DE102023106812A1 - Household appliance - Google Patents

Abstract

The invention relates to a household appliance with at least one container device in which a liquid can be stored, wherein at least one fill level measuring device is provided, by means of which a fill level in the at least one container device can be detected, wherein at least one first electrode element is provided, which can be used in a capacitive measurement of a fill level of the liquid in the container device, wherein at least one second electrode element is provided, which is suitable and intended to shield external electrical interference from the first electrode element.

Description

The invention relates to a household appliance with at least one container device in which a liquid can be stored.

The storage of liquids is necessary in a large number of household appliances. Such household appliances can be, for example, water-conducting household appliances such as dishwashers or washing machines. Such household appliances often have a dosing device by means of which treatment agents and/or detergents can be added to a suds container in which the items to be washed are located. Such treatment agents and/or detergents are often in liquid form. It is advantageous for a user or for a control system of the household appliance to know the fill level in the container device in order to be able to carry out any refills or to indicate the need for this.

The object of the present invention is to provide a household appliance which solves the problems mentioned.

This object is solved by the subject matter of the present claim 1.

According to the invention, a household appliance is provided with at least one container device in which a liquid can be stored. At least one fill level measuring device is provided, by means of which a fill level in the at least one container device can be detected, wherein at least one first electrode element is provided, which can be used for a capacitive measurement of a fill level of the liquid in the container device, wherein at least one second electrode element is provided, which is suitable and intended to shield external electrical interference and constant potentials from the at least one first electrode element.

A capacitive measuring method is advantageously used to determine the level of the liquid in the container device. Such measurements can be adversely affected by the influence of external electrical interference, electrical fields, constant potentials and ground on the first electrode element used. By providing a shield against such electrical interference, constant potentials and ground by the at least one second electrode element, a much more interference-free measurement can be carried out.

Preferably, the container device extends along a height axis Z, a longitudinal axis X and a width axis Y.

According to a preferred embodiment, the at least one first electrode element is arranged on or near an outer wall of the at least one container device. The at least one first electrode element can be arranged on the outer wall directly or indirectly via a further component. The at least one first electrode element can be connected to the outer wall. A possible connection can be a material-locking, a form-locking and/or a force-locking connection. The at least one first electrode element can be located on a further component which is arranged on or near the outer wall of the container device.

Advantageously, the at least one second electrode element is spaced apart from the at least one first electrode element along a width axis Y. Preferably, the at least one first electrode element has a first electrode surface and the second electrode element has a second electrode surface. Preferably, the second electrode surface is at least partially substantially parallel to the first electrode surface.

According to a further preferred embodiment, the outer wall of the container device consists of an electrically weakly or non-conductive material. Accordingly, the outer wall of the container device can advantageously be regarded as a dielectric. Preferably, the liquid in the container device is an electrically conductive liquid. Preferably, the at least one first sensor electrode and the liquid thus function as electrodes of a fictitious capacitor or a first capacitance and the outer wall of the container device functions as a dielectric of the fictitious capacitor or the first capacitance. The at least one first electrode element and the at least one electrode element advantageously consist of a conductive material, preferably of a metal.

According to a further preferred embodiment, an electrical potential of the same magnitude is applied to the at least one second electrode element and the at least one first electrode element. In this case, an electrical potential of the same magnitude can advantageously be applied to the at least one second electrode element and the at least one first electrode element for a predetermined time. Preferably, an electrical potential of the same magnitude is applied to the at least one second electrode element and the at least one first electrode element for a predetermined time. a first electrode element and at the at least one second electrode element during the capacitive measurement a corresponding electrical potential. Preferably, the electrical potentials at the at least one first electrode element and at the at least one second electrode element have the same sign, different sign or are connected to ground. Preferably, a positive electrical potential is present at the at least one first electrode element and at the at least one second electrode element. According to a further advantageous embodiment, ground is present at the second electrode element. Preferably, an electrical potential of the same magnitude is continuously present at the at least one second electrode element and the at least one first electrode element. Preferably, the at least one second electrode element and the at least one first electrode element are operated in a temporally pulsed manner. In an advantageous pulsed operation, the corresponding electrical potential is applied at predetermined time intervals. In an advantageous pulsed operation, according to one embodiment, the at least one second electrode element and the at least one first electrode element can be pulsed almost faithfully in phase and amplitude. According to an alternative embodiment, only the at least one first electrode element is operated in a pulsed manner, wherein during the intervals in which the corresponding electrical potential is applied to the at least one first electrode element, an electrical potential of the same magnitude is applied to the at least one second electrode element.

