International Journal of Engineering Materials and Manufacture (2021) 6(3) 176-186 

https://doi.org/10.26776/ijemm.06.03.2021.09 

 

Ochuokpa E. O
1
, Yawas, D. S.

2 
, Sumaila, M.

2
 and Adebisi A.A

1,3
 

1
Department of Metallurgical and Materials Engineering, Ahmadu Bello University, Zaria, Nigeria 

2
Department of Mechanical Engineering, Ahmadu Bello University, Zaria, Nigeria 

3Department of Metallurgical and Materials Engineering, Air Force Institute of Technology, Kaduna, Nigeria 

E-mail: dyawas@yahoo.com 

 

Reference: Ochuokpa et al. (2021). Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate 

Metal Matrix Composite. International Journal of Engineering Materials and Manufacture, 6(3), 176-186. 

 

 

Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash 

(MSSA) Particulate Metal Matrix Composite 

 

 

Ochuokpa E. O,
 
Yawas, D. S., Sumaila, M. and Adebisi A. A. 

 

 

Received: 11 March 2021 

Accepted: 11 May 2021 

Published: 15 July 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

A composite material is a combination of two or more chemically distinct and insoluble phases; its properties and 

structural performance are superior to those of the constituents acting independently. MMCs are made by dispersing 

a reinforcing material into a metal matrix to improve their properties. They are prepared by powder metallurgy and 

casting, although several technical challenges exist with casting technology. Achieving a homogeneous distribution of 

reinforcement within the matrix is one such challenge, and this affects directly on the properties and quality of 

composite. In this work a composite is developed by adding Mango seed shell Ash (MSSA) particulate in Al- Si-Mg 

Alloy by mass ratio 5%, 10%, 15% and 20%.  The composite was prepared by stir casting technique. It is proposed 

to use this material for production of motorcycle wheel hub which are subjected to continuous wear as the hubs are 

in direct contact with the brakes and rotating sprockets. The MSSA, was characterized using X- ray fluorescent (XRF). 

The result reveals SiO2, has the highest percentage composition followed by CaO, Al2O3, Fe2O3 and Mg2O as major 

phases. The presents of these hard constituent compounds suggests that the mango seed shell ash can be used as 

particulate reinforcement in various metal matrices since the chemical composition has similarity with the XRF analysis 

of Periwinkle shell ash, rice husk, fly ash, and bagasse ash currently used in metal matrix composite. Mechanical tests 

such as hardness test and impact test were conducted. The results revealed that increase in the percentage of MSSA 

progressively increased the hardness of the material from 5% wt to a maximum hardness of 43.2 HV at 15% addition 

of MSSA. This represents a 26.16% improvement over the unreinforced alloy. However, the impact energy 

progressively decreases of the material from 5%wt of MSSA and later increased to optimum energy at 15% addition 

of MSSA. From the results it is concluded that composite material such as Al- Si-Mg/ MSSA is one of the options as a 

material for production of motorcycle hub. The wear test of the composite was then carried out using Taguchi design 

to optimize the range of MSSA from 5% wt -15% wt., Sliding speed of 5cm/s -20cm/s, sliding distance from 50m to 

200m, and the load of 2N, 4N, 6N, & 8N respectively. Analysis of the result of SN ratio for wear rate shows the 

optimum wear resistant value is in the combination of Load=4N, sliding speed = 10cm/s sliding distance=200m and 

MSSA=15 wt% These also correspond with the analysis of wear maps & wear rate presented in the diagrams of 

dynamic friction coefficient (COF) for Al-Si- Mg/ MSSA Composite. 

Keywords: Aluminium Metal Matrix composite, Stir Casting, Mango Seed Shell Ash, motorcycle hub. 

