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Thermofluid 1

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Title: Thermofluid 1


1
Thermofluid 1
  • Introduction to Transport Phenomena Conduction
    Heat Transfer
  • Prof. Dongsik Kim

2
1. Introduction
  • Transport phenomena
  • Thermodynamics
  • Concerns initial and final states (not the
    process)
  • 1st law of thermodynamics ? energy conservation
  • 2nd law ? direction of energy transport
  • Transport phenomena
  • Fluid mechanics ? rate of momentum transport
  • Momentum in transit due to velocity gradient
  • Heat transfer? rate of thermal energy transport
  • Energy in transit due to temperature gradient

3
Symbols and units
  • Thermal energy EJ
  • Heat transfer rate qWJ/s
  • Heat transfer rate per unit length q/LW/m
  • Heat transfer rate per unit length q/A W/m2
  • Temperature ToC or K T(oC)T(K)273.15
  • Note When oC or K unit is in the denominator,
    unit change doesn't affect the numerical value,
    e.g., specific heat Cp 1 J/kg.oC1 J/kg.K,
    thermal conductivity 1 W/m.oC1 W/m.K

4
Mechanisms of transport
  • Diffusion
  • Carriers molecules, atoms (crystal lattices),
    electrons - translation, vibration, and rotation
    in a random fashion.
  • Mass, momentum, and thermal energy (heat or
    microscopically the kinetic energy of the
    particles) diffusion from the region of high
    potential to the region of low potential until an
    equilibrium state is reached.
  • Fluids- molecular random motion
  • Solids - lattice vibration and motion of free
    electrons

5
Transport by diffusion
6
Convection
  • Transport with "bulk" or "macroscopic" flow
  • Transport is not determined only by the random
    particle motion (diffusion) but also by the bulk
    fluid motion.
  • Transport by bulk flow is termed as advection or
    convection in a narrow meaning
  • Convection Conduction Bulk energy transport
    (advection)
  • (ex) HT between a solid object and fluid or HT in
    a moving fluid

7
Convective transport
8
Radiation
  • Thermal energy transport in the form of EM
    (electromagnetic) wave is called thermal
    radiation. Note that mass can not be transported
    by radiation.
  • Thermal energy is emitted by EM wave (light) due
    to the changes in electron configurations of
    matter. The EM wave emission is always present
    for surfaces at temperatures greater than
    absolute 0 K.

9
Review
  • (Q1) Are the three modes diffusion, convection,
    and radiation independent of each other? If not,
    how are they related?
  • (Q2) Show examples of heat, mass, and momentum
    transfer. Identify the mechanisms.

10
Methodology
  • Conservation principle Physical model
  • Review (Q3) What is the conservation principle
    for a control surface (infinitesimally thin
    control volume)?

11
Microscopic view
  • Characteristic length scales
  • MFP (mean free path) average distance a particle
    travels without a collision
  • Energy carriers
  • Phonon quantum of lattice vibration energy
  • Electron
  • Photon quantum of EM energy

12
Understanding diffusion by kinetic theory
13
Comparison with macroscopic observation
  • Thermal conductivity
  • In general, ksolgtkliqgtkgas (Fig. 2.4)
  • Solid
  • k(k by electron motion) (k by lattice
    vibration)
  • Good electrical conductors are good thermal
    conductors as well (Wiedemann-Franz law)
  • Well order materials (crystals) are good thermal
    conductors in comparison with amorphous materials
  • Gas
  • In general, kgas ? as T ? because v? as T ?
  • Insensitive to P and r. (n ? as P, r ? but l ? as
    P, r ?)

14
2. Heat transfer fundamentals
  • Fourier's law and thermal conductivity
  •  
  • HT rate a vector from high T to low T
  • Direction of HT perpendicular to isothermal
    surfaces
  • kk(T, P)
  • Often kk(T) (Incropera Figs. 2.5 - 2.7)
  • In general, thermal conductivity depends on the
    direction. If the material is isotropic, k is
    independent of direction and a constant.
    Otherwise, second-order tensor kij
  • How to measure thermal conductivity

15
Thermal conductivity
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Fouriers law
  • HT (area) ? (Temperature difference) /
    (distance)
  • HT rate is proportional to the temperature
    gradient
  • Minus sign (-) denotes the direction of heat
    flow.
  • Ficks law and bianary diffusion coefficient
  • Shear-law and viscosity

20
Newtons law of cooling
  • HT with "bulk" or "macroscopic" motion of fluid
    (HT between a solid object and fluid or HT in a
    moving fluid)
  • Convection Conduction Bulk energy transport
    (advection)
  • Convection Conduction on the wall (no slip BC).
  • Classification
  • Forced convection external means
  • Natural or free convection self-induced flow by
    buoyancy 
  • HT (area) ? (Temperature difference) ?
    (convection heat transfer coefficient)
  • Convection heat transfer coefficient h fn (fluid
    properties, flow speed, geometry, etc.)

