EP4060114A1 - Laundry apparatus, control device and method for performing a treatment program for a laundry apparatus - Google Patents

Abstract

A method (200) for carrying out a treatment program for a laundry treatment device comprises outputting (205) a switch-on signal to an interface to a heat pump in order to cause heating of process air, outputting (210) a heating signal to an interface to a heating unit in order to to cause heating of the process air, outputting (215) a process air signal to an interface to a process air fan to convey the process air through a circuit, outputting (220) a switch-off signal to the interface to the heat pump to switch off the heat pump if a switch-off criterion dependent on a temperature signal or the compressor temperature signal is met, and a renewed output (225) of the switch-on signal to the interface to the heat pump in order to switch on the heat pump when a switch-on criterion dependent on the compressor temperature signal is met.

Description

Method for carrying out a treatment program for a laundry treatment device, control device and laundry treatment device

The invention relates to a method for carrying out a treatment program for a laundry treatment device, a control device and a laundry treatment device.

The object of the invention is to provide an improved method for carrying out a treatment program for a laundry treatment appliance, an improved control device and an improved laundry treatment appliance.

According to the invention, this object is achieved by a method for carrying out a treatment program for a laundry treatment appliance, a control device and a laundry treatment appliance with the features of the main claims. Advantageous refinements and developments of the invention result from the following dependent claims.

The advantages that can be achieved with the invention consist not only in protecting the compressor from damage, but also in reducing acoustic interference.

• Ausgeben eines Einschaltsignals an eine Schnittstelle zu der Wärmepumpe, um ein Erwärmen der Prozessluft zu bewirken,
• Ausgeben eines Heizsignals an eine Schnittstelle zu der Heizeinheit, um ein Aufheizen der Prozessluft zu bewirken,
• Ausgeben eines Prozessluftsignals an eine Schnittstelle zu dem Prozessluftgebläse, um die Prozessluft durch den Kreislauf zu fördern,
• Ausgeben eines Abschaltsignals an die Schnittstelle zu der Wärmepumpe, um die Wärmepumpe abzuschalten, wenn ein von dem Temperatursignal oder dem Kompressortemperatursignal abhängiges Abschaltkriterium erfüllt ist, und
• Erneutes Ausgeben des Einschaltsignals an die Schnittstelle zu der Wärmepumpe, um die Wärmepumpe einzuschalten, wenn ein von dem Kompressortemperatursignal abhängiges Einschaltkriterium erfüllt ist.

A method for carrying out a treatment program for a laundry treatment device is presented, the laundry treatment device having a drum for receiving laundry, a heat pump for tempering process air, a heating unit for heating the process air, a process air fan for conveying the process air through a circuit out of the drum and through the heat pump and the heating unit back into the drum, a temperature sensor for providing a temperature signal representing a temperature in the drum, a compressor temperature sensor for providing a compressor temperature signal representing a temperature of a compressor of the heat pump and a control device for controlling the treatment program and wherein the method has the following steps:

• Outputting a switch-on signal to an interface to the heat pump in order to cause the process air to be heated,
• Outputting a heating signal to an interface to the heating unit in order to heat up the process air,
• Outputting a process air signal to an interface to the process air fan in order to convey the process air through the circuit,
• Outputting a switch-off signal to the interface to the heat pump in order to switch off the heat pump when a switch-off criterion dependent on the temperature signal or the compressor temperature signal is met, and
• Re-emission of the switch-on signal to the interface to the heat pump in order to switch on the heat pump when a switch-on criterion dependent on the compressor temperature signal is met.

