Showing posts with label ac power. Show all posts
Showing posts with label ac power. Show all posts

Wednesday, 1 April 2020

SAG in electrical power transmission.

What is  Sag.?

In electrical power transmission and mechanical design of overhead transmission line.

SAG.

A perfectly flexible wire of uniform cross-section, when string between the two supports at the same level, will form a catenary. However, if the sag is very small compared to the span, its shape approximation a parabola.
 The difference in level between the point of support and the lowest point on the conductor is known as sag 

The factors affecting the sag in an overhead line are given below.

1. Weight of the Conductor,
 This affect the sag directly. Heavier the conductor, greater will be the sag. In locations where ice formation takes place on the conductor, this will also cause increase in the sag.

2. Length Of the Span.
This also affect the sag. Sag is directly proportional to the square of the span length Hence other conditions, such as type of conductor, working tension, temperature etc. remaining the same a section with longer span will have much greater sag.

3. Working Tensile Strength.
The sag is inversely proportional to the working tensile strength of conductor if other conditions such as temperature, length of span remain the same. Working tensile strength of the conductor is determined by multiplying the ultimate stress and area of cross section and dividing by a factor of safety.

4. Temperature.
All metallic bodies expand with the rise in temperature and, therefore. The length of the conductor increases with the rise in temperature, and so does the sag.



Reference from .
Transmission and distribution of electrical power by-J.B.Gupta.
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Wednesday, 3 July 2019

Cooling Methods of a Transformer


Why it is needed to cool down the transformer?

No transformer is truly an 'ideal transformer' and hence each will incur some losses, most of which get converted into heat. If this heat is not dissipated properly, the excess temperature in transformer may cause serious problems like insulation failure. It is obvious that transformer needs a cooling system.



Transformers can be divided in two types as

  1.               Dry type transformers.
  2.               Oil immersed transformers.

Different cooling methods of transformers are

 For dry type transformers

  • Air Natural (AN)
  • Air Blast


For oil immersed Transformers

  • Oil Natural Air Natural (ONAN)
  • Oil Natural Air Forced (ONAF)
  • Oil Forced Air Forced (OFAF)
  • Oil Forced Water Forced (OFWF)



Cooling Methods for Dry Type Transformers

Air Natural or Self Air Cooled Transformer:  This method of transformer cooling is generally used in small transformers (upto 3 MVA). In this method the transformer is allowed to cool by natural air flow surrounding it.

Air Blast:   For transformers rated more than 3 MVA, cooling by natural air method is inadequate. In this method, air is forced on the core and windings with the help of fans or blowers. The air supply must be filtered to prevent the accumulation of dust particles in ventilation ducts. This method can be used for transformers upto 15 MVA.


Cooling Methods for Oil Immersed Transformers

Oil Natural Air Natural (ONAN):    This method is used for oil immersed transformers. In this method, the heat generated in the core and winding is transferred to the oil. According to the principle of convection, the heated oil flows in the upward direction and then in the radiator. The vacant place is filled up by cooled oil from the radiator. The heat from the oil will dissipate in the atmosphere due to the natural air flow around the transformer. In this way, the oil in transformer keeps circulating due to natural convection and dissipating heat in atmosphere due to natural conduction. This method can be used for transformers upto about 30 MVA.

Oil Natural Air Forced (ONAF):   The heat dissipation can be improved further by applying forced air on the dissipating surface. Forced air provides faster heat dissipation than natural air flow. In this method, fans are mounted near the radiator and may be provided with an automatic starting arrangement, which turns on when temperature increases beyond certain value. This transformer cooling method is generally used for large transformers upto about 60 MVA.


Oil Forced Air Forced (OFAF):   In this method, oil is circulated with the help of a pump. The oil circulation is forced through the heat exchangers. Then compressed air is forced to flow on the heat exchanger with the help of fans. The heat exchangers may be mounted separately from the transformer tank and connected through pipes at top and bottom as shown in the figure. This type of cooling is provided for higher rating transformers at substations or power stations.

Oil Forced Water Forced (OFWF):   This method is similar to OFAF method, but here forced water flow is used to dissipate hear from the heat exchangers. The oil is forced to flow through the heat exchanger with the help of a pump, where the heat is dissipated in the water which is also forced to flow. The heated water is taken away to cool in separate coolers. This type of cooling is used in very large transformers having rating of several hundred MVA.

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Saturday, 29 June 2019

WHAT IS REAL POWER IN ELECTRIC ENGINEERING

What Is Real Power?

Real Power: (P)

Real Power is the actual power which is really transferred to the load such as transformer, induction motors, generators etc. and dissipated in the circuit.

Alternative words used for Real Power (Actual Power, True Power, Watt-full Power, Useful Power, Real Power, and Active Power) and denoted by (P) and measured in units of Watts (W) 

i.e. The unit of Active or Real power is Watt where 1W = 1V x 1 A


Real Power in DC Circuits:

In DC Circuits, power supply to the DC load is simply the product of Voltage across the load and Current flowing through it.

i.e., P = V I because in DC Circuits, there is no concept of phase angle between current and voltage.

In other words, there is no frequency (f) or Power factor in DC Circuits.

