DE19515656A1 - Heater and method for controlling a heater - Google Patents

Description

State of the art

The invention is based on a control method a heater according to the type of the main claim, and from a heater to perform the procedure.

It is generally known that when operating heaters, in particular in the partial load range, the dew point of the water vapor from the exhaust gases generated during combustion can be fallen short of, so that condensate fails. Due to the acid generator NO _x , SO₂ and CO₂ contained in the condensate, the exhaust gas routing and the heat transfer of the heaters must be corrosion-resistant.

Heat exchangers are known from EP 0 184 612 B2 provided with a special protective layer and thus against the acid generator contained in the condensate of the exhaust gases are stable. With chimneys as exhaust gas routing offers the possibility of glazing fireclay inner tubes, flexible or rigid stainless steel tubes or too  Insert plastic pipes so the chimneys are insensitive to exhaust gas condensate.

Advantages of the invention

The control method according to the invention with the features of Claim 1 has the advantage that by avoiding Condensate in the exhaust gas routing largely on protective measures can be dispensed with.

By the measures listed in the subclaims advantageous developments of the control method are possible.

Is the set according to the heat requirement Burner output below the determined burner output Setpoint to reach the minimum necessary Exhaust gas temperature, the burner output is reduced to the previous certain burner output setpoint raised. Through this Measure is achieved that common control procedures such. B. weather-based or room-based regulations continue can be used without restriction and only by raising the lower control limit for burner output the avoidance of condensate is achieved.

The dependence of the burner output setpoints on the by a temperature sensor arranged in the exhaust gas path recorded exhaust gas temperatures and from the exhaust gas routing is in advantageously by in a control unit stored characteristic curve determined. This ensures that during operation of the heater at any exhaust gas temperature a necessary according to the avoidance of condensate Burner output setpoint as the lower limit of the Burner capacity control range can be assigned.  

Since the condensate formation of the exhaust gas from the Exhaust gas routing is dependent on different Exhaust gas routing different exhaust gas temperatures necessary. For example, an exhaust gas duct requires a long one Exhaust pipe higher burner output setpoints for Avoiding condensate in the exhaust pipe as an exhaust duct a short exhaust pipe. That is why they are different necessary exhaust gas temperatures due to different Exhaust gas routing different characteristics in the control unit filed. Depending on the exhaust gas routing used the necessary characteristic to avoid condensate on Heater or on the control unit. So that will achieved in an advantageous manner that the invention Control procedures also for heating systems with different Exhaust gas ducts can be used universally and especially when assembling on site to those there Existing exhaust gas routing is very easy to adapt.

It is particularly advantageous if the characteristic curve is represented by a pre-selectable potentiometer connected to the control unit is.

If the exhaust gas temperature falls below the minimum required the burner output is the same as the one selected Characteristic curve determined burner output setpoints corrected. Because these burner output setpoints are larger as the originally set burner output, the corrected burner output in an advantageous manner a shorter on-time and / or longer off-time balanced the burner. This ensures that Heater does not deliver more heating energy than corresponding the heat requirement is necessary.  

One for carrying out the control method according to the invention A particularly suitable heater is characterized by that in the exhaust duct of the heater the temperature sensor is arranged for the control unit.

drawing

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

Fig. 1, schematically represented heater according to the invention for carrying out the control method of the invention and FIG. 2 is a characteristic diagram in a burner power / exhaust temperature diagram.

Description of the embodiment

The heater according to the invention shown schematically in FIG. 1 has a burner 10 . A heat exchanger 16 arranged in a heating water circuit with a flow 12 and a return 14 is subjected to hot combustion gases from the burner 10 . At the heating water circuit, consumers can, for. B. in the form of a heating system with space heaters that emit the heating energy in the form of radiant heat to the environment, or systems for hot water supply, which are combined for example with the heating system.

Above the heat exchanger 16 , an exhaust gas guide 18 is arranged, which leads the exhaust gases generated during combustion to the outside environment. Combustion air can be supplied to the burner 10 via a line 20 arranged coaxially to the exhaust gas duct 18 in the case of the heater operating independently of the ambient air. Depending on the amount of heat demand, the output of the burner 10 is preferably continuously regulated between 60% and 100%.

It is known that when the exhaust gas temperature falls below the dew point, condensate arises in the exhaust gas duct 18 . The exhaust gas temperature is essentially dependent on the flow temperature of the heating water and the burner output set in accordance with the heat requirement, and on the length and type of the exhaust gas duct 18 .

