A study of membrane properties on air conditioning performance

Abstract

Energy consumption due to heating, ventilation, and air conditioning amounts to 10-20% of global electrical energy usage. Air conditioning alone uses one trillion kilowatt hours globally. This energy is required for the dehumidification of air in addition to its cooling. New membrane technologies have the potential to decrease air conditioning energy requirements by significant amounts. A membrane acts as a partial heat and mass exchanger in conjunction with a traditional air conditioning system to remove water content and reduce the cooling load. Membranes vary according to their properties and method of mass transport. Liquid membranes have high permeability and selectivity, dense membranes have high selectivity and low permeability, and porous membranes have low selectivity and high permeability. A theoretical model was created to observe how membrane properties affected the potential energy savings of such systems. The most influential properties were flow rate, water permeability and selectivity, membrane area and thickness, and the purge flow temperature. Other properties were determined to be minimally important such as outdoor temperature and humidity. The effect on energy savings in many cases was not a linear relationship but suggested an optimal value beyond which energy savings did not significantly increase. The best simulations showed electrical energy savings of 86-95%.