EP4212786A1 - Method for defrosting an air inlet grid of an evaporator of an air heat pump, device for carrying out the method and computer program product - Google Patents

Abstract

The invention relates to a method and a device for defrosting an air inlet grille (2) of an evaporator or heat exchanger (3) of an air heat pump, with a reverse flow of air (U) is generated through the evaporator (3) to the air inlet grille (2) and through it. The invention allows an air inlet grille (2) in front of an evaporator or heat exchanger (3), which is iced up due to weather conditions and/or operation, to be defrosted even at very low ambient temperatures below the freezing point of water and/or unfavorable wind conditions.

Description

The invention relates to a method for defrosting an air inlet grille exposed to the ambient air of a heat exchanger or an evaporator of an air heat pump, which extracts heat from the ambient air during normal operation. B. for heating a building and / or for heating domestic water. Ambient air is always understood here as the outside air, outside of buildings, even if the evaporator or heat exchanger itself is arranged in a building, for example a frost-free installation room. In such a case, the evaporator or heat exchanger is also traversed by outside air, which is conducted via suitable flow paths. The invention further relates to a computer program product for executing a method for defrosting an evaporator or heat exchanger of an air heat pump.

During normal operation, an evaporator of an air heat pump has a very cold coolant flowing through it inside, the temperature of which is significantly below that of the ambient air, heat being extracted from the ambient air and evaporating the coolant. In particular, parts of the outer surface of the evaporator can assume temperatures below the freezing point of water. This also applies accordingly to other heat exchangers that use brine as a heat transfer medium, for example. As a result, moisture from the air (water vapor) is condensed and freezes on these parts to form water ice. As this ice increases in thickness, it impedes heat exchange and can even lead to mechanical damage to the evaporator or heat exchanger. It is therefore customary to defrost icy evaporators or heat exchangers as required or periodically. For example, a heat pump can be operated in reverse (it then works like an air conditioner or refrigerator), whereby the inner surface of the evaporator (which then serves as a kind of condenser) is heated and ice on its outer surface is thawed as a result. The ice turns into liquid water, which drips off and can be drained away. However, icing occurs on evaporators or heat exchangers exposed to the ambient air, especially at low ambient temperatures, in particular at temperatures of the ambient air below the freezing point of water. This makes defrosting more difficult, while unfavorable wind conditions (wind direction and speed are important parameters) can cause additional difficulties.

Nevertheless, there are various suitable methods for defrosting the evaporator itself, which also work under difficult conditions. In some cases, an additional electric heater is switched on, which feeds heat into the system (somewhere). However, an air inlet grille typically located in front of the evaporator or heat exchanger was not included in the previous considerations. Since this is often close to the evaporator or heat exchanger and is even the first to be traversed by possibly moist ambient air, such an air inlet grille can also ice up, which on the one hand impedes the air flow to the evaporator or heat exchanger and on the other hand can lead to damage. There are also lamellar, adjustable entrance grilles whose mechanical function can be impaired by icing. Separate devices for de-icing an air inlet grille have not been customary to date and are also difficult to implement.

The object of the present invention is therefore to at least partially alleviate the problems described with reference to the prior art. In particular, the invention should include the creation of a method and a device for carrying out this method for defrosting or de-icing an air inlet grille of an evaporator or heat exchanger of an air heat pump and an associated computer program product. Additional or extensive equipment of the air heat pump should be avoided as far as possible.

A method and devices as well as a computer program product according to the independent claims serve to solve this task. Advantageous refinements and developments of the invention are specified in the respective dependent claims. The description, in particular in connection with the figures, illustrates the invention and specifies further exemplary embodiments.

A method for defrosting an air inlet grille of an evaporator or heat exchanger of an air heat pump contributes to this, in which during and/or (chronologically) after defrosting of the evaporator or heat exchanger and before it cools down again, a reverse flow of air is directed through the evaporator to the air inlet grille and through it is produced.

So far, attempts have always been made to keep the heat losses to the ambient air as low as possible when defrosting an evaporator or heat exchanger so that the overall efficiency of a system is not influenced too negatively by such processes. This means that, for example, a fan has been switched off and/or the entry of ambient air through flaps or the like has been reduced as far as possible. Thus, the heat supplied to the evaporator or heat exchanger was practically only used for its de-icing. It was not taken into account that, depending on the weather conditions, an air inlet grille can also ice up and then significantly impede the air flow, which also affects the overall efficiency of the system in the long term if no de-icing takes place.

