Staff Portal
Sheelan Mahmoud Hama Hama (Assistant Professor)

PhD in Structural Engineering
Lecturer
Civil - Engineering
drsheelan@uoanbar.edu.iq

Biography

Full name: Sheelan Mahmoud Hama Hama

Structural Engineering

 Prof. Dr. in Civil Engineering

College of Engineering/University Of Anbar

Publication

  1. Mahmoud Hama, S. Evalutions of strengths, impact and energy capacity of two-way concrete slabs incorprating waste plastic. 2021, 33(5), pp. 337–345. https://doi.org/10.1016/j.jksues.2020.09.007
  2. Hama, S.M. Behavior of concrete incorporating waste plastic as fine aggregate subjected to compression, impact load and bond resistance. European Journal of Environmental and Civil Engineeringthis, 2020. https://doi.org/10.1080/19648189.2020.1798287
  3. Hama Sheelan M. "Improving mechanical properties of lightweight Porcelanite aggregate concrete using different waste material. International Journal of Sustainable Built Environment 2017; 6:81–90. (2017). https://doi.org/10.1016/j.ijsbe.2017.03.002
  4. Hama Sheelan M., Dhifaf N. Hamdullah, Hayfaa M. Ashour " Effects of Eggshell Powder as Partial Replacement of Cement on Flexural Behavior of One-Way Concrete Slabs" Journal of Engineering Science and Technology, Vol. 15, No. 5 (2019) 2509 - 2521
  5. Hamdullah Dhifaf N., Hama Sheelan M., Yaseen Mohammed M. '' Effect of Eggshell Waste Powder on Impact Resistance and Bond Charcteristics of Reinforced Concrete '' Key Engineering Materials, Vol. 870, (2019). pp 21-28
  6. Ali Z. M., Hama S. M., Mohana M. H. (2020).  Flexural behavior of one-way ferrocement slabs with fibrous cementitious matrices.  Periodicals of Engineering and Natural Sciences. 8(3).1614-1624.
  7.  Aziz K. I., Hama S. M. and Kuhair H. M. L. (2018), Effenciency of Waste Plastic Fiber on Behavior of Composite Steel Plate-Concrete Push Out Test," 2018 11th International Conference on Developments in eSystems Engineering (DeSE), 2018, pp. 335-339, doi: 10.1109/DeSE.2018.00066.
  8. Hama S. M., Mahmoud A. S and Yassen M. M. (2019). Flexural behavior of reinforced concrete beam incorporating waste glass powder. Structures 20 (2019) 510–518. https://doi.org/10.1016/j.istruc.2019.05.012
  9. Mahmoud A. S, Yassen M. M. and Hama S. M. (2019). Effect of Glass Powder as Partial Replacement of Cement on Concrete Strength and Stress-Strain Relationship. 12th international conference development in e-systems engineering 2019: 109–114.
  10. DOI 10.1109/DeSE.2019.00030
  11. Mohammed V.B., Hama S.M. and Aziz K.I. (2019). Assessment Strength Properties of Modified Reactive Powder Concrete by Adding Waste Bricks, 12th International Conference on Developments in eSystems Engineering (DeSE), 2019: 83-87, doi: 10.1109/DeSE.2019.00025.
  12. Khudair, A.Y.Mohammed, M.K.Hama, S.M. Optimization of glass powder content in self-compacting concrete as partial replacement of cement. IOP Conference Series: Materials Science and Engineering, 2020, 928(2), 022140. doi:10.1088/1757-899X/928/2/022140
  13. Yassen M. M., Hama S. M., and Mahmoud A. S(2018). Reusing of glass wastes as Powder as partial of cement in Production of Concrete. 11th international conference development in e-systems engineering 2018: 330–4. https://doi.org/10.1109/DeSE.2018.00065.
