WO2021037539A1 - Laundry treatment appliance comprising a controller - Google Patents

Abstract

The invention relates to a method 200 for treating laundry 135 and to a laundry treatment appliance 100 which is designed to carry out the method, comprising an outer tub 105 for receiving washing fluid, a laundry drum 107 which is arranged in the outer tub 105, an oscillating system 109 for supporting the laundry drum 107 and the outer tub 105 in the laundry treatment appliance 100 in an oscillatable manner, a drum drive 123, a controller 119, and an output detection element 131 for detecting an electric output value 165 of the drum drive 123. The controller 119 is designed to activate the drum drive 123 during a detection time segment 163 of a washing time period 149 in order to rotate the laundry drum 107, wherein the output detection element 131 is designed to detect a first electric output value 165-1 of the drum drive 123 during a first detection interval 163-1 of the detection time segment 163 and to detect a second electric output value 165-2 of the drum drive 123 during a second detection interval 163-2 adjoining the first detection interval 163-1, and the controller 119 is designed to detect a non-changing laundry tunnel 137 within the laundry 135 received in the laundry drum 107 when the second electric output value 165-2 corresponds to the first electric output value 165-1.

Description

Laundry care device with one control

The present invention relates to a laundry care device with a controller.

In a conventional laundry care device, different methods are used for wetting the laundry received in the laundry drum. To wet the laundry, the washing liquid supplied can often also be injected into the laundry drum through a front drum opening facing the appliance door. With a large laundry load, the laundry in conventional laundry care devices often completely fills the volume of the laundry drum, so that the washing liquid supplied cannot penetrate into an inner area of the laundry received in the laundry drum, so that complete wetting cannot be ensured in all operating situations . For this reason, it can be advantageous to operate the laundry care device in such a way that a laundry tunnel is formed within the received laundry while the laundry drum is rotating, since in a subsequent step the supplied washing liquid can advantageously penetrate the laundry tunnel and wet the laundry.

A drum washing machine is disclosed in DE 19641309 B4.

DE 102014 104962 A1 discloses a water supply control and a fully automatic washing machine.

The object on which the invention is based is to provide a laundry care device in which, during a laundry care process, the presence of a laundry tunnel within the laundry received in the laundry drum can advantageously be detected.

This object is achieved by the objects with the features according to the independent claims. Advantageous embodiments are the subject matter of the dependent claims, the description and the drawings. According to a first aspect, the object of the invention is achieved by a laundry care device, with a tub for holding washing liquid, a washing drum for holding laundry, the washing drum being arranged in the tub, an oscillating system which is designed to hold the washing drum and the tub in to mount the laundry care device such that it can swing, a drum drive for rotating the laundry drum during a washing period, a controller for controlling the drum drive, and a power detection element for detecting an electrical power value of the drum drive, the controller being designed to activate the drum drive during a detection time segment of the washing period, in order to rotate the laundry drum, wherein the power detection element is designed to detect a first electrical power value of the drum drive during a first detection interval of the detection time segment, wherein d The power detection element is designed to detect a second electrical power value of the drum drive during a second detection interval following the first detection interval, and the controller is designed to detect a non-changing laundry tunnel within the laundry received in the laundry drum when the second electrical power value corresponds to the first electrical power value.

This achieves the technical advantage that by detecting electrical power values by the power detection element and by comparing the detected electrical power values with one another by the controller, it can advantageously be detected when a stable laundry tunnel has formed in the rotating laundry drum.

A laundry tunnel is created in the rotating laundry drum by centrifugal forces acting on the laundry, by means of which the laundry received in the rotating laundry drum is pressed against the laundry drum and the laundry tunnel is thereby formed. Thus, in the present case, the laundry tunnel is understood to mean that inner area in the laundry drum loaded with laundry in which there is no laundry, the inner area being at least partially surrounded, in particular completely, by laundry resting against a jacket of the laundry drum. In other words, by carefully distributing the laundry to the coat of the Laundry drum, a cavity is created within the batch of laundry, which is referred to as a laundry tunnel.

In particular, the power detection element is designed to detect a torque-generating current intensity and / or an electrical power consumption of the drum drive as an electrical power value of the drum drive.

On the basis of the detection of the electrical power value of the drum drive, the drive torque of the laundry drum can be evaluated if the speed is known. With an unchanged and therefore stable laundry tunnel, the drive torque of the laundry drum does not change either, so that the electrical power value detected by the power detection element remains constant during the first and second detection interval.

If the second electrical power value detected during the second detection interval corresponds to the first electrical power value detected during the previous first detection interval, the drive torque of the laundry drum has not changed and a stable laundry tunnel has been formed in the laundry drum, which is detected by the control.

A laundry care device is understood to mean a device that is used for laundry care, such as a washing machine, a washer-dryer or a tumble dryer. In particular, such a laundry care device is understood to mean a household laundry care device. So a laundry care device, which is used in the context of housekeeping, and with which laundry is treated in household quantities.

In an advantageous embodiment, the controller is designed to activate the drum drive during a maximum time segment of the washing period in order to rotate the laundry drum at a maximum speed, the maximum speed being greater than a resonance speed of the laundry drum, the resonance speed being a speed of the laundry drum at which an oscillation frequency of the oscillation system corresponds to a natural oscillation frequency of the oscillation system, and wherein in particular the acquisition time segment takes place during the maximum time segment and / or after the maximum time segment.

This has the technical advantage that by rotating the laundry drum at maximum speed during the maximum period of time, it can be ensured that even with large loads of laundry, the laundry received in the laundry drum is completely in contact with the laundry drum, so that a laundry tunnel is advantageously formed during the maximum period of time becomes. Since the detection time segment takes place in particular during and / or after the maximum time segment, an advantageous detection of the laundry tunnel can be ensured by the control.

In particular, the maximum time segment has a plurality of maximum time segment ranges, the laundry drum being rotated during the respective maximum time segment range in each case at a maximum range speed, the maximum range speeds differing in particular.