In the method described here, however, not only is an air flow through the evaporator or heat exchanger prevented, but also a reverse flow of air from the evaporator or heat exchanger during and/or after the defrosting of the evaporator or heat exchanger, i.e. in particular when it is warmer than the ambient air generated by the air inlet grille. This airflow should be limited so that little(er) heat is given off to the environment, but the inlet grille can still be heated and defrosted. It has been found that an airflow of at most 10%, preferably under 5%, of the maximum forward airflow during normal operation as an air source heat pump can be sufficient for this. Wind and other weather conditions can be taken into account when regulating this air flow.

The method for defrosting the air inlet grille can be automatically linked to a defrosting process of the evaporator or heat exchanger. It can be provided that the defrosting process of the evaporator or heat exchanger starts first and then, possibly after a sensory check of environmental parameters and/or a predetermined time interval, the method for defrosting the air inlet grille is initiated. It is possible that the defrosting process of the evaporator or heat exchanger ends first and then, possibly after a sensory check of ambient parameters and/or a predetermined time interval, the method for defrosting the air inlet grille is ended. It is possible that the procedure for defrosting the air intake grille and the defrosting process of the evaporator or heat exchanger (only) partially overlap in time, In particular, it can be provided that there is at least one time period in which only the defrosting process of the evaporator or heat exchanger is carried out. It is possible that the defrosting process of the evaporator or heat exchanger is completed first and then (possibly immediately) the defrosting of the air inlet grille is initiated (and ended again later). In particular, it is provided that not every defrosting process of the evaporator or heat exchanger automatically involves a (simultaneous and/or overlapping) execution of the defrosting of the air inlet grille. Methods and devices are set up in particular in such a way that, for a defrosting process of the evaporator or heat exchanger, defrosting of the air inlet grille can be initiated or omitted as desired.

The defrosting of the air inlet grille includes a targeted or sufficiently intensive heat transport from the evaporator or heat exchanger (or their immediate vicinity) to the air inlet grille, which takes place by means of the reverse air flow. The reversed air flow runs (unlike in normal operation of the air heat pump) from the evaporator or heat exchanger (or their immediate vicinity) to the air inlet grille. The air inlet grille regularly represents a boundary to the outside environment of the heat pump, so that the reverse air flow when defrosting the air inlet grille is at least partially directed through the air inlet grille into the outside environment. In particular, the defrosting of the air inlet grille is designed in such a way that ice build-up can actually be defrosted and not just a thin layer of frost.

The above-mentioned sensory testing of environmental parameters can include the following, for example: It is measured and checked whether a predefined humidity and/or temperature limit value has currently been reached. A measurement is carried out in particular using temperature and/or humidity sensors, and their measurement signals can be evaluated. A reverse flow of air can e.g. B. (only) then activated, if the formation of frost formations or ice build-up on the air inlet grille is likely due to the climatic environmental conditions, e.g. B at an air temperature below 7°C and/or relative humidity above 80% r. f.

The air heat pump is preferably switched over for or during defrosting, so that heat is supplied to the evaporator instead of being taken from the ambient air there. This switchover can be maintained until the air inlet grille has also (mainly or even completely) been defrosted. The changeover that has traditionally been used to defrost the evaporator can also provide enough heat under most conditions to also defrost the air intake grille when needed.

Alternatively or additionally, an electric heater can also be used during defrosting, particularly in the case of heat exchangers or non-switchable systems. This means in particular that for the defrosting process of the evaporator or heat exchanger, an electric heater can be provided and activated, which generates an increase in the temperature (of the ambient air) at the evaporator or heat exchanger, which is then (partially) transported by the reversed air flow to the air inlet grille.

In a preferred embodiment, the direction of flow of an existing fan of the air-to-air heat pump is switched over to generate the reverse air flow. This does not require any additional components or devices if the fan already allows switching due to its design, otherwise this could possibly also be adjusted accordingly in a computer program product for controlling the fan and/or the air heat pump. Otherwise, a separate fan can be switched on, which can have a significantly lower output than the actual fan.

In a preferred embodiment, a reverse flow of air from the evaporator or heat exchanger to the air inlet grille is maintained during the entire defrosting process of the evaporator or heat exchanger and air inlet grille. This means a time saving compared to successive defrosting processes. If the air flow is weak and its strength is maintained by suitable control, even against and with wind, the heat losses to the environment caused by the reverse air flow are small.