A laundry treatment device can be understood to mean a device in which laundry, for example textiles, can be treated. For example, this can be a washer-dryer or a tumble dryer. A treatment program can be understood, for example, as a drying program or a hygiene program. When the laundry treatment appliance is in operation, the laundry can be arranged in a laundry treatment space in the drum and treated using the process air. The heat pump can be understood to mean a device in which the components are functionally connected to one another in order to heat the process air flowing through. For example, the process air can first flow through an evaporator and then through a condenser. A refrigerant can be or can be arranged in a refrigerant circuit of the heat pump. The refrigerant can be vaporized in the evaporator using moist process air and condensed in the condenser using the dehumidified process air. The compressor and a throttle can also be arranged in the refrigerant circuit. The heat pump device can thus be used to take in the moist process air, for example from a laundry treatment room enclosed by the drum, to cool it and dry it, to heat it up again and to release it again. In addition, the laundry treatment device includes a heating unit that can be operated electrically, for example, and can be designed to heat the process air independently of the heat pump. For example, the process air, driven by the process air fan, can flow in a circuit both through the heat pump and through the heating unit and can be heated either by the heat pump or by the heating unit or by both at the same time. The switching on and switching off of the heat pump and heating unit can be controlled by the control device. The heated process air can then be used to heat the drum of the laundry treatment appliance and thus the laundry arranged in the drum, for example during the treatment program. In the method presented here, the heat pump can be switched off after a heating phase in which the process air is heated by both the heating unit and the heat pump, for example if a predefined target temperature in the drum or on the compressor has been reached. From a procedural point of view, it can make sense to generate the heat output of individual treatment programs exclusively via an additional electric heater. Under these circumstances, however, the heat pump's compressor, which can also be referred to as the compressor, can be damaged because the compressor can have a low heat level throughout the program when it is not in operation. The refrigerant, on the other hand, can absorb thermal energy from the process air in the heat exchangers, which can increase the enthalpy of the refrigerant and cause it to evaporate. Two different heat levels can then meet in the compressor. High enthalpy refrigerant and low enthalpy compressor. The refrigerant can release part of its thermal energy to the compressor, which can lead to condensation of the refrigerant. Since liquid refrigerant cannot be compressed, a subsequent start-up of the compressor would lead to damage and increased acoustics. To avoid this, the heat pump is switched on again in the method presented here when a switch-on criterion that is dependent on the compressor temperature signal, such as a drop in the temperature in the compressor to a predefined temperature value, is met. Such a typically relatively short repeated operation of the heat pump can protect it.

According to one specific embodiment, after the step of outputting the switch-on signal again, a step of outputting the switch-off signal again can take place if a switch-off criterion dependent on the compressor temperature signal is met. For example, the heat pump can be switched off again after a predetermined period of time or when a certain temperature is reached. This has the advantage that the heat output of the treatment program can largely be generated by means of the heating unit.

In addition, the steps of outputting the power-on signal again and outputting the power-off signal again can be carried out repeatedly. For example, the heat pump can be switched on and off several times over the course of the treatment program. Advantageously, the temperature of the compressor can thereby be kept at a level for the duration of the program at which condensation of the refrigerant and thus damage to the compressor can be avoided.

According to one specific embodiment, the switch-off signal can be output in the output step if the temperature signal represents a temperature corresponding to a predetermined target temperature value. In this case, the switch-on signal can be output in the re-output step if the compressor temperature signal represents a temperature corresponding to a predetermined threshold temperature value, with the threshold temperature value being able to be lower than the target temperature value. For example, the heat pump can be switched off from a defined target temperature, which can also be referred to as the hot gas temperature. The target temperature can be, for example, the temperature required for drying the laundry in the corresponding treatment program, for example 65°C. The heating-up phase is now over and the program can only be operated with the additional electrical heating. This state can be maintained until the temperature in the compressor falls below a second defined value at which condensation of the refrigerant in the compressor can be likely. If this is the case, the compressor can be activated again until the defined target temperature is reached again and the heat pump can be switched off again. This process can be repeated several times in the course of a hygiene program and advantageously ensures that the compressor always has a certain level of heat, thus preventing internal condensation.

The predetermined target temperature value can be at least 60°C and additionally or alternatively the threshold temperature value can be at least 40°C. Advantageously, a treatment program can be optimally carried out at a temperature of at least 60°C.