In an advantageous embodiment, the controller is designed to activate the drum drive during a drum time segment of the washing period following the detection time segment, in particular the maximum time segment, in order to rotate the laundry drum at a drum speed, the drum speed being greater than and lower than a detachment speed of the laundry drum as a resonance speed of the laundry drum, wherein the detachment speed is a maximum speed of the laundry drum at which the laundry received in the laundry drum is released from the laundry drum, and wherein the resonance speed is a speed of the laundry drum at which an oscillation frequency of the oscillation system is a natural oscillation frequency of the Oscillation system corresponds.

This has the technical advantage that rotating the laundry drum at the drum speed, which is greater than the detachment speed, prevents the laundry from becoming detached from the laundry drum during the drum period, so that the laundry tunnel detected during the detection period also can be sustained during the drum period. Because the drum speed is lower than the resonance speed, energy can be generated can be saved, vibrations occurring in the laundry care device can be reduced, and washing liquid absorbed in the laundry is not directly driven out of the laundry again to an undesired extent.

In an advantageous embodiment, the laundry care device has a washing liquid supply device for supplying washing liquid into the washing drum, and the control is designed that

Activate washing liquid supply device during the washing period, in particular after the detection time segment, in order to supply washing liquid into the laundry tunnel within the rotating laundry drum.

This achieves the technical advantage that after the presence of a stable laundry tunnel has been detected during the detection time segment, the washing liquid can advantageously be supplied, in particular injected, into the laundry tunnel. As a result of the centrifugal force acting on the supplied washing liquid, the washing liquid supplied into the laundry tunnel is driven radially outward through the laundry in order to wet the laundry as completely and advantageously as possible.

In an advantageous embodiment, the laundry care device has a washing liquid supply device for supplying washing liquid into the laundry drum, the control being designed to activate the washing liquid supply device during the maximum time segment and / or detection time segment in order to supply washing liquid to the laundry in the laundry drum and prewetting the laundry, and / or wherein the controller is designed to activate the washing liquid supply device during the drum period in order to supply washing liquid into the laundry tunnel within the rotating laundry drum.

This achieves the technical advantage that, in addition to feeding washing liquid into the stable laundry tunnel during the drum period, the washing liquid supply device can also supply washing liquid to the laundry during the maximum time segment and / or detection time segment, although a stable laundry tunnel may not yet have formed in the laundry drum to ensure effective pre-wetting of the laundry. In an advantageous embodiment, the washing liquid supply device has a pump which is designed to pump washing liquid out of the tub and to supply the washing liquid again to the laundry in the laundry drum, and the controller is designed to operate the pump during the washing period, in particular during the detection period, during the maximum period of time and / or during the drum period of time to be activated in order to circulate washing liquid and to supply the circulating washing liquid to the laundry received in the washing drum.

This achieves the technical advantage that washing liquid thrown free due to the rotation of the washing drum can be pumped around by activating the pump and advantageously fed back to the washing for wetting. In this way, a stable washing liquid gradient can be ensured in the laundry, particularly in the case of pre-wetted laundry.

In an advantageous embodiment, the laundry care device has and / or is a fill level sensor arranged in the tub for detecting a fill level of washing liquid in the tub

Power detection element designed to detect an electrical pump power value of the pump, the controller being designed to deactivate the pump or to reduce the pumping power of the pump when the level of washing liquid detected by the level sensor in the tub falls below a reference level, and / or when the The electrical pump power value of the pump detected by the power detection element falls below a reference power value.

This has the technical advantage that the tub can be prevented from running empty while the pump is being pumped around.

In an advantageous embodiment, the laundry care device has a vibration detection element for detecting vibration values of the vibration system, wherein the vibration detection element is designed to detect a first oscillation value during the first detection interval and to detect a second oscillation value during the second detection interval, and the controller is designed to a laundry tunnel inside the laundry drum to detect laundry brought in when the second electrical power value corresponds to the first electrical power value and when the first oscillation value corresponds to the second oscillation value.

This has the technical advantage that, in addition to the electrical power value, the vibration value of the vibration system can also advantageously be used to confirm the presence of a laundry tunnel within the laundry drum. If the size of the laundry tunnel within the rotating laundry drum no longer changes, the detected vibration values also remain the same during the first and second detection intervals.

In an advantageous embodiment, the laundry care device has an air flow element which is designed to guide an air flow to the laundry drum, the laundry care device has

Air flow detection element for detecting air flow values from an air flow emerging from the laundry drum, the controller being designed to detect a laundry tunnel within laundry introduced into the laundry drum if the second electrical power value corresponds to the first electrical power value and if an during the first and / or Second acquisition interval acquired air flow value falls below or exceeds an air flow reference value.

This achieves the technical advantage that, in addition to the electrical power value, the air flow of air through the laundry drum can also advantageously be used in order to confirm the presence of a laundry tunnel within the laundry drum. If a stable laundry tunnel has formed in the laundry drum, the supplied air can advantageously flow through the laundry tunnel and an air flow value that is too low or too high is detected.

In an advantageous embodiment, the power detection element is designed to detect at least one further electrical power value of the drum drive during at least one further detection interval of the detection time segment following the second detection interval, and the controller is designed to create a non-changing laundry tunnel within the laundry drum recorded laundry when the at least one further electrical power value corresponds to the first and / or second electrical power value.

This has the technical advantage that the acquisition of at least one further electrical power value during the acquisition time segment can improve the accuracy of the acquisition.

In an advantageous embodiment, the controller is designed to activate the drum drive during the first detection interval in order to rotate the laundry drum during the first detection interval at a first maximum range speed which is greater than the resonance speed, the controller being designed to operate the drum drive during the to activate the second detection interval in order to rotate the laundry drum during the second detection interval at a second maximum range speed which is greater than the resonance speed and which differs from the first maximum range speed, and wherein the control is designed in particular to activate the drum drive during at least one to activate the second detection interval subsequent further detection interval in order to activate the laundry drum during the at least one further detection interval with a further maximum range speed which is greater than the resonance speed ahl is to rotate, and which differs from the first maximum range speed and / or the second maximum range speed.

This achieves the technical advantage that, by changing the maximum range speed of the rotating laundry drum during the corresponding detection intervals, an existing laundry tunnel can advantageously be detected by means of speed differences detected in this way. In addition, a particularly even distribution of the laundry within the laundry drum can be supported, since localized laundry accumulations, for example, can be broken up by the changes in speed.

