U.S. patent application number 10/733556 was filed with the patent office on 2005-06-16 for detonative cleaning apparatus.
Invention is credited to Aarnio, Michael J., Berg, Gerald R., Flatness, Scott A., Hochstein, James R. JR..
Application Number | 20050130084 10/733556 |
Document ID | / |
Family ID | 34653117 |
Filed Date | 2005-06-16 |
United States Patent
Application |
20050130084 |
Kind Code |
A1 |
Aarnio, Michael J. ; et
al. |
June 16, 2005 |
Detonative cleaning apparatus
Abstract
An apparatus for cleaning a surface within a vessel is supported
at least partially above a support surface. The apparatus had an
elongate combustion conduit extending from an upstream end to a
downstream end The downstream end is associated with an aperture in
a wall of the vessel and positioned to direct a shock wave toward
the surface. A guide member is on the support surface. A number of
support assemblies support the combustion conduit at a number of
locations along a length of the combustion conduit and engage the
at least one guide member.
Inventors: |
Aarnio, Michael J.;
(Kirkland, WA) ; Hochstein, James R. JR.;
(Seattle, WA) ; Flatness, Scott A.; (Seattle,
WA) ; Berg, Gerald R.; (Renton, WA) |
Correspondence
Address: |
BACHMAN & LAPOINTE, P.C.
900 CHAPEL STREET
SUITE 1201
NEW HAVEN
CT
06510
US
|
Family ID: |
34653117 |
Appl. No.: |
10/733556 |
Filed: |
December 11, 2003 |
Current U.S.
Class: |
431/1 |
Current CPC
Class: |
F28G 7/005 20130101;
B08B 7/0007 20130101; F28G 7/00 20130101; B08B 9/08 20130101; F28G
15/02 20130101 |
Class at
Publication: |
431/001 |
International
Class: |
F23C 011/04 |
Claims
What is claimed is:
1. An apparatus for cleaning a surface within a vessel, the
apparatus supported at least partially above a support surface and
comprising: an elongate combustion conduit extending from an
upstream end to a downstream end associated with an aperture in a
wall of the vessel and positioned to direct a shock wave toward
said surface; a guide member on the support surface; and a
plurality of support assemblies supporting the combustion conduit
at a plurality of locations along a length of the combustion
conduit and engaging the at least one guide member
2. The apparatus of claim 1 wherein: the at least one guide member
comprises at least one track; and each support has at least one
wheel engaging the at least one track.
3. The apparatus of claim 2 wherein: the at least one track
comprises first and second spaced-apart rails; and each support
assembly comprises at least one pair of said at least one wheel
being first and second spaced-apart wheels.
4. The apparatus of claim 3 wherein: each support assembly
comprises a trolley having first and second of the at least one
pair of said at least one wheel.
5. The apparatus of claim 4 wherein: the combustion conduit
comprises a plurality of separable segments; and each of the
segments is supported atop a single associated one of the plurality
of trolleys.
6. The apparatus of claim 1 further comprising: a fuel and oxidizer
source coupled to the combustion conduit to deliver a charge to the
conduit; and an ignitor positioned to ignite the charge to cause a
deflagration-to-detonation transition for generating the shock
wave.
7. The apparatus of claim 1 further comprising: a resilient member
coupling the combustion conduit to the wall.
8. A plurality of apparatus of claim 1 positioned at a given level
of the vessel.
9. The plurality of claim 8 wherein: the combustion conduits are
oriented parallel to each other.
Description
BACKGROUND OF THE INVENTION
[0001] (1) Field of the Invention
[0002] The invention relates to industrial equipment. More
particularly, the invention relates to the detonative cleaning of
industrial equipment.
[0003] (2) Description of the Related Art
[0004] Surface fouling is a major problem in industrial equipment.
Such equipment includes furnaces (coal, oil, waste, etc.), boilers,
gasifiers, reactors, heat exchangers, and the like. Typically the
equipment involves a vessel containing internal heat transfer
surfaces that are subjected to fouling by accumulating particulate
such as soot, ash, minerals and other products and byproducts of
combustion, more integrated buildup such as slag and/or fouling,
and the like. Such particulate build-up may progressively interfere
with plant operation, reducing efficiency and throughput and
potentially causing damage. Cleaning of the equipment is therefore
highly desirable and is attended by a number of relevant
considerations. Often direct access to the fouled surfaces is
difficult. Additionally, to maintain revenue it is desirable to
minimize industrial equipment downtime and related costs associated
with cleaning. A variety of technologies have been proposed. By way
of example, various technologies have been proposed in U.S. Pat.
