CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of the filing date of United States application
Serial No. 60/474,470, filed on May 31, 2003, now pending.
FIELD AND BACKGROUND OF THE INVENTION
[0002] The field of the invention relates generally to fuel injection nozzles, and more
particularly, to a counterflow fuel injection nozzle.
[0003] Burners are used in boilers, heaters, and other applications for the conversion of
fuel to heat. The heat is then transferred to make hot water, steam, and/or warm air,
or to create power, depending upon the application. In a burner-boiler system (e.g.,
firetube and commercial and industrial watertube boilers), fuel is typically injected
through nozzles to create a flame. The fuel is combined with air flowing around or
adjacent the nozzle. Ultimately, the fuel is ignited to create a flame, with a goal
being to maximize the conversion of the fuel that is burned during this combustion
process so as to achieve complete combustion. The manner in which the fuel is injected
(i.e., its direction, velocity, and interaction with other fluid streams) into the
air stream affects the flame profile or shape and thus greatly determines the completeness
of the combustion and heat release into the furnace. The injection method affects
the overall geometry and physical characteristics of the nozzle itself. For example,
the fuel is typically injected through passageway(s) formed in the nozzle, and more
particularly, the nozzle body. These physical characteristics include the width or
diameter, spacing, and angling or pitch of the particular passageway(s) or channel(s).
[0004] It is a continuing design goal to control mixing (e.g., quality, uniformity, rate,
etc.) of the fuel and air by the burner so that air and fuel are evenly mixed. Variations
in the width, spacing and pitch of the passageways of the nozzle used for distributing
fuel from the nozzle yield varied mixing results, flame profiles, flame locations
and overall combustion performance factors. It has been found that angled injection
passageways that inject the fuel in a counterflow fashion contribute positively to
the aforementioned factors. By "counterflow" it is meant that the fuel is injected
into a flow of air such that at least one vector component of the fuel flow opposes
at least one vector component of the air flow. Therefore, it would be desirable, in
a burner using a gaseous fuel (e.g, natural gas), to be able to improve control of
the mixing of the fuel with air by introducing the fuel into the air in counterflow
fashion.
BRIEF SUMMARY OF THE INVENTION
[0005] Disclosed herein is a counterflow fuel injection nozzle for injecting fuel, the nozzle
comprising: a nozzle wall having an interior surface that defines a nozzle interior.
The interior for receiving a fuel therein, the nozzle further having a fuel passageway
formed in the nozzle wall for distributing the fuel from the interior to a location
exterior of the nozzle, the fuel distributed to the exterior location in a fuel flow
injection direction. When an airstream is provided in a prevailing air flow direction
in the location exterior of the nozzle, at least one vector component of the fuel
flow injection direction opposes at least one vector component of the prevailing air
flow direction.
[0006] Other objects, aspects, and advantages of the invention will be apparent upon a thorough
reading of the detailed description below along with the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0007] Embodiments of the invention are disclosed with reference to the accompanying drawings
and are for illustrative purposes only. The invention is not limited in its application
to the details of construction or the arrangement of the components illustrated in
the drawings. The invention is capable of other embodiments or of being practiced
or carried out in other various ways. Like reference numerals are used to indicate
like components. In the drawings:
Fig. 1 is perspective partially cut-away view of a burner incorporating an embodiment
of a counterflow fuel injection nozzle of the present invention;
Fig. 1a is a front view of a burner incorporating an embodiment of the counterflow
fuel injection nozzle of the present invention;
Fig. 2a is a side sectional view taken along line 2a-2a of Fig. 1a;
Fig. 2b is a diagram schematically illustrating the concept of counterflow with respect
to a representation of the present inventive counterflow fuel injection nozzles;
Fig. 2c is a representation of various hole and distance parameters associated with
the counterflow fuel injection nozzle illustrating the parameters that affect the
interaction of fuel jets from adjacent nozzles;
Fig. 2d is a graphical representation of various penetration depths of the fuel and
overall fuel distribution patterns associated with the present invention;
Fig. 3 is an enlarged sectional view taken along line 3-3 of Fig.2a;
Fig. 4 is a perspective view of one embodiment of the counterflow fuel injection nozzle
according to one aspect of the present invention;
Fig. 5 is a bottom sectional view taken along line 5-5 of Fig. 3;
Fig. 6 is a perspective view of another embodiment of the counterflow fuel injection
nozzle according to one aspect of the present invention;
Fig. 7 is a side sectional view of the counterflow fuel injection nozzle of Fig. 6;
Fig. 8 is a bottom sectional view taken along line 8-8 of Fig. 7 and illustrating
exemplary counterflow injection angles;
Fig. 9 is a perspective view of another embodiment of the counterflow fuel injection
nozzle according to one aspect of the present invention;
Fig. 10 is a side sectional view of the counterflow fuel injection nozzle of Fig.
