In 1981 Norwegian building regulations introduced quantitative requirements to air leakages in different types of buildings. The requirements were formed as maximum allowed air changes per hour at 50 Pa pressure difference according to the pressurization method. To evaluate the consequences of these new requirementsimposed to Norwegian building industry a model proposed by the Nordic Committee for Building Regulations (NKB) was used. The average air leakages of residential buildings , built before the new requirements,are known through a research project performed i n 1979.
The Act (1981.592) on amendments in the Building Ordinance (1959:612) and implementing regulations appertaining thereto in the Building Code come into force on 1st January 1984. The regulations apply only to permanently used houses.
Discusses the Swedish trend to build super insulated nearly airtight dwellings. Mentions problems encountered in tight buildings, such as severe ground floor condensation and mould growth. Shows the importance of the vapour barrier in preventing condensation. Compares exhaust and balanced ventilation systems in tight houses. States that sealing houses in Sweden is costeffective, partly because of an integrated approach to incorporating energy saving features in new housing.
Considers the dangers of gases which are present in indoor air and which cannot be detected orally. Notes current regulations in Finland governing indoor air quality. Illustrates sense of comfort with example using a bus and various measures to provide satisfactory air to all parts of the bus. Considers current knowledge on air change rates and personal comfort.
This report is a guide to give the canadian builder practical information in the area of energy conservation in new housing. Offers useful suggestions for planning, designing and building a more energy efficient home. Sections covered include energy use in dwellings, air tightness, ventilation andmoisture control, options for improving the building shell, space heating and cooling systems, and cost considerations. Takes the 1979 Ontario Building Code as the basis upon which to develop and evaluate improvements.
Measures air infiltration and tightness of Swedish houses using the tracer gas technique and the fan pressurisation technique. Uses a previously developed model correlating air tightness and infiltration to evaluate the performance of Swedish homes. Shows that it is difficult to achieve the recommended minimum ventilation rate according to the Swedish Building Code by relying on natural air infiltration. Most new homes do, however meet the Code's stringent air tightness requirements. A comparison with American houses show that Swedish homes are very tight.
Reviews new regulations and their consequences for external wall structures. Considers energy savings, air tightness requirements, U-values, air movement and zone division, heavy and light structures, building classification according to room temperature, incidental heat gains from insolation.
Reviews factors affecting indoor air quality, including the effect of mildew, high concentrations of microorganisms, radon, light air ions and chemical pollutants(especially formaldehyde). These are mentioned especially inconjunction with airtight residential buildings in Sweden. Current building standards in Sweden concerning materials, airtightness, air quality and energy conservation are also reviewed, along with areas of current and proposed research in air quality.
Describes wind tunnel study where both static and dynamic, local and spatially distributed loads have been measured for a variety of representative low-rise building geometries. Determines experimental pressure coefficients for the interior of buildings with various porosities and wall openings. Describes the assumptions made to reduce the large quantities of data to a small set of simplified pressure coefficient charts appropriate for use in a code or standard.
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