Light Bulb Basics
Light Bulb Basics
Used to be all you needed to know when buying a light bulb was whether you needed a 60-, 75-, or 100-watt bulb, and maybe whether it was clear or frosted. Nearly everyone had an idea of how much light these bulbs put out. However, with the advent of the compact flourescent lightbulb (CFL), and now the light-emitting diode (LED) bulb, wattage is no longer a reliable indication of brightness. A CFL or LED can output the same amount of light using only 20% to 25% as much energy. So you need to be looking at other measurements when selecting the new style of light bulbs. There are three main things to look for: brightness, wattage, and color. There may be other things you that are of interest to you. So here is a quick rundown of light bulb basics.
Wattage - The unit for measuring energy is the watt. Wattage indicates the amount of energy a device uses. Choosing lower-wattage bulbs can help lower your electric bill. CFLs and LEDs use less energy (lower wattage) than incandescent bulbs, while emitting the same amount of light. For example, a 60-watt incandescent light bulb emits about 800 lumens. A CFL with an output of 800 lumens consumes only 13 to 15 watts, while an LED of the same brightness consumes only 8 to 12 watts.
Brightness - Brightness, the amount of light emitted from a light bulb, is measured in lumens. More lumens means brighter light, while fewer lumens means dimmer light. A standard 100-watt incandescent light bulb produces about 1600 lumens. Brightness is sometimes called light output.
The Kelvin Color Scale
Energy Consumption (Watts)
- The Kelvin scale is a temperature scale in which its zero point is absolute zero, the temperature at which all thermal motion stops, -273.16° Celsius. The scale is named for William Thomson (who later became Lord Kelvin). Thomson wrote a paper in 1848 on the need for an absolute temperature scale. Until 1967, the unit on this scale was a degree Kelvin (°K) and was the same size as a degree Celsius (°C). That year, the General Conference on Weights and Measures (CGPM) dropped the term “degree” and redefined the absolute temperature unit as the kelvin (K). So now it is correct to say that the freezing point is 273.16 kelvins, not 276.16° Kelvin. It is written as 273.16 K, with a space between the number and the letter.
So what does the Kelvin scale have to do with colors. Well, without getting too scientific, a black body radiator emits a color that varies with its temperature. A black body whose temperature is below 4000 K appears more reddish in color, while one whose temperature is above 7000 K appear more bluish. By the way, 4000 K is 6740° F—that's pretty warm. This color temperature scale is used in photography and image projection. It has also become useful when defining the color emitted by light bulbs. Higher color temperatures tend to be be more white or blue (“cooler” colors), and lower color temperatures are more orangish or reddish (“warmer” colors). Sometimes light color is called light appearance, but regardless of what you call it, it still refers to the Kelvin color scale.
In our lighting guidelines, we specify bulbs with a color rating of 3000 K or lower—2700 K is preferred. Lighting colors are sometimes indicated as soft white, warm white, bright white, or daylight. We recommend only the soft white for outdoor lighting. However, some of the others may be appropriate for some indoor lighting. Here is what these ratings mean.
- 2700 K - 3000 K (yellowish range). This is the color of a typical incandescent bulb. These work well in living rooms, bedrooms, and outdoors.
- 3000 K - 4000 K (yellowish to white range). These work well in kitchens, bathrooms, and work areas.
- 4000 K - 5000 K (white to blue range). These are best used in kitchens and bathrooms with white or chrome fixtures.
- 5000K - 6500K (blue range). These are good for reading. Despite the name, these bulbs are bluer than real daylight.
- Sometimes called efficacy, efficiency indicates the how much light is emitted for a given amount of energy used. It is the number of lumens output by the bulb per watt of energy input (lumens/watt). While efficiency is sometimes indicated on the bulb label, you can calculate efficiency by dividing lumens by the number of watts. However, for simplicity just remember a CFL is much more efficient than an incandescent bulb, and LEDs are a little more efficient than CFLs.
- An incandescent bulb lasts on average about 1,000 to 2,000 hours. That's about one to two years based on an average usage of 3 hours per day. CFLs are supposed to last 10,000 to 20,000 hours or 10 to 15 years using the 3 hr/day criteria. However, LED bulbs are listed as having a lifespan of 25,000 to 35,000 hours, well over 25 years. So even if the initial cost of an LED is higher than an equivalent CFL, you may never need to replace it.
- This is the estimated cost to operate a given light bulb for a year. These calculations usually assume that the bulb will be on an average of 3 hours per day and the electric rate is $0.11 per kilowatt-hour. Obviuously, if you use it more or less than 3 hours a day, the actual cost would be different. It also depends on how much your electricity provider charges. Here in Blanco County, the rate is about $0.10 per kilowatt-hour.
- Other measurements are sometimes presented on bulb labels. Most of these are of little concern to the average user and we will not go into those here.
- Manufacturers of lighting products are now required to provide labels with certain information on their packaging. Examples of two of these labels are shown below: