Experimental Study of Thermal Conductivity of Concrete with Biosourced Material for Saved Energy in Buildings

[1] H. Necib and B. Necib, “Improve the calculation accuracy of the optimal insulation thickness in building walls as determined by a dynamic heat transfer model,” Asian Journal of Civil Engineering, 21, 5, (2020) 903-913 Search in Google Scholar

[2] H. Necib, R. Belakroum, and K. Belakroum, “Amélioration de l’isolation thermique des habitats dans les régions chaudes et arides”, Third International Conference on Energy, Materials, Applied Energetics and Pollution. ICEMAEP2016, October30-31, (2016) Constantine, Algeria Search in Google Scholar

[3] E. Tunçbilek, A. Komerska, and M. Arıcı, “Optimisation of wall insulation thickness using energy management strategies: Intermittent versus continuous operation schedule,” Sustainable Energy Technologies and Assessments, 49 (2022) 101778 Search in Google Scholar

[4] S. Nadia, S. Noureddine, N. Hichem, and D. Djamila, “Experimental study of thermal performance and the contribution of plant-covered walls to the thermal behavior of building,” Energy Procedia, 36 (2013) 995-1001 Search in Google Scholar

[5] G. Mangone and K. van der Linden, “Forest microclimates: Investigating the performance potential of vegetation at the building space scale,” Building and Environment, 73 (2014) 12-23 Search in Google Scholar

[6] E. Erell and B. Zhou, “The effect of increasing surface cover vegetation on urban microclimate and energy demand for building heating and cooling,” Building and Environment, 213, (2022) 108867 Search in Google Scholar

[7] M. Cherier, T. Benouaz, S. Bekkouche, and M. Hamdani, “Some solar passive concepts in habitat through natural ventilation case study: Dry climate in Algeria Ghardaia,” Case studies in thermal engineering, 12 (2018) 1-7 Search in Google Scholar

[8] Y. Elaouzy and A. El Fadar, “Energy, economic and environmental benefits of integrating passive design strategies into buildings: A review,” Renewable and Sustainable Energy Reviews, 167, (2022) 112828 Search in Google Scholar

[9] M. A. Mujeebu and F. Bano, “Integration of passive energy conservation measures in a detached residential building design in warm humid climate,” Energy, 255 (2022) 124587 Search in Google Scholar

[10] N. Hichem, S. Noureddine, S. Nadia, and D. Djamila, “Experimental and numerical study of a usual brick filled with PCM to improve the thermal inertia of buildings,” Energy Procedia, 36 (2013) 766-775 Search in Google Scholar

[11] J. Hou, Y. Huang, J. Zhang, X. Meng, and B. J. Dewancker, “Influence of phase change material (PCM) parameters on the thermal performance of lightweight building walls with different thermal resistances,” Case Studies in Thermal Engineering, 31(2022)101844 Search in Google Scholar

[12] X. Sun, Y. Zhang, K. Xie, and M. A. Medina, “A parametric study on the thermal response of a building wall with a phase change material (PCM) layer for passive space cooling” Journal of Energy Storage, 47 (2022) 103548 Search in Google Scholar

[13] D. Kim, Y. Yoon, J. Lee, P. J. Mago, K. Lee, and H. Cho, “Design and Implementation of Smart Buildings: A Review of Current Research Trend”, Energies, 15, 12 (2022) 4278 Search in Google Scholar

[14] E. Li, L. Chen, T. Zhang, J. Zhu, and R. Hou, “A nearly zero energy building design method based on architecture form design for high solar exposure areas in China’s severe cold and cold regions” Journal of Building Engineering, 45 (2022) 103641 Search in Google Scholar

[15] M. Charai, M. Salhi, O. Horma, A. Mezrhab, M. Karkri, and S. Amraqui, “Thermal and mechanical characterization of adobes bio-sourced with Pennisetum setaceum fibers and an application for modern buildings”, Construction and Building Materials, 326 (2022) 126809 Search in Google Scholar

[16] R. Belakroun et al., “Experimental investigation of mechanical and thermal properties of a new biosourced insulation material”, International Scientific Journal of Environmental Science, 4 (2015) 78-81 Search in Google Scholar

