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Global building physics

Rode, C.
2013
Journal of Building Physics April 36: 337-352,

Rode, C., (2013), "Global building physics", Journal of Building Physics April 36: 337-352,.
Abstract:
High ambitions are set for the building physics performance of buildings today. No single technology can achieve fulfilment of these ambitions alone. Integrated, multi-facetted solutions and optimization are necessary. A holistic, or ¡®global¡¯, technological perspective is needed, which includes all aspects of the building as defined in building engineering. We live in an international society and building solutions are developed across country borders. Building physics is a global theme. The International Association of Building Physics has global appeal. This brief article reports the keynote lecture and illustrates global relations to highlight some of the challenges that we see today.

Building physics international cooperation energy building envelope indoor and outdoor environment durability

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Author Information and Other Publications Notes
Rode, C.
Carsten Rode Pedersen
  1. eds. Annex 41 Final Report, Volume 1: Modelling Principles and Common Exercises
  2. Empirical validation of a transient computer model for combined heat and moisture transfer
  3. Experimental investigation of the hygrothermal performance of insulation materials
  4. Full-scale testing of indoor humidity and moisture buffering in building materials
  5. International building physics toolbox, general report
  6. Investigation of Microclimate by CFD Modeling of Moisture Interactions between Air and Constructions
  7. Latent heat flow in lightweight roofs and its influence on the thermal performance of buildings
  8. Model and experiments for hygrothermal conditions of the envelope and indoor air of buildings
  9. Moisture buffer value of building materials
  10. Moisture Buffer Value of Materials in Buildings
  11. Moisture buffering of building materials
  12. Moisture conditions of non-ventilated, wood-based, membrane-roof components
  13. Moisture: its effects on the thermal performance of a low-slope roof system
  14. Non-isothermal water vapour transmission through porous insulation. Part 1: The climate chamber
  15. Organic insulation materials: effect on indoor humidity and necessity of a vapor barrier
  16. Test cell measurements of moisture buffer effects
  17. The importance of moisture buffering for indoor climate and energy conditions of buildings
  18. The International Building Physics Toolbox in Simulink
  19. The self-drying concept for flat roofs
  20. Tools for performance simulation of heat, air and moisture conditions of whole buildings
  21. Whole-building Hygrothermal Simulation Model  


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