DE10037841A1 - Heating furnace chamber of drying and combustion furnaces for ceramic materials comprises dividing gaseous fuel into two partial streams of different pressures, and forming flames from partial streams - Google Patents

Abstract

Heating the furnace chamber of an industrial furnace to which a gaseous fuel and an oxygen carrier gas are introduced comprises dividing the gaseous fuel into two partial streams, one being at a higher pressure than the other; feeding the oxygen carrier gas to the fuel partial stream under the lower pressure to form a first flame; and feeding the fuel partial stream having the higher pressure to the furnace chamber to form a second flame ignited by the first flame and extending further into the chamber than the first flame. An Independent claim is also included for a burner for heating the furnace chamber comprising a burner head (2) arranged in a housing (1), an air line (3) formed upstream of the head, a gas line (4) leading to the head and having gas nozzles (S), a throttle site (6) provided in the gas line upstream of the gas nozzles, and a gas lance (7) connected to the gas line upstream of the throttle site and extending through the head up to the height of the gas nozzles.

Description

The invention relates to a method and a burner for heating a furnace space of an industrial furnace, the Industrial furnace a gaseous fuel and oxygen Carrier gas, preferably air, are supplied.

The combustion of gaseous fuels, in particular that of natural gas, is low in pollutants and therefore for reasons of Environmental protection very cheap. You can also choose an optimal one Achieve combustion with maximum energy yield.

For reasons of high product quality one is strives to achieve an optimal, d. H. a defined stay the same de, if necessary even temperature and heat distribution in the Ensure furnace space. The object of the invention is to create a particularly advantageous possibility for this.

To achieve this object, the method described at the outset is characterized according to the invention in that

• - That the gaseous fuel in two streams un one of which is under a higher pressure stands as the other,
• - That the oxygen carrier gas the lower Pressurized partial flow of the fuel is supplied and forms a first flame with it and
• - That the partial flow under higher pressure such that it is introduced into the furnace chamber of the industrial furnace forms a second flame ignited by the first flame, which extends farther than the first flame into the furnace chamber extends.

The main advantage of the invention is that the formation of two independently controllable Flames an adaptation of the heating to different Furnace chamber geometries and geometries of the material to be used The variability of the furnace space heating is almost unlimited and also allows adaptation to change  conditions. Above all, flame lengths can be of 5 m and more. For high-speed burners for example, the range is limited to 3 to 4 m.

An essential area of application of the invention is Ceiling heating of drying and kilns for ceramic Feedstock. The furnace rooms are relatively high and can be one Height of about 5 m to reach large quantities of fired goods take.

Especially in underdeveloped regions you have such stoves heated with oil; that one down from the ceiling dripped. This was already an improvement over solid fuels obtained only in the furnace were thrown. The dripping oil warmed up and evaporated before it caught fire. Through decades Adjustment of the location of the fuel addition and the respective the amount of fuel in product, stock and flow ratio In the furnace room, a certain optimization of the Temperature distribution.

The invention offers the possibility of oil heating to switch to gas heating and thus to a pollutant to pass poorer combustion. At the same time, a ver Improved product quality because the heat distribution optimal in the furnace space to the respective conditions can be adjusted. Even the floor areas of the furnace room are reliably heated.

In a development of the invention it is proposed that the partial flow of fuel under higher pressure downstream of that point in the furnace chamber of the industrial furnace is introduced, from which the oxygen carrier gas and the partial flow under lower pressure first flame forms. The second flame thus puts one in the continuation and extension of the furnace chamber penetrating first flame. The distance between the two flames However, it must not become too large, otherwise a reliable one Ignition cannot be guaranteed.  

According to a further advantageous feature, the two partial flows of the fuel parallel to each other preferably fed coaxially to the industrial furnace. You can the two flames are formed side by side, however again while maintaining the ignition distance. With coaxial Training the flames there is also the possibility that the second flame penetrates the first flame.

The configuration of the two flames can be done via the The pressure of the two partial flows of the fuel vary. As It has proven favorable that the one partial flow of the Fuel under a pressure of 1 to 80 mbar and the other partial flow under a pressure of more than 200 mbar stands.

The air ratio, based on the total throughput of the gaseous fuel, is preferably below 1 posed. For complete combustion, the im Accessed oxygen in the furnace chamber. It is particularly advantageous, the air ratio, based on the lower pressure partial flow of the fuel to set a maximum of 1. So the second flame works only with the oxygen in the furnace.

In a further development of the invention, it is also proposed conditions that the oxygen carrier gas is under low pressure standing partial flow of the fuel muzzle-mixing leads.

The proportion of the part under lower pressure current is advantageously at most 80% of the total fuel. So at least 20% of the fuel is available the second flame.

The ignition and monitoring of the combustion is limited preferably on the first flame, which in turn ignites the second flame.

The burner according to the invention is provided to achieve the object

• - a housing,  
• A burner head arranged in the housing,
• - Formed upstream of the burner head from the housing air duct,
• - A gas line leading to the burner head, which opens the height of the burner head is provided with gas nozzles,
• - one in the gas line upstream of the gas nozzles that choke point and
• - A gas lance, the upstream of the throttle point with the Gas line is connected and through the burner head by extending at least to the level of the gas nozzles.

By the interaction of the throttle and the gas lance ensures that it emerges from the gas lance partial flow of fuel under a higher pressure stands as the partial flow emerging from the gas nozzles. the accordingly, the gas nozzles generate a short flame, weh A long flame emerges from the gas lance. The Flam men form coaxially with each other, the distance between the Gas lance mouth the degree of embedding of the second flame determined in the first flame.

