METHOD AND CONTROL UNIT FOR ACTIVATING DETERGENT FOR A CLEANING APPLIANCE WITH A ROTATABLE DRUM WITHOUT RIBS, AND CLEANING APPLIANCE

Abstract

A detergent activation method for a cleaning appliance having a rotatable non-ribbed drum for holding the textiles) and includes a step of supplying a feed signal to a feed unit of the cleaning appliance. The feed signal causes the cleaning liquid to be fed into a suds container until a predetermined target fill level in the drum is reached. In the supplying step, a motion signal may be supplied to a drive of the cleaning appliance when the target fill level is reached, wherein the motion signal causes a rocking rhythm of the drum. The rocking rhythm defines successive rotational motions of the drum at increasing rotational speeds without a complete revolution of the drum. In the supplying step, a stop signal may be supplied to the drive when a final rotational speed of the rocking rhythm has been reached, to cause the rotational motions of the drum to stop.

Claims

1. A method for detergent activation for a cleaning appliance having a rotatable non-ribbed drum for holding the textiles, the method comprising the following steps: supplying a feed signal to an interface of a feed unit of the cleaning appliance, wherein the feed signal causes the cleaning liquid to be fed into a suds container of the cleaning appliance until a predetermined target fill level in the drum is reached; supplying a motion signal to an interface of a drive of the cleaning appliance when the target fill level is reached, wherein the motion signal causes a rocking rhythm of the drum, wherein the rocking rhythm defines successive rotational motions of the drum at increasing rotational speeds without a complete revolution of the drum; and supplying a stop signal to the interface of the drive when a final rotational speed of the rocking rhythm is reached, wherein the stop signal causes the rotational motions of the drum to stop.

2. The method according to claim 1, wherein the motion signal, in the step of supplying the motion signal, causes the rocking rhythm with a frequency between 0.1 Hz and 0.3 Hz.

3. The method according to claim 1, wherein in the step of supplying the motion signal, the motion signal causes successive rotational motions with a rotational speed increase of between 4 rpm and 6 rpm.

4. The method according to claim 1, wherein, in the step of supplying the stop signal, the final rotational speed is between 50 rpm and 70 rpm.

5. The method according to claim 1, comprising a step of reading in an amount signal via an interface of an amount determination device before the cleaning liquid is fed in, wherein the amount signal represents a load amount of the textiles.

6. The method according to claim 5, comprising a step of determining the target fill level using the amount signal.

7. The method according to claim 5, comprising a step of adjusting a frequency of the rocking rhythm using the amount signal.

8. The method according to claim 7, wherein, in the adjusting step, a first frequency of the rocking rhythm is adjusted if the amount signal represents a first load amount of the textiles, and a second frequency of the rocking rhythm is adjusted if the amount signal represents a second load amount of the textiles, wherein the second frequency is lower than the first frequency if the second load amount is smaller than the first load amount.

9. The method according to claim 1, wherein the step of supplying the feed signal is executed again after the step of supplying the stop signal until the predetermined target fill level is reached again.

10. A control unit which is designed configured to execute the steps of the method according to claim 1 in corresponding units.

11. A non-transitory computer-readable medium having program code for executing the method according to claim 1.

12. A cleaning appliance for cleaning textiles, comprising: a suds container for collecting a cleaning liquid; a rotatable non-ribbed drum disposed in the suds container for holding the textiles; a feed unit for feeding the cleaning liquid into the drum; a drive for causing the drum to execute a rotational motion; and the control unit according to claim 10.

13. The cleaning appliance according to claim 12, wherein an inside of a drum casing of the drum is smooth apart from an enlargement having a plurality of entraining elements.

14. The cleaning appliance according to claim 13, wherein the enlargement is directed inwards and projects into a holding space.

15. The cleaning appliance according to claim 13, wherein at least one of the entraining elements has at least one through-opening which is arranged on a side flank of the entraining element or on an upper edge of the entraining element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] An embodiment of the disclosure is shown in the drawings in a purely schematic manner and will be described in more detail below. In the drawings:

[0026] FIG. 1 is a schematic representation of a cleaning appliance according to one embodiment;

[0027] FIG. 2 is a schematic representation of a drum according to one embodiment of a cleaning appliance;

[0028] FIG. 3 is a block diagram of a control unit according to one embodiment of a cleaning appliance; and

[0029] FIG. 4 is a flowchart of a method for detergent activation for a cleaning appliance according to one embodiment.

