The Academic Perspective Procedia publishes Academic Platform symposiums papers as three volumes in a year. DOI number is given to all of our papers.
Publisher : Academic Perspective
Journal DOI : 10.33793/acperpro
Journal eISSN : 2667-5862
 Gong, H., Wang, S., Knysh, P., Korkolis, Y.B. (2016) “Experimental investigation of the mechanical response of laser-welded dissimilar blanks from advanced- and ultra-high-strength steels”, Materials and Design 90, 1115–1123.
 J.H. Lee, S.H. Park, H.S. Kwon, G.S. Kim, C.S. Lee, (2014) “Laser, tungsten inert gas, and metal active gas welding of DP780 steel: comparison of hardness, tensile properties and fatigue resistance”, Mater. Des. 64, 559–565.
 Xing, F., Qiu, X., Zhao, L., Ruan, Y., Wang, D. (2019) “Hardening, Softening, and Mechanical Properties in Ultra-High-Strength DP1180 Tailor-Welded Blanks” Journal of Materials Engineering and Performance volume 28, 2086–2093.
 Razmpoosh, M.H., Macwan, A., Biro, E., Zhou, Y. (2020) “Microstructure and dynamic tensile characteristics of dissimilar fiber laser welded advanced high strength steels” Materials Science & Engineering A 773, 138729.
 Yuce, C., Tutar, M., Karpat, F., Yavuz, N. (2016) “The Optimization of Process Parameters and Microstructural Characterization of Fiber Laser Welded Dissimilar HSLA and MART Steel Joints”, Metals 6, 245.
 Y. Zhao, Y. Zhang, W. Hu, Effect of welding speed on microstructure, hardness and tensile properties in laser welding of advanced high strength steel, Sci. Technol. Weld. Join. 18 (7) (2013) 581–590.
 Bachmann, M. Gumenyuk, A., Rethmeier, M. (2016) “Welding with High-power Lasers: Trends and Developments”, Physics Procedia, 83, 15-25.
 Goebel, G., Brenner, B., Beyer, E., (2007) “New application possibilities for fiber laser welding”, ICALEO 2007-26th International Congress on Application of Lasers & Electro-Optics, Orlando (FL) USA.
 Grünenwald, S., Unt, A., Salminen, A. (2018), “Investigation of the influence of welding parameters on the weld geometry when welding structural steel with oscillated high-power laser beam”, Procedia CIRP 74, 461–465.
 Schultz, V., Seefeld, T., Vollertsen, F. (2014) “Gap bridging ability in laser beam welding of thin aluminum sheets”, Physics Procedia 56, 545 – 553.
 Hao, K.; Li, G.; Gao, M.; Zeng, X. (2015) “Weld formation mechanism of fiber laser oscillating welding of austenitic stainless steel”, J. Mater. Process. Technol. 225, 77–83.
 Wang, L.; Gao, M.; Zhang, C.; Zeng, X. Effect of beam oscillating pattern on weld characterization of laser welding of AA6061-T6 aluminum alloy. Mater. Des. 2016, 108, 707–717.
 Wang, L.; Gao, M.; Zeng, X. (2019) “Experiment and prediction of weld morphology for laser oscillating welding of AA6061 aluminium alloy”, Sci. Technol. Weld. Join. 2019, 24, 334–341.
 Kuryntsev, S., Gilmutdinov, A.K. (2015), “The effect of laser beam wobbling mode in welding process for structural steels”, Int J Adv Manuf Technol. 81:1683–1691.
 Fetzer, F., Sommer, M., Weber, R., Weberpals, J., Graf, T. (2018) “Reduction of pores by means of laser beam oscillation during remote welding of AlMgSi”, Optics and Lasers in Engineering 108, 68–77.