In this case, the controller is designed to activate the drum drive during at least one reduction time segment between two successive detection intervals in order to rotate the laundry drum at a speed that is, in particular, greater than a resonance speed but less than that Maximum speed, in particular less than the first, second and / or further maximum range speed.

In an advantageous embodiment, the second maximum range speed is greater than the first maximum range speed, the at least one further maximum range speed being greater than the second maximum range speed, or wherein the at least one further maximum range speed comprises a plurality of further maximum range speeds, each of which is greater and / or lower than the are first and / or second maximum range speed.

This has the technical advantage that the presence of a laundry tunnel can advantageously be detected. In addition, a sufficiently high rotational speed of the laundry drum can be provided during the detection time segment, which is sufficient for the laundry to lie against the laundry drum.

According to an alternative, the maximum range speeds are continuously increased from the first, through the second, to the at least one further detection time segment until a speed limit value is reached at which no further improvement occurs, so that the control can determine step by step whether there is a laundry tunnel has formed.

According to a further alternative, the first maximum range speed is increased to the second maximum range speed, but the further maximum range speeds are varied during the further detection time segments, so that the further maximum range speeds are greater and / or lower than the first and / or second maximum range speed. This ensures an advantageous detection of a laundry tunnel. In addition, the formation of a uniformly formed laundry tunnel can be supported by braking and / or accelerating the speed of the laundry drum.

In an advantageous embodiment, the first, second and / or further electrical power value comprises a difference in each case between a first, second and / or further acceleration power value and a first, second and / or further no-load power value, the respective no-load power value being one by the ok

Power detection element corresponds to detected electrical power value of the electric drum drive, which was detected when rotating the laundry drum at a constant speed, and the respective

Acceleration power value corresponds to an electrical power value of the electric drum drive detected by the power detection element, which was detected when the speed of the laundry drum was increased.

This has the technical advantage that by taking power values into account during acceleration or while the laundry drum is idling, the accuracy of the determination of the respective electrical power values can be improved.

In an advantageous embodiment, the controller is designed to activate the drum drive in order to change the speed of the laundry drum if the first and second electrical power values differ, and / or the controller is designed to repeat the detection time segment when the first and second electrical power value differentiate.

This has the technical advantage that if there is a difference between the first and second electrical power values, it can be assumed that there is not yet a stable laundry tunnel within the laundry drum. Thus, the control can then subsequently detect a stable laundry tunnel by changing the speed of the rotating laundry drum or by repeating the detection time segment in a new measuring process.

According to a second aspect, the object of the invention is achieved by a method for caring for laundry in a laundry care device, the laundry care device having a tub for receiving washing liquid, a laundry drum for receiving laundry, the laundry drum being arranged in the tub, a vibrating system which is designed to swing the laundry drum and the tub in the laundry care device, a drum drive for rotating the laundry drum during a washing period, a controller for controlling the drum drive, and a power detection element for detecting an electrical power value of the Comprising the drum drive, the method comprising the following steps, activating the drum drive by the controller during a detection time segment of the washing period to rotate the laundry drum, detecting a first electrical power value of the drum drive during a first detection interval of the detection time segment by the power detection element, detecting a second electrical Power value of the drum drive during a second detection interval of the detection time segment by the

Power detection element, and detection of a non-changing laundry tunnel within the laundry received in the laundry drum when the second electrical power value corresponds to the first electrical power value.

This has the technical advantage that the presence of a laundry tunnel in the laundry drum can advantageously be detected.

The embodiments characterized as advantageous embodiments for the laundry care device according to the first aspect are likewise advantageous embodiments for the method according to the second aspect.

Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

1 shows a schematic view of a laundry care device;

2 shows a schematic view of a laundry care device with a control;

3 shows a schematic representation of the supply of washing liquid into a laundry tunnel formed in the laundry drum;

4 shows a graphic representation of a laundry care process according to a first embodiment; 5 shows a graphic representation of a laundry care process according to a second embodiment;

6 shows a graphic representation of a laundry care process according to a third embodiment;

7 shows a graphic representation of a laundry care process according to a fourth embodiment; and

8 shows a schematic representation of a method for caring for laundry in a laundry care device.

Figure 1 shows a schematic view of a general laundry care appliance 100, such as a washing machine. The laundry care device 100 comprises a rinsing bowl 101 into which detergent or other liquid substances can be filled. The laundry care device 100 has a device housing 102. The laundry care device 100 comprises an appliance door 103 for loading the laundry care device 100 with laundry.

Fig. 2 shows a schematic view of a laundry care device with a control. The laundry care device 100 has a tub 105 for receiving washing liquid, and has a laundry drum 107 for receiving laundry. The laundry drum 107 is arranged in the tub 105. In this case, the tub 105 and the laundry drum 107 arranged in the tub 105 are pivotably mounted in the laundry care appliance 100 by an oscillating system 109 of the laundry care device 100. The tub 105 has a drain opening 111. The laundry care device 100 has a feed element 113. The discharge opening 111 is fluidically connected to the supply element 113 by a liquid line 115, a pump 117 for pumping washing liquid through the liquid line 115 being arranged in the liquid line 115.

The pump 117 can pump washing liquid through the drain opening 111 from the tub 105 during a pumping process not shown in FIG. 2 into the liquid line 115 and the washing liquid through the liquid line 115 and through the feed element 113 to the tub 105 and the laundry drum Feed 107 again. As a result, the washing liquid can be effectively pumped around through the liquid line 115 during a laundry care process and fed back to the laundry in the laundry drum 107.

The liquid line 115, the pump 117 and the supply element 113 are thus designed as a washing liquid supply device 118 - 1 for supplying washing liquid into the laundry drum 107.

Here, the washing liquid supply device 118-1, in particular the supply element 113, is designed to direct the washing liquid in a directed manner into a washing tunnel formed within the washing in the rotating washing drum 107.

The laundry care device 100 further comprises a controller 119 which is connected to the pump 117 by a first control connection 121 and which is connected to a drum drive 123 for rotating the laundry drum 107 by a second control connection 125.

The controller 119 is also connected by a third control connection 127 to a further washing liquid supply device 118-2 for supplying washing liquid into the laundry drum 107, the further washing liquid supply device 118-2 being connected to the tub 105 by a supply line 129.