Nos. 5,494,004 and 6,438,191 and U.S. patent application
publication 2002/0112638. Additional technology is disclosed in
Huque, Z. Experimental Investigation of Slag Removal Using Pulse
Detonation Wave Technique, DOE/HBCU/OMI Annual Symposium, Miami,
Fla., Mar. 16-18, 1999. Particular blast wave techniques are
described by Hanjali and Smajevi in their publications: Hanjali, K.
and Smajevi, I., Further Experience Using Detonation Waves for
Cleaning Boiler Heating Surfaces, International Journal of Energy
Research Vol. 17, 583-595 (1993) and Hanjali, K. and Smajevi, I.,
Detonation-Wave Technique for On-load Deposit Removal from Surfaces
Exposed to Fouling: Parts I and II, Journal of Engineering for Gas
Turbines and Power, Transactions of the ASME, Vol. 1, 116 223-236,
January 1994. Such systems are also discussed in Yugoslav patent
publications P 1756/88 and P 1728/88. Such systems are often
identified as "soot blowers" after an exemplary application for the
technology.
[0005] Nevertheless, there remain opportunities for further
improvement in the field.
SUMMARY OF THE INVENTION
[0006] One aspect of the invention involves an apparatus for
cleaning a surface within a vessel. The apparatus is supported at
least partially above a support surface. The apparatus had an
elongate combustion conduit extending from an upstream end to a
downstream end The downstream end is associated with an aperture in
a wall of the vessel and positioned to direct a shock wave toward
the surface. A guide member is on the support surface. A number of
support assemblies support the combustion conduit at a number of
locations along a length of the combustion conduit and engage the
at least one guide member.
[0007] In various implementations, the at least one guide member
may comprise at least one track. Each support may have at least one
wheel engaging the at least one track. The at least one track may
comprise first and second spaced apart rails. Each support assembly
may comprise at least one pair of the at least one wheel being
first and second spaced apart wheels. Each support assembly may
comprise a trolley having first and second of the at least one pair
of the at least one wheel. The combustion conduit may comprise a
number of separable segments. Each of the segments may be supported
atop a single associated one of the number of trolleys. A fuel and
oxidizer source may be coupled to the combustion conduit to deliver
a charge to the conduit. An ignitor may be positioned to ignite the
charge to cause a deflagration to detonation transition for
generating the shock wave. A resilient member may couple the
combustion conduit to the wall. A number of such apparatus may be
positioned at a given level of the vessel. The combustion conduits
may be oriented parallel to each other.
[0008] The details of one or more embodiments of the invention are
set forth in the accompanying drawings and the description below.
Other features, objects, and advantages of the invention will be
apparent from the description and drawings, and from the
claims.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] FIG. 1 is a view of an industrial furnace associated with
several soot blowers positioned to clean a level of the
furnace.
[0010] FIG. 2 is a side view of one of the blowers of FIG. 1.
[0011] FIG. 3 is a partially cut-away side view of an upstream end
of the blower of FIG. 2.
[0012] FIG. 4 is a longitudinal sectional view of a main combustor
segment of the soot blower of FIG. 2.
[0013] FIG. 5 is an end view of the segment of FIG. 4.
[0014] FIG. 6 is a view of a conduit segment support trolley of the
system of FIG. 1.
[0015] FIG. 7 is a side view of an alternate combustion
conduit.
[0016] Like reference numbers and designations in the various
drawings indicate like elements.
DETAILED DESCRIPTION
[0017] FIG. 1 shows a furnace 20 having an exemplary three
associated soot blowers 22. In the illustrated embodiment, the
furnace vessel is formed as a right parallelepiped and the soot
blowers are all associated with a single common wall 24 of the
vessel and are positioned at like height along the wall. Other
configurations are possible (e.g., a single soot blower, one or
more soot blowers on each of multiple levels, and the like).
