DE19847448A1 - Procedure for matching burner-heated heater to air-exhaust system - Google Patents

Abstract

The procedure uses a heater with a gas-control device working according to the heat demand and a pressure measuring point (14) which is connected to the gas-control device. It releases the gas supply only when a certain pressure value is reached in the air-exhaust system. With first starting under established conditions of temperature and operation, the speed of the fan is slowly increased from a starting speed where the pressure value for the release of the gas supply, also for the shortest length of the air-exhaust system, is not attained, until the pressure value provided is reached. Afterwards a correction factor is evaluated from the speed where this value is reached. With the correction factor, operational characteristics can be calculated from standard characteristics according to which the gas-control device works.

Description

The invention relates to a method for adapting a burner-heated heater advises according to the preamble of claim 1.

For burner-heated heaters with fan-assisted exhaust gas routing, the length of the connected air exhaust system has a significant influence on the block air number and thus on the condensation and ignition behavior of the heater. Therefore the Heizge advises to be adapted to the air exhaust system during installation. So far, the An fit by inserting orifices in the air exhaust system, or it was Sliders in this system are set accordingly.

However, there is the disadvantage that this means that the necessary for safe operation criteria can be met, but not the operation itself through the panels can be optimally guided, because there are additional resistances in the exhaust air system to be built in. In addition, the adjustment process represents an installation effort that there is considerable potential for error.

The aim of the invention is to avoid these disadvantages and a method of the beginning mentioned type, in which the installation of additional resistors in the air Exhaust system can be dispensed with.

According to the invention, this is achieved in a method of the type mentioned at the outset by characteristic features of claim 1 achieved.  

The proposed method steps mean that the operating characteristics have to be adapted the respective resistance conditions of the air exhaust system of the heater are possible. This means that the optimal operation of each heating device is independent of the training Air exhaust system possible. This also ensures that the gas supply to the Burner of the heater is only possible if the intended passage through the Hei z device is ensured due to the fan.

The invention will now be explained in more detail with reference to the drawing. Show

Fig. 1 shows schematically a fan-assisted heating device and

FIGS. 2a to 2c schematically illustrate various embodiments of an air exhaust system for a heating device according to FIG. 1.

Fig. 3 is a diagram and

Fig. 4 control electronics.

The same reference numerals mean the same details in all figures.

The heating device 23 according to FIG. 1 has a burner 16 , which is arranged in a chamber 25 , which via a fresh air supply 20 , which coaxially surrounds an exhaust gas duct 11 , which is connected to the environment. This burner acts on a heat exchanger 13 which is connected via a return line 17 and a flow line 15 with a Heizkörperanord voltage.

Above the heat exchanger 13 , an exhaust gas hood 12 is arranged, which is connected to the gas guide 11 from .

The burner 16 can be connected to a gas supply 19 via a gas line 10 and a gas control device 18 . The gas control device 18 is provided with a modulation magnet 9 , which ensures the corresponding drive.

This modulation magnet 9 is controlled by control electronics 7 , which is connected via a control line 8 to the modulation magnet 9 .

In the exhaust duct 11 , a fan 3 is arranged, the speed of which is monitored by a Hall sensor 2 . This Hall sensor 2 is connected via a signal line 5 to a speed controller 22 .

The control electronics 7 is connected via a control line 6 to the speed controller 22 , which in turn is connected to the blower 3 via voltage supply lines 21 .

In the fresh air supply 20 , a pressure measuring point 14 is arranged, which is connected to a pressure switch ter 1 , which switches when a certain pressure is reached. The dynamic pressure in the fresh air supply 20 is detected via the pressure measuring point 14 , which can be formed by a pitot tube. The pressure switch 1 is connected to the control electronics 7 via a signal line 4 .

The standard characteristic curve 30 - speed as a function of the burner output Q is determined from the air number requirements of the device with regard to condensation behavior, freedom from pollutants and flame stability under standard conditions in laboratory tests and stored as table 41 in the control electronics 7 . A typical characteristic curve is shown in FIG. 3. The standard characteristic curve 30 represents the course in which optimum emission values result under standard installation conditions. To determine this, the burner is put into operation and the load is varied over the entire modulation range. The speed is then determined at each operating point, at which the CO and NOx emissions reach the required values, over-ignition is still guaranteed and, on the other hand, no condensate is yet generated in the exhaust pipe.

If the installation conditions with regard to exhaust gas routing deviate from the standard conditions, the modified resistances make other speeds necessary in order to maintain the same air ratio. A measure of this deviation is the speed at which the pressure switch point is reached. The operating characteristic curve is thus calculated from the standard characteristic curve by multiplying by the ratio "speed in the pressure switch point" to "speed in the pressure switch point under standard conditions". The latter, like the standard characteristic curve, is determined under standard conditions and stored in the memory 40 of the control electronics 7 .

FIG. 3 shows typical characteristics, the standard characteristic 30 correlating with the installation according to FIG. 2a, the operating characteristic 31 with FIG. 2b and the operating characteristic 32 with FIG. 2c.