Preferably, the distance between the at least one first electrode element and the at least one second electrode element and the extent of the at least one second electrode element are selected such that the electrical interference that occurs only interact with the at least one second electrode element.

According to a further preferred embodiment, at least one third electrode element is provided, which is arranged on or near the outer wall. The at least one third electrode element is preferably located along a height axis (Z) in a lower section of the outer wall. The at least one third electrode element is preferably connected to ground. The at least one third electrode element can advantageously be arranged directly or indirectly on the outer wall by means of a further component. The at least one third electrode element can be connected to the outer wall. A possible connection can be a material-locking, a form-locking and/or a force-locking connection. Alternatively, the at least one third electrode element can be located on a further component which is arranged on or near the outer wall of the container device.

Preferably, the at least one first electrode element is arranged along the height axis Z above the at least one third electrode element. The third electrode element is advantageously the lowest electrode element as seen along the height axis Z. Connecting the at least one third electrode element to ground contributes to the stability of the measuring method.

According to a further preferred embodiment, a plurality of first electrode elements are provided which are arranged at a distance from one another along the height axis Z on or near the outer wall of the container device. Different fill levels along the height axis Z can advantageously be detected by corresponding first electrode elements. An extension of the at least one second electrode element along the height axis Z preferably corresponds at least to the extension of the first electrode elements. Preferably, the at least one second electrode element essentially covers the plurality of first electrode elements along the height axis Z and the longitudinal axis X.

According to a further advantageous embodiment, the first electrode elements are arranged parallel to a horizontal axis. Preferably, the first electrode elements are also spaced apart from one another along the height axis Z.

According to a further advantageous embodiment, a fill level of the liquid in the container device is arranged essentially within a fill level plane. The fill level plane is preferably spanned by the longitudinal axis X and the width axis Y. The expression essentially is to be interpreted in such a way that the arrangement can also have certain tolerances and deviations. The first electrode elements are preferably arranged on the outer wall in such a way that above a limit height along the height axis Z at least two first electrode elements pass through the fill level plane at least once.

According to a further advantageous embodiment, the first electrode elements can enclose an angle α with the horizontal axis, wherein the angle α lies in a range between 5° and 60°, preferably in a range between 10° and 45°. Preferably the horizontally extending axis is substantially parallel to a fill level of the liquid in the container device. Preferably, the horizontally extending axis lies in the fill level plane. Accordingly, above the limit height, at least two first electrode elements pass through the fill level plane. Advantageously, there is at least one fill level through the height of which a first first electrode element and a second first electrode element pass.

According to a further advantageous embodiment, the first electrode elements are V-shaped or wave-shaped. A Z-shaped, U-shaped, L-shaped, H-shaped or step-shaped design of the first electrode elements would also be conceivable. These first electrode elements are arranged one above the other along the height axis Z. The first electrode elements are thus preferably arranged nested within one another. The first electrode elements are thus arranged directly or indirectly on or near the outer wall in such a way that above a limit height along the height axis Z at least two first electrode elements pass through the fill level at least once.

According to a further preferred embodiment, only one container device is provided on which at least one first electrode element is arranged. Preferably, several first electrode elements are arranged on the only one container device. Furthermore, at least one, preferably only one second electrode element is provided.

