INVESTIGATION OF MACHINING PERFORMANCE OF COATED CARBIDE BY MURAKAMI SURFACE PRETREATMENT KHAIRUL AZMI BIN MOHD MAWARDZI A report submitted in partial fulfillment of The requirements for the award of the degree of Bachelor of Mechanical Engineering With Manufacturing Engineering Faculty of Mechanical Engineering Universiti Malaysia Pahang JUNE 2012
vi ABSTRACT Tungsten carbide is the most widely used material for cutting tools. Due to extreme demands higher tool life several types of coating have been introduced to prolong the service time which include diamond coating. However cobalt binder in tungsten carbide prevents diamond to adhere well on the substrate and its content at the outer surface should be reduce to below 1%. Pretreatments have been studied by many researchers. But to date poor adhesion of diamond coating still an issue. In this work a murakami pretreatment was used to etch tungsten carbide at the surface of the substrate in order to solve poor adhesion problem. First step with Murakami's reagent 20 minutes and the second step of the process were carried out by etching in a solution of hydrochloric acid (45 seconds). The effect of murakami pretreatments on Co cemented tungsten carbide samples were study in term of surface morphology, surface roughness, and cobalt removal from the surface was examined. Based on the experimental, the following conclusions can be withdrawn. It is found that murakami suface pretreatment affecting the final surface roughness of substrate. Murakami pretreatment able to strengthened the diamond coating adhesion by modifying the surface roughness. The wear resistance of coated tungsten carbide was higher than uncoated tungsten carbide. Cutting tool with coated tungsten carbide produced better work piece s surface finish as compared to uncoated cutting tool. It was also further improved when pretreatment (murakami) was used.
vii ABSTRAK Tungsten karbida adalah bahan yang paling banyak digunakan dalam alat-alat pemotongan. Disebabkan oleh permintaan yang tinggi terhadap alatan pemotong yang berjangka hayat lama, kaedah saduran diperkenalkan untuk meningkatkan masa penggunaannya termasuklah saduran berlian. Walaubagaimanapun, pengikat kobalt di dalam tungsten karbida menghalang berlian daripada melekat dengan sempurna pada substrak dan kandungannya perlu dikurangkan kepada bawah daripada satu peratus. Kaedah langkah pra-rawatan telah dipelajari oleh ramai penyelidik sebelum ini. Tetapi masalah berlian yang tidak melekat dengan baik masih menjadi isu. Didalam kajian ini,pra-rawatan digunakan untuk menghakis tungsten karbida pada permukaan substrak dalam usaha menyelesaikan masalah perekatan yang tidak sempurna ini. Langkah pertama adalah dengan reagen Murakami 20 minit dan langkah kedua dalam proses ini ialah pengakisan menggunakan asid hidroklorik (45 saat). Kesan daripada eksperimen ini terhadap tungsten karbida semen dikaji dari segi morfologi permukaan, kekasaran permukaan dan penyingkiran kobalt dari permukaan. Berdasarkan eksperimen ini, kesimpulannya didapati bahawa prarawatan permukaan mempengaruhi kekasaran permukaan akhir substrate.murakami dapat mengukuhkan lekatan salutan berlian dengan mengubah rintangan permukaan. Tungsten karbida bersalut adalah lebih tinggi daripada tungsten karbida tidak bersalut, alat pemotongan tungsten karbida bersalut menghasilkan kemasan permukaan benda kerja yang lebih baik berbanding alat pemotong tidak bersalut. Ia juga menjadi lebih baik apabila prarawatan (Murakami) telah digunakan.
