DE19605918A1 - Atmospheric burner - Google Patents

Description

The invention relates to an atmospheric burner for gaseous fuel mixtures according to the characteristics in Preamble of claim 1.

The burner is part of a heating system, a boiler sels or another technical device on which the gaseous fuel enters the combustion chamber, ent is ignited and burned.

An atmospheric burner is a so-called surface burner without fan. The boiler and burner form usually a unit. There are versions without a front mixture of gas and air as well as with partial or full constant premixing.  

An economic burner efficiency is ensured by a appropriate coordination and design of the burner compo nents such as B. combustion chamber and burner rods under Be consideration of the fuel type reached.

Another essential requirement is that the speci pollutant emissions, especially nitrogen oxides and carbon monoxide under the respective law written values.

Firing measures such as combustion with a favorable air ratio, flame cooling or lowering the combustion chamber load have already made great strides in nitrogen oxide (NO _x ) formation. Nevertheless, an improvement or further development of pollutant-reducing technologies is fundamentally desirable.

From this point of view, as well as to save energy, a Development of burner designs with higher We degrees in partial load operation. Is demand here that a full load level and at least part load level is available. In this way, Operating phases in which only a lower performance may exist, fuel saved and according to the Pollutant emissions can be reduced.

A known solution realizes a full load / part load operation by separating the combustion chamber wall into two separate chambers is shared. Depending on the power requirement, a Kam always be switched off. The partition is required thus pollutant emissions, especially coal monoxide emissions, not increasing inadmissibly.  

This version is complex and economical Aspects disadvantageous, for example, two fires automatic circuit breakers and two pilot burners for operation are required. Furthermore, is also subject to complete separation required wall in the focal chamber of a high thermal load. It must therefore consist of thermally highly resilient materials.

The invention is based on the prior art Task based on a burner for full load and part load operation in terms of structure and design and to make it more economical, in particular from an environmental point of view, the specific Pollutant emissions below the legally required Values remain.

According to the invention, this object is achieved in those listed in the characterizing part of claim 1 Characteristics.

Advantageous refinements and developments of the basic idea according to the invention form the subject of dependent claims 2 to 4.

The heart of the invention is the measure between the Burner rods to incorporate an auxiliary burner rod which has a fuel mixture supply, the part load operation can be activated and deactivated at full load is feasible.

In this way a burner is available with one Full load level, which all economic and techni advantages of a low-pollutant gas-powered fuel ners. In addition, one or more parts load levels realizable.  

By connecting the auxiliary burner rod, the Combustion chamber thermally divided, under guarantee stung that the specific pollutant emissions, esp especially the nitrogen oxide formation, among those legally required written values lie without an inadmissible Increase in carbon monoxide emissions occurs.

Technically, there is the advantage that only one Pilot burner and only one automatic burner control required is.

The auxiliary burner rod can in terms of its diameter sers and its performance compared to the main burners nerstäben be made much smaller. The length of the auxiliary burner rod is corresponding to the length of the Main burner rods and the combustion chamber matched.

The height of the auxiliary burner rod is between two two main burner rods arranged so that it through the flames of the main burner rods do not thermally is partially charged. A touch with the main burns Nerstäben should be avoided.

The connection and disconnection of the auxiliary burner rod or one Some of the main burner rods are made, for example, electro magnetically through a relay. For this purpose, the Corresponding fuel elements in tegrated, linked by a circuit, in Ab dependence on full load operation or partial load operation can be controlled according to the drive phase.

In a particularly advantageous embodiment, each because several burner rods with respect to the fuel mixed feed grouped in groups. Each of these Groups is a distributor with appropriate nozzles for assigned the fuel mixture injection.  

The fuel mixture is fed to the auxiliary burner via a bypass that goes from one of the distributors. In by pass is a controllable switching element, at for example a valve. This is so in a tax and Circuitry that integrates the fuel mixture feed to the auxiliary burner rod is opened automatically, if the adjacent group of main burner rods is switched off.

