[Atkinson J., 2014, Environmental conditions for the safeguarding of collections – A background to the current debate on the control of relative humidity and temperature, Studies of Conservation, 59 (4), pp. 205-212.10.1179/2047058414Y.0000000141]Search in Google Scholar
[Bratasz L., Kozlowski R.,, Camuffo D., 2007, Impact of indoor heating on painted wood-Monitoring the altarpiece in the Church of Santa Maria Madalena in Rocca Pietore, Itally, Studies in Conservation, 53(3), pp.199-210.10.1179/sic.2007.52.3.199]Search in Google Scholar
[Camuffo D. della Vale D., 2007, Expert s Roundtable on Sustainable Climate Management Strategies, Tenerife, Spain.]Search in Google Scholar
[Camuffo, D., Pagan, E., Schellen, H. & Limpens-Neilen, D., 2014. A practical guide to the pros and cons of the various heating systems with a view to the conservation of the Cultural Heritage in Churches. Results of the European Project Friendly Heating EVK4-CT-2001-00067, s.l.: s.n.]Search in Google Scholar
[Camuffo, D., Pagan, E., Rissanen S, Bratasz L., 2010, An advancedchurch heating system favourable to artworks, Journal of Cultural Heritage 11 (2), pp.2015-219.10.1016/j.culher.2009.02.008]Search in Google Scholar
[Carstolovean, I.L., Hornet M., Ancas A.D., Profire M., 2018, Air Exchange Rate in Air Quality Assurance – A Case Study, Journal of Applied Engineering Aciences, 8(1), pp.13-18.10.2478/jaes-2018-0002]Search in Google Scholar
[Fluent Inc.Fluent 15 User, s Guide, January 2015.]Search in Google Scholar
[Hornet M., Carstolovean, I.L., Nastac L., Ancas A.D., Profire M., 2018, Using the Earth’s Natural Potential for Heating a Building, Journal of Applied Engineering Aciences, 8(1), pp.47-52.10.2478/jaes-2018-0006]Search in Google Scholar
[Jung-Yoon K., Chao-Hsien C., Sang-Moon S., 2014, ISSAQ an integrated sensing systems for real-time indoor air quality monitoring, IEEE Sensors Journal, 14(12), pp.4230-4244.10.1109/JSEN.2014.2359832]Search in Google Scholar
[Liu, J., Yao, R. & McCloy, R., 2012. A method to weight three categories of adaptive thermal comfort. Energy and Buildings, 47, pp. 312–320.10.1016/j.enbuild.2011.12.007]Search in Google Scholar
[Napp M., Kalamees T., 2015, Energy use and indoor climate of conservation heating, dehumidification and adaptive ventilation for the climate control of mediaeval church in a cold climate, Energy and Buildings, 108, pp.61-71.10.1016/j.enbuild.2015.08.013]Search in Google Scholar
[Schellen, H.; Lambertus H. 2002: Heating Monumental Churches - Indoor Climate and Preservation of Cultural Heritage. Eindhoven (NL): Technische Universiteit Eindhoven.]Search in Google Scholar
[Serbanoiu I., Verdes M., Turcanu F., 2014 Churches heating: a choice between conservation and thermal comfort, Ed. Politehnium, Iași, Romania, Tomul LX(LXIV), Fasc. 4.]Search in Google Scholar
[Silva H., Henriques F., 2014, Microclimatic analysis of istoric Buildings – a new methodology for temperate climates, Building and Environment, 82, pp.381-387.10.1016/j.buildenv.2014.09.005]Search in Google Scholar
[Torres M.I., Freitas V.P, 2007. Treatment of rising damp in historical buildings: wall base ventilation. Build. Environ. 42(1), pp.424–435.10.1016/j.buildenv.2005.07.034]Search in Google Scholar
[Varas Muriel, M., Martinez Garrido, M. & Fort, R., 2014. Monitoring the thermal–hygrometric conditions induced by traditional heating systems in a historic Spanish church (12th–16th C). Energy and Buildings, 75(3), pp. 119-132.10.1016/j.enbuild.2014.01.049]Search in Google Scholar
[Vuerich E., Malaspina F., Barazutti M., Georgiadis M., 2008, Indoor measurements of microclimate variables and ozone in the church of San Vicenzo, Italy, Microchemical Journal, 88 (2), pp.218-223.10.1016/j.microc.2007.11.014]Search in Google Scholar