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Erschienen in:

2018 | OriginalPaper | Buchkapitel

Surface Treatment of AISI 304 Using Pulsating Water Jet Peening

verfasst von : Madhulika Srivastava, Rupam Tripathi, Sergej Hloch, Ayush Rajput, Drupad Khublani, Somnath Chattopadhyaya, Amit Rai Dixit, Josef Foldyna, Pavel Adamčík, Jiri Klich, Michal Zelenak, Dagmar Klichová

Erschienen in: Applications of Fluid Dynamics

Verlag: Springer Singapore

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Abstract

Water jet peening has gained attention as a potential surface treatment process for improving the fatigue life of a component. The tensile residual stress in the component initiates the stress corrosion cracking and reduces its fatigue life. The mitigation of this tensile residual stress can be effectively achieved by water jet peening process due to its resistance to corrosion, flexibility in treating complex areas and capability to maintain the eco-friendly environment. In the present work, the AISI 304 plates were treated with pulsating water jet (actuator frequency f = 20.19 Hz) at the pressure of p = 20 MPa with traverse speed of v = 0.5 mm/s and v = 2.5 mm/s using two different types of nozzles; flat nozzle of diameter d = 1 mm (HAMMELMANN) and circular nozzle of diameter d = 1.9 mm (STONEAGE). The microstructural analysis of the treated and untreated region was conducted to analyse the effect of traverse speed and the type of nozzle on the erosion process. The study revealed that more erosion occurs at lower traverse speed; however, fewer surface depressions were observed in the case of flat nozzles. The X-ray diffraction technique was also used to analyse the effect of traverse speed and the type of nozzle on the residual stress of the samples. In addition to this, the acoustic emission during the ongoing process was monitored using LabView 2012 SP1 f5 ver. 12.0.1. The results indicate that acoustically monitored pulsating water jet peening process can be used as tool for the controlled local treatment process arising from the impact of the pulsed water jet on the surface of sample.

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Akbari P, Shafii MB (2002) Numerical simulation of an impinging water jet applied to cooling human skin. In: Proceedings of 21st international congress on applications of laser and electro-optics (ICALEO), 11 p

Arola D, McCain ML, Kunaporn S (2001) Waterjet and abrasive waterjet surface treatment of titanium: a comparison of surface texture and residual stress. Wear 249(10–11):943–950CrossRef

Chen L (2008) Study on prediction of surface quality in machining process. J Mater Process Technol 205:439–450CrossRef

Chen CC, Chiang KT, Chou CC, Liao YC (2011) The use of D-optimal design for modelling and analysing the vibration and surface roughness in the precision turning with a diamond cutting tool. Int J Adv Manuf Technol 54:465–478CrossRef

Colosimo BM, Monno M, Semeraro Q (2000) Process parameters control in water jet peening. Intern J Mater Product Technol 15(1–2):10–19CrossRef

Ding K, Ye L (2006) Simulation of multiple laser shock peening of a 35CD4 steel alloy. J Mater Process Technol 178:162–169CrossRef

Eftekhari A, Talia JE, Mazumdar PK (1995) Influence of surface condition on the fatigue of an aluminium-lithium alloy (2090-T3). Mater Sci Engg A 199:L3–L6CrossRef

Foldyna J (2011) Use of acoustic waves for pulsating water jet generation. In: Beghi MG (ed) Acoustic waves—from microdevicse to helioseisomology. Intech, pp 323–342

Foldyna J, Sitek L, Svehla B, Svehla S (2004) Utilization of ultrasound to enhance high-speed water jet effects. Ultrason Sonochem 11 3(4):131–137

Foldyna J, Sitek L, Scucka J, Martinec P, Valicek J, Palenikova K (2009) Effects of pulsating water jet impact on aluminium surface. J Mater Process Technol 209(20):6174–6180CrossRef

Foldyna J, Klich J, Hlavacek P, Zelenak M, Scucka J (2012) Erosion of metals by pulsating water jet. Tehnički vjesnik 19(2):381–386

Hashimoto T, Osawa Y, Itoh S, Mochizuki M, Nishimoto K (2013) Long-term stability of residual stress improvement by water jet peening considering working processes. J Press Vessel Technol 135:1–8CrossRef

Hashish M, Chillman A, Ramulu M (2005) Waterjet peening at 600 MPa: a first Investigation. In: Fluids engineering division, vol 261. The American Society of Mechanical Engineers, pp 45–52

Hassan AI, Chen C, Kovacevic R (2004) On-line monitoring of depth of cut in AWJ cutting. Int J Mach Tool Manuf 44:595–605CrossRef

