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Background and Applications

The Clean Air Act Amendments lists 189 "Hazardous Air Pollutants"; of them 160 are VOCs.

Any stationary source producing more than 10 tons per year of any listed substance, or 25 tons of any combination of listed substances, fall under Title V permitting requirements. Smaller process (under 5,000 cfm and 500 ppm) are now required to install controls.

VOCs can be reduced by switching materials used in a process, such as water based instead of petroleum based solvents and paints. If that is not practical or possible, exhaust can be passed through an incineration device, categorically called a thermal oxidizer.

Thermal oxidizers are used to reduce/remove Volatile Organic Compounds (VOCs) from process exhaust systems.

Typically large volumes of low VOC process air is passed into a concentration device that removes the VOCs from the air before it is exhausted. The VOCs are then driven off of the concentration device by heat, and burnt by a natural gas flame.
Industries that may need Emissions Controls include

Adhesive Coating
Asphalt Manufacturing
Bakery
Brewery
Coating
Combustion Turbines
Composite/Synthetic Materials
Chemical Processing
Electronics/Semiconductor
Food Processing
Industrial Boilers
Loading/Unloading
Metals Finishing
Odor Control
Paint Mfg/Paint Spray
Petroleum/ Hydrocarbon
Pharmaceutical
Plant process heaters
Printing/Laminating/Converting
Roasters
Sheet Board Manufacturing
Sheet Coil Coating
Soil Remediation
Steel Mills
Tape Coating
Utility Boilers
Vinyl Products
Waste Heat Cogeneration Systems
Waste Treatment
Wood Furniture

Types of Thermal Oxidizers

There are several types and variations of Thermal Oxidizers. Which one is 'right' for a given application will depend on the following factors:

level of control required
pollutant(s) to be removed
concentration of the pollutant(s) in the air stream
total volume/flow of the air stream
operating costs
first costs of equipment

After Burner

The typical afterburner consists of a burner, a burner train, a combustion blower and, if necessary, a process fan. Usually, this scheme is not used unless the concentration of the organic pollutant is elevated high enough to yield available energy to heat the products of combustion up to the chosen oxidation temperature. If the gas stream does not contain enough energy, then a burner is supplied to provide the necessary heat. Often, this type of system proves to be uneconomical from an operating cost basis, due to the high gas usage when oxidizing low concentrations of VOC's in the gas stream.

Recuperative

In a recuperative unit, the basic operation of the afterburner is retained except that much of the waste heat is captured. The fact that the system can capture this heat allows for it to operate very economically. In this type of system, a metallic tube or plate-type heat exchanger is built into the exhaust end of the combustion chamber of the oxidation system. Typically, a plate exchanger is used when the exhaust gas stream does not contain elevated amounts of particulate and the maximum amount of heat recovery is desired. Recuperative systems generally are smaller and lighter in weight than other oxidation systems, allowing for skid mounted installations.

Catalytic

Catalytic oxidation systems are another option for low VOC concentrations. These units are similar in design to recuperative units, but oxidize solvents with precious metal or metal-oxide based catalysts, instead of open flames. Operating at about half the temperature of thermal oxidizers, catalytic units have small footprints and relatively low operating costs.

Regenerative

A regenerative system provides extremely high thermal energy recovery. Initially, the incoming process gas passes through a ceramic heat recovery bed before entering the combustion chamber. It is preheated to within 5% of the combustion chamber temperature. After the process stream exits the ceramic bed, the already hot gases are further heated to the desired combustion chamber temperature. These gases are then sent through another heat exchange bed, where energy is absorbed and stored to heat the next cycle of contaminated air. Up to 95 percent of heat energy can be recovered with this multiple-bed approach. Low VOC concentrations can be processed in a self-sustaining mode without burning extra fuel.

Regenerative Catalytic

A more recent addition to the oxidation technologies available to the process engineer is the regenerative catalytic oxidizer. This device is very similar in operation to an RTO, but with a layer of catalyst in the combustion chamber. Both precious metal and metal oxide-based catalysts are presently in use. This technology has only recently been developed, with long term success or failure still to be determined.
More Information

See our Air Toxic Consortium web site at www.AirToxic.com

Source: Energy TechPro