 

1 INTRODUCTION 

The desire to develop a composite material using Mango seed shell Ash (MSSA) to reinforce the conventional 

motorcycle hub was prompted by the fact that the motorcycles usually referred to as "Okada" in Nigeria have become 

a popular mode of transportation, The hubs are in direct contact with the brakes and rotating sprockets hence they 

are subject to frequent mechanical failure due to wear as a result bad road. They are therefore in high demand for 

replacement. Similarly, there are large quantities of mango seeds discarded as waste on the streets across   Nigerian 

rural communities after consumption of the mango fruits constituting environmental hazards to the public. 

The local content policy of Nigerian government in recent times has stimulated great interest in the utilization of 

abundant agricultural waste for in production of engineering materials. Agricultural waste products such as Mellon 

shell, eggshell, sugarcane, bagasse, rice husk, coconut shell, bamboo leaf, ground nutshell and other organic waste 

have been successfully used for Aluminium alloy particulate composite reinforcement [1], This is in line with the global 



Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate Metal Matrix Composite  

177 

demand for the development of advanced engineering materials for various engineering applications in modern times 

[2]. However, to the best of our knowledge, no work has been done on the use of abundant mango ‘Mangiferaindica’ 

seed shell ash (MSSA) as reinforcement for aluminium matrix. This research therefore provides pioneering knowledge 

on the possibility of using mango seed shell as reinforcement for aluminium matrix composites (AMCs) for production 

of automobile component and other engineering applications. It is expected to reduce the high cost of the Synthetic 

reinforcements of AMCs such as silicon carbide (SiC) and alumina (Al2O3) which are imported at high foreign currency 

exchange rate in Nigeria Leading to high cost of production of motorcycle wheel hubs. 

There are some micro structural features that limit mechanical properties of cast Al- Si- Mg alloys such as Porosity, 

coarse acicular Si particles and coarse primary aluminium dendrites [3]. Similarly, the presence of Mg and Fe in the 

alloy gives an opportunity for the formation of eutectic α + Mg2Si and platelets of Fe2Si2Al9 in addition to the Si 
platelets. These plate-shaped phases provide easy crack nucleation sites and propagation paths, resulting in relative 

low strengths and ductility [4].  

Motorcycle hub is in direct contact with the brakes and rotating sprockets hence it is subject to frequent mechanical 

failure.  The main extent and reason for their failures include surface fatigue wear caused by fracture and breakages 

as a result of direct contact with the brakes and rotating sprockets, bad road and gallops, and poor quality of spares. 

After consumption of the mango fruits, a large quantity of mango seeds is discarded as waste in Nigeria constituting 

environmental hazards to the general public. This research is aimed at developing aluminium based Mango Seed 

Mangiferaindica Shell Ash (MSSA) particulate metal matrix composite for engineering application. To the best of our 

knowledge, no previous work has been done on the use of abundant mango seed shell as in the reinforcement of Al- 

Matrix composites (AMCs) for engineering applications. This study will therefore provide pioneering knowledge on 

the possibility of using mango seed shell Ash (MSSA) as reinforcement for AMCs for spare parts production. It will 

also succeed in creating employment opportunities in Nigeria by converting agro-waste product to wealth and 

positively influence the economy. It will help solve the environmental problems caused by the overwhelming 

quantity of agro-waste disposal challenges in Nigeria. 

 

2 LITERATURE REVIEW 

2.1 Aluminium Alloying Elements 

The typical alloying elements added to aluminium are Zinc (Zn), Copper (Cu), Silicon (Si), Iron (Fe), magnesium 

(Mg), Lithium (Li). Manganese (Mn), Nickel (Ni) and Tin (Ti) [5].  Because of their varying solid solubility, some are 

used as solid solution while others are added to form various desirable intermetallic compounds. 

 

2.2 Materials for Motorcycle Hubs 

Mostly, Aluminium motorcycle hubs are products of aluminium- magnesium alloys because of their unique casting 

properties, good resistance to corrosion, easy to cast into thin or thick sections, excellent machinability, and good 

strength to weight ratio [6]. 

