Saman Faramarzi scite author profile

Saman Faramarzi

2Publications

7Citation Statements Received

49Citation Statements Given

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Islamic Azad University South Tehran Branch, University of Tabriz

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Impact of inclined and perforated baffles on the laminar thermo-flow behavior in rectangular channels

2020

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In this paper, incompressible thermo-flow is simulated for a channel and with and without baffles. A baffle is connected to the channel from different angles. The effect of perforated inclined baffles on the flow pattern and heat transfer in a channel investigated. The computations are based on the finite element method, Galerkin scheme, and Newton-Raphson iterative method have been implemented. The flow regime was assumed to be laminar. Results show that the use of perforated baffles leads to an increase in the Nusselt number and minimized friction factor in comparison to the plain ones. The numerical results are compared with the available solutions in the literature. The defined efficiency of the baffle is obtained for various baffle types, baffle's angle, Reynolds number, and baffle's ratios. The optimum angle of the baffle inclinations was obtained. It was found that perforated baffles demonstrate show superior performance when compared with plain counterparts. Also, there is local heat transfer enhancement at the downstream of the stepped baffle caused by the impinging effect of flow, which is even more significant when baffle height becomes higher or the Reynolds number elevates. Obtained results show that a 135° perforated baffle is a better choice as it enhances the heat transfer with a minimal friction factor.

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Numerical investigation of the impact of inclined baffles and an elastic vibrating beam on the thermo-fluid behavior in a rectangular channel

2021

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In the present work, the influence of inclined baffles and an elastic vibrating beam is investigated on the flow pattern and heat transfer rate in a rectangular channel. The cylinder with the elastic vibrating beam develops the vibrating flow. The computations are based on the finite element method (FEM); Galerkin least-squares scheme and Newton–Raphson iterative method are implemented to solve the governing equations. The fluid structure-interaction (FSI) method is used to analyze the elastic vibrating beam. The friction factor coefficient and Nusselt number are examined for the inclined and conventional baffles. The flow regime is assumed to be laminar for various baffle angles and Reynolds numbers. The vibrating beam is connected to the cylinder located in the channel entrance. Optimized cases with the maximum heat transfer and minimum friction factor are introduced. The novelty of this study is the simultaneous use of the elastic vibrating beam and inclined baffles in a rectangular channel. The results show that mounting an elastic vibrating beam on the cylinder leads the heat transfer rate to increase. The channel with an elastic vibrating beam and inclined baffles at 135° is the optimized case compared to other cases.Article Highlights Take advantage of using an elastic vibrating beam in a rectangular channel. Influences of inclined baffles on thermal performance are examined numerically. The optimum case for the channel with inclined-baffles is reported.

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Saman Faramarzi

Impact of inclined and perforated baffles on the laminar thermo-flow behavior in rectangular channels

Numerical investigation of the impact of inclined baffles and an elastic vibrating beam on the thermo-fluid behavior in a rectangular channel

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