23 December 2011
22 December 2011
TRANSFORMER THEORY
A transformer is a device that transfers electrical energy from one circuit to another through inductively coupled conductors—the transformer's coils. A varying current in the first or primary winding creates a varying magnetic flux in the transformer's core and thus a varying magnetic field through the secondary winding. This varying magnetic field induces a varying electromotive force (EMF), or "voltage", in the secondary winding. This effect is called inductive coupling.
If a load is connected to the secondary, current will flow in the secondary winding and electrical energy will be transferred from the primary circuit through the transformer to the load. In an ideal transformer, the induced voltage in the secondary winding (Vs) is in proportion to the primary voltage (Vp), and is given by the ratio of the number of turns in the secondary (Ns) to the number of turns in the primary (Np) as follows:
Vs =Ns
Vp Np
By appropriate selection of the ratio of turns, a transformer thus enables an alternating current (AC) voltage to be "stepped up" by making Ns greater than Np, or "stepped down" by making Ns less than Np.
In the vast majority of transformers, the windings are coils wound around a ferromagnetic core, air-core transformers being a notable exception.
Transformers range in size from a thumbnail-sized coupling transformer hidden inside a stage microphone to huge units weighing hundreds of tons used to interconnect portions of power grids. All operate on the same basic principles, although the range of designs is wide. While new technologies have eliminated the need for transformers in some electronic circuits, transformers are still found in nearly all electronic devices designed for household ("mains") voltage. Transformers are essential for high-voltage electric power transmission, which makes long-distance transmission economically practical.
GENERATOR THEORY
Faraday's law:
In the years of 1831–1832, Michael Faraday discovered the operating principle of electromagnetic generators. The principle, later called Faraday's law, is that an electromotive force is generated in an electrical conductor that encircles a varying magnetic flux. He also built the first electromagnetic generator, called the Faraday disk, a type of homo polar generator, using a copper disc rotating between the poles of a horseshoe magnet. It produced a small DC voltage.
This design was inefficient due to self-cancelling counter flows of current in regions not under the influence of the magnetic field. While current was induced directly underneath the magnet, the current would circulate backwards in regions outside the influence of the magnetic field. This counter flow limits the power output to the pickup wires and induces waste heating of the copper disc. Later homo polar generators would solve this problem by using an array of magnets arranged around the disc perimeter to maintain a steady field effect in one current-flow direction.
Another disadvantage was that the output voltage was very low, due to the single current path through the magnetic flux. Experimenters found that using multiple turns of wire in a coil could produce higher more useful voltages. Since the output voltage is proportional to the number of turns, generators could be easily designed to produce any desired voltage by varying the number of turns. Wire windings became a basic feature of all subsequent generator designs.
Dynamo:
Dynamos are no longer used for power generation due to the size and complexity of the commutator needed for high power applications. This large belt-driven high-current dynamo produced 310 amperes at 7 volts, or 2,170 watts, when spinning at 1400 RPM.
The dynamo was the first electrical generator capable of delivering power for industry. The dynamo uses electromagnetic principles to convert mechanical rotation into pulsed DC through the use of a commutator. The first dynamo was built by Hippolyte Pixii in 1832.
Through a series of accidental discoveries, the dynamo became the source of many later inventions,including the DC electric motor, the AC alternator, the AC synchronous motor, and the rotary converter.
A dynamo machine consists of a stationary structure, which provides a constant magnetic field, and a set of rotating windings which turn within that field. On small machines the constant magnetic field may be provided by one or more permanent magnets; larger machines have the constant magnetic field provided by one or more electromagnets, which are usually called field coils.
Large power generation dynamos are now rarely seen due to the now nearly universal use of alternating current for power distribution and solid state electronic AC to DC power conversion. But before the principles of AC were discovered, very large direct-current dynamos were the only means of power generation and distribution. Now power generation dynamos are mostly a curiosity.
Alternator:
Without a commutator, a dynamo becomes an alternator, which is a synchronous singly fed generator. When used to feed an electric power grid, an alternator must always operate at a constant speed that is precisely synchronized to the electrical frequency of the power grid. A DC generator can operate at any speed within mechanical limits, but always outputs direct current.
Typical alternators use a rotating field winding excited with direct current, and a stationary (stator) winding that produces alternating current. Since the rotor field only requires a tiny fraction of the power generated by the machine, the brushes for the field contact can be relatively small. In the case of a brushless exciter, no brushes are used at all and the rotor shaft carries rectifiers to excite the main field winding.
