DE102015220461A1 - A method of operating a household appliance with detection of a vibration of a storage facility and household appliance - Google Patents

Abstract

The invention relates to a method for operating a household appliance (1) for the care of items of laundry, in which a laundry drum (2) for receiving items of laundry by means of a drive motor (4) is rotated at a current speed, wherein the laundry drum (2) by means of a storage device (9) is rotatably mounted, by means of a sensor device (10) sensor data are provided which describe a vibration of at least one component of the household appliance (1), and by means of an evaluation device (7) the sensor data are received and the drive motor (4) for changing the Current speed is controlled in response to the received sensor data, wherein by means of the evaluation device (7) based on the sensor data vibration of the bearing device (9) is detected and the drive motor (4) is driven to change the current speed, if the vibration of the bearing device ( 9) is detected.

Description

The present invention relates to a method for operating a domestic appliance for the care of laundry items, in which a laundry drum for receiving items of laundry by means of a drive motor is rotated at a current speed, wherein the laundry drum is rotatably supported by a bearing means are provided by sensor means sensor data, which describe a vibration of at least one component of the household appliance, and by means of an evaluation device, the sensor data is received and the drive motor is controlled to change the current speed in dependence on the received sensor data. Moreover, the present invention relates to a household appliance for the care of laundry items.

The interest is directed here to household appliances for the care of laundry, especially washing machines. During operation of the washing machine usually low amounts of noise are emitted from the washing machine under conventional conditions. This also applies to the case in which the washing machine is operated in the so-called spin cycle. In the operation of the washing machine nevertheless occur situations in which the emitted sound is much higher than in the conventional conditions. This may be due, for example, to the fact that the items of laundry within the washing drum have a random and irregular distribution and thus form imbalances which may, for example, lead to vibrations of the laundry drum. It is now desirable to control the operation of the washing machine so that the emitted sound is minimized.

For this purpose, it is known from the prior art that, for example, corresponding sensor devices are used in order to detect vibrations of at least one component of the household appliance during operation. For example, this describes the DE 10 2011 083 568 A1 a method for identifying a property of a periodically oscillating unit, in particular a drive motor of a household washing machine. In this case, the vibrations of windings of a drive motor are monitored by means of a corresponding structure-borne noise measuring device, for example an acceleration sensor. To detect the vibrations, for example, a frequency spectrum of the sensor signals can be determined.

In addition, the describes US 5,930,855 A a method for optimizing the rotational speed of a washing drum of a washing machine. In this case, an acceleration sensor is used to detect machine vibrations. Depending on the detected vibrations, the speed with which the laundry drum is rotated can then be adjusted.

It is an object of the present invention to provide a solution, as the noise during operation of a washing machine can be reduced reliably.

This object is achieved by a method and by a household appliance with the features according to the respective independent claims. Advantageous developments of the present invention are the subject of the dependent claims, the description and the figures.

An inventive method is used to operate a household appliance for the care of laundry, in which a laundry drum for receiving laundry by means of a drive motor is rotated at a current speed, wherein the laundry drum is rotatably supported by a bearing means. By means of a sensor device sensor data are provided which describe a vibration of at least one component of the household appliance. In addition, it is provided that the sensor data is received by means of an evaluation device and the drive motor is controlled to change the current rotational speed as a function of the received sensor data. In addition, by means of the evaluation device based on the sensor data, a vibration of the bearing device is detected and the drive motor is driven to change the current speed, if the vibration of the bearing device is detected.

Preferably, a characteristic value, in particular an energy value or an amplitude, of the oscillation of the bearing device is determined. In this case, the drive motor for changing the current speed depending on the determined characteristic value, in particular the energy value or the amplitude, driven, in particular, the change of the current speed occurs when exceeding a predetermined threshold, which by comparing the determined characteristic value with the Threshold can be determined. An energy value of an oscillation is understood in particular to mean the energy content of a determined oscillation.

