Air Pollution Control Technology
Fact Sheet
EPA-452/F-03-020
Name of Technology: Incinerator - Recuperative Type
This type of incinerator is also referred to as a thermal oxidizer, thermal incinerator, and afterburner; all "with
heat exchangers." However, the term afterburner is generally appropriate only to describe a thermal oxidizer
used to control gases coming from a process where combustion is incomplete.
Type of Technology: Destruction by thermal oxidation
Applicable Pollutants: Primarily volatile organic compounds (VOC). Some particulate matter (PM),
commonly composed as soot (particles formed as a result of incomplete combustion of hydrocarbons (HC),
coke, or carbon residue) will also be destroyed in various degrees.
Achievable Emission Limits/Reductions:
VOC destruction efficiency depends upon design criteria (i.e., chambertemperature, residence time, inlet VOC
concentration, compound type, and degree of mixing) (EPA, 1992). Typical recuperative incinerator design
efficiencies range from 98 to 99.9999% and above, depending on system requirements and characteristics
of the contaminated stream (EPA, 1992; EPA, 1996a). The typical design conditions needed to meet 98%or
greater control or a 20 parts per million by volume (ppmv) compound exit concentration are: 870°C (1600°F)
combustion temperature, 0.75 second residence time, and proper mixing. For halogenated VOC streams,
1100°C (2000°F) combustion temperature, 1.0 second residence time, and use of an acid gas scrubber on
the outlet is recommended (EPA, 1992).
Forvent streams with VOC concentration below approximately 2000 ppmv, reaction rates decrease, maximum
VOC destruction efficiency decreases, and an incinerator outlet concentration of 20 ppmv, or lower may be
achieved (EPA, 1992).
Controlled emissions and/or efficiency test data for PM in incinerators are not generally available in the
literature. Emission factors for PM in phthalic anhydride processes with incinerators are available, however.
The PM control efficiencies for these processes were found to vary from 79 to 96% (EPA, 1998). In EPA's
1990 National Inventory, incinerators used as control devices for PM were reported as achieving 25 - 99%
control efficiency of particulate matter 10 microns or less in aerodynamic diameter (PM10) at point source
facilities (EPA, 1998). Table 1 presents a breakdown of the PM10 control efficiency ranges by industry for
recuperative incinerators (EPA, 1996b). The VOC control efficiency reported for these devices ranged from
0 to 99.9%. These ranges of control efficiencies are large because they include facilities that do not have
VOC emissions and control only PM, as well as facilities which have low PM emissions and are primarily
concerned with controlling VOC (EPA, 1998).
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Table 1. Recuperative Incinerator PM10 Destruction Efficiencies by Industry (EPA, 1996b)
Industry/Types of Sources
PM10 Control
Efficiency (%)
Petroleum and Coal Products
asphalt roofing processes (blowing, felt
saturation); mineral calcining; petroleum
refinery processes (asphalt blowing, catalytic
cracking, coke calcining, sludge converter);
sulfur manufacturing
25 - 99.9
Chemical and Allied Products
carbon black manufacturing (mfg); charcoal
mfg; liquid waste disposal; miscellaneous
chemical mfg processes; pesticide mfg;
phthalic anhydride mfg (xylene oxidation);
plastics/synthetic organic fiber mfg; solid waste
incineration (industrial)
50 - 99.9
Primary Metals Industries
by-product coke processes (coal unloading,
oven charging and pushing, quenching); gray
iron cupola and other miscellaneous
processes; secondary aluminum processes
(burning/drying, smelting furnace); secondary
copper processes (scrap drying, scrap cupola,
and miscellaneous processes); steel foundry
miscellaneous processes; surface coating
oven
70 - 99.9
Electronic and Other Electric Equipment
chemical mfg miscellaneous processes;
electrical equipment bake furnace; fixed roof
tank; mineral production miscellaneous
processes; secondary aluminum roll/draw
extruding; solid waste incineration (industrial)
70 - 99.9
Electric, Gas, and Sanitary Services
internal combustion engines; solid waste
incineration (industrial, commercial/
institutional)
90-98
Food and Kindred Products
charcoal processing, miscellaneous;
corn processing, miscellaneous,
fugitive processing, miscellaneous;
soybean processing, miscellaneous
70-98
National Security and International Affairs
solid waste incineration
(commercial/institutional and municipal)
70
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Applicable Source Type: Point
Typical Industrial Applications:
Recuperative incinerators can be used to reduce emissions from almost all VOC sources, including reactor
vents, distillation vents, solvent operations, and operations performed in ovens, dryers, and kilns. They can
handle minor fluctuations in flow, however, excess fluctuations require the use of a flare (EPA, 1992). Their
fuel consumption is high, so recuperative units are best suited for smaller process applications with moderate-
to-high VOC loadings.
Incinerators are used to control VOC from a wide variety of industrial processes including, but not limited to,
the following (EPA, 1992):
Storing and loading/unloading of petroleum products and other volatile organic liquids;
Vessel cleaning (rail tank cars and tank trucks, barges);
Process vents in the synthetic organic chemical manufacturing industry (SOCMI);
Paint manufacturing;
Rubber products and polymer manufacturing;
Plywood manufacturing;
Surface coating operations:
Appliances, magnetic wire, automobiles, cans, metal coils, paper, film and foil, pressure
sensitive tapes and labels, magnetic tape, fabric coating and printing, metal furniture, wood
furniture, flatwood paneling, aircraft, miscellaneous metal products;
Flexible vinyl and urethane coating;
Graphic arts industry; and
Hazardous waste treatment storage, and disposal facilities (TSDFs).
Emission Stream Characteristics:
a. Air Flow: Typical gas flow rates for recuperative incinerators are 0.24 - 24 standard cubic meters
per second (sm3/sec) (500 to 50,000 standard cubic feet per minute (scfm)) (EPA, 1996a).
b. Temperature: Most incinerators operate at higher temperatures than the ignition temperature,
which is a minimum temperature. Thermal destruction of most organic compounds occurs between
590°C and 650°C (1100°F and 1200°F). Most hazardous waste incinerators are operated at 980°C
to 1200°C (1800°F - 2200°F) to ensure nearly complete destruction of the organics in the waste
(AWMA, 1992).
c. Pollutant Loading: Recuperative incinerators can be used over a fairly wide range of organic
vapor concentrations. For safety considerations, the concentration of the organics in the waste gas
must be substantially below the lower flammable level (lower explosive limit, or LEL) of the specific
compound being controlled. As a rule, a safety factor of four (i.e., 25% of the LEL) is used (EPA,
1991, AWMA, 1992). The waste gas may be diluted with ambient air, if necessary, to lower the
concentration. Considering economic factors, recuperative incinerators perform best at inlet
concentrations of around 1500 to 3000 ppmv, because the heat of combustion of hydrocarbon
gases is sufficient to sustain the high temperatures required without addition of expensive auxiliary
fuel (EPA, 1995).
d. Other Considerations: Incinerators are not generally recommended for controlling gases
containing halogen- orsulfur-containing compounds, because of the formation of hydrogen chloride,
hydrogen fluoride gas, sulfur dioxide, and other highly corrosive acid gases. It may be necessary
to install a post-oxidation acid gas treatment system in such cases, depending on the outlet
concentration. This would likely make incineration an uneconomical option (EPA, 1996a).
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Recuperative incinerators are also not generally cost-effective for low-concentration, high-flow
organic vapor streams (EPA, 1995).
Emission Stream Pretreatment Requirements:
Typically, no pretreatment is required, however, in some cases, a condenser may be used to reduce the total
gas volume to be treated by the more expensive incinerator.
Cost Information:
The following are cost ranges (expressed in 2002 dollars) for packaged recuperative incinerators of
conventional design under typical operating conditions, developed using EPA cost-estimating spreadsheets
(EPA, 1996a) and referenced to the volumetric flow rate of the waste stream treated. The costs do not include
costs for a post-oxidation acid gas treatment system. Costs can be substantially higher than in the ranges
shown when used for low to moderate VOC concentration streams (less than around 1000 to 1500 ppmv).
As a rule, smaller units controlling a low concentration waste stream will be much more expensive (per unit
volumetric flow rate) than a large unit cleaning a high pollutant load flow.
a. Capital Cost: $25,000 to $212,000 per sm3/sec ($12 to $100 per scfm)
b. O & M Cost: $10,000 to $53,000 per sm3/sec ($5 to $25 per scfm), annually
c. Annualized Cost: $17,000 to $95,000 per sm3/sec ($8 to $45 per scfm), annually
d. Cost Effectiveness: $105 to $2,000 per metric ton ($95 to $1,800 per short ton), annualized
cost per ton per year of pollutant controlled
Theory of Operation:
Incineration, orthermal oxidation is the process of oxidizing combustible materials by raising the temperature
of the material above its auto-ignition point in the presence of oxygen, and maintaining it at high temperature
for sufficient time to complete combustion to carbon dioxide and water. Time, temperature, turbulence (for
mixing), and the availability of oxygen all affect the rate and efficiency of the combustion process. These
factors provide the basic design parameters for VOC oxidation systems (ICAC, 1999).
The recuperative incinerator is comprised of the combustion chamber, the waste gas preheater, and, if
appropriate, a secondary energy recovery heat exchanger.