Real Power in AC Circuits:

But the situation in Sinusoidal or AC Circuits is more complex because of phase difference (θ) between Current and Voltage. 

Therefore average value of power (Real Power) is P = VI Cosθ is in fact supplied to the load.

In AC circuits, When circuit is pure resistive, then the same formula used for power as used in DC as P = VI


Real Power Formulas:

P = V I  (In DC circuits)

P = VI Cosθ    (in Single phase AC Circuits)

P = √3 VL IL Cosθ   or       (in Three Phase AC Circuits)
P = 3 VPh IPh Cosθ

P = √ (S2 – Q2) or

P =√ (VA2 – VAR2) or

Real or True power = √ (Apparent Power2– Reactive Power2)
 or
kW = √ (kVA2 – kVAR2)


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Thursday, 19 July 2018

What is ACCL? And how it works?

ACCL is a Automatic source Changeover cum Current Limiter


The ACCL is a fully automatic, high precision system installed in apartments, residential complexes, commercial buildings etc.


 It has the following functions:


• The ACCL allows unrestricted supply from mains. 

• When the main supply fails and stand by Generator supply is on, it connects the DG power to each consumer in sequence & starts monitoring its load. 

• The generator current allotment is software calibrated in Amps & sealed in each ACCL as per buyer's specification & is available on all load circuits. 

• When ever the load current exceeds the allotment, power is automatically switched off for 8/10/12 seconds, and then automatically restored.


Benefits and Specifications: 


• Available in Single Phase and 3 Phase configurations.from different make.

• Microprocessor based fully automated system to replace outdated manual systems.

• No separate wiring required.

• Assured availability of allotted current - no less, no more. Ensures equitable rationing of generator power.

• DIN channel mountable enclosures save space and make installation hassle-free.

• LED indication of operational states.

• Factory set and sealed calibration ensures that allotted limits cannot be tampered with.

• Single phase ACCL comes in TP MCB size (54mm).

• Tested at National Test House.




contain source http://electron.co.in/ACCL.html
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Tuesday, 22 March 2016

An Over view about MCCB (Moulded Case Circuit Breakers )

Molded Case Circuit Breakers

          Molded Case Circuit Breakers are electromechanical devices which protect a circuit from  Over-current and Short Circuit. It provides Short Circuit Protection and also Over-current and for circuits ranging from 63 Amps up to 3000 Amps.

             Their primary functions are to provide a means to manually and automatically open a circuit under overload or short circuit conditions. The over-current, in an electrical circuit, may result from short circuit, overload or faulty design.

          MCCB is an alternative to a fuse since it does not require replacement once an overload is detected. Unlike fuse, an MCCB can be easily reset after a fault and offers improved operational safety and convenience without incurring operating cost.

      Molded case circuit breakers generally have a  Thermal element for over-current and Magnetic element for short circuit release which has to operate faster.

         MCCBs are manufactured such that end user will not have access to internal workings of the over-current protection device. Generally constructed of two pieces of heavy-duty electrically insulated plastic, these two halves are riveted together to form the whole. Inside the plastic shell is a series of thermal elements and a Spring-loaded trigger.

       When the thermal element gets too warm, from an over-current situation, the spring trips, which in turn will shut off the electrical circuit.

Types of MCCBs

Larger molded case circuit breakers have adjustable range setting on the face of the device. Molded case circuit breakers can range in size from 32 Amperes up to 3000 Amperes.

Molded Case Circuit Breakers have the following Specifications
  • Current Rating - Amperes
  • Current Setting Range - Amperes
  • Short Circuit Rating - Kilo Amperes (KA)
  • Operating Characteristics - Normal / Current Limiting Type


MCCBs are now available with a variety of Releases or Operating Mechanisms these are given below

  • Thermal Magnetic Release
  • Electronic Release
  • Microprocessor Release
  • Thermal Magnetic Release MCCB


               Thermal-magnetic circuit breakers use bimetals and electromagnetic assemblies to provide over-current protection. Their characteristic inverse time tripping under overload conditions is ideally suited for many applications varying from residential to heavy industrial loads. For higher level (short circuit) over currents, instantaneous trip characteristics allow molded case circuit breakers to interrupt with no intentional delay.

               The adjustable overload protection is from 70% to 100% of the nominal current and short circuit setting from 5 to 10 times of the rated current is possible.

              The minor disadvantage of the release is that operating characteristics of the breaker may vary depending on the ambient temperature.
Electronic Release MCCB

           Electronic or Static Release Molded Case circuit breakers use power electronic circuitry to provide over-current protection. The Continuous adjustable overload protection from 60% to 100% of the nominal current and short circuit setting from 2 to 10 times of the rated current is possible.

         The advantage of the release is that operating characteristics of the breaker is independent of the ambient temperature.

                This wide flexibility takes care of future increases in load capacity of an installation and ensures better planning at an optimum cost.
Microprocessor release MCCB

             Microprocessor release Molded Case circuit breakers use microprocessors to provide over-current protection. The Microprocessor release works on monitoring of current True R.M.S value. It is simulated and calculated from peak values, which installed microprocessor, can detect.

                There is high Flexibility through multiple adjustments of protection settings, High repeat accuracy and High reliability.