viii TABLE OF CONTENTS EXAMINER S DECLARATION SUPERVISOR S DECLARATION STUDENT S DECLARATION ACKNOWLEDGEMENTS ABSTRACT ABSTRAK TABLE OF CONTENTS LIST OF TABLES LIST OF FIGURES LIST OF SYMBOLS LIST OF ABBREVIATIONS Page ii iii iv v vi vii viii x xi xii xiii CHAPTER 1 INTRODUCTION 1 1.1 Introduction 1 1.2 Problem Statement 2 1.3 Objectives of the Research 2 1.4 Scope of project 3 CHAPTER 2 LITERATURE REVIEW 4 2.1 Introduction 4 2.1.1 Introduction of investigation 4 2.1.2 Introduction of machining performance 5 2.1.3 Introduction of coated carbide 5 2.1.4 Introduction of turning machine 6 2.1.5 Introduction of CVD Coating 9 2.1.6 Introduction of chemical pretreatment 10 2.1.7 Introduction of murakami surface pretreatment 11 2.2 Summary of literature review 13 CHAPTER 3 METHODOLOGY 17 3.1 Introduction 17
ix 3.2 Surface pretreatment 3.3 CVD coating methods 3.4 Turning Experiment 3.5 Cutting tools characterization 3.5.1 Surface microstructure 3.5.2 Wear resistant 3.5.3 Hardness test 3.5.4 Surface roughness 3.5.5 Workpiece chips 18 19 20 21 21 22 23 23 24 CHAPTER 4 RESULT AND DISCUSSION 25 4.1 Introduction 25 4.2 Surface microstructure 25 4.3 Effect of murakami pre-treatment to coated carbide 27 machining performance 4.4 Effect of murakami surface pre-treatment to coated 29 carbide by Vickers micro hardness 4.5 Effect of murakami surface pre-treatment to 31 tungsten carbide surface roughness 4.6 Result of chips formation 33 CHAPTER 5 CONCLUSION AND RECOMANDATION 35 5.1 Conclusions 35 5.2 Recommendation 35 REFERENCES 36 APPENDICES 38 A 38
x LIST OF TABLES Table No. Title Page 2.1 Capability of turning 8 3.1 Parameter for ASTM B777-7 21
xi LIST OF FIGURES Figure No. Title Page 2.1 Manual lathe machine 7 2.2 Schematic view of the CVD chamber 9 2.3 SEM micrographs of fine grain substrates 12 3.1 Methodology flow chart 18 3.2 Schematic view of the CVD chamber 19 3.3 Shun Chuan turning machine model ERL13370 20 3.4 Scanning Electron Microscope (SEM) 22 3.5 Optical Measurement Microscope 22 3.6 Vickers Hardness Model: MATSUZAWA MMT-X7 23 4.1 Surface morphologies of tungsten carbide cutting tools 26 4.2 Graph length of wear vs cutting length 29 4.3 Graph hardness of cutting tool 31 4.4 Graph effect of surface pretreatment on surface roughness 32 4.5 Type of chips 34
xii LIST OF SYMBOLS µm Micrometer % Percentage g/cm 3 Gram per centimeter cube kg/m 3 Kilogram per meter cube Gpa Giga Pascal Mpa Mega Pascal c Thermal Expansion Coefficient K Kelvin HV Hardness Vickers
xiii LIST OF ABBREVIATIONS CVD PVD Ti-6Al-4V ELI HF SEM WC Chemical Vapour Deposition Physical Vapour Deposition Titanium alloy alpha-beta Extra Low Interstitial Hydrofluoric Scanning Electron Microscope Tungsten Carbide
ii UNIVERSITI MALAYSIA PAHANG FACULTY OF MECHANICAL ENGINEERING I certify that the project entitled investigation of machining performance of coated carbide by murakami surface pretreatment is written by Khairul Azmi Bin Mohd Mawardzi. I have examined the final copy of this project and in our opinion; it is fully adequate in terms of scope and quality for the award of the degree of Bachelor of Engineering. I here with recommend that it be accepted in partial fulfillment of the requirements for the degree of Bachelor of Mechanical Engineering with Manufacturing Engineering. Signature :.. Name of Examiner : Dr. Noraini Mohd Razali Position : Lecturer Date :
iii SUPERVISOR S DECLARATION I hereby declare that I have checked this project and in my opinion, this project is adequate in terms of scope and quality for the award of the degree of Bachelor of Mechanical Engineering with Manufacturing Engineering. Signature :.. Name of Supervisor :Dr. Siti Rabiatull Aisha Idris Position :Lecturer Date :
iv STUDENT S DECLARATION I hereby declare that this report entitled investigation of machining performance of coated carbide by murakami surface pretreatment is the result of my own research except as cited in the references. The report has not been accepted for any degree and is not concurrently submitted in candidature of any other degree.. Signature :.. Name : Khairul Azmi Bin Mohd Mawardzi ID Number : ME 08068 Date : 22 th of June 2012