[0018] Each soot blower 22 includes an elongate combustion conduit
26 extending from an upstream distal end 28 away from the furnace
wall 24 to a downstream proximal end 30 closely associated with the
wall 24. Optionally, however, the end 30 may be well within the
furnace. In operation of each soot blower, combustion of a
fuel/oxidizer mixture within the conduit 26 is initiated proximate
the upstream end (e.g., within an upstream most 10% of a conduit
length) to produce a detonation wave which is expelled from the
downstream end as a shock wave along with associated combustion
gases for cleaning surfaces within the interior volume of the
furnace. Each soot blower may be associated with a fuel/oxidizer
source 32. Such source or one or more components thereof may be
shared amongst the various soot blowers. An exemplary source
includes a liquified or compressed gaseous fuel cylinder 34 and an
oxygen cylinder 36 in respective containment structures 38 and 40.
In the exemplary embodiment, the oxidizer is a first oxidizer such
as essentially pure oxygen. A second oxidizer may be in the form of
shop air delivered from a central air source 42. In the exemplary
embodiment, air is stored in an air accumulator 44. Fuel, expanded
from that in the cylinder 34 is generally stored in a fuel
accumulator 46. Each exemplary source 32 is coupled to the
associated conduit 26 by appropriate plumbing below. Similarly,
each soot blower includes a spark box 50 for initiating combustion
of the fuel oxidizer mixture and which, along with the source 32,
is controlled by a control and monitoring system (not shown). FIG.
1 further shows the wall 24 as including a number of ports for
inspection and/or measurement. Exemplary ports include an optical
monitoring port 54 and a temperature monitoring port 56 associated
with each soot blower 22 for respectively receiving an infrared
and/or visible light video camera and thermocouple probe for
viewing the surfaces to be cleaned and monitoring internal
temperatures. Other probes/monitoring/sampling may be utilized,
including pressure monitoring, composition sampling, and the
like.
[0019] FIG. 2 shows further details of an exemplary soot blower 22.
The exemplary detonation conduit 26 is formed with a main body
portion formed by a series of doubly flanged conduit sections or
segments 60 arrayed from upstream to downstream and a downstream
nozzle conduit section or segment 62 having a downstream portion 64
extending through an aperture 66 in the wall and ending in the
downstream end or outlet 30 exposed to the furnace interior 68. The
term nozzle is used broadly and does not require the presence of
any aerodynamic contraction, expansion, or combination thereof.
Exemplary conduit segment material is metallic (e.g., stainless
steel). The outlet 30 may be located further within the furnace if
appropriate support and cooling are provided. FIG. 2 further shows
furnace interior tube bundles 70, the exterior surfaces of which
are subject to fouling. In the exemplary embodiment, each of the
conduit segments 60 is supported on an associated trolley 72, the
wheels of which engage a track system 74 along the facility floor
76. The exemplary track system includes a pair of parallel rails
engaging concave peripheral surfaces of the trolley wheels. The
exemplary segments 60 are of similar length L.sub.1 and are bolted
end-to-end by associated arrays of bolts in the bolt holes of their
respective flanges. Similarly, the downstream flange of the
downstream most of the segments 60 is bolted to the upstream flange
of the nozzle 62. In the exemplary embodiment, a reaction strap 80
(e.g., cotton or thermally/structurally robust synthetic) in series
with one or more metal coil reaction springs 82 is coupled to this
last mated flange pair and connects the combustion conduit to an
environmental structure such as the furnace wall for resiliently
absorbing reaction forces associated with discharging of the soot
blower and ensuring correct placement of the combustion conduit for
subsequent firings. Optionally, additional damping (not shown) may
be provided. The reaction strap/spring combination may be formed as
a single length or a loop. In the exemplary embodiment, this
combined downstream section has an overall length L.sub.2.
Alternative resilient recoil absorbing means may include non-metal
or non-coil springs or rubber or other elastomeric elements
advantageously at least partially elastically deformed in tension,
compression, and/or shear, pneumatic recoil absorbers, and the
like.
[0020] Extending downstream from the upstream end 28 is a
predetonator conduit section/segment 84 which also may be doubly
flanged and has a length L.sub.3. The predetonator conduit segment
84 has a characteristic internal cross-sectional area (transverse
to an axis/centerline 500 of the conduit) which is smaller than a
characteristic internal cross-sectional area (e.g., mean, median,
mode, or the like) of the downstream portion (60, 62) of the
combustion conduit. In an exemplary embodiment involving circular
sectioned conduit segments, the predetonator cross-sectional area
is a characterized by a diameter of between 8 cm and 12 cm whereas
the downstream portion is characterized by a diameter of between 20
cm and 40 cm. Accordingly, exemplary cross-sectional area ratios of
the downstream portion to the predetonator segment are between 1:1
and 10:1, more narrowly, 2:1 and 10:1. An overall length L between
ends 28 and 30 may be 1-15 m, more narrowly, 5-15 m. In the
exemplary embodiment, a transition conduit segment 86 extends
between the predetonator segment 84 and the upstream most segment
60. The segment 86 has upstream and downstream flanges sized to
mate with the respective flanges of the segments 84 and 60 has an
interior surface which provides a smooth transition between the
internal cross-sections thereof. The exemplary segment 86 has a
length L.sub.4. An exemplary half angle of divergence of the
interior surface of segment 86 is .ltoreq.12.degree., more narrowly
5-10.degree..
