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Thermal Performance of a Helical Coil Heat Exchanger Utilizing Nanofluids: A Review | ||
| Journal of Heat and Mass Transfer Research | ||
| دوره 10، شماره 1 - شماره پیاپی 19، شهریور 2023، صفحه 121-134 اصل مقاله (1.11 M) | ||
| نوع مقاله: Review Article | ||
| شناسه دیجیتال (DOI): 10.22075/jhmtr.2023.30124.1428 | ||
| نویسندگان | ||
| Mustafa Sabah Abdullah* 1، 2؛ Adnan Mohammed Hussein1 | ||
| 1Northern Technical University, Kirkuk, 36001, Iraq | ||
| 2Erbil Polytechnic University, Erbil, 44001, Iraq | ||
| تاریخ دریافت: 16 اسفند 1401، تاریخ بازنگری: 06 شهریور 1402، تاریخ پذیرش: 06 شهریور 1402 | ||
| چکیده | ||
| The manufacturing process of heating systems involves incorporating various heat exchangers, each with distinct characteristics. Among these, the helical heat exchanger stands out due to its space-efficient design and enhanced heat transfer rate compared to other variants. Recently, heat exchangers have witnessed novel nanofluid explorations aiming to replace conventional working fluids. Nanofluids possess unique properties that hold the potential for substantial improvements, consequently influencing the efficiency of heat exchangers employing them. The effectiveness of these heat exchangers is intrinsically tied to the properties of the employed nanofluids. Recent years have witnessed remarkable strides in comprehending the distinct traits exhibited by diverse nanofluids. This comprehensive study amalgamates findings from multiple investigations focused on helical-tube heat exchangers utilizing nanofluids as the primary medium. Notably, it underscores the existence of varying conclusions and perspectives among different researchers. This variance arises from the complexity of nanofluid behavior and its interactions within heat exchangers. Consequently, the efficacy of helical heat exchangers leveraging nanofluids hinges on the specifics of the chosen nanofluid and its characteristics. This subject continues to stimulate vigorous research and discussions among scholars. In summation, the dynamic landscape of heat exchanger innovation has brought the spotlight onto helical heat exchangers and their integration with nanofluids, showcasing the intricate interplay between fluid properties and efficient heat exchange. | ||
| کلیدواژهها | ||
| Nanofluid؛ Shell and coil heat exchanger؛ Thermal performance؛ Pitch ratio؛ Nusselt number | ||
| مراجع | ||
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[1] Bakhtiyar, N. K., Esmaeili, S., Javadpour, R., & Heris, S. Z., 2023. Experimental investigation of indirect heat transfer through a novel designed lab-scale setup using functionalized MWCNTs nanofluids (MWCNTs-COOH/water and MWCNTs-OH/water). Case Studies in Thermal Engineering, 45, 102951.
[2] Abdelghany, M. T., Sharafeldin, M. A., Abdellatif, O. E., & Elshamy, S. M., 2023. Experimental Investigation of the Thermal-hydraulic Performance of Conically Coiled Tubes using Al2O3/Water Nanofluid. Journal of Engineering Research, 7(1), 141-149.
[3] Tuncer, A. D., Khanlari, A., Sözen, A., Gürbüz, E. Y., & Variyenli, H. I., 2023. Upgrading the performance of shell and helically coiled heat exchangers with new flow path by using TiO2/water and CuO–TiO2/water nanofluids. International Journal of Thermal Sciences, 183, 107831.
[4] Hasan, S. S., Baqir, A. S., & Mahood, H. B., 2021. The effect of injected air bubble size on the thermal performance of a vertical shell and helical coiled tube heat exchanger. Energy Engineering, 118(6), 1595-1609.
[5] Zarei, A., Seddighi, S., Elahi, S., & Örlü, R., 2022. Experimental investigation of the heat transfer from the helical coil heat exchanger using bubble injection for cold thermal energy storage system. Applied Thermal Engineering, 200, 117559.
[6] Ahmed, F., 2021. Experimental investigation of Al2O3-water nanofluid as a secondary fluid in a refrigeration system. Case Studies in Thermal Engineering, 26, 101024.
