WO2009140986A1 - Demand-based line control of heating systems - Google Patents

Abstract

The present invention relates to a method for controlling a heating system in a building, comprising a heating device with an outlet for feeding heating water and an inlet for receiving heating water, and at least one line, which at one end is connected to the outlet of the heating device and supplies at least one heating surface with the heating water, comprising the steps of determining a difference between a temperature of the heating water on the side of the outlet of the heating device, a flow temperature, and a temperature of the heating water on the side of the inlet of the heating device, a return temperature, and regulating the flow temperature on the basis of the temperature difference that is determined.

Description

 Field of the invention

The present invention relates to a method for controlling heating systems and in particular a string control of heating systems as a function of a determined need that currently exists for individual heating surfaces.

Background of the invention

An essential aspect of the general energy consumption in buildings concerns the provision of heating in the rooms of the buildings. In times of growing environmental and energy-saving awareness, the task of efficient, economical heat supply is becoming increasingly important, not least in connection with economic considerations. In addition to measures for thermal insulation are in a rational control / regulation of the supply of heat from a heat generator or a transfer station to the individual heating surfaces in the premises of a building relatively high savings.

In the prior art heating systems are generally regulated in response to a determined by appropriate temperature sensor outside temperature and regardless of the actual heat demand in the individual rooms. This control method implies the need for an average increased supply of heat usually in the form of at least slightly excessively driven control curves for the flow temperature of the heating surfaces via individual strands supplied heating water to in the currently occurring case of need by turning one or more each attached to a radiator Sets thermostatic valves to be able to provide a sufficient amount of heat in a first approximation needs.

This problem, and in general the problem of excessive heat supply and the associated energy waste, is particularly relevant in single tube heating. Vertical or horizontal distribution systems that are advantageous in terms of tubing requirements and ease of installation over twin-tube systems. In single-pipe heating systems, however, a systemic permanent circulation of the entire amount of heating water in the case of parked radiator, ie in the case of a non-existent heating demand from the residents of the rooms of a building instead. In contrast to two-pipe heating systems in which each radiator is connected to a supply and a return line and thus receives an approximately same flow temperature, the individual radiators are connected in series and in addition with a bypass line, so that between supply and return connection each heating surface flows a portion of the mass flow of the supplied heating water in the bypass line and a part of this mass flow through the radiator, whereby in particular the shutting off and regulating a heating surface affects the temperature of the heating water supplied to the radiator following in the row.

As a further disadvantage occurs a significant pipe heat, which is discharged into the rooms, which not only the individual control option of heating heat is limited and possibly unwanted heat dissipation in individual rooms in an energy wasting manner, but also a distortion of registered by Heizkostenverteilern individual heating demand and associated costs are incurred.

Description of the invention

The above problems and disadvantages are solved by a method according to claim 1 or at least significantly mitigated. According to claim 1, in the present invention, a method for controlling a heating station or transfer station in a building is provided, which has a heater with an output for supplying heating water (supply) and an input for receiving the heating water (return) and at least one Strand, which is connected at one end to the output of the heating device, for supplying at least one heating surface with the heating water. The method comprises the steps: Determining a difference between a temperature of the heating water on the side of the output of the heater, flow temperature, and a temperature of the heating water on the side of the heater input, return temperature, and

Control the flow temperature based on the determined temperature difference.

Heating water can in the heater, z. B. in a boiler, are heated before it is fed through the output to at least one strand. Herein, however, the term "heater" in addition to boilers, etc. also include a installed in a building feeder, for example, include a heat exchanger of local or district heating systems with system separation.

At the entrance of the heater of the same is the heating water after passing through a heating circuit, which includes the passage through individual radiators in the rooms of the building or by bypass lines, in particular for reuse after heating, fed again. The at least one strand can be a main supply line, from which the heating water is distributed to lines which feed the individual heating elements or, as in the case of the single-pipe heating system (see below), also corresponding bypass lines.

It is understood by those skilled in the art that as usual in regulatory circuits, the size to be controlled depends on the result of the control that in the present case, a first flow temperature is set, which subsequently to a return temperature, depending on the determined difference of this flow temperature a second flow temperature is regulated, which may be different from the first. In the claimed control method, the flow temperature to which the heating water is heated, for example, in a boiler, as a control variable depending on, for example, by appropriate resistance temperature sensor or contact sensor, certain temperature of the heating water after passage of the heating circuit until re-entry into the heater, ie return temperature, and more precisely, depending on the difference between this temperature and the flow temperature.

