2019
DOI: 10.1007/s10973-019-08094-y
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A review on using nanofluids in heat pipes

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Cited by 42 publications
(10 citation statements)
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“…In these situations, the heat transfer coefficient is found to increase with the increasing velocity of the fluid relative to the particles. As may be expected, the heat transfer coefficient also increases with increasing thermal conductivity, increasing density, and decreasing viscosity of the fluid [30,33].…”
Section: Thermal Performancesupporting
confidence: 69%
“…In these situations, the heat transfer coefficient is found to increase with the increasing velocity of the fluid relative to the particles. As may be expected, the heat transfer coefficient also increases with increasing thermal conductivity, increasing density, and decreasing viscosity of the fluid [30,33].…”
Section: Thermal Performancesupporting
confidence: 69%
“…Nanofluids are produced by suspending particles of nanosize dimensions in the traditional heat transfer fluids such as water, oils, acetone and glycols [60]. A wide range of nanoparticles have been utilised in the formation of nanofluids, some of these include: Table 1 Reviews on heat transfer-related application of nanofluids published in 2019 References Application reviewed Number of reviewed papers [28] Nanofluids in solar dish concentrators [29] Enhancement of solar energy systems [30] A 10-year review of nanofluids in solar thermal collectors, hybrid PV/T and direct steam generation [31] Performance of solar collectors using carbon-based nanofluids [32] Performance of PVT systems using nanofluids [33] Nanofluids in heat exchangers for energy savings [34] Hybrid nanofluids in solar collectors [35] Nanofluids in solar collectors [36] Application of carbon-based nanofluids in heat exchangers [37] Effect of using nanofluids in several types of heat pipes [38] Review of experimental studies using nanofluids in heat pipes [39] Hybrid nanofluids in solar collectors [40] Review of heat pipe using mono and hybrid nanofluids as working medium [41] Factors affecting the use of nanofluids in flat plate solar collectors [42] Review of nanofluids in solar collectors [43] Water-based nanofluids in PVT [44] Thermal enhancement of parabolic through collectors using nanofluids [45] Nanofluids in automobile cooling [46] Nanofluids used for direct absorption solar collectors [47] Nanofluids in concentrating solar collectors [48] Application of nanofluids in solar collectors, heat exchangers and radiators [49] Nanofluids in flat plate solar collectors [50] The effect of nanofluid fuels on compression ignition engines [51] Nanofluids in double-pipe heat exchangers with twisted tape [52] Concentrating solar collectors [53] Nanofluids in parabolic trough collectors [54] Nanofluids in thermal photovoltaic systems …”
Section: Preparation Of Nanofluidsmentioning
confidence: 99%
“…Numerous efforts, such as wicking structures and nanoengineered surfaces, have been devoted to elevating heat pipes by improving evaporation efficiency 11–13 . Nanofluids, which are engineered by suspending ultrafine metallic or nonmetallic nanoparticles in traditional working fluids, have been revealed to provide remarkably higher thermal conductivity than conventional base fluids 14,15 . The enhanced thermal performance by using nanofluids is mainly attributed to the higher thermal conductivity of the nanofluid and increased nucleation sites.…”
Section: Introductionmentioning
confidence: 99%