DESIGNING AND FABRICATION OF RACKET TEST RIG.
SURAJ s/o VIJANATHAN
Report submitted in partial fulfillment of the requirements for the award of
Diploma of Mechanical Engineering
Faculty of Mechanical Engineering
UNIVERSITI MALAYSIA PAHANG
JUNE 2013
vi
ABSTRACT
This thesis deals with the designing and fabrication of racket test rig. Test rig is a useful
device as it is an apparatus used for assessing the performance of a piece of mechanical
equipment. The main objective of this final year project is to design and fabricate a
racket test rig for further study of the performance of a racket. This thesis describes the
methods of designing and fabricating the mechanical part of the test rig. There are many
steps taken to design and fabricate the mechanical parts of this test rig. The structural
three-dimensional solid modeling of the test rig was developed by using the SolidWorks
engineering drawing software. The fabrication process also undergoes many steps such
as material marking, cutting, drilling, welding, milling, turning, grinding and finishing
of the test rig by painting. The results of the testing of the performance of racket and
how far the shuttlecock can reach with certain applied force and angle on the racket also
discussed in this thesis.
vii
ABSTRAK
Tesis ini membincangkan tentang mereka bentuk dan fabrikasi pelantar ujian raket.
Pelantar ujian adalah alat yang berguna kerana ia adalah satu alat yang digunakan untuk
menilai prestasi sebuah peralatan mekanikal. Objektif utama projek tahun akhir ini
adalah, untuk mereka bentuk dan memfabrikasikan suatu pelantar ujian raket untuk
kajian selanjutnya tentang prestasi raket. Tesis ini juga menerangkan kaedah mereka
bentuk dan pembuatan setiap bahagian mekanikal pelantar ujian tersebut. Terdapat
beberapa langkah yang diambil untuk mereka bentuk dan membuat bahagian-bahagian
mekanikal pelantar ujian ini. Pemodelan tiga dimensi struktur pelantar ujian telah dibuat
dengan menggunakan SolidWorks yang merupakan perisian lukisan kejuruteraan.
Proses fabrikasi juga mengalami banyak langkah seperti menanda, memotong,
penggerudian, kimpalan, “milling”, “turning”, pengisaran dan kemasan pelantar ujian
dengan cat. Keputusan ujian prestasi raket dengan sejauh bulu boleh mencapai dengan
kuasa tertentu digunakan dan sudut pada raket juga dibincangkan dalam tesis ini.
viii
TABLE OF CONTENT
Page
SUPERVISOR’S DECLARATION ii
STUDENT’S DECLARATION iii
DEDICATION iv
ACKNOWLEDGEMENT v
ABSTRACT vi
ABSTRAK vii
TABLE OF CONTENT viii
LIST OF TABLES xiii
LIST OF FIGURES xiv
LIST OF SYMBOLS xvii
LIST OF ABBREVATIONS xviii
ix
CHAPTER 1 INTRODUCTION 1
1.1 Introduction 1
1.2 Problem Statement 2
1.3 Objective 2
1.4 Project Scope 3
CHAPTER 2 LITERATURE REVIEWS 4
2.1 Introduction 4
2.2 Types of Racket Test Rig 5
2.2.1 Rebound Impact Testing Machine 5
2.2.2 Racket Pressure Tester 7
2.2.3 Racket Twisting Strength Tester 8
2.2.4 Racket Drop Tester 9
2.3 Types of Materials Used In This Project 11
2.3.1 Stainless Steel 11
2.3.2 Mild Steel 12
2.3.3 Sheet Metal 13
2.4 The Fabrication Method 14
2.4.1 Grinding (Cutting) 14
2.4.2 Welding 15
2.4.3 Shearing 16
2.4.4 Bending 18
2.4.5 Drilling 19
x
2.4.6 Milling 20
2.4.7 Lathe (Turning) 21
2.4.8 Finishing 22
CHAPTER 3 METHODOLOGY 23
3.1 Introduction 23
3.2 Flowchart 24
3.3 Concept Generation 27
3.3.1 Concept Design No.1 27
3.3.2 Concept Design No.2 28
