Ultimate analysis.ppt
1,320 views
24 slides
Feb 28, 2023
Slide 1 of 24
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
About This Presentation
engineering
Slide Content
CHEMICAL
PROPERTIES
PROPERTIES
Elemental Analysis
Determination of various elemental chemical constituents such
as Carbon, Hydrogen, Oxygen, Sulphur, etc.
Elemental analysis is very useful
For determining the quantity of air required for
combustion
•For determining the volume and
composition of combustion gases
For calculation of flame temperature and flue
duct design
The ultimate analysis is determined
in a properly equipped laboratory by
a skilled chemist,
On the basis of proximate analysis
we can calculate ultimate analysis
by Gothal`s formula.
H.Cv = 147.6 C + aV
where,
C = % of carbon, V = % of volatile matter, a
is constant depends on the % of V.
% of V 1-4 10 15 20 25 30 35 40
Value of a 270 261 210.6 196.2 185.4 171 157.5 144
Determination of various elemental chemical constituents such
as Carbon, Hydrogen, Oxygen, Sulphur, etc.
Elemental analysis is very useful
For determining the quantity of air required for
combustion
•For determining the volume and
composition of combustion gases
For calculation of flame temperature and flue
duct design
The ultimate analysis is determined
in a properly equipped laboratory by
a skilled chemist,
On the basis of proximate analysis
we can calculate ultimate analysis
by Gothal`s formula.
H.Cv = 147.6 C + aV
where,
C = % of carbon, V = % of volatile matter, a
is constant depends on the % of V.
% of V 1-4 10 15 20 25 30 35 40
Value of a 270 261 210.6 196.2 185.4 171 157.5 144
Elemental Analysis
Relationship between Ultimate Analysis and Proximate Analysis
Note: The above equation is valid for coal containing greater than 15%
Moisture content.
Relationship between Ultimate Analysis and Proximate Analysis
Note: The above equation is valid for coal containing greater than 15%
Moisture content.
Carbon & Hydrogen
Carbon and hydrogen are determined by burning of the
sample in a stream of pure oxygen in combustion
apparatus.
Coal + O2 =H2O + CO2
Carbon and hydrogen present in a sample converted into
H2O & CO2 and they are absorbed by separate absorbing
tubes and tubes are weighted before and after absorption.
Methods to determine the Elemental Analysis
Carbon and hydrogen are determined by burning of the
sample in a stream of pure oxygen in combustion
apparatus.
Coal + O2 =H2O + CO2
Carbon and hydrogen present in a sample converted into
H2O & CO2 and they are absorbed by separate absorbing
tubes and tubes are weighted before and after absorption.
Methods to determine the Elemental Analysis
KOH and CaCl
2absorb CO
2and H2O respectively
Increase in weight of the tubes are noted
2absorb CO
2and H2O respectively
Increase in weight of the tubes are noted
Methods to determine the Elemental Analysis
Nitrogen
Nitrogen estimation is done by Kjeldahl’s method.
A known amount of powdered coal is heated with con.
H2SO4 and K2SO4in a long necked flask (called Kjeldahl’s
flask), there by converting nitrogen of coal to ammonium
sulphate.
Thus the nitrogen present in the coal is converted into
common salts, those salts are further distilled with acid
NaOH
Therefore the percentage of nitrogen is calculated from
the coal.
Nitrogen
Nitrogen estimation is done by Kjeldahl’s method.
A known amount of powdered coal is heated with con.
H2SO4 and K2SO4in a long necked flask (called Kjeldahl’s
flask), there by converting nitrogen of coal to ammonium
sulphate.
Thus the nitrogen present in the coal is converted into
common salts, those salts are further distilled with acid
NaOH
Therefore the percentage of nitrogen is calculated from
the coal.
Sulfur
Sulfur is determined by bomb washing obtained from the
combustion of a known mass of coal in bomb calorimeter.
Oxygen
Determined as follow
% of O = 100-C-H-N-S-ash
Ash
Ash is determined as by proximate analysis.
Methods to determine the Elemental Analysis
Sulfur is determined by bomb washing obtained from the
combustion of a known mass of coal in bomb calorimeter.
Oxygen
Determined as follow
% of O = 100-C-H-N-S-ash
Ash
Ash is determined as by proximate analysis.