 

2.2.1 Al-Si-Mg Alloy 

An alloy of Al-Si-Mg has wide application in automotive and aerospace industry due to their excellent castability and 

a high strength-to-weight ratio [7]. 

 

2.2.2 Aluminium Oxide 

Al2O3, is known to be stable in aluminium, but it reacts with magnesium in aluminium alloys containing Mg to form 

Mgo and MgAl2O4. (spinel) as shown in the following equations. MgO may form at high magnesium level and lower 

temperature whereas the spinel will form even at very low magnesium levels [8]. This explains why Al2O3 is not 

thermodynamically stable in most aluminium alloys. 

 

3Mg + Al2O3 = 3MgO + 2Al 

(∆G= -117KJ at 1000K)----------------------------------------------------------------- (2.1) 

And 3Mg + 4Al2O3 = 3MgAl2O4 + 2Al 

(∆G = - 215.1KJ at 1000K)------------------------------------------------------------ (2.2) 

 

2.3 The Role of Magnesium 

Improvement of wettability between the Al-Mg-Si alloy and the reinforcements. Magnesium and magnesium alloys 

are amongst the lightest materials for practical use as the matrix phase in metal matrix composites. When compared 

to other available structural materials, Magnesium is attractive because of its unique combination of low density and 

excellent machinability. 

The role of Silicon alloy; The role of silicon is for casting flowability. For foundry production of castings, contain 

amounts of silicon far more than the amount that is soluble or needed for strengthening alone are required [9]. The 

function here is chiefly to improve casting soundness and freedom from cracking, but the excess silicon also serves to 

increase wear resistance. Aluminium alloys that are used for wear resistance application base on aluminium silicon 

alloy system [10]. Aluminium casting alloys must contain enough amount of silicon which is a eutectic- forming 

element, this is to enhance adequate fluidity to fill the shrinkage that usually occur during casting. 



Ochuokpa et al. (2021). International Journal of Engineering Materials and Manufacture, 6(3), 176-186. 

178 

2.4 Defects in Al-Si-Mg Alloy 

The coarse acicular Si particles and coarse primary aluminium dendrites are bound to negatively affect the hardness 

properties of Al-Si-Mg alloy in production of motorcycle hub [11]. There is possibility of improving the properties of 

this alloy by the use of agro waste ’mango seed shell ash’ as reinforcement hence the need to study the use of mango 

seed shell ash. There are three micro structural features that limit mechanical properties of cast Al- alloys such as 

ductility, toughness and fatigue resistance: Porosity, coarse acicular Si particles and coarse primary aluminium 

dendrites [9]. 

 

2.5 Description of Motorcycle Wheel Hub 

The wheel rims are usually steel or aluminium generally with steel spokes and an aluminium hub. The rear motorcycle 

hub is at the central part of a motorcycle wheel that rotates on or with the axle and from which spokes radiates. It 

is in direct contact with the brakes and rotating sprockets hence it is subject to frequent Mechanical failure. 

 

 
 

Figure 1: The rear motorcycle wheel hub 

 

 

2.6 Classification of Composite Materials 

Based on the type of matrix, composites are classified into the followings: 

Metal matrix composites, Polymer matrix composites, Ceramic matrix composites, Carbon-Carbon composites, and 

hybrid composites. 

 

2.7 Benefits of Composite Materials 

In the recent past, materials development has shifted from monolithic to composite materials for adjusting to the 

global need for reduced weight, low cost, quality, and high performance in structural materials. Driving force for the 

utilization of Aluminium matrix composites (AMCs) in areas of aerospace and automotive industries include 

performance, economic and environmental benefits [12]. The conventional monolithic materials have limitations in 

achieving good combinations of strength, stiffness, toughness and density. Metal matrix composites (MMCs) possess 

significantly improved properties including high specific strength; specific modulus, damping capacity and good wear 

resistance compared to unreinforced alloys. Aluminium-metal matrix composite (AMC) materials having a lower 

density and higher thermal conductivity as compared to the traditionally used grey cast irons are expected to result 

in weight reduction of up to 60-65 % in automotive parts [13]. 

