In this research work, designing and fabrication of hybrid epoxy polymer composite materials had been carried out. It consists of basalt fiber (constant fraction) and marble dust particulates (0–10 wt% @ step of 2.5%) ensuing five compositions namely, MBE-0, MBE-2.5, MBE-5, MBE-7.5, and MBE-10. The specimen’s undergone physical, mechanical, and thermo-mechanical characterizations followed by three-body abrasive wear performance evaluation. Parametric optimizations of the wear have been evaluated with the Taguchi technique. The performance data are used to rank the compositions using a hybrid AHP-VIKOR selection making tool. It has been observed that voids content improves with reinforcement up to 5 wt% marble dust reinforcement, thereafter, it deteriorates sharply. The mechanical properties with 5 wt% marble dust reinforcement found to be highest. The thermo-mechanical characteristics like modulus and damping improve with marble dust reinforcement and temperature. The Cole-Cole plots reveal the heterogeneity present in the composites. The Taguchi’s analysis reveals the order of operating factors influencing specific wear rate as abrading distance > normal load > reinforcement composition > abrasive size. The steady state-specific wear rate of the composites reveals decremented rate across the abrading distance range irrespective of reinforcement proportions and at any specific abrading distance the order it followed as MBE-5 < MBE-7.5 < MBE-2.5 < MBE-10 < MBE-0. The ranking analysis using hybrid AHP-VIKOR technique predicts the ranking sequence as MBE-5 > MBE-7.5 > MBE-2.5 > MBE-10 > MBE-0, which are in-line with subjective analysis.
JeganmohanSRChristyTVSolomonDG, et al.Influence of calcium sulfate whiskers on the tribological characteristics of automotive brake friction materials. Eng Sci Technol Int J2019; 23(2): 445–451.
2.
JeganmohanSRSugozuBKumarM, et al.Experimental investigation on the friction and wear characteristics of palm seed powder reinforced brake pad friction composites. J Inst Eng Ser D2020; 101: 61–69.
3.
PatnaikAKumarPBiswasS, et al.Investigations on micro-mechanical and thermal characteristics of glass fiber reinforced epoxy based binary composite structure using finite element method. Comput Mater Sci2012; 62: 142–151.
4.
LameaMDaghighVSoroushM, et al.The buckling behavior of vacuum-infused open-hole unidirectional basalt-fiber composites experimental and numerical investigations. Mech Compos Mater2020; 55: 761–774.
5.
ToorchiDKhosraviHTohidlouE. Synergistic effect of nano-ZrO2/graphene oxide hybrid system on the high-velocity impact behavior and interlaminar shear strength of basalt fiber/epoxy composite. J Ind Text. Epub ahead of print 4 October 2019. DOI: 10.1177/1528083719879922.
6.
PrabhuTNDemappaTHarishV, et al.Mechanical, thermal and flame-retardant properties of epoxy-nylon fabric-clay hybrid laminates. High Perform Polym2013; 25: 559–565.
7.
ZulfliNHMBakarAAChowWS. Mechanical and thermal properties improvement of nano calcium carbonate-filled epoxy/glass fiber composite laminates. High Perform Polym2014; 26: 223–229.
8.
RaghavendraGOjhaSAcharyaSK, et al.Influence of micro/nanofiller alumina on the mechanical behavior of novel hybrid epoxy nanocomposites. High Perform Polym2015; 27: 342–351.
9.
KrishnadeviKSelvarajV. Biowaste material reinforced cyanate ester based epoxy composites for flame retardant applications. High Perform Polym2016; 28: 881–894.
10.
MatykiewiczD. Hybrid epoxy composites with both powder and fiber filler: a review of mechanical and thermomechanical properties. Materials2020; 13: 1–22.
11.
MatykiewiczDLewandowskiKDudziecB. Evaluation of thermomechanical properties of epoxy–basalt fibre composites modified with zeolite and silsesquioxane. Compos Interfaces2017; 24: 489–498.
12.
GaneshSGundaYMohanSRJ, et al.Influence of stacking sequence on the mechanical and water absorption characteristics of areca sheath-palm leaf sheath fibers reinforced epoxy composites. J Nat Fibers2020; 00: 1–11.
13.
