DE102020211169A1 - Method of controlling a heating system - Google Patents

Abstract

The invention relates to a method (100) for controlling a heating system (1), the heating system (1) having a heat generator (12) and at least two heating circuits (20a, 20b, 20c), each heating circuit (20a, 20b, 20c) at least one fluid regulator (22a,b,c; 23a,b,c; 25a,b,c), in particular a pump or a valve, is assigned, and the heat generator (12) is connected to the heating circuits by means of a heated fluid, in particular water (20a, 20b, 20c) provides thermal energy, characterized by the steps:• assignment (110) of a temperature setpoint to each heating circuit (20a, 20b, 20c);• determining (120) a heat requirement for at least two, in particular each, heating circuit ( 20a, 20b, 20c);• providing (130) thermal energy for a first selected heating circuit (20a, 20b, 20c) depending on the recorded heat requirement and the assigned temperature setpoint and• supplying (140) the thermal energy to the first selected heating circuit ( 20a, 20b, 20c) by means of d he activation of a fluid controller;• providing (150) thermal energy for a second selected heating circuit (20a, 20b, 20c) depending on the recorded heat requirement and the assigned temperature setpoint and• supplying (160) the thermal energy to the second selected heating circuit (20a, 20b, 20c) by controlling a fluid controller.

Description

The invention relates to a method for controlling a heating system, a computer program that is set up to carry out the steps of the method, a heating controller that is designed and set up to carry out the method, and a heating system with a heating controller.

State of the art

Known heating systems have at least one heat generator and at least one heating circuit. The heating circuit has heat transfer systems, such as underfloor heating and radiators, which extract heat from the heating circuit and transfer it to a medium. Each heating circuit has a temperature setpoint that depends on the heat transfer system of the heating circuit. For example, underfloor heating must not exceed a temperature of 40°C. Whereas radiators have a higher power output at temperatures above 40°C than at temperatures below 40°C. The heat generator provides thermal energy as a heated fluid. The temperature of the fluid must correspond to the maximum value of all temperature setpoints. Mixers and valves are necessary to achieve the desired temperature setpoint, which is lower than the maximum value.

Disclosure of Invention

The method according to the invention is used to control a heating system, the heating system having a heat generator and at least two heating circuits, each heating circuit being assigned at least one fluid controller, in particular a pump or a valve, and the heat generator using a heated fluid, in particular water, Heating circuits provides thermal energy. The pump is designed in particular as a circulating pump. The pump circulates the fluid through the heating circuit. The pump preferably also ensures that the fluid circulates through the heat generator.

The method advantageously has the steps listed below.

In one process step, a temperature setpoint is assigned to each heating circuit. In particular, the temperature setpoint for each heating circuit is determined and assigned. Determination includes, in particular, recording by means of measurements or recording by means of a query, for example a database.

In a method step, a heat requirement is determined for at least two, in particular each, of the heating circuits. In particular, a heat requirement leads to a heat requirement. The heat requirement can be determined in particular by means of a command and/or signal and/or measurement.

In a method step, thermal energy is provided for a first selected heating circuit as a function of the detected heat requirement and the assigned temperature setpoint.

In one process step, the thermal energy is fed into the first selected heating circuit by controlling a fluid controller.

In a method step, thermal energy is provided for a second selected heating circuit as a function of the recorded heat requirement and the assigned temperature setpoint.

In one method step, the thermal energy is fed into the second selected heating circuit by controlling a fluid controller.

It is advantageous that the number of components can be reduced by the method according to the invention and the complexity decreases.

It is advantageous that the invention makes it possible to save on components or installations (e.g. 3-way valves, actuators, pipe sections, sensors), which results in reduced installation effort and lower costs for components.

Furthermore, it is advantageous that the invention results in a reduction in the auxiliary energy for moving the fluid and a more precise design of the circulating pumps is achieved.

It can also be seen as advantageous that the fluid provided only has the temperature required to cover the heating load. This avoids unfavorable (excessively high) flow and return temperature levels, resulting in increased efficiency in heat pumps and condensing boilers.

