DE102020200057A1 - Process for temperature control of a building - Google Patents

Abstract

The invention relates to a method (100) for controlling the temperature of a building (40), the building (40) having at least two zones (42a, 42b, 42c) and a central heating system (5) with a circulating pump (30), in each zone (42a, 42b, 42c) at least one means (12a, 12b, 12c) for emitting or absorbing thermal energy is arranged, and in particular at least one of the means (12a, 12b, 12c) is designed as underfloor heating or as a radiator, characterized by the steps: • recording (110) the actual temperature in at least two, in particular all, zones (42a, 42b, 42c), • recording (120) the target air temperature in at least one zone (42a, 42b, 42c), • Controlling (130) the central heating (5), in particular the circulating pump (30), depending on the recorded actual and target air temperature in such a way that thermal energy is taken from a first zone and the removed thermal energy is released in a further zone.

Description

The invention relates to a method for controlling the temperature of a building, a computer program, a machine-readable storage medium and an electronic control unit.

State of the art

It is known to heat or cool zones of a building, in particular rooms, by means of central heating. In the known systems, however, a considerable amount of energy is required to generate heat or cold in the zones.

It is therefore the object of the invention to provide a method which enables temperature control, that is to say cooling or warming of the rooms, with a greatly reduced use of energy.

Disclosure of the invention

This invention relates to an advantageous method of controlling the temperature of a building. The building has at least two zones and central heating with a circulation pump. The zones are preferably assigned to the building. The zones can be formed inside the building or outside the building. At least one, in particular the majority, for example all, zone is preferably formed within the building. The zones are preferably only formed in the building.

The central heating is not limited to heating, i.e. warming up. It can also be designed in such a way that it cools the zones.

At least one means for emitting or absorbing thermal energy is arranged in each zone. The means is designed in particular as a heat exchanger, preferably as underfloor heating or as a radiator.

The advantageous method has several method steps.

In one process step, the actual temperature is recorded in at least two, in particular all, zones of the building. The actual temperature corresponds to the air temperature. The actual temperature is recorded with a temperature sensor.

According to an advantageous development, in particular an additional temperature sensor is arranged in the wall and / or the screed. The additional temperature sensor is preferably arranged in that part of the floor or that part of the wall in which the agent is also arranged. The temperature value of this sensor is preferably also recorded and is included in the actual temperature value.

In a further process step, the target air temperature is recorded in at least one zone. The acquisition is preferably triggered by a change in the user. A target temperature value can also be stored in a memory. The user defines the target air temperature. The specified target air temperature is recorded.

The actual temperature is preferably recorded at least in the zone in which a setpoint temperature is recorded.

In a further method step, the control of the central heating, in particular the circulation pump and / or at least one valve, takes place as a function of the recorded actual and target air temperatures. The control takes place in such a way that thermal energy is taken from a first zone and the removed thermal energy is released in a further zone.

Due to the redistribution of the thermal energy, no energy has to be used for heating or cooling. Rather, the thermal energy that is stored in a building can be redistributed. Only energy is required for the circulation pump. The energy is preferably only redistributed within the building.

The control is preferably carried out as a function of a selection of at least two zones. The zones are selected depending on the actual and target temperature of the zones. If, for example, heating is to take place in a first zone, a second zone is selected so that the actual temperature there is higher than the actual temperature in the first zone. The actual temperature is advantageously even higher than the setpoint temperature in the first zone.

Correspondingly, when cooling, the selection of a zone with a lower actual temperature applies.

The measures listed in the subclaims result in advantageous developments and improvements of the method specified in the main claim.

An advantageous development is that the building has more than two zones and that the thermal energy is taken from several zones and / or is released in several zones. The selection is made depending on the actual and target air temperature.

An advantageous development is characterized in that each means is part of a Heating circuit is, in particular, that the means, which are arranged in a zone, are part of the same heating circuit. A heating circuit is advantageously assigned to each zone. The heating circuit supplies the zone and the zone (s) with thermal energy or dissipates it.

A particularly advantageous development is that the absorption and release of thermal energy in or out of the zones is regulated by means of a valve which each heating circuit has. In particular, the valve is part of a heating circuit distributor. If the agent is designed as an underfloor heating circuit, it includes adjustable "snakes". The snakes hang on a heating circuit.