In particular, the reverse air flow should have such a (flow) speed that the flowing air, after passing through the air inlet grille, is 1 to 10 K [Kelvin], preferably 3 to 6 K, above the freezing point of water there. On the one hand, defrosting of the air inlet grille is thus ensured, but an unnecessarily large amount of energy is not released to the environment through the air inlet grille.

The air flow through the evaporator and/or the air inlet grille is observed and compared with reference data to detect the need to defrost the air inlet grille and/or a degree of icing that is still present during defrosting of the air inlet grille when the evaporator or heat exchanger has already been defrosted. For this purpose, all sensors that are typically present in an (air heat pump) system anyway and serve to monitor the function of the air heat pump can be used. If the air flow through the evaporator is detected directly and/or indirectly by sensors, it is not easy to distinguish between icing of the evaporator or heat exchanger and one of the air inlet grille, since both impede the air flow. After the evaporator or heat exchanger has been defrosted, however, such an obstruction can only be caused by the air inlet grille, so that icing can then be detected there. The same goes for other metrics that show whether the air heat pump is working correctly. If there are characteristic deviations from stored reference data (calibration data), it can be concluded that the air inlet grille is icing up, particularly if the evaporator or heat exchanger has just been defrosted. A particularly high level of reliability when diagnosing the state of the air inlet grille can be achieved by an inlet sensor between the air inlet grille and the evaporator or heat exchanger, in particular a flow sensor or a pressure sensor. Such can also be used particularly well to regulate the reverse air flow.

When detecting the need to defrost the air inlet grille as required, a (partial) blockage of the flow cross section of the air inlet grille can be detected directly or indirectly by suitable sensors and the reverse air flow can then be activated if necessary. A sensor signal evaluation and evaluation can be carried out or executed by a control unit. If the sensor signal limit values stored in the control unit are not reached or exceeded at the time of evaluation, the air inlet grille is automatically defrosted (possibly first the defrosting process of the evaporator or heat exchanger is activated and then). In particular, a sensor signal evaluation can also take place over time (trend evaluation) and defrosting of the air inlet grille can be activated when defined threshold values are reached.

• Signalauswertung und Beurteilung des geförderten Luftvolumenstroms über einen Volumenstromsensor;
• Signalauswertung und Beurteilung des geförderten Luftvolumenstroms über eine Druckdifferenz über den Verdampfer beziehungsweise Wärmetauscher;
• Signalauswertung und Beurteilung des geförderten Luftvolumenstroms über die elektrische Leistungsaufnahme eines Motors des Gebläses.

A (partial) blockage of the air inlet grille can be directly detected by decreasing the air volume flow conveyed by the fan:

• Signal evaluation and assessment of the conveyed air volume flow via a volume flow sensor;
• Signal evaluation and assessment of the conveyed air volume flow via a Pressure difference across the evaporator or heat exchanger;
• Signal evaluation and assessment of the conveyed air volume flow via the electrical power consumption of a fan motor.

• Signalauswertung und Beurteilung der Wärmeentzugsleistung über eine Temperaturdifferenz;
• Signalauswertung und Beurteilung der Wärmeentzugsleistung über die Verdampfungstemperatur, die üblicherweise in einem zugehörigen Steuergerat als Information zur Verfügung steht;
• Signalauswertung und Beurteilung der Wärmeentzugsleistung über die Verflüssigungs- oder/und Verdampfungsleistung, die üblicherweise in einem zugehörigen Steuergerat als Information zur Verfügung steht.

A (partial) blockage of the air inlet grille can be indirectly detected by reducing the heat extraction capacity via the evaporator/heat exchanger in heating mode:

• Signal evaluation and assessment of the heat extraction performance via a temperature difference;
• Signal evaluation and assessment of the heat extraction capacity via the evaporation temperature, which is usually available as information in an associated control unit;
• Signal evaluation and assessment of the heat extraction capacity via the condensation and/or evaporation capacity, which is usually available as information in an associated control unit.

In some application variants, the air inlet grille is adjustable (in terms of the free flow cross section and/or the direction of flow) and is brought into a position during defrosting that opposes the reverse air flow with a higher flow resistance than when the air inlet grille is completely open. Through this measure, its defrosting can be accelerated, and losses to the environment can possibly also be kept low.