Advantageous further developments of the method according to the invention according to the main claim are possible as a result of the features listed in the dependent claims.

In an advantageous further development, the provision of thermal energy for a third and/or further takes place in a method step selected heating circuit depending on the recorded heat requirement and the assigned temperature setpoint. In a further method step, the thermal energy is fed into the third and/or further selected heating circuit by controlling a fluid controller. Any number of heating circuits can be selected.

An advantageous development is that at least two of the heating circuits have different temperature setpoints. The heating circuits are supplied with thermal energy sequentially, one after the other or alternately. In particular, the heating circuits are supplied with thermal energy according to a previously determined process. The result is an optimal and energy-efficient provision of thermal energy.

An advantageous development is that the heating circuits are selected and the order in which the heating circuits are selected is determined as a function of the heat requirement and/or the prioritization and/or the assigned temperature setpoints. The efficiency can be further improved.

An advantageous development is that a heating circuit can be selected multiple times. This is advantageous when one heating circuit has a higher heat requirement than another heating circuit, or, for example, requires more heat energy or, viewed over time, has a longer heat energy requirement.

An advantageous development is that the prioritization takes place as a function of a priority assigned to each heating circuit. Each heating circuit is preferably assigned a priority. In particular, more important heating circuits can be preferentially supplied with thermal energy.

An advantageous development is that the heat request and/or the prioritization is dependent on the difference between the actual temperature and the desired temperature of the medium heated by the heating circuit. The desired value is specified in particular. The presetting takes place, for example, by means of a thermostat. The actual temperature is measured, for example with a temperature sensor, ie sensors.

An advantageous development is that the provision and supply of thermal energy to the heating circuits is repeated at least once. The feeding is preferably repeated several times.

An advantageous development is that the provision and supply of heat energy to a heating circuit is repeated until its heat requirement is below a defined limit, in particular until there is no longer any heat requirement.

An advantageous development is that in the event of a repetition, the selection and determination of the sequence in which the heating circuits are selected takes place again. The order in which the heating circuits are selected can be determined again if the provision and supply is repeated.

An advantageous further development is that a sequence is determined according to which the preparation and delivery to the heating circuits is carried out. In particular, the expiry for an hour, a day, etc. is determined. The process is preferably specified and stored in a database. In particular, the drain period can be divided into a number of time slots, with a heating circuit always being supplied with thermal energy for the duration of a time slot.

An advantageous development is that the heat generator heats the fluid to a fluid temperature, with the fluid temperature corresponding to the temperature setpoint that is assigned to the selected heating circuit. The fluid temperature preferably does not exceed the temperature setpoint, in particular only minimally, preferably by a maximum of 5° C., or only by 3° C., or only 1° C.

An advantageous further development is that the duration of the provision of thermal energy to a heating circuit depends on the heat requirement and/or the prioritization and/or a predetermined period of time and/or the assigned temperature setpoints of the heating circuit. The provision and delivery preferably takes place according to time slots.

An advantageous development is that the heating circuits each have at least one heat transfer system, and that the heat transfer systems are designed to remove heat energy from the heating circuit, the heat transfer system being in particular a radiator or a heat exchanger or underfloor heating.

An advantageous further development is that the heat requirement is dependent on the thermal energy requirement that is drawn from the heating circuit. The invention also relates to a computer program that is set up to carry out all the steps of the method according to the invention.

The invention also relates to a heating control that is set up and designed to carry out all the steps of the method according to the invention to lead. The invention also relates to a heating system with a heat generator and at least two heating circuits, with each heating circuit being assigned, in particular having, at least one fluid regulator, in particular a pump or a valve, and with the heat generator providing the heating circuits with thermal energy by means of a heated fluid, in particular water and wherein a heating control according to the invention is formed.

