International Journal of Engineering Materials and Manufacture (2017) 2(2) 31-36 

https://doi.org/10.26776/ijemm.02.02.2017.02 

 

M. A. Rahman , A. A. Jasani, and M. A. Ibrahim 

Department of Manufacturing and Materials Engineering 

International Islamic University Malaysia 

P.O. Box 10, 50728 Kuala Lumpur, Malaysia 

E-mail: mrahman@iium.edu.my 

 

Reference: Rahman, M. A., Jasani, A. A. and Ibrahim, M. A. (2017). Flexural Strength of Banana Fibre Reinforced Epoxy Composites 

Produced through Vacuum Infusion and Hand Lay-Up Techniques – A Comparative Study. International Journal of Engineering 

Materials and Manufacture, 2(2), 31-36. 

 

 

Flexural Strength of Banana Fibre Reinforced Epoxy Composites Produced 

through Vacuum Infusion and Hand Lay-Up Techniques – A Comparative 

Study 

 

 

Mohamed Abd Rahman, Abdul Aziz Jasani and Mohd Azizuddin Ibrahim 

 

 

Received: 15 March 2017 

Accepted: 30 June 2017 

Published: 30 June 2017 

Publisher: Deer Hill Publications 

© 2017 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Natural fibres from such as kenaf, sisal, pineapple leaf and banana are becoming popular nowadays due to their 

many advantages over traditional glass fibres in reinforcing polymer composites. These fibres are renewable, 

abundantly available, economical, lightweight and environmental friendly. This work compared the flexural property 

of banana fibre-reinforced epoxy composites produced via vacuum infusion and hand layup processes. Banana fibres 

were treated with sodium hydroxide (NaOH) solution for 1 hour before been dried in the oven for 24 hours at 

100°C. An aluminium vacuum infusion mold was manufactured per the standard flexural test specimen of 127mm x 

12.7mm x 3.2mm. Composite specimens were produced while varying fibre volume fraction of 20% and 40% as 

well as fibre length of 63 mm and 127mm. The highest flexural strength of 136.27 MPa was achieved by specimens 

made by vacuum infusion process with 40% volume fraction and 63mm fibre length while for hand layup process, 

the highest flexural strength was only 80.71 MPa with equal fibre content and fibre length. At both fibre lengths, 

using vacuum infusion resulted in the increase in flexural strength in the range of 31.4 to 107.9% over hand layup. 

Using vacuum infusion has resulted in banana fibre-reinforced epoxy composites with better flexural properties 

compared to those produced using hand layup process which allow excellent reinforcing characteristic of banana 

fibres to be realized.  

 

Keywords: Vacuum Infusion, Hand Lay-up, Banana Fibre, Epoxy, Volume Fraction, Fibre Length, Flexural Strength. 

 

 

1 INTRODUCTION 

Composites have always attracted interests in the production of goods as this class of materials is known to have 

excellent properties resulting from the individual components making each composite. The most vital of all the 

properties are mechanical properties for most applications [1]. Achieving important mechanical properties such as 

flexural strength cannot be easily done using a single material but is possible with composites [2]. 

Nowadays, due to environmental and economic reasons, there is an ever-increasing interest in the use of greener 

materials as replacement of more traditional ones in the production of goods? A good example of this trend is the 

research done on natural fibres as reinforcing materials in composites. Natural fibres originating from plants such as 

flax, hemp, jute, kenaf, oil palm, sisal, banana and many more are said to possess many advantages over their 

synthetic counterparts like glass and carbon fibres. These renewable materials are known to be strong, lightweight, 

readily available and less hazardous.  

Natural fibres are already known to possess numerous advantages with banana fibres becoming more popular 

with researchers and industrialists [3]. Venkateshwaran and Elayaperumal (2010) reviewed the works done on banana 

fibres, their uses as composite reinforcing phase and the resulting properties [4]. Banana fibres with their high specific 

strength can be utilized to produce light weight composites to manufacture light weight automobile interior parts 

[3]. In a few studies, banana fibres were used to reinforce epoxy while studying effect of fibre length and optimum 

fibre loading [5 - 7]. In the study of Santhosh et al (2014), 30% fibre fraction was used without specifying banana 

fibre length [6]. Raghavendra et al (2012) utilized short banana fibres of length 2 to 10 mm and a constant 20% fibre 



Flexural Strength of Banana Fibre Reinforced Epoxy Composites Produced through Vacuum Infusion and Hand Lay-up…. 