In a development of the invention it is proposed that the housing downstream of the burner head a combustion chamber bil det and that the gas lance at least until the outlet extends end of the combustion chamber.

The burner head is preferably provided with an ignition and Provide flame monitoring device.

The invention is based on a preferred Embodiment in connection with the accompanying Drawing explained in more detail. The drawing shows in:

Fig. 1 shows an axial section through the front part of a burner according to the invention.

The burner of Fig. 1 comprises a housing 1 which includes a burner head 2. Upstream of the burner head 2 , the housing 1 forms an air line 3 .

A gas line 4 leads to the burner head 2 and forms gas nozzles 5 at the level of the burner head. Upstream of the gas nozzles 5 , a throttle point 6 is seen in the gas line 4 .

A gas lance 7 is connected to the gas line 4 , namely upstream of the throttle point 6 . The gas lance 7 extends through the burner head 2 and opens downstream of the mouth of a combustion chamber 8 , which is formed by the housing 1 downstream of the burner head 2 .

In operation, air and gas get to the burner head 2 , namely through the air line 3 or through the gas line 4 . The gas nozzles 5 generate a first flame in the combustion chamber 8 . A second flame is formed at the mouth of the gas lance 7 . Because of the throttle point 6 , the gas flowing to the gas nozzles 5 is at a lower pressure than the gas emerging from the gas lance 7 . The second flame emerging from the gas lance 7 thus forms an extension of the first flame emerging from the gas nozzles 5 .

A device, not shown, ensures the ignition and flame monitoring of the first flame emerging from the gas nozzles 5 . This in turn ensures the ignition of the second flame emerging from the gas lance 7 . The distance by which the gas lance 7 protrudes from the mouth of the Brennkam mer 8 is chosen so that a reliable ignition is guaranteed.

The burner can be adapted to different circumstances, on the one hand via the throttle point 6 , which determines the pressure ratio of the two partial flows of the gas, and on the other hand via the length and diameter of the gas lance 7 .

For the rest, there are substantial modification possibilities within the scope of the invention. Thus, an adjustable gas divider can be provided, which allows a change in the pressure ratio between the two partial flows of the gas during operation. The gas lance can also be displaceable in the axial direction. It can also be ensured that the quantitative ratio between the two partial flows of the gas can be changed. The combustion chamber is only indicated schematically in FIG. 1. It can be shaped differently, both in terms of its length and in terms of its diameter. Diameter changes over the length are also conceivable.

The concept of gaseous fuel is in the present to interpret the trap broadly. The invention can also be with vaporous and possibly even with dusty burning realize fabric. Preferred as an oxygen carrier gas wise air in question. Operation with oxygen is the same possible, also also an operation with air, with Oxygen is enriched.

Claims (12)

1. A method for heating a furnace space of an induction furnace, the industrial furnace being supplied with a gaseous fuel and an oxygen carrier gas,
characterized by
that the gaseous fuel is divided into two partial flows, one of which is under a higher pressure than the other,
that the oxygen carrier gas is fed to the lower-pressure partial flow of the fuel and forms a first flame with it, and
that the partial pressure under higher pressure is introduced into the furnace chamber of the industrial furnace in such a way that it forms a second flame ignited by the first flame and extends further than the first flame into the furnace chamber. 2. The method according to claim 1, characterized in that that the partial pressure of the combustion under higher pressure substance downstream of that point in the furnace chamber of the Indu Strieofens is introduced, which results from the oxygen carrier gas and the lower pressure part srrom forms the first flame. 3. The method according to claim 1 or 2, characterized records that the two partial flows of the fuel in parallel to each other, preferably coaxially fed to the industrial furnace become. 4. The method according to any one of claims 1 to 3, characterized characterized in that a partial flow of fuel under a pressure of 1 to 80 mbar and the other partial flow under a pressure of more than 200 mbar.   5. The method according to any one of claims 1 to 4, characterized characterized that the air ratio, based on the total throughput of the gaseous fuel to below 1 is posed. 6. The method according to claim 5, characterized in that the air ratio, based on that under lower pressure standing partial flow of fuel, to a maximum of 1 is posed. 7. The method according to any one of claims 1 to 6, characterized characterized in that the oxygen carrier gas under low higher pressure partial flow of the fuel muzzle is fed mixing. 8. The method according to any one of claims 1 to 7, characterized characterized in that the proportion of under lower pressure partial flow at most 80% of the total fuel accounts. 9. The method according to any one of claims 1 to 8, characterized characterized in that the oxygen carrier gas and lower-pressure partial flow of fuel formed first flame is ignited and monitored. 10. Burner for heating the furnace space of an industrial furnace
a housing ( 1 ),
a burner head ( 2 ) arranged in the housing ( 1 ),
an air line ( 3 ) formed upstream of the burner head ( 2 ) by the housing ( 1 ),
one to the burner head ( 2 ) leading gas line ( 4 ), which is seen at the level of the burner head ( 2 ) with gas nozzles (S),
a throttle point ( 6 ) provided in the gas line ( 4 ) upstream of the gas nozzles ( 5 ) and
a gas lance ( 7 ) which is connected upstream of the throttle point ( 6 ) to the gas line ( 4 ) and extends through the burner head ( 2 ) at least to the level of the gas nozzles ( 5 ). 11. Burner according to claim 10, characterized in that the housing ( 1 ) downstream of the burner head ( 2 ) forms a combustion chamber ( 8 ) and that the gas lance ( 7 ) extends at least to the outlet end of the combustion chamber ( 8 ). 12. Burner according to claim 10 or 11, characterized in that the burner head ( 2 ) is provided with an ignition and flame monitoring device.