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Conduction Heat transfer
Alok kumar Ansu
Manipal University Jaipur
1
2
Objectives
• Understand how thermodynamics and heat transfer are related
to each other
• Distinguish thermal energy from other forms of energy, and
heat transfer from other forms of energy transfer
• Perform general energy balances as well as surface energy
balances
• Understand the basic mechanisms of heat transfer, which are
conduction, convection, and radiation, and Fourier's law of heat
conduction, Newton's law of cooling, and the Stefan–Boltzmann
law of radiation
• Identify the mechanisms of heat transfer that occur
simultaneously in practice
• Develop an awareness of the cost associated with heat losses
• Solve various heat transfer problems encountered in practice
3
THERMODYNAMICS AND HEAT TRANSFER
• Heat: The form of energy that can be transferred from one
system to another as a result of temperature difference.
• Thermodynamics is concerned with the amount of heat
transfer as a system undergoes a process from one
equilibrium state to another.
• Heat Transfer deals with the determination of the rates of
such energy transfers as well as variation of temperature.
• The transfer of energy as heat is always from the higher-
temperature medium to the lower-temperature one.
• Heat transfer stops when the two mediums reach the same
temperature.
• Heat can be transferred in three different modes:
conduction, convection, radiation
Difference between thermodynamics
and heat transfer
Thermodynamics tells us:
• how much heat is transferred (dQ)
• how much work is done (dW)
• final state of the system
Heat transfer tells us:
• how (with what modes) dQ is transferred
• at what rate dQ is transferred
• temperature distribution inside the body
4
5
6
Application Areas of Heat Transfer
6
7
Historical Background Kinetic theory: Treats molecules as
tiny balls that are in motion and thus
possess kinetic energy.
Heat: The energy associated with
the random motion of atoms and
molecules.
Caloric theory: Heat is a fluid like
substance called the caloric that is a
massless, colorless, odorless, and
tasteless substance that can be
poured from one body into another.
It was only in the middle of the
nineteenth century that we had a true
physical understanding of the nature
of heat.
Careful experiments of the
Englishman James P. Joule published
in 1843 convinced the skeptics that
heat was not a substance after all, and
thus put the caloric theory to rest.
8
9
ENGINEERING HEAT TRANSFER
Heat transfer equipment such as heat exchangers, boilers, condensers, radiators,
heaters, furnaces, refrigerators, and solar collectors are designed primarily on the
basis of heat transfer analysis.
The heat transfer problems encountered in practice can be considered in two
groups: (1) rating and (2) sizing problems.
The rating problems deal with the determination of the heat transfer rate for an
existing system at a specified temperature difference.
The sizing problems deal with the determination of the size of a system in order to
transfer heat at a specified rate for a specified temperature difference.
An engineering device or process can be studied either experimentally (testing
and taking measurements) or analytically (by analysis or calculations).
The experimental approach has the advantage that we deal with the actual
physical system, and the desired quantity is determined by measurement, within
the limits of experimental error. However, this approach is expensive, time-
consuming, and often impractical.
The analytical approach (including the numerical approach) has the advantage
that it is fast and inexpensive, but the results obtained are subject to the accuracy
of the assumptions, approximations, and idealizations made in the analysis.
10
Modeling in Engineering
11
• Energy can exist in numerous forms such as:
• thermal,
• mechanical,
• kinetic,
• potential,
• electrical,
• magnetic,
• chemical,
• nuclear.
• Their sum constitutes the total energy E (or e on a unit mass
basis) of a system.
• The sum of all microscopic forms of energy is called the
internal energy of a system.
HEAT AND OTHER FORMS OF ENERGY
12
• Internal energy: May be viewed as the sum of the kinetic and
potential energies of the molecules.
• Sensible heat: The heat associated with the temperature change.
• Latent heat: The internal energy associated with the phase of a
system.
• Chemical (bond) energy: The internal energy associated with the
atomic bonds in a molecule.
• Nuclear energy: The internal energy associated with the bonds within
the nucleus of the atom itself.
What is thermal energy?
What is the difference between thermal
energy and heat?
13
Internal Energy and Enthalpy
• In the analysis of systems that
involve fluid flow, we
frequently encounter the
combination of properties u
and Pv.
• The combination is defined as
enthalpy (h = u + Pv).
• The term Pv represents the
flow energy of the fluid (also
called the flow work).
14
Specific Heats of Gases,
Liquids, and Solids
• Specific heat: The energy required to raise
the temperature of a unit mass of a
substance by one degree.
• Two kinds of specific heats:
• specific heat at constant volume cv
• specific heat at constant pressure cp
• The specific heats of a substance, in
general, depend on two independent
properties such as temperature and
pressure.
