Modern plasma lighting is a family of lights that generate light through the use of radio frequency (RF) power to create exciting plasma in a closed transparent burner or bulb. Such lamps usually use a noble gas or a combination of these gases and other ingredients, including metal halides, sodium, mercury or sulfur. A waveguide is used for restricting and concentrating the electrical field into the plasma in modern plasma lamps. When the gas is in action, free electrons collide with gas and metal atoms through electrical fields accelerated. These collisions are exciting some atomic electrons circled by gas and metal atoms that bring them to an energy level higher. When the electron reverts to its original status, the photon is released and, depending on the fill materials, visible or ultraviolet light is produced.
This lamp led Fusion Lighting to the creation of the sulfur lamp-a bulb full of argons and sulphur bombarded by a hollow waveguide-which included microwave ovens. The first commercial plasma lamp was the ultra-violet cure. To keep it from burning, the bulb had to be spun hard. Fusion Lighting has not prospered commercially, but sulfur lamps are still being pushed by other manufacturers. Although rather efficient, sulfur lights had a number of difficulties, particularly: limited life–life for magnetrons was limited.
Big fire–sulphur is burned by the wall of the bulb unless it is turned rapidly.
High power demand–Power under 1000W could not support a plasma.
The magnetron used to produce microwaves had previously reduced the existence of the plasma lamps. You can use solid state RF chips and give long life. Nevertheless, it is at present a more expensive order than using a magnetron to produce RF by using solid state chips and thus only suitable for high-quality luminaires. Dipolar[ 1] from Sweden recently showed that magnetron lives can be extended to more than 40,000 hours and plasma lamps at low cost[1] are possible.
Heat and power The use of a high-dielectric waveguide allowed plasmas to be supported at significantly lower power rates–sometimes up to 100 W. The use of modern gas discharge lamps was also allowed to fill materials, removing the need to spin the bulb. The only problem with the ceramic ondulator was that the plasma light was trapped inside the opaque ceramic ondulator.
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