21
Convection heat transfer coefficients
  •  HT in liquid gt HT in gas (material property,
    kliqgtkgas, etc)
  • Aluminum k202 W/m.K, water 0.6, air 0.026
  • Effect of latent heat critical

22
Stefan-Boltzmann law of radiation
  • Energy transportation by EM (electromagnetic)
    wave
  • Thermal energy is emitted by the changes in
    electron configurations of matter
  • Emission is always present at temperatures
    greater than absolute 0 K
  • No medium required
  • Important in high-temperature HT, solar energy
    utilization, space applications, etc.
  • EM wave can be visible (light) at high
    temperature
  • Energy emitted by a surface per unit area
    (emissive power) T4

23
Radiation heat transfer
  • Blackbodymaximum value of thermal radiation at a
    given absolute temperature
  • Stefan-Boltzmann constant s5.67?10-8 W/m2K4, e
    emissivity (01)
  • Experimental implementation of a blackbody
    isothermal cavity (material independent)
  • A small object surround by large surroundings at
    Tsur, (AltltAsur)  

24
Review
  • (Q1) While thermal conductivity is a material
    property given as a function of thermodynamic
    state, heat transfer coefficient h is not a
    material property. What is the relation between k
    and h?
  • (Q2) What are the typical values of thermal
    conductivity for common materials?
  • (Q3) When is radiation heat transfer important?
    Give a quantitative answer.
  • (Q4) A woman informs her engineer husband that
    hot water will freeze faster than cold water.
    He calls this statement nonsense. She answers by
    saying that she has actually timed the freezing
    process for ice trays in the home refrigerator
    and found that hot water does indeed freeze
    faster. As a friend, you are asked to settle the
    argument. Is there any logical explanation for
    the womans observation? (J. P. Holman, Prob.
    1-35)

25
Governing equation (review)
26
Conduction equation
  • Cartesian
  • Cylindrical
  • Spherical

27
Initial and Boundary Conditions
  • Initial condition initial temperature
    distribution
  • Boundary conditions are assigned from physical
    observation of the domain boundary
  • BC of the 1st kind known temperature boundary
    condition, e.g., phase-change interface,
    temperature controlled surface
  • BC of the 2nd kind known heat-flux boundary
    condition, e.g., or , insulated surface
  • (insulated)
  • Mixed BC when a surface is exposed to air and
    neither temperature nor heat flux is known
  • Phase-change interface

28
Review
  • (Q1) For problems involving constant thermal
    properties and temperature boundary conditions,
    according to the governing equation, the
    temperature profile is independent of thermal
    conductivity. It depends only on thermal
    diffusivity. The thermal conductivity of iron is
    about 3000 times larger than that of air but the
    thermal diffusivity of iron is approximately
    equal to that air. How come can the temperature
    profile be the same? Is this puzzle related with
    dynamic viscosity vs. (kinematic) viscosity?
  • (Q2) What are the implicit assumptions the
    diffusion equation is based on?
  • (Q3) (Advanced problem) In heat conduction
    equation, is the heat capacity Cp or Cv? Why? Can
    you derive the governing equation from the 1st
    law of thermodynamics, i.e.,
    ?

29
3. Solutions of 1-d steady conduction equation
  • Steady ?
  • 1-d ?
  • The governing equation thus reduces to
  • If thermal conductivity is constant
  • linear profile
  • Note For prescribed temperatures at the two
    boundaries, T is independent of material
    properties. What is going on?

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Thermal resistance
  • Analogy between heat transfer and electricity
  • ?
  •  
  • Definition of thermal resistance, overall heat
    transfer coefficient
  • Thermal resistance of a plate K/W
  • Thermal resistance of a cylinder
  • Thermal resistance of a sphere
  • Convection thermal resistance m2.K/W
  • Thermal contact resistance

32
Thermal contact resistance
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Equivalent thermal circuit
35
Critical thickness of insulation layer
Thickness of the insulation layer that maximizes
(minimizes) heat transfer?
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37
4. 1-d steady conduction II
  • Variable thermal conductivity, cross-sectional
    area
  • In 1-d steady state HT, heat flux is conserved.
  • Direct integration of Fourier's law
  • (Ex1) Thermal conductivity (a,bgt0)
  • (Ex2)

38
Conduction with internal heat generation
39
Example
  • T(x)? TsT(l)?
  • Method 1
  • Method 2

40
Heat generation in a cylinder and a sphere
  • Cylinder
  • Governing equation
  • BC's
  • Heat flux increases linearly with r
  • Temperature profile?
  • Sphere of radius r0
  • Similarly,

41
5. Extended surfaces
  • Heat transfer enhancement
  • Natural convection
  • Forced convection
  • Extended surfaces
  • Phase change
  • Fins

42
Fin analysis
  • Deriving a governing equation
  • Steady-state, constant cross-sectional area

43
Solutions to fin equations
44
Fin performance
  • Fin resistance
  • Fin effectiveness
  • HT with a fin vs. HT without a fin
  • Fin efficiency
  • HT with a fin vs. HT with an ideal fin
  • What is an ideal fin?