  14. Ubeid, H.S.Hama, S.M.Mahmoud, A.S. Mechanical Properties, Energy Impact Capacity and Bond Resistance of concrete incorporating waste glass powder. IOP Conference Series: Materials Science and Engineering. 2020, 745(1), 012111. doi:10.1088/1757-899X/745/1/012111
  1. Aziz, K. I., Hama, S. M., & Kuhair, H. M. (2019). Effect of PET fibers on mechanical properties, stress-strain relationship and drying shrinkage of concrete. REVISTA AUS 26-1, 336–343. https://doi.org/10.4206/aus.2019.n26-1.31/.
  2. Hama, S. M., & Hilal, N. N. (2017). Fresh properties of self-compacting concrete with plastic waste as partial replacement of sand. International Journal of Sustainable Built Environment, 6(2), 299–308. https://doi.org/10.1016/j.ijsbe.2017.01.001
  3. Hama, S. M., & Hilal, N. N. (2019). Fresh properties of concrete containing plastic aggregate. In F. Pachego-Torgal, J. Khatib, F. Colangelo, & R. Tuladhar (Eds.), Use of recycled plastics in eco-efficient concrete (Chapter 5, pp. 85–114). Elsevier. ISBN 9780081026762. https://doi.org/10.1016/B978-0-08-102676-2.00005-0
  4. Abdulkader I. Al-Hadithi and Sheelan M. Hama 2009. Some Mechanical Properties of Polymer Modified Concrete Rreinforced with a Waste Plastic Fiber. The Iraqi Journal For Mechanical And Material Engineering, Special Issue (D), pp. 653-664.
  5. Hama, S.M. Behavior of Different Ferrocement Structural Elements under Different Condition of Loading: Review. Iraqi Journal of Civil Engineering (2021) 015–001
  6. Hama, S.M., Abdulghafor A. M., Nawar M. T.  Fresh, Mechanical Properties and Impact Resistance Behavior of Eco-Friend Self-Compacted Concrete.  Al-Nahrain Journal for Engineering Sciences NJES 22(3)208-212, 2019 http://doi.org/10.29194/NJES.22030208   
  7. Hama S. M. (2015). Efficiency of Using Steel Fibers Taken From Old Tyres in Polymer Concrete Comparison with Using Imported Fibers ".  Yanbu Journal of Engineering & Science, 10 (1436H). 49-57.
  8. Hilal, N. N., Hama, S. M., and M. M, Salman. The Effect of Particle Size Distribution (Psd) of Rubbrized Self-Compacting Concrete (RSCC). 2018(02):13-22. DOI:10.31272/jeasd.2018.2.46
  9. Hama, S.M., Nawar M. T., and AlHadithi A. I. Beneficial Role of Glass Wastes in Concrete – A Review. Journal of Engineering and Sustainable Development, 2018. 22(02):136-144. DOI:10.31272/jeasd.2018.2.75
  10. Hama, S., Hama, S., & Mhana, M. (2018). Improving Strengths of Porcelanite Aggregate Concrete by Adding Chopped Carbon Fibers. Al-Nahrain Journal for Engineering Sciences, 21(1), 161-165. https://nahje.com/index.php/main/article/view/390
  11. Mohammed T. Nawar Noor A. Rajab Sheelan M. Hama. Experimental Investigation on the Efficacy of Polyethylene Aggregate on Impact Resistance of Concrete Slab. Anbar Journal of Engineering Sciences, 2019, Volume 8, Issue 1, Pages 9-15
  12. Sheelan M. H. , Ibtihal A. M. , Nahla N. H. Influence of Mix Water Quality on Compressive Strength of Making Concrete. Iraqi Journal of Civil Engineering (2019) 013–001. https://www.iasj.net/iasj/download/4d23c3bed316f9ed
  13. Yassin, M., Mahmoud, A., & Hama, S. (2019). Effectiveness of Glass Wastes as Powder on Some Hardened Properties of Concrete. Al-Nahrain Journal for Engineering Sciences, 22(1), 14-17. https://doi.org/10.29194/NJES.22010014
  14. Mahmoud, A.S., Hama, S. M., and Ubeid, H.S. Some Mechanical and Thermal Properties of Concrete Incorporating Waste Glass Powder Subjected to Compression Load. REVISTA AUS 26-1. DOI:10.4206/aus.2019.n26-1.30/