According to a further preferred embodiment, two container devices are provided. Each of the container devices can be designed according to the embodiments described above. At least one first electrode element is advantageously provided on each of the container devices. The at least one first electrode element is advantageously arranged on the outer walls of the container devices. Furthermore, at least one second electrode element is advantageously assigned to each of the container devices.

According to a further preferred embodiment, two container devices are provided. Each of the container devices can be designed according to the embodiments described above. At least one first electrode element is provided on each of the container devices. The at least one first electrode element is arranged on the outer walls of the container devices. The two container devices are preferably arranged next to one another along the width axis Y. Furthermore, only one second electrode element is provided. Preferably, only one second electrode element is arranged between the two container devices. Thus, only one second electrode element ensures shielding of the at least one first electrode element of both container devices. Such a simple structure saves components and the level measuring device can be manufactured more cheaply. Furthermore, interaction between the first electrode elements of the container devices is reduced.

According to a further preferred embodiment, two container devices are provided. Preferably, at least one first electrode element is provided on each of the container devices. Preferably, the at least one first electrode element is arranged on the outer landings of the container devices. Preferably, the container devices are arranged next to one another along the width axis Y in such a way that the respective first electrode elements are opposite one another. Advantageously, a first electrode element of a first container device is operated in such a way that it is suitable and intended to shield external electrical interference from the first electrode element of the second container device. Of course, the reverse case is also possible. Thus, at a first point in time, a first electrode element of a first container device would function as a second electrode element for a first electrode element of a second container device. Furthermore, at a second point in time, a first electrode element of the second container device would function as a second electrode element for a first electrode element of the first container device. Such a simple structure saves components and the level measuring device can be manufactured more cheaply.

Preferably, various capacitive measuring methods are used to determine the fill level.

According to a further preferred embodiment, a first subset of first electrode elements is used in a level measurement and a second subset of first electrode elements is not used. The second subset of first electrode elements is preferably operated in such a way that it acts as a shield from external electrical interference and constant potentials for the first subset of first electrode elements. Advantageously, the second subset of first electrode elements is connected to ground or to the same electrical potential (V ₀ ) as the second The shielding is advantageously achieved by the aforementioned connection to ground or to the same electrical potential (V ₀ ) of the second electrode element.

According to a further advantageous embodiment, the fill level measuring device and the container device are part of an automatic dosing device of the household appliance. The dosing device advantageously comprises a control device which is connected to the fill level measuring device by means of signals. The fill level measuring device advantageously transmits the fill level in the container device to the control device continuously or at predetermined intervals. A lower limit value of the fill level is preferably specified. When the lower limit value of the fill level is reached, the control device advantageously sends a signal to an indicator device by means of which the need for refilling is indicated. The indicator device can be an optical or an acoustic indicator device.

According to a further advantageous embodiment, the dosing device comprises a pumping device by means of which the liquid can be conveyed out of the container device. The pumping device can preferably be deactivated by the control device when the lower limit of the fill level is reached.

The object is also achieved by a method for determining a fill level in a container device. The method can be equipped with all of the features already described above in the context of the household appliance, individually or in combination with one another, and vice versa.

Further advantages, objects and characteristics of the present invention will become apparent from the following description of the accompanying figures. Similar components may have the same reference numerals in the various embodiments.

• 1 ein Haushaltsgerät mit zumindest einer Behältereinrichtung nach einer Ausführungsform;
• 2 eine Behältereinrichtung nach einer Ausführungsform;
• 3 eine Behältereinrichtung nach einer Ausführungsform;
• 4 eine Behältereinrichtung nach einer Ausführungsform;
• 5 eine Behältereinrichtung nach einer Ausführungsform;
• 6 eine Behältereinrichtung nach einer Ausführungsform;
• 7 Anordnung zweier Behältereinrichtungen nach einer Ausführungsform;
• 8 Anordnung zweier Behältereinrichtungen nach einer Ausführungsform;
• 9 Anordnung zweier Behältereinrichtungen nach einer Ausführungsform;
• 10 Prinzipschaltskizze der Füllstandsmessvorrichtung nach einer Ausführungsform;
• 11 eine Behältereinrichtung nach einer Ausführungsform;
• 12 eine Behältereinrichtung nach einer Ausführungsform;
• 13 Füllstandsmessung nach einer Ausführungsform.