32 

weight [5]. One study tested the properties of single banana fibres and used them in finite element analysis of banana 

fibre reinforced composites while assuming continuous banana fibres and 5 – 20% fibre weight [8]. Earlier, Laly et al 

(2003) investigated banana fibre reinforced polyester composites and found that the optimum content of banana 

fibre is 40% [9]. 

To improve wettability, sodium hydroxide is the most commonly used chemical to treat natural fibres [5, 6]. 

Alkali treatment or mercerization using sodium hydroxide (NaOH) is the most commonly used treatment for 

bleaching and cleaning the surface of natural fibres to produce high-quality fibres. Modifying natural fibres with alkali 

has greatly improved the mechanical properties of the resultant composites. 

Most if not all the above studies used hand layup method to produce the composites. Hand layup process is 

inexpensive and simple but the composites may contain drawbacks like voids, poor fibre compaction and wrinkling 

[10]. There are other composite processing methods and vacuum infusion composite is one of the well-established 

methods. In vacuum infusion, resin is drawn into the reinforcing fibres using vacuum resulting in better fibre-to-resin 

ratio resulting in lightweight and stronger composite products. Vacuum infusion process produced composites with 

better mechanical properties than hand layup method [11]. Yuhazri et al (2010) however studied polyester composites 

reinforced with continuous kenaf fibres produced by hand layup and vacuum infusion methods in which they found 

that tensile strength and modulus of the composites produced using vacuum infusion technique were higher than 

those produced using hand layup [11]. 

Despite various works on banana fibres and their uses in reinforcing polymer composites, information on the 

usage of banana fibres in reinforcing polymers is somewhat limited in the literature [8]. Especially there was little if 

any on banana fibre reinforced epoxy composites made by using vacuum infusion and comparison of the resultant 

properties with those produced using hand layup process. Therefore, there was a need to further study the mechanical 

properties of banana fibre-reinforced epoxy composites using vacuum infusion method. By using this technique to 

make banana fibre-reinforced epoxy composites, it was expected that higher mechanical properties in particular 

flexural strength would result which would hopefully lead to higher utilization of these natural fibres for commercial 

use. To achieve this, banana fibre-reinforced epoxy composite specimens were prepared using vacuum infusion and 

hand layup methods while experimenting with different fibre contents and fibre lengths and studied the resulting 

flexural strength. 

 

 

2 METHODOLOGY  

Banana fibres were used as reinforcing phase in epoxy composites. The fibres were treated with 5% NaOH solution 

for 2 hours before thoroughly washed under running water. Drying of the fibres was done in the oven for 24 hours 

at 100
0
 C. E-110i epoxy resin was used with H-10 hardener in a 2:1 ratio. To make the composite specimens of banana 

fibre-reinforced epoxy, a vacuum infusion aluminium mold was prepared using CNC milling machine. The mold has 

cavities with dimensions 127mm long, 12.7mm wide and 3.2 mm deep as per ASTM D790 [12]. Figure 1 shows the 

schematic experimental setup of vacuum infusion (VI) process. 

Full factorial experiments were carried out with three factors and two levels (Table 1) totalling 8 experiments. 

Figure 2 (a and b) shows the various banana fibre-reinforced epoxy composites that were successfully manufactured 

using vacuum infusion (VI) and hand layup (HL) processes. In every specimen, banana fibres were arranged 

longitudinally in the mold cavities. 

 

 

 

 

a b 

 

Figure 1: Experimental setup; (a) vacuum infusion process, and (b) universal testing machine. 

 

 

 

 



Rahman et al., (2017): International Journal of Engineering Materials and Manufacture, 2(1), 31-36. 

