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TRANSCRIPT
UNIVERSITI TEKNIKAL MALAYSIA MELAKA
DEVELOPMENT OF VISE FOR DRILLING MACHINE
This report submitted in accordance with requirement of the Universiti
Teknikal Malaysia Melaka (UTeM) for the Bachelor Degree of Manufacturing
Engineering (Manufacturing Management) with Honours.
By
MOHD ZULHILMI BIN OMAR
Faculty of Manufacturing Engineering
2009
oval
UNIVERSITI TEKNIKAL MALAYSIA MELAKA (UTeM)
BORANG PENGESAHAN STATUS TESIS*
JUDUL: DEVELOPMENT OF VISE FOR DRILLING MACHINE
SESI PENGAJIAN: 2008/2009
Saya MOHD ZULHILMI BIN OMAR
mengaku membenarkan tesis (PSM/Sarjana/Doktor Falsafah) ini disimpan di Perpustakaan Universiti Teknikal Malaysia Melaka (UTeM) dengan syarat-syarat kegunaan seperti berikut:
1. Tesis adalah hak milik Universiti Teknikal Malaysia Melaka. 2. Perpustakaan Universiti Teknikal Malaysia Melaka dibenarkan membuat salinan
untuk tujuan pengajian sahaja. 3. Perpustakaan dibenarkan membuat salinan tesis ini sebagai bahan pertukaran
antara institusi pengajian tinggi. 4. **Sila tandakan (√)
SULIT
TERHAD
TIDAK TERHAD
(Mengandungi maklumat yang berdarjah keselamatan atau kepentingan Malaysia yang termaktub di dalam
AKTA RAHSIA RASMI 1972)
(Mengandungi maklumat TERHAD yang telah ditentukan
oleh organisasi/badan di mana penyelidikan dijalankan)
(TANDATANGAN PENULIS)
Alamat Tetap: NO 12,JLN 40/10, TMN KOPERASI POLIS FASA 2, 68100, KUALA LUMPUR Tarikh: 10 APRIL 2009
Disahkan oleh:
(TANDATANGAN PENYELIA)
Cop Rasmi: Tarikh: ________________
* Tesis dimaksudkan sebagai tesis bagi Ijazah Doktor Falsafah dan Sarjana secara penyelidikan, atau disertasi bagi pengajian secara kerja kursus dan penyelidikan, atau Laporan Projek Sarjana Muda (PSM). ** Jika tesis ini SULIT atau TERHAD, sila lampirkan surat daripada pihak berkuasa/organisasi berkenaan dengan menyatakan sekali sebab dan tempoh tesis ini perlu dikelaskan sebagai SULIT atau TERHAD.
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DECLARATION
I hereby, declared this report entitled “Development of Vise for Drilling Machine” is
the results of my own research expect as cited in references
Signature : __________________________________________
Author’s Name :
Date :
APPROVAL
The report is submitted to the Faculty of Manufacturing Engineering of UTeM as a
partial fulfillment of the requirements for the degree of Bachelor of Manufacturing
Engineering (Management) with Honours. The member of the supervisory committee
is as follow:
(Signature of Supervisor)
………………………
(Official Stamp of Supervisor)
APPROVAL
The report is submitted to the Faculty of Manufacturing Engineering of UTeM as a
partial fulfillment of the requirements for the degree of Bachelor of Manufacturing
Engineering (Management) with Honours. The member of the supervisory committee
is as follow:
(Signature of Principal Supervisor)
………………………
(Official Stamp of Principal Supervisor)
(Signature of Co-Supervisor)
………………………
(Official Stamp of Co-Supervisor)
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ABSTRACT
Nowdays vise is an important thing in manufacturing industry. The usage of this vise
is to clamp workpiece in drilling machine.The vise like comprises a pair of movable
jaws arranged to move in parallel and to cooperate with a fixed jaw for holding
workpieces for machining. There are a lot of competition among machine
manufacturer but none of them can clamping the workpiece in irregular shape.The
objective of this project is to propose a solution related to the vise in clamping
irregular workpiece in drilling operation. Thus, this project covered the drilling
machine specification and problem occurred during drilling operation. In addition,
the focus of this project is to increase the performance of vise in drilling machine
usage and the system itself. However, project design can only produce the prototype
but not covered usage of material factor which used in the vise, benefit of the design
and development cost. Due to the implementation of this project, problem related to
clamping of work piece in drilling machine can be solved with an additional function
and vise performance in the industry. The solution of the problem related to surface
of workpiece during clamping of workpiece when using ordinary vise is an indication
of project can perform successfully.
