Browsing by Author "Angelino, M."
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Item Open Access Numerical evidence of an undisturbed region of flow in a turbulent rectangular submerged free jet(Taylor & Francis, 2016-05-02) Boghi, Andrea; Angelino, M.; Gori, FabioThe evolution of turbulent rectangular submerged free jets is described in the literature by the presence of two regions of flow: the potential core region (PCR) and the fully developed region (FDR). However, experiments carried out in the last decade showed that a third region of flow is present, the undisturbed region of flow (URF), so-called in the average visualization, or the negligible disturbances flow (NDF) plus the small disturbances flow (SDF), so-called in the instant visualization. The URF is located between the slot exit and the beginning of the PCR. The main characteristics of URF, and NDF, are that velocity and turbulence profiles remain almost equal to those measured on the slot exit, and the height of the jet remains equal to the slot one. In the SDF the jet height undergoes small variations, i.e., contractions or expansions, but without formation of the vortex. To date, no numerical evidence of the presence of URF has been given by the literature. The present study, which concerns a two-dimensional jet, presents Large Eddy Simulations (LES), carried out at four Reynolds numbers, which are able to predict and characterize URF. The present numerical results are compared to previous theoretical approaches and confirm the presence of URF, between the slot exit and the PCR. Moreover, URF has a self-similar behavior and a new law for the evolution of the momentum is proposedItem Open Access Numerical solution of three-dimensional rectangular submerged jets with evidence of the undisturbed region of flow(Taylor & Francis, 2016-09-20) Angelino, M.; Boghi, Andrea; Gori, FabioThe evolution of turbulent rectangular submerged free jets has been investigated numerically with a two-dimensional approach, [1], by using the Large Eddy Simulations (LES) at several Reynolds numbers. The average numerical results confirmed the presence of the undisturbed region of flow, URF, located between the slot exit and the beginning of the potential core region, PCR, previously observed experimentally at the University of Rome “Tor Vergata”. The two-dimensional study, [1], carried out under the conditions previously investigated in the literature, showed that the URF has a self-similar behavior, and proposed a new law for the evolution of the momentum. The present paper extends the Large Eddy Simulations (LES) to three-dimensional rectangular submerged free jets, showing that the self-similar behavior of URF is present also in the three-dimensional numerical simulations, as well as in the PCR and in the fully developed region, FDR