               Time delays can be provided for Short Circuit Release better discrimination and co-ordination using LCD display. System Diagnosis is possible as it stores the Trip history within the internal memory. Trip current indication is also available for understanding of type of fault and set-up programming at site.


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Saturday, 21 November 2015

Little bit Introduction About MHD Generation

INTRODUCTION

     Magneto hydrodynamics (MHD) (magneto fluid dynamics or hydro magnetics) is the academic discipline which studies the dynamics of electrically conducting fluids. Examples of such fluids include plasmas, liquid metals, and salt water. The word magneto hydro dynamics (MHD) is derived from magneto- meaning magnetic field, and hydro- meaning liquid, and -dynamics meaning movement. The field of MHD was initiated by Hannes Alfvén , for which he received the Nobel Prize in Physics in 1970

o  80 % of total electricity produced in the world is hydal, while remaining 20% is produced from nuclear, thermal, solar, geothermal energy and from magneto hydro dynamic (mhd) generator.
o  MHD power generation is a new system of electric power generation which is said to be of high efficiency and low pollution. In advanced countries MHD generators are widely used but in developing countries like INDIA, it is still under construction, this construction work in in progress at TRICHI in TAMIL NADU, under the joint efforts of BARC (Bhabha atomic research center), Associated cement corporation (ACC) and Russian technologists.
o  As its name implies, magneto hydro dynamics (MHD) is concerned with the flow of a conducting fluid in the presence of magnetic and electric field. The  fluid may be gas  at elevated temperatures or liquid metals like sodium or potassium- SEEDING.

o  An MHD generator is a device for converting heat energy of a fuel directly into electrical energy without conventional electric generator.
o  In this system. An MHD converter system is a heat engine in which heat taken up at a higher temperature is partly converted into useful work and the remainder is rejected at a temperature. Like all heat engines, the thermal efficiency of an MHD converter is increased by supplying the heat at the highest practical temperature and rejecting it at the lowest practical temperature.
o  The output of the MHD is supplied to the conventional Thermal Plants.

PRINCIPLES OF MHD POWER GENERATION


o  When an electric conductor moves across a magnetic field, a voltage is induced in it which produces an electric current.
o  This is the principle of the conventional generator where the conductors consist of copper strips.
o  In MHD generator, the solid conductors are replaced by a gaseous conductor, an ionized gas. If such a gas is passed at a high velocity through a powerful magnetic field, a current is generated and can be extracted by placing electrodes in suitable position in the stream.
o  The principle can be explained as follows. An electric conductor moving through a magnetic field experiences a retarding force as well as an induced electric field and current.
       This effect is a result of FARADAYS LAWS OF ELECTRO MAGNETIC INDUCTION.
o  The induced EMF is given by
Eind = u x B
where   u = velocity of the conductor.
 B = magnetic field intensity.
o  The induced current is given by,
 Jind = C x Eind
where C = electric conductivity
The retarding force on the conductor is the Lorentz force given by                                                                                   Find = Jind X B

The electro magnetic induction principle is not limited to solid conductors. The movement of a conducting fluid through a magnetic field can also generate electrical energy.

When a fluid is used for the energy conversion technique, it is called MAGNETO HYDRO DYNAMIC (MHD), energy conversion.

The flow direction is right angles to the magnetic fields
                direction. An electromotive force (or electric voltage) is induced in the direction at right angles to both flow and field directions, as shown in the next slide.
The conducting flow fluid is forced between the plates with a kinetic energy and pressure differential sufficient to over come the magnetic induction force Find.

The end view drawing illustrates the construction of the flow channel.

An ionized gas is employed as the conducting fluid.

Ionization is produced either by thermal means I.e. by an elevated temperature or by seeding with substance like cesium or potassium vapors which ionizes at relatively low temperatures.

The atoms of seed element split off electrons. The presence of the negatively charged electrons makes the gas an electrical conductor.


VARIOUS MHD SYSTEMS

The MHD systems are broadly classified into two types.

OPEN CYCLE SYSTEM
CLOSED CYCLE SYSTEM
                Seeded inert gas system
                Liquid metal system

OPEN CYCLE SYSTEM
The fuel used maybe oil through  an oil tank or gasified coal through a coal gasification plant

The fuel (coal, oil or natural gas) is burnt in the combustor or combustion chamber.

The hot gases from combustor is then seeded with a small amount of ionized alkali metal (cesium or potassium) to increase the electrical conductivity of the gas.

The seed material, generally potassium carbonate is injected into the combustion chamber, the potassium is then ionized by the hot combustion gases at temperature of roughly 2300’ c to 2700’c.

To attain such high temperatures, the compressed air is used to burn the coal in the combustion chamber, must be adequate to at least 1100’c. A lower preheat temperature would be adequate if the air is enriched in oxygen. An alternative is used to compress oxygen alone for combustion of fuel, little or no preheating is then required. The additional cost of oxygen might be balanced by saving on the preheater.
The hot pressurized working fluid living in the combustor flows through a convergent divergent nozzle. In passing through the nozzle, the random motion energy of the molecules in the hot gas is largely converted into directed, mass of energy. Thus , the gas emerges from the nozzle and enters the MHD generator unit at a high velocity.

