U.S. patent application number 14/679712 was filed with the patent office on 2015-07-30 for after-treatment system.
This patent application is currently assigned to CATERPILLAR INC.. The applicant listed for this patent is Caterpillar Inc.. Invention is credited to Mirza P. Baig, Andrew M. Denis, Kristian N. Engelsen, Rick E. Jeffs, Thomas W. Manning, Pradyumna V. Rao.
Application Number | 20150211406 14/679712 |
Document ID | / |
Family ID | 49999270 |
Filed Date | 2015-07-30 |
United States Patent
Application |
20150211406 |
Kind Code |
A1 |
Baig; Mirza P. ; et
al. |
July 30, 2015 |
After-Treatment System
Abstract
An after-treatment system includes a Selective Catalytic
Reduction (SCR) catalyst or a similar aftertreatment unit or brick
that may be inserted into the opened end of a sleeve. The
aftertreatment brick includes a substrate matrix with catalytic
material that extends between a first face and a second face. A
mantle is disposed around the substrate matrix and extends between
a first rim proximate the first face and a second rim proximate the
second face. The mantle may include a overhang extension that
extends the first rim of the mantle beyond the first face of the
substrate matrix. To enable retrieval of the SCR catalyst from the
sleeve, a retrieval feature is disposed on a readily accessible,
inner surface of the overhang extension.
Inventors: |
Baig; Mirza P.; (Peoria,
IL) ; Manning; Thomas W.; (Metamora, IL) ;
Jeffs; Rick E.; (Peoria, IL) ; Engelsen; Kristian
N.; (South Bend, IN) ; Denis; Andrew M.;
(Peoria, IL) ; Rao; Pradyumna V.; (Peoria,
IL) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Caterpillar Inc. |
Peoria |
IL |
US |
|
|
Assignee: |
CATERPILLAR INC.
Peoria
IL
|
Family ID: |
49999270 |
Appl. No.: |
14/679712 |
Filed: |
April 6, 2015 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
13571053 |
Aug 9, 2012 |
9011782 |
|
|
14679712 |
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Current U.S.
Class: |
29/402.03 ;
422/180 |
Current CPC
Class: |
F01N 2450/00 20130101;
F01N 3/035 20130101; Y10T 29/49233 20150115; F01N 13/18 20130101;
F01N 2450/18 20130101; F01N 13/017 20140601; F01N 3/2066 20130101;
F01N 13/1838 20130101; F01N 3/2842 20130101; F01N 13/0097 20140603;
F01N 2450/30 20130101; F01N 2470/14 20130101; F01N 3/103 20130101;
Y02T 10/24 20130101; Y02T 10/12 20130101; F01N 2470/16 20130101;
Y10T 29/49721 20150115; F01N 2470/22 20130101; B01D 53/9431
20130101 |
International
Class: |
F01N 13/18 20060101
F01N013/18; B01D 53/94 20060101 B01D053/94 |
Claims
1. An aftertreatment brick for removable insertion into a sleeve
disposed in an aftertreatment module, the aftertreatment brick
configured as a flow-through device and further comprising: a
substrate matrix extending between a first face and an opposed
second face, the substrate matrix configured as a flow-through
device for the catalytic conversion of exhaust gases flowing from
the first face to the second face; a tubular mantle disposed around
the substrate matrix, the mantle extending between an open first
rim proximate the first face and an open second rim proximate the
second face, the mantle including an overhang extension extending
the first rim beyond the first face; and a retrieval feature
disposed on an inner surface of the overhang extension, the
retrieval feature enabling retrieval of the aftertreatment brick
from the sleeve.
2. The aftertreatment brick of claim 1, wherein the substrate
matrix is cylindrical and the first face and the second face are
circular; and wherein the tubular mantle is disposed around the
cylindrical substrate matrix so that the first rim and the second
rim are circular.
3. The aftertreatment brick of claim 2, wherein the retrieval
feature is a slot radially disposed in the inner surface of the
overhang extension of the tubular mantle, the slot adapted to
engage a retrieval tool enabling retrieval of the aftertreatment
brick from the sleeve.
4. The aftertreatment brick of claim 3, wherein the slot is an
elongated and narrow slot radially disposed in the overhang
extension between the first face of the substrate matrix and the
first rim of the mantle.
5. The aftertreatment brick of claim 2, where the retrieval feature
includes a first slot and a second slot each radially disposed into
the inner surface of the overhang extension and diametrically
opposed to each other.
6. The aftertreatment brick of claim 5, wherein the retrieval tool
is an inverted tong having a first leg and a second leg pivotally
joined together to articulate with respect to each other, the
retrieval tool further including a first rib formed at a first
distal end of the first leg and a second rib formed at a second
distal end of the second leg, the first and second ribs configured
to be received in the respective first and second slots when the
first and second legs are articulated.
7. The aftertreatment brick of claim 3, wherein the slot is
laser-cut completely through the overhang extension.
