Determination of the sensible heat effectiveness and pressure loss of a rotary regenerative heat exchanger using CFD

Zmrhal, Vladimír; Zelensky, P Petr; Boháč, Jindřich; Barták, M Martin; Kučera, Miroslav; Vavřička, Roman

doi:10.1007/s12273-022-0983-z

Cited by 4 publications

(1 citation statement)

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“…The scientists used computational fluid dynamics (CFD) simulations to model the heat exchanger's fluid flow and transfer behaviour. The results were then analyzed to see how different flow configurations and tube designs affected the effectiveness of pressure drop and heat transfer [10].…”

Section: Introductionmentioning

confidence: 99%

Study the heat exchanger through ANSYS Fluent

Sufian,

Muhammad Javaid Afzal,

Javaid

et al. 2023

Proceedings of International Exchange and Innovation Conference on Engineering &Amp; Sciences (IEICES)

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A heat exchanger is a tool used to move heat from one fluid to another without letting the fluids mix. The fluids can be liquids or gases, flowing in separate channels or passages separated by a solid wall. In order to get the cold fluid to the desired temperature, the heat exchanger converts thermal energy from the hot fluid to the cold fluid. They are commonly used in a number of businesses and industries to recover waste heat, cool or heat process fluids, and maintain or adjust temperatures. ANSYS Fluent software was used to model and simulate the heat exchanger in this investigation. The simulation results of the heat exchanger of velocity at the inlet and temperature at the outlet are 3.43 m/s and 3.4×10 2 K, respectively. The study aimed to understand better the heat exchanger's fluid flow and heat transfer properties to design it for better performance. A wide range of working situations was simulated, including various inlet velocities, outlet pressures, and temperatures. Experimental data were used to validate the simulation model, and the findings revealed good agreement between the two. For better findings, copper material was employed in the simulation in this study rather than aluminium in the work of other researchers. Copper is a better heat conductor than aluminium because it has a higher thermal conductivity. Because of this, it is a strong option for applications where heat transfer must happen swiftly and effectively. Copper is a superior material for applications that will be exposed to aggressive environments since it is more corrosion-resistant than aluminium. The simulation results were examined to determine how different factors affected the heat exchanger's output, including its heat transmission and fluid flow capabilities. The simulation was then used to improve the heat exchanger's design for improved performance.

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Section: Introductionmentioning

confidence: 99%