References
- Gimenez-Britos P, Widener C, Boldsaikhan E, Burford D: ‘Probability of detection analysis of NDT methods for friction stir welded panels’, Proc. 8th Int. Friction Stir Weld. Symp., Timmendorfer strand, Germany, 2010, TWI.
- de Backer J, Christiansson AK, Oqueka JM, Bolmsjö G: Ind. Robot: Int. J., 2012, 39, (6), 7-7.
- Cook GE, Crawford R, Clark DE, Strauss AM, Robot Ind: Int. J., 2004, 31, (1), 55-55-63.
- Soron M: ‘Robot system for flexible 3D friction stir welding’, PhD thesis, Örebro University, 2007.
- Smith C: ‘Friction Stir Welding using a Standard Industrial Robot’, 2nd Int. Friction Stir Welding Symp., Gothenburg, Sweden, 2000, TWI.
- Von Strombeck A, Schilling C, Dos Santos JF: ‘Robotic friction stir welding - tool technology and applications’, Proc. 2nd Int. Friction Stir Welding Symp., Gothenburg, Sweden, 2000, TWI.
- Cederqvist L, Öberg T: Reliab. Eng. System Safety, 2008, 93, (10), 1491–1499.
- Smith C, Schroeder K: ‘An automated path planning and programming system with real-time adaptive control for friction stir processing of cast surfaces’, Proc. 9th Int. Friction Stir Welding Symp., Huntsville (AL), USA, 2012, TWI.
- Fehrenbacher A, Duffie NA, Ferrier NJ, Pfefferkorn FE, Zinn MR: J. Manuf. Sci. Eng. Trans. ASME, 2011, 133, (5).
- Cederqvist L, Garpinger O, Hägglund T, Robertsson A: Control Eng. Pract., 2012, 20, (1), 35–48.
- Cederqvist L: ‘Friction stir welding of copper canisters using power and temperature feedback’, PhD thesis, Lund University, Lund, 2011.
- de Backer J, Soron M, Ilar T, Christiansson A.-K: ‘Friction stir welding with robot for light weight vehicle design’, Proc. 8th Int. Friction Stir Weld. Symp., Timmendorfer Strand, Germany, 18-20/05/2010, 2010, TWI.
- Shahdan MAM: ‘Temperature measurements of weld during friction stir welding using ultrasonic time of flight’, Proc. 9th Int. Conf. on ‘Trends in welding research’, 2012, ASM International.
- Schmidt H, Hattel J: Sci. Technol. Weld. Join., 2005, 10, (2), 176–186.
- Nandan R, Roy GG, Lienert TJ, Debroy T: Acta Mater., 2007, 55, (3), 883–895.
- Roy G, Nandan R, DebRoy T: Sci. Technol. Weld. Join., 2006, 11, (5), 606–608.
- Arora A, Nandan R, Reynolds AP, DebRoy T: Scr. Mater., 2009, 60, (1), 13–16.
- Schmidt HNB, Dickerson TL, Hattel JH: Acta Mater., 2006, 54, (4), 1199–1209.
- Sato YS, Kokawa H: Metall. Mater. Trans. A, 2001, 32, (12), 3023–3031.
- D’Errico GE, Calzavarini R, Settineri L: ‘Experiments on self tuning regulation of cutting temperature in turning process’, Control Applications, 1994, Proc. 3rd IEEE Conf., Aug 1994, 1165–1169.
- Hirao M: J. Mater. Shap. Technol., 1989, 6, (3), 143–148.
- Pantke K: ‘Entwicklung und Einsatz eines temperatursensorischen Beschichtungssystems für Zerspanwerkzeuge’, PhD thesis, Technische unversität Dortmund, Dortmund, 2012.
- Seebeck TJ: ‘Ueber den Magnetismus der galvanischen Kette’; 1822, Deutsche Akademie der Wissenschaften zu Berlin.
- Ørsted HC: Ann. Philos., 1820, 16, (4), 273–276.
- Bentley RE: ‘Handbook of temperature measurement 3. Theory and practice of thermoelectric thermometry’; 1998, Singapore, Springer.
- Nielsen PE, Taylor PL: Phys. Rev. B, 1974, 10B, (10), 4061–4070.
- Werheit H, Kuhlmann U, Herstell B, Winkelbauer W: J. Phys.: Conf. Ser., 2009, 176, (1), 012037.
- de Backer J, Soron M: ‘Three-dimensional friction stir welding of inconel 718 using the ESAB rosio FSW-robot’, in ‘Trends in welding research’, Chicago, IL, USA, 2012, ASM International.
- Kasap S: ‘Thermoelectric effects in metals: thermocouples’; 2001, Saskatchewan, Canada, University of Saskatchewan.
- Nandan R, Roy G, DebRoy T: Metall. Mater. Trans. A, 2006, A37, (4), 1247–1259.
- Miyazawa T, Iwamoto Y, Maruko T, Fujii H: Sci. Technol. Weld. Join., 2011, 16, (2), 188–192.
- Boywitt R: ‘Entwicklung und Erprobung von neuen Werkzeugmaterialien für das Rührreibschweißen von Stahl’, Große Schweißtechnische Tagung 2011, Hamburg, 2011, DVS, 166–170.