Title: ENERGY CONVERSION
1- ENERGY CONVERSION
- MME 9617A
- Eric Savory
- www.eng.uwo.ca/people/esavory/mme9617a.htm
- Lecture 4 Fuels
- Department of Mechanical and Material Engineering
- University of Western Ontario
2Aim To examine the different fuel sources These
include Fossil fuels - Coal - Fuel oil -
Natural gas - Bitumen Synthetic fuel
3Fossil fuels
- Four main types Coal, fuel oil, natural gas and
bitumen - Fossil Fuels are hydrocarbons, formed from the
remains of dead plants and animals. Fossil fuel
is a general term for buried combustible
geological deposits of organic materials, formed
from decayed plants and animals that have been
converted to crude oil, coal, natural gas or
heavy oils by exposure to heat and pressure in
the earth's crust over hundreds of millions of
years. - The chemical compound is Cx(H20)y, which is
produced by plants through photosynthesis where
solar energy is converted to chemical energy. - Most of the fossil fuels were produced in the
Carboniferous Period of the Paleozoic Era 299 -
359 million years ago. - The fuel formulation is CnH2n2.
4Fossil fuels
- Coal - it is composed primarily of carbon along
with assorted other elements, including sulphur. - Fuel oil - it is made of long hydrocarbon chains,
particularly alkanes, cycloalkanes and aromatics.
- Natural gas - consisting primarily of methane
(CH4) but including significant quantities of
ethane (C2H6), propane (C3H8), butane (C4H10),
carbon dioxide, nitrogen, helium and hydrogen
sulphide. It is found in oil fields, natural gas
fields and in coal beds.
5Fossil fuels
Bitumen it is a mixture of organic liquids that
are highly viscous, black, sticky, entirely
soluble in carbon disulphide (CS2), and composed
primarily of highly condensed polycyclic aromatic
hydrocarbons (PAHs). Bitumen is primarily used
for paving roads. Its other uses are for general
waterproofing products, including the its use in
the production of roofing felt. Oil shale - is a
general term applied to a group of rocks rich
enough in organic material (called kerogen) to
yield petroleum upon distillation.
6Coal
- Coal is formed from plant remains that have been
compacted, hardened, chemically altered, and
metamorphosed by heat and pressure over
geological time. - Coal was formed in swamp ecosystems which
persisted in lowland sedimentary basins. These
swamp environments were formed during slow
subsidence of passive continental margins, and
most seem to have formed adjacent to estuarine
and marine sediments. - When plants die in these peat swamp environments,
their biomass is deposited in anaerobic aquatic
environments where low oxygen levels prevent
their complete decay by bacteria and oxidation.
7Burial by sedimentary loading on top of the peat
swamp converts organic matter to coal by -
Compaction, due to loading of the sediments on
the coal which flattens the organic matter -
Removal of water held within the peat in between
the plant fragments - Ongoing compaction ?
removal of water from the inter-cellular
structure of fossilized plants - Heat and
compaction ? removal of water - Methanogenesis
similar to treating wood in a pressure cooker,
methane is produced, which removes hydrogen and
some carbon, and some further oxygen (as water)
- Dehydrogenation, which removes hydroxyl groups
(OH) from the cellulose and other plant
molecules, resulting in the production of
hydrogen-reduced coals Generally, to form a coal
seam 1m thick, some 10 - 30m of peat is required.
Peat has a moisture content of up to 90.
8Coal formation
9Coal mining
- The most economical method of coal extraction
from coal seams depends on the depth and quality
of the seams, and also the geology and
environmental factors of the area being mined. - Surface and mountain top mining
- If the coal seams are near the surface, the coal
is extracted by strip mining. Strip mining
exposes the coal by the advancement of an open
pit or strip. - Mountain top removal is a form of surface mining
that takes place at the topmost portion of a
mountain. Utilized for the past 30 years,
mountain top mining involves removing the highest
part of the mountain for the maximum recovery of
coal. - Underground mining
- Most coal seams are too deep underground for open
cast mining and thus this type of mining is
called underground mining. In deep mining, the
room and pillar method progresses along the
Mammoth coal vein seam, while pillars and timber
are left standing to support the coal mine roof.
10Petroleum (oil, gas)
- Petroleum forms from the remains of plants and
animals that lived in the ocean 10-160 million
years ago. - When organisms died and sank to the bottom, they
were covered in mud, sand, and other mineral
deposits. This rapid burial prevented immediate
decay, which would normally occur if the
organisms remained exposed on the sea floor. - The lack of oxygen in the sedimentary layers
caused organisms to slowly decay into carbon-rich
compounds. These compounds mixed with surrounding
sediments and formed source rock, which is a type
of fine-grained shale. - As more layers were deposited on top of one
another, pressure and heat acting on the source
rock compressed the organic material into crude
oil.
11Petroleum finding oil
- Discovering the location of oil within the earth
is difficult because of the presence of cap rock,
which can be miles thick in some locations. Oil
geologists study surface rocks and the terrain to
determine if any oil is present underground, but
the best evidence comes from various satellite
imaging techniques. - Oil flows may disrupt the earth's gravitational
or magnetic field and so gravity meters and
magnetometers can detect some oil sources. - The most reliable method for finding oil is
through the use of shock waves in a process
called seismology. In a seismological survey a
shock wave is aimed at the surface of the water
or land and the length of time it takes for the
waves to reflect back to the sensor is recorded.
The speed of the shock wave depends on the type
of rock it travels through, and by comparing the
travel times to known densities of rock,
seismologists can determine what rocks are
underground and predict if they might contain
oil.
12Petroleum production
- The most common method of obtaining petroleum is
extracting it from oil wells found in oil fields.
