EP0908670A1 - Method and device for operating an atmospheric gas burner - Google Patents

Abstract

An injector system for the mixture of gas and air is formed by a central nozzle and at least one peripheral nozzle in order to be able to break up the gas stream into several smaller streams in order to alter the air/gas ratio. The gas burner operating at atmospheric pressure is supplied with a homogeneous mixture of fuel and combustion air, where a gas stream dependent on the burner performance is injected into a mixer tube (14). This gas stream is divided into several smaller gas streams in order to change air intake characteristics, the creation of the smaller gas streams being dependent on the burner performance and/or type of gas being burnt. An Independent claim is also included for the above gas burner, containing an injector system consisting of a central nozzle (10) and at least one further peripheral nozzle (12a).

Description

State of the art

The invention is based on a method and one Device for operating an atmospheric gas burner. In known gas burners of this type, the Injection of the fuel through a nozzle with constant Exit cross-section that is at a fixed distance and fixed position is arranged to the mixing tube opening of the gas burner. The Air intake of the premixing system depends on Exit pulse of the driving fuel jet, the losses occurring with increasing fuel throughput increase disproportionately and thereby the fuel-air ratio over the modulation range of the gas burner is not constant. To this undesirable effect encounter, is proposed in DE-OS 44 07 758 by Movable flow obstacles prevent air from entering Mixing tube in the lower load range or reduce the nozzle slidable to store their distance from the To change the mixing tube opening. These measures require the Use of moving parts that are dirty and dirty are sensitive to interference and the arrangement is not insignificantly more expensive.

Advantages of the invention

The inventive method and the inventive Device allow a simple way Variation of the air-fuel ratio leading to Compensation for changes in the air-fuel ratio over the modulation range and / or to adjust the Gas burner on different fuels without changing the nozzle can be used. Furthermore, the arrangement according to the invention by a simple structure, that works without moving parts.

The features of the subclaims are advantageous Embodiments of the method and the arrangement possible.

The distribution of the total flow of fuel gas into one Centrally aligned with respect to the mixing tube opening Part gas flow and at least one other non-central aligned partial gas flow can be adjusted via the required burner output take place by Keeping the air-fuel ratio constant above that entire modulation range of the gas burner a central Nozzle is provided for a maximum required Combustion air intake at nominal load of the Gas burner is designed while an outer nozzle is provided is the minimum required combustion air intake is designed in the partial load range of the gas burner. The gas supply can take place in such a way that with decreasing Burner load an increasingly larger proportion of the supplied fuel passes through the outer nozzle while the partial gas flow emerging through the central nozzle is reduced. Because the relationship between burner performance and air ratio λ especially with atmospheric burners low pollution tendency is fixed, the Distribution of the partial gas flows in a characteristic curve or Characteristic curve set stored in the control unit of the heater become.

When changing the gas type, there is usually one Change in air ratio λ and burner load. In The division of the partial gas streams can be advantageous on the central nozzle and on the outer nozzle like this take place that the required burner output essentially is operated via the central gas flow, while to adjust or to keep the Fuel gas-air ratio of the non-centrally aligned Part gas flow or the outer nozzle is used, with a Gas type change during combustion by a additional sensor is detected. So that can over Control unit of a combustion control system Total gas flow to that consisting of the two types of nozzles Injector system so that the original Air ratio λ and thus also the original burner load to be kept.

In the modulating operation of an atmospheric gas burner with full premixing, this takes as the load decreases Air ratio too, because this increases the injector efficiency improved because of the reduced mass throughput. Further it is known that the injector effect remains the same Mass flow rate of the fuel with increasing size of the Outlet opening of the nozzle decreases. Starting from these Facts and based on the task, the Fuel-air ratio over the modulation range of the Keep gas burner constant or depending on the load curve to vary in certain ways, it is proposed that the outlet cross section of the central nozzle is smaller than the outlet cross section of the outer nozzle or the sum of the Outlet cross sections of the outer nozzle.

So that the fuel jet emerging from the outer nozzle Air access to the mixing tube opening is not hindered suggested that the outlet opening of the outer nozzle is axially set back with respect to the central nozzle.

In a first advantageous embodiment, the The outer nozzle is arranged as concentric with the central nozzle Ring nozzle formed while a second Embodiment the outer nozzle from radial to the central nozzle arranged individual nozzles.

So that the two gas paths to the central nozzle and External nozzle can be regulated separately, are two Control valves provided that two together Safety valves are upstream. In an alternative Embodiment come two combined Safety / control valves are used, which in this case only a common safety valve upstream are needed.

The presence of two separately controllable Fuel supplies to the injector system can be advantageous also for a temporary enrichment of the fuel-air mixture be used when the gas burner is cold started.

drawing

Two embodiments of the invention are in the Drawing shown schematically and in the following Description explained in more detail. Figure 1a shows that Injector system of the gas burner with the nozzle system in the Section and the entrance area of the mixing tube in Side view, Fig. 1b shows an alternative embodiment of a Gas supply and Fig. 1c an alternative embodiment of the Nozzle system.

Description of the embodiments

In a first embodiment, the injector system a central nozzle 10 with a circular cross-section, from a Ring nozzle 12a is surrounded concentrically. The ring nozzle 12a has a larger outlet cross section than the central nozzle 10 and is opposite this in the flow direction of the Axially set fuel.

The central nozzle 10 is made from a gas manifold 18 fed, which the fuel via a control valve 20th is fed. The ring nozzle 12a is with a Gas manifold 22 connected into which the fuel a control valve 24 arrives. The control valves 20 and 24 that are charged with the same gas, are on a Control unit 26 of a combustion control device connected, which depends on the fuel gas supply on the load status of the gas burner and / or the one used Gas type distributed to the two nozzles 10 and 12a.