Hloch S, Folydna J, Sitek L, Zelenak M, Hlavacek P, Hvizdos P, Kloc J, Monka P, Monkova K, Kozak D, Magurova D (2013a) Disintegration of bone cement by continuous and pulsating water jet. Tehnički vjesnik 20(4):593–598

Hloch S, Valicek J, Kozak D (2013b) Analysis of acoustic emission emerging during hydroabrasive cutting and options for indirect quality control. Int J Adv Manuf Technol 66(1–4):45–58CrossRef

Hnizdil M, Raudensky M (2010) Descaling by pulsating water jet. In: Proceedings of metal 19th international conference metallurgy and materials, pp 209–213

Hreha P, Hloch S, Peržel V (2012) Analysis of acoustic emission recorded during monitoring of abrasive waterjet cutting of stainless steel AISI 309. Tehnički vjesnik 19(2):355–359

Hreha P, Radvanska A, Hloch S, Perzel V, Krolczyk G, Monkova K (2015) Determination of vibration frequency depending on abrasive mass flow rate during abrasive water jet cutting. Int J Adv Manuf Technol 77:763–774CrossRef

Lehocka D, Klich J, Foldyna J, Hloch S, Krolczyk JB, Carach J, Krolczyk GM (2016) Copper alloys disintegration using pulsating water jet. Measurement 82:375–383CrossRef

Mahmoudi AH, Salahi F, Ghasemi A (2016) Comparison between residual stress induced by waterjet peening and shot peening. In: International conference on surface modification technologies

Meguid SA, Shagal G, Stranart JC (1999) Finite element modelling of shot-peening residual stresses. J Mater Process Technol 92–93:401–404CrossRefMATH

Mochizuki M, Enomoto K, Sakata S, Kurosawa K, Saito H, Tsujimura H, Ichie K (1993) A study on residual stress improvement by water jet peening. In: Proceedings of the 5th international conference on shot peening. Oxford, pp 247–256

Natarajan C, Muthu S, Karuppuswamy P (2011) Prediction and analysis of surface roughness characteristics of a non-ferrous material using ANN in CNC turning. Int J Adv Manuf Technol 57(9):1043–1051CrossRef

Ramulu M, Kunaporn S, Arola D (2000) Water jet machining and peening of metals. J Press Vessel Technol-Trans ASME 122(1):90–95CrossRef

Salak A, Vasilko K, Selecka M (2006) New short time face turning method for testing the machinability of PM steels. J Mater Process Technol 176:62–69CrossRef

Sharma V (2011) Multi response optimization of process parameters based on Taguchi-Fuzzy model for coal cutting by water jet technology. Int J Adv Manuf Technol 56:1019–1025CrossRef

Sharma NC, Lyle DM, Qaqish JG, Galustians J, Schuller R (2008) The effect of a dental water jet with orthodontic tip on plaque and bleeding in adolescent patients with fixed orthodontic appliances. Am J Orthod Dentofac Orthop 133(4):565–571CrossRef

Srivastava M, Tripathi R, Hloch S, Chattopadhyaya S, Dixit AR (2016) Potential of using water jet peening as a surface treatment process for welded joints. Procedia Eng 149:472–480CrossRef

Tripathi R, Srivastava M, Hloch S, Adamčík P, Chattopadhyaya S, Das AK (2016) Monitoring of acoustic emission during the disintegration of rock. Procedia Eng 149:481–488CrossRef

Valicek J, Hloch S (2010) Using the acoustic sound pressure level for quality prediction of surfaces created by abrasive waterjet. Int J Adv Manuf Technol 48:193–203CrossRef

Vijay MM, Foldyna J (1994) Ultrasonically modulated pulsed jets: basic study. In: Proceeding of the 12th international conference on jet cutting technology. Rouen, France

Zelenak M, Foldyna J, Scucka J, Hloch S, Riha Z (2015) Visualisation and measurement of high-speed pulsating and continuous water jets. Measurement 72:1–8CrossRef

Titel: Surface Treatment of AISI 304 Using Pulsating Water Jet Peening
verfasst von: Madhulika Srivastava
Rupam Tripathi
Sergej Hloch
Ayush Rajput
Drupad Khublani
Somnath Chattopadhyaya
Amit Rai Dixit
Josef Foldyna
Pavel Adamčík
Jiri Klich
Michal Zelenak
Dagmar Klichová
Verlag: Springer Singapore
Buch: Applications of Fluid Dynamics
Print ISBN: 978-981-10-5328-3

Electronic ISBN: 978-981-10-5329-0

Copyright-Jahr: 2018
DOI: https://doi.org/10.1007/978-981-10-5329-0_40

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