The two types of heat exchangers most commonly used are plate-to-plate and shell-and-tube. Plate-to-plate
exchangers offer high efficiency energy recovery at lower cost than shell-and-tube designs. Also, because
of their modular configuration, plate-to-plate units can be built to achieve a variety of efficiencies. However,
when gas temperatures exceed 540°C (1000°F), shell-and-tube exchangers usually have lower purchase
costs than plate-to-plate designs. Moreover, shell-and-tube exchangers offer better long-term structural
reliability than plate-to-plate units (EPA, 1996a).
Some of the energy added by auxiliary fuel in the traditional thermal units (but not recovered in preheating
the feed stream) can still be recovered. Additional heat exchangers can be added to provide process heat
in the form of low pressure steam or hot water for on-site application. The need for this higher level of energy
recovery will depend upon the specific facility (EPA, 1996a).
The heart of the thermal incinerator is a nozzle-stabilized flame maintained by a combination of auxiliary fuel,
waste gas compounds, and supplemental air added when necessary. Upon passing through the flame, the
waste gas is heated from its preheated inlet temperature to its ignition temperature. The ignition temperature
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varies for different compounds and is usually determined empirically. It is the temperature at which the
combustion reaction rate exceeds the rate of heat losses, thereby raising the temperature of the gases to
some higher value. Thus, any organic/air mixture will ignite if its temperature is raised to a sufficiently high
level (EPA, 1996a).
The required level of VOC control of the waste gas that must be achieved within the time that it spends in the
thermal combustion chamber dictates the reactortemperature. Theshorterthe residence time, the higher the
reactor temperature must be. The nominal residence time of the reacting waste gas in the combustion
chamber is defined as the combustion chamber volume divided by the volumetric flow rate of the gas. Most
thermal units are designed to provide no more than 1 second of residence time to the waste gas with typical
temperatures of 650 to 1100°C (1200 to 2000°F). Once the unit is designed and built, the residence time is
not easily changed, so that the required reaction temperature becomes a function of the particular gaseous
species and the desired level of control (EPA, 1996a).
Studies based on actual field test data, show that commercial incinerators should generally be run at 870°C
(1600°F) with a nominal residence time of 0.75 seconds to ensure 98% destruction of non-halogenated
organics (EPA, 1992).
Advantages:
Incinerators are one of the most positive and proven methods for destroying VOC, with efficiencies up to
99.9999% possible. Recuperative incinerators usually are more economical than straight thermal incinerators
because they recover about 70% of the waste heat from the exhaust gases. This heat can be used to preheat
incoming air, and oftentimes, sufficient waste heat will be available for process heating, orto generate steam
or hot water.
Disadvantages:
Even with recuperating waste heat energy, incinerator operating costs are relatively high due to
supplemental fuel costs.
Thermal incinerators, including recuperative types, are not well suited to streams with highly variable flow
because of the reduced residence time and poor mixing during increased flow conditions which decreases
the completeness of combustion. This causes the combustion chamber temperature to fall, thus decreasing
the destruction efficiency (EPA, 1991).
Incinerators, in general, are not recommended for controlling gases containing halogen- or sulfur-containing
compounds because of the formation of highly corrosive acid gases. It may be necessary to install a post-
oxidation acid gas treatment system in such cases, depending on the outlet concentration (EPA, 1996a).
Recuperative incinerators are also not generally cost-effective for low-concentration, high-flow organic vapor
streams (EPA, 1995).
Other Considerations:
Thermal recovery efficiencies typically are limited to 40 to 70% to prevent auto-ignition in the heat
exchange package, which could damage the package.
References:
AWMA, 1992. Air & Waste Management Association, Air Pollution Engineering Manual. Van Nostrand
Reinhold, New York.
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EPA, 1991. U.S. EPA, Office of Research and Development, "Control Technologies for Hazardous Air
Pollutants," EPA/625/6-91/014, Washington, D.C., June.
EPA, 1992. U.S. EPA, Office of Air Quality Planning and Standards, "Control Techniques for Volatile
Organic Emissions from Stationary Sources," EPA-453/R-92-018, Research Triangle Park, NC.,
December.
EPA, 1995. U.S. EPA, Office of Air Quality Planning and Standards, "Survey of Control Technologies for
Low Concentration Organic Vapor Gas Streams," EPA-456/R-95-003, Research Triangle Park, NC., May.
EPA, 1996a. U.S. EPA, Office of Air Quality Planning and Standards, "OAQPS Control Cost Manual,"
Fifth Edition, EPA 453/B-96-001, Research Triangle Park, NC. February.
EPA, 1996b. U.S. EPA, "1990 National Inventory," Research Triangle Park, NC, January.
EPA, 1998. U.S. EPA, Office of Air Quality Planning and Standards, "Stationary Source Control
Techniques Document for Fine Particulate Matter," EPA-452/R-97-001, Research Triangle Park, NC.,
October.
ICAC, 1999. Institute of Clean Air Companies internet web page www.icac.com, Control Technology
Information - Thermal Oxidation, page accessed March 1999.
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