New Polymer Composites Made of Recycled Polystyrene with Red Mud and Wind Blade Waste: An Industrial Ecology Case

[1] Ellen Macarthur Foundation. Circular economy introduction. (2022). https://ellenmacarthurfoundation.org/topics/circular-economy-introduction/overview.

DOI: 10.1007/978-981-15-8510-4_20

Google Scholar

[2] F. Pomponi, A. Moncaster, Circular economy for the built environment: a research framework, J Clean Prod. 143 (2017) 710-718.

DOI: 10.1016/j.jclepro.2016.12.055

Google Scholar

[3] W.R. Stahel, Circular economy, Nature. 531 (2016) 435-438.

Google Scholar

[4] G. Power, M. Gräfe, C. Klauber, Bauxite residue issues: I: current management, disposal and storage practices, Hydrometallurgy. 108 (2011) 33-45.

DOI: 10.1016/j.hydromet.2011.02.006

Google Scholar

[5] S.S. Rath, P. Archana, K. Jayasankar, A.K. Mitra, C.S Kumar, P.S. Mukherjee, B.K Mishra, Statistical modeling studies of iron recovery from red mud using thermal plasma, Plasma Sci Technol. 15 (2013) 459-464.

DOI: 10.1088/1009-0630/15/5/13

Google Scholar

[6] Red Mud Project. (2006). https://redmud.org/red-mud/disposal/.

Google Scholar

[7] H.L. Hendricks, V.E. Buchanan, Effect of material parameters on the mechanical properties of chemically treated red mud HDPE composites, Polymers and Polymer Composites. 29(8) (2011) 1126–1134.

DOI: 10.1177/0967391120954064

Google Scholar

[8] A. Gelencsér, N. Kováts, B. Turóczi, Á. Rostási, A. Hoffer, K. Imre, I. Nyirő-Kósa, D. Csákberényi-Malasics, Á. Tóth, A. Czitrovszky, A. Nagy, S. Nagy, A. Ács, A. Kovács, Á. Ferincz, Z. Hartyáni, M. Pósfai, The red mud accident in Ajka (Hungary): Characterisation and potencial health effects of fugitive dust, Environ Sci Technol. 45 (2011) 1608-1615.

DOI: 10.1021/es104005r

Google Scholar

[9] E.B. Silva Filho, M.C.M Alves, M. Motta, E.H.C Oliveira, W. Brander Junior, Study on the use of red mud for removal of dyes from textile effluents, Quim Nova. 31 (2008) 985-989.

Google Scholar

[10] S.R. Naqvia, H. Mysore Prabhakaraa, E.A Bramera, W. Dierkesa, R. Akkermanb, G. Brema, A critical review on recycling of end-of-life carbon fibre/glass fibre reinforced composites waste using pyrolysis towards a circular economy, Resour Conserv Recy. 136 (2018) 118-129.

DOI: 10.1016/j.resconrec.2018.04.013

Google Scholar

[11] R.S Chen, S. Ahmad, S. Gan, M.N Salleh, M.H. Ag Ghani, M.A. Tarawneh, Effect of polymer blend matrix compatibility and fibre reinforcement content on thermal stability and flammability of ecocomposites made from waste materials, Thermochim Acta. 640 (2016) 52–61.

DOI: 10.1016/j.tca.2016.08.005

Google Scholar

[12] Winde Europe. Circular Economy: Blade recycling is a top priority for the wind industry. (2020). https://windeurope.org/newsroom/news/blade-recycling-a-top-priority-for-the-wind-industry/.

Google Scholar

[13] Casper Star-Tribune. Wind turbine blades in coal mine pits? There's a new law in Wyoming to allow it. (2020). https://trib.com/business/energy/wind-turbine-blades-in-coal-mine-pits-theres-a-new-law-in-wyoming-to-allow/article_df17dbc9-f6db-5eb6-8164-32b25275aa9b.htm.

Google Scholar

[14] Electrek. World's first wind turbine with recyclable blades is up and spinning. (2022). https://electrek.co/2022/08/02/worlds-first-wind-turbine-with-recyclable-blades-is-up-and-spinning/.

Google Scholar

[15] D. Coughlan, C. Fitzpatrick C, M. McMahon, Repurposing end of life notebook computers from consumer WEEE as thin client computers – A hybrid end of life strategy for the Circular Economy in electronics, J Clean Prod. 192 (2018) 809-820.

DOI: 10.1016/j.jclepro.2018.05.029

Google Scholar

[16] P.R. Valério. Evaluation of the environmental impacts of electronic equipment by materials inventory. Sorocaba: Sorocaba São Paulo State University (Unesp). (2014).

Google Scholar

[17] Y.M.B. Saavedra, D.R. Iritani, A.L.R. Pavan, A.R. Ometto, Theoretical contribution of industrial ecology to circular economy, J Clean Prod. 170 (2018) 1514-1522.