DETAILED DESCRIPTION OF THE DRAWINGS

[0030] FIG. 1 is a schematic representation of a cleaning appliance 100 according to one embodiment. The cleaning appliance 100 can be implemented as a commercially available washing machine, which can be used, for example, for private purposes, but also for commercial purposes. The cleaning appliance 100 is designed to clean textiles 101. For this purpose, the cleaning appliance 100 has a suds container 102, a rotatable non-ribbed drum 104 arranged in the suds container 102, a feed unit 106, a drive 108, and a control unit 110. The suds container 102 is designed to collect a cleaning liquid. The drum 104 is designed to accommodate the textiles 101, for example for a cleaning process. The feed unit 106 is designed to feed the cleaning liquid to the drum 104. The drive 108 is designed to cause the drum 104 to execute a rotational motion. The control unit 110 is designed to actuate the feed unit 106 and the drive 108 according to this embodiment and to execute a detergent activation method, for example, as is described in more detail in one of the following drawings. Apart from an enlargement with a plurality of entraining elements, an inside of a drum casing of the drum 104 is smooth according to this embodiment, as is described in more detail in one of the following drawings. The drum 104 is non-ribbed.

[0031] FIG. 2 is a schematic view of a drum 104 according to one embodiment of a cleaning appliance. The drum 104 can be arranged in a cleaning appliance, for example, as was described in FIG. 1. The drum casing 200 of the drum 104 has the enlargement 204 on its inside 202, on which the plurality of entraining elements 206 is arranged. According to this embodiment, the enlargement 204 is directed inwards, so that it projects into a holding space 208 of the drum 104. This means that the entraining elements 206 form a cavity on a side of the drum casing 200 facing away from the inside 202 of the drum casing 200. According to this embodiment, at least one of the entraining elements 206 has at least one through-opening, which is arranged on a side flank of the entraining element or on an upper edge of the entraining element. According to this embodiment, the through-opening has a diameter of, for example, 1.5 mm to 3.6 mm.

[0032] FIG. 3 is a block diagram of a control unit 110 according to one embodiment of a cleaning appliance. The control unit 110 can be used, for example, in a cleaning appliance as described in FIG. 1 in order to move a non-ribbed drum as described in FIG. 2. In this case, the control unit 110 is designed to control a detergent activation method. For this purpose, according to this embodiment, the control unit 110 has a read-in unit 300 and a supply unit 302. In this case, the read-in unit 300 is designed to read in an amount signal 304 via an interface of an amount determination device 306. The amount signal 304 represents a load amount of the textiles. According to this embodiment, the control unit 110 determines a target fill level 308 using the amount signal 304 and is designed to set a frequency 310 of a rocking rhythm of the drum, also using the amount signal 304. For example, a first frequency of the rocking rhythm is adjusted when the amount signal 304 represents a first load amount of the textiles, and a second frequency of the rocking rhythm is adjusted, for example, when the amount signal 304 represents a second load amount of the textiles. In this case, the second frequency is lower than the first frequency if the second load amount is smaller than the first load amount.

[0033] The supply unit 302 is designed to provide a feed signal 312 to an interface of the feed unit 106 of the cleaning appliance. In this case, the feed signal 312 causes the cleaning liquid to be fed into the suds container of the cleaning appliance until the predetermined target fill level 308 reaching into the drum is reached. Furthermore, the supply unit 302 is designed to supply a motion signal 314 to an interface of a drive 108 of the cleaning appliance when the target fill level 108 has been reached. The motion signal 314 causes the drum to have a rocking rhythm, which defines successive rotational motions of the drum at increasing rotational speeds without a complete revolution of the drum. Furthermore, the supply unit 302 supplies a stop signal 316 to the interface of the drive 108 when a final rotational speed of the rocking rhythm has been reached. The stop signal 316 causes the rotational motions of the drum to stop. The motion signal 314 causes the rocking rhythm according to this embodiment at a frequency 310 between 0.1 Hz and 0.3 Hz. Furthermore, the motion signal 314 causes successive rotational motions at a rotational speed increase of between 4 rpm and 6 rpm. According to this embodiment, the final rotational speed is between 50 rpm and 70 rpm.

