Study The Effects of Welding Parameters on The Tensile Strength for Welded Joints of Low Carbon Steel Using ARC Welding
Keywords:
Low carbon steel, Arc welding process, Tensile testAbstract
Welding is considered one of the most important industrial processes, so many methods have been developed to obtain a weld joint with good mechanical properties at the lowest cost for different types of metals. The objective of this paper was to study the effect of welding parameters (current, welding wire diameter, and arc Force) on the tensile strength of welded joints of low-carbon steel. The length of the specimen was 200 mm, while the width was 130 mm and the thickness was 6 mm. An arc welding machine (deca E-ARC 860) was used. The experiments were designed based on three levels for each of the currents, the diameter of the welding wire, and the force of the arc. The experiments were carried out by fixing two of the factors changing the third factor, and so on. The test that included the tensile test of the joints was conducted, and compared with a sample of the same non-welding metal. The maximum tensile stress of the welded joint was (203 MPa) with a welding efficiency of (91.44%), and the minimum tensile stress of the welded samples was (138 Mpa) with a welding efficiency of (62.16%).
References
أولا: قائمة المراجع باللغة العربية
جاسم، أمجد رعد؛ فهد، نسرين داخل؛ عبد الرضا، مروة محمد (2018). تأثير السرعة والتيار على عيوب اللحام للفولاذ منخفض الكربون باستخدام اللحام بالقوس المعدني والغاز الخامل. مجلة جامعة بابل، العلوم الصرفة والتطبيقية والعلوم الهندسية، 26(2).
حسين، عباس خماس؛ جبار، محمد مهدي؛ أحمد، سحر حسين (2010). دراسة تأثير اللحام على خواص الشد والصلادة للفولاذ الكربوني باستخدام طريقتي (Arc Welding & Tig Welding). مجلة الهندسة والتكنولوجيا، 28(23).
ثانياً: قائمة المراجع باللغة الإنجليزية
Abdullahi, U. (2022). Effect of Tempering Treatment on the Post-Weld Properties and Chemical Compositions of Arc-Welded Alloy Steels. International Journal of Engineering Materials and Manufacture, 7(4), 89-94.
David S.A. and DebRoy T. (1992). Current Issues and Problems in Welding Science. Science, 257(5069), 497-502.
Kim, I. S., Son, J. S., Park, C. E., Kim, I. J., & Kim, H. H. (2005). An investigation into an intelligent system for predicting bead geometry in GMA welding process. Journal of Materials Processing Technology, 159(1), 113-118.
Lee, J. I., & Um, K. W. (2000). A prediction of welding process parameters by prediction of back-bead geometry. Journal of materials processing technology, 108(1), 106-113.
Rao, T. E., Krishna, G. R., & Kumar, M. V. (2019). Investigation of Microstructure and Mechanical Properties of MIG Welded Mild Steel Plates. In: Annales de Chimie Science des Materiaux, 43(4), 257-263.
Sumardiyanto, D., & Susilowati, S. E. (2019). Effect of welding parameters on mechanical properties of low carbon steel API 5L shielded metal arc welds. American Journal of Materials Science, 9(1), 15-21.
Talabi, S. I., Owolabi, O. B., Adebisi, J. A., & Yahaya, T. (2014). Effect of welding variables on mechanical properties of low carbon steel welded joint. Advances in Production Engineering & Management, 9(4), 181-186.
Tewari, S. P., Gupta, A., & Prakash, J. (2010). Effect of welding parameters on the weldability of material. International Journal of Engineering Science and Technology, 2(4), 512-516.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2023 معمر مصباح بن عيسى، أحمد فرج باكير
This work is licensed under a Creative Commons Attribution 4.0 International License.