The MHD generator is a divergent channel made of a heat resistant alloy with external water cooling. The hot gas expands through the rocket like generator surrounded by powerful magnet. During motion of the gas the +ve and –ve ions move to the electrodes and constitute an electric current.

The arrangement of the electrode connection is determined by the need to reduce the losses arising from the Hall effect. By this effect, the magnetic field acts on the MHD-generated current and produces a voltage in flow direction of the working fluid.

CLOSED CYCLE SYSTEM

Two general types of closed cycle MHD generators are being investigated.

Electrical conductivity is maintained in the working fluid by ionization of a seeded material, as in open cycle system.

A liquid metal provides the conductivity.

The carrier is usually a chemical inert gas, all through a liquid carrier is been used with a liquid metal conductor. The working fluid is circulated in a closed loop and is heated by the combustion gases using a heat exchanger. Hence the heat sources and the working fluid are independent. The working fluid is helium or argon with cesium seeding.

SEEDED INERT GAS SYSTEM

In a closed cycle system the carrier gas operates in the form of Brayton cycle. In a closed cycle system the gas is compressed and heat is supplied by the source, at essentially constant pressure, the compressed gas then expands in the MHD generator, and its pressure and temperature fall. After leaving this generator heat is removed from the gas by a cooler, this is the heat rejection stage of the cycle. Finally the gas is recompressed and returned for reheating.

The complete system has three distinct but interlocking loops. On the left is the external heating loop. Coal is gasified and the gas is burnt in the combustor to provide heat. In the primary heat exchanger, this heat is transferred to a carrier gas argon or helium of the MHD cycle. The combustion products after passing through the air preheated and purifier are discharged to atmosphere.

Because the combustion system is separate from the working fluid, so also are  the ash and flue gases. Hence the problem of extracting the seed material from fly ash does not arise. The fuel gases are used to preheat the incoming combustion air and  then treated for fly ash and sulfur dioxide removal, if necessary prior to discharge through a stack to the atmosphere.

The loop in the center is the MHD loop. The hot argon gas is seeding with cesium and resulting working fluid is passed through the MHD generator at high speed. The dc power out of MHD generator is converted in ac by the inverter and is then fed to the grid.

LIQUID METAL SYSTEM

When a liquid metal provides the electrical conductivity, it is called a liquid metal MHD system.
An inert gas is a convenient carrier

The carrier gas is pressurized and heated by passage through a heat exchanger within combustion chamber. The hot gas is then incorporated into the liquid metal usually hot sodium to form the working fluid. The latter then consists of gas bubbles uniformly dispersed in an approximately equal volume of liquid sodium.

The working fluid is introduced into the MHD generator through a nozzle in the usual ways. The carrier gas then provides the required high direct velocity of the electrical conductor.

After passage through the generator, the liquid metal is separated from the carrier gas. Part of the heat exchanger to produce steam for operating a turbine generator. Finally the carrier gas is cooled, compressed and returned to the combustion chamber for reheating and mixing with the recovered liquid metal. The working fluid temperature is usually around 800’c as the boiling point of sodium even under moderate pressure is below 900’c.

At lower operating temp, the other MHD conversion systems may be  advantageous from the material standpoint, but the maximum thermal efficiency is lower. A possible compromise might be to use liquid lithium, with a boiling point near 1300’c as the electrical conductor lithium is much more expensive than sodium, but losses in a closed system are less.

ADVANTAGES

The conversion efficiency of a MHD system can be around 50% much higher compared to the most efficient steam plants. Still higher efficiencies are expected in future, around 60 – 65 %, with the improvements in experience and technology.

Large amount of power is generated.

It has no moving parts, so more reliable.

The closed cycle system produces power, free of pollution.

It has ability to reach the full power level as soon as started.

The size if the plant is considerably smaller than conventional fossil fuel plants.

Although the cost cannot be predicted very accurately, yet it has been reported that capital costs of MHD plants will be competitive to conventional steam plants.

It has been estimated that the overall operational costs in a plant would be about 20% less than conventional steam plants.

Direct conversion of heat into electricity permits to eliminate the turbine (compared with a gas turbine power plant) or both the boiler and the turbine (compared with a steam power plant) elimination reduces losses of energy.

These systems permit better fuel utilization. The reduced fuel consumption would offer additional economic and special benefits and would also lead to conservation of energy resources.

It is possible to use MHD for peak power generations and emergency service. It has been estimated that MHD equipment for such duties is simpler, has capability of generating in large units and has the ability to make rapid start to full load.

