Browse > Article
http://dx.doi.org/10.15683/kosdi.2015.11.4.520

A Study on the Mechanical Properties of Gas Pressure Welded Splices of Deformed Reinforcing Bar  

Jeon, Juntai (A Inha Technical College)
Publication Information
Journal of the Society of Disaster Information / v.11, no.4, 2015 , pp. 520-526 More about this Journal
Abstract
Reinforcing bar splices are inevitable in reinforced concrete structure. In these days, there are three main types of splices used in reinforced concrete construction site - lapped splice, mechanical splice and welded splice. Low cost, practicality in construction site, less time consuming and high performance make gas pressure welding become a favorable splice method. However, reinforcing bar splice experiences thermal loading history during the welding procedure. This may lead to the presence of residual stress in the vicinity of the splice which affects the fatigue life of the reinforcing bar. Therefore, residual stress analysis and tensile test of the gas pressure welded splice are carried out in order to verify the load bearing capacity of the gas pressure welded splice. The reinforcing bar used in this work is SD400, which is manufactured in accordance with KS D 3504. The results show that the residual stresses in welded splice is relatively small, thus not affecting the performance of the reinforcing bar. Moreover, the strength of the gas pressure welded splice is high enough for the development of yielding in the bar. As such, the reinforcing bar with gas pressure welded splice has enough capacity to behave as continuous bar.
Keywords
Gas Pressure Welding; Deformed Reinforcing bar; Residual Stress; Three-dimensional Finite Element Analysis; Mechanical Properties;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Cho, B.H., Yoon, Y.H., Yang, J.S., Park, B.K., Yang, Y.S. (1995). "An experimental study on the mechanical properties of gas pressure welded joints of deformed reinforcing steel bars." Proceedings of the Architectural Institute of Korea, Vol. 15, No. 2, pp.643-650
2 Deng, D., Liang, W. and Murakawa, H. (2007). "Determination of welding deformation in fillet-welded joint by means of numerical simulation and comparison with experimental measurements." Journal of Materials Processing Technology, Vol. 183, pp.219-225.   DOI
3 Goldak, J. and Akhlagi, M. Computational welding mechanics, Springer, 2005.
4 Jack C. McCormac and James K. Nelson. Design of reinforced concrete ACI 318-05 Code Edition, 7thed., HarperCollinsCollegePublishers, 1993
5 Kang, K.W., Lee, J.S., Choi. L., Kim, J.K. (1999). "The behavior of fatigue crack growth in welded rail by gas pressure welding." Proceedings of the Korean Society of Mechanical Engineers, pp.697-702
6 Kim, K.S. (2012). "An Experimental Study on Strength Safety of Rail Steel using Gas Pressure Welding." Journal of the Korean society for railway, Vol. 15, No. 3, pp.266-271.   DOI
7 Lee, C. H. and Chang, K. H. (2007). "Numerical analysis of residual stresses in welds of similar or dissimilar steel weldments under superimposed tensile loads." Computational Material Science, Vol. 40, pp. 548-556   DOI
8 Lindgren, L-E. (2001). "Finite element modelling and simulation of welding, Part 2 Improved material modeling." Journal of Thermal Stresses, Vol. 24, pp.195-231.   DOI
9 Seo, D.S., Song, K.J., Hwang, K.T., You, B.T. (2005). "The developing direction of korean gas pressure welding machine." The Korea Institute of Building Construction, Vol. 5, No. 3, pp.131-138
10 Withers, P.J. (2007). "Residual stress and its role in failure." Reports on Progress in Physics, Vol. 70, pp. 2211-2264.   DOI
11 Jeon, J. T., Lee, C. H., Chang, K.H. (2015). "Behavior of girth-welded buried steel pipes under external pressure" Journal of The Korean Society of Disaster Information, Vol. 11, No. 1 pp.1-8   DOI