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The paper deals with a study of relations between the measured Ra, Rq, Rz surface roughness parameters, the traverse speed of cutting head v and the vibration parameters, PtP, RMS, vRa, generated during abrasive water jet cutting of the AISI 309 stainless steel. Equations for prediction of the surface roughness parameters were derived according to the vibration parameter and the traverse speed of cutting head. Accuracy of the equations is described according to the Euclidean distances. The results are suitable for an on-line control model simulating abrasive water jet cutting and machining using an accompanying physical phenomenon for the process control which eliminates intervention of the operator.
Czasopismo
Rocznik
Tom
Strony
315--326
Opis fizyczny
Bibliogr. 26 poz., rys., tab., wykr.
Twórcy
autor
- Faculty of Manufacturing Technologies TUKE with a seat in Prešov, Bayerova 1, 080 01 Prešov
autor
- Faculty of Manufacturing Technologies TUKE with a seat in Prešov, Bayerova 1, 080 01 Prešov
autor
- Faculty of Manufacturing Technologies TUKE with a seat in Prešov, Bayerova 1, 080 01 Prešov
autor
- Opole University of Technology, Faculty of Production Engineering and Logistics, Prószkowska 76, 45-758 Opole, Poland
autor
- Poznań University of Technology, Faculty of Mechanical Engineering and Management, Piotrowo 3, 60-965 Poznań, Poland
autor
- Opole University of Technology, Faculty of Production Engineering and Logistics, Prószkowska 76, 45-758 Opole, Poland
autor
- Faculty of Manufacturing Technologies TUKE with a seat in Prešov, Bayerova 1, 080 01 Prešov
- Institute of Geonics AS CR, v. v. i., Studentska 1768, Ostrava-Poruba, 708 00
autor
- Faculty of Manufacturing Technologies TUKE with a seat in Prešov, Bayerova 1, 080 01 Prešov
Bibliografia
- [1] Królczyk, G.M., Niesłony, P., Legutko, S. (2015). Determination of tool life and research wear during duplex stainless steel turning. Archives of Civil and Mechanical Engineering, 15(2), 347-354.
- [2] Foldyna, J. Sitek, L., Scucka, J., Martinec, P., Valicek, J., Palenikova, K. (2009). Effects of pulsating water jet impact on aluminium surface. Journal of Materials Processing Technology, 209, 6174-6180.
- [3] Sharma, V., Chattopadhyaya, S., Hloch, S. (2011). Multi response optimization of process parameters based on Taguchi-Fuzzy model for coal cutting by water jet technology. The Inter. J. of Adv. Manufact. Tech., 56(9-12), 1019-1025.
- [4] Foldyna, J., Klich, J., Hlavacek, P., Zelenak, M., Scucka, J. (2012). Erosion of metals by pulsating water jet.Tehnički vjesnik, 19, 381-386.
- [5] Riha, Z., Foldyna, J. (2012). Ultrasonic pulsation of pressure in a water jet cutting tool. Tehnički vjesnik, 19, 487-491.
- [6] Hreha, P., Radvanská A., Hloch S., Peržel V., Królczyk G., Monková K. (2015). Determination of vibration frequency depending on abrasive mass flow rate during abrasive water jet cutting. The Inter. J. of Advan. Manufact. Tech., 77, 763-774.
- [7] Wilcox, S.J., Reuben, R.L., Souquet, P. (1997). The use of cutting force and acoustic emission signals for the monitoring of tool insert geometry during rough face milling. Inter. J. of Mach. Tools and Manufact., 37(4), 481-494.
- [8] Monno, M., Ravasio, C. (2005). The effect of cutting head vibrations on the surfaces generated by waterjet cutting. Intern. J. of Mach. Tools and Manufact., 45(3), 355-363.
- [9] Perzel, V., Hreha, V., Hloch, S, Tozan, H., Valicek, J. (2011). Vibration emission as a potential source of information for abrasive waterjet quality process control. The Intern. J. of Advan. Manufact. Tech., 61(1-4), 285-294.