In particular, the further washing liquid supply device 118-2 comprises a rinsing bowl 101, not shown in FIG. 2, of the laundry care device 100 and / or a dispenser in FIG.

2, the fresh water connection of the laundry care device 100 (not shown), the controller 119 being designed to activate a wash liquor supply via the dispenser 101 and / or the fresh water connection in order to supply wash liquor and / or fresh water as washing liquid into the laundry drum 107.

The laundry care device 100 also has a power detection element 131 for detecting an electrical power value of the drum drive 123. In particular, the power detection element 131 is designed to detect a torque-generating current intensity and / or an electrical power consumption of the drum drive 123 as an electrical power value of the drum drive 123. In particular, the power acquisition element 131 can also be connected to other electrical components of the laundry care device 100, in particular the pump 117, in order to acquire electrical power values of the other electrical components, in particular the pump 117.

In particular, the power detection element 131 is arranged in the controller 119. Alternatively, the power detection element 131 can be arranged in particular outside the controller 119, as is not shown in FIG. 2. Alternatively, the power detection element 131 can be arranged, in particular, within the drum drive 123.

The laundry care device 100 further comprises an outlet line 128 which is fluidically connected to the liquid line 115. The pump 117 is designed to pump out washing liquid through the drain opening 111 from the tub 105, through the liquid line 115 and through the outlet line 128 from the laundry care appliance 100 during a pumping process (not shown in FIG. 2).

3 shows a schematic representation of the supply of washing liquid into a laundry tunnel formed in the laundry drum.

In FIG. 3, a laundry drum 107 of the laundry care device 100 is shown, which can be rotated by a drum drive 123, not shown in FIG. 3, about an axis of rotation 132 in a first direction of rotation 133-1 and / or a second direction of rotation 133-2. An appliance door 103 of the laundry care appliance 100 is shown only in sections.

The wetting of the laundry 135 accommodated in the laundry drum 107 with washing liquid takes place most quickly if it takes place radially, in particular by pumping or central spraying of washing liquid. For the radial wetting of the laundry 135, the formation of a laundry tunnel 137 is necessary, the formation of the laundry tunnel 137 being correlated with the centrifugal acceleration of the laundry 135 due to the rotation of the laundry drum 107. If a laundry tunnel 137 has formed in the laundry 135, an inflow 139 of washing liquid can be fed to the laundry tunnel 137 by a washing liquid supply device 118 - 1, in particular a supply element 113. At the impingement surface 141 of the washing liquid in the laundry tunnel 137, the washing liquid can wet the laundry 135 radially along a radial wetting direction 143 due to the centrifugal acceleration.

According to the present disclosure, it is ensured that, even with large loads of laundry 135, a sufficiently large laundry tunnel 137 is formed, which is large enough so that a sufficiently large amount of washing liquid 139 can penetrate in order to enable effective radial wetting of laundry 135.

4 shows a graphic representation of a laundry care process according to a first embodiment.

4 shows a time representation of the rotational speed of the laundry drum 107 and an electrical power value of the drum drive 123 detected by a power detection element 131, which are plotted along the ordinate axis 145 as a function of the time indicated along the abscissa axis 147. Here, the washing period 149 illustrated in FIG. 4 comprises a maximum period 151 and a drum period 153 following the maximum period 151.

The first curve 140-1 shown in FIG. 4 shows the temporal course of the speed of a laundry drum 107 rotated by a drum drive 123. As can be seen from the first curve 140-1, the controller 119 is designed, the drum drive 123 during the maximum period of time 151 of the washing period 149 to rotate the laundry drum 107 at a maximum speed 155, the maximum speed 155 being greater than a resonance speed 157 of the laundry drum 107. The resonance speed 157 is a speed of the laundry drum 107 at which an oscillation frequency of the oscillation system 109 corresponds to a natural oscillation frequency of the oscillation system 109. By rotating the laundry drum 107 at the maximum speed 155, it can be ensured during the maximum time segment 151 that the laundry 135 received in the laundry drum 107 forms a laundry tunnel 137. This is particularly advantageous in the case of large laundry loads, since the rotation of the laundry drum 107 at the maximum speed 155 ensures that the laundry 135 is pressed completely against the laundry drum 107 by the centrifugal force acting on it.

The second curve 140-2 shown in FIG. 4 shows an electrical power value of the drum drive 123 detected by a power detection element 131, in particular a torque-generating current intensity or a drive torque derived from the torque-generating current intensity.

As can be seen from the second curve 140-2, at the beginning of the maximum time segment 151 the detected electrical power value 165 increases until it remains constant as soon as the speed of the rotating laundry drum 107 has reached the maximum speed 155. The constant course of the detected electrical power value 165 during the rotation of the laundry drum 107 at the maximum speed 155 allows the conclusion that a stable laundry tunnel 137 has formed within the laundry 135 received in the laundry drum 107, which no longer changes.

The power detection element 131 detects a first electrical power value 165-1 of the drum drive 123 during a first detection interval 163-1 of a detection time segment 163, and detects a second electrical power value 165- during a second detection interval 163-2 following the first detection interval 163-1. 2 of the drum drive 123.

A controller 119 of the laundry care device 100 is then designed to detect a non-changing laundry tunnel 137 within the laundry 135 received in the laundry drum 107 when the second electrical power value 165-2 corresponds to the first electrical power value 165-1, as can be seen from the curve in FIG second curve 140-2 can be seen. As can be seen from the course of the first curve 140-1 shown in FIG. 4, the controller 119 then activates the drum drive 123 when a non-changing laundry tunnel 137 has been detected during a detection time segment 163, in particular the maximum time segment 151, subsequent drum period 153 of the washing period 149, in order to rotate the laundry drum 107 at a drum speed 159.

Here, the drum speed 159 is greater than a detachment speed 161 of the laundry drum 107 and lower than the resonance speed 157 of the laundry drum 107, the detachment speed 161 being a maximum speed of the laundry drum 107 at which the laundry 135 received in the laundry drum 107 moves away from the laundry drum 107 solves.