A device for defrosting an air inlet grille of an evaporator or heat exchanger of an air heat pump also contributes to solving the problem, the evaporator or heat exchanger being at least one in its flow direction associated with a reversible fan and/or a separate fan, which is set up to generate and maintain a reverse flow of air through the evaporator or heat exchanger to the air inlet grille during and/or after a defrosting process of the evaporator or heat exchanger.

This can preferably be achieved by an axial fan whose direction of rotation can be switched and regulated. The reverse air flow can be measured and regulated to a desired value, which means that different wind and weather conditions can also be compensated for or taken into account.

If the air inlet grille is adjustable (mechanically or electrically), it can be set up in such a way that it assumes an at least partially closed position during a defrosting process. In other words, this means in particular that the flow cross section or the maximum throughput (given the same ambient conditions) through the air inlet grille is/is reduced. This enables more effective defrosting with less heat loss to the environment.

There is preferably at least one sensor for measuring at least one parameter of an air flow through the evaporator or heat exchanger and air inlet grille, from whose measured value compared to reference data (calibration data) icing of the air inlet grille can be determined, at least when the evaporator or heat exchanger has just been defrosted. In a typical air heat pump, the measured values of several sensors are used for control, which also provide information about icing of the evaporator or heat exchanger and air inlet grille. There are usually sensors for air temperature, air humidity, air pressure and/or volume flow before and/or after the evaporator or heat exchanger, from their measured values or their comparison with reference data, the icing of the evaporator or heat exchanger or (at least when the evaporator is defrosted) the air inlet grille can be determined. Engine characteristics of a blower such as power consumption, speed, etc. can also be used for detection. An unexpectedly high power consumption and / or an unexpected drop in the efficiency of the air heat pump z. B. close to an icing.

• eine Lufttemperaturmessung vor/ hinter dem Verdampfer bzw. Wärmetauscher;
• eine Luftfeuchtemessung vor/ hinter dem Verdampfer bzw. Wärmetauscher;
• eine Luftdruckmessung vor/ hinter dem Verdampfer bzw. Wärmetauscher;
• eine Luftvolumenstrommessung vor/ hinter dem Verdampfer bzw. Wärmetauscher;
• eine Verwendung von Motorkenndaten des Gebläses wie z. b. dessen Leistungsaufnahme;
• ein zentrales Steuergerät, welches Sensordaten über eine geeignete Schnittstellenverbindung auslesen kann und über nachgelagerte Softwarefunktionen das Gebläse bzw. dessen Motor ansteuern kann;
• eine bidirektionale Verbindung zumindest einer Schnittstelle zwischen dem Gebläse bzw. dessen Motor und dem Steuergerät, um gleichzeitig den Empfang von relevanten Motordaten und als auch die Ansteuerung des Motors durch das Steuergerät zu realisieren.

Depending on the characteristics, the following sensors and/or actuators can be proposed for the automatic or demand-based activation of the reverse air flow or reverse operation:

• an air temperature measurement in front of/ behind the evaporator or heat exchanger;
• an air humidity measurement in front of/ behind the evaporator or heat exchanger;
• an air pressure measurement in front of/ behind the evaporator or heat exchanger;
• an air volume flow measurement upstream/downstream of the evaporator or heat exchanger;
• use of engine characteristics of the fan such as its power consumption;
• a central control unit, which can read out sensor data via a suitable interface connection and can control the blower or its motor via downstream software functions;
• a bidirectional connection of at least one interface between the blower or its motor and the control unit in order to simultaneously receive relevant motor data and control the motor by the control unit.

An inlet sensor for pressure and/or flow rate (volume flow) is preferably arranged between the air inlet grille and the evaporator or heat exchanger. Such a direct measurement is the easiest way to diagnose the condition of the entrance grille.

The invention can be used particularly sensibly for evaporators and air inlet grilles of air heat pumps, because with these, fast and effective defrosting processes are important, especially in winter when outside temperatures are low, so that the actual function of heating for defrosting does not have to be interrupted for long and not too much additional (possibly electrical) energy has to be used for defrosting. However, the method used for defrosting and the energy used to heat the evaporator are not important for the invention. It should be mentioned that the invention can also be used for air inlet grilles arranged remotely from the evaporator or heat exchanger (and in exceptional cases, analogously, however, then without reversing the air flow also for air outlet grilles, which, however, are hardly at risk of icing).

Furthermore, a computer program product is also proposed, comprising instructions that cause the devices described to execute the methods described using suitable means. In particular, the device can include a controller or a processor that can implement the commands of the computer program product and can thus, for example, control the motor. This computer program product can be used in a central electronic control (or as an update thereof) in order to coordinate all processes with the devices according to the invention described.