DOI: 10.1016/j.jclepro.2017.09.260

Google Scholar

[18] ABNT NBR NM248 (2003) Aggregates – Brazilian standard for particle-size distribution determination. ABNT, Rio de Janeiro.

Google Scholar

[19] ASTM 6913 (2017) Standard Test Methods for Particle-Size Distribution (Gradation) of Soils Using Sieve Analysis. ASTM International, West Conshohocken.

DOI: 10.1520/d6913-04r09

Google Scholar

[20] ASTM D3171 (2015) Standard Test Methods for Constituent Content of Composite Materials. ASTM International, West Conshohocken.

Google Scholar

[21] D.S. Costa Et al.: Utilization of red mud and vegetalble fiber –sisal and jute- in polymeric composites. Abstract for paper presented at the Brazilian Congresso of Ceramics, Águas de Lindoia, Brazil (2016).

Google Scholar

[22] V.A. Prabu, S. Kalirasu, M. Uthayakumar, V. Manikandan: Processing and characterisation of red mud filled sisal fiber reinforced polymer composite. Abstract for paper presented at the IEEE-International Conference On Advances In Engineering, Science And Management, Nagapattinam, India (2012).

Google Scholar

[23] V.A. Prabu, S. Kalirasu, M. Uthaykumar, V. Manikandan, Investigation of the mechanical properties on red mud filled polyester banana composites using grey relational technique, Mater Phys Mech. 14 (2012) 57-63.

Google Scholar

[24] ASTM D570 (1998) Standard Test Methods: Water absorption of plastics. ASTM International, West Conshohocken.

Google Scholar

[25] ASTM D1238 (2013) Standard Test Method for Melt Flow Rates of Thermoplastics by Extrusion Plastometer. ASTM International, West Conshohocken.

DOI: 10.1520/d1238-10

Google Scholar

[26] ASTM D638 (2014) Standard Test Method for Tensile Properties of Plastics. ASTM International, West Conshohocken.

Google Scholar

[27] ASTM D256 (2018) Standard Test Methods for Determining the Izod Pendulum Impact Resistance of Plastics. ASTM International, West Conshohocken.

Google Scholar

[28] M.L.P. Antunes, S.J. Couperthwaite, F.T. Conceição, C.P.C. Jesus, P.K. Kiyohara, A.C.V. Ceolho, R.L. Frost, Red Mud from Brazil: Thermal Behavior and Physical Properties, Ind Eng Chem Res. 51 (2012) 775 – 779.

DOI: 10.1021/ie201700k

Google Scholar

[29] R.C.C Costa, F.C.C. Moura, P.E.F. Oliveira, F. Magalhães, J.D. Adirsson, R.M. Lago Controlled reduction of red mud waste to produce active systems for environmental applications: Heterogeneous Fenton reaction and reduction of Cr(VI), Chemosphere. 78 (2010) 1116–1120.

DOI: 10.1016/j.chemosphere.2009.12.032

Google Scholar

[30] E.P. Manfroi, M. Chieraf, J.C. Rocha, Microstructure, mineralogy and environmental evaluation of cementitious composites produced with red mud waste, Constr Build Mater. 67 (2014) 29-36.

DOI: 10.1016/j.conbuildmat.2013.10.031

Google Scholar

[31] D.V. Ribeiro, J.A. Labrincha, M.R. Morelli, Effect of the addition of red mud on the corrosion parameters of reinforced concrete, Cement Concrete Res.42 (2012) 124–133.

DOI: 10.1016/j.cemconres.2011.09.002

Google Scholar

[32] Sinctronics. Sustainability Report. (2021). http://sinctronics.com.br/wp-content/uploads/2021/07/312_relatorio-anual_2020_sinctronics_a4_final-digital.pdf.

Google Scholar

[33] Y. Zhang, Y. QU, S. WU, apud apud Y. Liu, R. Naidu, H. Ming, Red mud as an amendment for pollutants in solid and liquid phases, Geoderma. 163 (2001) 1–12.

DOI: 10.1016/j.geoderma.2011.04.002

Google Scholar

[34] E.J.S. Cunha, R.M. Miranda, J.A.S. Souza, M.Jr.A. Oliveira: Influence of the addition of red mud from Bayer process in polymer matrixes of isophthalix polyester. Abstract for paper presented at the International Comitee for the Study of Bauxite Alumina Aluminium, Zhengzhou, China (2012).

Google Scholar

[35] H. Jena, A.K. Sataphaty: Fabrication mechanical characterization and wear response of hybrid composites filed with red mud: an alumina plant waste. Abstract for paper presented at the 5th International Conference on Advances in Mechanical Engineering, Gujarat, India (2011).

Google Scholar