33 

Table 1: Experimental parameters and responses 

 

Run 

Factors  Flexural Strength (MPa) 

Volume fraction 

(%) 

Fiber length 

(mm) 
Process 

 
Sample 1 Sample 2 Sample 3 Average 

1 20 127 VI  86.07 93.93 98.99 93.00 

2 20 63 VI  111.98 104.24 98.29 104.84 

3 40 127 VI  133.34 144.17 121.65 133.10 

4 40 63 VI  87.95 151.06 169.79 136.27 

5 20 127 HL  96.71 55.02 60.68 70.80 

6 20 63 HL  64.62 60.42 66.95 63.99 

7 40 127 HL  58.93 84.02 49.15 64.03 

8 40 63 HL  73.23 80.45 88.46 80.71 

 

 

 

  
 

a b c 

 

Figure 2: Specimens of banana fiber-epoxy composites; (a) produced by vacuum infusion process, (b)  produced by 

hand layup process, and (c) after undergoing flexural test. 

 

 

3 RESULTS AND DISCUSSIONS 

From the analysis of variance of the flexural strength data (see Table 2), fibre content and process type significantly 

affect the composite flexural strength. Fibre length did not seem to affect flexural strength significantly as both lengths 

may be considered to represent long fibres. Raghavendra et al (2012) determined that optimal condition was at 4 

mm length for banana fibre-reinforced epoxy composites when studying the effect of fibre length on tensile strength. 

They reported slight decrease of tensile strength when longer fibre lengths used [5]. 

Similar flexural strength values were obtained by Santhosh et al (2014) when they studied banana fibre-reinforced 

epoxy composites produced using hand layup [6]. At 20% and 40% fibre content, using vacuum infusion resulted 

in 63.8% and 68.8% increase in flexural strength respectively compared to hand layup. This increase was also 

consistent with works using conventional fibres in which flexural strength of material prepared by vacuum infusion 

almost double compared to those prepared using hand layup method [13].  

 

 

Table 2: Analysis of Variance of Flexural Strength Data 

 

Sources of Variation SS DOF MS Fo P-Value 

Fibre content (A) 2486.77 1 2486.77 6.72 0.0196 

Fibre length (B) 233.00 1 233.00 0.63 0.4390 

Process Type (C) 13198.60 1 13198.60 35.69 0.0000 

AB 82.81 1 82.81 0.22 0.6425 

AC 1420.19 1 1420.19 3.84 0.0677 

BC 10.06 1 10.06 0.03 0.8711 

ABC 386.72 1 386.72 1.05 0.3217 

Error 5917.63 16 369.85 
  

Total 23735.78 23 
   

 

 

 



Flexural Strength of Banana Fibre Reinforced Epoxy Composites Produced through Vacuum Infusion and Hand Lay-up…. 

34 

Figures 3 and 4 indicate clearly that using vacuum infusion made it possible to realize the reinforcing capability of 

the banana fibres as the fibre content increased. At both fibre lengths used, increasing fibre content resulted in large 

increases in composite flexural strength. Similar increases were not obtained using hand layup method. In fact, a slight 

reduction in flexural strength was observed. This is somewhat expected as hand layup process signifies variation in 

composite properties due to sources such skill, inability to remove air bubbles trapped, difficulty in handling large 

amount of fibre content. On the other hand, use of vacuum infusion entails more consistent process.  

Figures 5 and 6 below further indicate the benefits of using vacuum infusion method over hand layup method. It 

is clear that increasing the fibre content resulted in the increase in flexural strength. However, at each fibre content 

in the vacuum infusion process, using longer fibres resulted in very slight decreases in flexural strength. Similar decrease 

in flexural strength was also observed another previous work [8]. Since the length of banana fibres extracted from 

the tree trunks is inconsistent, shorter fibre lengths may be utilized in composite processes without jeopardizing the 

properties significantly. 

