BRPI0915469B1 - radiant burner - Google Patents

Abstract

radiant burner the present invention relates to a radiant burner comprising a body defining a premix chamber and a combustion chamber. the premix chamber is separated from the combustion chamber by at least one radiant burner plate (2) which has multiple levels of the burner surface. the combustion chamber is further limited by a first radiant screen (4). the radiant burner further comprises a second radiant screen (3) in the combustion chamber. the second radiant screen is spaced, however, close and parallel to the radiant burner plate (s), in such a way that this second radiant screen acts as an extended burning surface and also heats the said by least one radiant burner plate when in use.

Description

(54) Title: BURNING RADIANT (51) Int.CI .: F23D 14/14.

(30) Unionist Priority: 08/07/2008 EP 08159919.3.

(73) Holder (s): SOLARONICS S.A ..

(72) Inventor (s): KOEN CLAERBOUT; GEERT DUMORTIER; VALÉRIE OLALDE.

(86) PCT Application: PCT EP2009058429 of 07/03/2009 (87) PCT Publication: WO 2010/003904 of 01/14/2010 (85) Date of the Beginning of the National Phase: 05/01/2011 (57) Summary: RADIANT BURNER The present invention relates to a radiant burner comprising a body defining a premix chamber and a combustion chamber. The premix chamber is separated from the combustion chamber by at least one radiant burner plate (2) that has multiple levels of the burner surface. The combustion chamber is further limited by a first radiant screen (4). The radiant burner further comprises a second radiant screen (3) in the combustion chamber. The second radiant screen is spaced, however, near and parallel to the radiant burner plate (s), in such a way that this second radiant screen acts as an extended burning surface and also heats the said less a radiant burner plate when in use.

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Descriptive Report of the Invention Patent for BURNING RADIANT.

Technical Field [001] The present invention relates to radiant burners that comprise a radiant burner plate and screen.

Background Art [002] Radiant burners comprising a radiant plate and a screen are known, for example from documents US No. 4,799,878 and EP No. 0.539279. The screen together with the radiant burner plate provides the radiant output of the burner, with average values at levels around 50% efficiency. In the past, the radiant output of the burners has been increased by modifying the radiant burner plate by a plate with rows of through holes or perforations serving to channel the mixture of air and combustion agent through the back of the plate to a burner plate on which the through holes or perforations are arranged in what is currently designated a honeycomb configuration as described, for example, in US 4,569,657 or US 4,799,879. These or similar modifications of the radiant burner plate have increased the temperature level and consequently also the radiant output of the burner. On the other hand, these hive-shaped configurations are creating overheating of the burner plate in the places where the flames are present and also cause unsatisfactory temperature uniformity of the relatively low average burner surface and thus lower energy efficiency. These high local temperatures therefore also define the limitation on the use of said through holes or drilling patterns, and thus define the limitation of the radiation energy value that can be obtained with said systems.

[003] Another way to obtain higher radioactive emission was

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2/8 proposal, for example, in US Patent No. 3,847,536 which uses two screens above radioactive radiant burner plate. This modification of the radiant burner plate also caused the radiant burner plates to overheat in the center of the radiant burner, which compelled those skilled in the art to lower inputs which resulted in lower (local) temperatures of the radiant burner plate to prolong the life of the burner. radiant.

[004] However, an even higher efficiency of radiant burners is desired.

Description of the Invention [005] One aspect of the claimed invention features a radiant burner comprising a body defining a premix chamber and a combustion chamber. The premix chamber is separated from the combustion chamber by at least one radiant burner plate that has multiple levels of burner surface. The combustion chamber is additionally limited by a first radiant screen. The radiant burner also comprises a second radiant screen in the combustion chamber. The second radiant screen is spaced, however, near and parallel to the radiant burner plate (s), in such a way that this second radiant screen acts as an extended radiant burner surface and also heats said at least one plate radiant back burner when in use. In a preferred embodiment, the second radiant screen constitutes a set of circular bars or square bars spaced parallel. In a preferred embodiment, the first and second radiant screens are produced from highly heat resistant materials such as ceramic, especially aluminum or zirconium oxide, aluminum titanate, silicon oxide, corundum or mullite, silicon carbide, silicon nitride or infiltrated ceramic by metal, or silicon carbide infiltrated by silicon. Alternatively, the screens

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3/8 can also be made of thermo-resistant materials of another nature such as, for example, materials containing more than 50% by weight of a metallic silicide such as molybdenum disilicide (MoSi2) or tungsten disilicide (WSi2). In another preferred embodiment, the radiant screens are manufactured from highly thermoresistant steel qualities, such as high-grade stainless steel qualities such as Kanthal APM or APMT, different qualities of FeCrAl alloy designed for high temperature corrosion, Chrome / Nickel like Avesta 253 MA, 153 MA, Inconel 601, Incoloy 800HT 800 HT, Incoloy MA956.