In a first step of the control method according to the invention, the minimum necessary exhaust gas temperature is determined in order to keep the exhaust gas temperature above the dew point in the course of the exhaust gas duct 18 . For this purpose, the minimum necessary exhaust gas temperature was determined in laboratory tests immediately at the entry of the exhaust gases into the exhaust gas duct 18 so that no condensate was formed in the entire exhaust gas duct 18 . The minimum necessary exhaust gas temperature essentially depends on the length and diameter of the exhaust gas guide 18 and on the heat transfer between the exhaust gas guide 18 and the line 20 coaxially arranged for the supply of the combustion air. A long exhaust gas duct 18 requires a higher minimum necessary exhaust gas temperature than a short exhaust gas duct 18 .

In a second step of the control method according to the invention, the exhaust gas temperature is determined with the aid of a temperature sensor 24 arranged above the heat exchanger 16 and at the inlet of the exhaust gas duct 18 and evaluated in a control unit 22 connected to the temperature sensor 24 . If the value of the measured flue gas temperature is below the minimum necessary flue gas temperature, the burner output set according to the heat requirement is increased. The burner output is corrected until the minimum necessary exhaust gas temperature is reached.

To correct or increase the burner output to be regulated based on the measured exhaust gas temperature provided that the burner output depending on the Deviation of the measured exhaust gas temperature to the minimum necessary exhaust gas temperature is corrected. Therefore be at the different flue gas temperatures setpoints as the lower limit for the burner output Control range defined. For example, with one measured exhaust gas temperature of 60 ° C a larger Burner output setpoint necessary to a minimum necessary exhaust gas temperature of, for example, 120 ° C reach than at a currently measured exhaust gas temperature of 90 ° C.

During the heating process, the exhaust gas temperatures detected by the temperature sensor 24 are compared with the minimum necessary exhaust gas temperature. If the measured flue gas temperature is below the minimum necessary flue gas temperature, the actual burner output value set in accordance with the heat requirement is replaced by the burner output setpoint at the corresponding flue gas temperature. It is thereby achieved that the exhaust gas temperature does not fall below the dew point of the exhaust gas during heating and the exhaust gas duct 18 remains free of exhaust gas condensate.

The assignment of the burner output setpoints to the exhaust gas temperatures is stored as a characteristic curve in the control unit 22 . The characteristic curve, as shown in FIG. 2, falls with increasing exhaust gas temperatures, ie with increasing exhaust gas temperature, smaller burner output setpoints are possible as the lower limit of the burner output control range. If the heater is switched on and there is a request for heat at control unit 22 , the control method according to the invention is activated. According to a setpoint for the flow temperature of the heating water determined by the control unit 22 in cooperation with an outside temperature sensor, the heater starts to heat the heating water up to the setpoint. The heating output or burner output is set between 60% and 100% according to the heat requirement. If the measured exhaust gas temperature is below the minimum necessary exhaust gas temperature, the actual burner output value is corrected or increased by the burner output setpoint according to the characteristic curve in the control unit 22 .

Since the condensation of the exhaust gas depends on the exhaust gas guide 18, 18 different minimum exhaust gas temperatures are needed in various exhaust ducts. To the inventive control method used universally even with different exhaust ducts 18, were determined the minimum necessary exhaust gas temperature in laboratory experiments at various exhaust ducts 18th With a low exhaust gas cooling through a short exhaust duct 18 and / or a low heat transfer between exhaust duct 18 and the line 20 for the combustion air supply, smaller minimum exhaust gas temperatures are necessary than with a high exhaust gas cooling through a long exhaust duct 18 and / or high heat transfer between exhaust duct 18 and the line 20 for the combustion air supply. The heat transfer is dependent on the insulation of the area around the line 20 for the combustion air supply. Accordingly, depending on these parameters, different burner output setpoints are necessary as the lower limit for the burner output control range for a condensate-free exhaust gas duct 18 . For this reason, different characteristic curves are stored in the control unit 22 for different minimum necessary exhaust gas temperatures, which are shown in broken lines in FIG. 2.

