Development and Experimental Investigation of Pigeon Pea Stalk Particle Reinforced Epoxy Composites and their Hybrid Composites for Lightweight Structural Applications

Pujar, Nagaraj Malleshappa; Mani, Yuvaraja

doi:10.1590/1980-5373-MR-2022-0173

Nagaraj Malleshappa Pujar

PSG College of Technology, Mechanical Engineering Department, Coimbatore, India.

https://orcid.org/0000-0002-1711-8852

Yuvaraja Mani

PSG College of Technology, Mechanical Engineering Department, Coimbatore, India.

*e-mail: nagarajpm@sit.ac.in

Thumbnail

Figure 1
Preparation of PP stalk particles and the development of EP composites and their hybrid composites.

Thumbnail

Figure 2
Tensile characteristics of Epoxy, EP composites, and their hybrid composites.

Thumbnail

Figure 3
Mechanical characteristics of Epoxy, EP composites, and their hybrid composites: (a) Flexural characteristics, (b) Compressive strength.

Thumbnail

Figure 4
Mechanical characteristics of Epoxy, EP composites, and their hybrid composites: (a) Impact strength, (b) Hardness.

Thumbnail

Figure 5
DMA characteristics of EP2 composite, EJP2, and EGP2 hybrid composites: (a) Storage modulus, (b) Loss modulus.

Thumbnail

Figure 6
Tan delta curves: (a) EP2 composite, (b) EJP2, (c) EGP2 hybrid composites.

Thumbnail

Figure 7
SEM images of PP stalk and EP2 composites: (a) and (b) PP stalk particles; (c), (d), (e), and (f) Tensile fractured specimens; (g), (h), and (i) Flexural fractured specimens.

Thumbnail

Table 1
Specimen designation with the composition.

Thumbnail

Table 2
Theoretical density, actual density, & void content of EP composites, EJP, and EGP hybrid composites.

Thumbnail

Table 3
ILSS characteristics of EP composites, EJP, and EGP hybrid composites.

Thumbnail

Table 4
Decision matrix.

Thumbnail

Table 5
Normalized decision matrix.

Thumbnail

Table 6
Separation measure, relative closeness factor, and ranking of composites.

Thumbnail

Table 7
Comparative assessment of mechanical properties of PP stalk fiber-reinforced composites with other natural fiber-reinforced composites.

(1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

Sl. No.	Composite Specimen Designation	Fiber and matrix weight fraction in %					Thickness in mm
		Core		Skin			Thickness in mm
		PP	Epoxy	Jute (2 layers)	Glass (2 layers)	Epoxy
1	EP0	-	100	-	-	-	5.0
2	EP1	15	85	-	-	-	5.0
3	EP2	20	80	-	-	-	5.0
4	EP3	25	75	-	-	-	5.0
5	EJP1	15	85	40	-	60	5.0
6	EJP2	20	80	40	-	60	5.0
7	EJP3	25	75	40	-	60	5.0
8	EGP1	15	85	-	40	60	5.0
9	EGP2	20	80	-	40	60	5.0
10	EGP3	25	75	-	40	60	5.0

Composite specimens	Theoretical density (g/cc)	Actual density (g/cc)	Void (%)
EP0	1.170	1.131 (0.002)	3.3
EP1	1.230	1.182 (0.005)	3.9
EP2	1.252	1.191 (0.008)	4.9
EP3	1.274	1.174 (0.009)	7.8
EJP1	1.223	1.193 (0.003)	2.5
EJP2	1.252	1.199 (0.006)	4.2
EJP3	1.274	1.191 (0.008)	6.5
EGP1	1.293	1.262 (0.003)	2.4
EGP2	1.315	1.267 (0.005)	3.7
EGP3	1.338	1.254 (0.006)	6.3

Composite specimens	Shear load (N)	Shear deflection (mm)	ILSS (MPa)
EP0	1800 (20)	0.832 (0.002)	27.0 (0.30)
EP1	1245 (22)	0.864 (0.003)	18.7 (0.33)
EP2	1100 (26)	0.894 (0.003)	16.5 (0.39)
EP3	1030 (31)	0.832 (0.005)	15.5 (0.46)
EJP1	1488 (21)	1.012 (0.002)	22.3 (0.32)
EJP2	1250 (24)	1.245 (0.004)	18.8 (0.36)
EJP3	1220 (28)	1.134 (0.004)	18.3 (0.42)
EGP1	2066 (15)	1.821 (0.001)	31.0 (0.22)
EGP2	1916 (20)	1.924 (0.002)	28.7 (0.30)
EGP3	1728 (32)	1.815 (0.003)	25.9 (0.35)