According to a further embodiment, the switch-off signal can be output in the re-output step if a temperature represented by the compressor temperature signal is greater by a temperature difference than a temperature represented by the temperature signal. For example, the heat pump can be switched off when the temperature in the compressor is at least 15K higher , than the temperature in the drum. Advantageously, by switching the heat pump on and off in direct relation to the temperature conditions in the drum and in the compressor, condensation inside the compressor can be prevented.

In addition, the switch-on signal can be output in the re-output step if a temperature represented by the compressor temperature signal is lower by a temperature difference than a temperature represented by the temperature signal. For example, if the temperature in the compressor drops to a temperature value that is lower than the temperature in the drum, the heat pump can be switched on again be turned on. In this case, the temperature difference can correspond, for example, to the difference which results in the switch-off signal being output again, for example a temperature difference of 15K. Advantageously, by switching the heat pump on and off in direct relation to the temperature conditions in the drum and in the compressor, condensation inside the compressor can be prevented.

The temperature difference can be between 10K and 20K. For example, the heat pump can be switched on again when the difference between the temperature in the compressor and the temperature in the drum is 15K. Advantageously, this allows a temperature difference to be defined at which condensation is to be expected.

According to a further embodiment, the method can include a step of outputting a pump signal to an interface to a pump unit of the laundry treatment appliance in order to pump nebulized water into the drum. For example, the step of outputting the pump signal may occur prior to the steps of outputting the turn-on signal and the heating signal. A pump can be switched on for this purpose, for example, in order to moisten dry laundry with finely misted water, which can be pumped out of a condensate tank and sprayed into the drum, for example. The process air can then be heated so that the water in the drum can evaporate. A germ reduction in the laundry to be treated can advantageously be made possible by a combination of increased humidity with increased temperature in the course of a hygiene program. Alternatively, the step of outputting the pump signal can also take place after the steps of outputting the switch-on signal and the heating signal. For example, the process air and the laundry arranged with it in the drum can be heated to a predetermined temperature before it can be moistened by the pump as a result of the pump signal. This has the advantage that the laundry absorbs less water when it is subsequently moistened. As a result, the humidity can be kept higher and, advantageously, less water is required.

According to a further embodiment, the method can have a step of outputting a reversing signal to an interface to a drive of the drum in order to bring about a reversing state of the drum. For example, the drum of the laundry treatment appliance can be designed as a reversible drum, as a result of which a rotation process in two directions can advantageously be possible. For example, the drive of the drum can cause a change in the direction of rotation. Such a reversing state can be implemented in response to the reversing signal, for example. Advantageously, the laundry can be optimally dried with heated process air in the reversing state. In addition, using a reversing drum, for example the laundry can also be moistened in the reversing state in order to advantageously achieve optimum moisture penetration of the laundry. Otherwise, the volume flow generated by the process air fan would ensure that the nebulized water is directed into a filter of the device, for example, and not into the laundry.

According to a further embodiment, the treatment program can represent a hygiene program and the method can have a step of ending the hygiene program after a predetermined period of time after the step of outputting the switch-off signal. By means of a hygiene program, the laundry in the laundry treatment appliance can advantageously not only be dried, but also experience a germ reduction. The hygiene program can be used, for example, to hygienically prepare laundry that has already been washed and additionally or alternatively partially dried laundry. This can be advantageous, for example, when laundry has not been removed directly from the washing machine after a wash cycle, but has been left in the closed drum for a period of time, for example a few hours. In such or a similar case, the laundry can be moistened and heated, for example, in order to reduce the germs that have formed. In order to limit such a program in time, the control device can include a counter, for example, which can count down a predetermined period of time, for example 30 minutes, as a result of the step of outputting the switch-off signal, ie at the end of the heating-up phase. During this period of time, the temperature in the drum can be kept at a target temperature value by means of the heating unit. Advantageously, the hygiene program can be ended automatically after the time period has expired.

