DE4109841C2 - Control device for gas burners with a fan for supplying combustion air - Google Patents

Description

State of the art

The invention relates to a control device for gas burners a blower for supplying combustion air according to the genus of Main claim.

In a known control device of this type (DE 31 05 862 A1) is the setpoint generator for the gas control valve Throttle orifice arranged in the air volume flow, its opening cross cut is fixed unchangeable. With this arrangement the gas volume flow depends on the delivered air volume flow ge controls, but does not take into account that the density and thus the oxygen mass of the air volume flow depending on its temperature rature and this therefore also adversely affects the quality of combustion can influence. For a constant excess of air when burning The ratio of the combustion air mass to the fuel gas mass must be correct be kept constant. At constant combustion gas temperature and ver changing combustion air temperature succeeds with a fixed throttle orifice, however, because this does not affect the temperature Do not compensate the dependent change in density of the air volume flow can.  

DE 31 25 513 A1 describes a method for operating a Gasification burner / boiler system became known in which from the measured outside air temperature and the boiler flow temperature required burner power is determined and then the Air mass flow and the heating oil mass flow as a function of required burner output in a stoichiometric ratio Burners are fed. Air mass flow deviations from Setpoint are measured using an air mass flow sensor in the Total air flow recorded and fed to the control device as a signal. The Control device initiates a corresponding speed regulation of the Fan supplying combustion air.

DE 27 35 719 A1 is an air volume control for fireplaces became known, in which, based on a predetermined Amount of fuel, the amount of combustion air to be fed to the burner is set by means of a rotary valve. Around Compensating for temperature fluctuations in the combustion air is Rotary vane influenced by a bimetal actuator.  

In another control device of the type mentioned (DE 30 06 683 A1) the combustion air is downstream of the gas Control valve controlling orifice heated in a recuperator. Around a possible heating of the fuel gas by the gas burner Rech port, a metering orifice is located downstream of the gas control valve the fuel gas line installed and the gas pressure behind this measurement orifice fed back to the gas control valve as a correction signal. At this known arrangement, however, despite an increased appara tive effort the temperature of the combustion air upstream of the the orifice provided in the combustion air line also not taken into account, so that here too a constant excess of air different combustion air temperatures not observed can be.

The object of claim 1 is based on the object the air over shot over the entire controlled performance range under yourself active consideration of the combustion air temperature on the op regulate the maximum value. This is easy and without additional installations in the combustion air line possible because of the Setpoint generator for the gas control valve generating a differential pressure Control pressure orifice in the combustion air line is its more effective Cross section is controlled depending on the temperature.

The measures contained in the subclaims are advantageous liable further developments of the arrangement according to the main claim possible.

An advantageous arrangement can be such that with increasing Air mass flow temperature of the cross section increased and thereby the control pressure difference in  Reduced in order to lower the setpoint of the gas control valve becomes. The flow resistance of the tax is also reduced pressure diaphragm, so that this effect of the air masses current compared to the gas mass flow changed in the desired sense.

The effective cross section of the control pressure orifice can advantageously be from be influenced at least one control valve, which with one of the Air mass flow acted upon temperature-sensitive actuator is coupled.

A simple arrangement results when as an actuator for the Control flap a bimetal element is provided. The bimetal element can itself be designed as a control flap and directly on the Be fixed to the cover.

Instead of a bimetal element as an actuator, a can also be used Expansion fluid filled bellows or, for example, a wax expansion element may be provided. In these cases, the measuring location can be removed be arranged far from the actuator. The temperature of the burns Air can also be detected by electronic means on an electromechanical actuator, such as a magnet or motor Act.

In a preferred embodiment of the invention has a tax pressure aperture an uncontrolled main opening and at least one tem Temperature-controlled secondary opening. This is expediently one Control flap directly designed as a bimetallic element net. By appropriate selection of the dimensions of the control openings the control characteristic can meet the requirements of the respective An be adapted to the application. If two or more bi The control characteristic can be metal elements or control flaps can also be adjusted by stepped preloading of the bimetal elements.  

The control device according to the invention can be used in systems or Devices with forced draft burners as well as in devices with atmospheric Gas burners are used to support burning are supplied with a fan.