Because the drum speed 159 is greater than the detachment speed 161, it can be ensured that the laundry 135 within the rotating laundry drum 107 continues to remain in contact with the laundry drum 107, so that a stable laundry tunnel 137 can still be provided within the laundry drum 107, in order, for example, to supply washing liquid to the laundry 135 in a subsequent step.

Because the drum speed 159 is lower than the maximum speed 155 and also lower than the resonance speed 157, energy can be saved and in particular a buildup of the oscillating system 109 due to resonance can be prevented, which leads to a reduction in vibration during the laundry care process.

If a non-changing laundry tunnel 137 has been detected in the laundry drum 107 by the control 119, the control 119 can in particular activate a washing liquid supply device 118-1 of the laundry care device 100 for supplying washing liquid into the laundry drum 107 during the washing period in order to add washing liquid to the laundry tunnel 137 feed inside the rotating laundry drum 107.

In this case, the controller 119 can activate the washing liquid supply device 118 - 1 at any point in time during the washing period 149 in order to supply washing liquid to the laundry 135 in the laundry drum 107. In particular, the controller 119 can activate the washing liquid supply device 118-1 in order to supply washing liquid to the laundry 135 in the laundry drum 107 when the second electrical power value 165-2 corresponds to the first electrical power value 165-1. It can thereby be ensured that the washing liquid supplied by the washing liquid supply device 118-1 can be supplied, in particular injected, into a stable laundry tunnel 137 within the laundry drum 107.

The washing liquid fed into the laundry tunnel 137 is driven through the laundry 135 delimiting the laundry tunnel 137 due to the centrifugal force caused by the rotation of the laundry drum 107, so that an advantageous and complete wetting of the laundry 135 in the laundry drum 107 can be ensured.

In particular, the controller 119 can activate the washing liquid supply device 118 - 1 during the maximum time segment 151 and / or drum time segment 153 in order to supply washing liquid to the laundry 135 in the laundry drum 107.

In particular, the controller 119 can activate the washing liquid supply device 118 - 1 during the maximum time segment 151 in order to supply washing liquid to the laundry 135. In this case, under certain circumstances, no laundry tunnel 137 may have formed during the maximum time segment 151, so that in this case the washing liquid supplied merely pre-wets the laundry 135. Subsequent to a corresponding pre-wetting of the laundry 135, the washing liquid supply device 118-1 can be activated by the controller 119, for example during the drum period 153, in order to supply washing liquid into the then stable laundry tunnel 137 within the rotating laundry drum 107.

In this case, however, when the laundry 135 is pre-wetted with washing liquid, the pre-wetted laundry, compared to dry laundry, is displaced more outward over time during the rotation of the laundry drum 107, which is particularly influenced by the flow resistance of the laundry 135 so that the moment of inertia of the laundry 135 is thereby increased. To support this, a continuous pumping of washing liquid in the Laundry care device 100 can be carried out so that the mass of the laundry can be increased by the absorption of the washing liquid by the laundry.

The washing liquid supply device 118 - 1 has a pump 117 which is designed to pump washing liquid out of the tub 105 and to supply the washing liquid again to the laundry 135 in the laundry drum 107. The controller 119 is designed to activate the pump 117 during the washing period 149, in particular during the detection time segment 163, during the maximum time segment 151 and / or during the drum time segment 153, in order to pump washing liquid and supply the pumped washing liquid to the laundry 135 received in the laundry drum 107 .

Thus, as soon as the washing liquid exits through the jacket of the washing drum 107, it can be pumped around by the pump 117 and again supplied to the washing 135 in the washing drum 107, so that a stable washing liquid gradient is established within the washing 135 accommodated in the washing drum 107. As soon as the controller 119 activates the pump 117 for pumping washing liquid during the acquisition time segment 163, the corresponding first and second electrical power values 165-1, 165-2 can then be acquired during the first and second acquisition intervals 163-1, 163-2 , on the basis of which, as before with dry laundry 135, the moment of inertia of the laundry drum 107 can be detected.

In order to avoid emptying the tub 105, the controller 119 is designed in particular to deactivate the pump 117 or to reduce the pumping power of the pump 117 when the level of washing liquid in the tub 105, detected by a filling level sensor located in the tub 105, has a reference fill level falls below, and / or if an electrical pump power value of the pump 117 detected by the power detection element 131 falls below a reference pump power value.

The third curve 140-3 shown schematically in FIG. 4 shows an electrical power value 165 of the drum drive 123 detected by a power detection element 131 in a laundry tunnel 137, which is not yet completely has trained. In this case, the first and second electric power values 165-1, 165-2 which were detected during the first and second detection intervals 163-1 and 163-2 differ. In particular, the second electrical power value 165-2 is greater than the first electrical power value 165-1, so that the controller 119 detects that the laundry tunnel 137 is still growing, that is to say that a stable laundry tunnel 137 has not yet formed.

If the laundry tunnel 137 becomes larger, the moment of inertia of the laundry drum 107 also increases, which is reflected in the increased second electrical power value 165-2 during the second detection interval 163-2.

Even if this is not shown in FIG. 4, the controller 119 can in this case, if the first and second electrical power values 165-1, 165-2 differ, activate the drum drive 123 in order to change the rotational speed of the laundry drum 107 , and / or the controller 119 can repeat the acquisition period 163. As a result, the laundry 135 within the rotating laundry drum 107 can be acted upon in such a way that a stable laundry tunnel 137 is formed, and then the detected first and second electrical power values 165-1, 165-2 are the same.

5 shows a graphic representation of a laundry care process according to a second embodiment.

5 shows a time representation of the speed of the laundry drum 107 according to a fourth curve 140-4 and an electrical power value 165 of the drum drive 123 detected by a power detection element 131 according to a fifth curve 140-5, which along the ordinate axis 145 as a function of time, which is indicated along the axis of abscissa 147 are plotted.

As already stated in the first embodiment, the second embodiment shown in FIG. 5 also has a maximum period 151 during the washing period 149 and a drum period 153 following the maximum period 151, the laundry drum 107 at a maximum speed during the maximum period 151 155 is rotated, which is greater than is the resonance speed 157, and wherein the laundry drum 107 is rotated during the drum period 153 at a drum speed 159 which is greater than the detachment speed 161 and less than the resonance speed 157.

