2009年1月22日星期四

Hydraulic ram


A hydraulic ram, or hydram, is a cyclic water pump powered by hydropower. It functions as a hydraulic transformer that takes in water at one hydraulic head and flow-rate, and outputs water at a different hydraulic-head and flow-rate. The device utilizes a phenomenon called stagnation pressure, also known as water hammer, that is based on Bernoulli's principle. In operation, a portion of the input water that powers the pump is lifted to a point higher than where the water originally started. The hydraulic ram is sometimes used in remote areas, where there is both a source of low-head hydropower, and a need for pumping water to a destination higher in elevation than the source. In this situation, the ram is often useful, since it requires no outside source of power other than the kinetic energy of water.

History
In 1772 John Whitehurst of Cheshire in the United Kingdom invented a manually controlled precursor of the hydraulic ram called the "pulsation engine". The first one he installed, in 1772 at Oulton, Cheshire, raised water to a height of 16 ft (4.9 m). He installed another in an Irish property in 1783. He did not patent it, and details are obscure, but it is known to have had an air vessel.

The first self-acting ram pump was invented by the Frenchman Joseph Michel Montgolfier in 1796 for raising water in his paper mill at Voiron. His friend Matthew Boulton took out a British patent on his behalf in 1797. The sons of Montgolfier obtained an English patent for an improved version in 1816, and this was acquired, together with Whitehurst's design, in 1820 by Josiah Easton, a Somerset-born engineer who had just moved to London.

Easton's firm, inherited by his son James (1796–1871), grew during the nineteenth century to become one of the more important engineering manufacturers in the United Kingdom, with a large works at Erith, Kent. They specialised in water supply and sewerage systems world-wide, as well as land drainage projects. Eastons had a good business supplying rams for water supply purposes to large country houses, and also to farms and village communities, and a number of their installations still survived as of 2004.

The firm was eventually closed in 1909, but the ram business was continued by James R Easton. In 1929 it was acquired by Green & Carter, of Winchester, Hampshire, who were engaged in the manufacturing and installation of the well-known Vulcan and Vacher Rams.

The first US patent was issued to J. Cerneau and S.S. Hallet in 1809. US interest in hydraulic rams picked up around 1840, as further patents were issued and domestic companies started offering rams for sale. Toward the end of the 19th Century, interest waned as electricity and electric pumps became widely available.

By the end of the twentieth century interest in hydraulic rams has revived, due to the needs of sustainable technology in developing countries, and energy conservation in developed ones. A good example is AID Foundation International in the Philippines, who won an Ashden Award for their work developing ram pumps that could be easily maintained for use in remote villages. The hydraulic ram principle has been used in some proposals for exploiting wave power, one of which was discussed as along ago as 1931 by Hanns Günther in his book In hundert Jahren.

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Protection and monitoring of the electrical energy transmission networks

Large interconnected electrical networks require protection and monitoring of the electrical energy transmission networks. Electrical energy supply systems have three parts:

• Generating units, i. e. the power plants

• High voltage transmission networks moving large quantities of energy to distant consumers and maintaining synchronisation of the power system

• Medium voltage and low voltage distribution networks, supplying the customers.

Failures may occur in each part, such as insulation failure, fallen or broken transmission lines, incorrect operation of circuit breakers, short circuits and open circuits. Protection devices are installed with the aims of protection of assets, and ensure continued supply of energy. The three classes of protective devices are:

• Protective relays control the tripping of the circuit breakers surrounding the faulted part of the network

• Automatic operation, such as auto-reclosing or system restart

• Monitoring equipment which collects data on the system for post event analysis

While the operating quality of these devices, and especially of the protective relays, is always critical, different strategies are considered for protecting the different parts of the system. Very important equipment may have completely redundant and independent protective systems, while a minor branch distribution line may have very simple low-cost protection.

Protection of the generator sets
In a power plant, the protective relays are intended to prevent damage to alternators or of the transformers in case of abnormal conditions of operation, due to internal failures, as well as insulating failures or regulation malfunctions. Such failures are unusual, so the protective relay have to operate very rarely.

If a protective relay fails to detect a fault, the damage to the alternator or to the transformer may have important financial consequences for the repair or replacement of equipment and the value of the energy that otherwise would have been sold.


Protection of the high voltage transmission network
Protection on the transmission and distribution serves two functions: Protection of plant and protection of the public (including employees)

At a basic level protection looks to remove items of plant from service which experience an overload or a connection to earth. Some items in substations such as transformers may require additional protection based on temperature or gassing among others.

Overload protection
Overload protection requires a current transformer which simply measures the current in a circuit. If this current exceeds a pre-determined level a circuit breaker or fuse should operate.

Earth fault protection
Earth fault protection again requires current transformers and senses an imbalance in a three phase circuit. Normally a three phase circuit is in balance, so if a single (or multiple) phases are connected to earth an imbalance in current is detected. If this imbalance exceeds a pre-determined value a circuit breaker should operate.

Distance Protection
Distance protection detects both voltage and current. A fault on a circuit will generally create a sag in the voltage level. If this voltage falls below a pre-determined level and the current is above a certain level the circuit breaker should operate. This is useful on long lines where if a fault was experienced at the end of the line the impedence of the line itself may inhibit the rise in current. Since a voltage sag is required to trigger the protection the current level can actually be set below the normal load on the line.

Back Up Protection
At all times the objective of protection is too remove only the affected portion of plant and nothing else. Sometimes this does not occur for various reasons which acn include:

Mechanical failure of a circuit breaker to operate
Incorrect protection setting
Relay failures
A failure of primary protection will usually result in the operation of back-up protection which will generally remove both the affected and unaffected items of plant to remove the fault.