The method is intended to operate a domestic appliance for the care of items of laundry, in particular a washing machine. Such a washing machine has the laundry drum, in which the laundry items can be arranged. In the operation of the washing machine, the laundry drum is rotated by means of the drive motor. In this case, the laundry drum is rotatably supported by means of a bearing device. Such a bearing device, for example, a bearing with corresponding rolling elements, for example, a ball bearing have. In the operation of the washing machine, in which the laundry drum is rotated at a current speed, a vibration of at least one component of the household appliance or the washing machine is detected by means of a sensor device. The sensor device may be, for example, an acceleration sensor. With the sensor device, the sensor data are provided, which describe, for example, the vibration of the component of the household appliance. These sensor data are received by the evaluation device and evaluated accordingly. If it is detected by the evaluation device that a component of the washing machine oscillates, the drive motor can be controlled with the evaluation device, so that the rotational speed is changed. For this purpose, the evaluation device, for example, send a corresponding control signal to the drive motor or control electronics of the drive motor.

According to the invention, it is now provided that an oscillation of the bearing device is detected by means of the evaluation device on the basis of the sensor data. It should therefore be checked whether the bearing device or a bearing of the bearing device is excited to mechanical vibrations during operation of the washing machine. In investigations into the determination of the sound emitted during the operation of the washing machine, it was recognized that in certain operating situations noises may emanate from the bearing device or a bearing of the bearing device. This applies in particular to the case when the bearing device is designed as a rolling bearing or comprises a roller bearing. Depending on the current rotational speed and / or the loading state, situations may arise in which the rolling elements lift off from the running surface for a predetermined period of time and subsequently strike the running surface again. By the movement of the rolling elements, the bearing or the bearing device is excited to mechanical vibrations. These are transmitted as structure-borne noise, for example via the tub and are then perceived as airborne sound again. These sound noises can be perceived as disturbing by a user of the washing machine. In addition, it may be the case that corresponding noise emission limits can not be met by these sound waves. By means of the method, these vibrations of the bearing device can be detected and the speed can be changed. By changing the speed can then be achieved that the bearing device is no longer excited to oscillate. Thus, the noise can be effectively reduced.

Furthermore, it is advantageous if the sensor device, by means of which the sensor data are provided, comprises an acceleration sensor. Such an acceleration sensor can be arranged, for example, in the region of the tub. In particular, the acceleration sensor can be arranged such that the vibrations of the bearing device can be detected with it. It can also be provided that structure-borne noise is detected with the acceleration sensor, which forms as a result of the vibrations of the bearing device. In particular, the acceleration sensor is designed to measure the acceleration in all three spatial directions. Thus, the vibration of the bearing device can be reliably detected.

In principle, it can also be provided that the sensor device has a displacement sensor. It can also be provided that the sensor device is designed in the manner of a vibrometer. In principle, it is also conceivable that the sensor device comprises a microphone, by means of which the sound waves, which form as a result of the vibration of the bearing device, can be detected.

In another embodiment, a number of revolutions of the laundry drum during rotation is determined and the sensor data is evaluated for a predetermined number of revolutions. In particular, the number of full or full revolutions of the laundry drum is detected. The phenomenon described above, that the ball bearings or the rolling elements take off during operation of the tread and occur again on the tread, for example, at least once per revolution of the laundry drum. In addition, if the number of revolutions of the laundry drum is determined, it can be checked whether a corresponding sensor signal or a rash in the sensor signal is detected periodically in successive revolutions. It is provided in particular that, for example, sensor data for 16 or 32 consecutive drum revolutions are evaluated. In particular, it is anticipated that for 2 turns the sensor data will be evaluated, where P is a natural number greater than zero. If such a number of revolutions is evaluated, for example, a frequency analysis, in particular a Fourier transformation, can be carried out in a simple manner.

Furthermore, it is advantageous if, based on the sensor signal, an equal number of discrete measured values is determined for each of the revolutions. In the operation of the washing machine, it may be the case that the speed is increased, for example. If the sensor signal is sampled at a constant sampling rate, this results in a different number of samples depending on the number of revolutions per revolution. This problem can be remedied, in particular, by scanning the sensor signal at a constant sampling rate and, depending on the rotational speed at which the respective revolution was carried out, for example, measured values are determined on the basis of the sampled values by means of interpolation. Thus, it can be reliably achieved that the same number of discrete measured values are available for each revolution. This allows reliable comparison of the respective sensor data acquired during the respective revolutions.