[7] Shiravi, A. H., Shafiee, M., Firoozzadeh, M., Bostani, H., & Bozorgmehrian, M., 2021. Experimental study on convective heat transfer and entropy generation of carbon black nanofluid turbulent flow in a helical coiled heat exchanger. Journal of Thermal Analysis and Calorimetry, 145, 597-607.
[8] Singh, K., Sharma, S. K., & Gupta, S. M., 2021. An experimental investigation of hydrodynamic and heat transfer characteristics of surfactant-water solution and CNT nanofluid in a helical coil-based heat exchanger. Materials Today: Proceedings, 43, 3896-3903.
[9] Chandra, D. S., Hebbal, O., & kumar Reddy, K. V., 2021. Experimental analysis of heat transfer coefficient in counter flow shell and helical coil tube heat exchanger with hybrid nanofluids to enhance heat transfer rate using in food processing industries. Turkish Journal of Computer and Mathematics Education Vol, 12(2), 2868-2875.
[10] Hozien, O., El-Maghlany, W. M., Sorour, M. M., & Mohamed, Y. S., 2021. Experimental study on thermophysical properties of TiO2, ZnO and Ag water base nanofluids. Journal of molecular liquids, 334, 116128.
[11] Elshamy, S. M., Abdelghany, M. T., Salem, M. R., & Abdellatif, O. E., 2020. Energy and exergy analysis of shell and coil heat exchanger using water based Al2O3 nanofluid including diverse coil geometries: An experimental study. Journal of Nanofluids, 9(1), 13-23.
[12] Radwan, M. A., Salem, M. R., Refaey, H. A., & Moawed, M. A., 2019. Experimental study on convective heat transfer and pressure drop of water flow inside conically coiled tube-in-tube heat exchanger. Journal Homepage: www. feng. bu. edu. eg, 1(39), 86-93.
[13] Shankar, N., Parambakkattur, P. S., & Chandran, M., 2023. Heat transfer enhancement in a helically coiled convergent and divergent tube heat exchanger with alumina oxide nanofluid. Thermal Science, (00), 140-140.
[14] Abdullah, M. S., & Hussein, A. M., 2023. Impact of coil pitch on heat transfer enhancement of a turbulent flow of α-Al2O3/DW nanofluid through helical coils. Thermal Science, (00), 131-131.
[15] Algarni, S., Tirth, V., Alqahtani, T., Kshirsagar, P. R., & Abera, W., 2022. An Empirical Analysis of Heat Expulsion and Pressure Drop Attribute in Helical Coil Tube Using Nanomaterials. Journal of Nanomaterials, 2022.
[16] Maghrabie, H. M., Attalla, M., & Mohsen, A. A., 2021. Performance assessment of a shell and helically coiled tube heat exchanger with variable orientations utilizing different nanofluids. Applied Thermal Engineering, 182, 116013.
[17] Kulkarni, H. R., Dhanasekaran, C., Rathnakumar, P., & Sivaganesan, S., 2021. Experimental study on thermal analysis of helical coil heat exchanger using Green synthesis silver nanofluid. Materials Today: Proceedings, 42, 1037-1042..
[18] Rai, N., & Hegde, R. N., 2020. Thermal performance enhancement studies on a circular finned coil-in-shell heat exchanger using graphene oxide nanofluid. SN Applied Sciences, 2, 1-15.
[19] Lanjewar, A., Bhanvase, B., Barai, D., Chawhan, S., & Sonawane, S., 2020. Intensified thermal conductivity and convective heat transfer of ultrasonically prepared CuO–polyaniline nanocomposite based nanofluids in helical coil heat exchanger. Periodica Polytechnica Chemical Engineering, 64(2), 271-282.
[20] Koshta, N. R., Bhanvase, B. A., Chawhan, S. S., Barai, D. P., & Sonawane, S. H., 2020. Investigation on the thermal conductivity and convective heat transfer enhancement in helical coiled heat exchanger using ultrasonically prepared rGO–TiO2 nanocomposite-based nanofluids. Indian Chemical Engineer, 62(2), 202-215.
[21] Sunu, P. W., Anakottapary, D. S., Susila, I. D. M., Santosa, I. D. M. C., & Indrayana, I. N. E., 2020. Study of thermal effectiveness in shell and helically coiled tube heat exchanger with addition nanoparticles. In Journal of Physics: Conference Series, 1569(3), 032038.
