EP1631180A2

EP1631180A2 - Vacuum cleaner comprising a control device for a cleaning device for a ceramic filter

Info

Publication number: EP1631180A2
Application number: EP04739231A
Authority: EP
Inventors: Wolfgang Kemmerzell; Albert Kleinhenz; Michael Krammer; Thomas Strehler
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2003-05-15
Filing date: 2004-05-17
Publication date: 2006-03-08
Also published as: CN1791350A; WO2004100746A2; DE10321919A1; WO2004100746A3

Abstract

The invention relates to a device for separating particles (10) from the air, especially for filtering dust in a vacuum cleaner, said device comprising a housing (1) containing a motor/fan unit (11) for sucking air loaded with particles via an inlet (8), guiding said air through a ceramic filter (6), the particles (10) falling on the surface (18) of the ceramic filter on the inflow side, and for blowing out cleaned air on the outflow side via an outlet (19). In order to be able to operate a cleaning device (20) for the ceramic filter (6) as required, the inventive device comprises a control system (22) for operating the cleaning device (20). The inventive embodiment enables the cleaning mode to be switched on and off either automatically by the control system (22) or according to the decision of a user.

Description

Vacuum cleaner with a control device for one

Cleaning device for ceramic filters

The invention relates to a device for separating particles from air, in particular for filtering out dust in a vacuum cleaner according to the preamble of claim 1.

From WO 01/41619 A1 a vacuum cleaner with a housing and a blower is known, which has a dust separator and a dust collection unit. Air is led from the vacuum cleaner nozzle into an inlet chamber of the dust separator via a suction hose. The air directed into the inlet chamber can escape from the inlet chamber via an outlet chamber which has a multiplicity of small holes. The outlet chamber has a vertically arranged cylindrical filter which is arranged concentrically within the outlet chamber. The cylindrical filter can be made of ceramic material. A disadvantage of such ceramic filters, however, is that the upstream surface of the ceramic filter becomes clogged with dust particles separated from the air flow as the operating time increases. Due to the clogged filter surface, the pressure drop on the filter is so great that the function of the vacuum cleaner is significantly impaired or even made impossible.

The object of the invention is to improve a generic device such that a cleaning device for the ceramic filter can be operated as required.

This object is achieved according to the invention in that the device has a cleaning device for removing particles attached to the ceramic filter, which can be operated by means of a controller for operating the cleaning device. The controller can switch the cleaning device on or off depending on the contamination state of the ceramic filter. The cleaning operation can be switched on or off by the control either automatically or depending on the decision of the user. The controller preferably has a sensor for generating an output signal as a function of the particles attached to the ceramic filter. This has the advantage that the cleaning device can be operated as required by means of the control. The efficiency of the device or the vacuum cleaner depends on the function of the ceramic filter. If a large number of particles are already attached to the ceramic filter, the passage openings or the channels within the ceramic filter are blocked and the effective area for the passage of the air to be cleaned is reduced as the attached particles increase. The consequence of this is that, on the one hand, the effective area on the ceramic filter for depositing particles is reduced, that is, the separating capacity for particles from the air is reduced. On the other hand, the reduction in the flow area at the ceramic filter results in an increasing pressure loss, which reduces the performance of the device or the vacuum cleaner. A very high pressure drop across the ceramic filter leads to a low air throughput through the device or the vacuum cleaner, which has the consequence that the cleaning effect for the surfaces to be vacuumed is impaired.

The sensor can advantageously be designed to measure a pressure loss on the ceramic filter. When measuring the pressure loss at the ceramic filter, it is not the actual quantity of the particles that have accumulated that is measured, but rather the amount present on the ceramic filter. Pressure loss is a measure of the size of the remaining flowable area on the ceramic filter. The effective flow-through area is decisive for the performance of the ceramic filter, regardless of the amount of particles already attached to the ceramic filter. For example, a relatively thin layer of particles that accumulates over a large part of the upstream surface of the ceramic filter can cause a very high pressure drop, whereas a large amount of particles that, for example, can only be found in a thick layer over a small area of the upstream surface of the ceramic filter causes a rather low pressure drop.