8. The aftertreatment brick of claim 2, wherein the retrieval
feature includes a pocket-like catch disposed on and protruding
radially inward from the inner surface of the overhang extension,
the pocket-like catch defining an inner pocket directed away from
the first rim.
9. The aftertreatment brick of claim 8, wherein the pocket-like
catch is configured to receive in the inner pocket a hook-like
catch disposed on a retrieval tool inserted in the first rim.
10. The aftertreatment brick of claim 2, wherein the substrate
matrix is a thin-walled lattice, honeycombed, or meshed structure
and the tubular mantle is a relatively thicker sheet metal
material.
11. A method of servicing an aftertreatment module comprising:
providing an aftertreatment module including at least one sleeve
extending between an upstream end and a downstream end along a
longitudinal axis, the at least one sleeve including an axially
aligned opening formed at the upstream end; providing a first
aftertreatment brick including: (i) a substrate matrix configured
for catalytic conversion of exhaust gasses and configured as a
flow-through device between a first face and an opposing second
face, (ii) a tubular mantle disposed around the substrate matrix
and extending between an opened first rim proximate the first face
and an opened second rim proximate the second face, the tubular
mantle including an overhang extension extending the first rim
beyond the first face, and (iii) a retrieval feature disposed on an
inner surface of the overhang extension; accommodating the first
aftertreatment brick in the at least one sleeve, the first
aftertreatment brick axially aligned along the longitudinal axis;
and retrieving the first aftertreatment brick from the at least one
sleeve by engaging the retrieval feature and removing the first
aftertreatment brick through the opening of the at least one
sleeve.
12. The method of claim 11, wherein the retrieval feature is a slot
radially disposed in the inner surface of the overhang extension
between the first face of the substrate matrix and the first rim of
the tubular mantle.
13. The method of claim 12, wherein the step of retrieving includes
receiving a retrieval tool into the slot to pull the first
aftertreatment brick from the at least one sleeve.
14. The method of claim 11, wherein the retrieval feature includes
a first slot and a second slot radially disposed into the inner
surface of the overhang extension between the first face and the
first rim, the first slot and the second slot diametrically opposed
to each other.
15. The method of claim 14, further comprising providing a
retrieval tool in the form of a inverted tong including a first leg
and a second leg pivotally joined to articulate with respect to
each other, the first leg including a first rib at a first distal
end and the second leg including a second rib at a second distal
end.
16. The method of claim 15, wherein the step of retrieving includes
inserting the retrieval tool into the first rim and articulating
the first and second legs to engage the first and second ribs with
the respective first and second slots radially disposed in the
overhang extension.
17. The method of claim 11, wherein the retrieval feature includes
a pocket-like catch disposed onto an inner surface of the overhang
extension between the first face and the first rim, the pocket-like
catch defining an inner pocket directed away from the first
rim.
18. The method of claim 17, wherein the step of retrieving includes
inserting a hook-like retrieval tool into the first rim and
engaging the hook-like retrieval tool with the pocket-like catch.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. application Ser.
No. 13/571,053, filed on Aug. 9, 2012.
TECHNICAL FIELD
[0002] This patent disclosure relates generally to an exhaust
after-treatment system for reducing emissions from power systems
such as large internal combustion engines and, more particularly,
to a system in which individual catalysts or aftertreatment bricks
may be occasionally removed and serviced.
BACKGROUND
[0003] Power systems, particularly internal combustion engines like
diesel engines, gasoline engines and natural gas burning turbines,
create a number of byproducts and emissions during operation
including nitrogen oxide emissions such as NO and NO.sub.2,
sometimes represented as NO.sub.X. In response to increased
government-mandated regulations over such emissions, manufacturers
of internal combustion engines have developed measures to reduce
the amount or effect of the nitrogen oxides produced by the
internal combustion process. One method is a chemical process
called selective catalytic reduction, which may be referred to as
SCR. In the SCR process, a gaseous or liquid reductant agent is
introduced to the exhaust system where the reductant agent can
intermix with the exhaust gasses or it can be adsorbed onto a
catalyst located in the exhaust system downstream of the internal
combustion engine. A common reductant agent is urea, though other
suitable substances such as ammonia may be readily used in the SCR
process. The NO.sub.x pollutants can react with the reductant agent
and the catalyst such that the NO.sub.x is converted into nitrogen
(N.sub.2) and water (H.sub.2O).
[0004] The catalyst used in the SCR process may include an internal
support structure or substrate matrix that has been treated or
coated with an active material that promotes the SCR conversion
process. For example, the matrix may be metal or ceramic or a
combination like copper zeolite coated with a base metal like
vanadium. In a large scale application, multiple catalysts may be
disposed in a common housing or module, such as indicated in U.S.