Methods to determine the Elemental Analysis
SIGNIFICANCE OF
ELEMENTAL ANALYSIS
ELEMENTAL ANALYSIS
Significance of Ultimate Analysis
Carbon and hydrogen
Higher the % of carbon and hydrogen,
better the quality of coal and higher is
its calorific value
The % of carbon is helpful in the
classification of coal
Higher the % of carbon in coal reduces
the size of combustion chamber
required.
Nitrogen
Nitrogen does not have any calorific
value, and its presence in coal is
undesirable.
Good quality coal should have very little
nitrogen content
Hydrogen is volatile matter and affect
adversely
Carbon and hydrogen
Higher the % of carbon and hydrogen,
better the quality of coal and higher is
its calorific value
The % of carbon is helpful in the
classification of coal
Higher the % of carbon in coal reduces
the size of combustion chamber
required.
Nitrogen
Nitrogen does not have any calorific
value, and its presence in coal is
undesirable.
Good quality coal should have very little
nitrogen content
Hydrogen is volatile matter and affect
adversely
Sulphur
Affects clinkering and slagging
tendencies
Corrodes chimney and other equipment
such as air heaters and economizers
Limits exit flue gas temperature
Oxygen
Lower is the oxygen content better is
the coal
Significance of Ultimate Analysis
The combustion products of sulphur, i.e,
SO2 and SO3 are harmful for the
environment
Oxygen content increases the volatile
matter and is associated with moisture,
low heating value and low coking power
Affects clinkering and slagging
tendencies
Corrodes chimney and other equipment
such as air heaters and economizers
Limits exit flue gas temperature
Oxygen
Lower is the oxygen content better is
the coal
Significance of Ultimate Analysis
The combustion products of sulphur, i.e,
SO2 and SO3 are harmful for the
environment
Oxygen content increases the volatile
matter and is associated with moisture,
low heating value and low coking power
CARBONIZATION OF COAL………
METALLURGICAL COKE
When Coal is heated in the
absence of oxygen the
process is known as
carbonization
Solid (e.g. coke), Liquid form
(e.g. fuel oil) and Gas (e.g.
coal gas, mixture of CH4, H2,
CO, CO2
Bituminous coal is used for
carbonization
Carbonization of coal is the most important use of coal to produce coke mostly
for metallurgical purposes
When bituminous coal is heated strongly in
absence of air, the volatile matter escapes out
and a lustrous, dense, strong, porous and
coherent mass is left, which is called
metallurgical coke.
The most important industrial use of
coke is in the metallurgical industry,
especially in the blast furnace
METALLURGICAL COKE
When Coal is heated in the
absence of oxygen the
process is known as
carbonization
Solid (e.g. coke), Liquid form
(e.g. fuel oil) and Gas (e.g.
coal gas, mixture of CH4, H2,
CO, CO2
Bituminous coal is used for
carbonization
Carbonization of coal is the most important use of coal to produce coke mostly
for metallurgical purposes
When bituminous coal is heated strongly in
absence of air, the volatile matter escapes out
and a lustrous, dense, strong, porous and
coherent mass is left, which is called
metallurgical coke.
The most important industrial use of
coke is in the metallurgical industry,
especially in the blast furnace
METALLURGICAL COKE
When bituminous coal is heated strongly in the absence of air,
the volatile matter escapes out and the mass becomes hard,
porous and coherent which is called Metallurgical coke
There are three types of Carbonization
1.Low temperature carbonization
2.Medium temperature carbonization
3.High temperature carbonization
When bituminous coal is heated strongly in the absence of air,
the volatile matter escapes out and the mass becomes hard,
porous and coherent which is called Metallurgical coke
There are three types of Carbonization
1.Low temperature carbonization
2.Medium temperature carbonization
3.High temperature carbonization
LOW TEMPERATURE CARBONIZATION
500-700ºC
For manufacture of domestic fuel.
Low quality coke of about 75-80 yield is produced.
Coke produced contains 5-15% volatile matters. It is easily ignitable
valuable smokeless domestic fuel.
Not suitable for metallurgical purpose.
The gas produced as a by product is richer than high temperature
carbonization having calorific value of 6300 to 9300 Kcal/m3.
Its yield is about 150-330m3/ton of coal carbonized.
This process may be done with coking and non-coking coals.
When coke is too friable to use, it may be briquetted or pulverized.
