班級:碩研機械一甲 姓名:黃羽駿 指導老師:戴子堯老師

Slides:



Advertisements
Similar presentations
Electro-erosion edge honing
Advertisements

Machine Tools And Devices For Special Technologies Electrochemical machining Slovak University of Technology Faculty of Material Science and Technology.
Asst. Prof. Dr.Saad Kariem Shather
NONTRADITIONAL MACHINING Chapter 26
Machine Tools And Devices For Special Technologies Plasma machining Slovak University of Technology Faculty of Material Science and Technology in Trnava.
南台科技大學 精密製造實驗室, 100 年 5 月 30 日 Sequential Laser and EDM Micro- drilling for Next Generation Fuel Injection Nozzle Manufacture 指導老師 : 戴子堯 老師 學生 : 劉丞哲 學號.
Micro slit machining using EDM with a modified rotary disk electrode(RDE) H.M. Chow, B.H. Yan, F.Y. Huang Department of Mechanical Engineering, National.
Contents lists available at ScienceDirect CIRP Annals - Manufacturing Technology journal homepage: High aspect.
AAS and FES (Ch 10, 7th e, WMDS)
© 2012 Su-Jin Kim GNU Grinding, EDM Manufacturing Processes Grinding( 연삭 ), EDM Grinding( 연삭 ), EDM( 방전 ) Associate Professor Su-Jin KimSu-Jin Kim School.
Machine Tools And Devices For Special Technologies Electro erosive machining Slovak University of Technology Faculty of Material Science and Technology.
Analysis and Performance of Slotted Tools in Electrical Discharge Drilling Ramy Nastasi, Philip Koshy McMaster University Canada NANTES.
Introduction to Manufacturing Technology –Lecture 2 Instructors: (1)Shantanu Bhattacharya, ME, IITK, (2)Prof.
Non-traditional Machining Processes
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes (Review) EIN 3390 Manufacturing Processes Spring,
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes EIN 3390 Manufacturing Processes Summer A, 2012.
Machining is processes in which we get a desired final shape and size from of raw material. 1.Conventional / Traditional Machining 2.Non Conventional.
班級:碩研機械一甲 姓名:田正雨 學號: M Micro-EDM of sintered diamond.
Investigation of micro-EDM material removal characteristics using single RC-pulse discharges Class :碩研機械一甲 Student ID : MA Student :陳肇文 Professor.
PRESENTED BY ALBERT.N Under the guidance of Mr.N.RAMANUJAM M.E (Ph.d) (Associate Prof/Hod- Mech) DEPARTMENT OF MECHANICAL ENGINEERING E.G.S.PILLAY ENGINEERING.
INFLUENCE OF MACHINE FEED RATE IN WEDM OF TITANIUM Ti-6Al-4V WITH CONSTANT CURRENT (6A) USING BRASS WIRE 指導老師 : 戴子堯 碩研奈米一甲 ma31v205 蘇育儒.
Analysis of the effect of vibrations on the micro- EDM process at the workpiece surface 指導老師 : 戴子堯教授 學生 : 郭正宇 日期 : /13.
ABRASIVE JET MACHINE.
Micro-EDM process investigation and comparison performance of Al 3 O 2 and ZrO 2 based ceramic composites 指導老師 : 戴子堯 報告者 : 張瑋民.
Processes Used to Separate Metallic Materials
Study of the recast layer of a surface machined by sinking electrical discharge machining using water-in-oil emulsion as dielectric 班級:碩研機械一甲 學號:MA
Wire EDM cutting of PCD 報告者:陳思懿 指導教授 : 戴子堯 博士. Outline INTRODUCTION Influence of PCD machining conditions Conclusions 1/10.
班級:碩研奈米一甲 學號:MA31V206 姓名:黃宗偉 授課教師:戴子堯 教授
The Effect of Process Variables on Surface Grinding of SUS304 Stainless Steel S. Y. Lin, Professor Department of Mechanical Manufacturing Engineering.
Universal College Of Engineering & Technology
Development of an Active Micromixer by Dielectrophrosis Particle Manipulating 姓名:黃朝鴻 Chao-hong Huang 班級:奈米一甲 學號:MA11V108.
