Boilers

Boilers (Steam Generators)

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 Definition of a boiler  A boiler is a device used to generate steam at a desired pressure and temperature by transferring heat energy   produced by burning fuel to water to change it to steam.

It is a combination of apparatus used for    producing, furnishing or recovering heat together with the apparatus for  transferring the heat so made available to the fluid being heated and vaporized.

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 Definition of a boiler  A boiler is a device used to generate steam at a desired pressure and temperature by transferring heat energy   produced by burning fuel to water to change it to steam.

It is a combination of apparatus used for    producing, furnishing or recovering heat together with the apparatus for  transferring the heat so made available to the fluid being heated and vaporized.

Function of a boiler  •

The fluid is contained in the boiler  drum called  shell  and the thermal energy released during combustion of fuel is transferred to water and this converts water into steam at the desired temperature and pressure.

 Applications of boilers  

Power generation: Mechanical or electrical power  may be generated by expanding steam in the steam engine or steam turbine.

 Heating:

The steam can be used for heating residential and industrial buildings in cold weather  and for producing hot waters for hot water supply.

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Industrial processes: Steam can also be used for  industrial processes such as for sizing and bleaching etc. in textile industries and other applications like sugar mills, cement, agricultural and chemical industries.

Factors to be considered   for selection of good boiler  1) The working pressure and quality of steam required 2) Steam generation rate 3) Floor area available 4) Accessibility for repair and inspection 5) Comparative initial cost 6) Erection facilities 7) The portable load factor  8) The fuel and water available 9) Operating and maintenance costs

 Requirements of an efficient boiler  1.

The boiler should generate maximum amount of steam at a required pressure and temperature and quality with minimum fuel consumption and expenses

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Steam production rate should be as per requirements

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It should be absolutely reliable

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It should be light in weight

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It should not occupy large space.

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It should be capable of quick starting

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It should conform to safety regulations.

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The boiler components should be transportable without difficulty

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The installation of the boiler should be simple

10. It should have low initial cost, installation cost and maintenance cost. 11. It should be able to cope with fluctuating demands of steam supply. 12. All parts and components should be easily accessible for inspection, repair and replacement. 13. The tubes of the boiler should not accumulate soot or water deposits and should be sufficiently strong to allow for wear and corrosion 14. The water and gas circuits should be such as to allow minimum fluid velocity (for 

 Relative

Classification of boilers

position of hot gases and water  •Fire tube boilers (Cochran, Lancashire, Cornish, Locomotive) •Water tube boilers (Babcock and Wilcox boiler, Stirling boiler) Method of firing  •Internally fired boilers ( Lancashire, Locomotive) •Externally fired boilers (Babcock and Wilcox boiler)  Pressure of steam •High pressure boilers(>80 bars-Cochran,Lancashire,Cornish, Locomotive) •Low pressure boilers (<=80 bars-Babcock and Wilcox boiler, Lamont  boiler) Method of circulation of water  •  Natural circulation boilers (Lancashire, Locomotive, Babcock & Wilcox  boilers) •Forced circulation boilers (Two large fire tubes Lancashire boiler, Single large fire tube Cornish boiler, Cochran boiler, Many small tubes Locomotive  boiler, Babcock Wilcox water tube boiler)  Nature of service to be performed  •Land boilers •Portable boilers

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Once through boilers  Position and number of drums • Single drum boilers • Multi-drum boilers(Longitudinal or crosswise)  Design of gas passages • Single pass boilers • Return pass boilers • Multi-pass boilers  Nature of draught  • Natural draught boilers • Artificial draught boilers  Heat source • Combustion of solid, liquid or gaseous fuels • Electrical and nuclear energy • Hot waste gases of other chemical reactions  Fluid used  • Steam boilers • Mercury boilers • Special boilers for heating special chemicals Material of construction of boiler shell  • Cast iron boilers

 Differences between Water-tube and Fire-tube boilers Particulars

Fire tube boiler

Water tube boiler

Hot gases inside the tubes andWater inside the tube an osition of  hot gases outside the tubes water and hot  water outside the tube ases

ode of firing  Operating  ressure ate of steam consumption Suitability for  large power  lants