The sensor can be designed to generate the output signal on the basis of the measured value and a reference value. Due to the physical conditions, each ceramic filter, in particular a ceramic filter with a very fine flow-through structure and a high degree of separation, already has a relatively high pressure drop before particles are deposited on the surface of the ceramic filter. So is it makes sense depending on the type and size of the ceramic filter used and depending on the motor / blower unit present in the device or the vacuum cleaner to specify a reference value which defines the response behavior of the sensor for generating an output signal. The reference value suitable for a device is to be determined depending on the application and the device parameters.

The controller can preferably have a switching device for starting or stopping the cleaning operation of the cleaning device on the basis of an output signal of the sensor which is dependent on a differential pressure between the upstream surface and the downstream surface of the ceramic filter. In order to be able to carry out a very precise measurement of the differential pressure on the ceramic filter, it makes sense to carry out the differential pressure directly on the upstream surface and on the downstream surface of the ceramic filter. This enables the sensor to determine the exact differential pressure across the ceramic filter. Influencing factors that result from the construction of the other devices and that may also generate a pressure drop in the air flow can thus be excluded.

The switching device can be automatically switchable for starting or stopping the cleaning operation of the cleaning device. This has the advantage that the user does not have to pay attention to whether it is necessary to clean the ceramic filter. The device automatically measures the pressure loss at the ceramic filter using the sensor and, depending on a predetermined reference value, decides whether it is necessary to clean the ceramic filter. If, based on the measured value, it is necessary to clean the ceramic filter, the switching device switches the cleaning device on automatically. During the cleaning process, the control can continuously measure the pressure drop across the ceramic filter by means of the sensor and if the measured value of the sensor falls below a further reference value, the cleaning operation ends automatically.

As an alternative to such an automatic operation of the cleaning device, the switching device can also be used for starting and stopping the cleaning operation of the cleaning device by means of a manually operated actuating element be switchable. This has the advantage that the user can decide independently whether he wants to carry out a cleaning process or not.

The controller can have a first display center which, based on the output signal of the sensor, displays information about the degree of contamination of the ceramic filter. Such a display is particularly useful when the switching device for starting or stopping the cleaning operation is to be operated manually. If the sensor measures a pressure loss on the ceramic filter that is above the reference value, the control can indicate to the user through the display means that the ceramic filter is contaminated and cleaning of the ceramic filter is recommended. On the basis of the display of a degree of contamination of the ceramic filter, the user can then decide whether he wants to switch on the cleaning device manually. During the manually triggered cleaning operation, the display means can continue to show the degree of contamination. In addition to a digital display of the degree of contamination (dirty yes / no), the display means can also be designed such that it continuously shows the degree of contamination in an analogous manner. Such a continuous display can take place, for example, by means of a sequence of several light-emitting diodes, a number of light-emitting diodes corresponding to the degree of soiling lighting up depending on the degree of soiling. With such a display means, which can also function during the cleaning operation, the user is visually conveyed the progress of the cleaning operation even during the cleaning operation. If the display means shows little or no contamination on the ceramic filter, the user can, for example, manually switch the cleaning device off again. A display of the degree of contamination is not only useful with a manually switchable cleaning device, but also with an automatically operating and automatically switching cleaning device. In this way, even with an automatically switching cleaning device, the user can see how far the cleaning process has already progressed.

In particular, if the cleaning device can be switched automatically, it makes sense for the controller to have a second display which displays information about whether the cleaning device is started or the cleaning mode is finished. This has the advantage that the user receives information at any time as to whether the cleaning device is in operation or not.

In an advantageous embodiment of the invention, the cleaning device can be designed for thermal cleaning of the ceramic filter, i. H. the ceramic filter is cleaned by heating the ceramic filter, as a result of which the particles on the ceramic filter are pyrolyzed and the ceramic filter is thereby cleaned.

Alternatively, the cleaning device can be designed for mechanical or acoustic cleaning of the ceramic filter. Mechanical cleaning of the ceramic filter has the advantage that the device can be designed regardless of thermal requirements, i. H. the device or the vacuum cleaner can be produced more cost-effectively since no special means are required in order to be able to control the high temperatures which arise in a thermal cleaning operation.

