Rezultati - "Newtonian fluid"

Vorticity and incompressible flow od Majda, Andrew, 1949-

Teme: “...Non-Newtonian fluids....”
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Materiology : the creatives guide to materials and technologies / od Kula, Daniel, Ternaux, Elodie

Kazalo: “...Acrylonitrile butadiene styrene -- Aerogels -- Alucobond® -- Aluminum -- Asphalt -- Basalt, melted and lava -- Bakelite -- Bamboo -- Biopolymers -- Brass -- Bronze -- Burrs -- Carbon -- Cardboard -- Cast iron -- Cellulose acetate -- Ceramic, architectural -- Ceramic, technical -- Ceramic, traditional -- Chipboard -- Concretes, conventional -- Concretes, fibre -- Concrete, high performance -- Copper -- Cork -- Crystal -- Diamond -- Electroluminescence -- Emerald -- Epoxy or epoxides polyepoxides -- Felt -- Fibres, artificial -- Fibres, carbon, aramid, basalt -- Fibres, glass -- Fibres of animal origin -- Fibres of vegetable origin -- Fibres, synthetic -- Foams -- Full grain leather -- Fur -- Gallium -- Glass, 3D -- Glass, borosilicate -- Glass, coated -- Glass, security-safety -- Glass, toughened -- Glass, vitroceramic -- Gold -- Granite -- Honeycombs -- Horn -- Ivory -- Lacquer -- Laminated timber, glued -- Laminates -- Laser -- Latheboard or coreboard -- Lead -- LED -- LED, O-, P-, PHO- -- Light source, discharge fluorescent -- Light source, halogen incandescent -- Light source, sodium mercury discharge -- Light source, standard incandescent -- Limestone -- Liquidmetal® -- Lithium -- Magnesium -- Magnetic materials -- Marble -- MDF -- Mercury -- Metamaterials -- Mirrors -- Mortar -- Nacre -- Non-Newtonian fluids -- Nubuck-buckskin-suede -- Oriented strand-board -- Paper -- Parchment -- Phosphorescence-fluorescence -- Photovoltaic cell -- Piezoelectric materials -- Plaster -- Plywood -- Plywood, moulded -- Polyamide -- Polycarbonate -- Polyester -- Polymethyl methacrylate -- Polyoxymethylene -- Polypropylene -- Polystyrene -- Polytetrafluorethylene -- Polyurethane -- Polyvinal chloride -- Precious stones -- Rare earths -- Rubber-latex -- Ruby & sapphire -- Sandstone -- Schist -- Semiconductors -- Shape memory alloys -- Sharkskin or shagreen -- Shell -- Silicon -- Silicone -- Silver -- Solid surfaces -- Superconductors -- Stainless steel -- Steels -- Thermoplastic elastomers -- Tin -- Titanium -- Veneer -- Wood polymers -- Wood, retified -- Wood species -- XX-chromatic -- Zamak alloys -- Zinc -- Processes. ...”
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Porous media transport phenomena od Civan, Faruk

Kazalo: “...Equation of Motion for Non-Newtonian Fluids.13. Exercises.Chapter 6 Gas Transport in Tight Porous Media.1. ...”
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An introduction to transport phenomena in materials engineering od Gaskell, David R., 1940-

Kazalo: “...Momentum transport and laminar flow of Newtonian fluids -- 2.1 Introduction -- 2.2 Newton's lax of viscosity -- 2.3 Conservation of momentum in steady-state flow -- 2.4 Fluid flow between two flat parallel plates -- 2.5 Fluid flow down in inclined plane -- 2.6 Fluid flow in a vertical cylindrical tube -- 2.7 Capillary flowmeter -- 2.8 Fluid flow in an annulus -- 2.9 Mean residence time -- 2.10 Calculation of viscosity from the kinetic theory of gases -- 2.11 Viscosities of liquid metals -- 2.12 Summary -- Problems --...”
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Classical and modern engineering methods in fluid flow and heat transfer an introduction for engineers and students / od Dorfman, A. Sh. (Abram Shlemovich)

Kazalo: “...Conjugate heat transfer problem as a conduction problem -- 4.1 Formulation of conjugate heat transfer problem -- 4.2 Universal function for laminar fluid flow -- 4.2.1 Universal function for heat flux in self-similar flows as an exact solution of a thermal boundary-layer equation -- 4.2.2 Universal function for heat flux in arbitrary pressure gradient flow -- 4.2.3 Integral universal function for heat flux in arbitrary pressure gradient flow -- 4.2.4 Examples of applications of universal functions for heart flux -- Exercises 4.1-4.32 -- 4.2.5 Universal function for a temperature head -- 4.2.6 Universal function for unsteady heat flux in self-similar flow -- 4.2.7 Universal function for heat flux in compressible fluid flow -- 4.2.8 Universal function for heat flux for a moving continuous sheet -- 4.2.9 Universal function for power-law non-Newtonian fluids -- 4.2.10 Universal function for the recovery factor -- 4.2.11 Universal function for an axisymmetric body -- Exercises 4.33-4.50 -- 4.3 Universal functions for turbulent flow -- 4.4 Reducing a conjugate problem to a conduction problem -- 4.4.1 Universal function as a general boundary condition -- 4.4.2 Estimation of errors caused by boundary condition of the third kind -- 4.4.3 Equivalent conduction problem with the combined boundary condition -- 4.4.4 Equivalent conduction problem for unsteady heat transfer -- Exercises 4.51-4.61 --...”
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