Aghel B., Rahimi M., Sepahvand A., Alitabar M. and Ghasempour HR., Using a Wire coil insert for biodiesel production enhancement in a microreactor. Energy Conversion Management, Vol. 84, pp. 541-549. 2014.
|
Lee Y.J., Singh P.K. and Lee P.S., Fluid flow and heat transfer investigations on enhanced microchannel heat sink using oblique fins with parametric study. International Journal of Heat and Mass Transfer, Vol. 81, pp. 325-336, 2015.
|
Zhou H., Zhou F., Zhang Q., Wang Q. and Song Z., Thermal management of cylindrical lithium-ion battery based on a liquid cooling method with half-helical duct. Applied Thermal Engineering, Vol. 162, pp. 114257, 2019.
|
Sahin B., Gedik G., Manay E. and Karagoz S., Experimental investigation of heat transfer and pressure drop characteristics of Al2O3-water nanofluid. Experimental Thermal and Fluid Science, Vol. 50, pp. 21–28, 2013.
|
Peyghambarzadeh S.M., Hashemabadi S.H., Chabi A.R. and Salimi M., Performance of water based CuO and Al2O3 nanofluids in a Cu–Be alloy heat sink with rectangular microchannels. Energy Conversion and Management, Vol. 86, pp. 28-38, 2014.
|
Ambreen T. and Kim M.H., Effect of fin shape on the thermal performance of nanofluid-cooled micro pin-fin heat sinks. International Journal of Heat and Mass Transfer, Vol. 126 (Part B), pp. 245–256, 2018.
|
Zirakzadeh H., Mashayekh A.R., Noori Bidgoli H. and Ashjaee M., Experimental investigation of heat transfer in a novel heat sink by means of alumina nanofluids. Heat Transfer Research, Vol. 43, pp. 709–720, 2012.
|
Bahiraei M., Naseri M. and Monavari A., Irreversibility features of a shell-and-tube heat exchanger fitted with novel trapezoidal oblique baffles: Application of a nanofluid with different particle shapes. International Communications in Heat and Mass Transfer, Vol. 126, pp. 105352, 2021.
|
Ho C.J. and Chen W.C., An experimental study on thermal performance of Al2O3/water nanofluid in a minichannel heat sink, Applied Thermal Engineering, Vol. 50, pp. 516–522, 2013.
|
Bahiraei M. and Heshmatian S., Thermal performance and second law characteristics of two new microchannel heat sinks operated with hybrid nanofluid containing graphene–silver nanoparticles. Energy Conversion and Management, Vol. 168 pp. 357–370, 2018.
|
K. Narrein, S. Sivasankaran, P. Ganesan, Two-phase analysis of a helical microchannel heat sink using nanofluids. Numerical Heat Transfer, Part A: Applications, Vol. 68 pp. 1266–1279, 2015.
|
Alsarraf J., Alnaqi A.A. and Al-Rashed A.A.A., Effect of nanoparticles shape on the cooling process of a lithium ion battery in geometry with capillary channels in the presence of phase change material. Journal of Energy Storage, Vol. 48, pp. 103998, 2022.
|
Shahsavar A., Farhadi P., Yildiz C., Moradi M. and Arici M., Evolution of entropy generation characteristics of boehmite-alumina nanofluid with different shapes of nanoparticles in a helical heat sink. International Journal of Mechanical Sciences, Vol. 225, pp. 107338, 2022.
|
Rahmanian S., Rahmanian Koushakaki H. and Shahsavar A., Numerical assessment on the hydrothermal behaviour and entropy generation characteristics of boehmite alumina nanofluid flow through a concentrating photovoltaic/thermal system considering various shapes for nanoparticle. Sustainable Energy Technologies and Assessments, Vol. 52, pp. 102143, 2022.
|
Bahiraei M. and Monavari A., Irreversibility characteristics of a mini shell and tube heat exchanger operating with a nanofluid considering effects of fins and nanoparticle shape. Powder Technology, Vol. 398, pp. 117117, 2022.
|
Falahat A.R. and Bahoosh R., The Effect of Nanoparticle Shape on Hydrothermal Performance and Entropy Generation of Boehmit Alumina Nanofluid in a Cylindrical Heat Sink with Helical Minichannels. Journal of Heat and Mass Transfer Research, Vol.9, pp. 85-98, 2022.
|
Vanaki Sh.M., Mohammed H.A., Abdollahi A. and Wahid M.A., Effect of nanoparticle shapes on the heat transfer enhancement in awavy channel with different phase shifts. Journal of Molecular Liquids, Vol. 196, pp. 32–42, 2014.
|
A. A. Abbasian Arani, S. Sadripour, S. Kermani, Nanoparticle shape effects on thermal-hydraulic performance of boehmite alumina nanoßuids in a sinusoidal-wavy mini-channel with phase shift and variable wavelength. International Journal of Mechanical Sciences, Vol. 128-129, pp. 550–563, 2017.
|
Shahsavar A., Rahimi Z., and Salehipour H., Nanoparticle shape effects on thermal-hydraulic performance of boehmite alumina nanofluid in a horizontal double-pipe minichannel heat exchanger. Heat and Mass Transfer, Vol. 55, pp.1741–1751, 2019.
|
Alqarni M.M., Mahmoud E.E., Saeed T., Ali V. and Ibrahim M., Numerical simulation and exergy analysis of a novel nanofluid‑cooled heat sink. Journal of Thermal Analysis and Calorimetry, Vol. 145, pp. 1651-1660, 2021.
