Air Pollution Control Technology Fact Sheet Fabric Filter Reverse-Air Cleaned Type Reverse-Air Cleaned Type with Sonic Horn Enhancement Reverse-Jet Cleaned Type (also referred to as Baghouses)

EPA-452/F-03-026
Air Pollution Control Technology
Fact Sheet
Fabric Filter - Reverse-Air Cleaned Type
- Reverse-Air Cleaned Type with Sonic Horn Enhancement
- Reverse-Jet Cleaned Type
(also referred to as Baghouses)
Control Device - Capture/Disposal
Particulate Matter (PM), including particulate matter less than or equal to 10
micrometers (jjm) in aerodynamic diameter (PM10), particulate matter less than or equal to 2.5 jjm in
aerodynamic diameter (PM2 5), and hazardous air pollutants (HAPs) that are in particulate form, such as most
metals (mercury is the notable exception, as a significant portion of emissions are in the form of elemental
vapor).
Achievable Emission Limits/Reductions:
Typical new equipment design efficiencies are between 99 and 99.9%. Older existing equipment have a range
of actual operating efficiencies of 95 to 99.9%. Several factors determine fabric filter collection efficiency.
These include gas filtration velocity, particle characteristics, fabric characteristics, and cleaning mechanism.
In general, collection efficiency increases with increasing filtration velocity and particle size.
For a given combination of filter design and dust, the effluent particle concentration from a fabric filter is nearly
constant, whereas the overall efficiency is more likely to vary with particulate loading. For this reason, fabric
filters can be considered to be constant outlet devices rather than constant efficiency devices. Constant
effluent concentration is achieved because at any given time, part of the fabric filter is being cleaned. As a
result of the cleaning mechanisms used in fabric filters, the collection efficiency is constantly changing. Each
cleaning cycle removes at least some of the filter cake and loosens particles which remain on the filter. When
filtration resumes, the filtering capability has been reduced because of the lost filter cake and loose particles
are pushed through the filter by the flow of gas. As particles are captured, the efficiency increases until the
next cleaning cycle. Average collection efficiencies for fabric filters are usually determined from tests that
cover a number of cleaning cycles at a constant inlet loading. (EPA, 1998a)
Applicable Source Type: Point
Typical Industrial Applications:
Fabric filters can perform very effectively in many different applications. Common applications of fabric filter
systems with reverse-air cleaning are presented in Table 1, however, fabric filters can be used in most any
process where dust is generated and can be collected and ducted to a central location. Other cleaning-types
may also be used in these applications. Sonic horn enhancement of mechanical shaker cleaning is generally
used for applications with dense particulates such as utility boilers, metal processing, and mineral products.

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Name of Technology:
Type of Technology:
Applicable Pollutants:
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Table 1. Typical Industrial Applications of Reverse-Air -Cleaned Fabric Filters
(EPA, 1997; EPA, 1998a)
Application	Source Category Code
	(SCC)	
Utility Boilers (Coal)	1-01-002...003
Industrial Boilers (Coal, Wood)	1-02-001 ...003,
1-02-009
Commercial/Institutional Boilers (Coal, Wood) 1-03-001 ...003,
1-03-009
Non-Ferrous Metals Processing
(Primary and Secondary):
Copper 3-03-005,3-04-002
Lead 3-03-010,3-04-004
Zinc 3-03-030,3-04-008
Aluminum 3-03-000...002
3-04-001
Other metals production 3-03-011 ...014
3-04-005...006
3-04-010...022
Ferrous Metals Processing:
Coke 3-03-003...004
Ferroalloy Production 3-03-006...007
Iron and Steel Production 3-03-008...009
Gray Iron Foundries 3-04-003
Steel Foundries 3-04-007,-009
Mineral Products:
Cement Manufacturing 3-05-006...007
Coal Cleaning 3-05-010
Stone Quarrying and Processing 3-05-020
Other 3-05-003...999
Asphalt Manufacture 3-05-001 ...002
Grain Milling	3-02-007	
Emission Stream Characteristics:
a.	Air Flow: Baghouses are separated into two groups, standard and custom, which are further
separated into low, medium, and high capacity. Standard baghouses are factory-built, off the shelf
units. They may handle from less than 0.10 to more than 50 standard cubic meters per second
(sm3/sec) ("hundreds" to more than 100,000 standard cubic feet per minute (scfm)). Custom
baghouses are designed for specific applications and are built to the specifications prescribed by
the customer. These units are generally much largerthan standard units, i.e., from 50 to over 500
sm3/sec (100,000 to over 1,000,000 scfm). (EPA, 1998b)
b.	Temperature: Typically, gas temperatures upto about260°C (500°F), with surges to about290°C
(550°F) can be accommodated routinely, with the appropriate fabric material. Spray coolers or
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dilution air can be used to lower the temperature of the pollutant stream. This prevents the
temperature limits of the fabric from being exceeded. Lowering the temperature, however,
increases the humidity of the pollutant stream. Therefore, the minimum temperature of the pollutant
stream must remain above the dew point of any condensable in the stream. The baghouse and
associated ductwork should be insulated and possibly heated if condensation may occur. (EPA,
1998b)
c. Pollutant Loading: Typical inlet concentrations to baghouses are 1 to 23 grams per cubic meter
(g/m3) (0.5 to 10 grains per cubic foot (gr/ft3)), but in extreme cases, inlet conditions may vary
between 0.1 to more than 230 g/m3 (0.05 to more than 100 gr/ft3). (EPA, 1998b)
d. Other Considerations: Moisture and corrosives content are the major gas stream characteristics
requiring design consideration. Standard fabric filters can be used in pressure or vacuum service,
but only within the range of about ±640 millimeters of water column (25 inches of water column).
