Session 01_Combustion Technologies for Bioenergy (2).pdf

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Session 01
Characterization of fuel
BST 31212-Combustion Technologies for Bioenergy
Bachelor of Biosystems Technology Honors (BBST Hons) Degree Programme
Faculty of Technology
Sabaragamuwa university of Srilanka

Prepared by: Eng.Prasad Amarasinghe
Module Outline
Content Lecture Time
1. Characterization of fuel 06 Hours
2. Combustion fundamentals 14 Hours
3. Boiler technology for 10 Hours
bioenergy
Assessment : Continuous Assessment……..40% Final Assessment………60%
Practical:
Performance evaluation through an energy audit for a biomass boiler plant (24 Hours)
Laboratory Sessions:
(i) Bomb Calorimeter - Measure energy content of biofuel (03 Hours)
(ii) Proximate Analyzer - Determine the moisture, ash, volatile matter and fixed carbon in coal and
coke (03 Hours)
References/Reading Materials
Rosendahl, L. ed., 2013. Biomass combustion science, technology and
engineering. Woodhead Publishing.
Quaak, P., Knoef, H. and Stassen, H.E., 1999. Energy from biomass: a
review of combustion and gasification technologies.
Murgai, M.P. and Chandra, R., 1990. Boiler operations (Vol. 1). New
Age International
Learning Outcomes
At the completion of this course student will be able to
Identify biofuel types and their combustion properties
Understand biomass combustion technologies and their applications
Apply combustion principles for bio-based thermal energy generation
Operate low pressure steam boilers, steam distribution, and their
maintenance activities
Evaluate the performance of biomass combustion technologies
Combustion
Combustion is the process of burning of a substance in the presence
of air or oxygen with the liberation of light and heat.
Calorific Value
Amount of heat release from the complete combustion of a unit
mass(or volume) of the fuel is known as calorific value.
Gross or Higher calorific value (G.C.V or H.C.V)
Total quantity of heat release when one unit of fuel is burnt completely and
product of combustion has been cooled to room temperature
Net or Lower calorific value (N.C.V or L.C.V)
Total quantity of heat release when one unit of fuel is burnt completely and
products of has been permitted to escape

N.C.V = G.C.V – Latent heat of water vapor formed
Estimation of Calorific value of fuel
The bomb calorimeter is the instrument that is used
for determining the calorific value of a fuel

The principle of all the calorimeters is the
transference of heat of combustion of the given
weight of fuel to water and the vessel.
From the observed rise of temperature of the water
and the container the calorific value of the fuel can
be determined by equating the heat given out by
the fuel to the heat taken by the water and the
container.
Estimation of Calorific value of fuel

Advantage of using this king of instrument to determined calorific value of fuel
Complete combustion happens inside the vessel due to high presser of oxygen supplied , excess
oxygen is available
All heat released from the combustion will be given to the surrounding water
The additional oxygen and very small amount of water in the bomb do not effect the combustion
The test procedure and the arrangement employed favor the accurate computation of temperature
loss correction (cooling correction).
Estimation of Calorific value of fuel
Calculations for Calorific Value of Fuel
Heat given away by the fuel = heat gained by water
Q1 = Q2
m1 * CV = m2 * specific heat of water * (T2-T1)
Heat = mc∆t
Total heat released = Total heat absorbed
Heat released by fuel + Heat released by fuse wire + Heat released by cotton thread = Total heat absorbed by
(Water + Bomb + Calorimeter)

(m𝑓×cv)fuel +(m×cv)fues wire+(m×cv)Thread = (total weight of water +water equivalent of calorimeter
)×CW×(Temperature difference)
(g×j/g)+(g×j/g)+(g×j/g) = g×j/(g×0c)×0c

Calorific value taken from the bomb calorimeter test is the gross/high calorific value of the fuel
Net/low calorific value of fuel can be taken as
NCV/LCV = GCV/HCV- Latent heat of water vapor formed
Estimation of Calorific value of fuel
This is the standard instrument use to measure calorific value
of gas
Hot gases produce by combustion pass up the copper
chimney. It is surrounded by double coil of metal tube.
Known weight of Cooling water is circulate through this tube.
After passing upwards the hot gas are deflected downwards
through the space containing the inner coil.
By the time the gases reach the top of this passage, practically
the whole of their heat has been absorbed by the circulating
water. The gases are then passed away into the atmosphere.
The cooling water enters the outer coil. After circulating
through both coils it leaves at the water collecting tank
Its temperature is measured at inlet and outlet by
thermometers
Any water formed by combustion is drained through the pipe
Estimation of Calorific value of fuel
Heat release from fuel (gas) = Volume of gas(V) ×High calorific
value(H.C.V)
Heat absorb by water = Mw×C×∆T
water condensed during the experiment=Mc
latent heat of steam= L
GCV/HCV = Mw×C×∆T /𝑉
NCV/LCV= GCV- Mc×L
Estimation of Calcific value of fuel
Calorific values of some fuels
Estimation of Calorific value of fuel
Different formulae are available
HHV (MJ/kg) based on contents of C, H, O, and N (wt%)

