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CHEMICAL ENGINEERINGTRANSACTIONS 
 

VOL. 55, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors:Tichun Wang, Hongyang Zhang, Lei Tian
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN978-88-95608-46-4; ISSN 2283-9216 

Chemical Analysis of the Mechanical Properties of Aluminum 
Magnesium Alloy Badminton Racket under Heat Treatment 

Zhou Su 

Northwest University of Politics & Law, China 
suzhou2006@gmail.com 

At present, the pursuit of light weight and high strength of badminton racket has promoted the vigorous 
development of new badminton rackets materials and related research. Magnesium alloys, as the lightest 
metal structural materials, have been studied and applied to the new badminton rackets materials in recent 
years. This paper explores the effect of different heat treatment processes on mechanical properties after the 
new type Mg-4Al-2Si alloy badminton rackets materials is heat processed. It provides theoretical basis and 
technical support for the design, manufacture and selection of new type magnesium alloy badminton rackets. 

1. Introduction  
In recent years, badminton has been developed rapidly and widely in our country. The requirements of a light 
weight and high strength has promoted the development of new badminton racket materials and related 
research. The badminton rackets in different material not only have different responses to the force and speed 
of the ball, but also have great difference in the mechanical property of the rackets. Magnesium alloy, as the 
lightest metal material, has the advantages of high specific strength, stiffness, dimensional stability, good 
shock absorption and easy recovery, known as "the twenty-first Century green project metal structure 
materials (Fan, et al., 2014). It has a broad application prospect in the automotive, aerospace and other fields, 
and in recent years, it is also applied to new badminton rackets material. 
The effects of different heat treatment processes on the mechanical properties of the alloy are discussed in 
this paper, which provides theoretical basis and technical support for the design, manufacture and selection of 
new type magnesium alloy badminton rackets. 

2. An overview of magnesium alloy materials  
2.1 Characteristics of magnesium alloys 
The texture of pure magnesium is soft, not suitable for taking as a structural material to be directly used. By 
adding alloying elements, it can significantly improve and optimize the performance of magnesium (Feng, et 
al., 2014). In consequence, in the engineering application, it often appears as magnesium alloy. According to 
the actual needs, people have designed a series of magnesium alloy, and they usually have the following 
characteristics: 
(1)Light weight, high specific strength and high stiffness: magnesium alloy is the lightest structural material up 
to now, and its specific strength is the highest among the commonly used structural materials (Gzyl, et al., 
2015). Since that the magnesium alloy strength and stiffness ratio are significantly higher than those of 
aluminum, and compared with engineering plastics, it has high elastic modulus, stiffness and dimensional 
stability, making magnesium alloy become important materials in the development of lightweight (Mao, et al., 
2015). 
(2) High thermal conductivity, low thermal capacity, easy machining, and good casting performance (Min, et al., 
2014): this characteristic of magnesium alloy makes the magnesium alloy processing cost low, and it can be 
cast into complicated thin-walled components close to the size of the cost. 
(3) The magnesium alloy has strong ability to absorb the energy of the plastic deformation, and the fatigue 
resistant ability is better (Nasruddin, et al., 2016): magnesium alloy has strong absorption ability on the 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1655042

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Su Z., 2016, Chemical analysis of the mechanical properties of aluminum magnesium alloy badminton racket under 
heat treatment, Chemical Engineering Transactions, 55, 247-252  DOI:10.3303/CET1655042   

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mechanical oscillation, and it can resist fatigue, so the magnesium alloy can be applied in the occasions under 
high load effect and those require high security. 
(4) Magnesium alloy itself is not magnetic. It has good electromagnetic shielding, and the electrode potential is 
very negative. 
(5) The toxicity of magnesium alloy is very low, and it can be recycled (Oliveira, et al., 2014). This 
characteristic is beneficial to the sustainable development of economy, and cannot produce the strong toxic 
material pollution environment in the process of recycling. 

