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Journal of Polymer Research

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01-04-2021 | ORIGINAL PAPER

Compatibility effect of r-ABS/r-HIPS/r-PS blend recovered from waste keyboard plastics: evaluation of mechanical, thermal and morphological performance

Authors: Jaidev K, Manoranjan Biswal, Smita Mohanty, Sanjay K. Nayak

Published in: Journal of Polymer Research | Issue 4/2021

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Abstract

The primary aim of this study was to identify the polymers recovered from keyboard waste, and formulate a ternary blend from the recovered polymers, with improved mechanical, thermal and morphological characteristics, and encouraging product-based recycling. The recycling and reuse of polymers recovered from E-waste is one of the prime topics in solid waste management. The major drawbacks of utilizing recycled polymers are its lower mechanical strength. This was majorly evidenced in styrene based polymers such as acrylonitrile butadiene styrene (ABS) and high impact polystyrene (HIPS). In our case, the polymers ABS, HIPS and polystyrene (PS) were recovered from waste keyboards, and their impact strength was 29 J/m, 42 J/m and 20 J/m respectively. After formulating a ternary blend with PS as a major phase, the impact strength observed was 66 J/m. The thermal stability of the blends also improved from 380℃ to 396℃, after the addition of PS to the blends, but the glass transition temperature had negligible effect. The morphology of ternary blend shows salami structures after the addition of ABS/HIPS blends. This shows that the r-PS morphology had a brittle to ductile transition which leads to the improvement of impact properties.

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Thakur S, Verma A, Sharma B et al (2018) Recent developments in recycling of polystyrene based plastics. Curr Opin Green Sustain Chem 13:32–38CrossRef

Singh N, Hui D, Singh R et al (2017) Recycling of plastic solid waste: A state of art review and future applications. Compos Part B Eng 115:409–422CrossRef

Rahimifard S, Coates G, Staikos T et al (2009) Barriers, drivers and challenges for sustainable product recovery and recycling. Int J Sustain Eng 2:80–90CrossRef

Jung LB, Bartel TJ (1999) Computer take-back and recycling: An economic analysis for used consumer equipment. J Electron Manuf 9:67–77CrossRef

Lin C, hsu, Wen L, Tsai Y mi, (2010) Applying decision-making tools to national e-waste recycling policy: An example of Analytic Hierarchy Process. Waste Manag 30:863–869CrossRef

Schlummer M, Mäurer A, Leitner T, Spruzina W (2006) Report: Recycling of flame-retarded plastics from waste electric and electronic equipment (WEEE). Waste Manag Res 24:573–583CrossRef

Stenvall E, Tostar S, Boldizar A et al (2013) An analysis of the composition and metal contamination of plastics from waste electrical and electronic equipment (WEEE). Waste Manag 33:915–922CrossRef

Datta J, Kopczyńska P (2016) From polymer waste to potential main industrial products: Actual state of recycling and recovering. Crit Rev Environ Sci Technol 46:905–946CrossRef

Hamad K, Kaseem M, Deri F (2012) Preparation and Characterization of Binary and Ternary Blends with Poly(Lactic Acid), Polystyrene, and Acrylonitrile-Butadiene-Styrene. J Biomater Nanobiotechnol 03:405–412CrossRef

10.

Grigore ME (2017) Methods of recycling, properties and applications of recycled thermoplastic polymers. Recycling 2:1–11CrossRef

11.

Vollmer I, Jenks MJF, Roelands MCP et al (2020) Beyond Mechanical Recycling: Giving New Life to Plastic Waste. Angew Chemie - Int Ed 59:15402–15423CrossRef

12.

Scaffaro R, Botta L, Di Benedetto G (2012) Physical properties of virgin-recycled ABS blends: Effect of post-consumer content and of reprocessing cycles. Eur Polym J 48:637–648CrossRef

13.

Jaidev K, Suresh SS, Gohatre OK et al (2020) Development of recycled blends based on cables and wires with plastic cabinets: An effective solution for value addition of hazardous waste plastics. Waste Manag Res 38:312–321CrossRef

14.

Sarath P, Biswal M, Mohanty S, Nayak SK (2018) Effect of silicone rubber based impact modifier on mechanical and flammability properties of plastics recovered from waste mobile phones. J Clean Prod 171:209–219CrossRef

15.

Wang J, Li Y, Song J et al (2015) Recycling of acrylonitrile-butadiene-styrene (ABS) copolymers from waste electrical and electronic equipment (WEEE), through using an epoxy-based chain extender. Polym Degrad Stab 112:167–174CrossRef

16.

Vazquez YV, Barbosa SE (2016) Recycling of mixed plastic waste from electrical and electronic equipment. Added value by compatibilization Waste Manag 53:196–203CrossRef

17.

