B - A - 3.5 - DC Sources of Electricity-6.pdf

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Module 3: Electrical Fundaments
Topic 3.5: DC Sources of Electricity
 INTRODUCTION

On completion of this topic you should be able to:

3.5.1 Describe the construction & basic chemical action of the following
cells:
Primary
Secondary
Lead acid
Nickel cadmium
Other alkaline
3.5.2 Describe the purposes of connecting cells in series and parallel.
3.5.3 Describe internal resistance and its effect on a battery.
3.5.4 Describe construction and operation of thermocouples and list
materials used in their construction.
3.5.5 Identify photo-cells and describe their operation.

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 THE CELL

Galvanic / voltaic cells
Cell – device that transforms chemical energy into electrical energy.
Simplest cell – Galvanic or Voltaic cell.
Consists of piece of Carbon (C) and piece of Zinc (Zn) suspended in
electrolyte.
Electrolyte – a solution of Water (H20) and Sulfuric Acid (H2S04).
Cell – fundamental unit of the battery.
Some cells – container acts as one of the electrodes.
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 CONTAINER

May be constructed from many different materials (hard rubber, plastic etc.).
Provides a means of holding (containing) the electrolyte.
Also used to mount electrodes.
In voltaic cell – container material must NOT be acted upon by electrolyte.

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 ELECTRODES

Electrodes – conductors by which current leaves or returns to electrolyte.
In simple cell – Carbon and Zinc strips placed in electrolyte.
In dry cell – Carbon rod in centre and Zinc container.

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 ELECTROLYTE

Electrolyte – solution that acts upon the electrodes.
Provides a path for electron flow.
May be salt, acid, or alkaline solution.
In simple galvanic cell – electrolyte is in a liquid form.
In dry cell – electrolyte is a paste.

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 ELECTROCHEMICAL ACTION

Cell – device in which chemical energy is converted to electrical energy.
Process is called electrochemical action.
Load connected – electrons flow from -ve through load to +ve.
Voltage across electrodes depends upon electrode materials and
electrolyte.
Current delivered depends upon resistance of entire circuit – including cell
itself.

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 ELECTROCHEMICAL ACTION

Internal resistance of cell depends upon:
Size of the electrodes
Distance between electrodes in electrolyte
Resistance of electrolyte
The larger the electrodes and closer they are in electrolyte (without touching):
The lower the internal resistance of cell
The more current the cell is capable of supplying to load

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 CELLS

Electric cells are classified into 2 categories:
Primary
Secondary

Primary cell – cannot be recharged satisfactorily.
Part of electrode deteriorates as cell produces current – cannot be restored.

Secondary cell – chemical action can be reversed.

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 PRIMARY CELL

Cell in which chemical action eats away one of the electrodes – usually
negative.
When this occurs – electrode must be replaced or cell must be discarded.
In galvanic-type cell – Zinc electrode and liquid electrolyte are usually
replaced.

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 PRIMARY CELL

With dry cell – usually cheaper to buy a new cell.
For both electrolytic and galvanic cells:
Positive terminal is the electrode at which oxidation occurs – It has a
positive charge
Negative terminal is the electrode at which reduction occurs – It has
a negative charge

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 ALKALINE CELLS

Similar to Carbon-Zinc cells.

Electrolyte – alkali solution (Potassium Hydroxide).

Enables delivery of sustained high current.

More efficient than Carbon-Zinc cell.

Much longer shelf life.

Perform better under drain and in cold weather.

Do not produce any gaseous products.

May be rechargeable.

Types - Mercury Oxide, Silver Oxide, Zinc air.

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 SECONDARY CELL

Cell in which electrodes and electrolyte are altered when it delivers current.
May be restored to original condition by charging.
Charging – electric current through cell in opposite direction to that of
discharge.
Secondary cells sometimes known as wet cells.
Automobile battery – common example of secondary cell.