In a further embodiment, an order analysis of the sensor data is carried out for detecting the oscillation of the bearing device, wherein the order analysis describes the respective energy of the sensor signal for a plurality of orders. In this case, the energy content of the oscillation of the bearing device is plotted over the order. The order can be a multiple of the speed. In other words, each order in a known manner corresponds to a predetermined multiple of the rotational frequency defined by the rotational speed. By means of the order analysis can be determined in a simple way, in which orders of the sensor signal is a relatively high amount of energy. It can also be examined whether these orders are then assigned to the vibration of the bearing device. Thus, the vibration of the bearing device can be easily detected.

In principle, it can also be provided that a frequency spectrum of the sensor signal is determined for detecting the oscillation of the bearing device. Thus, it can be determined, for example, whether the sensor signal has corresponding frequency components that are due to the vibration of the bearing device.

In addition, it is advantageous if those orders which are assigned to a possible oscillation of the bearing device are selected from the plurality of orders of the order analysis, and the selected orders for detecting the oscillation are checked. It can also be provided that those orders are selected from the plurality of orders, which are assigned to a so-called bang effect or a stroke of the bearing device. In other words, the order analysis can not take into account those orders which, with a high probability, do not originate from the vibration of the storage facility. For example, the orders can be removed from the order analysis, which are due to an imbalance, for example. These are in particular dominant orders. Furthermore, higher orders can be removed. Thus, those orders can be examined, possibly derived from a possible vibration. Thus, for example, computing time can be saved.

In a further embodiment, an average value is determined for checking the selected orders from a predetermined number of the selected orders, and the predetermined number of selected orders is assigned to the vibration of the storage facility if the determined average exceeds a predetermined threshold. From the selected orders, which are highly likely from the vibration of the storage facility, each of a certain number can be selected. From this certain number then the mean can be determined. In principle, it is also conceivable that a median is determined. The determined average may then be compared to a predetermined threshold. If this threshold is exceeded, it can be assumed with high probability that the orders of which the mean value was determined are attributable to the oscillation. Thus, the vibration of the bearing device can be easily identified. In addition, it can be determined which of the selected orders are to be assigned to the oscillation.

In this case, provision is made in particular for the predetermined number to be determined in succession from the selected orders and the mean value to be determined for the predetermined number of selected orders. In other words, a window is defined in which the predetermined number of orders are arranged. This window will be moved step by step along the orders. For each of the steps of moving the window, the average is then formed and compared to the threshold. Thus, the orders can be evaluated with a low computational power within a short time duration.

Furthermore, it is advantageous if the current speed is reduced by a predetermined speed value for changing the speed, if the current speed is within a predetermined Enddrehzahlbereichs. For example, an end speed range may be over a range of 85 Percent of a final speed to 100 percent of the final speed extend. It is provided that the speed is reduced by the predetermined speed value, if the vibration of the bearing device is detected. Thus, the washing machine can be operated in a speed range in which the bearing device, for example, is no longer excited to the vibrations.

In a further embodiment, the current speed is increased by a predetermined speed value for changing the speed, if the current speed is below the predetermined end speed range. If the speed of the laundry drum has not yet reached the final speed range, it is possible to increase the speed if the vibration of the bearing device is detected. It can also be provided that the current speed is increased within a predetermined time duration by the predetermined speed value. Thus, it can be achieved, for example, that the critical speed range in which the bearing device is excited to oscillate is left as quickly as possible.

An inventive household appliance for the care of items of laundry comprises a laundry drum for receiving laundry items, wherein the laundry drum is rotatably supported by means of a bearing device. In addition, the household appliance comprises a drive motor for rotating the laundry drum at a current speed. Furthermore, the household appliance comprises a sensor device for providing sensor data which describe a vibration of at least one component of the household appliance. Furthermore, the household appliance comprises an evaluation device for receiving the sensor data and for driving the drive motor to change the current speed as a function of the received sensor data. In this case, the evaluation device is designed to detect a vibration of the bearing device based on the sensor data and to drive the drive motor to change the rotational speed of the laundry drum, if the vibration of the bearing device is detected.

The embodiments presented with reference to the method according to the invention and their advantages apply correspondingly to the household appliance according to the invention.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. The features and feature combinations mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures, can be used not only in the respectively specified combination but also in other combinations or in isolation, without the frame to leave the invention. There are therefore also embodiments of the invention as encompassed and disclosed, which are not explicitly shown and explained in the figures, however, emerge and can be generated by separate feature combinations of the described embodiments. Embodiments and combinations of features are also to be regarded as disclosed, which thus do not have all the features of an originally formulated independent claim.

