Air Pollution Control Technology Fact Sheet Selective Non-Catalytic Reduction (SNCR)

EPA-452/F-03-031
Air Pollution Control Technology
Fact Sheet
Name of Technology: Selective Non -Catalytic Reduction (SNCR)
Type of Technology: Control Device - Chemical reduction of a pollutant via a reducing agent.
Applicable Pollutants: Nitrogen Oxides (NO^
Achievable Emission Limits/Reductions:
NOx reduction levels range from 30% to 50% (EPA, 2002). For SNCR applied in conjunction with
combustion controls, such as low NOx burners, reductions of 65% to 75% can be achieved (ICAC 2000).
Applicable Source Type: Point
Typical Industrial Applications:
There are hundreds of commercially installed SNCR systems on a wide range of boiler configurations
including: dry bottom wall fired and tangentially fired units, wet bottom units, stokers, and fluidized bed
units. These units fire a variety of fuels such as coal, oil, gas, biomass, and waste. Other applications
include thermal incinerators, municipal and hazardous solid waste combustion units, cement kilns,
process heaters, and glass furnaces.
Emission Stream Characteristics:
a. Combustion Unit Size: In the United States, SNCR has been applied to boilers and other
combustion units ranging in size from 50 to 6,000 MMBtu/hr (5 to 600MW/hr) (EPA, 2002).
Until recently, it was difficult to get high levels of NOx reduction on units greater than 3,000
MMBtu (300 MW) due to limitations in mixing. Improvements in SNCR injection and control
systems have resulted in high NOx reductions (> 60%) on utility boilers greater than 6,000
MMBtu/hr (600MW). (ICAC, 2000).
b. Temperature: The NOx reduction reaction occurs at temperatures between 1600°F to 2100°F
(870°C to 1150°C) (EPA, 2002). Proprietary chemicals, referred to as enhancers or additives,
can be added to the reagent to lower the temperature range at which the NOx reduction
reactions occur.
c. Pollutant Loading: SNCR tends to be less effective at lower levels of uncontrolled NOx.
Typical uncontrolled NOx levels vary from 200 ppm to 400 ppm (NESCAUM, 2000). SNCR is
better suited for applications with high levels of PM in the waste gas stream than SCR.
d. Other Considerations: Ammonia slip refers to emissions of unreacted ammonia that result
from incomplete reaction of the NOx and the reagent. Ammonia slip may cause: 1) formation
of ammonium sulfates, which can plug or corrode downstream components, 2) ammonia
absorption into fly ash, which may affect disposal or reuse of the ash, and 3) increased plume

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visibility. In the U.S., permitted ammonia slip levels are typically 2 to 10 ppm (EPA, 2002).
Ammonia slip at these levels do not result in plume formation or pose human health hazards.
Process optimization after installation can lower slip levels.
Nitrous Oxide (N20) is a by-product formed during SNCR. Urea based reduction generates
more NzO than ammonia-based systems. At most, 10% of the NOx reduced in urea-based
SNCR is converted to NzO. Nitrous oxide does not contribute to ground level ozone or acid
formation. (ICAC,2000)
Emission Stream Pretreatment Requirements: None
Cost Information: All costs are in year 1999 dollars. (NESCAUM, 2000; ICAC, 2000; and EPA, 2002)
The difficulty of SNCR retrofit on existing large coal-fired boilers is considered to be minimal. However,
the difficulty significantly increases for smaller boilers and packaged units. The primary concern is
adequate wall space within the boiler for installation of injectors. Movement and/or removal of existing
watertubes and asbestos from the boiler housing may be required. In addition, adequate space adjacent
to the boiler must be available for distribution system equipment and for performing maintenance. This
may require modifications to ductwork and other boiler equipment.
A typical breakdown of annual costs for industrial boilers will be 15% to 35% for capital recovery and 65%
to-85% for operating expense (ICAC,2000). Since SNCR is an operating expense-driven technology, its
cost varies directly with NOx reduction requirements and reagent usage. Optimization of the injection
system after start up can reduce reagent usage and, subsequently, operating costs. Recent
improvements in SNCR injection systems have also lowered operating costs.
There is a wide range of cost effectiveness for SNCR due to the different boiler configurations and site-
specific conditions, even within a given industry. Cost effectiveness is impacted primarily by uncontrolled
NOx level, required emissions reduction, unit size and thermal efficiency, economic life of the unit, and
degree of retrofit difficulty. The cost effectiveness of SNCR is less sensitive to capacity factor than SCR.
