SE536751C2 - Method and apparatus for regulating the indoor temperature of a property - Google Patents

Abstract

Method for regulating the indoor temperature in a property comprising an existing system. (210) for controlling said indoor temperature, which system is arranged to direct a heating (22l, 23l) or cooling medium past a heating or cooling element son1 in turn is arranged to heat. or the cooling indoor air. in the property. by transferring heat energy between the heating or cooling medium and the indoor air, and the existing system is arranged to read the temperature of the medium via at least one input for a signal representing a measured temperature of the medium at a certain food number (212.2l3.24, 2l5,2l6,2l7) with the medium along the vague through the system. The invention is characterized in that the method comprises the steps a) determining a desired instantaneous heating or cooling effect as. the system is desired to deliver to the property's indoor air; b) based on knowledge of the properties of the system and using the rule algorithm. a fictitious' temperature * son1 the fictitiously fed temperature of the medium at said food stall which would give rise to the desired instantaneous effect; and c) the said input 'with. a signal that. represents the fictitious temperature. Application text document 2012-10-18 120039EN

Description

Many such systems are controlled by means of an integrated control device, which regulates the heating and cooling effect of the system by means of a predetermined control algorithm, based on the current operating situation in terms of, for example, actual and setpoints for the indoor temperature.

Such control algorithms are often quite effective in keeping the indoor temperature within a certain predetermined range. However, in many cases it is desirable to be able to control the power of such a system according to an alternative control algorithm, for example where information is taken into account which the integrated control device is not arranged to take into account. In particular, in many cases it is desirable to be able to control such systems1 remotely, such as from a central control device which is arranged to control several such systems for heating and / or cooling.

To achieve this, however, intervention in, or replacement of, the integrated control device is generally required, which is costly.

The present invention solves the problems described above.

Thus, the invention relates to a method for controlling the indoor temperature in a property comprising an existing system for controlling said indoor temperature, which system is arranged to guide a heating or cooling medium past a heating or cooling element which in turn is arranged to heat or cool the indoor air in the property by transferring heat energy between the heating or cooling medium and the indoor air, whereby. the existing system is arranged to read the temperature of the medium via at least one input for a signal representing a 'measured temperature' of the medium at a certain measuring point along the path of the medium through the system, and wherein a control device belonging to the existing system is arranged to, based on the value of said measured temperature, control the existing system to emit an instantaneous heating or cooling effect, and is characterized in that the method comprises the steps a) determining a desired instantaneous heating or cooling effect which the system is desired to emit to the property's indoor air; b) based on knowledge of the properties of the system and using control algorithm, calculate a fictitious' temperature as. the fictitiously measured temperature of the medium at said measuring point which, via said control device, would give rise to the desired instantaneous effect; and c) supplying said input with a signal representing the fictitious temperature.

The invention also relates to a device for carrying out such a method.

The invention will now be described in detail, with reference to exemplary embodiments of the invention and the accompanying drawings, in which: Figure 1 is a schematic diagram of a conventional system for heating or cooling the indoor air in a property; Figure 2 is a principle sketch of the system according to figure 1 supplemented by. a device according to the present invention; and Figure 3 is a schematic diagram of a diving pipe with a temperature sensor device according to the invention.

Figure 1 shows a property in the form of a house 100 comprising a system 10 for heating and cooling the indoor air in the house 10, respectively. It is preferred that the housing 100 be a multi-family house, but the invention is also applicable to small houses. The system 110 may be arranged to heat and / or cool one or more houses, in the latter case preferably several houses which are located in the vicinity of each other.

The system 110 is arranged to control the housing 100, the indoor temperature in and for this purpose comprises a control device 111, which preferably forms an integral part of the system 110.

Furthermore, the system 110 comprises a heat pump device 120 of the air-air type, arranged to transfer heat between the outdoor air at the housing 100 to the indoor air. The heat pump device 120 is connected to a fan convector 121, via pipelines 122 for a medium. In a conventional manner, the heat pump device 120 can be operated to heat or cool the indoor air in the housing 100. The heating and cooling effect of the heat pump device 120 can be regulated by means of a pump 123.

In addition, the system 110 includes a heat exchanger device 130 for receiving, via pipelines 132 for an external medium, and utilizing heat or cooling supplied in the form of district heating or district cooling. The heat exchanger device 130 is arranged to distribute such heat or cooling, via an internal medium in pipelines 133 and radiators 131 inside the housing 100.