45
Fins of nonuniform cross-sectional area
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Review
  • (Q1) In order to use the simple solution for an
    infinitely long fin, how long should a fin be?
  • (Q2) In the above analysis, it is assumed that
    the temperature is uniform over the
    cross-sectional area of a fin. Discuss the
    validity of the assumption.

48
6. Introduction to transient heat transfer problem
  • Governing equation
  • Thermal conductivity vs. thermal diffusivity
  • Dimensionless parameters
  • Biot number
  • conduction thermal resistance vs. convection
    thermal resistance
  • Fourier number
  • Dimensionless time
  • Rate of heat conduction vs. rate of heat storage
    for t (thermal diffusivity heat conduction /
    heat storage)

49
Dimensionless form of governing equation
50
Lumped heat capacitance method
  • Neglecting spatial distribution of temperature
    T(t)
  • Validity of the lumped heat capacitance analysis
    small Bi

51
Review
  • (Q1) In the above cooling problem, the lumped
    body experiences a negligibly small temperature
    change after sufficient time has elapsed. What is
    the characteristic time (time constant)?
  • (Q2) What is the physical meaning of very
    large/small Fourier number?

52
7. Solutions of 1-d transient heat conduction
equation
  • ltInitial temperature Ti, suddenly exposed to
    ambient temperature T? with convection heat
    transfer coefficient hgt

53
Analytical solutions
  • Slab of thickness 2L  
  • Cylinder of radius r0
  • Sphere of radius r0

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Semi-infinite wall
  • Similarity solution
  • Similarity variable
  • Temperature profiles at different moments are
    similar by scaling the position by some function
    of time f(t)
  • PDE in x and t ? transform ? ODE in h
  • Initial temperature Ti, constant temperature Ts
    at the boundary x0
  • Initial temperature Ti, constant heat flux at
    the boundary x0

56
Temperature profiles
57
Thermal penetration depth
  • Exact solution
  • Scaling of governing equation

58
Other related topics
  • Analogy with Stokes problem of momentum
    diffusion
  • Sudden thermal contact of two infinite bars at
    different temperatures (TAi, TBi)

59
Review
  • (Q1) A metal surface feels colder than a wood
    surface when touched, though they are at the same
    temperature. Why?
  • (Q2) (Advanced topic) Can you define the speed of
    thermal wave using the concept of thermal
    penetration depth? How is the thermal wave
    different from the shock wave?

60
8. Analytical methods for multidimensional heat
transfer problems
  • Separation of variables
  • Most common technique
  • Trial solution
  • Some math
  • Eigenvalue problem
  • Strum-Liouville theorm
  • Details (Incropera pp. 163-167)

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  • Are these steps crystal clear?
  • Need more details?
  • H.S. Carslaw and J.C. Jaeger, 1996, Conduction of
    Heat in Solids, Oxford
  • M. Necati Ozisik Heat Conduction John Wiley
    Sons

64
Integral method
  • Write integral form of the governing equation
  • Construct an approximate solution satisfying the
    boundary conditions
  • Substitute the approximate solution
  • An example fin problem

65
Other analytical methods (advanced)
  • Greens function
  • Superposition using diffusion delta
  • Integral transform
  • Use of Laplace transform, Fourier transform

66
9. Numerical methods for multidimensional heat
transfer problems
  • Finite difference schemes

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Finite difference solutions
  • Matrix inversion method

72
  • Gauss-Seidel Iteration

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Numerical experiment
  • Java Applets for Engineering Education
  • http//www.engapplets.vt.edu/
  • A set of NSF-funded applets (primarily fluids and
    heat transfer) for web-based tutoring of simple
    Heat Transfer problems
  • Try web surfing for heat transfer
  • http//www.engr.colostate.edu/allan/heat_trans/pa
    ge4/page4f.html
  • http//www.oilsurvey.com/EngToolkit/Process/heatma
    sstransfer.htm
  • FEHT (Finite Element Heat Transfer)
  • S.A. Kleins FEM package for HT education
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