Generally internally fired Externally fired Operating pressure limited toCan work under as hig 16 bar   pressures as 100 bar  Lower Higher   Not suitable

Involves isk on bursting/explos explosion  pressure ion

loor area

lesser due

For a given power, occupies more

Suitable

risk onInvolves more risk to lower    bursting due to  pressure For a given power, occupies less

o high

 Differences between Water-tube and Fire-tube boilers Contd….. Particulars

Construction Transportation Shell diameter  Chances of  explosion Treatment of water  ccessibility of  various parts

Fire tube boiler

Water tube boiler

Difficult Difficult Large for same power Less

Simple Simple Small for same power  More

Not so necessary Various parts are not so easily accessible for  cleaning, repair and inspection

More necessary Various parts are more accessible

equirement of skill Require less skill for  efficient and economic working

Require more skill and careful attention

COCHRAN BOILER  Features of Cochran boiler: 1)Vertical 2)Multi-tubular  3)Internally fired 4)Natural circulation 5)Fire tube boiler  6)Up to maximum steam pressure of 15 bar  7)Maximum evaporative capacity of 4000 kg of steam per hour.

Construction of COCHRAN BOILER  Cochran boiler  consists of a vertical cylindrical shell, fitted with a hemispherical crown at its top which form the steam space, and a hemispherical dome which forms the furnace of fire box. A platform over which the fuel burns called fire gate is provided in the furnace. Beneath the grate there is a space, called ash pit to facilitate the collection of ashes. The fuel is charged through the fire door provided at the front end of the furnace. The combustion chamber at the rear end in the middle portion of the boiler  is lined with the fire bricks which prevents the overheating of the combustion chamber plate. The furnace and the combustion chamber are interconnected by the elliptical flue tube. The unburnt volatile matter leaving the furnace along with the hot gases are burnt in the combustion chamber.   Number of flue tubes connects the combustion chamber and the smoke box fitted at the front end. The chimney provided above the smoke box serves for  the escape of gases. The man hole provided at the crown of the boiler facilitates the inspection

Working of COCHRAN BOILER  The Cochran boiler  is filled with water to the specified level and maintained at that level by charging with makeup water using a feed water pump and when the water level drops below its specified level. The entire surface of the furnace except the openings for the fire door and the combustion chamber will be surrounded by water. The flue tubes will also be completely submerged in the water. The hot gases from the furnace along with the unburnt volatile matter pass to the combustion chamber through the elliptical flue tube where the unburnt volatile matter burns completely. From the combustion chamber they pass through the horizontal flue tubes to the smoke box. The gases from the smoke  box escape to the atmosphere through the chimney. The hot gases while passing through the flue tubes transfer their heat to the water which is also heated by the furnace directly, gets converted into steam and accumulates in the steam space. The steam stop valve allows the steam from the boiler to the steam supply pipe. The Cochran boiler is mounted with the essential mountings and accessories like steam stop valve, safety valve, pressure gauge, water level indicator, fusible plug, blow off valve, feed check valve. The working pressure and steam

 Advantages & Disadvantages of  COCHRAN BOILER  Advantages 1)Cochran Boiler occupies less floor space. 2)Construction cost of Cochran Boiler is Low. 3)Cochran boiler is semi-portable and hence easy to install and transport. 4)Because of self contained furnace no brick work setting is necessary. Disadvantages 1)The capacity of the Cochran boiler is less because of the vertical design. 2)Cochran Boiler requires high head room space. 3)Because of the vertical design, it often presents difficulty in cleaning and inspection.

 BABCOCK & WILCOX BOILER  Features of  Babcock & Wilcox boiler: 1)Horizontal, Straight & Stationary 2)Externally fired 3)Natural circulation 4)Water tube boiler  5)Minimum steam pressure of 10 bar  6)Minimum evaporative capacity of 7000 kg of steam per hour.