2.2 Heat treatment of magnesium alloy 
The mechanical and technological properties of magnesium alloys can be improved by heat treatment. Heat 
treatment of magnesium alloy generally adopts two methods, solid solution aging or annealing. In order to 
reduce the casting stress or quenching stress of the alloy, the annealing method is generally adopted, which is 
helpful to improve the dimensional stability of the work-piece. Only the alloy elements in the solid solubility 
change with temperature can heat treatment strengthen the role of the alloy (Phomsoupha, et al., 2015). The 
recent research results show that the solid solubility of alloying elements of most magnesium in magnesium 
alloys will change with temperature change, so most of magnesium alloy can be strengthened by heat 
treatment. 
According to the type of alloying elements in magnesium alloy, in the magnesium alloy, there are 6 series that 
can be strengthened by heat treatment, namely Mg-Al-Mn (such as AM100A), Mg-Al-Zn (such as AZ63A, 
AZ81A, AZ91C and AZ92A), Mg-Zn-Ar (such as ZK51A and ZK61A) and Mg-RE-Zn-Zr (such as EZ33A and 
ZE41A), Mg-Ag-RE-Zr (such as QE22A) and Mg-Zn-Cu (such as ZC63A); in the wrought magnesium alloy, 
there are 3 series that can be strengthened by heat treatment, namely Mg-Al-Zn (such as AZ80A), Mg-Zn-Zr 
(ZK60A) and Mg-Zn-Cu (such as ZC71A) (Sun and Wang, 2014). Heat treatment hardening does not have 
obvious effect on all heat treatments of magnesium alloy, then can use annealing as the final heat treatment 
method, and thus strengthen the strengthening effect of heat treatment on magnesium alloy. 
During the process of heat treatment, the alloy phase decomposition and the diffusion of the alloying elements 
are extremely slow, so the heat treatment process of the magnesium alloy has the following two 
characteristics: 
(1) Solid solution aging treatment time is relatively long, which is the most important characteristics of the heat 
treatment of magnesium alloy. 
(2) After the quenching, the magnesium alloy work-piece is usually cool in the natural environment, it also can 
help it cool with artificial manufacturing flow air. Generally, do not need to quickly cool the work-piece. 

3. Experimental method  
3.1Sample preparation 
The nominal compositions of Mg-4Al-2Si alloy are Al 4.0 and Si 2.0, and the rest is Mg. Industrial specialized 
protection agent is used in alloy SG2-5-10 type well crucible furnace, to make ɸ50 mm * 120 mm ingot. The 
ingots are homogenized; the craft is to keep warm at 420 Deg. C for 12h. In the 3150kN hydraulic press, make 
use of special mold for reciprocating extrusion of the casting samples. The alloy material is carried out with 2 
times, 4 times and 6 times of reciprocating extrusion (The materials, through the times of the core, are defined 
as the number of reciprocating extrusion), to prepare the extruded samples. 

3.2 Heat treatment 
Solid solution treatment and aging treatment are carried out for 6 times reciprocating extrusion samples. 
(1) solid solution treatment (4 schemes): to keep warm at 420 DEG C for 4h, water-cooled; to keep warm at 
420 DEG C for 8h, water-cooled; to keep warm at 420 DEG C for 12h, water-cooled; to keep warm at 420 
DEG C for 16h, water-cooled (Suttner, 2016). 
(2) solid solution + aging treatment (4 scheme): to keep warm at 420 DEG C for 12h, water-cooled +100 DEG, 
2h; to keep warm at 420 DEG C for 12h, water-cooled +150 DEG for 2h; to keep warm at 420 DEG C for 12h, 
water-cooled +200 DEG C for 2h; to keep warm at 420 DEG C for 12h, water-cooled +250 DEG C for 2h. 

3.3 Organization observation and performance test 
Etching agent is 60mL ethanol, 20mL acetic acid, 19mL H2O and 1mL HNO3; micro-structure observation is 
carried out in Olympus optical microscope; phase analysis is carried out in XRD-7000S type X ray 
diffractometer; hardness testing is carried out in HV-120 Vivtorinox hardness; tensile test is carried out in the 
electronic universal tensile machine; fracture morphology is observed by JSM-6700F scanning electron 
microscope; TEM observation is carried out in Nissan JEM-3010 transmission electron microscope (Tian, et 
al., 2015). 

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4. Experiment results and discussion 
4.1 Micro-structure of heat treated alloy 
Figure 1 shows the micro-structure of heat treated alloy after reciprocating extrusion. According to XRD 
analysis, it is known that the alloy structure of the solid solution treatment after reciprocating extrusion is 
composed of α(Mg) matrix, β(Mg17Al12) phase and Mg2Si phase. This suggests that in the 420 DEG heat 
insulation for 12h water-cooled solid solution treatment, the β(Mg17Al12) phase is only partially dissolved 
(Zhang, et al., 2015). 
After solid solution treatment and solution treatment + aging treatment, the morphology and size of Mg2Si 
phase have no obvious change, which shows that Mg2Si phase has higher thermal stability, as shown in 
Figure 1 (a), (b), (c). 
 Reciprocating extrusion and solid solution treatment state after reciprocating extrusion, the grain size of the 
α(Mg) matrix is small, the size is not obviously different, and the grain size is coarse after the solid solution 
and aging treatment, as shown in Figure 1 (b), (c). 
 