Patent Publication No. 2009/0113709 titled "Method of Manufacturing
Exhaust Aftertreatment Devices," herein incorporated by reference
in its entirety. That application describes a plurality of
monolithic substrates that may be wrapped in a support mat and
inserted via a soft-stuffing process into a cylindrical housing for
retention.
[0005] Over time, the active material in SCR catalysts may become
depleted or may become deactivated due to other products in the
exhaust gasses such as phosphorous or sulfur collecting in the
catalyst. Additionally, the substrate matrix is commonly designed
as a thin-walled grid or frame that may become damaged.
Accordingly, it may be necessary to occasionally remove the SCR
catalysts from the exhaust system for repair or replacement.
However, where multiple catalysts are included in a housing or
module, especially in exhaust systems associated with large power
systems, removal and replacement of an individual catalyst may be
complicated.
SUMMARY
[0006] The disclosure describes, in one aspect, an aftertreatment
brick for insertion into a sleeve. The aftertreatment brick
includes a substrate matrix extending between a first face and a
second face. A mantle is disposed around the substrate matrix. The
mantle may extend between a first rim proximate the first face and
a second rim proximate the second face. The mantle may further
include an overhang extension extending the first rim beyond the
first face. To enable retrieval of the aftertreatment brick from
the sleeve, the aftertreatment brick can include a retrieval
feature disposed on an inner surface of the overhang extension.
[0007] In another aspect, the disclosure describes a method of
servicing an aftertreatment module when needed. The aftertreatment
module includes at least one longitudinal sleeve that extends
between an upstream end and a downstream end along a longitudinal
axis. The sleeve has an axially aligned opening formed at the
upstream end. The method includes accommodating a first
aftertreatment brick in the sleeve to be axially aligned along the
longitudinal axis. The method further involves retrieving the first
aftertreatment brick from the sleeve by engaging a retrieval
feature on the first aftertreatment brick and removing the first
SCR catalyst axially through the opening.
[0008] In yet another aspect, the disclosure describes an
aftertreatment module including a plurality of longitudinal sleeves
arranged in a bundle. Each of the sleeves extends between an
upstream end and a downstream end along a longitudinal axis and
includes an opening formed at each of the upstream ends. A
plurality of aftertreatment bricks are axially inserted into each
sleeve, including at least a first aftertreatment brick disposed
toward the upstream end and a second aftertreatment brick disposed
toward the downstream end. Each of the aftertreatment bricks
includes a substrate matrix and a mantle disposed around the
substrate matrix. The mantle may have an overhang extension
extending beyond the substrate matrix. Each of the aftertreatment
bricks further includes a retrieval feature disposed on the
overhang extension. The retrieval feature enables retrieval of the
first aftertreatment brick and the second aftertreatment brick from
the sleeve axially through the opening of the upstream end.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] FIG. 1 is a side elevational view of a power system
including an internal combustion engine coupled to a generator and
associated with a clean emissions module.
[0010] FIG. 2 is a perspective view of the clean emissions module
with the top removed to illustrate the components inside of, and
the exhaust flow through, the module.
[0011] FIG. 3 is a perspective view of an SCR module disposed in
the clean emissions module of FIG. 2 that includes at least one
sleeve receiving a plurality of SCR catalysts.
[0012] FIG. 4 is a perspective view of an embodiment of an
aftertreatment brick, particularly an SCR catalyst, having a
retrieval feature in the form of a slot disposed in an overhang
extension of the outer mantle of the SCR catalyst with the
substrate matrix of the catalyst illustrated in detail.
[0013] FIG. 5 is a perspective view of the SCR catalyst of FIG. 4
being retrieved from the sleeve of a SCR module, depicted in dashed
lines, by a retrieval tool engaged with the slot.
[0014] FIG. 6 is a perspective view of another embodiment of a
retrieval tool engaging diametrically opposing slots disposed on
the SCR catalyst.
[0015] FIG. 7 is a perspective view of another embodiment of the
SCR catalyst having a retrieval feature in the form of a handle
attached to brackets disposed on the overhang extension with a
bracket illustrated in detail.
[0016] FIG. 8 is a perspective view of another embodiment of the
SCR catalyst having a retrieval feature in the form of a catch
disposed on the circular overhang extension that is engagable with
a retrieval tool.
DETAILED DESCRIPTION
[0017] This disclosure relates generally to an exhaust
after-treatment system and more particularly to catalysts for
selective catalytic reduction (SCR) that are adapted to be
retrieved from such systems. Now referring to the drawings, wherein
like reference numbers refer to like elements, there is illustrated
in FIG. 1 a power system 100 that can generate power by combusting
fossil fuels or the like. The illustrated power system 100 can
include an internal combustion engine 102 such as a diesel engine
operatively coupled to a generator 104 for producing electricity.
