DE4014693A1 - Burner for combustion chamber of a tunnel furnace - uses coanda effect to control supply of combustion air - Google Patents

Abstract

A tunnel furnace, of the type used in the ceramic industry has a burner (4) mounted in the wall (2) of the combustion chamber (3). The burner is supplied with fuel through a pipe (5) which is fitted with a control valve (6). Combustion air (15) is drawn into the amplifying element (15) which is operated by means of a gas which is delivered through a pipe (12). A Coanda effect is produced by the gas issuing from the pipe (12) so that a controlled quantity of air is drawn through the amplifying element. USE - Combustion chamber for tunnel furnace.

Description

The invention relates to a device as well a method for feeding a gaseous over a flowing with a switching element provided Fuel and an oxygen carrier, preferably Air in the combustion chamber of a ceramic tunnel furnace Industry.

In firing technology, in certain areas, in which a linear adjustment characteristic of the burner and / or A high level of turbulence in the combustion chamber is required, pulse firings prevailed. This applies particularly to tunnels ovens of the ceramic industry in which the operating temperature of the combustion chamber regularly above the ignition temperature and therefore no ignition and monitoring facilities are required. Here it turned out to be Proven to be useful with short pulses in sizes order from milliseconds to a few seconds To fire the stove.

As part of the energy optimization of the tunnel kilns however, the free oxygen in the combustion chamber decreases, so that on the one hand the usual impulse addition of Fuel without air or with uncontrolled air volumes  no longer meets the requirements and on the other hand the achievable by the injector effect of the fuel gas Mixture with the furnace atmosphere is not large enough.

Smaller amounts of gas with a high switching frequency can be used by means of known actuators, which The required air volume can vary depending on the operating situation up to a factor of 20; and for such amounts currents, however, there are no actuators that the required high switching speed and also the have the necessary wear resistance.

The object of the invention is therefore a device and a method for supplying a gaseous over an inflow provided with a switching element Fuel and an oxygen carrier, preferably Air in the combustion chamber of a ceramic tunnel furnace Industry by means of which it is very simple Way is possible, the volume flow of the oxygen carrier to regulate according to the respective requirements and thus individually adjust the burner output. In addition, the gaseous in the pressure of the supplied Mechanical energy contained in the fuel if possible without losses in the speed of the fuel gases and thus to be converted into turbulence in the combustion chamber to achieve an even temperature distribution. The the construction effort required for this should be kept low, nevertheless, reliable control of the fuel is said to be mixtures to be easy to do.

According to the invention, the device by means of this is possible, characterized in that for control The introduction of the oxygen carrier into the combustion chamber associated burner a fluidic amplifier element  is connected upstream to the one with a switching element provided LPG-carrying line is connected.

It is also expedient to use the burner as to train fluidic amplifier element, which to the The combustion chamber of the tunnel kiln must be connected, or the Burner to connect a fluidic amplifier element, the via a line to the LPG line of the pre switched fluidic amplifier element or to a provided with a switching element propellant gas line is closed.

The fluidic amplifier elements can be used as Coanda or Venturi propellant gas nozzles, and which in the propellant gas lines or fluidic amplifier elements Switching elements used can each be triggered by an impulse as controllable electromagnetic switching valve ge be formed.

Furthermore, it is appropriate to the flow-through cross-section of the leading gaseous fuel Line, for example, axially adjustable arranged, in a recess of the line taking sheathing engaging cone adjustable to design.

To the length of the flame of the burner using the propellant To be able to adjust the gas jet, the jet of the Fuel gas deflected by the jet of propellant be, depending on the arrangement with increasing pressure of the Propellant a shorter or a longer burner flame can be generated.  

The process of feeding a gaseous over a a switching element provided line incoming combustion substance and an oxygen carrier, preferably air, in the combustion chamber of a tunnel kiln in the ceramic industry, is characterized in that the supply of oxygen carrier to a burner assigned to the combustion chamber a fluidic upstream of this, preferably as Coanda or Venturi propellant nozzle element is made and that for controlled introduction tion of the oxygen carrier in the burner to the amplifier element ment via a line provided with a switching element in the pulsed propellant gas is supplied.

