DE3539327A1 - Method of controlling a heat source and control device for implementing the method - Google Patents

Abstract

Method of controlling a circulating water heater of a central heating installation which has a first consumer circuit consisting of radiators and a second consumer circuit which is connected via a mixing valve and forms a floor heating installation, which are fed with heating water of different forward-run temperatures, the respectively higher of the two forward-run desired temperature values serving as reference variable for the circulating water heater.

Description

Method for controlling a heat source and control

apparatus for carrying out the method The present invention relates on a control method for a heat source of a central heating system and on a control unit for performing this method in accordance with the generic terms of Claims one and two.

There are central heating systems known that several on independent Consumers that are at the setpoint temperatures have to be fed. Think once to a domestic hot water tank to be charged by a central heating boiler simultaneous feeding of a radiator heating system or when feeding a Radiator heating system from a boiler that is also an underfloor heating system is connected in parallel. So far it has been customary to use the one on the higher Temperature level directly to consumers the heat source to be coupled, where, however, the coupling of the lying on the lower temperature level Consumer takes place via a mixing valve. Both heating circuits were shared Flow temperature control started, which is usually done via a clock. It it has become common practice to operate heating systems with night setbacks, whereby a high daytime setpoint and a low nighttime setpoint are specified in the clock on which the two circles are driven. According to the state of the art it is only possible to lower and raise both heating circuits together.

This results in decisive disadvantages, especially if the Lowering of the consumer circuit at the higher temperature level on the actually lower heating circuit level is affected draws, as the flow temperature must be driven just higher than it Heat source actually pretends.

The present invention is based on this disadvantage to avoid and thus the temperature setpoint for the connected consumer circuits specify that the consumer at the higher temperature level has the setpoint dictated.

The solution to the problem lies in the characteristic features of Method claim one. The claim gives for the special solution of this process two the corresponding device-technical design. Further refinements and particularly advantageous developments can be seen from the following description, an embodiment of the invention with reference to Figures one and two of the drawing explained in more detail.

It shows: Figure one is a hydraulic schematic diagram of a central heating system and FIG. two shows an electrical block diagram.

In both figures, the same reference numerals mean the same in each case Details.

A gas or oil-fired central heating boiler 1 - it could just as well a gas-fired circulating water heater or an electric water heater act - is via a flow line 2 and a return line 3 to a central heating system 4 connected.

Furthermore, an electrical connection 5 to a feeding network is provided. The flow line 2 leads to a branch point 6, from which two consumer circuits 7 and 8 branch off. The first consumer circuit 8 is via a check valve 9 and a circulation pump 10 that have a Has drive motor 11 on a first consumer 12 to be operated at a relatively high temperature level is connected, the rear connection 13 of which opens into the return line 3. With this consumer 12 is either a domestic hot water tank that is set to a temperature of a maximum of 800 is to be charged, or to a radiator network, which then has a maximum Has a temperature of about 600 in the flow. The flow line 2 of the first heating circuits 8 is provided with a contact temperature sensor 15, which is connected via a measuring line 16 is connected to a control unit 17. The one connected to junction 6 second heating circuit 7 has a flow line 18 in which a check valve 19 is provided, to which a 3-way mixing valve 20 is connected, its servomotor 21 can be adjusted by the control unit 17 via a control line 22. Instead of a 3-way mixing valve A 4-way mixer could also be used. It doesn't matter whether it is is a mixing valve or a flap mixer.

An output of the mixing valve is connected to a bypass line 23, which leads directly to the return line 3.

The forward flow line 18 'is connected to a second circulating pump 24, the drive motor 25 of which is provided via a mains voltage supply line 26 is connected to the control unit 17. Also on the flow line 18 ' is a contact flow temperature sensor 27 is provided, which via a measuring line 28 with the control unit 17 is coupled. A second consumer is connected to the flow line 18 ' 29 fed, which in each case towards the consumer 12 on a usual lower temperature level. Is the consumer 12 as a domestic hot water storage tank formed, the consumer 29 can consist of a radiator heating system, If the consumer 12 itself is designed as a radiator group, the consumer can 29 can also be designed as a group of radiators, which for some reason is to operate at a normally lower temperature level, the consumer 29 can also represent an underfloor heating system or part of such a system. On the return side, the consumer 29 is connected to the return line via a line 30 3 connected. The boiler is activated by the control unit 17 via a line 31.