Protection of the low voltage networks
The low voltage network generally relies upon fuses or low voltage circuit breakers to remove both overload and earth faults.

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Flyback converter


The flyback converter is a DC to DC converter with a galvanic isolation between the input and the output(s). More precisely, the flyback converter is a buck-boost converter with the inductor split to form a transformer, so that the voltage ratios are multiplied with an additional advantage of isolation. When driving for example a plasma lamp or a voltage multiplier the rectifying diode of the Buck-Boost converter is left out and the device is called a flyback transformer.

Structure and principle
The schematic of a flyback converter can be seen in figure 1. It is equivalent to that of a buck-boost converter, with the inductor split to form a transformer . Therefore the operating principle of both converters is very close:

When the switch is on (see figure 2), the primary of the transformer is directly connected to the input voltage source. This results in an increase of magnetic flux in the transformer. The voltage across the secondary winding is negative, so the diode is reverse-biased (i.e blocked). The output capacitor supplies energy to the output load.
When the switch is off, the energy stored in the transformer is transferred to the output of the converter.

Operation
The flyback converter is an isolated power converter, therefore the isolation of the control circuit is also needed. The two prevailing control schemes are voltage mode control and current mode control. Both require a signal related to the output voltage. There are two common ways to generate this voltage. The first is to use an optocoupler on the secondary circuitry to send a signal to the controller. The second is to wind a separate winding on the coil and rely on the cross regulation of the design.

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Electromagnetic compatibility

Electromagnetic compatibility (EMC) is the branch of electrical sciences which studies the unintentional generation, propagation and reception of electromagnetic energy with reference to the unwanted effects (Electromagnetic Interference, or EMI) that such energy may induce. The goal of EMC is the correct operation, in the same electromagnetic environment, of different equipment which use electromagnetic phenomena, and the avoidance of any interference effects.

In order to achieve this, EMC pursues two different kinds of issues. Emission issues are related to the unwanted generation of electromagnetic energy by some source, and to the countermeasures which should be taken in order to reduce such generation and to avoid the escape of any remaining energies into the external environment. Susceptibility or immunity issues, in contrast, refer to the correct operation of electrical equipment, referred to as the victim, in the presence of unplanned electromagnetic disturbances.

Interference, or noise, mitigation and hence electromagnetic compatibility is achieved primarily by addressing both emission and susceptibility issues, i.e., quieting the sources of interference and hardening the potential victims. The coupling path between source and victim may also be separately addressed to increase its attenuation.

Types of Interference
Electromagnetic interference divides into several categories according to the source and signal characteristics.

The origin of noise can be man made or natural.


Continuous Interference
Continuous Interference arises where the source regularly emits a given range of frequencies. This type is naturally divided into sub-categories according to frequency range, and as a whole is sometimes referred to as "DC to daylight".

Audio Frequency, from very low frequencies up to around 20 kHz. Frequencies up to 100 kHz may sometimes be classified as Audio. Sources include:
Mains hum from power supply units, nearby power supply wiring, transmission lines and substations.
Radio Frequency Interference, RFI, from 20 kHz to a limit which constantly increases as technology pushes it higher. Sources include:
Wireless and Radio Frequency Transmissions
Television and Radio Receivers
Industrial, scientific and medical equipment
High Frequency Circuit Signals (For example microcontroller activity)
Broadband noise may be spread across parts of either or both frequency ranges, with no particular frequency accentuated. Sources include:
Solar Activity
Continuously operating spark gaps such as arc welders

Pulse or Transient Interference
Electromagnetic Pulse, EMP, also sometimes called Transient disturbance, arises where the source emits a short-duration pulse of energy. The energy is usually broadband by nature, although it often excites a relatively narrow-band damped sine wave response in the victim.

Sources divide broadly into isolated and repetitive events.

Sources of isolated EMP events include:
Switching action of electrical circuitry.
Electrostatic Discharge (ESD), as a result of two charged conductors coming into close proximity or even contact.
Lightning Electromagnetic Pulse (LEMP)
Nuclear Electromagnetic Pulse (NEMP), as a result of a nuclear explosion.
Non-Nuclear Electromagnetic Pulse, NNEMP weapons.
Power Line Surges/Pulses
Sources of repetitive EMP events, sometimes as regular pulse trains, include:
Electric Motors
Electric Fast Transient/Bursts (EFT)

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Funny Farm (webcomic)

Funny Farm is a webcomic authored by Ryan Smith (R. Smith) and hosted by Keenspot. The comic details the lives of a group of anthropomorphic animals, who live on a boarding house owned by Ront and Mewn. The author has explained the apparent peculiarity of having humans and anthropomorphic animals coexisting. The main characters are in fact humans just like everyone else. It is merely in the mind of the reader that they appear as animals because this to some extent reflects their personal characteristics.

The story started as a simple gag-a-day webcomic, with characters starting to live on the boarding house, but it soon began to become something of greater proportions, and the life of the cast started to get more and more complicated; for example, there is a masked terrorist, a super-computer who intends to rule the world, giant corporations battling for power, and a psychotic pet monkey.

One of the characteristics of the webcomic are the fan-made comic jams, which are comics drawn by persons other than Ryan Smith. These comics are published on the Funny Farm forum and each artist takes turns to make one, followed immediately (though 'immediately' tends to mean 'within months') by another artist, making an overall very complex and strange story outside continuity. There are many running-gags on this, like making the appearance of characters as Naked Anime Flying Kitty, Pirate Mewn, or Millena Marvel, and making Naked Anime Flying Kitty speak many languages.

