DE19607854A1 - 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 exchanger of the heaters must be corrosion-resistant. Heat exchangers are known from EP 0 184 612 B2 which are provided with a special protective layer and are therefore resistant to the acid formers contained in the condensate of the exhaust gases.

Furthermore, they are working according to the saturation process Known dew point hygrometer with which such parameters as Air humidity and dew point temperature can be determined can.  

Advantages of the invention

The control method according to the invention with the features of Claim 1 has the advantage that by avoiding or early detection of condensate in the exhaust system Protective measures can largely be dispensed with. The The method is universally applicable to heaters because it regardless of variable sizes such as type of Fuel, air pressure, air ratio λ etc. the elimination of Water vapor recorded directly.

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

The dew point sensitive designed as a dew point hygrometer Element is placed under the with the help of a Peltier element Ambient temperature cooled down, so that first a Condensation on the dew point hygrometer. The limit, i.e. H. the exhaust gas temperature at which water vapor Depends on the dew point hygrometer, depending on the Ambient conditions can be set. With that are in Advantageous warnings at a relative Humidity below 100% possible in the heater.

If the dew point sensitive element condenses, this advantageously sends a signal to the control unit to increase the burner output and thus to increase the Exhaust gas temperature given.

The u. a. for condensation in the exhaust system crucial exhaust gas temperature correlates with the Flow temperature of the heating water. Raising the Burner output is advantageously carried out in  Dependence on the temperature of the heating water, since anyway the flow temperature of Heaters is adjustable.

Burner output dependent on the flow temperature Setpoints are stored as a characteristic in a control unit. This ensures that during operation of the heater each flow temperature one corresponding to the safe one Avoidance of condensate necessary burner output is set.

Because these burner output setpoints are larger than that the originally set burner output becomes 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.

Another advantageous measure in the case of condensation on the Dew point sensitive element consists in an increase in the Air ratio λ, which leads to a lowering of the dew point. This also causes condensation in the exhaust system prevented.

The air ratio λ is advantageously controlled by a fan, that also serve to supply the combustion air can, regulated. The speed control of the Fan also via the control unit.

A third advantageous measure in the case of condensation on the Dew point sensitive element consists in switching a Bypasses to or in the heat exchanger. By reducing the heat transfer surface is advantageously the  Exhaust gas temperature raised and thus condensation prevented.

A fourth advantageous measure in the case of condensation on the dew point sensitive element consists of an additional element Ventilation of the exhaust gas duct by a fan that also serves to supply the combustion air. Here is in the burner breaks by the fan running on condensate in the exhaust duct evaporates.

One for carrying out the control method according to the invention A particularly suitable heater is characterized by that at least one dew point sensitive element for the Control unit arranged in the exhaust duct of the heater is. This means that water vapor is eliminated of variable sizes such as type of fuel, Air pressure, air number etc. can be recorded directly.

The dew point sensitive element is advantageously on End of the exhaust gas duct at the condensate formation most vulnerable point. This ensures that there is no condensate in the entire exhaust system.

The dew point sensitive element is advantageously as Dew point hygrometer trained. One in the dew point hygrometer Integrated pelletizing element is used for cooling, the Condensation detected capacitively by a stray field capacitor is. By cooling the dew point hygrometer Warnings for a relative humidity below 100% in Heater possible.

On or in the heat exchanger is an advantageous Bypass line with a bypass valve arranged in  Dependence on the signal of the dew point sensitive element can be opened or closed.

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 curve in a burner power / flow temperature diagram.

Description of the embodiment

The heater shown schematically in FIG. 1 has a burner 10 . A heat exchanger 15 arranged in a heating water circuit with a flow 12 and a return 14 is subjected to hot combustion gases from the burner 10 . The heat exchanger 15 is designed as a coil, which is shown in dashed lines in FIG. 1. 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. A bypass line 17 provided with a bypass valve 16 is arranged parallel to part of the coil of the heat exchanger 15 .

Above the heat exchanger 15, an exhaust gas guide 18 is arranged, which discharges the exhaust gases produced during the combustion to the outside environment with the aid of a fan 19 arranged in the exhaust gas guide 18 . Combustion air is fed 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. In the flow direction behind an indicated masonry 20 , a connection head 24 is provided at the end of the coaxial combustion air exhaust gas duct, which enables the exhaust gas to be discharged and the combustion air to be fed separately. Depending on the amount of heat demand, the output of the burner 10 is continuously regulated, preferably between 60% and 100%, via a control unit 26 . In addition, the flow temperature of the heating water is detected by a temperature sensor 27 , which can also be set depending on the heat requirement. The amount of air required for optimal combustion is adjusted via the fan 19 arranged on the exhaust gas side and connected to the control unit 26 .

It is known that when the exhaust gas temperature falls below the dew point, condensate arises in the exhaust gas duct 18 . In order to prevent condensation in the entire exhaust duct 18 or to signal it early, a dew point hygrometer 28 is arranged at the end of the inner wall of the exhaust duct 18 , at the level of the masonry 22 . The structure and mode of operation of a dew point hygrometer are known from the literature (eg SENSOR report 3/1995, pp. 30, 31); wherein a stray field condenser detects condensing water vapor by changing the stray field capacitance.

A pelleting element integrated in the dew point hygrometer 28 lowers the temperature of the sensor by a few Kelvin compared to the surroundings. The limit for condensation can thus be set using the Peltier element. Taking certain ambient conditions into account (e.g. heat transfer between the exhaust gas duct 18 and the line 20 ), a measure that prevents the formation of condensate can thus already take place at a relative air humidity of, for example, 90% or 95%.

