The present invention relates to burners and more specifically to burners that are employed in industrial applications such as glassmelting furnaces, incinerators, cement kilns, and power plants. In such burners fuel is combusted with gaseous oxidant to produce heat that is employed in the industrial application to heat, melt or combust material.
The operation of industrial burners, in which streams of fuel and gaseous oxidant are fed into a burner and combusted in the burner, can generate significant acoustic resonance which has several drawbacks. The “Rayleigh criterion” (Rayleigh, J. L., Nature 18 (1878) 319-321) is commonly used for assessing the stability of a combustor. It states that if pressure and heat release fluctuations are in phase, the instability is fed by the flame and acoustics coupling.
The acoustic resonance can be exhibited as levels of noise that are unpleasant and even unsafe to nearby operators. In addition, interactions between the acoustic resonance and the flame of the burner can damage the burner, for instance by causing the flame to be unstable which can lead to overheating at certain surfaces of the burner. These phenomena are especially pronounced in burners in which the flame is formed within an enclosed chamber of the burner and emerges from an open end of the burner.
The present invention is a discovery of a burner that enables reduction of the acoustic resonance that may be exhibited by the burner.
One aspect of the present invention is a burner comprising
(A) a chamber having longitudinally opposed first and second ends, and a flame opening through the first end;
(B) a baffle in the chamber, having an outer edge which is adjacent to the interior surface of the chamber, the baffle having a first surface that faces toward the first end of the chamber and having a second surface that faces toward the second end of the chamber, and wherein the baffle is located in the chamber so that the second baffle surface is 5 to 10 inches from the interior surface of the second end of the chamber;
(C) a conduit that extends from a conduit inlet outside the chamber into the chamber and terminates at a conduit outlet in the section of the chamber that is between the first baffle surface and the flame opening, wherein the conduit outlet opens toward the flame opening;
(D) a passage that extends from a passage inlet outside the chamber and terminates at a passage outlet in the section of the chamber that is between the first baffle surface and the flame opening;
wherein the baffle comprises (1) a metal plate having a first plate surface that faces the flame opening and a second plate surface that faces the second end of the chamber, and (2) a layer of metal filaments in contact with the second plate surface,
wherein the metal plate is one-eighth to half an inch in thickness, and a plurality of holes one-eighth to half an inch in diameter pass through the metal plate between the first and second plate surfaces, in a sufficient number of holes so that the total area of the openings of all holes in each plate surface is 30% to 50% of the surface area of the metal plate, and
wherein the layer of metal filaments is a quarter of an inch to 4 inches thick, preferably at least 1.5 inches thick, exhibits a density of up to 0.5 ounces per cubic inch, and is composed of filaments up to 0.005 inches thick.
In yet another aspect of the present invention, the baffle further comprises a second metal plate that is in contact with the layer of metal filaments so that said layer is sandwiched between the second metal plate and the metal plate, and wherein the second metal plate is one-eighth to half an inch in thickness, and a plurality of holes one-eighth to half an inch in diameter pass through the second metal plate between its surfaces, in a sufficient number of holes so that the total area of the openings of all holes in each surface of the second metal plate is 30% to 50% of the surface area of the second metal plate.
The present invention is applicable with a large variety of burner configurations. It is especially useful with burners in which one end of the flame that is formed by combustion of the fuel and the oxidant is inside a chamber or enclosure of the burner, so that a portion of the flame that extends from that end is also inside the chamber or enclosure of the burner, with the balance of the flame extending out of an opening of the burner.
The Figures illustrate several embodiments of burners with which the present invention is particularly useful.
Reference is made first to
First end 2 is open, so that flame 22 having one end inside the chamber 1 can extend out through flame opening 4 to the space outside burner 100. Flame opening 4 can comprise the entire opening that is defined by the ends of sidewall 9. However, the present invention is particularly effective in embodiments in which first end 2 is partially closed by end plate 20, such that the area of flame opening 4 is smaller than the total area of first end 2 that is defined by the ends of sidewall 9. Second end 3 is closed, and may have one or more conduits passing through it as described herein provided that the joint between second end 3 and any such conduits is sealed against gas passing through the joint.