The internal combustion engine 102 may have any number of cylinders
as may be appreciated by one of ordinary skill in the art. The
internal combustion engine 102 and the generator 104 can be
supported on a common mounting frame 106. The power system 100 can
provide on-site stand-by power or continuous electrical power at
locations where access to an electrical grid is limited or
unavailable. Accordingly, the generator 104 and internal combustion
engine 102 can be scaled or sized to provide suitable wattage and
horsepower. It should be appreciated that in other embodiments, the
power system of the present disclosure can be utilized in other
applications such as gasoline burning engines, natural gas
turbines, and coal burning systems. Further, in addition to
stationary applications, the present disclosure can be utilized in
mobile applications such as locomotives and marine engines.
[0018] To direct intake air into and exhaust gasses from the power
system 100, the power system can include an air introduction system
110 and an exhaust system 112. The air introduction system 110
introduces air or an air/fuel mixture to the combustion chambers of
the internal combustion engine 102 for combustion while the exhaust
system 112 includes an exhaust pipe or exhaust channel 114 in fluid
communication with the combustion chambers to direct the exhaust
gasses produced by the combustion process to the environment. To
pressurize intake air by utilizing the positive pressure of the
expelled exhaust gasses, the power system 100 can include one or
more turbochargers 116 operatively associated with the air
introduction system 110 and the exhaust system 112.
[0019] The exhaust system 112 can include components to condition
or treat the exhaust gasses before they are discharged to the
environment. For example, an exhaust after-treatment system module
120 in the form of a clean emissions module (CEM) can be disposed
in fluid communication with the exhaust system 112 downstream of
the turbochargers 116 to receive the exhaust gasses discharged from
the internal combustion engine 102. The after-treatment module 120
can be designed as a separate unit that can be mounted to the power
system 100 generally over the generator 104, for example, and can
receive exhaust gasses from the exhaust channel 114. By
manufacturing the after-treatment module 120 as a separate modular
unit, the design can be utilized with different sizes and
configurations of the power system 100. The after-treatment module
120 can be configured to treat, remove or convert regulated
emissions and other constituents in the exhaust gasses.
[0020] Referring to FIG. 2, the after-treatment module 120 can
include a box-like housing 122 that is supported on a base support
124 adapted to mount the after-treatment module to the power
system. The box-like housing 122 can include a forward-directed
first wall 126, an opposing rearward second wall 128, and
respective third and fourth sidewalls 130, 132. However, it should
be appreciated that terms like forward, rearward and side are used
only for orientation purposes and should not be construed as a
limitation on the claims. Additionally, extending between the
forward first wall 126 and rearward second wall 128 and located
midway between the third and fourth sidewalls 130, 132 can be an
imaginary central module axis line 134. The housing 122 may be made
from welded steel plates or sheet material.
[0021] To receive the untreated exhaust gasses into the
after-treatment module 120, one or more inlets 140 can be disposed
through first wall 126 of the housing 122 and can be coupled in
fluid communication to the exhaust channel from the exhaust system.
In the embodiment illustrated, the after-treatment module 120
includes two inlets 140 arranged generally in parallel and
centrally located between the third and fourth sidewalls 130, 132
on either side of the module axis line 134 so that the entering
exhaust gasses are directed toward the rearward second wall 128.
However, other embodiments of the after-treatment module 120 may
include different numbers and/or locations for the inlets. To
enable the exhaust gasses to exit the after-treatment module 120,
two outlets 142 can also be disposed through the first wall 126 of
the housing 122. Each outlet 142 can be parallel to the centrally
oriented inlets 140 and can be disposed toward one of the
respective third and fourth sidewalls 130, 132.
[0022] To treat or condition the exhaust gasses, the housing 122
can contain various types or kinds of exhaust treatment devices
through or past which the exhaust gasses are directed. For example
and following the arrows indicating exhaust flow through the
after-treatment module 120, in order to slow the velocity of the
incoming exhaust gasses for treatment, the inlets 140 can each be
communicatively associated with an expanding, cone-shaped diffuser
144 mounted exteriorly of the front first wall 126. Each diffuser
144 can direct the exhaust gasses to an associated diesel oxidation
catalyst (DOC) 146 located proximate the first wall 126 inside the
housing 122 that then directs the exhaust gasses to a common
collector duct 148 centrally aligned along the module axis line
134. The DOCs 146 can contain materials such as platinum group
metals like platinum or palladium which can catalyze carbon
monoxide and hydrocarbons in the exhaust gasses to water and carbon
dioxide via the following possible reactions:
CO+1/2O.sub.2=CO.sub.2 (1)
[HC]+O.sub.2=CO.sub.2+H.sub.2O (2)
[0023] To further reduce emissions in the exhaust gasses and
particularly to reduce nitrogen oxides such as NO and NO.sub.2,
sometimes referred to as NO.sub.X, the after-treatment module may
include an SCR system 150. In the SCR process, a liquid or gaseous
reductant agent is introduced to the exhaust system and directed
through an SCR catalyst along with the exhaust gasses. The SCR
catalyst can include materials that cause the exhaust gasses to
react with the reductant agent to convert the NO.sub.X to nitrogen
(N.sub.2) and water (H.sub.2O). A common reductant agent is urea
((NH.sub.2).sub.2CO), though other suitable substances such as
ammonia (NH.sub.3) can be used in the SCR process. The reaction may
occur according to the following general formula:
NH.sub.3+NO.sub.X=N.sub.2+H.sub.2O (3)
[0024] Referring to FIG. 2, to introduce the reductant agent, the
SCR system 150 includes a reductant injector 152 located downstream
of the collector duct 148 and upstream of a centrally aligned
mixing duct 154 that channels the exhaust gasses toward the
rearward second wall 128 of the housing 122. The reductant injector
152 can be in fluid communication with a storage tank or reservoir
storing the reductant agent and can periodically, or continuously,
inject a measure of the reductant agent into the exhaust gas stream
in a process sometimes referred to as dosing. The amount of
reductant agent introduced can be dependent upon the NO.sub.X load
of the exhaust gasses. The elongated mixing duct 154 uniformly
intermixes the reductant agent with the exhaust gasses before they
enter the downstream SCR catalysts. Disposed at the end of the
mixing duct 154 proximate the second wall 128 can be a diffuser 156
that redirects the exhaust gas/reductant agent mixture toward the
third and fourth sidewalls 130, 132 of the after-treatment module
120. The third and fourth sidewalls 130, 132 can redirect the
exhaust gas/reductant agent mixture generally back towards the
front first wall 126.