v ACKNOWLEDGEMENT I would like praise to almighty God who has given me the strength and potency to complete this research. In particular, I want to express my sincere appreciation to my supervisor, Dr. Siti Rabiatull Aisha Binti Idris for her encouragement, motivation, guidance, and critics in completing this thesis. I am also very thankful to all staff, for providing the guideline, advice, and friendship. Without their continued support and interest, this report would not have been the same as presented here. They are always guiding me in doing my research and writing this project report and God bless all their sacrifices and efforts. As well I would like to extend my sincere appreciation to all the staffs in Laboratory for their support and guidance in performing the laboratory tasks. I also would like to thank all my lecturers for their advice and motivation. I will remember and implement them in the future. Finally, I want to thank to all of my friends for their aid in finishing this research.
vi ABSTRACT Tungsten carbide is the most widely used material for cutting tools. Due to extreme demands higher tool life several types of coating have been introduced to prolong the service time which include diamond coating. However cobalt binder in tungsten carbide prevents diamond to adhere well on the substrate and its content at the outer surface should be reduce to below 1%. Pretreatments have been studied by many researchers. But to date poor adhesion of diamond coating still an issue. In this work a murakami pretreatment was used to etch tungsten carbide at the surface of the substrate in order to solve poor adhesion problem. First step with Murakami's reagent 20 minutes and the second step of the process were carried out by etching in a solution of hydrochloric acid (45 seconds). The effect of murakami pretreatments on Co cemented tungsten carbide samples were study in term of surface morphology, surface roughness, and cobalt removal from the surface was examined. Based on the experimental, the following conclusions can be withdrawn. It is found that murakami suface pretreatment affecting the final surface roughness of substrate. Murakami pretreatment able to strengthened the diamond coating adhesion by modifying the surface roughness. The wear resistance of coated tungsten carbide was higher than uncoated tungsten carbide. Cutting tool with coated tungsten carbide produced better work piece s surface finish as compared to uncoated cutting tool. It was also further improved when pretreatment (murakami) was used.
vii ABSTRAK Tungsten karbida adalah bahan yang paling banyak digunakan dalam alat-alat pemotongan. Disebabkan oleh permintaan yang tinggi terhadap alatan pemotong yang berjangka hayat lama, kaedah saduran diperkenalkan untuk meningkatkan masa penggunaannya termasuklah saduran berlian. Walaubagaimanapun, pengikat kobalt di dalam tungsten karbida menghalang berlian daripada melekat dengan sempurna pada substrak dan kandungannya perlu dikurangkan kepada bawah daripada satu peratus. Kaedah langkah pra-rawatan telah dipelajari oleh ramai penyelidik sebelum ini. Tetapi masalah berlian yang tidak melekat dengan baik masih menjadi isu. Didalam kajian ini,pra-rawatan digunakan untuk menghakis tungsten karbida pada permukaan substrak dalam usaha menyelesaikan masalah perekatan yang tidak sempurna ini. Langkah pertama adalah dengan reagen Murakami 20 minit dan langkah kedua dalam proses ini ialah pengakisan menggunakan asid hidroklorik (45 saat). Kesan daripada eksperimen ini terhadap tungsten karbida semen dikaji dari segi morfologi permukaan, kekasaran permukaan dan penyingkiran kobalt dari permukaan. Berdasarkan eksperimen ini, kesimpulannya didapati bahawa prarawatan permukaan mempengaruhi kekasaran permukaan akhir substrate.murakami dapat mengukuhkan lekatan salutan berlian dengan mengubah rintangan permukaan. Tungsten karbida bersalut adalah lebih tinggi daripada tungsten karbida tidak bersalut, alat pemotongan tungsten karbida bersalut menghasilkan kemasan permukaan benda kerja yang lebih baik berbanding alat pemotong tidak bersalut. Ia juga menjadi lebih baik apabila prarawatan (Murakami) telah digunakan.
