1. Field of the Invention
The present invention relates to a method for igniting a burner, especially a burner that is used in industrial furnaces.
2. Description of the Related Art
There exist burners of various kinds, having in common that a gaseous fuel and a gaseous oxidant are introduced near or at a distance from each other into a combustion zone within a furnace. The gases are usually introduced through lances in a burner head.
For safety reasons, a burner needs to be monitored with respect to whether a flame is present during operation. Such monitoring is usually carried out by the use of a UV sensor, which is a sensor that is sensitive to and that detects ultraviolet radiation. The sensor is usually mounted in the burner in such a way that the sensor can detect a part of an existing flame.
Ignition of the fuel/oxidant mixture normally takes place by means of a spark plug at the outlet or outlets of the burner, to emit a spark for igniting the fuel/oxidant mixture. An electrode is commonly mounted inside a ceramic tube that extends up to the surface of the burner head that faces the furnace interior space. The ceramic tube has a relatively low strength and is therefore easily broken. The tube can also crack because of thermal stresses.
In addition to the problems noted above relative to the ceramic tube, it has developed that it is relatively difficult to obtain a correct electric arc. During furnace operation the spark plug often gets clogged, and as a result it cannot give off a sufficient spark for igniting the fuel/oxidant mixture.
Also, it is usual practice that the spark ignites a pilot flame, which in turn ignites the main flame. That arrangement increases the cost.
The present invention solves these problems by providing another way of igniting a burner.
Thus, the present invention relates to a method for use when burning a fuel together with an oxidant in an industrial furnace. The fuel and the oxidant are supplied to a burner head, and the flame is monitored by a light detector for ultraviolet light, or for detecting other light. At least one fuel supply conduit and at least one oxidant supply conduit are provided, each of which includes an outlet opening that opens on the side of the burner head that faces the furnace interior. A laser is provided to emit a laser beam onto a contact point on the burner head adjacent the fuel and oxidant conduit outlets. The laser beam heats the contact point to a temperature that is above the ignition temperature of the fuel and the oxidant, and when the burner has ignited the light detector emits a signal to a control circuit that turns off the laser beam.
The structure, operation, and advantages of the present invention will become further apparent upon consideration of the following description, taken in conjunction with the accompanying drawing in which:
In accordance with the invention, there is provided at least one fuel supply conduit 3 and at least one oxidant supply conduit 4, each of which opens at a respective outlet at the outer surface 5 of the burner head that faces the furnace interior.
It is evident that the fuel and oxidant conduits can be configured and positioned in other ways, and that they can number more than two.
Light detector 2 can be provided adjacent the inlet of the fuel supply conduit 3, or adjacent the inlet of the oxidant supply conduit 4. Conveniently, the detector is provided at the upstream end of the associated conduit, and is positioned so that ultraviolet light that passes into the conduit from the flame impinges upon the detector. The detector is connected to a control circuit 6 that includes a detector circuit, by which the existence of a flame at the burner outlet is detected. If a flame is not detected by the light detector the supply of fuel and oxidant to the burner head is interrupted.
For use with the present invention, oxidants with an O2 content of over 85 percent by weight are preferred. The fuel can be natural gas, propane, butane, liquefied petroleum gas, light fuel oil, etc.
The oxidant is introduced into the combustion space within the furnace through one or several nozzles, which can be formed as straight tubes, or as Laval or venturi nozzles.
In accordance with the invention, a laser, such as laser 7, 9, or 11, is positioned to emit a laser beam on a point on the burner head near the conduit outlets, and is made to heat that point to a temperature that exceeds the ignition temperature of the fuel/oxidant mixture. When the burner 1 has been ignited and a flame is detected by the light detector 2, the detector emits a signal to the control circuit 6, after which the control circuit turns off the laser 7.
The laser is a suitable, known laser with a sufficient output power to heat the point on the burner head to a temperature greater than 700-800° C. within a short period of time, such as within a few seconds. That condition will result in a very reliable ignition. When the fuel and oxidant mixture ignites, the detector 2 detects a flame, indicating ignition, and emits a signal to the control circuit 6 at the moment of ignition, at which time the control circuit immediately turns off the laser. Even if the laser has a sufficient power to quickly heat the point on the burner head to the above-mentioned temperatures, it will not melt the material at any point on the burner head because of the rapid extinction of the beam from the laser.
Instead of impinging on a point on the burner head, the laser beam can impinge on, for example, a protrusion of suitable metal (not shown), that projects from the burner head. The important factor is that the point that the laser beam impinges upon is adjacent to or located along the path of transportation of the fuel/oxidant mixture.
In accordance with a preferred embodiment, a laser beam impinges upon a point on or adjacent to the side of the burner head facing the furnace interior space and between the outlets of conduits 3, 4.
In accordance with another preferred embodiment, a laser beam is directed at an angle slightly less than a right angle with respect to the longitudinal axis of the burner 1, as is illustrated by laser beam 8 emitted by laser 9 in
In accordance with an alternative embodiment, a laser beam is directed toward the outer surface of the burner head that faces the furnace interior space, and in a direction coinciding substantially with the longitudinal axis of the burner 1, as illustrated by laser beam 10 emitted by laser 11 in
In accordance with an alternative embodiment a laser beam 12 is emitted from laser 7 in such a way that it extends within one of the oxidant supply conduits 4, and in a direction toward the outer surface 5 of the burner head 1 that faces the furnace interior space. In that arrangement the laser beam 12 impinges on the inner surface of the conduit 4 adjacent to its outlet opening at burner head outer surface 5, as is also illustrated in
Different embodiments have been described above. The laser can be of various known models, and it can be directed toward any suitable point on the burner head. The laser can be integrated into the burner head or can be separate therefrom.
Although particular embodiments of the present invention have been illustrated and described, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit of the present invention. It is therefore intended to encompass within the appended claims all such changes and modifications that fall within the scope of the present invention.
Number | Date | Country | Kind |
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0600220 | Feb 2006 | SE | national |
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