Abstract
A hybrid ventilation system combining both natural and mechanical ventilation has proven very promising in moderating indoor climate, based on its ability to ensure indoor air quality with low energy consumption. The system maintains indoor thermal comfort conditions by switching to mechanical mode whenever natural ventilation is not possible. However, the application of such a system in severe arid climates is still very limited and challenging, and almost half the urban peak load for energy demand is used to supply cooling and air-conditioning in summer. This paper assessed the application of the hybrid ventilation mode for an educational building in a hot, arid climate, with the aim of reducing the building’s energy consumption without compromising the occupants’ thermal comfort. A dynamic simulation was conducted using Integrated Environmental Simulation in a Virtual Environment building energy software, and the outcomes were validated against actual consumption data over one year. The results were then evaluated for indoor thermal comfort and energy reduction and showed the potential of the hybrid system to provide energy savings of 23% across the year. Better energy performance was achieved during the cooler seasons (33.5%) compared to hot (17.1%). When photovoltaic systems were incorporated, by examining different inclination angles and locations for energy savings and carbon emissions (CO2) reductions, the outcomes proved that photovoltaic south and a 25° tilt angle recorded the maximum energy and minimum CO2 emissions annually. This integration of hybrid ventilation and photovoltaics reduced the building’s energy consumption from 106.1 MWh to 36.6 MWh, saving almost 85% in total annual energy and cut down the carbon emissions from 55,227 kgCO2 to 6390 kgCO2.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- ASHRAE:
-
American Society of Heating, Refrigerating and Air-Conditioning Engineers
- BSI:
-
British Standards Institution
- BWh:
-
Hot desert climate
- CIBSI:
-
Chartered Institution of Building Services Engineers
- °C:
-
Celsius/Centigrade
- \(i\) :
-
Variable i
- kWh:
-
Kilowatt-hour
- m2 :
-
Meter square
- MWh:
-
Megawatt-hour
- m/s:
-
Metre per second
- N :
-
Number of non-missing data points
- RMSE:
-
Root Mean Square Error
- W/m2-K:
-
Watts per meter square-Kelvin
- \({x}_{i}\) :
-
Actual observations time series
- x i^:
-
Estimated time series
References
Albatayneh, A., Alterman, D., Page, A., & Moghtaderi, B. (2018). The impact of the thermal comfort models on the prediction of building energy consumption. Sustainability, 10, 3609. https://doi.org/10.3390/su10103609
Alves, C. A., Duarte, D. H., & Gonçalves, F. L. (2015). Residential buildings’ thermal performance and comfort for the elderly under climate changes context in the city of São Paulo, Brazil. Energy and Buildings, 114, 62–71.
American Society of Heating, & Refrigerating and Air-Conditioning Engineers . (2009). ASHRAE Handbook: Fundamentals; American Society of Heating: Atlanta (p. 2009). GA.
Annan, G., Ghaddar, N., & Ghali, K. (2014). Natural ventilation in Beirut residential buildings for extended comfort hours. International Journal of Sustainable Energy, 35(10), 1–18.
Bahrain Electricity and Water Authority (EWA). Retrieved from 26 Mar 2021. https://www.ewa.bh/en/Customer/BillsTariffs/electricity-water-tariffs
Bairi, A. (1990). Method of quick determination of the angle of slope and the orientation of solar collectors without a sun tracking system. Solar & Wind Technology, 7, 327–330.
Bari, S. (2000). Optimum slope angle and orientation of solar collectors for di_erent periods of possible utilization. Energy Converservation Management, 41, 855–860.
Bianco, V., Manca, O., & Nardini, S. (2009). Electricity consumption forecasting in Italy using linear regression models. Energy, 34(9), 1413–1421.
Brager, G., & de Dear, R. (2000). A Standard for Natural Ventilation. UC Berkeley: Center for the Built Environment. Retrieved from https://escholarship.org/uc/item/3f73w323
BSI, BS EN 15251. (2007). Indoor environmental input parameters for design and assessment of energy performance of buildings addressing indoor air quality, thermal environment, lighting and acoustics, British Standards Institution, London, 2008.
Cardinale, N., Micucci, M., & Ruggiero, F. (2003). Analysis of energy saving using natural ventilation in a traditional Italian building. Energy and Buildings, 35(2), 153–159.
CIBSE (2006). Environmental Design Guide A, CIBSE Publications, London.
CIBSE, CIBSE TM52 (2013). The limits of thermal comfort: Avoiding overheating in European buildings (p. 2013). The Chartered Institution of Building Services Engineers.