On January 16 2006 R. Smith began publishing his second webcomic, Banished, with Jamie Anderson as the artist. After a brief hiatus at the end of chapter 5 (December 6 2006), chapter 6 began January 22 2007 with Brandon Zuckerman as the new artist and Megan M. Risbergs as colourist.

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Glanford Brigg Power Station


Glanford Brigg Power Station, also known as Glanford Brigg Generating Station is a 240 megawatt (MW) gas-fired power station located between the towns of Brigg and the villages of Scawby and Hibaldstow, on the River Ancholme in North Lincolnshire, England.

History
Construction of the power station started in late 1991 and it was opened in December 1993. It was built just south of a former British Sugar sugar beet factory, which is the planned location of Brigg Renewable Energy Plant[1]. Initially, it was owned by Yorkshire Electricity, but operated by a Finnish company, Fortum, under the name Regional Power Generators Ltd. In 2000 it was bought by Fortum, who were then known as IVO Energy. In July 2002 the plant was bought by Centrica for £37 million, with the operating company known as Centrica Brigg Ltd.

Operations
Glanford Brigg power station is a natural gas, combined cycle gas turbine power station with four gas turbines, four heat recovery steam generators, and two steam turbines, divided into two modules. It can produce 240 MW of base load electricity and 272 MW at peak load, from a thermal input of around 515 MW. In the event of interruption of main fuel supply, it can burn diesel instead. It can run at a maximum thermal efficiency of 46.8% when on constant running; the actual efficiency depends on factors in the local weather conditions such as temperature and humidity. It is used to fulfill peak load requirements from the National Grid, as the electricity output can be decreased when demand is less. Each gas turbine and both steam turbines are connected to a 40 MW electrical generator (alternator).

The station's four chimneys are 70 m (230 ft) high. The gas turbines are a General Electric Frame 6 MS6001B type, producing 39.16 MW at 31.6% thermal efficiency. They rotate at 5135 Revolutions per minute (rpm), and are connected via a gearbox to the electrical generator revolving at 3000rpm. Exhaust gas reaches the steam generator at 541°C. The gas turbine electrical generators are rated at 50.2 MVA, with a terminal voltage of 11 kilovolts (kV). The electricity enters the National Grid via a transformer at 132 kV.

The station falls within the supply area formerly ran by Yorkshire Electricity, with distribution currently run by CE Electric UK. The site employs thirty six people.

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Electrical bonding

Electrical bonding is the practice of intentionally electrically connecting all metallic non-current carrying items in a room or building as protection from electric shock. If a failure of electrical insulation occurs, all metal objects in the room will have the same electrical potential, so that an occupant of the room cannot touch two objects with significantly different potentials. Even if the connection to a distant earth ground is lost, the occupant will be protected from dangerous potential differences.

Bonding refers to the fact that in a building with electricity it is normal for safety reasons to connect all metal objects such as pipes together to the mains earth to form an equipotential zone. This is done in the UK because many buildings are supplied with a single phase supply cable where the neutral and earth conductors are combined. Close to the electricity meter this conductor is divided into two, the earth terminal and the wire going to the neutral busbar in the consumer unit. In the event of a break in a neutral connection this earth terminal provided by the supply company will be at a potential (relative to the true earth) which is the same as the live wire (phase wire) coming to the home.

Examples of articles that may be bonded include metallic water piping systems, gas piping, ducts for central heating and air conditioing systems, and exposed metal parts of buildings such as hand rails, stairs, ladders, platforms and floors.

If a person was to touch the metal (earthed casing) of an electrical device during the a fault condition and be in contact with a metal object connected to a remote earth then they would get an electric shock. If all metal objects are connected together, all the metal objects in the building will be at the same potential. It then will not be possible to get a shock by touching two 'earthed' objects at once.

Bonding is particularly important for swimming pools and fountains. In pools and fountains, any metallic object (other than conductors of the power circuit)over a certain size must be bonded to assure that all conductors are equipotential and do not provide a hazardous conductive path. SInce is is buried in the ground, a pool can be a better ground than the electric panel ground. With all the conducting elements bonded, it is less likely that electric current will find a path through a swimmer. In concrete pools even the reinforcing bars of the concrete must be connected to the bonding system to ensure no dangerous potential gradients are produced during a fault.


How the earth protects
In a system with a grounded (earthed) neutral, connecting all non-current-carrying metallic parts of equipment to earth ground at the main service panel, will ensure that current due to faults (such as a "hot" wire touching the frame or chassis of the device) will be diverted to earth. In a TN system where there is a direct connection from the installation earth to the transformer neutral, earthing will allow the branch circuit overcurrent protection (a fuse or circuit breaker) to detect the fault rapidly and interrupt the circuit.

In the case of a TT system where the impedance is high due to the lack of direct connection to the transformer neutral, an RCD (Residual-Current Device, sometimes known as a Residual Current Circuit Breaker or Ground Fault Circuit Interrupter) must be used to provide disconnection. RCDs are also used in other situations where rapid disconnection of small earth faults (including a human touching a live wire by accident, or damage) is desired.


Equipotential bonding
Equipotential bonding involves joining together metalwork that is or may be earthed so that it is at the same potential (i.e., voltage) everywhere. Such is commonly used under transformer banks by power companies and under large computer installations.

Equipotential bonding is done from the Service Panel consumer unit (also known as a fuse box, breaker box, or distribution board) to incoming water and gas services. It is also done in bathrooms where all exposed metal that leaves the bathroom including metal pipes and the earths of electrical circuits must be bonded together to ensure that they are always at the same potential. Isolated metal objects including metal fittings fed by plastic pipe (water in a thin pipe is actually a very poor conductor) are not required to be bonded. European and North American practices differ here; equipotential bonding in bathrooms is not required by North American codes, although it is required around swimming_pools.