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ABSTRAK
Hari ini ragum adalah benda penting dalam industri pembuatan.Salah satu
kegunaannya adalah memegang bahan kerja pada mesin gerudi. Ragum terdiri dari
satu rahang bergerak yang disusun seiring dengan rahang tetap.untuk memegang
bahan kerja pada mesin..Banyak persaigan dikalangan pembuat mesin tetapi
sehingga hari ini tiada satu pun yang boleh memegang bahan kerja yang tidak rata
secara pegangan terus. Objektif untuk projek ini adalah untuk mencadangkan
penyelesaian berkaitan dengan ragum untuk memegang bahan kerja yang tidak rata
dan berlekuk.ketika operasi menggerudi. .Oleh itu projek ini merangkumi spesifikasi
mesin gerudi dan masalah yang berlaku pada ragum ketiaka menggunakan mesin
tersebut. .Fokus projek ini adalah untuk meningkatkan keupayaan ragum pada mesin
gerudi.dari segi penggunaan dan sistemnya. Namun pada bahagian rekabentuk,
projek ini hanya menghasilkan prototaip sahaja dan tidak merangkumi faktor bahan
yang digunakan, kelebihan bentuk rekaan dan kos pembuatan.Dengan terlaksananya
projek ini, masalah yang berkaitan dengan pemegangan bahan kerja pada mesin
gerudi akan dapat diselesaikan dengan penambahan fungsi dan prestasi ragum
tersebut dalam industri pembuatan.Kejayaan projek ini juga dapat menyelesaikan
masalah kerosakan permukaan bahan kerja semasa process memegang bahan kerja
yang berlaku apabila menggunakan ragum biasa.
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DEDICATION
Thankful to Allah S.W.T for the opportunity to finish this project
Specially dedicated to
Omar Ismail,Sahara Wahid En. Shafiq Jumali, brother and sisters
who have encouraged, guided and inspired me throughout my journey of education
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ACKNOWLEDGEMENT
First of all, I would like to thank the Almighty Allah for His blessings and
His power for me to complete this Projek Sarjana Muda.
I would like to take this opportunity to express my deepest gratitude to my
project supervisor, En. Shafiq bin Jumali who has persistently and determinedly
assisted me during the whole course of this project. It would have been very difficult
to complete this project without the enthusiastic support, insight and advice given by
him.
My outmost thanks also go to my family who has given me support
throughout my academic years. I would like to thank them for understanding and
always giving me courage and the strength I need to carry on this project. Without
them, I might not be the person I am today.
It is to my advantage that I have received help and support from friends and
staffs in the Faculty of Manufacturing Engineering My special gratitude to my father
and mother for giving me amount of budget and idea to support my project. It is of
my greatest thanks and joy that I have met these people. Thank you so much.
v
TABLE OF CONTENT
Abstract i
Abstrak ii
Ancknowledgement iii
Table of Content v
List of Table viii
List of Figures ix
List Abbreviations xi
1. INTRODUCTION 1
1.1 Background 1
1.2 Problems Statement 2
1.3 Objectives and Aims of this Project 2
1.4 Scope and Limitation of Project 2
1.5 Importance of Project 2
1.6 Outline of Report 3
2. LITERATURE REVIEW 4
2.1 Definition of Drilling Machine 4
2.2 Parts of Machine 6
2.3 Standard Operations of Drilling Machine 8
2.4 Principal Types of Drilling Machine 8
2.5 Types of Drilling Machines 9
2.6 Introduction of Vise 14
2.7 Vise System 20
2.8 Types of Vise System 21
2.8.1 Hydraulic System 21
2.8.2 Pneumatic System 22
2.9 Previous Case Study 23
2.9.1 Vise for a Directional Drilling Machine 23
2.9.2 Vise Clamp 23
vi
2.9.3 Adjustable Clamp Jaws 24
2.9.4 Vise for Holding a Workpiece on an EDM Machine 24
2.9.5 Replaceable Vise Jaw Insert Assembly 25
2.9.6 Portable Vise 25
2.9.7 Hold-Down Device for Movable Jaw of a Vise 26
2.9.8 Precision Machine Tool Vise with Self Adjusting Clamp 26
2.9.9 Vise with Two Sets of Clamping Jaws 27
2.9.10 Flexible Jaw Vise Accessory for Irregular Objects 27
3. METHODOLOGY 29
3.1 Planning of the Study 29
3.1.1 Process Flow Diagram 29
3.1.2 Gantt Chart 31
3.2 Data Collection 31
3.2.1 Primary Data Collection 31