Cipriano, J., Mor, G., Chemisana, D., Pérez, D., Gamboa, G., & Cipriano, X. (2015). Evaluation of a multi-stage guided search approach for the calibration of building energy simulation models. Energy Buildings, 87, 370–385.
Clarke, J. A. (2001). Energy simulation in building design. Oxford: Butterworth Heinernann.
Daaboul, J., Ghali, K., & Ghaddar, N. (2017). Mixed-mode ventilation and air conditioning as alternative for energy savings: a case study in Beirut current and future climate. Energy Efficiency, 11, 13–30. https://doi.org/10.1007/s12053-017-9546-z.
DS/EN. 2008. DS/EN 15603: Energy performance of buildings - Overall energy use and definition of energy ratings. Charlotten lund Denmark.
Elnabawi, M. H., & Hamza, N. (2019). Behavioural perspectives of outdoor thermal comfort in urban areas: Acritical review. Atmosphere, 11, 51.
Elnabawi, Mohamed H., & Hamza, Neveen. (2020). A behavioural analysis of outdoor thermal comfort: A comparative analysis between formal and informal shading practices in urban sites. Sustainability, 12(21), 9032.
Evola, G., Costanzo, V., Infantone, M., & Marletta, L. (2021). Typical-year and multi-year building energy simulation approaches: A critical comparison, Energy, Volume 219, 2021. ISSN, 119591, 0360–5442. https://doi.org/10.1016/j.energy.2020.119591
Ezzeldin, S., & Rees, S. J. (2013). The potential for office buildings with mixed-mode ventilation and low energy cooling systems in arid climates. Energy and Buildings, 65, 368–381.
Feng, W., Zhang, Q., Ji, H., Wang, R., Zhou, N., Ye, Q., Hao, B., Li, Y., Luo, D., & Lau, S. S. Y. (2019). A review of net zero energy buildings in hot and humid climates: Experience learned from 34 case study buildings. Renewable and Sustainable Energy Reviews. https://doi.org/10.1016/j.rser.2019.109303109303
Fiorentini, M., Tartarini, F., LedoGomis, L., Daly, D., & Cooper, P. (2019). Development of an enthalpy-based index to assess climatic potential for ventilative cooling of buildings: An Australian example. Applied Energy. https://doi.org/10.1016/j.apenergy.2019.04.165113169
Givoni, B. (1992). Comfort, climate analysis and building design guidelines. Energy Buildings, 18(1), 11–23. https://doi.org/10.1016/0378-7788(92)90047-
Gomis, L. L., Fiorentini, M., & Daly, D. (2021). Potential and practical management of hybrid ventilation in buildings. Energy and Buildings. https://doi.org/10.1016/j.enbuild.2020.110597
Griffiths, M., & Eftekhari, M. (2008). Control of CO2 in a naturally ventilated classroom. Energy and Buildings, 40(4), 556–560.
Hailu, G., & Fung, A. S. (2019). Optimum tilt angle and orientation of photovoltaic thermal system for application in greater toronto area, Canada. Sustainability, 11, 6443.
Harish, V. S. K. V., & Kumar, Arun. (2016). A review on modeling and simulation of building energy systems. Renewable and Sustainable Energy Reviews, Elsevier, 56, 1272–1292.
Harlan, S. H., Brazel, A. J., Prashad, L., Stefanov, W. L., & Larsen, L. (2006). Neighborhood microclimates and vulnerability to heat stress. Journal of Social Science & Medicine, 63, 2847–2863.
Hong, T., Kim, J., Jeong, J., Lee, M., & Ji, C. (2017). Automatic calibration model of a building energy simulation using optimization algorithm. Energy Procedia, 105, 3698–3704.
Humphreys, M., Nicol, F., & Roaf, S. (2015). Adaptive thermal comfort: Foundations and analysis. Taylor & Francis Group.
Humphreys, M. A., & Nicol, J. F. (1998). Understanding the adaptive approach to thermal comfort. ASHRAE Transactions, 104, 991–998.
Humphreys, M. A., Rijal, H. B., & Nicol, J. F. (2013). Updating the adaptive relation between climate and comfort indoors; new insights and an extended database. Building and Environment, 63(2013), 40–55. https://doi.org/10.1016/j.buildenv.2013.01.024.
IEA. (2019). Global Energy & CO2 Status Report 2019, IEA, Paris. https://www.iea.org/reports/global-energy-co2-status-report-2019
Kalogirou, S. A. (2013). Building integration of solar renewable energy systems towards zero or nearly zero energy buildings. International Journal of Low-Carbon Technologies, 10, 379–385.
