The Recommend of Filler Metal to Increasing the Corrosion Resistance of Gas Pipeline
محورهای موضوعی : Additive manufacturing processesEsmaeil Jafari 1 , Mohammad Sadegh Karimi 2
1 - Materials Science and Engineering Dept., Islamic Azad University, Shiraz Branch
2 - Member of South Zagros Oil and Gas Company
کلید واژه: numerical analysis, Implant, Bone Scaffold, Additive Manufacturing,
چکیده مقاله :
The high strength carbon steels such as API X65 is widely used to build the pipelines. In this study, the corrosion behavior welds region of the gas pipeline was studied. For this purpose, Shield Metal Arc Welding (SMAW) was used to evaluate the proposed method. The welding processes were performed with E6010, E6013, and ER70S-6 electrodes as filler metal and welding carried out in 3 passes by a single butt welded method. The corrosion behavior was determined in the gas fluid solution at environment temperature using potentiodynamic polarization test. The microstructure of the base metal, weld zone, and heat-affected zone were investigated with optical microscopy. Results show that the microstructure changes that formed during the welding process were correlated with electrochemical results. And the corrosion performance of the weld joints was influenced by the type of filler metal. As the welded sample with ER70S-6 has high corrosion resistance in comparison to other electrodes.
[1] Yesen, Z., Yunze, X., Mingyu, W., Xiaona, W., Gang, L. and Yi, H. 2019. Understanding the influences of temperature and microstructure on localized corrosion of subsea pipeline weldment using an integrated multi-electrode array. Ocean Engineering. 189:1-14.
[2] Sabet, A. R. and Montazerolghaem, H. 2018. Manufacturing of Aluminum Thin Cylindrical Parts By Using Friction Stir Welding Method, Journal of Modern Processes in Manufacturing and Production. 7:21-28
[3] Moradi, M., Ghoreishi, M. and Rahmani, A. 2016. Numerical and Experimental Study of Geometrical Dimensions on Laser-TIG Hybrid Welding of Stainless Steel 1.4418. Journal of Modern Processes in Manufacturing and Production. 5: 21-31
[4] Granjon, H. Fundamentals of Welding Metallurgy. 1991. Abington Publishing. 156-177.
[5] Aneesh, K. and Prashant, D. 2020. Investigating the effects of filler material and heat treatment on hardness and impact strength of TIG weld. Materials Today: Proceedings. 33: 1-7.
[6] Deen, K. M., Ahmad, R., Khan, I. H. and Farahat, Z. 2010. Microstructural study and electrochemical behavior of low alloy steel weldment. Materials and Design. 31 (1), 3051–3055.
[7] Waqar, H., Masood, U. and Tariqc, M. 2020. Assessment of fatigue and electrochemical corrosion characteristics of dissimilar materials weld between alloy 617 and 12 Cr steel. Journal of Manufacturing Processes. 53:275-282.
[8] Hongyang, J., Yongdian, H., Zhicao, F. and Lianyong, X. 2016. Recommend design of filler metal to minimize carbon steel weldmetal preferential corrosion in CO2-saturated oilfield produced water. Applied Surface Science. 389: 609-622
[9] Abioyea, T.E., Ariwoolac, O.E., Ogedengbec, T.I., Farayibib, P.K. and Gbadeyanc, O.O. 2019. Effects of Welding Speed on the Microstructure and Corrosion Behavior of Dissimilar Gas Metal Arc Weld Joints of AISI 304 Stainless Steel and Low Carbon Steel. Materials Today, Proceedings, 17(3): 871–877.
[10] Anbarasu, P., Yokeswaran, R., Godwin, A. and Sivachandran, S. 2020. Investigation of filler material influence on hardness of TIG welded joints. Materials Today: Proceedings. 33: 1-4.
[11] Zhanga, Y., Hongyang, J., Lianyong, X., Yongdian, H. and Lei, Z. 2018. Design and performance of weld filler metal to match an advanced heat resistant Fe-Cr-Ni alloy. Materials Science & Engineering A. 721:103-116.
[12] Liqing, H., Guobiao, L., Zidong, W., Hong, Z., Feng, Li. and Long, You. 2010. Study on Corrosion Resistance of 316L Stainless Steel Welded Joint. Rare Metal Materials and Engineering. 3: 393–396.
[13] Tan, H., Wang, Z., Jiang,Y., Yang,Y., Deng, Bo. and Song, H. 2012. Influence of welding thermal cycles on microstructure and pitting corrosion resistance of 2304 duplex stainless steels. Corrosion Science. 55:368–377.
[14] Yang, Y., Yan, B., Li, J. and Wang, J. 2011. The effect of large heat input on the microstructure and corrosion behavior of simulated heat affected zone in 2205 duplex Stainless Steel. Corrosion Science. 53:3756-3763.
[15] Rudra, P., Pratap , S. and Subodh, K. 2020. Effect of current and chemical composition on the hardness of weld in shielded metal arc welding. Materials Today: Proceedings. 26-2:1888-1891.
[16] Fuyun, L., Caiwang, T., Xiangtao, G., Laijun, W. and Jicai, F. 2020. A comparative study on microstructure and mechanical properties of HG785D steel joint produced by hybrid laser-MAG welding and laser welding. Optics & Laser Technology.128:106247.