An advantageous development is that the heat transfer medium is provided for transporting the thermal energy in the heating circuits, the heat transfer medium being circulated by means of the circulating pump. The heat transfer medium is designed to absorb thermal energy from the environment and to release it to the environment.

An advantageous development is that the amount of heat transfer medium that flows through a heating circuit depends on the speed of the circulation pump ( 30th ) and / or the performance of the circulation pump ( 30th ) and / or the degree of opening of the heating circuit valve. It is possible to regulate the heat energy supplied to a heating circuit or taken from it.

An advantageous development of the method has the following method steps.

Determine whether there is a discrepancy between the actual and the target air temperature in a zone, with the zone to be cooled if the actual temperature is higher than the target air temperature. In response, a zone is sought which has a lower actual temperature. If the target temperature is higher than the actual temperature, the zone should be heated. At least one further zone is sought which has a higher actual temperature. If at least one zone is found which fulfills the aforementioned conditions, it is selected.

Activation of the circulation pump and / or the valves of the zone and the selected zone in such a way that the heat transfer medium circulates between the determined zones. The heat transfer medium transports thermal energy from the zone with the higher actual temperature to the zone with the lower actual temperature.

An advantageous development is that the zones are selected as a function of a prioritization. This prevents, for example, a zone with a higher priority from being additionally heated or cooled by a zone with a lower priority. In particular, a zone is only selected if it has a lower priority.

The invention also relates to a computer program which is set up to carry out all steps of the method.

The invention also relates to a machine-readable storage medium on which the computer program is stored.

The invention also relates to an electronic control unit, in particular for a central heating system, which is set up to carry out all steps of the method. The central heating is designed for air conditioning, i.e. heating or cooling a building.

• 1 ein Beispiel für ein Gebäude,
• 2 ein Ablaufdiagramm eines erfindungsgemäßen Verfahrens und
• 3 ein beispielhafter Temperaturverlauf.

The invention is to be explained in more detail below with reference to the drawings, the same or corresponding elements being provided with the same reference symbols. Show it:

• 1 an example of a building
• 2 a flow chart of a method according to the invention and
• 3 an exemplary temperature profile.

The invention relates to a method 100 to regulate central heating 5 . The central heating 5 includes a central heat generator 20th , at least two, in 1 three heating circuits, for example 10a , 10b , 10c and a circulation pump 30th .

The central heating 5 can be designed as hot water heating, steam heating or hot air heating. Furthermore, the central heating has an electronic control unit which is designed according to the method 100 to execute.

The central heating 5 is usually used for a building 40 to heat or to cool. In particular, central heating systems with heat pumps as heat generators 20th offer the possibility of the building 40 also to cool. The central heating 5 in the sense of this application is therefore not limited to a heating or warming function.

According to a further development of the invention, the thermal energy is only redistributed. The heat generator 20th does not add any additional energy or take it from the central heating 5 .

The building 40 is exemplary in zones 42a , 42b , 42c divided. Usually the zones are formed by spaces. In particular, each room forms a zone and vice versa.

The heating circuits 10a , 10b , 10c assign at least one remedy 12a , 12b , 12c on. The middle 12a , 12b , 12c is like that in a zone 42a , 42b , 42c arranged and designed to the zone 42a , 42b , 42c in particular to heat or cool by means of convection. One zone 42a , 42b , 42c can be a room, an area of a room but also an area of a building 40 represent. The middle 12a , 12b , 12c is a heat exchanger for receiving or releasing thermal energy, in particular underfloor heating, wall heating or a radiator, preferably a radiator or a heating strip, or an air outlet.

Underfloor heating is a surface heating system that heats rooms by means of pipes, in particular snakes, laid in the floor. Underfloor heating can be designed as a wet system or a dry system. The heating circuits have pipes laid in the floor, walls or ceilings. The laying is either meandering, modulating or bifilar. Thanks to the large surface area, modern underfloor heating systems offer the possibility of influencing the zones or room and floor temperatures even with small temperature differences.

The central heat generator 20th generates thermal energy and provides this to the means during normal use 12a , 12b , 12c ready. It can also generate negative heat energy, which cools accordingly. The central heat generator 20th can in particular be designed as a boiler, combination boiler, heat pump, fireplace, fuel cell, condensing boiler, burner. It heats a heat transfer medium, in particular a fluid or gas, preferably water or air.

