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Research Article
Review: Investigation of Elliptical and Conical Flower-Shaped Internal Ribs to Determine Temperature Distribution and Nusselt Number
Prem Chand1
Vijaykant Pandey2
1M-Tech Research Scholar, Bhabha Engineering Research Institute, Bhopal (M.P.), India. 2Assistant Professor, Bhabha Engineering Research Institute, Bhopal (M.P.), India.
Published Online: January-February 2023
Pages: 66-69
Cite this article
No DOIReferences
1. EvangelosBellos, Christos Tzivanidis, DimitriosTsimpoukis, “Optimum number of internal fins in parabolic trough collectors, Applied
Thermal Engineering 137 (2022) 669–677
2. LuanfangDuan, Xiang Ling, HaoPeng, Flow and heat transfer characteristics of a double-tube structure internalfinned tube with
blossom shape internal fins, Applied Thermal Engineering 128 (2018) 1102–1115.
3. M.J. Li, H. Zhang, J. Zhang, Y.T. Mu, E. Tian, D. Dan, X.D. Zhang, W.Q. Tao, “Experimental and numerical Study and Comparison of
Performance for WavyFin and a Plain Fin with Radiantly Arranged Winglets around Each Tube in Finand-tube Heat Exchangers”,
https://doi.org/10.1016/j.applthermaleng.2021
4. Mohammad. Sikindar Baba, A.V.Sita Rama Raju,M.BhagvanthRao, Heat transfer enhancement and pressure drop ofFe3O4 -water
nanofluid in a double tube heatexchanger with internal longitudinal fins, https://doi.org/10.1016/j.csite.2018.08.001.
5. SwastikAcharya, Sukanta K. Dash, Natural convection heat transfer from a horizontal hollow cylinder withinternal longitudinal fins,
International Journal of Thermal Sciences 134 (2021) 40–539.
6. GuodongQiu, Jian Sun, Yuanyang Ma, JiagangQu, WeihuaCai, Theoretical study on the heat transfer characteristics of a plain fin in
thefinned-tube evaporator assisted by solar energy, International Journal of Heat and Mass Transfer 127 (2018) 847–855.
7. EvangelosBellos, Christos Tzivanidis, DimitriosTsimpoukis, “Optimum number of internal fins in parabolic trough collectors, Applied
Thermal Engineering 137 (2019) 669–677
8. Mohammad Sepehr, SeyedSaeedHashemi,MohammadRahjoo, VahidFarhangmehr, AshkanAlimoradi, “Prediction of heat transfer,
pressure drop and entropygeneration in shell and helically coiled finned tube heatexchangers”, https://doi.org/10.1016/j.cherd.2018
9. EvangelosBellos, Christos Tzivanidis, DimitriosTsimpoukis, Thermal enhancement of parabolic trough collector with internally
finnedabsorbers, Solar Energy 157 (2017) 514–531.
10. Yong-Hui Wang, Ji-Li Zhang, Zhi-Xian Ma “Experimental study on single-phase flow in horizontal internal helically-finnedtubes: the
critical Reynolds number for turbulent flow,” https://doi.org/10.1016/j.expthermflusci.2017.11.003.
11. Peilun Wang, Hua Yao, ZhipengLan, ZhijianPeng, Yun Huang, Yulong Ding, “Numerical investigation of PCM melting process in sleeve tube withinternalfins”Energy Conversion and Management 110 (2016) 428–435.
12. HaoPeng., “Thermo-hydraulic performances of internally finned tube with a new type wave fin arrays,http://dx.doi.org/doi:
10.1016/j.applthermaleng.
13. Y. Naresh, C. Balaji, “Experimental investigations of heat transfer from an internally finned two phaseclosed
thermosyphon”http://dx.doi.org/10.1016/j.applthermaleng.2016.10.084.
14. Dong-Kwon Kim, “Thermal optimization of internally finned tube with variable fin thickness,”
http://dx.doi.org/10.1016/j.applthermaleng.2016.04.060.
15. YounghwanJoo, Sung Jin Kim, “Thermal optimization of vertically oriented, internally finned tubesin natural convection,” International Journal of Heat and Mass Transfer 93 (2016) 991–999.
16. AlaaRuhma Al-Badri, Andreas Bär, AchimGotterbarm, Michael Heinrich Rausch Andreas Paul Fröba, “The influence of fin structure
and fin density on the condensation heattransfer of R134a on single finned tubes and in tube bundles,” International Journal of Heat and Mass Transfer 100 (2016) 582–589.
17. José Fernández-Seara, Ángel Á. Pardiñas, Rubén Diz, “Heat transfer enhancement of ammonia pool boiling with an integral-fintube,”
http://dx.doi.org/doi: 10.1016/j.ijrefrig.2016.05.012.
18. Min Zeng, Ting Ma, BengtSundén, Mohamed B. Trabia, Qiuwang Wang, “Effect of lateral fin profiles on stress performance of
internallyfinned tubes in a high temperature heat exchanger,” Applied Thermal Engineering 50 (2013) 886e895.
19. Yungang Wang, Qinxin Zhao, Qulan Zhou, Zijin Kang, Wenquan Tao, “Experimental and numerical studies on actual flue gas
condensationheat transfer in a left–right symmetric internally finned tube,” International Journal of Heat and Mass Transfer 64 (2013)
10–20.
