Surface integrity in broaching of AA 7075-T651 aluminum alloys

References

• ASM Metals Handbook (1997) Vol. 16 Machining, ASM Handbook Committee: 3rd Edition, USA.
   Google Scholar
• ASTM E384-16 (2016) Standard Test Method for Microindentation Hardness of Materials. American Society for Testing and Materials, West Conshohocken, 405–440. Available: https://www.astm.org/DATABASE.CART/HISTORICAL/E384-16.htm.
   Google Scholar
• Bonnardel, Q.; Wagner, V.; Dessein, G.; Dutilh, V.; Mandrile, S. (2017) Effects of cutting parameters over turning of UDIMET 720 superalloy in a broaching process simulation. Procedia CIRP, 58: 572–577.
   Google Scholar
• Chen, Z.; Peng, R.L.; Moverare, J.; Avdovic, P.; Zhou, J.M.; Johansson, S. (2016) Surface integrity and structural stability of broached Inconel 718 at high temperatures. Metallurgical and Materials Transactions A, 47: 3664–3676.
   Google Scholar
• Davim, J.P. (2010) Surface Integrity in Machining, Springer Science & Business Media, London, Berlin, Germany.
   Google Scholar
• Ertunga, C.; Öztürk, Ö.Ö.; Budak, E. (2011) Identifying parameters of a broaching design using non-linear optimization. International Journal of Modelling, Identification and Control, 12: 244–252.
   Google Scholar
• Gonçalves, D.A.; Schroeter, R.B. (2016) Modeling and simulation of the geometry and forces associated with the helical broaching process. International Journal of Advanced Manufacturing Technology, 83: 205–215.
   Web of Science ®Google Scholar
• He, G.; Zhang, Y.Z. (1985) Experimental investigations of the surface integrity of broached titanium alloy. CIRP Annals: Manufacturing Technology, 34: 491–494.
   Google Scholar
• Hosseini, A.; Kishawy, H.A. (2014) On the optimized design of broaching tools. Journal of Manufacturing Science and Engineering, 136: 011011-1–011011-10. doi: 10.1115/1.4025415.
   Web of Science ®Google Scholar
• Hosseini, A.; Kishawy, H.A.; Moetakef-Imani, B. (2016) Effects of broaching operations on the integrity of machined surface. Procedia CIRP, 45: 163–166.
   Google Scholar
• Kishawy, H.A.; Hosseini, A.; Moetakef-Imani, B.V.; Astakhov, P. (2012) An energy based analysis of broaching operation: cutting forces and resultant surface integrity. CIRP Annals: Manufacturing Technology, 61: 107–110.
   Web of Science ®Google Scholar
• Klocke, F.; Vogtel, P.; Gierlings, S.; Lung, D.; Veselovac, D. (2013) Broaching of Inconel 718 with cemented carbide. Production Engineering Research and Development, 7: 593–600.
   Google Scholar
• Klocke, F.; Döbbeler, B.; Seimann, M. (2016) Dry broaching using carbon free steel as tool material. Procedia CIRP, 46: 496–499.
   Google Scholar
• Klocke, F.; Gierlings, S.; Brockmann, M.; Veselovac, D. (2014) Force based temperature modeling for surface integrity prediction in broaching nickel-based alloys. Procedia CIRP, 13: 1–10.
   Google Scholar
• Kokturk, U.; Budak, E. (2004) Optimization of broaching tool design. In Intelligent Computation in Manufacturing Engineering (ICME 04), Proceeding of the CIRP, Sorrento, Italy, Teti, R.; Minutolo, F.C.; D'Addona, D.; Segreto, T. (Eds.), 1–6.
   Google Scholar
• Liu, G.; Huang, C.; Zou, B.; Wang, X.; Liu, Z. (2016) Surface integrity and fatigue performance of 17-4PH stainless steel after cutting operations. Surface and Coatings Technology, 307: 182–189.
   Web of Science ®Google Scholar
• Makarov, V.F.; Tokarev, D.I.; Tyktamishev, V.R. (2008) High speed broaching of hard machining materials. International Journal of Material Forming, 1: 547–550.
   Web of Science ®Google Scholar
• Makarov, V.F.; Tuktamyshev, V.R. (2010) Numerical modelling of high speed broaching multitoothes broaches. International Journal of Material Forming, 3: 523–526.
   Web of Science ®Google Scholar
• Meier, H.; Ninomiya, K.; Dornfeld, D.; Schulze, V. (2014) Hard broaching of case hardened SAE 5120. Procedia CIRP, 14: 60–65.
   Google Scholar
• Mo, S.P.; Axinte, D.A.; Hyde, T.H.; Gindy, N.N.Z. (2005) An example of selection of the cutting conditions in broaching of heat-resistant alloys based on cutting forces, surface roughness and tool wear. Journal of Materials Processing Technology, 160: 382–389.
   Web of Science ®Google Scholar
• Ni, J.; Li, B.; Xu, J.; Li, L. (2016) Investigation on broaching performance and unloading mechanism of micro-textured broach. International Journal of Advanced Manufacturing Technology, 86: 2449–2458.
   Web of Science ®Google Scholar
• Oberg, E. (2012) Machinery’s Handbook, 29th Edition. Industrial Press, Norwalk.
   Google Scholar
• Schulze, V.; Meier, H.; Strauss, T.; Gibmeier, J. (2012) High speed broaching of case hardening steel SAE 5120. Procedia CIRP, 1: 431–436.
   Google Scholar
• Stephenson, D.A.; Agapiou, J.S. (2016) Metal Cutting Theory and Practice, 3rd Edition. CRC Press, Florida, 395–411.
   Google Scholar
• Vogtel, P.; Klocke, F.; Lung, D.; Terzi, S. (2015) Automatic broaching tool design by technological and geometrical optimization. Procedia CIRP, 33: 496–501.
   Google Scholar
• Yao, C.F.; Tan, L.; Ren, J.X.; Lin, Q.; Liang, Y.S. (2014) Surface integrity and fatigue behavior for high-speed milling Ti–10V–2Fe–3Al titanium alloy. Journal of Failure Analysis and Prevention, 14: 102–112.
   Google Scholar
• Yao, C.F.; Zuo, W.; Wu, D.; Ren, J.; Zhang, D. (2015) Control rules of surface integrity and formation of metamorphic layer in high-speed milling of 7055 aluminum alloy. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 229: 187–204.
   Web of Science ®Google Scholar
• Zanger, F.; Boev, N.; Schulze, V. (2014) Surface quality after broaching with variable cutting thickness. Procedia CIRP, 13: 114–119.
   Google Scholar