Efficiency and Environmental Impact
Approximately 90% of the power consumed by an incandescent light bulb is emitted as heat, rather than as visible light.
Luminous efficacy of a light source may be defined in two ways. The radiant luminous efficacy (LER) is the ratio of the visible light flux emitted (the luminous flux) to the total power radiated over all wavelengths. The source luminous efficacy (LES) is the ratio of the visible light flux emitted (the luminous flux) to the total power input to the source, such as a lamp. Visible light is measured in lumens, a unit which is defined in part by the differing sensitivity of the human eye to different wavelengths of light. Not all wavelengths of visible electromagnetic energy are equally effective at stimulating the human eye; the luminous efficacy of radiant energy (LER) is a measure of how well the distribution of energy matches the perception of the eye. The units of luminous efficacy are "lumens per watt" (lpw). The maximum LER possible is 683 lm/W for monochromatic green light at 555 nanometres wavelength, the peak sensitivity of the human eye.
The luminous efficiency is defined as the ratio of the luminous efficacy to the theoretical maximum luminous efficacy of 683 lpw, and, as for luminous efficacy, is of two types, radiant luminous efficiency (LFR) and source luminous efficacy (LFS).
The chart below lists values of overall luminous efficacy and efficiency for several types of general service, 120-volt, 1000-hour lifespan incandescent bulb, and several idealized light sources. The values for the incandescent bulbs are source efficiencies and efficacies. The values for the ideal sources are radiant efficiencies and efficacies. A similar chart in the article on luminous efficacy compares a broader array of light sources to one another.
Type | Overall luminous efficiency | Overall luminous efficacy (lm/W) |
---|---|---|
40 W tungsten incandescent | 1.9% | 12.6 |
60 W tungsten incandescent | 2.1% | 14.5 |
100 W tungsten incandescent | 2.6% | 17.5 |
glass halogen | 2.3% | 16 |
quartz halogen | 3.5% | 24 |
high-temperature incandescent | 5.1% | 35 |
ideal black-body radiator at 4000 K (or a class K star like Arcturus) | 7.0% | 47.5 |
ideal black-body radiator at 7000 K (or a class F star like Procyon) | 14% | 95 |
ideal monochromatic 555 nm (green) source | 100% | 683 |
Unfortunately, the spectrum emitted by a blackbody radiator does not match the sensitivity characteristics of the human eye. Tungsten filaments radiate mostly infrared radiation at temperatures where they remain solid – below 3,695 K (3,422 °C; 6,191 °F). Donald L. Klipstein explains it this way: "An ideal thermal radiator produces visible light most efficiently at temperatures around 6,300 °C (6,600 K; 11,400 °F). Even at this high temperature, a lot of the radiation is either infrared or ultraviolet, and the theoretical luminous efficacy (LER) is 95 lumens per watt." No known material can be used as a filament at this ideal temperature, which is hotter than the sun's surface. An upper limit for incandescent lamp luminous efficacy (LER) is around 52 lumens per watt, the theoretical value emitted by tungsten at its melting point.
For a given quantity of light, an incandescent light bulb produces more heat (and thus consumes more power) than a fluorescent lamp. In buildings where air conditioning is used, incandescent lamps' heat output increases load on the air conditioning system. Heat from lights will displace heat required from a building's heating system; generally space heating energy is of lower cost than electricity.
High-quality halogen incandescent lamps have higher efficacy, which will allow a 60-watt bulb to provide nearly as much light as a non-halogen 100-watt bulb. Also, a lower-wattage halogen lamp can be designed to produce the same amount of light as a 60-watt non-halogen lamp, but with much longer life.
Many light sources, such as the fluorescent lamp, high-intensity discharge lamps and LED lamps offer higher efficiency, and some have been designed to be retrofitted in existing fixtures. These devices produce light by luminescence, instead of heating a filament to incandescence. These mechanisms produce discrete spectral lines and so don't have the broad "tail" of wasted invisible infrared emissions. By careful selection of which electron energy level transitions are used, the spectrum emitted can be tuned to mimic the appearance of incandescent sources, or other different color temperatures of white light.
Read more about this topic: Incandescent Light Bulb
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