HHV (MJ/kg) based on fixed carbon (wt%)

HHV (MJ/kg) based on fixed carbon (wt%) and volatile matter (wt%)
Estimation of Calorific value of fuel
Exercise …..
Calculate the calorific value of below mentions compounds
1. Tea waste
2. Beech wood
3. Soft wood
Characteristics of ideal fuel
High calorific value
If it is good fuel, it will give us more heat per unit mass. that’s means it should
have a high calorific value
Burn without giving harmful gases
An ideal fuel does not pollute air on burning by giving out smoke or poisonous
gases
A good fuel can be burned easily so that it should have a proper
ignition temperature
The ignition temperature of ideal fuel should neither be too low nor too high. If
ignition temperature of the fuel is very low, then the fuel will catch fire too
easily and hence it will be very unsafe to use it. If the ignition temperature too
high, then it will be very difficult to light the fuel
Characteristics of ideal fuel
Good fuel should be easily available and cheap
Good fuel is not more expensive and it is available in everywhere
It should be easy to handle, safe to transport and convenient to store
Ideal fuel will not create safety risk during handling ,transporting one location
to another or during its storage.
Good fuel should not leave much ash behind after burning
An ideal fuel should have low percentage of non volatile materials which do not
burn. It may burn completely without leaving much ash
It should burn smoothly
Ideal fuel should have moderate rate of combustion, and burn at steady rate.
The fuel should not burn either too fast or too slow
Proximate and ultimate analysis of fuel
Proximate analysis
From proximate analysis it will give idea about the physical properties of the fuel and it
consist of the moisture content, ash content, volatile matter as well the fixed carbon.
Moisture content
Determination of moisture is carried out by placing a sample in an uncovered crucible
and it is placed in the oven kept at 108±2°C. Then the sample is cooled to room
temperature and weighed again. The loss in weight represents moisture.
(𝑔−𝑥)
%MC= ×100
𝑔
g is the Weight of sample, x is the Weight of dry matter
Ash Content
After removing moisture remaining sample is ignited until getting a constant weight
that is the Ash content of the sample
(𝑥)
%𝐴𝑠ℎ = ×100
𝑔
g is the weight of sample and x is the weight of ash
Proximate and ultimate analysis of fuel
Volatile Matter
Get sample of material is weighed, place in a crucible and heated in a furnace
at 925 ± 25°C. The sample is cooled and weighed. Loss of weight represents
moisture and volatile matter
(𝑥−𝑦)
%𝑉. 𝑀 = ×100
𝑔
g is the weight of sample, X is the Weight of dry matter and y is the Weight of
residue,
Fixed Carbon
Above mentioned test ,remaining residue is fixed carbon
%FC= 100 − (𝑉𝑀 + 𝐴𝑠ℎ + 𝑀𝐶)
Proximate and ultimate analysis of fuel
Proximate analysis of coal
Initially take air drayed coal sample = w1
It was taken in silica crucible, Then heated in an electric oven (105-110) 0c.
Residue weight =w2
The residue was ignited at (700-750) 0c until getting a constant weight =W3
Get another sample from this same coal sample = w4
it was heated in a silica crucible covered with a vented lid at a temperature
(925-950) oc
After cooling weight of residue was taken =w5
Proximate and ultimate analysis of fuel
(𝑤1−𝑤2)
% moisture in coal = ×100
𝑤1(𝑏𝑒𝑓𝑜𝑟𝑒 ℎ𝑒𝑎𝑡𝑖𝑛𝑔)
𝑊3
% of Ash in coal = ×100
𝑤1(𝑏𝑒𝑓𝑜𝑟𝑒 ℎ𝑒𝑎𝑡𝑖𝑛𝑔)

(w4-w5)= Weight of moisture + weight of volatile matters
(𝑤4−𝑤5)
% of VM in coal = ×100- %moisture
𝑤4
% of fixed carbon =100-(%Moisture +%volatile matter +%Ash)
Proximate and ultimate analysis of fuel
Exercise
Initially take air drayed coal sample its weight is 24kg and It was taken in
silica crucible, Then heated in an electric oven (105-110) 0c. remaining
residue weight was 16kg.Then residue was ignited at (700-750) 0c until
getting a constant weight 2kg
Get another sample from this same coal sample 15kg and it was heated in
a silica crucible covered with a vented lid at a temperature (925-950) 0c.
After cooling weight of residue was taken 6kg

