Hygrothermal performance of super-insulated double-stud wood frame wall assemblies: an experimental study
Khalkhali-Shijini, Nima (author) Tariku, Fitsum (thesis advisor) British Columbia Institute of Technology Building Science (Degree granting institution)
Dissertation/thesis
http://rightsstatements.org/vocab/InC/1.0/http://creativecommons.org/licenses/by-nc-nd/2.5/ca/
British Columbia Institute of Technology
2018-07
300 pages
In cold climates, much of wood-frame building enclosure durability failures and indoor air quality issues stem mainly from excessive moisture within enclosure components and these issues are more pronounced in buildings with higher levels of thermal insulation, with frequent mold and fungal growth complications. Nevertheless, buildings have been increasing their insulation levels (and this trend is expected to continue) due to climate change, depleting natural resources, ever-rising energy prices and growing expectation for occupants’ comfort and health. Incorporation of insulation materials with higher moisture storage and buffering capacities and also employing vapour retarders that can let walls dry out to both interior and exterior spaces are potential solutions. While the hygrothermal behaviour of these insulation materials have been extensively tested in material labs and computer modeling projects, their actual performance in different climatic zones demands more field experimental studies. In this study, a field experiment was designed to assess hygrothermal behaviors of five highly insulated test wall panels under Marine climatic zone of, Burnaby, British Columbia. Full size wall panel specimens of ‘double-stud’ wood-frame were instrumented with moisture and temperature sensors and filled with Dense Cellulose Insulation (DCI) and Low-Density Spray Polyurethane Foam Insulation (LD SPFI) under different vapour control layer scenarios of 4-mil Polyethylene film, Smart Vapour Retarder (SVR), and none. All test panels were exposed to the 4 controlled indoor and the actual outdoor climates and their hygrothermal response was recorded and analysed from 01 Sept 2016 to 31 May 2017. The experimental results suggested DCI is a proper insulation material provided that it is equipped with a dedicated interior vapour barrier. The results also suggested while both DCI had LD SPF had acceptable moisture behaviour; DCI had slightly better performance than LD SPF. As for vapour control strategies, Smart Vapour Retarder (SVR) did not show an obvious advantage over 4-mil Polyethylene film and in some cases was slightly outperformed by polyethylene hygrothermally. As a general comment, the exterior sheathing board, plywood had the highest moisture activity and all other components, mainly the exterior and interior studs and plates remained in safe moisture ranges throughout the test period.
Insulation Dense Cellulose Insulation Low-Density Spray Polyurethane Foam Insulation Hygrothermal performance
Building, Wooden Moisture
electronic
Master of Applied Science/Building Engineering
