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Class #
or Lab #
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Date
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Important Concepts
(Section # in Text Reading and Example)
or Lab Activities
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Problems Assigned,
due next class: by 5:00 pm
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1
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Aug 24
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Definition fluid; continuum hypothesis; fluid properties
(Text 1.1 - 1.5)
Example:
Ideal gas equation (1.29)
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1.28 (g,r,SG)
e5) 1.36 (ideal gas)
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2
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26
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Viscosity, shear stress and rate of strain;
compressibility; vapor pressure/cavitation;
surface tension and capillary effects; flow
classification
(Text 1.6-1.11)
Example:
Shear stress (1.65)
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1.59 (t)
1.77 (Ev)
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3, L1
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28
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Fluid Mechanics: AFD,
EFD, and CFD
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1.90 (pv)
1.100 (s)
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4
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31
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Pressure definition, force, and transmission;
absolute/gage/vacuum;
pressure variation with elevation liquids/gases;
pressure measurement (barometer, piezometer,
manometers)
(Text 2.1-2.7)
Example:
Effects of surface tension
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e5) 2.13
(pressure transmission)
e5) 2.19
(gases)
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5, L2
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Sep 2
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Experimental Methodology and
Uncertainty Assessment Procedures: EFD Pre-test
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6
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4
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Hydrostatic forces on plane surfaces
(Text 2.8-2.9)
Example:
Manometer (2.40)
Concepts of EFD Lab 1
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2.31 (u-tube manometer)
e5) 2.42 (differential
manometer)
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7
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Labor
Day: No Class
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L3
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8
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EFD Lab1 (1)
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|
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7
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9
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Continued
Example:
Plane surface (2.66)
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2.61, 2.68 (plane surface)
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L3
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10
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EFD Lab1 (2)
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8
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11
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Hydrostatic forces curved surfaces (horizontal and
vertical components); buoyancy; hydrometer
(Text 2.10-2.11)
Example1:
Plane surface (2.67)
Example2:
Curved surface (1)
Example3:
Curved surface (2) (2.89)
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2.92, 2.95 (curved surface)
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9
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14
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Stability immersed and floating bodies; rigid body
translation and rotation
(Text 2.12-2.13)
Example:
Buoyancy (e5 2.87)
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e5) 2.83 (buoyancy)
e5) 2.88 (hydrometer)
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L3
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15
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EFD Lab1 (3)
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10
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16
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Continued
Example1:
Stability
Example2: Translation (1)
Example3:
Translation (2)
Example4: Rotation (1)
Example5:
Rotation (2)
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SP.1, SP.2 (stability)
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L3
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17
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EFD Lab1 (4)
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|
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11
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18
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Continued
Example:
Translation (3)
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2.111 (translation)
2.117 (rotation)
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12
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21
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Newton's 2nd Law for a Fluid, Steamline Coordinates, Bernoulli equation
(Text 3.1-3.4)
Example1:
Bernoulli equation (along streamline) (3.4)
Example2: Bernoulli equation (normal
to streamline) (3.16)
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3.5, e5) 3.11 (streamline coordinates)
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L4
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22
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EFD Lab2 (1)
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13
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23
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Static Dynamic and total pressure, applications
Bernoulli equation, Flow Rate
(Text 3.5-3.6)
Example1:
Bernoulli equation (Q) (3.53)
Example2: Bernoulli equation (along
streamline)
Concepts of
EFD Lab 2 & CFD Lab 1
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3.49 (Bernoulli equation, Q)
3.51 (Bernoulli equation, static and total
pressure)
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L4
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24
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EFD Lab2 (2)
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14
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25
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Limitations Bernoulli equation
(Text 3.7-3.9)
Example1:
Bernoulli equation (Sluice gate) (3.112)
Example2: Bernoulli equation (along
streamline)
Fluid kinematics, velocity, acceleration
(Text 4.1 - 4.2)
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3.75 (Bernoulli equation, cavitation)
e5) 3.93 (Bernoulli
equation, channel flow)
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15
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28
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Continued, fluid kinematics, velocity,
acceleration
Example:
Velocity (4.3)
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4.5, 4.37 (velocity)
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L4
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29
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EFD Lab2 (3)
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|
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16
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30
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Flow classification
Example1:
Acceleration (1) (4.36)
Example2: Acceleration (2)
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4.24, 4.33 (acceleration)
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L4
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Oct 1
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EFD Lab2 (4)
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17
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2
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Review 1
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18
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5
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EXAM 1
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19, L5
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7
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Introduction to Computational Fluid
Dynamics: CFD Pre-test
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|
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20
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9
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Control volume approach and RTT
(Text 4.3-4.5)
Example1:
RTT (4.71)
Example2:
RTT (4.72)
Control Volume Analysis, continuity equation
(Text 5.1)
Example:
Continuity (5.12)
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5.9, 5.17
(control volume)
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21
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12
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Continued, continuity equation
Example1:
Steady flow continuity (5.18)
Example2:
Unsteady flow continuity (5.30)
Example3: Falling cylinder
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e5) 5.14, 5.25
(continuity)
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L6
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13
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CFD
PreLab1 (1)
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22
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14
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Momentum Equation
(Text 5.2)
Example1:
Momentum, bend (e5 5.31)
Example2: Momentum, nozzle (5.66)
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5.45 (momentum, bend)
5.46 (momentum, nozzle)
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L6
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15
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CFD PreLab1 (2)
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23
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16
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Continued
Example1:
Bend (e5 5.48)
Example2:
Vane (e5 5.62)
Example3:
Jet (e5 5.65)
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e5) 5.