Construction of  BABCOCK & WILCOX BOILER  Babcock and Wilcox boiler is a horizontal, externally fired, natural circulation, stationary, and water tube   boiler. The Babcock and Wilcox water tube boiler consists mainly four parts such as water and steam drum, water tubes, chain grate stoker, superheater tubes. The water and steam drum is suspended from iron girders resting on the iron columns, and is independent of the brick work setting. This arrangement prevents unequal expansion troubles and facilitates repair of the  brick work. A number of inclined water tubes at a very low inclination are connected at right angles to the end   boxes called headers. The water tubes will be arranged in a number of vertical rows, each row consisting of  40 to 5 tubes. In each vertical row the tubes will be arranged one below the other in a serpentine form. There will be a number of such vertical rows one behind the other. Each one such vertical row of inclined water  tubes are connected to one set of two headers. The header at the right end of the water tubes is called down take header and the other at the left end of the water tubes is called uptake header. Each of the vertical rows of  water tubes which are arranged one behind the other are connected to one set of headers which are also arranged one behind the other. Each set of the headers are inturn connected to the boiler drum by one set of  two tubes, on eat the uptake end and the other at the downtake end. A mud box is provided just below the downtake header. Any sediment in the water, due to its heavier specific gravity will settle down in the mud  box and is blown off from time to time through the blow off pipe. The grate is provided at the front end below the uptake header. The boilers of higher capacity are usually   provided with a chain grate stoker, which consists of a slowly moving endless chain of grate bars. The coal fed on at the front end of the grate is burnt on the moving grate in the furnace and the residual ash falls at the outer end of the grate into the ash pit. The boiler is fitted with a superheater. The superheater consists of  number of U-tubes secured at each end to the horizontal connecting boxes and placed in the combustion chamber below the boiler drum. The upper box of the superheater tube is connected to a T-tube, the upper   branches of the T-tube being situated in the steam space in the drum. The lower box of the superheater tubes is connected to the steam stop valve mounted over the drum through a vertical tube passing outside the drum.

Working of  BABCOCK & WILCOX BOILER  The water is introduced into the boiler drum through a feed valve. A constant water level is maintained in the boiler drum. The water descends at the rear end into the downtake headers and   passes up in the inclined water tubes, uptake headers and in the tubes connecting the uptake header and the drum. Thus a circuit is established between the drum and the water tubes for the flow of water. The hot gases from the furnace grate are compelled by the baffle plate to pass upwards around the water tubes lying in between the combustion chamber under the water drum, then downwards around the water tubes in between the baffle plates, then once again upwards between the baffle   plate and the downtake header, and finally passes out of the boiler through the exit door and the chimney. During this path of the hot gases, the hottest gases emerging directly from the grate come in contact with the hottest portions of the water tubes. The water in these portions of the water tubes gets evaporated. The water and the steam mixture from this portion of the water tubes ascend through the uptake headers and reach the boiler drum. The steam from the steam space in the boiler drum is led into the branches of T-tube, and then it passes into the upper connecting box of the superheater, then through its U-tubes. Since the superheater tubes are fitted in the combustion chamber and exposed to the hot gases, the steam  passing in it will be superheated. The superheated steam from the superheater tubes are passed to the steam stop valve through the lower connecting box and the vertical tube fitted outside the drum. From the steam stop valve the superheated steam is passed to the prime-mover. When the superheated steam is not required the steam from the steam space directly passes out to the  prime-mover through the steam stop valve.

 BOILER MOUNTINGS  1) 2) 3) 4) 5) 6) 7) 8)

Pressure gauge Fusible plug  Steam stop valve Feed check valve Blow off cock  Man and mud(sight)holes Two safety valves Two water level Indicators

Man and mud(sight)holes

Two safety valves

The commonly used safety valves are: 1)Dead weight safety valve 2)Lever safety valve 3)Spring loaded safety valve 4)High steam and low water safety valve

 BOILER ACCESSORIES  1) 2) 3) 4) 5) 6)

Economiser  Air Preheater  Superheater  Feed Pump Steam Separator  Steam Trap