The features described with reference to the method can equally be used to describe and further characterize the device, and vice versa.

Fig. 1:

eine Anordnung eines abzutauenden Lufteintrittsgitters eines Verdampfers in einem Gehäuse.

A schematic embodiment of the invention, to which it is not limited, and the operation of a method according to the invention and associated device are explained in more detail below with reference to the drawing. It shows:

Figure 1:

an arrangement of an evaporator air inlet grille to be defrosted in a housing.

1 shows schematically a typical application of the invention. This occurs mainly with air heat pumps with an evaporator, which is used here as an example. But there are other use cases, e.g. B. in air-brine heat exchangers with a similar problem.

A refrigerant circuit 8 extracts heat from the ambient air 20 by means of an evaporator 3 . Refrigerant flows through the evaporator 3, which is compressed in the circuit by a compressor 9, gives off heat in a heat exchanger 10 to a heating circuit (not shown) and is expanded in an expansion valve 11, thereby liquefying and being cooled very strongly.

Ambient air 20 is directed through the evaporator 3 in a forward airflow V by means of a blower 4 (or fan) with a motor 7 . The heat contained in the ambient air and thus transferred evaporates the refrigerant in the evaporator 3 again. The evaporator 3 is very cold during operation, namely z. B. 10 to 30 K below the freezing point of water, which is why moisture from the ambient air 20, at least in unfavorable weather conditions, freeze there and form a layer of ice. This hinders the transfer of heat and can lead to damage, which is why the evaporator 3 must be defrosted if necessary. Defrosted ice drips into a collecting pan 6 as water and is discharged from there.

In many cases, the drip tray 6 must also be heatable in order to prevent it from icing up. However, these well-known and mastered processes, in which the evaporator 3 is temporarily heated using various methods, have not yet taken into account that the evaporator 3 is typically housed in an evaporator housing 1 (or in a suitable installation room), with the ambient air 20 passing through an air inlet grille 2 enters the evaporator housing 1 (or a shaft leading to the installation room), which in turn can also ice up. This can be caused by the weather (snow, freezing rain, etc.), but also by physical proximity to the evaporator 3, which cools the air inlet grille 2 at least during a downtime after an operating phase and can thus contribute to the freezing of humidity. (In principle, this also applies to an air outlet 5, but this is typically flowed through by very dry air during operation because air humidity at the evaporator 3 has at least partially been frozen out, so that there is hardly any icing problem at the air outlet 5).

In order to be able to defrost the air inlet grille 2 if necessary, a reverse flow of air U is passed through the evaporator 3 to the air inlet grille 2 and through this during and/or after defrosting the evaporator 3 . This does not necessarily have to be done with every defrosting process, but only if an analysis of sensor data provides indications of an iced air inlet grille 2 .

At least one entry sensor 12 can be very useful for this purpose. B. either the pressure or the volume flow between the air inlet grille 2 and evaporator 3 measures. In conjunction with at least one corresponding outlet sensor 13, statements about the icing of the evaporator 3 and the air inlet grille 2 can be obtained. The entry sensor 12 is connected to a control and regulation unit 18 via a measuring line 14 connected, as well as the exit sensor 13 via a measuring line 15. The motor 7 of the blower 4 is also connected via a combined measuring and control line 16 to the control and regulation unit 18, so that on the one hand information z. B. receives the speed and power consumption of the fan 4, on the other hand can give control commands to the fan 4, in which direction and how much it should promote ambient air 20. Further sensors 21 can be connected to the control and regulation unit 18 via further sensor connections 17 .

Much information can be used in diagnosing the condition of the evaporator 3 and air inlet grille 2, in particular data on the respective efficiency of the air source heat pump compared to an expected efficiency under given conditions. In general, reference values (calibration data) can be stored in the control and regulation unit 18, with which actually measured parameters can be compared in order to identify whether icing is present and, if so, whether it is occurring on the evaporator 3 and/or on the air inlet grille 2 .

If the air inlet grille 2 has to be defrosted, either the fan 4 is activated during and/or after the defrosting of the evaporator 3 to generate a reverse flow U, provided the design of the fan allows this (e.g. with an axial fan), or a separate blower 19 is switched on (with the blower 4 switched off) in order to generate the reverse air flow U. The reverse air flow U is typically significantly weaker than the maximum possible forward air flow V, which is illustrated by the corresponding length of the associated arrows. It is usually less than 10%, possibly 1 to 5% of the maximum forward air flow V. Therefore, a separate fan 19 that may be required can be significantly smaller than the fan 4 for normal operation.

