Newton's Three Laws of Motion

Newton's First Law of Motion:

I. Every object in a state of uniform motion tends to remain in that state of motion unless an external force is applied to it.

This we recognize as essentially Galileo's concept of inertia, and this is often termed simply the "Law of Inertia".

Newton's Second Law of Motion:

II. The relationship between an object's mass m, its acceleration a, and the applied force F is F = ma. Acceleration and force are vectors (as indicated by their symbols being displayed in slant bold font); in this law the direction of the force vector is the same as the direction of the acceleration vector.

This is the most powerful of Newton's three Laws, because it allows quantitative calculations of dynamics: how do velocities change when forces are applied. Notice the fundamental difference between Newton's 2nd Law and the dynamics of Aristotle: according to Newton, a force causes only a change in velocity (an acceleration); it does not maintain the velocity as Aristotle held.
This is sometimes summarized by saying that under Newton, F = ma, but under Aristotle F = mv, where v is the velocity. Thus, according to Aristotle there is only a velocity if there is a force, but according to Newton an object with a certain velocity maintains that velocity unless a force acts on it to cause an acceleration (that is, a change in the velocity). As we have noted earlier in conjunction with the discussion of Galileo, Aristotle's view seems to be more in accord with common sense, but that is because of a failure to appreciate the role played by frictional forces. Once account is taken of all forces acting in a given situation it is the dynamics of Galileo and Newton, not of Aristotle, that are found to be in accord with the observations.

Newton's Third Law of Motion:

III. For every action there is an equal and opposite reaction.

Archimedes' Principle or Law

Archimedes' Principle or Law

Archimedes' principle states that:

"If a solid body floats or is submerged in a liquid - the liquid exerts an upward thrust force - a buoyant force - on the body equal to the gravitational force on the liquid displaced by the body."

The buoyant force can be expressed as

F_B =  W

    = V γ

    = V ρ g     (1)

where

F_B = buoyant force acting on the submerged or floating body (N, lb_f)

W = weight of the displaced liquid (N, lb_f)

V = volume of the body below the surface of the liquid (m³, ft³)

γ   = specific weight of the fluid (weight per unit volume) (N/m³, lb_f/ft³)

ρ = density of the fluid (kg/m³, slugs/ft³)

g = acceleration of gravity (9.81 m/s², 32.174 ft/s²) 

Example - Density of a Body that floats in Water

A body that floats is 96% submerged in water with density 1000 kg/m³.

For a floating body the buoyant force equal the weight of the displaced water.

F_B =  W

or

V_b ρ_b g = V_w ρ_w g 

where

V_b = volume body (m³)

ρ_b = density body (kg/m³)

V_w = volume water (m³)

ρ_w  = density water (kg/m³)

The equation can be transformed to

ρ_b = V_w ρ_w / V_b 

Since 95% of the body is submerged

0.95 V_b = V_w 

and the density of the body can be calculated as

ρ_b = 0.95 V_b (1000 kg/m³) / V_b

    = 950 kg/m³

Example - Buoyant force acting on a Brick submerged in Water

A standard brick with actual size 3 5/8 x 2 1/4 x 8 (inches) is submerged in water with density 1.940 slugs/ft³. The volume of the brick can be calculated as

V_brick = (3 5/8 in) (2 1/4 in) (8 in)

         = 65.25 in³

The buoyant force acting on the brick is equal to the weight of the water displaced by the brick and can be calculated as

F_B =  ((65.25 in³) / (1728 in/ft³)) (1.940 slugs/ft³) (32.174 ft/s²)  

    = 2.36 lb_f

The weight or the gravity force acting on the brick - common red brick has specific gravity 1.75 - can be calculated to

W_B = (2.36 lb_f) 1.75

     = 4.12 lb_f

The resulting force acting on the brick can be calculated as

W_{(WB - FB)} = (4.12 lb_f) - (2.36 lb_f)

   = 1.76 lb_f

Calorific values

Calorific values

The calorific value of a fuel is the quantity of heat produced by its combustion - at constant pressure and under "normal" ("standard") conditions (i.e. to 0^oC and under a pressure of 1,013 mbar).

The combustion process generates water vapor and certain techniques may be used to recover the quantity of heat contained in this water vapor by condensing it.

• Higher Calorific Value (or Gross Calorific Value - GCV, or Higher Heating Value - HHV) -  the water of combustion is entirely condensed and that the heat contained in the water vapor is recovered
• Lower Calorific Value (or Net Calorific Value - NCV, or Lower Heating Value - LHV) - the products of combustion contains the water vapor and that the heat in the water vapor is not recovered