The two main parts of a generator or motor can be described in either mechanical or electrical terms.
Mechanical:
- Rotor : The rotating part of an electrical machine
- Stator: The stationary part of an electrical machine
Electrical :
- Armature: The power-producing component of an electrical machine. In a generator, alternator, or dynamo the armature windings generate the electric current. The armature can be on either the rotor or the stator.
- Field: The magnetic field component of an electrical machine. The magnetic field of the dynamo or alternator can be provided by either electromagnets or permanent magnets mounted on either the rotor or the stator.
Because power transferred into the field circuit is much less than in the armature circuit, AC generators nearly always have the field winding on the rotor and the stator as the armature winding. Only a small amount of field current must be transferred to the moving rotor, using slip rings.Direct current machines (dynamos) require a commutator on the rotating shaft to convert the alternating current produced by the armature to direct current,so the armature winding is on the rotor of the machine.
Excitation:
An electric generator or electric motor that uses field coils rather than permanent magnets requires a current to be present in the field coils for the device to be able to work. If the field coils are not powered, the rotor in a generator can spin without producing any usable electrical energy, while the rotor of a motor may not spin at all.
Smaller generators are sometimes self-excited, which means the field coils are powered by the current produced by the generator itself.The field coils are connected in series or parallel with the armature winding. When the generator first starts to turn, the small amount of remanent magnetism present in the iron core provides a magnetic field to get it started, generating a small current in the armature.This flows through the field coils, creating a larger magnetic field which generates a larger armature current. This "bootstrap" process continues until the magnetic field in the core levels off due to saturation and the generator reaches a steady state power output.
Very large power station generators often utilize a separate smaller generator to excite the field coils of the larger. In the event of a severe widespread power outage where islanding of power stations has occurred, the stations may need to perform a black start to excite the fields of their largest generators, in order to restore customer power service.
21 December 2011
TURBINE THEORY
Principle of operation and design:-
An ideal steam turbine is considered to be an isentropic process, or constant entropy process, in which the entropy of the steam entering the turbine is equal to the entropy of the steam leaving the turbine. No steam turbine is truly isentropic, however, with typical isentropic efficiencies ranging from 20–90% based on the application of the turbine. The interior of a turbine comprises several sets of blades, or buckets as they are more commonly referred to. One set of stationary blades is connected to the casing and one set of rotating blades is connected to the shaft. The sets intermesh with certain minimum clearances, with the size and configuration of sets varying to efficiently exploit the expansion of steam at each stage.
Impulse turbines:
Impulse turbines:
An impulse turbine has fixed nozzles that orient the steam flow into high speed jets. These jets contain significant kinetic energy, which the rotor blades, shaped like buckets, convert into shaft rotation as the steam jet changes direction. A pressure drop occurs across only the stationary blades, with a net increase in steam velocity across the stage.
As the steam flows through the nozzle its pressure falls from inlet pressure to the exit pressure (atmospheric pressure, or more usually, the condenser vacuum). Due to this higher ratio of expansion of steam in the nozzle the steam leaves the nozzle with a very high velocity. The steam leaving the moving blades has a large portion of the maximum velocity of the steam when leaving the nozzle. The loss of energy due to this higher exit velocity is commonly called the carry over velocity or leaving loss.
Reaction turbines:
In the reaction turbine, the rotor blades themselves are arranged to form convergent nozzles. This type of turbine makes use of the reaction force produced as the steam accelerates through the nozzles formed by the rotor. Steam is directed onto the rotor by the fixed vanes of the stator. It leaves the stator as a jet that fills the entire circumference of the rotor. The steam then changes direction and increases its speed relative to the speed of the blades. A pressure drop occurs across both the stator and the rotor, with steam accelerating through the stator and decelerating through the rotor, with no net change in steam velocity across the stage but with a decrease in both pressure and temperature, reflecting the work performed in the driving of the rotor.
Operation and maintenance:
When warming up a steam turbine for use, the main steam stop valves (after the boiler) have a bypass line to allow superheated steam to slowly bypass the valve and proceed to heat up the lines in the system along with the steam turbine. Also, a turning gear is engaged when there is no steam to the turbine to slowly rotate the turbine to ensure even heating to prevent uneven expansion. After first rotating the turbine by the turning gear, allowing time for the rotor to assume a straight plane (no bowing), then the turning gear is disengaged and steam is admitted to the turbine, first to the astern blades then to the ahead blades slowly rotating the turbine at 10–15 RPM (0.17–0.25 Hz) to slowly warm the turbine.