viii TABLE OF CONTENTS EXAMINER S DECLARATION SUPERVISOR S DECLARATION STUDENT S DECLARATION ACKNOWLEDGEMENTS ABSTRACT ABSTRAK TABLE OF CONTENTS LIST OF TABLES LIST OF FIGURES LIST OF SYMBOLS LIST OF ABBREVIATIONS Page ii iii iv v vi vii viii x xi xii xiii CHAPTER 1 INTRODUCTION 1 1.1 Introduction 1 1.2 Problem Statement 2 1.3 Objectives of the Research 2 1.4 Scope of project 3 CHAPTER 2 LITERATURE REVIEW 4 2.1 Introduction 4 2.1.1 Introduction of investigation 4 2.1.2 Introduction of machining performance 5 2.1.3 Introduction of coated carbide 5 2.1.4 Introduction of turning machine 6 2.1.5 Introduction of CVD Coating 9 2.1.6 Introduction of chemical pretreatment 10 2.1.7 Introduction of murakami surface pretreatment 11 2.2 Summary of literature review 13 CHAPTER 3 METHODOLOGY 17 3.1 Introduction 17
ix 3.2 Surface pretreatment 3.3 CVD coating methods 3.4 Turning Experiment 3.5 Cutting tools characterization 3.5.1 Surface microstructure 3.5.2 Wear resistant 3.5.3 Hardness test 3.5.4 Surface roughness 3.5.5 Workpiece chips 18 19 20 21 21 22 23 23 24 CHAPTER 4 RESULT AND DISCUSSION 25 4.1 Introduction 25 4.2 Surface microstructure 25 4.3 Effect of murakami pre-treatment to coated carbide 27 machining performance 4.4 Effect of murakami surface pre-treatment to coated 29 carbide by Vickers micro hardness 4.5 Effect of murakami surface pre-treatment to 31 tungsten carbide surface roughness 4.6 Result of chips formation 33 CHAPTER 5 CONCLUSION AND RECOMANDATION 35 5.1 Conclusions 35 5.2 Recommendation 35 REFERENCES 36 APPENDICES 38 A 38
x LIST OF TABLES Table No. Title Page 2.1 Capability of turning 8 3.1 Parameter for ASTM B777-7 21
xi LIST OF FIGURES Figure No. Title Page 2.1 Manual lathe machine 7 2.2 Schematic view of the CVD chamber 9 2.3 SEM micrographs of fine grain substrates 12 3.1 Methodology flow chart 18 3.2 Schematic view of the CVD chamber 19 3.3 Shun Chuan turning machine model ERL13370 20 3.4 Scanning Electron Microscope (SEM) 22 3.5 Optical Measurement Microscope 22 3.6 Vickers Hardness Model: MATSUZAWA MMT-X7 23 4.1 Surface morphologies of tungsten carbide cutting tools 26 4.2 Graph length of wear vs cutting length 29 4.3 Graph hardness of cutting tool 31 4.4 Graph effect of surface pretreatment on surface roughness 32 4.5 Type of chips 34
xii LIST OF SYMBOLS µm Micrometer % Percentage g/cm 3 Gram per centimeter cube kg/m 3 Kilogram per meter cube Gpa Giga Pascal Mpa Mega Pascal c Thermal Expansion Coefficient K Kelvin HV Hardness Vickers
xiii LIST OF ABBREVIATIONS CVD PVD Ti-6Al-4V ELI HF SEM WC Chemical Vapour Deposition Physical Vapour Deposition Titanium alloy alpha-beta Extra Low Interstitial Hydrofluoric Scanning Electron Microscope Tungsten Carbide
1 CHAPTER 1 INTRODUCTION 1.1 INTRODUCTION Machining process play an important role in product making and widely use in manufacturing industries. Machining is the process of removing materials from excess and unwanted stock by use of machine tools and converting them into a usable parts. All of these related to the metal cutting. Therefore the characteristic of cutting tools need to be consider during in machining operation in order to get a good quality of product in time, and can reduce the production cost. Cemented tungsten carbide is the most widely used material for cutting tools. Due to extreme demands higher tool life several types of coating have been introduced to prolong the service time which include diamond coating. The