EP3162266A1 - Reinigungsgerät und verfahren zum betrieb eines reinigungsgerätes - Google Patents

Abstract

The invention relates to a cleaning device (1), in particular household vacuum cleaner, with a blower (2) and an evaluation and control device (4) for varying a suction power of the blower (2) in dependence on a determined assignment state of the cleaning device (1) to a surface (3), namely a contact state, in which the cleaning device (1) is placed on the surface (3), or a Nonkontaktzustand in which the cleaning device (1) is lifted from the surface (3). In order to create a cleaning device (1) with which a cleaning task which is remote from the surface can also be carried out successfully, it is proposed that the evaluation and control device (4) is set to set the suction power to a higher level when determining a non-contact state than when determining a contact state. Furthermore, the invention relates to a method for operating a cleaning device (1).

Description

Field of engineering

The invention relates to a cleaning device, in particular a household vacuum cleaner, with a blower and an evaluation and control device for varying a suction of the blower in response to a determined assignment state of the cleaning device to a surface, namely a contact state in which the cleaning device is placed on the surface , or a non-contact state in which the cleaning device is lifted off the surface.

Furthermore, the invention relates to a method for operating a cleaning device, wherein a state of assignment of the cleaning device is determined to a surface, namely a contact state in which the cleaning device is placed on the surface, or a non-contact state in which the cleaning device is lifted from the surface , and wherein a suction power of a blower of the cleaning device is varied in dependence on the determined assignment state of the cleaning device.

State of the art

There are already known cleaning devices or methods for operating a cleaning device in which the suction power of the fan is varied depending on a determined assignment state of the cleaning device to a surface, d. H. depending on whether the cleaning device is on the surface to be cleaned or lifted off from it.

The patent EP 2 548 491 B1 discloses, for example, a vacuum cleaner with an evaluation and control device, which means for reducing the electrical power consumption of a blower during a non-use of the vacuum cleaner, in which it is lifted from the surface has.

The disadvantage here is that the suction power of the blower is always reduced when the cleaning device is lifted off the surface. As a result, no optimal suction power is available, for example, to remove cobwebs in a ceiling area of a room.

Summary of the invention

Based on the illustrated prior art, it is an object of the invention to provide a cleaning device, with which a cleaning task remote from the surface, for example in the field of a ceiling, can be successfully carried out.

To achieve this object, the invention proposes that the evaluation and control device of the cleaning device is set to set the suction power when determining a Nonkontaktzustandes to a higher amount than when determining a contact state.

According to the invention, the cleaning device is now designed or set up so that the suction power is increased when lifting the cleaning device from a surface, so that even then optimal suction power is available when, with the cleaning device, deviating from a usual use, a spider web or the like should be removed on a ceiling. A cleaning device according to the aforementioned prior art does not allow such a surface-distant cleaning with increased suction power just because a decrease in the cleaning device is just a power reduction. The cleaning device according to the invention has a Device for detecting a state in which the cleaning device is lifted off the surface. This evaluation and control device can work in different ways, as will be explained below.

The evaluation and control device is advantageously associated with a data storage device in which reference data are stored for different assignment states of the cleaning device. The evaluation and control device is designed to compare current measurement data, which indicate the assignment state, with this reference data. Depending on the assignment state determined therefrom, the evaluation and control device subsequently controls the blower of the cleaning device, wherein corresponding control commands can likewise be stored in the data storage device.

It is proposed that the evaluation and control device is designed to compare a volume flow currently generated by the blower of the cleaning device with a predetermined volume flow threshold, which corresponds in particular to a non-contact state of the cleaning device, and to increase the suction power of the blower if the volume flow rate is exceeded. Threshold to increase by the current flow rate. In a contact state of the cleaning device, the volume flow generated by the blower is lower than during a non-contact state in which air without obstruction can pass through an area from outside the cleaning device to the blower. The volume flow is thus dependent inter alia on a flow resistance which the air flowing to the fan experiences between the cleaning device and a surface. In the event that the cleaning device is not standing on a surface, the air can flow to the fan with a larger volume flow. The characteristic Volumetric flow can be stored as a volume flow threshold within the data storage device associated with the evaluation and control device. If a currently determined volume flow exceeds this volume flow threshold value, the evaluation and control device determines a non-contact state of the cleaning device, whereupon the evaluation and control device causes the increase of the suction power of the blower. The volume flow currently generated by the blower is determined by means of a blower characteristic of the blower, which contains a pressure increase measured during operation of the blower or an electric power received by the blower. The volume flow therefore does not have to be measured directly, but can be derived from other measured parameters (pressure, power, etc.). If a current volume flow results which exceeds the predefined volumetric flow threshold value, the suction power of the fan is increased, so that even cleaning tasks that are remote from the surface, such as, for example, the removal of a spiderweb under a ceiling, can be carried out successfully.