An outside temperature sensor 32 is connected to the control unit via a line 33 connected, it is possible to use a remote control unit 34 via a line 35 to connect the control device 17 if the control device 17, for example, the boiler is assigned immediately adjacent and a remote control from a room dtr apartment to be heated is to be carried out.

The control unit has two clocks 36 and 37 with which the day and night setpoints of the two heating circuits or the two consumers 12 and 29 can be controlled. It is also possible to do this with a clock, if this only has different switching contacts.

The present invention is not limited to controlling a Heat source for two heating circuits, several others arranged in parallel can also be used There may be heating circuits that are at different temperatures. These are then in turn approached via a mixing valve each, and the flow lines behind the mixing valves are provided with temperature sensors, which are then shown in the outlined Manner with the control unit 17 are connected. It is then necessary to and night setpoints for these additional consumer circuits via separate clocks or controlled via separate contact levels of a single clock.

The control unit are adjusting buttons 38 for the day setpoint of the first Heating circuit, 39 for the night setpoint of the first heating circuit and 40 for the slope the heating curve of the first heating circuit as well as 41, 42 and 43 for the same values of the assigned to the second heating circuit. The mains voltage supply for the pump motor 11 takes place via a line 44 which is looped through the boiler 1 is and is connected to line 31.

The control device 17 is only in accordance with the illustration of the figure two explained in more detail. The control unit has a setpoint comparator as a central element 50, the output 51 of which is connected to a flow temperature controller 52. Upper line 51 is given the current setpoint value to the flow temperature controller.

The flow temperature controller 52 is the actual value of the flow temperature sensor 15 abandoned flow value sensed via line 16. Due to the control deviation at output 53 of the flow temperature controller a with the control deviation occurs proportional signal which is also given to the solenoid valve 45 of the boiler 1 and either activates or deactivates. It follows that the flow temperature controller is designed as a two-point controller, but this does not have to be.

Likewise, it is not necessary to be within the controller a flow temperature control takes place, it could be technically equivalent Way also a return temperature control or a control of the consumer lying difference temperature take place.

The setpoint comparator 50 has two inputs 54 and 55, of which the input 54 is connected to the output of a target value processing element 56 is. One of them Input 57 is the heating curve slope adjuster 40. A second input 58 of the setpoint conditioning element is on the line 33 of the outside temperature sensor 32 is connected. A third input 59 of the setpoint processing element is connected to the switching contact level 60 * of the clock 36. This switching contact level switches either line 61 or line 62 with the day setpoint, set on adjuster 38, or with the night setpoint set on adjuster 39 the line 59 through and blocks the other line.

Similarly, a second setpoint processing element 63 is provided, which is assigned to the second heating circuit 7.

The output 64 of this setpoint processing element is once with the line 55 and on the other hand electrically in parallel with an input 65 of the mixer controller 66 connected. The mixer controller is a flow temperature controller for the flow temperature of the second heating circuit. The measuring element for this is the flow temperature sensor 27 and the actuator is the position of the mixer 20. The reference variable is over the line 65 supplied. At the output, the mixer controller has two lines 67 and 68, which lead to the drive motor 21 of the mixer 20 and either in cycles result in slow opening or slow closing of the mixer.

A first input 69 of the setpoint processing element 63 is from Adjuster 43 is formed, which determines the steepness of the heating curve for this second consumer circuit 7 pretends.

A second input 70 is connected electrically in parallel to the line 33. A third input 71 is led to the switching contact level 72 of the second clock 37, depending on the switching position of their contacts either the line 73 or 74 on the line 71 switches through. The line 73 is the line with the night value setpoint adjuster 42 74 connected to the day setpoint adjuster 41.

A line 75 is also electrically parallel to the line 33 connected, which is connected to an input 76 of a first pump control element 77 is that dominates the pump motor 11 of the pump 10 via the line 44. The second Input 78 of the pump control element is coupled to line 59. Farther a second pump control member 79 is provided, the output of which connects to the line 26 is connected and thus dominates the pump motor 25 of the second heating circuit pump 24. An input 80 of the second pump control member 79 is electrically in parallel with the Line 33, the second input 81, is coupled to line 71 via a line 82.

