Transcript Slide 1

PH0101 UNIT-5 LECTURE 1
Introduction
A fuel cell configuration
Types of fuel cell
Principle, construction and working
Advantage, disadvantage and application
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1. Introduction
What is fuel cell?
A Fuel cell is a electrochemical device that converts
chemical energy into electrical energy
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Every fuel cell has two electrodes, one positive and one
negative, called, respectively, the cathode and anode. The
reactions that produce electricity take place at the
electrodes
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In all types of fuel cell, hydrogen is used as fuel and can be
obtained from any source of hydrocarbon.
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The fuel cell transform hydrogen and oxygen into electric
power, emitting water as their only waste product.
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• Every fuel cell also has an electrolyte, which carries
electrically charged particles from one electrode to the
other, and a catalyst, which speeds the reactions at the
electrodes.
• A single fuel cell generates a tiny amount of direct
(DC) electricity.
current
• A converter is used to produce AC current
• In practice, many fuel cells are usually assembled into a
stack. Cell or stack, the principles are the same.
• In 1932, Francis Bacon developed the first successful
FC. He used hydrogen, oxygen, an alkaline electrolyte,
and nickel electrodes.
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2. A fuel cell configuration
A fuel cell consists of two
electrodes namely an anode
and
a
cathode
and
sandwiched
around
an
electrolyte.
An electrolyte is a substance,
solid or liquid, capable of
conducting oving ions from
one electrode to other.
(+)
(-)
Anode
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Cathode
Electrolyte
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3. Types of fuel cells
There are diffrent types of fuel cells, differentiated by the
type of electrolyte separating the hydrogen from the
oxygen.The types of fuel cells are:
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Alkaline fuel cells (AFC)
Direct methanol fuel cells (DMFC)
Molten carbonate fuel cell (MFFC)
Phosphoric acid fuel cells (PAFC)
Polymer electrolyte membrane fuel cells (PEMFC)
Solid oxide fuel cells (SOFC)
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4. Principle, construction and working of H2-O2 fuel cell
Principle:
Electrons
The fuel is oxidized
(e-)
on the anode and oxidant
reduced on the cathode.
One species of ions are
Cations
transported
from
one
(+ve)
electrode to the other
Anions (-ve)
through the electrolyte to
Oxidant
Fuel
combine there with their
Electrolyte
counterparts, while electrons
travel through the external
Fuel
Oxidant
circuit
producing
the Permeable
Permeable
Anode
Cathode
electrical current.
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Working
The Fuel gas (hydrogen rich) is passed towards the anode
where the following oxidation reaction occurs:
H2 (g) = 2H+ + 2eThe liberated electrons from hydrogen in anode side do not
migrate through electrolyte.
Therefore, they passes through the external circuit where work
is performed, then finally goes into the cathode.
On the other hand, the positive hydrogen ions (H+) migrate
across the electrolyte towards the cathode.
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At the cathode side the hydrogen atom reacts with oxygen
gas (from air) and electrons to form water as byproduct
according to:
The overall cell reaction is
fuel + oxidant
H2 + 1/2 O2 +2e -
product + Heat
H2O + Heat
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The liberated electrons from the hydrogen are responsible for
the production of electricity.
The water is produced by the combination of hydrogen, oxygen
and liberated electrons and is sent out from the cell.
The DC current produced by fuel cell is later converted into AC
current using an inverter for practical application.
The voltage developed in a single fuel cell various from 0.7 to
1.4 volt.
More power can be obtained by arranging the individual fuel cell
as a stack. In this case, each single cell is sandwiched with one
another by a interconnect.
Therefore, electricity power ranging from 1 kW to 200 kW can be
obtained for domestic as well as industrial application.
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Electrical power production by fuel cell
Hydrogen
Oxygen
Rotating shaft connected to generator for electricity production
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5. Advantage, disadvantage and applications
Advantages
• Zero Emissions: a fuel cell vehicle only emits water
vapour. Therefore, no air pollution occurs.
• High efficiency: Fuel cells convert chemical energy
directly into electricity without the combustion process.
As a result, Fuel cells can achieve high efficiencies in
energy conversion.
• High power density: A high power density allows fuel
cells to be relatively compact source of electric power,
beneficial in application with space constraints.
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• Quiet operation: Fuel cells can be used in residential or
built-up areas where the noise pollution can be avoided.
• No recharge: Fuel cell systems do not require recharging.
Disadvantages
• It is difficult to manufacture and stores a high pure hydrogen
• It is very expense as compared to battery
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Applications
1. Portable applications
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They used in portable appliances and power tools
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They can be used in small personal vehicles
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They are used Consumer electronics like laptops, cell
phones can be operated
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They can be used in Backup power
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2. Transportation applications
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They can be used for transport application in the following
areas,
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Industrial transportation
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Public transportation
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Commercial transportation (truck, tractors)
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Marine and Military transportation
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3. Power distribution application
• Fuel cells can be used for the distribution of power
various fields such as,
in
• Homes and small businesses
• Commercial and industrial sites
• Remote,
off-grid
locations
(telecom
towers,
weather
stations)
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