3.2.1.1 Field Observation 34
3.2.1.2 Archival Collections 34
3.2.2 Secondary Data 34
3.2.2.1 Book, Internet and Journal 35
3.3 Phase of Project 35
3.3.1 Phase 1: Selection of System 36
3.3.2 Phase 2: Design a vise 36
3.3.3 Phase 3: Produce Physical Part 37
3.3.3 Phase 4: Pneumatic System Installation 39
3.3.4 Phase 5: Testing Performance of Vise 39
4. VISE DESIGN 40
4.1 Material 40
4.2 Workpiece 41
4.3 Product Structure Tree 41
4.4 Mechanical Design 43
4.4.1 Jaw Part 43
4.4.2 Cover Part 44
4.4.3 Base Part 44
vii
4.4.4 Pin Part 45
4.5 Pneumatic Design 48
4.5.1 Fitting 48
4.5.2 Pressure Gauge 49
4.5.4 Push button 50
4.5.6 Directional Valve 51
5. RESULT AND DISCUSSION 53
5.1 Pneumatic Test 53
5.2 Clamping Test 57
5.2.1 Result of Clamping Test 59
5.3 Drilling Test 60
5.3.1 Result of Drilling Test 61
5.4 Surface Roughness Test 62
5.4.1 Result of Surface Roughness Test 63
5.5 Result and Discussion of the Project 67
6. CONCLUSION AND RECOMMENDATION 68
6.1 Conclusion 68
6.2 Future Recommendations 69
REFERENCES 70
APPENDICES
A Gantt Chart
B Result Surface Roughness Test (Part 1)
C Result Surface Roughness Test (Part 2)
D Result Surface Roughness Test (Part 3)
E Dimension the Vise
viii
LIST OF TABLES
2.1 Types of Drilling Machine 10
2.2 Types of Vise 17
3.1 The Differences between Primary and Secondary Data 33
3.2 Types of Machine Used 39
4.1 Mechanical Part Used in the Vise 46
4.2 Dimension of the Vise 46
4.3 Pneumatic Component Used in the Vise 52
5.1 Result of Clamping Test 59
5.2 Result of Drilling Machine 61
5.3 Result at Part 1 before Drilling Process 63
5.4 Result at Part 1 after Drilling Process 63
5.5 Result Part 2 before Drilling Process 64
5.6 Result Part 2 after Drilling Process 64
5.7 Result Part 3 before Drilling Process 65
5.8 Result Part 3 after Drilling Process 65
ix
LIST OF FIGURES
2.1 Drilling Machine. 5
2.2 Parts of Machine. 6
2.3 Parts of Radial Drill Machine 7
3.1 Process Flow. 32
3.2 Drawing of New Vise 37
4.1 Workpiece Used in this Project 41
4.2 Product Structure Tree 42
4.3 Jaw Part 43
4.4 Cover Part 44
4.5 Base Part 44
4.6 Pin Part 45
4.7 Physical Part of the Vise 47
4.8 Fitting Component 48
4.9 Pressure Gauge Component 49
4.10 Pressure Gauge Symbol 49
4.11 Flow Controller Component 50
4.12 Flow Controller Symbol 50
4.13 Push Button Component 50
4.14 Push Button Symbol 50
4.15 Directional Valve Component 51
4.16 Directional Valve Symbol 51
4.17 Complete Component 51
5.1 Pneumatic Diagram 54
5.2 Pneumatic Diagram before Running Program 54
5.3 Pneumatic Diagram When Push Button 1 has Push 53
5.4 Pneumatic Diagram When Push Button 2 has Push 53
5.5 Complete Pneumatic Circuit 54
x
5.6 Clamping Test 55
5.7 Top View while Clamping Test 57
5.8 Left Side View while Clamping Test 58
5.9 Right Side View while Clamping Test 59
5.10 Top View while Drilling Test 60
5.11 Side View while Drilling Test 60
5.12 Surface Roughness Diagram 62
5.13 Area of Part 1 63
5.14 Area of Part 2 64
5.15 Area of Part 3 65
5.16 Surface Roughness Test 66
5.17 Finished Vise 67
xi
LIST OF ABBREVIATIONS
ANSI - America National Standard Institute
ABS - Acrylonitrile/ Butadiene/ Styrene
CNC - Computer Numerical Control
FKP - Fakulti Kejuruteraan Pembuatan
ISO - International Standards Organization
NC - Normally Closed
PFD - Process Flow Diagram
UteM - Universiti Teknikal Malaysia Melaka
1
CHAPTER 1
INTRODUCTION
This chapter is intended to provide background information of the study. It covers
background of study, problem statements, objectives, scope and limitation of project,
important of project, and outline of project
1.1 Background
Traditional drill vises provide a clamping jaw which has only one angle of attack in
order to effect clamping. The clamping jaw is limited so it may only be moved
laterally in the direction of the main body. However, the disadvantages of the
structure is the workpiece being clamped is of an irregular shape and where one
desires to bend the workpiece along the edge of the device while it is clamped
In addition, traditional drill vises also do not provide for an adequate working surface
which can be utilized for working on the workpiece during the clamping thereof.
