Determining the Optimal Range of Volume Fraction of Nanofluid in an Evaporator Tube by Eulerian-Lagrangian Method

Document Type : Research Paper

Authors

Mechanical Engineering Department, Shahid Rajaee Teacher Training University, Tehran, Iran

Abstract

The addition of nanoparticles to the base fluid has adverse consequences, including a greater pressure drop than the base fluid, which leads to an increase in pump work, which is not economical. To improve the efficiency, we must look for a suitable range of particle volume fraction so that by adding this amount to the base fluid, the increase in heat transfer is greater than the increase in pressure drop. In this study, by introducing the criterion ratio of PEC performance evaluation, this suitable range of volume fraction for several types of individual particles and mixed particles in a part of an evaporator tube has been determined by numerical calculations and Eulerian-Lagrangian approach. The results showed that the use of mixed nanoparticles in the volume percentage range of less than 1% has better feedback than the nanofluid with single type particles. For water-ethylene glycol/Co nanofluid, this optimal volume percentage range is between 0.01 and 0.2 percent, and for water-ethylene glycol/CuO it is 0.01 to 0.14, and for the combined nanoparticle water-ethylene glycol/ Al2O3+TiO2 is equal to 0.01 to 0.04, for water-ethylene glycol/Al2O3 up to 0.03 percent by volume. Water-ethylene glycol/SiO2 nanofluid always has a PEC ratio of nanofluid and fluid less than 1, and from this point of view, its use in heat exchanger is not economical.