Figure 7 above shows the flexural strength of the specimens with 40% fibre content and specimens of neat resin 

made by vacuum infusion process. At 40% fibre content, the use of vacuum infusion resulted in 29.7% increase in 

flexural strength compared to neat resin.  Additionally, the specimens with 40% volume fraction achieved highest 

flexural strength at 136.27MPa. The variations of flexural strength for the samples prepared by vacuum infusion 

process and hand layup process are compared as shown in Figure 8. 

 

 

 

 

 
 

Figure 3: Shows the relationship of volume fraction 

on flexural strength of specimens with fiber length 127 

mm 

Figure 4: Shows the relationship of volume fraction on 

flexural strength of specimens with fiber length 63 mm 

 

 

 

 

 

 

 

Figure 5: Shows the relationship of volume fraction on 

flexural strength of specimens with volume fraction 

20% 

Figure 6: Shows the relationship of fiber length on 

flexural strength of specimen with volume fraction 40%. 

 

 



Rahman et al., (2017): International Journal of Engineering Materials and Manufacture, 2(1), 31-36. 

35 

  

Figure 7: Relationship between specimen with 40% 

volume fraction offiber and specimen with no-fiber 

manufacture by vacuum infusion process. 

Figure 8: The Variation of flexural strength of specimens 

with different factors produce with different process. 

 

 

 

The above results clearly indicate the advantages of vacuum infusion process in terms of producing banana fibre 

reinforced composites with better mechanical properties hence quality. The vacuum causes bubbles from resin to be 

removed from the experimental setup and atmospheric pressure to compress the fibre laminates forcing better wetting 

of the fibres by the resin. Better wetting of fibres led to better fibre-matrix interface and the resultant higher flexural 

strength. In contrast, for hand lay-up method, the process was carried out in environment exposed to moisture and 

other gases which could react thus affect the composites during curing process [11]. 

Vacuum infusion may be used to produce greener products made of polymer composites reinforced with natural 

fibres like banana fibres. Excellent characteristics of natural fibres as reinforcing phase in composites may be realized. 

Not only product quality will be increased, an eco-friendlier and less wasteful process will result.  

 

 

4 CONCLUSIONS 

In this study, banana fibre-reinforced epoxy composites were successfully made using hand layup and vacuum infusion 

methods. Flexural properties of these composites were studied with 20% and 40% fibre contents and 63 mm and 

127 mm fibre lengths. It may be concluded that: 

 

1. Using vacuum infusion method to produce banana fibre-reinforced epoxy composites resulted in an increase in 

flexural strength compared to neat resin with a maximum of 29.7% increase at 40% fibre content. 

2. Banana fibre-reinforced composites had higher flexural strength when produced using vacuum infusion process. 

3. At both 63 mm and 127 mm fibre length, increasing fibre content from 20% to 40% resulted in the increase in 

flexural strength by 30.0% and 43.1% respectively. In similar instances, the use of hand layup resulted in 

reductions in flexural strength. 

4. At both fibre lengths, using vacuum infusion resulted in the increase in flexural strength in the range of 31.4 to 

107.9% over hand layup. 

5. At both 20 and 40% fibre contents, flexural strengths slightly reduced upon using 127 mm over 63 mm long 

fibres. Using hand layup resulted modest increase and even higher reduction respectively. 

6. At both fibre contents, using vacuum infusion however resulted in much greater increases in flexural strength 

compared to the use of hand layup. 

7. The highest flexural strength was obtained with a specimen having 40% fibre content and 63 mm fibre length 

produced by vacuum infusion process which is 136.27MPa. 

8. Vacuum infusion has been shown to produce banana fibre-reinforced epoxy composites with better flexural 

properties compared to those produced using hand layup process. Combination of other natural fibres can be 

used with banana fibres to develop hybrid composites and the properties determined. Filler material can be 

also used in the composites for possible improvements of the composite properties. 

 

 

ACKNOWLEDGEMENT 

The authors are grateful to the International Islamic University Malaysia for funding the study and the Kulliyyah of 

Engineering where the experimental studies were conducted. 

 

 

 



Flexural Strength of Banana Fibre Reinforced Epoxy Composites Produced through Vacuum Infusion and Hand Lay-up…. 

36 

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