[22] Ardekani, A. M., Kalantar, V., & Heyhat, M. M., 2019. Experimental study on heat transfer enhancement of nanofluid flow through helical tubes. Advanced Powder Technology, 30(9), 1815-1822.
[23] K. Palanisamy and P. C. Mukesh Kumar, "Experimental investigation on convective heat transfer and pressure drop of cone helically coiled tube heat exchanger using carbon nanotubes/water nanofluids," Heliyon, vol. 5, no. 5, p. e01705, 2019, doi: 10.1016/j.heliyon.2019.e01705.
[24] Radkar, R. N., Bhanvase, B. A., Barai, D. P., & Sonawane, S. H., 2019. Intensified convective heat transfer using ZnO nanofluids in heat exchanger with helical coiled geometry at constant wall temperature. Materials Science for Energy Technologies, 2(2), 161-170.
[25] Daghigh, R., & Zandi, P., 2018. Experimental analysis of heat transfer in spiral coils using nanofluids and coil geometry change in a solar system. Applied Thermal Engineering, 145, 295-304.
[26] Naik, B. A. K., & Vinod, A. V., 2018. Heat transfer enhancement using non-Newtonian nanofluids in a shell and helical coil heat exchanger. Experimental Thermal and Fluid Science, 90, 132-142.
[27] Kabeel, A. E., El-Said, E. M., & Abdulaziz, M., 2017. Thermal solar water heater with H2O-Al2O3 nano-fluid in forced convection: experimental investigation. International Journal of Ambient Energy, 38(1), 85-93.
[28] Fule, P. J., Bhanvase, B. A., & Sonawane, S. H., 2017. Experimental investigation of heat transfer enhancement in helical coil heat exchangers using water based CuO nanofluid. Advanced Powder Technology, 28(9), 2288-2294.
[29] Srinivas, T., & Vinod, A. V., 2016. Heat transfer intensification in a shell and helical coil heat exchanger using water-based nanofluids. Chemical Engineering and Processing: Process Intensification, 102, 1-8.
[30] Tajik, M., Dehghan, M., & Zamzamian, A., 2015. Analysis of variance of nanofluid heat transfer data for forced convection in horizontal spirally coiled tubes. Journal of Heat and Mass Transfer Research, 2(2), 45-50.
[31] Sultan, K. F., Rishag, H. T., & Fadhal, J. M., 2015. Augmentation of heat transfer for spiral coil heat exchanger in solar energy systems by using nano fluids. In The 5th International Scientific Conference for Nanotechnology and Advanced Materials and Their Applications ICNAMA (Vol. 2015)..
[32] Kahani, M., Heris, S. Z., & Mousavi, S. M., 2013. Effects of curvature ratio and coil pitch spacing on heat transfer performance of Al2O3/water nanofluid laminar flow through helical coils. Journal of Dispersion Science and Technology, 34(12), 1704-1712.
[33] Hashemi, S. M., & Akhavan-Behabadi, M. A., 2012. An empirical study on heat transfer and pressure drop characteristics of CuO–base oil nanofluid flow in a horizontal helically coiled tube under constant heat flux. International Communications in Heat and Mass Transfer, 39(1), 144-151.
[34] Srinivas, T., & Vinod, A. V., 2015. Heat transfer enhancement using CuO/water nanofluid in a shell and helical coil heat exchanger. Procedia engineering, 127, 1271-1277.
[35] Khorasani, S., & Dadvand, A., 2017. Effect of air bubble injection on the performance of a horizontal helical shell and coiled tube heat exchanger: An experimental study. Applied Thermal Engineering, 111, 676-683.
[36] Kahani, M., Heris, S. Z., & Mousavi, S. M., 2013. Comparative study between metal oxide nanopowders on thermal characteristics of nanofluid flow through helical coils. Powder technology, 246, 82-92.
[37] Suresh M., 2023. Numerical investigations on a triple fluid heat exchanger with helical and sinusoidal coils. Journal of Energy Systems, 7(1), 46-56.
[38] Li, Y. X., Wu, J. H., Wang, H., Kou, L. P., & Tian, X. H., 2012. Fluid flow and heat transfer characteristics in helical tubes cooperating with spiral corrugation. Energy Procedia, 17, 791-800.