[0021] A fuel/oxidizer charge may be introduced to the detonation
conduit interior in a variety of ways. There may be one or more
distinct fuel/oxidizer mixtures. Such mixture(s) may be premixed
external to the detonation conduit, or may be mixed at or
subsequent to introduction to the conduit. FIG. 3 shows the
segments 84 and 86 configured for distinct introduction of two
distinct fuel/oxidizer combinations: a predetonator combination;
and a main combination. In the exemplary embodiment, in an upstream
portion of the segment 84, a pair of predetonator fuel injection
conduits 90 are coupled to ports 92 in the segment wall which
define fuel injection ports. Similarly, a pair of predetonator
oxidizer conduits 94 are coupled to oxidizer inlet ports 96. In the
exemplary embodiment, these ports are in the upstream half of the
length of the segment 84. In the exemplary embodiment, each of the
fuel injection ports 92 is paired with an associated one of the
oxidizer ports 96 at even axial position and at an angle (exemplary
90.degree. shown, although other angles including 180.degree. are
possible) to provide opposed jet mixing of fuel and oxidizer.
Discussed further below, a purge gas conduit 98 is similarly
connected to a purge gas port 100 yet further upstream. An end
plate 102 bolted to the upstream flange of the segment 84 seals the
upstream end of the combustion conduit and passes through an
igniter/initiator 106 (e.g., a spark plug) having an operative end
108 in the interior of the segment 84.
[0022] In the exemplary embodiment, the main fuel and oxidizer are
introduced to the segment 86. In the illustrated embodiment, main
fuel is carried by a number of main fuel conduits 112 and main
oxidizer is carried by a number of main oxidizer conduits 110, each
of which has terminal portions concentrically surrounding an
associated one of the fuel conduits 112 so as to mix the main fuel
and oxidizer at an associated inlet 114. In exemplary embodiments,
the fuels are hydrocarbons. In particular exemplary embodiments,
both fuels are the same, drawn from a single fuel source but mixed
with distinct oxidizers: essentially pure oxygen for the
predetonator mixture; and air for the main mixture. Exemplary fuels
useful in such a situation are propane, MAPP gas, or mixtures
thereof. Other fuels are possible, including ethylene and liquid
fuels (e.g., diesel, kerosene, and jet aviation fuels). The
oxidizers can include mixtures such as air/oxygen mixtures of
appropriate ratios to achieve desired main and/or predetonator
charge chemistries. Further, monopropellant fuels having
molecularly combined fuel and oxidizer components may be
options.
[0023] In operation, at the beginning of a use cycle, the
combustion conduit is initially empty except for the presence of
air (or other purge gas). The predetonator fuel and oxidizer are
then introduced through the associated ports filling the segment 84
and extending partially into the segment 86 (e.g., to near the
midpoint) and advantageously just beyond the main fuel/oxidizer
ports. The predetonator fuel and oxidizer flows are then shut off.
An exemplary volume filled the predetonator fuel and oxidizer is
1-40%, more narrowly 1-20%, of the combustion conduit volume. The
main fuel and oxidizer are then introduced, to substantially fill
some fraction (e.g., 20-100%) of the remaining volume of the
combustor conduit. The main fuel and oxidizer flows are then shut
off. The prior introduction of predetonator fuel and oxidizer past
the main fuel/oxidizer ports largely eliminates the risk of the
formation of an air or other non-combustible slug between the
predetonator and main charges. Such a slug could prevent migration
of the combustion front between the two charges.
