Energy Resources PDF

Summary

This document provides an overview of different energy resources, their characteristics, and applications. It covers renewable sources like solar and wind, and non-renewable resources like fossil fuels. The document also includes a section on the environmental impact of various energy sources.

Full Transcript

ENERGY RESOURCES
Energy = Power x time
Energy (Watts)= J/s

Average house consumption in a city = 500
units= 500 KWh

Every year energy
usage across world= 1000 MW power plant; 75% capacity
500 Exa joules
1000 x 0.75 x 365 x 24 h= 6.6 billion KWh in a year
Electricity: Coal,
With this 6.6 billion KWh in a year, and
lignite, Thermal
average consumption of electricity=
power plants
500 KWh; we can Distribute 1.1 million
Transportation:
homes per year electricity
Petrol, diesel, CNG,
Battery
Scale of
quantities Watts
ENERGY
Examples
RESOURCES
Femto 10-15 Lasers: Medical devices
Pico 10-12 Lab scale AC/DC source
Nano 10-9
Micro 10-6 Artificial pacemakers
Milli 10-3 Scientific calculator
Kilo 103 House hold bulbs (10-100 W)
Mega 106 Submarines; propulsion engines
Giga 109
Tera 1012
Peta 1015
Exa 1018
Zetta 1021
Yotta 1024
 ENERGY RESOURCES
1) Renewable: Regenerates as fast as
they are consumed and are
continuously available, Eg: Solar,
wind, water, geothermal
2) Non-Renewable: cannot be
replenished. Eg:, Fossil Fuel and
Nuclear materials.

Renewable Energy Installed Capacity
Source (MW) as on 2017
Solar 16611
Wind 32746
Biomass 8181
Why focus on renewable energy resources???
Small Hydro Power 4399 ▪ Global warming
▪ Ocean Acidification
Waste to Energy 114
 SOLAR ENERGY
Two ways to utilize
1. Conversion of solar energy into thermal: Solar collectors
2. Photovoltaic cell

Solar collector
Photovoltaic cell
Photo voltaic cells or Solar cells are made of thin wafers of semiconductor materials
like silicon and germanium.
When solar radiations fall on them, a potential difference is produced, which causes
the flow of electrons.
The direct current gets converted to alternating current using inverters
Typical output of a module (~30 cells) is ≈ 15 V, with 1.5 A current
 APPLICATIONS OF SOLAR ENERGY
Photovoltaic cells Solar cookers
Solar thermal power generation
Solar drying system
Solar cooler
Solar water heater
Cooling and refrigeration
Solar water heating systems

EUREF Campus Berlin
 ADVANTAGES AND DISADVANTAGES OF
SOLAR ENERGY
Advantages
It is clean, noise-free, renewable energy resources
Eco-friendly
A typical solar cell can produce about 0.7 W of
electricity
Low maintenance cost as no moving parts
Can be used in remote, inaccessible areas where power
transmission is difficult and quite expensive
Limitations
Solar cells can produce electricity only on sunny days largest solar power plant in india is found in
Solar power stations do not match the power output of Rajasthan Bhadla Solar Park.
the conventional stations
Energy swaraj Yatra - case study
Mostly used for charging batteries
 WIND ENERGY
kinetic energy, caused due to the differential heating
of the atmosphere (WIND).
Can be easily used in the grid, pumping,
desalination, and telecommunication
Influences more by terrain, water bodies,
vegetation, and geographical region
Wind Energy conversion system: wind turbine,
generator, interconnected apparatus and control
system
WECS can operate in parallel with public and local
grid
APPLICATIONS: To lift water from the ground or
flooded mines, To grind cereals and grains, to Wind Energy Conversion System - These systems are
designed to convert wind energy into usable electrical
generate electricity power. They primarily include wind turbines along with
associated equipment like controllers, inverters, and
sometimes storage solutions.
 ADVANTAGES AND DISADVANTAGES OF WIND
ENERGY
Advantages
Clean fuel source, No recurring expenses
Wind turbines can be built on farms, where most of the best wind sites are found. Farmers
can continue to work the land because the wind turbines use only a fraction of the land.
Wind power plant owners make rent payments to the farmer for the use of the land.

Disadvantages:
Wind flowing with sufficient speed is required
Speed and direction of the wind is seasonal
Installation cost is high
Establishment of a wind farm requires a large land area of about 12 hectares for 1 MW
Low energy density
 Aralvaimozhi, the Muppandal wind farm Structure of Windmill, Germany
which the largest in Asia is located near the
village of Muppandal

450px-Aralvaimozhy_station

examples of wind turbines:
1. vertical axis wind turbine
2. omni directional wind turbine
 GEOTHERMAL ENERGY
Geothermal energy is a renewable thermal/ heat energy
found in the rock formation of the earth. Possible
manifestation: hot water spring, geysers
When the mantle becomes melted, magma is created. The
magma reaches the crust and heats nearby rocks and
water. The heated water can reach the surface and form
hot springs and geysers.
Geothermal energy is an underused heat and power
resource, reliable (average system availability of 95%),
and homegrown (making us less dependent on foreign
oil).
 GEOTHERMAL RESOURCES
Hydrothermal
Hot Water : Hot water below 100 degree Celsius.
The geothermal aquifer is covered by confining
layer that keep hot water under pressure.
Wet Steam filed: The water is pressurized at
more than 100 degree. (super heated water from
highly pressurizes underground reservoir
Vapor dominated resource: dry saturated streams
above atmospheric pressure and temperature of 350
degree C. Hokkaido in Japan

Geopressured resource: moderate temperature Fumaroles - openings in the earth's crust, often
brines (160 degrees C) containing dissolved found near volcanoes, that emit steam and
gases like CO2, SO2 and H2S. These gases are
methane. Trapped in impermeable sedimentary released when magma heats groundwater to
formation at high pressure. create steam.