Furthermore, a fluidic Ver stronger element trained burner gases from the combustion chamber of the tunnel kiln mixed with the fuel / air mixture or it can be connected to the burner fluidic amplifier element propellant the fuel / Air mixture are supplied.

The mixing ratio between the gaseous fuel and the oxygen carrier can be changed the pressure of the supplied propellant and / or the free flow-through outlet cross-section of the amplifier element mentes can also be set in the lines of the gaseous fuel and the propellant gas switching elements delayed and / or with a difference adjustable switching duration can be controlled.

The length of the flame of the burner can be adjusted using the Pressure of the fuel gas or the propellant gas set , the length setting depending on the temperature distribution in the combustion chamber preferably with the help of a temperature difference measurement and adjusting the flame length by changing the Pressure of the propellant gas is made in such a way that the fuel gas jet is deflected by a propellant gas jet becomes.  

By means of the device designed according to the invention and the method according to the invention, it is not difficult possible the quantity to be fed to a burner of the oxygen carrier, even with its pulse Introduction to control exactly, so that the mix ver Reliability between this and the fuel is to be observed. Namely, the oxygen carrier is over a fluidic amplifier element fed to the burner, that is activated with the help of a propellant gas via a quantity control of the propellant gas without further ado also regulate the volume flow of the oxygen carrier. And the quantity control of the propellant gas flow can be done without Difficulties with the help of switching elements in the form accomplished by electromagnetic switching valves will.

Because the flow of fuel gas with the switching valve open and constant admission pressure constant during a pulse remains, the mixing ratio can also be simple Way about the pressure of the propellant, which is preferred also consists of air, or across the gap width the Coanda or Venturi nozzles are set reproducibly will. The gap width expediently becomes indi vidual setting of the individual burner used, the propellant pressure, on the other hand, to adjust the mixture Control zone, which can consist of several burners.

Different durations of fuel gas and air supply Leadership can be easily offset by tax impulses are compensated. Likewise, one can be found under Different duty cycles of air and fuel gas Use the mixture setting. This is especially true for the Generation of reduction atmospheres applicable in the with the help of a control unit to a stoichiometric  Burning phase an adjustable phase is added in that only gas flows. Analog can be used for oxidizing operation an air phase to the stoichiometric burning phase be connected. There are therefore several possible options given the atmospheric settings.

The burner turns out to be a fluidic amplifier element formed or this is such an element nachge switches, so the mechanical contained in the gas pressure Energy with almost no loss in speed Fuel gases and thus converted into turbulence in the combustion chamber and there can be as much free as possible Oxygen from the furnace atmosphere into the combustion chamber be involved. This will make the intense Mixing the fuel with the combustion air further increased.

Furthermore, the exit speed can Range of the mixture of propellant and aspirated Fresh air or furnace atmosphere can be influenced. This applies to both fluidic amplifier elements that are single generate a free jet as well as for venturi and Coanda nozzles. So both gases can be adjusted the distribution of fire. This can happen with Measurement of at least two temperatures in the direction the beam axis by automatically changing the focal or propellant pressure. So the procedure fits for a single burner or a burner group automatically the range of the burner to changing Operating conditions.

Since a change in the fuel gas pressure is the caloric Burner performance affected, i.e. the temperature impaired control, the LPG pressure appears as the more suitable control variable for adjusting the burner Range.  

In many cases there is a relatively high fuel gas pressure available so that with additional impulse by the LPG the range will often be too great. To over the mechanical energy of the fuel gas is the greatest possible To achieve a mixing effect, it is impractical to burn reduce gas pressure. Rather, a distraction one or more fuel gas jets by a preferred the same number of propellant jets be, depending on the arrangement of the beam angle Increasing the LPG pressure reduces or enlarges can affect the range.