• 1 eine bekannte Heizungsanlage,
• 2 eine erfindungsgemäße Heizungsanlage,
• 3 ein Ablaufdiagramm des Verfahrens,
• 4 eine Übersichtstabelle mit Temperaturverläufe.

The figures show a schematic representation of a heating system according to the invention and a method according to the invention, which is explained in more detail in the following description. Show it

• 1 a well-known heating system,
• 2 a heating system according to the invention,
• 3 a flow chart of the procedure,
• 4 an overview table with temperature curves.

In 1 a known heating system 10 is shown. The heating system 10 has a heat generator 12 . The heat generator 12 is designed and set up to provide thermal energy.

The heat generator 12 provides heat energy by the heat generator 12 heating fluid. The thermal energy is provided as a fluid with a previously defined temperature. The heated fluid then circulates through at least one heating circuit 20a, 20b, 20c. Each heating circuit has at least one heat transfer system 21a, 21b, 21c, which is intended to remove the thermal energy from the fluid and to supply it to a medium. A heat transfer system can be, for example, underfloor heating or a radiator or a heat exchanger. With underfloor heating, for example, the medium would be the air in a room. With a heat exchanger domestic water.

Furthermore, a heating system 10 has two manifolds 14a and 14b. The collecting lines 14a and 14b supply the heating circuits 21a, 21b, 21c with the thermal energy. The manifold 14a forms the flow and the manifold 14b forms the return.

Furthermore, each heating circuit has a pump 25a, 25b, 25c. The pump ensures the circulation of the fluid within the heating circuit. The pump is controlled by a heating circuit control 29a, 29b, 29c. It is also known that only one pump is provided for all heating circuits.

Furthermore, valves 23a, 23b, 23c are formed upstream of the heat transfer system of a heating circuit. Further valves 22a, 22b, 22c are formed in the return after the heat transfer system of a heating circuit.

The heating circuit controller is also connected to an optional temperature sensor 28b, 28c which detects the temperature of the fluid in the heating circuit.

The temperature setpoint of each heating circuit is dependent in particular on the heat transfer system 21a, 21b, 21c of the heating circuit. For example, underfloor heating must not exceed a temperature of 40°C. Whereas radiators have a higher power output at temperatures above 40°C than at temperatures below 40°C. If the temperature measured by the temperature sensor 28b, 28c exceeds a predetermined value, the pump is switched off and/or the valves are closed.

In addition, the heating system has mixers 27b, 27c or valves 26c, which ensure that the cold return is mixed into the warmer flow. Mixing in causes the flow temperature to be lowered by the cooler return. The mixers and valves are necessary to lower the temperature of the fluid in a heating circuit to the temperature setpoint.

A control unit 30 controls the heating system 10.

With the mixers 27b, 27c, the valves 26c, the temperature sensors 28b, 28c, a large number of components are required in order to provide the heat transfer systems with the fluid at the temperature you require. The fluid must also have a temperature that corresponds to the maximum required temperatures of all heat transfer systems. In the case of heat pumps in particular, however, an increase in the temperature of the fluid leads to a drop in efficiency.

In 2 a heating system 1 according to the invention is shown.

In some cases, the same reference symbols are used as in 1 used. It should be shown that the components are similar. It doesn't have to be the identical components. In particular, some of the components may only have the same basic function. In particular, the pump 25a from 1 a different performance class than the pump 25a 2 exhibit.

However, it can be seen and noted that the mixers 27b, 27c or valves 26c are not necessary in a heating system according to the invention and can therefore be omitted. A reduction in complexity advantageously results. The heating system 1 according to the invention has a heat generator 12 . The heat generator 12 can be configured in particular as a condensing boiler, heat pump, solar thermal system, pellet heating system, oil heating system, fuel cell, district heating transfer, etc. Its task is to provide thermal energy. The heat generator 12 provides thermal energy by heating a fluid, in particular water. The heated fluid is made available to the heating circuits 20a, 20b, 20c via collecting lines 14a, 14b.

A heating controller 40 is also provided. The heating controller 40 is designed to control the heat generator 12 . Furthermore, the heating controller 40 is designed to control the pumps 25a, 25b, 25c and/or the valves 22a, 22b, 22c, 23a, 23b, 23c either directly or via optional heating circuit controllers 41a, 41b, 41c.

According to the invention, a heating circuit can also have no pump or only one pump and/or only one or more valves. The pumps and/or valves of a heating circuit form fluid regulators 22, 23, 25. Fluid regulators 22, 23, 25 are intended to generate and/or regulate the flow in a heating circuit. According to the invention, it is not absolutely necessary for each heating circuit to have a valve and a pump or, in general, a valve or a pump. It is also possible for a pump and/or valve to be formed centrally. If the pump is designed centrally, however, each heating circuit must have at least one valve. The valve regulates the flow through the heating circuit. while in 2 of the heating system is shown as an example with 3 heating circuits, this can also be expanded or reduced to 2 heating circuits as desired.

It is also advantageous that the heating circuit control 29a, 29b, 29c could be omitted. Due to the reduced complexity, the control of the fluid regulators can also be taken over directly by the heating control 40 .

In 3 the process sequence of the method 100 according to the invention is shown.

In a first method step 110, a temperature setpoint is assigned to each heating circuit 20a, 20b, 20c. The assignment of the temperature setpoint depends, among other things, on the heat transfer system 21a, 21b, 21c of the heating circuit 20a, 20b, 20c. For example, the temperature setpoint of a heating circuit with underfloor heating as the heat transfer system is a maximum of 40°C, optimally 30-35°C. On the other hand, for example, the temperature setpoint of a heating circuit with a radiator as the heat transfer system is greater than 40°C. The temperature setpoint of a heating circuit for heating service water is greater than 50 or equal to 55°C.

In a further method step 120, the heat requirement is determined. A heat request exists, for example, if the heating circuit is intended to heat a medium using its heat transfer system and this medium has a lower temperature than the desired one. A desired temperature, which the medium should have, is specified here. If the desired temperature is above the current actual temperature of the medium, then there is a need for heat. The heat requirement is reflected in the heat requirement. The medium can in particular be air or water. It is usually air when the medium is the air in a room. The actual temperature then corresponds to the room temperature. If the medium is water, it could be process water, for example.

There is a heat request if the actual temperature is below the setpoint temperature.

In method step 120, the heat requirement is determined for at least two heating circuits, in particular the heat requirement is determined for each heating circuit. Correspondingly for a version of the heating system 2 the heat requirement of all three heating circuits would preferably be determined.

In particular, at least two of the heating circuits have different temperature setpoints. If necessary, two or more heating circuits can also have the same temperature setpoint. Any number of heating circuits can also have the same temperature setpoint as long as at least two heating circuits have a different temperature setpoint. If two heating circuits have the same or very similar desired temperature value, both can be supplied with thermal energy at the same time.

In a further method step 130, thermal energy is provided for a first selected heating circuit.

The selection of the first heating circuit from the heating circuits of the heating system 10 has previously taken place in method step 125 . In method step 125, the order in which the heating circuits are selected is determined. Assign two heating circuits the same Chen temperature setpoint, they can be selected in particular together. They then form, for example, together the first or second or third etc. selected heating circuit.

According to a development of the invention, a heating circuit can also be selected several times in succession before a further heating circuit is selected.

The heating circuits are selected and the order in which the heating circuits are selected is determined depending on the heat requirement and/or the prioritization and/or the assigned temperature setpoint and/or when the heating circuit is required.

In a selection based on the heat requirement, for example, a heating circuit can be selected first whose heat requirement is greater than the heat requirement of the other heating circuits. When making a selection based on prioritization, this depends on a priority that has been assigned to the individual heating circuits. For example, the priority of heating circuits that supply more important rooms, such as the living room, can be higher than heating circuits that only supply a basement. When selecting according to use, the time at which the heating circuit is used is decisive. The time of use can also flow into the priority in particular. For example, the priorities can change over a period of time, in particular a day.