Even if the approach described is described using a household appliance, the method described here can be used accordingly in connection with a commercial or professional appliance, for example a medical appliance such as a cleaning or disinfection appliance.

The approach presented here also creates a device that is designed to carry out, control or implement the steps of a variant of a method presented here in corresponding devices. The object on which the invention is based can also be achieved quickly and efficiently by this embodiment variant of the invention in the form of a device.

The device can be designed to read in input signals and to determine and provide output signals using the input signals. An input signal can, for example, be read in via an input interface of the device Display sensor signal. An output signal may represent a control signal or a data signal that may be provided at an output interface of the device. The device can be designed to determine the output signals using a processing specification implemented in hardware or software. For example, the device can include a logic circuit, an integrated circuit or a software module and can be implemented as a discrete component, for example, or can be comprised of a discrete component.

• eine Trommel zum Aufnehmen von Wäsche,
• eine Wärmepumpe zum Temperieren von Prozessluft,
• eine Heizeinheit zum Aufheizen der Prozessluft,
• ein Prozessluftgebläse zum Fördern der Prozessluft durch einen Kreislauf aus der Trommel heraus und durch die Wärmepumpe und die Heizeinheit hindurch zurück in die Trommel,
• einen Temperatursensor zum Bereitstellen eines eine Temperatur in der Trommel repräsentierenden Temperatursignals, und
• einen Kompressortemperatursensor zum Bereitstellen eines eine Temperatur eines Kompressors der Wärmepumpe repräsentierenden Kompressortemperatursignals.

In addition, a laundry treatment device for treating laundry using a treatment program with a variant of the previously presented control device is presented. In addition to the control device, the laundry treatment device has the following features:

• a drum for receiving laundry,
• a heat pump for tempering process air,
• a heating unit for heating the process air,
• a process air fan for conveying the process air through a circuit out of the drum and back into the drum through the heat pump and the heating unit,
• a temperature sensor for providing a temperature signal representative of a temperature in the drum, and
• a compressor temperature sensor for providing a compressor temperature signal representing a temperature of a compressor of the heat pump.

Advantageously, the previously presented method for carrying out a treatment program can be optimally implemented in such a laundry treatment appliance.

A computer program product or computer program with program code, which can be stored on a machine-readable carrier or storage medium such as a semiconductor memory, a hard disk memory or an optical memory, is also advantageous. If the program product or program is executed on a computer or a device, then the program product or program can be used to carry out, implement and/or control the steps of the method according to one of the embodiments described above.

Figur 1

eine schematische Darstellung eines Wäschebehandlungsgeräts gemäß einem Ausführungsbeispiel;

Figur 2

ein Ablaufdiagramm eines Ausführungsbeispiels eines Verfahrens zum Durchführen eines Behandlungsprogramms;

Figur 3

ein Ablaufdiagramm eines Ausführungsbeispiels eines Verfahrens zum Durchführen eines Behandlungsprogramms;

Figur 4

ein Diagramm eines Ausführungsbeispiels einer temperaturbedingten Ansteuerung des Kompressors;

Figur 5

ein Diagramm eines Ausführungsbeispiels einer temperaturbedingten Ansteuerung des Kompressors.

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. It shows

figure 1

a schematic representation of a laundry treatment appliance according to an embodiment;

figure 2

a flowchart of an embodiment of a method for performing a treatment program;

figure 3

a flowchart of an embodiment of a method for performing a treatment program;

figure 4

a diagram of an embodiment of a temperature-related control of the compressor;

figure 5

a diagram of an embodiment of a temperature-related control of the compressor.

figure 1 shows a schematic representation of a laundry treatment appliance 100 according to an embodiment. The laundry treatment appliance 100 comprises a drum 105 for receiving laundry, which is configured as a reversing drum, merely by way of example, in order to circulate the laundry in a reversing state in two different directions of rotation by means of a drive 107 and in this exemplary embodiment in response to a reversing signal 110 . The reversing signal 110 can only be provided by a control device 115 as an example. The control device 115 is also designed to receive a temperature signal 125 provided by a temperature sensor 120 arranged on the drum 105 , the temperature signal 125 representing a temperature in the drum 105 .

