Restricted accessResearch articleFirst published online 2025
Fused-granular-fabrication 3D printing of recycled expanded polystyrene/polypropylene: Research on mechanical properties,thermal behavior,and morphology
Recycling of expanded polystyrene (EPS) waste plastic is costly and inefficient, leading to low recovery rates and exacerbating environmental pollution. This study introduces a custom-built Fused Granular Fabrication (FGF) 3D printer and designs printers with a mixing screw (MSP) and a conventional screw (CSP) for the direct recycling and modification of EPS. The mixing capabilities of the MSP and CSP were compared through fluid simulation. Experimental studies were conducted to investigate the effects of both printers and compatibilizer on the thermal and mechanical properties of recycled polystyrene/polypropylene (rPP/rEPS). The results showed that, MSP provided a higher proportion of stretching flow than CSP, facilitating polymer fragmentation and breaking down the compatibilizer and rEPS into smaller particles, thus enhancing mixing dispersion in single-screw extrusion. The addition of rPP and maleic anhydride-grafted polypropylene (PP-g-MAH) effectively improved the mechanical properties of rEPS. The rEPS/rPP/PP-g-MAH composites printed with MSP exhibited the best mechanical properties, with tensile strength and elongation at break increasing by 129.3% and 98.7%, respectively, compared to neat rEPS. The high shear effect of CSP caused the degradation of rPP and PP-g-MAH, with the degradation temperature of rEPS/rPP/PP-g-MAH printed by CSP being 7.2°C lower than that of MSP, thus deteriorating the thermal properties of the rEPS/rPP/PP-g-MAH composites. This study offers valuable insights into improving the mechanical properties of recycled rEPS and achieving a “one-stop” solution for waste plastic recycling.
MongGRTanHChin Vui ShengDD, et al.A review on plastic waste valorisation to advanced materials: solutions and technologies to curb plastic waste pollution. J Clean Prod2024; 434: 140180.
2.
DuttaNMondalPGuptaA. Optimization of process parameters using response surface methodology for maximum liquid yield during thermal pyrolysis of blend of virgin and waste high-density polyethylene. J Mater Cycles Waste Manag2022; 24: 1182–1193.
3.
LeeALiewMS. Tertiary recycling of plastics waste: an analysis of feedstock, chemical and biological degradation methods. J Mater Cycles Waste Manag2021; 23: 32–43.
4.
ChoJKimBKwonT, et al.Electrocatalytic upcycling of plastic waste. Green Chem2023; 25: 8444–8458.
5.
Anuar SharuddinSDAbnisaFWan DaudWMA, et al.Energy recovery from pyrolysis of plastic waste: study on non-recycled plastics (NRP) data as the real measure of plastic waste. Energy Convers Manag2017; 148: 925–934.
6.
GarciaJMRobertsonML. The future of plastics recycling. Science2017; 358: 870–872.
7.
LingSLKoaySCChanMY, et al.Wood plastic composites produced from postconsumer recycled polystyrene and coconut shell: effect of coupling agent and processing aid on tensile, thermal, and morphological properties. Polym Eng Sci2020; 60: 202–210.
8.
HongMChenEYX. Chemically recyclable polymers: a circular economy approach to sustainability. Green Chem2017; 19: 3692–3706.
9.
ThakurSVermaASharmaB, et al.Recent developments in recycling of polystyrene based plastics. Curr Opin Green Sustainable Chem2018; 13: 32–38.
10.
HamadKKaseemMDeriF. Recycling of waste from polymer materials: an overview of the recent works. Polym Degrad Stabil2013; 98: 2801–2812.
11.
KanADemirboğaR. A new technique of processing for waste-expanded polystyrene foams as aggregates. J Mater Process Technol2009; 209: 2994–3000.
12.
SasseFEmigG. Chemical recycling of polymer materials. Chem Eng Technol1998; 21: 777–789.
13.
NoguchiTMiyashitaMInagakiY, et al.A new recycling system for expanded polystyrene using a natural solvent. Part 1. A new recycling technique. Packag Technol Sci1998; 11: 19–27.
14.
PaoCZYengCM. Properties and characterization of wood plastic composites made from agro-waste materials and post-used expanded polyester foam. J Thermoplast Compos Mater2018; 32: 951–966.
15.
VermaRVinodaKSPapireddyM, et al.Toxic pollutants from plastic waste-a review. Procedia Environ Sci2016; 35: 701–708.
16.
WuCNahilMAMiskolcziN, et al.Processing real-world waste plastics by pyrolysis-reforming for hydrogen and high-value carbon nanotubes. Environ Sci Technol2014; 48: 819–826.
17.
SinghNHuiDSinghR, et al.Recycling of plastic solid waste: a state of art review and future applications. Compos B Eng2017; 115: 409–422.
18.
JanQMUHabibTXiL, et al. Sustainable recycling of polypropylene waste: characterization and statistical analysis of wood husk-PP composite. J Reinforc Plast Compos2025. doi:10.1177/07316844251344001.
Tri PhuongNGilbertVChuongB. Preparation of recycled polypropylene/organophilic modified layered silicates nanocomposites Part I: the recycling process of polypropylene and the mechanical properties of recycled polypropylene/organoclay nanocomposites. J Reinforc Plast Compos2008; 27: 1983–2000.
21.