[0025] To perform the SCR reaction process, the after-treatment
module 120 can include a first SCR module 160 disposed proximate
the third sidewall 130 and a second SCR module 162 disposed toward
the fourth sidewall 132. The first and second SCR modules 160, 162
are oriented to receive the redirected exhaust gas/reductant agent
mixture. Referring to FIGS. 2 and 3, the first and second SCR
modules 160, 162 can accommodate a plurality of SCR catalysts 164,
sometimes referred to as aftertreatment bricks, in one or more
sleeves 166. The term aftertreatment brick, however, may refer to a
variety of exhaust aftertreatment devices which SCR catalysts are a
subset of. The sleeves 166 can be generally elongated, tubular
structures having an upstream end 168 and an opposing downstream
end 170 aligned along a longitudinal axis 172. In those embodiments
that include more than one sleeve in the first and second SCR
modules 160, 162, the sleeves can be supported in a truss or frame
174. The frame 174 can be oriented so that the upstream ends 168
are directed toward the respective third and forth sidewalls 130,
132 and the downstream ends 170 communicate with a central region
175 of the after-treatment module 120 generally surrounding but
fluidly separated from the mixing duct 154. The central region 175
can direct the treated exhaust gasses forward to the outlets 142
disposed through the front first wall 126. In various embodiments,
one or more additional exhaust treatment devices can be disposed in
the after-treatment module 120 such as diesel particulate filters
178 for removing soot.
[0026] Referring to FIG. 3, to receive the SCR catalysts 164 in the
sleeves 166, the upstream end 168 of each sleeve can remain open
and unobstructed. As shown in the illustrated embodiment, the
catalysts 164 and the sleeves 166 can have complementary
cylindrical shapes, although in other embodiments it will be
appreciated that the sleeves and catalysts can have other suitable
complementary shapes. The catalysts 164 can be aligned along the
longitudinal axis 172 and slidably inserted into the sleeves 166.
The catalysts 164 can be flow-through devices so that the exhaust
gas/reductant agent mixture can pass through them. In those
embodiments in which a plurality of catalysts 164 are accommodated
per each sleeve 166, the insertion process can involve a first
catalyst 180 and a second catalyst 182 that are inserted in such an
order that the first catalyst is oriented toward the upstream end
168 and the second catalyst is oriented toward the downstream end
170. In the illustrated embodiment, a third catalyst 184 can be
inserted between the upstream first catalyst 180 and the downstream
second catalyst 182. The catalysts may have the same or different
axial lengths.
[0027] To facilitate insertion and removal of the catalysts a 2-3
millimeter gap may exist between portions of the catalysts 164 and
the sleeve. Further, to prevent leakage of the exhaust
gas/reductant agent mixture through the SCR module, the catalysts
164 and sleeves 166 can be adapted to form a sealing engagement
with each other along at least a portion of their engaging
peripheries. For example, one or more circular protruding ribs 188
can protrude radially about the circumference of the catalysts 164
that can form a seal with the inner surface of the sleeves 166. To
access the SCR modules 160, 162 for insertion or removal of the
catalysts 164, a removable access panel 176 can be disposed in the
respective third and fourth sidewalls 130, 132 of the housing
122.