The laundry treatment appliance 100 is designed to carry out a treatment program through which laundry can be dried. According to one exemplary embodiment, the treatment program can be carried out as a hygiene program in which the laundry can first be moistened in order to achieve an improved hygiene result.

The laundry treatment appliance 100 also includes a heat pump 130 which is designed to temper process air within the laundry treatment appliance 100 . For this purpose, the heat pump 130 has an evaporator 132, a compressor 134, a condenser 136 and a throttle 138, merely by way of example. In this exemplary embodiment, the heat pump 130 can be switched on by the control device 115 using a switch-on signal 140, the switch-on signal 140 only being an example Beginning of a treatment program for drying arranged in the drum 105 laundry can be output in order to heat the process air guided by the heat pump 130 . A compressor temperature sensor 144 assigned to compressor 134 is designed to detect a temperature of compressor 134 and to provide a compressor temperature signal 146 representing the temperature of compressor 134 to control device 115 . The compressor temperature sensor 144 is embodied here as a refrigerant temperature sensor (NTC) that detects the temperature of the refrigerant on the pressure side of the compressor 134 . The temperature of the compressor 134 can be determined via the coolant temperature. Alternatively, the temperature of the compressor can be detected via a temperature sensor arranged directly on the compressor 134 .

Using the compressor temperature signal 146, the control device 115 is designed to provide a switch-off signal 150 to the heat pump 130 in order to switch it off when a switch-off criterion dependent on the temperature signal 125 is met. For example only, the switch-off criterion in this exemplary embodiment consists in reaching a predetermined target temperature value of 65° C. in drum 105, for example only.

At the same time, control device 115 is designed to output switch-on signal 140 again and thus switch heat pump 130 back on when a switch-on criterion dependent on compressor temperature signal 146 is met. The switch-on criterion in this exemplary embodiment is, purely by way of example, a temperature of the compressor 134 falling below a predetermined threshold temperature value, the threshold temperature value corresponding to 40° C. merely by way of example. The heat pump 130 can thus be activated and deactivated again several times during the treatment program.

In addition to the heat pump 130, the laundry treatment appliance 100 in this exemplary embodiment includes a heating unit 160, which is designed to cause the process air to be heated. For this purpose, the heating unit 160 can be controlled by the control device 115 using a heating signal 165 . Thus, both the heat pump 130 and the heating unit 160 are designed to heat the process air.

In this exemplary embodiment, a process air fan 170 is designed to convey the process air in a circuit out of the drum 105 , through the heat pump 130 and the heating unit 160 back into the drum 105 . Optionally, the process air in the circuit is also conveyed through a filter 172 . That too In this exemplary embodiment, the process air fan 170 can be controlled by the control device 115 using a process air signal 175 .

In this exemplary embodiment, the laundry treatment appliance 100 also includes, purely by way of example, a pump unit 180 for pumping nebulized water into the drum 105. By pumping in water, the laundry in the drum 105 can be moistened, for example during a hygiene program to reduce germs. For example only, the pump unit 180 is designed to draw water from a condenser tank 182 for pumping. In this exemplary embodiment, the water can be pumped into the condensate tank 182 by a condensate pump 185 after it has condensed in the circuit of the heat pump 130 . In this exemplary embodiment, the pump unit 180 can be controlled by a control device 115 by means of a pump signal 190 .