As an alternative to mechanical cleaning, the ceramic filter can also be operated, for example, by acoustic means, i.e. are cleaned by a vibration generator, which preferably generates vibrations in the ultrasonic range. Such a vibration generator in the ultrasound range can be a piezo element, for example. When using a vibration generator or a piezo element, make sure that the vibration frequency is outside the resonance frequency of the ceramic filter in order to avoid destruction of the ceramic filter.

In the configuration as a mechanical cleaning device, the cleaning device can have a compressed air generator for blowing off the particles from the upstream surface of the ceramic filter. In a particularly advantageous embodiment, the existing motor / blower unit can be used as a compressed air generator in a vacuum cleaner, for example. Either the direction of rotation of the motor / blower unit must be reversed, or the overpressure side of the motor / blower unit must be connected to the surface of the ceramic filter on the outflow side. As an alternative to mechanical cleaning of the ceramic filter by blowing, other mechanical means, such as. B. scrapers or scratches, are used, which removes particles from the upstream surface of the ceramic filter.

The device can also have a conveying means for transporting particles, preferably detached from the surface of the ceramic filter, into a dust collector. In which a conveying means is provided, the particles detached from the ceramic filter can be conveyed into a dust collector separate from the filter ceramic. The dust collector can in particular be designed to be detachable from the device.

The invention is explained in more detail with reference to the figure.

The figure shows a schematic representation of a device according to the invention;

The schematic illustration in the figure shows a housing 1 of a vacuum cleaner. An intermediate wall 2 extends within the housing and separates the housing 1 into a blower chamber 3 and a dust chamber 4. The intermediate wall 2 has an opening section 5 through which suction air is drawn in from the dust chamber 4 into the blower chamber 3. The opening section 5 is covered by a ceramic filter 6. The ceramic filter 6 has an open-pore structure and can be produced, for example, as a foam ceramic in known processes. The ceramic filter 6 can be detachably fastened in the housing 1. A removal opening 7 can be formed on the housing 1, through which the detachable ceramic filter 6 can be removed from the housing 1. Dust-laden air can enter the dust chamber 4 via an inlet opening 8. In the embodiment of the device as a vacuum cleaner, the inlet opening 8 is formed by a coupling piece arranged in a dust chamber cover, to which a suction hose with a telescopic tube and nozzle can be connected (not shown). The bottom surface and parts of the side wall of the dust chamber 4, which are located below the ceramic filter 6, form a collecting container 9 for particles 10.

A motor / blower unit 11 is arranged within the blower chamber 3. The motor / blower unit 11 has an electric drive motor 12, the drive shaft 13 of which carries an impeller 14. The fan wheel 14 fluidically separates the fan chamber 3 into a vacuum chamber 15 and a pressure chamber 16. The Pressurized space. 15 is fluidly connected to a downstream surface 17 of the ceramic filter 6. Because of the negative pressure generated in the vacuum chamber 15 by the motor / blower unit 11, air laden with particles or dust is sucked into the dust chamber 4 via the inlet opening 8. The suction air flow is sucked through the open-pore ceramic filter 6 into the vacuum chamber 15. Due to the small pore size of a few micrometers of the ceramic filter 6, the particles 10 are retained in the dust chamber 4 without being able to pass through the ceramic filter 6. The particles 10 accumulate on an upstream surface 18 of the ceramic filter 6. The suction air stream freed from particles 10 passes via the impeller 14 from the negative pressure space 15 into the positive pressure space 16. From the overpressure chamber 16, the air cleaned of particles is blown out of the device via an outlet opening 19. By means of the motor / blower unit 11, air cleaned of particles is thus conveyed in a flow channel from the downstream surface 17 of the ceramic filter 6 for blowing out to the outlet opening 19. A cleaning device 20 is coupled to the ceramic filter 6. The cleaning device 20 can be a mechanical cleaning device such as, for example, a compressed air-operated blowing or suction device or mechanical scratches or sliders in order to repel the particles 10 from the ceramic filter 6. However, the cleaning device 20 can also be designed as an ultrasound generator, in particular as a piezo element, in order to detach the particles 10 from the ceramic filter 6 by means of vibration. Alternatively, the cleaning device 20 can be designed as a thermally operating pyrolysis device, by means of which particles 10 deposited on the ceramic filter 6 are burned.