Several works have been carried out on development Aluminium matrix composites (AMCs) in Nigeria. Adebisi 

et al [14] studied the effect of particle size of SiO2 on the properties of Al-Si particulates. Their results show that the 

use of fine particles have a higher degree of strengthening than the use of coarse reinforcement particles. 

Maleque et al [15] stated that in composites, materials are combined in such a way as to enable one to make 

better use of their parent material while minimizing to some extent the effects of their deficiencies. 

Aigbodion [16] studied the possibility of using kankara clay found in abundance in kankara village in Kastina state 

Nigeria as reinforcement for Al-Si-alloy. the result shows that kankara clay can serve as potential reinforcement for 

aluminium alloy up to a maximum of 20wt% of this clay body in the alloy. 

Amaren & Aku [17] carried out an XRF analysis on Periwinkle shell ash and confirmed that SiO2, CaO, MgO, Cr2 

O3. and Fe2O3 were found to be major constituents of Periwinkle ash. The presence of hard elements like SiO2, CaO, 

MgO, Cr2 O3. and Fe2O3   suggested that Periwinkle shell ash particles can be used as reinforcement material. 



Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate Metal Matrix Composite  

179 

Madakson et al [18] characterized coconut ash as a constituent of metal matrix composite for potential application 

in automobile sector. Microscopic (particle size, SEM and XRF) and spectroscopic analysis (XRD and FTIR) were 

carried out for characterization of the coconut shell ash. 

Mostly, Aluminium motorcycle hubs are products of alloys of Al-Si-Mg because of their unique casting properties, 

good resistance to corrosion, easy to cast into thin or thick sections, excellent machinability, and a high strength-to-

weight ratio as compared to cast iron hub. 

Ezatpour & Sajjadi [19] revealed that the addition of Al2O3-MgO reinforcement to aluminium resulted to 

enhancement of hardness and strength of material.  

Li et al [20] studied a Production Planning Model for Make-to-Order Foundry Flow Shop with Capacity 

Constraint. The results shows that the proposed approach can achieve better profit rate of orders in actual foundry 

industry more effectively. 

 

3 MATERIALS AND METHODS 

The materials used in this research includes: 

• 5kg of waste mango seed were obtained from Palladan and Samara Zaria Kaduna State Nigeria. 

• The scrapped of convectional motorcycle hub containing Al-Si-Mg, 

 

3.1 Methodology 

Determine the Chemical Composition  

Min pal compact energy dispersive X-ray spectrometer was used for elemental analysis of mango seed shell ash and 

the powder from the conventional motorcycle hub. Carbonization of mango seed shell ash was carried the following 

steps, 

• The Mango seeds shells collected were dried in the sun for three days,  

• Decorticated manually to remove the seed from the shell and grinded into powder. 

• The powder of MSSA was packed in a steel box and carbonized in an air tightened condition using a furnace at 

600°C for four hours.  

• Sieved & the particle size analysis carried out from 250цm to 106 µm 
 

Development of the Composite through Stir Casting is a suitable way for manufacturing composites with up to 30% 

volume fractions. The stir casting was carried out according to standard casting procedures as shown in Figure.2 

below. 

 

 
 

Figure.2: Casting procedures. 

 

Table 1: charging of matrix and reinforcement into crucible furnace 

 

Casting Runs % Al-Si-Mg Alloy % MSSA Samples No 

8 1 100 - Control C 

2 95 5 A 

3 90 10 B 

4 85 15 D 

5 80 20 E 



Ochuokpa et al. (2021). International Journal of Engineering Materials and Manufacture, 6(3), 176-186. 

