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THERMOPHYSICAL CHARACTERISTICS OF ECO-FRIENDLY CONCRETE CONTAINING RECYCLED HDPE AS PARTIAL SAND REPLACEMENT
Keywords:
waste, concrete, HDPE, thermophysical properties, sand, ecological concrete.DOI:
https://doi.org/10.17654/0973576323037Abstract
In the environmental field, the valorization of plastic waste has become a primary issue. The approach is achievable by developing ways to use this waste as an alternative to make new building materials. Their reuse can promote the elimination of these wastes and the protection of the environment, as well as the progress in sustainable development. The main objective of this study is to develop the functionality of the thermal properties of concrete by incorporating HDPE waste in an ecological concrete mix. This concrete is characterized by the partial replacement of the sand by HDPE (5%, 10%, 15%, 20%, 25% and 30%). For this purpose, experimental studies were made to determine the thermophysical parameters including thermal conductivity and volumetric specific heat at an ambient temperature of 24°C. The results obtained show that the density in the dry state has decreased by a rate of 13%. This resulted a decrease in thermal conductivity, specific heat and thermal diffusivity by 33.91%, 25.45% and 16.13%, respectively, compared to the reference concrete. This method has improved the thermal performance of a sustainable and environmental-friendly building material.
Received: May 3, 2023
Accepted: June 14, 2023
References
I. Iadav, Laboratory investigations of the properties of concrete containing recycled plastic aggregates, Laboratory Investigations of the Properties of Concrete Containing Recycled Plastic Aggregates, 2008.
M. Batayneh, I. Marie and I. Asi, Use of selected waste materials in concrete mixes, Waste Management 27(12) (2007), 1870-1876.
D. K. Dadzie, A. K. Kaliluthin and D. R. Kumar, Exploration of waste plastic bottles use in construction, Civil Engineering Journal 6(11) (2020), 2262-2272.
F. Tahir, S. Sbahieh and S. G. Al-Ghamdi, Environmental impacts of using recycled plastics in concrete, Materials Today: Proceedings 62 (2022), 4013-4017.
A. Kumi-Larbi, D. Yunana, P. Kamsouloum, M. Webster, D. C. Wilson and C. Cheeseman, Recycling waste plastics in developing countries: use of low-density polyethylene water sachets to form plastic bonded sand blocks, Waste Management 80 (2018), 112-118.
R. M. Bajracharya, A. C. Manalo, W. Karunasena and K. Lau, An overview of mechanical properties and durability of glass-fibre reinforced recycled mixed plastic waste composites, Materials and Design 62 (2014), 98-112.
M. Amin, B. A. Tayeh and I. S. Agwa, Effect of using mineral admixtures and ceramic wastes as coarse aggregates on properties of ultrahigh-performance concrete, Journal of Cleaner Production 273 (2020), 123073.
M. A. Al-Osta, A. S. Al-Tamimi, S. M. Al-Tarbi, O. S. Baghabra Al-Amoudi, W. A. Al-Awsh and T. A. Saleh, Development of sustainable concrete using recycled high-density polyethylene and crumb tires: mechanical and thermal properties, Journal of Building Engineering 45 (2022), 103399.
W. A. Al-Awsh, O. S. Baghabra Al-Amoudi, M. A. Al-Osta, A. Ahmad and T. A. Saleh, Experimental assessment of the thermal and mechanical performance of insulated concrete blocks, Journal of Cleaner Production 283 (2021), 124624.
Md. J. Islam, Md. Shahjalal and N. M. A. Haque, Mechanical and durability properties of concrete with recycled polypropylene waste plastic as a partial replacement of coarse aggregate, Journal of Building Engineering 54 (2022), 104597.
Q. Mustafa Abdullah and J. H. Haido, Response of hybrid concrete incorporating eco-friendly waste PET fiber: experimental and analytical investigations, Construction and Building Materials 354 (2022), 129071.
S. Bahij, S. Omary and F. Feugeas, Fresh and hardened properties of concrete containing different forms of plastic waste - a review, Waste Management 113 (2020), 157-175.
F. Fraternali, V. Ciancia and R. Chechile, Experimental study of the thermo-mechanical properties of recycled PET fiber-reinforced concrete, Composite Structures 93(9) (2011), 2368-2374.
R. Merli, M. Preziosi and A. Acampora, Recycled fibers in reinforced concrete: a systematic literature review, Journal of Cleaner Production 248 (2020), 119207.
A. Samaouali, H. S. E. Idrissi and Y. E. Rhaffari, Thermal conductivity and porosity characterization of calcarenites stones used in historical buildings, JP Journal of Heat and Mass Transfer 21(2) (2020), 237-250.
M. Abdelkrim, S. Abderrahim and E. Abdellah, The thermal behavior of the laminated composite material (clay reinforced with copper fibers) on the effect of temperature and composition, JP Journal of Heat and Mass Transfer 20(2) (2020), 189-204.
S. Belarouf, A. Samaouali and A. Moufakkir, Thermal behavior of concrete with recycled concrete aggregates on the effect of temperature and composition, JP Journal of Heat and Mass Transfer 21(2) (2020), 167-182.
O. Nasry, A. Samaouali and H. S. El Idrissi, Experimental study of the thermophysical properties of the red earth composite stabilized with cement containing waste glass powder, Crystals 12(3) (2022), 396.
H. S. E. Idrissi, Y. E. Rhaffari and O. Nasry, Thermo-physical characterization of oil shale from the Timahdit region in Morocco, JP Journal of Heat and Mass Transfer 24(1) (2021), 97-111.
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