Geothermal Energy PDF

Summary

This presentation describes geothermal energy, covering its resources, different energy sources, and the thermodynamics involved in converting geothermal energy into electricity. It discusses the merits and demerits of using geothermal energy. A comprehensive guide, focusing on topics like geothermal energy resources and their application in generating electricity.

Full Transcript

Artificial Neural Networks
- Introduction -
Birinderjit Singh Kalyan
EEDEPARTMENT OF MECHANICAL ENGG.
UNIVERSITY INSTITUTE OF ENGINEERING
Assistant Professor
CHANDIGARH UNIVERSITY, MOHALI

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 Non Conventional Energy Resources
MEO-453
Session : Jan-May,2024
Dr. Surender Kumar
Assistant Professor
Chandigarh University

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 1.16 Geothermal Energy

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 Resources of geothermal energy

 70% comes from the decay of radioactive nuclei with long half lives that are
embedded within the Earth. Geothermal energy comes from heat in the Earth's
core which was generated by the radioactive decay of materials when the planet
formed. This thermal energy, stored by rocks and fluids at the centre of the
Earth, can be used as a renewable energy resource.

 Some energy is from residual heat left over from earth’s formation.

 The rest of the energy comes from meteorite impacts.
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 Different Geothermal Energy Sources

Hot Water Reservoirs: As the name implies these are reservoirs of hot underground water.
There is a large amount of them in the US, but they are more suited for space heating than for
electricity production.

Natural Stem Reservoirs: In this case a hole dug into the ground can cause steam to come to
the surface.

Geopressured Reservoirs: In this type of reserve, brine completely saturated with natural gas
in stored under pressure from the weight of overlying rock. This type of resource can be used
for both heat and for natural gas.

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 Normal Geothermal Gradient: At any place on the planet, there is a normal temperature
gradient of +300C per km dug into the earth. Therefore, if one digs 20,000 feet the
temperature will be about 1900C above the surface temperature. This difference will be
enough to produce electricity. However, no useful and economical technology has been
developed to extracted this large source of energy.

Hot Dry Rock: This type of condition exists in 5% of the US. It is similar to Normal
Geothermal Gradient, but the gradient is 400C/km dug underground.

Molten Magma: No technology exists to tap into the heat reserves stored in magma. The
best sources for this in the US are in Alaska and Hawaii.
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Thermodynamics of geo-thermal energy conversion-electrical conversion

Direct Sources function by sending water down a well to be heated by the Earth’s warmth.

Then a heat pump is used to take the heat from the underground water to the substance that heats

the house.

Then after the water it is cooled is injected back into the Earth.

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 Generation of Electricity is appropriate for sources >150oC

Dry Steam Plants:
The production of geothermal power using Rising Steam from the Earth is based on harnessing
naturally occurring steam from geothermal reservoirs to generate electricity. This process,
primarily used in Dry Steam geothermal power plants

Working Principle
A Dry Steam plant is the simplest type of geothermal power plant, which directly
uses geothermal steam to turn a turbine. This plant is feasible in regions with high-
temperature geothermal reservoirs (around 150°C or more) that produce natural
steam. Here’s how it operates:
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 Extraction of Steam: High-temperature steam is extracted
directly from geothermal wells drilled into underground
reservoirs.

Steam to Turbine: The extracted steam is routed through
pipelines to a turbine.

Turbine Rotation: The high-pressure steam flows over the
blades of the turbine, causing it to rotate and, in turn, drive an
attached generator.

Condensation and Reinjection: The steam exits the turbine at
lower pressure and is condensed back into water, typically in a
cooling system, and is reinjected into the reservoir to sustain the
geothermal source.
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Thermodynamics of Dry Steam Plant :

Here’s a breakdown of the thermodynamic steps involved:

Isentropic Expansion (Turbine): The high-pressure steam from the reservoir expands
isentropically through the turbine (i.e., without heat exchange), converting thermal energy to
mechanical work to drive the generator. The steam's enthalpy decreases as it expands, producing
work output.

Isobaric Cooling (Condenser): The steam leaving the turbine is cooled at constant pressure in a
condenser, converting it into liquid water. This phase change releases latent heat into the cooling
system.

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Isentropic Compression (Pump): The condensed water is pumped back into the injection well to
maintain pressure in the geothermal reservoir, completing the cycle.

1. The Dry Steam cycle’s efficiency depends on the high temperature and pressure of the
steam, as these increase the turbine's output.
2. Since there’s no working fluid change, the cycle is simpler but limited to high-temperature
geothermal reservoirs.