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References

[1] Webb, Robert Louis. Principles of Enhanced Heat Transfer. John Wiley & Sons, New York, 1994.
[2] Mousa, Mohamed Hassan, Nikola Miljkovic, and Khurram Nawaz. "Review of Heat Transfer Enhancement Techniques for Single Phase Flows." Renewable and Sustainable Energy Reviews 137 (2021): 110566.
[3] Gupta, Mohit, Vikram Singh, Rakesh Kumar, and Zahir Ahmad Said. "A Review on Thermophysical Properties of Nanofluids and Heat Transfer Applications." Renewable and Sustainable Energy Reviews 74 (2017): 638–670.
[4] Angayarkanni, Sathish Anoop, and John Philip. "Review on Thermal Properties of Nanofluids: Recent Developments." Advances in Colloid and Interface Science 225 (2015): 146–176.
[5] Ilyas, Syed Usman, Ramesh Pendyala, and Nabil Marmeni. "Stability of Nanofluids." In Engineering Applications of Nanotechnology: From Energy to Drug Delivery. Springer, Berlin/Heidelberg, 2017.
[6] Abdullah, Muhammad, Syed Rizwan Malik, Muhammad Hassan Iqbal, Muhammad Mujtaba Sajid, Nadeem Ahmad Shad, Shahzad Zafar Hussain, and Waqar Razzag. "Sedimentation and Stabilization of Nanofluids with Dispersant." Colloids and Surfaces A 554 (2018): 86–92.
[7] Kamyar, Ali, Rashed Saidur, and Mohammad Hasanuzzaman. "Application of Computational Fluid Dynamics (CFD) for Nanofluids." International Journal of Heat and Mass Transfer 55 (2012): 4104–4115.
[8] Kumar, Sandeep, and Subrata Anupam Chakrabarti. "A Review: Enhancement of Heat Transfer with Nanofluids." International Journal of Engineering Research and Technology 3 (2014): 549–557.
[9] Kakac, Sadik, and Apichart Pramuanjaroenkij. "Single-Phase and Two-Phase Treatments of Convective Heat Transfer Enhancement with Nanofluids." International Journal of Thermal Sciences 100 (2016): 75–97.
[10] Mahian, Omid, Lyes Kolsi, Mehdi Amani, Patrick Estellé, Goodarz Ahmadi, Clement Kleinstreuer, James Stephen Marshall, Richard Alan Taylor, and Masoud Siavashi. "Recent Advances in Modeling and Simulation of Nanofluid Flows – Part I." Physics Reports 790 (2019): 1–48.
[11] Mahian, Omid, Lyes Kolsi, Mehdi Amani, Patrick Estellé, Goodarz Ahmadi, Clement Kleinstreuer, James Stephen Marshall, Richard Alan Taylor, and Saeid Rashidi. "Recent Advances in Modeling and Simulation of Nanofluid Flows – Part II." Physics Reports 791 (2019): 1–59.
[12] Boertz, Henning, Alexander Johannes Baars, Jan Tomasz Cieslinski, and Stanislaw Smolen. "Numerical Study of Turbulent Flow and Heat Transfer of Nanofluids in Pipes." Heat Transfer Engineering 39 (2018): 241–251.
[13] Kristiawan, Budi, Budi Santoso, Agung Tri Wijayanta, Muhammad Aziz, and Takashi Miyazaki. "Heat Transfer Enhancement of TiO₂/Water Nanofluid." Energies 11 (2018): 1584.
[14] Sajjad, Muhammad, Muhammad Salman Kamran, Rashid Shaukat, and Mohammed Ismail Mohammed Zeinelabdeen. "Numerical Investigation of Laminar Convective Heat Transfer of Graphene Oxide/Ethylene Glycol–Water Nanofluids." Engineering Science and Technology 21 (2018): 727–735.
[15] Minea, Adrian Aurelian, Bruno Buonomo, Johannes Burggraf, Davide Ercole, Kiran Raj Karpaiya, Andrea Di Pasqua, Ghislain Sekrani, Jens Steffens, Jure Tibaut, and Norbert Wichmann. "NanoRound: A Benchmark Study on the Numerical Approach in Nanofluids Simulation." International Communications in Heat and Mass Transfer 108 (2019): 104292.
[16] Onyiriuka, Efe Joseph, and Edward Andrew Ikponmwonba. "Numerical Investigation of Mango Leaves–Water Nanofluid under Laminar Flow Regime." Nigerian Journal of Technology 38 (2019): 348–354.
[17] Jamali, Mohammad, and Davood Toghranie. "Investigation of Heat Transfer Characteristics in the Developing and Developed Flow of Nanofluid Inside a Tube with Different Entrances in the Transition Regime." Journal of Thermal Analysis and Calorimetry 139 (2020): 685–699.
[18] Fadodun, Olumide Gabriel, Akeem Adewale Amosun, Adewale Olusegun Salau, Damilola Oluwaseun Olaloye, Joseph Ayodeji Ogundeji, Folorunso Isaac Ibitoye, and Funsho Adekunle Balogun. "Numerical Investigation and Sensitivity Analysis of Turbulent Heat Transfer of Al₂O₃/H₂O Nanofluid." Archives of Thermodynamics 41 (2020): 3–30.
[19] Saeed, Faris Raheem, and Mohammed Ali Al-Dulaimi. "Numerical Investigation for Convective Heat Transfer of Nanofluid Laminar Flow Inside a Circular Pipe." Archives of Thermodynamics 42 (2021): 71–95.