• At low pressures and high temperature all
real gases approach ideal gas behavior, and
therefore their specific heats depend on
temperature only.
15
• Incompressible substance: A
substance whose specific volume (or
density) does not change with
temperature or pressure.
• The constant-volume and constant-
pressure specific heats are identical for
incompressible substances.
• The specific heats of incompressible
substances depend on temperature
only.
16
Energy Transfer
Energy can be transferred to or from a given
mass by two mechanisms:
heat transfer and work.
Heat transfer rate: The amount of heat
transferred per unit time.
Heat flux: The rate of heat transfer per unit
area normal to the direction of heat transfer.
when is constant:
Power: The work
done per unit time.
17
THE FIRST LAW OF THERMODYNAMICS
17
The energy balance for any
system undergoing any process
in the rate form
The first law of thermodynamics (conservation of energy
principle) states that energy can neither be created nor destroyed
during a process; it can only change forms.
The net change (increase or
decrease) in the total energy of
the system during a process is
equal to the difference between
the total energy entering and the
total energy leaving the system
during that process.
18
In heat transfer problems it is convenient
to write a heat balance and to treat the
conversion of nuclear, chemical,
mechanical, and electrical energies into
thermal energy as heat generation.
19
Energy Balance for Closed Systems (Fixed Mass)
A closed system consists of a fixed mass.
The total energy E for most systems
encountered in practice consists of the
internal energy U.
This is especially the case for stationary
systems since they don’t involve any
changes in their velocity or elevation
during a process.
20
Energy Balance for
Steady-Flow Systems
A large number of engineering devices such as
water heaters and car radiators involve mass
flow in and out of a system, and are modeled as
control volumes.
Most control volumes are analyzed under steady
operating conditions.
The term steady means no change with time at a
specified location.
Mass flow rate: The amount of mass flowing
through a cross section of a flow device per unit
time.
Volume flow rate: The volume of a fluid flowing
through a pipe or duct per unit time.
21
Surface Energy Balance
This relation is valid for both steady
and transient conditions, and the
surface energy balance does not
involve heat generation since a
surface does not have a volume.
A surface contains no volume or mass,
and thus no energy. Therefore, a
surface can be viewed as a fictitious
system whose energy content remains
constant during a process.
22
HEAT TRANSFER MECHANISMS
• Heat is the form of energy that can be transferred from one system to
another as a result of temperature difference.
• A thermodynamic analysis is concerned with the amount of heat transfer
as a system undergoes a process from one equilibrium state to another.
• The science that deals with the determination of the rates of such energy
transfers is the heat transfer.
• The transfer of energy as heat is always from the higher-temperature
medium to the lower-temperature one, and heat transfer stops when the
two mediums reach the same temperature.
• Heat can be transferred in three basic modes:
• conduction
• convection
• radiation
• All modes of heat transfer require the existence of a temperature
difference.
25
Heat conduction
through a large plane
wall of thickness x
and area A.
CONDUCTION
Conduction: The transfer of energy from the more
energetic particles of a substance to the adjacent
less energetic ones as a result of interactions
between the particles.
In gases and liquids, conduction is due to the
collisions and diffusion of the molecules during their
random motion.
In solids, it is due to the combination of vibrations
of the molecules in a lattice and the energy
transport by free electrons.
The rate of heat conduction through a plane layer is
proportional to the temperature difference across
the layer and the heat transfer area, but is inversely
proportional to the thickness of the layer.
26
When x → 0 Fourier’s law of
heat conduction
Thermal conductivity, k: A measure of the ability
of a material to conduct heat.
Temperature gradient dT/dx: The slope of the
temperature curve on a T-x diagram.
Heat is conducted in the direction of decreasing
temperature, and the temperature gradient
becomes negative when temperature decreases
with increasing x. The negative sign in the equation
ensures that heat transfer in the positive x direction
is a positive quantity.
The rate of heat conduction
through a solid is directly
proportional to its thermal
conductivity.
In heat conduction
analysis, A represents
the area normal to the
direction of heat
transfer.
27
28
Thermal Conductivity
Thermal conductivity:
The rate of heat transfer
through a unit thickness
of the material per unit
area per unit
temperature difference.
The thermal conductivity
of a material is a
measure of the ability of
the material to conduct
heat.
A high value for thermal
conductivity indicates
that the material is a
good heat conductor,
and a low value indicates
that the material is a
poor heat conductor or
insulator.
A simple experimental setup
to determine the thermal
conductivity of a material.
29
The range of
thermal
conductivity of
various
materials at
room
temperature.
30
The mechanisms of heat
conduction in different
phases of a substance.