As can be seen from FIG. 5, the acquisition time segment 163 corresponds to the maximum time segment 151.

According to the second embodiment, however, the maximum time segment 151 is subdivided into a plurality of maximum time segment areas 151-1, 151-2, 151-3, in particular three maximum time segment areas 151-1, 151-2, 151-3, wherein in the respective maximum time segment area 151- 1, 151-2, 151-3 the laundry drum 107 is rotated with a respective different maximum range speed 155-1, 155-2, 155-3.

As can be seen from the fifth curve 140-5, a first idling power value 165-3 and a first accelerating power value 165-5 become during the first detection interval 163-1, and a second idling power value 165-4 and a second become during the second detection interval 163-2 Acceleration power value 165-6 recorded.

The respective idling power value 165-3, 165-4 reflects the drive torque of the drum drive 123 at a constant maximum range speed 155-1, 155-2. The respective acceleration power value 165-5, 165-6 gives the drive torque of the drum drive 123 when accelerating from the first to the second maximum range speed 155-1, 155-2, or when accelerating from the second to the third maximum range speed 155-2, 155-3 again.

The first electrical power value 165-1 here comprises the difference between the first acceleration power value 165-5 and the first idling power value 165-3. The second electrical power value 165-2 here comprises the difference between the second acceleration power value 165-6 and the second idling power value 165-4.

Here, the control 119 is designed to detect a non-changing laundry tunnel 137 within the laundry 135 received in the laundry drum 107, when the second electric power value 165-2 corresponds to the first electric power value 165-1.

The advantage of the iterative acquisition of electrical power values 165 with a continuous increase in the speed of the laundry drum 107 during the acquisition time segment 163 is that the specific maximum speed 155 can be targeted during the maximum time segment 151, which is required to form the laundry tunnel 137.

6 shows a graphic representation of a laundry care process according to a third embodiment.

Fig. 6 shows a time representation of the speed of the laundry drum 107 according to a sixth curve 140-6 and an electrical power value 165 of the drum drive 123 detected by a power detection element 131 according to a seventh curve 140-7, which along the ordinate axis 145 as a function of time, which is indicated along the axis of abscissa 147 are plotted.

For further explanations, reference is made to the explanations relating to FIGS. 4 and 5.

In contrast to FIGS. 4 and 5, the acquisition time segment 163 of the third exemplary embodiment shown in FIG. 6 has, in addition to the first and second acquisition intervals 163-1, 163-2, a plurality of further acquisition intervals 163-3, which follow the second Connect the detection interval 163-2, the power detection element 131 being designed to detect a further electrical power value 165-7 of the drum drive 123 during each of the further detection intervals 163-3.

As is also shown in the second exemplary embodiment shown in FIG. 5, in the third exemplary embodiment according to FIG. 6 the respective electrical power value 165-1, 165-2, 165-7 here comprises the difference between the respective acceleration power value 165-5, 165-6, 165-8 and the respective idle power value 165-3, 165-4, 165-9. The maximum time segment 151 further comprises a plurality of maximum time segment areas 151-1, 151-2, 151-3, 151-4, 151-5, wherein in the respective maximum time segment area 151-1, 151-2, 151-3, 151-4, 151-5 the laundry drum 107 is rotated at a respective different maximum range speed 155-1, 155-2, 155-3.

In contrast to the second exemplary embodiment shown in FIG. 5, in which the speed of the laundry drum 107 is continuously increased during the maximum time segment 151, in the third exemplary embodiment according to FIG. 6 the respective maximum range speed includes 155-1, 155-2, 155-3 different high speeds, with a reduction time section 152 taking place between the respective maximum time section ranges 151-1, 151-2, 151-3, 151-4, 151-5, in which the laundry drum 107 is rotated at a speed which is greater than the resonance speed 157 is less than the maximum speed 155, in particular less than the maximum range speeds 155-1, 155-2, 155-3.

7 shows a graphic representation of a laundry care process according to a fourth embodiment.

7a shows a time representation of the rotational speed of the laundry drum 107 according to an eighth curve 140-8 and FIG. 7b shows a time representation of a vibration value of the vibration system 109 detected by a vibration detection element according to a ninth curve 140-9, which runs along the ordinate axis 145 in FIG Dependence of the time, which is indicated along the abscissa axis 147, are plotted.

As can be seen from the ninth curve 140-9, the oscillation detection element is designed to detect a first oscillation value 166-1 during the first detection interval 163-1 and a second oscillation value 166-2 during the second detection interval 163-2.

Even if this is not shown in FIG. 7, in addition to the respective electrical power values 165-1, 165-2, the controller 119 can also use the detected vibration values 166-1, 166-2 to determine the laundry tunnel 137. The controller 119 is thus designed to detect a laundry tunnel 137 within laundry 135 placed in the laundry drum 107 if the second electrical power value 165-2 corresponds to the first electrical power value 165-1 and if the first oscillation value 166-1 corresponds to the second oscillation value 166- 2 corresponds.

Alternatively or additionally, the detection of the resistance of the laundry 135 received in the laundry drum 107 to an air flow can also be taken into account.

Here, the laundry care device 100 has an air flow element which is designed to guide an air flow to the laundry drum 107, the laundry care device 100 having an air flow detection element for detecting air flow values from an air flow emerging from the laundry drum 107. The controller 119 is designed to detect a laundry tunnel 137 within the laundry 135 placed in the laundry drum 107 if the second electrical power value 165-2 corresponds to the first electrical power value 165-1 and if a during the first and / or second detection interval 163- 1, 163-2 detected air flow value falls below or exceeds an air flow reference value.

As long as no laundry tunnel 137 is formed, the air resistance in the laundry drum 107 is very high, because the air has to flow through narrow spaces or through the gap between the cuff and the laundry drum 107. If, on the other hand, a laundry tunnel 137 has formed, the air resistance drops significantly so that an air flow reference value for the presence of a laundry tunnel 137 can be established as a function of the laundry care device 100 and / or the laundry load.

8 shows a schematic representation of a method for caring for laundry in a laundry care device.