In the drawing, an embodiment of the according device designed for feeding a gaseous fuel and an oxygen portrayed in the combustion chamber of a tunnel kiln, which is explained in detail below. Here shows, each in a schematic representation:

Fig. 1 is a burner of the tunnel kiln with pre switched off fluidic amplifier element,

FIG. 2 is designed as a fluidic amplifier element burner of FIG. 1 with an adjustable outlet opening of the fuel gas,

Fig. 3 shows the apparatus of FIG. 1 with an additional downstream the burner fluidic amplifier element,

Fig. 4, the burner of FIG. 1, the fuel gas jet is deflected by the propellant jet to shorten the burner flame and

Fig. 5, the burner of FIG. 1, the fuel and propellant jet flame to extend the burner are brought together.

The devices shown in FIGS. 1, 2 and 3 and each designated 1 serve for the controlled introduction of a gaseous fuel and an oxygen carrier, for example air, into the combustion chamber 3 of a tunnel furnace 1 of the ceramic industry, which via a burner 4 leads to the combustion chamber 3 are fed. A fuel supply line 5 is connected to the burner 4 , in which a switching element 6 in the form of an electromagnetic switching valve is inserted. With pulsed supply of fuel, the switching element 6 clocked switching pulses 7 are supplied.

In order to be able to regulate the air volume flow depending on the duration of a combustion process and to optimize it, the burner 4 is preceded by a fluidic amplifier element 11 which is activated by means of propellant gas. For this purpose, a propellant gas line 12 is connected to the fluidic amplifier element 11 , in which a switching element 13 is also used in the form of an electromagnetic switching valve, the clocked switching pulses 14 can be supplied. The propellant gas introduced into the fluidic switching element 11 amplifies the air flow 15 flowing through it to a considerable extent and can thus be regulated in a simple manner with the aid of the propellant gas flow. In addition, the air / gas mixture 16 emerging from the burner 4 is intensively mixed.

In the embodiment of FIG. 2, the burner 4 'also as a fluidic amplifier element in the form of a venturi nozzle 27 is formed, which is seen with openings 28 ver. Through the openings 28 , a smoke gas stream 29 can be sucked from the combustion chamber 3 of the tunnel furnace 2 and supplied to the gas / air mixture, a large amount of free oxygen from the furnace atmosphere can be included in the combustion process in this way.

Furthermore, in this embodiment, the possibility of an individual adjustment of the power of the burner 4 'is given. For this purpose, on the end 21 of the gas supply line 5 equipped with a cone 23 , a casing 22 provided with a recess 24 is placed, in the recess 24 of which the cone 23 engages. And since the casing 22 is adjustable by means of a thread 26 , the free exit cross section resulting from the gap 25 between the casing 22 and the cone 23 can be adjusted to the respective operating conditions and the mechanical energy contained in the fuel gas can be converted into speed, so that a large turbulence in the combustion chamber 3 can be generated by the exiting gas / air mixture 16 '.

According to FIG. 3, the burner 4 is followed by a further fluidic amplifier element 31 , to which propellant gas can also be supplied via a line 32 connected to the propellant gas line 12 . However, it is also possible, as shown in dash-dotted lines, to assign the amplifier element 31 to a separate propellant gas line 33 , in which a switching element 34 which can be switched in cycles is inserted. In this way, a gas stream 29 can also be supplied from the combustion chamber 3 to the air / gas mixture 16 ''.

To set the flame length of the burner 4 , as shown in FIGS . 4 and 5, the fuel gas jet can be deflected by the propellant gas jet, a shorter or a longer burner flame being able to be generated depending on the arrangement with increasing pressure of the propellant gas.

According to FIG. 4, the fuel gas steel emerging from line 5 'is deflected by the propellant gas jet flowing out of line 12 such that the length of the flame of the burner 4 is shortened, as shown in FIG. 5, however, the two from lines 5 ' and 12 '' emerging propellant gas and fuel gas jets deflected so that the length of the flame of the burner 4 is extended.

