Transformer Power Supply

2009年1月20日星期二

RJ11, RJ14, RJ25

RJ11 is a physical interface often used for terminating telephone wires. It is probably the most familiar of the registered jacks, being used for single line POTS telephone jacks in most homes across the world.

RJ14 is similar, but for two lines, and RJ25 is for three lines. RJ61 is a similar registered jack for four lines. The telephone line cord and its plug are more often a true RJ11 with only two conductors.

Contact arrangement
All of these registered jacks are described as containing a number of potential contact "positions" and the actual number of contacts installed within these positions. RJ11, RJ14, and RJ25 all use the same six-position modular connector, thus are physically identical except for the different number of contacts (two, four and six respectively).

RJ11 wiring
Cables sold as RJ11 are nearly always 6P4C (six position, four conductor), with four wires running to a central junction box. Two of its six possible contact positions connect tip and ring and the other two conductors are then unused. 6P2C and 6P6C can also be found in stores.

The conductors other than the two central tip and ring conductors are in practice used for various things such as a ground for selective ringers, low voltage power for a dial light, or for 'anti-tinkle' circuitry to prevent pulse dialing phones from ringing the bell on other extensions. With tone dialing anti-tinkle measures are not required.

Powered version of RJ11
In the powered version, Pins 2 and 5 (black and yellow) may carry low voltage AC or DC power. While the phone line itself (tip and ring) supplies enough power for most telephone terminals, old telephone terminals with incandescent lights in them (such as the classic Western Electric Princess and Trimline telephones) need more power than the phone line can supply. Typically, the power on Pins 2 and 5 comes from a transformer plugged into a wall near one jack, supplying power to all of the jacks in the house. Trimline and Princess phone dial lights are rated at 6.3 volts and the transformer output is typically around 5 volts, providing a long service life for the incandescent lamps.

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Desert Power & Water Co., Electric Power Plant

Desert Power & Water Co. Electric Power Plant is located at 120 Andy Devine Avenue in Kingman, Arizona. The building was built in 1907-08 with additions in the following years 09, 10, & 11. Tracy Engineering Co. was the architect and McCafe Contracting Co. out of Los Angeles, Ca. was the contractor. The plant was considered one of the largest steam plant on the Pacific Coast. It had a powerhouse, transformer house and office. It operated until 1938; Hoover Dam took over the power supply. The building was vacant for some time, then used as a salvage yard. Sometime in the 1980’s, a couple of local people got together and formed a group known as the Powerhouse Gang. Their goal was to renovate the old building into something useful. In 1997, the building was open to the public. The building belongs to the City of Kingman and is the home of Kingman Chamber of Commerce and Kingman Tourism Office and Visitor Center, along with the Historic Route 66 Association of Arizona and the Route 66 Museum. The building was placed on the National Register of Historic Places and the number is 86001137.

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Krka (Croatia)

Krka is a river in Croatia's Dalmatia region, with length circa 73 km; it is famous for its numerous waterfalls.

The river has its source near the border of Croatia with Bosnia and Herzegovina, at the foot of the Dinara mountain. It flows past Knin in Inner Dalmatia towards the south and enters the Prokljansko jezero near Skradin. The best known sites on the river path are the Visovac Monastery (Roman Catholic)and the Monastery Krka (Serbian Orthodox).

Before its outflow the river forms beautiful and well known waterfalls called Skradinski Buk, part of Krka National Park. Skradinski Buk is the location of the first hydroelectric power station in Croatia. This plant started supplying power to the nearby city of Šibenik on the 28th of August 1895, making Šibenik the first city in the world to be supplied with hydroelectricity. (the Adams Power Plant Transformer House near Niagara Falls was deemed operational three days earlier on the 25th of August 1895, but the transmission lines to Buffalo, New York were not ready until over a year later on 16th of November 1896)

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Infrastructure in London

Below is information on the utility infrastructure in the city of London, England.

Electric power supply
Several power stations were built to generate electricity in the centre of London, including the famous power stations at Bankside and Battersea (both now disused). Bankside power station has now been converted into Tate Modern, but still houses part of a large electricity transformer substation.

HVDC Kingsnorth has been a unique element of the London power grid since 1975, the first urban high voltage direct current transmission system in the world. It was subsequently converted to standard 3-phase alternating current.

Water
The Thames Water Ring Main supplies much of London with water. Sewage disposal was historically a problem, causing major pollution of the River Thamesand potable water supplies. London suffered from major outbreaks of cholera and typhus well into the mid-1800s. Indeed, the problem was so severe that Parliament was suspended on occasion due to the stench from the river. These problems were solved when Sir Joseph Bazalgette completed his system of intercepting mains to divert sewage from the Thames to outfalls east of London, where the tide would sweep the sewage out to sea.

Telecommunications
There are 188 telephone exchanges in London and all offer ADSL internet services. Most of London, and some adjacent places, are covered by the 020 area code. Some parts of outer London are covered by the 01322, 01689, 01708, 01895, 01923 and 01959 codes. There is extensive wireless LAN coverage, especially in central London such as the City of London Corporation, who are developing blanket coverage for the financial district.There is wide coverage from five mobile phone networks of which four are GSM/UMTS and one is UMTS-only.

Most analogue and digital television and radio channels are received throughout the London area from either the Crystal Palace Transmitter or Croydon Transmitter in south London. Cable television is widespread with service provided by Virgin Media, however coverage is not universal. Tiscali TV provide an expanding video on demand cable television service over ADSL to the London area. Broadband internet and telephone services are also provided by the cable television networks.

With computers and technology playing a key part in the economy, companies have created a large number of datacentres within Greater London, many of which are in the Docklands area. As a result, London now hosts key parts of the Internet, including LINX (London INternet eXchange), the largest Internet Exchange Point in the world, carrying over 310 Gb/sec of Internet traffic (as of 2008).

