id |
ecaaderis2023_44 |
authors |
Foged, Isak |
year |
2023 |
title |
Thermal Engagement: A method and model for analysing and organising thermal-active materials close to the human body |
source |
De Luca, F, Lykouras, I and Wurzer, G (eds.), Proceedings of the 9th eCAADe Regional International Symposium, TalTech, 15 - 16 June 2023, pp. 89–97 |
summary |
This study examines the performance and application of thermal-active materials by use of phase-change-composite structures close to the human body. The aim is to understand and model the thermal impact on a person in an office environment through 3 design test cases. In this process a design method is proposed to position PCM-wood based composites. Investigations are based on material studies by composite development and thermographic analysis, computational studies by generative design and thermal sensation modelling, and comparative studies from computational design and analysis processes by graphical mapping of results. The study finds that the PCM-wood composites have an impact on the thermal sensation within the cases studied, but only by the application of a large thermal-active surface close to the human. |
keywords |
mal Active Materials, Thermal Sensation, Generative, Simulation |
series |
eCAADe |
email |
|
full text |
file.pdf (1,246,247 bytes) |
references |
Content-type: text/plain
|
Barreneche, C., Vecstaudza, J., Bajare, D. and Fernandez, A.I. (2017)
PCM/wood composite to store thermal energy in passive building envelopes
, IOP Conference Series: Materials Science and Engineering, 251, 012111
|
|
|
|
Battle, G. (2003)
The Air We Breathe
, Princeton: Princeton Architectural Press
|
|
|
|
Fanger, P.O. (1970)
Thermal Confort: Analysis and applications in environmental engineering
, Copenhagen: Danish Technical Press
|
|
|
|
Foged, .I.W (2017)
The Power of Transformation: Modifying Colour and Geometry as the Primary Means of Transforming Existing Building Envelopes
, Proceedings of the 33rd International Conference PLEA 2017, 2-5 July 2017, pp. 2053-2060
|
|
|
|
Foged, I.W. (2019)
Thermal responsive performances of a Spanish balcony-based vernacular envelope
, Buildings, 9(4), 80. https://doi.org/10.3390/buildings9040080
|
|
|
|
Kiamili, C., Hollberg, A. and Habert, G. (2020)
Detailed assessment of embodied carbon of HVAC systems for a new office building based on BIM
, Sustainability, 12(8), 3372 https://doi.org/10.3390/su12083372
|
|
|
|
Moe, K. (2014)
Insulating Modernism - Isolated and Non-Isolated Thermodynmaics in Architecture
, Basel: Birkhäuser
|
|
|
|
Pomianowski, M., Heiselberg, P. and Jensen, R.L. (2012)
Dynamic heat storage and cooling capacity of a concrete deck with PCM and thermally activated building system
, Energy and Buildings, 53, pp. 96-107
|
|
|
|
Pomianowski, M. (2013)
Energy Optimized Configuration of Concrete Element with PCM
, Aalborg: Aalborg University
|
|
|
|
van Hoof, J. (2008)
Forty years of Fangers model of thermal comfort: comfort for all?
, Indoor Air, 18, pp. 182-201
|
|
|
|
Wi, S., Yang, S., Park, J.H., Chang, S.J. and Kim, S. (2020)
Climatic cycling assessment of red clay/perlite and vermiculite composite PCM for improving thermal inertia in buildings
, Building and Environment, 167, 106464
|
|
|
|
Yang, K., Venkataraman, M., Zhang, X., Wiener, J., Zhu, G., Yao, J. and Militky, J. (2022)
Review: incorporation of organic PCMs into textiles
, Journal of Materials Science, 57, pp. 798-847
|
|
|
|
last changed |
2024/02/05 14:28 |
|