Recycling of Polyamide from Scrap Tyres as Polymeric Composites

https://doi.org/10.17221/51/2015-RAECitation:Müller M., Žarnovský J., Drlička R. (2015): Recycling of Polyamide from Scrap Tyres as Polymeric Composites. Res. Agr. Eng., 61: S79-S83.
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Rubber granulate, metal waste and textile waste (polyamide fibres) come into the mechanical process of waste tyres recycling. The pollution and degradation processes are problematic in using of secondary raw material. The matrix was in the form of three various adhesives in testing – two-component epoxy adhesives and a polyester adhesive. The filler was in the form of textile waste (polyamide fibres) from the process of tyres recycling containing approximately 10–12% of rubber granulate. The filler was added in app. 15% of weight ratio into the matrix. The aim of the research was to determine a possible utilisation of unsorted textile waste from the process of tyres recycling in the area of polymeric composite systems.
References:
Kim Byung Chul, Park Sang Wook, Lee Dai Gil (2008): Fracture toughness of the nano-particle reinforced epoxy composite. Composite Structures, 86, 69-77  https://doi.org/10.1016/j.compstruct.2008.03.005
 
Park Dong Chang, Kim Seong Su, Kim Byung Chul, Lee Seung Min, Lee Dai Gil (2006): Wear characteristics of carbon-phenolic woven composites mixed with nano-particles. Composite Structures, 74, 89-98  https://doi.org/10.1016/j.compstruct.2005.03.010
 
Drlička R., Mikuš R., Kročko V. (2004): Optimalizácia materiálu tesnenia veka ježkovacích komôr. In: Quality and Reliability of Machines, Nitra, 2004: 167–169.
 
Ferreira Caio T., Perez César A.B., Hirayama Denise, Saron Clodoaldo (2013): Recycling of polyamide (PA) from scrap tires as composites and blends. Journal of Environmental Chemical Engineering, 1, 762-767  https://doi.org/10.1016/j.jece.2013.07.016
 
Kejval J., Müller M. (2013): Mechanical properties of multi-component polymeric composite with particles of Al2O3/SiC. Scientia Agriculturae Bohemica, 44, 237-242  https://doi.org/10.7160/sab.2013.440407
 
Mikuš R., Drlička R., Kročko V. (2005): Riešenie utesňovania ježkovacích komôr plynovodov. Technical Diagnostics, 14: 246–252.
 
Müller M., Valášek P. (2012): Abrasive wear effect on polyethylene, polyamide 6 and polymeric particle composites. Manufacturing Technology, 12: 55–59.
 
Valášek P., Müller M. (2012): Influence of bonded abrasive particles size on wear of polymeric particle composites based on waste. Manufacturing Technology, 12: 268–272.
 
Valášek P., Müller M. (2012): Polymeric particle composites with filler saturated matrix. Manufacturing Technology, 12, 272–276.
 
Valášek P., Müller M. (2013): Changes of polyurethane mechanical properties filled with glass powder. Manufacturing Technology, 13: 563–568.
 
Valášek P., Müller M. (2014): EPDM rubber material utilization in epoxy composite systems. Agronomy Research, 12: 291–298.
 
Valášek P., Müller M., Proshlyakov A. (2012): Effect of sedimentation on the final hardness of polymeric particle composites. Research in Agricultural Engineering, 58: 92–98.
 
Valášek Petr, Žarnovský Jozef, Müller Miroslav (2013): Thermoset Composite on Basis of Recycled Rubber. Advanced Materials Research, 801, 67-73  https://doi.org/10.4028/www.scientific.net/AMR.801.67
 
Jiao Weizhou, Liu Youzhi, Qi Guisheng (2009): Studies on mechanical properties of epoxy composites filled with the grafted particles PGMA/Al2O3. Composites Science and Technology, 69, 391-395  https://doi.org/10.1016/j.compscitech.2008.11.003
 
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