- [10] He, W., Xu, G., Rong, Z., Li, G., Liu, M. (2014). Automatic calibration system for digital - display vibrometers based on machine vision. Metrol. Meas. Syst., 21(2), 317-328.
- [11] Tonshoff, H.K., Jung, M., Männel, S., Reitz, W. (2000). Using acoustic emission signals for monitoring of production processes. Ultrasonics, 37, 681-686.
- [12] Babu, M., K., Chetty, O.V.K., (2002). Studies on recharging of abrasives in abrasive water jet machining. The Inter. J. of Advan. Manufact. Tech., 19, 697-703.
- [13] Brezina, I. (1991). Surface roughness, importance of roughness quantify - metrology aspects – development trends. Jo.of Fine Mech. Opt., 7, 245-255.
- [14] Arola, D. Ramulu, M. (1997). Material removal in abrasive waterjet machining of metals surface integrity and texture. Wear, 210, 50-58.
- [15] Azmir, M.A., Ahsan, A.K. (2008). Investigation on glass/epoxy composite surfaces machined by abrasive water jet machining. J. of Mater. Proc. Tech., 198, 122-128.
- [16] Bitter, J. (1963). A study of erosion phenomena. Part I. Wear, 6, 5-21.
- [17] Boud, F., Carpenter, C, Folkes, J, Shipway, P.H. (2010). Abrasive waterjet cutting of a titanium alloy: The influence of abrasive morphology and mechanical properties on workpiece grit embedment and cut quality. J. of Mater. Proce. Tech., 210, 2197-2205.
- [18] Kong, M.C., Axinte, D., Voice, W. (2010). Aspects of material removal mechanism in plain waterjet milling on gamma titanium aluminide. J. of Mater. Proc. Tech., 210, 573-584.
- [19] Fowler, G., Pashby, I.R., Shipway, P.H., (2009). The effect of particle hardness and shape when abrasive water jet milling titanium alloy Ti6Al4V. Wear, 266, 613-620.
- [20] Hashish, M. (1991). Optimization factors in abrasive waterjet machining. Journal of Engineering for Industry-Transactions of the ASME, 113, 9-37.
- [21] Vikram, G., Babu, N.R. (2002). Modelling and analysis of abrasive water jet cut surface topography. Intern. J. of Machine Tools and Manufact., 42, 1345-1354.
- [22] Chiffre De L., Lonardo, P., Trumpold, H., Lucca, D.A., Goch, G., Brown, C.A., Raja, J. Hansen, H.N. (2000). Quantitative characterisation of surface texture. Annals of the CIRP, 49(2), 635-642.
- [23] Kovacevic, R. (1992). Monitoring the depth of abrasive waterjet penetration. Inter. J. of Machine Tools and Manufacture, 32(5), 725-736.
- [24] Momber, A.W., Mohan, R.S., Kovacevic, R. (1999). On-line analysis of hydro-abrasive erosion of precracked materials by acoustic emission. Theoretical and Applied Fracture Mechanics, 17(31), 1-17.
- [25] Ravishankar, S.R., Murthy, C.R.L. (2000). Application of acoustic emission in drilling of composite laminates.NDT&E International, 33, 101-110.
- [26] Asraf, I., Hassan, A.I., Chen, C., Kovacevic, R. (2004). On-line monitoring of depth of cut in AWJ cutting. Intern. J. of Machine Tools and Manufact., 44, 595-605.
Uwagi
EN
This work was supported by the Slovak Research and Development Agency under the contract No. APVV-207-12 and VEGA 1/0972/11. The measurements have been carried out with a support of the Institute of clean technologies for mining and utilization of raw materials for energy use, Reg. No. CZ.1.05/2.1.00/03.0082 supported by the Research and Development for Innovations Operational Programme financed by the Structural Funds of the European Union and the State budget of the Czech Republic, and with a support for the long term conceptual development of the research institution RVO: 68145535.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-063188a4-b163-4a0a-98bf-142501a6258b