Claims (15)

1. Device for supplying a gaseous fuel flowing in via a line provided with a switching element and an oxygen carrier, preferably air, into the combustion chamber of a tunnel furnace in the ceramic industry, characterized in that a burner ( 3 ) assigned to the combustion chamber ( 3 ) is used for the controlled introduction of the oxygen carrier. 4 ) a fluidic amplifier element ( 11 ) is connected upstream, to which a gas-conducting line ( 12 ) provided with a switching element ( 13 ) is connected. 2. Device according to claim 1, characterized in that the burner ( 4 ) is designed as a fluidic amplifier element ( 27 ) which is connected to the combustion chamber ( 2 ) of the tunnel furnace ( 1 ). 3. Apparatus according to claim 1 or 2, characterized in that the burner ( 4 ) is followed by a fluidic amplifier element ( 31 ) which via a line ( 32 ) to the propellant gas line ( 12 ) of the upstream fluidic amplifier element ( 11 ) or a propellant gas line ( 33 ) provided with a switching element ( 34 ) is connected. 4. The device according to one or more of claims 1 to 3, characterized in that the fluidic amplifier elements ( 11 ; 27 ; 31 ) are designed as Coanda or Venturi propellant gas nozzles. 5. The device according to one or more of claims 1 to 4, characterized in that in the propellant gas lines ( 12 ; 33 ) of the fluidic amplifier elements ( 11 ; 31 ) used switching elements ( 13 ; 34 ) each by a pulsed triggerable electromagnetic electromagnetic Switch valve are formed. 6. The device according to one or more of claims 1 to 5, characterized in that the flow-through outlet cross section of the line carrying the gaseous fuel ( 5 ; 21 ), for example by means of an axially adjustable angeord Neten, in a recess ( 24 ) of the line ( 22 ) receiving cone ( 22 ) engaging cone ( 23 ), is adjustable. 7. The device according to one or more of claims 1 to 6, characterized in that for adjusting the length of the flame of the burner ( 4 ) the jet of the fuel gas (line 5 ') by the jet of the propellant gas (line 12 ') is deflectable, depending on the arrangement with a rising pressure of the propellant gas, a shorter or a longer burner flame can be generated. 8. A method for the controlled supply of a gaseous fuel flowing through a line provided with a switching element and an oxygen carrier, preferably air, into the combustion chamber of a tunnel furnace in the ceramic industry, characterized in that the supply of the oxygen carrier to a burner ( 3 ) assigned to the combustion chamber ( 4 ) upstream of this fluidic, preferably designed as a Coanda or Venturi propellant nozzle amplifier element ( 11 ) and that for the controlled introduction of the oxygen carrier into the burner ( 4 ) the amplifier element ( 11 ) via a member with a switching element ( 13 ) provided line ( 12 ) pulse gas is supplied. 9. The method according to claim 8, characterized in that via a fluidic amplifier element ( 27 ) designed burner ( 4 ') gases from the combustion chamber ( 3 ) of the tunnel furnace ( 2 ) are mixed with the fuel / air mixture. 10. The method according to claim 8, characterized in that propellant gas is supplied to the fuel / air mixture via a burner ( 4 ) connected downstream fluidic amplifier element ( 31 ). 11. The method according to one or more of claims 8 to 10, characterized in that the mixing ratio between the gaseous fuel and the oxygen carrier is adjusted by changing the pressure of the supplied propellant gas and / or the free flowable outlet cross-section of the amplifier element ( 11 ). 12. The method according to one or more of claims 8 to 11, characterized in that the switching elements ( 6 ; 13 ; 34 ) used in the lines ( 5 ; 12 ; 33 ) of the gaseous fuel and the propellant gas are staggered in time and / or with under different adjustable switching duration can be controlled. 13. The method according to one or more of claims 7 to 11, characterized in that the length of the flame of the burner ( 4 ) is adjusted with the aid of the pressure of the fuel gas or the propellant gas. 14. The method according to claim 12, characterized in that the setting of the length of the flame of the burner ( 4 ) as a function of the temperature distribution in the combustion chamber ( 3 ), preferably with the aid of a temperature difference measurement. 15. The method according to claim 12 or 13, characterized in that the adjustment of the length of the flame of the burner ( 4 ) is carried out by changing the pressure of the propellant gas in such a way that the fuel gas jet is deflected by a propellant gas jet such that depending on the arrangement a shorter or a longer burner flame is generated with increasing pressure of the propellant gas.