Any imbalance of the rotor can lead to vibration, which in extreme cases can lead to a blade breaking away from the rotor at high velocity and being ejected directly through the casing. To minimize risk it is essential that the turbine be very well balanced and turned with dry steam - that is, superheated steam with a minimal liquid water content. If water gets into the steam and is blasted onto the blades (moisture carry over), rapid impingement and erosion of the blades can occur leading to imbalance and catastrophic failure. Also, water entering the blades will result in the destruction of the thrust bearing for the turbine shaft. To prevent this, along with controls and baffles in the boilers to ensure high quality steam, condensate drains are installed in the steam piping leading to the turbine. Modern designs are sufficiently refined that problems with turbines are rare and maintenance requirements are relatively small.
Speed regulation:
The control of a turbine with a governor is essential, as turbines need to be run up slowly, to prevent damage while some applications (such as the generation of alternating current electricity) require precise speed control.Uncontrolled acceleration of the turbine rotor can lead to an overspeed trip, which causes the nozzle valves that control the flow of steam to the turbine to close. If this fails then the turbine may continue accelerating until it breaks apart, often spectacularly. Turbines are expensive to make, requiring precision manufacture and special quality materials.
During normal operation in synchronization with the electricity network, power plants are governed with a five percent droop speed control. This means the full load speed is 100% and the no-load speed is 105%. This is required for the stable operation of the network without hunting and drop-outs of power plants. Normally the changes in speed are minor. Adjustments in power output are made by slowly raising the droop curve by increasing the spring pressure on a centrifugal governor. Generally this is a basic system requirement for all power plants because the older and newer plants have to be compatible in response to the instantaneous changes in frequency without depending on outside communication.
BOILER THEORY
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| TWO PASS BOILER |
Boiler systems are classified in a variety of ways. They can be classified according to the end use, such as foe heating, power generation or process requirements. Or they can be classified according to pressure, materials of construction, size tube contents (for example, waterside or fireside), firing, heat source or circulation. Boilers are also distinguished by their method of fabrication. Accordingly, a boiler can be pack aged or field erected. Sometimes boilers are classified by their heat source. For example, they are often referred to as oil-fired, gas-fired, coal-fired, or solid fuel –fired boilers.
Types of boilers:
Fire tube boilers :
Fire tube boilers consist of a series of straight tubes that are housed inside a water-filled outer shell. The tubes are arranged so that hot combustion gases flow through the tubes. As the hot gases flow through the tubes, they heat the water surrounding the tubes. The water is confined by the outer shell of boiler. To avoid the need for a thick outer shell fire tube boilers are used for lower pressure applications. Generally, the heat input capacities for fire tube boilers are limited to 50 mbtu per hour or less, but in recent years the size of firetube boilers has increased.
Most modern fire tube boilers have cylindrical outer shells with a small round combustion chamber located inside the bottom of the shell. Depending on the construction details, these boilers have tubes configured in either one, two, three, or four pass arrangements. Because the design of fire tube boilers is simple, they are easy to construct in a shop and can be shipped fully assembled as a package unit.
These boilers contain long steel tubes through which the hot gases from the furnace pass and around which the hot gases from the furnace pass and around which the water circulates. Fire tube boilers typically have a lower initial cost, are more fuel efficient and are easier to operate, but they are limited generally to capacities of 25 tonnes per hour and pressures of 17.5 kg per cm2.
Water tube boilers:
Water tube boilers are designed to circulate hot combustion gases around the outside of a large number of water filled tubes. The tubes extend between an upper header, called a steam drum, and one or more lower headers or drums. In the older designs, the tubes were either straight or bent into simple shapes. Newer boilers have tubes with complex and diverse bends. Because the pressure is confined inside the tubes, water tube boilers can be fabricated in larger sizes and used for higher-pressure applications.Small water tube boilers, which have one and sometimes two burners, are generally fabricated and supplied as packaged units. Because of their size and weight, large water tube boilers are often fabricated in pieces and assembled in the field.
In water tube or “water in tube” boilers, the conditions are reversed with the water passing through the tubes and the hot gases passing outside the tubes. These boilers can be of a single- or multiple-drum type. They can be built to any steam capacity and pressures, and have higher efficiencies than fire tube boilers.
