Cooling demand in museum premises – numerical prediction and measurement validation

• Autorzy: Ferdyn-Grygierek J. , Baranowski A.
• Języki publikacji: EN

Abstrakty

EN

The paper presents the results of identification and assessment of the energy demand for cooling purposes in the museum building. The analysis of cooling demand and assessment of indoor air quality were performed by the simulation analysis and validated by the measurement campaign of the indoor air quality in the building under consideration. For the purpose of thermal analysis the IDA ICE software was used. All simulations were carried out using meteorological data recorded by the local weather station. The results of the study indicate the necessity to use cooling in the museum premises. Presented analysis of the heat loads, which can occur in the exhibition rooms, can be helpful in making the decision about the installation of air conditioning systems in the museum, especially when thermal renovation of the building is planned. Such system can guarantee proper protection of the exhibits as well as thermal comfort for visitors.

PL

Artykuł przedstawia wyniki wielowariantowej analizy i oceny zapotrzebowania energii na cele chłodzenia w wybranym budynku muzeum. Analizy zapotrzebowania na chłód i oceny jakości powietrza wewnętrznego przeprowadzono na bazie symulacji komputerowej wykorzystując do tego celu program IDA ICE. Model obejmujący sale wystawowe został zwalidowany i dopasowany na podstawie danych pomiarowych parametrów środowiska wewnętrznego. Wszystkie obliczenia przeprowadzono w oparciu o dane meteorologiczne zarejestrowane przez lokalną stację meteo. Symulacje wykazały potrzebę chłodzenia sal wystawowych w okresie letnim. Zaprezentowane analizy obciążeń cieplnych w salach wystawowych mogą być pomocne przy podejmowaniu decyzji w spawie instalacji systemu klimatyzacji, który będzie gwarantować właściwą ochronę eksponatów, jak również komfort cieplny osób zwiedzających, szczególnie w przypadku planowania termomodernizacji budynku.

Słowa kluczowe

EN

museum microclimate; energy demand; indoor air quality; simulation methods

PL

mikroklimat muzeum; zapotrzebowanie na energię; jakość powietrza wewnętrznego; metoda symulacyjna

• Wydawca: Silesian University of Technology
• Czasopismo: Architecture Civil Engineering Environment
• Rocznik: 2016
• Tom: Vol. 9, no. 2
• Strony: 125--135
• Opis fizyczny: Bibliogr. 23 poz.

Twórcy

autor

Ferdyn-Grygierek J.

• Faculty of Energy and Environmental Engineering, The Silesian University of Technology, Konarskiego 18, 44-100 Gliwice, Poland

autor

Baranowski A.

• Faculty of Energy and Environmental Engineering, The Silesian University of Technology, Konarskiego 18, 44-100 Gliwice, Poland

Bibliografia

• [1] Pavlogeorgatos G.; Environmental parameters in museums. Building and Environment, Vol.38, 2003; pp.1457-1462.
• [2] EN 15757:2010 Conservation of cultural property ― Specifications for temperature and relative humidity to limit climate-induced mechanical damage in organic hygroscopic materials.
• [3] Camuffo D.; Microclimate for Cultural Heritage. Elsevier Science, 1998.
• [4] La Gennusa M., Lascari G., Rizzo G., Scaccianoce G.; Conflicting needs of the thermal indoor environment of museums: In search of a practical compromise. Journal of Cultural Heritage, Vol.9, No.2, 2008; pp.125-134.
• [5] Mueller H.F.O.; Energy efficient museum buildings. Renewable Energy, Vol.49, 2013; pp.232-236.
• [6] ASHRAE Handbook-HVAC Applications. Ch.21: Museums, Galleries, Archives, and Libraries.: American Society of Heating, Refrigerating and Air- Conditioning Engineers, Inc., Atlanta, 2007.
• [7] Corgnati S. P., Perino M.; CFD application to optimize the ventilation strategy of Senate Room at Palazzo Madama in Turin (Italy). Journal of Cultural Heritage, Vol.14, 2013; pp.62-69.
• [8] Jeonga J-H., Lee K-H.; The physical environment in museums and its effects on visitors’ satisfaction. Building and Environment Vol.41, 2006, pp.963-969.
• [9] Ascione F., Bellia L., Capozzoli A., Minichiello F.; Energy saving strategies in air-conditioning for museums. Applied Thermal Engineering, Vol.29, 2009; pp.676-686.
• [10] Lipska B., Trzeciakiewicz Z., Ferdyn-Grygierek J., Popiołek Z.; The improvement of thermal comfort and air quality in the historic assembly hall of a university. Indoor and Built Environment, Vol.21, 2012; pp.332-347.
• [11] Ferdyn-Grygierek J.; Indoor environment quality in the museum building and its effect on heating and cooling demand. Energy and Buildings, Vol.85, 2014; pp.32-44.
• [12] Ferdyn-Grygierek J., Baranowski A.; Internal environment in the museum building – assessment and improvement of air exchange and its impact on energy demand for heating. Energy and Buildings, Vol.92, 2015; pp.45-54.
• [13] La Gennusa M., Rizzo G., Scaccianoce G., Nicoletti F.; Control of indoor environments in heritage buildings: experimental measurements in an old Italian museum and proposal of a methodology. Journal of Cultural Heritage, Vol.6, 2005; pp.147-155.
• [14] Camuffo D., Bernardi A., Sturaro G., Valentino A.; The microclimate inside the Pollaiolo and Botticelli rooms in the Uffizi Gallery. Florence Journal of Cultural Heritage, Vol.3, 2002; pp.155-161.
• [15] Camuffo D., Pagan E., Bernardi A., Becherini F.; The impact of heating, lighting and people in re-using historical buildings: a case study. Journal of Cultural Heritage, Vol.5, 2004; pp.409-416.
• [16] Ascione F., Bellia L., Capozzoli A.; A coupled numerical approach on museum air conditioning: Energy and fluid-dynamic analysis. Applied Energy Vol.103, 2013; p.416-427.
• [17] Fanger P.O.; Thermal comfort, Danish Technical Press., Copenhagen, 1970.
• [18] IDA Indoor Climate and Energy 4.0, EQUA Simulation AB, 2009.
• [19] Baranowski A., Ferdyn-Grygierek J.; Energy demand for heating and ventilation in museum buildings before and after thermo modernization – numerical analysis. Proceedings of the 2nd international conference, Kaunas, Lithuania, 2010.
• [20] Roulet C-A.; Ventilation and Airflow in Buildings. Earthscan, London 2008.
• [21] Mahyuddin N., Awbi H.B.; A Review of CO2 Measurement Procedures in Ventilation Research. International Journal of Ventilation, Vol.10, No.4, 2012, pp. 353-370.
• [22] Baranowski A., Ferdyn-Grygierek J.; Numerical prediction of the air exchange in the museum premises equipped with natural ventilation systems. Proceedings of the 33rd AIVC Conference and 2nd TightVent Conference. Copenhagen, 2012.
• [23] EN ISO 7730 Moderate thermal environments – Determination of the PMV and PPD indices and specification of the conditions for thermal comfort, 1997.