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 SECONDARY CELLS

Some basic types are:
Lead-acid
Nickel-cadmium
Silver-Zinc
Silver-cadmium

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 LEAD-ACID BATTERY CONSTRUCTION

Container houses separate cells – 6 cells for 12 volt / 12 cells for 24 volt.
Most containers are hard rubber, plastic, or some other insulating material.
Resistant to electrolyte and mechanical shock & withstand extreme
temperatures.
Vent plugs allow gases to escape.

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 LEAD-ACID BATTERY CONSTRUCTION

Separators – hold plates apart whilst allowing free movement of electrolyte.
Separator material – wood, perforated glass, rubber or plastic.
Space at bottom of cell – collects sediment formed as cell is used.
Always one more -ve plate than +ve plates.
All cells have uneven number of plates, i.e.. 9 plate cell has 5 -ve & 4 +ve.

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 LEAD-ACID BATTERY CONSTRUCTION

-ve plate group is all -ves of individual cells and +ve plate group is all
+ves
Plates are interlaced with a terminal attached to each plate group.
Terminals of individual cells are connected together by link connectors.
Cells are connected in series.
+ve terminal of one end cell becomes +ve terminal of battery.
-ve terminal of opposite end cell becomes -ve terminal of battery.

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 LEAD-ACID BATTERY CONSTRUCTION

Terminals usually identified from one another by their size and markings.
+ve terminal marked (+) – sometimes coloured red.
+ve terminal is physically larger than -ve terminal marked (–) (typical).
Individual cells of lead-acid battery are not replaceable.
In event one cell fails – battery must be replaced..

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 LEAD-ACID ELECTROLYTE

Specific Gravity (SG) – weight of a given volume of liquid in comparison to
eight of same volume of pure water.
The higher the SG of a liquid – the denser (thicker) it is.
Mixture of 64% distilled water (H20) and 36% sulfuric acid (H2SO4).
Typical – SG of 1.270 when fully charged (at 20°C, 68°F).

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 ADDING WATER

When adding water to a battery –
use ONLY distilled water.
Minerals / chemicals in regular
water react with plate material &
shorten battery life.
Lead-acid – electrolyte level no
higher than 1/8 inch below bottom
of vent well.
To avoid permanent damage,
ensure electrolyte level never
drops below top of plates.
Also, avoid over filling – this may
result in electrolyte overflow from
battery.

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 LEAD-ACID

Most widely used secondary cell.
Car battery – very common example.
Positive terminal – lead peroxide
Negative terminal – spongy lead
Electrolyte – sulfuric acid and water
Nominal open-circuit cell voltage – 2 volts.

12 V lead-acid aircraft
battery
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 LEAD-ACID DISCHARGING

Discharging

Sulphuric acid combines with
active material in both plates.
Forms ‘Lead Sulphate’ on plates
and water (H2O) in electrolyte.
Increase in battery internal
resistance & decrease in
electrolyte specific gravity (SG).
(SG - 1.150 – completely
discharged).
If left discharged for substantial
period – sulphation occurs – cells
lose capacity.

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 LEAD ACID CHARGING

Charging
Chemical action is reversed.
Sulphate on +ve and -ve plates
disassociates from lead.
Sulphate returns to electrolyte to
form Sulphuric Acid (H2SO4).
+ve plate changes back to lead
peroxide & -ve back to spongy
lead.
Specific gravity of electrolyte
rises to charged value (1.270
approx.).

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 LEAD ACID CHARGING

Final Charging Phase
Little or no Sulphate left on plates.
Charging current decomposes
water into its Hydrogen and
Oxygen components.
Gases released via vent plugs
(Hydrogen gas is explosive).
Batteries in service need to be
periodically topped up with water
(distilled water).

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 LEAD-ACID BATTERY OPERATION REVIEW

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 LEAD-ACID BATTERY OPERATION REVIEW

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 LEAD-ACID BATTERY OPERATION REVIEW

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 LEAD-ACID BATTERY OPERATION REVIEW

Discharging a lead acid battery below 10.5 volts will severely damage it.