The invention will now be described with reference to preferred embodiments and with reference to the accompanying drawings. Showing:

1 from household appliance for the care of laundry in a schematic representation;

2 a flowchart of a method for operating the household appliance according to an embodiment of the present invention;

3 the evaluation of sensor signals of a sensor device of the household appliance based on an order analysis;

4 a schematic flow diagram of a method for evaluating the sensor signals; and

5 a schematic flow diagram for operating the household appliance according to an embodiment of the present invention.

In the figures, identical and functionally identical elements are provided with the same reference numerals.

1 shows a schematic representation of a household appliance 1 according to an embodiment of the invention. The household appliance 1 In the exemplary embodiment, a device for the care of laundry items, for example a washing machine, a tumble dryer or a washer-dryer. In known manner, the household appliance 1 a laundry drum 2 for picking up laundry items. The laundry drum 2 is about a belt 3 by means of a drive device 4 driven. As an alternative to the belt drive, a direct drive can also be provided here. The drive device 4 comprises an electric machine, which has a schematically indicated stator 5 and a rotor also shown schematically 6 having. In addition, the home appliance points 1 an evaluation device 7 on, by means of which the drive device 4 can be controlled. The evaluation device 7 can, for example, a Microcontroller and / or a digital signal processor include. The household appliance 1 also includes a control panel 8th with controls and optionally a display element or display. The control panel 8th serves to select an operating program and to set other operating parameters of the household appliance 1 ,

The laundry drum 2 is by means of a storage facility 9 stored. In particular, the storage device 9 have at least one rolling bearing. Furthermore, the household appliance includes 1 a sensor device 10 , which serves to oscillations of the storage facility 9 capture. In the sensor device 10 For example, it may be an acceleration sensor that can absorb accelerations in three spatial directions. With the sensor device 10 can vibrations of the bearing device 9 during operation of the household appliance 1 be recognized. For this purpose, the sensor device 10 be arranged for example in the area of the tub. The sensor device 10 can also be designed to detect structure-borne noise and / or sound waves, which are due to the vibration of the bearing device 9 result. The vibration of the storage facility 9 results, for example, in that the rolling elements of the bearing device 9 lift off the tread in certain operating conditions and then hit the tread again.

The evaluation device 7 is for data transmission with the sensor device 10 connected. With the sensor device 10 Sensor data is provided which determines the vibration of the bearing device 9 describe. This sensor data can then be determined by means of the evaluation device 7 be evaluated. If with the evaluation device 7 it is recognized that the storage facility 9 can swing, the drive motor 4 be controlled accordingly. In particular, the speed of the drive motor 4 and thus the speed of the laundry drum 2 to be changed. Thus, the household appliance 1 be operated at a speed at which the storage facility 9 no longer excited to the vibrations. Thus, noises and in particular sound waves in the operation of the household appliance 1 be reduced.

2 shows a schematic flow diagram of a method for operating the household appliance 1 , The method is started in a step S1. The process is started, for example, when the home appliance 1 or the drive device 4 reached a start speed. This starting speed may for example correspond to a predetermined spin speed. It can also be provided that the starting time or the time for the start of the process of a loading amount of the laundry drum 2 is made dependent. In particular, the method is started when it can be guaranteed that no resonance phenomena occur during the current and the following, increasing speed. In a step S2, a sampling rate for the sensor device 10 or the acceleration sensor specified. In a step S3, the number of revolutions of the laundry drum 2 certainly. In a step S4, based on the samples of the sensor data and the determined number of revolutions of the laundry drum 2 determined discrete measured values. In this case, the same number of discrete measured values can be determined for each of the revolutions. Thus, for example, a corresponding interpolation of the samples can be performed.