Fuel	Higher Calorific Value (Gross Calorific Value - GCV)		Lower Calorific Value (Net Calorific Value - NCV)
	kJ/kg	Btu/lb	kJ/kg
Acetone	29000
Alcohol 96%	30000
Anthracite	32500 - 34000	14000 - 14500
Bituminous coal	17000 - 23250	7300 - 10000
Butane	49510	20900	45750
Carbon	34080
Charcoal	29600	12800
Coal (Lignite - Anthrasite)	15000 - 27000	8000 - 14000
Coke	28000 - 31000	12000 - 13500
Diesel fuel	44800	19300	43400
Ethane	51900		47800
Ethanol	29700	12800
Ether	43000
Gasoline	47300	20400	44400
Glycerin	19000
Hydrogen	141790	61000	121000
Kerosene	46200		43000
Lignite	16300	7000
Methane	55530		50000
Methanol	23000
Oil, heavy fuel	43000
Oil, light distillate	48000
Oil, light fuel	44000
Oils vegetable	39000 - 48000
Paraffin	46000		41500
Peat	13800 - 20500	5500 - 8800
Pentane			45350
Petrol	48000
Petroleum	43000
Propane	50350		46350
Semi anthracite	26700 - 32500	11500 - 14000
Sulfur	9200
Tar	36000
Turpentine	44000
Wood (dry)	14400 - 17400	6200 - 7500
	kJ/m3	Btu/ft3
Acetylene	56000
Butane C4H10	133000	3200
Hydrogen	13000
Natural gas	43000	950 - 1150
Methane CH4	39820
Propane C3H8	101000	2550
Town gas	18000
	kJ/l	Btu/Imp gal
Gas oil	38000	164000
Heavy fuel oil	41200	177000
Kerosene	35000	154000

• 1 kJ/kg = 1 J/g = 0.4299 Btu/ lb_m = 0.23884 kcal/kg
• 1 Btu/lb_m = 2.326 kJ/kg = 0.55 kcal/kg
• 1 kcal/kg = 4.1868 kJ/kg = 1.8 Btu/lb_m
• 1 dm³ (Liter) = 10^-3 m³ = 0.03532 ft³ = 1.308x10^-3 yd³ = 0.220 Imp gal (UK) = 0.2642 Gallons (US)

Scavenging Methods

Since one engine cycle in a two-stroke engine is completed in one crankshaft rotation, gas exchange has to occur while the piston is near BDC. There are two important consequences of this:

1. Since gas exchange commences before and ends after BDC, a portion of the expansion and compression stroke is unusable.
2. Piston velocity is low during the entire gas exchange phase and is unable to provide a significant pumping effect on the cylinder charge. Hence, gas exchange can only occur when the intake pressure is sufficiently higher than the exhaust pressure to allow the incoming fresh charge to displace the burned gas in the time available. This process of simultaneously purging exhaust gas from the previous cycle and filling the cylinder with fresh charge for a new cycle is referred to as scavenging. To ensure adequate scavenging, two-stroke engines must be equipped with some form of intake air compression and the intake and exhaust ports and/or valves must be open simultaneously for a sufficient period of time.

Both valves in the cylinder head and ports in the cylinder liner are applied as gas exchange control elements. In the case of ports, the piston also assumes the function of a control slide.

Scavenging in two-stroke engines is performed mainly by one of three methods:

• Cross-scavenging
• Loop-scavenging
• Uniflow-scavenging

To Measure Indicated Power in Diesel Engine with Indicator Diagram

The burning of fuel in an engine cylinder (2 stroke or 4 stroke diesel engine) will result in the production of power at an output shaft, some of the power produced in the cylinder will be used to drive the rotating masses of the engine.

Typical indicator diagram for a 2 stroke engine is shown in figure below. This power card or pv diagram can be used to measure indicated power in diesel engines. The area within the diagram represents the work done within the cylinder in one cycle.

Measuring Indicated Power of Diesel Engine

The area can be measured by an instrument known as ‘Planimeter’ or by the use of the mid ordinates rule. [On modern engines this diagram can be continuously taken by employing two transducers, one pressure transducer in the combustion space and other transducer on the shaft. Through the computer we can thus get on line indicated diagram and power of all cylinders.]

The area is then divided by the length of the diagram in order to obtain mean height. This mean height, when multiplied by the spring scale of the indicator mechanism, gives the indicated mean effective pressures for the cylinder. The mean effective or average pressure [Pm] can now be used to determine the workdone in the cylinder. Following calculations can be made to the area of indicator diagram to measure indicated power.

Calculations

Area of the indicator diagram = a [mm2]

Average height of the diagram = a [mm2] / l [mm]

Average mean indicator pressure = a [mm2] / l [mm] x k [bar / mm]

or Pm = ( a / l ) x k [bar]

where k = spring scale in bar per mm

Work done in one cycle = Mean Indicated Pressure x Area of the Piston x Length of stroke

= [Pm] x [A] x [L]

To obtain the power of this unit, it is necessary to determine the rate at which work is done,

i.e. multiply work by number of power strokes in one second.

Now, Indicated Power of Unit [ip] =

Mean Indicated Pressure [Pm] x Area of Piston [A] x Length of Stroke [L] x Number of Power Strokes per Second [N]

or

Indicated Power of Unit = Pm L A N

Unit of Final Result

Indicated Power = Pm L A N

= ( a / l ) x k [bar] x L [m] x A [m2] x N [1/s]

= [bar] x [m] x [m2] x [1/s]

= 105 N/m2 x m x m2 x 1/s

= 105 Nm/s

= 105 Joules/s

= 105 Watts

Hence, multiply the result obtained from calculating indicated power with 105 and the final unit will be in Watts

Air Compressor

It was common for shops to have a central power source that drove all the tools through a system of belts, wheels and driveshafts. The power was routed around the work space by mechanical means. While the belts and shafts may be gone, many shops still use a mechanical system to move power around the shop. It's based on the energy stored in air that's under pressure, and the heart of the system is the air compressor.