FUTURE PROSPECTS

It  is estimated that by 2020, almost 70 % of the total electricity generated in the world will be from MHD generators.
Research and development is widely being done on MHD by different countries of the world.
Nations involved:
USA
Former USSR
Japan
India
China
Yugoslavia
Australia
Italy

Poland


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Saturday, 14 June 2014

Little bit of A History of Electrical Engineering.....War of Currents

War of Currents                                                       

In the War of Currents era (sometimes, War of the Currents or Battle of Currents) in the late 1880s, George Westinghouse and Thomas Edison became adversaries due to Edison's promotion of direct current (DC) for electric power distribution over alternating current (AC).
Edison's direct-current system generated and distributed electric power at the same voltage as used by the customer's lamps and motors. This meant that the current in transmission was relatively large, and so heavy conductors were required and transmission distances were limited, to about a mile (kilometre); otherwise transmission losses would make the system uneconomical. At the time, no method was practical for changing voltages of DC power. The invention of an efficient transformer allowed high voltage to be used for AC transmission. An AC generating plant could then serve customers at a great distance (tens to hundreds of miles), or could serve more customers within its economical transmission distance. The fewer much larger plants needed for AC would achieve an economy of scale that would lower costs further. The invention of a practical AC motor increased the usefulness of alternating current for powering machinery.
Edison's company had invested heavily in DC technology and was vigorously defending its DC based patents. George Westinghouse saw AC as a way to get into the business with his own patented competing system and set up the Westinghouse Electric Company to design and build it. The Westinghouse company also purchased the patents for alternating current devices from inventors in Europe and licensed patents from Nikola Tesla. In spite of a protracted anti-AC campaign waged by the Edison company, the economics of the alternating current system prevailed. Alternating current was selected in 1893 for transmission of power from Niagara Falls to Buffalo, New York - the technical and economic success of this project led the way for the adoption of alternating current as the preferred electrical system.
The "War of Currents" is often personified as Westinghouse vs. Edison.[citation needed] However, the "War of Currents" was much larger than that: It involved both American and European companies whose heavy investments in one current type or the other led them to hope that use of the other type would decline, such that their share of the market for "their" current type would represent greater absolute revenue once the decline of the other current type enabled them to expand their existing distribution networks.[citation needed]

Direct current remained in commercial power distribution use for about a century after the "war of the currents", confined to high density urban areas, where, for example, passenger 


and freight elevators ran on direct current motors. Direct current found a new application in high voltage direct current transmission used to connect power plants to distant customer load. Direct current remained useful in certain traction systems, within vehicles, and in battery-operated systems. Often direct current loads were powered from the alternating current public grid with a rectifier. Direct current is also seeing new application in computer data centers, where DC distribution within a building can provide useful energy savings.
Electric power transmission

DC

                       Figure 1 Schematic of Edision's three wire DC electrical power distribution system

During the initial years of electricity distribution, Edison's direct current was the standard for the United States, and Edison did not want to lose all his patent royalties. Direct current worked well with incandescent lamps, which were the principal load of the day, and with motors. Direct-current systems could be directly used with storage batteries, providing valuable load-leveling and backup power during interruptions of generator operation. Direct-current generators could be easily paralleled, allowing economical operation by using smaller machines during periods of light load and improving reliability. At the introduction of Edison's system, no practical AC motor was available. Edison had invented a meter to allow customers to be billed for energy proportional to consumption, but this meter worked only with direct current. The DC distribution system consisted of generating plants feeding heavy distribution conductors, with customer loads (lighting and motors) tapped off them. The system operated at the same voltage level throughout; for example, 100 volt lamps at the customer's location would be connected to a generator supplying 110 volts, to allow for some voltage drop in the wires between the generator and load. The voltage level was chosen for convenience in lamp manufacture; high-resistance carbon filament lamps could be constructed to withstand 100 volts, and to provide lighting performance economically competitive with gas lighting. At the time it was felt that 100 volts was not likely to present a severe hazard of fatal electric shock.
To save on the cost of copper conductors, a three-wire distribution system was used. The three wires were at +110 volts, 0 volts and −110 volts relative potential. 100-volt lamps could be operated between either the +110 or −110 volt legs of the system and the 0-volt "neutral" conductor, which carried only the unbalanced current between the + and − sources. The resulting three-wire system used less copper wire for a given quantity of electric power transmitted, while still maintaining (relatively) low voltages. However, even with this innovation, the voltage drop due to the resistance of the system conductors was so high that generating plants had to be located within 1.6 km or so of the load. Higher voltages could not so easily be used with the DC system because there was no efficient low-cost technology that would allow reduction of a high transmission voltage to a low utilization voltage.

Since direct current could not easily be converted to higher or lower voltages, separate electrical lines had to be installed to supply power to appliances that used different voltages, for example, lighting and electric motors. This required more wires to lay and maintain, wasting money and introducing unnecessary hazards. These hazards, for example, proved fatal to a number of people in the Great Blizzard of 1888, with their deaths being attributed to collapsing overhead power lines in New York City.

Edison considered the need for many local power plants in the direct current system more democratic. Each locale could build electrical plants to suit its need and would not have to rely on a large monopoly to supply electricity. The proponents of AC counter-argued that building a local plant would be too costly for rural areas, leaving them with no electrical supply at all.
A bipolar open-core power transformer developed by Lucien Gaulard and John Dixon Gibbs was demonstrated in London in 1881, and attracted the interest of Westinghouse. They also exhibited the invention in Turin in 1884. However these early induction coils with open magnetic circuits are inefficient at transferring power to loads. Until about 1880, the paradigm for AC power transmission from a high voltage supply to a low voltage load was a series circuit. Open-core transformers with a ratio near 1:1 were connected with their primaries in series to allow use of a high voltage for transmission while presenting a low voltage to the lamps. The inherent flaw in this method was that turning off a single lamp (or other electric device) affected the voltage supplied to all others on the same circuit. Many adjustable transformer designs were introduced to compensate for this problematic characteristic of the series circuit, including those employing methods of adjusting the core or bypassing the magnetic flux around part of a coil.

