Capacitors

(Difference between revisions)
 Revision as of 19:33, 28 January 2009 (view source)Nbrewer (Talk | contribs)← Older edit Revision as of 01:05, 17 February 2009 (view source)K3hz (Talk | contribs) mNewer edit → Line 13: Line 13: == Units of Measurement  == == Units of Measurement  == − The unit of capacitance was known as the "Jar" until 1872, when the SI unit of "Farad" was assigned. (Other units were assigned at this time, volt, ampere, coulomb, ohm and farad.) + The unit of capacitance was known as the "Jar" until 1872, when the SI unit of "Farad" was assigned. (Other units were assigned at this time, volt, ampere, coulomb, ohm and farad.)   All practical realisations of the capacitor have some resistance, both leakage as well as charging and it is this combination which defines the 'loss factor'. [[Category:Components,_circuits,_devices_&_systems|Category:Components,_circuits,_devices_&_systems]] [[Category:Electronic_components]] [[Category:Capacitors]] [[Category:Components,_circuits,_devices_&_systems|Category:Components,_circuits,_devices_&_systems]] [[Category:Electronic_components]] [[Category:Capacitors]]

Capacitors

These are examples of modern capacitors. They measure about an inch long and might be found in radios or televisions. Capacitors come in all sizes, from car-size ones that are used in electric power distribution to microscopic ones built into integrated circuits.

A capacitor is a device for temporarily storing electric charge. What is considered to be the very first capacitor was called the Leyden jar, which was invented by Pieter van Musschenbroek in 1746 at the University of Leyden (or Leiden) in Holland. It was a glass jar wrapped inside and out by a thin metal foil. The outer foil was connected to the ground, and the inner foil was connected to a source of electricity such as an electrostatic generator. Although how it works was not understood at the time, experimenters discovered that the Leyden jar seemed to store an electric charge even after it was disconnected from the generator. Like many early electrical devices, there was no particular use for the Leyden jar at first, other than to allow scientists to do a greater variety of electrical experiments. Benjamin Franklin, for example, used a Leyden jar to store electricity from lightning in his famous kite flying experiment in 1752. By doing so he proved that lightning was really electricity.

Capacitors such as a Leyden jar consist of layers made of an electrically conducting material (such as metal foil) separated by layers of a nonconducting material (glass in the case of the Leyden jar, but it can also be wax, mica, oil, paper, tantalum, plastic, ceramic material, or even air). If an electrical voltage is applied to the layers of a capacitor, the plates will become charged, one positively and one negatively. If the externally applied voltage is then removed, the plates of the capacitor remain charged, and the presence of the electric charge induces an electrical potential between the plates. Today’s capacitors are used for a wide variety of purposes in electric power systems, radio receivers, computers, and nearly every other electrical device. They range in size from the size of a refrigerator to the microscopic capacitors built into integrated circuits. The capacity of the device for storing electric charge (called its capacitance) can be changed by changing the area of the plates, by increasing or decreasing their separation, or by using different kinds of materials for the non-conducting layers.

Inventors

In 1745 the Leyden jar was competitively invented by Ewald Jurgen von Kleist - 4 Nov 1745. Pieter van Musschenbroek produced the first working example in Jan 1746, with the name coming from Leiden University. In 1747 William Watson discharges a Leyden jar through a circuit and comprehends electric current.

Units of Measurement

The unit of capacitance was known as the "Jar" until 1872, when the SI unit of "Farad" was assigned. (Other units were assigned at this time, volt, ampere, coulomb, ohm and farad.)   All practical realisations of the capacitor have some resistance, both leakage as well as charging and it is this combination which defines the 'loss factor'.