Control of NOx is often only required during the ozone season, typically June through August. Since
SNCR costs are a function of operating costs, SNCR is an effective control option for seasonal NOx
reductions.
Costs are presented below for industrial boilers greater than 100 MMBtu/hr.
a. Capital Cost: 900 to 2,500 $/MMBtu/hr (9,000 to 25,000 $/MW)
b. O&M Cost: 100 to 500 $/MMBtu/hr (1,000 to 5,000 $/MW)
c. Annualized Cost: 300 to 1000 $/MMBtu/hr (3,000 to 10,000 $/MW)
d. Cost per Ton of Pollutant Removed:
Annual Control: 400 to 2,500 $/ton of NOx removed
Seasonal Control: 2,000 to 3,000 $/ton of NOx removed
Theory of Operation:
SNCR is based on the chemical reduction of the NOx molecule into molecular nitrogen (N2) and water
vapor (H20). A nitrogen based reducing agent (reagent), such as ammonia or urea, is injected into the
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post combustion flue gas. The reduction reaction with NOx is favored over other chemical reaction
processes at temperatures ranging between 1600°F and 2100°F (870°C to 1150°C), therefore, it is
considered a selective chemical process (EPA, 2002).
Both ammonia and urea are used as reagents. Urea-based systems have advantages over ammonia
based systems. Urea is non-toxic, less volatile liquid that can be stored and handled more safely. Urea
solution droplets can penetrate farther into the flue gas when injected into the boiler, enhancing the
mixing with the flue gas which is difficult in large boilers. However, urea is more expensive than ammonia.
The Normalized Stoichiometric Ratio (NSR) defines the ratio of reagent to NOx required to achieve the
targeted NOx reduction. In practice, more than the theoretical amount of reagent needs to be injected
into the boiler flue gas to obtain a specific level of NOx reduction.
In the SNCR process, the combustion unit acts as the reactor chamber. The reagent is generally injected
within the boiler superheater and reheater radiant and convective regions, where the combustion gas
temperature is at the required temperature range. The injection system is designed to promote mixing of
the reagent with the flue gas. The number and location of injection points is determined by the
temperature profiles and flow patterns within the combustion unit.
Certain application are more suited for SNCR due to the combustion unit design. Units with furnace exit
temperatures of 1550°F to 1950°F (840°C to 1065°C), residence times of greater than one second, and
high levels of uncontrolled NOx are good candidates.
During low-load operation, the location of the optimum temperature region shifts upstream within the
boiler. Additional injection points are required to accommodate operations at low loads. Enhancers can
be added to the reagent to lower the temperature range at which the NOx reduction reaction occurs. The
use of enhancers reduces the need for additional injection locations.
Advantages:
Capital and operating costs are among the lowest of all NOx reduction methods.
Retrofit of SNCR is relatively simple and requires little downtime for large and medium size
units.
Cost effective for seasonal or variable load applications.
Waste gas streams with high levels of PM are acceptable.
Can be applied with combustion controls to provide higher NOx reductions.
Disadvantages:
The waste gas stream must be within a specified temperature range.
Not applicable to sources with low NOx concentrations such as gas turbines.
Lower NOx reductions than Selective Catalytic Reduction (SCR).
May require downstream equipment cleaning.
Results in ammonia in the waste gas stream which may impact plume visibility, and resale or
disposal of ash.
References:
EPA, 1998. U.S. Environmental Protection Agency, Innovative Strategies and Economics Group, "Ozone
Transport Rulemaking Non-Electricity Generating Unit Cost Analysis", Prepared by Pechan-Avanti Group,
Research Triangle Park, NC. 1998.
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EPA, 1999. US Environmental Protection Agency, Clean Air Technology Center. "Technical Bulletin:
Nitrogen Oxides (NOx), Why and How They Are Controlled". Research Triangle Park, NC. 1998.
EPA, 2002. U.S. Environmental Protection Agency, Office of Air Quality Planning and Standards. EPA
Air Pollution Control Cost Manual, Section 4 Chapter 1. EPA 452/B-02-001. 2002.
http://www.epa.gov/ttn/catc/dir1/cs4-2ch1 .pdf
ICAC, 2000. Institute of Clean Air Companies, Inc. "White Paper: Selective Non-Catalytic Reduction
(SNCR) for Controlling NOx Emissions". Washington, D.C. 2000.
NESCAUM, 2000. Northeast States for Coordinated Air Use Management. "Status Reports on NOx
Controls for Gas Turbines, Cement Kilns, Industrial Boilers, and Internal Combustion Engines:
Technologies & Cost Effectiveness". Boston, MA. 2002.
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