论文信息 - Utilizing Latent Building Thermal Mass for Dehumidification

Utilizing Latent Building Thermal Mass for Dehumidification

Traditionally, attic space in buildings is perceived as a source of nuisance. In winter, moisture condensation on the attic ceiling encourages mildew growth. In summer, the heat buildup in the attic space increases the cooling load. However, if the attic is integrated in a holistic design and control strategy, it can function as a solar energy collector, a heat exchanger, and a desiccant. This research investigates energy saving by optimizing direct and indirect ventilation through the attic to precool buildings and to reduce humidity. The proposed energy saving strategies are examined in a double story house with an attic. The house is located in a moderate-humid climate. The built-up heat in the attic space and outside air ventilation is used to dry up roof construction materials during the day. When outside air cools down during the night but maintains high humidity, the indoor air is circulated through the attic space. The attic construction materials absorb moisture from the indoor air. Thus, indoor air loses both heat and moisture. EnergyPlus Simulation software was used to simulate these cooling and dehumidification strategies. The simulation results show a significant passive cooling and dehumidification in the building.

Hussein Abaza

[1] Anatol Worch,et al. The Behaviour of Vapour Transfer on Building Material Surfaces: The Vapour Transfer Resistance , 2004 .

[2] P. C. Martin,et al. Investigation of dynamic latent heat storage effects of building construction and furnishing materials , 1986 .

[3] C. Isetti,et al. Predicting vapour content of the indoor air and latent loads for air-conditioned environments: Effect of moisture storage capacity of the walls , 1988 .

[4] A. Desjarlais,et al. Water-vapor measurements of low-slope roofing materials , 1995 .

[5] C. O. Pedersen,et al. Modeling the energy effects of combined heat and mass transfer in building elements: Part 1 -- Theory , 1999 .

[6] J. Arfvidsson. A New Algorithm to Calculate the Isothermal Moisture Penetration for Periodically Varying Relative Humidity at the Boundary , 1999 .

[7] C. Simonson,et al. Moderating indoor conditions with hygroscopic building materials and outdoor ventilation , 2004 .

[8] Carey J. Simonson,et al. Heat and Mass Transfer between Indoor Air and a Permeable and Hygroscopic Building Envelope: Part II – Verification and Numerical Studies , 2004 .

[9] R. Liesen,et al. Development of a response factor approach for modeling the energy effects of combined heat and mass transfer with vapor adsorption in building elements , 1994 .