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Abstract

In a previous paper by the same author [1], a simplified analysis of the heat and moisture response of protected membrane roofs (PMR) was discussed. The analysis included a ΔU-correction to the thermal transmission coefficient U of the equivalent, conventional roof to account for the effects of percolation, evapora tion, and butt joint losses between the insulation boards. This second paper presents experimental results.

The hygrothermal performances of five Protected Membrane Roof systems (PMR) were monitored to a varying degree of completeness for a number of years in the period between 1981-1992. The systems included extruded polystyrene boards, mineral fibre boards, a composite foam-concrete board manufactured with expanded polystyrene, and a composite foam-concrete board manufactured with extruded polystyrene.

The monitoring indicated that the heat and moisture response of a protected mem brane roof is substantially reduced when ponding water is present either below or above the insulation. The reduction increases when the vapour diffusion resistance of the insulation material is low. Both conclusions supported the ΔU-correction, derived from the simple model. They have prompted changes in the design of PMRs and modifications to the corresponding design rules.

Keywords

thermal insulation protected membrane roof mineral fibre ex panded polystyrene extruded polystyrene field testing moisture flow heat flow laboratory tests thermal resistance.

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References

Hens, H. 1995. "Protected Membrane Roofs: A Simplified Heat and Moisture Analysis," Journal of Thermal Insulation and Building Envelopes , 18:377-389.

Hedlin, C.P. 1974. "Moisture Attack on Insulations in Protected Membrane Roofing," Paper 2.7.3 of the CIB-RILEM Rotterdam Conference on Moisture Problems in Buildings

Hedlin, C.P. 1975. "Moisture Content in Protected Membrane Roof Insulation—Effect of Design Features," ASTM Symposium on Roofing Systems , Montreal.

Künzel, H. 1977. "Feuchtigkeitsverhältnisse, Temperaturverhältnisse und Warme-schutz bei nicht belufteten Flachdachern mit uber der Abdichtung angebrachter Wärmedämmung aus PSE, FhG, IBP," rapport B Ho 5/77.

Christensen, G. , M. Vesterlokke and K. Prebensen. 1986. "Sammenligning Mellem Retvendt og Omvendt Merisolering of Flade Tage," (Comparison between Conventional and Inverted Additional Insulation of Flat Roofs) (in Danish), COWIConsult, publication 492.

Homb, A. and M. Støre. 1995. "Moisture Content in Inverted Roof Constructions : Results from a Test House," Report T5-N-95/01 IEA-Annex 24.

Laboratorium Bouwfysica. 1982-1986. "Onderzoeksrapporten MW omgekeerde Daken" (research reports MW PM-roofs), rapport 82/3, 83/32, 84/21(1)(2)(3), 85/40, 86/22.

Hens, H. 1983. "The Inverted Roof System: New Developments," Proceedings of the 5th International Congress on Roofing and Waterproofing , Strassbourg, pp. 303-325.

Vaes, F. and H. Hens. 1986. "An Inverted Roof with Mineral Wool ," Building Research and Practice, 14(4):245-251.

10.

Laboratorium Bouwfysica. 1984-1985. " Onderzoeksrapporten Vekooisol Tegels" (research Reports Vekooisol Boards), rapport 84/7(1), 84/7(2), 84/7(3), 85/10.

11.

Hens, H. 1987. "Buitenwandoplossingen voor de residentiële bouw:platte Daken" (Outside Wall Solutions for Residential Buildings: Flat Roofs), final report RD-Energy, Belgium, pp. 1-150.

12.

Basf. 1989. " Gutachten über das Langzeitverhalten von Umkehrdächern mit Styrodur," internal report.

13.

Basf. 1990. "Gutachten über das Langzeitverhalten von Parkdecks und Gründächern," internal report.

Hygrothermal Performance of Protected Membrane Roof Systems: Part 2: Experimental Verification

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