Thermal behavior and energy saving analysis of a flat with different energy efficiency measures in six climates

El-Hadi Drissi Lamrhari; Brahim Benhamou

doi:10.1007/s12273-018-0467-3

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Research Article

Thermal behavior and energy saving analysis of a flat with different energy efficiency measures in six climates

El-Hadi Drissi Lamrhari^{¹^,²}, Brahim Benhamou^{¹^,²}(

)

1Energy Processes Research Group at LMFE (URAC 27), Faculty of Science Semlalia, Cadi Ayyad University, Marrakech, Morocco

2EnR2E laboratory, National Center of Studies and Research on Water and Energy (CNEREE), Cadi Ayyad University, Marrakech, Morocco

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Abstract

This article aims at studying the impact of many construction parameters of a flat on its energy performance and thermal comfort. The studied parameters are: the envelope thermal insulation, the orientation, the floor level, the ground coupling, the roof and the external walls absorption coefficient and the controlled mechanical ventilation. The TRNSYS based numerical study is performed in six different climates ranging from cold to desert one. The numerical model has been validated against experimental results obtained from summer and winter long term monitoring campaigns of the flat located in the Marrakech city, Morocco. The apartment’s heating and cooling loads as well as thermal discomfort indexes are calculated for the possible eleven configurations combining the studied parameters. The results show that high thermal insulation of the walls leads to an apparent summer overheating with an increase in the flat’s total thermal load by up to 18% in all the considered climates, except for the cold one. It was found that the walls’ light thermal insulation resulting from the cavity wall technique is sufficient to reach an acceptable level of thermal comfort thus preventing summer overheating. Similarly, thermal insulation of the slab-on-grade floor was found to perform an increase in thermal load for hot and moderate climates by at least 67%. The best combination of all the studied energy efficiency measures for each climate conditions was evaluated via comparison to a reference case that represents the actual apartment.

Keywords

energy saving thermal performance thermal insulation ground coupling overheating thermal discomfort

References

FF Al-ajmi, I Hanby V (2008). Simulation of energy consumption for Kuwaiti domestic buildings.Energy and Buildings, 40: 1101–1109.

Crossref Google Scholar

KA Al-Sallal (1998). Sizing windows to achieve passive cooling, passive heating, and daylighting in hot arid regions. Renewable Energy, 14: 365–371.

Crossref Google Scholar

ASHRAE (1997). Handbook of Fundamentals, Chapter 24: Thermal and water vapor transmission data. Atlanta, GA, USA: American Society of Heating, Refrigerating and Air-Conditioning Engineers.

M Asim, J Dewsbury, S Kanan (2016). TRNSYS simulation of a solar cooling system for the hot climate of Pakistan. Energy Procedia, 91: 702–706.

Crossref Google Scholar

DP Aviram, AN Fried, JJ Roberts (2001). Thermal properties of a variable cavity wall. Building and Environment, 36: 1057–1072.

Crossref Google Scholar

WA Beckman, L Broman, A Fiksel, SA Klein, E Lindberg, M Schuler, J Thornton (1994). TRNSYS: The most complete solar energy system modeling and simulation software. Renewable Energy, 5: 486–488.

Crossref Google Scholar

B Benhamou, A Bennouna (2013). Energy performances of a passive building in Marrakech: Parametric study. Energy Procedia, 42: 624–632.

Crossref Google Scholar

BINAYATE (2015). Assessment of the buildings energy performance and control of the conformity with the Moroccan Thermal Regulation for Construction. Available at http://www.amee.ma/ index.php/fr/expertise/efficacite-energetique/batiment. Accessed 30 May 30 2016. (in French)

A Bolattürk (2008). Optimum insulation thicknesses for building walls with respect to cooling and heating degree-hours in the warmest zone of Turkey. Building and Environment, 43: 1055–1064.

Crossref Google Scholar

M Boumhaout, L Boukhattem, H Hamdi, B Benhamou, FA Nouh (2017). Thermomechanical characterization of a bio-composite building material: Mortar reinforced with date palm fibers mesh. Construction and Building Materials, 135: 241–250.