At a partial load level of 50%, for example two groups of main burner rods are provided. Between the auxiliary burner rod is located there. At the transition from full load operation to partial load operation becomes one Group of main burner sticks switched off. Automatically The auxiliary burner rod is controlled for tax purposes switches. This achieves the same effect that otherwise only through a complete partition in the Combustion chamber could be realized.

Even if it is basically conceivable, the auxiliary burner Its shutdown is also to operate at full load device makes sense in this operating state, since it a higher nitrogen oxide than the main burners push generated.

A further developing the general idea of the invention Embodiment provides below the auxiliary burner to arrange a partition, which the auxiliary burner rod not touched. This can be a simple one Trade sheet metal. This measure supports the invention according to the desired effect of thermal division. In particular Especially in partial load operation, air can circulate below the main burner rods between each Groups to be avoided.  

Even if basically each in the burner according to the invention Type of burner rod can be used shown that as the main burner oval rod burner with a integrated venturi are particularly well suited. So an optimal mixture of gas and air is achieved with a complete combustion and correspondingly low Emissions. The distance between the Burner rods can be chosen very small.

With a combination of oval main burners and round Auxiliary burners work the main burners superstoichiologically tric and the auxiliary burner substoichiometric. That be indicates that the auxiliary burners work primarily with the led air from the premixed fuel / air mixture mix while the auxiliary burner needs secondary air, which he pulls from the switched off part of the boiler.

Depending on the position of the auxiliary brake (s) and / or the number of auxiliary burners can be a boiler operate in varying stages.

The invention is based on in the drawing technically generalized execution described examples. Show it:

Figure 1 shows a burner according to the invention in plan view.

Fig. 2 is a vertical cross section through the Dar position of FIG. 1 along the line II-II, and

Fig. 3 shows another embodiment.

In Figs. 1 and 2, 1 denotes a burner of a heating boiler system for gaseous fuel mixtures designated net.

In a combustion chamber 2 burner rods 3-8 are arranged with a cross-sectional oval configuration. These extend in a horizontal plane HE and are essentially parallel to each other. The burner rods 3-8 are attached to a burner plate 9 on the head side.

With regard to the fuel mixture supply, the burner rods 3-5 are combined into a group 10 and the burner rods 6-8 into a group 11 . A distributor 12 , 13 is assigned to each group 10 , 11 . The distributors 12 , 13 have a gas connection 14 , 15 and are equipped with nozzles 16 and 17 for the fuel mixture injection.

Between the burner rods 5 and 6 , an auxiliary burner rod 18 is incorporated. This has a fuel mixture supply 19 , which can be activated in part-load operation and deactivated in full-load operation.

The fuel mixture supply 19 comprises a bypass 20 which is connected to the distributor 12 . A valve 21 is integrated in the bypass 20 . The valve 21 is re-controlled switchable and opens the fuel mixture feed 19 automatically when the fuel mixture feed to group 11 is switched off. The fuel mixture then flows through a nozzle 22 into the auxiliary burner rod 18 and burns when it enters the combustion chamber 2 .

A circuit 23 with a relay 24 for controlling full-load and part-load operation is shown in dash-dotted lines in FIG. 1. 25 with a group 11 assigned switching element is designated.

Furthermore, a partition 26 can be seen in FIG. 2, which is arranged below the auxiliary burner 18 . The partition wall 26 extends over the depth of the combustion chamber 2 . With its foot 27 , the partition 26 is attached to the Bo 28 of the combustion chamber 2 .

Even if the height H 1 of the partition wall in the illustration in FIG. 2 speaks approximately half the combustion chamber height H 2, it is in principle possible to design the partition wall 26 larger or smaller. It is important that the auxiliary burner rod 18 is arranged at a height H _x at which it does not suffer any disadvantageous thermal stress due to the flames of the burner rods 5 or 6 .

The burner 1 realizes a full load stage if they are operated in groups 10 , 11 . The auxiliary burner rod 18 is then switched off in order to avoid the pollutant emission of the auxiliary burner rod 18 .

In addition, a partial load level is implemented. Group 11 is switched off. The fuel mixture feed to the auxiliary burner rod 18 is then automatically opened in a sequential manner. By connecting the auxiliary burner rod it can be ensured that the nitrogen oxide formation is below the legally prescribed values in part-load operation, and without an inadmissible increase in carbon monoxide formation.

