Sage Journals: Discover world-class research

Abstract

The present work reports on the development of a novel set of ramie–epoxy composites filled with sponge iron (SI) slag (0–30 wt.%) and on their response to solid particle erosion wear under different test conditions. SI slag is a by-product generated during the processing of SI to steel in arc or induction furnace. While these composites are fabricated using the conventional hand layup technique, the erosion tests are carried out using an air jet erosion tester following ASTM G76 test standard as per Taguchi's L₂₇ orthogonal array. Mechanical characterization of ramie–epoxy composites suggests that the incorporation of SI slag improves their tensile strength by about 52%, flexural strength by 10% and micro-hardness by about 30%. A parametric appraisal of the erosion response carried out using Taguchi method reveals that the filler content, impact velocity and impingement angle are the most significant control factors influencing the erosion rate of these composites. The individual effects of different factors in wider ranges (impact velocity 25–125 m/s, filler content 0–30 wt.% and impingement angle 30–90°) are ascertained by conducting steady-state erosion experiments in controlled conditions. Preference selection index method, which is an effective multi-criteria decision-making tool is used to select the best candidate among all composites based on different physical, mechanical and wear test results. It is found that the composite with 30 wt.% SI slag content displays the optimal combination of properties. The worn morphologies of the eroded surfaces of the composites are studied and analyzed using electron microscopy to identify possible mechanisms causing the wear loss.

Keywords

Ramie–epoxy composites sponge iron slag steady state erosion preference selection index method scanning electron microscopy

Get full access to this article

View all access options for this article.

References

Biswas

Patnaik

Kaundal

. Effect of red mud and copper slag particles on physical and mechanical properties of bamboo-fiber-reinforced epoxy composites. Adv Mech Eng 2012. Epub ahead of print 2012.

Arunprasath

Amuthakkannan

Manikandan

, et al. Study of mechanical properties of copper slag reinforced particulate polymer composite. Mater Phys Mech 2021; 47: 896–904.

Vigneshwaran

Uthayakumar

Arumugaprabu

. Development and sustainability of industrial waste-based red mud hybrid composites. J Cleaner Prod 2019; 230: 862–868.

Pati

Satapathy

. Prediction and simulation of wear response of Linz-Donawitz (LD) slag filled glass-epoxy composites using neural computation. Polym Adv Technol 2015; 26: 121–127.

Purohit

Satapathy

. Development and characterization of epoxy-based composites filled with Linz-Donawitz sludge. J Compos Mater 2017; 51: 899–911.

Tambrallimath

Keshavamurthy

Davim

, et al. Synthesis and characterization of flyash reinforced polymer composites developed by Fused Filament Fabrication. J Mater Res Technol 2022; 21: 810–826.

Padhi

Satapathy

. Processing and wear analysis of blast furnace slag filled polypropylene composites using Taguchi model and ANN. Int Polym Process 2014; 29: 233–244.

Nayak

Satapathy

. Development and characterization of polymer-based composites filled with micro-sized waste marble dust. Polym Polym Compos 2021; 29: 497–508.

Boggarapu

Gujjala

Ojha

. A critical review on erosion wear characteristics of polymer matrix composites. Mater Res Express 2020; 7. Epub ahead of print 2020.

10.

Rasool

Sharifi

Johnstone

, et al. Mapping synergy of erosion mechanisms of tidal turbine composite materials in sea water conditions. J Bio Tribo-Corros 2016; 2: 1–15.

11.

Mahapatra

Satapathy

. Processing and physico-mechanical characterization of sponge iron slag filled ramie fiber reinforced epoxy-based composites. Polym Compos 2022; 43: 6191–6203.

12.

Biswas

Satapathy

. A comparative study on erosion characteristics of red mud filled bamboo-epoxy and glass-epoxy composites. Mater Des 2010; 31: 1752–1767.

13.

Biswas

Satapathy

. A study on tribological behavior of alumina-filled glass-epoxy composites using Taguchi experimental design. Tribol Trans 2010; 53: 520–532.

14.

Nayak

Satapathy

Mantry

. Impact of process parameters on solid particle erosion behavior of waste marble dust-filled polyester composites. Arab J Sci Eng 2021; 46: 7197–7209.

15.

Nayak

Satapathy

Mantry

. Role of test parameters and material composition on the erosion behavior of waste marble dust-filled glass-polyester composites. J Braz Soc Mech Sci Eng 2021; 43: 1–14.

16.

Latha

Rao

. Investigation into effect of ceramic fillers on mechanical and tribological properties of bamboo-glass hybrid fiber reinforced polymer composites. Silicon 2018; 10: 1543–1550.

17.

Kumar Padhi

Satapathy

. Solid particle erosion behavior of BFS-filled epoxy-SGF composites using Taguchi’s experimental design and ANN. Tribol Trans 2014; 57: 396–407.

18.

Padhi

Satapathy

Nakka

. Processing, characterization, and wear analysis of short glass fiber-reinforced polypropylene composites filled with blast furnace slag. J Thermoplast Compos Mater 2015; 28: 656–671.

19.

Patnaik

Biswas

Satapathy

, et al. Processing, characterisation and erosion wear analysis of SiC filled glass-epoxy-composites. Int J Comput Mater Sci Surf Eng 2011; 4: 168–184.

20.

Patnaik

Satapathy

Biswas

. Effect of particulate fillers on erosion wear of glass polyester composites: a comparative study using Taguchi approach. Polymer 2010; 5: 49–68.

21.

Singh

Tejyan

Patnaik

, et al. Optimal design of needlepunched nonwoven fiber reinforced epoxy composites using improved preference selection index approach. J Mater Res Technol 2020; 9: 7583–7591.