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Voltage converter

Voltage converter
From Wikipedia, the free encyclopedia
Jump to: navigation, search
A voltage converter changes the voltage of an electrical power source and is usually combined with other components to create a power supply. The term "voltage converter" is sometimes used as a generic term for a power supply. A voltage converter or a power supply may be called a "transformer" even if it does not contain an actual transformer as the term is used in electronics.

A common use of the term voltage converter is for a device that allows appliances made for the voltage of the common electrical outlets of one geographical region for the outlets of another area. Most single phase alternating current electrical outlets in the world have a voltage range of 210 to 230 volts or a range of 110 to 120 volts. Converters usually can only double the voltage or halve the voltage but some are set up to do both.

Often these are sold with plug end adaptors that provide conversion of the size and shape of the plug end. If voltage conversion is not needed the plug adaptor can be used without a voltage converter.

There are a number of methods for converting voltage. For Alternating current (AC) a transformer can be used to decrease or increase the voltage. The common power supplies for small electronics usually have a transformer that drops the voltage down to relatively small voltage ranging from 4.5 to 12 volts, a full-wave rectifier to convert the AC to a pulsed Direct Current and some additional components to flatten the wave. Some devices have only a transformer in the external power supply with any rectifier or additional power conditioning provided inside the appliance.

Voltage converters sold for use in cars with 12 volt Direct Current outlets almost always have no transformer and instead use a Zener diode to drop the DC voltage with a relatively large power loss as heat. Converting a low DC voltage to a high DC voltage requires conversion to AC, the use of a transformer to increase the voltage and then a rectifier and conditioning circuit to convert it back to DC. Going through an AC step can also be used to drop voltage. For example one might use an inverter to produce 110 AC current from a car's electrical system and then use the conventional power supply that came with the device.

There are two types of voltage converters, step up and step down. Step up converts from 110 volts to 230 volts and step down will convert from 230 volts to 110 volts. Most voltage converters convert both ways.

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Vibrator (electronic)

In early electronics vibrators were used in inverter circuits to provide an alternating current (AC) electric power supply from a direct current (DC) source.

The primary use for this type of circuit was for vacuum tube type automobile radios. Vacuum tubes require relatively high voltages ranging from about 45 volts to 450 volts in consumer electronics. For portable radios, hearing aids and similar equipment, B batteries were manufactured with various voltage ratings. In order to provide the necessary voltage for a radio from the typical 6 volt DC supply available in a car, it was necessary to convert the DC supply to AC and use a transformer to increase the voltage.

The rapid motion of the vibrator was used to operate a switch. The switch was used to alternate the connection of the 6 volt DC power between two terminals of a transformer, in effect, supplying an AC input voltage to the transformer. The transformer produced a higher voltage AC supply at its output terminals. This arrangement is a simple type of inverter circuit. The vibrator switches used for this purpose were usually encased in a steel or aluminum can equipped with a plug for mounting in a tube socket.

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger

Universal Travel Charger

Grid tie inverter

A grid-tie inverter, or a (GTI) is an electrical device that allows solar power users to complement their grid power with solar power. It works by regulating the amount of voltage and current that is received from the direct current solar panels (or other D.C. energy source) and converting this into alternating current. The main difference between a standard electrical inverter and a grid-tie inverter is that the latter also ensures that the power supplied will be in phase with the grid power. This allows individuals with surplus power (wind, solar, etc) to sell the power back to the utility. This is sometimes called "spinning the meter backwards" as that is what literally happens.

On the AC side, these inverters must supply electricity in sinusoidal form, synchronized to the grid frequency, and limit feed in voltage to no higher than the grid voltage including disconnecting from the grid if the grid voltage is turned off.

On the DC side, the power output of a module varies as a function of the voltage in a way that power generation can be optimized by varying the system voltage to find the 'maximum power point'. Most inverters therefore incorporate 'maximum power point tracking'.

The inverters are designed to connect to one or more strings.

For safety reasons a circuit breaker is provided both on the AC and DC side to enable maintenance. The AC output usually goes through an electricity meter into the public grid.

The meter must be able to run in both directions.

Installations will require, "rate of change of frequency" (ROCOF), vector shift, and a voltage monitor with disconnection of all phases to prevent power being fed back during power outages.

Typical Operation
Inverters work by taking the 12 or 24 volt DC voltage from the source, such as solar panels or micro hydroelectric generators and 'chopping' by turning it on and off at grid supply frequency (e.g. 60 Hz) using a local oscillator and a power transistor. This chopped DC signal is then filtered to make it into a sine wave (removing the upper 3,5,7 harmonics that make up the square wave and then applying it to a transformer to up the voltage to 120 or 240 to supply the needs of load.

A grid tie inverter does the same but has two key differences. Firstly the frequency has to be matched in phase to the grid. This means the local oscillator has to be in sync with the grid. Secondly the voltage of the inverter output needs to be variable to allow it to be slightly higher than the grid voltage to enabling current to flow out to the grid. This is done by sensing current flow and raising the voltage on the output (or duty cycle of the transformer input) until the current flow results in the resulting output power matching the input power from the DC supply.

Effects on Grid Power Quality
In order for grid tie inverters to comply with utility electrical standards, the output power needs to be clean, undistorted and in phase with the AC grid. Typical modern GTI's have a fixed unity power factor, which means its output voltage and current are perfectly lined up, and its phase angle is within 1 degree of the AC power grid. The inverter has an on board computer which will sense the current AC grid waveform, and output a voltage to correspond with the grid.

AC Travel Charger

Phone Solar Charger

Industrial Battery Charger

oem battery charger

nimh smart charger

Solar Battery Chargers

Portable Battery Charger

NI-MH Battery Charger