Since the return temperature depends on the current use of individual radiators, a need-based regulation of the heating system for the at least one strand is thus achieved. If no radiator connected to the string is turned on (all radiator controls, eg thermostatic valves, are closed), the return temperature of the string (heating water temperature on the side of the heater inlet) will be approximately equal to the flow temperature (and thus clearly deviating from the design spread), which means that there is no current demand for heating heat and the flow temperature can be regulated down accordingly. However, if a large difference between flow temperature and return temperature determined (measured, for example), a higher control of the flow temperature can be done to meet the current heating demand on the at least one strand can.

Thus, the inventive method for controlling a heating system allows a demand-based setting of the flow temperature instead of a predetermined only by the outside temperature regardless of the actual use of the individual radiator flow temperature. In particular, as a function of the outside temperature, significantly excessively high driving curves, which lead to an energy waste, can be avoided. Then, in the case of single-pipe heating systems (see below), the superfluous and / or uncontrollable pipe heat can be controlled according to the actual needs, whereby the detection accuracy of heat cost allocators can be significantly improved.

According to a further development, the method according to the invention can be combined with the state-of-the-art control method according to the outside temperature, such that it comprises measuring a temperature outside the housing (outside temperature) and the flow temperature also on the basis of the temperature measured outside the housing is regulated. Thus, in an existing heating control system, which is based on heating curves, the flow temperatures to be set for outdoor temperatures can be assigned to a controller of a boiler entered "outside temperature is a function of the determined difference between flow temperature and return temperature modified temperature, which may differ according to the actual heating demand in the rooms of the building described by the difference of the actually measured outside temperature. The method according to the invention can therefore be realized relatively simply and inexpensively by expanding existing control systems.

As already mentioned above, the method according to the invention in its various developments is particularly advantageously applicable to a single-pipe heating system in which the at least one strand for supplying the at least one radiator is connected to the heating water at another end to the input of the heating device. In this system form, the at least one strand of heating water with flow temperature leads to individual heating surfaces (such as radiators) and a bypass line to this radiator, and he leads after flowing through the radiator or the bypass line, the heating water of the heater to the entrance of the same with return temperature.

In the case of several strands, the flow temperature of each strand can be determined either centrally or decentrally on the side of the output of the heating device and a return temperature characteristic of the respective strand on the side of the input of the heating device. The return temperatures of different strands will thus generally be different according to the need for individual radiators.

In this regard, there is provided a further development of the inventive method in which a plurality of strands are connected to the output of the heater such that they are supplied with heating water at the flow temperature, and wherein the plurality of strands is connected to the input of the heating device , and wherein the method comprises:

Determining the differences between the flow temperature and temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heater, return temperatures, and wherein in the method the flow temperature is controlled on the basis of the differences between the flow temperature and the return temperatures.

Thus, information about temperature differences for several or all strands can be used to control the flow temperature. In particular, the method may include determining the largest difference between the flow temperature and the return temperatures, and then may be configured to control the flow temperature based on the determined largest difference. This applies, of course, for one-pipe and two-pipe systems.

As a result, the strand is determined at which the largest current heating demand (demand for supplied by the heating water heat) consists. The flow temperature is regulated according to this requirement, so that the necessary amount of heat is made available.

In addition, when providing a heating curve that maps a standard flow temperature to a temperature measurable outside of a housing, it may be desirable to limit the modified temperature down. Accordingly, in a development, the method for controlling a heating system comprises the steps:

Providing a heating curve that assigns a standard flow temperature to a temperature measurable outside the enclosure, and wherein controlling the flow temperature comprises:

Modifying a temperature measured outside the housing based on the determined difference between the flow temperature and the return temperature of a strand or the determined differences between the flow temperature and the return temperatures of individual strands to obtain a modified temperature; and

Regulating the flow temperature to the standard flow temperature assigned by the heating curve of the modified temperature; in which the modified temperature is minimally modified to the temperature measured outside the housing and / or maximally to a predetermined maximum value.

The term standard flow temperature refers to the temperature which, according to a standard method of the prior art, is assigned on the basis of a heating curve to a measured outside temperature and to which the flow temperature is regulated in the prior art. In the embodiment described here, the flow temperature is controlled to the standard flow temperature, which is associated with a modified outside temperature over the heating curve.

