Dr. Saad Ali Al-Taan
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Dr. Saad Ali Al-Taan

Professor
University of Mosul, Iraq

Highest Degree
Ph.D. in Civil and Structural Engineering from Sheffield University, U.K.

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Biography

Dr. Saad Ali Al-Taan is currently working as Professor at Mosul University, Egypt. He has completed his Ph.D. in Civil and Structural Engineering from Sheffield University (U.K.). He is member of International conference on Engineering and Information Technology, Canada, Second Conference on Engineering, Mosul University, Mosul, Iraq. He supervised 19 MSc students, and 2 PhD students. He has published 1 book and 20 research articles in journals contributed as author/co-author.

Area of Interest:

Physical Science Engineering
100%
Civil Engineering
62%
Structural Engineering
90%
Material Science
75%
Construction
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
0
Abstracts
0

Selected Publications

  1. Al-Ta'an, S.A., W.N. Al-Rifaie and K.A. Al-Neimee, 2016. Properties of fresh and hardened high strength steel fibres reinforced self-compacted concrete. Tikrit J. Eng. Sci., 23: 29-37.
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  2. Al-Taan, S.A. and N.S.H. Al-Husaini, 2014. Softened truss model theory for the analysis of fibre reinforced concrete deep beams and corbels. Al-Rafadain Eng. J., 22: 12-23.
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  3. Al-Hassani, H.M., S.A. Al-Taan and A.A. Mohammed, 2013. Behavior of damaged reinforced concrete beams strengthened with externally bonded steel plate. Tikrit J. Eng. Sci., 20: 48-59.
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  4. AlTaan, S.A., A.A. Mohammed and A.A. Al-Jaffal, 2012. Breakout capacity of headed anchors in steel fibre normal and high strength concrete. Asian J. Applied Sci., 5: 485-496.
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  5. Al-Taan, S.A. and Z.S. Al-Neimee, 2011. Fresh and hardened properties of steel fibres reinforced self-compacted concrete. Int. J. Applied Eng. Res., 6: 1565-1578.
  6. Al-Taan, S.A. and A.A.H. Al-Jaffal, 2011. Tensile capacity of short headed anchor bolts embedded in high strength concrete. Int. J. Applied Eng. Res., 6: 235-247.
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  7. Al-Taan, S.A. and S.S. Majeed, 2010. Pullout strength of headed deformed reinforcement embedded in fibrous concrete. Al-Rafidain Eng. J., 18: 1-12.
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  8. Al-Taan, S.A. and A.A. Mohammed, 2010. Tensile strength of short headed anchors embedded in steel fibrous concrete. Al-Rafidain Eng. J., 18: 35-49.
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  9. Al-Taan, S.A. and N.S. Al-Saffar, 2008. Nonlinear finite element analysis of fibrous reinforced concrete joints. Eng. J., 16: 57-69.
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  10. Al-Taan, S.A. and N.S. Al-Saffar, 2008. Nonlinear finite element analysis of fibrous reinforced concrete beam-column joints. Cement Concrete Composites, 12: 57-69.
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  11. Al-Taan, S.A. and N.S. Al-Saffar, 2007. Investigation of shear response of fibrous reinforced concrete beams using incremental-iterative method. Al-Rafidain Eng., 15: 1-18.
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  12. Al-Taan, S.A. and J.A. Al-Hamdony, 2006. Bearing capacity of steel fibrous concrete. Al-Rafidain Eng. J., 14: 1-11.
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  13. Lihua, X.u., Y. Chi, J. Su, D. Xia, 2003. Non Linear finite element analysis of fibrous reinforced concrete deep beams. J. Eng.Technol., 11: 47-62.
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  14. Al-Taan, S.A. and A.A. Abdul-Razzaque, 1999. Modeling flexural behavior of fibrous reinforced concrete beams. Scient. J. Tikrit Univ., 6: 89-102.
  15. Al-Taan, S.A. and A.A. Abdul-Razzaque, 1999. Influence of support simulation on the analysis of fibrous reinforced concrete deep beams. Al-Rafidain Eng. J., 7: 70-85.
  16. Al-Taan, S.A. and T.Q.M. Ali, 1998. Nonlinear finite element analysis of reinforced fibrous concrete deep beams. J. Eng. Technol., 17: 862-877.
  17. Al-Taan, S.A. and B.A. Ali, 1996. Free vibration analysis of continuous plates by the integral equation method. Al-Rafidain Eng. J., 4: 2-11.
  18. Al-Taan, S.A. and N.A. Ezzadeen, 1995. Flexural analysis of reinforced fibrous concrete members using the finite element method. J. Comput. Struct., 56: 1065-1072.
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  19. Al-Taan, S.A. and B.A. Ali, 1995. Analysis of stiffened plates by the integral equation method. Dirasat J., 22: 1345-1357.
  20. Al-Taan, S.A., 1992. Flexural analysis of reinforced fibrous concrete beams. J. Eng. Technol., 11: 7-19.
  21. Al-Taan, S.A. and J.R. Al-Feel, 1990. Evaluation of shear strength of fibre reinforced concrete beams. Cem. Concr. Compos., 12: 87-94.
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  22. Swamy, R.N. and S.A. Al-Taan, 1981. Deformations and ultimate strength in flexure of reinforced concrete beams made with steel fibre concrete. ACI J., 78: 395-405.
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  23. Swamy, R.N., S.A. Al-Taan and S.A.R. Ali, 1980. Use of steel fibres to control cracking and deflection in concrete structures. J. Iraqi Soc. Eng., 25: 22-32.
  24. Swamy, R.N., S. Al-Taan and S.A.R. Ali, 1979. Steel fibres for controlling cracking and deflection. J. Concr. Int. Design Constr., 1: 41-49.
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  25. Swamy, R.N. and S.A. Al-Taan, 1977. Discussion of analysis of reinforced fibrous concrete beams. Proc. ASCE J. Struct. Division, 103: 300-300.