The invention relates to a fuel burner and, in particular, relates to a fuel burner that imparts a centrifugal force upon combustion air or a combination of air and fuel.
Power burners of various types have been in use for many years. “Nozzle mix” or “gun style” burners are those burners that inject fuel and air separately in some manner so as to provide a stable flame without a ported flame holder component. Other types of power burners use some method of pre-mixing the fuel and air and then delivering the fuel-air mixture to a ported burner “head”. These “heads” or “cans” can be made of a variety of materials including perforated sheet metal, woven metal wire, woven ceramic fiber, etc. Flame stability, also referred to as flame retention, is key to making a burner that has a broad operating range and is capable of running at high primary aeration levels. A broad operating range is desired for appliances that benefit from modulation, in which the heat output varies depending on demand. High levels of primary aeration are effective in reducing NOx emissions, but tend to negatively impact flame stability and potentially increase the production of Carbon Monoxide (CO). High levels of primary aeration (also referred to as excess air) also reduce appliance efficiency. There is a need in the art for a fuel burner that reduces the production of NOx while maintaining flame stability. Even more desirable is a burner that produces very low levels of NOx while operating at low levels of excess air.
In accordance with the present invention, a fuel burner includes an outer tube that extends along a central axis and has an outer surface and an inner surface defining a passage. An inner tube positioned within the passage of the outer tube has an outer surface and an inner surface defining a central passage. A fluid passage is defined between the outer surface of the inner tube and the inner surface of the outer tube. The fluid passage is supplied with a mixture of air and combustible fuel. The inner tube has fluid directing structure for directing the mixture from the fluid passage to the central passage such that the mixture rotates radially about the central axis.
In accordance with another aspect of the present invention, a fuel burner includes an outer tube that extends along a central axis and has a tapered portion for defining a passage. An inner tube is positioned within the passage of the outer tube and has an outer surface and an inner surface that defines a central passage. The inner tube extends from a first end to a second end. An end wall secured to the first end of the inner tube closes the first end of the inner tube in a gas-tight manner. A cap secures the second end of the inner tube to the outer tube in a gas-tight manner. A fluid passage is defined between the outer tube and the outer surface of the inner tube and is supplied with a mixture of air and combustible fuel. The inner tube has fluid directing structure for directing the mixture from the fluid passage to the central passage such that the mixture swirls about the central axis. The fluid directing structure provides the only fluid path between the fluid passage and the central passage.
Other objects and advantages and a fuller understanding of the invention will be had from the following detailed description of the preferred embodiments and the accompanying drawings.
The invention relates to a fuel burner and, in particular, relates to a fuel burner that imparts a centrifugal force upon combustion air or a combination of air and fuel.
The fuel burner 20 extends along a central axis 26 from a first end 22 to a second end 24. The fuel burner 20 includes a first, inner housing or tube 40 and a second, outer housing or tube 60. The inner tube 40 and the outer tube 60 are concentric with one another and are centered about the central axis 26. The inner tube 40 has a tubular shape and extends along the central axis 26 of the fuel burner 20 from a first end 42 to a second end 44. Although the inner tube 40 is illustrated as having a circular shape, it will be appreciated that the inner tube may exhibit alternative shapes, such as triangular, square, oval or any polygonal shape. The inner tube 40 includes an outer surface 46 and an inner surface 48 that defines a central passage 50 extending through the inner tube and terminating at an opening 58 at the second end 44 of the inner tube. The inner tube 40 is made from a durable, flame-resistant material, such as metal. The inner tube 40 has a constant cross-section as illustrated in
The space between the inner and outer tubes 40, 60 defines a fluid passage 112 for receiving fuel and air. The periphery of the inner tube 40 includes fluid directing structure 52 for directing fluid to the central passage 50. As shown in
The fluid direction structure 52 may include a series or openings with associated fins or guides for directing the fluid in the desired manner (
Each opening 54 includes a corresponding fluid directing projection or guide 56 for directing the air/fuel mixture passing through the associated opening radially inward into the central passage 50 in a direction that is offset from the central axis 26 of the fuel burner 20, i.e., a direction that will not intersect the central axis. The guides 56 are formed in or integrally attached to the inner tube 40. Each guide 56 extends at an angle (shown in
In
In
In
In
As shown in
A cap 120 is integrally formed with or secured to the inner tube 40 and seals and secures the inner tube to the outer tube 60. More specifically, the cap 120 is formed on the second end 44 of the inner tube 40 and is secured to the second end 64 of the outer tube 60 such that the inner tube extends into the passage 74 of the outer tube towards the first end 62 of the outer tube. The cap 120 has an annular shape and includes a wall 122 that exhibits a U-shaped configuration. The wall 122 defines a passage 124 for receiving the second end 64 of the outer tube 60. The wall 122 also defines a central opening 126 that is aligned with the opening 58 in the inner tube 40 and the opening 76 in the outer tube 60.
An end wall 80 is secured to the first end 42 of the inner tube 40 and closes the first end of the inner tube in a gas-tight manner. The end wall 80 includes an annular rim 82 that exhibits a U-shaped configuration. The rim 82 defines a passage 84 for receiving the first end 42 of the inner tube 40. The end wall 80 closes the first end 42 of the inner tube 40 to prevent the incoming fuel/air mixture from directly entering the central passage 50 of the inner tube.