In addition, the modified (manipulated) temperature is limited downwards by the actual measured temperature. This can be avoided that is regulated to an unnecessarily high flow temperature according to an undesirably low changed (manipulated) "outside temperature" when one or more users open, for example, at relatively cold outside temperatures window fully open thermostatic radiator valves in the rooms with the windows open Also, the modified "outside temperature" may be changed at most to a predetermined maximum value from the actual outside temperature in order to provide some reserve for heating in a currently occurring heating case.

Due to the central control of the flow temperature, this is also applied to the other strands, but their current heat requirement is lower. Therefore, it is advantageous to control the mass flow of the heating water in at least one of these strands, based on the difference between the flow temperature and the return temperature for that strand. In particular, the mass flow in each of the strands can be regulated depending on how large the respective difference between the flow temperature and the return temperature of each strand is. This further reduces energy waste. The combined control of the flow temperature and the mass flow for each strand, the supply of the amount of heat can be further optimized. In this case, it can advantageously be provided that the mass flow is not controlled below a predetermined value, so that a current change in the heat demand, ie in particular the onset of a new or intensified heating phase reliably detected and a timely adjustment of the amount of heat to be supplied in the strand can.

It should be emphasized in this connection that the provision of a mass flow regulation is also advantageous in that no additional hydraulic balancing is required or an existing faulty hydraulic balancing is compensated by the mass flow regulation as a function of the difference between flow and return temperatures can. Since heating pipe networks generally have considerable pipe lengths with numerous pressure-reducing branches, bends and fittings, the flow rate of the heating water and the heat transfer with increasing distance from boiler system and feed pump are increasingly low. For radiators that are at the end of a heating line, this may result in a shortage.

For this reason, a hydraulic balancing is usually carried out, which must be carried out in Germany according to VOB / C - DIN 18380 on each heating system. In the implementation of the flow of radiators, which are close to the pump, reduced and throttled with increasing distance less and less. Hydraulic balancing can be carried out by presetting the thermostatic valves and the return screw connections on the individual radiators. Different heating strands are matched once in the prior art by regulating valves. By contrast, according to the above development, the mass flow is regulated, for example by means of actuators on such line regulating valves (see below).

It has already been mentioned above that the method according to the invention is also advantageous in that it can be used for the cost-effective and relatively easy to install modification of existing control circuits of heating systems, in particular single-pipe heating systems. Therefore, a method for retrofitting a heating system in a building is provided here, wherein the heating system has a heating device with an outlet for supplying Heating water and an inlet for receiving the heating water and at least one strand for supplying at least one heating surface with the heating water, wherein the strand is connected at one end to the output of the heater, an outdoor sensor for measuring a temperature outside the housing and a standard controller, adapted to control the heater based on the measured temperature outside the housing, comprising the steps of:

Installing a measuring device configured to measure a temperature of the heating water on the side of the heater input, return temperature, and / or a difference between a temperature of the heating water on the side of the heater output, flow temperature, and a temperature of the heating water on the side of the input of the heater, return temperature, to determine, and

Incorporating a further controller between the outdoor sensor and the standard controller for controlling the heater, the further controller being adapted to modify the value of the measured temperature outside the housing based on the difference between the flow temperature and the return temperature and the standard Controller to enter the modified temperature value so that the standard controller can regulate the heater based on the modified temperature value.

In this case, the difference can be determined by the further controller on the basis of the return temperature measured by the measuring device according to an alternative.

The heating system may in this case be a one-pipe system in which a plurality of strands is connected to the output of the heating device, so that they heating water is supplied to the flow temperature, and the plurality of strands is connected to the input of the heater, and wherein the measuring device is designed to measure temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heating device, return temperatures, and / or to determine differences between the flow temperature and return temperatures, and

the further controller installed between the outdoor sensor and the standard controller is adapted to modify the value of the measured temperature outside the housing and to input the modified temperature value to the standard controller based on the differences between the flow temperature and the return temperatures ,

The heating system may include riser valves, or other throttling devices at the ends of strands or heating circuits on the side of the output of the heater, and the retrofit process may further comprise

Incorporation of strand control mechanisms;

Installation of actuators;

Connecting the actuators to the strand control mechanisms; and

Connecting the strand control mechanisms to the other regulator built in between the outside sensor and the standard regulator; in which

the strand control mechanisms are adapted to cause the actuators, in response to signals from the further regulator, to actuate the strand regulating valves.

