Heat is a form of energy that is transferred between objects by radiation, conduction, or convection. The document discusses these three methods of heat transfer and provides examples. It also defines important concepts such as temperature, insulators, conductors, and how materials expand and contract with changes in heat. The key learning points are to understand the different forms of heat transfer and how temperature and heat energy are related but distinct concepts.
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Heat Transfer
The heat transfer is defined as the transmission of heat energy from one region to another region as a result of temperature gradient. In actual practice, the heat transfer always takes place from the region of high temperature to the region of low temperature.
Modes of Heat Transfer
The transfer of heat energy from one region to another region takes place by the following three modes −
Conduction
Convection
Radiation
In a majority of real situations, heat transfer occurs as a result of a combination of these modes of heat transfer.
Conduction
When the heat transfers from one part of the substance to another part without the movement in the molecules of the substance, it is called the conduction mode of heat transfer.
In this mode, the rate of heat transfer, i.e., the rate of conduction of heat along the substance depends upon the temperature gradient.
Mathematically, for a cubic body with parallel faces with
Thickness=tmeters
Crosssectionalarea=Am2
Temperatureoftwofaces=T1∘CandT2∘C
Timeforwhichheattransfertakespalce=Thours
Then, the amount of heat passed through this cubic body is given by,
H=kAt(T1−T2)T
Where, H is measured in Mega Joules (MJ) and k is the coefficient of the thermal conductivity for the substance and it is measured in MJ/m3/∘C/hr
.
Examples of heat transfer through the conduction mode are refractory heating, the heating of insulating material, etc.
Convection
When the transfer of heat takes place from one part to another part of the substance or fluid due to the actual motion of the molecules, it is called the convection mode of heat transfer. In this method, the rate of heat transfer depends mainly upon the difference in the fluid density at different temperature.
The transfer of heat energy from immersion water heater to water is an example of convection mode of heat transfer. The amount of heat absorbed by water from the heater through convection partly depends upon the temperature of the heating element and partly upon the position of the heater.
Mathematically, the heat dissipation in convection mode of heat transfer is given by the following expression −
H=a×(T1−T2)bW/m2
Where,
'a' and 'b' are the constants whose values depend upon the heating surface.
T1
and T2
are the temperatures of heating element and the fluid / substance in °C.
Radiation
When the heat transfer takes place from the source of heat to the substance to be heated without direct contact between them, it is called the radiation mode of heat transfer. The heat transfer through the radiation depends upon the surface. The transfer of heat in case of solar heater is an example of radiation mode of heat transfer.
Mathematically, the rate of heat dissipation through radiation is given by Stefan's law, that is
H=(5.72×104)×ke[(T11000)4−(T21000)4]W/m2
Where,
σ = (5.72× 104) is the Stefan's constant
'e' is the emissivity (it is 1 for ideal radiator)
T1
is the temperature of source in Kelvin
T2
is the temperature of the subs
2. By the end of this chapter you
will be able to:
• Describe heat energy, its’ units and explain how
it converts to other forms
• Explain how heat affects expansion and
contraction of materials
• Explain conduction, convection and radiation
• Identify good and bad conductors of heat
(insulators V conductors)
• Differentiate between heat energy and
temperature
3. What is Heat?
• Form of energy because it can move
things
- E.g: Makes a hot air balloon rise.
- Steam engines
• Measured in JOULES (J)
4. Heat can be converted to other
forms of energy
• Sunlight (heat) is used by plants for
Photosynthesis (to make food), it is
converted to chemical energy.
• Oil and gas are burned in power stations
to produce heat energy, this is used to
turn turbines which produce electricity
(electrical energy)
5. How is heat produced?
• The movement of particles/molecules
produces heat
• Particles move about more and take
up more room if heated – this is why
things expand if heated
• It is also why substances change form
when heated
solids liquids gases
6. Heat Transfer
• Heat always moves from a warmer place
to a cooler place.
• Hot objects in a cooler room will cool to
room temperature.e.g: tea, coffee
• Cold objects in a warmer room will heat up
to room temperature.e.g: butter, ice
8. Forms of Heat Transfer
• 3 types;
• Conduction
• Convection
• Radiation
9. Radiation
How does heat energy get
from the Sun to the Earth?
There are no particles between
the Sun and the Earth so it
MUST travel by radiation
?
RADIATION
10. Radiation
• The transfer of heat in rays, from a hot
object, without needing a medium to pass
through
• It travels in all directions from a hot object
• The hotter an object is, the more heat it
will radiate out
• Does the surface affect the way heat is
radiated?
11. • What colour should we paint
radiators?
Which colour is better to
wear on a sunny day?
black or white?
• A dull black surface will radiate and
absorb heat better than a bright shiny
surface.
12. Four containers were filled with warm water. Which
container would have the warmest water after ten minutes?