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, as well as on the length and type of the exhaust gas duct 18 . A measure preventing the formation of condensate in the exhaust gas duct 18 therefore consists in increasing the burner output set in accordance with the heat requirement, a signal being sent to the control unit 26 to increase the burner output in the event of condensation by the dew point hygrometer 28 . If the end of the condensation is signaled by the dew point hygrometer 28 , the burner output is regulated again depending on the heat requirement (e.g. weather-dependent).

Since the exhaust gas temperature increases with the flow temperature of the heating water, the burner output is increased as a function of the flow temperature of the heating water detected by the sensor 27 . Therefore, burner output setpoints are determined for reaching the flue gas temperature required for condensate-free operation at different flow temperatures. If condensation is detected on the dew point hygrometer 28 , the actual burner output value set according to the heat requirement is replaced by the burner output setpoint at the corresponding flow temperature.

The assignment of the burner output setpoints to the flow temperatures is stored as a characteristic in the control unit 26 . The characteristic curve, as shown in FIG. 2, decreases with increasing flow temperatures, ie smaller burner output setpoints are possible with increasing flow temperature. If the heater is switched on and there is a request for heat at the control unit 26 , the control method is activated. According to a setpoint for the flow temperature of the heating water determined by the control unit 26 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 condensation of the dew point hygrometer is signaled, the actual burner output value is corrected or raised by the burner output setpoint in accordance with the characteristic curve in control unit 26 .

If the burner output is corrected on the basis of the control method according to the invention, the heating energy supply would be greater than the originally required according to the heat requirement if the burner 10 was kept on or off. 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 device 26 . 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.

A second measure preventing the formation of condensate in the exhaust gas duct 18 consists in an increase in the air ratio λ which leads to a lowering of the dew point, since the percentage of water vapor in the fuel gas / air mixture decreases. The increase in the air ratio λ is achieved by a corresponding increase in the speed of the fan 19 arranged on the exhaust gas side. Complete combustion and compliance with statutory limits for pollutant emissions (CO, NO _x ) are criteria for an upper limit for the increase in the air ratio λ.

A third measure preventing the formation of condensate in the exhaust gas duct 18 consists in partially bridging the coil of the heat exchanger 15 by means of a bypass line 17 provided with a bypass valve 16 . in the event of condensation, the dew point hygrometer 28 sends a signal to the control unit 26 and the bypass valve 16 and thus the bypass line 17 are opened. This reduces the heat transfer area and raises the exhaust gas temperature.

If thawing of the dew point-sensitive element occurs only at a humidity of 100%, ie without a corresponding warning for the formation of condensate in the exhaust gas duct 18 , there is a possibility that small amounts of condensate have already formed in the exhaust gas duct 18 . In this case, the condensate can be dried or evaporated in the burner pauses by the fan 18 running on.

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 (17)

1. A method for controlling a gas or oil-operated heating device in particular with a burner, with an exhaust gas guide and with a control device by which the output of the heater can be regulated as a function of the heat requirement, characterized in that by a in the exhaust gas guide ( 18 ) arranged dew point sensitive element ( 28 ) an exhaust gas condensate monitoring takes place. 2. The method according to claim l, characterized in that a limit value for the dewing of the dew point sensitive element ( 28 ) is set with the aid of a Peltier element. 3. The method according to claim 1 or 2, characterized in that in the event of thawing of the dew point-sensitive element ( 28 ) a signal is given to the control device ( 26 ) for increasing the burner output. 4. The method according to claim 3, characterized in that the Increase in burner output depending on the Flow temperature of the heating water takes place.   5. The method according to claim 4, characterized in that burner output setpoints for increasing the burner output in connection with the associated flow temperatures are stored as a characteristic curve in the control unit ( 26 ). 6. 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 / or longer off-time of the burner ( 10 ). 7. The method according to claim 1 or 2, characterized in that in the case of thawing of the dew point-sensitive element ( 28 ), the dew point of the exhaust gas is lowered by increasing the air ratio λ. 8. The method according to claim 7, characterized in that the air ratio λ is controlled by a fan ( 19 ). 9. The method according to claim 8, characterized in that the speed of the fan ( 19 ) is controlled by the control device ( 26 ). 10. The method according to claim 1 or 2, characterized in that in the case of condensation of the dew point-sensitive element ( 28 ) at least part of the heat transfer is bypassed via a bypass line ( 17 ) and a bypass valve ( 16 ) to raise the exhaust gas temperature. 11. The method according to claim 1, characterized in that in the case of condensation of the dew point-sensitive element ( 28 ) during the downtimes of the burner ( 10 ), the evaporation of condensate in the exhaust gas duct ( 18 ) is accelerated by a fan ( 19 ). 12. A heater with a gas or oil-operated burner, with an exhaust gas duct and with a control device by which the performance of the heater can be regulated depending on the heat requirement, in particular for performing the method according to one of the preceding claims, characterized in that in the Exhaust gas guide ( 18 ) at least one dew point sensitive element ( 28 ) is arranged as a transmitter for the control unit ( 26 ). 13. A heater according to claim 12, characterized in that the dew point sensitive element ( 28 ) is arranged at the end of the exhaust duct ( 18 ). 14. A heater according to claim 12 or 13, characterized in that the dew point sensitive element is designed as a dew point hygrometer ( 28 ). 15. Heater according to one of claims 12 to 14, characterized in that the dew point hygrometer ( 28 ) has a Peltier element and the condensation is capacitively detected by a stray field capacitor. 16. A heater according to any one of claims 12 to 15, characterized in that at least part of the heat exchanger ( 15 ) can be bridged by a bypass line ( 17 ) and by a bypass valve ( 16 ). 17. Heater according to one of claims 12 to 16, characterized in that a fan ( 18 ) is arranged in the heater to support the combustion air supply.