Contribution To The Short Measurement Method For Determining The Thermal Characteristics Of Existing Buildings: Total Heat Transmission Coefficient Estimation Based On Double Measurement
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Kośny J., Kossecka E.; Multi-dimensional heat transfer through complex building envelope assemblies in hourly energy simulation programs, Energy and Buildings 34 (2002), p.445-454Search in Google Scholar
Byrne A., Byrne G., Davies A., Robinson A. J.; Transient and quasi-steady thermal behaviour of a building envelope due to retrofitted cavity wall and ceiling insulation, Energy and Buildings 61 (2013), p.356-365Search in Google Scholar
Laurenti L., Marcotullio F., De Monte F.; Determination of the thermal resistance of walls through a dynamic analysis of in-situ data, International Journal of Thermal Sciences 43 (2004), p.297-306Search in Google Scholar
Oral G. K., Yilmaz Z.; The limit U values for building envelope related to building form in temperate and cold climatic zones, Building and Environment 37 (2002), p.1173-1180Search in Google Scholar
Al-Sanea S. A., Zedan M. F., Al-Hussain S. N.; Effect of thermal mass on performance of insulated building walls and the concept of energy savings potential, Applied Energy 89 (2012), p.430-442Search in Google Scholar
Bellamy L.; Towards the development of new energy performance indicators for the external walls of residential buildings, Energy and Buildings, 68 (2014), p.696-702Search in Google Scholar
Albatici R.; On site evaluation of U-value of opaque building elements: a new methodology, Passive and Low Energy Architecture (PLEA) Conference, Dublin, Ireland 2008Search in Google Scholar
Lee S., Kato S.; Feasibility study of in situ measurement method using the infrared camera to measure u-value of walls on residential house installed an convection stove, Journal of Environmental Engineering 76 (2011), p.289-295Search in Google Scholar
Roels S.; Reliable building energy performance characterization based on full scale dynamic measurements, International Energy Agency EXCO Energy Conservation in Buildings and Community Systems Annex 58, 2011Search in Google Scholar
Bacher P., Madsen H.; Identifying suitable models for the heat dynamics of buildings, Energy and Buildings 43 (2011), p.1511-1522Search in Google Scholar
Santamouris M.et al.; Energy performance of residential buildings: a practical guide for energy rating and efficiency. James&James/Earthscan. p.140, 2005Search in Google Scholar
Abadie M., Mendes N.; Comparative Analysis of Response-factor and Finite-volume based Methods for predicting Heat and Moisture Transfer through Porous Building Materials, Journal of Building Physics 30 (2006), p.7-37Search in Google Scholar
Sjögren J-U., Andersson S., Olofsson T., Sensitivity of the total heat loss coefficient determined by the energy signature approach to different time periods and gained energy, Energy and Buildings 41 (2009), p.801-808Search in Google Scholar
Oschatz B.; Physikalische Bewertung vorgeschlagener Messverfahren zur energetischen Inspektion von Heizungsanlagen. Des Bundesministerium für Verkehr, Bau und Stadtentwicklung. Dresden, 2006Search in Google Scholar
Donath M.; Analyse des Betriebsverhaltens von Heizungsanlagen bei der Wärmeversorgung von Gebäuden. Dissertation. Universität Rostock, 2012Search in Google Scholar
Foit H., Szewczyk M.; Określanie zapotrzebowania na ciepło końcowe budynku mieszkalnego na podstawie krótkotrwałego pomiaru (Determination of heat demand of residential building based on brief measurement), Rynek Energii 97 (2011), p.86-91 (in Polish)Search in Google Scholar
Foit H. et al.; Poradnik Diagnostyki cieplnej budynków Tom 2 (Handbook of Thermal Diagnostics of Buildings Vol.2). Wydawca Politechnika Śląska. p.346, 2013 (in Polish)Search in Google Scholar
Foit H., Świerc A.; Wyznaczanie wymaganej mocy źródła ciepła na potrzeby diagnostyki cieplnej budynku mieszkalnego. (Measurement based determination of demanded power of heat source for thermal diagniostics of dwelling houses), Rynek Energii 102 (2012), p.76-80 (in Polish)Search in Google Scholar
Świerc A., Foit H.; Evaluation of required heat source power in existing buildings based on short measurements. Pastatu inzinerines sistemos. 16-osios jaunuju mokslininku konferencijos “Mokslas – Lietuvos ateitis” (Engineering systems for Buildings. Proceedings of the 16th Conference for Junior Researchers “Science – Future of Lithuania”). Vilniaus Gedimino Technikos Universitetas. Aplinkos inzinerijos fakultetas. Vilnius: Technika, p.140-145, 2013Search in Google Scholar
Foit H., Świerc A., Szewczyk M.; Miarodajna temperatura zewnętrzna na potrzeby charakterystyki energetycznej budynku (Equivalent external temperature for energy performance of buildings), Rynek Energii 106 (2013), p.108-112 (in Polish)Search in Google Scholar
EN 15378:2007 Heating systems in buildings – Inspection of boilers and heating systems.Search in Google Scholar
Świerc A., Świerc S., Foit H., Koper P., Applying the Exodus method to calculate the set of impulse response functions of a wall, Energy and Buildings 69 (2014), p.301-306Search in Google Scholar
Directive 2010/31/EU of the European Parliament and of the Council of 19 May 2010 on the energy performance of buildings (recast)Search in Google Scholar
Directive 2002/91/EC of the European Parliament of the Council of 16 December 2002 on the energy performance of buildingsSearch in Google Scholar
Rozporządzenie Ministra Infrastruktury dnia 6 listopada 2008r. w sprawie metodologii obliczania charakterystyki energetycznej budynku i lokalu mieszkalnego lub części budynku stanowiącej samodzielną całość techniczno-użytkową oraz sposobu sporządzania i wzorów świadectw ich charakterystyki energetycznej, Dz. U. Nr 201, poz.1240 (Regulation of the Polish Minister of Infrastructure. Methodology for calculating the energy performance of buildings)Search in Google Scholar
EN 12831:2003 Heating systems in buildings – Method for calculation of the design heat loadSearch in Google Scholar