Quoted for "Because of the non-linear nature of the transport equations, mass and energy conservation is not guaranteed: e.g. the slope of isotherm curve isnot constant during a time step. To solve this problem Janssen et al. proposed an iterative solution procedure in which the property that has to be conserved is

estimated by a truncated Taylor series"

• HAM hygrothermal simulation

1. A comparison of the Nordtest and Japanese test methods for the moisture buffering performance of building materials
2. Impact, absorption and evaporation of raindrops on building facades
3. In situ determination of the moisture buffer potential of room enclosures
4. Qualitative and quantitative assessment of interior moisture buffering by enclosures
5. The influence of soil moisture in the unsaturated zone on the heat loss from buildings via the ground
6. The influence of soil moisture transfer on building heat loss via the ground
7. Wind-driven rain as a boundary condition for HAM simulations: Analysis of simplified modelling approaches  

1. A review of wind-driven rain research in building science
2. A simplified numerical model for rainwater runoff on building facades: Possibilities and limitations
3. Driving rain on building envelopes II: representative experimental data for driving rain estimation
4. Pedestrian wind environment around buildings: literature review and practical examples
5. Quantification of driving rain as a boundary condition for water flow modelling in building parts
6. Rainwater runoff from building facades: A review
7. Spatial and temporal distribution of driving rain on a low-rise building
8. Spatial and temporal distribution of driving rain on buildings: numerical simulation and experimental verification
9. Validation of external BES-CFD coupling by inter-model comparison
10. Wind, rain and the building envelope: studies at the Laboratory of Building Physics, KULeuven
11. Wind-driven rain as a boundary condition for HAM simulations: Analysis of simplified modelling approaches  

1. A comparison of different techniques to quantify moisture content profiles in porous building materials
2. A multiscale network model for simulating moisture transfer properties of porous media
3. A review of wind-driven rain research in building science
4. A simplified numerical model for rainwater runoff on building facades: Possibilities and limitations
5. Description of the moisture capacity of building materials
6. Determination of the isothermal moisture transport properties of porous building materials
7. Determination of the liquid water diffusivity from transient moisture transfer experiments
8. Determination of the moisture capacity of porous building materials
9. Driving rain on building envelopes II: representative experimental data for driving rain estimation
10. Microscopic analysis of imbibition processes in oolitic limestone
11. Modeling fluid flow in fractured media using continuum, network and discrete aproaches
12. Pedestrian wind environment around buildings: literature review and practical examples
13. Performance prediction for masonry walls with EIFS using calculation procedures and laboratory testing
14. Position paper on material characterization and HAM model benchmarking
15. Rainwater runoff from building facades: A review
16. Simulating non-isothermal water vapour transfer: an experimental validation on multi-layered building components
17. Spatial and temporal distribution of driving rain on a low-rise building
18. The influence of soil moisture in the unsaturated zone on the heat loss from buildings via the ground
19. Wind, rain and the building envelope: studies at the Laboratory of Building Physics, KULeuven
20. Wind-driven rain as a boundary condition for HAM simulations: Analysis of simplified modelling approaches