Fluorescent lamps give off the same amount of light as their traditional incandescent counterparts, but they require considerably less electricity, which in turn reduces the damaging effects electric power generation causes to the environment. Incandescent light bulbs actually require four times the amount of energy to produce equivalent light in a fluorescent lamp. Fluorescent lamps are four to six times more efficient than incandescent lamps, reducing the power demand from local utilities. Because most power stations use coal as a source for electrical generation, they are large emitters of both greenhouse gas and mercury, which is naturally occurring in most coal that is used today.
Mercury does present significant health and safety risks to consumers and handlers. However, proper packaging does exist that has been proven to protect people from mercury vapor exposure when handling fragile fluorescent lamps. To ensure sufficient packaging methods are used, packaging regulations should be defined and enforced.
Brad Buscher
Chairman and CEO
VaporLok Products LLC
Wednesday, November 24, 2010
Thursday, November 18, 2010
One Broken Bulb: The Health and Safety Risks
One broken four-foot fluorescent lamp in a small room or vehicle can release enough mercury vapor to exceed the OSHA mercury exposure eight-hour limit—posing significant health and safety risks to handlers and consumers. Plus, mercury vapor can be emitted for weeks after a single bulb is broken, continually polluting the air in consumers’ homes. When carelessly handled or improperly disposed of, mercury can get into drinking water, lakes, rivers and streams, posing a critical threat to human health, as well as the environment. Recent studies have linked mercury exposure to increased risk of heart attack in men, to mental retardation and neurological disorders in children, and dangerous levels of mercury in the blood of women of childbearing age.
Despite these health concerns, the EPA estimates that approximately 75 to 80 percent of fluorescent lamps are not recycled and are usually placed in dumpsters or trash containers, presenting a considerable risk. One study found that mercury is "strongly and persistently" emitted from dumpsters that contain broken fluorescent lamps.(1) Broken fluorescent lamps need to be properly recycled to prevent the release of mercury vapor. Learn how to clean up a broken bulb or how to safely package and recycle fluorescent lamps by reading our Layers of protection: Packaging used fluorescent lamps post.
1. Lindberg, S.E.; Owens, J. PaMSWaD (Pathways of Mercury in Solid Waste Disposal); Lockheed Martin Energy Research Corporation (LMER). 1999. 6.
Brad Buscher
Chairman and CEO
VaporLok Products LLC
Despite these health concerns, the EPA estimates that approximately 75 to 80 percent of fluorescent lamps are not recycled and are usually placed in dumpsters or trash containers, presenting a considerable risk. One study found that mercury is "strongly and persistently" emitted from dumpsters that contain broken fluorescent lamps.(1) Broken fluorescent lamps need to be properly recycled to prevent the release of mercury vapor. Learn how to clean up a broken bulb or how to safely package and recycle fluorescent lamps by reading our Layers of protection: Packaging used fluorescent lamps post.
1. Lindberg, S.E.; Owens, J. PaMSWaD (Pathways of Mercury in Solid Waste Disposal); Lockheed Martin Energy Research Corporation (LMER). 1999. 6.
Brad Buscher
Chairman and CEO
VaporLok Products LLC
Thursday, November 11, 2010
Which Packaging Configuration Effectively Contains Mercury Vapor?
To avoid both health and environmental risks associated with mercury vapor emissions from broken fluorescent lamps, they should be packaged, stored and transported to recycling facilities in a configuration that is specifically designed to contain mercury vapor—and proven to be effective.
The University of Minnesota study measured the performance of three different categories of packaging configurations that are used to store and transport used fluorescent lamps: single layer cardboard boxes, single layer cardboard boxes with a plastic bag, and double-layer cardboard boxes with a bag between the two layers. In ten replicate experiments, each box was filled with 40 used low-mercury T4 fluorescent lamps, dropped and shaken in a test chamber until the lamps were broken. During the next six hours, the level of mercury vapor inside the test chamber was measured and recorded. (1)
1. Single Layer Cardboard Box: Similar to the package in which fluorescent lamps are usually sold in, this packaging configuration was the least effective. It resulted in airborne mercury vapor levels in the test chamber exceeding all workplace exposure levels, as defined by state and federal authorities.
2. Single Layer Cardboard Box with a Plastic Bag: This contained the mercury better than the first box, but still emitted some mercury vapor.