In Australia and South Africa, a house's earth cables must be connected both to an earthing rod/stake driven into the ground and also to the plumbing.

Exact rules for electrical installations vary by country, locality, or supplying power company.

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Dispatcher training simulator

A dispatcher training simulator (DTS), also known as an operator training simulator, is a computer-based training system for operators (known as dispatchers) of electrical power grids.It performs this role by simulating the behaviour of the electrical network forming the power system under various operating conditions, and its response to actions by the dispatchers.Student dispatchers may therefore develop their skills from exposure not only to routine operations but also to adverse operational situations without compromising the security of supply on a real transmission system.

Description
Early simulations modelled the transmission system with banks of analog computers linked by scaled-down representations of the interconnecting lines. The operator would simulate the operation of circuit breakers by physically operating their miniature replicas. As transmission systems grew in size and complexity, they could no longer be adequately represented in this manner, and computerised simulations came to the fore.

A modern DTS combines or simulates the following elements:

An energy management system (EMS): a computer system for controlling a power grid. The EMS enables remote operation of electrical equipment, such as circuit breakers or transformers. It also receives information transmitted back to an electricity control centre, such as the status of equipment or notification of alarms. The user interface typically displays the state of the transmission system on computerised one-line diagrams with controllable points for simulated operation of plant such as circuit breakers or transformer tap-changers.
A SCADA (Supervisory control and data acquisition) system, which provides collection and assimilation of data from substations and transmits operator instructions back to the same plant.
A load-flow study to calculate power flows and voltages on the transmission system and to model its responses to disturbances such as line trips, relay action, and generator-demand mismatch. The model will normally extend to the limits of the system operator's region of interest, and include representations of plant such as lines, generators, transformers, circuit breakers and capacitors.
The system may additionally provide facilities for modelling and optimising the economic dispatch of generating units. Any generation's dynamic characteristics and limits, in particular its voltage regulation, maximum generation, and rate of change of output are usually incorporated.

Operation
A DTS is frequently purchased by a customer (such as a transmission system operator) at the same time and from the same manufacturer as an energy management system, and is usually designed to mimic it as closely as possible. Operational scenarios are created on the DTS to represent the operator's transmission system under a variety of conditions. These may represent normal operating conditions, or be specially designed to test the student's responses to adverse circumstances, such as frequent line trips during severe weather. The DTS is administered by a team of instructors, who select scenarios and simulate operational events, monitoring the trainee's actions in response.

Scenarios may also represent circumstances that the system operator hopes never occur, such as complete system shut-down, and allow it to develop strategies for restoration of service (known as black start).

Deficiencies in operator training were identified as a contributory cause of the 2003 North American blackout, a factor similarly connected to earlier power failures. The joint US-Canadian task force investigating the incident recommended mandatory periods of simulation time for operators, and validation of the models against actual system characteristics.

To enable the training simulator to respond as realistically as possible to the student's actions, the power flow study at its heart must run on a frequent time basis, such as every few seconds. The simulation may model electrical networks consisting of many thousands of nodes and containing several hundred generating units.

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Song Audio


Song Audio Ltd. is a specialist high-end audio equipment manufacturer, importer, and distributor based in Canada. Song Audio manufactures vacuum tube preamplifiers, power amplifiers, and loudspeakers and imports solid-state integrated amplifiers under the marque Vasant_K from Thailand. Song Audio also distributes and supports Loth-X loudspeakers in Canada, though the original manufacturer has since closed operations in Singapore.

History
In 2001, Song Audio was established by its eponymous founder, Song Kim, in Toronto, Canada. In North America, Song Audio was one of the first to source manufacture of high-end products from Thailand (esp. Vasant_K). Song Audio was also one of the first to import and distribute single-driver crossover-less high sensitivity loudspeakers from Asia (Loth-X from Singapore). Currently, the renaissance of low power triode output vacuum tube amplifiers and single-driver loudspeakers is more established in Asian and European markets, but interest is gradually increasing in North America.

Being a specialist company, Song Audio produces its products in limited quantities and distributes primarily in North America. The Company is recognised as decidedly non-mainstream, even within the high-end community; for example, it avoids parallel design in output tubes on purist grounds and does not provide remote control handsets in its products. The Company adopts a longevity approach to its products by not phasing any out of production (its earliest products are still in production) and supports their usage world-wide by having a user-adjustable internal voltage switch between 120V/60Hz (North America) and 220V/50Hz (Europe and Asia).

Research and Development
Pre/Power & Integrated Amplifiers
In Song Audio vacuum-tube amplification equipment, the model number prefix 'SA' refers to its corporate acronym; the suffix 'MB' indicates 'monoblock' amplifier and 'SB' indicates 'stereoblock' amplifier.

Though Song Audio produces a flagship preamplifier (SA-1) with separate power supply and single-ended triode zero negative feedback 300B output monoblock power amplifier (SA-300MB), the Company's primary contribution to the typology of vacuum-tube power amplification is the SA-34SB (2003-) integrated amplifier (upper right), now in 'Cecilia' edition (lower right) made in Canada. It is one of the first in absolute purist design consisting of single-ended triode operation with zero negative feedback utilising the EL34 output vacuum tube (which is especially difficult to operate in triode mode without negative feedback). Currently, the only other such similar design appears to be from Decware in U.S.A.