20. 19.A. Szajding , T. Telejko, R. Straka, A. Gołdasz, “Experimental and numerical determination of heat transfer coefficient betweenoil and outer surface of monometallic tubes finned on both sides with twistedinternal longitudinal fins,” International Journal of Heat and Mass Transfer 58 (2013) 395–401.
Thermal Engineering 137 (2022) 669–677
2. LuanfangDuan, Xiang Ling, HaoPeng, Flow and heat transfer characteristics of a double-tube structure internalfinned tube with
blossom shape internal fins, Applied Thermal Engineering 128 (2018) 1102–1115.
3. M.J. Li, H. Zhang, J. Zhang, Y.T. Mu, E. Tian, D. Dan, X.D. Zhang, W.Q. Tao, “Experimental and numerical Study and Comparison of
Performance for WavyFin and a Plain Fin with Radiantly Arranged Winglets around Each Tube in Finand-tube Heat Exchangers”,
https://doi.org/10.1016/j.applthermaleng.2021
4. Mohammad. Sikindar Baba, A.V.Sita Rama Raju,M.BhagvanthRao, Heat transfer enhancement and pressure drop ofFe3O4 -water
nanofluid in a double tube heatexchanger with internal longitudinal fins, https://doi.org/10.1016/j.csite.2018.08.001.
5. SwastikAcharya, Sukanta K. Dash, Natural convection heat transfer from a horizontal hollow cylinder withinternal longitudinal fins,
International Journal of Thermal Sciences 134 (2021) 40–539.
6. GuodongQiu, Jian Sun, Yuanyang Ma, JiagangQu, WeihuaCai, Theoretical study on the heat transfer characteristics of a plain fin in
thefinned-tube evaporator assisted by solar energy, International Journal of Heat and Mass Transfer 127 (2018) 847–855.
7. EvangelosBellos, Christos Tzivanidis, DimitriosTsimpoukis, “Optimum number of internal fins in parabolic trough collectors, Applied
Thermal Engineering 137 (2019) 669–677
8. Mohammad Sepehr, SeyedSaeedHashemi,MohammadRahjoo, VahidFarhangmehr, AshkanAlimoradi, “Prediction of heat transfer,
pressure drop and entropygeneration in shell and helically coiled finned tube heatexchangers”, https://doi.org/10.1016/j.cherd.2018
9. EvangelosBellos, Christos Tzivanidis, DimitriosTsimpoukis, Thermal enhancement of parabolic trough collector with internally
finnedabsorbers, Solar Energy 157 (2017) 514–531.
10. Yong-Hui Wang, Ji-Li Zhang, Zhi-Xian Ma “Experimental study on single-phase flow in horizontal internal helically-finnedtubes: the
critical Reynolds number for turbulent flow,” https://doi.org/10.1016/j.expthermflusci.2017.11.003.
11. Peilun Wang, Hua Yao, ZhipengLan, ZhijianPeng, Yun Huang, Yulong Ding, “Numerical investigation of PCM melting process in sleeve tube withinternalfins”Energy Conversion and Management 110 (2016) 428–435.
12. HaoPeng., “Thermo-hydraulic performances of internally finned tube with a new type wave fin arrays,http://dx.doi.org/doi:
10.1016/j.applthermaleng.
13. Y. Naresh, C. Balaji, “Experimental investigations of heat transfer from an internally finned two phaseclosed
thermosyphon”http://dx.doi.org/10.1016/j.applthermaleng.2016.10.084.
14. Dong-Kwon Kim, “Thermal optimization of internally finned tube with variable fin thickness,”
http://dx.doi.org/10.1016/j.applthermaleng.2016.04.060.
15. YounghwanJoo, Sung Jin Kim, “Thermal optimization of vertically oriented, internally finned tubesin natural convection,” International Journal of Heat and Mass Transfer 93 (2016) 991–999.
16. AlaaRuhma Al-Badri, Andreas Bär, AchimGotterbarm, Michael Heinrich Rausch Andreas Paul Fröba, “The influence of fin structure
and fin density on the condensation heattransfer of R134a on single finned tubes and in tube bundles,” International Journal of Heat and Mass Transfer 100 (2016) 582–589.
17. José Fernández-Seara, Ángel Á. Pardiñas, Rubén Diz, “Heat transfer enhancement of ammonia pool boiling with an integral-fintube,”
http://dx.doi.org/doi: 10.1016/j.ijrefrig.2016.05.012.
18. Min Zeng, Ting Ma, BengtSundén, Mohamed B. Trabia, Qiuwang Wang, “Effect of lateral fin profiles on stress performance of
internallyfinned tubes in a high temperature heat exchanger,” Applied Thermal Engineering 50 (2013) 886e895.
19. Yungang Wang, Qinxin Zhao, Qulan Zhou, Zijin Kang, Wenquan Tao, “Experimental and numerical studies on actual flue gas
condensationheat transfer in a left–right symmetric internally finned tube,” International Journal of Heat and Mass Transfer 64 (2013)
10–20.
20. 19.A. Szajding , T. Telejko, R. Straka, A. Gołdasz, “Experimental and numerical determination of heat transfer coefficient betweenoil and outer surface of monometallic tubes finned on both sides with twistedinternal longitudinal fins,” International Journal of Heat and Mass Transfer 58 (2013) 395–401.
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