The direct current systems did not have these drawbacks, giving it significant advantages over early AC systems.

AC
                                            Figure 2  Westinghouse Early AC System 1887 (U.S. Patent 373,035)

In the alternating current distribution system power could be transmitted more efficiently over long distances at high voltages, around ten times that of the loads, using lower current. For a given quantity of power transmitted via DC or AC, the wire cross-sectional area is inversely proportional to the voltage used. Alternatively, the allowable length of a circuit, given a wire size and allowable voltage drop, increases approximately with the square of the distribution voltage. With AC current, a transformer is used to down step the (relatively) high voltage to low voltages for use in homes and factories. This had—and still has—the practical significance that fewer, larger generating plants can serve the load in a given area. Large loads, such as industrial motors or converters for electric railway power, can be served by the same distribution network that fed lighting, by using a transformer with a suitable secondary voltage.

Transmission loss

Figure 3  Tesla's US390721 Patent for a "Dynamo Electric Machine"
The advantage of AC for distributing power over a distance is due to the ease of changing voltages using a transformer. Available electric power is the product of current × voltage at the load. For a given amount of power, a low voltage requires a higher current and a higher voltage requires a lower current. Since metal conducting wires have an almost fixed electrical resistance, some power will be wasted as heat in the wires. This power loss is given by Joule's first law and is proportional to the square of the current. Thus, if the overall transmitted power is the same, and given the constraints of practical conductor sizes, high-current, low-voltage transmissions will suffer a much greater power loss than low-current, high-voltage ones. This holds whether DC or AC is used.

Converting DC power from one voltage to another required a large spinning rotary converter or motor-generator set, which was difficult, expensive, inefficient, and required maintenance, whereas with AC the voltage can be changed with simple and efficient transformers that have no moving parts and require very little maintenance. This was the key to the success of the AC system. Modern transmission grids regularly use AC voltages up to 765,000 volts.[6] Power electronic devices such as the mercury-arc valve and thyristor made high-voltage direct current transmission practical by improving the reliability and efficiency of conversion between alternating and direct current, but such technology only became possible on an industrial scale starting in the 1960s.

The Ganz AC system
                                    
                                   Figure 4 The prototype transformer is on display at the Széchenyi István Memorial Exhibition, Nagycenk, Hungary

In the autumn of 1884, Károly Zipernowsky, Ottó Bláthy and Miksa Déri (ZBD), three engineers associated with the Ganz factory, had determined that open-core devices were impracticable, as they were incapable of reliably regulating voltage. In their joint 1885 patent applications for novel transformers (later called ZBD transformers), they described two designs with closed magnetic circuits where copper windings were either a) wound around iron wire ring core or b) surrounded by iron wire core. The two designs were the first application of the two basic transformer constructions in common use to this day, which can as a class all be termed as either core form or shell form (or alternatively, core type or shell type), as in a) or b), respectively (see images). The Ganz factory had also in the autumn of 1884 made delivery of the world's first five high-efficiency AC transformers, the first of these units having been shipped on September 16, 1884. This first unit had been manufactured to the following specifications: 1,400 W, 40 Hz, 120:72 V, 11.6:19.4 A , ratio 1.67:1, one-phase, shell form. In both designs, the magnetic flux linking the primary and secondary windings traveled almost entirely within the confines of the iron core, with no intentional path through air (see Toroidal cores below). The new transformers were 3.4 times more efficient than the open-core bipolar devices of Gaulard and Gibbs.

The ZBD patents included two other major interrelated innovations: one concerning the use of parallel connected, instead of series connected, utilization loads, the other concerning the ability to have high turns ratio transformers such that the supply network voltage could be much higher (initially 1,400 to 2,000 V) than the voltage of utilization loads (100 V initially preferred). When employed in parallel connected electric distribution systems, closed-core transformers finally made it technically and economically feasible to provide electric power for lighting in homes, businesses and public spaces. Bláthy had suggested the use of closed cores, Zipernowsky had suggested the use of parallel shunt connections, and Déri had performed the experiments; The other essential milestone was the introduction of 'voltage source, voltage intensive' (VSVI) systems' by the invention of constant voltage generators in 1885. Ottó Bláthy also invented the AC electricity meter to complete the competition of AC and DC technology. Transformers today are designed on the principles discovered by the three engineers. They also popularized the word 'transformer' to describe a device for altering the emf of an electric current, although the term had already been in use by 1882. In 1886, the ZBD engineers designed, and the Ganz factory supplied electrical equipment for, the world's first power station that used AC generators to power a parallel connected common electrical network, the steam-powered Rome-Cerchi power plant. The reliability of the AC technology received impetus after the Ganz Works electrified a large European metropolis: Rome in 1886.
In North America one of the believers in the new technology was George Westinghouse. Westinghouse was willing to invest in the technology and hired William Stanley, Jr. to work on an AC distribution system using step up and step down transformers of a new design in March 1886 at Great Barrington. Stanley's alternating current transformer, central-station system for public service was the "very first in America beyond all dispute." Westinghouse tested it more during summer 1886 in Pittsburgh, over a distance of 3 miles. This system used an alternator designed by Stanley to replace the Siemens model, which regulated voltage poorly. Satisfied with the pilot system, Westinghouse began commercial production and shipped his company's first commercial plant to Buffalo NY, where a local utility placed it in service. Orders for 25 alternating-current plants followed within months.With Stanley leaving Westinghouse, Oliver Shallenberger took control of the AC project. In July 1888, George Westinghouse licensed Nikola Tesla's US patents for a polyphase AC induction motor and transformer designs and hired Tesla for one year to be a consultant at the Westinghouse Electric & Manufacturing Company's Pittsburgh labs. Westinghouse purchased a US patent option on induction motors from Galileo Ferraris in an attempt to own a patent that would supersede Tesla's. But with Tesla's backers getting offers from another capitalist to license Tesla's US patents, Westinghouse concluded that he had to pay the rather substantial amount of money being asked to secure the Tesla license. Westinghouse also acquired other patents for AC transformers from Lucien Gaulard and John Dixon Gibbs.
Commercial rivalry