You'll find air compressors used in a wide range of situations—from corner gas stations to major manufacturing plants. And, more and more, air compressors are finding their way into home workshops, basements and garages. Models sized to handle every job, from inflating pool toys to powering tools such as nail guns, sanders, drills, impact wrenches, staplers and spray guns are now available through local home centers, tool dealers and mail-order catalogs.

The big advantage of air power is that each tool doesn't need its own bulky motor. Instead, a single motor on the compressor converts the electrical energy into kinetic energy. This makes for light, compact, easy-to-handle tools that run quietly and have fewer parts that wear out.

Air compressor types

While there are compressors that use rotating impellers to generate air pressure, positive-displacement compressors are more common and include the models used by homeowners, woodworkers, mechanics and contractors. Here, air pressure is increased by reducing the size of the space that contains the air. Most of the compressors you'll run across do this job with a reciprocating piston.

Like a small internal combustion engine, a conventional piston compressor has a crankshaft, a connecting rod and piston, a cylinder and a valve head. The crankshaft is driven by either an electric motor or a gas engine. While there are small models that are comprised of just the pump and motor, most compressors have an air tank to hold a quantity of air within a preset pressure range. The compressed air in the tank drives the air tools, and the motor cycles on and off to automatically maintain pressure in the tank.

At the top of the cylinder, you'll find a valve head that holds the inlet and discharge valves. Both are simply thin metal flaps–one mounted underneath and one mounted on top of the valve plate. As the piston moves down, a vacuum is created above it. This allows outside air at atmospheric pressure to push open the inlet valve and fill the area above the piston. As the piston moves up, the air above it compresses, holds the inlet valve shut and pushes the discharge valve open. The air moves from the discharge port to the tank. With each stroke, more air enters the tank and the pressure rises.

Typical compressors come in 1- or 2-cylinder versions to suit the requirements of the tools they power. On the homeowner/contractor level, most of the 2-cylinder models operate just like single-cylinder versions, except that there are two strokes per revolution instead of one. Some commercial 2-cylinder compressors are 2-stage compressors–one piston pumps air into a second cylinder that further increases pressure.

Compressors use a pressure switch to stop the motor when tank pressure reaches a preset limit–about 125 psi for many single-stage models. Most of the time, though, you don't need that much pressure. Therefore, the air line will include a regulator that you set to match the pressure requirements of the tool you're using. A gauge before the regulator monitors tank pressure and a gauge after the regulator monitors air-line pressure. In addition, the tank has a safety valve that opens if the pressure switch malfunctions. The pressure switch may also incorporate an unloader valve that reduces tank pressure when the compressor is turned off.

Many articulated-piston compressors are oil lubricated. That is, they have an oil bath that splash-lubricates the bearings and cylinder walls as the crank rotates. The pistons have rings that help keep the compressed air on top of the piston and keep the lubricating oil away from the air. Rings, though, are not completely effective, so some oil will enter the compressed air in aerosol form.

Having oil in the air isn't necessarily a problem. Many air tools require oiling, and inline oilers are often added to increase a uniform supply to the tool. On the down side, these models require regular oil checks, periodic oil changes and they must be operated on a level surface. Most of all, there are some tools and situations that require oilfree air. Spray painting with oil in the airstream will cause finish problems. And many new woodworking air tools such as nailers and sanders are designed to be oilfree so there's no chance of fouling wood surfaces with oil. While solutions to the airborne oil problem include using an oil separator or filter in the air line, a better idea is to use an oilfree compressor that uses permanently lubricated bearings in place of the oil bath.

A variation on the automotive-type piston compressor is a model that uses a one-piece piston/connecting rod. Because there is no wrist pin, the piston leans from side to side as the eccentric journal on the shaft moves it up and down. A seal around the piston maintains contact with the cylinder walls and prevents air leakage.

Where air requirements are modest, a diaphragm compressor can be effective. In this design, a membrane between the piston and the compression chamber seals off the air and prevents leakage.

Compressor power
One of the factors used to designate compressor power is motor horsepower. However, this isn't the best indicator. You really need to know the amount of air the compressor can deliver at a specific pressure.

The rate at which a compressor can deliver a volume of air is noted in cubic feet per minute (cfm). Because atmospheric pressure plays a role in how fast air moves into the cylinder, cfm will vary with atmospheric pressure. It also varies with the temperature and humidity of the air. To set an even playing field, makers calculate standard cubic feet per minute (scfm) as cfm at sea level with 68 degrees F air at 36% relative humidity. Scfm ratings are given at a specific pressure–3.0 scfm at 90 psi, for example. If you reduce pressure, scfm goes up, and vice versa.

You also may run across a rating called displacement cfm. This figure is the product of cylinder displacement and motor rpm. In comparison with scfm, it provides an index of compressor pump efficiency.

The cfm and psi ratings are important because they indicate the tools that a particular compressor can drive. When choosing a compressor, make sure it can supply the amount of air and the pressure that your tools need.

Thermal Power Plant

At present 54.09% or 93918.38 MW (Data Source CEA, as on 31/03/2011) of total electricity production in India is from Coal Based Thermal Power Station. A coal based thermal power plant converts the chemical energy of the coal into electrical energy. This is achieved by raising the steam in the boilers, expanding it through the turbine and coupling the turbines to the generators which converts mechanical energy into electrical energy.

