Iea ebc energy in Buildings and Community Proposal for a new iea ecbcs‐Annex

REFERENCES

An example of deteriorated vacuum insulation panels in a building façade, Brunner, T. Stahl, K. Ghazi Wakili, Energy and Buildings 54 (2012) 278–282

Vacuum insulation panels – A promising solution for high insulated tanks: Benjamin Fuchsa, Klaus Hofbecka, Martin Faulstich, Energy Procedia 30 ( 2012 ) 424 – 427

Heat transfer modeling in vacuum insulation panels containing nanoporous silicas—A review : Mathias Bouquerel, Thierry Duforestel, Dominique Baillis, Gilles Rusaouen; Energy and Buildings 54 (2012) 320–336.

Baetens R., Jelle, B.P. and Gustavsen, A. (2011) Aerogel insulation for building applications: A state-of-the art review, Energy and Buildings, 43(4) 761 - 769

Buratti, C. and Moretti, E. Experimental performance evaluation of aerogel glazing systems Applied Energy http://dx.doi.org/10.1016/j.apenergy.2011.12.055

Stahl, Th., Brunner, S., Zimmermann, M. and Wakili K.G. (2012) Thermo-hygric properties of a newly developed aerogel based insulation rendering for both exterior and interior applications, Energy and Buildings, 44(1) 114 – 117

Wei, G., Liu, Y., Zhang, X. Yu, F. and Du, X. (2011) Thermal conductivities study on silica aerogel and its composite insulation materials, International Journal of Heat and Mass Transfer, 54(11) 2355 – 2366

Yang, X., Sun, Y., Shi, D. and Liu, J. (2011) Experimental investigation on mechanical properties of a fiber reinforced silica aerogel composite, Materials Science and Engineering: A, 528(13) 4830 – 4836

Baetens, R., Jelle, B.P., Gustavsen, A. and Grynning, S. (2010) Gas-filled panels for building applications: A state of-the-art review, Energy and Buildings, 42(11) 1969 – 1975

Baetens, R., Jelle, B.P., Thue, J.V., Tenpierik, M.J., Grynning, S. Uvslokk, S. and Gustavsen, A. (2010) Vacuum insulation panels for building applications: A review and beyond, Energy and Buildings, 42(2) 147 – 172

Brunner, S. and Simmler, H. (2008) In situ performance assessment of vacuum insulation panels in a flat roof construction, Vacuum, 82(7) 700 – 707

Fricke, J., Heinemann, U., and Ebert, H.P. (2008) Vacuum insulation panels---From research to market, Vacuum, 82(7) 680 - 690

Nordtest Method, NT Build 495, Building materials and components in the vertical position: Exposure to accelerated climatic strains”, Nordtest, 2000.

H. Schwab, U. Heinemann, A. Beck, H.-P. Ebert and J. Fricke, Permeation of different gases through foils used as envelopes for vacuum insulation panels, Journal of Thermal Envelope & Building Science, 28, 293-317, 2005.

H. Schwab, U. Heinemann, A. Beck, H.-P. Ebert and J. Fricke, ”Dependence of thermal conductivity on water content in vacuum insulation panels with fumed silica kernels”, Journal of Thermal Envelope & Building Science, 28, 319-326, 2005.

H. Schwab, U. Heinemann, J. Wachtel, H.-P. Ebert and J. Fricke, ”Predictions for the increase in pressure and water content of vacuum insulation panels (VIPs) integrated into building constructions using model calculations”, Journal of Thermal Envelope & Building Science, 28, 327-344, 2005.

H. Schwab, U. Heinemann, A. Beck, H.-P. Ebert and J. Fricke, ”Prediction of service life for vacuum insulation panels with fumed silica kernel and foil cover”, Journal of Thermal Envelope & Building Science, 28, 357-374, 2005.

H. Simmler, S. Brunner, U. Heinemann, H. Schwab, K. Kumaran, P. Mukhopadhyaya, D. Quènard, H. Sallèe, K. Noller, E. KücküpinarNiarchos, C. Stramm, M. Tenpierik, H. Cauberg and M. Erb, ”Vacuum Insulation Panels. Study on VIP-Components and Panels for Service Life Prediction in Building Applications (Subtask A)”, HiPTI - High Performance Thermal Insulation, IEA/ECBCS

Annex 39, September 2005.

M. Tenpierik, W. van der Spoel and H. Cauberg, ”Simplified analytical models for service life prediction of a vacuum insulation panel”, Proceedings of the 8th International Vacuum Insulation Symposium, 2007, ZAEBayern/Würzburg, September 18-19, 2007.

Va-Q-tec AG, ”va-Q-vip B – Product data”, http://www.va-q-tec.com/va-q-vip_b_en,2755.html

Wegger, E., Jelle B.P., Sveipe, E., Grynning, S., Gustavsen, A., Baetens, R. and Thue, J.V. (2011) Aging effects on thermal properties and service life of vacuum insulation panels, Journal of Building Physics, 35(2) 128-167

M. K. Willems, K. Schild and G. Hellinger, ”Numerical investigation on thermal bridge effects in vacuum insulating elements”, Proceedings of the 7th International Vacuum Insulation Symposium, EMPA, Duebendorf, Switzerland, 28-29 September, 2005, pp. 145-152, 2005.

Mavromatidis L.E., Bykalyuk A., Mankibi, M.E. and Michel, P. and Santamouris M. (2012) Numerical estimation of air gaps' influence on the insulating performance of multilayer thermal insulation, Building and Environment, 49(0) 227 – 237.

Saber, H.H. (2012) Investigation of thermal performance of reflective insulations for different applications, Building and Environment, 52(1) 32 – 44

Al-Homoud M.S. (2005) Performance characteristics and practical applications of common building thermal insulation materials, Building and Environment, 40(1) 353- 366

Pavlik Z. and Černy, R. (2009) Hygrothermal performance study of an innovative interior thermal insulation system, Applied Thermal Engineering, 29(10) 1941 – 1946

ETA : European Technical Assessment (www.eota.eu )

CUAP 12.01/30 Common Understanding of Assessment Procedure for European Technical Approval to Article 9.2 of the Construction Products Directive Factory made vacuum insulation panels Version June 2010

CUAP 12.01/36 Common Understanding of Assessment procedure for European Technical Approval according to Article 9.2 of the Construction Products Directive Fibre Reinforced Silica Aerogel Thermal Insulation June 2011
FP7 : European Projects

AEROCOINs ‐ Aerogel‐Based Composite / Hybrid Nanomaterials -

HIPIN ‐ HIgh Performance INsulation based on Nanostructure encapsulation of air

NANOFOAM ‐ New NANO‐technology based high performance insulation FOAM

NANOINSULATE ‐ Nanotechnology‐based High‐performance Opaque & Transparent Insulation Systems
LCA

Life cycle assessment of building materials: Comparative analysis of energy and environmental impacts and evaluation of the eco-efficiency improvement potential, Ignacio Zabalza Bribián, Antonio Valero Capilla, Alfonso Aranda Usón, Building and Environment 46 (2011) 1133e1140

http://en.wikipedia.org/wiki/Building_insulation_materials#Health_and_safety_issues

J. Noordegraaf, P.Matthijssen et all (2004): A comparative LCA of Building Insulation Products.

G. Sequeira (2012): Environmental impacts of the life cycle of thermal insulation materials of buildings.

Urge-Vorsatz, D. (2011) et al. Employment Impacts of a Large-Scale Deep Building Energy Retrofit Programme in Hungary. Center for Climate Change and Sustainable Energy Policy – Central European University & European Climate Foundation