References
- 1. Aramis v6.1 User Manual, GOM Gmbh, 2009.
- 2. ASTM E 1820-05, Standard Test Method for Measurement of Fracture Toughnes,. ASTM, Philadelphia; 2000.
- 3. Bhadeshia H.K.D.H. (2001), Bainite in Steels, Institute of Materials, London.
- 4. Dzioba I. (2011), The influence of the microstructural components on fracture toughness of 13HMF steel, Materials Science, 47(5), 357-364.
- 5. Dzioba I., Pała T. (2014), Mechanical properties of welded joints made of high-strength steel S960-QC by laser method, Logistyka, 6, 3458-3464 (in Polish).
- 6. Dzioba I., Pała T., Valkonen I. (2013), Strength and fracture toughness of the welded joints made of high-strength ferritic steel, Acta Mechanica et Automatica, 7(4), 226-229.
- 7. Gałkiewicz J., Pała T., Dzioba I. (2012), Mechanical properties of the welded joints of ultra-strength ferritic steels, XXIII Symposium on Fatigue and Fracture Mechanics Bydgoszcz–Pieczyska, 63-72 (in Polish).
- 8. Górka J. (2015), Weldability of Thermomechanically Treated Steels Having a High Yield Point, Archives of Metallurgy and Materials, 60(1), 469-475.
- 9. Hakansson K., Weld Metal Properties for Extra High Strength Steels, Report 2002 – August, Division of Welding, Department of Production Engineering, The Royal Institute of Technology, 1-36.
- 10. Keehan E., Zachrisson J., Karlsson L. (2010), Influence of cooling rate on microstructure and properties of high strength steel weld metal, Science and Technology of Welding and Joining, 15, 233-238.
- 11. Lambert-Perlade A., Gourgues A.F., Besson J., Sturel T., Pineau A. (2004), Mechanisms and modeling of cleavage fracture in simulated heat-affected zone microstructures of a high-strength low alloy steel, Metall Mater Trans A; 35(13):1039-53.
- 12. Lillemäe I., Remes H., Liinalampi S., Itävuo A. (2016), Influence of weld quality on the fatigue strength of thin normal and high strength steel butt joints, Welding in the World, 4, 1-10.
- 13. Lisiecki A. (2014), Weldability of Thermomechanically Treated Steels Having a High Yield Point, Archives of Metallurgy and Materials, 59(4), 1625-1631.
- 14. Liu F., Yu X., Huang C., He L., Chen Y., Bu W. (2015), Microstructure and mechanical properties of AerMet 100 ultra-high strength steel joints by laser welding, Journal of Wuhan University of Technology-Mater. Sci. Ed., 8/2015, 30, 827-830.
- 15. Mazanek K., Sniezek l., Slezak T. (2013), Fatigue research of welded joints of high strength S960QL steel, Bulletin of the Military University of Technology, 42(1), 253-269 (in Polish).
- 16. Pała T., Gałkiewicz J., Dzioba I. (2016), Determination of Strain and Stress Fields in Laser Welded Joints by Means of the Aramis Video System, Solid State Phenomena, 250, 151-156.
- 17. PN-EN ISO 6507-1:2006. Metals, toughness measurement by the Vicker's method, part 1, testing method (in Polish).
- 18. PN-EN ISO 6892-1:2010. Metals, tensile test, part 1: Testing method at room temperature (in Polish).
- 19. Tweed J.R., Knott J.F. (1987), Micromechanisms of failure in C-Mn weld metal, Acta Metallurgica, 35(7), 1401-1414.
- 20. Yang Y., Shi L., Xu Z., Lu H., Chen X., Wang X. (2015), Fracture toughness of the materials in welded joints of X80 pipeline steel, Engineering Fracture Mechanics, 148, 337-349.