The heating and cooling power of the heat exchanger device 130 can be regulated by means of a pump 134.

The control device 111 is arranged to control the power of the heat pump device 120, by controlling the pump 123, based on measured values for the momentarily measured temperature of the medium in the pipelines 122, partly upstream of the fan convector 121, partly downstream of the fan convector 121. The temperature 10 15 20 25 30 536 751 in question are measured by means of temperature sensors 114 and 115 connected to the control device 111, respectively.

On. correspondingly, the control device 111 is arranged. to control. out the effect. of the heat exchanger device. 130 to control the pump 134 based on the corresponding instantaneous temperatures of the medium in the pipelines 133 upstream and downstream of the radiators 131, respectively, measured by temperature sensors 116 and 117, respectively.

For the regulation. of the devices 120, 130, the control device 111 may also be connected to one or more outdoor temperature sensors 113 and one or more indoor temperature sensors 112.

It will be appreciated that the heat pump device 120, which gives rise to heat or cooling by local heat pumping to the outdoor air, and the heat exchanger device 130, which. gives rise to heat or cold through. externally supplied. such heating or cooling, are only two examples of the different systems. for heating and / or cooling to which the present invention is applicable. The invention is applicable to essentially any combination of one or more different systems for heating and / or cooling, based on heat pumping and / or heat exchange, and uses local and / or external heat and / or cooling sources, as long as control devices 111 is arranged to control the used systems 120, 130 based on at least an instantaneously measured temperature of a medium flowing in a pipeline upstream and / or downstream of a thermal load in the form of a convector, a radiator or other equipment. which is arranged to heat and / or cool the indoor air in the housing 100. It is preferred that the wet point or points for the temperature of the medium on which the equipment or devices are based are located indoors.

The system 110 is thus arranged to direct the heating or cooling medium past a heating or cooling element 112, 133 which in turn is arranged to heat or cool the indoor air in the housing 100 by transferring heat energy between the heating or cooling medium and the indoor air, and the system l10 is further arranged to read the temperature of the medium via at least one input for a signal representing a measured temperature of the medium at a certain measuring point ll4, ll5, ll6, ll7 along the path of the medium through the system.

It is preferred that the control device III use a per se known and conventional control algorithm to control the indoor temperature in the housing 100 as efficiently as possible within a permissible temperature range, based on the temperature data available for the control device III. An example of such a control algorithm is a conventional PID control.

Figure 2 shows the same property with the same housing 200 as in Figure 1, but to which property the present invention has been applied. Figure 2 has the same reference numerals as Figure 1 for the same parts, for the last two digits of each reference numeral. The first digit of each reference numeral is always “1” in Figure 1 and “2” in Figure 2.

Figure 2 shows a control device 240, which may be arranged locally in the property, but which is preferably arranged outside the property. It is especially preferred that several houses 200 in several properties are connected to one and the same control device 240, which can then control the supply, of heat and / or cooling to all connected such houses 200. This gives partly scale advantages. , and the possibility of load balancing available heat and / or cooling between the connected housings 200.

It is preferred that the control device 240 not be directly connected to any stable devices which directly control the flow of medium in the system 210 pipelines 222, 232, 233, especially that the control device 240 not be connected to any stable devices which the control device 211 uses to control heating and / or or the cooling effect, such as the pumps 223, 234.

In addition, it is preferred that the control device 240 be not directly connected to the control device 211, except possibly via one or more existing inputs of the control device 211 for the temperature sensors 212, 213, 214, 215, 216, 217, see below.

On the other hand, a system according to the invention comprises a signal device, which in turn is arranged to be controlled out of the control device. 240 and. sonl ar arranged. to feed. a signal representing a fictitious temperature to one or more of the existing inputs of the control device 211 via which the control device or devices 211 are arranged to read the temperature of the medium in the form of a signal representing a measured temperature of the medium at a certain food stall 214, 215, 216, 217 along the vagus of the medium through the system. Thus, in the example illustrated in Figure 2, these inputs constitute the connections to the control device 211 for the cables which pass between the temperature sensors 212, 213, 214, 217 and 215, 216, the control devices 211.

In the exemplary embodiment illustrated in Figure 2 between 216 and in addition the signal device of connections 215, the control device 240 and the temperature sensors 214, 217, as well as any devices in direct connection to 536 751 and measuring point 214, 215, 216, 217, respectively. In other embodiments (see below), the signaling device may also comprise, for example, connection cables between the places for temperature measurement and the control device 211.