Finally, traditional vises of which aware are not readily adaptable for use anywhere
on the surface of a machine, but rather, are adapted to be used only at an edge
thereof.
Thus, it will be appreciated that there remains a need for a drill vise having a
clamping jaw capable of clamping a workpiece utilizing a variety of angles of attack.
There is also a need to provide a bench vise which provides a surface adequate to
permit work to be performed and combines all of these features, that is more
compact, that provides better "purchase power" and stability and which is adaptable
for use on any portion of the surface of a machine.
2
1.2 Problems Statement
Nowadays, in global market have many design of drill vise. Every manufacture
compete each others in order to produce good product. However there is no one of
vice can clamp for crooker shape with direct clamp till today. So, by producing this
project, the problem can be solving in the future.
1.3 Objectives and Aims of this Project
In the preparation of this project, a few objectives have been identified. The main
objectives of this study are to identify:
1. To propose solution problem related vise tool for holding irregular shape
2. To produce prototype vise that can holding irregular shape for drilling
machine
3. Develop application of vise system in drill vise
1.4 Scope and Limitation of Project
The scope of this project is only focus on development of vise in drill vise. Design
for the vise only produce prototype. This project is only focused on hold a irregular
workpiece by two jaws. This project not covers types of material and specific process
for market product because of the researcher ability time and financial constrain
limit. The project is started from July 2008 until December 2008. Result of this
project for drill vise only. The project is only covered
1.5 Importance of Project
The importance of project is to:
1. Improve functional of drill vise in manufacturing industry.
2. Reduce crack of material during holding workpiece.
3
3. Improve accuracy during drill a workpiece
4. Improve performance of produce in manufacturing industry
5. Reduce vibration during drilling process
1.6 Outline of Report
The Gant-chart has been constructed in managing this project (see appendix A).This
project encompasses five (5) chapters which are:
Chapter 1
This chapter provide the introduction of this project, describes the background and
problem statement of the project. The objective, scope, importance of the project and
the project outline are also presented in this chapter.
Chapter 2
This chapter provides the literature review about drilling machine, parts of drilling
machine and types of drilling machine. The literature review covered about vise,
types of vise, vise system and previous case study.
Chapter 3
In this chapter will give the readers an overview of research methodology, presents
the appropriate methodology of this project. This chapter includes the project process
planning, flowchart, Gantt chart, and data analysis.
Chapter 4
In addition this discusses the analysis and discussion, present findings of the project.
Chapter 5
The conclusion, summarizing the project work that has been done will inform the
readers of the overall of the project in this chapter. It will describe the
recommendation and proposes future improvement about vise tool.
4
CHAPTER 2
LITERATURE REVIEW
2.1 Definition of Drilling Machine
From the resource of Krar, F.S (2005), the drilling machine or drill press is essential
in any metalworking shop. Basically, a drilling machine consists of a spindle which
turns the drill and can be advanced into the work, either automatically or by hand and
a work table (which holds the workpiece rigidly in position as the hole is drilled). A
drilling machine is used primarily to produce holes in metal. However, operations
such as tapping, reaming, counterboring, countersinking, boring, and sport facing can
also be performed. Figure 2.1 at below show the drilling machine.
Drill Press machine also define a machine used for drilling operations available in a
wide variety of types and size to suit different types and sizes of workpieces
(Rapisarda, M. 1996). Drilling machines are used for drilling holes, tapping,
reaming, and small-diameter boring operations. The workpiece is placed on an
adjustable table, either by clamping it directly into the slots and holes on the table or
by using a vise, which in turn is clamped to the table. The drill is lowered manually
by a hand wheel or by power feed at preset rates. Manual feeding requires some skill
in judging the appropriate feed rate.