[006] The radiant burner plate is preferably constructed of a ceramic material with high temperature resistance, and excellent mechanical and thermodynamic properties such as for example cordierite or zirconia; partially stabilized zirconia (PSZ), alumina, silicon carbides or other high-level technical ceramics. Height difference between two burner surface levels of the radiant burner plate is preferably 1 to 20 mm. More preferable from 1 to 10 m. Even more preferable from 2 to 7 mm. Preferably 5 mm.

[007] The radiant burner plate has multiple levels of burner surface. In a preferred embodiment, these multiple levels are arranged in rows and alternate by row or through holes / perforations on the radiant burner plate. An example of said burner plate can be found in figure 1, or alternative examples in figures 2 and 3. These types of burner plates as such provide less emissivity compared to ceramic tiles with honeycomb patterns or similar drilling configurations. This is due to the multi-level burner surface, in which the lower levels of the burner surface of the radiant burner plates provide a radioactive emission

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4/8 higher due to the sides of the rows also heating up and providing an additional radioactive outlet, however the maximum height level of the burner surface does not have the said additional radioactive outlet. Thus the total radiative output, and therefore also the energy efficiency, of said multi-level radiative burner plate as such, is lower than the honeycomb perforations in the radiant burner plate.

[008] However, even though radiant burner plates are used that as such have a lower radiative performance, it was surprisingly observed that by the use of a second radiant screen next to the radiant burner plates, the radiative performance of the heating plates radiant burner can be increased without leading to local overheating of the burner plates, as this would result in premature failure of the radiant burner plates. This can be explained, without claiming to be scientifically correct, by the fact that the retroradiation of the second radiant screen on the multilevel radiant burner plates is higher at the highest level of the burner surface as it is closer to the second radiant screen. The higher level in this way also warms more than the lower levels of the burner surface which are at a greater distance from the second radiant screen. As these lower levels on the burner surface were already at higher temperatures due to the effect of the flames heating the surface surrounding the cavity in which the perforations open, the overall effect of the present invention is that the different levels on the burner surface of the radiant burner plates are at the same temperature when in use. In other words, greater temperature uniformity of the burner surface of the radiant burner plate is achieved. Those versed in the technique that this greater temperature uniformity combined with the plurality of radiant screens re

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5/8 results in a significant energy efficiency of the complete radiant burner. In a preferred embodiment, the distance between the second radiant screen and the highest level of the burner surface of at least one burner plate is between 3 and 50 mm. Preferably, the distance between the second radiant screen and the highest level of the radiant burner plate is between 5 and 30 mm, even more preferably between 10 and 25 mm, preferably between 15 and 20 mm. In a preferred embodiment, the second radiant screen is positioned in such a way that the second radiant screen follows the direction of the rows of the highest burner surface level of the radiant burner plate.

[009] The first radiant screen is preferably a metal grid. In another preferred embodiment, the first radiant screen is a set of circular bars or square bars spaced parallel. Preferably, the first and second radiant screens are made up of a set of circular bars or parallel square circular bars. In another preferred mode, the first and second radiant screens are arranged in the same direction. In an alternative preferred embodiment, the first and second radiant screens are arranged at mutually offset angles. Preferably, the first and second radiant screens are arranged at an angle of 90 °.

[0010] Another observed advantage of the present invention resides in a lower level of emissions of combustion by-products, such as Nitrogen Oxides or Carbon Monoxide, which is likely due to the second radiant screen that acts as an extended burner surface and provides a more complete combustion of the gas / air mixture.

[0011] Another aspect of the claimed invention features a radiant burner with at least one other radiant screen in the chamberPetition 870200013502, of 28/01/2020, p. 9/20

6/8 of combustion.

Brief Description of the Figures in the Drawings [0012] Typical modalities are described below with reference to the attached drawings, according to which [0013] figures 1 to 3 show a cross section of typical modalities of radiant burner plates used in the present invention;

[0014] figure 4 shows a typical embodiment of the present invention, in the absence of the construction of the radiant burner for a better view;

[0015] figure 5 shows a side view of the radiant burner of figure 4, also in the absence of the construction of the radiant burner for a better view;

[0016] figure 6 shows a typical alternative embodiment of the present invention;

[0017] figure 7 shows a side view of the typical radiant burner in figure 6.

Modes for Carrying Out the Invention [0018] Typical embodiments of the present invention are now described with reference to figures 1 to 7.

[0019] Figures 1 to 3 show cross sections of typical modalities of the radiant burner plates that could be used in the present invention. Figure 1 shows two levels of the burner surface of the typical radiant burner plate 2, figures 2 and 3 show three levels of the burner surface, in two alternative forms.