Introductory overview

In a coal based power plant coal is transported from coal mines to the power plant by railway in wagons or in a merry-go-round system. Coal is unloaded from the wagons to a moving underground conveyor belt. This coal from the mines is of no uniform size. So it is taken to the Crusher house and crushed to a size of 20mm. From the crusher house the coal is either stored in dead storage( generally 40 days coal supply) which serves as coal supply in case of coal supply bottleneck or to the live storage(8 hours coal supply) in the raw coal bunker in the boiler house. Raw coal from the raw coal bunker is supplied to the Coal Mills by a Raw Coal Feeder. The Coal Mills or pulverizer pulverizes the coal to 200 mesh size. The powdered coal from the coal mills is carried to the boiler in coal pipes by high pressure hot air. The pulverized coal air mixture is burnt in the boiler in the combustion zone.
Generally in modern boilers tangential firing system is used i.e. the coal nozzles/ guns form tangent to a circle. The temperature in fire ball is of the order of 1300 deg.C. The boiler is a water tube boiler hanging from the top. Water is converted to steam in the boiler and steam is separated from water in the boiler Drum. The saturated steam from the boiler drum is taken to the Low Temperature Superheater, Platen Superheater and Final Superheater respectively for superheating. The superheated steam from the final superheater is taken to the High Pressure Steam Turbine (HPT). In the HPT the steam pressure is utilized to rotate the turbine and the resultant is rotational energy. From the HPT the out coming steam is taken to the Reheater in the boiler to increase its temperature as the steam becomes wet at the HPT outlet. After reheating this steam is taken to the Intermediate Pressure Turbine (IPT) and then to the Low Pressure Turbine (LPT). The outlet of the LPT is sent to the condenser for condensing back to water by a cooling water system. This condensed water is collected in the Hotwell and is again sent to the boiler in a closed cycle. The rotational energy imparted to the turbine by high pressure steam is converted to electrical energy in the Generator.

Diagram of a typical coal-fired thermal power station

Principal

Coal based thermal power plant works on the principal of Modified Rankine Cycle.

Components of Coal Fired Thermal Power Station:

• Coal Preparation

                        i)Fuel preparation system: In coal-fired power stations, the raw feed coal from the coal storage area is first crushed into small                         pieces and then conveyed to the coal feed hoppers at the boilers. The coal is next pulverized into a very fine powder, so that                               coal will undergo complete combustion during combustion process.

                                   ** pulverizer is a mechanical device for the grinding of many different types of materials. For example, they

                                         are used to pulverize coal for combustion in the steam-generating furnaces of fossil fuel power plants.

                                       

                                         Types of Pulverisers: Ball and Tube mills; Ring and Ball mills; MPS; Ball mill; Demolition.

                       ii)Dryers:  they are used in order to remove the excess moisture from coal mainly wetted during transport. As the                                                      presence of moisture will result in fall in efficiency due to incomplete combustion and also result in CO emission. 

                        iii)Magnetic separators: coal which is brought may contain iron particles. These iron particles may result in wear and tear. The iron particles may include bolts, nuts wire fish plates etc. so these are unwanted and so are removed with the help of                                          magnetic separators.

The coal we finally get after these above process are transferred to the storage site.
Purpose of fuel storage is two –

•  Fuel storage is insurance from failure of normal operating supplies to arrive.
• Storage permits some choice of the date of purchase, allowing the purchaser to take advantage of seasonal market conditions. Storage of coal is primarily a matter of protection against the coal strikes, failure of the transportation system & general coal shortages.

There are two types of storage:

1. Live Storage(boiler room storage): storage from which coal may be withdrawn to supply combustion equipment with little or no remanding is live storage. This storage consists of about 24 to 30 hrs. of coal requirements of the plant and is usually a covered storage in the plant near the boiler furnace. The live storage can be provided with bunkers & coal bins. Bunkers are enough capacity to store the requisite of coal. From bunkers coal is transferred to the boiler grates.
2. Dead storage- stored for future use. Mainly it is for longer period of time, and it is also mandatory to keep a backup of fuel for specified amount of days depending on the reputation of the company and its connectivity.There are many forms of storage some of which are –
   1. Stacking the coal in heaps over available open ground areas.
   2. As in (I). But placed under cover or alternatively in bunkers.
   3. Allocating special areas & surrounding these with high reinforced concerted retaking walls.

• Boiler and auxiliaries

A Boiler or steam generator essentially is a container into which water can be fed and steam can be taken out at desired pressure, temperature and flow. This calls for application of heat on the container. For that the boiler should have a facility to burn a fuel and release the heat. The functions of a boiler thus can be stated as:-

1. To convert chemical energy of the fuel into heat energy
2. To transfer this heat energy to water for evaporation as well to steam for superheating.

The basic components of Boiler are: -

1. Furnace and Burners
2. Steam and Superheating

a. Low temperature superheater

b. Platen superheater

c. Final superheater

• Economiser

It is located below the LPSH in the boiler and above pre heater. It is there to improve the efficiency of boiler by extracting heat from flue gases to heat water and send it to boiler drum.

Advantages of Economiser include

1) Fuel economy: – used to save fuel and increase overall efficiency of boiler plant.

2) Reducing size of boiler: – as the feed water is preheated in the economiser and enter boiler tube at elevated temperature. The heat transfer area required for evaporation reduced considerably.