[0028] As mentioned above, over time the SCR catalysts may become
less effective due to deposits of phosphor, sulfur, and other
materials from the exhaust gasses building up on the active sites
of the catalysts. Additionally, the internal structure of the
catalyst might become damaged, preventing flow through it or the
seal between the catalyst and the sleeve might fail allowing
exhaust gasses to leak through the SCR module untreated. It may
therefore become necessary to remove and replace the SCR catalysts
from the SCR module. As can be appreciated from FIG. 3, though, the
orientation and order of insertion of the catalysts 164 may make
retrieval of the catalysts from the sleeves difficult. For example,
the second catalyst 182 may be inserted deep into the sleeve 166
from the opened upstream end 168 complicating its retrieval.
Likewise, the complementary size and shape and the sealing
engagement between the first catalyst 180 and the sleeve 166 may
make it difficult to grip or secure the first catalyst. In some
embodiments, the catalysts may be relatively heavy, for example,
between 13 and 17 kilograms each, thereby further complicating
their retrieval. Accordingly, the catalysts 164 can be provided
with a retrieval feature that assists in their retrieval and
removal from the sleeves 166.
[0029] Referring to FIG. 4, there is illustrated an embodiment of
an SCR catalyst 200 of the type for use with the described SCR
module that incorporates a retrieval feature to assist in removing
the catalyst from the sleeve 166. To support the catalytic
material, the catalyst 200 can include an internal substrate matrix
210 made of a triangular lattice, honeycomb lattice, metal mesh
substrate, or similar thin-walled support structure 212 onto which
the catalytic material or catalytic coating 214 can be disposed.
Such designs for the support structures enable the exhaust
gas/reductant agent mixture to pass into and through the catalyst.
Any suitable material can be used for the support structure 212
including, for example, ceramics, titanium oxide, or copper
zeolite. Catalytic coatings 214 that initiate the SCR reaction can
include various types of metals such as vanadium, molybdenum and
tungsten. The catalytic coating 214 can be deposited on the support
structure 212 by any suitable method including, for example,
chemical vapor deposition, adsorption, powder coating, spraying,
etc. In other embodiments, instead of having separate support
structures and catalytic coatings that are often employed together
to reduce material costs, the substrate matrix can be made entirely
from a catalytic material. In the illustrated embodiment, the
substrate matrix 210 has a generally cylindrical shape and extends
between a first circular face 220 and a second circular face 222 to
delineate a first length 224, however, in other embodiments,
different shapes can be applied to the substrate matrix, e.g.,
square, rectangular, etc. By way of example only, the first length
may be about 7 inches long.
[0030] To protect the support structure 212, a tubular mantle 230
can be generally disposed around the substrate matrix 210. The
tubular mantle 230 can be made of a thicker or more rigid material
than the thin-walled support structure 212, such as aluminum or
steel. For example, the mantle may be about 1.2 millimeters thick
to provide sufficient structural rigidity to the catalyst. The
tubular mantle 230 can have a shape complementary to that of the
substrate matrix 210 which, in the illustrated embodiment, is
generally cylindrical. The cylindrical mantle 230 can therefore
extend between a first circular rim 232 and a second circular rim
234. However, in other embodiments the mantle and its first and
second rims can have other shapes. The mantle can have a second
length 236 delineated between the first rim 232 and a second rim
234 that is slightly larger than the first length 224 of the
substrate matrix 210. By way of example only, the second length 236
may be approximately 8 inches. Accordingly, when disposed around
the shorter substrate matrix 210, the mantle 230 can have an
overhang extension 240 extending beyond at least the first face 220
of the substrate matrix such that the overhang extension displaces
the first rim 232 a distance beyond the first face. For the
examples given above, the overhang extension 240 may be on the
order of one inch, although the disclosure is not limited thereto.
In the illustrated embodiment, the overhang extension 240 curves
with the circular first rim 232 and includes a cylindrical inner
surface 242 extending between the first rim and the first face 220
of the substrate matrix 210.
[0031] To facilitate retrieval of the illustrated embodiment of the
catalyst 200 from the sleeves of the SCR module, the retrieval
feature 250 can be located on the inner surface 242 of the overhang
extension 240, a location that is the generally accessible from
outside of the first rim 232. In the illustrated embodiment, the
retrieval feature 250 can be an elongated, relatively narrow slot
252 disposed along the overhang extension 240 and that can be
generally located mid-way between the first rim 232 and the first
face 220 of the substrate matrix 210. The slot 252 can have any
suitable dimensions relative to the catalyst 200. For example, if
the overhang extension 240 is approximately 1 inch in length, the
slot 252 can have a width of about 0.125 inches. The slot 252 can
extend in a radial direction about part of the circumference of the
circular inner surface 242 and the arc length 256 of the slot 252
can be about 5% to 10% of the circumferential dimension of the
catalyst 200. For example, if the catalyst 200 has a diameter
indicated by arrow 254 of about 14 inches, the circumferential
length will be approximately 44 inches and the arc length 256 of
the slot can be approximately 2.2 to 4.4 inches. Moreover, although
the embodiment illustrate in FIG. 4 depicts two, diametrically
opposed slots 252 disposed in the overhang extension 240, in other
embodiments, any suitable number of slots can be included. The
slots can extend completely through the overhang extension or can
be partially recessed into the extension. To form the slot 252, in
various embodiments, the slot can be stamped or laser-cut into the
mantle 230 either before or after the mantle is disposed about the
substrate matrix 210. Possible advantages of laser cutting include
a cleaner edge, and that laser cutting is less likely to damage or
deform the overhang extension, especially if the slot-forming
operation is performed after the mantle has already been disposed
around the substrate matrix.