9;
Fig. 11 is a front sectional view taken along line 11-11 of Fig. 10 and illustrating
exemplary angular spacing of the fuel injection holes;
Fig. 12 is a perspective view of another embodiment of the counterflow fuel injection
nozzle according to one aspect of the present invention;
Fig. 13 is a side sectional view of the counterflow fuel injection nozzle of Fig.
12;
Fig. 14 is a partial side sectional view of another embodiment of the counterflow
fuel injection nozzle according to one aspect of the present invention; and
Fig. 15 is a perspective view of the counterflow fuel injection nozzle of Fig. 14.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0008] In the Figures, like numerals are employed to designate like parts through the drawings,
and various pieces of equipment, such as valves, fittings, pumps, and the like, are
omitted so as to simplify the description of the invention. However, those skilled
in the art will realize that such conventional equipment can be employed as desired.
In addition, although the invention is applicable to various fuel-burning equipment,
it will be discussed for purposes of illustration in connection with a steam or hot
water boiler.
[0009] Fig. 1 is perspective partially cut-away view of a burner 1 incorporating an embodiment
of a counterflow fuel injection nozzle 2 of the present invention. Burner 1 can receive
a gaseous fuel (e.g., propane, natural gas, etc.) from a fuel source (not shown) via
a fuel line or pipe (also not shown) and delivery within the burner via lance 14.
Total combustion air flow is indicated by arrow 3, with primary air 4, secondary air
5, and tertiary air 6 flowing through other paths (as directed at the burner entrance,
for example, around a diffuser 7 and between injection nozzles) to promote complete
combustion. The air flows may have, in addition to air, flue gas products (FGR). In
general, the O
2 levels are lower in flue gas products than in air. Therefore, more air may be necessary
in the primary, secondary or tertiary air flows to achieve the necessary oxygen levels
required for complete combustion. Oxygen levels can preferably be in the range of
11-21%, more preferably in the 15-21% range, and most preferably in the 16-19% range.
[0010] Fig. 1a is a front view of a burner incorporating an embodiment of the counterflow
fuel injection nozzle of the present invention and Fig. 2a is a side elevational view
taken along line 2a-2a of Fig.1a. Referring to Figs. 1a and 2a, fuel is introduced
into the burner 10 at a number of locations via manifold 11. More specifically, fuel
is introduced via a plurality of radially disposed fuel lines or lances 14. In addition,
central injection pipe 13 is used for distributing fuel via nozzles 15 to create a
flame in the center of the burner. Burner 10 further includes a diffuser (also called
a "swirler"), generally referred to by numeral 18, having blades 20. Tertiary air
is introduced into burner 10, also indicated by numeral 6, and diffuser 18 imparts
a rotating motion to the air so as to increase mixing of the air and the fuel. The
radially disposed lances 14 terminate with injection nozzles 16, also referred to
herein as simply "injectors" or "nozzles". The distance 19 between the head 17 of
nozzle 16 and the beginning of the diffuser plane area 21 is an important factor for
successful application of the nozzle 16 as it will affect mixing capabilities of the
fuel and air. The gap between nozzle 16 and outer ring 25, as indicated by arrow 27,
is also important for mixing capabilities.
[0011] Primary, secondary and tertiary air is introduced into the burner 10 as shown. In
the embodiment shown, the "prevailing air flow direction" corresponds to an air flow
direction in which the air travels from a location generally upstream of the fuel
injectors to a location generally downstream of the fuel injectors. The flow of air
can be influenced by structures or "bluff bodies" within the burner itself (e.g.,
the diffuser, manifolds, fuel lines, etc.). As will be described in greater detail
below, and as shown in Fig. 1, at least a portion of the air flow is directed or distributed
past the diffuser and generally along or past the nozzles 16.