When reinstalling an entire heating system, e.g. B. in a new house or when installing the heater according to the invention to an existing exhaust duct 18 can be selected depending on the exhaust duct 18 between the characteristics shown in Fig. 2. Characteristic curve 1 is selected as the lower adjustable characteristic curve in heating systems with a short exhaust gas duct 18 and a low value for the heat transfer between the exhaust gas duct 18 and the line 20 for the supply of the combustion air, while characteristic curve 5 as the upper adjustable characteristic curve with a long exhaust duct 18 and one high value for the heat transfer between the exhaust duct 18 and the line 20 is selected for the supply of combustion air. Corresponding fine adjustments with regard to the length of the exhaust gas duct 18 and the heat transfer through the characteristic curves 2, 3 and 4 are possible between these two characteristic curves.

The decision as to which characteristic curve is chosen is then based on experience of the heating installer or on Measurements of the minimum necessary exhaust gas temperature in the Apron.

A potentiometer 26 is used to set the characteristic curve required for exhaust gas routing. The potentiometer 26 connected to the control device is attached to the heater in such a way that the operator or the installer of the heating system can make the appropriate adjustment without having to dismantle the heater. If the burner output is corrected on the basis of the control method according to the invention, if the on-time or the off-time of the burner 10 is maintained, the heating energy supply would be greater than that originally required in accordance with the heat requirement. In order to correct this higher burner power output in such a way that the heating energy supply corresponds to the amount of heat actually required, shorter switch-on phases and / or longer switch-off phases of the burner 10 are set by the control unit 22 . The switching hysteresis in a two-point control can be optimized as already described in an earlier application with the file number P 39 07 955.4-34.

For reasons of component integration and to avoid complex cabling, the exhaust gas temperature at the inlet of the exhaust gas guide 18 is determined, ie the temperature sensor 24 is arranged inside the heater. Of course, it is also possible to use a temperature sensor 24 to determine the exhaust gas temperature at the end of the exhaust gas duct 18 . As a result, the determination of the minimum necessary exhaust gas temperature is independent of the length of the exhaust gas guide 18 . If you attach the temperature sensor 24 ' - to measure the wall temperature - at the end of the inner wall of the exhaust duct 18 , different heat transitions are also taken into account. Both points taken together, that is, the arrangement of the temperature sensor 24 'at the end of the exhaust duct 18 and the attachment to the inner wall of the exhaust duct 18 lead to the result that only one characteristic curve for determining the burner output setpoints is necessary as the lower limit for the burner output control range; but taking into account a larger cabling effort.

The application of the standard procedure is not restricted on a heater according to the embodiment, but can be used wherever with one conventional control method to an exhaust gas duct connected heater is operated.

Claims (9)

1. A method for regulating a gas or oil-operated heating device in particular with a burner, with an exhaust gas duct and with a control device by means of which the output of the heating device can be regulated as a function of the heat requirement, characterized by the following process steps:
Determining the minimum exhaust gas temperature at a defined location in the heating system, which is necessary to keep the exhaust gas temperature above the dew point in the course of the exhaust gas duct ( 18 ),
Measuring the exhaust gas temperature,
Increase the burner output if the measured flue gas temperature is below the minimum necessary flue gas temperature. 2. The method according to claim 1 with the further steps:
Determination of burner output setpoints for reaching the minimum necessary exhaust gas temperature with different deviations of the measured exhaust gas temperature from the minimum necessary exhaust gas temperature,
Use the determined burner output setpoints as the lower limit for the burner output control range. 3. The method according to claim 1 or 2, characterized in that the burner output setpoints are stored in connection with the associated exhaust gas temperatures as a characteristic curve (s) in the control unit ( 22 ). 4. The method according to claim 3, characterized in that different characteristic curves are stored in the control unit ( 22 ) for different necessary exhaust gas temperatures. 5. The method according to claim 4, characterized in that the characteristic curve required for the respective exhaust gas routing ( 18 ) on the heater or on the control device ( 22 ) is adjustable. 6. The method according to claim 5, characterized in that the different characteristic curves are adjustable by a potentiometer ( 26 ) connected to the control device ( 22 ). 7. The method according to any one of the preceding claims, characterized in that the corrected burner output is compensated for by a shorter on-time and / or longer off-time of the burner ( 10 ). 8. Heater with a gas or oil-powered burner, with an exhaust gas duct and with a control unit by which the performance of the heater can be regulated depending on the heat requirement, for carrying out the method according to any one of the preceding claims, characterized in that in the exhaust gas duct ( 18 ) of the heater at least one temperature sensor ( 24, 24 ') for the control device ( 22 ) is arranged. 9. A heater according to claim 8, characterized by a with the control device ( 22 ) connected potentiometer ( 26 ) with which different characteristics for the minimum necessary exhaust gas temperature can be selected ( Fig. 2).