018

Published date: June 20, 2018