[0012] Fig. 2b is a diagram schematically illustrating the concept of counterflow with respect
to a representation of the present inventive counterflow fuel injection nozzle. As
shown, fuel flows into the nozzle 510 in an initial fuel flow direction 518 and flows
into the interior 514 of the nozzle. Fuel is distributed from the nozzle interior
514 along a fuel flow injection direction 520 (F
fuel). The fuel is typically injected at a preferred pressure of up to 20 psig. "Fuel
flow injection angle" is that angle at which the fuel is injected out of the counterflow
fuel injection nozzle, and more specifically, the nozzle interior, via apertures,
holes, or openings 516a-b to a location exterior of the nozzle. Fuel flow injection
direction is determined by the fuel flow injection angle θ at which fuel is distributed
from the nozzle interior. The trajectory is determined by the angle, as well as the
fuel and the air velocity. As shown, the angle is measured from a plane that is normal
or perpendicular to the surface of the nozzle. Fuel flowing along fuel flow injection
direction 520 includes a perpendicular flow vector component 522 (
) and a counterflow vector component 524 (
). By "perpendicular" it is meant that the vector component is perpendicular to the
prevailing air flow direction, and by "counterflow" it is meant that the vector component
opposes the prevailing air flow direction.
[0013] To promote mixing of fuel and air, the fuel is injected along the fuel injection
direction 520 into air flowing in a prevailing air flow direction 526 (F
air). Mixing typically occurs at a location exterior of the nozzle. It is noted that
the fuel flow injection direction vector is shown in schematic fashion to illustrate
the fuel flow injection angle with greater clarity, but that the fuel flow trajectory
takes on a more complex path (i.e., it curves or swirls) due to the injection of the
fuel into the prevailing air flow and as the distance the fuel travels from the nozzle
increases. This more complex path is indicated by the arrow 525.
[0014] Fuel flows in the fuel flow injection direction such that is generally angled with
respect to the prevailing air flow direction resulting in a counterflow angle Δ, which
is measured with respect to the prevailing air flow direction. A "counterflow angle"
exists when at least one vector component (i.e., a counterflow fuel vector component)
of the fuel flow injection direction is opposite at least one vector component of
the prevailing air flow direction (i.e., a counterflow air vector component). As shown
schematically, counterflow fuel vector component 524 opposes or is opposite (and thus
flows counter to) at least one counterflow air vector component of the prevailing
air flow direction 526. A significant purpose for distributing fuel into an air flow
to create a counterflow angle is to achieve, or to substantially achieve, complete
mixing of the fuel in the air. Preferably, the spectrum of fuel flow injection angles
θ ranges from about 15 degrees to about 90 degrees (i.e., with 90 degrees meaning
complete counterflow). In one preferred embodiment, the counterflow angle is about
30 degrees.
[0015] Fig. 3 is an enlarged sectional view taken along line 3-3 of Fig.2a, in particular,
illustrating a sectional view of nozzle 16 according to one aspect of the present
invention in greater detail. Fig. 4 is a perspective view of one embodiment of the
counterflow fuel injection nozzle according to one aspect of the present invention.
Injection nozzle 16 includes a nozzle body 28. And Fig. 5 is a bottom sectional view
taken along line 5-5 of Fig. 3.
[0016] Referring to Figs. 3-5, the nozzle body 28 has a nozzle wall 30, and the nozzle wall
30 defines a nozzle interior 32. As shown, nozzle 16 is generally "T"-shaped. It is
nozzle interior 32 that receives the fuel to be distributed and ultimately injected
into to the airstream to produce a flame. Since nozzle interior 32 acts as a fuel
conduit, the hole shape, hole diameters, hole distribution and injection angles all
contribute to how the fuel is distributed throughout the nozzle interior 32. The embodiment
shown is representative only, and it is contemplated that other shapes, geometric
features and body outlines could be suitably employed. That is, the nozzle may have
other particularized curves, tapers, angles, and interior surface and interior geometries
and still accomplish the objectives of the injection nozzle 16. Also, any suitable
materials may be used in the construction of injection nozzle 16, although stainless
steel is one preferred material, among others. Interior surface 34 of nozzle wall
30 defines nozzle interior 32 into which fuel is received from fuel line 14. Various
means of connection between the fuel line 14 and the injection nozzle 16 are possible.
