DE10033941A1 - Burner control method involves interrupting hot water circulation pump drive if drinking water tank temperature falls below value lower than desired value by defined amount - Google Patents

Abstract

The method involves holding the temp. of the drinking water tank (1) above the maximum anticipated inlet temp. of the hot water. The drive to a hot water circulation pump (11) is interrupted if the temp. of the drinking water tank has fallen below a value lower than the desired drinking water tank temp. by a defined amount whilst simultaneously keeping the burner (2) operating. An Independent claim is also included for an arrangement for implementing the method.

Description

The invention relates to a method according to the preamble of claim 1 and a facility for its implementation.

With such methods, the problem arises that the drinking water tank is constantly on a temperature level that must be kept above the maximum expected Flow temperature is. This leads to high standby losses. Further results in the known methods of this type have the problem that there is no heating up of drinking water is given, which is only a rather modest comfort for the User results.

The aim of the invention is to avoid these disadvantages and a method of the beginning Propose the kind mentioned, in which a high level of comfort for the user is ensured.

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 measures make it easy to prioritize the Provision of service water ensured. It is also taken into account that the  The drinking water is heated very quickly and heat is removed from the Drinking water storage is avoided by decoupling heating energy.

Another object of the invention is to provide a device for carrying out the propose method according to the invention.

Starting from a device according to the preamble of claim 2 are therefore the characterizing features of claim 2 proposed.

The proposed measures ensure in a simple manner that as soon as the temperature of the drinking water tank below that of the specified value reduced setpoint, the circulation pump of the heating circuit is switched off. This ensures that it does not continue to dissipate heat from the Drinking water storage tank comes to supply the heating circuit. This ensures that the drinking water tank can be heated up very quickly and thus a correspondingly high one Comfort for the user is guaranteed.

The features of claim 3 ensure that the circulation pump Heating circuit is started again as soon as the temperature of the drinking water tank again exceeds the setpoint for the temperature of the hot water.

The invention will now be explained in more detail with reference to the drawing, which schematically shows a device according to the invention shows.

In the lowest area of a drinking water tank 1 there is a combustion chamber 31 in which a burner 2 is arranged. In this case, an exhaust pipe 32 leading upward from the combustion chamber 31 penetrates the drinking water reservoir 1 , which is enclosed by a heat exchanger 5, which is surrounded by the drinking water.

The heat exchanger 5 is connected via a flow line 6 and a return line 7 to a radiator arrangement 8 of a room heater. Here, a mixer 9 in the flow line 6 is arranged which is connected via a bypass line 33 with the return line. 7

In the lowermost portion of the drinking water storage tank 1, a cold water inlet 3 and flows out of the top area of the memory 1 4 performs a process water pipe away.

Furthermore, a temperature sensor 12 is arranged in the central area of the drinking water storage 1 , which is connected via a signal line 34 to an input of three comparators 23 , 25 and 28 .

Furthermore, an outside temperature sensor 14 is connected via a signal line 35 to a heating curve memory 20 , in which curves for setting the desired flow temperatures are stored. The heating curve memory 20 is connected via a signal line 36 to a room temperature controller 30 , the second input of which is connected via a signal line to a flow temperature sensor 10, which is arranged in the flow line 6 between the mixer 9 and the radiator arrangement 8 , in which also a circulation pump 11 is arranged. The output of the room temperature controller 30 is connected to the mixer 9 via a control line 44 and controls it.

Furthermore, the heating curve memory 20 is connected via a signal line 38 with a fixed value, e.g. B. 8K adder 21 connected, which is connected via a signal line 39 to a logic 22 , the second input of which is connected via a signal line 40 to a setpoint generator 13 , the logic 22 switching the higher value to its output. The output of the logic 22 is connected to the second input of the comparator 23 via a signal line 41 .

The output of this comparator 23 is connected via a control line 42 to a gas valve 15 which is arranged in a gas line 43 leading to the burner 2 .

As already mentioned, an input of the comparator 25 is connected via the signal line 34 to the temperature sensor 12 of the drinking water tank 1 . The second input of this comparator 25 , which is part of a control of the priming of domestic hot water, is via the control line 40 and one with a fixed value, e.g. B. 10K applied subtractor 26 , and a further signal line 45 connected to the setpoint generator 13 .

