Amirkabir University of Technology Amirkabir Journal of Mechanical Engineering 2008-6032 53 9 2021 11 22 Study of the Flow and Heat Transfer of Pulsed Sinusoidal Impinging Jet at Distances Close To the Concave Surface Study of the Flow and Heat Transfer of Pulsed Sinusoidal Impinging Jet at Distances Close To the Concave Surface 4943 4960 4383 10.22060/mej.2021.19176.6971 FA Saeed Rakhsha Department of Mechanical Engineering, Semnan University Mehran Rajabi Zargarabadi Department of Mechanical Engineering, Semnan University Seyfolah Saedodin Department of Mechanical Engineering, Semnan University Journal Article 2020 10 29 <strong>The main purpose of this study is to investigate the effect of the pulsating of the inlet jet on the heat transfer rate short distances of the</strong> <strong>nozzle from the concave surface. For this purpose, three-dimensional simulation of flow and heat transfer of sinusoidal pulsed jets on the concave surface has been performed at distances of 0.5 times of nozzle diameter to 4 and for Reynolds numbers of 7000 and 14000. The results of the</strong> <strong>numerical simulation are in good agreement with the experimental results of the steady jet. The result shows that the effect of pulsating the flow with the sine function decreases at short distances between the jet and the concave surface.</strong><strong> So that at a</strong> <strong>distance of 4 times of nozzle diameter, pulsating jet led to a 10% increase in the average <em>Nu</em>, while this value is equal to 5% for a</strong> <strong>distance of 0.5 times of nozzle diameter. It can be found that pulsating the flow decreases <em>Nu</em> at low frequencies, and then with increasing the frequency of the pulsed jet, the <em>Nu</em> number increases. Furthermore</strong>,<strong> with increasing the distance between the surface and the inlet jet, the <em>Nu</em> number decreases significantly. This rate of reduction is lower in comparison to the steady jet.</strong> <strong>The main purpose of this study is to investigate the effect of the pulsating of the inlet jet on the heat transfer rate short distances of the</strong> <strong>nozzle from the concave surface. For this purpose, three-dimensional simulation of flow and heat transfer of sinusoidal pulsed jets on the concave surface has been performed at distances of 0.5 times of nozzle diameter to 4 and for Reynolds numbers of 7000 and 14000. The results of the</strong> <strong>numerical simulation are in good agreement with the experimental results of the steady jet. The result shows that the effect of pulsating the flow with the sine function decreases at short distances between the jet and the concave surface.</strong><strong> So that at a</strong> <strong>distance of 4 times of nozzle diameter, pulsating jet led to a 10% increase in the average <em>Nu</em>, while this value is equal to 5% for a</strong> <strong>distance of 0.5 times of nozzle diameter. It can be found that pulsating the flow decreases <em>Nu</em> at low frequencies, and then with increasing the frequency of the pulsed jet, the <em>Nu</em> number increases. Furthermore</strong>,<strong> with increasing the distance between the surface and the inlet jet, the <em>Nu</em> number decreases significantly. This rate of reduction is lower in comparison to the steady jet.</strong> https://mej.aut.ac.ir/article_4383_6de4bfe9504589a457d6e92fae4f9613.pdf