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• W4383959720 abstract "Heat and mass transfer equipment is the heart of many industrial applications in the thermal engineering. Apart from the driving potential difference, the system's overall process efficiency is steered by how these fluids interact. The interaction pattern depends on the type of heat exchanger used and employed based type of fluid, phase flow, density, chemical composition, viscosity and many other thermodynamic properties of interacting fluids. Augmentation in the heat transfer is one of the promising and challenging tasks in the thermal dealings. The increase in energy requirement and consumption has made this issue more crucial. Many researchers reported that methods of increasing heat transfer can be broadly classified into three major divisions as active techniques, passive techniques, and a combination of these two techniques i.e. compound technique. Active techniques involve the influence of fields such as electric, magnetic and acoustic. Whereas, in passive methods, additives are added to the working fluid or new surface textures are formed on the heat transfer surfaces. Nyborg, J Acoust Soc Am 25:68–75, 1953, [1] reported that under the influences of sound sources the fluid particles moves sinusoidal as well as forms patterns like steady vortices or time independently circulations in the fluid body. As high intensity sound projected into the fluid, it generates the effect of some kind of streaming in the fluid called as quartz wind. Sonication is the act of applying sound energy to agitate particles in a fluid." @default.
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• W4383959720 date "2023-01-01" @default.
• W4383959720 modified "2023-09-26" @default.
• W4383959720 title "A Review: Experimental Investigation on Low Frequency Excited Tube in Tube Heat Exchanger with Applications of Nano Fluids" @default.
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• W4383959720 doi "https://doi.org/10.1007/978-981-99-2382-3_27" @default.
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