SBIR Success Stories Mercury Sorbents and Carbon Black Derived From Waste Tires


Mercury Sorbents and Carbon Black Derived From Waste Tires

Advanced Fuel Research, Inc.

87 Church Street
East Hartford, CT 06108-3728
Telephone: 860-528-9806
http://www.afrinc.com

Environmental Problem

The U.S. power generation industry relies heavily
on coal, burning nearly 1 billion tons per year to
provide heat and electricity. Burning coal, however,
emits mercury into the air, where it contributes to
air pollution and falls to earth again during rainfall,
contaminating water supplies. Consumption of fish
exposed to mercury in these contaminated sources
can lead to many adverse health effects. One of the
most effective methods of controlling mercury
emissions from power plants is carbon injection,
whereby activated carbon is injected into the flue
gas stream exiting the boiler and adsorbed onto
particulate matter that then is removed. The cost of
commercially available activated carbon, however,
is prohibitive (approximately $0.40-$0.50 cents/lb).
Thus, low-cost carbons are extremely attractive for
this application.

A promising new source for these low-cost activat-
ed carbons takes advantage of waste tires, which
present their own serious environmental problem.
Scrap tires are immune to biological degradation
and thus present formidable disposal problems.
Landfilling of the 280 million tires generated each
year in the United States is an unacceptable solu-
tion. In addition to the continuous flow of waste
tires, there are approximately 2-3 billion tires al-

ready stored in piles throughout the country; illegal
dumping also is a problem. The tires take up large
amounts of valuable landfill space, provide breed-
ing sites for mosquitoes and rodents, and present
fire and health hazards. Tire pyrolysis (thermal
decomposition into usable end products like steel,
oil, and carbon black) is an effective method of dis-
posing of scrap tires, but the economic leverage
needs to be improved because the end products
are of low quality compared to the virgin materials.
This leveraging can be accomplished by producing
value-added products such as carbon black, a high-
value feedstock for the rubber industry, and activat-
ed carbon, which is used as a mercury sorbent in
power plants.

SBIR Technology Solution

With support from EPA's SBIR Program, Advanced
Fuel Research, Inc. (AFR), developed
a technology to address both:

(1) removal and recovery of mercury
from combustion/incineration flue
gas, and (2) reprocessing of waste
tires into value-added products.

AFR's approach is based on mercury
adsorption on low-cost, sulfur-rich
activated carbons derived from scrap
tires. The sulfur added to tire rubber
in the process of vulcanization makes
the tire-derived sorbents particularly
effective in mercury removal. The
first step in the waste-tire processing
scheme is pyrolysis, which involves
thermal decomposition of tire rubber
in an oxygen-free atmosphere. The
solid product of pyrolysis (tire char)

Coal

subsequently is converted into activated carbon.
The sulfur content increases during tire processing,
which is believed to facilitate mercury-capture effi-
ciency. The cost-performance characteristics of tire-
derived carbons are excellent and more favorable
than those of the benchmark commercial carbon,
Norit FGD.

Two possible implementations of the process are
envisioned: (1) sorbent injection into the flue gas
duct (near-term applications), and (2) a patented
regenerative scheme (long-term applications). AFR's
technology for the removal of mercury from com-
bustion/incineration flue gas, which is combined
with the simultaneous utilization of massive
amounts of solid waste (scrap tires), has applications
for coal-fired power plants and municipal, medical,
and hazardous waste incinerators.

Scrap Tires

Tire Char

Activated Carbon

Particulate
Removal

carbon injection

carbon recycling

Baghouse









disposal/Hg recovery

SBIR Success Stories

Schematic of AFR's process that converts solid waste (scrap tires) to
mercury sorbents.

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In another SBIR-supported project, AFR devel-
oped a technology based on reprocessing tire-
pyrolysis oils into virgin carbon black. In addition
to manufacturing carbon black, this process also
creates a market for the large stream of solid
waste comprised of scrap tires. In addition, this
process reduces the demand for fossil fuels, the
conventional feedstock for carbon black manufac-
turing.

Commercialization Information

AFR has secured two patents for the mercury
sorbent technology and was invited to participate in
a full-scale Department of Energy/National Energy
Technology Laboratory (DOE/NETL) evaluation of
mercury-control technologies. The invitation was
extended to AFR on the basis of data showing
excellent performance characteristics of tire-derived
sorbents combined with their exceptional cost-
effectiveness. Participation in the DOE/NETL pro-
gram is an important recognition of AFR's approach
to mercury control and waste tire utilization. AFR
currently is pursuing business arrangements for the
production of ton quantities of tire-derived mercury
sorbents.

Company History and Awards

Founded in 1980, AFR celebrated its 25th
r anniversary in early 2005. The East
Hartford, Connecticut-based company
\ y has 14 employees at present. Through
SBIR and industrial support, AFR has
il successfully developed a number of

innovative laboratory and process con-
trol instruments and software products

that today are serving industrial and academic
clients throughout the world. AFR received the
U.S. Small Business Administration's prestigious
Tibbetts Award in 2000 for exemplary achievement
in commercializing technology developed with the

support of the SBIR Program. AFR's success has led
to two spin-off companies: MKS Instruments On-
Line Products Group and the newly formed Real-
Time Analyzers, Inc.

SBIR Impact

Mercury emissions from coal combustion and incineration of municipal and
hazardous wastes and the disposal of scrap tires represent two serious envi-
ronmental problems.

AFR developed a novel technology for the removal of mercury from combus-
tion/incineration flue gas while at the same time utilizing massive amounts of
solid waste (scrap tires).

Applications of this technology include use in coal-fired power plants and
municipal, medical, and hazardous waste incinerators.

AFR also has demonstrated the feasibility of making virgin carbon
black from oils produced by waste-tire pyrolysis.

SBIR Success Stories

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