The selection can also be made depending on the difference between the actual temperature and the desired temperature of the medium heated by the heating circuit.

According to a further development of the invention, the sequence can also be selected using a number of the aforementioned criteria.

According to a development, the heating circuits are selected as a function of a sequence pattern.

In method step 130, thermal energy is provided for a first selected heating circuit. For this purpose, the heating controller 40 sends a signal and/or command to the heat generator 12. The signal and/or the command causes the heat generator 12 to generate thermal energy and make it available as a heated fluid. The heating takes place depending on the temperature setpoint of the selected heating circuit.

In the further method step 140, the thermal energy is fed into the first selected heating circuit. The supply takes place by means of appropriate control of the fluid regulator, in particular by the heating control 40.

The fluid which flows into the heating circuit preferably has a temperature setpoint corresponding to the temperature. Due to tolerances, the temperature can also deviate slightly from the temperature setpoint. A slight deviation is in particular +/-5°C, preferably +/-3°C, for example +/-1°C. The tolerances result in particular from losses due to the supply line or from other external influencing factors.

According to a development of the invention, method steps 130 and/or 140 can be repeated.

In method step 150, thermal energy is provided for a second selected heating circuit. For this purpose, the heating controller 30 sends a signal and/or command to the heat generator 12. The signal and/or the command causes the heat generator 12 to generate thermal energy and make it available as a heated fluid. The heating takes place depending on the temperature setpoint of the selected heating circuit.

In the further method step 160, the thermal energy is supplied to the second selected heating circuit. The supply takes place by means of appropriate control of the fluid regulator, in particular by the heating control 30.

If the heating system has additional heating circuits that also require heat, these can be selected as the third, fourth, etc. selected heating circuit. Accordingly, thermal energy is made available and the thermal energy is supplied in accordance with the statements relating to method step 130 or 150 and 140 or 160.

According to a development of the invention, the provision and supply of thermal energy to the heating circuits can be repeated at least once.

Preferably, it can be repeated any number of times. The length of time for which heat energy is generated for a heating circuit and is supplied to it depends in particular on the heat requirements of the other heating circuits, the prioritization and specified time values, in particular time slots.

According to a development of the invention, only method steps 130-160 etc. can be repeated. However, it is also conceivable that step 125, ie the selection of the sequence is repeated with each repetition.

In 4 a table with eight temperature curves is shown. The x-axis shows the time spread over a day. The y-axis together with the thick line shows the temperature, in particular the temperature setpoint. The y-axis also shows, together with the dashed line, whether thermal energy is supplied to the heating circuit. In the left column ( 4a , 4c , 4e , 4f) temperature curves are shown which result in a heating system which is known from the prior art. Or. be specified for the heat generator. In the right column ( 4b , 4d , 4f , 4 hours) the temperature curves of a heating system according to the invention are shown.

Line 1 shows the temperature curves that are specified for the heat generator.

In particular, they can be checked when measuring the fluid at the outlet of the heat generator 12. In particular, the temperature can be detected with the temperature sensor 15. Preferably, the temperature and thus the temperature profile shown in line 1 is recorded with the temperature sensor 15 and/or specified to the heat generator.

Line 2 shows the temperature curves that are desired in heating circuit A. Line 3 shows the temperature curves that are desired in heating circuit B, and line 4 shows the temperature curves that are desired in heating circuit 4.

For example, the temperature setpoint of heating circuit A is 75°C. For example, the temperature setpoint of heating circuit B is 55°C. For example, the temperature setpoint of heating circuit C is 30°C.

Heating circuit A should be supplied with thermal energy, for example, from midnight to 1 am, 6 am to 8 am, 1 pm to 3 pm and 8 pm to 11 pm (see 4d ). Heating circuit B should be supplied with thermal energy from 1 a.m. to 2 a.m., 5 a.m. to 6 a.m., 3 p.m. to 6 p.m. (see 4f) . Heating circuit C should be supplied with thermal energy from 2 a.m. to 5 a.m., 8 a.m. to 1 p.m., 6 p.m. to 8:23 p.m. to midnight ( 4 hours) . In most cases, no continuous care is necessary as shown in the left column. In this way, additional energy can be saved.