(a) 420℃×12h (b) 420℃×12h+100℃×2h (c) 420℃×12h+250℃×2h  

Figure 1: The micro-structure of heat treatment state after Mg-4Al-2Si alloy reciprocating extrusion 

4.2 Mechanical properties of extruded alloy after heat treatment 
Figure 2 to Figure 6 show the relationship curves between the extruded aluminum alloy heat treatment and 
mechanical properties; by Figure 2 and Figure 3, it shows that the hardness of the alloy decreases by solid 
solution treatment and aging treatment, and when the solid solution is 420 DEG C * 12h, the hardness is the 
lowest, 58 HV; the hardness of the alloy also decreases by solid solution and aging treatment, and when the 
solid solution is 420 DEG C * 12h and aging is 250 DEG C * 2h, the hardness is the lowest, 57HV. 

-2 0 2 4 6 8 10 12 14 16 18
55

60

65

70

75

80

H
or

dn
es

s(
H

V
)

Time/s

Squeezed state

 

Figure 2: The effect of solid solution treatment time on alloy hardness 

249



0 50 100 150 200 250
55

60

65

70

75

80

H
or

dn
es

s(
H

V
)

Temperature/℃

Squeezed state

 

Figure 3: The impact of aging temperature on alloy hardness 

From Figure 4, it is seen that, after 420 DEG C solution treatment, the tensile strength and yield strength of 
the alloy decrease, and the tensile strength and yield strength of the alloy decrease to 217MPa and 205MPa, 
respectively, when the keep warm for 16h. From Figure 5, it is seen that, the elongation of the alloy during the 
solid solution treatment of thermal insulation for 4h is the maximum, which is 28.6%; the elongation at 8h is 
the lowest, which is 13% (Wen and Ji, 2014). Figure 6 shows the relationship between aging temperature and 
alloy strength. Obviously, the tensile strength and yield strength of the alloy decrease at 420 DEG C * 12h and 
aging treatment. The tensile strength is lowest at 200 DEG C, which is 195MPa; the yield strength is the 
lowest at 100 DEG C, which is 205MPa. 

-2 0 2 4 6 8 10 12 14 16 18
200

210

220

230

240

250

260 Squeezed state

St
re

ng
th

/M
pa

 σ
b

 σ
0.2

 

Figure 4: The influence of solution treatment time on alloy strength 

250



-2 0 2 4 6 8 10 12 14 16 18

12

14

16

18

20

22

24

26

28

30

Squeezed state

E
lo

ng
at

io
n/

%

 

Figure 5: The effect of solid solution treatment time on the tensile strength 

0 50 100 150 200 250

160

180

200

220

240

260 Squeezed state

St
re

ng
th

/M
pa

σ
b

 σ
0.2

 

Figure 6: The impact of aging temperature on the alloy strength 

In the Mg-Nd-Zr hot extrusion state alloy, there are a lot of dislocation sub-grains, and after the solid solution + 
aging treatment, the sub-grains disappear, replaced by a small amount of straight dislocation lines. It shows 
that the crystal grain has grown up after high temperature treatment. In the research in this paper, there is no 
obvious growth found in the grain after solution treatment, but the yield strength decreases from 260MPa to 
205MPa after the solution treatment, which indicates that the grains also grow (Zhao, et al., 2015). This study 
shows that the grain size grows after aging treatment. Coarse grains have a serious impact on the mechanical 
properties of the materials. Because the effect of aging hardening is relatively weak, and the negative effect of 
coarse grain is more significant, the strength and plasticity of the alloy decrease. 

5. Conclusion  
(1) Solid solution treatment and solution treatment and aging treatment reduce the hardness of Mg-4Al-2Si 
alloy. Alloy after solution treatment, the tensile strength and yield strength decrease, and the elongation is the 
maximum; after solid solution and aging treatment, the crystal grain obviously grows; the tensile strength 
decreases, the yield strength decreases, and the elongation of the material decreases rapidly. 
(2) The fracture form of the solid solution treated extruded alloy is ductile fracture, and the fracture form of the 
extruded alloy after solid solution and aging treatment is brittle fracture. 

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