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 INTERNAL RESISTANCE

Every cell has internal resistance.
Opposes current flow through cell – limits battery output.
Inversely proportional to area of electrodes (exposed to electro-chemical
action).
Directly proportional to distance separating electrode surfaces.
Influenced by nature and condition of electrolyte – typically increases with
age.
Becomes part of overall circuit resistance.

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 NICKEL-CADMIUM CELL

Known as Ni-Cad – far superior to Lead-acid cell.

Generally require less maintenance in regard to adding of electrolyte or water.

Negative terminal – Cadmium.

Positive terminal – Nickel Oxide.

Electrolyte – Potassium Hydroxide and water (30% by weight).
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 NICKEL-CADMIUM CELL

Electrolyte – SG of 1.300 – does not vary with state of charge.

Electrolyte only visible and checked at end of charge cycle.

When cell is discharged:

Negative terminal becomes Cadmium Hydroxide

Positive terminal becomes Nickel Hydroxide

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 NICKEL-CADMIUM CELL

Ni-Cad and Lead-acid cells – comparable capacities at normal discharge
rates.
At high discharge rates – Ni-Cad cell can deliver a larger amount of power.
In addition, Ni-Cad cell can:
Be charged in a shorter time
Stay idle longer in any state of charge
Keep a full charge when stored for a longer period of time
Be charged and discharged any number of times without detriment
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 NICKEL-CADMIUM CELL

Nominal open-circuit cell voltage – 1.3 volts

Distinct advantage over Lead-acid – internal resistance is very low:
Voltage remains constant until almost totally discharged (70-80% of
charge)
Advantage in recharging – allows high charging rates without damage
While high discharge and charging rates are favourable – dangers involved.
Dangers begin with high battery temperatures.

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 NICKEL-CADMIUM CELL THERMAL RUNAWAY

High charging cycle produces high temperatures.
High temperatures lowers internal resistance – causes higher current draw.
Higher current draw increases temperature – lowers internal resistance.
Snow-balling effect.

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 NEUTRALISING SPILLS

Acid - Sulphuric
Neutralise with Bicarbonate of soda (baking soda) or Ammonia.
On skin – flush with copious amounts of cold water
Alkaline - Potassium Hydroxide
Off aircraft - use a 3% solution of Boric acid or Acetic acid (vinegar).
On aircraft - use a chromic acid solution
On skin – flush with copious amounts of cold water

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 AIRCRAFT LEAD-ACID BATTERY

Differs only slightly from standard automotive or general purpose lead-acid
battery.
Quality of manufacturing and maintenance standards are higher.
Aircraft battery cell plates slightly thinner – allows more plates per cell.
Separators – superior materials allow plates to be placed closer together.
Increases efficiency and lowers internal resistance.
Aircraft batteries typically have 19 plates per cell and 12 cells for a 24 volt
battery.
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 AIRCRAFT NICKEL-CADMIUM BATTERY

From outside – Ni-Cad battery differs very little from lead-acid battery.
Cases are about same size – especially large types.
Real difference appears when you lift top cover:
Lead-acid – 12 cells all formed in one case – large vent caps
Ni-Cad – 19 or 20 cells, interconnected individual cells – no large vent caps
Ni-Cad – very low internal resistance – introduced into aircraft for high start
current.
Handle heavy load currents better than lead acid – last longer when used that
way.
Used on small loads over long period of time – lowers capacity – memory effect.

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 CHEMICAL STATES IN CELLS

***** CAUTION *****

All aircraft batteries release hydrogen and oxygen during charging

HYDROGEN IS HIGHLY EXPLOSIVE!!!!!
Do not use naked flames or cause sparks anywhere near charging batteries

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 TYPES OF CELLS

Development of new and different types of cells has been rapid.