In a step S5, the determined discrete measured values are stored in a memory. Subsequently, in a step S6, a data reduction takes place. In this case, the measured values can be counted to a number of 2 be converted. Subsequently, in a step S7, data interpolation takes place. Here, the measured values can be entered one after the other in a common vector. For steps S6 and S7, make sure that the readings are the readings from multiple, complete drum revolutions. Subsequently, in a step S8, a frequency spectrum of the sensor signal or of the discrete measured values of the sensor signal is determined. Thereafter, an order analysis is performed or an order spectrum determined in a step S9. In a step S10 it is checked on the basis of the order analysis, whether a vibration of the bearing device 9 is present. If a vibration has been detected, in a step S11, the rotational speed of the drive device 4 customized. It should be noted that the speed is increased in the conventional process step up to a final speed. Increasing or decreasing the speed is a characteristic of the spin process itself. The method described here only affects the speed if the vibration of the bearing device 9 was detected.

3 schematically shows how the order analysis, the vibration of the storage facility 9 can be recognized. It is in 3 a first diagram 11 the order analysis shown. The individual orders O are plotted along the abscissa. The ordinate describes the amount of energy of the respective orders. First, in the order analysis those orders are determined that are not the vibration of the storage facility 9 are assigned. These are for example an offset 12 or a dominant order 13 which forms, for example, as a result of an imbalance. In addition, higher orders 14 not considered. Another diagram 15 show the selected orders used to detect the vibration of the storage facility 9 are relevant. In another diagram 16 is the review of these selected orders shown. This will be a window 17 defined, which comprises a predetermined number of selected orders. The window 17 includes a predetermined number of selected orders. For each of these orders a mean value is calculated 18 certainly. Here is the window 17 moved gradually along the orders. For each step or at each position then the mean value 18 certainly.

4 shows a schematic flow diagram of a method for detecting the vibration of the bearing device 9 based on order analysis. In this case, the method is started in a step S12. In a subsequent step S13, as previously described in connection with 3 explains the respective averages. This will be the window 17 moved along the respective orders. At each of the positions, the arithmetic mean is then formed. By averaging very short orders, which arise in the calculation of the spectrum, can be compensated. Subsequently, it is checked in a step S14 whether a predetermined number of average values 18 is greater than a predetermined factor times the mean at the start time. For example, it can be checked if there are three consecutive averages 18 are greater than 1.5 times the mean 18 at the start time. If this is not the case, the method is continued in a step S15. Here, it is determined that the predetermined number of consecutive averages 18 are greater than a certain factor times the mean at the start time. Subsequently, in a step S16, the previous result is discarded.

If the check in step S14 shows that the predetermined number of average values 18 which succeed each other are larger than a certain factor times the mean value at the start time, becomes the next average value 18 checked in the series and it is examined whether this by a predetermined factor, for example, 0.8 times the current average 18 can be, has sunk. Subsequently, it is checked in a step S18 whether a signal peak has been detected in the orders or the selected orders, which is responsible for the oscillation of the bearing device 9 or the vibration generated thereby is typical. In a step S19 it can then be checked whether a predetermined number of signal peaks has been reached. If this is the case, an alarm can be output in a step S20 or the rotational speed by means of the drive device 4 to be changed.

5 shows a schematic flow diagram for operating the household appliance 1 according to a further embodiment. In this case, it is first checked in a step S21 whether the oscillation of the bearing device 9 based on order analysis. In a step S22 it is checked whether the predetermined final speed has been reached. If this is the case, the speed is reduced by a predetermined speed value in a step S23. This predetermined speed value can, for example 100 Revolutions per minute. In a step S24, the alarm that occurs upon detection of the vibration of the bearing device 9 was issued, deleted.

Furthermore, it can be provided that in a step S22 'it is checked whether the current rotational speed is greater than 85 percent of the final rotational speed. If this is the case, the speed in step S23 'can also be lowered by the predetermined speed value. It can also be provided that it is checked in a step S22 "whether the current speed is less than 85 percent of the final speed. If this is the case, the current speed can be increased in a step S23 ".

With the illustrated method, the household appliance 1 operated such that disturbing noises caused by the vibrations of the bearing device 9 are justified. Thus, a low-noise operation of the household appliance 1 be enabled. By using the sensor device 10 , in particular the acceleration sensor, and the signal evaluation by means of the order analysis, the vibration of the bearing device 9 be recognized at an early stage. Thus, this vibration of the bearing device 9 be recognized, for example, before the structure-borne noise propagates through the vibration of the bearing device, which then can result in an airborne sound again. Instead of the order analysis described above, other statistical methods for evaluating the sensor signal can also be used. For example, only the frequency spectrum could be considered. Instead of the averaging described above, a group-based median can also be formed, which is compared, for example, with a corresponding threshold value.