The thermal conductivities of gases
such as air vary by a factor of 104 from
those of pure metals such as copper.
Pure crystals and metals have the
highest thermal conductivities, and
gases and insulating materials the
lowest.
31
The variation of
the thermal
conductivity of
various solids,
liquids, and gases
with temperature.
32
Thermal Diffusivity
cp Specific heat, J/kg·°C: Heat capacity
per unit mass
cp Heat capacity, J/m3·°C: Heat capacity
per unit volume
 Thermal diffusivity, m2/s: Represents
how fast heat diffuses through a material
A material that has a high thermal
conductivity or a low heat capacity will
obviously have a large thermal diffusivity.
The larger the thermal diffusivity, the faster
the propagation of heat into the medium.
A small value of thermal diffusivity means
that heat is mostly absorbed by the
material and a small amount of heat is
conducted further.
33
CONVECTION
Convection: The mode of
energy transfer between a
solid surface and the
adjacent liquid or gas that is
in motion, and it involves
the combined effects of
conduction and fluid motion.
The faster the fluid motion,
the greater the convection
heat transfer.
In the absence of any bulk
fluid motion, heat transfer
between a solid surface and
the adjacent fluid is by pure
conduction.
Heat transfer from a hot surface to air
by convection.
34
Forced convection: If
the fluid is forced to flow
over the surface by
external means such as
a fan, pump, or the wind.
Natural (or free)
convection: If the fluid
motion is caused by
buoyancy forces that are
induced by density
differences due to the
variation of temperature
in the fluid.
The cooling of a boiled egg by
forced and natural convection.
Heat transfer processes that involve change of phase of a fluid are
also considered to be convection because of the fluid motion
induced during the process, such as the rise of the vapor bubbles
during boiling or the fall of the liquid droplets during condensation.
35
Newton’s law of cooling
h convection heat transfer coefficient, W/m2 · °C
As the surface area through which convection heat transfer takes place
Ts the surface temperature
T the temperature of the fluid sufficiently far from the surface
The convection heat transfer
coefficient h is not a property
of the fluid.
It is an experimentally
determined parameter
whose value depends on all
the variables influencing
convection such as
- the surface geometry
- the nature of fluid motion
- the properties of the fluid
- the bulk fluid velocity
36
37
RADIATION
• Radiation: The energy emitted by matter in the form of
electromagnetic waves (or photons) as a result of the changes in
the electronic configurations of the atoms or molecules.
• Unlike conduction and convection, the transfer of heat by radiation
does not require the presence of an intervening medium.
• In fact, heat transfer by radiation is fastest (at the speed of light)
and it suffers no attenuation in a vacuum. This is how the energy
of the sun reaches the earth.
• In heat transfer studies we are interested in thermal radiation,
which is the form of radiation emitted by bodies because of their
temperature.
• All bodies at a temperature above absolute zero emit thermal
radiation.
• Radiation is a volumetric phenomenon, and all solids, liquids, and
gases emit, absorb, or transmit radiation to varying degrees.
• However, radiation is usually considered to be a surface
phenomenon for solids.
38
Stefan–Boltzmann law
 = 5.670  108 W/m2 · K4 Stefan–Boltzmann constant
Blackbody: The idealized surface that emits radiation at the maximum rate.
Blackbody radiation represents the maximum
amount of radiation that can be emitted from
a surface at a specified temperature.
Emissivity  : A measure of how closely
a surface approximates a blackbody for
which  = 1 of the surface. 0   1.
Radiation emitted
by real surfaces
39
Absorptivity : The fraction of the radiation energy incident on a
surface that is absorbed by the surface. 0   1
A blackbody absorbs the entire radiation incident on it ( = 1).
Kirchhoff’s law: The emissivity and the absorptivity of a surface at
a given temperature and wavelength are equal.
The absorption of radiation incident on
an opaque surface of absorptivity .
40
Radiation heat transfer between a
surface and the surfaces surrounding it.
Net radiation heat transfer:
The difference between the
rates of radiation emitted by
the surface and the radiation
absorbed.
The determination of the net
rate of heat transfer by
radiation between two
surfaces is a complicated
matter since it depends on
• the properties of the surfaces
• their orientation relative to
each other
• the interaction of the medium
between the surfaces with
radiation
R a d i a t i o n i s u s u a l l y
s i g n i f i c a n t r e l a t i v e t o
c o n d u c t i o n o r n a t u r a l
convection, but negligible
relative to forced convection.
When a surface is completely enclosed by a
much larger (or black) surface at temperature
Tsurr separated by a gas (such as air) that
does not intervene with radiation, the net rate
of radiation heat transfer between these
two surfaces is given by
41
Combined heat transfer coefficient hcombined
includes the effects of both convection and radiation.