Virtually impossible to have a complete knowledge of all the various types.

A few cell types are:

Silver-Zinc

Nickel-Zinc

Nickel-Cadmium

Silver-Cadmium

Organic and inorganic Lithium

Mercury cells

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 SILVER-Zinc CELLS

Used extensively to power emergency equipment.
Relatively expensive.
Can be charged and discharged fewer times than other types.
Light weight, small size, and good electrical capacity.
Same electrolyte as Nickel-Cadmium cell (Potassium Hydroxide and water).
Positive terminal – Silver Oxide.
Negative terminal – Zinc.

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 COMBINING CELLS

In many cases, a device may require more electrical energy than 1 cell can
provide.
May require either a higher voltage or more current, and in some cases both.
Necessary to combine or interconnect cells to meet higher requirements.
Aircraft batteries - nominally rated at 12 or 24 volts.
Open circuit voltages of serviceable batteries are a little higher:
12-cell Lead-acid and 20-cell Ni-Cad batteries – 25 to 26.5 volts
19-cell Ni-Cad batteries – 24 to 25 volts
Work on basis of 2 volts per lead-acid cell and 1.3 volts per Ni-Cad cell.

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 CONNECTING CELLS IN SERIES

Batteries - 2 or more cells grouped together to form 1 source of supply.

Usually housed in one container.

Series connection - gives a total emf equal to sum of individual voltages.

Purpose – to provide higher output voltage.

Higher voltage does not mean more current supply.

Current supply capability – same as a single cell.

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 SERIES-CONNECTED CELLS

Assume load requires 6 volts and
current of 1/8 amp.
Single cell normally supplies only
1.5 volts – connect 4 together in
series – 6 volts.
CAUTION
To connect cells in series –
connect alternate terminals
together (- to +, - to +, etc.).
2 remaining terminals are used for
connection to load only.
Do not connect 2 remaining
terminals together – will short
battery.
Would quickly discharge cells but
could cause some cell types to
explode.

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 CONNECTING CELLS IN PARALLEL

Connecting cells in parallel increases battery’s current supplying capability.

Purpose – to provide higher output current.

Output voltage is same as that of a single cell – 1.5 volts.

Parallel circuit – voltage as per single cell, but total current available increases.

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 PARALLEL-CONNECTED CELLS

Assume an electrical load requires
only 1.5 volts, but 1/2 amp of
current.
Assume that a single cell will supply
only 1/8 amp.
To meet requirement, cells are
connected in parallel.
All +ve electrodes together and all -
ve electrodes together.
Voltage between lines is same as
that of one cell, or 1.5 volts.
Each cell may contribute 1/8 amp to
line – 4 cells x 1/8 Amp = 1/2 Amp.

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 SERIES-PARALLEL CONNECTED CELLS

Example – load requirement of 4.5 volts and ½ amp.
To provide required 4.5 volts, 3 x 1.5-volt cells connected in series.
To provide required 1/2 ampere of current, 4 series groups connected in
parallel.

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 CONNECTING CELLS

A - Lamp will be normal brightness – 1.5 volt supply.

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 CONNECTING CELLS

B – Lamp will be normal brightness – batteries in parallel – 1.5 volts.

Batteries will last twice as long.

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 CONNECTING CELLS

C – Batteries in series – 3 volts.

Lamp will be very bright but will blow very quickly.

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 BATTERY QUESTIONS

1. What is the purpose of a cell?
A cell is a device that converts chemical energy to electrical energy.
2. What are the 3 parts of a cell?
Electrodes, electrolyte, and container.
3. What is the purpose of each of the 3 parts of a cell?
Electrodes are the current conductors of the cell.
Electrolyte is the solution that acts upon the electrodes.
Container holds electrolyte and provides a means of mounting
electrodes.
4. What is electrochemical action?
The process of converting chemical energy into electrical energy.
5. What serves as the negative terminal of a dry cell?
The Zinc container.

