Brown, S. and Beausoleil-Morrison, I. (2023a). Experimental performance of a full-scale solar thermal system designed to meet residential heating demands with passive solar energy. Solar Energy, 264:112044. [ DOI ]
Brown, S. and Beausoleil-Morrison, I. (2023c). Long-term implementation of a model predictive controller for a hydronic floor heating and cooling system in a highly glazed house in canada. Applied Energy, 349:121677. [ DOI ]
Brown, S. and Beausoleil-Morrison, I. (2023b). Investigation of a model predictive controller for use in a highly glazed house with hydronic floor heating and cooling. Science and Technology for the Built Environment, 29(4):347--365. [ DOI ]
Pinto, R. and Beausoleil-Morrison, I. (2023). Experimental validation of a numerical model for a sand-based seasonal thermal energy storage. Journal of Building Performance Simulation, 16(6):644--659. [ DOI ]
Brown, S. and Beausoleil-Morrison, I. (2021). Characterizing the performance of a passive solar house with hydronic floor energy capture system--heating season experiments. Energy and Buildings, 252:111404. [ DOI ]
Meister, C. and Beausoleil-Morrison, I. (2021). Experimental and modelled performance of a building-scale solar thermal system with seasonal storage water tank. Solar Energy, 222:145--159. [ DOI ]
Pinamonti, M., Beausoleil-Morrison, I., Prada, A., and Baggio, P. (2021). Water-to-water heat pump integration in a solar seasonal storage system for space heating and domestic hot water production of a single-family house in a cold climate. Solar Energy, 213:300--311. [ DOI ]
Brideau, S. A., Beausoleil-Morrison, I., and Kummert, M. (2020). Effects of controls and floor construction of radiant floor heating systems for residential application with high variability of solar gains. Science and Technology for the Built Environment, 26(4):524--540. [ DOI ]
Dumitrascu, L. and Beausoleil-Morrison, I. (2020). A model for predicting the solar reflectivity of the ground that considers the effects of accumulating and melting snow. Journal of Building Performance Simulation, 13(3):334--346. [ DOI ]
Manganielloa, P., Govaerts, J., Horvatha, I. T., Chowdhury, G., Yordanov, G. H., Goverde, H., Aldalali, B., Beausoleil-Morrison, I., Valkealahti, S., Lappalainen, K., and Poortmans, J. (2020). Tuning electricity generation throughout the year with PV module technology. Renewable Energy, 160:418--427. [ DOI ]
Beausoleil-Morrison, I., Kemery, B., Wills, A. D., and Meister, C. (2019). Design and simulated performance of a solar-thermal system employing seasonal storage for providing the majority of space heating and domestic hot water heating needs to a single-family house in a cold climate. Solar Energy, 191:57--69. [ DOI ]
Beausoleil-Morrison, I. (2019). Learning the fundamentals of building performance simulation through an experiential teaching approach. Journal of Building Performance Simulation, 12(3):308--325. [ DOI ]
Brideau, S., Beausoleil-Morrison, I., and Kummert, M. (2018). Above-floor tube-and-plate radiant floor model development and validation. Journal of Building Performance Simulation, 11(4):449--469. [ DOI ]
Pinto, R. and Beausoleil-Morrison, I. (2022). Predicting the thermal performance of a sand-based seasonal thermal storage. In Proc. eSim 2022, Ottawa Canada. [ http ]
Dumitrascu, L. and Beausoleil-Morrison, I. (2019). On the prediction of ground-reflected solar radiation and its relevance in the context of building performance simulation (BPS). In Proc. Building Simulation 2019, pages 4754--4761, Rome, Italy. [ .pdf ]
Dumitrascu, L. and Beausoleil-Morrison, I. (2018). Snow/ground reflectivity model for simulating energy use in buildings. In Proc. eSim 2018, Montréal, Canada.
Govaerts, J., Horvath, I. T., Goverde, H., Aldalali, B., Beausoleil-Morrison, I., and Poortmans, J. (2018). A lower TC: In the future maybe not always the best idea? In Proc. 35th European Photovoltaic Solar Energy Conference and Exhibition, Brussels, Belgium. [ DOI ]
Meister, C. and Beausoleil-Morrison, I. (2018). Preliminary results for the first year of operation of a seasonal storage solar combisystem for a single detached house. In Proc. EuroSun 2018, pages 1144--1153, Rapperswil, Switzerland. [ DOI ]
Beausoleil-Morrison, I., Brown, S., and Brideau, S. (2017). Full-scale experimental investigation of a heat-pump-based system for maximizing passive solar gains in housing--preliminary results. In Proc. IEA heat pump conference 2017, Rotterdam, Netherlands. [ http ]
Brideau, S., Beausoleil-Morrison, I., and Kummert, M. (2017). Experimental validation of above-floor tube-and-plate radiant floor model. In Proc. Building Simulation 2017, pages 126--135, San Francisco, USA. [ .pdf ]
Meister, C. and Beausoleil-Morrison, I. (2017). Experimental characterization of a solar combisystem with seasonal storage for a single detached house. In Proc. Solar World Congress 2017, Abu Dhabi, United Arab Emirates. [ .pdf ]
Kosteniuk, I. (2023). Modelling and simulation of seasonal, solar driven sorption thermal energy storage in cold climate residential application. Master's thesis, Carleton University.
Meister, C. H. (2022). Seasonal thermal energy storage in buried water tanks for single detached houses. PhD thesis, Carleton University. [ DOI ]
Dmytrenko, N. (2018). Assessing the impact of rock-bed storage for tempering air-to-air heat pumps. Master's thesis, Carleton University. [ http ]
Dumitrascu, L. (2018). Empirical model for snow/ground reflectivity prediction. Master's thesis, Carleton University. [ http ]
Kemery, B. P. (2017). Analysis and design of a solar-combisystem for high solar fraction canadian housing with diurnal and seasonal water-based thermal stores. Master's thesis, Carleton University. [ http ]
Brideau, S. (2016). Collection and storage of solar gains incident on a radiant floor in highly glazed houses. PhD thesis, Carleton University. [ http ]
Beausoleil-Morrison, I. (2021). Fundamentals of Building Performance Simulation. Routledge, New York, USA. ISBN: 978-0-367-51806-6. [ http ]
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