The SA-34SB is somewhat unusual in aspects of its construction, including: proprietary transformer winding, bronze chassis in the original SA-34SB integrated amplifier, high-density acrylic front plate in the 'Cecilia' edition (which frequently breaks drill bits during its construction), lavish use of 18K gold plating, and solid wood side panels instead of wood veneer. By contrast to conventional wisdom of using a single sub-woofer, the Company advises using a mono pair of sub-woofers since the source of bass is directional in a live performance (the bass tends to originate from the right side of stage in an orchestra). For this reason, the SA-34SB provides stereo variable RCA outputs to independently connect a pair of sub-woofers to augment the loudspeakers without the interference of a crossover to them.

For signal wiring, Song Audio has experimented with 98% pure solid-core silver and cryogenic-treated silver plated oxygen-free copper in its circuit wiring and AC power cords; presently, the Company uses both methods in its products. For connections to AC plugs, the Company uses both audio-grade and hospital-grade connectors together with a locking hospital-grade duplex outlet (as provided with Vasant_K).

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Surge protector


A surge protector is an appliance designed to protect electrical devices from voltage spikes. A surge protector attempts to regulate the voltage supplied to an electric device by either blocking or by shorting to ground voltages above a safe threshold. The following text discusses specifications and components relevant only to the type of protector that diverts (shorts) a voltage spike to ground.

Many power strips have surge protection built-in; these are typically clearly labeled thus. However, sometimes power strips that do not provide surge protection are erroneously referred to as surge protectors.

Important specifications
Some specifications which define a surge protector for AC mains and some communication protection.

Clamping voltage — better known as the let-through voltage. This specifies what voltage will cause the metal oxide varistors (MOVs) inside a protector to conduct electricity to the ground line. A lower clamping voltage indicates better protection, but a shorter life expectancy. The lowest three levels of protection defined in the UL rating are 330 V, 400 V and 500 V. The standard let-through voltage for 120 V AC devices is 330 volts.
Joules — This number defines how much energy the surge protector can absorb without failure. A higher number indicates greater protection and longer life expectancy because the device will divert more energy elsewhere and will absorb less energy. More joules conducting the same surge current means a reduced clamping voltage. Generally, 200 joules is undersized protection since harmful voltage spikes are significantly larger than 200 joules. Better protectors start at 1000 joules and 50,000 amperes. If properly installed, for every joule absorbed by a protector, another 4 or 30 joules may be dissipated harmlessly into ground.
Response time — Surge protectors don't kick in immediately; a slight delay exists. The longer the response time the longer the connected equipment will be exposed to the surge. However, surges don't happen immediately either. Surges usually take around a few microseconds to reach their peak voltage and a surge protector with a nanosecond response time would kick in fast enough to suppress the most damaging portion of the spike .
Surge current in kiloamperes (see Joules above).
Standards — The surge protector may meet IEC 61643-1, BS6651, Telcordia TR-NWT-001011, ANSI / IEEE C62.xx, or UL1449. Each standard defines different protector characteristics, test vectors, or operational purpose. For example, a protector may obtain UL1449 approval even though it fails during testing. That standard tests only for fire hazards and other safety threats. Irrelevant to that approval test is whether the protector actually provides protection throughout testing. BS6651 and ANSI / IEEE C62.xx define what spikes a protector might be expected to divert. IEC only writes standards and does not certify any product to meet those standards. None of those standards say a protector will provide proper protection. Each standard defines what a protector should do or might accomplish.

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Semi-trailer truck


A semi-trailer truck, also known as tractor-trailer or (in the United Kingdom and Ireland) articulated lorry, is an articulated truck or lorry consisting of a towing engine (tractor in the United States, prime mover in Australia, and truck in the UK, Canada and New Zealand), and a semi-trailer (plus possible additional trailers) that carries the freight.

Colloquial terms for semi-trailer truck include truck and trailer, transfer truck, 18-wheeler, semi, Diesel, Mack truck (named for a prominent brand), big rig (US), transport (Canada), artic (UK and Ireland), and juggernaut (UK).

Regional Configurations
In North America, semi tractors usually have 3 axles, the front, or "steer", axle having two wheels, and each of the two rear, "drive", axles having a pair of "dualies" (double) wheels on each side. Thus, the most common configuration of tractor has 10 wheels, however in some cases dual wheels are replaced by tires known as "super singles" or Wide-base singles, to reduce the weight of the tractor. In this case the tractor will only have six wheels. "Super singles" are substantially wider than normal tires. A smaller tractor, having a single drive axle (six wheeler) is often used to pull shorter trailers in tight urban environments, such as downtown areas where a 60-foot rig would be too difficult to maneuver. These tractors are referred to as day cabs and do not have sleepers.

The cargo trailer usually has two "tandem" axles at the rear, each of which has dual wheels, or 8 wheels on the trailer. Many trailers are equipped with movable tandems that can be set to balance the weight of the trailer to stay within legal limits.

Although the cargo's weight added to the semi's weight can equal a certain amount of gross some roads are marked with a different gross restriction so the roads are not damaged. Cargos that exceed allowed weights are usually marked with overweight load and must obtain a permit to use certain roads.

Rules governing the maximum size and weight of vehicles differ among states in the US. However, since the majority of hauling is done on the interstate system, the vast majority of trucks and trailer made in the US are built to the specifications of the Department of Transportation (D.O.T.) which governs the use of the interstate system. The D.O.T. has established vehicle limits of: 102 inches wide, 13.5 feet in height, and 80,000 lbs gross weight. These limits can be exceeded as individual states have the right to issue temporary oversize and/or overweight permits.

Trailer dimensions vary greatly depending on amount and type of cargo it was designed to haul. See types of trailers under Construction below.

Although dual wheels are most common, use of a single, wider tire (known as "super singles") on each axle is becoming popular, particularly among bulk cargo carriers and other weight-sensitive operators. The advantages of this configuration are dual: the lighter tire weight allows a truck to be loaded with more freight, and the single wheel covers less of the brake unit, which allows faster cooling. The biggest disadvantage is that when a tire becomes deflated or destroyed, it is not possible to drive the vehicle to a service location without risking damage to the rim, as it is with dual wheels.