Brennan LB, Isaac DH, Arnold JC (2002) Recycling of Acrylonitrile – Butadiene – Styrene and High- Impact Polystyrene from Waste Computer Equipment. J Appl Polym Sci 86:572–578CrossRef

18.

De Souza AMC, Cucchiara MG, Ereio AV (2016) ABS/HIPS blends obtained from WEEE: Influence of processing conditions and composition. J Appl Polym Sci 133:1–7CrossRef

19.

Hirayama D, Saron C (2015) Characterisation of recycled acrylonitrile-butadiene-styrene and high-impact polystyrene from waste computer equipment in Brazil. Waste Manag Res 33:543–549CrossRef

20.

Vilaplana F, Ribes-Greus A, Karlsson S (2006) Degradation of recycled high-impact polystyrene. Simulation by reprocessing and thermo-oxidation. Polym Degrad Stab 91:2163–2170CrossRef

21.

Oksman K, Lindberg H, Holmgren A (1998) The nature and location of SEBS–MA compatibilizer in polyethylene–wood flour composites. J Appl Polym Sci 69:201–209CrossRef

22.

Munteanu SB, Vasile C (2005) Spectral and thermal characterization of styrene- butadiene copolymer with different architectures 7:3135–3148

23.

Hirayama D, Saron C (2018) Morphologic and mechanical properties of blends from recycled acrylonitrile-butadiene-styrene and high-impact polystyrene. Polymer (Guildf) 135:271–278CrossRef

24.

Tarantili PA, Mitsakaki AN, Petoussi MA (2010) Processing and properties of engineering plastics recycled from waste electrical and electronic equipment (WEEE). Polym Degrad Stab 95:405–410CrossRef

25.

Tiganis BE, Burn LS, Davis P, Hill AJ (2002) Thermal degradation of acrylonitrile – butadiene – styrene ( ABS ) blends. 76:425–434.

26.

Kolawole EG, Agboola MO (1982) Environmental degradation of some polymer blends. Blends of polystyrene with acrylonitrile butadiene styrene, poly(vinyl chloride), and polybutadiene and blends of polybutadiene with poly(vinyl chloride). J Appl Polym Sci 27:2317–2335CrossRef

27.

Chen B, Evans JRG (2011) Mechanical properties of polymer-blend nanocomposites with organoclays: Polystyrene/ABS and high impact polystyrene/ABS. J Polym Sci Part B Polym Phys 49:443–454CrossRef

28.

Arnold JC, Watson T, Alston S et al (2010) The use of FTIR mapping to assess phase distribution in mixed and recycled WEEE plastics. Polym Test 29:459–470CrossRef

29.

Perrin D, Mantaux O, Ienny P, et al (2016) Influence of impurities on the performances of HIPS recycled from Waste Electric and Electronic Equipment (WEEE). Waste Manag. 1–8.

30.

Hamad K, Kaseem M, Deri F (2013) Recycling of waste from polymer materials: An overview of the recent works. Polym Degrad Stab 98:2801–2812CrossRef

31.

Hedenqvist MS, Gedde UW (1999) Parameters affecting the determination of transport kinetics data in highly swelling polymers above T g 40:2381–2393

32.

Taurino R, Pozzi P, Zanasi T (2010) Facile characterization of polymer fractions from waste electrical and electronic equipment (WEEE) for mechanical recycling. Waste Manag 30:2601–2607CrossRef

33.

Kim JK, Kang CK (1995) Basic studies on recycling of ABS resin. Polym Plast Technol Eng 34:875–890CrossRef

34.

Siregar JP, Salit MS, Zaki M, Rahman A (2011) Thermogravimetric Analysis ( TGA ) and Differential Scanning Calometric ( DSC ) Analysis of Pineapple Leaf Fibre ( PALF ) Reinforced High Impact Polystyrene ( HIPS ) Composites. 19:161–170.

35.

Suzuki M, Wilkie CA (1995) The thermal degradation of acrylonitrile-butadiene-styrene terpolymei as studied by TGA/FTIR. Polym Degrad Stab 47:217–221CrossRef

36.

Cella RF, Mumbach GD, Andrade KL et al (2018) Polystyrene recycling processes by dissolution in ethyl acetate 46208:1–7

37.

Piorkowska E, Argon AS, Cohen RE (1993) Izod impact strength of polystyrene-based blends containing low molecular weight polybutadiene. Polymer (Guildf) 34:4435–4444CrossRef

Title: Compatibility effect of r-ABS/r-HIPS/r-PS blend recovered from waste keyboard plastics: evaluation of mechanical, thermal and morphological performance
Authors: Jaidev K
Manoranjan Biswal
Smita Mohanty
Sanjay K. Nayak
Publication date: 01-04-2021
Publisher: Springer Netherlands
Published in: Journal of Polymer Research / Issue 4/2021
Print ISSN: 1022-9760
Electronic ISSN: 1572-8935
DOI: https://doi.org/10.1007/s10965-021-02481-6

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