FUMAROLES
RING OF FIRE
GEOTHERMAL RESOURCES
 ADVANTAGES AND DISADVANTAGES OF
GEOTHERMAL ENERGY
Advantages
Low running cost
It is a clean fuel source with no pollution.
Easy and modular construction

Disadvantages
Poor efficiency compared to fossil fuel plants (15 %)
Large amount of withdrawal can cause surface subsidence
Hot water can contain gases like radon, ammonia, and hydrogen sulfide.
Large area is needed
Available only in some selected areas.
 HYDROENERGY
Energy of moving water obtained when a descent of Top 5 dams in Power
the river is compressed to a single location. India generation
Small hydropower: produce electricity upto 25 MW capacity
Large hydropower Tehri Dam- 1000 Megawatts
Utarakhand
Advantages
Bhakra Nangal 1000 Megawatts
Low operating and maintenance cost
Dam- HP
Short gestation period (time taken from initial planning and
approval stages of a hydroelectric Hirakud dam- 347.5
Disadvantages project to its completion and operation)
Odisha Megawatts
Need areas with sufficient supply of water Nagarjuna sagar 816 Megawatts
Floods in low lying area dam- Telangana
Emission of Green house gas Sardar Sarovar 1450 Megawatts
Sardar Sarovar dam in Gujarat is the largest dam - case study dam- Gujarat
(Narmada Bhacha Andolan!!!)
 OCEAN ENERGY
Indirect form of solar energy
Sources: Tide, Waves, and Ocean Thermal Energy Conversion (OTEC)

Wave Energy
Affected by/ Factor governing:
Wind speed
Fetch value (the uninterrupted
distance on the ocean over which
wind can below before reaching the
point of reference ): 5-45 km
Depth of seawater
Wave energy is more efficient than wind
energy, as waves are formed by the
concentration of wind energy
 TIDAL ENERGY
Energy is extracted from tides, which are
generated due to the gravitational effect
of the sun and moon on the Earth.
The height of the tide above and below
the tidal basin result in the movement
of the turbine
Need a suitable bay area to store water
and release it during low tide. The bay
area is defined by tidal range.

https://www.offshore-energy.biz/tidal-energy-
demonstration-a-worthwhile-endeavor/
ADVANTAGES AND DISADVANTAGES OF WAVE
ENERGY AND TIDE ENERGY
Advantages Advantage
More energy efficient than wind energy 1. No dependent on seasonal variation,
Do not require large landmass predictable
2. Low operational cost
Disadvantages
Capital and operational cost is high Disadvantages
1. Capital is high
Limited zone of capture.
2. Silting of the basin is common.
Potential to impact marine biodiversity 3. Efficiency depends on turbine and tidal
Highly variable. range.
 OCEAN THERMAL ENERGY CONVERSION
Makes use of the temperature difference
between the surface water of the ocean and the
depth of the ocean
Harnessed in tropical oceans ( 28 to 5 degrees C)
A difference of 20o C and more is required to run
the OTEC power plants
Principle:
The warm surface is used to vaporize the liquids
like ammonia to run a heat engine, and the deep
water is used to condense the vapors
The energy carrier, seawater, is free, although it
has an access cost associated with the pumping
materials and pumps energy costs
 FACTORS TO BE CONSIDERED WHILE
CHOOSING A OTEC SITE mariculture - branch of aquaculture that
deals with the cultivation of marine
organisms in enclosed sections of the sea to
Advantages farm seafood among other requirements.
Thermal gradient in the ocean
Produces desalinated water
Topography of the ocean floor Provides air-conditioning for buildings
Meteorological conditions – Provides moderate-temperature refrigeration
hurricanes Especially beneficial for small islands
Seismic activity Promotes mariculture
Floating OTEC can provide power to offshore mining
Local electricity and
desalinated water demand. and processing
Limitations:
Cost and availability of Low-grade solar energy with poor energy recovery
shoreline sites
efficiency
first Indian OTEC plant will be in the Lakshadweep
Islands. Floating plants – navigational hazard
Chlorine used for preventing biofouling – hazardous
Mixing of warm and cold seawater affects dissolved
oxygen
NOT sustainable for the flora and fauna of the marine environments
 BIOMASS ENERGY
Biomass refers to solid carbonaceous material developed from
plants and animals. Examples of biomass include wood, leaves,
animal waste, crops, and bones.
Biomass energy is the utilization of energy stored in organic
matter.
Considered carbon-neutral energy source
Biomass is stored solar energy.
Biomass energy is extracted as:
By direct burning of dry plants
By fermentation: Ethanol, exclusively from corn.
Petro crops: Euphorbias and oil palms are rich in
hydrocarbons
Agri. & urban waste biomass: Crop residue, bagasse,
fermentation is neither completely
coconut shells, peanut hulls, cotton stalks, animal waste, aerobic nor anaerobic it is in
fishery, and poultry waste used as charcoal, briquetting between.
(3500 kcal/ kg)
 BIOMASS POWER CONVERSION
1. Convert biomass into heat and electricity
Process similar to fossil fuel: Biomass is burnt to heat a boiler. The steam is directed
towards the turbine. The charged magnetic field produced a current
2. Other conversion techniques
1. Densification: bulky biomass is reduced to volume-to-weight ratio by compression at
controlled temperature and pressure
2. Combustion
3. Thermochemical conversion: Pyrolysis, Gasification
4. Biochemical Conversion: Anaerobic digestion and Ethanol fermentation
cleanest city in India - Indore (it houses the largest bio CNG or CBG plant in Asia
 THERMOCHEMICAL CONVERSION
PYROLYSIS (anaerobic process) GASIFICATION (aerobic process)