A circulation pump 30th transports the heated heat transfer medium to the heating circuits 12a , 12b , 12c pumped through this. The flow of the heat transfer medium is controlled by the speed and / or the power of the circulation pump 30th regulated.

The type of central heating depends on the heat transfer medium 5 . Fluids such as water can be designed as the heat transfer medium.

The warm air heating uses the room air as a heat transfer medium. This is done in a heat generator 20th generated warm air via the heating circuits 10a , 10b , 10c and the means 12a , 12b , 12c which are designed as air ducts and air outlets are directed into the zones. The warm air introduced into the zone leads to a heating of the zone.

The central heating is advantageous 5 several, in particular at least two, three, four etc. heating circuits 10a , 10b , 10c on. The heating circuits 10a , 10b , 10c each have one zone 42a , 42b , 42c to warm up.

A heating circuit distributor 50 distributes the heat energy. Preferably there are valves in the heating circuit distributor 60 arranged. All heating circuits 10a , 10b , 10c are with the flow and return to the heating circuit distributor 50 connected.

The valves 60 can be designed as solenoid valves or by means of servomotors. The valves 60 can take different valve positions, which in turn controls the flow through the heating circuit 10a , 10b , 10c regulated. By regulating the flow, the can be sent to the heating circuit 10a , 10b , 10c heat energy emitted or the heat energy absorbed by it can be regulated.

In addition, room thermostats with temperature sensors are provided which detect the actual temperature in the zones. The target air temperature of the rooms is stored centrally or in the room thermostats.

According to a further development of the invention, at least one additional temperature sensor is formed, in particular arranged, in the screed of a zone. It records the actual temperature of the screed. The screed serves in particular as a heat store.

The valves of the heating circuit distributor 50 are in 1 interconnected for example in such a way that the heating circuits 10a and 10b form a cycle. Valves in the heating circuit distributor 50 enable such an interconnection. However, there can also be an interconnection that the heat transfer medium through the heat generator 20th circulates. An interconnection can also be made that the heat transfer medium is additionally or alternatively used by a further heating circuit 10c circulates.

In 2 is the method according to the invention 100 shown in a flow chart.

In one process step 110 the actual temperature is recorded. The actual temperature is in at least two zones 42a , 42b . The actual temperature is preferably in at least one further zone 42c or recorded in all zones. The actual temperature preferably corresponds to the air temperature in at least one zone. The actual temperature of the zone which is to be cooled or heated preferably corresponds to the temperature of the air in this zone.

The actual temperature of the further zones can also be based on the air temperature or the temperature of part of the screed or part of the wall. The actual temperature can also be based on a combination of the recorded temperatures of a zone.

In a further process step 120 the target air temperature is recorded in at least one zone. In particular, the method can be triggered by a change in a setpoint air temperature.

In one process step 125 it is determined whether there is a discrepancy between the actual temperature, here air temperature, and the target air temperature in a zone, with at least one further zone being selected 127 with a higher actual temperature than the target air temperature, which has a lower actual temperature. Temperature.

In the case of a lower actual temperature, at least one further zone is selected 127 which has a higher actual temperature.

The selection 127 of the further zone can also take place on the basis of the recorded temperature of an additional temperature sensor. As already mentioned, the additional temperature sensor is formed in the screed or a wall in which the center of the zone is also formed, in particular arranged. The temperature of the screed or the wall is used as the actual temperature. The detected temperature preferably corresponds to the actual temperature or is included in the detection of this.

selection 127 the zone and thus the associated heating circuit.

In one process step 130 the central heating, in particular the circulation pump or the valves, is activated. The control takes place in such a way that, depending on the recorded actual and target air temperature, thermal energy is taken from a first zone, and the removed thermal energy is released in a further zone.

For example, it is in a first zone 42a If the actual temperature is above the target air temperature, cooling is desired. Accordingly, a zone is sought in which the actual temperature is lower than the actual temperature in the first zone 42a . A zone is preferably sought in which the actual temperature is below the setpoint temperature. A zone is preferably sought whose screed or wall has a lower temperature. When the actual temperature is recorded in the other rooms, only the temperature of the additional temperature sensor is preferably recorded.