The method 200 comprises, as a first method step, the activation 201 of the drum drive 123 by the controller 119 during a detection time segment 163 of the washing period 149 in order to rotate the laundry drum 107. The method 200 comprises, as a second method step, the acquisition 203 of a first electrical power value 165-1 of the drum drive 123 during a first acquisition interval 163-1 of the acquisition time segment 163 by the power acquisition element 131.

The method 200 comprises, as a third method step, the detection 205 of a second electrical power value 165-2 of the drum drive 123 during a second detection interval 163-1 of the detection time segment 163 by the power detection element 131.

The method 200 comprises, as a fourth method step, the detection of 207 a non-changing laundry tunnel 137 within the laundry received in the laundry drum 107 when the second electrical power value 165-2 corresponds to the first electrical power value 165-1.

All features explained and shown in connection with individual embodiments of the invention can be provided in different combinations in the subject matter according to the invention in order to realize their advantageous effects at the same time. The scope of protection of the present invention is given by the claims and is not restricted by the features explained in the description or shown in the figures.

List of reference symbols

100 laundry care device

101 detergent dispenser

102 Device housing

103 Appliance door

105 Suds container 107 Laundry drum 109 Oscillating system 111 Drain opening 113 Feed element 115 Liquid line 117 Pump

118-1 washing liquid supply device

118-2 Further washing liquid supply device

119 Control

121 First control connection

123 drum drive

125 Second control connection

127 Third tax connection

128 outlet pipe

129 feed line

131 Performance recording element

132 axis of rotation

133-1 First direction of rotation

133-2 Second direction of rotation

135 laundry

137 laundry tunnel

139 Inflow of washing liquid

140-n Corresponding curve

141 impact area

143 Radial wetting direction

145 ordinate axis

147 axis of abscissa 149 washing period

151 Maximum time period

151 -n maximum time period ranges

153 drum period

155 maximum speed

155-n maximum range speeds

157 resonance speed

159 drum speed

161 Separation speed

163 Acquisition period

163-1 First acquisition interval

163-2 Second acquisition interval

163-3 Further acquisition interval

165 Electrical power value of the drum drive 165-1 First electrical power value

165-2 Second electric power value 165-3 First no-load power value 165-4 Second no-load power value 165-5 First accelerating power value 165-6 Second accelerating power value 165-7 Another electric power value 165-8 Another accelerating power value

165-9 Another idle power value

166 vibration value

166-1 First vibration value 166-2 Second vibration value

200 Procedures for caring for laundry

201 First step: activating the drum drive

203 Second method step: Detecting a first electrical power value 205 Third method step: Detecting a second electrical power value 207 Fourth method step: Detecting a laundry tunnel that does not change

Claims

PATENT CLAIMS

1. Laundry care device (100) with a tub (105) for receiving washing liquid, a laundry drum (107) for receiving laundry, the laundry drum (107) being arranged in the tub (105), an oscillating system (109), which is formed is to swing the laundry drum (107) and the tub (105) in the laundry care device (100), a drum drive (123) for rotating the laundry drum (107) during a washing period (149), a controller (119) for controlling the Drum drive (123), and a power detection element (131) for detecting an electrical power value (165) of the drum drive (123), characterized in that the controller (119) is designed to operate the drum drive (123) during a detection time segment (163) of the washing period (149) to rotate the laundry drum (107), wherein the power detection element (131) is formed during a first detection interval (163-1) of the detection z eitabschnitts (163) to detect a first electrical power value (165-1) of the drum drive (123), wherein the power detection element (131) is formed during a second detection interval (163-2) following the first detection interval (163-1) to detect the second electrical power value (165-2) of the drum drive (123), and wherein the controller (119) is designed to detect a non-changing laundry tunnel (137) within the laundry (135) received in the laundry drum (107), when the second electric power value (165-2) corresponds to the first electric power value (165-1).

2. laundry care device (100) according to claim 1, characterized in that the controller (119) is designed to activate the drum drive (123) during a maximum time segment (151) of the washing period (149) to the laundry drum (107) at a maximum speed (155) to rotate, the maximum speed (155) being greater than a resonance speed (157) of the laundry drum (107), the resonance speed (157) being a speed of the laundry drum (107), at which an oscillation frequency of the oscillation system (109) corresponds to a natural oscillation frequency of the oscillation system (109), and in particular the detection time segment (163) takes place during the maximum time segment (151) and / or after the maximum time segment (151).

3. Laundry care device (100) according to claim 1 or 2, characterized in that the controller (119) is designed to drive the drum drive (123) during a drum time segment ( 153) of the washing period (149) to rotate the laundry drum (107) at a drum speed (159), the drum speed (159) being greater than a detachment speed (161) of the laundry drum (107) and less than a resonance speed (157) ) of the laundry drum (107), the detachment speed (161) being a maximum speed of the laundry drum (107) at which the laundry (135) received in the laundry drum (107) is released from the laundry drum (107), and the Resonance speed (157) is a speed of rotation of the laundry drum (107) at which an oscillation frequency of the oscillation system (109) corresponds to a natural oscillation frequency of the oscillation system (109).

4. laundry care device (100) according to any one of the preceding claims, characterized in that the laundry care device (100) a

Has washing liquid supply device (118-1, 118-2) for supplying washing liquid into the laundry drum (107), and that the control (119) is designed to control the washing liquid supply device (118-1, 118-2) during the washing period (149), in particular to be activated after the detection period (163) in order to feed washing liquid into the laundry tunnel (137) within the rotating laundry drum (107).

5. laundry care device (100) according to any one of the preceding claims, characterized in that the laundry care device (100) a

Washing liquid supply device (118-1, 118-2) for supplying washing liquid into the laundry drum (107), the controller (119) being designed to control the washing liquid supply device (118-1, 118-2) during the maximum period of time (151) and / or to activate detection time segment (163) in order to supply washing liquid to the laundry (135) in the laundry drum (107) and to prewet the laundry (135), and / or wherein the controller (119) is designed to activate the washing liquid supply device (118-1, 118-2) during the drum period (153) in order to supply washing liquid into the laundry tunnel (137) within the rotating laundry drum (107).

