Thursday, May 31, 2012

How is the Lighting Industry Reducing Mercury Use?

The lighting industry has slowly reduced the amount of mercury used in fluorescent lamps over the past 20 years and, according to NEMA surveys, mercury use has been reduced dramatically over the last 7 years. Since 1990, NEMA has conducted a number of surveys, which indicate the total amount of mercury contained in all lamps in the U.S. declined to 17 tons in 1994, 13 tons in 1999, 9 tons in 2001 and 7 tons in 2003—nearly a 90% reduction from previous years. According to this trend, researchers believe this number will continue to decline in future years.

The lighting industry accomplished these dramatic reductions by collectively investing millions of dollars in new lamp manufacturing equipment and processes. However, fluorescent lamps must still be handled, stored and transported to recycling facilities with care. To ensure the safety of people who handle these lamps and the environment, there is a need for better regulations for packaging that controls the release of mercury vapor emitted from broken lamps.

Brad Buscher
Chairman and CEO
VaporLok Products LLC

Wednesday, May 23, 2012

Toxic Characteristic Leaching Procedure (TCLP) Mercury Test

According to EPA estimates, approximately 75 to 80 percent of fluorescent lamps are not recycled and are usually placed in dumpsters or trash containers. Fluorescent lamps in dumpsters present a considerable danger. One study found that mercury is "strongly and persistently" emitted from dumpsters that contain broken fluorescent lamps.1 The data indicates a preliminary loss rate of ~25µg/h from one bulb contained in a closed dumpster. The bulb continued to emit mercury at this rate for more than a week, and at ~50 µg/h on the 8th day following breakage.

Federal policies contain exemptions that help keep the recycling rate low. For instance, lamps that pass the Toxic Characteristic Leaching Procedure (TCLP) mercury test are currently exempt from recycling requirements. However, some lamp manufacturers put extraneous additives in the lamps—such as ascorbic acid—that compromise the test and skew the results.

In 2000—following an extensive debate focused on whether or not a disposal ban should apply to lamps that pass the TCLP—the Maine Legislature decided to enact the ban on all mercury-added lamps. New and used lamps from ten popular lamp models were collected and tested for total mercury and TCLP mercury by dedicated testing procedures. Results indicate that lamps that pass the TCLP test contain comparable total mercury results as the corresponding lamps that fail TCLP, suggesting that the disposal ban on all mercury-added lamps is appropriate.2

1. Lindberg, S.E.; Owens, J. PaMSWaD (Pathways of Mercury in Solid Waste Disposal); Lockheed Martin Energy Research Corporation (LMER). 1999. 6.
2. Maine Fluorescent Lamp Study, DRAFT 1.0, November 15, 2001.

Brad Buscher
Chairman and CEO
VaporLok Products LLC

Wednesday, May 16, 2012

How Can You Easily Recycle Used Fluorescent Bulbs?

Products containing mercury, including fluorescent lamps, need to be handled and recycled properly to effectively contain and prevent mercury vapor from releasing into the environment. Mercury-containing waste that isn't properly recycled poses a serious environmental and health concern and can be regulated more stringently.

Fluorescent lamps can easily be recycled or disposed if burned out. Available recycling methods include:
  • Use Mercury VaporLok® Bags for safely accumulating spent fluorescent lamps for recycling.
  • Waste Management LampTracker®: The prepaid program includes recycling containers, shipping both ways via UPS or FedEx ground, recycling of the wastes and complete online documentation of every container ordered and recycled.
  • State Collection Sites: Check with you local and/or state regulators and use Earth911.com to find a drop-off near you. Also note that many National retailers accept spent lamps for recycling.

Brad Buscher
Chairman and CEO
VaporLok Products LLC

Wednesday, May 9, 2012

The Mercury Debate: Is the CFL Bulb the Right Choice?


The 2007 energy conservation measure passed by Congress set standards to essentially ban incandescent lights by 2013, requiring households to make the switch to more energy efficient lights. However, many consumers are raising the question, whether or not CFLs and fluorescent bulbs are really the more efficient lighting choice. Due to their mercury content, many consumers are wary about placing them in their homes.

However, incandescent bulbs actually result in more mercury pollution than fluorescents. Because mercury is a byproduct of burning coal, coal-fired power plants are one of the largest sources of mercury pollution. Because incandescent bulbs use several times more electricity over their lifetimes, they require far more power generation and, ultimately, result in more mercury emission than fluorescents. With the coming “maximal achievable technology” clean air standards, it is fully expected that mercury emissions will have to be severely reduced in order to stop this proliferation. Fluorescent lights are four to six times more efficient than incandescent lamps, significantly reducing the power demand from local utilities. The reduced demand for electricity in turn reduces both greenhouse gas and mercury emissions.

Furthermore, consumers can safely use energy efficient bulbs if they are properly handled and disposed of when broken or burned out. Learn how to safely clean up a broken bulb or safely package a used bulb to send to a recycling facility.

Brad Buscher
Chairman and CEO

Wednesday, May 2, 2012

Layers of Packaging Help Protect Used Fluorescent Lamps

Many customers repurpose the packages fluorescent lamps are sold in—to store used lamps and eventually transport these lamps for disposal or recycling. However, the recent University of Minnesota study I conducted with my team of researchers found that these packages do not contain mercury vapor below permissible workplace exposure levels, as defined by state and federal authorities.

We also tested packaging configurations that enhance this single cardboard layer with a plastic bag, as well as packages that add a second layer of cardboard to the design—with the bags positioned between the two cardboard layers. The latter group contained two package varieties: a double-box with a thicker, tape-sealed plastic bag, and a double box with a foil-plastic laminate bag containing a zip closure. Both of these packages performed better than the other configurations. Yet, only the double box with the foil-plastic laminate bag delivered the necessary levels of protection.

This study indicates that all three layers of the last packaging configuration are critical in the effective containment of mercury vapor. The first cardboard layer provides structure to the configuration and protects contents from outside elements. The bag—which should feature a suitable material and tight seal—contains the mercury vapor, and the inner layer of cardboard prevents broken glass from puncturing the bag and rendering it ineffective.

Brad Buscher
Chairman and CEO
VaporLok Products LLC