SchadeAMelzerMZimmermannS, et al.Plastic waste recycling─a chemical recycling perspective. ACS Sustainable Chem Eng2024; 12: 12270–12288.
22.
KarakurtILinL. 3D printing technologies: techniques, materials, and post-processing. Curr Opin Chem Eng2020; 28: 134–143.
23.
WoernALByardDJOakleyRB, et al.Fused particle fabrication 3-D printing: recycled materials’ optimization and mechanical properties. Materials2018; 11: 1413.
24.
ByardDJWoernALOakleyRB, et al.Green fab lab applications of large-area waste polymer-based additive manufacturing. Addit Manuf2019; 27: 515–525.
25.
ReichMJWoernALTanikellaNG, et al.Mechanical properties and applications of recycled polycarbonate particle material extrusion-based additive manufacturing. Materials2019; 12: 1642.
26.
BandinelliFTitoEParisiE, et al.Recycling a carbon fiber-reinforced polyamide through 3D printing: a mechanical and physicochemical analysis. Compos B Eng2025; 294: 112147.
27.
AlexandreACruz SanchezFABoudaoudH, et al.Mechanical properties of direct waste printing of polylactic acid with universal pellets extruder: Comparison to fused filament fabrication on open-source desktop three-dimensional printers. 3D Print Addit Manuf2020; 7: 237–247.
28.
PandeyVChenHMaJ, et al.Extension-dominated improved dispersive mixing in single-screw extrusion. Part 2: comparative analysis with twin-screw extruder. J Appl Polym Sci2021; 138: 49765.
29.
PandeyVMaiaJM. Comparative computational analysis of dispersive mixing in extension-dominated mixers for single-screw extruders. Polym Eng Sci2020; 60: 2390–2402.
30.
ChuJSKoaySCChanMY, et al.Recycled plastic filament made from post-consumer expanded polystyrene and polypropylene for fused filamant fabrication. Polym Eng Sci2022; 62: 3786–3795.
31.
ParameswaranpillaiJJosephGJoseS, et al.Phase morphology, thermomechanical, and crystallization behavior of uncompatibilized and PP-g-MAH compatibilized polypropylene/polystyrene blends. J Appl Polym Sci2015; 132: app.42100.
32.
ZanderNEGillanMBurckhardZ, et al.Recycled polypropylene blends as novel 3D printing materials. Addit Manuf2019; 25: 122–130.
33.
Ariel LeongJJKoaySCChanMY, et al.Composite filament made from post-used styrofoam and corn husk fiber for fuse deposition modeling. J Nat Fibers2022; 19: 7033–7048.
BirdRHJTotSoRW. Hydrodynamic interaction effects in rigid dumbbell suspensions. I. Kinetic theory1971; 15: 741–750.
36.
TadmorZ. Forces in dispersive mixing. Ind Eng Chem Fund1976; 15: 346–348.
37.
CarsonSOCovasJAMaiaJM. A new extensional mixing element for improved dispersive mixing in twin-screw extrusion, part 1: design and computational validation. Adv Polym Technol2017; 36: 455–465.
38.
RondinJBouqueyMMullerR, et al.Dispersive mixing efficiency of an elongational flow mixer on PP/EPDM blends: morphological analysis and correlation with viscoelastic properties. Polym Eng Sci2014; 54: 1444–1457.
39.
WangWManas‐ZloczowerI. Temporal distributions: the basis for the development of mixing indexes for scale-up of polymer processing equipment. Polym Eng Sci2001; 41: 1068–1077.
40.
YangH-HManas‐ZloczowerI. Flow field analysis of the kneading disc region in a co-rotating twin screw extruder. Polym Eng Sci1992; 32: 1411–1417.
41.
YuHWangYTanL, et al.Numerical simulation of mixing enhancement in a single screw extruder by different internal baffles. Macromol Theory Simul2025; 34: 70002.
42.
MarschikCOsswaldTARolandW, et al.Numerical analysis of mixing in block-head mixing screws. Polym Eng Sci2019; 59: E88–E104.
43.
YeCYuQHeT, et al.Physical and rheological properties of maleic anhydride-incorporated PVDF: does MAH act as a physical crosslinking point for PVDF molecular chains?ACS Omega2019; 4: 21540–21547.
44.
OromiehieAMamizadehA. Recycling PET beverage bottles and improving properties. Polym Int2004; 53: 728–732.
45.
DengJYiBMašekO, et al.Co-pyrolysis of biomass and plastic waste into carbon materials with environmental applications: a critical review. Green Chem2025; 27: 6320–6341.
46.
AbuoudahCKGreishYEAbu‐JdayilB, et al.Graphene/polypropylene nanocomposites with improved thermal and mechanical properties. J Appl Polym Sci2021; 138: 50024.
47.
Al-SalehMAYussufAAAl-EneziS, et al.Polypropylene/graphene nanocomposites: effects of GNP loading and compatibilizers on the mechanical and thermal properties. Materials2019; 12: 3924.
48.
ParameswaranpillaiJJoseSSiengchinS, et al.Phase morphology, mechanical, dynamic mechanical, crystallization, and thermal degradation properties of PP and PP/PS blends modified with SEBS elastomer. Int J Plast Technol2017; 21: 79–95.
49.
SchallCSchöppnerV. Measurement of material degradation in dependence of shear rate, temperature, and residence time. Polym Eng Sci2022; 62: 815–823.