In some cases the air inlet grille 2 is adjustable, e.g. B. in the form of lamellae and can be opened more or less wide, sometimes even completely closed. Such an adjustable air inlet grille 2, which also serves as a weather protection grille, should not be completely closed while it is being defrosted (otherwise you could not generate a reverse air flow U), but it should not be completely open either, since then more heat is released into the environment than is necessary. An almost closed position supports an efficient defrosting process.

Should the air outlet 5 actually have to be defrosted, this can be done analogously with an air flow, but this cannot be done at the same time as the air inlet grille 2 is defrosted, but would have to be done before or after.

The present invention allows an air inlet grille 2 in front of an evaporator 3, which is iced up due to weather conditions and/or operation, to be defrosted even at very low ambient temperatures below the freezing point of water and/or unfavorable wind conditions.

Reference List

1

evaporator housing

2

air inlet grille

3

evaporator (or heat exchanger)

4

Blower / axial fan

5

air outlet

6

collection tray

7

engine

8th

Refrigerant circulation

9

compressor

10

Heat exchanger to a heating circuit

11

relief valve

12

entry sensor

13

exit sensor

14

Measuring line from the entry sensor

15

Measuring line from the outlet sensor

16

Measuring and control line

17

Sensor connections (to other components)

18

control and regulation unit

19

Separate blower

20

ambient air

21

More sensors

V

Forward airflow

u

reverse airflow

Claims (12)

Method for defrosting an air inlet grille (2) of an evaporator or heat exchanger (3) of an air heat pump, wherein during and/or after defrosting of the evaporator or heat exchanger (3) before it cools down again, a reverse flow of air (U) through the evaporator (3) to Air inlet grille (2) is generated towards and through this. Method according to one of the preceding claims, wherein the air heat pump is switched over for defrosting, so that heat is supplied to the evaporator or heat exchanger (3) instead of being removed there from the ambient air (20) and this switchover is maintained until the air inlet grille (2) is defrosted. Method according to Claim 1 or 2, in which the flow direction (V, U) of an existing fan (4) is switched over to generate the reverse air flow (U) or a separate fan (19) is switched on. Method according to claim 3, wherein a reverse flow of air (U) from the evaporator or heat exchanger (3) to the air inlet grille (2) is maintained during the entire defrosting process of the evaporator or heat exchanger (3) and air inlet grille (2). Method according to one of the preceding claims, in which the reverse air flow (U) has just such a speed that the flowing air, after passing through the air inlet grille (2), is 1 to 10 K above the freezing point of water there. Method according to one of the preceding claims, wherein to detect the need to defrost the air inlet grille (2) and/or a degree of icing still present during the defrosting of the air inlet grille (2) when the evaporator or heat exchanger (3) has already been defrosted, the air flow (V, U) observed through the evaporator or heat exchanger (3) and the air inlet grille (2) and compared to reference data. Method according to one of the preceding claims, in which the air inlet grille (2) is adjustable and when it is defrosted it is brought into a position which opposes a higher flow resistance to the reverse air flow (U) than when the air inlet grille (2) is fully open. Device for defrosting an air inlet grille (2) of an evaporator or heat exchanger (3) of an air heat pump, wherein the evaporator or heat exchanger (3) is assigned at least one fan (4) with a reversible flow direction and/or a separate fan (19), which is set up to generate a reverse flow of air (U) through the evaporator or heat exchanger (3) to the air inlet grille (2) during and/or after a de-icing process of the evaporator or heat exchanger (3). Device according to Claim 8, in which the air inlet grille (2) is adjustable and is set up to assume an at least partially closed position during a defrosting process. Device according to Claim 8 or 9, in which there is at least one sensor (12, 13) for measuring at least one parameter of an air flow through the evaporator or heat exchanger (3) and air inlet grille (2), whose measured value in comparison with reference data indicates icing of the air inlet grille (2) can be determined, at least when the evaporator or heat exchanger (3) has just been defrosted. Device according to Claim 10, in which an inlet sensor (12) for pressure or flow rate is arranged between the air inlet grille (2) and the evaporator or heat exchanger (3). A computer program product comprising instructions that cause the apparatus of any one of claims 8 to 11 to carry out the method of any one of claims 1 to 7.

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