When radiation and convection occur
simultaneously between a surface and a gas:
42
SIMULTANEOUS HEAT
TRANSFER MECHANISMS
Although there are three mechanisms of
heat transfer, a medium may involve
only two of them simultaneously.
Heat transfer is only by conduction in opaque solids,
but by conduction and radiation in semitransparent
solids.
A solid may involve conduction and radiation but not
convection. A solid may involve convection and/or
radiation on its surfaces exposed to a fluid or other
surfaces.
Heat transfer is by conduction and possibly by
radiation in a still fluid (no bulk fluid motion) and by
convection and radiation in a flowing fluid.
In the absence of radiation, heat transfer through a
fluid is either by conduction or convection,
depending on the presence of any bulk fluid motion.
Convection = Conduction + Fluid motion
Heat transfer through a vacuum is by radiation.
Most gases between two solid surfaces
do not interfere with radiation.
Liquids are usually strong absorbers of
radiation.
One
dimensional
Heat
Conduction
through Long
Cylinder
(2.1)
Fig 2-1
q=Δ Toverall / ΣRth The units for the thermal resistance are ◦C/W
[2-3]
2-9 CONDUCTION-CONVECTION SYSTEMS
The heat that is conducted through a body must frequently be removed (or
delivered) by some convection process. For example, the heat lost by
conduction through a furnace wall must be dissipated to the surroundings
through convection. In heat-exchanger applications a finned-tube
arrangement might be used to remove heat from a hot liquid. The heat
transfer from the liquid to the finned tube is by convection. The heat is
conducted through the material and finally dissipated to the surroundings by
convection. Obviously, an analysis of combined conduction-convection
systems is very important from a practical standpoint. We shall examine some
simple extended-surface problems. Consider the one-dimensional fin exposed
to a surrounding fluid at a temperature T∞ as shown in Figure 2-9. The
temperature of the base of the fin is T0. We approach the problem by making
an energy balance on an element of the fin of thickness dx as shown in the
figure. Thus Energy in left face=energy out right face + energy lost by
convection The defining equation for the convection heat-transfer coefficient
is recalled as
q=hA(T−T∞) [2-29]
Figure 2-9 Sketch illustrating
one-dimensional conduction
and convection through a
rectangular fin.
where the area in this equation is the surface area for convection. Let the cross-
sectional area of the fin be A and the perimeter be P. Then the energy quantities
are
- k A
𝑑𝑇
𝑑𝑥
= −k A
𝑑𝑇
𝑑𝑥
− kA
𝑑2
𝑇
𝑑𝑥2
𝑑𝑥 + ℎ 𝑃 dx (T-T∞)
From energy balance on right and left
side and heat lost due to convection
𝑑𝜃
𝑑𝑥
=
𝑑𝑇
𝑑𝑥
+ 0;
𝑑2
𝜃
𝑑𝑥2 =
𝑑2
𝑇
𝑑𝑥2
- k A
𝑑𝑇
𝑑𝑥
= − k A
𝑑𝑇
𝑑𝑥
− kA
𝑑2
𝑇
𝑑𝑥2 + ℎ 𝑃 dx (T-T∞)
2.30a
2.30b
At x=0, 𝜃0= (𝐶1𝑒-m0 + 𝐶2𝑒m0)
𝜃0= (𝐶1 . 1 + 𝐶2 .