• Air Preheater

The heat carried out with the flue gases coming out of economiser are further utilized for preheating the air before supplying to the combustion chamber. It is a necessary equipment for supply of hot air for drying the coal in pulverized fuel systems to facilitate grinding and satisfactory combustion of fuel in the furnace

•  Reheater

Power plant furnaces may have a reheater section containing tubes heated by hot flue gases outside the tubes. Exhaust steam from the high pressure turbine is rerouted to go inside the reheater tubes to pickup more energy to go drive intermediate or lower pressure turbines.

• Steam turbines

Steam turbines have been used predominantly as prime mover in all thermal power stations. The steam turbines are mainly divided into two groups: -

1. Impulse turbine
2. Impulse-reaction turbine

The turbine generator consists of a series of steam turbines interconnected to each other and a generator on a common shaft. There is a high pressure turbine at one end, followed by an intermediate pressure turbine, two low pressure turbines, and the generator. The steam at high temperature (536 ‘c to 540 ‘c) and pressure (140 to 170 kg/cm2) is expanded in the turbine.

• Condenser

The condenser condenses the steam from the exhaust of the turbine into liquid to allow it to be pumped. If the condenser can be made cooler, the pressure of the exhaust steam is reduced and efficiency of the cycle increases. The functions of a condenser are:-

1) To provide lowest economic heat rejection temperature for steam.

2) To convert exhaust steam to water for reserve thus saving on feed water requirement.

3)  To introduce make up water.

We normally use surface condenser although there is one direct contact condenser as well. In direct contact type exhaust steam is mixed with directly with D.M cooling water.

• Boiler feed pump

Boiler feed pump is a multi stage pump provided for pumping feed water to economiser. BFP is the biggest auxiliary equipment after Boiler and Turbine. It consumes about 4 to 5 % of total electricity generation.

• Cooling tower

The cooling tower is a semi-enclosed device for evaporative cooling of water by contact with air. The hot water coming out from the condenser is fed to the tower on the top and allowed to tickle in form of thin sheets or drops. The air flows from bottom of the tower or perpendicular to the direction of water flow and then exhausts to the atmosphere after effective cooling.

The cooling towers are of four types: -

1. Natural Draft cooling tower

2. Forced Draft cooling tower

3. Induced Draft cooling tower

4. Balanced Draft cooling tower

• Fan or draught system

In a boiler it is essential to supply a controlled amount of air to the furnace for effective combustion of fuel and to evacuate hot gases formed in the furnace through the various heat transfer area of the boiler. This can be done by using a chimney or mechanical device such as fans which acts as pump.

i) Natural draught 

When the required flow of air and flue gas through a boiler can be obtained by the stack (chimney) alone, the system is called natural draught. When the gas within the stack is hot, its specific weight will be less than the cool air outside; therefore the unit pressure at the base of stack resulting from weight of the column of hot gas within the stack will be less than the column of extreme cool air. The difference in the pressure will cause a flow of gas through opening in base of stack. Also the chimney is form of nozzle, so the pressure at top is very small and gases flow from high pressure to low pressure at the top.

ii) Mechanized draught

There are 3 types of mechanized draught systems

1)                  Forced draught system

2)                  Induced draught system

3)                  Balanced draught system

Forced draught: – In this system a fan called Forced draught fan is installed at the inlet of the boiler. This fan forces the atmospheric air through the boiler furnace and pushes out the hot gases from the furnace through superheater, reheater, economiser and air heater to stacks.

Induced draught: – Here a fan called ID fan is provided at the outlet of boiler, that is, just before the chimney. This fan sucks hot gases from the furnace through the superheaters, economiser, reheater and discharges gas into the chimney. This results in the furnace pressure lower than atmosphere and affects the flow of air from outside to the furnace.

Balanced draught:-In this system both FD fan and ID fan are provided. The FD fan is utilized to draw control quantity of air from atmosphere and force the same into furnace. The ID fan sucks the product of combustion from furnace and discharges into chimney. The point where draught is zero is called balancing point.

• Ash handling system

The disposal of ash from a large capacity power station is of same importance as ash is produced in large quantities. Ash handling is a major problem.

i) Manual handling: While barrows are used for this. The ash is collected directly through the ash outlet door from the boiler into the container from manually.

ii) Mechanical handling: Mechanical equipment is used for ash disposal, mainly bucket elevator, belt conveyer. Ash generated is 20% in the form of bottom ash and next 80% through flue gases, so called Fly ash and collected in ESP.

iii) Electrostatic precipitator: From air preheater this flue gases (mixed with ash) goes to ESP. The precipitator has plate banks (A-F) which are insulated from each other between which the flue gases are made to pass. The dust particles are ionized and attracted by charged electrodes. The electrodes are maintained at 60KV.Hammering is done to the plates so that fly ash comes down and collect at the bottom. The fly ash is dry form is used in cement manufacture.

• Generator

Generator or Alternator is the electrical end of a turbo-generator set. It is generally known as the piece of equipment that converts the mechanical energy of turbine into electricity. The generation of electricity is based on the principle of electromagnetic induction.