Almost any solid, liquid or gaseous fuel can be burnt in a water tube boiler. The common fuels are coal, oil, natural gas, biomass and solid fuels such as municipal solid waste (MSW), tire-derived fuel (TDF) and RDF. Designs of water tube boilers that burn these fuels can be significantly different.
Coal-fired water tube boilers are classified into three major categories: stoker fired units, PC fired units and FBC boilers.
Package water tube boilers come in three basic designs: A, D and O type. The names are derived from the general shapes of the tube and drum arrangements. All have steam drums for the separation of the steam from the water, and one or more mud drums for the removal of sludge. Fuel oil-fired and natural gas-fired water tube package boilers are subdivided into three classes based on the geometry of the tubes.
The “A” design has two small lower drums and a larger upper drum for steam-water separation. In the “D” design, which is the most common, the unit has two drums and a large-volume combustion chamber. The orientation of the tubes in a “D” boiler creates either a left or right-handed configuration. For the “O” design, the boiler tube configuration exposes the least amount of tube surface to radiant heat. Rental units are often “O” boilers because their symmetry is a benefit in transportation
“D” Type boilers
“This design has the most flexible design. They have a single steam drum and a single mud drum, vertically aligned. The boiler tubes extend to one side of each drum. “D” type boilers generally have more tube surface exposed to the radiant heat than do other designs. “Package boilers” as opposed to “field-erected” units generally have significantly shorter fireboxes and frequently have very high heat transfer rates (250,000 btu per hour per sq foot). For this reason it is important to ensure high-quality boiler feedwater and to chemically treat the systems properly. Maintenance of burners and diffuser plates to minimize the potential for flame impingement is critical.
“A” type boilers:
“A” type boilers:
This design is more susceptible to tube starvation if bottom blows are not performed properly because “A” type boilers have two mud drums symmetrically below the steam drum. Drums are each smaller than the single mud drums of the “D” or “O” type boilers. Bottom blows should not be undertaken at more than 80 per cent of the rated steam load in these boilers. Bottom blow refers to the required regular blow down from the boiler mud drums to remove sludge and suspended solids.
15 December 2011
THERMAL PLANTS IN INDIA
More than 50% of india india
| Name | Operator | Location | State | Units | Capacity (MW) |
Assan | 4 x 110 | 440.00 | |||
Assan | 2 x 210+ 2 x 250 | 920.00 | |||
1 x 55 | 55.00 | ||||
Khedar | 1 x 600 | 600.00 | |||
Bathinda | 4 x 110 | 440.00 | |||
Lehra Mohabbat | 2 x 210+2 x250 | 920.00 | |||
Ghanauli | 6 x 210 | 1260.00 | |||
Suratgarh | 6 x 250 | 1500.00 | |||
2 x 110+ 3 x 210+ | 1240.00 | ||||
Thumbli | 2 x 125 | 250.00 | |||
Mothipura | 2 x 250 | 500.00 | |||
1 x 40+3 x 94+5 x 200 | 1322.00 | ||||
3 x 210+2x500 | 1630.00 | ||||
2 x 105 | 210.00 | ||||
2 x 110+2 x 210 | 640.00 | ||||
1 x 55+1 x 60+1 x 105 | 220.00 | ||||
3 x 95+2 x 210 | 705.00 | ||||
