Warianty tytułu
The Effectiveness Indicators of Experimental Research in Electrodischarge Machining and Electrochemical Machining
Języki publikacji
Abstrakty
Ciągły wzrost zapotrzebowania na coraz mniejsze produkty, szczególnie wykonywane z materiałów trudnoobrabialnych czy materiałów kompozytowych, wymaga odpowiednich technologii ich wytwarzania. Elementy w skali mikro muszą cechować się wysoką precyzją wykonania, dokładnością wymiarowo - kształtową, wysoką jakością powierzchni. Wśród technologii, które mogą sprostać tym wymaganiom znajdują się niekonwencjonalne metody obróbki erozyjnej. W artykule omówiono proces obróbki elektroerozyjnej i elektrochemicznej w aspekcie efektywności stosowania obu metod.(abstrakt oryginalny)
Nowdays it can notice more interesting miniaturization in industry. Significantly performing micro - parts and products from difficult - to - machine materials or composite materials. Machining conventional methods of micro elements is often very difficult and impossible. The performed micro - elements must have high accuracy and quality surface, precision dimensional. That is why it notices unconventional process such as electrical discharge machining and electrochemical machining. In article are presented characteristic below the methods in aspect of efficiency using.(original abstract)
Słowa kluczowe
Twórcy
Bibliografia
- 1. Abbas N. M., Yusoff N., Wahab R. M., Electrical Discharge Machining (EDM): Practices in Malaysian Industries and Possible Change towards Green Manufacturin. Procedia Engineering 2012, 41, s. 1684 - 1688
- 2. Ali S., Hinduja S., Atkinson J., Pandya M., Shaped tube electrochemical drilling of good quality holes. CIRP Annals - Manufacturing Technology 58 2009, s. 185-188
- 3. Bhattacharyya B., Mitra S., Boro A.K., Electrochemical machining: new possibilities for micromachining. Robotics and Computer Integrated Manufacturing 2002, 18, s.283-289
- 4. BhattacharyyaB., Munda J., Experimental investigation into electrochemical micromachining (EMM) process. Journal of Materials Processing Technology 2003, 140, s. 287-291
- 5. Bilgi D. S. , Kumar R. , Jain V. K. , Shekhar R., Predicting radial overcut in deep holes drilled by shaped tube electrochemical machining. Int J Adv Manuf Technol 2008, 39, s. 47-54
- 6. Bilgi D. S., Jain V. K., Shekhar R., Kulkarni A. V., Hole quality and interelectrode gap dynamics during pulse current electrochemical deep hole drilling. Int J Adv Manuf Technol 2007, 34, s. 79-95
- 7. Chavoshi S. Z., Analysis and predictive modeling of performance parameters in electrochemical drilling process. Int J Adv Manuf Technol 2011, 53, s. 1081-1101
- 8. Chenthil Jegan T. M., Dev Anand M., Ravindran D., Determination of electro discharge machninig parameters in AISI202 stainless steel using grey relational analysis. Procedia Engineering 2012, 38, s. 4005 - 4012
- 9. El-Hofy H.: Advanced Machining Process. Nontraditional and hybirid machining process. Alexandria University, Egyp 2005
- 10. Fan Z. - W., Hourng L.- W., Electrochemical micro-drilling of deep holes by rotational cathode tools. Int J Adv Manuf Technol 2011, 52, s. 555-563
- 11. Gaoyang W., Zhijing Z., Weimin Z., Xinglun T., High frequency group pulse electrochemical machining. Front. Mech. Eng. China 2007, 2(3), s. 293-296
- 12. Hackert-Oschätzchen M., Martin A., Gunnar Meichsner G., Zinecker M., Schubert A., Microstructuring of carbide metals applying Jet Electrochemical Machining. Precision Engineering 2013, 37, s. 621- 634
- 13. Hinduja S., Kunieda M., Modelling of ECM and EDM processes. CIRP Annals - Manufacturing Technology 2013, 62, s. 775-797
- 14. Jahan M.P., Rahman M., Wong Y.S., A review on the conventional and micro-electrodischarge machining of tungsten carbide. International Journal of Machine Tools & Manufacture 2011, 51, s. 837-858
- 15. Jaźwiński J., Boroń J., Niezawodność eksploatacyjna i bezpieczeństwo lotów. WKiŁ, Warszawa 1989
- 16. Kao C. - C., Shih A. J., Design and tuning of a fuzzy logic controller for micro-hole electrical discharge machining. Journal of Manufacturing Processes 2008, 10, s. 61 - 73
- 17. Klocke F., Klink A., Veselovac D., Aspinwall D. K., Sein Leung Soo S. L., Schmidt M., Schilp J., Levy G., Kruth J. - P., Turbomachinery component manufacture by application of electrochemical, electro-physical and photonic processes. CIRP Annals - Manufacturing Technology 2014, 63, s. 703-726
- 18. Kock M., Kirchner V., Schuster R., Electrochemical micromachining with ultrashort voltage pulses a versatile method with lithographical precision. Electrochimica Acta 2003, 48, s. 3213 - 3219
- 19. Lee S. H., Li X. P., Study of the effect of machining parameters on the machining characteristics in electrical discharge machining of tungsten carbide. Journal of Materials Processing Technology 2001, 115, s. 344 - 358
- 20. Lipiec P., Machno M., Obróbka elektroerozyjna materiałów ceramicznych. XLI Szkoła Inżynierii Materiałowej, Kraków-Krynica 24-27.09.2013, s. 353 - 358
- 21. Liu K., Lauwers B., Reynaerts D., Process capabilities of Micro-EDM and its applications. Int J Adv Manuf Technol 2010, 47, s. 11-19