180 

3.2 Stir Casting Process 

A sand mold was prepared with diameter 30mm and the length 80mm and used to produce the test bars.  The scrap 

motorcycle hub to be melted was first charged into the furnace and temperature was raised to 750
o
C to superheat 

the aluminium alloy melt. The 15%wt. of MSSA particle was pre-heated to 650
o
C to enhance wettability with the 

matrix. The pre-heated MSSA particles were added and stirred continuously for 60 seconds to achieve uniform 

distribution of the reinforcement by manual process at a stirring speed 100 rpm. The pouring temperature was 

controlled at about 720
o
C. The crucible was removed from the furnace with special tongs was used as a ladle to pour 

into the prepared molds directly. After casting, the bars were machined to standard samples for mechanical tests. 

 

3.3 Determination of Hardness Value 

The hardness values of the cast samples were determined using a Vickers Hardness Testing Machine according to 

ASTM; E18-15 standards. The cast bars were machined to standard dimensional specifications of the test samples. The 

average reading of three different locations on the sample surfaces were taken in each case. 

 

3.4 Determination of Impact Strength 

The Impact strength was determined using the Charpy Universal Impact testing machine with specifications 

Hounsfield Balance impact machine serial No 3203, Total force capacity 48Ib in the department of mechanical 

engineering, Ahmadu Bello University Zaria. 

The sample were prepared with diameter of 8 mm, v- notched to 0,5 mm depth from the middle with the total 

length of 46 mm according to standard of ISO 8256 (2004) for dent specified. The sample was fixed parallel between 

the stationary clamp and at a cross head of the pendulum hammer set to hit the cross head at the lowest point of the 

circular motion. The hammer speed was set at 1.5m/s which corresponded to the falling angle of 60. 

The specimen was broken by a single overload event due to the impact of the pendulum. A stop pointer is used 

to record how far the pendulum swings back up after fracturing the specimen. The impact toughness of a metal is 

determined by measuring the energy absorbed in the fracture of the specimen. This is simply obtained by noting the 

height at which the pendulum is released and the height to which the pendulum swings after it has struck the specimen. 

The height of the pendulum times the weight of the pendulum produces the potential energy and the difference in 

potential energy of the pendulum at the start and the end of the test is equal to the absorbed energy [15]. 

 

3.5 Taguchi Experimental Design (Wear Test & Tribological Analysis) 

Taguchi experimental Design was used to optimize the range of reinforcement of MSSA from 5%wt-15%wt in the 

Al- alloy matrix.  Standard formula according to ASTM D 6079-97/EN 590 standards was used in examining the 

abrasive wear. The test samples were fabricated with a length of 35mm and a diameter of 10mm and were subjected 

to abrasive wear condition. The wear test of the composite was carried out using 0%wt, 5%wt.10%wt, & 15%wt 

of MSSA, sliding speed of 5cm/s -20cm/s, sliding distance from 50m to 200m, and the load of 2N, 4N, 6N & 8N 

respectively. The Wear testing machine used was Anton Paar GmbH Anton Paar Strasse 208054 Graz – Austria in the 

faculty of Engineering Ahmadu Bello University Multi-user laboratory.  

Taguchi Design L16 (4^4) Factors: 4 Runs: 16; The result of Taguchi Orthogonal Array Design L16 (4^4) Factors is 

shown in table 3. Evaluation of the impute process parameters based on based on Taguchi design. The result of 

Evaluation of the impute process parameters based on based on Taguchi L16 design. is shown in Table. Table 2 and 

Table 3 above provides adequate data required for tribological (wear & friction) analysis. 

 

 

Table 2: Taguchi L16 orthogonal array design 

 

 Factors  1 2 3 4 

1 Load (N) A 2 4 6 8 

2 Sliding Speed (m/s) B 5 10 15 20 

3 Sliding distance (M) C 50 100 150 200 

4 MSSA reinforcement (wt%) D 0 (c) 5(a) 10(b) 15 (d) 

 

  



Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate Metal Matrix Composite  

181 

4 RESULTS AND DISCUSSIONS 

4.1 Analysis of SN Ratio for Wear Rate 

From Table 4. the input functions with higher delta values have higher ranking and have more influence on the wear 

rate. Load. MSSA, Sliding Speed and Sliding Distance. (ADBC). (MSSA). A2=4N, B2= 10cm/s C4=200m D4=15 wt%. 