SharmaVMeenaMLKumarM. Mechanical properties of unfilled and particulate filled glass fiber reinforced polymer composites—A Review. Advances in Polymer Composites: Mechanics, Characterization and Application. AIP Conference Proceedings2019; 2057: 020037-(1–8). DOI: 10.1063/1.5085608.
14.
SharmaVMeenaMLKumarM. A review on tribological behaviour of polymeric composites materials. ISST J Mech Eng2019; 10: 1–5.
15.
KumarR. Three body abrasive wear and mechanical characterization using optimization technique of marble powder filled basalt epoxy composites. M.Tech. (Production Engineering) Thesis, Mechanical Engineering Department, MNIT Jaipur, Rajasthan, India, 2019, pp. 1–250.
16.
KumarRKumarM. A review of wear and mechanical behavior using optimization technique on basalt-epoxy hybrid reinforced with marble powder. In: International conference on global trends & future prospects in multidisciplinary research, 4–7 February 2019, Poddar International College, Jaipur, Rajasthan, India, 2019, pp. 1–1459.
17.
JamshaidHMishraR. A green material from rock: basalt fiber—a review. J Text Inst2016; 107: 923–937.
18.
RalphCLemoinePSummerscalesJ, et al.Relationships among the chemical, mechanical and geometrical properties of basalt fibers. Text Res J2019; 89: 3056–3066.
19.
DhandVMittalGRheeKY, et al.A short review on basalt fiber reinforced polymer composites. Compos Part B Eng2015; 73: 166–180.
20.
BhatTChevaliVLiuX, et al.Fire structural resistance of basalt fibre composite. Compos Part A Appl Sci Manuf2015; 71: 107–115.
21.
BhatTFortomarisDKandareE, et al.Properties of thermally recycled basalt fibres and basalt fibre composites. J Mater Sci2018; 53: 1933–1944.
22.
DalinkevichAAGumargalievaKZMarakhovskySS, et al.Modern basalt fibrous materials and basalt fiber-based polymeric composites. J Nat Fibers2009; 6: 248–271.
23.
DemirelBAlyamacKE. Waste marble powder/dust. Waste Suppl Cem Mater Concr2018; 181–197.
24.
JinFLLiXParkSJ. Synthesis and application of epoxy resins: a review. J Ind Eng Chem2015; 29: 1–11.
25.
KimSHHeoYJParkM, et al.Effect of hydrophilic graphite flake on thermal conductivity and fracture toughness of basalt fibers/epoxy composites. Compos Part B Eng2018; 153: 9–16.
26.
LapenaMHMarinucciGCarvalhoOD. Mechanical characterization of unidirectional basalt fiber epoxy composite tube. Mater Res J Mater2018. DOI: 10.1590/1980-5373-mr-2017-0324.
27.
KumarCSArumugamVDhakalHN, et al.Effect of temperature and hybridisation on the low velocity impact behavior of hemp-basalt/epoxy composites. Compos Struct2015; 125: 407–416.
28.
MahantaSSamantaSChandrasekaranM. Processing and investigation of tribological properties of basalt epoxy composites. Mater Today Proc2017; 4: 8185–8191.
29.
MatykiewiczDBarczewskiMKnapskiD, et al.Hybrid effects of basalt fibers and basalt powder on thermomechanical properties of epoxy composites. Compos Part B Eng2017; 125: 157–164.
30.
ZhangTLiuHZhangD, et al.Mechanical and wear properties of polyetheretherketone composites filled with basalt fibres. IEEE J Sel Top Quantum Electron2019; 26: 317–326.
31.
RaajeshkrishnaCRPradeepASKumarRRD. Influence of fiber content on mechanical, tribological properties of short basalt fiber-reinforced nylon 6 and polypropylene composites. J Thermoplast Compos Mater. Epub ahead of print 30 May 2019. DOI: 10.1177/0892705719853613.
32.
MohanNNatarajanSKumaresh BabuSP. Abrasive wear behaviour of hard powders filled glass fabric-epoxy hybrid composites. Mater Des2011; 32: 1704–1709.
33.
ChairmanCAKumaresh BabuSP. Three-body abrasive wear behavior of basalt and glass fabric reinforced epoxy composites. Appl Mech Mater2012; 121–126: 534–538.
34.