22.

Singh

Patnaik

Fekete

, et al. Application of hybrid analytical hierarchy process and complex proportional assessment approach for optimal design of brake friction materials. Polym Compos 2019; 40: 1602–1608.

23.

Ganesh

Keerthiveettil Ramakrishnan

Palani

, et al. Investigation on the mechanical properties of ramie/kenaf fibers under various parameters using GRA and TOPSIS methods. Polym Compos 2022; 43: 130–143.

24.

Jha

Kumar

Verma

, et al. Application of modified TOPSIS technique in deciding optimal combination for bio-degradable composite. Vacuum 2018; 157: 259–267.

25.

Karande

Chakraborty

. Application of multi-objective optimization on the basis of ratio analysis (MOORA) method for materials selection. Mater Des 2012; 37: 317–324.

26.

Swain

Priyadarshini

Mohapatra

, et al. Parametric optimization of atmospheric plasma spray coating using fuzzy TOPSIS hybrid technique. J Alloys Compd 2021; 867: 159074.

27.

Chauhan

Singh

Tiwari

, et al. Hybrid entropy – TOPSIS approach for energy performance prioritization in a rectangular channel employing impinging air jets. Energy 2017; 134: 360–368.

28.

Sharma

Meena

Kumar

, et al. Optimization of waste fly ash powder filled glass fiber reinforced epoxy composite by hybrid AHP-TOPSIS approach. Mater Today Proc 2020; 44: 4789–4794.

29.

Mitra

Saha

Guha

, et al. Ramie: The strongest bast fibre of nature. Technical Bulletin No 8, Central Research Institute for Jute and Allied Fibres 2013; 1–38.

30.

Biswas

Satapathy

. Tribo-performance analysis of red mud filled glass-epoxy composites using Taguchi experimental design. Mater Des 2009; 30: 2841–2853.

31.

Evans

. Analysis and performance of fiber composites (second edition). Mater Sci Eng A 1992; 151. Epub ahead of print 1992.

32.

Maniya

Bhatt

. A selection of material using a novel type decision-making method: preference selection index method. Mater Des 2010; 31: 1785–1789.

33.

Ray

Pati

Gupta

, et al. Analysis and prediction of abrasion wear properties of glass–epoxy composites filled with eggshell powder. Proc Inst Mech Eng, E J Process Mech Eng Epub ahead of print 2022.

34.

Pati

Satapathy

. Processing, characterization and erosion wear response of Linz-Donawitz (LD) slag filled polypropylene composites. J Thermoplast Compos Mater 2016; 29: 1282–1296.

35.

Daniel-Mkpume

Ugochukwu

Okonkwo

, et al. Effect of Luffa cylindrica fiber and particulate on the mechanical properties of epoxy. Int J Adv Manuf Technol 2019; 102: 3439–3444.

36.

Matykiewicz

Barczewski

Knapski

, et al. Hybrid effects of basalt fibers and basalt powder on thermomechanical properties of epoxy composites. Compos B: Eng 2017; 125: 157–164.

37.

Rajesh

Ratna Prasad

Gupta

. Mechanical and degradation properties of successive alkali treated completely biodegradable sisal fiber reinforced poly lactic acid composites. J Reinf Plast Compos 2015; 34: 951–961.

38.

Chandraker

Dutt

Agrawal

, et al. Development and characterization of epoxy-based polymeric composite with bio-particulates as filler material. Arab J Sci Eng 2022; 47: 8069–8080.

39.

Agrawal

Gupta

Pati

, et al. Dry-sliding wear analysis and prediction using response surface method and fuzzy logic for Kota stone dust–fly ash–epoxy hybrid composites. Proc Inst Mech Eng, E J Process Mech Eng 2023: 095440892311589.

40.

Nayak

Satapathy

Mantry

. Parametric analysis for erosion wear of waste marble dust-filled polyester using response surface method and neural networks. J Mater Eng Perform 2021; 30: 3942–3954.

41.

Nayak

Satapathy

Mantry

. Response surface method and neural computation for the analysis and prediction of erosion response of glass-polyester composites filled with waste marble dust. Mater Today Proc 2020; 44: 4425–4432.

42.

Harsha

Tewari

Venkatraman

. Solid particle erosion behaviour of various polyaryletherketone composites. Wear 2003; 254: 693–712.

43.

Mohanta

Acharya

. Mechanical and tribological performance of Luffa cylindrica fibre-reinforced epoxy composite. BioResources 2015; 10: 8364–8377.

44.

Barkoula

. Processes and influencing parameters of the solid. J Mater Sci 2002; 37: 3807–3820.

45.

Pradhan

Acharya

. Solid particle erosive wear behaviour of Eulaliopsis binata fiber reinforced epoxy composite. Proc Inst Mech Eng, J: J Eng Tribol 2021; 235: 830–841.

46.

Arnold

Hutchings

. Erosive wear of rubber by solid particles at normal incidence. Wear 1993; 161: 213–221.

47.

Harsha

Thakre

. Investigation on solid particle erosion behaviour of polyetherimide and its composites. Wear 2007; 262: 807–818.

48.

Suresh

Harsha

Ghosh

. Solid particle erosion of unidirectional fibre reinforced thermoplastic composites. Wear 2009; 267: 1516–1524.

49.

Harsha

Jha

. Erosive wear studies of epoxy-based composites at normal incidence. Wear 2008; 265: 1129–1135.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.02 MB

1.18 MB

2.17 MB

Parametric analysis of erosion wear of sponge iron slag-filled ramie–epoxy composites using Taguchi and preference selection index methods

Abstract

Keywords

Get full access to this article

References

Supplementary Material