In order to solve the above problems, a heating system is further provided which includes

a heating device with an outlet for supplying heating water and an inlet for receiving the heating water and at least one strand which is connected to a nem end connected to the output of the heater, for supplying at least one heating surface with the heating water;

a measuring device configured to measure a temperature of the heating water on the side of the input of the heater, return temperature, and / or a difference between a temperature of the heating water on the side of the output of the heater, flow temperature, and a temperature of the heating water the side of the input of the heater, return temperature to determine; and

a control device which is connected to the heating device and the measuring device and which is adapted to regulate the flow temperature provided by the heating device on the basis of the difference between the flow temperature and the return temperature measured by the measuring device.

The heating system may be a single-pipe heating system comprising

a plurality of strands connected to the output of the heater such that they are supplied with heating water at the flow temperature and connected to the input of the heater, and in the

the measuring device is adapted to measure return temperatures in at least a part of the plurality of strands on the side of the input of the heater and / or differences between the flow temperature and temperatures of the heating water in at least a part of the plurality of strands on the side of the input of Heating device, return temperatures, to determine, and in the

the control means is adapted to control the flow temperature based on the differences between the flow temperature and the return temperatures.

Furthermore, the heating system can comprise an outside sensor for measuring a temperature outside the housing, and the regulating device can be equipped to this end. forms to regulate the flow temperature on the basis of the temperature measured by the outdoor sensor outside the housing.

According to a development, the heating system includes

Strand regulating valves (or other regulating devices) at the ends of strands or heating circuits on the side of the outlet of the heating device;

Actuators connected to the balancing valves for actuating the same; and

Strand control mechanisms connected to the actuators and the control means and arranged to cause the actuators to actuate the rail regulating valves in response to signals from the control means.

In this case and in the above developments, the regulating device may be a main regulator, and the strand regulating mechanisms may be subregulators, one for each strand.

Further features and exemplary embodiments of the present invention will be explained in more detail below with reference to the drawing. It is understood that the illustrated embodiments do not exhaust the scope of the present invention. It is further understood that some or all of the features described below may be combined with each other in other ways.

FIG. 1 is a flowchart showing steps of an exemplary embodiment of the method according to the invention.

Figure 2 illustrates the operation of a main regulator and n sub-regulators adapted to control a n-string heating system according to an example of the present invention. As shown in FIG. 1, in an example of the method of controlling a heating system in a building, the temperature outside the building is measured 1 and the flow temperature of the heating water is adjusted according to the measured outside temperature, for example by means of previously prepared and provided heating curves 2. A boiler is regulated to treat the heating water with the flow temperature, which is then fed to a strand for distribution to radiators 3. So far, the control method is well known in the prior art.

According to the invention, the return temperature of the heating water after this has, for example, partially passed one or more heating elements and partly a bypass line and has flowed back to the combustion vessel is measured 4. Then, the temperature difference of the heating surfaces via the strand supplied water and the back-flowing water (ie, supply temperature - return temperature) determines 5, and it is checked whether this difference exceeds a predetermined limit or not. If the difference is below the barrier, in the exemplary case heating water is still supplied with the unchanged flow temperature. The barrier may in turn depend on the outside temperature.

If the difference is above the barrier, indicating an increased heat demand of the string, a controller lowers the measured outside temperature 6 and adjusts the flow temperature based on the above-mentioned heating curve according to the lowered (manipulated) outside temperature Flow temperature is delivered. If the difference is smaller than another predetermined threshold, it may be provided that the outside temperature is increased, whereby a lower flow temperature is set. In this case, therefore, as shown in Figure 1, the flow temperature is not maintained. Such a case occurs, for example, when at some time the control devices (eg thermostatic valves) of the heating surfaces of all strands are turned off. In this case, the difference between the flow and return temperatures for these beaches is ge ever smaller, and it can be the flow temperature, after only a small difference of these temperatures was found to be lowered.

