Abstract
Due to remarkable applications of the curved ducts in engineering fields, scientists have paid much attention to invent new characteristics of curved-duct flow in mechanical systems. In the ongoing study, a computational modeling of fluid flow and energy distribution through a curved rectangular duct of large aspect ratio is presented. Governing equations are enumerated by using a spectral-based numerical technique together with the function expansion and collocation method. The main purpose of the paper is to analyze the effect of centrifugal force in the flow transition as well as heat transfer in the fluid. The investigations are performed for the aspect ratio, Ar = 4; the curvature ratio, delta = 0.5; the Grashof number, {text{Gr}} = 1000; and varying the Dean number, 0 < {text{Dn}} le 1000. It is found that various types of flow regimes including steady-state and irregular oscillations occur as Dn is increased. To well understand the characteristics of the flow phase spaces and power spectrum of the solutions are performed. Next, pattern variations of axial and secondary flow velocity with isotherms are illustrated for different Dn’s. It is revealed that the flow velocity and the isotherms are significantly influenced by the duct curvature and the aspect ratio. Convective heat transfer and temperature gradients are calculated which explores that the fluids are diversified due to centrifugal instability, and as a consequence the overall heat transfer is enhanced significantly in the curved duct.
Highlights
Three different types of investigations have been performed, namely transitional behavior of the time-dependent flow, convective heat transfer with temperature gradients and the numerical result is validated with experimental outcomes
All these phenomena are analyzed for aspect ratio (Ar) 4; curvature ratio δ 0.5; the Grashof number Gr 1000 over a wide range of the Dean number 0 < Dn ≤ 1000
To discern the flow transition of the present study, time-evolution calculations are performed for Dn > 0 to Dn 145 and it is obtained that the unsteady solutions (US) give steady-state graph for these Dean numbers in time vs. Resistance coefficient plane
Summary
J. Plus (2021) 136:382 curvature, and under a critical flow condition the two-vortex secondary flow changes into fourvortex. The newly two vortices are designated in their study as Dean vortex. There are numerous studies on fluid flows through different types of ducts; some of them may be mentioned by Mondal [2] (curved square duct (CSD) and CRD), Chandratilleke et al [3,4,5] (elliptical and rectangular duct), Ahmadpour and Akhavan-Behabadi [6] (U-shaped duct), Abu-Hamdeh et al [7] (helical tube), Pourhedayat et al [8] (cylindrical tube) and Umavathi and Bég [9] (straight duct) for some outstanding works on this field
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