This paper outlines progress in the THERMIE Target project Energy Comfort 2000 after three and a half years. Seven of the eight buildings are under construction and the eighth will be starting on site in May 1997. The project covers the design, construction, commissioning and monitoring of the buildings which are offices, university buildings, and public and recreational buildings, together with "horizontal activities" which link the projects together.
This paper presents a method for the dynamic numerical analysis in calculating the thermal environment in the atrium space of an institution for the elderly. The analysis is carried out and using BASIC. In Kushiro, it is very foggy, cool and highly humid in Summer. On the other hand, it has little snow with clear skies while still being cold in Winter. In Winter, the atrium space is heated by satisfactory solar radiation in the daytime, so outdoor air flowing into the atrium space is warmed .
A time constant has been proposed to characterize the time it takes to fill an atrium space with smoke for design purposes. This was defined through the use of the empirical equation expressing the mass entrainment rate to the 312 power of the clear height. However, the equation holds only when the flame tip touches the smoke layer, and the flame temperature was taken to be 1100 K (827°C 1521°F).
In recent years, the atrium building has become commonplace. This paper explains the physical concepts of the steady fire, unsteady fire, zone fire model, and the fire plume that are the basis of atrium smoke management. The approach to smoke control design calculation in codes is based on the zone fire model concept. In the zone model, smoke forms an upward-flowing fire plume that reaches the ceiling and is considered to form a perfectly mixed layer under the ceiling of the room of fire origin.
In recent years, approaches to smoke management in atria have been introduced into many codes and engineering guides. This paper presents information that can be used for design analysis of atrium smoke management systems. Various approaches to manage smoke in atria are discussed Often a hot layer of air forms under the ceiling of an atrium, and this hot layer can prevent smoke from reaching the ceiling. A method is discussed for dealing with smoke detection when such a hot air layer prevents smoke from reaching the ceiling.
This paper presents results of a project initiated by ASHRAE and the National Research Council of Canada. The project applies both physical and numerical modeling techniques to atrium smoke exhaust systems to investigate the effectiveness of such systems and to develop guidelines for their design. This paper compares experimental results obtained from testing a physical model of a mechanically exhausted atrium space with results of two sets of numerical predictions of the same space.