Nucleate boiling in a flat grooved heat pipe Paper review.
SEMINAR ON HIGH SPEED MACHINING (HSM). CONTENTS  Introduction  Definition of HSM  Advantages  Application areas  Machining system  Some recommended.
Electrochemical Machining (ECM)
南台科技大學 精密製造實驗室, 102 年 8 月 8 日 班級 : 碩研機械一甲 姓名 : 鄧文斌 指導老師 : 曾信智.
Feasibility of 3-D Surface Machining by Dry EDM 1/15 班級 : 碩研奈米一甲 學號 :M98R0105 報告者:陳致維 報告日期: 06/04/2010.
Mold Texturing Trevor Thorwart Andrew Meier Josh Hoover.
Pin-plate micro assembly by integrating micro-EDM and Nd-YAG laser 指導老師:戴子堯 學生:駱宏明 International Journal of Machine Tools & Manufacture – 1464.
102 年 12 月 23 日 機械工程系所 精密製造實驗室 1/8 Strengthening via the formation of strain-induced martensite instainless steels 授課老師:戴子堯 老師 班級:碩研二甲 學號: MA 姓名:鄧文斌.
Development of a combined machining method using electrorheological fluids for EDM 姓名:吳涵玉 日期: 100/2/23 1/13.
Electrical Methods of Material Removal Chapter 5.
老師:戴 子 堯 學生:陳 立 偉 日期: Outline INTRODUCTION THE DRY EDM PROCESS EXPERIMENTAL SETUP CONCLUSIONS 2.
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes (Review) EIN 3390 Manufacturing Processes Summer A,
URL: 12-1, Hisakata 2-chome, Tempaku-ku, Nagoya JAPAN (C)2001 Manufacturing Engineering Laboratory,
班級:碩研機械一甲 報告人: 黃柏慶 Electrode Wear Process in Electrical Discharge Machining Annals of the CIRP.
1 Teaching Innovation - Entrepreneurial - Global The Centre for Technology enabled Teaching & Learning, N Y S S, India DTEL DTEL (Department for Technology.
MANUFACTURING OF MICRO V-GROOVE WITH AN ELECTRICALLY CONDUCTIVE DIAMOND ELECTRODE IN EDM Name:吳涵玉 Date:6/13.
Effect of micro-powder suspension and ultrasonic vibration of dielectric fluid in micro-EDM processes - Taguchi approach 指導老師:戴子堯 教授 學生:杜弘翔 4A 報告日期:
Study of heat and chemical treatments effects on the surface of ultra-precision machined discs for CLIC X-band Accelerating Structure Review (24 Nov. 2014)
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes EIN 3390 Manufacturing Processes Spring, 2012.
IN THE NAME OF ALLAH, THE MOST MERCIFUL, THE MOST BENEFICIENT. 1.
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes (Review) EIN 3390 Manufacturing Processes Spring, 2011.
Knoop Hardness for Various Materials
EBB440 Applied Metallurgy Abrasive Machining.
Chapter 19 Electronic Electrochemical Chemical and Thermal Machining Processes EIN 3390 Manufacturing Processes Summer A, 2011.
M EASUREMENT AND OPTIMIZATION OF DRILLING PROCESS PARAMETERS Presented by:  Rahul Bhat  Hardik Thummar  Maunik.
ELECTRICAL ENERGY BASED PROCESSES
ELECTRICAL ENERGY BASED PROCESSES
ULTRASONIC MACHINING PROCESS Prepared by B.BALAMURALI AP/MECH
Chemical and Electro-Chemical Energy Based Processes
Chemical and Electro-Chemical Energy Based Processes
Electrical Discharge Machine - EDM
ELECTRICAL ENERGY BASED PROCESSES
ELECTRICAL ENERGY BASED PROCESSES
ELECTRIC DISCHARGE MACHINING
Comparative study on discharge conditions in micro-hole electrical discharge machining of tungsten carbide (WC-Co) material Hyun-Seok TAK 1 , Chang-Seung.
Metal cutting. Introduction Metal cutting or “Machining” is a process which removing unwanted materials from the work piece by the form of chips. The.
Manufacturing Processes
Unconventional Machining
Manufacturing Processes
Presentation transcript:

班級:碩研機械一甲 姓名:黃羽駿 指導老師:戴子堯老師 CIRP Annals - Manufacturing Technology 63 (2014) 209–212 Micro-electrical discharge machining of polycrystalline diamond using rotary cupronickel electrode Jiwang Yan a,*, Kazunori Watanabe a, Tojiro Aoyama (1)b a Department of Mechanical Engineering, Keio University, Yokohama 223-8522, Japan b Department of System Design Engineering, Keio University, Yokohama 223-8522, Japan 班級:碩研機械一甲 姓名:黃羽駿 指導老師:戴子堯老師

Introduction In recent years, micro-electrical discharge machining (m-EDM) of PCD has become a new focus of research [3–5]. In most studies, copper, tungsten, and Cu–W alloy wires were used as electrodes [2–7]. However, the resulting material removal rate (MRR) was quite low, and the consumption of electrode wire was significant, leading to very high production costs. In this study, a copper–nickel (Cu–Ni) alloy, cupronickel, was adopted as an electrode material for generating microstructures on PCD by EDM. The material removal mechanisms in the EDM process were investigated by Raman spectroscopy and energy dispersive X-ray spectroscopy analysis, and the optimal EDM conditions were explored. The findings of this study provide a new approach for high-precision and high-efficiency micromachining of PCD and other carbon-based ultra-hard materials

Design of EDM electrode (a) conventional electrodes Reason: By way of reduction of the MRR of Co binder and inducement of graphitization of diamond grains. Result: However, this decreased the total MRR of PCD. Therefore, it has become essential to improve the total MRR of PCD, while preventing the dislodging of diamond grains.

Design of EDM electrode (a) conventional electrodes It is known that diamond tools show severe wear when cutting Ni. This is because Ni has a very high affinity for diamond, resulting in thermal and electrical chemical reactions when they are in contact. The MRR of diamond grains might be significantly improved by utilizing these chemical reactions between Ni and diamond (C) in addition to diamond graphitization .

Design of EDM electrode 1.The cross section of the electrode can be precisely shaped into arcs, knife-edges, and free-form curves for generating different kinds of microstructures on PCD. 2. Through wheel rotation, debris generated during EDM can be removed effectively from the discharge gap. 3.The wear rate of the electrode is uniform across the wheel surface, which is helpful for accuracy improvement and shape compensation. 4.The service life of wheel electrodes is longer than that of wire electrodes and block electrodes, enabling long-time continuous machining without electrode change. 5.The wheel electrode unit is compact, and can easily be installed for on-machine EDM tool fabrication

EDM system construction and experimental procedures

Results and discussion Effect of electrode type/material on MRR For the same cupronickel material, the rotary electrode has significantly higher MRR than the die-sinking block electrode. These results demonstrate strongly that the material removal mechanism of PCD in EDM using cupronickel electrodes is distinctly different from that of other electrode materials.

Results and discussion Effect of electrode rotation rate on MRR That a high rotation rate contributes to the emission of debris from the discharge gap. At a rotation rate higher than 350 rpm, however, the MRR hardly changes, showing a saturation state where no debris stagnation occurs in the gap.

Results and discussion Surface topography The latter (0.15 mm Ra) is distinctly smoother than the former (0.21 mm Ra). In Fig. 6b, the protrusion of diamond grains from the binder surface is very small, which agrees with the surface formation mechanism shown in Fig. 1b.

Results and discussion Surface topography By using a low discharge energy, an extremely low surface roughness (m0.1 mm Ra) was obtained.

Results and discussion Surface topography The deviation between the cross-sectional profile of the groove and that of the electrode is m1 mm, indicating that the shape of the electrode has been precisely replicated in the PCD workpiece. The longitudinal profile of the groove shows that straightness of the groove is m0.5 mm over a range of 1 mm.

Results and discussion Electrode-workpiece interfacial phenomena

Results and discussion Electrode-workpiece interfacial phenomena The concentration of C detected in the subsurface region is as high as that on the electrode surface, indicating that the diffusion of C from diamond into cupronickel during EDM is very significant. It can be estimated from Fig. 10 that the depth of diffusion was a few micrometers, similar to that in high-temperature erosion tests.

Results and discussion Electrode-workpiece interfacial phenomena As electrical discharges occur in a very narrow gap for a very short duration, the temperature in the gap is extremely high , which causes melting and evaporation of the binder (Co). The high temperature then causes two kinds of material dissipation effects of diamond: graphitization and diffusion-based chemical reaction The diamond grains protruding a lot from the binder surface make contact with cupronickel and diffuse to a great extent into Ni, whereas the diamond grains of less protrusion undergo partial surface graphiti- zation.

Results and discussion Microstructure fabrication Other alloys such as ferrous metal alloys might also be used for the high-efficiency and high-precision EDM of PCD. This m-EDM method might also be applied to machining other carbon-based ultra-hard materials .

Conclusions A prototype m-EDM system was developed for fabricating microstructures on PCD. A wheel-shaped cupronickel electrode was used and was rotated by the flow of EDM fluid. Results show that material removal rate of PCD is improved by a factor of five compared to conventional electrode materials, and surface rough- ness is reduced greatly. Raman spectroscopy and energy dispersive X-ray spectroscopy analysis show two interfacial phenomena occurring, graphitization of diamond and diffusion-based chemical reactions between Ni and diamond, with the latter tending to be dominant. Increasing the rotation rate of the electrode improved significantly the material removal rate of PCD. Typical microstruc- tures were successfully generated on PCD with high form accuracy and low surface roughness.