[39] ABED T. H., & KOÇ I., 2021. Thermal Performance Improvement of Shell and Helical Coil Heat Exchanger. AURUM Journal of Engineering Systems and Architecture, 5(2), 237-259.
[40] Heydari, O., Miansari, M., Arasteh, H., & Toghraie, D., 2021. Optimizing the hydrothermal performance of helically corrugated coiled tube heat exchangers using Taguchi's empirical method: energy and exergy analysis. Journal of Thermal Analysis and Calorimetry, 145, 2741-2752.
[41] Miansari, M., Jafarzadeh, A., Arasteh, H., & Toghraie, D., 2021. Thermal performance of a helical shell and tube heat exchanger without fin, with circular fins, and with V-shaped circular fins applying on the coil. Journal of Thermal Analysis and Calorimetry, 143, 4273-4285.
[42] Hasan, M. J., Ahmed, S. F., & Bhuiyan, A. A., 2022. Geometrical and coil revolution effects on the performance enhancement of a helical heat exchanger using nanofluids. Case Studies in Thermal Engineering, 35, 102106.
[43] Zaboli, M., Saedodin, S., Mousavi Ajarostaghi, S. S., & Nourbakhsh, M., 2021. Numerical evaluation of the heat transfer in a shell and corrugated coil tube heat exchanger with three various water‐based nanofluids. Heat Transfer, 50(6), 6043-6067.
[44] Zaboli, M., Nourbakhsh, M., & Ajarostaghi, S. S. M., 2022. Numerical evaluation of the heat transfer and fluid flow in a corrugated coil tube with lobe-shaped cross-section and two types of spiral twisted tape as swirl generator. Journal of Thermal Analysis and Calorimetry, 147, 999-1015.
[45] Omidi, M., Farhadi, M., & Darzi, A. A. R., 2018. Numerical study of heat transfer on using lobed cross sections in helical coil heat exchangers: effect of physical and geometrical parameters. Energy conversion and management, 176, 236-245.
[46] Wang, J., Hashemi, S. S., Alahgholi, S., Mehri, M., Safarzadeh, M., & Alimoradi, A., 2018. Analysis of Exergy and energy in shell and helically coiled finned tube heat exchangers and design optimization. International Journal of Refrigeration, 94, 11-23.
[47] Aly, W. I., 2014. Numerical study on turbulent heat transfer and pressure drop of nanofluid in coiled tube-in-tube heat exchangers. Energy Conversion and Management, 79, 304-316.
[48] Darzi, A. R., Farhadi, M., Sedighi, K., Aallahyari, S., & Delavar, M. A., 2013. Turbulent heat transfer of Al2O3–water nanofluid inside helically corrugated tubes: numerical study. International Communications in Heat and Mass Transfer, 41, 68-75.
[49] Najm, A., Jumaah, I. D., & Karim, A. M. E. A., 2022. Effect of Using A Double Coil Tube with Modified Pitch on The Overall Heat Transfer Rate. Diyala Journal of Engineering Sciences, 40-53.
[50] Ghaderi, A., Veysi, F., Aminian, S., Andami, Z., & Najafi, M., 2022. Experimental and Numerical Study of Thermal Efficiency of Helically Coiled Tube Heat Exchanger Using Ethylene Glycol-Distilled Water Based Fe3O4 Nanofluid. International Journal of Thermophysics, 43(8), 118.
[51] Larpruenrudee, P., Bennett, N. S., Gu, Y., Fitch, R., & Islam, M. S., 2022. Design optimization of a magnesium-based metal hydride hydrogen energy storage system. Scientific Reports, 12(1), 13436.
[52] Mahdi, A. S., Kalash, A. R., Suffer, K. H., & Habeeb, L. J., 2020. Experimental And Numerical Investigation Of Heat Transfer Enhancement By Using Different Geometry Coiled Tubes. Journal of Mechanical Engineering Research and Developments, 43(4), 92-104.
[53] Sheeba, A., Abhijith, C. M., & Prakash, M. J., 2019. Experimental and numerical investigations on the heat transfer and flow characteristics of a helical coil heat exchanger. International Journal of Refrigeration, 99, 490-497.