Advantages of coal based thermal Power Plant

• They can respond to rapidly changing loads without difficulty
• A portion of the steam generated can be used as a process steam in different industries
• Steam engines and turbines can work under 25 % of overload continuously
• Fuel used is cheaper
• Cheaper in production cost in comparison with that of diesel power stations

Disadvantages of coal based thermal Power Plant

• Maintenance and operating costs are high
• Long time required for erection and putting into  action
• A large quantity of water is required
• Great difficulty experienced in coal handling
• Presence of troubles due to smoke and heat in the plant
• Unavailability of good quality coal
• Maximum of  heat  energy lost
• Problem of ash removing

Major Thermal Power Plants in India

Power station	Operator	Location	District	State	Sector	Region	Unit wise Capacity	Installed Capacity (MW)
Rajghat Power Station	IPGCL	Delhi	Delhi	NCT Delhi	State	Northern	2 x 67.5	135.00
Deenbandhu Chhotu Ram Thermal Power Station	HPGCL	Yamunanagar	Yamunanagar	Haryana	State	Northern	2 x 300	600.00
Panipat Thermal Power Station I	HPGCL	Assan	Panipat	Haryana	State	Northern	4 x 110	440.00
Panipat Thermal Power Station II	HPGCL	Assan	Panipat	Haryana	State	Northern	2 x 210, 2 x 250	920.00
Faridabad Thermal Power Station	HPGCL	Faridabad	Faridabad	Haryana	State	Northern	1 x 55	55.00
Rajiv Gandhi Thermal Power Station	HPGCL	Khedar	Hisar	Haryana	State	Northern	1 x 600	600.00
Guru Nanak dev TP	PSPCL	Bathinda	Bathinda	Punjab	State	Northern	4 x 110	440.00
Guru Hargobind TP	PSPCL	Lehra Mohabbat	Bathinda	Punjab	State	Northern	2 x 210, 2 x 250	920.00
Guru Gobind Singh Super Thermal Power Plant	PSPCL	Ghanauli	Rupnagar	Punjab	State	Northern	6 x 210	1260.00
Suratgarh Super Thermal Power Plant	RVUNL	Suratgarh	Sri Ganganagar	Rajasthan	State	Northern	6 x 250	1500.00
Kota Super Thermal Power Plant	RVUNL	Kota	Kota	Rajasthan	State	Northern	2 x 110, 3 x 210, 2 x 195	1240.00
Giral Lignite Power Plant	RVUNL	Thumbli	Barmer	Rajasthan	State	Northern	2 x 125	250.00
Chhabra Thermal Power Plant	RVUNL	Mothipura	Baran	Rajasthan	State	Northern	2 x 250	500.00
Orba Thermal Power Station	UPRVUNL	Obra	Sonebhadra	Uttar Pradesh	State	Northern	1 x 40, 3 x 94, 5 x 200	1,322.00
Anpara Thermal Power Station	UPRVUNL	Anpara	Sonebhadra	Uttar Pradesh	State	Northern	3 x 210, 2 x 500	1630.00
Panki Thermal Power Station	UPRVUNL	Panki	Kanpur	Uttar Pradesh	State	Northern	2 x 105	210.00
Parichha Thermal Power Station	UPRVUNL	Parichha	Jhansi	Uttar Pradesh	State	Northern	2 x 110, 2 x 210	640.00
Harduaganj Thermal Power Station	UPRVUNL	Harduaganj	Aligarh	Uttar Pradesh	State	Northern	1 x 55, 1 x 60, 1 x 105	220.00
Badarpur Thermal power plant	NTPC	Badarpur	New Delhi	NCT Delhi	Central	Northern	3 x 95, 2 x 210	705.00
Singrauli Super Thermal Power Station	NTPC	Shaktinagar	Sonebhadra	Uttar Pradesh	Central	Northern	5 x 200, 2 x 500	2000.00
Barsingsar Lignite Power Plant	NLC	Barsingsar	Bikaner	Rajasthan	Central	Northern	1 x 125	125.00
Rihand Thermal Power Station	NTPC	Rihand Nagar	Sonebhadra	Uttar Pradesh	Central	Northern	4 x 500	2000.00
National Capital Thermal Power Plant	NTPC	Vidyutnagar	Gautam Budh Nagar	Uttar Pradesh	Central	Northern	4 x 210, 2 x 490	1820.00
Feroj Gandhi Unchahar Thermal Power Plant	NTPC	Unchahar	Raebareli	Uttar Pradesh	Central	Northern	5 x 210	1050.00
Tanda Thermal Power Plant	NTPC	Vidyutnagar	Ambedkar Nagar	Uttar Pradesh	Central	Northern	4 x 110	440.00
Raj west Lignite Power Plant	JSW	Barmer	Barmer	Rajasthan	Private	Northern	1 x 135	135.00
VS Lignite Power Plant	KSK	Gurha	Bikaner	Rajasthan	Private	Northern	1 x 125	125.00
Rosa Thermal Power Plant Stage I	Reliance	Rosa	Shahjahanpur	Uttar Pradesh	Private	Northern	2 x 300	600.00
Northern							28	104