5 x 200+2 x 500 | 2000.00 | ||||
Barsingsar | 2 x 125 | 250.00 | |||
4 x 500 | 2000.00 | ||||
4 x 210+2 x 490 | 1820.00 | ||||
5 x 210 | 1050.00 | ||||
4 x 110 | 440.00 | ||||
1 x 135 | 135.00 | ||||
KSK | Gurha | 1 x 125 | 125.00 | ||
2 x 300 | 600.00 | ||||
2 x 120+2 x 200+1 x 210 | 850.00 | ||||
2 x 120+3 x 210 | 870.00 | ||||
7 x 210 | 1470.00 | ||||
2 x 120 | 240.00 | ||||
2 x 110 | 220.00 | ||||
2 x 70+2 x 75 | 290.00 | ||||
GIPCL | 4 x 125 | 500.00 | |||
GMDC | 2 x 125 | 250.00 | |||
5 x 37.5+1 x 200+ 3 x 210 | 1017.50 | ||||
4 x 210+1 x 500 | 1340.00 | ||||
2 x 120, 1 x 210 | 450.00 | ||||
4 x 50+2 x 120 | 440.00 | ||||
2 x 250 | 500.00 | ||||
4 x 210 | 840.00 | ||||
1 x 200+2 x 210 | 620.00 | ||||
3 x 210 | 630.00 | ||||
2 x 210 | 420.00 | ||||
2 x 250 | 500.00 | ||||
3 x 210+2 x 250 | 1130.00 | ||||
4 x 210 | 840.00 | ||||
4 x 210+3 x 500 | 2340.00 | ||||
Vindhya Nagar | 6 x 210+ 4 x 500 | 3260.00 | |||
3 x 200+3 x 500 | 2100.00 | ||||
2 x 500 | 1000.00 | ||||
Bhilai | 2 x 250 | 500.00 | |||
Torrent Power | 1 x 60+1 x 120+ 2 x 110 | 400.00 | |||
Mundra | 4 x 330+5 X 660 | 4620.00 | |||
Jindal | Tamnar | 4 x 250 | 1000.00 | ||
Lanco | Pathadi | 2 x 300 | 600.00 | ||
Trombay | 1 x 150+2 x 500+1 x 250 | 1400.00 | |||
Reliance Energy Limited | 2 x 250 | 500.00 | |||
KSK | Warora | 1 x 135 | 135.00 | ||
10 X 270 | 2700.00 | ||||
1 x 62.5 | 62.50 | ||||
4 x 60+ 4 x 120 | 720.00 | ||||
2 x 250+1X500 | 1000.00 | ||||
6 x 210+1 x 500 | 1760.00 | ||||
5 x 210 | 1050.00 | ||||
1 x 500 | 500.00 | ||||
Raichur | 7 x 210+1 x 250 | 1720.00 | |||
Kudatini | 1 x 500 | 500.00 | |||
TNEB | 3 x 210 | 630.00 | |||
TNEB | 2 x 60+3 x 110 | 450.00 | |||
TNEB | 4 x 210 | 840.00 | |||
TNEB | 5 x 210 | 1050.00 | |||
Jyothi Nagar | 3 x 200+4 x 500 | 2600.00 | |||
Simhadri | 2 x 500 | 1000.00 | |||
6 x 50+3 x 100+ | 1020.00 | ||||
2 x 210 | |||||
7 x 210 | 1470.00 | ||||
Vijayanagar | 2 x 130 | 260.00 | |||
Vijayanagar | 2 x 300 | 600.00 | |||
Lanco | Nandikoor | 1 x 600 | 600.00 | ||
STPS | Neyveli | 1 x 250 | 250.00 | ||
Southern | 20 | 83.00 | |||
BSEB | 2 x 50+2 x 105 | 310.00 | |||
KBUCL | 2 x 110 | 220.00 | |||
JSEB | 4 x 40+2 x 90+ | 770.00 | |||
2 x 105+2 x 110 | |||||
TVNL | 2 x 210 | 420.00 | |||
WBPDCL | Mecheda | 6 x 210 | 1260.00 | ||
WBPDCL | Suri | 5 x 210 | 1050.00 | ||
WBPDCL | 4 x 60+1 x 210 | 450.00 | |||
WBPDCL | 4 x 120+1 x 250 | 730.00 | |||
WBPDCL | Monigram | 2 x 300 | 600.00 | ||
DPL | 2 x 30+1 x 70+ | 690.00 | |||
2 x 75+1 x110+ | |||||
1 x 300 | |||||
OPGCL | Banharpali | 8 x 120 | 960.00 | ||
Captive Power Plant | NALCO | Angul | 2 x 210 | 420.00 | |
4 x 210+3 x 500 | 2340.00 | ||||
3 x 210 | 630.00 | ||||
3 x 130+3 x120+ | 1250.00 | ||||
2 x 250 | |||||
3 x 200, 2 x 500 | 1600.00 | ||||
1 x 140+1x 210 | 350.00 | ||||
Durlavpur | 4 x 210+2 x 250+ 2 x 500 | 2340.00 | |||
6 x 500 | 3000.00 | ||||
4x 60+2 x110 | 460.00 | ||||
Hindalco Industries | Hirakud | 1x 67.5+3 x 100 | 367.50 | ||
Achipur | 3 x 250 | 750.00 | |||
4 x 60 | 240.00 | ||||
3 x 67.5 | 135.00 | ||||
Jojobera TPP | Jojobera | 3 x 120+1x67.5 | 427.50 | ||
Jharsuguda TPP | Vedanta | Jharsuguda | 4x600 | 2400.00 | |
Vedanta Aluminim CPP | Vedanta | Jharsuguda | 9x135 | 1215.00 |
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