Well-designed and operated baghouses have been shown to be capable of reducing overall
particulate emissions to less than 0.05 g/m3 (0.010 gr/ft3), and in a number of cases, to as low as
0.002 to 0.011 g/dsm3 (0.001 to 0.005 gr/dscf). (AWMA, 1992)
Emission Stream Pretreatment Requirements:
Because of the wide variety of filtertypes available to the designer, it is not usually required to pretreat a waste
stream's inlet temperature. However, in some high temperature applications, the cost of high temperature-
resistant bags must be weighed against the cost of cooling the inlet temperature with spray coolers or dilution
air (EPA, 1998b). When much of the pollutant loading consists of relatively large particles, mechanical
collectors such as cyclones may be used to reduce the load on the fabric filter, especially at high inlet
concentrations (EPA, 1998b).
Cost Information:
Cost estimates are presented below for reverse-air cleaned fabric filters, for sonic horn enhancement, and for
reverse-jet cleaned fabric filters. The costs are expressed in 2002 dollars for reverse-air cleaned and sonic
horn enhancement. The cost estimates assume a conventional design under typical operating conditions.
The costs do not include auxiliary equipment such as fans and ductwork.
The costs for reverse-air cleaned systems are generated using EPA's cost-estimating spreadsheet for fabric
filters (EPA, 1998b). The cost estimate for sonic horn enhancement is obtained from the manufacturer quote
given in the OAQPS Control Cost Manual (EPA, 1998b). Sonic horns are presented as an incremental cost
to the capital cost for a shaker-cleaned system. The operational and maintenance (O&M) cost for shaker-
cleaned systems are reduced by 1% to 3% with the sonic horn enhancement. The capital costforthe reverse-
jet cleaned fabric baghouse is based on a manufacturer quote (Carrington, 2000). This quote includes only
the baghouse purchased equipment cost. O&M costs, annualized costs, and cost effectiveness were not
estimated for reverse-jet. In general, reverse-jet has higher capital costs and O&M costs than reverse-air due
to its complexity (see Section 10, Theory of Operation).
Costs are primarily driven by the waste stream volumetric flow rate and pollutant loading. In general, a small
unit controlling a low pollutant loading will not be as cost effective as a large unit controlling a high pollutant
loading. The costs presented are for flow rates of 470 m3/sec (1,000,000 scfm) and 1.0 m3/sec (2,000 scfm),
respectively, and a pollutant loading of 9 g/m3 (4.0 gr/ft3). For reverse-jet, the capital cost presented is for
a baghouse of 378,000 m3/sec (800,000 scfm).
Pollutants that require an unusually high level of control or that require the fabric filter bags or the unit itself
to be constructed of special materials, such as Gore-Tex or stainless steel, will increase the costs of the
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system (EPA, 1998b). The additional costs for controlling more complex waste streams are not reflected in
the estimates given below. For these types of systems, the capital cost could increase by as much as 40%
and the O&M cost could increase by as much as 5%.