[0034] According to this embodiment, the rocking rhythm is characterized such that the motion signal 314 only optionally causes a first rotational motion of the drum in a first direction until the drum has reached a first target rotational speed. A second motion signal 318 causes, for example, a second rotational motion of the drum in a second direction, opposite the first direction, until the drum has reached a second target rotational speed greater than the first target rotational speed. A further first motion signal 320 continues to cause a further first rotational motion of the drum in the first direction until the drum has reached a further first target rotational speed greater than the second target rotational speed of the preceding second rotational motion. Analogously to this, a further second motion signal 322 causes a further second rotational motion of the drum in the second direction until the drum has reached a further second target rotational speed greater than the further first target rotational speed of the preceding further first rotational motion. As a result, only optionally the rotational motion, the second rotational motion, the further first rotational motion, and the further second rotational motion cause the rocking rhythm of the drum, which is formed, for example, from a predetermined frequency, the final rotational speed, and a predetermined increase in rotational speed. According to this embodiment, the first motion signal also optionally causes a first acceleration of the drum, the second motion signal can cause a second acceleration of the drum greater than the first acceleration, the further first motion signal can cause a further first acceleration of the drum greater than the second acceleration, and the further second motion signal causes a further second acceleration greater than the further first acceleration.

[0035] In other words, the approach presented herein presents an opportunity for detergent activation in a non-ribbed drum, which is also referred to as a washing drum. Detergent activation requires good mixing and agitation of, for example, a liquid, detergent and textiles so that the detergent is completely dissolved in the liquid. For this purpose, a target fill level of the cleaning liquid is adjusted so high that the suds mixture that has not yet been completely dissolved and activated becomes visible in the drum and comes into contact with the textiles and an outer surface of the drum. According to this embodiment, the drum is set in the rocking rhythm so that the mixture of water and detergent, which is referred to as cleaning liquid, is entrained and homogenized on the one hand by frictional forces on a drum base and on the other hand by the moving textiles. In the case of small load amounts, according to this embodiment, the rocking rhythm is slowed down in such a way that the drum casing glides under the textiles, which are also referred to as laundry. The saturated textile and the precisely adjusted liquid level allow a “gliding function” so that the entrained water flows through and around the laundry and mixes to form homogeneous suds. According to this embodiment, the rocking rhythm is characterized in that the drum does not complete a complete revolution and, after reaching the final rotational speed, a pause or a drum standstill is inserted so that the water level returns to a level that allows the process described to be repeated as desired.

[0036] According to this embodiment, small holes, which are referred to herein as through-openings, in the region of the entraining honeycomb support the activation of the detergent. According to this embodiment, the enlargement, which is also referred to as an entraining honeycomb, forms a cavity on the rear side of the drum casing, in which air is trapped when immersed in the cleaning liquid. This air escapes in the direction of the textiles through small through-openings with a diameter of, for example, 1.5 mm to 3.6 mm and then, due to its suction effect, draws cleaning liquid with it. This is now pressed into the textiles like a geyser, so that the activation process and the washing effect are supported. The through-openings are preferably attached to a lower and upper side flank and/or to an upper side of the entraining element.

[0037] According to an alternative embodiment, an additional use of an existing circulation is possible, which accelerates the activation process by feeding the cleaning liquid.

[0038] FIG. 4 is a flowchart of a method 400 for detergent activation for a cleaning appliance according to one embodiment. The method 400 can be executed, for example, by a control unit as was described in FIG. 3. Correspondingly, the method 400 can be executed in a cleaning appliance, as was described in FIG. 1. The method 400 comprises a step 402 of supplying a feed signal to an interface of a feed unit of the cleaning appliance, wherein the feed signal causes the cleaning liquid to be fed into a suds container of the cleaning appliance until a predetermined target fill level reaching into the drum is reached. In a step 404 of supplying, a motion signal is supplied to an interface of a drive of the cleaning appliance when the target fill level is reached, wherein the motion signal causes a rocking rhythm of the drum. The rocking rhythm defines successive rotational motions of the drum at increasing rotational speeds without a complete revolution of the drum. Furthermore, the method 400 comprises a step 406 of supplying a stop signal to the interface of the drive when a final rotational speed of the rocking rhythm is reached. The stop signal causes the rotational motions of the drum to stop.

[0039] According to this embodiment, the method 400 comprises a step 408 of reading in an amount signal via an interface of an amount determination device before the cleaning liquid is fed in, wherein the amount signal represents a load amount of the textiles. In a step 410 of determining, according to this embodiment, the target fill level is determined using the amount signal. Furthermore, the method 400 according to this embodiment comprises a step 412 of adjusting a frequency of the rocking rhythm using the amount signal. According to this embodiment, step 402 is executed again after step 406 of supplying the stop signal, until the predetermined target fill level is reached again.