If at least one suitable zone is found, the heating circuit distributor is used 50 , especially the valves 60 and / or the circulation pump 30th controlled in such a way that the heat transfer medium circulates between the heating circuits of the zones. The heat transfer medium takes over the means in the first zone, here 42a with the warmer actual temperature and emits this in the further zone, here 42b with the lower air temperature. Preferably there is a balance between the zones. It is advantageous if, for example, zones in the basement are interconnected with zones on the ground floor or on the upper floor or top floor.

Zones or rooms can be specifically excluded by, for example, the respective valve 60 is closed.

In 3 a temperature curve is shown as an example. Here's in the zones 42a and 42c the target air temperature is lower than the actual temperature. It should be cooled in these zones. The procedure 100 was started at 7:30 a.m. The warmer zones 42a and 42c cool and the temperature in 42b increases. There is a redistribution of thermal energy from the zones 42a and 42c into the zone 42b .

It can also be seen here that several zones are also advantageous 42a , 42b , 42c , or their heating circuits 10a , 10b , 10c can be merged. The heat transfer medium circulates through the heating circuits 10a , 10b , 10c of the zones 42a , 42b , 42c .

The same applies if the air in the zone is to be heated. For example, when the air is in the zone 42b should be heated. This is the case when the target air temperature is higher than the actual temperature, i.e. the actual air temperature. A search is then made for at least one zone which has a higher temperature. Here those would be the zones 42a and 42c .

If necessary, the prioritization can come into play here. According to this it is not desired that 42b to the disadvantage of 42a and 42c is heated.

Furthermore, the method 100 can be limited by prioritization. A zone with a higher priority is preferred to a zone with a lower priority. For example, the bedroom can be given higher priority for cooling than the living room and the basement. Accordingly, if the living room had to be cooled, the thermal energy would not be released to the bedroom, but to the cellar.

Claims (11)

Method (100) for controlling the temperature of a building (40), the building (40) having at least two zones (42a, 42b, 42c) and a central heating system (5) with a circulation pump (30), wherein in each zone (42a, 42b , 42c) at least one means (12a, 12b, 12c) for emitting or absorbing thermal energy is arranged, and in particular at least one of the means (12a, 12b, 12c) is designed as underfloor heating or as a radiator, characterized by the steps: a. Detecting (110) the actual temperature in at least two, in particular all, zones (42a, 42b, 42c), b. Detecting (120) the target air temperature in at least one zone (42a, 42b, 42c), c. Controlling (130) the central heating (5), in particular the circulating pump (30), depending on the recorded actual and target air temperature in such a way that thermal energy is taken from a first zone and the removed thermal energy is released in a further zone. Method (100) according to the preceding claim, characterized in that the building has more than two zones, and that the thermal energy is taken from several zones and / or is released in several zones. Method (100) according to one of the preceding claims, characterized in that each means (12a, 12b, 12c) is part of a heating circuit (10a, 10b, 10c), in particular that the means (12a, 12b, 12c), which in a zone (42a, 42b, 42c) are part of the same heating circuit (10a, 10b, 10c). Method (100) according to the preceding claim, characterized in that the absorption and release of thermal energy in or from the zones (42a, 42b, 42c) is regulated by means of at least one valve (60). Method (100) according to one of the preceding claims, characterized in that a heat transfer medium is provided for transporting the thermal energy in the heating circuits (10a, 10b, 10c), the heat transfer medium being circulated by means of the circulating pump (30). Method (100) according to the preceding claim, characterized in that the amount of heat transfer medium that flows through a heating circuit (10a, 10b, 10c) depends on the speed of the circulating pump (30) and / or the power of the circulating pump (30) and / or the degree of opening of the valve (60) of the heating circuit (10a, 10b, 10c). Method (100) according to one of the preceding claims, comprising the steps: • Determining (125) whether there is a discrepancy between the actual and the target air temperature in a zone, with at least one further zone being selected which has a lower actual temperature and if the actual temperature is higher than the target air temperature with a lower actual temperature at least one further zone is selected which has a higher actual temperature, • Activation (130) of the circulation pump (30) and the valves (60) of the zone and the selected zone in such a way that the heat transfer medium circulates between the determined zones. Method (100) according to the preceding claim, characterized in that the selection of the zones (42a, 42b, 42c) takes place as a function of a prioritization. Computer program which is set up to carry out all steps of the method (100) according to one of the preceding claims. Machine-readable storage medium on which the computer program is based Claim 9 is stored. Electronic control unit (60) which is set up to carry out all the steps of the method (100) according to the Claims 1 to 8th to execute.

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