The control device 115 is thus designed to control the execution of a treatment program by controlling the individual components of the laundry treatment appliance 100 .

figure 2 FIG. 2 shows a flowchart of an embodiment of a method 200 for performing a treatment program. The method can only be carried out by way of example in a laundry treatment appliance, as was described in the previous figure. The method 200 includes a step 205 of outputting a switch-on signal to an interface to a heat pump of the laundry treatment appliance in order to cause heating of the process air and a step 210 of outputting a heating signal to an interface to the heating unit in order to also cause the process air to be heated . At the beginning of the program, the heat pump is also operated in addition to the electric heating. On the one hand, this increases the temperature of the compressor of the heat pump and, on the other hand, the heating-up phase of the system is shortened. The method 200 also includes a step 215 of outputting a process air signal to an interface to the process air fan in order to circulate the process air through the drum, the heat pump and the heating unit. In this exemplary embodiment, steps 205, 210, 215 of outputting the switch-on signal, the heating signal and the process air signal are carried out in direct succession. In another exemplary embodiment, steps 205, 210, 215 can also be carried out in parallel or simultaneously or in another suitable order. In any case, the process air is heated during the heating-up phase, ie until a temperature in the drum of the laundry treatment appliance corresponding to a predetermined target temperature value is reached, both by means of the heat pump and by means of the heating unit heated. The target temperature value in this exemplary embodiment is 65° C., purely by way of example.

In this exemplary embodiment, the heating-up phase ends when this target temperature value is reached, and a step 220 of outputting a switch-off signal to the interface to the heat pump follows in response to a temperature signal representing the target temperature value in order to switch off the heat pump. In an alternative exemplary embodiment, the switch-off signal can be output as a result of another switch-off criterion, for example when a temperature in the compressor of the heat pump is greater than a temperature in the drum by a predetermined temperature difference, for example a difference of 15K. In other words, in this exemplary embodiment, the heat pump is switched off from a defined hot gas temperature, which is permanently measured, for example, via a thermistor (NTC). The heating-up phase is thus ended and the program is to be operated during a further treatment phase following the heating-up phase only with the additional electrical heating. For example, the treatment phase extends to the end of the treatment program, so that the process air is temperature-controlled after the heating-up phase, if possible, exclusively using the heating unit. In order to avoid damaging the deactivated heat pump during the treatment phase, the heat pump can be activated temporarily during the treatment phase.

For example, the state in which the heat pump is deactivated is retained until the temperature of the compressor of the heat pump, which can also be referred to as the hot gas temperature, falls below a second defined value, ie a predetermined threshold temperature value. In this exemplary embodiment, the threshold temperature value is 40° C. and is therefore lower than the target temperature value. As soon as the compressor temperature signal represents a temperature corresponding to the threshold temperature value, the heat pump is controlled again in a step 225 of re-emitting the switch-on signal to the interface to the heat pump in order to switch on the heat pump. The heat pump is now in operation again, for example, until the temperature of the compressor again approximately corresponds to the temperature of the drum, i.e. until the target temperature value is reached. In one exemplary embodiment, this is followed by a step 227 of re-emitting a switch-off signal in order to switch off the heat pump again. By way of example only, the steps 225, 227 of re-issuing the turn-on signal and re-issuing the turn-off signal are repeatedly performed during the treatment phase and the heat pump is repeatedly turned on and off. This process ensures that the compressor always has a certain level of heat and thus prevents condensation inside.

In one exemplary embodiment, after a predetermined period of time, for example 30 minutes, step 220 of the initial output of the switch-off signal is followed by a step 230 of ending the treatment program.

figure 3 FIG. 2 shows a flowchart of an embodiment of a method 200 for carrying out a hygiene program. The method 200 corresponds or is similar to that in the previous one figure 2 illustrated method, wherein in this embodiment, the treatment program is executed as a hygiene program. For this purpose, step 205 of outputting the switch-on signal is preceded by a step 305 of outputting a reversing signal to an interface to a drum drive and a step 310 of outputting a pump signal to an interface to a pump unit of the laundry treatment appliance. In step 305 of outputting the reversing signal, the drum of the laundry treatment appliance, which is designed as a reversing drum, is controlled in order to be put into a reversing state. Thus, in the following step 310 of outputting a pump signal, the laundry in the drum is evenly moistened with nebulized water pumped into the drum. The damp laundry is heated by the subsequent steps 210, 215 of outputting a switch-on signal and a heating signal, in order thereby to reduce germs.

figure 4 shows a diagram of an embodiment of a temperature-related activation of a compressor of a heat pump of a laundry treatment appliance during the execution of a treatment program, as in the previous one figure 1 was described.