Thermal decomposition without oxygen Chemical and thermal conversion of
Temperature range 300 and 850°C. carbon-based materials into a primarily
Solid: a char-like substance (10–35 MJ/kg) gaseous output air, oxygen, or steam.
and 20–50%, Temperature range from 800 to 1100°C
: Ash (10–50%). when air as an oxidant,
Liquid: a complex mixture of hydrocarbons 1500°C when using oxygen.
(5–15 MJ/kg) and 30–50%. Solid: Ashes 30–50% of the input weight.
Gas: a mixture of CO, CH4, CO2, H2, and Liquid: Oil or tar, 10–20%
other volatile waste constituents. Gas: Higher CO2 fractions (3–12 MJ/Nm3), 30
The heating value and gas yield may be to 60%
around 3–12 MJ/Nm3 and 20–50%,
respectively.
 BIOCHEMICAL CONVERSION
Anaerobic Digestion
Process through which bacteria break down
organic matter in the absence of free
oxygen.
Primary objective – Energy Production.
Major drawback- Sensitive process and need
of proper maintenance.
Biogas: Methane (CH4) and carbon dioxide
(CO2), hydrogen sulfide (H2S), moisture
Calorific value 5000 to 5500 kCal/ kg
Factor affecting: Solid-to-water ratio,
Temperature, Seeding, pH, Carbon to nitrogen
ratio (30:1), Stirring

Ethanol Fermentation
Decomposition of biomass containing
sugar like sugarcane, potato, etc Schematic of Anaerobic Digestor Source: Internet
BIOCHEMICAL CONVERSION

( separate hydrolysis and
fermentation)

Simultaneous Saccharification and Fermentation.

Schematic of Anaerobic Digestor Source: Internet
 BIOGAS
Purified biogas is compressed to create Bio-
CBG, a high-energy-density fuel.

Bio-CNG or CBG has several benefits:

- Renewable and sustainable energy source
- Reduces greenhouse gas emissions
- Can replace fossil fuels in vehicles and
industrial applications
- Supports waste management and reduction

Largest Bio-CNG or CBG plant in Asia of Bio-CBG can be used as a:
550 TPD capacity (Asia’s largest - Transportation fuel (vehicles)
Gobardhan (BioCNG) plant on Zero-waste - Industrial fuel (power generation, heating)
discharge model). Madhya Pradesh- - Replacement for LPG and CNG
Indore- Clean city
GOBAR GAS PLANT

biofuels:

first level - preparing with
food crops

second level- non-food
sources eg waste,wood.

third level- Algae and
genetically modified
organisms
 BIO-FUELS
Liquid fuel recovered from agricultural and forest crops and residue through fermentation route

TYPES OF BIOFUELS GENERATIONS
Primary: used in unprocessed form First: conventional biofuels made from sugar or
such as fuel wood, chips, etc. starch. Food crop is used directly
Secondary: Material resulting from Second: produced from non-food crops such as
processing of Biomass waste, woods
Third: made from engineered crops such as
algae
Fourth: produced from hydroprocessing
Biodiesel
Produced from non-edible oil such as Jatrops, Karanja. Raw oil was subjected to
transesterification.
Biodegrabale, produce less CO2, and less SO2 emissions., Neat fuel, Higher flash point
the likeliness of a fuel catching fire at lower temperatures
 URBAN PROBLEM RELATED TO ENERGY
Now 50%population lives in Urban areas
Urban sprawl: Uncontrollable and unplanned growth
Densely populated, consume more resources, NEED MORE ENERGY

Energy demanding activities
Residential and Commercial lighting- Malls, offices, hotels.
Private and Public transport: EV vehicles
Modern lifestyle: electronic gadgets.
Industries
Waste disposal, Prevention and Control of pollution

Consequence
Unequal distribution of energy
Power cuts and load–shedding
Economics