Edison's publicity campaign


Edison carried out a campaign to discourage the use of alternating current, including spreading disinformation on fatal AC accidents, publicly electrocuting animals, and lobbying against the use of AC in state legislatures. Edison directed his technicians, primarily Arthur Kennelly and Harold P. Brown, to preside over several AC-driven killings of animals, primarily stray cats and dogs but also unwanted cattle and horses. Acting on these directives, they were to demonstrate to the press that alternating current was more dangerous than Edison's system of direct current. He also tried to popularize the term for being electrocuted as being "Westinghoused". Years after DC had lost the "war of the currents," in 1903, his film crew made a movie of the electrocution with high voltage AC, supervised by Edison employees, of Topsy, a Coney Island circus elephant which had recently killed three men.
Edison opposed capital punishment, but his desire to disparage the use of alternating current led to the invention of the electric chair. Harold P. Brown, who was being secretly paid by Edison, built the first electric chair for the state of New York to promote the idea that alternating current was deadlier than DC.
When the chair was first used, on August 6, 1890, the technicians on hand misjudged the voltage needed to kill the condemned prisoner, William Kemmler. The first jolt of electricity was not enough to kill Kemmler, and only left him badly injured. The procedure had to be repeated and a reporter on hand described it as "an awful spectacle, far worse than hanging." George Westinghouse commented: "They would have done better using an axe."

Willamette Falls to Niagara Falls
In 1889, the first long distance transmission of DC electricity in the United States was switched on at Willamette Falls Station, in Oregon City, Oregon. In 1890 a flood destroyed the Willamette Falls DC power station. This unfortunate event paved the way for the first long distance transmission of AC electricity in the world when Willamette Falls Electric company installed experimental AC generators from Westinghouse in 1890. That same year, the Niagara Falls Power Company (NFPC) and its subsidiary Cataract Company formed the International Niagara Commission composed of experts, to analyze proposals to harness Niagara Falls to generate electricity. The commission was led by Sir William Thomson (later Lord Kelvin) and included Eleuthère Mascart from France, William Unwin from England, Coleman Sellers from the US, and Théodore Turrettini from Switzerland. It was backed by entrepreneurs such as J. P. Morgan, Lord Rothschild, and John Jacob Astor IV. Among 19 proposals, they even briefly considered compressed air as a power transmission medium, but preferred electricity. But they could not decide which method would be best overall.

International Electro-Technical Exhibition
The International Electro-Technical Exhibition of 1891 featured the long distance transmission of high-power, three-phase electric current. It was held between 16 May and 19 October on the disused site of the three former “Westbahnhöfe” (Western Railway Stations) in Frankfurt am Main. The exhibition featured the first long distance transmission of high-power, three-phase electric current, which was generated 175 km away at Lauffen am Neckar. It successfully operated motors and lights at the fair.
When the exhibition closed, the power station at Lauffen continued in operation, providing electricity for the administrative capital, Heilbronn, making it the first place to be equipped with three-phase AC power.
Many corporate technical representatives (including E.W. Rice of Thomson-Houston Electric Company, what became General Electric) attended. The technical advisors and representatives were impressed.

AC deployment at Niagara
In 1893, NFPC was finally convinced by George Forbes to award the contract to Westinghouse, and to reject General Electric and Edison's proposal. Work began in 1893 on the Niagara Falls generation project: power was to be generated and transmitted as alternating current, at a frequency of 25 Hz to minimize impedance losses in transmission (changed to 60 Hz in the 1950s).
Some doubted that the system would generate enough electricity to power industry in Buffalo. Tesla was sure it would work, saying that Niagara Falls could power the entire eastern United States. When finished, the first Niagara River hydraulic tunnel would have a capacity to develop 75 MW. None of the previous polyphase alternating current transmission demonstration projects were on that scale of power:
·         The Lauffen-Neckar demonstration in 1891 had the capacity of 225 kW
·         Westinghouse successfully used AC in the commercial Ames Hydroelectric Generating Plant in 1891 at 75 kW (Single phase)
·         The Chicago World's Fair in 1893 exhibited a complete 11,000 kW polyphase generation and distribution system with multiple generators, installed by Westinghouse
·         Almirian Decker designed a three-phase 250 kW AC system at Mill Creek California in 1893.
On November 16, 1896, electrical power was transmitted to industries in Buffalo from the hydroelectric generators at the Edward Dean Adams Station at Niagara Falls. The generators were built by Westinghouse Electric Corporation using Tesla's AC system patent. The nameplates on the generators bore Tesla's name. To appease the interests of General Electric, they were awarded the contract to construct the transmission lines to Buffalo using the Tesla patents