Crossref Google Scholar

C Buratti, E Moretti, E Belloni, F Cotana (2013). Unsteady simulation of energy performance and thermal comfort in non-residential buildings. Building and Environment, 59: 482–491.

Google Scholar

A Byrne, G Byrne, A Davies, AJ Robinson (2013). Transient and quasi-steady thermal behaviour of a building envelope due to retrofitted cavity wall and ceiling insulation. Energy and Buildings, 61: 356–365.

Google Scholar

CSN 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 contents. Available at https://www.en-standard.eu/ csn-en-15251. Accessed 14 Sept 2017.

M Dabaieh, O Wanas, MA Hgazy, E Johansson (2014). Reducing cooling demands in a hot dry climate: A simulation study for non-insulated passive cool roof thermal performance in residential buildings. Energy and Buildings, 89: 142–152.

Google Scholar

A Ebrahimpour, M Maerefat (2011). Application of advanced glazing and overhangs in residential buildings. Energy Conversion and Management, 52: 212–219.

Google Scholar

Z Fang, N Li, B Li, G Luo, Y Huang (2014). The effect of building envelope insulation on cooling energy consumption in summer. Energy and Buildings, 77: 197–205.

Google Scholar

PO Fanger (1970). Thermal Comfort: Analysis and Applications in Environmental Engineering. New York: McGraw-Hill Book Company.

B Farhanieh, S Sattari (2006). Simulation of energy saving in Iranian buildings using integrative modelling for insulation. Renewable Energy, 31: 417–425.

Google Scholar

C Flory-celini (2008). Modélisation et Positionnement de Solutions Bioclimatiques Dans Le Bâtiment Résidentiel Existant. PhD Thesis, Claude Bernard University, France. (in French)

B Givoni (1976). Man, Climate and Architecture, 2nd Edn. Cambridge, MA, USA: Harvard University Press.

B Givoni (2011). Indoor temperature reduction by passive cooling systems. Solar Energy, 85: 1692–1726.

Google Scholar

X Gong, Y Akashi, D Sumiyoshi (2012). Optimization of passive design measures for residential buildings in different Chinese areas. Building and Environment, 58: 46–57.

Google Scholar

N Hester, K Li, JR Schramski, J Crittenden (2012). Dynamic modeling of potentially conflicting energy reduction strategies for residential structures in semi-arid climates. Journal of Environmental Management, 97: 148–153.

Google Scholar

IAE (2016). Energy Efficiency Indicators highlights. Available at https:// www.iea.org/publications/freepublications/publication/energy-efficiency-indicators-highlights-2016.html. Accessed 18 Aug 2017.

ISO (2014). ISO 9869. Thermal Insulation—Building Elements In-situ Measurement of Thermal Resistance and Thermal Transmittance. Part 1: Heat Flow Meter Method. Available at https://www.iso.org/ standard/59697.html. Accessed 19 Dec 2017.

S Jaber, S Ajib (2011). Optimum, technical and energy efficiency design of residential building in Mediterranean region. Energy and Buildings, 43: 1829–1834.

Google Scholar

O Kaynakli (2012). A review of the economical and optimum thermal insulation thickness for building applications. Renewable and Sustainable Energy Reviews, 16: 415–425.

Google Scholar

M Khabbaz, B Benhamou, K Limam, P Hollmuller, H Hamdi, A Bennouna (2016). Experimental and numerical study of an earth-to-air heat exchanger for air cooling in a residential building in hot semi-arid climate. Energy and Buildings, 125: 109–121.

Google Scholar

DI Kolaitis, E Malliotakis, DA Kontogeorgos, I Mandilaras, DI Katsourinis, MA Founti (2013). Comparative assessment of internal and external thermal insulation systems for energy efficient retrofitting of residential buildings. Energy and Buildings, 64: 123–131.

Google Scholar

E Krüger, E González-Cruz, B Givoni (2010). Effectiveness of indirect evaporative cooling and thermal mass in a hot arid climate. Building and Environment, 45: 1422–1433.

Google Scholar

A Kumar, BM Suman (2013). Experimental evaluation of insulation materials for walls and roofs and their impact on indoor thermal comfort under composite climate. Building and Environment, 59: 635–643.

