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Space humidity/interior basement wall insulation moisture content relationships with and without vapor retarders

Goldberg, L.F. and Aloi, T.
2001
Indoor Air Quality 2001 Moisture, Microbes, and Heath Effects: Indoor Air Quality and Moisture in Buildings


Goldberg, L.F. and Aloi, T., (2001), "Space humidity/interior basement wall insulation moisture content relationships with and without vapor retarders", Indoor Air Quality 2001 Moisture, Microbes, and Heath Effects: Indoor Air Quality and Moisture in Buildings.
Abstract:
An interior basement wall finishing system consisting of mold/mildew resistant rigid fiberglass panels mounted in a polyvinyl chloride frame was tested experimentally over two heating seasons in a 19 ft, 4 in. (5.9 m) square foundation test module having hollow masonry block walls without any exterior waterproofing. Three vapor retarder configurations were tested, namely, no vapor retarder, a polyethylene vapor retarder on the interior side of the insulation, and a polyethylene vapor retarder on the wall side of the insulation. Conditioned basement interior conditions with temperature and relative humidity setpoints of 68 ¡ãF (20 ¡ãC) and 40% to 50%, respectively, were maintained over the first heating season. During the second heating season, the temperature was maintained at 56 ¡ãF (13.3 ¡ãC) with no dehumidification to emulate an unconditioned basement. During the intervening summer, the internal relative humidity ranged from 50% to 82%. A comprehensive set of transient and weekly manual data coupled with weekly observations of moisture conditions were collected. Under the particular "worst-case," cold-climate experimental conditions used, these data show that the no vapor retarder configuration has a stable annual wetting/ drying cycle for a conditioned basement and allows the conservative inference of a stable annual wetting/drying cycle for an unconditioned basement as well, so indicating the suitability of this configuration for interior basement insulation. The internal vapor retarder configuration demonstrated an unstable annual wetting/drying cycle with a single episode of condensate pooling on the floor. The wall-side configuration also yielded a stable annual wetting/drying cycle but produced prolonged condensate pooling on the slab. Thus, neither of the latter two vapor retarder configurations was demonstrated experimentally to be appropriate for long-term usage with this interior basement insulation system.

Related Resources:
  • This link has not been checked.ANSI-- American National Standards Institute
    "a private, non-profit organization (501(c)3) that administers and coordinates the U.S. voluntary standardization and conformity assessment system. to enhance both the global competitiveness of U.S. business and the U.S. quality of life by promoting and facilitating voluntary consensus standards and conformity assessment systems, and safeguarding their integrity."
  • This link has not been checked.Laboratory of Building Physics, Leuven, Belgium
    "...research and educational activities in the field of heat and mass transfer in building materials, building parts and buildings, the energy use in buildings, building installations and building acoustics. Also research in urban physics is part of our activities.
  • Conference: Indoor Air : Conference
  • Conference: Indoor Air Quality
  • Journal: Indoor Air : Journal


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