Drilling machine usually is designed by the largest workpiece diameter that can be
accommodated on the table and typically range from 150 to 1250 mm. In order to
maintain proper cutting speeds at the cutting edges of drills, the spindle speed on
drilling machines has to be adjustable to accommodate different drill sizes
(Kalpakjian, S. 2006)
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According to Kibbe, R.R (2002), drilling holes is one of the most basic of machining
operations that is very frequently done by machinist. Metal cutting requires
considerable pressure of feed on the cutting edge. A drill press provides the
necessary feed pressure either by hand or power drive. The primary use of the drill
press is to drill holes, but it can be used for other operations such as countersinking,
counterboring, spot facing, reaming, and tapping, which are processes that modify
the drilled hole.
Lastly, based on Oswald (1999), drill machine is machine to grip, revolve, and feed a
twist drill in order to produce a hole in a piece of metal or other material
Figure 2.1: Drilling Machine
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2.2 Parts of Machine
Figure 2.2: Parts of Machine
From the resource of Krar, F.S. (2005), although drill presses are manufactured in a
wide variety of types and sizes, all drilling machines contain certain basic parts. The
main parts on the drilling machine are base, column table, and drilling head. In base
part, a material made by cast iron for provides stability for the machine and rigid
mounting for the column. The base usually has holes so that it may be bolted to a
table or bench. The slots in the base allow the workholding device or the workpiece
to be fastened to the base. Figure 2.2 at the top show the parts of the machine.
According to study of Rapisarda, M. (1996), another main part in drilling machine is
column. Column is an accurate cylindrical post that fits into the base. The table,
which is fitted on the column, may be adjusted to any point between the base and
head. The head of the drill press is mounted near the top of the column.
Table is one of part for drilling machine. The table, either round or rectangular, is
used to support the workpiece to be machined. The table whose surface is at 90
degree in either direction for drilling holes on a angle. Slots are provided in most
tables to allow jigs, fixtures, or large workpiece to be clamped directly to the table
(Krar , S. 2002)
Parts of Machine
Table Base
Column Drilling Head
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Last part of drilling machining is drilling head. Drilling head mounted close to the
top of the column, contains the mechanism which is used to revolve the cutting tool
and advance it into the workpiece. The head contains the spindle, a round shaft that
holds and drives the cutting tool, and is housed in the spindle sleeve or quill. The
spindle sleeve does not revolve but can move up and down inside the head to provide
a down feed for the cutting tool. The end of the spindle may have a tapered hole to
hold taper-shank tolls, or it may be threaded or tapered for attaching drill chuck. The
hand feed lever is used to control the vertical movement of the spindle, sleeve and
the cutting tool. A depth stop, attached to the spindle sleeve, can be set to control the
dept that cutting tools enter the workpiece (Krar, F.S. 2005). Figure 2.23 at the
below show the parts of the radial drill machine.
Figure 2.3: Parts of Radial Drill Machine (Krar F.S et al, 2005)
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2.3 Standard Operations of Drilling Machine
Drilling machines may be used for performing a variety of operations besides drilling
a round hole. A few of the more standard operations, cutting tool, and work setups
will be briefly discussed.
1) Drilling maybe defined as the operation of producing a hole by removing
metal from a solid mass using a cutting tool called a twist drill
2) Countersinking is the operation of producing a tapered or cone shaped
enlargement to end of a hole
3) Reaming is the operation of sizing and producing a smooth, round hole from
a previously drilled or bored hole with the use of a cutting tool having several
cutting edges.
4) Boring is the operation of truing and enlarging a hole by means of a single-
point cutting tool, which is usually held in a boring bar.
5) Spot-facing is the operation of soothing and squaring the surface around a
hole to provide a seat for the head of a cap screw or a nut.
6) Tapping is the operation of cutting internal threads in a hole with a cutting
tool called a tap.
7) Counterboring is the operation of enlarging th top of a previously drilled hole
to a given depth to provide a square shoulder for the head of a bolt or cap
screw.
2.4 Principal Types of Drilling Machine
A wide variety of drill presses are available, ranging from the simple sensitive drill to
highly complex automatic and numerically controlled machines. The size of a drill
press may be designated in different ways by different companies. Some companies
state the size as the distance from the center of the spindle to the column of the
machine. Other specifies the size by the diameter of the largest circular piece that can
be drilled in the center (Krar, F.S. 2005)