Nozzle body 28 further includes a series of fuel passageways 40 terminating in holes
or openings 42 formed in the nozzle wall for distributing the fuel from the interior.
[0017] Accordingly, fuel flows from the nozzle interior 32 through the passageways 40 and
out of the nozzle 16 via holes 42 into an air flow (see Figs. 1-2). It is contemplated
that the size, shape, and placement of the holes and passageways can be varied to
achieve the desired mixing effect (i.e., mixing between the air flow and the fuel
injected into the air). The size of the nozzle holes are critical, since, if the holes
are too small, "fouling" and other similar problems may occur. One factor in determining
the appropriate size, shape and placement of holes and passages is the position of
the nozzle relative the air flow. Another factor is the geometry of the nozzle itself.
Hole placement can be selected to promote mixing by distributing fuel into the prevailing
air flow. The result is that the air is entrained (carried in a current) within the
fuel to achieve better mixing. Ultimately, the goal is to achieve uniform mixing,
and it has been found that more uniform mixing results from a wide dispersal of fuel
into an air flow.
[0018] In the embodiment illustrated in Figs. 3-5, representative passageways and placement
of holes are shown in a representative nozzle. Fuel is injected along a fuel injection
direction 40. Representative fuel injection trajectories are illustrated by arrows
44. More specifically, in one embodiment, the passageways can be cylindrical and the
holes can be round. Although any hole size is contemplated, in one embodiment, the
holes can be sized to have a diameter in a range of from about 0.0625 inches to about
0.141 inches. In one embodiment, the holes can be spaced apart, as measured from their
respective centers, from about 0.325 to about .75 inches, with an exemplary hole distance
of 0.5 inches apart.
[0019] It is a design goal to select the size, shape and placement of the holes in the nozzle
to minimize, or substantially eliminate, interference between the holes (e.g., one
fuel injection direction crossing, in whole or in part, another fuel injection direction).
As shown in Fig. 2c, for a given nozzle N, the distance between the holes of an exemplary
nozzle is L and the diameter of the holes is D. The ratio L/D will define the interaction
between adjacent holes. The diameter of the holes will determine the penetration depth
of the fuel (gas) and overall fuel distribution patterns. L determines whether the
adjacent fuel jets result in mixing or combining of the fuel streams. As shown in
Fig. 2d, exemplary penetration depth of fuel and fuel distribution patterns x1 and
x2 are illustrated for 2 holes y and z of different hole diameters. It is contemplated
that the variations of size, shape and placement of the holes can be from nozzle to
nozzle (i.e., for a given nozzle the holes and spacings are identical), or the size,
shape and placement can vary from hole to hole. In a preferred embodiment, the ratio
of L to D is about 5. The interaction between adjacent nozzles (in addition to staggering
of holes) can be an effective means to effect fuel jet interaction.
[0020] In general, it can be said that the counterflow angle (i.e., the angle created by
the fuel flow injection direction with respect to the prevailing air flow direction)
effects mixing downstream of the holes. It has been found that ideal mixing conditions
occur when the counterflow angle is such that the fuel flow direction is not entirely
opposed to the prevailing air flow direction. The counterflow angle also effects the
air/fuel mixing location and permits control over whether mixing occurs more or less
downstream of the nozzles. This can be advantageous for a variety of reasons. For
example, by keeping the mixing of the air and fuel further downstream of the nozzles,
the flame can be created further downstream, and the nozzle can be protected from
exposure to high levels of heat. This can serve to prevent the nozzles from burning
out prematurely. Also, the size, number and placement of passages and holes in the
nozzle body permits flame sculpting (also called flame shaping, or flame forming)
to achieve optimum mixing in relation to the furnace geometry. In general, it has
been found that when the conditions approach "complete counterflow" (i.e., when the
fuel and air trajectories are completely opposed to each other), better mixing can
occur, although less control of the mixing will be achieved, since the paths of the
trajectories will be unpredictable. Also, counterflow angle selection is dependant
upon such conditions as the burner air flow distribution, direction and velocity.
[0021] Fig. 6 is a perspective view of another embodiment of a counterflow fuel injection
nozzle according to one aspect of the present invention. Fig. 7 is a side sectional
view of the counterflow fuel injection nozzle of Fig. 6 and Fig. 8 is a bottom sectional
view taken along line 8-8 of Fig. 7. Figs. 6-8 also illustrate exemplary counterflow
injection angles.