The two control valves 20, 24, as shown in FIG. together upstream two safety valves 28, 30 which i.a. when the gas burner is switched off Take over the tightness control. In Fig. 1b is a second alternative embodiment of the gas supply shown. Under Maintaining double security are the two Valves for the gas distribution pipes 18, 22 in this case as combined safety / control valves 32, 34 are formed, which together is preceded by a safety valve 36.

With an appropriate design of the outlet cross section of the central nozzle 10 and their distance from the mixing tube 14 and at a corresponding design of the entrance area 16 of the mixing tube 14 are via the control unit 26 Partial gas flows to the central nozzle 10 and to the ring nozzle 12a divided so that the desired air ratio λ results, which thus over the entire modulation range of the Gas burner can be kept constant. Becomes For example, natural gas is used as a fuel Nominal load operation of the gas burner only with the central nozzle 10 Fuel gas is applied while the control valve 24 for the Ring nozzle 12a is closed. With decreasing Burner loading takes place via the control unit 26 Combustion control device a disproportionate Reduction of the mass flow through the central nozzle 10 and a continuous increase in the proportion through the ring nozzle 12a. Because of their larger outlet cross-section the air intake deteriorates, causing the basic increase in air ratio at low load counteracted and the desired fuel-air ratio is kept constant. Such control of Gas supply can be in a characteristic curve or family of curves in the Control unit 26 are stored.

So that air-number changes also due to one Gas type change can be regulated in one second method for controlling the gas nozzles 10, 12a provided that the burner output in both the partial and Full load range through the gas supply via the central Nozzle 10 is determined. The gas supply to the ring nozzle 12a takes place depending on the during combustion detected air number λ, which e.g. through one with the control unit 26 connected λ probe 38 arranged in the exhaust gas path can be determined. The system is designed so that combustion even when the gas burner is operating at full load with a fuel gas with a high Wobbe number and thus high Combustion air requirement (e.g. natural gas H) overstoichiometric takes place so that when changing the gas type on Fuel gas with lower combustion air requirements (e.g. natural gas L) resulting increase in air ratio by an additional substoichiometric gas mixture supply via the ring nozzle 12a is reduced to an optimal air ratio. If the burner's load changes, it can also an optimal air ratio value is set via the ring nozzle 12a become. With that gfs. linked target-actual deviations in the Burner performance can be corrected by the Flow temperature of the heating water or the room temperature of the rooms to be heated as a manipulated variable for the Burner capacity can be used.

In the second embodiment of the device according to FIG 1c are used as an outer nozzle instead of the ring nozzle 12a Individual nozzles arranged radially to the central nozzle 10 or Single holes 12b used. The sum of the Exit cross sections of the individual nozzles 12b is also larger than the outlet cross section of the central nozzle 10. Furthermore, the individual nozzles 12b are like that Embodiment according to Figure 1a compared to the central Nozzle 10 axially in the direction of flow of the fuel set back. The distribution of the gas flows can on the same way as the first Embodiment.

Claims (13)

Method of operating an atmospheric gas burner for a heater, especially with full premix from Fuel and combustion air, one of which is under load of the gas burner dependent gas flow for generating a Fuel gas-air mixture is injected into a mixing tube, characterized in that to change the Air intake characteristic of the gas flow in several Partial gas flows is divided depending on Load state of the gas burner and / or depending on the Gas type can be determined. A method according to claim 1, characterized in that the distribution of the total flow of fuel gas into one Centrally aligned with respect to the mixing tube opening Part gas flow and at least one other non-central aligned partial gas flow takes place. A method according to claim 1 or 2, characterized in that that to set a desired fuel-air ratio with increasing burner load of the centrally aligned partial gas flow is increased while the non-central partial gas flow is reduced, and vice versa. A method according to claim 3, characterized in that the division of the partial gas flows in a characteristic curve or Family of curves are stored. A method according to claim 1 or 2, characterized in that that for setting a predetermined fuel-air ratio the central gas flow with increasing burner load, and vice versa, while the non-central partial gas flow in Dependence on that recorded during the combustion Air number λ is determined. Atmospheric gas burner for a heater especially with full premixing of fuel and air, whose injector system with means to influence the Intake characteristics and thus the fuel-air ratio is provided, characterized in that the injector system is a combined arrangement of one central nozzle (10) and at least one second outer nozzle (12a, 12b). Gas burner according to claim 6, characterized in that the outlet cross section of the central nozzle (10) is smaller than the exit cross section or the sum of the Outlet cross sections of the outer nozzle (12a, 12b). Gas burner according to claim 6 or 7, characterized characterized in that the outlet opening of the outer nozzle (12a, 12b) axially with respect to the central nozzle (10) is set back. Gas burner according to one of claims 6 to 8, characterized characterized in that the outer nozzle as a concentric to the Central nozzle (10) arranged ring nozzle (12a) is formed is. Gas burner according to one of claims 6 to 8, characterized characterized in that the outer nozzle from radial to the central Nozzle (10) arranged individual nozzles (12b). Gas burner according to one of claims 6 to 10, characterized characterized in that the control of the gas supply for central nozzle (10) and the outer nozzle (12) via two Control valves (20, 24), two of which together Safety valves (28, 30) are connected upstream. Gas burner according to one of claims 6 to 10, characterized characterized in that the control of the gas supply for central nozzle (10) and the outer nozzle (12) via two Combined safety / control valves (32, 34), which together a safety valve (36) is connected upstream. Gas burner according to one of claims 6 to 10, characterized characterized in that the distribution of fuel supply the central nozzle (10) and one on the outer nozzle (12a, 12b) temporary enrichment of the fuel-air mixture Cold start of the gas burner.

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