Referring again to
Passage 15 is also provided. It extends from passage inlet 16 that is outside burner 100 to passage outlet 17 that is inside chamber 1. Passage inlet 16 can be connected to a source of gaseous oxidant to be combusted in chamber 1 with the fuel that is fed through conduit 10. Suitable gaseous oxidant includes air, oxygen-enriched air, and commercial high purity oxygen. Thus, the oxygen content of the gaseous oxidant can be that of air (about 21 vol. %) up to 95 vol. % or higher, even 99 vol. % or higher.
The burners of the present invention also include baffle 5. As seen in
As seen in
It has been found that when a baffle 5 as described herein, is included in the construction and operation of a burner as described herein, the operation of the burner is accompanied by much less noise and acoustic resonance than is observed upon combustion without the baffle. It has been found that the baffle 5 should be located in chamber 1 so that the distance from the interior surface 6 of second end 3 to the second surface 43 of baffle 5 should be 5 to 10 inches, preferably about 6 inches. Surprisingly it has been found that this characteristic distance is independent of the other dimensions of the burner and of the operating conditions of the burner.
The baffle is further described herein with reference to
Metal plate 44 is made of any metal that retains its shape at the combustion temperatures which are produced in combustion section 7. Examples of suitable metals include brass and steel. Metal plate 44 is preferably one-eighth of an inch to half an inch in thickness, where the thickness is defined as the distance between surface 42 and rear surface 45 of metal plate 44. Metal plate 44 should extend throughout the diametrical width of baffle 5, that is, all the way to edge 41 all the way around baffle 5.
As seen in
Baffle 5 also includes layer 46 of metal filaments. Layer 46 should be in contact with surface 45, although of course not all of the material of which layer 46 is formed needs to be in contact with surface 45. The metal filaments, shown as 48, are each up to 0.005 inch in diameter and are randomly intertwined with each other sufficiently to form a unitary mat of material. Such a mat is considered to be unitary if, when a single unitary quantity of the mat is held at one point so that it hangs from that one point of support and is not otherwise supported, it remains as one unitary quantity and does not break into additional pieces. The layer 46 is not a solid block but also contains spaces between the intertwined filaments. The density (uncompressed) of the layer should be up to 0.5 ounces per cubic inch. Suitable examples of material for layer 46 include products known as “metal wool”, such as steel wool or brass wool.
Layer 46 when incorporated into baffle 5 should be at least a quarter of an inch (0.25 inch) thick along the axis that extends between ends 2 and 3 of chamber 1. This thickness should preferably be up to 6 inches thick. Thicker layers are acceptable provided that the distance between the rear surface 43 and the interior surface 6 remains as described herein. The benefit in reduced acoustic resonance, with each additional inch of thickness of the layer 46, may decrease.
In operation of the burner, fuel is fed through conduit outlet 12 into combustion section 7 of chamber 1, and oxidant is passed out of passage outlet 17 into combustion section 7 of chamber 1, and they are ignited and combusted. The combustion forms a flame whose base is at outlet 12. The flame extends out of chamber 1 through flame opening 4. The fuel and oxidant should be fed at relative mass flow rates so that the oxygen in the oxidant constitutes 300 to 20,000% of the amount of oxygen needed to completely combust the fuel. The velocities of each flow prior to combustion are preferably an oxygen flow rate of 5 to 20 feet per second and a fuel flow rate of 30 to 50 feet per second.
This application claims the benefit of U.S. Provisional Application Ser. No. 62/529,025, filed on Jul. 6, 2017, which is incorporated herein by reference.
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Rayleigh, J.L., The Explanation of Certain Acoustical Phenomena, Nature, Jul. 18, 1878, 319-321, Nature Publishing Group. |
Number | Date | Country | |
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20190011125 A1 | Jan 2019 | US |
Number | Date | Country | |
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62529025 | Jul 2017 | US |