[0022] Referring to Figs. 6-8, the nozzle body 128 has a nozzle wall 130, and the nozzle
wall 130 defines a nozzle body interior 132. As shown, nozzle 116 is generally "Truncated
T-shaped" in that it is truncated when compared to the embodiment of Figs. 3-5. It
is nozzle body interior 132 that receives the fuel to be distributed and ultimately
injected in the airstream to produce a flame. Since nozzle body interior 132 acts
as a fuel conduit, the hole shapes, as with the other embodiments, the hole diameters,
hole distribution and injection angles all contribute to how the fuel is distributed
throughout the nozzle interior 132. The embodiment shown is representative only, and
it is contemplated that other shapes, geometric features and body outlines could be
suitably employed. Also, any suitable materials may be used in the construction of
injection nozzle 116, although stainless steel is one preferred material, among others.
Interior surface 134 of nozzle wall 130 defines nozzle interior 132 into which fuel
is received from fuel line 114. Fuel line 114 includes an optional threaded portion
136 for threaded insertion into a mating threaded portion 138 of interior surface
134 if a threaded connection is desired. Although a threaded engagement is shown and
preferred, it is contemplated that other means of connection between the fuel line
114 and the injection nozzle 116 are possible. Nozzle body 128 further includes a
series of fuel passageways 140 terminating in holes or openings 142 formed in the
nozzle wall for distributing the fuel from the interior.
[0023] Accordingly, fuel flows from the nozzle interior 132 through the passageways 140
and out of the nozzle 116 via holes 142 into an air flow (again, see Figs. 1-2). It
is contemplated that the size, shape, and placement of the holes and passageways can
be varied to achieve the desired mixing effect (i.e., mixing between the air and the
fuel injected into the air). Again, hole placement will be selected to promote mixing
by distributing fuel into the prevailing air flow.
[0024] In the embodiment illustrated in Figs. 6-8, representative passageways and placement
of holes are shown in a representative nozzle. Fuel is injected along representative
fuel injection directions 144.
[0025] The size and placement of the various passageways and holes are similar to those
described in detail above with respect to Figs. 3-5.
[0026] Fig. 9 is a perspective view of another embodiment of the counterflow fuel injection
nozzle according to one aspect of the present invention. One design parameter of the
embodiment of Fig. 9 is the limited footprint shown, such that the nozzle shown could
be incorporated into smaller burners, particularly where the insertion of a larger
area T or other shaped nozzle would not fit properly into the space provided. Fig.
10 is a side sectional view of the counterflow fuel injection nozzle of Fig. 9. Fig.
11 is a front sectional view taken along line 11-11 of Fig. 10. Figs. 9-11 illustrate
exemplary fuel flow injection angles and angular hole spacing.
[0027] Referring to Figs. 9-11, the nozzle body 228 has a nozzle wall 230, and the nozzle
wall 230 defines a nozzle body interior 232. As shown, nozzle 216 includes several
contours which define a primary centralized circumferentially disposed notch or groove
233 which defines a surface 235. The shape of the nozzle is generally termed herein
"mushroom-shaped". It is nozzle body interior 232 that receives the fuel to be distributed
and ultimately injected in the airstream to produce a flame. Since nozzle body interior
232 acts as a fuel conduit, the particularized curves, tapers, angles and surface
and interior geometry of the injection nozzle 216 will dictate how the fuel is distributed
throughout the nozzle body interior 232. The embodiment shown is representative only,
and it is contemplated that other shapes, geometric features and body outlines could
be suitably employed. Also, any suitable materials may be used in the construction
of injection nozzle 216, although steel is one preferred material, among others. Interior
surface 234 of nozzle wall 230 defines nozzle interior 232 into which fuel is received
from fuel line 214. Fuel line 214 includes threaded portion 236 for threaded insertion
into a mating threaded portion 238 of interior surface 234. Although a threaded engagement
is shown and preferred, it is contemplated that other means of connection between
the fuel line 214 and the injection nozzle 216 are possible. Nozzle body 228 further
includes a series of fuel passageways 240 terminating in holes or openings 242 formed
in the nozzle wall for distributing the fuel, and more particularly, the holes are
formed in the surface 235 of primary centralized circumferentially disposed notch
or groove 233.