Another comparator 28 is connected on the one hand to the temperature sensor 12 of the drinking water container 1 via the signal line 34 and on the other hand via the signal line 40 to the setpoint generator 13 .

The outputs of the comparators 25 and 28 are connected via signal lines 46 , 47 to a reset memory 29 , which is followed by a negator 27 via a connecting line 48 . This negator 27 is connected via a control line 49 to the circulation pump 11 of the heating circuit.

In operation, the target flow temperature of the heating circuit is determined as a function of the outside temperature detected by the sensor 14 . The set flow temperature is determined by means of the heating curves stored in the heating curve memory 20 .

This value is increased in the adder 21 by 8K and passed on to the logic 22 , to which the setpoint generator 13 is also connected and which in turn switches the higher value to the comparator 23 , which compares this value with the temperature of the drinking water tank 1 .

If the temperature of the drinking water tank 1 is below the comparison temperature, the burner 2 is started or the gas valve 15 is opened.

The setpoint value of the flow temperature determined via the heating curve stored in the heating curve memory 20 as a function of the outside temperature is compared in the room temperature controller 30 with the temperature detected by the temperature sensor 10 and the mixer 9 is controlled as a function of this comparison result.

If the temperature of the drinking water boiler 1 , which is detected by the temperature sensor 12, rises above the comparison value, which is given either by the value of the desired supply temperature increased by 8K or by the desired value of the temperature of the drinking water tank 1 , which is determined by the desired value transmitter 13 is, the gas valve 15 is closed and the burner 2 is stopped.

Due to a stronger tap, the temperature of the drinking water tank 1 drops below that by a predetermined value, e.g. B. 10K, reduced setpoint of the temperature of the drinking water tank 1 , the comparator 25 emits a signal to the reset memory 29 , whereby the circulating pump 11 of the heating circuit is shut down via the negator 27 and thus removal of heat from the drinking water tank 1 is prevented.

Since the burner 2 is in operation in this case, since the drinking water storage tank does not exceed the set flow temperature increased by 8K, the temperature of the drinking water storage tank 1 increases . If its temperature exceeds the setpoint, the comparator 28 emits a signal to the reset memory 29 and resets it. As a result, the circulation pump 11 is put into operation again via the negator 27 . And the heating circuit can be supplied with heating water again.

Claims (3)

1.Procedure for controlling a burner ( 2 ) of a directly heated drinking water storage tank ( 1 ) with heat coupling for supplying a room heating system with circulating heating water, the temperature of the drinking water storage tank ( 1 ) being kept above the maximum expected supply temperature of the heating water, thereby in that the drive of a circulation pump (11) of the heating water is interrupted when the temperature of the drinking water storage tank (1) by a predetermined amount below the desired temperature of the drinking water storage tank (1) value lying has dropped below one, at the same time the burner (2) in Operation is held. 2. Device for performing the method according to claim 1, in which a by means of a burner ( 2 ) directly heated drinking water tank ( 1 ) is provided, in which a heat exchanger ( 5 ) for coupling heat for a heating circuit is arranged, in which a circulation pump ( 11 ) is arranged, a temperature sensor ( 12 ) being arranged in the drinking water reservoir ( 1 ), which is connected to a controller which has a comparator ( 23 ) connected to a setpoint generator ( 13 ) and which controls the burner ( 2 ) , The one input of the comparator ( 23 ) is preceded by a heating curve memory ( 20 ) connected to an outside temperature sensor ( 14 ) and an adder ( 21 ) connected downstream with a fixed value and the second input of which is connected to the temperature sensor ( 12 ) of the drinking water tank ( 1 ) is connected, characterized in that a further comparator ( 25 ) is provided, one input of which the desired value Via ( 13 ) and a subtractor ( 26 ) charged with a fixed value, the second input of which is connected to the temperature sensor ( 12 ) of the drinking water tank ( 1 ) and the output of which controls the circulation pump ( 11 ) of the heating circuit. 3. Device according to claim 1, characterized in that is connected to the output of the circulation pump (11) controlling the comparator (25) with a reset memory (29), whose second input a with the nominal value transmitter (13) and the temperature sensor (12) the comparator ( 28 ) connected to the drinking water reservoir ( 1 ) and the output of which controls the circulation pump ( 11 ).