There are several possible sets for the control device 240 to, via the signal device, supply the control device 211 with a signal representing a fictitiously measured temperature. The essential thing is that the control device 211 is supplied with a signal which for the control device 211 does not differ significantly from a signal which had come from a temperature sensor which is intended for conventional use with the control device 211.

A first example is the signaling device. 240 is directly connected to the respective input of the control device 211, and that the signal device 240 supplies this input with a signal, in a suitable format and accepted by the control device 211, which represents the fictitious temperature.

A second example is that the respective temperature sensor 214, 215, 216, 217 is replaced with a part of the signal device, so that the existing connection between the respective temperature sensor and the control device 211 is used to transmit a signal, representing the fictitious temperature, from the place where the temperature sensor was originally present for the control device 211. In this case, therefore, the part of the signal device which replaces the original temperature sensor must supply the signal in a format corresponding to that supplied by the original temperature sensor in question.

A third example is that the input of the control device 211 is supplied with the fictitious temperature in that a temperature controlling part of the signal device is arranged to control the temperature in a local environment to the existing temperature sensor 214, 215, 216. , 217, which. maintained, to the fictitious temperature. Thus, the existing temperature sensor 214, 215, 216, 217 will assume the fictitious temperature, and. therefore also. feed. a signal representing this fictitious temperature to the control device 211. In this case, therefore, no special considerations need to be made regarding the signal format, since the existing temperature sensor is used.

Figure 3 illustrates a particularly preferred way for the signal device to supply the control device 211 with a signal representing the fictitious temperature, with. by means of a temperature chamber device 300 according to the invention.

The temperature chamber device 300 includes an elongate temperature sensor device 320, which is located in a dip tube 312 arranged in a conduit 310 for the medium at the particular measuring point 214, 215, 216, 217, so that the temperature sensor device 320 extends a distance in the diving pipe 312 and thus is in thermal contact with the medium 311 inside the pipeline 310. The pipeline 310 is shown in figure 3 in cross section.

However, the point where the temperature is actually measured along the longitudinal direction of the temperature sensor device 320, in the illustrated example by and with the aid of a temperature sensor 321, is located outside the diving tube 312, outside the cross-sectional periphery of the pipeline 310. The temperature sensor 321, which may be of a conventional type per se, such as a so-called PT element, is further connected to the above-mentioned respective input of the control device 211 by means of a line 322. The line 322 and the signal format are selected so that they are compatible with the current input of the control device 211.

W ü 20 25 30 536751 A temperature regulating device 330 in the form of a temperature chamber is arranged to regulate the temperature in a local environment to the temperature sensor 321 to the desired fictitious Thus, the measured value, the temperature. the temperature sensor, which is also communicated to the control device 211, to be the fictitious temperature.

The temperature sensor 321 may be the existing temperature sensor, which was originally arranged inside the diving tube 312, which. can also be an existing submersible pipe ~ in the system, which before the initial step housed the existing temperature sensor.

In this way, in an initial step before starting operation according to the invention, only supplementing an existing temperature sensor with a temperature sensor device 320 and a temperature regulating device 330, the signal device can be achieved in a cost-effective manner.

With. thus, by means of the temperature regulating device 330, the temperature sensor 321 can be made to register. however, it is desirable that a signal representing the actual temperature of the medium 311 in the pipeline 310 be fed to the controller. this is achieved in the order 211, by. to turn off the temperature regulating device 330. Then comes the immediate vicinity of the temperature sensor 321, and thus also the temperature sensor. 321 itself, via heat conduction 'through the device. 320, soon to be adopted. a temperature son1 is close to the actual temperature of the medium 311. In this connection, it is preferred that the device 320 comprises an elongate metal structure with good thermal conductivity, such as an elongated metal tube, which runs from the temperature sensor 321 and down into the diving tube 312. According to the invention, the control device 240 is arranged to first determine a desired instantaneous heating or cooling effect which the system 210 is desired to deliver to the indoor air in the housing 200, then, and based on knowledge of the properties of the system 210 and use control algorithm, calculate a fictitious temperature as the fictitiously measured temperature of the medium at said measuring point which, hypothetically, would give rise to the desired instantaneous heating or cooling effect. The control device 240 is further arranged to, in one of the ways discussed above, then supply an input of the control device 211 for a signal from a temperature sensor with a signal representing the fictitious temperature.