Ukai Thermal Power Station	GSECL	Ukai dam	Tapi	Gujarat	State	Western	2 x 120, 2 x 200, 1 x 210	850
Gandhinagar Thermal Power Station	GSECL	Gandhinagar	Gandhinagar	Gujarat	State	Western	2 x 120, 3 x 210	870
Wanakbori Thermal Power Station	GSECL	Wanakbori	Kheda	Gujarat	State	Western	7 x 210	1470
Sikka Thermal Power Station	GSECL	Jamnagar	Jamnagar	Gujarat	State	Western	2 x 120	240
Dhuvaran Thermal Power Station	GSECL	Khambhat	Anand	Gujarat	State	Western	2 x 110	220
Kutch Thermal Power Station	GSECL	Panandhro	Kutch	Gujarat	State	Western	2 x 70, 2 x 75	290
Surat Thermal Power Station	GIPCL	Nani Naroli	Surat	Gujarat	State	Western	4 x 125	500
Akrimota Thermal Power Station	GMDC	Chher Nani	Kutch	Gujarat	State	Western	2 x 125	250
Satpura Thermal Power Station	MPPGCL	Sarni	Betul	Madhya Pradesh	State	Western	5 x 37.5, 1 x 200, 3 x 210	1017.5
Sanjay Gandhi Thermal Power Station	MPPGCL	Birsinghpur	Umaria	Madhya Pradesh	State	Western	4 x 210, 1 x 500	1340
Amarkantak Thermal Power Station	MPPGCL	Chachai	Anuppur	Madhya Pradesh	State	Western	2 x 120, 1 x 210	450
Korba East Thermal Power Plant	CSPGCL		Korba	Chattisgarh	State	Western	4 x 50, 2 x 120	440
Dr Shyama Prasad Mukharjee Thermal Power Plant	CSPGCL		Korba	Chattisgarh	State	Western	2 x 250	500
Korba West Hasdeo Thermal Power Plant	CSPGCL		Korba	Chattisgarh	State	Western	4 x 210	840
Koradi Thermal Power Station	MAHAGENCO	Koradi	Nagpur	Maharastra	State	Western	4 x 105, 1 x 200, 2 x 210	1040
Nashik Thermal Power Station	MAHAGENCO	Nashik	Nashik	Maharastra	State	Western	2 x 125, 3 x 210	880
Bhusawal Thermal Power Station	MAHAGENCO	Deepnagar	Jalgaon	Maharastra	State	Western	1 x 50, 2 x 210	470
Paras Thermal Power Station	MAHAGENCO	Vidyutnagar	Akola	Maharastra	State	Western	1 x 55, 2 x 250	555
Parli Thermal Power Station	MAHAGENCO	Parli-Vaijnath	Beed	Maharastra	State	Western	2 x 20, 3 x 210, 2 x 250	1170
Kaparkheda Thermal Power Station	MAHAGENCO	Kaparkheda	Nagpur	Maharastra	State	Western	4 x 210	840
Chandrapur Super Thermal Power Station	MAHAGENCO	Chandrapur	Chandrapur	Maharastra	State	Western	4 x 210, 3 x 500	2340
Vindhyachal Super Thermal Power Station	NTPC	Vidhya Nagar	Sidhi	Madhya Pradesh	Central	Western	6 x 210, 4 x 500	3260
Korba Super Thermal Power Plant	NTPC	Jamani Palli	Korba	Chattisgarh	Central	Western	3 x 200, 3 x 500	2100
Sipat Thermal Power Plant	NTPC	Sipat	Bilaspur	Chattisgarh	Central	Western	2 x 500	1000
Bhilai Expansion Power Plant	NTPC-SAIL(JV)	Bhilai	Durg	Chattisgarh	Central	Western	2 x 250	500
Sabarmati Thermal Power Station	Torrent	Ahamadabad		Gujarat	Private	Western	1 x 60, 1 x 120, 2 x 110	400
Mundra Thermal Power Station	Adani	Mundra	Kutch	Gujarat	Private	Western	2 x 330	660
Jindal Megha Power Plant	jindal	Tamnar	Raigarh	Chattisgarh	Private	Western	4 x 250	1000
Lanco Amarkantak Power Plant	Lanco	Pathadi	Korba	Chattisgarh	Private	Western	2 x 300	600
Trombay Thermal Power Station	Tata	Trombay	Mumbai	Maharastra	Private	Western	1 x 150, 2 x 500, 1 x 250	1400
Dahanu Thermal Power Station	Reliance	Dahanu	Thane	Maharastra	Private	Western	2 x 250	500
Wardha Warora Power Station	KSK	Warora	Chandrapur	Maharastra	Private	Western	1 x 135	135
Western							32	135
Ramagundam B Thermal Power Station	APGENCO	Ramagundam	Karimnagar	Andhra Pradesh	State	Southern	1 x 62.5	62.5
Kothagudem Thermal Power Station	APGENCO	Paloncha	Khammam	Andhra Pradesh	State	Southern	4 x 60, 4 x 120	720
Kothagudem Thermal Power Station V Stage	APGENCO	Paloncha	Khammam	Andhra Pradesh	State	Southern	2 x 250	500
Dr Narla Tatarao TPS	APGENCO	Ibrahimpatnam	Krishna	Andhra Pradesh	State	Southern	6 x 210, 1 x 500	1760
Rayalaseema Thermal Power Station	APGENCO	Cuddapah	YSR	Andhra Pradesh	State	Southern	4 x 210	840
Kakatiya Thermal Power Station	APGENCO	Chelpur	Warangal	Andhra Pradesh	State	Southern	1 x 500	500
