Authors:
Firas F. Qader Kirkuk Technical Engineering College, Northern Technical University, Kirkuk, Iraq

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Barhm Mohamad Department of Petroleum Technology, Koya Technical Institute, Erbil Polytechnic University, Erbil, Iraq

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Adnan M. Hussein Kirkuk Technical Engineering College, Northern Technical University, Kirkuk, Iraq

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Suad H. Danook Kirkuk Technical Engineering College, Northern Technical University, Kirkuk, Iraq

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Abstract

Forced convection heat transfer was studied in a horizontally heated circular pipe with constant heat flux. Porous medium was created using 1 and 3 mm stainless-steel balls (porosity: 0.3690 and 0.3912). Reynolds numbers ranged from 3,200 to 6,500 based on pipe diameter, with heat flux rates of 6,250 and 12,500 W m−2. ANSYS Fluent simulated a 51.4 mm diameter, 5 mm thick, 304 mm long stainless-steel pipe. Results showed increased turbulence and eddy formation. Analysis revealed higher convective heat transfer coefficient, pressure drop, and Nusselt number with increasing Reynolds number. Nusselt number also increased with 1–3 mm ball diameter. 6% porosity increase reduced pressure drop by 84.4%. Nusselt number rose by 46.7% (Reynolds 3,200–6,500) and 4.36% (heat flux 6,250–12,500 W m−2).

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0,26
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Scopus  
Scopus
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1,5
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Civil and Structural Engineering 232/326 (Q3)
Computer Science Applications 536/747 (Q3)
General Materials Science 329/455 (Q3)
Modeling and Simulation 228/303 (Q4)
Software 326/398 (Q4)
Scopus
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0,613

2020  
Scimago
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11
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Journal Rank
0,257
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Scopus
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340/243=1,4
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Modeling and Simulation 217/290 (Q4)
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1,09
Scopus
Cites
321
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67
Days from submission to acceptance 136
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48%

 

2019  
Scimago
H-index
10
Scimago
Journal Rank
0,262
Scimago
Quartile Score
Civil and Structural Engineering Q3
Computer Science Applications Q3
Materials Science (miscellaneous) Q3
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Software Q3
Scopus
Cite Score
269/220=1,2
Scopus
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Civil and Structural Engineering 206/310 (Q3)
Computer Science Applications 445/636 (Q3)
General Materials Science 295/460 (Q3)
Modeling and Simulation 212/274 (Q4)
Software 304/373 (Q4)
Scopus
SNIP
0,933
Scopus
Cites
290
Scopus
Documents
68
Acceptance
Rate
67%

 

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Pollack Periodica
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