A problem associated is poor transmission of heat through the coal
charge which may be overcome by modern techniques and methods.
500-700ºC
For manufacture of domestic fuel.
Low quality coke of about 75-80 yield is produced.
Coke produced contains 5-15% volatile matters. It is easily ignitable
valuable smokeless domestic fuel.
Not suitable for metallurgical purpose.
The gas produced as a by product is richer than high temperature
carbonization having calorific value of 6300 to 9300 Kcal/m3.
Its yield is about 150-330m3/ton of coal carbonized.
This process may be done with coking and non-coking coals.
When coke is too friable to use, it may be briquetted or pulverized.
A problem associated is poor transmission of heat through the coal
charge which may be overcome by modern techniques and methods.
MEDIUM TEMPERATURE CARBONIZATION
700-900ºC
Gas yield is lower.
Amount of NH3 produced is same as in high temperature carbonization.
Yield of tar is more and its properties are different from High temperature
carbonization.
Yield of light oils and phenols (particularly cresol) are more and these light
oils contains more paraffinic and di-olefenic hydrocarbons.
It is used to gain more byproduct
700-900ºC
Gas yield is lower.
Amount of NH3 produced is same as in high temperature carbonization.
Yield of tar is more and its properties are different from High temperature
carbonization.
Yield of light oils and phenols (particularly cresol) are more and these light
oils contains more paraffinic and di-olefenic hydrocarbons.
It is used to gain more byproduct
MEDIUM TEMPERATURE CARBONIZATION
900-1200ºC
Used for production of pure, hard, strong and porous
metallurgical coke.
The yield of coke is 65-75%, volatile matters 1-3%,
The byproduct is about 370 to 480 m3/ton but its calorific value
is lower (5000 to 6000 Kcal/m3).
Process is used to produce town gas and gas coke at the gas
works of cities.
900-1200ºC
Used for production of pure, hard, strong and porous
metallurgical coke.
The yield of coke is 65-75%, volatile matters 1-3%,
The byproduct is about 370 to 480 m3/ton but its calorific value
is lower (5000 to 6000 Kcal/m3).
Process is used to produce town gas and gas coke at the gas
works of cities.
PREPARATION (OTTOHOFFMAN’S
METHOD)
(i)To increases the
thermal efficiency of
the carbonization
process and,
(ii)(ii) To recover the
valuable by products
(like coal gas,
ammonia, benzyl oil,
etc).
METHOD)
(i)To increases the
thermal efficiency of
the carbonization
process and,
(ii)(ii) To recover the
valuable by products
(like coal gas,
ammonia, benzyl oil,
etc).
PREPARATION (OTTOHOFFMAN’S
METHOD)
The oven consists of a number of
silica chambers , each chamber is
provided with a charging hole at
the top, it is also provided with a
gas off take valve and iron door at
each end for discharging coke.
Coal is introduced into the silica
chamber and the chambers are
closed.
The chambers are heated to
1200
o
C by burning the preheated
air and the producer gas mixture in
the interspaces between the
chambers.
METHOD)
The oven consists of a number of
silica chambers , each chamber is
provided with a charging hole at
the top, it is also provided with a
gas off take valve and iron door at
each end for discharging coke.
Coal is introduced into the silica
chamber and the chambers are
closed.
The chambers are heated to
1200
o
C by burning the preheated
air and the producer gas mixture in
the interspaces between the
chambers.
PREPARATION (OTTOHOFFMAN’S
METHOD)
The air and gas are preheated by
sending them through 2
nd
and
3
rd
hot regenerator.
Hot flue gases produced during
carbonization are allowed to pass
through 1
st
and 4
th
regenerators
until the temperature has been
raised to 1000ċ.
While 1
st
and 4
th
regenerated are
heated by hot flue gases, the
2
nd
and 3
rd
regenerators are used
for heating the incoming air and
gas mixture.
METHOD)
The air and gas are preheated by
sending them through 2
nd
and
3
rd
hot regenerator.
Hot flue gases produced during
carbonization are allowed to pass
through 1
st
and 4
th
regenerators
until the temperature has been
raised to 1000ċ.
While 1
st
and 4
th
regenerated are
heated by hot flue gases, the
2
nd
and 3
rd
regenerators are used
for heating the incoming air and
gas mixture.