 

Lectures


No. Subjects Lectures Stage File Video
1 Steel Structure References + Introduction Fourth
2 Steel Structure Tension members Fourth
3 Steel Structure Design of Tension members Fourth
4 Steel Structure Connectors Fourth
5 Steel Structure Welding Fourth
6 Steel Structure Analysis of Compression members Fourth
7 Steel Structure Local buckling Fourth
8 Steel Structure Inelastic Effective Length Factors Fourth
9 Steel Structure Design of base plate Fourth
10 Steel Structure Bending members Fourth
11 Steel Structure Theory of plastic analysis Fourth
12 Steel Structure Classification of Cross-Section Fourth
13 Steel Structure Selecting sections Fourth
14 Steel Structure Biaxial Bending Fourth
15 Steel Structure Beam-Column member Fourth
16 Theory of elastic stability Introduction Postgraduate
17 Theory of elastic stability Elastic Buckling of Columns Postgraduate
18 Theory of elastic stability Strength of Compression Members In Practice Postgraduate
19 Theory of elastic stability Large Deflection Theory (The Elastica) Postgraduate
20 Theory of elastic stability Beam-Column Buckling Postgraduate
21 Theory of elastic stability Slope-Deflection Equation without Axial Force Postgraduate
22 Theory of elastic stability Buckling of Frames Postgraduate
23 Theory of elastic stability Approximate Calculation of Critical Loads Postgraduate
24 Theory of elastic stability Column Buckling Analysis by Finite Difference Meth Postgraduate
25 Theory of elastic stability Free Vibration of Columns under Compressive Loads Postgraduate
26 Theory of elastic stability Inelastic Buckling Postgraduate
27 Theory of elastic stability Flexural-Torsional Buckling of Columns Postgraduate
28 Theory of elastic stability Lateral-Torsional Buckling Postgraduate
29 Theory of elastic stability Lateral-Torsional Buckling by Energy Method Postgraduate
30 Dynamic Kinematics of Particles Second
31 Dynamic Curvilinear Motion: Position, Velocity & Accel Second
32 Dynamic Kinetics of Particles Second
33 Dynamic Equations of Motion: Normal and Tangential Coordin Second
34 Dynamic Kinetics of Particles: Work And Energy Second
35 Dynamic Power and Efficiency Second
36 Dynamic Kinetics of Particles: Impulse and Momentum Second
37 Dynamic Kinematics of Rigid Bodies Second
38 Dynamic Plane Motion of Rigid Bodies: Forces and Accelerat Second
39 Theory of elasticity and plasticity Introduction Postgraduate
40 Theory of elastic stability Two-Dimensional Elasticity Postgraduate
41 Theory of elastic stability Strain at point Postgraduate
42 Theory of elastic stability Two Dimensional Problems in Cartesian Coordinate S Postgraduate
43 Theory of elastic stability Bending of A Narrow Cantilever Beam Subjected to E Postgraduate
44 Theory of elastic stability Problems Postgraduate
45 Theory of elastic stability 3D Elasticity Postgraduate
46 Theory of elastic stability Elastic Stress-Strain Relations Postgraduate
47 Theory of elastic stability Torsion Postgraduate
48 Theory of elastic stability Torsion of Thin-Walled Sections Postgraduate
49 Theory of elastic stability Theory of Plasticity Postgraduate
50 Theory of elastic stability Theory Of Yield Criterion Postgraduate
51 Theory of elastic stability Strain Hardening Postgraduate
52 Theory of elastic stability Methods of Plastic Analysis Postgraduate
53 Theory of elastic stability TORSIONAL AND FLEXURAL TORSIONAL BUCKLING OF COLUM Postgraduate
54 Steel Structures Introduction Fourth

Other