[0032] Referring to FIG. 5, the SCR catalyst 200 can be
accommodated in a sleeve 166 of the first SCR module 160 such that
the overhang extension 240 is oriented toward the opened upstream
end 168 of the sleeve. To retrieve the SCR catalyst 200 from within
the sleeve 166, the slot 252 can engage with an appropriate
retrieval tool 260 that may be inserted through the opened upstream
end 168. To engage the slot 252, the retrieval tool 260 can be a
generally L-shaped bracket with a distal hook 262 protruding at a
right angle from the end of an elongated arm 264 such that the hook
can be inserted or received into the slot. The L-shaped retrieval
tool can be made from a pressed, elongated blank of sheet or plate
metal. Once the retrieval tool engages the slot 252, the catalyst
200 can be pulled from the sleeve 166 through the opened upstream
end 168.
[0033] Referring to FIG. 6, there is illustrated another embodiment
of a retrieval tool 270 that can engage with diametrically opposed
slots 252 disposed on the SCR catalyst 200. In this embodiment, the
retrieval tool 270 can resemble a pair of inverted forceps or tongs
having first and second articulating legs 272, 274 pivotally joined
at a pivot point 276. Formed at the opposing first and second
distal ends 278, 280 of the respective first and second legs 272,
274 can be a ridge-like rib 282. Handles can be formed in the
opposite, proximal ends of the first and second legs 272, 272.
Moving the handles of the first and second legs 272, 274 together
will cause the first and second distal ends 278, 280 to move apart.
Accordingly, when the first and second distal ends 278, 280 are
placed within the circumference delineated by the overhang
extension 240, the first and second distal ends can be moved apart
so that the ribs 282 formed thereon can be received in and engage
the diametrically opposed slots 252.
[0034] Referring to FIG. 7, there is illustrated another embodiment
of an SCR catalyst 300 having a retrieval feature 350 in the form
of a handle 352. The illustrated SCR catalyst 300 can have the same
general structure as described above including a substrate matrix
310 with a protective tubular mantle 330 disposed around the
substrate matrix that extends between a first rim 332 and a second
rim 334. The substrate matrix and mantle can have any suitable
shape including cylindrical as illustrated. The tubular mantle 330
can include an overhang extension 340 that offsets the first rim
332 of the mantle from the forward first face 320 of the substrate
matrix 310. The overhang extension 340 thereby defines an
accessible circumferential inner surface 342. To attach the handle
352 to the catalyst, a first bracket 360 and a second bracket 362
can be disposed on the inner surface 342 of the overhang extension
340. Referring to the detailed view, the first and second brackets
360, 362 can be formed from stamped metal with an offset surface
364 supported between two depending bracket legs 366 and a circular
hole 368 disposed through the offset surface. When attached to the
inner surface 342 of the overhang extension 340, the first and
second brackets 360, 362 can be arranged generally diametrically
opposed to each other. The first and second brackets 360, 362 can
be attached to the mantle 330 by any suitable method such as
welding, riveting or with fasteners.
[0035] To form the handle 352, an elongated rod can be bent or
formed into an arch-like or curved shape including a first leg 370
and a second leg 372 with the handle therebetween at an apex 374.
In the illustrated embodiment, the apex 374 may be formed as a
straight grip. To mount the handle 352 to the catalyst 300
utilizing the first and second brackets 360, 362, there can be
formed or disposed at the opposing distal ends of first and second
legs 370, 372 a respective first and second doweled end 376, 378.
The handle 352 is thereby supported across the diameter of the
circular first rim 332. The first and second doweled ends 376, 378
can have a size and shape complementary to the circular holes 368
disposed in the first and second brackets 360, 362 so that they can
be insertably received into the holes.
[0036] In an embodiment, to pivot or articulate the handle 352 with
respect to the catalyst 300, the first and second doweled ends 376,
378 can form journals with the holes 368. As illustrated in FIG. 7,
the handle 352 can be articulated so that it stands perpendicular
to the SCR catalyst 300 to pull the catalyst from the sleeves.
Further, the curved shape of the handle 352 can be sized so that it
can be set or accommodated within the circumference of the overhang
extension 340 when pivoted adjacent to the first face 320 of the
substrate matrix 310. Accordingly, multiple catalysts can be
aligned and stacked adjacent to each other in the sleeves without
the handles interfering. In another embodiment, to obtain the same
benefit, the handle 352 can be removed from the catalyst 300 by
moving or pressing the first and second legs 370, 372 toward each
other so that the first and second doweled ends 376, 378 are
removed and released from the respective holes 368 in the first and
second brackets 360, 362. The handle can be selectively reattached
when necessary to remove the catalyst.