In this case, partial figure 4A represents an activity state 400 of the compressor, which is repeatedly switched on and off during the treatment program. The compressor control in this exemplary embodiment is directly dependent on a compressor temperature 405 of the compressor, as shown in subfigure 4B, and on a process air temperature 410 of a process air routed through the heat pump, as shown in subfigure 4C. In this exemplary embodiment, the process air temperature 410 corresponds to the temperature in the drum of the laundry treatment appliance.

In the representation shown here, the compressor is switched on with the start 415 of the treatment program. At this point in time, the compressor temperature 405, like the process air temperature 410, corresponds, for example, to an installation temperature of the laundry treatment appliance of just 18° C., for example. During a heating-up phase 420, the temperature increases, with the compressor temperature 405 rising faster than the process air temperature 410. During the heating-up phase 420 according to one embodiment, both the heat pump and an additional heating unit are used to heat the process air.

When a target temperature value 425, of just 60°C, for example, is reached, the compressor is switched off and the compressor temperature 405 drops again, while the process air temperature 410 continues to rise slightly, for example due to the further operation of the heating unit, for example until the temperature in the drum also reaches the target temperature value or another target temperature value. In this exemplary embodiment, the compressor temperature 405 falls while the heat pump is switched off to a predetermined threshold temperature value 430 of just 40° C., for example. When this threshold temperature value 430 is reached, the compressor is switched on again, the compressor temperature 405 rises again to the target temperature value 425, whereupon the compressor is switched off again. The heat pump is thus switched on temporarily for a maintenance phase 440 . During the maintenance phase 440, according to one embodiment, the heating unit is also switched on.

During the further implementation of the treatment program, the compressor can be switched on and off multiple times if the compressor temperature 405 repeatedly falls below the threshold temperature value 430 and then reaches the target temperature value again. The heat pump can be protected from damage by switching the compressor on again from time to time. Thus, depending on the situation, several maintenance phases 440 can be carried out until the end of the treatment program.

According to an alternative exemplary embodiment, the heating-up phase 420 ends when the process air temperature 410 reaches a corresponding target temperature value.

figure 5 shows a diagram of an embodiment of a temperature-related control of a compressor. The compressor control shown here in sub-figures 5A, which can also be referred to as compressor control, is similar to the previous one figure 4 described.

In this exemplary embodiment, the compressor is also switched off when the compressor temperature 405 reaches the target temperature value 425 . The heating-up phase 420 is thus ended. Alternatively, the heating-up phase 420 ends when the process air temperature 410 reaches a corresponding target temperature value.

According to this exemplary embodiment, the compressor is switched on again when the compressor temperature 405 is lower than the process air temperature 410 . According to this exemplary embodiment, the maintenance phase 440 that begins therewith ends when there is a predetermined temperature difference between the compressor temperature 405 and the process air temperature 410 , for example when the compressor temperature 405 is more than 15K greater than the process air temperature 410 . In another embodiment, the temperature difference is between 10K and 20K, for example. At the end of the maintenance phase 440, the compressor and thus the heat pump are switched off. The further temperature control of the process air then only takes place via the heating unit until a new maintenance phase 440 begins. Such a new maintenance phase 440 begins with the compressor being switched on again as soon as the compressor temperature 405 is lower than the process air temperature 410 again.

