Cairo University Faculty of Engineering Electrical Power Engineering (EPE) Lectures - Principles of Energy Conversion (EPEG102)

Summary

These lecture notes cover fossil power plants, outlining fuel storage and handling, boilers, turbines, generators and electrical systems within the context of energy conversion. The document is from a Cairo University class.

Full Transcript

Cairo University
Faculty of Engineering
Electrical Power Engineering (EPE)

Principles of Energy Conversion
(EPEG102)

Lecture 4 – Fossil Power Plants

Dr. Ahmed M. Zobaa
Contact email: [email protected]
Fossil Power Plants
Fuel Storage and Handling
Boiler
Turbine
Generator and Electrical System
Combustion Turbine
Combined Cycle Plants
Fossil Power Plants
An assortment of energy sources, including both renewable
and nonrenewable
Most nonrenewable electricity generating schemes today
require a thermal-to-mechanical-to-electrical energy
conversion process
The renewable forms, including solar, wind, hydroelectric,
and ocean-based energy, take a variety of energy conversion
paths to produce electric power.
Fossil Power Plants
The steam boiler burns fuel in a furnace.
The heat generates steam that drives the turbine–generator set.
The turbine-driven generator converts the mechanical
rotational energy to electrical energy.
Fossil Power Plants
The major components of a thermal power plant are:
Fossil Power Plants
1-Fuel Storage and Handling
A- Coal
The heating value “per-unit mass”
Transportation to power plant
Coal train
Conveyer belts open-air
Barge coal yard

Additional conveyer belts move the coal into the power
plant where the coal is fed through hoppers to large mills

The mills pulverize the coal to a fine powder
The coal powder is mixed with air and injected into the boiler
through burners.
The mixture is ignited as it enters the furnace.
Fossil Power Plants
1-Fuel Storage and Handling
B- Oil and liquefied natural gas
The heating value “per-unit volume”
Transportation to power plant
Rail
Pumping System large steel
Pipelines tanks

The oil is pumped to the burners, which atomize the oil
and mix the small oil particles with air.

The mixture is injected into the furnace and ignited

Note:
Natural gas is the easiest of the fossil fuels to burn as it mixes well with
air and it burns cleanly with little ash.
Fossil Power Plants
2 Boiler
* The boiler is an inverted U-shaped steel structure.
* Water tubes cover the walls of the boiler.
* The major systems of a boiler are the following:
Fuel injection system,
Water–steam system,
Air–flue gas system, and
Ash handling system.
Fossil Power Plants
2- Boiler
Fossil Power Plants
Condenser
*A deaerator is built in the condenser to remove the air from the condensed
water.
*This is necessary because the air (oxygen) in the water causes corrosion
of the pipes

* Heat dissipation techniques include:
Once-through cooling to a river, lake, or ocean.
Cooling ponds, including spray ponds.
Cooling towers.
Fossil Power Plants
Electrostatic precipitators:
Fossil Power Plants
Ideally, the hydrocarbon combustion produces water and carbon dioxide
gases.

The main gaseous pollutants from combustion sulfur oxides (SOX), nitrous
oxides (NOX), and CO.
Both SOX and NOX can create acid rain composed of sulfuric acid
(H2SO4) and nitric acid (HNO3), respectively.
The SOX, mostly SO2 and some SO3, can cause respiratory irritation.
The NOX contributes to smog and ozone formation and vegetation
damage.
The CO reduces the oxygen-carrying capability of the blood, referred to as
carbon monoxide poisoning

Note:
Ground-level ozone is a harmful air pollutant that is the main ingredient in “smog”. It is
also known as tropospheric ozone or low-level ozone. The stratospheric ozone, on the other
hand, is a naturally occurring atmospheric gas that forms the ozone layer that protects the
Earth from catastrophic ultraviolet rays produced by the sun
Fossil Power Plants
*Most fossil plants utilize a Rankine thermal cycle employing
steam. The thermal efficiency is defined as:

* The maximum thermal efficiency is defined by the Carnot
cycle as:
Fossil Power Plants
3-Turbine
* The heat energy in the steam is converted to mechanical energy
Fossil Power Plants
3-Turbine
Fossil Power Plants
4-Generator and Electrical System
Fossil Power Plants
4- Generator and Electrical System
Synchronous machines are principally used as alternating
current (AC) generators. They supply the electric power used by
all sectors of modern societies: industrial, commercial,
agricultural, and domestic.
Synchronous generators are built in large units, their rating
ranging from tens to hundreds of megawatts.
Synchronous generator converts mechanical power to ac electric
power. The source of mechanical power, the prime mover, may
be a diesel engine, a steam turbine, a water turbine, or any similar
device.
For high-speed machines, the prime movers are usually steam
turbines employing fossil or nuclear energy resources.
Low-speed machines are often driven by hydro-turbines that
employ water power for generation.
Fossil Power Plants
4- Generator and Electrical System
Types of Synchronous Machine
According to the arrangement of the field and armature windings,
synchronous machines may be classified as rotating-armature type
or rotating-field type.