In the case of a heater without a pneumatic compound controller, the temperature-dependent throttling of the air volume according to the invention current also independent of the temperature of the combustion air pending excess air during combustion can be achieved. Also for the control pressure orifices described above can be used for this purpose be set.

drawing

An embodiment of the invention is shown in the drawing shown in fold and explained in more detail in the following description tert. Show it

Fig. 1 is a schematic overall view of the burner device for a gas-fired water heater,

Fig. 2 is the tenansicht a control pressure orifice of the device of FIG. 1 and

Fig. 3 is a section along the line III-III in Fig. 2.

Description of the embodiment

The burner device has a fan 10 for supplying combustion air, the speed of which is controlled in accordance with the heat requirement. The fan 10 conveys the combustion air into a channel 12 , into which a gas line 16 supplying the fuel gas opens at the point 14 . The channel 12 leads into a distribution chamber 18 of a premix burner 20 , from which the fuel-air mixture passes through a perforated plate 22 to the combustion zone 24 of the premix burner 20 , evenly distributed. The combustion takes place in a combustion chamber 26 which is arranged between the premix burner 20 and a heat exchanger (not shown) for the water to be heated.

A control pressure orifice 30 , which forms a setpoint generator for a gas pressure regulator 32 in the gas line 16, is installed in the channel 12 upstream of the point 14 . The control pressure orifice 30 derives from the air volume flow in the channel 12 a differential pressure which is transmitted via lines 34 , 36 as a control variable to the gas pressure regulator 32 . The control pressure orifice 30 and the gas pressure regulator 32 are, as is known, designed so that there is a constant excess of air in the fuel-air mixture over a predetermined power range of the premix burner 20 for a predetermined normal value of the combustion air temperature.

The control pressure orifice 30 is also formed according to the invention so that it also detects the temperature of the combustion air and the setpoint of the gas pressure regulator 32 depending on temperature so steu ert that there is a constant excess air even at different temperatures of the combustion air. For this purpose, the control pressure orifice 30 is provided in addition to a main opening 38 with an unchangeable opening cross section with a secondary opening 40 , the opening cross section of which can be changed by a temperature-dependent adjustable control flap 42 . The control flap 42 is designed as a metal strip which is attached directly to the control pressure orifice 30 and is thus exposed to the temperature of the combustion air.

The openings 38 , 40 in the control pressure orifice 30 and the control flap 42 are so dimensioned and designed and matched to one another that at all temperatures of the combustion air occurring in practice within a predetermined performance range of the premix burner 20 the ratio of air mass to gas mass approximating is the same, so that the air excess is approximately constant in this power range.

Claims (7)

1.Control device for gas burners with a blower for supplying combustion air and with a setpoint generator for a gas control valve which is arranged downstream of the blower and derives a control variable from the air mass flow and which controls the mixture ratio of fuel gas and combustion air within a predetermined burner output range in order to optimize combustion,
characterized,
that the setpoint device ( 30 ) for the gas control valve ( 32 ) also detects the temperature of the combustion air and controls the setpoint temperature-dependent and
that the setpoint generator of the gas control valve ( 32 ) has a differential pressure-generating control pressure orifice ( 30 ) in a combustion air line ( 12 ) leading to the gas burner ( 20 ), the effective cross section of which is controlled in a temperature-dependent manner, so that the mass fraction of the fuel gas in the total mass of the combustion gas increases with increasing temperature Fuel gas-air mixture decreases and vice versa. 2. Control device according to claim 1,
characterized,
that the effective cross section of the control pressure orifice ( 30 ) is influenced by at least one control flap ( 42 ) which is coupled to a temperature-sensitive actuator acted upon by the air mass flow. 3. Control device according to claim 2,
characterized,
that the temperature sensitive actuator ( 42 ) is a bimetallic element. 4. Control device according to claim 3,
characterized,
that the bimetallic element ( 42 ) itself forms the control flap. 5. Control device according to one of the preceding claims,
characterized,
that the control pressure orifice ( 30 ) has an uncontrolled main opening ( 38 ) and at least one temperature-controlled secondary opening ( 40 ). 6. Control device according to one of the preceding claims,
characterized,
that the gas control valve ( 32 ) is a differential pressure controlled gas pressure regulator. 7. Control device for gas burners with a blower for supplying combustion air, a gas actuator in a fuel gas line leading to the burner, and with actuators controlled by a heat demand signal for the combustion air and fuel gas supply,
characterized,
that an orifice controlling the air mass flow as a function of its temperature is provided downstream of the blower.