This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
NEMCSICS Á.: Environment friendly and ecological architecture. (textbook). KKMF, Budapest, 1999.Search in Google Scholar
TRUBAEV P: Exergy analysis of thermal processes in the building materials industry Theoretical Foundations of Chemical Engineering volume 40, pages 175–182 (2006)Search in Google Scholar
LIU M., LI B., YAO R.: A generic model of Exergy Assessment for the Environmental Impact of Building Lifecycle; Energy and Buildings, Volume 42, Issue 9, September 2010, Pages 1482-1490Search in Google Scholar
NEMCSICS Á.: Some aspects to the pollution reduction related with built environment. Óbuda University e-Bulletin [on line], vol. 3, pp. 1–12. Disponible en: http://uni-obuda.hu/e-bulletin/Nemcsics_3.pdf. 2012.Search in Google Scholar
NEMCSICS Á.: Earth houses or the earth as a ecological building element in the ecological architecture. Bioépítészet. Bába Kiadó, Szeged, pp. 96–114, 2007.Search in Google Scholar
NEMCSICS Á.: Wärmebilanz der Lehmwand oder Modelling vom Wärmetransport. Conference proc. of Energy and Mass Flow in the Life Cycle of Buildings. Aug. Vienna, pp. 639–642, 1996.Search in Google Scholar
ISTVÁNFI GY..: History of the architecture, prehistoric age and the vernacular architecture. Nemzeti Tankönyv Kiadó, Budapest, 1997Search in Google Scholar
MINKE G.: Das neue Lehmbau-Handbuch. Staufen bei Freiburg: Ökobuch Verlag, 2001.Search in Google Scholar
NEMCSICS Á.: Some Aspects to the Pollution Reduction Related with Built Environment; Óbuda University e- Bulletin Vol. 3, No. 1, 2012 pp 1-12Search in Google Scholar
RUSIRAWAN D.: Energetic modelling of photovoltaic modules in grid connected systems. S.l Thesis.: Univ. István Széchenyi, Gödöllő. 2012Search in Google Scholar
GEREBEN Z.:. Building physics for architekts. Műszaki.Könyvkiadó, Budapest, 1981.Search in Google Scholar
LOHMEYER G.: Praktische Bauphysik. Stuttgart: B.G. Teubner Verlag, 1992.Search in Google Scholar
BROWN P.W., CLIFTON J.R.: Adobe I: The Properties of Adobe; Studiesi n Conservation, 23(1978),1 39-146Search in Google Scholar
SALEH M.A.E.: Adobe as Thermal Regulating Material; Solar and Wind Technology vol 7 1990 pp 407-416Search in Google Scholar
PAIVA H., VELOSA A., COROADO J., VEIGA M.R., FERRERIA V.M.: Conservation of Adobe Walls – Rendering Mortars; HERITAGE 2008 - World Heritage and Sustainable Development International Conference, Portugal, 7-9 May 2008Search in Google Scholar
OBAFEMI A.P.O., KURT S.: Environmental impacts of adobe as a building material: The north cyprus traditional building case; Case Studies in Construction Materials 4 (2016) 32–41Search in Google Scholar
NEMCSICS Á., ÜRMÖS A.: The adobe wall as an ecological building structure, Conf. Proc. of ELCAS3, 7-9 July, Nysiros, Greece, 2013.Search in Google Scholar
AKTAS D.Y., ZHU H., AYALA D.D., WEEKS C.: Impact of surface waterproofing on the performance of brick masonry through the moisture exposure life-cycle; Building and Environment; Volume 197, 15 June 2021, 107844Search in Google Scholar
SATHIPARAN N., MEGURO K.: Strengthening of adobe houses with arch roofs using tie-bars and polypropylene band mesh; Construction and Building Materials, Volume 82, 1 May 2015, Pages 360-375Search in Google Scholar
PARRACHA J.L., LIMA J., FARIA P.: Vernacular earthen buildings from Leiria, Portugal – Architectural survey towards their conservation and retrofitting; Journal of Building Engineering Volume 35, March 2021, 102115Search in Google Scholar
NAIMA F., MÉBIRIKA B., BELKACEM D., ROULET C-A.: The traditional house with horizontal opening: a trend towards zero-energy house in the hot, dry climates; Energy Procedia 96 ( 2016 ) 934 – 944Search in Google Scholar
BARABÁS J., GILYÉN N.: Vezérfonal népi építészetünk kutatásához, MK, Budapest 1979Search in Google Scholar