|
Azizi Z., Alamdari A. and Malayeri M.R., Convective heat transfer of Cu–water nanofluid in a cylindrical microchannel heat sink. Energy Conversion and Management, Vol. 101, pp. 515–524, 2015.
|
Fan Y., Lee P.S., Jin L.W. and Chua B.W., A simulation and experimental study of fluid flow and heat transfer on cylindrical oblique-finned heat sink. International Journal of Heat and Mass Transfer, Vol. 61, pp. 62–72, 2013.
|
Fan Y., Lee P.S., Jin L.W. and Chua B.W., Experimental investigation on heat transfer and pressure drop of a novel cylindrical oblique fin heat sink. International Journal of Thermal Sciences, Vol. 76, pp.1–10, 2014.
|
Khosravi R., Rabiei S., Bahiraei M. and Teymourtash A., Predicting entropy generation of a hybrid nanofluid containing graphene–platinum nanoparticles through a microchannel liquid block using neural networks. International Communications in Heat and Mass Transfer, Vol. 109, pp.104351, 2019.
|
Jeong J.H., Hah S., Kim D., Lee J.H. and Kim S.M., Thermal analysis of cylindrical heat sinks filled with phase change material for high-power transient cooling. International Journal of Heat and Mass Transfer, Vol. 154, pp.119725, 2020.
|
Azizi Z., Alamdari A. and Malayeri M.R., Thermal performance and friction factor of a cylindrical microchannel heat sink cooled by Cu-water nanofluid. Applied Thermal Engineering, Vol. 99, pp. 970–978, 2016.
|
Falahat A.R., Bahoosh R. and Noghrehabadi A.R., A numerical investigation of heat transfer and pressure drop in a novel cylindrical heat sink with helical minichannels. Journal of Heat and mass transfer research, Vol. 5, pp. 11–26, 2018.
|
Falahat A.R., Bahoosh R., Noghrehabadi A.R. and Rashidi M.M., Experimental study of heat transfer enhancement in a novel cylindrical heat sink with helical minichannels. Applied Thermal Engineering, Vol. 154, pp. 585–592, 2019.
|
Khalifa M.A. and Jaffal H.M., Effects of channel configuration on hydrothermal performance of the cylindrical mini-channel heat sinks. Applied Thermal Engineering, Vol. 148, pp. 1107–1130, 2019.
|
Bahoosh R. and A.R. Falahat, Heat transfer of nanofluid through helical minichannels with secondary branches, Heat and Mass Transfer 57 (2020) 703-714.
|
Rabiei S., Khosravi R., Bahiraei M., Raziei M. and Ahmadian Hosseini A.j., Thermal and hydraulic characteristics of a hybrid nanofluid containing graphene sheets decorated with platinum through a new wavy cylindrical microchannel. Applied Thermal Engineering, Vol. 181, pp.115981, 2020.
|
Etghani M.M. and Hosseini Baboli S.A., Numerical investigation and optimization of heat transfer and exergy loss in shell and helical tube heat exchanger. Applied Thermal Engineering, Vol. 121, pp. 294-301, 2017.
|
Caliskan S., Sevik S. and Ozdilli O., Heat transfer enhancement by a sinusoidal wavy plate having punched triangular vortex generators. International Journal of Thermal Sciences, Vol. 181, pp. 107769, 2022.
|
Jiang J., Wang F., Yang X., Zhang Y., Deng J., Wei Q., Cai W. and Chen C., Evaluation of the long-term performance of the deep U-type borehole heat exchanger on different geological parameters using the Taguchi method. Journal of Building Engineering, Vol. 59, pp. 105122, 2022.
|
Heydari O., Miansari M., Arasteh H. and Toghraie D., 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, Vol. 145, pp. 2741-2752, 2021.
|
Feng Z., Hu Z., Lan Y., Huang Z. and Zhang J., Effects of geometric parameters of circular pin-fins on fluid flow and heat transfer in an interrupted microchannel heat sink. International Journal of Thermal Sciences, Vol. 165, pp. 106956, 2021.
|
Webb R.L., Performance evaluation criteria for use of enhanced heat transfer surface in heat exchanger design. International Journal of Heat and Mass Transfer, Vol. 24, pp. 715–726, 1981.
|
Chai L., Xia G., Zhou M., Li J. and Qi J., Optimum thermal design of interrupted microchannel heat sink with rectangular ribs in the transverse microchambers. Applied Thermal Engineering, 51, pp. 880–889, 2013.
|
Timofeeva E.V., Routbort J.L. and Singh D., Particle shape effects on thermophysical properties of alumina nanofluids. Journal of Applied Physics, Vol. 106, pp. 014304, 2009.
|
Corcione M., Empirical correlating equations for predicting the effective thermal conductivity and dynamic viscosity of nanofluids. Energy Conversion and Management, Vol. 52, pp. 789-793, 2011.
|
Mahian O., Kianifar A., Zeinali Heris S. and Wongwises S., First and second laws analysis of a minichannel-based solar collector using boehmite alumina nanofluids: Effects of nanoparticle shape and tube materials. International Journal of Heat and Mass Transfer, Vol. 78, pp. 1166–1176, 2014.
|
Kotcioglu I., Cansiz A. and Nasiri Khalaji M., Experimental investigation for optimization of design parameters in a rectangular duct with plate-fins heat exchanger by Taguchi method. Applied Thermal Engineering, Vol. 50, pp. 604-613, 2013.
|
Roy R.K., Design of experiments using Taguchi approach. Jhon Wiley & Sons, New York, 2001.
|
Krishnaiah K., and Shahabudeen P., Applied Design of Experiments and Taguchi Methods, PHI Learning Pvt. Ltd., 2012.
|
|