passive cooling

The Weidmuller hq at West Malling, built in 1994, uses the Swedish passive cooling system Termodeck. We examine the results of in-use system performance tests.

A new parametrical model for the prediction of the thermal performance of the earth to air heat exchangers is presen1ed. The system consists of an earth tube, buried in the ground, through which ambient or indoor air is propelled and cooled by the bulk temperature of the natural ground. The proposed model has been developed by analysing temperature data of the circulated air at the pipe's outlet using a systematic parametrical process.

In France, air conditioning of offices is often required especially in areas with high noise levels and in the Mediterranean climates. Evaporative cooling systems appear able to give a cost effective solution to the growing demand for summer comfort: hence, the CSTB and Gaz de France are currently conducting a joint research on the efficiency of such systems. On the basis of a comfort criteria, this have been done by computer simulations taking into account different kinds of systems, buildings, and climatic areas.

The present paper deals with the cooling potential of earth to air heat exchangers. The cooling system consists of an underground pipe laid horizontally where ambient or indoor air is propelled through and cooled by the bulk temperature of the natural ground. The dynamic thermal performance of the system during the summer period and its operational limits have been calculated using an accurate transient numerical model. Multiyear soil and ambient air climatic measurements have been used as inputs to the model.

With the growth of living standards, there is an increasing demand for the cooling of living space. Rational energy use demands the use of alternative ways of cooling because the energy consumption of compressor cooling is high. In this article a new cheap and efficient paperboard compact heat exchanger and indirect evaporative cooling are presented.

This paper is not intended as an exhaustive account of all the available natural cooling techniques, including an interminable list of references, the advantages and disadvantages of each technique, and their field of application. Rather, it is intended to present the perspectives of future research and the topics that should be covered within the frame of a European concerted action. Thus, it will concentrate on the main obstacles and faults that we feel exist in the current research, and subsequently on the measures that should be taken to correct this.

The paper describes the possible role of monitoring activities in the study of passive cooling concepts. Special attention goes to monitoring activities for post-implementation performance analysis on real buildings. Various aspects of the monitoring method, the set-up of a monitoring campaign, accuracy aspects of monitoring results as well as their extrapolation are discussed.

The work in progress of an Expert system called ISOLDE that is being prepared in a specific Tusk of the International Energy Agency is presented. This program will give intelligent user support on energy use and thermal comfort during the design process of commercial buildings through general advices, simplified methods, detailed simulations. In particular the paper focuses on the passive cooling approach covered by this tool. 

This paper surveys the state of integration of passive cooling devices in buildings. This survey illustrates the fact that there are no general prescriptions for the integration in the design of passive cooling devices. Further the present paper does not intend to propose general prescriptions for the integration of cooling devices in design but only to illustrate a number of existing problems.

The need for auxiliary heating and cooling systems in European buildings is established on the basis of building physics and climatic conditions, emphasizing that cooling systems may not be needed in most regions if there are no large internal gains and the building envelope is well designed, through the use of bioclimatic design principles. Occupant attitudes and the consequences upon indoor environmental quality are also compared for the cases of actively and naturally controlled buildings.