In order for this supply to be possible with the known heating system, the heating system must continuously provide a fluid with a temperature corresponding to the maximum temperature of all heating circuits. This corresponds to 75°C as shown in Figure 4a.

In contrast, in a heating system 1 according to the invention or when using a method 100 according to the invention, the heat generator 12 provides the fluid at different temperatures according to the requirements and the temperature profiles of the individual heating circuits.

For example, the heating system provides the fluid from 12:00 a.m. to 1:00 a.m. at 75°C, from one to 2:00 a.m. at 55°C, from 2:00 a.m. to 5:00 a.m. at 30°C, from 5:00 a.m to 6:00 a.m. at 55°C from 6:00 a.m. to 8:00 a.m. at 75°C, from 8:00 a.m. to 1:00 p.m. at 30°C, from 1:00 p.m. to 3:00 p.m. at 75°C , from 3pm to 6pm at 55°C, from 6pm to 8pm at 30°C, from 8pm to 11pm at 75°C and from 11pm to midnight: 00 o'clock with 30°C ready. This is just an example progression. The fluid regulators are controlled accordingly so that the thermal energy provided is fed to the respective heating circuit.

As can be seen from the curves, the order can be determined flexibly. The duration in which a heating circuit is supplied can also be flexibly determined.

According to a development of the invention, the order in which the individual heating circuits are selected is defined in method step 125 . In particular, one and the same heating circuit can also be specified several times in this determination in method step 125 . In particular using the example of 4b the first circuit selected is circuit A, the second circuit selected is circuit B, the third circuit selected is circuit C, the fourth circuit selected is circuit B, the fifth circuit selected is circuit A, the sixth circuit selected is the Circuit C, the seventh circuit selected is circuit A, the eighth circuit selected is circuit B, the ninth circuit selected is circuit C, the tenth circuit selected is circuit A, eleventh circuit selected is circuit C.

In method step 125, a sequence is preferably determined. The system then follows this procedure. The process is linked in particular to the time, but can also depend on the heat requirement.

It is also possible that there are fixed time slots. For example, from 15 minutes, 30 minutes, 45 minutes, 1 hour, 2 hours, 3 hours, etc. For example, if the time slots in 4a one hour corresponding, the following selection would result. The first selected heating circuit corresponds to heating circuit A (12:00 a.m. to 1:00 a.m.), the second selected heating circuit corresponds to heating circuit B (1:00 a.m. to 2:00 a.m.), the third selected heating circuit corresponds to heating circuit C (2:00 a.m. to 3:00 a.m.: 00 o'clock), the fourth selected heating circuit also corresponds to heating circuit C (3:00 to 4:00 a.m.), the fifth selected heating circuit also corresponds to heating circuit C, the sixth selected heating circuit corresponds to heating circuit B (5:00 to 6:00 a.m.) and so on.

Furthermore, thanks to the system according to the invention, the temperature sensors in the heating circuits can also be omitted.

The dashed lines show when the fluid controller of a heating circuit and the heat generator are activated. At 1 it is activated at 0 it is not. In the case of the heat generator, controlled is to be understood as meaning that it provides heat energy. Controlled in the case of the fluid regulator is to be understood as meaning that this conveys or regulates the fluid, but generally enables a fluid flow. If it is 0, the heat generator does not generate any heat energy. The fluid regulator, designed as a valve, blocks the further flow of the fluid. It blocks the heating circuit. The fluid regulator, designed as a pump, does not deliver the fluid.