Rotating-Armature Type: The armature winding is on the rotor and the
field system is on the stator.

Rotating-Field Type: The armature winding is on the stator and the field
system is on the rotor.

*According to the shape of the field, synchronous machines may be
classified as cylindrical-rotor (non-salient pole) machines and
salient-pole machines
Fossil Power Plants
4- Generator and Electrical System
Generator and Electrical System inside the Power Plant
Fossil Power Plants
Other types of fossil power plants include:
Combustion Turbine.
Combined Cycle Plants.
Fossil Power Plants
Combustion Turbine
Petroleum and natural gas can be burned in a furnace boiler-
based plant to produce steam for input to a turbine generator.
Light fuel oil and natural gas can undergo combustion in a
conventional gas turbine that utilizes the Brayton thermal
cycle.
The figure below shows that a gas turbine plant is significantly
simpler in structure than the coal-fired unit described earlier.
Fossil Power Plants
Combustion Turbine

Fuel is added to compressed air, which, upon combustion, creates
expansive gases that drive the gas turbine.
The compressor and generator are shaft-connected to the turbine.
The simplicity and size of these plants permit locating them on
small sites, but the thermal efficiency of these simple cycles is
low.
With the higher cost of fossil fuels and the low thermal efficiency,
these conventional gas turbine plants are generally restricted to
serving as peaking or reserve units. Fortunately, gas turbines can
be taken from a cold start to 100% power within minutes.
Fossil Power Plants
Combined Cycle Plants
Combined cycle plants have become a popular generation scheme
in recent years
A combined cycle unit utilizes a gas turbine (Brayton) top cycle
with the excess heat going to a steam turbine (Rankine) bottom
cycle.
Fossil Power Plants
Combined Cycle Plants
* The efficiency of a combined cycle plant without heat
augmentation is determined from the efficiencies of the
Brayton and Rankine cycles using:
Fossil Power Plants
Combined Cycle Plants

The overall thermal efficiency of combined cycle plants built today is
a remarkable 60%.
Combined cycle plants are designed for intermediate load since they
are relatively quick to start.
Additional advantages of these plants are that they can be constructed
in a relatively short period (about 2 years) and their use of natural
gas, which is an environmentally good choice (except for greenhouse
gas emission) and a reasonably priced fuel.
Combined cycle plants should not be confused with cogeneration,
also known as combined heat and power (CHP), which is the
production of electricity in-house along with industrial process steam.
Fossil Power Plants

Useful Videos:

Thermal Power Plants:
https://youtu.be/IdPTuwKEfmA?feature=shared

Combined Cycle Power Plants:
https://youtu.be/bnR-CLpZE9I?feature=shared
Fuel Calorific (Heating or Energy) Value

The calorific value is a measure of the amount of heat a substance
produces after complete combustion.
It is also known as the heating value, energy value, or specific energy
of combustion.
It is usually expressed in energy units / mass units, i.e., kWH/kg or
kJ/kg.
This energy is the input power to the station and can be expressed as:

𝐸𝑖𝑛 = 𝑚 ∗ 𝐶𝑉
The mass is often expressed as mass flow rate (𝑚),
ሶ thus, the power
can be expressed as:

𝑃𝑖𝑛 = 𝑚ሶ ∗ 𝐶𝑉
Plant Output Power and Efficiency

The station output power can be expressed as:

𝑃𝑜𝑢𝑡 = 3𝑉𝐿 𝐼𝐿 cos(∅)
In case of three phase (which is the practical case), where VL is the line
voltage and IL is the line current, and ∅ is the phase shift between the
phase voltage and phase current waveforms.

For simplicity, we may consider the output of the station is DC; hence
the output power is:
𝑃𝐷𝐶 𝑜𝑢𝑡 = 𝑉𝐼
Plant Output Power and Efficiency

The station efficiency can be expressed as:

𝐸𝑜𝑢𝑡 𝑃𝑜𝑢𝑡 𝑃𝑖𝑛 − 𝑃𝑎𝑢𝑥𝑖𝑙𝑙𝑖𝑎𝑟𝑦 − 𝑃𝑙𝑜𝑠𝑠𝑒𝑠
η= = =
𝐸𝑖𝑛 𝑃𝑖𝑛 𝑃𝑖𝑛