3. Double-Layer Cardboard Boxes with a Bag Between the Two Layers: Out of all of the configurations, only this package design kept mercury vapor levels in the test chamber below all workplace exposure regulations and guidelines.
REFERENCES
1. Glenz, Tracy T., Lisa M. Brosseau, and Richard W. Hoffbeck. "Preventing Mercury Vapor Release from Broken Fluorescent Lamps during Shipping." Journal of the Air & Waste Management Association 59 (2009): 266-72. Print.
Brad Buscher
Chairman and CEO
VaporLok Products LLC
The University of Minnesota study measured the performance of three different categories of packaging configurations that are used to store and transport used fluorescent lamps: single layer cardboard boxes, single layer cardboard boxes with a plastic bag, and double-layer cardboard boxes with a bag between the two layers. In ten replicate experiments, each box was filled with 40 used low-mercury T4 fluorescent lamps, dropped and shaken in a test chamber until the lamps were broken. During the next six hours, the level of mercury vapor inside the test chamber was measured and recorded. (1)
1. Single Layer Cardboard Box: Similar to the package in which fluorescent lamps are usually sold in, this packaging configuration was the least effective. It resulted in airborne mercury vapor levels in the test chamber exceeding all workplace exposure levels, as defined by state and federal authorities.
2. Single Layer Cardboard Box with a Plastic Bag: This contained the mercury better than the first box, but still emitted some mercury vapor.
3. Double-Layer Cardboard Boxes with a Bag Between the Two Layers: Out of all of the configurations, only this package design kept mercury vapor levels in the test chamber below all workplace exposure regulations and guidelines.
REFERENCES
1. Glenz, Tracy T., Lisa M. Brosseau, and Richard W. Hoffbeck. "Preventing Mercury Vapor Release from Broken Fluorescent Lamps during Shipping." Journal of the Air & Waste Management Association 59 (2009): 266-72. Print.
Brad Buscher
Chairman and CEO
VaporLok Products LLC
Thursday, November 4, 2010
What Happens When the Bulb Breaks?
When a fluorescent lamp breaks, it emits mercury vapor, which can cause severe health and safety risks. Mercury vapor, which can be absorbed through the skin or inhaled, can cause neurological damage to adults, children and fetuses. (1) It is considered a persistent bioaccumulative toxic chemical, since it doesn't degrade in the environment. (2) When mercury vapor gets into water, it is converted to methyl mercury and can enter the food chain through fish. Methyl mercury causes damage to the central nervous system and it is also thought to be a possible human carcinogen. (3)
To avoid both health and environmental risks associated with mercury vapor emissions from broken fluorescent lamps, they should be packaged, stored and transported to recycling facilities in a configuration that is specifically designed to contain mercury vapor—and proven to be effective.
1. Mercury Fact Sheet; Agency for Toxic Substances and Disease Registry, 1999; available at http://www.atsdr.cdc.gov/tfacts46.pdf (accessed October 1, 2007).
2. Persistent Bioaccumulative Toxic (PBT) Chemicals; Final Rule. Fed Regist. 1999, 64, 58666-58753.
3. Mercury Compounds Hazard Summary, 2000. Technology Transfer Network Air Toxics web site; U.S. Environmental Protection Agency; available at http://www.epa.gov/ttn/atw/hlthef/mercury.html (accessed November 20, 2007).
Brad Buscher
Chairman and CEO
VaporLok Products LLC
To avoid both health and environmental risks associated with mercury vapor emissions from broken fluorescent lamps, they should be packaged, stored and transported to recycling facilities in a configuration that is specifically designed to contain mercury vapor—and proven to be effective.
1. Mercury Fact Sheet; Agency for Toxic Substances and Disease Registry, 1999; available at http://www.atsdr.cdc.gov/tfacts46.pdf (accessed October 1, 2007).
2. Persistent Bioaccumulative Toxic (PBT) Chemicals; Final Rule. Fed Regist. 1999, 64, 58666-58753.
3. Mercury Compounds Hazard Summary, 2000. Technology Transfer Network Air Toxics web site; U.S. Environmental Protection Agency; available at http://www.epa.gov/ttn/atw/hlthef/mercury.html (accessed November 20, 2007).
Brad Buscher
Chairman and CEO
VaporLok Products LLC
Labels:
CFL,
fluorescent lamps,
health and safety,
mercury,
mercury vapor,
methyl mercury,
packaging,
vaporlok
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