The present invention relates to radiant burners comprising a radiant burner plate and a screen.
Radiant burners comprising a radiant burner plate and a screen are known e.g. from U.S. Pat. No. 4,799,879 or EP0539279. The screen together with the radiant burner plate provides the radiative output of the burner, which averages at levels around 50% efficiency. In the past the radiative output of the burners has been increased by modification of the radiant burner plate from a radiant burner plate with rows of through holes or perforations serving to channel the mixture of air and combustion agent from the rear of the plate to the radiating face, to a radiant burner plate wherein the through holes or perforations are arranged in what is nowadays called honeycomb pattern as described in e.g. U.S. Pat. No. 4,569,657 or U.S. Pat. No. 4,799,879. This or similar modifications of the radiant burner plate increased the temperature level and consequently also the radiative output of the burner. On the other hand, these honeycomb-like patterns are creating local overheating of the burner plate on the places where the flames are, and also cause poor temperature uniformity and relative low average burner surface temperature and thus lower energy efficiency. These local high temperatures define therefore also the limitation of the use of such through hole or perforation patterns, and also define the limitation on the amount of radiation energy which can be obtained with such systems.
Another way of achieving higher radiative output was proposed in e.g. U.S. Pat. No. 3,847,536 which uses two radiative screens above the radiant burner plate. Also this modification of the radiant burner caused local overheating of the radiant burner plates in the middle of the radiant burner, which urged the skilled person to lower inputs which resulted in lower (local) temperatures of the radiant burner plate for prolonging the life time of the radiant burner.
However, still further enhanced efficiency of the radiant burners is desired.
An aspect of the claimed invention provides a radiant burner which comprises a body defining a premixing chamber and a combustion chamber. The premixing chamber is separated from the combustion chamber by at least one radiant burner plate which has multiple levels of burner surface. The combustion chamber is further limited by a first radiant screen. The radiant burner further comprises a second radiant screen in the combustion chamber. The second radiant screen is spaced from, but near and parallel to the radiant burner plate(s), such that this second radiant screen acts as an extended burner surface and also heats up said at least one radiant burner plates by back radiation when in use. In a preferred embodiment, the second radiant screen is an arrangement of parallel spaced round rods or square bars. In a preferred embodiment, first and second radiant screens are produced from highly heat resistant materials such as ceramics, especially aluminium or zirconium oxide, aluminium titanate, silicon oxide, corundum or mullite, silicon carbide, silicon nitride or metal infiltrated ceramics, such as silicon-infiltrated silicon carbide. Alternatively, the radiant screens can also be fabricated from heat-resistant materials of other nature such as e.g. materials which contain more than 50% by weight of a metal silicide, such as molybdenum disilicide (MoSi2) or tungsten disilicide (WSi2). In another preferred embodiment, the radiant screens are fabricated from highly heat resistant steel grades, such as high level stainless steel grades like Kanthal APM or APMT, different grades of FeCrAl alloy designed for high temperature corrosion, Chrome/Nickel steel grades like Avesta 253 MA, 153 MA, Inconel 601, Incoloy 800HT, Incoloy MA956.
The radiant burner plate is preferably made of a ceramic material with high temperature resistance, and excellent mechanical and thermodynamic properties such as e.g. cordierite or zirconia; partially stabilised zirconia (PSZ), alumina, silicon carbides or other high level technical ceramics. Height difference in between two levels of burner surface of the radiant burner plate is preferably from 1 to 20 mm. More preferably, from 1 to 10 mm. Even more preferably, from 2 to 7 mm. Most preferably 5 mm.
The radiant burner plate has multiple levels of burner surfaces. In a preferred embodiment, these multiple levels are arranged in rows and are alternating per one row of through holes/perforations on the radiant burner plate. An example of such burner plate can be found in
However, although radiant burner plates are used which as such have a lower radiative output, it was surprisingly observed that by the use of such a second radiant screen near the radiant burner plates, the radiative output of the radiant burner plates can be increased without leading to local overheating of the burner plates, as this would result in early failure of the radiant burner plates. This might be explained, without pretending to be scientifically correct, by the fact that the back radiation of the second radiant screen on the radiant multilevel burner plates is the highest on the highest level of the burner surface as this is closest to the second radiant screen. This highest level thereby also heats up more than the lower levels of the burner surface, which are at a bigger distance from this second radiant screen. As these lower levels in the burner surface of the radiant burner plates were already at higher temperatures by the effect of the flames heating up the surface surrounding the cavity wherein the perforations open, the overall effect of the present invention is that the different levels in the burner surface of the radiant burner plates are at the same temperature when in use. Stated otherwise, a greater temperature uniformity of the burner surface of the radiant burner plate is attained. The person skilled in the art will understand that this greater temperature uniformity combined with the plurality of radiant screens results in a significant higher energy efficiency of the complete radiant burner. In a preferred embodiment, the distance between the second radiant screen and the highest level of burner surface of the at least one radiant burner plates is between 3 and 50 mm. More preferably, the distance between the second radiant screen and highest level of the radiant burner plate is between 5 and 30 mm, even more preferably between 10 and 25 mm, most preferably between 15 and 20 mm. In a preferred embodiment, the second radiant screen is positioned such that the second radiant screen follows the direction of the rows of the highest level of burner surface of the radiant burner plate.
The first radiant screen is preferably a metal grid. In another preferred embodiment, the first radiant screen is an arrangement of parallel spaced round rods or square bars. More preferably, the first and second radiant screens are made of an arrangement of parallel spaced round rods or square bars. In a further preferred embodiment, 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 in shifted angles with respect to one another. More preferably, the first and second radiant screens are at a 90° angle.
A further observed advantage of the present invention is a lower level of emissions of byproducts of combustion, such as Nitrogen Oxides or Carbon Monoxide, which is probably due to the second radiant screen which acts as an extended burner surface and provides a more complete combustion of the gas-air mixture.
Another aspect of the claimed invention provides a radiant burner with at least one further radiant screen in the combustion chamber.
Example embodiments of the invention are described hereinafter with reference to the accompanying drawings in which
Example embodiments of the present invention will now be described with reference to
Thus there has been described a new radiant burner 1 possessing great flexibility of use and which is capable of reaching temperatures of about 1300° C. with a considerable radiation factor increase of about 10% compared to existing technology.
Because of their possible use at very high temperatures e.g. 1300° C. and higher, their high energy efficiency and their long service life, the radiant burner of the present invention are particularly suitable for drying web materials at high web speeds. One preferred area of application is the drying of moving paper webs.
The new improved radiant burner comprises a body defining a premixing chamber and a combustion chamber. The premixing chamber is separated from the combustion chamber by at least one radiant burner plate which has multiple levels of burner surface. The combustion chamber is further limited by a first radiant screen. The radiant burner further comprises a second radiant screen in the combustion chamber.
The second radiant screen is spaced from, but near the radiant burner plate(s), such that this second radiant screen acts as an extended burner surface and also heats up said at least one radiant burner plate when in use.
Number | Date | Country | Kind |
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08159919.3 | Jul 2008 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/058429 | 7/3/2009 | WO | 00 | 1/5/2011 |