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 Constructional features and associated prime movers
Flash Steam Plants:

These are the most common plants. These systems pull deep, high pressured hot water that
reaches temperatures of 1820C/3600F or more to the surface. This water is transported to low
pressure chambers, and the resulting steam drives the turbines. The remaining water and steam
are then injected back into the source from which they were taken

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Binary Cycle Geothermal Power Plant
Working Principle

Binary Cycle plants are used in low-to-moderate temperature geothermal areas (typically
between 85–170°C), where the geothermal fluid alone cannot reach the steam requirements to
drive a turbine. Instead, a secondary working fluid with a lower boiling point (like isobutane or
pentane) is used to create a closed-loop system. Here’s how a Binary Cycle plant works:

Heat Transfer to Working Fluid: Hot geothermal water (or brine) is pumped from the reservoir
and flows through a heat exchanger. This brine does not directly contact the turbine but transfers
its heat to a secondary working fluid.

Vaporization of Working Fluid: The secondary fluid in the heat exchanger absorbs heat from
the geothermal brine and vaporizes. This vapor then expands, creating high pressure to drive the
turbine.
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Turbine and Generator: The high-pressure vapor
flows into a turbine, causing it to rotate and generate
electricity through an attached generator.

Condensation and Recirculation: After passing
through the turbine, the vapor is cooled in a
condenser, converting it back to liquid form. The
working fluid is then recirculated to the heat
exchanger, repeating the process.

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Thermodynamics of Binary Cycle Plant
The Binary Cycle plant operates based on the Organic Rankine Cycle (ORC), as it uses organic
fluids with lower boiling points than water. This system’s thermodynamic steps are as follows:
Isobaric Heating (Heat Exchanger): The geothermal brine transfers heat to the organic working
fluid at constant pressure, causing it to vaporize. This phase change absorbs heat and converts the
fluid to high-energy vapor.
Isentropic Expansion (Turbine): The vaporized working fluid expands isentropically through
the turbine, converting heat into mechanical work, which drives the generator. The working fluid's
enthalpy decreases, releasing energy as it expands.

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 Isobaric Cooling (Condenser): The expanded vapor is condensed back into liquid in a

condenser at constant pressure, allowing the release of latent heat to the environment or a cooling
medium.
Isentropic Compression (Pump): The condensed working fluid is then pumped back to the heat

exchanger, where it is reheated, and the cycle begins anew.
The efficiency of the Binary Cycle is enhanced by the lower boiling point and specific heat

properties of the organic working fluid, allowing the plant to harness energy from lower-
temperature sources.
This closed-loop cycle minimizes the release of geothermal fluids into the environment and can

operate with a relatively low geothermal brine temperature.
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 Availability of Geothermal Energy
On average, the Earth emits 1/16 W/m2. However,
this number can be much higher in areas such as
regions near volcanoes, hot springs and fumaroles.
As a rough rule, 1 km3 of hot rock cooled by
1000C will yield 30 MW of electricity over thirty
years.
It is estimated that the world could produce
600,000 EJ over 5 million years.

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Geothermal production of energy is 3rd highest among renewable energies. It is
behind hydro and biomass, but before solar and wind.

Iceland is one of the more countries successful in using geothermal energy:
-86% of their space heating uses geothermal energy.
-16% of their electricity generation uses geothermal energy.

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 Merits of Geothermal Energy

1.Renewable and Sustainable: Geothermal energy is derived from the Earth's natural heat,
which is continually replenished, making it a renewable energy source with a reliable supply.

2.Environmentally Friendly: It emits significantly fewer greenhouse gases compared to fossil
fuels, making it a cleaner energy source.

3.Low Operating Costs: Once a geothermal plant is established, the operating costs are
relatively low compared to traditional fossil fuel-based power plants.

4.Local Economic Benefits: It can create jobs and stimulate local economies, especially in
areas with substantial geothermal resources.

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 Demerits of Geothermal Energy:
1.High Initial Costs: The cost of drilling and establishing a geothermal plant is high, especially
if the site requires deep drilling to access the heat.
2.Location-Specific: Geothermal resources are only available in certain areas, typically near
tectonic plate boundaries, which limits widespread adoption.
3.Potential Environmental Impact: Drilling into geothermal reservoirs can release trapped
gases and minerals into the atmosphere and water, which may harm the environment if not
managed carefully.
4.Earthquake Risk: Geothermal drilling and the process of injecting water into hot rocks can
trigger small seismic events.

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