a. Capital Cost: $19,000 to $180,000 per sm3/s ($9 to $85 per scfm), reverse-air
$1,000 to $1,300 per m3/sec ($ 0.51 to $0.61 per scfm), additional cost for
sonic horns
$2,000 to $4,200 per m3/sec ($1 to $2 per scfm), reverse-jet purchased
equipment cost
b. O & M Cost: $14,000 to $58,000 per sm3/s ($6 to $27 per scfm), annually
c. Annualized Cost: $17,000 to $106,000 per sm3/s ($8 to $50 per scfm), annually
d. Cost Effectiveness: $58 to $372 per metric ton ($53 to $337 per short ton)
Theory of Operation:
In a fabric filter, flue gas is passed through a tightly woven or felted fabric, causing PM in the flue gas to be
collected on the fabric by sieving and other mechanisms. Fabric filters may be in the form of sheets,
cartridges, or bags, with a number of the individual fabric filter units housed together in a group. Bags are
most common type of fabric filter. The dust cake that forms on the filter from the collected PM can significantly
increase collection efficiency. Fabric filters are frequently referred to as baghouses because the fabric is
usually configured in cylindrical bags. Bags may be 6 to 9 m (20 to 30 ft) long and 12.7 to 30.5 centimeters
(cm) (5 to 12 inches) in diameter. Groups of bags are placed in isolable compartments to allow cleaning of
the bags or replacement of some of the bags without shutting down the entire fabric filter. (STAPPA/ALAPCO,
1996)
Operating conditions are important determinants of the choice of fabric. Some fabrics (e.g., polyolefins,
nylons, acrylics, polyesters) are useful only at relatively low temperatures of 95 to 150°C (200 to 300°F). For
high-temperature flue gas streams, more thermally stable fabrics such as fiberglass, Teflon®, or Nomex® must
be used (STAPPA/ALAPCO, 1996).
Practical application of fabric filters requires the use of a large fabric area in order to avoid an unacceptable
pressure drop across the fabric. Baghouse size for a particular unit is determined by the choice of air-to-cloth
ratio, or the ratio of volumetric air flow to cloth area. The selection of air-to-cloth ratio depends on the
particulate loading and characteristics, and the cleaning method used. A high particulate loading will require
the use of a larger baghouse in order to avoid forming too heavy a dust cake, which would result in an
excessive pressure drop As an example, a baghouse for a 250 megawatt (MW) utility boiler may have 5,000
separate bags with a total fabric area approaching 46,500 m2 (500,000 square feet). (ICAC, 1999)
Determinants of baghouse performance include the fabric chosen, the cleaning frequency and methods, and
the particulate characteristics. Fabrics can be chosen which will intercept a greater fraction of particulate, and
some fabrics are coated with a membrane with very fine openings for enhanced removal of submicron
particulate. Such fabrics tend to be more expensive. Cleaning intensity and frequency are important variables
in determining removal efficiency. Because the dust cake can provide a significant fraction of the fine
particulate removal capability of a fabric, cleaning which is too frequent or too intense will lower the removal
efficiency. On the other hand, if removal is too infrequent or too ineffective, then the baghouse pressure drop
will become too high. (ICAC, 1999)
Reverse-air cleaning is a popular fabric filter cleaning method that has been used extensively and improved
over the years. It is a gentler but sometimes less effective clearing mechanism than mechanical shaking.
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Most reverse-air fabric filters operate in a manner similarto shaker-cleaned fabric filters. Typically, the bags
are open on the bottom, closed on top and the gas flows from the inside to the outside of the bags with dust
being captured on the inside. However, some reverse-air designs collect dust on the outside of the bags. In
eitherdesign, reverse-air cleaning is performed by forcing clean airthrough the filters in the opposite direction
of the dusty gas flow. The change in direction of the gas flow causes the bag to flex and crack the filter cake.
In internal cake collection, the bags are allowed to collapse to some extent during reverse-air cleaning. The
bags are usually prevented from collapsing entirely by some kind of support, such as rings that are sewn into
the bags. The support enables the dust cake to fall off the bags and into the hopper. Cake release is also
aided by the reverse flow of the gas. Because felted fabrics retain dust more than woven fabrics and thus,
are more difficult to clean, felts are usually not used in reverse-air systems. (EPA, 1998a)
There are several methods of reversing the flow through the filters. As with mechanical shaker-cleaned fabric
filters, the most common approach is to have separate compartments within the fabric filter so that each
compartment can be isolated and cleaned separately while the other compartments continue to treat the dusty
gas. One method of providing the reverse flow air is by the use of a secondary fan or cleaned gas from the
other compartments. Reverse-air cleaning alone is used only in cases where the dust releases easily from
the fabric. In many instances, reverse-air is used in conjunction with shaking, pulsing or sonic horns. (EPA,
1998a)
Sonic horns are increasingly being used to enhance the collection efficiency of mechanical shaker and
reverse-air fabric filters (AWMA, 1992). Sonic horns utilize compressed air to vibrate a metal diaphragm,
producing a low frequency sound wave from the horn bell. The number of horns required is determined by
fabric area and the number of baghouse compartments. Typically, 1 to 4 horns per compartment operating
at 150 to 200 hertz are required. Compressed air to power the horns is supplied at 275 to 620 kiloPascals
(kPa) (40 to 90 pounds persquare inch gage (psig)). Sonic horns activate for approximately 10 to 30 seconds
during each cleaning cycle (Carr, 1984) .
Sonic horn cleaning significantly reduces the residual dust load on the bags. This decreases the pressure
drop across the filter fabric by 20 to 60%. It also lessens the mechanical stress on the bags, resulting in
longer operational life (Carr, 1984). As stated previously, this can decrease the O&M cost by 1 to 3%,
annually. Baghouse compartments are easily retrofitted with sonic horns. Sonic assistance is frequently used
with fabric filters at coal-burning utilities (EPA, 1998a).
