References
- Collision safety performance assessment technologies to protect people in crashes. 3. Japan New Car Assessment Program; 2020.
- Oikawa H, Murayama G, Hiwatashi S, et al. Resistance spot weldability of high strength steel sheets for automobiles and the quality assurance of joints. Weld World. 2007;51(3–4):7–18.
- Furusako S, Watanabe F, Murayama G, et al. Current problems and the answer techniques in welding technique of auto bodies – first part. Nippon Steel Tech Rep. 2013;103:69–75.
- Watanabe F, Furusako S, Hamatani H, et al. Fracture mechanical analysis of cross tension test for high-strength spot welded joints. Math Model Weld Phenom. 2012;10:653–667.
- Hamatani H, Watanabe F, Miyazaki Y, et al. Characterization of cross tension strength in resistance spot welding ultrahigh strength steel sheets. Preprints Natl Meet JWS. 2011;89:44–45. (in Japanese)
- Furusako S, Miyazaki Y, Hamatani H, et al. Dependence of strength and fracture behavior on chemical compositions in spot-welded L-type joints. Q J Jpn Weld Soc. 2015;33(2):133–143. (in Japanese)
- WES 7301: recommended practice for spot welding (low carbon steel and low alloy steel); 1986.
- Wakabayashi C, Yasuyama M, Furusako S, et al. Spot-welded joint-strength improvement by acceleration of auto-tempering at HAZ. Preprints Natl Meet JWS. 2015;96:38–39. (in Japanese)
- Taniguchi K, Matsuda H, Ikeda R, et al. Heat distribution in weld by short-time high-current post-heating and its improving effect on cross tension strength–development of resistance spot welding with pulsed current pattern for ultra high strength steel sheets. Q J Jpn Weld Soc. 2014;32(3):164–171. (in Japanese)
- Sakiyama T, Murayama G, Naito Y, et al. Dissimilar metal joining technologies for steel sheet and aluminum alloy sheet in auto body. Nippon Steel Tech Rep. 2013;103:91–98.
- Meschut G, Hahn O, Janzen V, et al. Innovative joining technologies for multi-material structures. Weld World. 2014;58(1):65–75.
- Nentwig AWE, Jenicek A. Research into the possible applications of friction stud welding. Weld Res Abroad. 1996;42(2):36–40.
- Cai W, Daehn G, Vivek A, et al. A state-of-the-art review on solid-state metal joining. J Manuf Sci Eng. 2019;141:031012–1–031012-35.
- Folgar Ribadas H, Böddeker T, Chergui A, et al. Joining TWIP-steel simulation models. Proc Struct Integr. 2017;5:516–523.
- Papadimitriou I, Efthymiadis P, Kotadia HR, et al. Joining TWIP to TWIP and TWIP to aluminum: a comparative study between joining process, joint properties and mechanical performance. J Manuf Process. 2017;30:195–207.
- Absar S, Ruszkiewicz BJ, Skovron JD, et al. Temperature measurement in friction element welding process with micro thin film thermocouples. Proc Manuf. 2018;26:485–494.
- Varma A. Thermal mechanical numerical modeling of friction element welding. All Theses. 2018;3021:1–99.
- Ruszkiewicz BJ, Skovron JD, Absar S, et al. Parameter sensitivity and process time reduction for friction element welding of 6061-T6 aluminum to 1500 MPa press-hardened steel. SAE Int J Mater Manf. 2018;12(1):41–56.
- Oliveira JP, Ponder K, Brizes E, et al. Combining resistance spot welding and friction element welding for dissimilar joining of aluminum to high strength steels. J Mater Process Tech. 2019;273:1–10.
- Grimm TJ, Varma A, Deshpande AB, et al. Characterization of aluminum flow during friction element welding. Proc Manuf. 2021;53:107–117.
- Takegami H, Shinoda T, Saito T, et al. Friction welding of pipe to plate – estimate of heat input and comparison with MAG welding. Q J Jpn Weld Soc. 2003;21(2):310–315. (in Japanese)
- Kawai G, Ochi H, Morikawa K, et al. Strength of carbon steel stud joints by friction welding. J Jpn Soc Strength Fract Mater. 2009;43(2):37–41. (in Japanese)
- Kimura M, Saito H, Kusaka M, et al. Stud shape and joint strength for low carbon steel joints fabricated by friction stud welding with low load force requirement. Q J Jpn Weld Soc. 2021;39(3):141–150. (in Japanese)
- Hayashi K, Miyata K, Katsuki F. Deformation behavior in high-strength dual-phase steel sheets during bend forming. Tetsu-to-Hanage. 2012;98(6):82–88. (in Japanese)
- Nakada N, Nishiyama M, Koga N, et al. Hierarchical strain distribution analysis formed in DP steel using a combination of metallographic image and digital image correlation method. Tetsu-to-Hanage. 2014;100(10):58–65. (in Japanese)
- Hasegawa K, Kawamura K, Urabe T, et al. Effect of microstructure on stretch-flange-formability of 980MPa grade cold-rolled ultra high strength steel sheets. ISIJ Int. 2004;44(3):603–609.
- Shirasawa H, Tanaka Y, Korida K. Effect of continuous annealing thermal pattern on strength and ductility of cold rolled dual phase steel. Tetsu-to-Hagane. 1988;74(2):326–333. (in Japanese)
- Ishiguro T, Yoshida Y, Yukawa N, et al. Influence of microstructure on ductile damage behavior of dual phase steel. Tetsu-to-Hagane. 2011;97(3):136–144. (in Japanese)
- Matsuno T. Shearing of high tensile strength steel plates effects of mechanical properties of steel and hole-drilling methods on hole spreadability of high tensile strength steel plates. SOKEIZAI. 2012;53(10):2–7. (in Japanese)