The R-2000 Super Energy-Efficient Home Program is a cooperative industry/government initiative sponsored by Energy, Mines and Resources Canada (EMR) and delivered by the Canadian Home Builders Association. The program supports building industry development, training of builders and the construction of energy-efficient houses incorporating high levels of insulation, a well sealed air barrier and mechanical ventilati on systems with heat recovery. In 1983, with assistance from the Buildings Energy Conservation Sub-Committee (B.E.C.S.
The multiple tracer gas technique developed at UMIST has been applied to the measurement of roof-space ventilation rates and house to roof-space air movement, for various types and combinations of roof-space ventilation. It has been shown that ridge tile ventilators, whilst increasing roofspace ventilation rates at low wind speeds, also significantly increase house to roof-space airflows over the whole range of wind speeds. This has implications not only in terms of energy wastage, but, more significantly , in terms of increased moisture rates to the roof-space.
It is often stated that advanced ventilation or air conditioning is expensive or energy-wasting. There are, however, several examples of highly energy-efficient air conditioning systems in industrial, commercial and public buildings. Energy-efficiency can be achieved by - optimizing air flows or demand-controlled ventilation - avoiding simultaneous heating and cooling (except if "free") - advanced automatic control system - good operation and maintenance The performance of ventilation and air-conditioning depends on several factors in the building process.
Various ventilation systems have been examined in unoccupied test houses under natural climatic conditions. Two identical test houses were used to enable comparison of the effects of different ventilating systems on the air change rate and heat consumption. The systems examined were natural ventilating devices placed in the window area and centralized and decentralized mechanical systems. With the decentralized systems, draughts were generally unavoidable. Heat recovery from exhaust air at an air change rate of 1.0 h-1 gave a measured heat consumption saving of about 16 per cent.
Three blocks of flats on the outskirts of Worms were equipped with a mechanical ventilation system with heat recovery, a mechanical ventilation system, and stack assisted natural ventilation, respectively. Building description, air quality, air change rate, draught protection, noise level, energy balance, individual heating costs, efficiency calculations, planning and installation experience and user behaviour were studied. Systems with heat recovery were found to permit a 15-20 per cent reduction of heat consumption. User behaviour in opening windows is dependent on habit.
This study investigates the structure and availability of ventilation systems in domestic housing. A measurement programme of natural ventilation efficiency was carried out and evaluated. Mechanical ventilation systems were compared. Their suitability for efficient ventilation of various house types is discussed.
Presents the results to date of the use of the multiple tracer gas technique to determine interzonal airflow and ventilation rates in large, multicelled buildings like offices. This work is part of a wider project designed toextend knowledge of natural ventilation in all types of buildings other than dwellings.
A two-part experimental study was conducted to identify antecedents of complaints from office workers in a sealed, air conditioned building. Building illness was documented as increased incidence of absenteeism and complaints among office workers in the study group compared to control subjects in a non-sealed building of a similar age. The second part monitored complaints and symptoms from subgroups when lighting was changed and when fresh air was introduced. Complaints and symptoms decreased with changes in air and lighting and increased again when previous conditions were established.
The Brookhaven air infiltration measurement system (BNL/AIMS) uses a family of four passive perfluorocarbon tracer sources and miniature passive adsorbent samplers to inexpensively but very effectively tag individual zones within multizone buildings with uniquely discernible tracer vapors.
Facts and ideas are presented to improve cost effective designs for airtightness and ventilation systems. Schematically alternative measures to save energy are presented. An investigation of the rate of ventilation in 25occupied houses is described, using pressurization, tracer gas and measurements of air flow through exhaust air terminal devices. At a mechanical ventilation rate of 0.25 ach, the measured total ventilation rate averaged 0.29 ach (minimum 0.12 and maximum 0.50). Further results are given for 5 more recently constructed houses.
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