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1	Experimental and CFD Study of Flow Phenomenon in Flowrate-amplified Flotation Element Xinzhe, Wang, Xin, Li 03 May 2016 (has links) (PDF) Focusing on reducing the air consumption of an air flotation rail system, a flowrate-amplified flotation element was recently developed. This new flotation element ulitises the rotational flow to intake extra air via an intake hole, and thus, effectively improves the flotation height. Compared to a conventional flotation element, the flowrate-amplified flotation element can reduce air consumption by approximately 50% for the same load and flotation height. To gain an understanding of the flow phenomenon in the flowrate-amplified flotation element, experiments and CFD simulations are conducted in this study. Based on the results, we found that the flowrate-amplified flotation element could take a part of the kinetic energy of the rotating air to suck in extra air. The intake hole greatly affects the pressure field and velocity field of the flotation element. Additionally, the effects of the variant gap height and supplied flow rate were also discussed. The results indicate that the pressure distribution decreases as the gap height increases and increases as the supplied flow rate increases. ddc:620 rvk:ZQ 5460
2	Shear flow experiments: Characterizing the onset of turbulence as a phase transition Avila, Kerstin 05 November 2013 (has links) No description available. 571.4 shear flow transition to turbulence phase transition pipe flow rotational flow Taylor-Couette Biologie (PPN619462639)
3	Experimental and CFD Study of Flow Phenomenon in Flowrate-amplified Flotation Element Xinzhe, Wang, Xin, Li January 2016 (has links) Focusing on reducing the air consumption of an air flotation rail system, a flowrate-amplified flotation element was recently developed. This new flotation element ulitises the rotational flow to intake extra air via an intake hole, and thus, effectively improves the flotation height. Compared to a conventional flotation element, the flowrate-amplified flotation element can reduce air consumption by approximately 50% for the same load and flotation height. To gain an understanding of the flow phenomenon in the flowrate-amplified flotation element, experiments and CFD simulations are conducted in this study. Based on the results, we found that the flowrate-amplified flotation element could take a part of the kinetic energy of the rotating air to suck in extra air. The intake hole greatly affects the pressure field and velocity field of the flotation element. Additionally, the effects of the variant gap height and supplied flow rate were also discussed. The results indicate that the pressure distribution decreases as the gap height increases and increases as the supplied flow rate increases. info:eu-repo/classification/ddc/620 ddc:620
4	PIV measurements of rotational flow in a porous medium : A masters thesis in fluid dynamics and experimental mechanics Skarman, Björn January 2022 (has links) The purpose of this work is to test the feasibility of using particle image velocimetry(PIV) for measurements of flow through a porous medium, more specifically in this casea rotating bed reactor S3. The results from experiments preformed can then be usedto validate and improve computational fluid dynamics models. The report presentsdifferent possible combinations of solids and fluids for refractive index matchingand tests some velocity limits of the optical equipment used. PIV appears to be apromising method for measuring flow through a porous medium. The theoreticallimit due to motion blur is an angular velocity of around 3800 RPM, and the actualtested lower bound for this limit is 453 RPM. PIV particle image velocimetry velocimetry refractive index matching porous medium rotational flow Fluid Mechanics and Acoustics Strömningsmekanik och akustik
5	Theoretical Models for Wall Injected Duct Flows Saad, Tony 01 May 2010 (has links) This dissertation is concerned with the mathematical modeling of the flow in a porous cylinder with a focus on applications to solid rocket motors. After discussing the historical development and major contributions to the understanding of wall injected flows, we present an inviscid rotational model for solid and hybrid rockets with arbitrary headwall injection. Then, we address the problem of pressure integration and find that for a given divergence free velocity field, unless the vorticity transport equation is identically satisfied, one cannot find an analytic expression for the pressure by direct integration of the Navier-Stokes equations. This is followed by the application of a variational procedure to seek novel solutions with varying levels of kinetic energies. These are found to cover a wide spectrum of admissible motions ranging from purely irrotational to highly rotational fields. Subsequently, a second law analysis as well as an extension of Kelvin's energy theorem to open boundaries are presented to verify and corroborate the variational model. Finally, the focus is shifted to address the problem of laminar viscous flow in a porous cylinder with regressing walls. This is tackled using two different analytical techniques, namely, perturbation and decomposition. Comparisons with numerical Runge--Kutta solutions are also provided for a variety of wall Reynolds numbers and wall regression speeds. Fluid Mechanics Inviscid Flow Rotational Flow Variational Solutions Solid Rocket Motors Kelvin's Energy Theorem Navier-Stokes Equations Aerodynamics and Fluid Mechanics Fluid Dynamics Partial Differential Equations Propulsion and Power

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