Since the control algorithm used by the control device 211 is known, and is typically readily available via, for example, manuals, and results in an equipped heating or cooling effect based on one or more measured values from one or more temperature sensors, the control device 240 can use this knowledge for to first calculate which fictitious such measured values from one or more temperature sensors would result in a certain desired equipped power, and then supply the control unit 211 with these fictitious measured values.

Thereby, the control device 211 will use these fictitious measured values and thus control the system 210 to the desired heating or cooling effect.

The actual calculation scheme for calculating one or more fictitious temperatures based on a desired hypothetically effected effect is suitably performed by means of a software module in the control device 240, which can be adjusted, for example, via appropriate choice of parameters to reflect each specific type of control device 211. 11 10 15 20 25 30 536751 In order to increase the precision of this equipment, it is preferred that the control device 240, for each individual temperature sensor 212, 213, 214, 215, 216, 217 which is connected to the control device 211, is either arranged to supply the corresponding input of the control device 211 with a signal corresponding to a respective fictitious temperature measured value, or is itself connected to a temperature sensor which measures the corresponding temperature in parallel. In the latter case, the controller 240 may use such parallel measured temperatures in the calculation of the fictitious object. temperatures' as. shall be supplied to the control unit 211. Figure 2 shows two exemplary such temperature sensors 241, 242, viz. to measure the outdoor temperature at parallel to the temperature sensors 213 and 212 respectively. the housing 200 and the indoor temperature in the housing 200, respectively.

Especially if the system 210 is a heating system, it is preferred that the temperature sensors for outdoor air 241 and indoor air 242 be used in this manner.

According to a preferred embodiment, the control device 211 in the system 210 is arranged to read the temperature of the medium via at least two inputs for a signal representing a respective measured temperature of the medium at two respective measuring points. 214, 215; 216, 217 along the path of the Inediet 'through the system 210, between which measuring points. the medium passes an element 221; 231. Namely, the fictive temperature can then be calculated as the fictitious temperature difference of the medium after passing past the element 221; 231 which would give rise to the desired heating or cooling effect. In this case, the two respective inputs of the control device 211 are fed with respective respective temperatures, where the difference between these fed temperatures is the said fictitious temperature. Particularly in cooling systems, such equipment can be provided without the signal from any other temperature sensor, possibly in addition to a temperature sensor 212 for the indoor temperature in the housing 200, to the control device 211 being either overridden or replicated, by means of sensor 242, to the control device 240. Particularly preferred is that the system 210 in this case is a system for cooling indoor air, where the cooling is provided via either district cooling or local cooling by means of, for example, a cooling heat pump or a local cooling storage.

The control device 211 is typically of the so-called black box type, and in any case can not easily be influenced more than to a limited extent with regard to its equipment by the system 210, especially not via automatic. With the aid of the present invention, an inability to achieve the control device is achieved. 240 to perform such an automated actuation 211, without the actual control algorithm used by the control device 211 having to be adjusted per se. Thus, information regarding factors other than those known for the control device 211 can be used to optimize the control of the system 210.

Such additional information includes information about future events, such as experience-based or planned use of the house 200, such as information that a conference will take place at a certain time after which substantially fewer people will be in the house 200; or * weather forecasts. Other examples of additional information may include knowledge of, for example, current solar radiation towards the house 200, especially with regard to differences in solar radiation towards different rooms in the house 200, and current operating conditions for a central heating or cooling source, such as a district cooling system approaching its maximum effect. With such knowledge, appropriate measures can be taken, such as regulating the cooling effect for a certain time before the end of the conference; start heating a certain time before one or more rooms are to be used or before an expected cooling of the local weather; implement automatic control according to algorithms not supported by the existing control device 211, such as. to reduce cooling during weekends in office properties; temporarily accept higher temperatures in certain rooms against which the solar radiation is currently unusually strong; increase the cooling or heating effect during times of the day when the electricity tariff is lower; or manage power peaks when operating a central district cooling or district heating plant by allocating the available power. over a number of properties without deviating from a desired respective temperature range more than necessary. such information may be connected to an external source of information 243, such as a weather forecast server, the Internet or another suitable external and / or centrally located source of information.

According to a particularly preferred embodiment, an existing system 110 is supplemented with a control device 240 as above.

