CFD Comfort Analysis of a Sustainable Solution for Church Heating

Abstract Historic building heating and, in particular, church heating represents a challenging task because many objectives have to be reached simultaneously, such as occupants thermal comfort and optimal internal climate suitable for the preservation of fragile building components and artworks. Moreover, current requirements for sustainability impose to make efforts, where possible, to minimize the amount of energy needed and the consequent environmental impact. Innovative solutions are currently under research and development and are mainly based on electric radiant surfaces. The present work represents actually a detailed performance analysis of a novel hydronic high-efficiency pew-based heating system coupled with a ground-source heat pump. The system was specifically developed for the above-described application field, with particular reference to the Basilica di Collemaggio (L’Aquila, Italy), a church of worldwide relevance currently under restoration. In detail, within the work a three-dimensional CFD analysis of the heating solution was carried out considering as application field a virtual test room containing two benches with three virtual sitting manikins. Heat exchanges between the human body surfaces, the room environment and the heated benches were simulated in order to assess the whole performance. The results show that the air temperature in the room is not significantly influenced by the heating system, but the heat is directly radiated to people, ensuring comfortable conditions and contributing to artworks preservation.

[1]  Tiziana Cardinale,et al.  The Influence of Indoor Microclimate on Thermal Comfort and Conservation of Artworks: The Case Study of the Cathedral of Matera (South Italy) , 2014 .

[3]  Muhsin Kilic,et al.  Numerical analysis of air flow, heat transfer, moisture transport and thermal comfort in a room heat , 2011 .

[4]  Massimiliano Manfren,et al.  Energy Savings through Variable Speed Compressor Heat Pump Systems , 2012 .

[5]  R. Grieken,et al.  Influence of different types of heating systems on particulate air pollutant deposition: The case of churches situated in a cold climate , 2007 .

[6]  Łukasz Bratasz,et al.  The impact of electric overhead radiant heating on the indoor environment of historic churches , 2007 .

[7]  D Camuffo,et al.  Church Heating and the Preservation of the Cultural Heritage. Guide to the Analysis of the Pros and Cons of Various Heating Systems , 2006 .

[8]  Standard Ashrae Thermal Environmental Conditions for Human Occupancy , 1992 .

[9]  Massimiliano Manfren,et al.  Sustainable church heating: The Basilica di Collemaggio case-study , 2016 .

[10]  Sirkka Rissanen,et al.  An advanced church heating system favourable to artworks: A contribution to European standardisation , 2010 .

[11]  Massimiliano Manfren,et al.  Cost optimal analysis of heat pump technology adoption in residential reference buildings , 2013 .

[12]  Niccolò Aste,et al.  ENERGY RETROFIT OF HISTORICAL BUILDINGS: AN ITALIAN CASE STUDY , 2012 .

[13]  Dario Camuffo,et al.  Laboratory tests for the evaluation of the heat distribution efficiency of the Friendly-Heating heaters , 2015 .

[14]  Giuseppe Peter Vanoli,et al.  Energy retrofit of an educational building in the ancient center of Benevento. Feasibility study of energy savings and respect of the historical value , 2015 .