Abstract
Paper deals with copper CW004A deformation characteristics evaluation after pulsating water jet disintegration. Experimental samples were prepared from copper CW004A with marking A, B, and C. As variable factors were selected combinations of pressure of pump pressure and nozzle diameter: A (p = 65 MPa; d = 1.067 mm), B (p = 49 MPa; d = 1.321 mm), C (p = 38 MPa; d = 1.600 mm). Surface topography was evaluated using optical profilometry. Microhardness measurement was measured using Vickers indenter. Hardness measurement was performed on seventeen points under disintegrated area in distance from 0.1 to 3 mm. Measured values indicate slight increase of strain hardening undercutting area.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Kumar, R., Chattopadhyaya, S., Dixit, A.R., Bora, B., Zelenak, M., Foldyna, J., et al.: Surface integrity analysis of abrasive water jet-cut surfaces of friction stir welded joints. Int J Adv Manuf Technol. 88, ISSN 1687–1701 (2017)
Hlaváček, P., Cárach, J., Hloch, S., Vasilko, K., Klichová, D., Klich, J., et al.: Sandstone turning by abrasive waterjet. Rock Mech. Rock Eng. 48, ISSN 2489–93 (2015)
Hloch, S., Hlaváček, J., Vasilko, K., Cárach, J., Samardžić, I., Kozak, D., et al.: Abrasive waterjet (AWJ) titanium tangential turning evaluation. Metalurgija. 53, 537–540 (2014)
Zhong, Z.W., Han, Z.Z.: Turning of glass with abrasive waterjet. Mater Manuf. Process. 17, 339–349 (2002)
Yue, Z., Huang, C., Zhu, H., Wang, J., Yao, P., Liu, Z.: Optimization of machining parameters in the abrasive waterjet turning of alumina ceramic based on the response surface methodology. Int. J. Adv. Manuf. Technol. 71, 2107–2114 (2014)
Lissek, F., Kaufeld, M., Tegas, J., Hloch, S.: Online-monitoring for abrasive waterjet cutting of CFRP via acoustic emission: Evaluation of machining parameters and work piece quality due to burst analysis. Proced. Eng. 149, 67–76 (2016)
Botko, F., Hatala, M., Kormoš, M., Ungureanu, N., Šoltés, P.: Using Edgecam for creating CNC programs in education process. In: SAMI 2015. Danvers: IEEE, pp. 255–259, ISBN 978-1-4799-8220-2 (2015)
Duplak, J., Hatala, M., Botko, F., Kormos, M.: Analysis of cutting tools durability importance in turning process of steel C60. In: Key Engineering Materials: Operation and Diagnostics of Machines And Production Systems Operational States 3., Vol. 669, pp. 319–326 (2016)
Kušnerová, M., Foldyna, J., Sitek, L., Valíček, J., Hloch, S., Harničárová, M., et al.: Innovative approach to advanced modulated waterjet technology. Inovativni pristup naprednoj moduliranoj tehnologiji vodenog mlaza. Teh Vjesn 19, 475–480 (2012)
Zelenak, M., Foldyna, J., Scucka, J., Hloch, S., Riha, Z.: Visualisation and measurement of high-speed pulsating and continuous water jets. Meas J Int Meas Confed. 71, 1–8 (2015)
Vijay M.M., Foldyna J., Remisz J.: Ultrasonic modulation of high-speed water jets. Int Conf: Geomech. 93, 327–332 (1994)
Říha, Z., Foldyna, J., Ultrasonic pulsations of pressure in a water jet cutting tool. Ultrazvučne pulzacije tlaka u alatu za rezanje vodenim mlazom. Teh Vjesn 19, 487–491 (2012)
Foldyna, J., Sitek, L., Švehla, B., Švehla, S., Utilization of ultrasound to enhance high-speed water jet effects. Ultrason Sonochem 11, 131–137 (2004)
Foldyna, J., Klich, J., Hlavacek, P., Zelenak, M., Scucka, J.: Erosion of Metals by Pulsating Water Jet. Teh Vjesn Gaz 19, 381–386 (2012)
Foldyna, J., Sitek, L., Ščučka, J., Martinec, P., Valíček, J., Páleníková, K.: Effects of pulsating water jet impact on aluminium surface. J. Mater Process Technol. 209, 6174–6180 (2009)
Sitek, L., Foldyna, J., Souček, K.: Shaping of rock specimens for testing of uniaxial tensile strength by high speed abrasive water jet: First experience. In: Impact of Human Activity on the Geological Environment—Proceedings of International Symposium International Society for Rock Mechanics Eurock 2005 (2005)
Sitek, L., Foldyna, J., Martinec, P., Ščučka, J., Bodnárová, L., Hela, R.: Use of pulsating water jet technology for removal of concrete in repair of concrete structures. Baltic J. Road Bridge Eng. 6, 235–242 (2011)
Dehkhoda, S., Hood, M.: An experimental study of surface and sub-surface damage in pulsed water-jet breakage of rocks. Int. J. Rock Mech. Min. Sci. 63, 138–147 (2013)
Bortolussi A., et al.: Ornamental stones surface finishing by pulsating jet: A project for an industrial application. In: Water Jet 2013—Research, Development, Applications, pp. 17–24, ISBN 978-80-86407-43-2 (2013)
Hloch, S., Foldyna, J., Pude, F., Kľoc, J., Zeleňák, M., Hvizdoš, P., et al.: Experimental in-vitro bone cements disintegration with ultrasonic pulsating water jet for revision arthroplasty. Teh Vjesn Tech Gaz 22, 1609–1615 (2015)
Lehocka, D., Klich, J., Foldyna, J., Hloch, S., Krolczyk, J.B., Carach, J., et al.: Copper alloys disintegration using pulsating water jet. Meas J. Int. Meas Confed. 82, 375–383 (2016)
Lehocka, D., Klich, J., Foldyna, J., Hloch, S., Hvizdoś, P., Fides, M., et al.: Surface integrity evaluation of brass CW614N after impact of acoustically excited pulsating water jet. Procedia Eng. 149, 236–244 (2016)
Acknowledgements
This work was supported by the Slovak Research and Development Agency under Contract No. APVV-207-12. Experiments were carried out with the support of the Institute of Clean Technologies for Mining and Utilization of Raw Materials for Energy Use–Sustainability Program, reg. no. LO1406 financed by Ministry of Education, Youth, and Sports of the Czech Republic, and with support for the long-term conceptual development of the research institution RVO: 68145535.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2018 Springer International Publishing AG
About this paper
Cite this paper
Lehocka, D., Simkulet, V., Legutko, S. (2018). Assessment of Deformation Characteristics on CW004A Copper Influenced by Acoustically Enhanced Water Jet. In: Hamrol, A., Ciszak, O., Legutko, S., Jurczyk, M. (eds) Advances in Manufacturing. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-319-68619-6_69
Download citation
DOI: https://doi.org/10.1007/978-3-319-68619-6_69
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-68618-9
Online ISBN: 978-3-319-68619-6
eBook Packages: EngineeringEngineering (R0)