Composite specimen	Tensile strength (MPa)	Flexural strength (MPa)	Impact strength (kJ/m²)	Compressive Strength (MPa)	Hardness (Shore D)	ILSS (MPa)	water absorption (%)	void (%)
EP1	20.8	33.64	1.88	62.83	68	18.7	4.52	3.9
EP2	24.95	49.3	2.98	71.84	64	16.5	5.17	4.9
EP3	21.87	39.13	3.97	57.99	55	15.45	9.35	7.8
EJP1	21.52	54.38	2.78	65.33	71	22.33	4.32	2.5
EJP2	30.91	59.38	3.62	73.11	68	18.75	4.98	4.2
EJP3	27.45	51.54	5.01	61.69	60	18.3	9.14	6.5
EGP1	48.4	91	44.82	74.15	82	31	3.11	2.4
EGP2	54.04	111.92	45.68	83.12	76	28.75	3.82	3.7
EGP3	48.16	109.89	46.33	73.88	72	25.92	6.11	6.3

Composite specimen	Tensile strength (MPa)	Flexural strength (MPa)	Impact strength (kJ/m²)	Compressive Strength (MPa)	Hardness (Shore D)	ILSS (MPa)	water absorption (%)	void (%)
EP1	0.1958	0.1550	0.0237	0.3004	0.3291	0.2786	0.2516	0.2598
EP2	0.2349	0.2271	0.0375	0.3434	0.3097	0.2458	0.2878	0.3264
EP3	0.2059	0.1803	0.0500	0.2772	0.2662	0.2302	0.5200	0.5196
EJP1	0.2026	0.2505	0.0350	0.3123	0.3436	0.3327	0.2403	0.1665
EJP2	0.2910	0.2736	0.0455	0.3495	0.3291	0.2793	0.2771	0.2798
EJP3	0.2580	0.2374	0.0630	0.2949	0.2904	0.2726	0.5084	0.4330
EGP1	0.4556	0.4192	0.5640	0.3545	0.3969	0.4619	0.1728	0.1599
EGP2	0.5087	0.5156	0.5748	0.3974	0.3678	0.4283	0.2122	0.2465
EGP3	0.4533	0.5063	0.5830	0.3532	0.3485	0.3862	0.3398	0.4197

Composite specimen	Ideal separation ( $S_{i}^{+}$ )	Negative ideal separation ( $S_{i}^{-}$ )	Relative closeness factor (c_i)	Rank
EP1	0.1152	0.0415	0.2648	7
EP2	0.1079	0.0408	0.2743	6
EP3	0.1163	0.0247	0.1749	9
EJP1	0.1052	0.0486	0.3161	5
EJP2	0.0992	0.0474	0.3230	4
EJP3	0.1049	0.0310	0.2279	8
EGP1	0.0179	0.1158	0.8659	2
EGP2	0.0083	0.1231	0.9370	1
EGP3	0.0231	0.1151	0.8327	3