The optimum wear value will be obtained from the combination of Load=4N, Sliding speed = 10cm/s sliding 

distance=200m and MSSA=15 wt%. 

The Analysis of the result shows the optimum value is in the combination of Load=4N, sliding speed = 10cm/s 

sliding distance=200m and MSSA=15 wt% These also correspond with the Analysis of wear maps & wear rate 

diagrams displayed below.  

 

Table 3: Evaluation of the impute process parameters based on based on Taguchi L16 design 

 

 A B C D 
Wear rate 

(mm
3
/N/M) 

Sample Load (N) Sliding speed (cm/s) Sliding distance (m) MSSA Reinforcement (wt%) 

C1 2 5 50 0 0.04499 

A2 2 10 100 5 0.02248 

B3 2 15 150 10 0.01538 

D4 2 20 200 15 0.02036 

B5 4 5 100 10 0.03131 

D6 4 10 50 15 0.01348 

C7 4 15 200 0 0.01783 

A8 4 20 150 5 0.02371 

D9 6 5 150 15 0.01788 

B10 6 10 200 10 0.01628 

A11 6 15 50 5 0.05062 

C12 6 20 100 0 0.03671 

A13 8 5 200 5 0.01318 

C14 8 10 150 0 0.01614 

D15 8 15 100 15 0.02452 

B16 8 20 50 10 0.04225 

D17 4 1O 200 15 0.01532 

 

 

 
 

Figure 3: The SN ratio for the data means load, sliding speed, sliding distance and the mango seed shell ash  



Ochuokpa et al. (2021). International Journal of Engineering Materials and Manufacture, 6(3), 176-186. 

182 

Table 4: Analysis of SN ratio for wear rate 

 

Input function Symbols 

S/N Ratio 

Max-Min (delta) Rank 

L1 L2 L3 L4 

Load A 32.5 33.8 31.5 33.5 2.3 4 

S/S B 32.4 35.5 32.2 30.5 5 2 

S/D C 29.5 31.0 35.1 35.8 6.3 1 

MSSA D 31.2 32.0 32.1 34.9 3.7 3 

 

A= Load (N) B=sliding speed (cm/s) C= sliding distance (M) D= Mango Seed Shell Ash Wt% 

 

 

4.2 Analysis of Wear Maps & Wear Rate 

 

Sliding distance (M)

lo
ad

  (
N

)

2001 751 501 251 007550

8

7

6

5

4

3

2

>  

–  

–  

–  

<  0.02

0.02 0.03

0.03 0.04

0.04 0.05

0.05

Wear rate

Contour Plot of Wear rate vs load  (N), Sliding distance (M)

 

 

Figure 4: Wear Map 1 shows the lowest wear rate at sliding distance, 200m/s and the load of 4N 

 

 

MSSA

Sl
id

in
g 

sp
ee

d 
(c

m
/s

)

1 41 21 086420

20.0

1 7.5

1 5.0

1 2.5

1 0.0

7.5

5.0

>  

–  

–  

–  

<  0.02

0.02 0.03

0.03 0.04

0.04 0.05

0.05

Wear rate

Contour Plot of Wear rate vs Sliding speed (cm/s), MSSA

 
 

Figure 5: Wear Map 2 shows the lowest wear rate at sliding speed of 10cm/s and 15 wt% MSSA  



Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate Metal Matrix Composite  

183 

Sliding distance (M)

Sl
id

in
g 

sp
ee

d 
(c

m
/s

)

2001 751 501 251 007550

20.0

1 7.5

1 5.0

1 2.5

1 0.0

7.5

5.0

>  

–  

–  

–  

<  0.02

0.02 0.03

0.03 0.04

0.04 0.05

0.05

Wear rate

Contour Plot of Wear rate vs Sliding speed (c, Sliding distance

 

 

Figure 6: Wear Map 3 shows the lowest wear rate at sliding speed, 10cm/s and sliding distance, 200m. 