Furthermore, it is alternatively or additionally proposed that the cleaning device has a contact sensor, which is arranged on the cleaning device such that it is placed on the surface during a contact state. Instead of determining the assignment state of the cleaning device indirectly via the volume flow generated by the fan, the contact sensor directly detects a contact between the cleaning device and the surface. The contact sensor is advantageously arranged with respect to a conventional cleaning of a bottom surface under the cleaning device, so that the contact sensor immediately detects the contact state when the cleaning device is placed on the surface. The contact sensor can be designed, for example, as a pressure sensor, optical sensor or the like. According to one embodiment, the cleaning device, for example, both have a contact sensor, as well as a determination of the volume flow use. As a result, it can be prevented, for example, that a contact state is erroneously determined on the basis of a low volume flow caused by other causes. As additional security in the determination of the assignment state, not only a current volume flow is used, but also a detection result of the contact sensor.

Furthermore, it is proposed that the evaluation and control device is designed to increase the suction power of the fan when determining a Nonkontaktzustandes to a predetermined maximum value. A volume flow exceeding the volume flow threshold or a determined contact between the cleaning device and a surface thus leads to a maximum increase in the suction power of the fan. Regardless of the amount of the current volume flow, the suction power is increased to a maximum, so that an optimal cleaning is always possible.

Furthermore, it is proposed that the cleaning device has a time detection device, which is designed to determine the duration of a current assignment state of the cleaning device, wherein the evaluation and control device is designed to vary the suction depending on the duration of the assignment state only when the Duration exceeds a predetermined minimum duration. The evaluation and control device of the cleaning device is thus designed not to evaluate each short-term lifting of a surface as a non-contact state. During a typical cleaning operation, it may happen that the user lifts the cleaning device from the surface, for example, to implement it in another direction, to overcome an obstacle such as a carpet edge or the like. Such a temporally relatively short event should not be regarded as a transition from a contact state to a noncontact state become. Therefore, the time detection device detects the duration of the currently effective assignment state and transmits it to the evaluation and control device. The evaluation and control device compares the duration with a preferably stored in the data storage device minimum duration, which is crucial for whether the change in state is regarded as an actual change of the assignment state of the cleaning device, or only a short-term interruption of the contact state of the cleaning device is present. The predetermined minimum duration, from which an assignment state is evaluated, for example, as a non-contact state, can be, for example, 2 seconds. Only when exceeding this period of 2 seconds, the evaluation and control device increases the suction power of the fan. If the current assignment state, in particular the non-contact state, lasts less than these 2 seconds, the suction power of the fan is not changed. The same applies mutatis mutandis to a change from a non-contact state in a contact state, ie, the suction power is reduced only when starting from a non-contact state, a contact state over a period of more than 2 seconds is determined.

In addition to the previously presented cleaning device, the invention also proposes a method for operating a cleaning device, in particular for operating a cleaning device of the aforementioned type, wherein a state of assignment of the cleaning device is determined to a surface, namely a contact state in which the cleaning device placed on the surface is, or a non-contact state in which the cleaning device is lifted from the surface, and wherein a suction power of a blower of the cleaning device in dependence on the determined assignment state of the cleaning device is varied, and wherein the suction power is determined upon detection of a Nonkontaktzustandes to a higher amount than upon determination of a contact state. The invention thus achieved Advantages result as previously explained with respect to the cleaning device according to the invention.

Furthermore, it is proposed that, to determine the current assignment state, a current volume produced by the fan is determined and compared with a predetermined volume flow threshold, which corresponds in particular to a noncontact state of the cleaning device, the suction power of the fan being exceeded when the preset volume flow rate is exceeded. Threshold is increased. As explained above with respect to the cleaning device according to the invention, it is not necessarily necessary to measure the volume flow directly. Rather, the volume flow can be derived from a current pressure increase of the blower or also current and voltage values of the blower. For this purpose, the blower characteristics of the blower are used. The evaluation and control device of the cleaning device preferably accesses a data storage device which contains volume flow threshold values for comparison with the currently determined volume flow values. The volumetric flow threshold values advantageously correspond in particular to a non-contact state of the cleaning device, but may also be less than a volumetric flow, which clearly represents a non-contact state of the cleaning device. For example, a volumetric flow threshold value may be stored which is higher than a volumetric flow during a customary cleaning process, but less than a volumetric flow when the scrubber is completely lifted off the surface. For example, a volume flow may be defined at which the cleaning device only partially rests on a surface, for example only with one edge of an attachment.