1) = 𝐶1 + 𝐶2
At x=∞,
𝜃∞=0= (𝐶1𝑒- m∞ + 𝐶2𝑒m∞ )
𝜃∞=0= (𝐶1/∞ + 𝐶2 𝑥 ∞)
Not possible, since 𝐶2 𝑥 ∞
Becomes∞ and 𝑥 ∞ can not
be equal to zero, then 𝐶2 =0
So 2nd solution is possible
Hence 𝐶1 = 𝜃0 and 𝐶2= 0;
Solu is 𝜃= (𝐶1𝑒-mx) = (𝜃0𝑒-mx)
Hence ,
𝜃
𝜃0
= 𝑇−𝑇∞
𝑇0
−𝑇∞ =
𝑒−mx
Therefore
𝑑2
𝜃
𝑑𝑥2
−
𝑚2𝜃 = 0
The solution is
𝜽
𝜽𝟎
= 𝑻−𝑻∞
𝑻𝟎
−𝑻∞
= 𝒆−mx [2.32]
𝑻 = 𝑻∞ + (𝑻𝟎 − 𝑻∞)𝒆−mx
At x=∞, 𝜃∞ = 𝑇∞ − 𝑇∞ = 0
𝑎𝑡 𝑥 = 0 ; 𝜃0 = 𝑇0 − 𝑇∞
𝐶1 = 𝜃0 and 𝐶2= 0;
Fin efficiency and effectiveness
{2.38]
Fin Effectiveness =
For Case 2

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Heat and mass transfer

  • 1. Conduction Heat transfer Alok kumar Ansu Manipal University Jaipur 1
  • 2. 2 Objectives • Understand how thermodynamics and heat transfer are related to each other • Distinguish thermal energy from other forms of energy, and heat transfer from other forms of energy transfer • Perform general energy balances as well as surface energy balances • Understand the basic mechanisms of heat transfer, which are conduction, convection, and radiation, and Fourier's law of heat conduction, Newton's law of cooling, and the Stefan–Boltzmann law of radiation • Identify the mechanisms of heat transfer that occur simultaneously in practice • Develop an awareness of the cost associated with heat losses • Solve various heat transfer problems encountered in practice
  • 3. 3 THERMODYNAMICS AND HEAT TRANSFER • Heat: The form of energy that can be transferred from one system to another as a result of temperature difference. • Thermodynamics is concerned with the amount of heat transfer as a system undergoes a process from one equilibrium state to another. • Heat Transfer deals with the determination of the rates of such energy transfers as well as variation of temperature. • The transfer of energy as heat is always from the higher- temperature medium to the lower-temperature one. • Heat transfer stops when the two mediums reach the same temperature. • Heat can be transferred in three different modes: conduction, convection, radiation
  • 4. Difference between thermodynamics and heat transfer Thermodynamics tells us: • how much heat is transferred (dQ) • how much work is done (dW) • final state of the system Heat transfer tells us: • how (with what modes) dQ is transferred • at what rate dQ is transferred • temperature distribution inside the body 4
  • 5. 5
  • 6. 6 Application Areas of Heat Transfer 6
  • 7. 7 Historical Background Kinetic theory: Treats molecules as tiny balls that are in motion and thus possess kinetic energy. Heat: The energy associated with the random motion of atoms and molecules. Caloric theory: Heat is a fluid like substance called the caloric that is a massless, colorless, odorless, and tasteless substance that can be poured from one body into another. It was only in the middle of the nineteenth century that we had a true physical understanding of the nature of heat. Careful experiments of the Englishman James P. Joule published in 1843 convinced the skeptics that heat was not a substance after all, and thus put the caloric theory to rest.
  • 8. 8
  • 9. 9 ENGINEERING HEAT TRANSFER Heat transfer equipment such as heat exchangers, boilers, condensers, radiators, heaters, furnaces, refrigerators, and solar collectors are designed primarily on the basis of heat transfer analysis. The heat transfer problems encountered in practice can be considered in two groups: (1) rating and (2) sizing problems. The rating problems deal with the determination of the heat transfer rate for an existing system at a specified temperature difference. The sizing problems deal with the determination of the size of a system in order to transfer heat at a specified rate for a specified temperature difference. An engineering device or process can be studied either experimentally (testing and taking measurements) or analytically (by analysis or calculations). The experimental approach has the advantage that we deal with the actual physical system, and the desired quantity is determined by measurement, within the limits of experimental error. However, this approach is expensive, time- consuming, and often impractical. The analytical approach (including the numerical approach) has the advantage that it is fast and inexpensive, but the results obtained are subject to the accuracy of the assumptions, approximations, and idealizations made in the analysis.
  • 11. 11 • Energy can exist in numerous forms such as: • thermal, • mechanical, • kinetic, • potential, • electrical, • magnetic, • chemical, • nuclear. • Their sum constitutes the total energy E (or e on a unit mass basis) of a system. • The sum of all microscopic forms of energy is called the internal energy of a system. HEAT AND OTHER FORMS OF ENERGY
  • 12. 12 • Internal energy: May be viewed as the sum of the kinetic and potential energies of the molecules. • Sensible heat: The heat associated with the temperature change. • Latent heat: The internal energy associated with the phase of a system. • Chemical (bond) energy: The internal energy associated with the atomic bonds in a molecule. • Nuclear energy: The internal energy associated with the bonds within the nucleus of the atom itself. What is thermal energy? What is the difference between thermal energy and heat?
  • 13. 13 Internal Energy and Enthalpy • In the analysis of systems that involve fluid flow, we frequently encounter the combination of properties u and Pv. • The combination is defined as enthalpy (h = u + Pv). • The term Pv represents the flow energy of the fluid (also called the flow work).
