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Published byKelly Briggs Modified over 9 years ago
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Dr.Sarreshtehdari Farhad Abbassi Amiri Shahrood university of technology 2
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Nanofluids are a relatively new class of fluids which consist of a base fluid with nano-sized particles (1–100 nm) suspended within them. It is introduced by choi on Argonne National Laboratory at1995. 4
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5 Conventional heat transfer fluids have inherently poor thermal conductivity compared to solids. Conventional fluids that contain mm- or m-sized particles do not work with the emerging “miniaturized” technologies because they can clog the tiny channels of these devices. Modern nanotechnology provides opportunities to produce nanoparticles. Argonne National Lab (Dr. Choi’s team) developed the novel concept of nanofluids. Nanofluids are a new class of advanced heat-transfer fluids engineered by dispersing nanoparticles smaller than 100 nm (nanometer) in diameter in conventional heat transfer fluids. Solids have thermal conductivities that are orders of magnitude larger than those of conventional heat transfer fluids.
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6 The basic concept of dispersing solid particles in fluids to enhance thermal conductivity can be traced back to Maxwell in the 19th Century. Studies of thermal conductivity of suspensions have been confined to mm- or mm-sized particles. The major challenge is the rapid settling of these particles in fluids. Nanoparticles stay suspended much longer than micro-particles and, if below a threshold level and/or enhanced with surfactants/stabilizers, remain in suspension almost indefinitely. Furthermore, the surface area per unit volume of nanoparticles is much larger (million times) than that of microparticles (the number of surface atoms per unit of interior atoms of nanoparticles, is very large). These properties can be utilized to develop stable suspensions with enhanced flow, heat-transfer, and other characteristics
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Compared to conventional solid-liquid suspensions for heat transfer intensifications, properly engineered thermal nanofluids possess the following advantages: 1. High specific surface area and therefore more heat transfer surface between particles and fluids. 2. High dispersion stability with predominant Brownian motion of particles. 3. Reduced pumping power as compared to pure liquid to achieve equivalent heat transfer intensification. 4. Reduced particle clogging as compared to conventional slurries, thus promoting system miniaturization. 5. Adjustable properties, including thermal conductivity and surface wettability, by varying particle concentrations to suit different applications. 7
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1.Nano-particle materials include: ◦ Oxide ceramics – Al 2 O 3, CuO ◦ Metal carbides – SiC ◦ Nitrides – AlN, SiN ◦ Metals – Al, Cu ◦ Nonmetals – Graphite, carbon nanotubes ◦ Layered – Al + Al 2 O 3, Cu + C ◦ PCM – S/S ◦ Functionalized nanoparticles 2.Base fluids include: ◦ Water ◦ Ethylene- or tri-ethylene- glycols and other coolants ◦ Oil and other lubricants ◦ Bio-fluids ◦ Polymer solutions ◦ Other common fluids 8
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Two nanofluid production methods has been developed: In two-step process for oxide nanoparticles (“Kool-Aid” method), nanoparticles are produced by evaporation and inert-gas condensation processing, and then dispersed (mixed, including mechanical agitation and sonification) in base fluid. A patented one-step process (see schematic) simultaneously makes and disperses nanoparticles directly into base fluid; best for metallic nanofluids. 9
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Transportation (Engine cooling/vehicle thermal management) Electronics cooling Defense Space Nuclear systems cooling Heat exchanger Biomedicine Other applications (heat pipes, fuel cell, Solar water heating, chillers, domestic refrigerator, Diesel combustion, Drilling, Lubrications, Thermal storage,…). 10
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Properties of consideration Single phase convective heat transfer Properties of interest: k, cp, viscosity Particle size, shape and concentration Multiphase flow and heat transfer Properties of interest: k, cp, viscosity, surface tension, wetting. Particle size, shape and concentration Interaction of particles with surface 11
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Eulerian-Eulerian Eulerian-Lagrangian Mixture VOF (volume of fluid) 12
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Numerical and experimental studies in this field show that there are some parameters that can enhance the heat transfer coefficient, includig: Nano-particle concentration Nano-particle size Re number Pe number Interaction between particles Sphericity of nano-particles Axial distance from the channel inlet 13
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lack of agreement of results obtained by different researchers lack of theoretical understanding of the mechanisms responsible for changes in properties poor characterization of suspensions stability of nanoparticles dispersion Increased pressure drop and pumping power Nanofluids thermal performance in turbulent flow and fully developed region Higher viscosity, Lower specific heat High cost of nanofluids Difficulties in production process 17
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thermalscienceapplication.asmedigitalcollection.asme.org Argonne National Laboratory (ANL), Dr. S.Choi & Dr. J.Hull www.kostic.niu.edu www.kostic.niu.edu www.researchgate.net www.researchgate.net www.nanoscalereslett.com www.nanoscalereslett.com 18
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Thank you 19
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