[0028] Accordingly, fuel flows from the nozzle interior 232 through the passageways 240
and out of the nozzle 216 via holes 242 into an air flow (again, see Figs. 1-2). It
is contemplated that the size, shape, and placement of the holes and passageways can
be varied to achieve the desired mixing effect. Here too, hole placement will be selected
to promote mixing by distributing fuel into the prevailing air flow.
[0029] In the embodiment illustrated in Figs. 9-11, representative passageways and placement
of holes are shown in a representative nozzle. Fuel is injected along a fuel injection
direction 244. Representative fuel injection trajectories are illustrated by arrows
244.
[0030] The size and placement of the various passageways and holes are similar to those
described in detail above with respect to Figs. 3-5.
[0031] Fig. 12 is a perspective view of another embodiment of the counterflow fuel injection
nozzle 416 according to one aspect of the present invention. Fig. 13 is a side sectional
view of the counterflow fuel injection nozzle 416 of Fig. 12. Figs. 12-13 also illustrate
fuel injection and counterflow fuel injection trajectories.
[0032] Referring to Figs. 12-13, the nozzle body 428 has a nozzle wall 430, and the nozzle
wall 430 defines a nozzle interior 432. It is nozzle body interior 432 that receives
the fuel to be distributed and ultimately injected into the airstream to produce a
flame. Since nozzle body interior 432 acts as a fuel conduit, the particularized curves,
tapers angles and surface and interior geometry of the injection nozzle 416 will dictate
how the fuel is distributed throughout the nozzle body interior 432. Here too, the
embodiment shown is representative only, and it is contemplated that other shapes,
geometric features and body outlines could be suitably employed. Here again, any suitable
materials may be used in the construction of injection nozzle 416, although stainless
steel is one preferred material, among others.
[0033] Interior surface 434 of nozzle wall 430 defines nozzle interior 432 into which fuel
is received from fuel line 414. Fuel line 414 includes threaded portion 436 for threaded
insertion into a mating threaded portion 438 of interior surface 434. Although a threaded
engagement is shown and preferred, it is contemplated that other means of connection
between the fuel line 414 and the injection nozzle 416 are possible. Nozzle body 428
further includes a series of fuel passageways 440 terminating in holes or openings
442 formed in the nozzle wall 430, and more specifically, groove 433, for distributing
the fuel. Groove 433 prevents air from shearing off the gas exiting the holes and
permitting gas to develop into a jet stream, resulting in more consistent mixing.
[0034] Fuel flows from the nozzle interior 432 through the passageways 440 and out of the
nozzle 416 via holes 442 into an air flow (again, see Figs. 1-2). It is contemplated
that the size, shape, and placement of the holes and passageways can be varied to
achieve the desired mixing effect. Again, hole placement can be selected to promote
mixing by distributing fuel into the prevailing air flow.
[0035] In the embodiment illustrated in Figs. 12-13, representative passageways and placement
of holes are shown in a representative nozzle. Fuel is injected along a fuel injection
direction 444.
[0036] In one embodiment of the counterflow fuel injection nozzles depicted in Figs. 12
and 13, the passageways can be cylindrical and the holes can be round. Although any
hole size is contemplated, in one embodiment, the holes can be sized to have a diameter
in a range of from about 0.0625 inches to about 0.141 inches. Angular spacing of the
holes ranges, in one embodiment, from between about 45 degrees to about 60 degrees.
It is contemplated that variations in size, shape and placement can be on a hole by
hole and/or nozzle by nozzle basis. It is understood, however, that it is a design
goal to select the size, shape and placement of the holes to minimize, or eliminate
interference between the fuel flow trajectories from the holes (e.g., one fuel injection
direction crossing, in whole or in part, another fuel injection direction).
[0037] Hole pattern (i.e, the number and position of the holes), as well as hole size (e.g.,
as determined by hole diameter) can be varied. In this manner, mixing of the air and
fuel can be accomplished so as to control and achieve complete or substantially complete
combustion, a hallmark of the present invention.