In this way, the flexibility of the temperature control in the housing 100 can be increased in a cost-effective and simple manner. Correspondingly, a plurality of properties can in this way be connected to a common control system comprising the control device 240, so that a centralized temperature control of several properties can be achieved at a relatively low cost.

It is further preferred that the above-described inputs for signals from the temperature sensor to the control device 211, each 212, 213, 214, 215, during operation of the system 210 be supplied with a signal representing the actual temperature of the medium at the respective measuring point, except. when a certain future event is expected to occur. In other words, during operation of the system in this case there is a temperature sensor which continuously measures the actual temperature of the medium at the respective measuring point.

The future event in question is of a type that affects the need for heating or cooling of the indoor air in the future, and may for example be of one of the types discussed above. It is preferably about. a time-discrete future event with. a well-defined start and. a well-defined ending.

Before or before such an event, according to this embodiment, the said input is instead temporarily supplied with a signal representing the calculated fictitious temperature, so that the system 210 heats or cools the indoor air with a different effect than what would have been the case of the input in question. constantly fed with a signal representing the fact- after the temperature. Correspondingly, the event can be completed. In this way, the functionality of the system 110 can be expanded in a cost-effective and simple manner.

Preferred embodiments have been described above. However, it will be apparent to those skilled in the art that many changes may be made to the described embodiments without departing from the spirit of the invention.

For example, it will be appreciated that more temperature sensors than those illustrated 212-217 may be used, correspondingly. Other types of sensors, such as light sensors and clocks, can of course also be connected to the control unit 211.

Furthermore, the figures show the connections between the control device 24O and the temperature sensors 212-215, and between the temperature sensors 212-217 and the control unit 211, as fixed cable connections 536 751 connections. It is understood that these connections can also be arranged, for example, as wireless connections, or connections “via the Internet. This. also "the connection" between the controller 240 and the external data source 243.

Finally, the control device 111, 211 can control the heating and / or cooling devices 120, 130 in another, inherently conventional manner, set by controlling the pumps 112, 134.

Thus, the invention should not be limited by the embodiments described, but may be varied within the scope of the appended claims. 16

Claims (14)

