The Influence of Welding Parameters on Brittle Fracture of Liquefied Natural Gas Storage Tank Welded Joint

Abd El Fattah Mustafa Khourshid; Mohamed Ahmed Ghanem

doi:10.4236/msa.2013.43024

Materials Sciences and Applications > Vol.4 No.3, March 2013

The Influence of Welding Parameters on Brittle Fracture of Liquefied Natural Gas Storage Tank Welded Joint

Abd El Fattah Mustafa Khourshid, Mohamed Ahmed Ghanem
Production Engineering and Mechanical Design Department, Faculty of Engineering, Tanta University, Tanta, Egypt..
DOI: 10.4236/msa.2013.43024 PDF HTML XML 5,315 Downloads 8,747 Views Citations

Abstract

Many applications operate at sufficiently low temperature conditions where most structural steels become very brittle and, therefore, unsuitable for use in safety-critical structures. So the materials used in the vessels or storage tanks which keep the natural gas at liquefaction temperatures need to remain ductile and crack resistant with a high level of safety. The material also needs to have high strength in order to reduce the wall thickness of the container and it must permit welding without any risk of brittle fracture. 9% Ni steel plates are one of most common used materials in the LNG storage tank application. However, the welding procedure for 9% Ni steel plates requires high level of skills of welding that is strictly controlled welding parameter for balancing avoidance of cold and hot cracking and maintenance of high strength. Mechanical properties are important characteristics of the weldment that must confirm to the application feasibility as well as functional requirements of the welded joint. The only way to enhanced the mechanical properties of welded joint by controlling the parameters of using welding process. From the main variables of the arc welding process are the heat input and interpass temperature where the two variables control the thermal cycle of welding process. The experiment show that for thin test specimen with thickness ≤ 14 mm, the heat input range from 1.4 to 2 KJ/mm and controlling interpass temperature within 80°C give high tensile strength with improving the toughness properties of welded joint and reduce the probability of brittle fracture happened by increase the ductility and reduce the yield strength and increased the transition temperature.

Keywords

9% Ni Steel Plate; LNG Tank; Heat Input; Mechanical Properties; Welding Process and Brittle Fracture

Share and Cite:

