boiler operation costs

7/30/2019 Boiler Operation costs

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Boiler Operating Costs with

Natural Gas and #6 OilDr. Herbert Eckerlin

Center for Boiler Studies

Raleigh, NC

March 27, 2002


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Why Measure Parasitic Losses?

Cost comparison based on stack loss onlyignores parasitic losses and costs associatedwith oil-firing

Important to quantify thermal losses andparasitic losses to determine the truebottom line efficiency and steam cost

Bottom line efficiency helps in choosing themost economic fuel


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Fuel

Stack Loss

Tg

% O2

Fire Tube Boiler


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Effects of Excess Air on Flue

Gas Composition15

10

5

0

-50 0 50 100 150 200

Excess Air

CO

CO2

CO2

O2

C

O2,CO,or

O2(%)

Incomplete

Combustion

Excess Air (%)


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+

+

+

Typical Oil Firing SetTypical Oil Firing Set--upup


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+

+

+

Q Stack

Thermal Losses Common forThermal Losses Common for

Natural Gas and #6 OilNatural Gas and #6 Oilstack lossstack loss


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Thermal Losses Common for

Natural Gas and #6 Oil

Stack Loss Largest single loss

Depends on flue gas temperature, ambient air

temperature, excess air and type of fuel

To determine stack loss, measure all above

parameters


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+

+

Q Stack

Q CO

Q CH

Thermal Losses Common for NaturalThermal Losses Common for Natural

Gas and #6 OilGas and #6 OilCO and UnCO and Un--burnt CHburnt CH


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Thermal Losses Common for

Natural Gas and #6 Oil

CO and un-burnt CH Caused by incomplete combustion

Lack of air to support complete combustion

Poor mixing of fuel and air

Poor atomization of fuel oil


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+

+

Q Oil Storage Tank

Q Stack

Q CO

Q CH

Parasitic Losses for #6 OilParasitic Losses for #6 Oil

Tank HeatingTank Heating


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Parasitic Losses for #6 Oil

Oil Tank Heating Fuel oil is viscous and requires heating to

facilitate pumping

Generally heated to 140 F

Heat loss can be quite high for single wall un-

insulated oil storage tanks


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+

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Q Oil Heater

Q Oil Storage Tank

Q Stack

Q CO

Q CH

Q Oil Pumping


Pumping & PreheatingPumping & Preheating


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Oil Pumping Pumps are required to circulate oil from storagetank to the burner

Oil Preheating To ensure proper atomization, oil must be

heated 200 220 oF

Generally heated by steam or hot water

In some fire tube boiler application, steam/hotwater heating is augmented by electric heating


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+

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Q Oil Heater

Q Oil Storage Tank

Q Atom

Q Stack

Q CO

Q CH

Q Oil Pumping


AtomizationAtomization


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Oil Atomization For proper combustion, oil must be broken up

into small particles

Done by injecting steam or compressed air intosmall oil supply at the burner

Q St k


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+

+

+

Q Oil Heater

Q Oil Storage Tank

Q Atom

Q Stack

Q SootBlowers

Q CO

Q CH

Q Oil Pumping


Soot BlowingSoot Blowing


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Soot Blowing Soot is created by oil burning

Soot leaves deposits on boiler tubes

Reduces heat transfer to boiler fluid

Generally cleaned by steam or compressed air

Fire tube boiler generally do not use soot blowers

Soot removal must be done by punching the tubes whenstack temperature gets too high

Should be done at least quarterly to prevent high stacktemperature resulting in high stack loss

Boiler must be shut down when tubes are punched


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Flue Gas Temperature

Over Time

200

250

300

350

400

450

0 5 10 15 20 25 30

Days

D

egF

#6 Oil High Fire

Gas High Fire

Gas Low Fire

#6 Oil Low Fire

Q Stack


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+

+

Q Oil Heater

Q Oil Storage Tank

Q Atom

Q Stack

$ Water$ Chemical $ Preheating

$ Maintenance$ Fuel Oil Additives

$ Oil Inventory

$ Corrosion

Additional Makeup Water

Q SootBlowers

Q CO

Q CH

Q Oil Pumping

Parasitic Losses and Cost for #6 OilParasitic Losses and Cost for #6 Oil

Inventory, Additives, Maintenance etc.Inventory, Additives, Maintenance etc.


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Parasitic Losses and Cost

for #6 Oil Oil Storage Inventory

Storing oil on site ties up capital This investment yields no return

Oil Additives

Purposes Reduce sludge in oil storage tank

Improve combustion

Reduce soot deposits

reduce cold end corrosion


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Parasitic Losses and Cost for

#6 Oil

Corrosion and Maintenance Sulphur in oil causes cold end corrosion

Adds to maintenance costs

Reduces boiler life

Q Stack 12.4%

S f Th l d


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+

+

Q Oil Heater

0.35%

Q Oil Storage Tank8.40%

Q Atom0.93%

Stack 12.4%

Q SootBlowers

Q CO

Q CH

Q Oil Pumping

1.15%

220oF

Radiation 1.0%

$ Water$ Chemical $ Preheating

$ Maintenance3.41%

$ Fuel Oil Additives

$ Oil Inventory0.30%

$ Corrosion

Additional Makeup Water

140

o

F

Summary of Thermal andSummary of Thermal and

Parasitic LossesParasitic Losses


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Bottom Line Efficiency for

Oil Firing

100

Stack Loss 12.4

Radiation 1.0

Oil Pumping 1.15

Oil Atomization 0.93

Corrosion & Maintenance 3.41

Oil Inventory 0.3Oil Heating 0.35

Oil Tank Heating 8.4

Bottom Line Efficiency 72%


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Bottom Line Boiler Efficiency

Comparison

82.5 90

72

0

10

20

30

40

50

60

70

80

90

100

N.G. Standard

Boiler

N.G. High

Efficiency Boiler

#6 Fuel Oil


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Effect of Parasitic Losses on

Cost of Delivered Steam

$7.32

30.6

$/GJ

cents/litre

Cost of Delivered Steam(considering stack and parasitic losses)

$1.23

8.6

$/GJ

cents/litre

Incremental Cost Increase(due to parasitic losses)

$6.09$/GJCost of Delivered Steam

(considering stack and radiation losses)

22.0

$5.27

cents/litre

$/GJ

Average Fuel Cost


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Conclusions

On average, parasitic losses can add about 9cents per litre to #6 fuel oil price

Take into account all parasitic losses and

costs associated with #6 fuel oil firing while

comparing costs with natural gas

Keep boilers properly tuned for maximumefficiency

boiler operation costs

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