  • 14. 14 Specific Heats of Gases, Liquids, and Solids • Specific heat: The energy required to raise the temperature of a unit mass of a substance by one degree. • Two kinds of specific heats: • specific heat at constant volume cv • specific heat at constant pressure cp • The specific heats of a substance, in general, depend on two independent properties such as temperature and pressure. • At low pressures and high temperature all real gases approach ideal gas behavior, and therefore their specific heats depend on temperature only.
  • 15. 15 • Incompressible substance: A substance whose specific volume (or density) does not change with temperature or pressure. • The constant-volume and constant- pressure specific heats are identical for incompressible substances. • The specific heats of incompressible substances depend on temperature only.
  • 16. 16 Energy Transfer Energy can be transferred to or from a given mass by two mechanisms: heat transfer and work. Heat transfer rate: The amount of heat transferred per unit time. Heat flux: The rate of heat transfer per unit area normal to the direction of heat transfer. when is constant: Power: The work done per unit time.
  • 17. 17 THE FIRST LAW OF THERMODYNAMICS 17 The energy balance for any system undergoing any process in the rate form The first law of thermodynamics (conservation of energy principle) states that energy can neither be created nor destroyed during a process; it can only change forms. The net change (increase or decrease) in the total energy of the system during a process is equal to the difference between the total energy entering and the total energy leaving the system during that process.
  • 18. 18 In heat transfer problems it is convenient to write a heat balance and to treat the conversion of nuclear, chemical, mechanical, and electrical energies into thermal energy as heat generation.
  • 19. 19 Energy Balance for Closed Systems (Fixed Mass) A closed system consists of a fixed mass. The total energy E for most systems encountered in practice consists of the internal energy U. This is especially the case for stationary systems since they don’t involve any changes in their velocity or elevation during a process.
  • 20. 20 Energy Balance for Steady-Flow Systems A large number of engineering devices such as water heaters and car radiators involve mass flow in and out of a system, and are modeled as control volumes. Most control volumes are analyzed under steady operating conditions. The term steady means no change with time at a specified location. Mass flow rate: The amount of mass flowing through a cross section of a flow device per unit time. Volume flow rate: The volume of a fluid flowing through a pipe or duct per unit time.
  • 21. 21 Surface Energy Balance This relation is valid for both steady and transient conditions, and the surface energy balance does not involve heat generation since a surface does not have a volume. A surface contains no volume or mass, and thus no energy. Therefore, a surface can be viewed as a fictitious system whose energy content remains constant during a process.
  • 22. 22 HEAT TRANSFER MECHANISMS • Heat is the form of energy that can be transferred from one system to another as a result of temperature difference. • A thermodynamic analysis is concerned with the amount of heat transfer as a system undergoes a process from one equilibrium state to another. • The science that deals with the determination of the rates of such energy transfers is the heat transfer. • The transfer of energy as heat is always from the higher-temperature medium to the lower-temperature one, and heat transfer stops when the two mediums reach the same temperature. • Heat can be transferred in three basic modes: • conduction • convection • radiation • All modes of heat transfer require the existence of a temperature difference.
  • 23.
  • 24.
  • 25. 25 Heat conduction through a large plane wall of thickness x and area A. CONDUCTION Conduction: The transfer of energy from the more energetic particles of a substance to the adjacent less energetic ones as a result of interactions between the particles. In gases and liquids, conduction is due to the collisions and diffusion of the molecules during their random motion. In solids, it is due to the combination of vibrations of the molecules in a lattice and the energy transport by free electrons. The rate of heat conduction through a plane layer is proportional to the temperature difference across the layer and the heat transfer area, but is inversely proportional to the thickness of the layer.
  • 26. 26 When x → 0 Fourier’s law of heat conduction Thermal conductivity, k: A measure of the ability of a material to conduct heat. Temperature gradient dT/dx: The slope of the temperature curve on a T-x diagram. Heat is conducted in the direction of decreasing temperature, and the temperature gradient becomes negative when temperature decreases with increasing x. The negative sign in the equation ensures that heat transfer in the positive x direction is a positive quantity. The rate of heat conduction through a solid is directly proportional to its thermal conductivity. In heat conduction analysis, A represents the area normal to the direction of heat transfer.
  • 27. 27
  • 28. 28 Thermal Conductivity Thermal conductivity: The rate of heat transfer through a unit thickness of the material per unit area per unit temperature difference. The thermal conductivity of a material is a measure of the ability of the material to conduct heat. A high value for thermal conductivity indicates that the material is a good heat conductor, and a low value indicates that the material is a poor heat conductor or insulator. A simple experimental setup to determine the thermal conductivity of a material.
  • 29. 29 The range of thermal conductivity of various materials at room temperature.