A. Khourshid and M. Ghanem, "The Influence of Welding Parameters on Brittle Fracture of Liquefied Natural Gas Storage Tank Welded Joint," Materials Sciences and Applications, Vol. 4 No. 3, 2013, pp. 198-204. doi: 10.4236/msa.2013.43024.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	J. Stromberg and S. S.-H. Pak, “Cost Efficient LNG Storage Tank Constructed by High Productivity Welding,” ESAB, Gothenburg.
[2]	J.-B. Ju, W.-S. Kim and J.-I. Jang, “Variations in DBTT and CTOD within Weld Heat-Affected Zone of API X65 Pipeline Steel,” Journal of Materials Science and Engineering A, Vol. 546, 2012, pp. 258-262.
[3]	M. Lei and Y. Y. Guo, “Formation of Precipitated Austenite in 9% Ni Steel and Its Performance at Cryogenic Temperature,” Acta Metallurgica Sinica (English Edition), Series A, Vol. 2 No. 4 1989, pp. 244-248.
[4]	K. Hickmann, A. Kern, U. Schriever and J. Stumpfe, “Production and Properties of High Strength Nickel Alloy Steel Plates for Low Temperature Applications,” 2005.
[5]	N. Shun-Ichi, M. Toshio and W. Tsunemi “Technology and Products of JFE Steel’s Three Plate Mills,” JFE Technical Report No. 5, Mar. 2005.
[6]	C. K. Syn, B. Fultz and J. W. Morris, “Mechanical Stability of Retained Austenite in Tempered 9Ni Steel,” 1978, Article ID: ADA055240.
[7]	S. Ohkita, “Control of Strength and Toughness in Weld Metals,” Welding International, Vol. 17, No. 9, 2003, pp. 693-698. doi:10.1533/wint.2003.3169
[8]	C. Thaulowa, M. Haugea, Z. L. Zhanga, é. Ranestada and F. Fattorini, “On the Interrelationship between Fracture Toughness and Material Mismatch for Cracks Located at the Fusion Line of Weldments,” Engineering Fracture Mechanics, Vol. 64, No. 4, 1999, pp. 367-382. doi:10.1016/S0013-7944(99)00087-9
[9]	C. Thaulow, A. J. Paauw, M. Hauge, M. Toyoda and F. Minami, “Fracture Property of HAZ-Notched Weld Joint with Mechanical Mis-Matching—Part II,” ESIS Publ., Vol. 17, 1994. pp. 417-432.
[10]	R. Scott Funderburk, “A Look of Heat Input,” Welding Innovation, Vol. XVI, No. 1, 1999.
[11]	J. Wang, Y. J. Li and P. Liu, “Effect of Weld Heat Input on Toughness and Structure of HAZ of a New Super-High Strength Steel,” Bulletin of Material Science, Vol. 26, No. 3, 2003, pp. 301-305. doi:10.1007/BF02707450
[12]	B. K. Srivastava, S. P. Tewari and J. Prakash, “A Review on Effect of ARC Welding Parameters on Mechanical Behavior of Ferrous Metals/Alloys,” International Journal of Engineering Science and Technology Vol. 2, No. 5, 2010, pp. 1425-1432.
[13]	L. H. Xu, J. Zhang and Y. Q. Chen, “Effect of Heat Input on the Microstructure and Mechanical Properties of 07 MnCrMoVR Weld Joints,” Chinese Journal of Mechanical Engineering, Vol. 24, No. 2, 2010.
[14]	J. F. Lancaster, “Metallurgy of Welding”, 6th Edition, Abington Publishing, Abington, 1999. doi:10.1533/9781845694869
[15]	J. Lancaster, “Handbook of Structural Welding,” Abington Publishing, Abington, 1992.
[16]	N. Bailey, “Weldability of Ferritic Steels,” Abington Publishing, Abington, 1994. doi:10.1533/9781845698935
[17]	G. M. Evans and N. Bailey, “Metallurgy of Basic Weld Metal,” Abington Publishing, Abington, 1999.
[18]	M. Lord, “Interpass Temperature and the Welding of Strong Steels,” Welding in the World, Vol. 41, 1998, pp. 452-459.
[19]	T. Takino and R. Fujimoto, “Welding Technology of LNG Tank,” Seitetsu Kenkyu, Vol. 307, 1982, 14229-NS-13.
[20]	K. Agusa, M. Kosho, N. Nishiyama, A. Kamada and Y. Nakano, “Matching Ferritic Filler MIG Welding of 9% Ni Steel,” Kawasaki Steel Technical Report No. 6, September 1982.
[21]	T. Kubo, A. Ohmori and O. Tanigawa, “Properties of High Toughness 9% Ni Heavy Section Steel Plate and Its Applicability to 200 000K/LNG Storage Tak,” Kawasaki Steel Giho, Vol. 30, 1998, 167-KW-20.
[22]	S. Yoshihiro, H. Kohsuke and K. Hisaya, “Welding Heat Input Limit Rolled Steels for Building Structures Based on Simulated HAZ Tests Trans,” JWRI, Vol. 30, No. 1, 2001, pp. 127-134.
[23]	J. Stromberg, “Welding Spherical Tanks Made of 9% Nickel Steel by TISSOT in France,” Svetsaren-ESAB, Goteborg, Vol. 56, No. 2-3, 2001.
[24]	J.-I. Jang, B.-W. Lee, J.-B. Ju, D. I. Kwon and W.-S. Kim, “Effects of Microstructural Change on Fracture Characteristics in Coarse Grained Heat-Affected Zones of QLT-Processed 9% Ni Steel,” Materials Science and Engineering A, Vol. 340, No. 1-2, 2003, pp. 68-79. doi:10.1016/S0921-5093(02)00190-9
[25]	A. Bukvic, Z. Burzic, R. Prokic-Cvetkovic, O. Popovic, M. Burzic and R. Jovicic, “Welding Technology Selection Effect on Fracture-Toughness Parameters of Bi-Material Welded Joints,” Technical Gazette, Vol. 19, No. 1, 2012, pp. 167-174.
[26]	ESAB, “Welding Liquid Natural Gas Tanks and Vessels in 5% and 9% Nickel Steels, Printed in Sweden,” 2001. consumables@esab.se.
[27]	P. Bourges and M. Malingraux, “Fabrication and Welding of Thick Plates in 9% Ni Cryogenic Steel,” INDUSTEEL Co., 2008.
[28]	ASME Sec II Part C “Specifications for Welding Rods, Electrodes, and Filler Metals,” 2010.
[29]	ASME Sec IX, “Qualification Standard for Welding and Brazinf Procedures, Welders, Brazers, and Welding and Brazing Operators,” 2010.
[30]	ASME Sec II Part A, “Ferrous Material Specifications,” 2010.

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