Claims (16)

Method (100) for controlling a heating system (1), the heating system (1) having a heat generator (12) and at least two heating circuits (20a, 20b, 20c), each heating circuit (20a, 20b, 20c) having at least one fluid controller ( 22a,b,c; 23a,b,c; 25a,b,c), in particular a pump or a valve, and wherein the heat generator (12) is connected to the heating circuits (20a, 20b , 20c) provides thermal energy, characterized by the steps: • assignment (110) of a temperature setpoint to each heating circuit (20a, 20b, 20c); • Determining (120) a heat requirement for at least two, in particular each, the heating circuit (20a, 20b, 20c); • Providing (130) thermal energy for a first selected heating circuit (20a, 20b, 20c) depending on the detected heat requirement and the assigned temperature setpoint and • Supplying (140) the thermal energy to the first selected heating circuit (20a, 20b, 20c) by means the control of a fluid controller; • Providing (150) thermal energy for a second selected heating circuit (20a, 20b, 20c) depending on the detected heat requirement and the assigned temperature setpoint and • supplying (160) the thermal energy to the second selected heating circuit (20a, 20b, 20c) by means the control of a fluid controller. Method (100) according to the preceding claim, characterized in that at least two of the heating circuits (20a, 20b, 20c) have different temperature setpoints. Method (100) according to one of the preceding claims, characterized in that the selection (125) of the heating circuits (20a, 20b, 20c) and the determination of the order in which the heating circuits (20a, 20b, 20c) are selected are dependent the heat request and/or the prioritization and/or the assigned temperature setpoints. Method (100) according to one of the preceding claims, characterized in that a heating circuit (20a, 20b, 20c) can be selected (125) several times. Method (100) according to one of the preceding claims, characterized in that the prioritization takes place as a function of a priority assigned to each heating circuit (20a, 20b, 20c). Method (100) according to one of the preceding claims, characterized in that the heat requirement and/or the prioritization is dependent on the difference between the actual temperature and the desired temperature of the medium heated by the heating circuit. Method (100) according to one of the preceding claims, characterized in that the provision and the supply of thermal energy to the heating circuits (20a, 20b, 20c) is repeated at least once, in particular the provision and the supply of thermal energy to a heating circuit (20a , 20b, 20c) is repeated until its heat request is below a defined limit, in particular until there is no longer a heat request. Method (100) according to one of the preceding claims, characterized in that when it is repeated, the selection and determination of the order in which the heating circuits (20a, 20b, 20c) are selected takes place again. Method (100) according to one of the preceding claims, characterized in that a sequence is determined according to which the heating circuits are selected and/or the preparation and supply to the heating circuits is carried out. Method (100) according to one of the preceding claims, characterized in that the heat generator heats the fluid to a fluid temperature, the fluid temperature corresponding to the temperature setpoint associated with the selected heating circuit (20a, 20b, 20c). Method (100) according to the preceding claim, characterized in that the duration of the provision of thermal energy to a heating circuit (20a, 20b, 20c) depending on the heat requirement and / or the prioritization and / or a predetermined period and / or the associated Temperature setpoints of the heating circuit (20a, 20b, 20c) takes place. Method (100) according to one of the preceding claims, characterized in that the heating circuits (20a, 20b, 20c) each have at least one heat transfer system, and that the heat transfer systems are designed to remove thermal energy from the heating circuit (20a, 20b, 20c), wherein the heat transfer system is in particular a radiator or a heat exchanger or underfloor heating. Method (100) according to one of the preceding claims, characterized in that the heat requirement is dependent on the requirement for heat energy which is taken from the heating circuit. Computer program which is set up to carry out all the steps of the method (100) according to one of the preceding claims. Heating control (40), which is set up and designed, all the steps of the method (100) according to claims 1 until 12 to execute. Heating system (1) with a heat generator (12) and at least two heating circuits (20a, 20b, 20c), each heating circuit (20a, 20b, 20c) having at least one fluid controller 22a, b, c; 23a,b,c; 25a,b,c), in particular a pump or a valve, and wherein the heat generator (12) provides thermal energy to the heating circuits (20a, 20b, 20c) by means of a heated fluid, in particular water, and wherein a heating control (40) is formed according to the preceding claim.

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