The United States also allows 2-axle tractors to tow two 1-axle 28.5-foot (8.7 m) semi-trailers known officially as STAA doubles and colloquially as doubles, a set, or a set of joints on all highways that are part of the National Network. The second trailer in a set of doubles uses a converter gear, also known as a con-gear or dolly. This apparatus supports the front half of the second trailer. Individual states may further allow longer vehicles (known as "longer combination vehicles" or LCVs), and may allow them to operate on roads other than those part of the National Network.

LCV types include:

Triples: Three 28.5-foot (8.7 m) trailers; maximum weight up to 129,000 pounds (58.5 t).
Turnpike Doubles: Two 48-foot (14.6 m) trailers; maximum weight up to 147,000 pounds (66.7 t)
Rocky Mountain Doubles: One 40 (12.2 m) to 53 (16.2 m) foot trailer (though usually no more than 48 feet) and one 28.5-foot (8.7 m) trailer (known as a "pup"); maximum weight up to 129,000 pounds (58.5 t)
In Canada, a Turnpike Double is two 53-foot trailers and a Rocky Mountain Double is a 50-foot trailer with 24-foot "pup"
Regulations on LCVs vary widely from state to state. No state allows more than three trailers without a special permit. Reasons for limiting the legal trailer configurations include both safety concerns and the impracticality of designing and constructing roads that can accommodate the larger wheelbase of these vehicles and the larger minimum turning radii associated with them.

Most states restrict operation of larger tandem trailer setups such as triple units, the "Turnpike Double" (twin 48-53 ft units) or the "Rocky Mountain Double." (A full 48-53 ft unit and a shorter 28 ft unit) In general, these types of setups are restricted to tolled turnpikes such as I-80 through Ohio and Indiana, and select Western states. Tandem setups are not restricted to certain roads anymore than a single setup. The exception are the units listed above. They are also not restricted because of weather or "difficulty" of operation.

The long-haul tractors used in interstate travel are often equipped with a "sleeper" behind the driver's cab, which can be anything from a small bunk to a rather elaborate miniature apartment.

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Irish pork crisis of 2008


The Irish pork crisis of 2008 is an ongoing situation in Ireland that has led to an international recall of pork products from Ireland dating from September to December of that year. It was disclosed in early December 2008 that contaminated animal feed supplied by one Irish manufacturer to thirty-seven beef farms and nine pig farms across Republic of Ireland, and eight beef farms and one dairy farm in Northern Ireland, had caused the contamination of pork with between 80 and 200 times the EU's recommended limit for dioxins and dioxin-like PCBs i.e. 0.2 ng/g TEQ fat (0.2 ppb). The Food Safety Authority of Ireland moved on 6 December to recall from the market all Irish pork products dating from 1 September 2008 to that date. The contaminated feed that was supplied to forty-five beef farms across the island was judged to have caused no significant public health risk, accordingly no recall of beef was ordered. Also affected was a dairy farm in Northern Ireland; some milk supplies were withdrawn from circulation.

Within days thousands of jobs were either lost or under threat at pig processing plants across the country as processors refused to resume slaughter of pigs until they received financial compensation. Pork supplies to a total of twenty-three countries have thus far been affected, thirteen within the European Union and the remainder outside in an area across at least three continents. Countries blacklisted are Italy, Germany, the Netherlands, Poland, Sweden, Denmark, Belgium, Estonia, the UK, France, Portugal, Cyprus, Romania, Russia, the United States, Canada, Switzerland, China, South Korea, Japan and Republic of Singapore.

It is now suspected that the oil that contaminated the offending pig feed with dioxins came from County Tyrone. Some reports suggest the recovery of the Irish pork market will take up to a decade.The Irish government has been criticised over their handling of the incident.

On the 18 December 2008 it was disclosed that the beef samples from the affected farms had dioxin levels between 100 and 400 times the legal limit. However the Irish authorities insisted that the threat to public health from Irish beef products, even though the dioxin levels were higher than in the affected pork, was insignificant.

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2009年1月19日星期一

Phase converter

A phase converter is a device that converts power provided as single or multiple phases to a different number of phases. The majority of phase converters are used to produce three phase electrical power from a single-phase source, thus allowing the operation of three-phase equipment at a site that only has single-phase electrical service. Phase converters are used where three-phase service is not available from the utility, or is too costly to install due to a remote location. A utility will generally charge a higher fee for a three-phase service because of the extra equipment for transformers and metering and the extra transmission wire.

Three phase induction motors may operate adequately on an unbalanced supply if not heavily loaded. This allows various imperfect techniques to be used. A single-phase motor can drive a three-phase generator, which will produce a high-quality three-phase source but with high cost for apparatus. Several methods exist to run three-phase motors from a single-phase supply, these can in general be classified as:

Electronic means of creating three phase where the incoming power is rectified, and the three phase power is synthesized with electronics. Power electronic devices directly produce a three-phase waveform from single-phase power, using a rectifier and inverter combination. This also offers the advantage of variable frequency.
A digital phase converter uses a rectifier and inverter to create a single voltage with power electronics, which is added to the two legs of the single-phase source to create three-phase power. Unlike a phase converting VFD, it cannot vary the frequency and motor speed since it generates only one leg which must match the voltage and frequency of the single-phase supply. It does have the advantage of a sine-wave output voltage and excellent voltage balance between the phases.
Rotary phase converters constructed from a three-phase electric motor or generator "idler". These normally require some kind of starting aid and capacitors to improve phase balance and power factor. This is a two motor solution. One motor is not connected to a load and produces the three phase power, the second motor driving the load runs on the power produced.
Static conversion techniques in which the motor is run at less than full efficiency mainly on two of the legs of the three phase motor. Current is sometimes injected into the third leg with a capacitor or transformer arrangements that provide imperfect phase shift. In these systems the motor must be derated.
Methods in which the connection of the windings of the motor, normally a wye and or delta configurations, are replaced with novel connections. These techniques are covered in patents of Dr. Otto J. M. Smith, such as 5,545,965. Aug. 13, 1996. “Three Phase Motor Operated From a Single-Phase Power Supply and Phase Converter”.
Each of the above methods has its own set of advantages and drawbacks.