Furthermore, it is proposed that the current assignment state is determined by means of a contact sensor of the cleaning device. This Contact sensor may be, for example, a pressure sensor or an optical sensor. The method according to the invention can then equally include a contact measurement and / or a determination of the volumetric flow, which may result in a redundancy which offers additional security in the case of a state of assignment that can not be determined unambiguously.

It is proposed that the suction power of the fan is increased to a predetermined maximum value when a non-contact state is determined.

Finally, it is provided that a duration of the current assignment state of the cleaning device is determined, wherein the suction power is varied only when the duration exceeds a predetermined minimum duration. As explained above with respect to the cleaning device according to the invention, only short-term changes in the assignment state can not lead to a change in the current suction power of the blower in terms of time. The predetermined minimum duration may be, for example, at least 2 seconds, assuming that the user needs at least 2 seconds to lift the cleaning device from a floor surface to remove a spiderweb under a ceiling. However, there are also other minimum durations conceivable, depending on the purpose of the cleaning device.

Brief description of the drawings

Fig. 1

Ein Reinigungsgerät während eines Nonkontaktzustandes.

In the following the invention will be explained in more detail with reference to an embodiment. It shows:

Fig. 1

A cleaning device during a non-contact state.

Description of the embodiments

The cleaning device 1 shown in the figure is designed as a hand vacuum cleaner, which usually serves to clean a surface 3. The surface 3 here is a bottom surface, but it could also be cleaned over-ground surfaces by means of the cleaning device 1.

The cleaning device 1 has a base unit 6 and a header 5. The header 5 is detachable from the base 6, so that the base 6 can be used without the header 5. The base unit 6 has a handle 7, which is here preferably telescopic, so that a user of the cleaning device 1 can set a comfortable length for him. On the handle 7, a handle 8 is arranged, on which the user can guide the cleaning device 1 during a cleaning operation. For example, switches, such as an on-off switch, can be arranged on the handle 8. In the base unit 6, a fan 2 is arranged, which generates an air flow through the cleaning device 1 during operation, so that suction material through the header 5 passes through the base unit 6, for example, a filter chamber disposed therein, so that only purified air to the Blower 2 passes. The cleaning device 1 further has an evaluation and control device 4, which here for example comprises a data storage device and a time recording device (stopwatch, timer or the like).

The evaluation and control device 4 is connected to the blower 2 and designed to vary the suction power of the blower 2 as a function of a current spatial allocation state of the cleaning device 1 to the surface 3. A spatial assignment state here is, for example, a contact state of the cleaning device 1, in which the cleaning device 1 stands on the surface 3. Another spatial assignment state is a Noncontact state of the cleaning device 1, in which the cleaning device 1 is lifted off the surface 3 as shown in the figure. In addition, further spatial assignment states may be defined, for example those which also include an angle of inclination of the cleaning device 1 to the surface 3, namely those in which the cleaning device 1 is rotated for example for a cleaning activity under a ceiling by 180 degrees, ie Attachment 5 points upward.

In order to determine the current spatial assignment state of the cleaning device 1, the evaluation and control device 4 continuously or at defined intervals from current operating parameters of the blower 2, which suggest whether the cleaning device 1 is currently on the surface 3 or lifted off this , Here, the evaluation and control device 4 is connected to a sensor which determines the current recorded by the blower 2 power. The power results in the usual way from the voltage and the current required by the blower 2 current. From known blower characteristics of the blower 2 can be concluded based on the current power consumption of the blower 2 on the volume flow generated by the blower 2. This determined volume flow is compared by the evaluation and control device 4 with a predetermined volume flow threshold, which is stored in the data storage device. The predetermined volumetric flow threshold corresponds to a volume flow which occurs in the case of a non-contact state of the cleaning device 1. If the currently determined volume flow of the blower 2 is greater than this predetermined volume flow threshold or equal to this volume flow threshold, the evaluation and control device 4 concludes that the cleaning device 1 is currently in a non-contact state. The evaluation and control device 4 then controls the blower 2 such that the suction power of the blower 2 is increased. This is done regularly by increasing the speed of the fan motor. The fan 2 has now a sufficiently large suction, so that the user of the cleaning device 1, for example, can remove cobwebs under a ceiling. Preferably, the suction power of the blower 2 is increased to a predetermined maximum value.

During the non-contact state of the cleaning device 1, the sensor continues to measure the power consumption of the blower 2 and transmits the measured values to the evaluation and control device 4. The evaluation and control device 4 continuously compares these measured values with the predetermined threshold value and reduces the suction power of the blower 2 as soon as detected is that the volume flow currently generated by the blower 2 is less than the predetermined volume flow threshold. When the current volume flow drops below the threshold value, a contact state of the cleaning device 1 is detected, so that then the suction power of the fan 2 is reduced.