It is understood that the modification of the outside temperature depends on the magnitude of the temperature difference between flow and return. For certain heating systems, the change in the outside temperature depending on this difference can be easily determined empirically so that a desired control of the climate in the rooms of the building or a desired saving of the heating energy is achieved. Alternatively or additionally, numerical simulations of the control of the heating system in question may be designed and carried out by a person skilled in the art. Obviously, the effects of a certain modification of the outside temperature depending on certain differences between the flow and return temperatures can be tested and analyzed. In fact, a savings potential for a monotube heating plant controlled according to the invention of up to 20% of the amount of heat compared with a conventionally controlled plant could be demonstrated in detailed simulation calculations. Analogously, this also applies to horizontal single-pipe heating, e.g. with flat distribution.

FIG. 1 shows a simplified illustration of the control principle in that, in general, the heating system to be controlled will comprise more than one strand. In this case, the modification of the measured outside temperature is carried out in accordance with the determined largest difference between the return temperatures of the individual strands and the flow temperature in order to meet the currently largest requirement of a strand. Thus, in a residential building heating water can be supplied through a string directly superimposed rooms. For example, one strand supplies rooms that are typically used as living rooms, another, for example, rooms that are typically used as bedrooms, etc.

In addition, a control of the flow temperature advantageously on the basis of the differences of averaged over a plurality of time intervals flow and return temperatures to avoid unwanted swinging of the control loop by individual outliers. In addition, the flow temperature in predetermined Steps are set over a certain period of time to the value assigned to the modified outside temperature in the heating curve.

Figure 2 shows an example of the realization of the here disclosed control of a heating system using a main controller and n sub-regulators according to n strands, where the heating water is supplied to the flow temperature. The sub-controllers and the main controller communicate data via data lines or by radio. The main controller is connected to a boiler (not shown) and controls the flow temperature S _y1 of the heating _{water provided} by the boiler.

Each sub-controller receives from the main controller, the central or decentralized predetermined flow temperature Q _y1 and entered by a sensor, the return temperature S ^ of its associated strand as input data. As shown in Figure 2, the main _controller receives the outside temperature 3 _ΛU measured by an outside sensor and data, in particular the return temperature 3 _RL , from the sub-controllers. Based on the difference between flow and return temperatures determined by the sub-controllers or the main _controller, the _{main controller} modifies the outside temperature so that the flow temperature S _{y1 is set} using a heating curve based on the modified outside temperature 9 _AUman .

In one embodiment, each sub-controller transmits a change request for the flow temperature according to the heat demand determined via the difference between the flow temperature S _y1 and the return temperature S _{RL of} the line assigned to it. Of the

Main controller receives all change requests (which may include the trivial case that no change is desired) and evaluates the change requests for priority. The request of the string with the highest heat demand results in a change of the flow temperature S _{y1 of} the heating water supplied from a boiler on instruction of the main controller.

As a rule, heating water with approximately the same flow temperature Sy _{1 is} supplied in all strands. The n sub-controllers can, however, their assigned Regulate cords via throttle valves. In accordance with the flow temperature input to them, the sub-regulators can thus regulate the mass flow through their respective strands by sending corresponding valve lift signals ΔHi,..., ΔH _n to actuators of the throttle valves, whereby the amount of heat supplied to the individual strands can be optimized according to current needs.

Claims

claims

A method of controlling a heating system in a building, comprising a heating device having an outlet for supplying heating water and an inlet for receiving the heating water and at least one strand connected at one end to the outlet of the heating device for supplying at least one heating surface with the heating water comprising the steps of:

Determining a difference between a temperature of the heating water on the side of the output of the heater, flow temperature, and a temperature of the heating water on the side of the heater input, return temperature, and

Control the flow temperature based on the determined temperature difference.

2. The method of claim 1, further comprising determining a temperature outside the housing, and controlling the flow temperature based on the temperature determined outside the housing.

3. The method according to any one of the preceding claims, wherein the heating system is a Einrohrheizungsanlage and the at least one strand for supplying the at least one heating surface with the heating water is connected at another end to the input of the heating device.

The method of claim 3, wherein a plurality of strands are connected to the output of the heater such that they are supplied with heating water at the flow temperature, and connected to the input of the heater, and comprising Determining the differences between the flow temperature and temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heater, return temperatures, and in the

the flow temperature is controlled on the basis of the differences between the flow temperature and the return temperatures.

5. The method of claim 1, further comprising determining the largest difference between the flow temperature and the return temperatures, and controlling the flow temperature based on the determined largest difference.

The method of claim 4 or 5, further comprising

Controlling the mass flow of the heating water in at least one strand based on the difference between the flow temperature and the return temperature for that strand.