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High leg delta


A high leg delta (also known as wild-leg or red-leg delta) is a type of electrical service connection sometimes found in older three-phase electric power installations. It was used where both lighting and three-phase motor loads were to be fed from the same distribution system.

This type of service is supplied by a transformer having four wires coming out of the secondary: the three phases, plus a neutral that is used to center-tap one of the windings. The voltages between the three phases are the same in magnitude, however the voltage magnitudes between a particular phase and the neutral vary. The phase-to-neutral voltage of two of the phases will be half of the phase-to-phase voltage. The remaining phase-to-neutral voltage will be √3 times half the phase-to-phase voltage. Typically, the transformer is connected such that the 'B' phase is the 'high' leg. According to Article 110.15 of the 2005 National Electrical Code, panelboards connected to this type of transformer must explicitly identify the high leg, preferably by coloring it orange.

Advantages
This type of services is usually supplied using 240V line-to-line and 120V phase to neutral. In some ways, the high leg delta service provides the best of both worlds: a line-to-line voltage that is higher than the usual 208V that most three-phase services have, and a line-to-neutral voltage (on two of the phases) sufficient for connecting appliances and lighting. Thus, large pieces of equipment will draw less current than with 208V, requiring smaller wire and breaker sizes. Lights and appliances requiring 120V can be connected to phases 'A' and 'C' without requiring an additional step-down transformer.

Disadvantages
Since one phase-to-neutral voltage (phase 'B') is higher than the others, no single phase loads can be connected to this phase. This essentially eliminates one third of the breakers in a panel if there are many single-phase loads.



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Virginia Transformer Corporation

Virginia Transformer Corp is the 4th largest power transformer manufacturer in USA. The company supplies custom-made transformers to Power generating and distributing companies, heavy industries and other businesses. The company has 3 manufacturing facilities in North America. The Product range covers a wide range, from larger distribution transformers to large power transformers, rectifier and drive-duty transformers, and special transformers for a wide array of applications. The VTC team has designed transformers to perform at 14,000 feet (4,300 m) in the mines in mountains of Chile and for the day to day grueling New York Subway System to Generator and substation applications.

Company History
Virginia Transformer Corp was established and incorporated in the Commonwealth of Virginia in 1971 to supply Power Transformers to the underground mining industry in the nearby Appalachian Mountains. Low profile construction, tough environmental conditions, and other non-standard specifications required for both Dry-type and Liquid-filled Power Transformers in this application started VTC down the road of custom transformer designs and manufacturing excellence.

During the 70’s, customer base and product scope became more diversified, adding rectifier duty transformers and reactors for adjustable frequency drive and NEMA R19 extra heavy duty traction applications. Most major urban transit systems today employ transformers built by Virginia Transformer Corp. Later in this decade, VTC also established a predominate reputation for retrofitting the PCB market.

Beginning in the 80’s, its current President took the helm at Virginia Transformer Corp and the product range was further expanded to include Industrial and Commercial Power Transformers for distribution applications, including those with automatic load tap changing requirements, and trademarked fully encapsulated coil UNICLAD transformer. This decade saw the beginnings of the truly phenomenal 10% - 30% annual growth of VTC, which has been further exceeded in recent years with a continuation of product line expansion into the larger voltage class II sizes of Power Transformers.

The 90’s witnessed entry into the demanding Utility market, as customers sought to find additional suppliers for their requirements of high quality and lower cost units. During this decade VTC moved to a new facility and its current corporate headquarters – a 120,000-square-foot (11,000 m2) custom designed facility for modern transformer manufacturing. Virginia Transformer Corp further expanded by adding a second custom manufacturing facility in Chihuahua, Mexico. This modern state-of-the-art 60,000-square-foot (5,600 m2) operation, designed from the ground up as a transformer plant, has been ISO certified from the beginning. Visiting customers have proclaimed it to be one of the finest facilities for manufacturing transformers in North America.

During the 21st century, Virginia Transformer Corp continued to grow, acquiring the U S Transformer West facility in Pocatello, Idaho – providing yet another step toward world-class recognition. In addition to this facility building new Medium Voltage class Power Transformers, currently up to 100MVA top rated at 161kV, they also provide world-class reconditioning and repair services to both Utility and Industrial clients. Today, VTC stands at the top as a worldwide presence in the Power Transformer industry providing individualized solutions and custom designs with Dry-type and Liquid-filled transformers from its three manufacturing facilities in North America. All major components, core and coil assemblies, tanks, etc. are produced on-site with complete testing capabilities up to 950BIL for the complete range of Power Transformers – 300KVA to 300MVA, 230kV class for Utility, Industrial, Commercial, and Export markets.

