Reports on use of supply and exhaust ventilation with heat recovery in prefabricated houses and multi-storey buildings. In thermal super insulated buildings the system can supply heat demand down to an outside temperature of5 degrees C: additional electric storage heating is used below thistemperature. The ventilation system operates at an air change rate of approximately 0.7 per hour in the following way: exhaust air from the kitchen, bathroom, and WC, supply air to the living and bedrooms. It is combined with an air to air heat pump.
Outlines the foundations for calculating and designing natural ventilation: conditions for the building unit: technological prerequisites: components: sound insulation: calculation methods: fields of application: combination of mechanical and natural ventilation: and models for optimization of new buildings and for reconstructing factories.
Examines providing some existing multifamily houses with mechanical ventilation with heat exchanger by installing new inlet air ducts to bring back the heat contents of the outlet air.
The text of a paper on ventilation equipment and systems for existing air-tight houses, presented at the Bouwcentrum/Vakinfo one-day conference, Rotterdam, November 1, 1984. Treats the application of 1. natural ventilation systems with vertical ducts and adjustable openings, 2. the same with mechanical exhaust via kitchen, bathroom, and toilet, 3. mechanical supply to all rooms and exhaust via kitchen, bathroom, and toilet, 4. balanced supply and exhaust. Treats the possibility of the private buyer or tenant estimating the quality of the house.
In newly built well insulated houses, a wind of 4 m/s will produce an air change rate of almost 0.3 h-1. However it is considered necessary to obtain air change rates of 0.7 h-1.
Infiltration models are used to simulate the rates of incoming and outgoing air flows for a building with known leakage under given weather and shielding conditions.
An indoor air quality investigation of a 60,000 m2 8 storey government office building was carried out as a part of an in-depth study of the Total Building Performance of the building. The transdisciplinary study included the following areas of building performance: lighting, acoustics, thermal comfort, ventilation, energy use, air circulation, air quality, occupant comfort, building envelope thermography, functional use and enclosure integrity. The air quality conclusions generic to large offices are presented.
Since 1974 the french Authorities have insisted on energy being saved in all buildings. There was very strong pressure on manufacturers to obtain better sealed window frames . In practise less than two or three meters cubed per hour at a pressure of ten pascals penetrates. Also television campaigns have insisted on weather stripping all windows and window frames in all old buildings. The result of these campaigns is that all buildings with no or natural ventilation systems actually have indoor condensation problems.
For optimum building design it is of importance to investigate the comfort and the energy conservation obtained with different types of ventilation systems and levels of airtightness of buildings. This could be achieved by aid of computer models based on full-scale and model measurements. In order to obtain experimental data as input data to such a computer model, an experimental, detached one-family house has been built near to Gothenburg on the Swedish west coast.
Discusses the problems of designing ventilation for small houses. Small houses are considered to be far too elementary and there is no total view of the balance of energy and no regard for the interplay between different flows. Mechanical ventilation is often not controlled or inspected in small houses. Recommendations are: increased knowledge, differentiated requirements on ventilation, inspection of systems, definition of comfort criteria, changed conditions for heat recovery, and well-documented requirements for air tightness.