In the figures show:

• 1 a household appliance with at least one container device according to one embodiment;
• 2 a container device according to one embodiment;
• 3 a container device according to one embodiment;
• 4 a container device according to one embodiment;
• 5 a container device according to one embodiment;
• 6 a container device according to one embodiment;
• 7 Arrangement of two container devices according to one embodiment;
• 8 Arrangement of two container devices according to one embodiment;
• 9 Arrangement of two container devices according to one embodiment;
• 10 Schematic diagram of the level measuring device according to one embodiment;
• 11 a container device according to one embodiment;
• 12 a container device according to one embodiment;
• 13 Level measurement according to one embodiment.

In 1 a household appliance 1 is shown with at least one container device 2, 10, 11 in which a liquid 3 can be stored. At least one fill level measuring device 4 is provided, by means of which a fill level 5 in the at least one container device 2, 10, 11 can be detected, wherein at least one first electrode element 6 is provided, which can be used for a capacitive measurement of a fill level 5 of the liquid 3 in the container device 2, 10, 11, wherein at least one second electrode element 7 is provided, which is suitable and intended to shield external electrical interference and constant potentials from the at least one first electrode element 6.

The container device 2 extends along a height axis Z, a longitudinal axis X and a width axis Y. Otherwise, the container device 2 can be designed in any way. The fill level 5 of the liquid 3 extends along the height axis Z. The fill level 5 of the liquid 3 also changes along the height axis Z. The container device 2 comprises an outer wall 2a which at least partially, preferably completely, encloses a corresponding inner volume of the container device 2 (except for corresponding supply and discharge lines). The inner volume is filled with liquid 3 and/or air.

According to one embodiment, the fill level measuring device 4 and the container device 2 are part of an automatic dosing device 15 of the household appliance 1. The dosing device 15 can comprise a control device 16, which is connected to the fill level measuring device 4 by means of signals. When a predetermined lower limit value of the fill level 5 is reached, the control device 16 sends a signal to an indication device 17, by means of which cher the need for refilling is indicated. The indication device 17 can be an optical or an acoustic indication device 17. The dosing device 15 comprises a pump device 18, by means of which the liquid 3 can be conveyed from the container device 2. The pump device 18 can be deactivated by the control device 16 when the lower limit of the fill level is reached.

The liquid 3 in the container device 2 is an electrically conductive liquid 3, for example a water-based liquid 3. When liquid 3 is removed from the container device 2, the volume released in the container device 1 is filled with air. This is usually the ambient air. Thus, depending on the fill level of the liquid 3 in the container device 2, the first capacitance 8 is advantageously formed by the at least one first electrode element 6 with the liquid 3 and/or the air in the container device 2. The resulting capacitance of the at least one first electrode element with air is also called parasitic capacitance. The at least one first electrode element 6 and the liquid 3 or air act as electrodes of a fictitious capacitor or the first capacitance 8. The outer wall 2a of the container device 2 consists of an electrically weakly or non-conductive material, for example a plastic. This thus acts as a dielectric of the fictitious capacitor or the first capacitance 8.

In the 2 to 9 different embodiments of the at least one container device 2, 10, 11, or the container devices 2, 10, 11 are shown. The at least one first electrode element 6 is arranged on an outer wall 2a 10a, 11a of the at least one container device 2, 10, 11. In 2 A minimal configuration is shown which only comprises a first electrode element 6 and a second electrode element 7. The at least one second electrode element 7 is spaced from the at least one first electrode element 6 along the width axis Y. The at least one first electrode element 6 has a first electrode surface 6a which extends in a plane which is spanned by the height axis Z and the width axis Y. The second electrode element 7 comprises a second electrode surface 7a which extends at least in sections essentially parallel to the first electrode surface 6a.