 

 

4.3 Morphology of Mango Seed Shell Ash (MSSA) 

Table 5 shows the result of X- ray fluorescent (XRF) pattern of mango shell ash (MSSA) which reveals that SiO2, has 

the highest percentage composition followed by CaO, Al2O3, Fe2O3, Mg2O, K2O, ZnO, Na2O and TiO2, as major 

phases. The presences of these hard constituent compounds suggests that the mango seed shell ash can be used as 

particulate reinforcement in various metal matrices since the chemical composition has similarity with the XRF analysis 

of Periwinkle shell ash, rice husk, fly ash, and bagasse ash currently used in metal matrix composite. Amaren & Aku 

[17], Aigbodion, and Hassan [1]. Si and Mg, enhances wettability and formation of Mg2Si and eutectic Si α-Al matrix 
with MSSA particles. Therefore, they are attractive material for reinforcement of AMC for wear applications. 

 

4.4 Characterize of the Convectional Motorcycle Hub 

Table 6 shows the XRF pattern and elemental Composition of the convectional motorcycle hub. It reveals Al2O3, 

SiO2, Fe2O3 and Mgo as major phases. The elemental composition of silicon content is 6. 55 wt% as reflected in Table 

6. This is below the standard requirement for the Aluminium Alloy 356 (7% Si) which is the popular   alloy used for 

sand casting. This may account for the frequent wear and failure of the conventional Motorcycle Hub. The addition 

of MSSA which has content of silicon as particulate composite reinforcement may help address the problem of wear 

of the conventional motorcycle hub. 

 

4.5 Hardness Test 

Hardness values of Al-Si-Mg/ MSSA particulate composite with various percentage weight of MSSA loading is shown 

in Table 7. There is increasing trend of hardness strength with increase in weight percentage of MSSA up to 15% 

weight fraction. Beyond this weight fraction the hardness trend started decreasing as MSSA particles interact with 

each other leading to clustering of particles and consequently settling down. It is observed that the unreinforced alloy 

has the least hardness value of 31.9 HV while at 15% MSSA addition had the highest hardness value of 43.2 HV. This 

represents a 26.16% improvement over the convectional alloy. This indicates that there was good interfacial bonding 

between the matrix and the reinforcement.  

Therefore, the optimized 15% wt of MSSA reinforcement which has the best mechanical properties was selected 

for production of the hub. The increase in hardness is due to the presence of silicon particles formed because of 

reaction between the reinforcement MSSA particles and the molten Al- alloy matrix as well as other processing 

parameters. Factors such as non-uniform distribution of particles, cooling rate of the casting has affected the hardness 

value negatively hence there is no uniform hardness.  

The result of impact energy of Al-Si-Mg/ MSSA particulate composite with various percentage weight of MSSA 

loading is shown in Table4.4. It is observed that the impact energy is lowest at 5% MSSA while at 15% MSSA addition 

had the highest hardness value of impact energy This indicates that there was good interfacial bonding between the 

matrix and the reinforcement. Beyond this weight fraction the impact energy trend started decreasing as MSSA 

particles interact with each other leading to clustering of particles and consequently settling down.  

  



Ochuokpa et al. (2021). International Journal of Engineering Materials and Manufacture, 6(3), 176-186. 