[0037] Referring to FIG. 8, there is illustrated another embodiment
of the SCR catalyst 400 equipped with a variation of the retrieval
feature 450 for retrieving the catalyst from the sleeve of an SCR
module. The catalyst 400 can include a substrate matrix 410 having
opposing first and second faces 420, 422 that is surrounded by a
tubular mantle 430 extending between a first rim 432 and a second
rim 434. The mantle 430 can form an overhang extension 440
extending rearward from the first rim 432 to the first face 420 of
the substrate matrix 410. The retrieval feature 450 can be in the
form of a pocket-like catch 452 disposed on the cylindrical inner
surface 442 of the overhang extension 440. In various embodiments,
a plurality of pocket-like catches 452 can be disposed about the
cylindrical inner surface 442. The catch 452 can protrude outward
from the inner surface 442 and can define an inner pocket that is
accessible via a lip 454 that is directed away from the first rim
432 and toward the first face 420 of the substrate matrix 410. To
engage the catch 452, a retrieval tool 460 can include a hook 462
disposed at the distal end of an elongated shaft or handle 464 that
can be hooked around the lip 454 and partially received in the
inner pocket. Pulling the retrieval tool in a particular direction
will accordingly pull the SCR catalyst in that direction.
INDUSTRIAL APPLICABILITY
[0038] The present disclosure is applicable to retrieval of
aftertreatment bricks or units accommodated in a large-scale
after-treatment module in the event the aftertreatment bricks
require servicing. Although the disclosure describes SCR catalysts
in particular, the disclosure can relate to other suitable
aftertreatment devices such as diesel oxidation catalysts (DOCs)
and/or diesel particulate filters (DPFs) also sometimes referred to
as bricks. Referring back to FIGS. 2 and 3, to access the
catalysts, an operator can remove the access panel 176 that may be
proximately facing the respective first or second SCR module
160/162 inside the after-treatment system 120. Using an elongated
tool, the operator can reach through the access panel and insert
the tool into the opened upstream end 168 of the elongated sleeves
166 that may be bundled together in the SCR module 160/162. The
retrieval tool can engage a retrieval feature disposed on the
catalyst in any of the foregoing manners. For example, in the
embodiment where the retrieval feature is a slot 252, the retrieval
tool can engage the slot and can be retracted to pull the catalyst
from the sleeve 166. In those embodiments in which the retrieval
feature is a handle, the retrieval tool can be a hook that is
inserted into the opened upstream end of the sleeves 166 to hook
around the handle. Alternatively, the operator may insert his arm
into the sleeves to grasp the handle with his hand.
[0039] The disclosure is particularly suited to the retrieval of a
plurality of catalysts 164 that may be accommodate in an axially
aligned fashion within the same elongated sleeve 166 of the SCR
module 160/162. Referring to FIG. 3, it will be appreciated that
the second catalyst 182 located deep within the sleeve 166 toward
the downstream end 170 can be satisfactorily reached with the
elongated retrieval tool. Accordingly, the disclosure enables the
ordered insertion and/or extraction of a plurality of SCR catalysts
164 that may be accommodated at different distances from the opened
upstream end 168 of the sleeve 166. Moreover, referring to FIG. 4
for example, because the retrieval feature 250 is disposed on the
inner surface 242 of the overhang extension 240, it will generally
not interfere with adjacent catalysts that may be axially inserted
in an abutting relation in the same sleeve, even in those
embodiments where the retrieval feature is a pivoting handle.
Additionally, the location of the retrieval feature inside the
overhang extension helps ensure that it will not interfere with the
sleeve surrounding the catalyst. In certain embodiments, the
retrieval tool can also assist in inserting new SCR catalysts into
the sleeves for replacement purposes after the expended SCR
catalysts have been removed.
[0040] It will be appreciated that the foregoing description
provides examples of the disclosed system and technique. However,
it is contemplated that other implementations of the disclosure may
differ in detail from the foregoing examples. All references to the
disclosure or examples thereof are intended to reference the
particular example being discussed at that point and are not
intended to imply any limitation as to the scope of the disclosure
more generally. All language of distinction and disparagement with
respect to certain features is intended to indicate a lack of
preference for those features, but not to exclude such from the
scope of the disclosure entirely unless otherwise indicated.
[0041] Recitation of ranges of values herein are merely intended to
serve as a shorthand method of referring individually to each
separate value falling within the range, unless otherwise indicated
herein, and each separate value is incorporated into the
specification as if it were individually recited herein. All
methods described herein can be performed in any suitable order
unless otherwise indicated herein or otherwise clearly contradicted
by context.
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