Abstract
Within the context of nearly Zero-Energy Buildings, it is debated that the energy-centred notion of design, proposed
by regulatory frames, needs to be combined with a further focus toward users’ comfort and delight. Accordingly, the
underlying theory of the research is that designers should take responsibility for understanding the heat flows
through the building parts and its spaces. A design, which is sensible to the micro-thermal conditions coexisting in a
space, allows the inhabitants to control the building to their needs and desires: for instance, maximising the benefits
of heat gain from the sun moving a series of internal partitions so as to avoid the danger of over-heating.
It is thus necessary that existing simulation software tools are tested to the purpose of modelling and visualizing the
indoor thermal environment complexity. The research discusses how thermal comfort maps, which are prepared
with the use of Computational Fluid Dynamic simulation method, could integrate energy simulation outputs to
uphold qualitative architectural design decisions. Mean radiant temperature maps were thus used to design the
retrofit of a small educational building in Copenhagen. The thermal opportunities of movable interior partitions
(operated by the users) could be estimated, providing a new layer of information to the designer. The applicability of
the thermal maps within an architectural design process is discussed adopting standard energy simulation comfort
outputs as a reference. The capabilities and the limitations of the method are appraised.
by regulatory frames, needs to be combined with a further focus toward users’ comfort and delight. Accordingly, the
underlying theory of the research is that designers should take responsibility for understanding the heat flows
through the building parts and its spaces. A design, which is sensible to the micro-thermal conditions coexisting in a
space, allows the inhabitants to control the building to their needs and desires: for instance, maximising the benefits
of heat gain from the sun moving a series of internal partitions so as to avoid the danger of over-heating.
It is thus necessary that existing simulation software tools are tested to the purpose of modelling and visualizing the
indoor thermal environment complexity. The research discusses how thermal comfort maps, which are prepared
with the use of Computational Fluid Dynamic simulation method, could integrate energy simulation outputs to
uphold qualitative architectural design decisions. Mean radiant temperature maps were thus used to design the
retrofit of a small educational building in Copenhagen. The thermal opportunities of movable interior partitions
(operated by the users) could be estimated, providing a new layer of information to the designer. The applicability of
the thermal maps within an architectural design process is discussed adopting standard energy simulation comfort
outputs as a reference. The capabilities and the limitations of the method are appraised.
| Original language | English |
|---|---|
| Article number | 33856 |
| Journal | Procedia Engeenering |
| Number of pages | 10 |
| ISSN | 1877-7058 |
| Publication status | Published - 2017 |
Keywords
- Building Retrofit
- Thermal Comfort Map
- Computational Fluid Dynamics
- Mean Radiant Temperature
- Architectural Design Process
Artistic research
- No