Presentation is loading. Please wait.

Presentation is loading. Please wait.

Elementary Mechanics of Fluids CE 319 F Daene McKinney Viscosity.

Published byDylan Park Modified over 9 years ago

Similar presentations

Presentation on theme: "Elementary Mechanics of Fluids CE 319 F Daene McKinney Viscosity."— Presentation transcript:

1 Elementary Mechanics of Fluids CE 319 F Daene McKinney Viscosity

2 Some Simple Flows Flow between a fixed and a moving plate Fluid in contact with the plate has the same velocity as the plate u = x-direction component of velocity u=V Moving plate Fixed plate y x V u=0 B Fluid

3 Some Simple Flows Flow through a long, straight pipe Fluid in contact with the pipe wall has the same velocity as the wall u = x-direction component of velocity r x R V Fluid

4 Fluid Deformation Flow between a fixed and a moving plate Force causes plate to move with velocity V and the fluid deforms continuously. u=V Moving plate Fixed plate y x u=0 Fluid t0t0 t1t1 t2t2

5 u=V+  V Moving plate Fixed plate y x u=V Fluid Fluid Deformation t t+tt+t xx yy  LL Shear stress on the plate is proportional to deformation rate of the fluid

6 Shear in Different Fluids Shear-stress relations for different types of fluids Newtonian fluids: linear relationship Slope of line (coefficient of proportionality) is “viscosity”

7 Viscosity Newton’s Law of Viscosity Viscosity Units Water (@ 20 o C) –  = 1x10 -3 N-s/m 2 Air (@ 20 o C) –  = 1.8x10 -5 N-s/m 2 Kinematic viscosity V V+dv

8 Flow between 2 plates u=V Moving plate Fixed plate y x V u=0 B Fluid Force acting ON the plate Thus, slope of velocity profile is constant and velocity profile is a st. line Force is same on top and bottom

9 Flow between 2 plates u=V Moving plate Fixed plate y x V u=0 B Shear stress anywhere between plates   Shear on fluid

10 Flow between 2 plates 2 different coordinate systems r x B V y x

11 Example: Journal Bearing Given –Rotation rate,  = 1500 rpm –d = 6 cm –l = 40 cm –D = 6.02 cm –SG oil = 0.88 – oil = 0.003 m 2 /s Find: Torque and Power required to turn the bearing at the indicated speed.

12 Example: cont. Assume: Linear velocity profile in oil film

13 Example: Rotating Disk Assume linear velocity profile: dV/dy=V/y=  r/y Find shear stress

Download ppt "Elementary Mechanics of Fluids CE 319 F Daene McKinney Viscosity."

Similar presentations

Density, ρ= mass/unitvolume –Slugs/ft3;kg/m3

Density, ρ= mass/unitvolume –Slugs/ft3;kg/m3
Fluid Properties and Units CEE 331 April 26, 2015 CEE 331 April 26, 2015 

Fluid Properties and Units CEE 331 April 26, 2015 CEE 331 April 26, 2015 
L ECTURE 5 Properties Of Fluids-Cont. By Dr. Mohamed Fekry 2 nd Sem.1434.

L ECTURE 5 Properties Of Fluids-Cont. By Dr. Mohamed Fekry 2 nd Sem.1434.
Aero-Hydrodynamic Characteristics

Aero-Hydrodynamic Characteristics
Convection.

Convection.
Elementary Mechanics of Fluids

Elementary Mechanics of Fluids
Pharos University ME 352 Fluid Mechanics II

Pharos University ME 352 Fluid Mechanics II
Chapter 2: Overall Heat Transfer Coefficient

Chapter 2: Overall Heat Transfer Coefficient
II. Properties of Fluids. Contents 1. Definition of Fluids 2. Continuum Hypothesis 3. Density and Compressibility 4. Viscosity 5. Surface Tension 6. Vaporization.

II. Properties of Fluids. Contents 1. Definition of Fluids 2. Continuum Hypothesis 3. Density and Compressibility 4. Viscosity 5. Surface Tension 6. Vaporization.
Chapter 2 Reynolds Transport Theorem (RTT) 2.1 The Reynolds Transport Theorem 2.2 Continuity Equation 2.3 The Linear Momentum Equation 2.4 Conservation.

Chapter 2 Reynolds Transport Theorem (RTT) 2.1 The Reynolds Transport Theorem 2.2 Continuity Equation 2.3 The Linear Momentum Equation 2.4 Conservation.
CE 230-Engineering Fluid Mechanics Lecture # 4and5 Fluid properties (2)

CE 230-Engineering Fluid Mechanics Lecture # 4and5 Fluid properties (2)
Marine Boundary Layers Shear Stress Velocity Profiles in the Boundary Layer Laminar Flow/Turbulent Flow “Law of the Wall” Rough and smooth boundary conditions.

Marine Boundary Layers Shear Stress Velocity Profiles in the Boundary Layer Laminar Flow/Turbulent Flow “Law of the Wall” Rough and smooth boundary conditions.
AOSS 321, Winter 2009 Earth System Dynamics Lecture 6 & 7 1/27/2009 1/29/2009 Christiane Jablonowski Eric Hetland cjablono@umich.edu ehetland@umich.edu.

AOSS 321, Winter 2009 Earth System Dynamics Lecture 6 & 7 1/27/2009 1/29/2009 Christiane Jablonowski Eric Hetland
Momentum flux across the sea surface

Momentum flux across the sea surface
Navier-Stokes. Viscosity  A static fluid cannot support a shear.  A moving fluid with viscosity can have shear. Dynamic viscosity  Kinematic viscosity.

Navier-Stokes. Viscosity  A static fluid cannot support a shear.  A moving fluid with viscosity can have shear. Dynamic viscosity  Kinematic viscosity.
Fluid Flow Pressure, momentum flux and viscosity..

Fluid Flow Pressure, momentum flux and viscosity..
Fluid Properties and Units CVEN 311 . Continuum ä All materials, solid or fluid, are composed of molecules discretely spread and in continuous motion.

Fluid Properties and Units CVEN 311 . Continuum ä All materials, solid or fluid, are composed of molecules discretely spread and in continuous motion.
Forces Acting on a Control Volume Body forces: Act through the entire body of the control volume: gravity, electric, and magnetic forces. Surface forces:

Forces Acting on a Control Volume Body forces: Act through the entire body of the control volume: gravity, electric, and magnetic forces. Surface forces:
Numerical Hydraulics Wolfgang Kinzelbach with Marc Wolf and Cornel Beffa Lecture 1: The equations.

Numerical Hydraulics Wolfgang Kinzelbach with Marc Wolf and Cornel Beffa Lecture 1: The equations.
Stress, Strain, and Viscosity San Andreas Fault Palmdale.

Stress, Strain, and Viscosity San Andreas Fault Palmdale.

Similar presentations

Ads by Google