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 BATTERY QUESTIONS

6. Why is a dry cell called a DRY cell?
The electrolyte is not a liquid but is in the form of a paste.
7. What are the 2 types of cells?
Primary and secondary.
8. What is the main difference between the 2 types of cells?
Secondary cell can be restored to its original condition by an electric
current. The primary cell cannot.
9. Can a battery be recharged by adding more electrolyte?
No, a current must be passed through the battery.

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 BATTERY QUESTIONS

11. What are the 3 ways of combining cells, and what is each used
for?
Series – to increase voltage but not current.
Parallel – to increase current but not voltage.
Series-Parallel – to increase both current and voltage.
12. What are some advantages of a Ni-Cad cell over a lead-acid cell?
Can deliver a larger amount of power.
Can be charged in a shorter time.
Stays idle longer in any state of charge.
Be charged and discharged any number of times without detriment.
13. What is used to neutralise (a) acid and (b) alkaline spills?
(a) acid – bicarbonate of soda (baking soda) or ammonia.
(b) alkaline – Chromic acid solution on aircraft, 3% solution of boric
acid or acetic acid (vinegar).

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 BATTERY SUMMARY

ELECTROCHEMICAL ACTION – process of converting chemical energy into
electrical energy.

CELL – device that transforms chemical energy into electrical energy.
3 parts – electrodes, electrolyte, and container.
2 basic cells – primary and secondary.

ELECTRODES – current conductors of cell.

ELECTROLYTE – solution that acts upon electrodes.

CONTAINER – holds electrolyte and provides means of mounting electrodes.

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 BATTERY SUMMARY

PRIMARY CELL – chemical action destroys one of electrodes (typically –ve)
Primary cell cannot be recharged.

SECONDARY CELL – chemical action alters electrodes and electrolyte
Electrodes and electrolyte restored to original condition by recharging.

DRY CELL – type commonly referred to as "flashlight battery".
Electrolyte not in liquid form, but paste – term dry cell used.
In most dry cells – case is negative terminal.

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 BATTERY SUMMARY

LEAD-ACID CELL – most widely used secondary cell
Positive terminal – Lead Peroxide – when charged
Negative terminal – sponge lead – when charged
Electrolyte – Sulfuric Acid and water – dilutes when discharged
NICKEL-CADMIUM CELL – NICAD
Positive terminal – Nickel Hydroxide – when discharged
Negative terminal – Cadmium Hydroxide – when discharged
Electrolyte – Potassium Hydroxide and water – does not change
Advantages over lead-acid cell:
Charges in a shorter period of time
Delivers a larger amount of power
Stays idle longer
Can be charged and discharged many times

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 BATTERY SUMMARY

BATTERY – voltage source in a single container made from one or more cells
Cells can be combined in series, parallel, or series-parallel.

SERIES CONNECTED CELLS – provide a higher voltage than a single cell,
with no increase in current.

PARALLEL CONNECTED CELLS – provide a higher current than a single
cell, with no increase in voltage.

SERIES-PARALLEL CONNECTED CELLS – provide a higher voltage and a
higher current than a single cell.

HYDROMETER – provides means to check specific gravity of electrolyte.

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 BATTERY SUMMARY

CAPACITY – an indication of current-supplying capability of battery for a
specific period of time; e.g., 400 ampere-hour.

BATTERY CHARGE – process of reversing current flow through battery to
restore to its original condition.
Addition of active ingredient to electrolyte will NOT recharge battery

GASSING – production of hydrogen gas caused by charge current breaking
down water in electrolyte.
Steady gassing is normal during charging process.
Violent gassing indicates that charge rate is too high.