- Primary recovery methods are used to extract oil
that is brought to the surface by underground
pressure and can generally recover about 20 of
the oil present. - After the oil pressure has depleted to the point
that the oil is no longer brought to the surface,
secondary recovery methods draw another 5 to 10
of the oil in the well to the surface. - Finally, when secondary oil recovery methods are
no longer viable, tertiary recovery methods
reduce the viscosity of the oil in order to bring
more to the surface.
13Crude oilrefinement fractional distillation
14Oil shale fine grained sedimentary rock
containing kerogen
- The kerogen in oil shale can be converted to oil
by the chemical process of pyrolysis, during
which the oil shale is heated to 445 - 500C in
the absence of air (pyrolysis) and the kerogen
is converted to oil and separated out, a process
called "retorting". - Oil shale has been burnt directly as a low-grade
fuel. - It was estimated that in earths crust there are
6.5x1015 Tons of oil shale, about 1,000 times
more than coal. - The US Energy Information Administration
estimates the world supply of oil shale at 2.6
trillion barrels of recoverable oil, 1.0-1.2
trillion barrels of which are in the US. However,
attempts to develop these reserves have been
going on for over 100 years with limited success. - The caloric value of oil shale is 100 times
smaller than coal.
15Crude oil production from oil shale
16Energy overview
17(No Transcript)
18Crude oil and natural gas field counts,
cumulative production, proven reserves, and
ultimate recovery
19US Coal Demonstrated Reserve Base (as at 1
January 2005)
Energy Information Administration / Annual Energy
Review 2005
20US Uranium Reserves and Resources
Energy Information Administration / Annual Energy
Review 2005
21World Primary Energy Production by Region and
Country
Energy Information Administration/ Annual Energy
Review 2005
22World Crude Oil and Natural Gas Reserves (as at 1
Jan 2005)
DOE-EIA /Annual Energy Review 2005
23World Crude Oil Production
DOE-EIA / Annual Energy Review 2005
24World Natural Gas Plant Liquid Production
DOE-EIA / Annual Energy Review 2005
25Retail Motor Gasoline Prices in Selected
Countries, 2005
DOE-EIA/ Annual Energy Review 2005
26World Petroleum Consumption
DOE-EIA / Annual Energy Review 2005
27World Dry Natural Gas Consumption
DOE-EIA / Annual Energy Review 2005
28 29Introduction
- Synthetic fuel or synfuel is any liquid fuel
obtained from coal, natural gas, or biomass. It
can sometimes refer to fuels derived from other
solids such as oil shale, tar sand, waste
plastics, or from the fermentation of biomatter.
It can also refer to gaseous fuels produced in a
similar way. - The process of producing synfuels is often
referred to as Coal-To-Liquids (CTL),
Gas-To-Liquids (GTL) or Biomass-To-Liquids (BTL),
depending on the initial feedstock.
30Motivation
- Synthetic fuels require a relatively high price
of crude oil in order to be competitive with
petroleum-based fuels without subsidies. However,
they offer the potential to supplement or replace
petroleum-based fuels if oil prices continue to
rise. Several factors make synthetic fuels
attractive relative to competing technologies
such as biofuels, ethanol / methanol or hydrogen - The raw material (coal) is available in
quantities sufficient to meet current demand for
centuries - It can produce gasoline, diesel or kerosene
directly without the need for additional steps
such as reforming or cracking - There is no need to convert vehicle engines to
use a different fuel - There is no need to build a new distribution
network
31Substitute Natural Gas (SNG)
- Infrastructure of gas supply near coal mining.
- The obtained gas is often Methane CH4 which has
a caloric value of 1,000 Btu/scf. - Gasification is a process that converts
carbonaceous materials, such as coal, petroleum,
or biomass, into carbon monoxide and hydrogen. - Produces High Btu Gas (1,000) Low Btu Gas
(500). - The gas tends to be cheaper than coal.
- The gas production technology is simple.
32Gasification processes using coal
- 1. COAL H2 ? CH4 C (heat)
- 2. COAL 2H2 ? CH4 (heat)
- 3. COAL H2O ? CO H2 (-heat)
- 4. 4C O2 ? CO2 heat
- 5. 2C O2 ? 2CO2 heat
H20
O2 (AIR)
33Upgrading
- CH4, CO, H2 Raw Gas (500 Btu/scf)
- CO2, H2S, NH3 Residual
- 1. CO H2O ? CO2 H2
- 2. CO2 H2, H2S Acid gases removal
- 3. CO 3H2 ? CH4 H2O Catalytic methanation
- Pipe line gas 1000 Btu/scf
34Technological parameters
- Type of coal being used
- Preparation
- Feeding technique to the reactor
- Reactor type
- Fixed bed
- Fluidized bed
- Entrained flow
- Heat supply - external / internal
- Temperature and pressure
35Fischer-Tropsch process
- Oil gasification is a catalyzed chemical reaction
in which carbon monoxide and hydrogen are
converted into liquid hydrocarbons of various
forms. Typical catalysts used are based on iron
and cobalt. The principal purpose of this process
is to produce a synthetic petroleum substitute
for use as synthetic lubrication oil or as
synthetic fuel.
36- In-direct method
- Following the gasification process, by using H2
and CO, these reactions can occur - (2m1)H2 mCO ? CmH2m2 mH2O
- (n1)H2 2mCO ? CmH2m2 nCO2
- CmH2m2 is fuel ? C8H18
- Direct method
- Coal dissolving and by adding H2 (at temp. of
5000C) - nC (n1)H2 ? CnH2n2
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38Contamination
- CO unburned fuel
- Hydrocarbons unburned fuel
- NOx, N2OS, NO2 reaction at high temp.
- SO2 after oxidation, once in contact with water
turns to H2SO4 - More information on these processes can be found
at SASOL Technology - www.sasol.com