[0024] With the charges introduced, the spark box is triggered to
provide a spark discharge of the initiator igniting the
predetonator charge. The predetonator charge being selected for
very fast combustion chemistry, the initial deflagration quickly
transitions to a detonation within the segment 84 and producing a
detonation wave. Once such a detonation wave occurs, it is
effective to pass through the main charge which might, otherwise,
have sufficiently slow chemistry to not detonate within the conduit
of its own accord. The wave passes longitudinally downstream and
emerges from the downstream end 30 as a shock wave within the
furnace interior, impinging upon the surfaces to be cleaned and
thermally and mechanically shocking to typically at least loosen
the contamination. The wave will be followed by the expulsion of
pressurized combustion products from the detonation conduit, the
expelled products emerging as a jet from the downstream end 30 and
further completing the cleaning process (e.g., removing the
loosened material). After or overlapping such venting of combustion
products, a purge gas (e.g., air from the same source providing the
main oxidizer and/or nitrogen) is introduced through the purge port
100 to drive the final combustion products out and leave the
detonation conduit filled with purge gas ready to repeat the cycle
(either immediately or at a subsequent regular interval or at a
subsequent irregular interval (which may be manually or
automatically determined by the control and monitoring system)).
Optionally, a baseline flow of the purge gas may be maintained
between charge/discharge cycles so as to prevent gas and
particulate from the furnace interior from infiltrating upstream
and to assist in cooling of the detonation conduit.
[0025] In various implementations, internal surface enhancements
may substantially increase internal surface area beyond that
provided by the nominally cylindrical and frustoconical segment
interior surfaces. The enhancement may be effective to assist in
the deflagration-to-detonation transition or in the maintenance of
the detonation wave. FIG. 4 shows internal surface enhancements
applied to the interior of one of the main segments 60. The
exemplary enhancement is nominally a Chin spiral, although other
enhancements such as Shchelkin spirals and Smirnov cavities may be
utilized. The spiral is formed by a helical member 120. The
exemplary member 120 is formed as a circular-sectioned metallic
element (e.g., stainless steel wire) of approximately 8-20 mm in
sectional diameter. Other sections may alternatively be used. The
exemplary member 120 is held spaced-apart from the segment interior
surface by a plurality of longitudinal elements 122. The exemplary
longitudinal elements are rods of similar section and material to
the member 120 and welded thereto and to the interior surface of
the associated segment 60. Such enhancements may also be utilized
to provide predetonation in lieu of or in addition to the foregoing
techniques involving different charges and different combustor
cross-sections.
[0026] The apparatus may be used in a wide variety of applications.
By way of example, just within a typical coal-fired furnace, the
apparatus may be applied to: the pendants or secondary
superheaters, the convective pass (primary superheaters and the
economizer bundles); air preheaters; selective catalyst removers
(SCR) scrubbers; the baghouse or electrostatic precipitator;
economizer hoppers; ash or other heat/accumulations whether on heat
transfer surfaces or elsewhere, and the like. Similar possibilities
exist within other applications including oil-fired furnaces, black
liquor recovery boilers, biomass boilers, waste reclamation burners
(trash burners), and the like.
[0027] FIG. 6 shows further details of the exemplary trolley 72 and
track system 74. The exemplary track system comprises a pair of
parallel vertex-up right angle channel elements 140 (e.g., of
steel) secured such as by welding to mounting plates 142. The
mounting plates are, in turn, secured to the floor 76 such as via
bolts (not shown) in bolt holes 144. The exemplary trolley includes
a structural frame 150 having a pair of left and right longitudinal
members 152 and fore and aft crossmembers 154. At the left and
right sides of each crossmember, a wheel 156 is mounted on a
depending bracket 158. The wheel periphery has a concavity (e.g., a
right-angle V-groove 160) receiving the vertex of the right angle
channel elements 140. The exemplary trolley has means for
supporting the associated conduit segment and means for securing
the segment in place. The exemplary support means include a pair of
fore and aft tube/pipe clamps 170 each positioned and supported by
nuts 172 on associated left and right threaded shafts 174 secured
at their lower ends to the frame. The clamps 170 have a concave
surface 176 complementary to the exterior body surface of the
associated conduit segment to support the segment from below. The
securing means comprises similar top brackets 180 also mounted to
the shafts 174 and held downward in place in compressive engagement
with the segment via nuts 182.
[0028] A number of options are available for using the trolleys.
The individual segments may be preassembled to their associated
trolleys and rolled into place along the track system, whereupon
the segments may be secured to each other via their end flanges.