Reverse-jet is a cleaning method developed in the 1950's to provide better removal of residual dusts. In this
method, the reverse air is piped to a ring around the bag with a narrow slot in it. The air flows through the slot,
creating a high velocity air stream that flexes the bag at that point. The ring is mounted on a carriage, driven
by a motor and cable system, that travels up and down the bag. This method provides excellent cleaning of
residual dust. Due to its complexity, however, maintenance requirements are high. In addition, air
impingement on the bags results in increased wear (Billings, 1970). The application of reverse-jet cleaning
has been declining (EPA, 1998a).
Advantages:
Fabric filters in general provide high collection efficiencies on both coarse and fine (submicron) particulates.
They are relatively insensitive to fluctuations in gas stream conditions. Efficiency and pressure drop are
relatively unaffected by large changes in inlet dust loadings for continuously cleaned filters. Filter outlet air
is very clean and may be recirculated within the plant in many cases (for energy conservation). Collected
material is collected dry for subsequent processing or disposal. Corrosion and rusting of components are
usually not problems. Operation is relatively simple. Unlike electrostatic precipitators, fabric filter systems
do not require the use of high voltage, therefore, maintenance is simplified and flammable dust may be
collected with proper care. The use of selected fibrous or granular filter aids (precoating) permits the high-
efficiency collection of submicron smokes and gaseous contaminants. Filter collectors are available in a large
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number of configurations, resulting in a range of dimensions and inlet and outlet flange locations to suit
installation requirements. (AWMA, 1992)
Disadvantages:
Temperatures much in excess of 290°C (550°F) require special refractory mineral or metallic fabrics, which
can be expensive. Certain dusts may require fabric treatments to reduce dust seepage, or in other cases,
assist in the removal of the collected dust. Concentrations of some dusts in the collector, approximately 50
g/m3 (22 gr/ft3), may represent a fire or explosion hazard if a spark or flame is accidentally admitted. Fabrics
can burn if readily oxidizable dust is being collected. Fabric filters have relatively high maintenance
requirements (e.g., periodic bag replacement). Fabric life may be shortened at elevated temperatures and
in the presence of acid or alkaline particulate or gas constituents. They cannot be operated in moist
environments; hygroscopic materials, condensation of moisture, or tarry adhesive components may cause
crusty caking or plugging of the fabric or require special additives. Respiratory protection for maintenance
personnel may be required when replacing fabric. Medium pressure drop is required, typically in the range
of 100 to 250 mm of water column (4 to 10 inches of water column). (AWMA, 1992)
Other Considerations:
Fabric filters are useful for collecting particles with resistivities either too low or too high for collection with
electrostatic precipitators. Fabric filters therefore may be good candidates for collecting fly ash from low-sulfur
coals or fly ash containing high unburned carbon levels, which respectively have high and low resistivities, and
thus are relatively difficult to collect with electrostatic precipitators. (STAPPA/ALAPCO, 1996)
References:
AWMA, 1992. Air & Waste Management Association, Air Pollution Engineering Manual. Van Nostrand
Reinhold, New York.
Billings, 1970. Billings, Charles, et al, Handbook of Fabric Filter Technology Volume I: Fabric Filter
Systems Study, GCA Corp., Bedford MA, December.
Carr, 1984. Carr, R. C. and W. B. Smith, Fabric Filter Technology for Utility Coal-Fired Power Plants, Part
V: Development and Evaluation of Bag Cleaning Methods in Utility Baghouses, J. Air Pollution Control
Assoc., 34(5):584, May.
Carrington, 2000. Personal communication from W. Edson of Carrington Engineering Sales Co. to P.
HemmerofThe Pechan-Avanti Group, Division of E.H. Pechan and Assoc., Inc, January 21.
EPA, 1997. U.S. EPA, Office of Air Quality Planning and Standards, "Compilation of Air Pollutant
Emission Factors, Volume I, Fifth Edition, Research Triangle Park, NC., October.
EPA, 1998a. 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.
EPA, 1998b. U.S. EPA, Office of Air Quality Planning and Standards, "OAQPS Control Cost Manual,"
Fifth Edition, Chapter 5, EPA 453/B-96-001, Research Triangle Park, NC. December.
ICAC, 1999. Institute of Clean Air Companies internet web page www.icac.com, Control Technology
Information - Fabric Filters, page last updated January 11, 1999.
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STAPPA/ALAPCO, 1996. State and Territorial Air Pollution Program Administrators and Association of
Local Air Pollution Control Officials, "Controlling Particulate Matter Under the Clean Air Act: A Menu of
Options," July.
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