Google Scholar

T Kusuda, PR Achenbach (1965). Earth temperature and thermal diffusivity at selected stations in the United States. ASHRAE Transactions, 71(1): 61–74.

Google Scholar

H Mastouri, B Benhamou, H Hamdi (2013). Pebbles bed thermal storage for heating and cooling of buildings. Energy Procedia, 42: 761–764.

Google Scholar

H Mastouri, B Benhamou, H Hamdi, E Mouyal (2017). Thermal performance assessment of passive techniques integrated into a residential building in semi-arid climate. Energy and Buildings, 143: 1–16.

Google Scholar

NM ISO 7730 (2010). Institut Marocain de Normalisation, Ergonomie des ambiances thermiques-Détermination analytique et interpretation du confort thermique par le calcul des indices PMV et PPD et par des criteres de confort thermique local. Available at http://www.imanor.gov.ma/?keyword-type=course_id&s=NM+ ISO+7730. Accessed 19 Dec 2017. (in French)

M Ozel (2013). Determination of optimum insulation thickness based on cooling transmission load for building walls in a hot climate. Energy Conversion and Management, 66: 106–114.

Google Scholar

RTCM (2014). Règlement Général de Construction Fixant Les Règles de Performance Énergétique de Constructions Au Maroc. Morocco, Bulletin officiel N°6306-2014. Available at http:// www.amee.ma/index.php/ar/publicationsetmedias/publications. Accessed 25 April 2017.

SB Sadineni, S Madala, RF Boehm (2011). Passive building energy savings: A review of building envelope components. Renewable and Sustainable Energy Reviews, 15: 3617–3631.

Google Scholar

F Sick, S Schade, A Mourtada, D Uh, M Grausam (2014). Dynamic building simulations for the establishment of a moroccan thermal regulation for buildings. Journal of Green Building, 9: 145–165.

Google Scholar

I Sobhy, A Brakez, B Benhamou (2014). Effect of thermal insulation and ground coupling on thermal load of a modern house in Marrakech. In: Proceedings of the International Renewable and Sustainable Energy Conference, IRSEC 2014.

I Sobhy, A Brakez, B Benhamou (2017). Analysis for thermal behavior and energy savings of a semi-detached house with different insulation strategies in hot semi arid climate. Journal of Green Building, 12: 78–106.

Google Scholar

I Sobhy (2017). Modélisation dynamique d’un bâtiment résidentiel à Marrakech et propositions pour améliorer ses performances énergétiques. PhD Thesis, Cadi Ayyad University, Morocco. (in French)

F Stazi, A Vegliò, C Di Perna, P Munafò (2013). Experimental comparison between 3 different traditional wall constructions and dynamic simulations to identify optimal thermal insulation strategies. Energy and Buildings, 60: 429–441.

Google Scholar

F Stazi, E Tomassoni, C Di Perna (2016). Super-insulated wooden envelopes in Mediterranean climate: Summer overheating, thermal comfort optimization, environmental impact on an Italian case study. Energy and Buildings, 138: 716–732.

Google Scholar

H Suehrcke, EL Peterson, N Selby (2008). Effect of roof solar reflectance on the building heat gain in a hot climate. Energy and Buildings, 40: 2224–2235.

Google Scholar

T Van Hooff, B Blocken, JLM Hensen, HJP Timmermans (2014). On the predicted effectiveness of climate adaptation measures for residential buildings. Building and Environment, 82: 300–316.

Google Scholar

Y Yaşar, SM Kalfa (2012). The effects of window alternatives on energy efficiency and building economy in high-rise residential buildings in moderate to humid climates. Energy Conversion and Management, 64: 170–181.

Google Scholar

Building Simulation

Volume 11 Issue 6,
December 2018

Pages 1123-1144

DOI: 10.1007/s12273-018-0467-3

Cite this article:

Lamrhari E-HD, Benhamou B. Thermal behavior and energy saving analysis of a flat with different energy efficiency measures in six climates. Building Simulation, 2018, 11(6): 1123-1144. https://doi.org/10.1007/s12273-018-0467-3

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Received: 14 January 2018

Revised: 09 July 2018

Accepted: 27 July 2018

Published: 20 September 2018