Raichur Thermal Power Station	KPCL	Raichur	Raichur	Karnataka	State	Southern	7 x 210, 1 x 250	1720
Bellary Thermal Power Station	KPCL	Kudatini	Bellary	Karnataka	State	Southern	1 x 500	500
North Chennai Thermal Power Station	TNEB	Athipattu	Thiruvallore	Tamilnadu	State	Southern	3 x 210	630
Ennore Thermal Power Station	TNEB	Ennore	Chennai	Tamilnadu	State	Southern	2 x 60, 3 x 110	450
Mettur Thermal Power Station	TNEB	Metturdam	Salem	Tamilnadu	State	Southern	4 x 210	840
Tuticorin Thermal Power Station	TNEB	Tuticorin	Tuticorin	Tamilnadu	State	Southern	5 x 210	1050
NTPC Ramagundam	NTPC	Jyothi Nagar	Karimnagar	Andhra Pradesh	Central	Southern	3 x 200, 4 x 500	2600
Simhadri Super Thermal Power Plant	NTPC	Simhadri	Visakhapatnam	Andhra Pradesh	Central	Southern	2 x 500	1000
Neyveli Thermal Power Station – I	NLC	Neyveli	Cuddalore	Tamilnadu	Central	Southern	6 x 50, 3 x 100, 2 x 210	1020
Neyveli Thermal Power Station – II	NLC	Neyveli	Cuddalore	Tamilnadu	Central	Southern	7 x 210	1470
JSW EL-SBU-I Power Plant	JSW	Vijayanagar	Bellary	Karnataka	Private	Southern	2 x 130	260
JSW EL-SBU-II Power Plant	JSW	Vijayanagar	Bellary	Karnataka	Private	Southern	2 x 300	600
Udupi Thermal Power Plant	Lanco	Nandikoor	Udupi	Karnataka	Private	Southern	1 x 600	600
Neyveli Zero Unit	STPS	Neyveli	Cuddalore	Tamilnadu	Private	Southern	1 x 250	250
Southern							20	83
Barauni Thermal Power Station	BSEB	Barauni	Begusarai	Bihar	State	Eastern	2 x 50, 2 x 105	310
Muzafferpur Thermal Power Station	KBUCL	Kanti	Muzaffarpur	Bihar	State	Eastern	2 x 110	220
Patratu Thermal Power Station	JSEB	Patratu		Jharkhand	State	Eastern	4 x 40, 2 x 90, 2 x 105, 2 x 110	770
Tenughat Thermal Power Station	TVNL			Jharkhand	State	Eastern	2 x 210	420
Kolaghat Thermal Power Station	WBPDCL	Mecheda	East Midnapore	West Bengal	State	Eastern	6 x 210	1260
Bakreshwar Thermal Power Station	WBPDCL	Suri	Birbhum	West Bengal	State	Eastern	5 x 210	1050
Bandel Thermal Power Station	WBPDCL		Hooghly	West Bengal	State	Eastern	4 x 60, 1 x 210	450
Santaldih Thermal Power Station	WBPDCL		Purulia	West Bengal	State	Eastern	4 x 120, 1 x 250	730
Sagardigi Thermal Power Station	WBPDCL	Monigram	Murshidabad	West Bengal	State	Eastern	2 x 300	600
Durgapur Thermal Power Plant	DPL	Durgapur	Bardhaman	West Bengal	State	Eastern	2 x 30, 1 x 70, 2 x 75, 1 x 110, 1 x 300	690
IB Thermal Power Plant	OPGCL	Banharpali	Jharsuguda	Orissa	State	Eastern	8 x 120	960
Captive Power Plant	NALCO	Angul	Angul	Orissa	State	Eastern	2 x 210	420
Kahalgaon Super Thermal Power Station	NTPC	Kahalgaon	Bhagalpur	Bihar	Central	Eastern	4 x 210, 3 x 500	2340
Bokaro Thermal Power Station B	DVC	Bokaro	Bokaro	Jharkhand	Central	Eastern	3 x 210	630
Chandrapura Thermal Power Station	DVC	Chandrapura	Bokaro	Jharkhand	Central	Eastern	3 x 130, 3 x 120, 2 x 250	1250
Farakka Super Thermal Power Station	NTPC	Nagarun	Murshidabad	West Bengal	Central	Eastern	3 x 200, 2 x 500	1600
Durgapur Thermal Power Station	DVC	Durgapur	Bardhaman	West Bengal	Central	Eastern	1 x 140, 1 x 210	350
Mejia Thermal Power Station	DVC	Durlavpur	Bankura	West Bengal	Central	Eastern	4 x 210, 2 x 250	1340
Talcher Super Thermal Power Station	NTPC	Kaniha	Angul	Orissa	Central	Eastern	6 x 500	3000
Talcher Thermal Power Station	NTPC	Talcher	Angul	Orissa	Central	Eastern	4x 60, 2 x 110	460
Budge Budge Thermal Power Plant	CESC	Achipur	South 24 Paraganas	West Bengal	Private	Eastern	3 x 250	750
Titagarh Thermal Power Station	CESC		North 24 Paraganas	West Bengal	Private	Eastern	4 x 60	240
CESC Southern Generating Station	CESC			West Bengal	Private	Eastern	3 x 67.5	135
Jojobera TPP	Tata	Jojobera	Jamshedpur	Jharkhand	Private	Eastern	3 x 120,1×67.5	427.5
Jharsuguda TPP	Vedanta	Jharsuguda	Jharsuguda	Orisa	Private IPP	Eastern	4×600	2400
Vedanta Aluminim CPP	Vedanta	Jharsuguda	Jharsuguda	Orisa	Private CPP	Eastern	9×135	1215
Eastern							22	104
Total							102	426