[0038] Referring now to Figs. 14 and 15, another embodiment of the counterflow fuel injection
nozzle 500 according to one aspect of the present invention is shown. In this embodiment,
nozzle 500 includes an outer threaded surface 502 with retaining nut 504 threaded
thereon to secure nozzle 500 against burner housing portion 506, such as by engaging
slot 507 and rotating nozzle 500 appropriately. Nozzle 500 includes a bored out portion,
channel or passageway 508 (shown in phantom) terminating in nozzle opening 509. Fuel
enters fuel passageway 508 in a direction indicated by arrow 512, and proceeds through
passageway 508, where it is flows out of the nozzle into an airflow via nozzle opening
509. Fuel is injected at a fuel flow injection direction (F
fuel) into a prevailing air direction (F
air). Again, the fuel is injected through nozzle opening 509 such that at least a component
of F
fuel is opposite to F
air.
[0039] More localized mixing can occur at each counterflow injection nozzle, and more specifically,
via the holes through which fuel is distributed or dispersed from each nozzle into
the prevailing air flow. In this fashion, the amount or level of mixing, as well as
the location(s) at which mixing takes place, can be adjusted or varied to convenience
by varying the size and location of the holes.
[0040] It is contemplated that each of the above-described embodiments of the inventive
counterflow fuel injection nozzles can include plurality of passageways, each having
a unique noninterfering fuel injection direction. By "noninterfering" it is meant
that, at the point at which fuel exits the nozzles (via the nozzle openings), fuel
from one passageway having a direction tends not cross the direction of fuel passing
from another passageway. The holes can also be directed at various angles to achieve
the desired mixing qualities.
[0041] In another aspect of the present invention, a method of mixing a fuel and air in
a burner-boiler system is disclosed. The system comprises a nozzle having a nozzle
wall that defines a nozzle interior for receiving the fuel, and the nozzle further
includes a fuel passageway formed in the nozzle wall. The method comprises passing
air in a prevailing airstream direction along an exterior of the nozzle wall. The
method further includes distributing the fuel in a fuel flow injection direction from
the interior through the fuel passageway into the air passing in the prevailing airstream
direction along the exterior of the nozzle wall. The method still further includes
counterflow mixing the fuel distributed in the fuel flow injection direction with
the air passing in the prevailing airstream direction. Significantly, at least one
vector component of the fuel flow injection direction opposes at least one vector
component of the prevailing airstream direction.
[0042] Also, the use of the counterflow nozzle provides additional burner stability with
increased flue-gas recirculation (FGR) rates (when FGR is used) to achieve lower NOx
levels.
[0043] As is known to those skilled in the art, the turndown ratio is the ratio of maximum
fuel input rate to minimum fuel rate of a variable input burner, and depends on burner
size and control methodology. Typical low NOx burners have limited turndown, but with
this invention, advantageously, with low NOx operation a higher turndown ratio is
possible, and a turndown of from about 7 to 1 to about 10 to 1 has been achieved using
the present counterflow injection nozzles.
[0044] It is noted that a gas mixing nozzle retrofit for a burner used with a firetube boiler,
commercial watertube or larger industrial watertube boiler is contemplated. The retrofit
may be part of a kit that includes a counterflow fuel injection nozzle that is used
to replace a non-counterflow fuel injection nozzle. A non-counterflow fuel injection
nozzle would not provide for at least one vector component of a fuel flow injection
direction that opposes at least one vector component of a prevailing air flow direction
when an airstream is provided in a prevailing air flow direction in a location exterior
of the nozzle.
[0045] Despite any methods being outlined in a step-by-step sequence, the completion of
acts or steps in a particular chronological order is not mandatory. Further, modification,
rearrangement, combination, reordering, or the like, of acts or steps is contemplated
and considered within the scope of the description and claims.
[0046] While the present invention has been described in terms of a preferred embodiment(s),
it is recognized that equivalents, alternatives, and modifications, aside from those
expressly stated, are possible and within the scope of the appending claims.
1. A counterflow fuel injection nozzle for injecting fuel, the nozzle comprising:
a nozzle wall having an interior surface that defines a nozzle interior, the interior
for receiving a fuel therein, the nozzle further having a fuel passageway formed in
the nozzle wall for distributing the fuel from the interior to a location exterior
of the nozzle, the fuel distributed to the exterior location in a fuel flow injection
direction;
wherein, when an airstream is provided in a prevailing air flow direction in the
location exterior of the nozzle, at least one vector component of the fuel flow injection
direction opposes at least one vector component of the prevailing air flow direction.