Fig. 3 shows a detail of a burner with a total of eight main burner rods 29 a- 29 h. The positions of auxiliary burner rods 30 a- 30 d are indicated as an example for the demonstration of four possible partial load stages.

The arrangement of the auxiliary burner rods 30 a- 30 d, the thermal splitting of the combustion chamber 31 can be varied. A boiler can be built with a full load level of 100% output and a partial load level of 80%, 67%, 33% or 20%, for example.

A partial load level of 80% results, for example, if the auxiliary burner 30 d is installed. During operation, the main burner rod 29 h can then be switched off and the auxiliary burner rod 30 d activated. The other main burner rods 29 a-29 g are useful in the partial load level of 80% in operation.

If a partial load level of 20% is desired, the auxiliary burner rod would be installed at 30 a. In partial load operation, the main burner rod 29 a and the auxiliary burner rod 30 a would be operated, while all the other main burner rods 29 b- 29 h were switched off.

In this way, a boiler that can be regulated in two power levels is implemented. An increase in pollutant emissions in part-load operation is avoided. A heavy load on the burner surface 32 , which can otherwise be found in down-regulated burners, since the combustion takes place closer to the burner surface, can be prevented with the embodiment according to the invention.

Basically, it is also within the scope of the invention bar to realize a burner in which several auxiliary burner rods are provided so that several parts load levels are available.

Reference list

1 burner
2 combustion chamber
3 burner rod
4 burner rod
5 burner rod
6 burner rod
7 burner rod
8 burner rod
9 burner plate
10 group of burner rods
11 group of burner rods
12 distributors
13 distributors
14 gas connection
15 gas connection
16 nozzle
17 nozzle
18 auxiliary burner rod
19 fuel mixture supply from 18
20 bypass
21 valve
22 nozzle
23 circuit
24 relays
25 switching element
26 partition
27 feet from 26
28 floor of 2
29 burner rod
29 a burner rod
29 b burner rod
29 c burner rod
29 d burner rod
29 e burner rod
29 f burner rod
29 g burner stick
29 h burner rod
30 auxiliary burner rod
30 a auxiliary burner rod
30 b auxiliary burner rod
30 c auxiliary burner rod
30 d auxiliary burner rod
31 combustion chamber
32 burner surface
HE horizontal plane
H₁ height of 26
H₂ amount of 2
H _x height of 18

Claims (4)

1. Atmospheric burner for gaseous fuel mixtures with at least two arranged in a combustion chamber ( 2 ), essentially in a horizontal plane (HE) parallel to each other extending burner rods ( 3-8 ; 29 a- 29 h), through which the combustion mixture of substances is led into the combustion chamber ( 2 , 31 ) and burned there, optionally all burner rods ( 3-8 ; 29 a- 29 h) at full load or individual burner rods ( 3-5 ; 29 a- 29 h) at part load can be opened, characterized in that between the burner rods ( 5 , 6 ; 29 a, 29 b; 29 c, 29 d; 29 e, 29 f; 29 g, 29 h) at least one auxiliary burner rod ( 18 ; 30 a- 30 d ) is integrated with a fuel mixture supply ( 19 ) which can be activated in part-load operation and deactivated in full-load operation. 2. Burner according to claim 1, characterized in that a combustion chamber ( 2 ) partially separating wall ( 26 ) is arranged below the auxiliary burner ( 18 ). 3. Burner according to claim 1 or 2, characterized in that the fuel mixture supply ( 19 ) to the auxiliary burner ( 18 ; 30 a- 30 d) is relay-controlled logically linked depending on the full load or part load operation. 4. Burner according to one of claims 1 to 3, characterized in that each Weil several burner rods ( 3-5 ; 6-8 ) are grouped together with respect to the fuel mixture supply and each group ( 10 , 11 ) a distributor ( 12 , 13 ) is assigned, the fuel mixture supply ( 19 ) to the auxiliary burner ( 18 ) via a bypass ( 20 ) provided with a switching element ( 21 ) from one of the distributors ( 12 ).