Shiny metal
Dull metal
Dull black
Shiny black
The __________ container would be the warmest after ten
minutes because its shiny surface reflects heat _______ back
into the container so less is lost. The ________ container
would be the coolest because it is the best at _______ heat
radiation.
shiny metal
radiation
dull black
emitting
13. Radiation – Think Pair-Share
Radiation travels in straight lines
True/False
Radiation can travel through a vacuum
True/False
Radiation requires particles to travel
True/False
Radiation travels at the speed of light
True/False
14. Radiation questions
Why are houses painted white in hot countries?
White reflects heat radiation and keeps the house cooler.
Why are shiny foil blankets wrapped around marathon runners at the end of a
race?
The shiny metal reflects the heat radiation from the runner back in, this stops
the runner getting cold.
15. Conduction
• Transfer of heat is through a SOLID by
being passed from one particle to the next
• Particles at the warm end move faster and
this then causes the next particles to move
faster and so on. e.g: poker in fire
spoon in tea
• In this way heat in an object travels from:
the HOT end the cold end
16. Conduction
• When you heat a metal strip at one end, the heat travels
to the other end.
• As you heat the metal, the particles vibrate, these
vibrations make the adjacent particles vibrate, and so on
and so on, the vibrations are passed along the metal and
so is the heat. We call this? Conduction
17. Conductors/Insulators
• If a substance easily allows heat to move
through it, we can say it is a good
conductor of heat. e.g: most metals
• If a substance does not allow heat to pass
through it easily we can say it is an
Insulator. E.g: wood, plastic, glass
• Why do many sauce pans have plastic
handles?
20. Convection
What happens to the particles in a liquid or a
gas when you heat them?
The particles spread out and
become less dense.
A liquid or gas.
21. Convection
• It is the way in which particles in a GAS or
LIQUID move upwards, carrying heat with
them
• Think about when you boil water, the bubbles move
upwards
• Or think of a gas heater in the room, the heat rises
around the room
23. Convection
Where is the
cooling
compartment
put in a fridge?
Cooling
compartment
It is put at the top,
because cool air
sinks, so it cools the
food on the way
down.
It is warmer at
the bottom, so
this warmer air
rises and a
convection
current is set up.
25. Convection questions
Why are boilers placed beneath hot water
tanks in people’s homes?
Hot water rises.
So when the boiler heats the water, and the hot water rises, the water tank
is filled with hot water.
Why does hot air rise and cold air sink?
Cool air is more dense than warm air, so the cool air ‘falls
through’ the warm air.
26. Heat Vs Temperature
• The temperature of an object tells us how
HOT it is
• Measured in degrees Celsius - °C
• It is NOT the same as heat energy
although the two quantities are related.
e.g. a beaker of water at 60 °C is
hotter than a bath of water at 40 °C BUT
the bath contains more joules of heat
energy
27. Heating and Cooling
• If an object has become hotter,
it means that it has gained heat energy.
• If an object cools down, it means it has
lost energy
28. Heating and Cooling cont…
• Heat energy always moves from:
• HOT object COOLER object
e.g. Cup of water at 20 °C in a room at 30°C -
gains heat energy and heats up – its
temperature rises
Cup of water at 20 °C in a room at 10°C
loses heat energy and cools down – its
temperature will fall.
29. Expansion/Contraction
• Why are gaps left in pavements, railway
tracks, and floor boards?
• Why are electricity cables left slack?
• Why are bottles of minerals not filled up to
the top?
• Because materials expand when they
heat up we need to leave room for that.
30. Expansion V Contraction
• The reason materials expand when
heated is because the heat gives the
molecules energy and as a result they
begin to move, leaving them further apart
and hence the material expands
• Cooling has the opposite effect, the
particles move closer together causing the
molecules to contract
• One exception: water expands when
cooled
31. Revision
1. Which of the following is not a
method of heat transfer?
A. Radiation
B. Insulation
C. Conduction
D. Convection
32. Revision
1. Which of the following is not a
method of heat transfer?
A. Radiation
B. Insulation
C. Conduction
D. Convection
33. 2. In which of the following are
the particles closest together?
A. Solid
B. Liquid
C. Gas
D. Fluid
34. 2. In which of the following are
the particles closest together?
A. Solid
B. Liquid
C. Gas
D. Fluid
35. 3. How does heat energy reach
the Earth from the Sun?
A. Radiation
B. Conduction
C. Convection
D. Insulation
36. 3. How does heat energy reach
the Earth from the Sun?
A. Radiation
B. Conduction
C. Convection
D. Insulation
37. 4. Which is the best surface for
reflecting heat radiation?
A. Shiny white
B. Dull white
C. Shiny black
D. Dull black
38. 4. Which is the best surface for
reflecting heat radiation?
A. Shiny white
B. Dull white
C. Shiny black
D. Dull black
39. 5. Which is the best surface for
absorbing heat radiation?
A. Shiny white
B. Dull white
C. Shiny black
D. Dull black
40. 5. Which is the best surface for
absorbing heat radiation?
A. Shiny white
B. Dull white
C. Shiny black
D. Dull black