2. The counterflow fuel injection nozzle of Claim 1 wherein the fuel passageway terminates
in an opening having a diameter in a range of between about .063 inches to about .141
inches.
3. The counterflow fuel injection nozzle of Claim 1 wherein the nozzle wall includes
a plurality of the fuel passageways, each of which terminate in an opening.
4. The counterflow fuel injection nozzle of Claim 3 wherein each of the plurality of
the fuel passageway openings has a diameter D and there is a distance L between the
plurality of openings and wherein a ratio L/D is used as a design parameter.
5. The counterflow fuel injection nozzle of Claim 4 wherein the ratio of L/D is approximately
5.
6. The nozzle of Claim 1 wherein the fuel is natural gas.
7. The counterflow fuel injection nozzle of Claim 3 wherein each of the plurality of
passageways has a unique noninterfering fuel injection direction.
8. The counterflow fuel injection nozzle of Claim 3, wherein the nozzle includes one
of a primary centralized circumferentially disposed notch and a groove into which
fuel is initially distributed from at least one of the plurality of passageways.
9. The counterflow fuel injection nozzle of Claim 1 wherein the distributing occurs by
injecting the fuel at a fuel flow injection angle that is in a range of about 15 degrees
to about 90 degrees.
10. The counterflow fuel injection nozzle of Claim 9 wherein the fuel flow injection angle
is substantially 30 degrees.
11. A method of mixing a fuel and air in a burner system, the system comprising a counterflow
fuel injection nozzle having a nozzle wall that defines a nozzle interior for receiving
the fuel, the nozzle further having a fuel passageway formed in the nozzle wall, the
method comprising:
passing the air in a prevailing air flow direction exterior of the nozzle wall;
distributing the fuel in a fuel flow injection direction from the nozzle interior
through the fuel passageway into the air passing in the prevailing air flow direction
exterior of the nozzle wall; and
counterflow mixing the fuel distributed in the fuel flow injection direction with
the air passing in the prevailing air flow direction such that at least one vector
component of the fuel flow injection direction opposes at least one vector component
of the prevailing air flow direction.
12. The method of claim 10 wherein the fuel is natural gas.
13. The method of Claim 10 wherein the distributing occurs by injecting the fuel at a
fuel flow injection angle that is in a range of about 30 degrees to about 90 degrees.
14. The method of Claim 13 wherein the fuel flow injection angle is substantially 45 degrees.
15. A gas mixing nozzle retrofit for a burner, the retrofit comprising:
a counterflow fuel injection nozzle wall having an interior surface that defines a
nozzle interior, the interior for receiving a fuel therein, the nozzle further having
a fuel passageway formed in the nozzle wall for distributing the fuel from the interior
to a location exterior of the nozzle, the fuel distributed to the exterior location
in a fuel flow injection direction;
wherein, when an airstream is provided in a prevailing air flow direction in the
location exterior of the nozzle, at least one vector component of the fuel flow injection
direction opposes at least one vector component of the prevailing air flow direction;
and
wherein the counterflow fuel injection nozzle is used to replace a non-counterflow
fuel injection nozzle that does not provide for at least one vector component of the
fuel flow injection direction that opposes at least one vector component of the prevailing
air flow direction when an airstream is provided in a prevailing air flow direction
in the location exterior of the nozzle.
16. The counterflow fuel injection nozzle of claim 15 wherein the fuel is natural gas.
17. The counterflow fuel injection nozzle of Claim 15 wherein the nozzle wall includes
a plurality of the fuel passageways, each of which terminate in an opening.
18. A burner system comprising:
a fuel line for introducing fuel to create a flame in a combustion chamber within
the burner system; and
a counterflow fuel injection nozzle, the nozzle having:
nozzle wall having an interior surface that defines a nozzle interior, the interior
for receiving a fuel therein, the nozzle further having a fuel passageway formed in
the nozzle wall for distributing the fuel from the interior to a location exterior
of the nozzle, the fuel distributed to the exterior location in a fuel flow injection
direction;
wherein, when an airstream is provided in a prevailing air flow direction in the
location exterior of the nozzle, at least one vector component of the fuel flow injection
direction opposes at least one vector component of the prevailing air flow direction.