This study aims to provide any assistance in the design of a green thermal comfort solution that is aware of the current climate change and considers sustainable development. This concept is helpful to the environment and offers a possibility of popular use. The process results are reproducible to a maximum of eventuality in the thermal building field, but in this article, we discussed the cases of Malagasy thatched cottage with envelope in mud and roof in thatch and the case of an ordinary house of the popular Malagasy mass, with fired clay brick envelope, cement coating, galvanized corrugated iron roof. The approach is as follows: locate the study area, analyze the scenarios of ecological thermal solutions, carry out the heat balances according to the scenarios, and classify the optimal solution. To do this, METEONORM is used for geographical location, the heat balance is carried out using the THERMEXCEL tool, and the multi-criteria analysis is made by the PROMETHEE tool in the educational version.

ANSI/ASHRAE, Standard 55 (2017) Thermal Environmental Conditions for Human Occupancy.

Camuffo D., (2019), A key variable in Conservation and Thermal Comfort, Microclimate for Cultural Heritage (3rd edition), Chapter 2 Elsevier

Charles K.E., (2013), Fanger’s Thermal Comfort and Draughts Models, National Research Council of Canada. Institute for Research in Construction.

Dal zotto, P., Larre, J.M., Merlet, A., Picau, L. (2003) Mémotech Génie Energétique (3è éd.). A.Capliez

De Dear R., (2004), Thermal Comfort in Practice, Indoor Air, vol.14, no.7

EN 15217, (2017) Energy Performance of Buildings-Methods Simulation: A Workbook Using Design-Builder, New York: CRC Press

Farasoa, V.J. (2014) Etude technico économique comme outil d’aide à la décision de l’exploitation du gisement aurifère d’Ambohimiarina II- Vatovavy Fitovinany, Mémoire de fin d’études pour l’obtention du Diplôme d’Etudes Approfondies en Génie Minéral à l’ESPA.

Humpreys M.A., (2001), Thermal comfort temperatures world-wide-the current position, Renewable Energy-vol. 08

ISO 52000, (2017), Energy Performance of Buildings, Overarching EPB, Part 1:General framework and Procedures

Taleghani, M., Tenpierik, M., Kurvers S. and Van Den Dobbelsteen A. (2013), A review into thermal comfort in buildings, Renewable and Sustainable Energy Reviews, vol.26, no 1364-0321, pp. 201-215

Timplalexis C., Dimara A., Krinidis S., Tzovaras D., Thermal Comfort Metabolic Rate and Clothing Inference, (2019), International Conference on Computer Vision System, Thessaloniki.

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