[20] Uribe, Sebastian, Nabil Zouli, and Miguel Ernesto Cordero. "Development and Validation of a Mathematical Model to Predict the Thermal Behaviour of Nanofluids." Heat and Mass Transfer 57 (2021): 93–110.
[21] Taskesen, Erhan, Emre Tekir, and Emrah Gedik. "Numerical Investigation of Laminar Forced Convection and Entropy Generation of Fe₃O₄/Water Nanofluids." Journal of Thermal Engineering 7 (2021): 1752–1767.
[22] Yildiz, Murat, and Ahmet Aktürk. "Numerical Investigation on Heat Transfer and Hydraulic Performance of Al₂O₃–Water Nanofluid." International Journal of Heat and Mass Transfer 115 (2021): 535–547.
[23] Zhang, Xing, and Jian Li. "A Review of Uncertainties in the Study of Heat Transfer Properties of Nanofluids." Heat and Mass Transfer 58 (2022): 1–33.
[24] Ndoye, Fallou Tall, Philippe Schalbart, Didier Leducq, and Gilles Alvarez. "Numerical Study of Energy Performance of Nanofluids Used in Secondary Loops of Refrigeration Systems." International Journal of Refrigeration (2014).
[25] Hemmat Esfe, Mohammad. Designing an Artificial Neural Network Using Radial Basis Function (RBF-ANN) to Model Thermal Conductivity of Ethylene Glycol-Based Nanofluids. 2016.
[26] Hemmat Esfe, Mohammad, and Ali Akbar Abbasian Arani. "Experimental Determination and Accurate Prediction of Dynamic Viscosity of MWCNT(40)–SiO₂(60)/5W50 Nano-Lubricant." Journal of Molecular Liquids (2017).
[27] Hemmat Esfe, Mohammad, Hossein Rostamian, and Mohammad Reza Sarlak. "A Novel Study on Rheological Behavior of ZnO–MWCNT/10W40 Nanofluid." Journal of Molecular Liquids 254 (2018): 406–413.
[28] Hemmat Esfe, Mohammad, and Soheil Aliodust. "Modeling and Precise Prediction of Thermophysical Attributes of Water/EG Blend-Based CNT Nanofluids." Arabian Journal for Science and Engineering (2020).
[29] Goutam, Suman, and Manabendra Chandra Paul. "Discrete Phase Approach for Nanofluids Flow in Pipe." Proceedings of the Second International Conference on Advances in Civil, Structural and Mechanical Engineering (CSM 2014), Birmingham, UK.
[30] Selvakumar, Ramachandran Deepak, and Subramanian Dhinakaran. "Heat Transfer and Particle Migration in Nanofluid Flow around a Circular Bluff Body." International Journal of Heat and Mass Transfer 115 (2017): 282–293.
[31] Bovand, Mohammad, Ghasem Rashidi, Javad Ali Ahmadi, and Mohammad Esfahani. "Effects of Trap and Reflect Particle Boundary Conditions on Particle Transport and Convective Heat Transfer for Duct Flow." Applied Thermal Engineering (2016).
[32] Murshed, Shafiul Mahmud, Kai Choong Leong, and Chun Yang. "Thermophysical and Electrokinetic Properties of Nanofluids: A Critical Review." Applied Thermal Engineering 28 (2018): 2109–2125.
[33] Zakaria, Laila, Sakina El-Hamdani, Abdelaziz Bendou, and Karim Limam. "Numerical Study of the Turbulent Natural Convection of Nanofluids in a Partially Heated Cubic Cavity." Thermal Science 25 (2021): 57–67.
[34] Melinder, Anders. Properties of Secondary Working Fluids for Indirect Systems. International Institute of Refrigeration, Paris, 2010.
[35] Vajiha, Rajesh Subhash, Dinesh Kumar Das, and Balaji Mahagaonkar. "Density Measurement of Different Nanofluids and Their Comparison with Theory." Petroleum Science and Technology 27 (2009): 612–624.
[36] Murshed, Shafiul Mahmud. "Determination of Effective Specific Heat of Nanofluids." Journal of Experimental Nanoscience 6 (2011): 539–546.
[37] Maxwell, James Clerk. A Treatise on Electricity and Magnetism. Clarendon Press, Oxford, 1881.
[38] Hamilton, Robert Lee, and Oliver Kenneth Crosser. "Thermal Conductivity of Heterogeneous Two-Component Systems." Industrial & Engineering Chemistry Fundamentals 1 (1962): 187–191.
[39] Jung, Jong-Yun, Changho Cho, Won Ho Lee, and Yong Tae Kang. "Thermal Conductivity Measurement and Characterization of Binary Nanofluids." International Journal of Heat and Mass Transfer 54 (2011): 1728–1733.
[40] Ferrouillat, Sylvain, Alain Bontemps, Jean-Pierre Ribeiro, Jean-Antoine Gruss, and Olivier Soriano. "Hydraulic and Heat Transfer Study of SiO₂/Water Nanofluids in Horizontal Tubes." International Journal of Heat and Fluid Flow 32 (2011): 424–439.
 
Journal of Modeling in Engineering
Volume 24, Issue 84
In Progress
March 2026
Pages 71-86

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History

  • Receive Date: 02 September 2023
  • Revise Date: 01 November 2024
  • Accept Date: 23 December 2024

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