TY - RPRT
T1 - A Mathematical Model for Infiltration Heat Recovery
Y1 - 2000/
A1 - Christopher R. Buchanan
A1 - Max H. Sherman
AB - Infiltration has traditionally been assumed to affect the energy load of a building by an amount equal to the product of the infiltration flow rate and the sensible enthalpy difference between inside and outside. However, laboratory and simulation research has indicated that heat transfer between the infiltrating air and walls may be substantial, reducing the impact of infiltration. In this paper, two- and three-dimensional CFD simulations are used to study the fundamental physics of the infiltration heat recovery process and a simple macro-scale mathematical model for the prediction of a heat recovery factor is developed. CFD results were found to compare well (within about 10 percent) with limited published laboratory data corresponding to one of the scenarios examined. The model, based on the steady-state one-dimensional convection-diffusion equation, provides a simple analytical solution for the heat recovery factor and requires only three inputs: the infiltration rate, the U value for the building, and estimates of the effective areas for infiltration and exfiltration. The most difficult aspect of using the model is estimation of the effective areas, which is done here through comparison with the CFD results. With proper input, the model gives predictions that agree well with CFD results over a large range of infiltration rates. Results show that infiltration heat recovery can be a substantial effect and that the traditional method may greatly over-predict the infiltration energy load, by 80-95 percent at low leakage rates and by about 20 percent at high leakage rates. This model for infiltration heat recovery could easily be incorporated into whole-building energy analysis programs to help provide improved predictions of the energy impact of infiltration.
U1 - 2.3

U2 - LBNL-44294
ER -
TY - RPRT
T1 - Leakage Diagnostics, Sealant Longevity, Sizing and Technology Transfer in Residential Thermal Distribution Systems; Part II
Y1 - 1999///
A1 - Iain S. Walker
A1 - Max H. Sherman
A1 - Jeffrey A. Siegel
A1 - Duo Wang
A1 - Christopher R. Buchanan
A1 - Mark P. Modera
PB - Phase VI Report to CIEE
CY - Berkeley
U2 - LBL-42691
ER -
TY - CONF
T1 - CFD Simulation of Infiltration Heat Recovery
T2 - Proceedings of the 19th AIVC Conference, Oslo, Norway, Sept. 28-30, 1998
Y1 - 1998/09//
A1 - Christopher R. Buchanan
A1 - Max H. Sherman
AB - Infiltration has traditionally been assumed to affect the energy load of a building by an amount equal to the product of the infiltration flow rate and the sensible enthalpy difference between inside and outside. Results from detailed computational fluid dynamics simulations of five wall geometries over a range of infiltration rates show that heat transfer between the infiltrating air and walls can be substantial, reducing the impact of infiltration. Factors affecting the heat recovery are leakage path length, infiltration flow rate, and wall construction. The classical method for determination of the infiltration energy load was found to over-predict the amount by as much as 95 percent and by at least 10 percent. However, the air flow paths typical of building envelopes give over-predictions at the low end of this range.
JF - Proceedings of the 19th AIVC Conference, Oslo, Norway, Sept. 28-30, 1998
CY - Air Infiltration and Ventilation Centre, Coventry, United Kingdom
U1 - 2.3

U2 - LBNL-42098
ER -