Before the evaluation and control device 4 increases or reduces the suction power of the blower 2, the current spatial allocation state must additionally exist over a predetermined minimum duration. The lifting of the cleaning device 1 of the surface 3 thus does not immediately at the moment of lifting off the surface 3 to increase the suction power, but only when this state is a predetermined minimum period of time. For this purpose, the evaluation and control device 4, the time detection device, which is designed to determine the duration of the current spatial assignment state. The time recording device measures the time from the moment the cleaning device 1 is lifted off the surface 3 or the time from the moment the cleaning device 1 is placed on the surface 3. The evaluation and control device 4 compares the measured time duration with a predetermined minimum duration. The predetermined minimum duration is stored in the data storage device. As soon as the current time duration exceeds the predetermined minimum duration, the evaluation and control device 4 varies the suction power of the blower 2.

Based on a state change in which the cleaning device 1 is lifted off the surface 3, the time detection device is first started at the time of lifting, while the suction power remains constant. Only when the lifted non-contact state of the cleaning device 1 lasts longer than the predetermined minimum duration, the evaluation and control device 4 controls the blower 2 such that the suction power is increased. In the same way, the variation of the suction power also occurs when the cleaning device 1 is transferred from a non-contact state to a contact state. Even then, the suction power is reduced only when the predetermined minimum duration is exceeded.

In addition to or as an alternative to the above-described determination of the spatial assignment state based on the volume flow generated by the blower 2, the spatial assignment state can also be measured with the aid of one or more contact sensors which are arranged on the cleaning device 1 such that they touch the surface during a contact state 3 are attached. The contact sensor (s) may be, for example, pressure sensors, optical sensors or the like.

List of reference numbers

1

cleaner

2

fan

3

area

4

Evaluation and control device

5

header

6

basic unit

7

stalk

8th

handle

Claims (10)

Cleaning device (1), in particular household vacuum cleaner, with a blower (2) and an evaluation and control device (4) for varying a suction power of the blower (2) in dependence on a determined assignment state of the cleaning device (1) to a surface (3), namely a contact state in which the cleaning device (1) is placed on the surface (3), or a Nonkontaktzustand in which the cleaning device (1) is lifted from the surface (3), characterized in that the evaluation and control device ( 4) is set to set the suction power when determining a Nonkontaktzustandes to a higher amount than when determining a contact state. Cleaning device (1) according to claim 1, characterized in that the evaluation and control device (4) is formed, a current of the blower (2) of the cleaning device (1) generated volume flow with a predetermined volume flow threshold, which in particular a non-contact state of Cleaning device (1) corresponds, and to increase the suction power of the blower (2) when the volume flow threshold is exceeded by the current flow rate. Cleaning device (1) according to claim 1 or 2, characterized by a contact sensor which is arranged on the cleaning device (1) such that it is placed on the surface (3) during a contact state. Cleaning device (1) according to one of the preceding claims, characterized in that the evaluation and control device (4) is formed is to increase the suction power of the blower (2) when determining a non-contact state to a predetermined maximum value. Cleaning device (1) according to one of the preceding claims, characterized by a time detection device, which is designed to determine the duration of a current assignment state of the cleaning device (1), wherein the evaluation and control device (4) is formed, the suction power depending on the duration of the assignment state to vary only if the duration exceeds a predetermined minimum duration. Method for operating a cleaning device (1), in particular a cleaning device according to one of the preceding claims, wherein an association state of the cleaning device (1) is determined to a surface (3), namely a contact state in which the cleaning device (1) on the surface ( 3), or a Nonkontaktzustand in which the cleaning device (1) is lifted from the surface (3), and wherein a suction of a blower (2) of the cleaning device (1) in dependence on the determined assignment state of the cleaning device (1) is varied, characterized in that the suction power is set upon determination of a non-contact state to a higher amount than when determining a contact state. A method according to claim 6, characterized in that for determining the current assignment state, a current of the fan (2) generated volumetric flow and with a predetermined volumetric flow threshold, which in particular a non-contact state of the cleaning device (1) corresponds, the suction power the blower (2) is increased when the predetermined volume flow threshold value is exceeded. A method according to claim 6 or 7, characterized in that the current assignment state by means of a contact sensor of the cleaning device (1) is determined. Method according to one of claims 6 to 8, characterized in that the suction power of the blower (2) is increased upon determination of a Nonkontaktzustandes to a predetermined maximum value. Method according to one of claims 6 to 9, characterized in that a duration of the current assignment state of the cleaning device (1) is determined, wherein the suction power is not varied until the duration exceeds a predetermined minimum duration.

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