The present invention relates generally to the field of fuel burners and in particular to a new and useful air separation cone for expanding the internal recirculation zone near the exit of one or more air zones surrounding a fuel delivery nozzle.
Low-NOx fossil fuel burners operate on the principle of controlled separation and mixing of fuel and oxidizer for minimizing the oxidation of fuel-bound nitrogen and nitrogen in the air to NOx (i.e., NO+NO2). Use of overfire air in conjunction with fuel-rich combustion is referred to as external (or air) staging. Internal staging involves the creation of fuel-rich and fuel-lean combustion zones within the burner flame. With proper design, fuel-air mixing and swirl patterns can be optimized to create a reverse flow region or “internal recirculation zone” (IRZ) near the burner exit for recycling heat and combustion products including NOx from fuel-lean regions into fuel-rich zones to sustain ignition, maintain flame stability, and convert NOx to N2. Both internal and external staging are often necessary for maximum NOx reduction. Flames with large, high temperature, sub-stoichiometric (oxygen-deficient) IRZ's generally produce very low NOx levels since such conditions are conducive for NOx destruction. Low-NOx burner designs produce the IRZ by imparting swirl on the air and/or fuel streams as well as flow deflecting devices such as flame holders and air separation cones.
Secondary air 910, or the majority of combustion air, is delivered to inner and outer secondary air zones 914 and 916 from the burner windbox. Swirl can be imparted into the zones 914 and 916 via adjustable angle spin vanes 922 in the inner air zone 914 and both fixed spin vanes 920 and adjustable angle spin vanes 922 in the outer air zone 916. The inner and outer secondary air zones 914 and 916 are formed by concentrically surrounding walls. The inner air zone 914 concentrically surrounds the tubular burner nozzle 906 and the outer air zone 916 concentrically surrounds the inner air zone 914.
An air separation cone 924, concentrically surrounding the end of the tubular burner nozzle 906, helps channel the secondary air 910 leaving the inner and outer air zones 914 and 916. A flame stabilizer 926 and a slide damper 928 control the secondary air 910. The flame stabilizer 926 is mounted at the end of the tubular burner nozzle 906 while the air separation cone 924 is installed on a cylindrical sleeve that separates the inner and outer secondary air zones 914 and 916.
The inner and outer zones 914 and 916 direct the secondary air radially outward by the combined action of the burner throat and the swirl imparted by the spin vanes 922, generating internal recirculation zones (IRZ) 930.
The size of the IRZ can be increased somewhat by imparting more swirl on the secondary air flow, and extending the flow deflection devices, or increasing their angle of attack. Generation of high swirling flows require fan power boosting due to higher pressure drop. High swirl combustion can also intensify the fuel/oxidizer mixing and generate high NOx emissions. Extension of flow deflecting devices (flame holder or air separation cone) into the furnace could expose those parts to high flame temperatures and cause damage. Increasing the angle of attack on the flow deflecting devices could restrict the air flow passages, raise the pressure drop, and diminish the swirl effects. Therefore, a device is needed for safely and effectively increasing the size of the IRZ, without damaging flow deflecting devices, causing increased NOx emissions, or raising pressure drop.
It is an object of the present invention to provide a device which safely and effectively increases the size of the IRZ, without damaging flow deflecting devices, causing increased NOx emissions, or raising pressure drop.
Accordingly, a large diameter mid-zone air separation cone is provided for increasing the IRZ and decreasing NOx. The air separation cone has a larger diameter than the conventional air separation cone. The mid-zone air separation cone has a short cylindrical leading edge that fits in the outer air zone of a burner. The mid-zone air separation cone is supported by standoffs inside the outer air zone. The mid-zone air separation cone splits the outer air zone secondary air flow into two equal or unequal streams depending on the position of the air separation cone with respect to the outer air zone, and deflects a portion of the secondary air flow radially outward. Since the radial position of the mid-zone air separation cone is farther from the burner centerline than the radial position of the conventional air separation cone, the size of the IRZ is expanded and NOx emissions are minimized.
The mid-zone air separation cone can be used with many types of burners. The mid-zone air separation cone can be used with burners fueled by pulverized coal, oil, or natural gas. The mid-zone air separation cone can be used with burners with primary air and coal in the center or a large central passage of secondary air surrounded by primary air and coal. The mid-zone air separation cone can essentially be used with any burner where there is at least one air zone surrounding a fuel delivery nozzle or annulus, where the air separation cone is of a large diameter and therefore the IRZ is enlarged.