Claims (13)

Method (200) for carrying out a treatment program for a laundry treatment device (100), the laundry treatment device (100) having a drum (105) for receiving laundry, a heat pump (130) for tempering process air, a heating unit (160) for heating the process air , a process air fan (170) for conveying the process air through a circuit out of the drum (105) and through the heat pump (130) and the heating unit (160) back into the drum (105), a temperature sensor (120) for providing a a temperature signal (125) representing a temperature in the drum (105), a compressor temperature sensor (144) for providing a compressor temperature signal (146) representing a temperature of a compressor (134) of the heat pump (130), and a control device (115) for controlling the treatment program and wherein the method (200) comprises the following steps: Outputting (205) a switch-on signal (140) to an interface to the heat pump (130) in order to cause the process air to be heated; Outputting (210) a heating signal (165) to an interface to the heating unit (160) in order to cause the process air to be heated; Outputting (215) a process air signal (175) to an interface to the process air fan (170) in order to convey the process air through the circuit; Outputting (220) a switch-off signal (150) to the interface to the heat pump (130) in order to switch off the heat pump (130) when a switch-off criterion dependent on the temperature signal (125) or the compressor temperature signal (146) is met; and Re-emission (225) of the switch-on signal (140) to the interface to the heat pump (130) in order to switch on the heat pump (130) when a switch-on criterion dependent on the compressor temperature signal (146) is met. Method (200) according to claim 1, wherein after the step (225) of re-emitting the switch-on signal (140) there is a step (227) of re-emitting the switch-off signal (150) if a switch-off criterion dependent on the compressor temperature signal (146) is met . The method (200) of claim 2, wherein the steps (225, 227) of re-issuing the power-up signal (140) and re-issuing the power-down signal (150) are repeatedly performed. Method (200) according to one of the preceding claims, wherein in the step of outputting (220) the switch-off signal (150) is output if the temperature signal (125) represents a temperature corresponding to a predetermined target temperature value (425) and wherein in step (225) des outputting the switch-on signal (140) again when the compressor temperature signal (146) represents a temperature corresponding to a predetermined threshold temperature value (430), the threshold temperature value (430) being smaller than the target temperature value (425). The method (200) of claim 4, wherein the predetermined target temperature value (425) is at least 60°C and/or the threshold temperature value (430) is at least 40°C. Method (200) according to one of claims 2 to 5, wherein in the step (227) of re-outputting the switch-off signal (150) is output if a temperature represented by the compressor temperature signal (146) is greater by a temperature difference than a temperature represented by the temperature signal ( 125) represented temperature. Method (200) according to one of claims 2 to 6, wherein in the step of re-outputting (225) the switch-on signal (140) is output when a temperature represented by the compressor temperature signal (146) is lower by a temperature difference than a temperature represented by the temperature signal ( 125) represented temperature. A method (200) according to any one of claims 6 to 7, wherein the temperature difference is between 10K and 20K. Method (200) according to one of the preceding claims, with a step (310) of outputting a pump signal (190) to an interface to a pump unit (180) of the laundry treatment appliance (100) in order to pump nebulized water into the drum (105) to effect. Method (200) according to one of the preceding claims, with a step (305) of outputting a reversing signal (110) to an interface to a drive (107) of the drum (105) in order to bring about a reversing state of the drum (105). Method (200) according to one of the preceding claims, wherein the treatment program represents a hygiene program and the method (200) represents a Step (230) of ending the hygiene program after a predetermined period of time, after the step (220) of outputting the switch-off signal (150). Control device (115) which is designed to carry out and/or control the steps (205, 210, 215, 220, 225) of the method (200) according to one of the preceding claims in corresponding units. Laundry treatment appliance (100) for treating laundry, the laundry treatment appliance (100) having the following features: a drum (105) for receiving laundry; a heat pump (130) for tempering process air; a heating unit (160) for heating the process air; a process air fan (170) for circulating the process air out of the drum (105) and back into the drum (105) through the heat pump (130) and the heating unit (160); a temperature sensor (120) for providing a temperature signal (125) representing a temperature in the drum (105); a compressor temperature sensor (144) for providing a compressor temperature signal (146) representing a temperature of a compressor (134) of the heat pump (130); and a controller (115) according to claim 12.

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