Polymer matrix	Natural fiber	Fiber loading (% w/v)	TS (MPa)	FS (MPa)	IS (kJ/m²)	Reference
Epoxy	PP stalk	20	24.95	49.3	2.98	Present work
	Jute/PP hybrid	20	30.91	59.38	3.62
	Glass/PP hybrid	20	54.04	111.92	45.68
Epoxy	Bagasse	30	29.23	-	4.5 (J/m)	²¹21 Prasad L, Kumar S, Patel RV, Yadav A, Kumar V, Winczek J. Physical and mechanical behaviour of sugarcane bagasse fibre-reinforced epoxy bio-composites. Materials. 2020;13(23):1-13.
Epoxy	Groundnut shell	12.5	36.66	43.43	-	³²32 Jacob Olaitan A, Emmanuel Terhemen A, Danladi King G, Rapheal Oluwatoyin O. Comparative assessment of mechanical properties of groundnut shell and rice husk reinforced epoxy composites. Am J Mech Eng. 2017;5(3):76-86.
Epoxy	Rice husk	12.5	12.71	22.72	-
Epoxy	Banana	16	16.39	57.53	2.25	³³33 Venkateshwaran N, Elayaperumal A, Jagatheeshwaran MS. Effect of fiber length and fiber content on mechanical properties of banana fiber/epoxy composite. J Reinf Plast Compos. 2011;30(19):1621-7.
Epoxy	Coir	30	13.05	35.42	17.5	³⁹39 Biswas S, Kindo S, Patnaik A. Effect of fiber length on mechanical behavior of coir fiber reinforced epoxy composites. Fibers Polym. 2011;12(1):73-8.
Epoxy	Date palm	50	36.17	58.2	10.69 (J/m)	⁴⁰40 Supian ABM, Jawaid M, Rashid B, Fouad H, Saba N, Dhakal HN, et al. Mechanical and physical performance of date palm/bamboo fibre reinforced epoxy hybrid composites. J Mater Res Technol. 2021;15:1330-41.
Epoxy	Sunflower husk	15	25	42	-	⁴¹41 Barczewski M, Sałasińska K, Szulc J. Application of sunflower husk, hazelnut shell and walnut shell as waste agricultural fillers for epoxy-based composites: a study into mechanical behavior related to structural and rheological properties. Polym Test. 2019;75:1-11.
	Hazelnut shell	15	28	58	-
	Walnut shell	15	35	48	-
Epoxy	Coconut shell	15	41.3	68.25	-	⁴²42 Ojha S, Raghavendra G, Acharya SK. A comparative investigation of bio waste filler (wood apple-coconut) reinforced polymer composites. Polym Compos. 2014;35(1):180-5.
Epoxy	Wood apple	15	43.6	78.19	-
Epoxy	Soya fiber	20	53.56	94.59	3.61	⁴³43 Vinod A, Sanjay MR, Siengchin S, Fischer S. Fully bio-based agro-waste soy stem fiber reinforced bio-epoxy composites for lightweight structural applications: influence of surface modification techniques. Constr Build Mater. 2021;303:124509.
Epoxy	Napier grass	20	28.45	56.21	-	⁴⁴44 Kommula VP, Reddy KO, Shukla M, Marwala T, Rajulu AV. Mechanical properties, water absorption, and chemical resistance of napier grass fiber strand–reinforced epoxy resin composites. Int J Polym Anal Charact. 2014;19(8):693-708.
Epoxy	Curaua	50	30.29	67.45	-	²⁸28 Jawaid M, Khalil HPSA. Effect of layering pattern on the dynamic mechanical properties and thermal degradation of oil palm-jute fibers reinforced epoxy hybrid composite. BioResources. 2011;6(3):2309-22.
Polyester resin	Ricinus communis	40	20.1	43.2	41.4	⁴⁵45 Nijandhan K, Muralikannan R, Venkatachalam S. Ricinus communis fiber as potential reinforcement for lightweight polymer composites. Mater Res Express. 2018;5(9):95307.
Unsaturated polyester	Sisal/ silk hybrid	25	18.94	46.18	-	⁴⁶46 Noorunnisa Khanam P, Mohan Reddy M, Raghu K, John K, Venkata Naidu S. Tensile, flexural and compressive properties of sisal/silk hybrid composites. J Reinf Plast Compos. 2007;26(10):1065-70.
Polypropylene	Pineapple/Betel nut hybrid	10	28	44	-	³⁴34 Jahan E, Akter M, Hasan M. Effect of fibre ratio and chemical treatment on the properties of pineapple leaf and betel nut husk fibre-reinforced hybrid polypropylene composites. Adv Mater Process Technol. 2020;6(3):637-46.
Polypropylene	Kenaf	30	15.83	29.34	14.5	³⁵35 Feng NL, Malingam SD, Razali N, Subramonian S. Alkali and silane treatments towards exemplary mechanical properties of kenaf and pineapple leaf fibre-reinforced composites. J Bionics Eng. 2020;17(2):380-92.
Polypropylene	Pineapple	30	17.07	45.25	15.0
Polypropylene	Pigeon pea	30	25.0	47.0	28 (J/m)	¹⁶16 Luthra P, Singh R, Kapur GS. Preparation and studies of pigeon pea stalk/polypropylene composites with and without compatibilizer. Polym Polymer Compos. 2019;27(6):337-46.
Polypropylene	Banana peel	20	26.3	38.8	29 (J/m)	³⁶36 Luthra P, Singh R, Kapur GS. Development of polypropylene/banana peel (treated and untreated) composites with and without compatibilizer and their studies. Mater Res Express. 2019;6(9):95313.
Polypropylene	Betel nut	30	27.0	55.0	1.6	³⁷37 Chakrabarty J, Hassan MM, Khan MA. Effect of surface treatment on betel nut (Areca catechu) fiber in polypropylene composite. J Polym Environ. 2012;20(2):501-6.
Polylactic acid	Juliflore wood	20	24.89	67.73	1.09	³⁸38 Raj SS, Kannan TK, Rajasekar R. Influence of prosopis juliflora wood flour in poly lactic acid - developing a novel bio-wood plastic composite. Polímeros. 2020;30(1):1-11.

ρ_{_{T}} = \frac{1}{(\frac{W_{P P}}{_{ρ_{P P}}}) + (\frac{W_{M}}{_{ρ_{M}}}) + (\frac{W_{E}}{_{ρ_{E}}})}

[1] *e-mail: nagarajpm@sit.ac.in

Brasil

Brasil

Development and Experimental Investigation of Pigeon Pea Stalk Particle Reinforced Epoxy Composites and their Hybrid Composites for Lightweight Structural Applications

Abstract