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 THERMOCOUPLES

One of a number of devices used to sense temperature.
Typical uses in aircraft:
Sense temperature of cylinder heads on piston engines
Sense temp of gas passing into, through or from turbines (gas turbine
engines)
Some older aircraft – fire warning detectors – sense abnormally rapid
temp increases

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 THERMOCOUPLE OPERATION

Production of EMF by heat – apply heat to a junction formed by 2 dissimilar
metals.
Joined metal junction – hot junction Unjoined section – cold junction.
Application of heat to metal results in freeing electrons.
Energy required to free electrons from each metal varies – resultant charge varies.
Potential difference between metals can be measured at cold junction.
Phenomenon of generating a potential via heat – Seebeck effect.
Combination of the junction and the 2 dissimilar metals is known as a
thermocouple.
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 THERMOCOUPLE OPERATION

Hot junction is connected to a meter – calibrated in degrees Celsius.
Meter effectively forms the cold junction.
Leads made from same combination of metals – prevents more junctions.
Used in aircraft to measure:
Engine turbine inlet temperatures
Engine exhaust gas temperatures
Engine cylinder head temperatures

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 THERMOCOUPLE

2 dissimilar metal wires connected at 2 junctions to form a loop.
Temperature difference between 2 junctions – small EMF is generated.
emf – proportional to temperature difference.
Typically 4 to 5 millivolts per 100ºC.
Common combinations used in aircraft are:
Chromel-Alumel – up to 1200ºC (typical – gas turbine engines)
Iron-Constantan – up to 850ºC (typical – piston engines)
Copper-Constantan – up to 400ºC (typical – piston engines)

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 THERMOCOUPLE CONSTRUCTION

Constructed of 2 dissimilar metal wires joined at one end.
May be constructed of several different combinations of materials.
Most important factor – "thermoelectric difference" between 2 materials.
A significant difference between 2 materials will result in better performance.
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 THERMOCOUPLE CONSTRUCTION

Some thermocouple types:
T type – Copper-Constantan up to 400ºC typical on piston engines.
J type – Iron-Constantan up to 850ºC typical on piston engines.
K type – Chromel-Alumel up to 1200º typical on turbine engines.

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 LIGHT

Light is electromagnetic radiation – thought to travel in form similar to radio waves.
Like radio waves, light is measured in wavelengths.
Travels at 186,000 miles / second or 300,000,000 metres / second in a vacuum.
Frequency range of light – 300 to 300,000,000 gigahertz (giga = 1,000,000,000).
Below 400,000 gigahertz – infrared light
400,00 to 750,000 gigahertz – visible to human eye
Above 750,000 gigahertz – ultraviolet light
Light waves at upper end of frequency range have more energy than at lower end.

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 PHOTO CELL

Also known as a solar cell or photovoltaic cell.

A solar cell is a device that converts sunlight directly into a usable amount of
direct current (DC) electricity. Assemblies of cells are used to make solar
panels.
Photons in sunlight hit the solar panel and are absorbed by semiconducting
materials. Electrons are knocked loose from their atoms, allowing them to
flow through the material to produce electricity.
Thus, it can be said that photons absorbed in the semiconductor create
mobile electron-hole pairs.

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 PHOTO CELL

An antireflective coating is applied to the top of the cell to reduce reflection
losses to less than 5 percent.

Solar modules are made by connecting several cells (usually 36) to achieve
useful levels of voltage and current.

The most that cells could absorb is around 25 percent, and more likely is 15
percent or less.

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 CONCLUSION

Now that you have completed this topic, you should be able to:

3.5.1 Describe the construction & basic chemical action of the following
cells:
Primary
Secondary
Lead acid
Nickel cadmium
Other alkaline
3.5.2 Describe the purposes of connecting cells in series and parallel.
3.5.3 Describe internal resistance and its effect on a battery.
3.5.4 Describe construction and operation of thermocouples and list
materials used in their construction.
3.5.5 Identify photo-cells and describe their operation.

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 This concludes:

Module 3: Electrical Fundaments
Topic 3.5: DC Sources of Electricity