LIST OF REFERENCE NUMBERS

1

 household appliance

2

 washing drum

3

 belt

4

 driving means

5

 stator

6

 rotor

7

 evaluation

8th

 control panel

9

 Storage facility

10

 sensor device

11

 diagram

12

 offset

13

 dominant order

14

 higher order

15

 diagram

16

 diagram

17

 window

18

 Average

e

 energy

S1-S24

 step

S22 ', S22' '

 step

S23 ', S23' '

 step

O

 order

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011083568 A1 [0003]
• US 5930855 A [0004]

Claims (13)

Method for operating a household appliance ( 1 ) for the care of laundry, in which a laundry drum ( 2 ) for receiving laundry items by means of a drive motor ( 4 ) is rotated at a current speed, the laundry drum ( 2 ) by means of a storage device ( 9 ) is rotatably mounted by means of a sensor device ( 10 ) Sensor data are provided which a vibration of at least one component of the household appliance ( 1 ), and by means of an evaluation device ( 7 ) the sensor data are received and the drive motor ( 4 ) is controlled to change the current speed as a function of the received sensor data, characterized in that by means of the evaluation device ( 7 ) based on the sensor data a vibration of the storage facility ( 9 ) and the drive motor ( 4 ) is controlled to change the current speed, if the vibration of the bearing device ( 9 ) is recognized. A method according to claim 1, characterized in that a characteristic value, in particular an energy value or a vibration amplitude, the vibration of the bearing device is determined, and the drive motor for changing the current speed depending on the determined characteristic value, in particular the energy value or the amplitude is controlled. A method according to claim 2, characterized in that a comparison of the determined characteristic value is carried out with a predetermined threshold value and the change of the current speed occurs when exceeding the predetermined threshold value. Method according to one of claims 1 to 3, characterized in that the sensor device ( 10 ), by means of which the sensor data are provided, comprises an acceleration sensor. Method according to one of the preceding claims, characterized in that a number of revolutions of the laundry drum ( 2 ) is determined during the rotation and the sensor data are evaluated for a predetermined number of revolutions. A method according to claim 5, characterized in that based on the sensor signal for each of the revolutions an equal number of discrete measured values is determined. Method according to one of the preceding claims, characterized in that for detecting the oscillation of the bearing device ( 9 ) an order analysis of the sensor data is performed, wherein the order analysis describes the respective energy (E) of the sensor signal for a plurality of orders (O). Method according to Claim 7, characterized in that, of the plurality of orders (O) of the order analysis, those orders are selected which correspond to a possible oscillation of the bearing device ( 9 ) and the selected orders for detecting the vibration are checked. A method according to claim 8, characterized in that for checking the selected orders of a predetermined number of the selected orders an average value ( 18 ) and the predetermined number of selected orders are assigned to the oscillation, if the determined mean value ( 18 ) exceeds a predetermined threshold. Method according to claim 9, characterized in that in each case the predetermined number of the selected orders is determined in each case and for each predetermined number of selected orders the average value ( 18 ) is determined. Method according to one of the preceding claims, characterized in that for changing the speed, the current speed is reduced by a predetermined speed value, if the current speed is within a predetermined Enddrehzahlbereichs. Method according to one of the preceding claims, characterized in that for changing the speed, the current speed is increased by the predetermined speed value, if the current speed is below the predetermined end speed range. Household appliance ( 1 ) for the care of laundry, with a laundry drum ( 2 ) for receiving laundry items, wherein the laundry drum ( 2 ) by means of a storage device ( 9 ) is rotatably mounted, with a drive motor ( 4 ) for turning the laundry drum ( 2 ) at a current speed, with a sensor device ( 10 ) for providing sensor data which a vibration of at least one component of the household appliance ( 1 ), and with an evaluation device ( 7 ) for receiving the sensor data and for driving the drive motor ( 4 ) for changing the current rotational speed as a function of the received sensor data, characterized in that the evaluation device ( 7 ) is adapted, based on the sensor data, a vibration of the bearing device ( 9 ) and the drive motor ( 4 ) to control the speed change, if the vibration of the storage facility ( 9 ) is recognized.

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