- 22. Machno M., BizońW., Skoczypiec S., Badania doświadczalne wiercenia elektroerozyjnego stali 0H18N9. Innowacje w zarządzaniu i inżynierii produkcji. T. 1 pod red. R. Knosali, Opole 2015
- 23. Mahardika M., Tsujimoto T., Mitsui K., A new approach on the determination of ease of machining by EDM processes. International Journal of Machine Tools & Manufacture 48 2008, s. 746-760
- 24. Mao-sheng L., Guan-xin C., Zhen-long W., Yu-kui W., Li D., Micro electrical discharge machining of small hole in TC4 alloy. Transaction of Nonferrous Metals Society of China 2009, 19, s. 434 - 439
- 25. Mithu M.A.H., Fantoni G., Ciampi J., Santochi M., On how tool geometry, applied frequency and machining parameters influence electrochemical microdrilling. CIRP Journal of Manufacturing Science and Technology 5 2012, s. 202-213
- 26. Munda J., Bhattacharyya B., Investigation into electrochemical micromachining (EMM) through response surface methodology based approach. Int J Adv Manuf Technol 2008, 35, s. 821-832
- 27. Munda J., Malapati M., Bhattacharyya B. , Control of micro-spark and stray-current effect during EMM process. Journal of Materials Processing Technology 194 2007, s. 151-158
- 28. Neto J. C. da S., Silva E. M., Silva M. B., Intervening variables in electrochemical machining. Journal of Materials Processing Technology 2006, 179, s. 92-96
- 29. Ningsong Q., Xiaolei C., Hansong L., Yongbin Z., Electrochemical micromachining of micro-dimple arrays on cylindrical inner surfaces using a dry-film photoresist. Chinese Journal of Aeronautics 2014, 27 (4), s. 1030-1036
- 30. Ozgedik A., Cogun C., An experimental investigation of tool wear in electric discharge machining. Int J Adv Manuf Technol 27 2006 , s. 488-500
- 31. Pham D.T., Dimov S.S., Bigot S., Ivanov A., Popov K.: Micro-EDM-recent developments and research issues. Journal of Materials Processing Technology 2004, 149, s. 50-57
- 32. Porwal R. K., Vinod Yadava V., Ramkumar J., Modelling and multi-response optimization of hole sinking electrical discharge micromachining of titanium alloy thin sheet. Journal of Mechanical Science and Technology 2014, 28 (2), s. 653 - 661
- 33. Rao S. R., Padmanabhan G., Mahesh Naidu K., Rukesh Reddy A., Parametric Study for Radial over Cut in Electrochemical Drilling of Al-5%B4Cp Composites. Procedia Engineering 2014, 97, s. 1004 - 1011
- 34. ReliaSoft Corporation. Life Data Analysis Reference. Weibull++ 7. Reliasoft Publishing. Tucson AZ USA 1999-2007
- 35. Ruszaj A., Skoczypiec S., Kształtowanie mikroelementów obróbką elektrochemiczną i elektroerozyjną. Mechanik 2011, R. 84, nr 12, s. XX-XXI
- 36. Ruszaj A.: Niekonwencjonalne metody wytwarzania maszyn i narzędzi. Instytut Obróbki Skrawaniem IOS, Kraków 1999
- 37. Senthilkumar C., Ganesan G., Karthikeyan R., Study of electrochemical machining characteristics of Al/SiCp composites. Int J Adv Manuf Technol 2009, 43, s. 256-263
- 38. Sharma S., Jain V. K., Shekhar R., Electrochemical Drilling of Inconel Superalloy with Acidified Sodium Chloride Electrolyte. Int J Adv Manuf Technol 2002, 19, s. 492-500
- 39. Shu K.M., Tu G.C., Study of electrical discharge grinding using metal matrix composite electrodes. International Journal of Machine Tools & Manufacture 2003, 43, s. 845-854
- 40. Skoczypiec S., Kozak J., Ruszaj A., Wybrane problemy technologii elektrochemicznej i elektroerozyjnej mikronarzędzi. IM Inżynieria Maszyn 2009, R. 14, z. 1, s. 20-30
- 41. Skoczypiec S., Ruszaj A., A sequential electrochemical-electrodischarge process for micropart manufacturing. Precision Engineering 2014, 38, s. 680-690
- 42. Thanigaivelan R. , Arunachalam R. M., Drukpa P., Drilling of micro-holes on copper using electrochemical micromachining. Int J Adv Manuf Technol 2012, 61, s. 1185-1190
- 43. Wang D., ZhaoW.S., Gu L., Kang X.M., A study on micro-hole machining of polycrystalline diamond by micro-electrical discharge machining. Journal of Materials Processing Technology 2001, 211, s. 1 3-11
- 44. Wang J., Chen W., Gao F., Han F., A new electrode sidewall insulation method in electrochemical drilling. The International Journal Advanced Manufacturing Technology 2014, 75, s. 21-32
- 45. Wang W., Zhu D., Qu N., Huang S., Fang X, Electrochemical drilling inclined holes using wedged electrodes. The International Journal Advanced Manufacturing Technology 2010, 47, s. 1129-1136
- 46. Yonghua L., Kai L., Dongbiao Z., Electrochemical Machining Analysis on Grid Cathode Composed of Square Cells. Chinese Journal of mechanical engineeringVol. 26 2013, No. 4, s. 668 - 674
- 47. Zhu D., Wang W., Fang X.L., Qu N.S., Xu Z.Y., Electrochemical drilling of multiple holes with electrolyte-extraction. CIRP Annals - Manufacturing Technology 2010, 59, s. 239-242
- 48. Zilong P., Zhenlong W., Yinghuai D., Hui C.: Development of a reversible machining method for fabrication of microstructures by using micro-EDM. Journal of Materials Processing Technology 2010, 210, s. 129 - 136
Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.ekon-element-000171587698