Disassembly may be by a reverse of this process. The trolleys may
also allow the combustion conduit to be moved as a unit (e.g., if
it is desired that the downstream portion of the conduit not be
inserted into the furnace all the time). Additionally, as noted
above, the trolleys may accommodate movement as a unit associated
with longitudinal thermal expansion and/or with recoil during
discharge cycles while maintaining conduit segment alignment.
[0029] FIG. 7 shows an alternate system 200 wherein the combustion
conduit 202 is suspended from brackets 204 (e.g., as part of a
free-standing support structure or secured to a ceiling or roof 206
of the facility). Such a system may be particularly useful where
the conduit is positioned high above a facility floor. The
exemplary system 200 navigates the conduit 202 around environmental
obstacles external to the furnace. Exemplary obstacles include
upper and lower tube bundles 210 and 212 between which the conduit
passes. In the exemplary embodiment, the conduit is circuitous to
permit positioning of its outlet 214 in a position on the furnace
wall aligned with one of the two bundles. In such a situation, a
straight conduit would be interfered with by the bundles.
Accordingly, the conduit is provided with one or more curved
sections 216 to accommodate the bundles.
[0030] From upstream to downstream, the exemplary support system
includes an upstream and an intermediate spring hanger 220 and 222
coupled to associated conduit segments by turnbuckle systems 224
and 226. Exemplary spring hangers are available from LISEGA, Inc.,
Newport, Tenn. In the exemplary embodiment, the spring hanger 222
may have substantially higher capacity due to a higher static load
at that location. The particular combination of hanger sizings may
be influenced by the relative locations of the hangers along the
conduit in view of mass parameters of the conduit (e.g., center of
gravity, mass distribution, and the like), strength parameters of
the conduit (e.g., various modulus), and the location of any
additional support. The exemplary spring hangers serve as
essentially constant-load hangers, with supportive tensile force
essentially constant over an operating range. One function of the
vertical compliance afforded by the hangers is to accommodate
thermally-associated changes in the vertical position of the outlet
214 relative to the ceiling surface 206 or other combustion conduit
support structure. For example, thermal expansion of the furnace
wall may cause a change in outlet vertical position between hot and
cold (e.g., running and off) furnace conditions. In the embodiment
of FIG. 2, such expansion is addressed by non rigid vertical
coupling of the conduit and wall with sufficient vertical play for
the conduit within the oversized wall aperture. With rigid
mounting, however, if furnace heating raises the conduit outlet
height, in the absence of the constant force hangers, a greater
fraction of the conduit mass would be carried by the furnace wall
and a lesser fraction by the upstream supports. This would be
associated with shear/bending forces/moments and associated
deformations. The spring hangers, however, will tend to contract,
raising the segment(s) to which they are attached to so that the
mass supported by the furnace wall does not substantially increase
and thus to at least partially, and advantageously in major part,
relieve/prevent stresses that otherwise would be associated with
the outlet elevation increase the hangers may, therefore maintain
an essentially constant orientation of the conduit (e.g.,
maintaining its upstream major portion in an essentially horizontal
orientation).
[0031] In the exemplary embodiment, a support structure 240
external to the combustion conduit further reinforces the
associated assembled segments. Such reinforcement advantageously
handles structural stresses associated with shock reflections
occurring within the curved segments. In the illustrated
embodiment, the structure further rigidly ties downstream portions
of the conduit to the furnace wall. In the exemplary embodiment,
the turnbuckle 226 is connected via its lower threaded rod to a
fixture 242 secured to the upstream end of the support structure
and having snubbers 244 to accommodate and dampen side-to-side
motion of the conduit which may arise from the combustion process.
In the exemplary embodiment, the rigid connection of the support
structure to the furnace wall absorbs the recoil forces,
essentially preventing recoil. To the extent that longitudinal
thermal expansion of the conduit remains an issue, such expansion
may be taken up by allowing the hangers to pivot (e.g., relative to
connection locations 246 to the brackets 204 above and the
connection point 248 with the associated conduit engagement fixture
below. Alternative embodiments may remove the rigid coupling of the
conduit to the wall and permit a resilient or damped coupling.
[0032] One or more embodiments of the present invention have been
described. Nevertheless, it will be understood that various
modifications may be made without departing from the spirit and
scope of the invention. For example, the invention may be adapted
for use with a variety of industrial equipment and with variety of
soot blower technologies. Aspects of the existing equipment and
technologies may influence aspects of any particular
implementation. Accordingly, other embodiments are within the scope
of the following claims.
* * * * *