The central heating system described in Figures one and two or their control has the following 12 function on: For the description it is assumed that the consumer 12 is from a group of radiators consists, with the individual radiators specific rooms of a family house assigned. The second consumer 29 consists of an underfloor heating system, the other rooms of this house should supply heat. It can be assumed here that that the flow temperature setpoint of the consumer 29 both day and night is lower than the flow temperature setpoint of consumer 12. It should continue be assumed that the consumer 12, for example, a granny flat this Single-family home is assigned. With this, the user hands over the granny flat the timer 36 and the setpoint adjuster 38 to 40 his individual program before. Provided that the resident for reasons of savings or other Motives a relatively early lowering of his heating circuit, for example at 9 p.m. Clock, or an early heating of its heating circuit, for example at 5.30 a.m., if he wishes, he will set the corresponding switching points in the contact level of his watch to mark. For the further description it is assumed that the resident of the Main residence of this house, i.e. the one that controls heating circuit 29, a reduction to the night setpoint only around 10:00 p.m. and heating to the day setpoint first at 7:00 am. It is now assumed that the central heating system and therefore boiler 1 is in operation and it is 5:00 p.m., both heating circuits are switched on supplied by the boiler with the corresponding specified flow temperatures, the flow temperatures are controlled, the first heating circuit has a control circuit that consists of the Sensor 15, the control unit 17 and, as an actuator, the solenoid valve 45 of the boiler 1 exists. The control circuit of the second heating circuit 7 consists of the sensor 27, the Control unit 17 and the mixer 20. Now comes the first switchover command to the lower one Night setpoint through the clock 36, so that would be a whole in the prior art Effect a lowering of both heating circuits.

In the invention, however, this setpoint value is still high second setpoint of the second heating circuit 7 compared. The two setpoints are in place via lines 54 and 64 to the setpoint comparator 50, whichever is higher Setpoint of the two switches through.

This means that one user's wish to lower the system is not recognized taken, and the heat source works with the high setpoint of one heating circuit Further.

It does not matter which of the two heating circuits or with a large number of heating circuits from which heating circuit the higher desired value originates. Only when both heating circuits or, generally speaking, all of them Heating circuits specify the reduction, heat source 1 has a low overall flow temperature drove.

If after the end of the night reduction period there is only one setpoint the two or many setpoints jumps back to the higher value, is over the setpoint comparator 50 the highest setpoint on the heat source temperature control given. The further reduction requests from other heating circuits are suppressed.

However, the user of a heating circuit has the option of using the Reduction setpoint, i.e. by turning the knobs 39 or 42, under the The actual outside temperature value lowers that the associated pump control element 77 or 79 Further running of the pump is suppressed. Namely, the pump controllers 77 and 79 are themselves designed as comparators and compare the room temperature setpoint once via lines 78 and 82 with the actual outside temperature values via the lines 33 and 75 and 80, respectively. So it is the associated consumer users possible to use a maximum of energy, including electrical energy for the associated pump motors, to save if this is desired.

It should also be noted that the term night setpoint generator can refer not only to nighttime reductions, but also to daytime reductions. Meant a desired decrease compared to a first high setpoint is of no consequence at what time it lies.

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Claims (3)

Claims 1. A method for controlling a heat source of a central heating system with a first directly connected consumer circuit and a second via a mixing valve connected consumer circuit, a circulation pump and a setpoint generator for different temperatures in the two consumer circuits, characterized. that the higher of the two temperature setpoints is used as the reference variable for the Heat generator is provided. 2. Control device for performing the control method according to claim one, characterized in that a threshold value comparator (50) is provided, its Exit (51) with a Solenoid valve (45) in the fuel path of the heat source (1) is connected and its inputs (54, 55) each with a setpoint processing element (56, 63) are connected to each one with an outside temperature (32) variable Value, a heating curve slope value (40, 43) and the high or low temperature setpoints are switched. 3. Control device according to claim two, characterized in that for each pump motor (11, 25) a pump control member (77, 79) is provided, which as Comparator is switched, whose first inputs (76, 80) with the outside temperature sensor (32) and its second inputs (78, 80) with the setpoint adjusters (38, 39, 41, 42) are connected via timer contacts (60, 72).