184 

Table 5: Elemental Composition of MSSA using (XRF) 

 

S/NO ELEMENT Concentration of oxide (wt%). Elemental composition (wt%) 

1 Na20 2.302 1.708 

2 MgO 3.173 1.904 

3 Al2O3 13.847 7.331 

4 SiO2 43.574 20.334 

5 P2O5 4.173 1.854 

6 SO3 1.797 0.719 

7 Cl 0.467 0.464 

8 K2O 4.559 3.783 

9 CaO 14.895 10.639 

10 Tio2 2.129 1.277 

11 Cr2O3 0.005 0.003 

12 Mn2O3 0.130 0.091 

13 Fe2O3 6.211 4.348 

14 ZnO 2.653 2.129 

15 SrO 0.089 0.075 

 

Table 6: Elemental Composition of Sample (motorcycle hub) using (XRF) 

 

S/NO ELEMENT Concentration of oxide (wt%) Converted to Element (wt%) 

1 Na20 0.419 0.310 

2 MgO 1.014 0.608 

3 Al2O3 82.117 43.474 

4 SiO2 14.034 6. 55 

5 P2O5 0.000 0.053 

6 SO3 0.133 0.455 

7 Cl 0.013 0.017 

8 K2O 0.024 0.089 

9 CaO 0.124 0.03 

10 Tio2 0.050 0.018 

11 Cr2O3 0.026 0.115 

12 Mn2O3 0.165 0.801 

13 Fe2O3 1.144 0.59 

14 ZnO 0.736 47.323 

15 SrO 0.000 0.00 

 

Table 7: Variation of hardness property of the composite 

 

% MSSA Hardness Value (HV) 

Control C 0% MSSA 31.9 

A 5% MSSA 33.63 

B 10% MSSA 42.9 

D 15% MSSA 43.2 

E 20% MSSA 36.5 



Development of Aluminium Based Mango Seed Mangiferaindica Shell Ash (MSSA) Particulate Metal Matrix Composite  

185 

Table 8: Impact test results 

 

Samples Diameter (mm) Notch (mm) 
Energy 

(Ib. pounds) 

Average En 

(pounds) 

Average 

(Joules) 

Control C. 0% 

MSSA 

10.3 

10.4 

10.0 

9.8 

9.4 

9.3 

2.2 

1.3 

1.5 

1.66 2.251 

A. 5% MSSA 

10.0 

10.3 

10.5 

9.0 

9.4 

9.7 

0.5 

1.5 

1.0 

1.0 1.356 

B 10% MSSA 

10.5 

10.5 

10.2 

9.9 

10.0 

9.6 

1.6 

2.0 

1.5 

1.7 2.305 

D 15% MSSA 

10.4 

9.8 

10.4 

9.8xvvg 

9.7 

9.6 

2.0 

1.5 

1.9 

1.80 2.440 

E 20% MSSA 

10.0 

10.0 

10.0 

9.3 

9.0 

9.4 

1.3 

1.0 

1.0 

1.1 1.491 

1Ib = 1.356J 

 

 

5 CONCLUSIONS 

The following conclusions can be drawn: 

 

1. The result of XRF pattern of mango shell ash reveals the presence of hard constituent compounds like SiO2, CaO, 

Al2O3, Fe2O3, Mg2O. This suggests the possibility of mango seed shell ash particulate in metal matrix composite 

since the chemical composition has similarity with the XRF analysis of rice husk, fly ash, and bagasse ash currently 

used in metal matrix composite. 

2. Addition of Mango Shall Ash particles to a conventional Al alloy used for production of motorcycle has resulted 

in micro-structural changes, it shows an increase of 26.16% hardness value over the as- cast Al-Si-Mg alloy used 

for conventional motorcycle hub which confirms that it can be used as a reinforcement material for Aluminium 

matrix composite. 

3. The optimum hardness value was obtained at 15% wt of MSSA as particulate reinforcement, Similarly, the wear 

rate of the alloy was significantly improved at 15% wt of MSSA, load of 4N, Sliding speed = 10cm/s sliding 

distance=200m. 

4. By these results, it can be concluded that Mango Seed Shell Ash can be successfully added at 15wt% as 

reinforcement to Al-Si-Mg alloy for Production of Motorcycle hub hence providing the desired light weight, good 

mechanical, tribological and wear resistant properties and reducing the environmental problems created by them. 

 

 

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https://doi.org/10.1155/2017/6315613