When the fuel burner 20 is assembled (
An ignition device (not shown) of any number of types well known in the art can be positioned in any number of suitable locations to light the fuel burner 20. For example, the end wall 80 may be provided with an opening (not shown) through which an igniter extends. Flame proving means (not shown) may be positioned in any number of suitable locations to detect the presence of flame. A supply of pre-mixed air and combustible fuel is delivered to the outer tube 60, which then flows into the passage 74 of the outer tube. Any number of pre-mixing systems which are well known in the art may be used in accordance with the present invention.
In operation, the pre-mixing system (not shown) supplies a mixture of air and fuel to the fuel burner 20. In particular, the system pre-mixes the air and fuel and delivers the mixture as a stream to the passage 74 of the outer tube 60. The air/fuel mixture stream is delivered in the direction indicated by arrow D into the fluid passage 112 between the inner tube 40 and the outer tube 60. As shown in
Since the fluid directing structure 52, i.e., the openings 54 and guides 56, extend around the entire periphery of the inner tube 40 the air/fuel mixture within the central passage 50 is forced in a direction, indicated by arrow R (
The rotating, spiraling air/fuel mixture is ignited by an ignition device (not shown) of any number of types well known in the art and positioned in any number of suitable locations to light the fuel burner 20. For example, the wall 80 may be provided with an opening (not shown) through which an igniter extends. Flame proving means (not shown) may be positioned in any number of suitable locations to detect the presence of flame.
Due to the continued supply of air and fuel to the fuel burner 20 from the pre-mixing system, the air/fuel mixture streams become radially layered within the central passage 50. It is believed that the layering of air/fuel mixture streams within the central passage 50 increases the input flexibility of the burner assembly of the present invention. More specifically, it is believed that radially layering the air/fuel mixture streams allows the burner assembly of the present invention to operate effectively over a large range of air/fuel ratios and a large range of fuel input levels.
The burner assembly of the present invention is advantageous over conventional burners for several reasons. In conventional burners, the flame is propagated primarily by molecular conduction of heat and molecular diffusion of radicals from the flame into the approaching stream of reactants (fuel/air mixture). It is believed that the disclosed burner assembly forces additional paths of heat transfer by convection and radiation from the high velocity flame envelope overlaying and intermixing with the incoming fuel/air mixture. The incoming fuel/air mixture is pre-heated while the flame zone is being cooled, which advantageously helps to reduce NOx. Radicals are also forced into the incoming reactant stream by the overlaying and intermixing flame envelope. The presence of radicals in a mixture of reactants lowers the ignition temperature and allows the fuel to burn at lower than normal temperature. It also helps to significantly increase flame speed, which shortens the reaction time, thereby additionally reducing NOx formation while significantly improving flame stability/flame retention. Typical combustors achieve flame retention/stability by incorporating a region where reactants' flow is low in order to anchor the flame, such as edges of ports, bluff bodies, mesh surfaces, small “flame holder” ports of low velocity surrounding larger ports, and many others. Different types of “swirl” burners have also been developed over the years. These types of combustors create recirculation regions of low velocities for anchoring the flame.
Due to the exceptional flame retention/stability of the burner of the present invention, it is capable of running at very high port loadings. High port loadings allow the burner of the present invention to run in a stable “lifted flame” mode, i.e., the flame is spaced from the inner surface 48 of the inner tube. Lifting of the flame in this manner is desirable in that the inner tube 40 is not directly heated, thereby maintaining the inner tube at a lower temperature and lengthening the usable life of the fuel burner 20. A high port loading also allows the use of a smaller, space saving and less costly burner for a given application.
Furthermore, NOx production in the burner assembly of the present invention is significantly lower than in other burner systems, confirming a lower flame temperature and reduced reaction time. Low CO confirms a longer dwell time of combustion gases in the reaction zone (swirling inside of the burner head). More specifically, typical pre-mixed ported or mesh covered burners will run total NOx of about 10 ppm at about 8% CO2 (or less) when burning natural gas, depending somewhat on the application. On the other hand, the disclosed burner of the present invention has achieved 10 ppm of total NOx at 10% CO2. Anyone skilled in the art of appliance design and heat transfer will recognize the significant increase in appliance efficiency when running at 10% CO2 compared with the same appliance operating at 8% CO2. The disclosed burner, due to the exceptional flame retention as discussed above, is also capable of operating cleanly, i.e., low CO, at very high levels of excess air, which produces NOx levels well below those achievable with conventional burners.
The preferred embodiments of the invention have been illustrated and described in detail. However, the present invention is not to be considered limited to the precise construction disclosed. Various adaptations, modifications and uses of the invention may occur to those skilled in the art to which the invention relates and the intention is to cover hereby all such adaptations, modifications, and uses which fall within the spirit or scope of the appended claims.
This application filed under 35 U.S.C §371 is a national phase application of International Application Ser. Number PCT/US2012/050278 filed Aug. 10, 2012, which claims priority to U.S. Provisional Application 61/522,412, filed. Aug. 11, 2011 and 61/602,261, filed Feb. 23, 2012.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2012/050278 | 8/10/2012 | WO | 00 | 2/10/2014 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/023127 | 2/14/2013 | WO | A |
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Entry |
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PCT/US2012/050278 International Search Report & Written Opinion completed Oct. 18, 2012. |
Number | Date | Country | |
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20140186784 A1 | Jul 2014 | US |
Number | Date | Country | |
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61522412 | Aug 2011 | US | |
61602261 | Feb 2012 | US |