Thus, some of the advantages of using the mid-zone air separation cone of the present invention are expansion of the IRZ, better flame stabilization and attachment, and lower NOx emissions. Also, there is no adverse effect on burner operation, such as damage to air separation cone or other components of the burner and pressure drop is not raised. The mid-zone air separation cone is a simple cost-effective solution that requires no additional conduits inside a burner and can be installed with relative ease inside the air zone of many burners.
The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which a preferred embodiment of the invention is illustrated.
In the drawings:
Referring now to the drawings, in which like reference numerals are used to refer to the same or similar elements,
The diverging angle of the mid-zone air separation cone can be between 25 to 45° from the horizontal axis A (50 to 90° included angle). Although the embodiment in
A mid-zone air separation cone 1 of the present invention is provided for increasing the IRZ zone and decreasing NOx. The air separation cone 1 has a larger diameter than the air separation cone shown in
The burner 40 includes a mid-zone air separation cone 1 having a short cylindrical leading edge 3 that fits in the middle of the outer air zone 50. The mid-zone air separation cone 1 is supported by standoffs (not shown) inside the outer secondary air zone annulus. The mid-zone air separation cone 1 splits the outer air zone 50 secondary air flow into two streams and deflects a portion of the secondary air flow radially outward. Since the radial position of the air separation cone 1 is farther from the burner centerline than the conventional air separation cone shown in
Structurally, the design of the burner 40 (DRB-4Z®) according to the present invention is based largely on that for the DRB-XCL® burner shown in
Secondary air 78 is supplied by forced draft fans or the like, preheated in air heaters, and supplied under pressure. Feeder duct 69 supplies core air to central zone 66. Wedged shaped pieces 68A and 69B provide a more contoured flow path for the PAIPC 61 as it travels past the core air supply feeder duct 69. The core air proceeds down central zone 66 until it exits. Some secondary air flows into transition zone 76 or outer air zone 77. Secondary air can be throttled to one zone or the other, or to supply lesser quantities of air to both zones to cool the burner when the burner is out of service. The transition zone 76 is separated from the outer air zone 77. The transition zone 76 is constructed to provide air for near-burner mixing and stability. Adjustable angle spin vanes 81 are situated in the transition zone 76 to provide swirl to transition air. Outer air proceeds through fixed spin vanes 80 and adjustable angle spin vanes 82 which impart swirl to the outer air.
A large diameter mid-zone air separation cone 1 with a short cylindrical leading edge 3 (not shown in
Performance of the mid-zone air separation cone was further tested with low NOx central air jet pulverized coal burner at 100 million Btu/hr while firing a pulverized eastern bituminous coal. At 17% overall excess air level, and 0.80 burner stoichiometry, NOx emissions were 0.276 lb/million Btu with the conventional air separation cone installed on the end of the cylindrical sleeve 5 separating the transition zone 76 from outer air zone 77, and 0.238 lb/million Btu with the mid-zone air separation cone, shown in
Mid-zone air separation cone 1 having a short cylindrical leading edge 3 is provided within outer air zone 108. Air separation cone 1 is supported by standoffs (not shown) inside the outer air zone 108. Air separation cone 1 splits the outer air zone 108 secondary air flow into two streams and deflects a portion of the secondary air flow radially outward. Since the radial position of the air separation cone 1 is farther from the burner centerline than the conventional air separation cone shown in
While a specific embodiment of the invention has been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.
Number | Name | Date | Kind |
---|---|---|---|
4545307 | Morita et al. | Oct 1985 | A |
4836772 | LaRue | Jun 1989 | A |
5199355 | Larue | Apr 1993 | A |
5263426 | Morita et al. | Nov 1993 | A |
5651320 | Leisse et al. | Jul 1997 | A |
5697306 | LaRue et al. | Dec 1997 | A |
5937770 | Kobayashi et al. | Aug 1999 | A |
6024030 | Okamoto et al. | Feb 2000 | A |
6145450 | Vatsky | Nov 2000 | A |
7028622 | Taylor | Apr 2006 | B2 |
Number | Date | Country | |
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20070281265 A1 | Dec 2007 | US |