PREPARATION (OTTOHOFFMAN’S
METHOD)
When the process is complete, the
coke is removed and quenched
with water.
The yield of coke is about 70%.
The valuable by products like coal
gas, tar, ammonia, H
2S and benzyl,
etc. can be recovered from flue gas.
METHOD)
When the process is complete, the
coke is removed and quenched
with water.
The yield of coke is about 70%.
The valuable by products like coal
gas, tar, ammonia, H
2S and benzyl,
etc. can be recovered from flue gas.
RECOVERY OF BY-PRODUCTS
(i) Tar\
The flue gases are first passed
through a tower in whichliquor
ammonia (flocculant) is sprayed.
Tar and dust get dissolved and
collected in a tank below
(ii) Ammonia
The gases are then passed through
another tower in whichwateris
sprayed. Here ammonia gets
converted to NH
4OH.
(iii) Naphthalene
The gases are again passed
through a tower, in whichcooled
wateris sprayed, naphthalene gets
condensed.
(i) Tar\
The flue gases are first passed
through a tower in whichliquor
ammonia (flocculant) is sprayed.
Tar and dust get dissolved and
collected in a tank below
(ii) Ammonia
The gases are then passed through
another tower in whichwateris
sprayed. Here ammonia gets
converted to NH
4OH.
(iii) Naphthalene
The gases are again passed
through a tower, in whichcooled
wateris sprayed, naphthalene gets
condensed.
RECOVERY OF BY-PRODUCTS
(iv) Benzene
The gases are passed through
another tower, wherepetroleumis
sprayed, benzene gets condensed
to liquid.
(v) Hydrogen Sulphide
The remaining gases are then
passed through a purifier packed
with moist Fe
2O
3. Here H
2S is
retained.
The final gas left out is calledcoal
gaswhich is used as a gaseous fuel.
(iv) Benzene
The gases are passed through
another tower, wherepetroleumis
sprayed, benzene gets condensed
to liquid.
(v) Hydrogen Sulphide
The remaining gases are then
passed through a purifier packed
with moist Fe
2O
3. Here H
2S is
retained.
The final gas left out is calledcoal
gaswhich is used as a gaseous fuel.
ADVANTAGES OF OTTO HOFFMAN’S
PROCESS
Valuable by products like ammonia, coal gas, Naphthalene etc.
are recovered.
The carbonization time is less.
Heating is done externally by producer gas.
PROCESS
Valuable by products like ammonia, coal gas, Naphthalene etc.
are recovered.
The carbonization time is less.
Heating is done externally by producer gas.
REQUISITE FOR METALLURGICAL COKE
1
•High purity. i.e. moisture (<4%), ash
(<6%), Sulphur (<0.5%), Phosphorous
(<0.1%)
2
•Porosity. High porosity is desirable in
furnace cokes to obtain high rates of
combustion.
3
•Strength. The Coke should be enough
strong and hard
4
•Size. The coke should have uniformity
in size
Calorific value5
•Coke should have higher calorific value
Combustibility6
•It should burn easily
Reactivity7
•It refers to its ability to react with O2,
CO2, steam and air. The metallurgical
coke must have low reactivity
8Cost
Should be cheap and readily available
1
•High purity. i.e. moisture (<4%), ash
(<6%), Sulphur (<0.5%), Phosphorous
(<0.1%)
2
•Porosity. High porosity is desirable in
furnace cokes to obtain high rates of
combustion.
3
•Strength. The Coke should be enough
strong and hard
4
•Size. The coke should have uniformity
in size
Calorific value5
•Coke should have higher calorific value
Combustibility6
•It should burn easily
Reactivity7
•It refers to its ability to react with O2,
CO2, steam and air. The metallurgical
coke must have low reactivity
8Cost
Should be cheap and readily available
Why is coke superior as a metallurgical fuel
Coke is stronger and more porous than coal
Coke contains lesser amount of sulphur than coal
Coke does not contain much volatile matter
Higher heating value than coal
Coke is a better fuel because coke produces more heat on
burning as compared to coal
Coke is stronger and more porous than coal
Coke contains lesser amount of sulphur than coal
Coke does not contain much volatile matter
Higher heating value than coal
Coke is a better fuel because coke produces more heat on
burning as compared to coal
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 1,320
- Slides 24
- Age 1011 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
35 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
32 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
29 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
30 views