[0020] Figures 4 and 5 show a typical embodiment of the present invention.

[0021] The first radiant screen 4 is a highly heat-resistant metal grid manufactured from highly resistant steel qualities,

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7/8 such as high-grade stainless steel, such as Kanthal APM or APMT, different FeCrAl alloy qualities designed for high temperature corrosion, Chrome / Nickel steel qualities such as Avesta 253 MA, 153 MA. INCONEL 601 800, INCOLOY 800HT, INCOLOY MA956. The second radiant screen 3 is produced from a highly heat-resistant ceramic material, in this example aluminum or zirconium oxide, aluminum titanate, silicon oxide, corundum or mullite, silicon carbide, silicon nitride or metal infiltrated ceramics, such as carbides silicon infiltrates with a degree of silicon infiltration of 5 to 50% or even higher. Alternatively, the radiant screens can also be made of thermo-resistant materials of another nature such as, for example, materials containing more than 50% by weight of a metal such as molybdenum disilicide (MoSi2) or tungsten disilicide (WSi2). The radiant burner plate 2 is produced from a two-level burner surface, ceramic tile produced from cordorite or alternatively from thermodynamically suitable ceramic as mentioned above.

[0022] Figures 6 and 7 show a typical alternative embodiment of the present invention. The first and second radiant screens are produced from highly resistant material, in this example a ceramic such as aluminum or zirconium oxide, aluminum titanate, silicon oxide, corundum or mullite, silicon carbide, silicon nitride or metal infiltrated ceramic, such as silicon carbide infiltrated silicon with a silicon infiltration ratio of 5 to 50% or even higher. Alternatively, the radiant screens can also be made of thermo-resistant materials of another nature such as, for example, materials containing more than 50% by weight of a metal silicide, such as molybdenum disilicide (MoSi2) or tungsten disilicide (WSi2). In this example, these first and second screens are arranged in directions that are 90 ° apart. The plate

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8/8 radiant burner 2 is produced from a two-level burner surface, a ceramic tile made of cordiarite.

[0023] A new radiant burner 1 has thus been described as having great flexibility of use and which is capable of reaching temperatures of around 1300 ° C with a considerable increase in the radiation factor of about 10%, compared to existing technology.

[0024] Due to its possible use of very high temperatures, for example 1300 ° C and higher, its high energy efficiency and its long service life, the radiant burner of the present invention is particularly suitable for drying materials on high to continuous sheet rolls. roller speeds. A preferred area of application is the drying of web rolls of paper in motion.

[0025] The new radiant burner comprises a body defining a premix chamber and a combustion chamber. The premix chamber is separated from the combustion chamber by at least one radiant burner plate that has multiple levels of burner surface. The combustion chamber is additionally limited by a first radiant screen. The radiant burner also comprises a second radiant screen in the combustion chamber. The second radiant screen is spaced, however, contiguous to the radiant burner plates, in such a way that this second radiant screen acts as an extended burner surface and also heats said at least one radiant burner plate when in use.

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Claims (6)

1. Radiant burner (1) comprising a body defining a premix chamber and a combustion chamber, said premix chamber being separated from the combustion chamber by at least one radiant burner plate (2) which has multiple levels burning surface, the combustion chamber is further limited by a first radiant screen (4), characterized by the fact that the radiant burner (1) additionally comprises a second radiant screen (3) in the combustion chamber, the second radiant screen being (3) spaced from, but close to and parallel to said at least one radiant burner plate (2) and the distance between said second radiant screen (3) and the highest level of the burning surface of at least one radiant burner plate (2 ) being between 2 and 50 mm, in such a way that the second radiant screen (3) acts as an extended burning surface and also heats said at least one radiant burning plate when in use. 2. Radiant burner (1), according to claim 1, characterized by the fact that the second radiant screen (3) consists of a set of parallel spaced circular bars or square bars. 3. Radiant burner (1) according to claim 1 or 2, characterized by the fact that the first radiant screen (4) consists of a metallic grid or a set of circular bars or square bars spaced parallel. 4. Radiant burner (1) according to any one of claims 1 to 3, characterized in that said at least one radiant burner plate (2) is a ceramic burner plate. 5. Radiant burner (1) according to any one of claims 1 to 4, characterized by the fact that said by the Petition 870200013502, of 01/28/2020, p. 13/20 2/2 minus a radiant burner plate (2) has a difference in height between 2 levels of burning surface from 1 to 20 mm. 6. Radiant burner (1) according to claim 1, characterized in that said combustion chamber additionally comprises at least one other radiant screen. Petition 870200013502, of 01/28/2020, p. 14/20 1/3

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