The method of claim 6, wherein the mass flow is not controlled below a predetermined value.

8. The method according to any one of claims 2 to 7, further comprising

Providing a heating curve that assigns a standard flow temperature to a temperature determinable outside the enclosure, and wherein controlling the flow temperature comprises:

Modifying a temperature determined outside the housing based on the determined difference between the flow temperature and the return temperature or the determined differences between the flow temperature and the return temperatures to obtain a modified temperature; and Regulating the flow temperature to the standard flow temperature assigned by the heating curve of the modified temperature; in which

the modified temperature is minimally modified to the temperature measured outside the housing and / or maximally to a predetermined maximum value.

9. A method of retrofitting a heating system in a building, comprising a heating device with an outlet for supplying heating water and an inlet for receiving the heating water and at least one strand, which is connected at one end to the output of the heating device, for supplying at least one heating surface with the heating water, an outdoor sensor for measuring a temperature outside the housing and a standard controller configured to control the heater based on the measured temperature outside the housing, comprising the steps of:

Installing a measuring device configured to determine a temperature of the heating water on the side of the input of the heater, return temperature, and / or a difference between a temperature of the heating water on the side of the output of the heater, flow temperature, and a temperature of the heating water on the side of the input of the heater, return temperature, to determine, and

Installing another regulator between the outside sensor and the standard controller for controlling the heater, the further controller being adapted to modify the value of the measured temperature outside the housing based on the difference between the flow temperature and the return temperature and the standard Controller to enter the modified temperature value so that the standard controller can regulate the heater based on the modified temperature value.

10. The method of claim 9, wherein the heating system is a one-pipe system in which a plurality of strands is connected to the output of the heating device, such that they heating water is supplied to the flow temperature, and is connected to the input of the heater, and being in the process

the measuring device is adapted to measure temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heating device, return temperatures, in at least a part of the plurality of strands on the side of the input of the heating device and / or differences between the Flow temperature and temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heater, return temperatures to determine, and

the further controller installed between the outdoor sensor and the standard controller is adapted to modify the value of the measured temperature outside the housing and to input the modified temperature value to the standard controller based on the differences between the flow temperature and the return temperatures ,

11. The method according to claim 9 or 10, wherein the heating system comprises regulating or throttling devices, in particular balancing valves, at the ends of strands or heating circuits on the side of the output of the heating device and further comprising

Incorporation of strand control mechanisms;

Installation of actuators;

Connecting the actuators to the strand control mechanisms; and

Connecting the strand control mechanisms to the other regulator built in between the outside sensor and the standard regulator; in which the strand control mechanisms are adapted to cause the actuators, in response to signals from the further regulator, to actuate the strand regulating valves.

12. Heating system, comprising

a heating device having an outlet for supplying heating water and an inlet for receiving the heating water and at least one strand connected at one end to the outlet of the heating device for supplying at least one heating surface with the heating water;

a measuring device configured to determine a temperature of the heating water on the side of the input of the heater, return temperature, and / or a difference between a temperature of the heating water on the side of the output of the heater, flow temperature, and a temperature of the heating water the side of the input of the heater, return temperature to determine; and

a controller connected to the heater and the meter and configured to control the flow temperature provided by the heater based on the difference between the flow temperature and the return temperature.

13. The heating installation according to claim 12, in which the heating installation is a single-pipe heating installation comprising

a plurality of strands connected to the output of the heater such that they are supplied with heating water at the flow temperature and connected to the input of the heater, and in the

the measuring device is adapted to return temperatures in at least a part of the plurality of strands on the side of the entrance of the heating device to determine and / or differences between the flow temperature and temperatures of the heating water in at least a part of the plurality of strands on the side of the input of the heater, return temperatures, and in the

the control means is adapted to control the flow temperature based on the differences between the flow temperature and the return temperatures.

14. The heating system according to claim 12 or 13, further comprising an outdoor sensor for measuring a temperature outside the housing, and in which the control means is adapted to control the flow temperature based on the temperature measured by the outdoor sensor outside the housing.

15. The heating system according to claim 13 or 14, further comprising

Regulating or throttling devices, in particular balancing valves, at the ends of strands or heating circuits on the side of the output of the heating device;

Actuators connected to the balancing valves for actuating the same; and

Strand control mechanisms connected to the actuators and the control means and arranged to cause the actuators to actuate the rail regulating valves in response to signals from the control means.