[17] R. Belakroum et al., “Design and properties of a new sustainable construction material based on date palm fibers and lime”, Construction and Building Materials, 184 (2018) 330-343 Search in Google Scholar

[18] J. Claramunt, M. Ardanuy, J. A. García-Hortal, and R. D. Tolêdo Filho, “The hornification of vegetable fibers to improve the durability of cement mortar composites”, Cement and Concrete Composites, 33, 5 (2011) 586-595 Search in Google Scholar

[19] E. Campello, M. V. Pereira, and F. Darwish, “The effect of short metallic and polymeric fiber on the fracture behavior of cement mortar”, Procedia materials science, 3 (2014) 1914-1921 Search in Google Scholar

[20] M. Ramli and T. Dawood, “Behavior of Flowable high strength concrete repair material for sustainable Engineering construction”, in Proceedings of the 2nd International Conference on Built Environment in Developing Countries (ICBEDC’08) (2008) 444-460 Search in Google Scholar

[21] E. T. Dawood and M. Ramli, “High strength characteristics of cement mortar reinforced with hybrid fibres”, Construction and building materials, 25, 5 (2011) 2240-2247 Search in Google Scholar

[22] B. Krobba, M. Bouhicha, S. Kenai, and L. Courard, “Formulation of low cost eco-repair mortar based on dune sand and Stipa tenacissima microfibers plant”, Construction and Building Materials, 171 (2018) 950-959 Search in Google Scholar

[23] S. Said, M. Habib, and M. Iqbal, “Database for building energy prediction in Saudi Arabia”, Energy Conversion and Management, 44, 1 (2003) 191-201 Search in Google Scholar

[24] K. T. Papakostas, A. M. Papadopoulos, and I. G. Vlahakis, “Optimisation of thermal protection in residential buildings using the variable base degree-days method”, International Journal of Sustainable Energy, 24, 1 (2005) 19-31 Search in Google Scholar

[25] B. M. Ziapour, M. Rahimi, and M. Y. Gendeshmin, “Thermoeconomic analysis for determining optimal insulation thickness for new composite prefabricated wall block as an external wall member in buildings”, Journal of Building Engineering, 31, (2020) 101354 Search in Google Scholar

[26] M. A. Kallioğlu, U. Ercan, A. S. Avcı, C. Fidan, and H. Karakaya, “Empirical modeling between degree days and optimum insulation thickness for external wall”, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 42, 11 (2020) 1314-1334 Search in Google Scholar

[27] H. Huang et al., “Optimum insulation thicknesses and energy conservation of building thermal insulation materials in Chinese zone of humid subtropical climate”, Sustainable Cities and Society, 52 (2020) 101840 Search in Google Scholar

[28] A. Ucar and F. Balo, “Effect of fuel type on the optimum thickness of selected insulation materials for the four different climatic regions of Turkey”, Applied Energy, 86, 5 (2009) 730-736 Search in Google Scholar

[29] Y. Wang, Z. Huang, and L. Heng, “Cost-effectiveness assessment of insulated exterior walls of residential buildings in cold climate”, International Journal of Project Management, 25, 2 (2007) 143-149 Search in Google Scholar

[30] Ö. A. Dombaycı, M. Gölcü, and Y. Pancar, “Optimization of insulation thickness for external walls using different energy-sources”, Applied Energy, 83, 9 (2006) 921-928 Search in Google Scholar

[31] K. Çomaklı and B. Yüksel, “Environmental impact of thermal insulation thickness in buildings”, Applied Thermal Engineering, 24, 5-6 (2004) 933-940 Search in Google Scholar

[32] A. Hasan, “Optimizing insulation thickness for buildings using life cycle cost”, Applied energy, 63, 2 (1999) 115-124 Search in Google Scholar

[33] L. Derradji, K. Imessad, M. Amara, and F. B. Errebai, “A study on residential energy requirement and the effect of the glazing on the optimum insulation thickness”, Applied Thermal Engineering, 112 (2017) 975-985 Search in Google Scholar

[34] “Document Technique Reglementaire - Reglementation Thermique Du Batiment,” in DTR C3-T, C. N. d. E. e. d. R. I. d. B.-C. -, Ed., ed. Alger: CNERIB (2011) Search in Google Scholar