Key People
Matthew Gregg - Vice President, Plant Operations
Subhas Sarkar - Vice President, Engineering
Prabhat Jain - President / CEO
Lawrence Horne - Vice President, Sales & Marketing
Steve Nelson - Chief Financial Officer

Locations
Roanoke, Virginia
Pocatello, Idaho
Chihuahua, Mexico
Mumbai, India
Delhi, India


Products
Liquid Filled
Automatic Load Tap Changing
Voltage Regulators
Dry Type
Uniclad
Repair and Refurbishment


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Spot network substation

In electricity distribution networks, spot network substations are used in interconnected distribution networks. They have the secondary network (also called a grid network) with all supply transformers bussed together on the secondary side at one location. Spot networks are considered the most reliable and most flexible arrangement of connecting power to all types of loads.Switching can be done without interrupting the power to the loads.


Description
Electricity distribution networks are typically of two types, radial or interconnected. A radial network leaves the station and passes through the network area with no connection to any other supply. This is typical of long rural lines with isolated load areas. In general, the radial distribution network has more power failures than the interconnected distribution networks.

Urban network substations can be used to make the interconnected distribution networks to serve a single campus or facility. Examples of such single campuses and facilities include airports, hospitals, major data processing centers (especially those using uninterruptible power supply), and sports arenas that regularly broadcast nationally televised events.

EPRI lists urban network supply systems has having Momentary and Long-duration Interruptions on 50 year intervals .

In large cities, many electric utility companies use grid feeders to make interconnected distribution networks to serve the downtown core. The interconnected network has multiple connections to the points of supply.

Reverse current relays are used to detect any open circuits that are letting the electrical current flow back towards its source.

Examples
A local spot network of 2 to 8 primary transformers can be connected to the same secondary buss to provide reliable power to a particular facility, like a large hospital or computer and major data processing center. St. Jude Children's Research Hospital in Memphis, Tennessee has 8 primary transformers that are connected to the same secondary bus. The FedExForum(home of the NBA Grizzlies basketball team) in Memphis has a network of 4 primary transformers connected to the same secondary buss. In some arrangements with 4 transformers, any of the 4 transformers can carry all of its connected loads. The Toronto Pearson International Airport is electrically fed by 4 grid feeders, each capable of carrying the entire 20+ MW load.


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Buck–boost transformer


A buck–boost transformer is a type of autotransformer used to make small adjustments to the voltage applied to alternating current equipment. Buck–boost connections are used in several places such as uninterruptible power supply (UPS) units for computers, electric power distribution, and in the tanning bed industry.

Types
There are two basic types, self adjusting (active) or passive designs. The active types monitor incoming voltages and will adjust the outgoing voltage to be within an acceptable range. This is typically between 115VAC and 225VAC for computer UPS systems. The system will either buck (lower) or boost (raise) the voltage if it senses a variance in the incoming voltage. Several taps are provided on the transformer winding which allow adjustment of the ratio. In an active buck–boost transformer, a control circuit selects which tap to use to maintain the output voltage within the desired range, over a range of input voltages.

Passive transformers are used for larger equipment where the amount of buck or boost is fixed. For example, a fixed boost would be used when connecting equipment rated for 230 VAC to a 208 V power source.

The passive transformers are rated in volt-amperes (or more rarely, amperage) and are rated for a percent of voltage drop or rise. For example, a buck–boost transformer rated at 10% rise at 208VAC will raise incoming voltage of 210VAC to 231VAC. A rating of 5% drop at 240VAC will yield the result of 233VAC if the actual incoming voltage is 245VAC.


Frequency
All transformers only operate with alternating current. Transformers only change voltage, not frequency. Equipment that uses induction motors will operate at a different speed if operated at other than the design frequency. Some equipment is marked on its nameplate to run at either 50Hz or 60Hz, and would only need the voltage adjusted with a buck–boost transformer.


Configuration
Most passive transformers come semi-wired, where the installer completes the last internal connections to have the unit perform the amount of buck or boost needed. They have multiple taps on both the primary and secondary coils to achieve this flexibility. They are designed for hard wired installations (no plugs) and allow the same transformer to be used in several different applications. The same transformer can be rewired to raise or lower voltage by 5%, 10% or 15% for either 208VAC or 240VAC applications, depending on the final wiring done by the electrician.

Fixed transformers with around the same cost were introduced primarily for the tanning market. They are prewired, and must be purchased with the exact amount of buck or boost needed for the application. They have factory-installed plugs and receptacles making installation very quick and easy, and reducing the need for hard-wiring small loads.

A typical fixed unit will have a NEMA 6-20 plug for attachment to the prewired 240V wall receptacle, and a receptacle for the load equipment. This eliminates the need for professional installation if the exact incoming voltage can be determined. To make them easier for end-users to select, they are rated in load amps (A) rather than buck–boost volt-amps (kVA). These are used almost exclusively in light to moderate applications that require 40 amps or less.


[edit] Purpose
Not all 240V equipment requires voltage correction. These transformers are used when electrical equipment has a voltage requirement that is slightly out of tolerance with the incoming power supply. This is most common when using 240V equipment in a business with 208V service or vice versa.

Equipment should be labeled with its voltage rating, and may advertise the amount of tolerance it will accept before degraded performance or damage can be expected. A unit that requires 230VAC with a tolerance of 5% will not require a buck–boost transformer if the branch circuit (under load) is between 219VAC and 241VAC. Measurement should be made while the circuit is loaded, as the voltage can drop several volts compared to the open measurement. The transformer must be rated to carry the full load current or it will be damaged.

Operating electrical equipment at other than its designed voltage may result in poor performance, short operating life, or possibly overheating and damage.

For large adjustments in voltage (more than 15% to 20%), usually a two-winding transformer is used with the required voltage ratio, for example 240VAC to 120VAC. These transformers are more costly than buck–boost transformers since both windings must carry the full power delivered to the load, whereas the buck–boost winding must only carry a fraction of the load power.


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