study of CVD diamond coatings can be expected to significantly prolong the lifetime of coated tools during cutting and milling. The Co in the hard metal binder phase can Influence the chemical vapour deposition of diamond. Co vapour pressure, surface migration, and carbon solubility are the main parameters influencing diamond nucleation and growth and coating adhesion. Pre-treatment procedures are usually aimed at decrease the Co in the substrate surface by select chemical etching. In this paper the special surface pre-treatment procedure reported in the patent was investigated. After small amounts of WC are removed from the hard metal substrate surface by etching with Murakami solution (K 3 [Fe(CN) 6 ] n KOH), the remaining Co binder network is treated with H 2 SO 4 /H 2 O 2 solution. The effects of this surface treatment with respect to diamond growth rate, morphology and adhesion of the deposited coating on the substrates were investigated.
2 1.2 PROBLEM STATEMENT Performance of turning machine almost depending in how fast the machine can cut the work piece, its meant more faster the turning machine process material more finish product are produce in a period of time and the productivity of the machine are high. High productivity needed high rate of metal removal, so it will reduce manufacturing cost and operation time. Although the faster process is needed, it did not guarantee the quality of the produce good in term of surface roughness. Customer always prefer to a quality product and the quality of work piece machined surface and its integrity are most depend on tool wear and it directly depend on life of the tool. Moreover, despite having the target of achieving optimum finishing with the shortest possible time one must take into account the consideration the quality of surface roughness, so that the complete finishing operation can be carried out with just one tool, avoiding the intermediate stops in order to change the tool due to its wear. Eventually, sudden failure of cutting tools lead to loss of productivity, rejection of parts and consequential economic losses. Selection of cutting tools and cutting conditions represents. Plus tool wear/tool life is an important aspect commonly considered in evaluating the performance of a machining process. In this research, the main objective is to study the effect and performance of coated cutting tools with Murakami surface pretreatment in order to get the best quality of work piece surface roughness while using turning machine. 1.3 OBJECTIVE OF THE RESEARCH These are the objectives for this research: (a) (b) To determine the effect of the murakami pretreatment onto tungsten carbide s surface morphology prior to coating. To determine the effect of machining performance of tungsten carbide on titanium (focusing on size and shape of the chip).
3 (c) To evaluate the effect of tungsten carbide s wear resistance using coated and uncoated tungsten carbide. 1.4 SCOPE OF PROJECT The scope of this research can be divided into three main parts: a) Murakami surface pretreatment of the cutting tools -The tungsten carbide cutting tools will be etched (soaked) in murakami solution. b) Coating the cutting tools -The cutting tools will be coated by chemical vapor deposition (CVD) technique. c) Machining (testing the cutting tools) -The cutting tools will be testing by using turning machine with titanium workpiece based on the specified parameters.