[54] Boumari, E., Amiri, M. M., Khadang, A., Maddah, H., Ahmadi, M. H., & Sharifpur, M., 2023. Numerical investigation of heat transfer in helical tubes modified with aluminum oxide nanofluid and modeling of data obtained by artificial neural network. Numerical Heat Transfer, Part A: Applications, 83(3), 265-284.
[55] Prof. Om Prakash, Jha S. K., 2020. Effect of MWCNT/Water Nanofluid on Heat Transfer Enhancement in a Shell-and-coiled Tube Exchanger using CFD. International Journal of Trend in Scientific Research and Development (ijtsrd), 4(6), 1004-1014,
[56] Guo, W., Li, G., Zheng, Y., & Dong, C., 2020. The effect of flow pulsation on Al2O3 nanofluids heat transfer behavior in a helical coil: a numerical analysis. Chemical Engineering Research and Design, 156, 76-85.
[57] Hasan, A. F., & Hossain, S. T., 2020. Numerical Investigation of Heat Transfer Rate in Helically Coiled Pipe Using Al2O3/Water Nanofluid. Diyala Journal of Engineering Sciences, 27-36.
[58] Zaboli, M., Ajarostaghi, S. S. M., Noorbakhsh, M., & Delavar, M. A., 2019. Effects of geometrical and operational parameters on heat transfer and fluid flow of three various water based nanofluids in a shell and coil tube heat exchanger. SN Applied Sciences, 1, 1-17.
[59] Kumar, P. M., & Chandrasekar, M., 2019. CFD analysis on heat and flow characteristics of double helically coiled tube heat exchanger handling MWCNT/water nanofluids. Heliyon, 5(7).
[60] Bahrehmand, S., & Abbassi, A., 2016. Heat transfer and performance analysis of nanofluid flow in helically coiled tube heat exchangers. Chemical Engineering Research and Design, 109, 628-637.
[61] Sisodiya, V., & Geete, A., 2016. Heat Transfer Analysis of Helical Coil Heat Exchanger with Al2O3 Nanofluid. Int. Res. J. Eng. Technol, 3(12), 366-370.
[62] Fsadni, A. M., Whitty, J. P., Stables, M. A., & Adeniyi, A. A., 2017. Numerical study on turbulent heat transfer and pressure drop characteristics of a helically coiled hybrid rectangular-circular tube heat exchanger with Al2O3-water nanofluids. Applied Thermal Engineering, 114, 466-483.
[63] Ranjbar, S. F., & Seyyedvalilu, M. H., 2014. The effect of geometrical parameters on heat transfer coefficient in helical double tube exchangers. Journal of Heat and Mass Transfer Research, 1(2), 75-82.
[64] Khairul, M. A., Saidur, R., Rahman, M. M., Alim, M. A., Hossain, A., & Abdin, Z., 2013. Heat transfer and thermodynamic analyses of a helically coiled heat exchanger using different types of nanofluids. International Journal of Heat and Mass Transfer, 67, 398-403.
[65] Mola A., Askar A. & Salman G., 2020. Experimental Enhancement of Helical Coil Tube Heat Exchanger Using CuFe2O4/Water Nanofluids. Journal of Mechanical Engineering Research and Developments. 43. 94-105.
[66] Rakhsha, M., Akbaridoust, F., Abbassi, A., & Majid, S. A., 2015. Experimental and numerical investigations of turbulent forced convection flow of nano-fluid in helical coiled tubes at constant surface temperature. Powder Technology, 283, 178-189.
[67] Akbaridoust, F., Rakhsha, M., Abbassi, A., & Saffar-Avval, M., 2013. Experimental and numerical investigation of nanofluid heat transfer in helically coiled tubes at constant wall temperature using dispersion model. International Journal of Heat and Mass Transfer, 58(1-2), 480-491.
[68] Amori, K. E., & Sherza, J. S., 2013. An investigation of shell-helical coiled tube heat exchanger used for solar water heating system. Innovative Systems Design and Engineering, 4(15), 78-90.
[69] Naphon, P., & Suwagrai, J., 2007. Effect of curvature ratios on the heat transfer and flow developments in the horizontal spirally coiled tubes. International Journal of Heat and Mass Transfer, 50(3-4), 444-451. | ||
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آمار تعداد مشاهده مقاله: 246 تعداد دریافت فایل اصل مقاله: 208 |
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