As can be seen from FIGS. 2a to 2c, the heating device 23 can be provided with differently designed air exhaust systems 24 , which are formed by the fresh air supply 20 and an exhaust gas duct 11 enclosed by this, as well as the blower 3 . Thus, the air exhaust system 24 can be angled ( Fig. 2a, 2b) or straight ( Fig. 2c). In addition, the length of the air exhaust system 24 can vary considerably ( Fig. 2a, 2b), where there are significant differences in terms of the flow resistance of the air exhaust system 24 .

The structure of the electronics 7 is shown in detail in FIG. 4. So in this control electronics, a first table i = f (Q) is provided, in which the dependence of the output of the burner in kW, depending on the current flow through the modulation magnet 9 . This means that each current value in amperes through the modulation magnet 9 is assigned a specific burner output in kW. There is also a second table n = f (Q) 41, in which the assignment of the fan speeds in 1 / min is assigned as a function of the same burner output. This means that a certain fan speed must be available to guarantee a certain burner output. If the speed falls below a certain burner output, the combustion is incomplete; if it is exceeded, the efficiency drops.

A third table 42 with the function Q = f (T) is also provided and in it is the Assignment filed, which results for the burner output if it according to the Control deviation should be approached.

The control deviation is defined for the deviation of the actual flow temperature, measured by the temperature sensor 34 to the set target value, which is given to the evaluation electronics 7 via the adjuster 43 . This adjuster can be an outside temperature sensor or a fixed value. The control electronics 7 also contains a microprocessor which has access to all tables via data lines 45 , 46 and 47 . Furthermore, the microprocessor is connected with all actual values to the target value transmitter.

From the diagram of Fig. 3 shows the dependence of the air ratio (proportional to the speed n), that is the deviation of the actual air flow rate from the target air flow rate for the stoichiometry of the combustion in relation to the burner output Q. There are three curves 30 , 31 and 32 which form approximately straight lines. When the device is started up for the first time with an unknown long air / exhaust gas duct 24 or an unknown pneumatic resistance of this line, the following happens: The control electronics 7 first give a start command to start the fan of the fan 3 . For this purpose, the speed controller 22 is activated via the line 6 and supplies the motor of the blower 3 (not shown ) with current via the line 21 . The fan 3 starts up and a speed is detected via the Hall sensor 2 and the controller is reported back via line 5 as the actual value. If the speed continues to increase, the dynamic pressure is reached at a certain air throughput in the supply air line 20 , so that the pressure cell 1 switches through. This is reported back via line 4 to the control electronics 7 . At the same time, the associated speed value is communicated to controller 22 via Hall sensor 2 in line 5 . From Fig. 3, the assignment of the fan speed and the air flow generated by it proceeds at a known flow resistance in the air / exhaust path. This air flow rate is then assigned to the burner output via table 41 . However, the graph of FIG. 3 sets a certain pneumatic resistance in the air / exhaust flow path of the heating device ahead. This can be chosen arbitrarily. The middle curve 30 initially results for this resistance. From this curve 30 one can read how high the air flow rate is at a certain speed of the fan with the chosen pneumatic resistance.

The boundary characteristics 31 and 32 determine the highest or lowest speed, so that safe burner operation is possible within the field between these boundary characteristics. Too much excess air would result in the flames rising and thus incomplete combustion, and too little air flow would also result in incomplete combustion with carbon monoxide components.

In order to adapt the heating device 23 at the air-exhaust system 24 is in the initial startup of the device and consequently the speed of the fan 3, starting from a starting speed in which even with a very short length and, therefore, the lowest resistance of the air-exhaust system 24, the switching point the pressure switch is not reached, slowly raise it until the pressure switch 1 switches. In order to largely rule out temperature influences and avoid loss of comfort, new measurements are only carried out in heating mode after a defined minimum burner downtime.

A correction factor is determined from the speed at the switching point of the pressure switch 1 , with which operating characteristics are calculated from the standard characteristics stored in the control electronics 7 .

The control of the modulation magnet 9 and thus the gas supply to the burner 16 and the speed of the fan 3 is controlled by the control electronics according to these operating characteristics.

In this way, optimal operation of the heating device 23 is possible under the respective conditions determined by the air exhaust system 24 .

Claims (1)

Method for adapting a burner-heated Heizge device ( 23 ) to an associated air exhaust system ( 24 ) which is provided with a blower ( 3 ), the heater ( 23 ) depending on the respective heat demand gas control device ( 7 , 18th ) and a pressure measuring point ( 14 ), which is connected to the gas regulating device ( 7 , 18 ), which only releases the gas supply when a certain pressure value in the air-exhaust system ( 24 ) is reached, characterized in that at a first start-up under specified tem perature and operating conditions, the speed of the fan ( 3 ), starting from a starting speed at which the pressure value intended for the release of the gas supply is not reached even with the shortest length of the air exhaust system ( 24 ), is slowly increased until the provided pressure value is reached, after which a correction factor is determined from the speed at which this value was reached, with which Operating characteristics can be calculated from the standard characteristic curves according to which the gas control device ( 7 , 18 ) operates.