3.3.3 Concept Design No.3 29
3.4 Concept Scoring 30
3.5 Concept Finalization 31
3.5.1 Control Box 32
3.5.2 Racket Holding Arm 32
3.5.3 The Static Body and Adjustable Body 33
3.5.4 The Base 33
3.6 List of Materials 34
3.7 Fabrication Planning 35
3.7.1 Measuring and Marking Process 35
3.7.2 Cutting Process 36
3.7.3 Drilling Process 37
xi
3.7.4 Welding Process 37
3.7.5 Riveting and Bending 38
3.7.6 Milling Process 39
3.7.7 Turning Process 39
3.7.8 Grinding and Coating Process 40
CHAPTER 4 RESULTS AND DISCUSSION 41
4.1 Introduction 41
4.2 Final Product 42
4.2.1 Overview of Product 42
4.2.2 Overview of Control Box and Spring System 43
4.2.3 Overview of the Body 44
4.2.4 Overview of the Arm 45
4.2.5 Overview of the Base 45
4.3 Result 46
4.3.1 Hitting Test 46
4.4 Problems 47
4.4.1 Problems Faced During Progressing the Project 47
4.4.3 Problems At The Racket Test Rig 48
xii
CHAPTER 5 CONCLUSION AND RECOMMENDATION 49
5.1 Introduction 49
5.2 Conclusion 50
5.3 Recommendation 51
REFERENCES 52
APPENDICES 53
A Figures of machines 53
B Personal protective equipment 57
C Figures of Drawing Each Part 59
xiii
LIST OF TABLES
Table No. Page
2.1 Specification of Racket Twisting Strength Tester 8
2.2 Specification of Racket Drop Tester 10
3.1 Gantt Chart 27
3.2 Concept Scoring 31
3.3 Material List 35
4.1 Hitting Results for Method 1 46
4.2 Hitting Results for Method 2 46
xiv
LIST OF FIGURES
Figure No. Page
2.1 Parts of a Badminton Racket 5
2.2 Feather Bat and Net Bat Rebound Impact Testing Machine 6
2.3 Racket Pressure Tester 7
2.4 Racket Twisting Strength Tester 9
2.5 Racket Drop Test 10
2.6 Stainless Steel 11
2.7 Mild Steel 12
2.8 Aluminum Sheet Metal 13
2.9 Grinding Cutting Process 15
2.10 Welding Process 16
2.11 Shearing Process 17
2.12 Shearing Machine 17
2.13 Schematic of Air Bending with a Back Gauge 18
2.14 Drilling Process 19
2.15 Vertical Milling Machine 20
2.16 Lathe Machine 21
2.17 Hand Grinder 22
2.18 Spray Paint 22
3.1 Process Flowchart 24
3.2 Design Concept 1 27
xv
3.3 Design Concept 2 28
3.4 Design Concept 3 29
3.5 3D Concept Design 3 31
3.6 Control Box 32
3.7 Racket Holding Arm 32
3.8 Static Body 33
3.9 Adjustable Body 33
3.10 The Base 33
3.11 Measuring Material 35
3.12 Marking Material 35
3.13 Cutting Material 36
3.14 Grinding Cutting 36
3.15 Shearing Process 36
3.16 Drilling Process 37
3.17 Welding Process 38
3.18 Riveting Process 38
3.19 Bending Process 38
3.20 Milling Process 39
3.21 Turning Process 40
3.22 Grinding Process 40
3.23 Coating Process 40
4.1 Overview of the Racket Test Rig 42
xvi
4.2 Control Box 43
4.3 Spring System 43
4.4 The Body 44
4.5 Method 1 Arm 45
4.6 Method 2 Arm 45
4.7 The Base 45
xvii
LIST OF SYMBOLS
Kg Kilogram
m Meter
MPa Megapascals
Rpm rotation per minute
mm Milimeter
Ø Diameter
R Radius
Psi pounds per square inch
d diameter
Pi (3.1242)
xviii
LIST OF ABBREVIATION
UMP Universiti Malaysia Pahang
MASUM Majlis Sukan Universiti Malaysia
SMAW Shielded Metal Arc Welding
GMAW Gas Metal Arc Welding
MIG Metal Inert Gas
PPE Personal Protective Equipment
3D Three Dimension
CHAPTER 1
INTRODUCTION
1.1.1 INTRODUCTION
A racket or racquet is a sports implement consisting of a handled frame with an
open hoop across which a network of cord is stretched tightly. It is used for striking
a ball in such games as squash, tennis, racquetball, and badminton. Collectively, these
games are known as racquet sports.