52 (nozzle)
5.64
(vane)
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24
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19
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Energy
equation
(Text
5.3-5.5)
Example1: Head loss (5.95)
Example2: Moving vane
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5.96
(head loss)
e5) 5.95 (head
loss)
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L7
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20
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CFD Lab1 (1)
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25
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21
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Concept of Hydraulic and Energy
Grade Lines
Example1: Energy, pump (5.109)
Example2: Energy, turbine (e5 5.119)
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5.113
(energy, turbine)
e5) 5.111 (energy, pump)
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L7
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22
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CFD Lab1 (2)
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26
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23
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Application of the Energy,
Momentum, and Continuity Equations in Combination
Example1: Bend (5.128)
Example2: Sluice gate
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SP-1 (energy
+ momentum)
SP-2
(energy + momentum)
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27
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26
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Differential
Analysis, relative motion, vorticity, continuity, and stream function
(Text
6.1-6.2)
Example1: Fluid kinematics and vorticity (6.4)
Example2: Continuity (6.23)
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6.7
(vorticity)
6.13
(continuity)
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L8
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27
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EFD Lab3 (1)
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28
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28
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Momentum equation and
differential analysis of fluid flow
(Text 6.3, 6.8-6.11)
Example1: Cotinuity
(6.24)
Example2: Exact solutions of NS (Couette
flow) (6.93)
Concepts of EFD Lab 3 & CFD Lab 2
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6.89 (Couette flow)
6.85
(Flow between fixed plates)
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L8
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29
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EFD Lab3 (2)
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29
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30
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Continued
Example1: Exact solutions of NS (Rotating cylinder) (6.102)
Example2: Exact solutions of NS (Poiseuille
flow) (6.86)
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e5) 6.78 (Poiseuille flow)
6.100
(pipe flow)
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30
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Nov 2
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Dimensional
homogeneity; dimensional analysis; Pi theorem; Important
non-dimensional parameters
(Text
7.1-7.7)
Example1: Pi parameters (7.18)
Example2: Pi parameters (e5 7.19)
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7.16, e5) 7.12 (Pi parameters)
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L8
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3
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EFD Lab3 (3)
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31
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4
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Similarity and model testing
(Text 7.8-7.11)
Example1: Re similarity (1) (7.56)
Example2: Fr similarity (1) (7.55)
Example3: Re similarity (2)
Example4: Fr similarity (2)
EFD Lab3 concepts: drag calculation
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e5) 7.55 (Re similarity)
7.75 (Fr similarity)
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L8
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5
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EFD Lab3 (4)
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32
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6
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Review 2
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33
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9
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EXAM 2
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L9
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10
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CFD PreLab2 (1)
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34
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11
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Viscous Flow in Pipes, entrance
and developing flow, laminar flow, friction factor
(Text 8.1-8.2)
Example1: 8.17
Example2: 8.19
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e5) 8.12, 8.24 (laminar)
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L9
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12
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CFD PreLab2 (2)
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35
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13
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Turbulent flow
(Text 8.3)
Example1: 8.25
Example2: 8.33
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e5) 8.21, e5) 8.27 (turbulent)
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36
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16
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roughness,
application pipe systems
(Text
8.4-8.7)
Example1: Friction factor
Example2: Friction factor (8.49)
Example3: 8.36
Example4: 8.39
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e5) 8.31 (f)
8.74 (head loss)
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L10
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17
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CFD Lab2 (1)
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37
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18
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Continued,
Example1: Head loss (e5 8.35)
Example2: Flow rate
Example3: Pipe diameter
Example4: Pipe diameter
Example5: 8.81 (Diameter)
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SP3 (flow
rate)
8.80 (pipe diameter)
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L10
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19
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CFD Lab2 (2)
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38
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20
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Minor losses,
Example1: Minor losses
Example2: Minor losses
Example3: Minor losses
Example4: Minor losses (e5 8.85)
Example5: 8.72
Example6: 8.77
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e5) 8.85 (minor losses)
8.99 (minor losses)
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23
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24
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25
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Thanksgiving
Recess
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26
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27
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39
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30
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Flow over
immersed bodies, lift and drag, boundary layer theory
(Text
9.1-9.2)
Example1: Laminar BL
Example2: Laminar BL
Summary of EFD and CFD study for the flow around Clark-Y
airfoil
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9.13, 9.14
(laminar BL)
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40
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Dec 2
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Laminar
boundary layer, continued
Example1: Laminar BL drag (9.46)
Example2: Laminar BL drag (e5 9.29)
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9.48
(laminar drag)
9.51 (transitional drag)
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41
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4
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Turbulent
boundary layer
Example1: Turbulent BL velocity profile
Example2: Turbulent BL velocity profile
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SP.4,
SP.5 (turbulent flat plate drag)
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42
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7
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Bluff
body drag and lift
(Text
9.3-9.5)
Example1: Turbulent BL drag
Example2: Turbulent BL drag
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9.68
(drag)
9.71 (drag)
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43
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9
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Continued,
Example1: Stokes flow
Example2: Drag (9.61)
Example3: Drag and lift (9.95)
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e5) 9.38 (Stokes flow)
9.101 (lift)
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44
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11
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Post-test,
Post-survey
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Final Exam: TBD
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