AgarwalGPatnaikASharmaRK. Parametric optimization and three-body abrasive wear behavior of SiC filled chopped glass fiber reinforced epoxy composites. Int J Compos Mater. 2013; 3(2): 32–38.
35.
SureshaBChandramohanGSiddaramaiahP, et al.Three-body abrasive wear behaviour of carbon and glass fiber reinforced epoxy composites. Mater Sci Eng A2007; 443: 285–291.
36.
BorsellinoCCalabreseLDi BellaG. Effects of powder concentration and type of resin on the performance of marble composite structures. Constr Build Mater2009; 23: 1915–1921.
37.
KumarMKumarA. Sliding wear performance of graphite reinforced AA6061 alloy composites for rotor drum/disk application. Mater Today Proc2019; 27: 1972–1976.
38.
BhaskarSKumarM.PatnaikA. Silicon carbide ceramic particulate reinforced AA2024 alloy composite—part I: evaluation of mechanical and sliding tribology performance. Silicon2019; 12: 843–865.
39.
GangilBPatnaikAKumarA, et al.Investigations on mechanical and sliding wear behaviour of short fibre-reinforced vinylester-based homogenous and their functionally graded composites. Proc Inst Mech Eng Part L J Mater Des Appl2012; 226: 300–315.
40.
KumarAKumarM. Mechanical and dry sliding wear behaviour of B4C and rice husk ash reinforced Al 7075 alloy hybrid composite for armors application by using Taguchi techniques. Mater Today Proc2020; 53: 1–1498.
41.
JahanAMustaphaFIsmailMY, et al.A comprehensive VIKOR method for material selection. Mater Des2011; 32: 1215–1221.
SharmaNChoudharyR. Multi-objective performance optimization of a ribbed solar air heater. In: TyagiH (ed) Solar energy. Berlin: Springer Nature Singapore Pte Ltd, 2020, 79–96.
44.
KumarM. Mechanical and sliding wear performance of AA356-Al2O3/SiC/graphite alloy composite materials: parametric and ranking optimization using Taguchi DOE and hybrid AHP-GRA method. Silicon. Epub ahead of print 21 July 2020. DOI: 10.1007/s12633-020-00544-9.
45.
NayebiMAAsadollahiA. Application of the VIKOR-AHP model in VSP. Arch Des Sci2012; 65: 85–101.
46.
JayantASinghP.Application of AHP-VIKOR hybrid MCDM approach for 3PL selection: a case study. Int J Comput Appl2015; 125: 4–11.
47.
KokocMErsozS. Comparison of AHP-TOPSIS and AHP-VIKOR methods in product selection in terms of inventory management. Uluslararası Muhendis Arastirma ve Gelistirme Derg2019; 11: 163–172.
48.
MohammedRKumarBRVenkateshY, et al.Characterization of marble powder filled epoxy composites. Int J Sci Res Rev2018; 7: 206–215.
49.
ASTM standards. D792-13: Standard test methods for density and specific gravity (relative density) of plastics by displacement. ASTM Int2013; 15: 145–149.
50.
BhaskarSKumarMPatnaikA. Microstructure, thermal, thermo-mechanical and fracture analyses of hybrid AA2024-SiC alloy composites. Trans Indian Inst Met2020; 73: 181–190.
51.
BhaskarSKumarMPatnaikA. Application of hybrid AHP-TOPSIS technique in analyzing material performance of silicon carbide ceramic particulate reinforced AA2024 alloy composite. Silicon2020; 12: 1075–1084.
52.
KumarSSatapathyBKPatnaikA. Thermo-mechanical correlations to erosion performance of short glass/carbon fiber reinforced vinyl ester resin hybrid composites. Comput Mater Sci2012; 60: 250–260.
53.
KumarMKumarA. Thermomechanical analysis of hybrid friction composite material and its correlation with friction braking performance. Int J Polym Anal Charact2020; 0: 1–17.
54.
ChandNNaikANeogiS. Three-body abrasive wear of short glass fibre polyester composite. Wear2000; 242: 38–46.
55.
PatnaikASatapathyABiswasS. Investigations on three-body abrasive wear and mechanical properties of particulate filled glass epoxy composites. Malaysian Polym J2010; 5: 37–48.