6. laundry care device (100) according to any one of the preceding claims, characterized in that the washing liquid supply device (118-1) has a pump (117) which is designed to pump washing liquid from the tub (105) and the washing liquid again the laundry ( 135) in the laundry drum (107), and the controller (119) being designed to operate the pump (117) during the washing period (149), in particular during the detection period (163), during the maximum period (151) and / or during of the drum time segment (153), in order to circulate washing liquid and to supply the pumped washing liquid to the laundry (135) accommodated in the washing drum (107).

7. laundry care device (100) according to claim 6, characterized in that the laundry care device (100) has a level sensor arranged in the tub (105) for detecting a filling level of washing liquid in the tub (105), and / or that the power detection element (131 ) is designed to detect an electrical pump power value of the pump (117), the controller (119) being designed to deactivate the pump (117) or to reduce the pumping power of the pump (117) when the level detected by the level sensor is from Washing liquid in the tub (105) falls below a reference level, and / or when the

Power detection element (131) detected electrical pump power value of the pump (117) falls below a reference pump power value.

8. laundry care device (100) according to any one of the preceding claims, characterized in that the laundry care device (100) a

A vibration detection element for detecting vibration values (166) of the vibration system (109), the vibration detection element being designed to detect a first vibration value (166-1) during the first detection interval (163-1), and to detect a second vibration value (166-2) during the second detection interval (163-2), and wherein the controller (119) is designed to detect a laundry tunnel (137) within laundry (135) placed in the laundry drum (107), when the second electric power value (165-2) corresponds to the first electric power value (165-1) and when the first vibration value (166-1) corresponds to the second vibration value (166-2).

9. laundry care device (100) according to any one of the preceding claims, characterized in that the laundry care device (100) has an air flow element which is designed to direct an air flow to the laundry drum (107) that the laundry care device (100) has an air flow sensing element for detecting Has air flow values of an air flow emerging from the laundry drum (107), the controller (119) being designed to detect a laundry tunnel (137) within laundry (135) placed in the laundry drum (107) when the second electrical power value (165- 2) corresponds to the first electrical power value (165-1) and if an air flow value detected during the first and / or second detection interval (163-1, 163-2) falls below or exceeds an air flow reference value.

10. Laundry care device (100) according to one of the preceding claims, characterized in that the power detection element (131) is formed during at least one further detection interval (163-3) of the detection time segment (163) following the second detection interval (163-2) to detect a further electrical power value (165-7) of the drum drive (123), and wherein the controller (119) is designed to detect a non-changing laundry tunnel (137) within the laundry (135) received in the laundry drum (107) when the at least one further electrical power value (165-7) corresponds to the first and / or second electrical power value (165-1, 165-2).

11. Laundry care device (100) according to one of the preceding claims 2 to 10, characterized in that the controller (119) is designed to activate the drum drive (123) during the first detection interval (163-1) in order to activate the laundry drum (107) during the first acquisition interval (163-1) with a first Maximum range speed (151-1), which is greater than the resonance speed (157), to rotate, the controller (119) being designed to activate the drum drive (123) during the second detection interval (163-2) in order to activate the laundry drum ( 107) to rotate during the second detection interval (163-2) at a second maximum range speed (155-2) which is greater than the resonance speed (157) and which is different from the first maximum range speed (155-2), and wherein the controller (119) is designed in particular to activate the drum drive (123) during at least one further detection interval (163-3) following the second detection interval (163-2) in order to activate the laundry drum (107) during the at least one further detection interval (163-3) to rotate with at least one further maximum range speed (155-3), which is greater than the resonance speed (157), and which differs from the first maximum range speed (155-1) and / or second maximum range speed (155-2).

12. Laundry care device (100) according to claim 11, characterized in that the second maximum range speed (155-2) is greater than the first maximum range speed (155-1), wherein the at least one further maximum range speed (155-3) is greater than the second maximum range speed ( 155-2), or wherein the at least one further maximum range speed (155-3) is a plurality of further ones

Maximum range speeds (155-3) which are each greater and / or lower than the first and / or second maximum range speed (155-1, 115-2).

13. Laundry care device (100) according to one of the preceding claims, characterized in that the first, second and / or further electrical power value (165-1, 165-2, 165-7) is a difference in each case between a first, second and / or further acceleration power value (165-5, 165-6, 165-8) and a first, second and / or further idle power value (165-3, 165-4, 165-9), the respective idle power value (165-3, 165 -4, 165-9) corresponds to an electrical power value (165) of the electric drum drive (123) detected by the power detection element (131), which was detected when the laundry drum (107) was rotating at a constant speed, and wherein the respective acceleration power value (165-5, 165-6, 165-8) corresponds to an electrical power value (165) of the electric drum drive (123) detected by the power detection element (131), which is detected when the speed of the laundry drum (107) is increased has been.

14. laundry care device (100) according to any one of the preceding claims, characterized in that the controller (119) is designed to activate the drum drive (123) to change the speed of the laundry drum (107) when the first and second electrical Differentiate power values (165-1, 165-2), and / or that the controller (119) is designed to repeat the detection time segment (163) if the first and second electrical power values (165-1, 165-2) differ .

15. A method (200) for caring for laundry (135) in a laundry care device (100), wherein the laundry care device (100) has a tub (105) for receiving washing liquid, a laundry drum (107) for receiving laundry, the laundry drum ( 107) is arranged in the tub (105), an oscillating system (109) which is designed to swing the laundry drum (107) and the tub (105) in the laundry care device (100), a drum drive (123) for rotating the Laundry drum (107) during a washing period (149), a controller (119) for controlling the drum drive (123), and a power detection element (131) for detecting an electrical power value (165) of the drum drive (123), characterized in that the Method (200) comprises the following steps,

Activating (201) the drum drive (123) by the controller (119) during a detection time segment (163) of the washing period (149) in order to rotate the laundry drum (107),

Detection (203) of a first electrical power value (165-1) of the drum drive (123) during a first detection interval (163-2) of the detection time segment (163) by the power detection element (131),

Detection (205) of a second electrical power value (165-2) of the drum drive (123) during a second detection interval (163-2) of the detection time segment (163) by the power detection element (131), Detection (207) of a non-changing laundry tunnel (137) within the laundry (135) received in the laundry drum (107) when the second electrical power value (165-2) corresponds to the first electrical power value (165-1).