The frame of rackets for all sports was traditionally made of laminated wood and
the strings of animal intestine known as catgut. The traditional racket size was limited by
the strength and weight of the wooden frame which had to be strong enough to hold the
strings and stiff enough to hit the ball or shuttle. Manufacturers started adding non-wood
laminates to wood rackets to improve stiffness. Non-wood rackets were made first of steel,
then of aluminum, and then carbon fiber composites. Wood is still used for real
tennis, rackets, and xare. Most rackets are now made of composite materials
including carbon fiber, fiberglass, metals such as titanium alloys or ceramics. Gut has
partially been replaced with synthetic materials including nylon, polyamide, and other
polymers. Rackets are restrung when necessary, which may be after every match for a
professional or never for a social player.
A racket base game is mostly just the same where we should hit the object coming
towards us with the racket. In my project I focused more into the swinging hitting method
as most of the racket game r played by swinging to hit the object.
2
1.2 PROBLEM STATEMENT
Many of the existing racket test rig doesn’t have any machine that tests a racket by using a
swinging method. Most of the machine built is to test the string band of the racket and also
the strength of the racket itself. Plus it is hard to determine the actual hitting power of the
racket without using the swinging method. The reason is that during any racket game is
played the will be an error where the players will hit the object such as the shuttlecock with
the frame of the racket.
1.3 OBJECTIVE
From the problem statement an objective had had been done which is to design and
fabricate a racket test rig that can test the hitting force, angle and the distance of the
shuttlecock after hitting from the racket by using swinging method.
3
1.4 PROJECT SCOPE
i. To design 3D racket test rig by using SolidWorks.
ii. Material used for the design:
iii. To fabricate a portable racket test rig by using materials such as stainless steel
(round hollow & metal sheet) , aluminum (solid &metal sheet) , and mild steel
(square hollow)
iv. To fabricate an adjustable height, angle and force for the racket test rig.
CHAPTER 2
LITERATURE REVIEWS
2.1 INTRODUCTION
The title “Designing & Fabricating Racket Test Rig” requires an amount of good
understanding on the knowledge of types of rackets especially badminton racket as it
has been the main reason for this project. Therefore, executing a research is necessary to
obtain all the relevant and useful information that are available and related to this
project. The information or literature reviews obtained are essentially valuable to assist
in the fabrication and specification of this final year project. With this ground
established, the project can be accomplished with guidance in achieving the target mark.
In the same view, swinging method is a method that use in most racket based games
to play. For example in badminton sports, the racket is swing by the player to hit the
object (shuttlecock) that coming towards him so that the object can go back to the
opposite direction with the impact of collision cause between the object and the racket.
This also happens in other racket based sports such as tennis, squash and ping pong.
Figure 2.1 shows the parts of a racket badminton.
5
Figure 2.1: Parts of a badminton racket
Source: www.badminton-information.com
2.2 TYPES OF EXISTING RACKET TEST RIG.
2.2.1 Rebound Impact Testing Machine (ZME-1601)
Feather bat and net bat rebound impact testing machine is mainly use for
badminton and tennis racket rebound test. It is also an ideal tester to produce result on
the impact that occurs between the string band of the racket and the shot towards it such
as shuttlecock or tennis ball. The shooting speed of this machine can go up to a
maximum hitting speed of 200km/h. This machine is expensive due to the sensors, air
compressor and more. The price of this rebound impact testing machine can cost from
US $200 and up to US$ 5,000 per set based on the specification that we require.
This machine functions by clamping the head of the racket at the clamping area
and the specific object such as the shuttlecock or a tennis ball to be shot is put in to the
6
launching area. The air is compressed by the air compressor and we can set the hitting
speed of the object towards the stringed area of the racket.
With a push of a single button at the control box the object will be shot
towards the racket and the sensors will take the reading of the impact and show at the
screen located at the control box. Figure 2.2 shows the rebound impact testing machine.