(01.) Calculate percentage of %moisture ,%Ash, % VM and % Fixed carbon in
this sample.
Impact of Moisture, Volatile material ,Ash and
Fixed carbon for fuel
Moisture Content:
Moisture contain in coal must be transported, handled and stored and it
will replace combustible materials. It will decrease heat content per kg of
coals.
Moisture will increase heat loss due to evaporation and superheating of vapor
It will reduce binding property of fuel
Help to heat transfer by radiation
Ash Content:
Ash is an impurity that will not burn
Increase handling cost
Reduce handling and burning capacity
Affects combustion efficiency and boiler efficiency
Impact of Moisture, Volatile material ,Ash and
Fixed carbon for fuel
Volatile Matter
Volatile matters are the methane, hydrocarbons, hydrogen and carbon
monoxide, and incombustible gases like carbon dioxide and nitrogen found
in coal. Thus the volatile matter is an index of the gaseous fuels present
It will help to easier ignition of coal and increases flame length
Sets minimum limit on the furnace height and volume.
Influences secondary oil support
Fixed carbon:
Fixed carbon is the solid fuel left in the furnace after volatile matter is
distilled off. It consists mostly of carbon but also contains some hydrogen,
oxygen, sulphur and nitrogen not driven off with the gases.
Fixed carbon gives a rough estimate of heating value of coal.
Proximate and ultimate analysis of fuel

The heating value of a fuel directly decreases with moisture content.
If moisture content is more than 55wt% ,it is very difficult to maintain combustion.
The water content will increase residence time of a fuel in a furnace.
In wood pallet moisture content has reduced to below 10wt% then heating value is higher
than woodchips.
The torrefaction of wood is a relatively new process, in this process volatiles and moisture
are evaporated from the fuel.
This upgrades the wood fuel quality compared to palletization.
Fixed carbon composition of coal is higher than wood then it has high heating value
Proximate and ultimate analysis of fuel
The basic combustion route of a solid fuel
Proximate and ultimate analysis of fuel
Ultimate Analysis
From ultimate analysis it will give idea about the chemical properties of the
fuel and it consists of the carbon content, oxygen content, hydrogen content,
nitrogen content and Sulphur content.
Proximate and ultimate analysis of fuel
All types of biomass feedstock, contains a large fraction of oxygen
compared to coal.
Wood also has very little fuel- bound nitrogen and Sulphur
According to the biomass feedstock nitrogen and Sulphur contain will
varies.
The main elements of biomass are cellulose, hemicelluloses and
lignin.
Biomass also contains small amounts of lipids, proteins, simple sugars
and starch as well as inorganic constituents and moisture
Combustion efficiency
Combustion efficiency is defined as the heat release by the fuel to the
heat input by the fuel.
Combustion efficiency will vary with below mentioned points
Fuel type
Bed temperature
Gas velocity
Excess air levels
Combustion efficiency increase with volatile matter content of a fuel
and bed temperature
Ignition point of liquid biofuels
Ignition point is the minimum
temperature at which combustible
substance in the air will continue to
burn without addition external heat.
For high volatile matter contain fuels
generally ignition temperature is low.
Ignition temperature is not a unique
property of a fuel. It is depend on
several other factors (oxygen, partial
pressure, particle size, rate of heating)
flash point of liquid biofuels
Flash point is minimum temperature at which volatile combustible
substance will start to burn in the presence of external heat source.
This temperature is not directly depend on the temperature of the ignition
source. Ignition source temperature is higher than the flash point.
Flammable liquid has a vapor pressure, with an increasing temperature
vapor pressure increases. Flammable liquid requires a certain
concentration of vapor in the air to sustain the combustion.
By knowing flash point we can minimize explosion and fire risk , we can get
idea for storing and transportation.
To measure flash point we can use open cup or close cup method
flash point of liquid biofuels
Open cup method
In this test use a vessel, or container, that is exposed to the
outside air.
Material sample place inside the vessel then gradually raise
its temperature, and pass an ignition source over it
It will flashes and ignites at a certain temperature. That is
the flash point of that sample
The most common open cup method is the Cleveland open
cup (COC). Tag and Setaflash are other methods.
In this method vapors are free to escape into the
atmosphere
flash point of liquid biofuels
Closed cup method
In this test we use vessel that is sealed
off from the outside atmosphere.
Then heat both the vessel and sample
then introducing an ignition source into
a sealed container
here are four main closed cup flash
point testing methods: Pensky
Martens, Abel, Tag and Setaflash.