The cleaning device 20 is connected to a switching device 21, by means of which the cleaning device 20 can be switched on and off. The switching command for the switching device 21 is generated by a controller 22. The controller 22 issues a switching command to the switching device 21 as a function of an input signal received from a sensor 23.

The sensor 23 measures a first pressure on the upstream surface 18 of the ceramic filter 6 via a first pressure line 31 and a second pressure on the downstream surface 17 of the ceramic filter 6 via a second pressure line 32. The sensor 23 determines from the first pressure and the second pressure a pressure difference, which is fed to the controller 22 as an input signal. When the pressure difference transmitted by the sensor 23 is compared with a stored reference value, the control 22 sends a switching command to the switching device 21 in order to switch the cleaning device 20 on or off. A first display means 27 is connected to the control 22 and displays the pressure difference determined by the sensor 23, or information about the amount of the particles 10 deposited on the ceramic filter 6. A second display means 28 is connected to the controller 22 and displays information about whether the cleaning device 20 is in operation or out of operation. Via a manually operated button 33, a user can operate the switching device 21 and start the cleaning device 20 independently of a switching command from the control 22 or end the cleaning operation.

Claims

claims

1.A device for separating particles (10) from air, in particular for filtering dust in a vacuum cleaner, with a housing (1) which has a motor / blower unit (11) for sucking in particle-laden air via an inlet opening (8 ), for conveying the air through a ceramic filter (6), on the upstream surface (18) of which the particles (10) attach, and for blowing out cleaned air from an outlet opening (19), with a cleaning device (20) for removal of particles (10) attached to the ceramic filter (6), characterized in that the device has a

Control (22) for the operation of the cleaning device (20).

2. Device according to claim 1, characterized in that the controller (20) has a sensor (23) for generating an output signal as a function of the particles (10) attached to the ceramic filter (6).

3. Device according to claim 2, characterized in that the sensor (23) is designed to measure a pressure loss on the ceramic filter (6).

4. The device according to claim 2, characterized in that the sensor (23) is designed to generate the output signal on the basis of the measured value and a reference value.

5. Device according to one of claims 2 to 4, characterized in that the controller (22) has a switching device (21) for starting or stopping the cleaning operation of the cleaning device (20) on the basis of a differential pressure between the upstream surface (18) and of the downstream surface (17) of the ceramic filter (6) dependent output signal of the sensor (23).

6. The device according to claim 4 or 5, characterized in that the switching device (21) for starting or stopping the cleaning operation of the cleaning device (20) is automatically switchable.

7. The device according to claim 4 or 5, characterized in that the switching device (21) for starting or stopping the cleaning operation of the cleaning device (20) by means of a manually operated actuating element (26) is switchable.

8. Device according to one of claims 2 to 7, characterized in that the controller has a first display means (27), which is based on the

Output signal of the sensor (23) displays information about the degree of contamination of the ceramic filter (6).

9. Device according to one of claims 2 to 8, characterized in that the controller (22) has a second display means (28) which displays information about whether the cleaning device (20) is started or the

Cleaning operation is ended.

10. Device according to one of claims 1 to 9, characterized in that the cleaning device (20) is designed for thermal cleaning of the ceramic filter (6).

11. Device according to one of claims 1 to 9, characterized in that the cleaning device (20) is designed for mechanical or acoustic cleaning of the ceramic filter (6).

12. The device according to claim 11, characterized in that the mechanical cleaning device (20) has a compressed air generator for blowing off the particles (10) from the upstream surface (18) of the ceramic filter (6).

13. The apparatus according to claim 11, characterized in that the mechanical cleaning device (20) has a vibration generator, in particular a piezo element for exciting the ceramic filter (6).

14. Device according to one of claims 1 to 13, characterized in that the device has a conveying means (30) for transporting preferably particles (10) detached from the surface of the ceramic filter (6) into a dust collector (29).