  • 30. 30 The mechanisms of heat conduction in different phases of a substance. The thermal conductivities of gases such as air vary by a factor of 104 from those of pure metals such as copper. Pure crystals and metals have the highest thermal conductivities, and gases and insulating materials the lowest.
  • 31. 31 The variation of the thermal conductivity of various solids, liquids, and gases with temperature.
  • 32. 32 Thermal Diffusivity cp Specific heat, J/kg·°C: Heat capacity per unit mass cp Heat capacity, J/m3·°C: Heat capacity per unit volume  Thermal diffusivity, m2/s: Represents how fast heat diffuses through a material A material that has a high thermal conductivity or a low heat capacity will obviously have a large thermal diffusivity. The larger the thermal diffusivity, the faster the propagation of heat into the medium. A small value of thermal diffusivity means that heat is mostly absorbed by the material and a small amount of heat is conducted further.
  • 33. 33 CONVECTION Convection: The mode of energy transfer between a solid surface and the adjacent liquid or gas that is in motion, and it involves the combined effects of conduction and fluid motion. The faster the fluid motion, the greater the convection heat transfer. In the absence of any bulk fluid motion, heat transfer between a solid surface and the adjacent fluid is by pure conduction. Heat transfer from a hot surface to air by convection.
  • 34. 34 Forced convection: If the fluid is forced to flow over the surface by external means such as a fan, pump, or the wind. Natural (or free) convection: If the fluid motion is caused by buoyancy forces that are induced by density differences due to the variation of temperature in the fluid. The cooling of a boiled egg by forced and natural convection. Heat transfer processes that involve change of phase of a fluid are also considered to be convection because of the fluid motion induced during the process, such as the rise of the vapor bubbles during boiling or the fall of the liquid droplets during condensation.
  • 35. 35 Newton’s law of cooling h convection heat transfer coefficient, W/m2 · °C As the surface area through which convection heat transfer takes place Ts the surface temperature T the temperature of the fluid sufficiently far from the surface The convection heat transfer coefficient h is not a property of the fluid. It is an experimentally determined parameter whose value depends on all the variables influencing convection such as - the surface geometry - the nature of fluid motion - the properties of the fluid - the bulk fluid velocity
  • 36. 36
  • 37. 37 RADIATION • Radiation: The energy emitted by matter in the form of electromagnetic waves (or photons) as a result of the changes in the electronic configurations of the atoms or molecules. • Unlike conduction and convection, the transfer of heat by radiation does not require the presence of an intervening medium. • In fact, heat transfer by radiation is fastest (at the speed of light) and it suffers no attenuation in a vacuum. This is how the energy of the sun reaches the earth. • In heat transfer studies we are interested in thermal radiation, which is the form of radiation emitted by bodies because of their temperature. • All bodies at a temperature above absolute zero emit thermal radiation. • Radiation is a volumetric phenomenon, and all solids, liquids, and gases emit, absorb, or transmit radiation to varying degrees. • However, radiation is usually considered to be a surface phenomenon for solids.
  • 38. 38 Stefan–Boltzmann law  = 5.670  108 W/m2 · K4 Stefan–Boltzmann constant Blackbody: The idealized surface that emits radiation at the maximum rate. Blackbody radiation represents the maximum amount of radiation that can be emitted from a surface at a specified temperature. Emissivity  : A measure of how closely a surface approximates a blackbody for which  = 1 of the surface. 0   1. Radiation emitted by real surfaces
  • 39. 39 Absorptivity : The fraction of the radiation energy incident on a surface that is absorbed by the surface. 0   1 A blackbody absorbs the entire radiation incident on it ( = 1). Kirchhoff’s law: The emissivity and the absorptivity of a surface at a given temperature and wavelength are equal. The absorption of radiation incident on an opaque surface of absorptivity .