Kern, J., & Harris, I. (1975). On the optimum tilt of a solar collector. Solar Energy, 17, 97–102.
Khovalyg, D., Kazanci, O. B., Halvorsen, H., Gundlach, I., Bahnfleth, W. P., Toftum, J., & Olesen, B. W. (2020). Critical review of standards for indoor thermal environment and air quality. Energy Buildings, 213, 109819. https://doi.org/10.1016/j.enbuild.2020.109819
Kim, J., Hong, T., & Koo, C. W. (2012). Economic and environmental evaluation model for selecting the optimum design of green roof systems in elementary schools. Environmental Science & Technology, 46(15), 8475–8483.
Maile, T., Fischer, M., & Bazjanac, V. (2007). Building energy performance simulation tools-a life-cycle and interoperable perspective, in CIFE Working Paper 107, 1–49.
Mardiana, A., & Riffat, S. B. (2015). Building energy consumption and carbon dioxide emissions: Threat to climate change. J Earth Sci Climat. Change, S3(001), 1–3. https://doi.org/10.4172/2157-7617.S3-001
Morsy, A. D., & Al-Bahrana, N. (1995). Energy conservation in buildings in Bahrain. University of Bahrain.
Nikolopoulou, M., & Steemers, K. (2003). Thermal comfort and psychological adaptation as a guide for designing urban spaces. Journal of Energy and Buildlings, 35, 95–101.
Peel, M. C., Finlayson, B. L., & McMahon, T. A. (2007). Updated world map of the Köppen-Geiger climate classification. Hydrology and Earth System Sciences, 11, 1633–1644.
Pfafferott, J., Herkel, S., & Wambsganß, M. (2004). Design, monitoring and evaluation of a low energy office building with passive cooling by night ventilation. Energy and Buildings, 36(5), 455–465.
Pollock, M., Roderick, Y., McEwan, D., & Wheatley, C. (2009). Building simulation as an assisting tool in designing an energy efficient building: a case study. Proceedings of the Eleventh International IBPSA Conference, Glasgow, Scotland, July 27–30, 2009.
Prado, R. T. A., & Ferreira, F. L. (2005). Measurement of albedo and analysis of its influence the surface temperature of building roof materials. Energy and Buildings, 37, 295–300.
Rijal, H. B., Tuohy, P., Humphreys, M. A., Nicol, J. F., Samuel, A., & Clarke, J. (2007). Using results from field surveys to predict the effect of open windows on thermal comfort and energy use in buildings. Energy Buildings, 39(7), 823–836. https://doi.org/10.1016/j.enbuild.2007.02.003
Rupp, R. F., & Ghisi, E. (2014). What is the most adequate method to assess thermal comfort in hybrid commercial buildings located in hot-humid summer climate? Renewable and Sustainable Energy Reviews. https://doi.org/10.1016/j.rser.2013.08.102
Sudimac, B., Ugrinović, A., & Jurčević, M. (2020). The application of photovoltaic systems in sacred buildings for the purpose of electric power production: The case study of the Cathedral of St. Michael the Archangel in Belgrade. Sustainability, 12(4), 1–18.
Taleb, H. M. (2015). Natural ventilation as energy efficient solution for achieving low-energy houses in Dubai. Energy and Buildings, 99, 284–291.
UN Environment and International Energy Agency. (2017). Towards a zero-emission, efficient, and resilient buildings and construction sector. Global Status Report 2017.
Ürge-Vorsatz, D., Petrichenko, K., Staniec, M., & J. (2013). EomEnergy use in buildings in a long-term perspective. Curr Opin Environ Sustain, 5(2), 141–151.
Wang, H., & Chen, Q. (2014). Impact of climate change heating and cooling energy use in buildings in the United States. Energy and Buildings, 82, 428–436.
Wang, L., & Greenberg, S. (2015). Window operation and impacts on building energy consumption. Energy and Buildings, 92, 313–321.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Human and animal rights
With reference to the above-mentioned manuscript, the authors whose names are listed immediately below certify that This study does not contain any studies with human participants or animals performed by any of the authors
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Elnabawi, M.H., Saber, E. Reducing carbon footprint and cooling demand in arid climates using an integrated hybrid ventilation and photovoltaic approach. Environ Dev Sustain 24, 3396–3418 (2022). https://doi.org/10.1007/s10668-021-01571-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10668-021-01571-1