10 15 20 25 30 536 751 P A T E N T K R A V A method of controlling the indoor temperature of a property comprising an existing system (210) for controlling said indoor temperature, the system being arranged to direct a heating or cooling medium past a heating or cooling element (221,231) son1 in its luck is arranged to heat or cool the indoor air in the property through. to transfer heat energy between the heating or cooling medium and the indoor air, the existing system being arranged to read the temperature. of the medium via at least one input 'for' a signal representing a measured temperature of the medium at a certain height (212,2l3,2l4,2l5,2l6,217) along the path of the medium through the system, and wherein a control device (211) belonging to the existing system is arranged to, based on the value of said measured temperature, control the existing system to emit an instantaneous heating or cooling effect, characterized in that the method comprises the steps a) determining a desired instantaneous heating or cooling - effect that the system is desired to give off to the property's indoor air; b) based on knowledge of the properties of the system and using control algorithm, calculate a fictitious temperature as the fictitious measured temperature of the medium at said measuring point which, via said control device, would give rise to the desired instantaneous effect; and c) supplying said input with a signal representing the fictitious temperature. The method of claim 1, wherein the system (210) is arranged to read the temperature. of the medium via at least two inputs for a signal representing a respective measured temperature of the medium at two respective certain measuring points (214.215; 216.217) along the path of the medium through the system, between which measuring points the medium passes the element (22l; 23l), characterized in that, in step b), the fictitious temperature is calculated as the fictitious temperature difference of the medium after * passage past the element as. would give rise to the desired effect, and that, in step c), the two inputs are fed with their respective temperatures, where the difference between these fed temperatures is the fictitious temperature. 3. A method according to claim 1 or 2, characterized in that the input is fed with the fictitious temperature by causing the temperature in a local environment to an existing temperature (321), temperature sensors connected to the input to be regulated to the fictitious temperature. A method according to any one of the preceding claims, characterized in - drawing rod (320), that, in an initial step, a temperature comprising a temperature sensor (321), (312) sensor device is placed in a diving tube arranged in a conduit for the medium at the certain measuring point, so that the temperature sensor device extends a distance into the diving tube but so that the point where the temperature is actually measured along the temperature sensor is outside where the temperature sensor device arranged the diving tube is made to be connected to the inlet, and by, in step c), the signal is fed to the input by causing the temperature in a local environment to the said point to be regulated to the fictitious temperature. so that the measured value of the temperature sensor device becomes the fictitious temperature. Method according to claim 4, characterized in that the diving tube is an existing diving tube in the system (210), 18 10 15 20 25 30 35 536 751 which housed an existing temperature sensor before the initial step. k ä n n e - (210) Method according to one of the preceding claims, characterized in that the input during operation of the system is supplied with a signal representing the actual temperature of the medium at the measuring point (214,215,216,217), except when a certain future event is expected to occur, which event affects the need for heating or cooling of the indoor air in the future, whereby. the input is instead temporarily fed with. a signal representing the fictitious temperature so that the system heats or cools the indoor air with a different effect than would have been the case if the input had been constantly supplied with a signal representing the actual temperature. A method according to any one of the preceding claims, characterized in that the system (210) is a system for cooling indoor air, where the cooling is effected via either district cooling or local cooling by means of a cooling heat pump or a local cooling storage. An apparatus for controlling the indoor temperature of a property comprising an existing system (210) for controlling said indoor temperature, the system being arranged to direct a heating or cooling medium past a heating or cooling element (221,231) in its luck is arranged to heat or cool the indoor air in the property through. to transfer heat energy between the heating or cooling medium and the indoor air, the existing system being arranged to read the temperature. of the medium via at least one input 'for "a signal representing a measured temperature of the medium at a certain measuring point (212,2l3,2l4,2l5,2l6,217) along the path of the medium through the system, and wherein a control device (211) belonging to the existing system is arranged to, based on the value of said measured temperature, control the existing system to emit an instantaneous heating or cooling effect, characterized in that the device comprises a control device ( 240), arranged to determine a desired instantaneous heating or cooling effect which the system is desired to deliver to the indoor air, and, based on knowledge of the properties of the system and use control algorithm, to calculate a fictitious temperature as the fictitious measured temperature of the medium at said measuring point. via said control device, would give rise to the desired instantaneous effect, and from the fact that the device also comprises a signal device which is arranged to be controlled out of the control device. and. to feed. a signal representing the fictitious temperature of said input. The device of claim 8, wherein the system (210) is arranged to read the temperature. of the medium via at least two inputs for a signal representing a respective measured temperature of the medium at two respective certain measuring points (214.215; 216.217) along the path of the medium through the system, between which measuring points the medium passes the element (221; 231) , characterized in that the control device (240) is arranged to calculate the fictitious temperature as the fictitious temperature difference of the medium after passage past the element which would give rise to the desired effect, and in that the control device is arranged to supply the two inputs via the signal device with each respective temperature, where the difference Between these. fed temperatures ”is the fictitious temperature. 10. l0. Device 'according to claim EB or "9, characterized in that the device comprises a temperature regulating device (330), arranged to regulate the temperature in a local (321) device environment to an existing temperature sensor to the fictitious the temperature, and that the existing temperature sensor is connected to the input. Device according to any one of claims 8-10, characterized in that the device comprises a temperature sensor device (320), comprising a temperature sensor (321), which is placed in a diving pipe (312) arranged in a pipeline (310) for the medium (311) at the particular measuring point, so that the temperature sensor device extends a distance into the diving tube but so that the point where the temperature is actually measured along the temperature sensor device. is arranged. outside the diving tube, in that the temperature sensor device is connected to the input, and in that the signal is fed to the input by means of a temperature regulating device (330) arranged to regulate the temperature in a local environment to the said point to the fictitious temperature sensor device. the fictitious temperature. Device according to claim 11, characterized (312) in that the diving tube is an existing diving tube in the system (210), and in that the system is modified so that an existing temperature sensor, which was previously housed in the diving tube, is replaced by the device temperature sensor device (320). Device according to one of Claims 8 to 12, characterized in that the control device (240) is arranged to supply the input during operation of the system (210) with a signal representing the actual temperature of the medium at the measuring point ( 214,215,216,217), except when a certain future event is expected to occur, which event affects the need for heating or cooling of the indoor air in the future, the control device being arranged to instead supply the input with a signal representing the fictitious temperature so that the system the heat heats or cools the indoor air with an effect other than what would have been the case if the inlet had been constantly supplied with a signal representing the actual temperature. Device according to one of Claims 8 to 13, characterized in that the system (210) is a system for cooling indoor air, in which the cooling is effected via either district cooling or local cooling. using a cooling heat pump or a local cooling warehouse. 22