  • 40. 40 Radiation heat transfer between a surface and the surfaces surrounding it. Net radiation heat transfer: The difference between the rates of radiation emitted by the surface and the radiation absorbed. The determination of the net rate of heat transfer by radiation between two surfaces is a complicated matter since it depends on • the properties of the surfaces • their orientation relative to each other • the interaction of the medium between the surfaces with radiation R a d i a t i o n i s u s u a l l y s i g n i f i c a n t r e l a t i v e t o c o n d u c t i o n o r n a t u r a l convection, but negligible relative to forced convection. When a surface is completely enclosed by a much larger (or black) surface at temperature Tsurr separated by a gas (such as air) that does not intervene with radiation, the net rate of radiation heat transfer between these two surfaces is given by
  • 41. 41 Combined heat transfer coefficient hcombined includes the effects of both convection and radiation. When radiation and convection occur simultaneously between a surface and a gas:
  • 42. 42 SIMULTANEOUS HEAT TRANSFER MECHANISMS Although there are three mechanisms of heat transfer, a medium may involve only two of them simultaneously. Heat transfer is only by conduction in opaque solids, but by conduction and radiation in semitransparent solids. A solid may involve conduction and radiation but not convection. A solid may involve convection and/or radiation on its surfaces exposed to a fluid or other surfaces. Heat transfer is by conduction and possibly by radiation in a still fluid (no bulk fluid motion) and by convection and radiation in a flowing fluid. In the absence of radiation, heat transfer through a fluid is either by conduction or convection, depending on the presence of any bulk fluid motion. Convection = Conduction + Fluid motion Heat transfer through a vacuum is by radiation. Most gases between two solid surfaces do not interfere with radiation. Liquids are usually strong absorbers of radiation.
  • 45. q=Δ Toverall / ΣRth The units for the thermal resistance are ◦C/W [2-3]
  • 46. 2-9 CONDUCTION-CONVECTION SYSTEMS The heat that is conducted through a body must frequently be removed (or delivered) by some convection process. For example, the heat lost by conduction through a furnace wall must be dissipated to the surroundings through convection. In heat-exchanger applications a finned-tube arrangement might be used to remove heat from a hot liquid. The heat transfer from the liquid to the finned tube is by convection. The heat is conducted through the material and finally dissipated to the surroundings by convection. Obviously, an analysis of combined conduction-convection systems is very important from a practical standpoint. We shall examine some simple extended-surface problems. Consider the one-dimensional fin exposed to a surrounding fluid at a temperature T∞ as shown in Figure 2-9. The temperature of the base of the fin is T0. We approach the problem by making an energy balance on an element of the fin of thickness dx as shown in the figure. Thus Energy in left face=energy out right face + energy lost by convection The defining equation for the convection heat-transfer coefficient is recalled as q=hA(T−T∞) [2-29]
  • 47. Figure 2-9 Sketch illustrating one-dimensional conduction and convection through a rectangular fin. where the area in this equation is the surface area for convection. Let the cross- sectional area of the fin be A and the perimeter be P. Then the energy quantities are - k A 𝑑𝑇 𝑑𝑥 = −k A 𝑑𝑇 𝑑𝑥 − kA 𝑑2 𝑇 𝑑𝑥2 𝑑𝑥 + ℎ 𝑃 dx (T-T∞) From energy balance on right and left side and heat lost due to convection
  • 48. 𝑑𝜃 𝑑𝑥 = 𝑑𝑇 𝑑𝑥 + 0; 𝑑2 𝜃 𝑑𝑥2 = 𝑑2 𝑇 𝑑𝑥2 - k A 𝑑𝑇 𝑑𝑥 = − k A 𝑑𝑇 𝑑𝑥 − kA 𝑑2 𝑇 𝑑𝑥2 + ℎ 𝑃 dx (T-T∞) 2.30a 2.30b
  • 49. At x=0, 𝜃0= (𝐶1𝑒-m0 + 𝐶2𝑒m0) 𝜃0= (𝐶1 . 1 + 𝐶2 . 1) = 𝐶1 + 𝐶2 At x=∞, 𝜃∞=0= (𝐶1𝑒- m∞ + 𝐶2𝑒m∞ ) 𝜃∞=0= (𝐶1/∞ + 𝐶2 𝑥 ∞) Not possible, since 𝐶2 𝑥 ∞ Becomes∞ and 𝑥 ∞ can not be equal to zero, then 𝐶2 =0 So 2nd solution is possible Hence 𝐶1 = 𝜃0 and 𝐶2= 0; Solu is 𝜃= (𝐶1𝑒-mx) = (𝜃0𝑒-mx) Hence , 𝜃 𝜃0 = 𝑇−𝑇∞ 𝑇0 −𝑇∞ = 𝑒−mx Therefore 𝑑2 𝜃 𝑑𝑥2 − 𝑚2𝜃 = 0 The solution is 𝜽 𝜽𝟎 = 𝑻−𝑻∞ 𝑻𝟎 −𝑻∞ = 𝒆−mx [2.32] 𝑻 = 𝑻∞ + (𝑻𝟎 − 𝑻∞)𝒆−mx At x=∞, 𝜃∞ = 𝑇∞ − 𝑇∞ = 0 𝑎𝑡 𝑥 = 0 ; 𝜃0 = 𝑇0 − 𝑇∞ 𝐶1 = 𝜃0 and 𝐶2= 0;
  • 50. Fin efficiency and effectiveness {2.38] Fin Effectiveness =