Figure 2.2: Feather Bat And Net Bat Rebound Impact Testing Machine (ZME-1601)
Source: http://www.gotech.biz
7
2.2.2 Racket Pressure Tester (ZME-1602)
This Racket Pressure Tester (ZME-1602) is a machine used to test the loading
force applied on the racket. Other than that, this machine also functions to test the
deformation range and ratio of the racket itself when pressure is applied on it. Plus, this
racket pressure tester machine is mainly used for inspecting the deformation of net bat
when it is set on the pivot point and then the force or pressure is applied with a constant
speed. The speed of the pressure applying arm set from 0mm and up to 1000 mm/min.
The force applying arm can travel from 0mm to 300mm with a range of punch tip of
φ20 × 470 mm. This machine weigh 100kg and it is not a moveable machine. The price
is also expensive where it can cost from US$ 200 to US$ 5000 based on the
specification or function that we require.
Racket pressure tester function by putting the racket the table and set the
travelling distance of the pressure applying arm. The travelling speed need to be set
within the suggested range. The pressure applying arm will move upwards n downwards
with a constant speed as we set it before at the controlling box. The reading of the
loading force applied on the racket will be printed out by a printer located next to the
controlling box. The reading of pressure applied is determined by the pressure applying
arm where it will take the reading of the force that opposes it cause by the racket. Figure
2.3 shows the racket pressure tester.
Figure 2.3: Racket Pressure Tester (ZME-1602)
Source: http://www.gotech.biz
8
2.2.3 Racket Twisting Strength Tester (GT-7074- AD)
This machine is designed to determine the resistance of badminton racket and
tennis racket to twist. A racket is tested in such a manner that the handle is fixed and a
given torsion or torsion angle is applied. The torsion sensor detects the torsion and the
rotary encoder detects the angle. Together with the U25 controller, it returns to the zero
point to check the damage of the racket. Figure 2.4 shows the machine.
This machine uses the accurate torsion sensor and rotary encoder to accurately
detect the torsion and rotation angle. The U25 controller is used for controlling the test
system so that you can set test conditions as you wish. It is convenient to clamp the
specimen. The torsion speed can be set to a given range, and the torsion direction can be
set based on your test requirements. Table 2.1 shows the features and specification of
racket twisting strength tester.
Table 2.1: Features and Specification of GT-7074-AD Racket Twisting Strength Tester
Source: http://www.gotech.biz
Features Specifications
Indicator U25 (can display torsion , angle,
rotation rate of angle)
Capacity 100 N
Max. torsion angle ±35°
Torsion speed 90~180 °/min
Angle resolution 0.1°
Force resolution 1/50,000
Distance between the clamped position 110±5mm
and the head of the racket frame
Dimension (W × D × H)160×60×106 cm
Weight 103 kg
Power 1∮ , AC 220V, 50/60 Hz
(Specified by user)
9
Figure 2.4: Racket Twisting Strength Tester (GT-7074-AD )
Source: http://www.gotech.biz
2.2.4 Racket Drop Tester (GT-7066-A )
This racket drop tester machine is designed for determining the resistance of a
racket to impact. The racket handle is fixed to the clamping device. Use the
electromagnet to release the racket when the clamping device is at the top. After the
racket along with the clamping device drops naturally, examine if the frame of the
racket is damaged. The clamping device moves up and down automatically controlled
by this machine. The sensitive photoelectric sensor plus various counterweights can
meet the specified requirements. Figure 2.5 shows the machine.
The price of this test rig is in the range between US$ 600 to US$ 800. It is also a
non-moveable machine. Table 2.2 shows the features and specifications of the racket
drop tester.
10
Table 2.2: Specification of GT-7066-A Racket Drop Tester
Source: http://www.gotech.biz
Features Specifications
Test height 1800mm (from frame top to base)
Base thickness 12mm
Load 500g (Including racket)
Drop method Electromagnetic release
Dimension (W × D × H)40 × 50 ×350 cm
Weight 130 kg
Power 1∮ , AC 220V, 50/60 HZ (Specified by user)
Figure 2.5: Racket Drop Tester (GT-7066-A)
Source: http://www.gotech.biz
Top Related