Competition outcome
As a result of the successful field trial in the International Electro-Technical Exhibition of 1891, three-phase current, as far as Germany was concerned, became the most economical means of transmitting electrical energy.
In 1892, General Electric formed and immediately invested heavily in AC power (at this time Thomas Edison's opinions on company direction were muted by President Coffin and the GE board of directors). Westinghouse was already ahead in AC, but it only took a few years for General Electric to catch up, mainly thanks to Charles Proteus Steinmetz, a Prussian mathematician who was the first person to fully understand AC power from a solid mathematical standpoint. General Electric hired many talented new engineers to improve its design of transformers, generators, motors and other apparatus.
In Europe, Siemens & Halske became the dominant force. Three phase 60 Hz at 120 volts became the dominant system in North America while 220-240 volts at 50 Hz became the standard in Europe.
Alternating current power transmission networks today provide redundant paths and lines for power routing from any power plant to any load center, based on the economics of the transmission path, the cost of power, and the importance of keeping a particular load center powered at all times. Generators (such as hydroelectric sites) can be located far from the loads.

Remnant DC distribution systems
1947 advertisement for the Dremel Moto-Tool. Note the "AC-DC" designation.

Some cities continued to use DC well into the 20th century. In central Helsinki, there was a DC network in existence up until the late 1940s, and in the 1960s, Stockholm's dwindling DC network was eliminated. A mercury-arc valve rectifier station could convert AC to DC where networks were still used. In 1942, the Greenwich Village neighborhood in New York City used DC. Parts of Boston, Massachusetts along Beacon Street and Commonwealth Avenue still used 110 volts DC in the 1960s, causing the destruction of many small appliances (typically hair dryers and phonographs) used by Boston University students, who ignored warnings about the electricity supply. New York City's electric utility company, Consolidated Edison, continued to supply direct current to customers who had adopted it early in the twentieth century, mainly for elevators. The New Yorker Hotel, constructed in 1929, had a large direct-current power plant and did not convert fully to alternating-current service until well into the 1960s. This was the building in which AC pioneer Nikola Tesla spent his last years, and where he died in 1943. In January 1998, Consolidated Edison started to eliminate DC service. At that time there were 4,600 DC customers. By 2006, there were only 60 customers using DC service, and on November 14, 2007, the last direct-current distribution by Con Edison was shut down.[49][53] Customers still using DC were provided with on-site AC-to-DC rectifiers. The city of San Francisco, California featured a DC power grid to supply power for pre-1940s winding-drum elevators. Around the end of 2010, the DC grid was divided into 171 separate islands with each island supplying 7 to 10 customers.

The Central Electricity Generating Board in the UK continued to maintain a 200 volt DC generating station at Bankside Power Station on the River Thames in London as late as 1981. It exclusively powered DC printing machinery in Fleet Street, then the heart of the UK's newspaper industry. It was decommissioned later in 1981 when the newspaper industry moved into the developing docklands area farther down the river (using modern AC-powered equipment). The building was converted into an art gallery, the Tate Modern.
Electric railways that use a third-rail system generally employ DC power between 500 and 750 volts; railways with overhead catenary lines use a number of power schemes including both high-voltage AC and high-current DC.

Long distance DC power transmission

High-voltage direct current (HVDC) systems are used for bulk transmission of energy from distant generating stations, or for interconnection of separate alternating current systems. These HVDC systems use electronic devices like mercury-arc valves, thyristors, or IGBTs that were unavailable during the War of Currents era. Power is converted to and from alternating current at each side of the HVDC link. An HVDC system can transmit more power over a given right-of-way than an AC system, which is an advantage in overall cost. HVDC systems allow better control of power flows in transient and emergency conditions, which help prevent blackouts. HVDC is an alternative to AC systems for long-distance, high-load transmission.

DC uses

DC power is still common when distances are small, and especially when energy storage or conversion uses batteries or fuel cells. Some of these applications include electronic devices, Vehicle starting, lighting, and ignition systems. "Off-grid" isolated power installations using wind or solar power may use DC between sources and loads, over limited distances. One concept for use in a computer data center would power individual processing units from a DC system distributed around a computer room or building. This would eliminate individual system rectifiers. The distributed DC system would eliminate some energy losses associated with individual computer power supply rectifiers. By feeding the system from batteries, the cost and unreliability of individual uninterruptible power supplies (UPS) would be reduced. The 380 volt level is compatible with the typical ratings of components now used in computer power supplies.[55] Similarly, copper telephone lines can be used to transmit network line power at 380 volts DC for long distances, which then can be converted to lower voltages to power outdoor electronic equipment. Power and safety standards for network line power (NLP) technology are defined in the National Electric Code (NEC) Article 830.


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