The fill level 5 can be determined using various capacitive measuring methods. By providing shielding by the at least one second electrode element 7, the capacitive fill level measurement can be operated without interference. The first electrode element 6 is sensitive to electric fields normal to the capacitor plane or normal to the first electrode surface 6a. By providing the at least one second electrode element 7, influences of the electric fields on the side facing away from the container device 2, 10, 11 are reduced. The side of the first electrode element 6 facing the container device 2, 10, 11 remains unaffected by the second electrode element 7 and thus remains sensitive to the capacitive fill level measurement.

An electrical potential V ₀ of the same magnitude is applied to the at least one second electrode element 7 and the at least one first electrode element 6. This is the case, for example, in 4 shown. A positive potential +V ₀ is applied to both the at least one first electrode element 6 and the at least one second electrode element 7. The electric field between the at least one first electrode element 6 and at least one second electrode element 7 is therefore zero. It would also be conceivable that a negative potential -V ₀ is applied to the at least one second electrode element 7 or that the at least one second electrode element 7 is connected to ground.

According to the embodiment according to the 3 , 5 and 6 a plurality of first electrode elements 6 are provided. These are arranged at a distance from one another along the height axis Z on the outer wall 2a, 10a, 11a of the container device 2, 10, 11. An extension of the at least one second electrode element 7 along the height axis Z corresponds at least to the extension of all first electrode elements 6 along the height axis Z. Furthermore, an extension of the at least one second electrode element 7 along the longitudinal axis X also corresponds at least to the extension of the first electrode elements 6 along the longitudinal axis X. In the 3 it is evident that the extension of the second electrode element 7 even extends beyond the first electrode elements 6. The second electrode surface 7a is, at least in sections, essentially parallel to the first electrode surfaces 6a of the first electrode elements 6.

Furthermore, at least one third electrode element 9 can be provided, which is arranged along a height axis Z in a lower section 2b, 10b, 11b of the outer wall 2a, 10a, 11a. The at least one third electrode element 9 is connected to ground. The at least one first electrode element 6 is arranged along the height axis Z above the at least one third electrode element 9. The at least one third electrode Element 9 is the lowest electrode element along the height axis Z.

According to one embodiment, the at least one first electrode element 6 and the at least one third electrode element 9 are each arranged in an electrode plane 19, 20. The electrode planes 19, 20 form an angle β, wherein the angle β is greater than or equal to 90° and less than or equal to 180° (90°≤ β ≤ 180°). Each of the first electrode elements 6 is arranged in a corresponding electrode plane 19, 20. In the 5 , 6 and 11 the electrode planes 19, 20 are parallel, ie β =180°. In 12 an embodiment with a curved outer wall 2a is shown. The at least one third electrode element 9 is arranged in a first electrode plane 19 and the at least one first electrode element 6 is arranged in a second electrode plane 20. The first electrode plane 19 and the second electrode plane 20 enclose an angle β of less than 180° and greater than 90°.

According to an embodiment according to 5 the first electrode elements 6 are arranged parallel to a horizontal axis A. Furthermore, the first electrode elements 6 are spaced apart from one another along the height axis Z.

A fill level of the liquid 3 in the container device 2 is essentially arranged within a fill level plane FE. The fill level plane FE is preferably spanned by the longitudinal axis X and the width axis Y. The expression essentially is to be interpreted in such a way that the arrangement can also have certain tolerances and deviations. Deviations can arise, for example, from an installation of the container device 2 deviating from the horizontal or from a non-horizontal position of the household appliance. The first electrode elements 6 are arranged on the outer wall 2a in such a way that above a limit height along the height axis Z at least two first electrode elements 6 pass through the fill level plane FE at least once.

According to a further embodiment according to 6 the first electrode elements 6 form an angle α with the horizontally extending axis A. The arrangement of the first electrode elements 6 is thus oblique with respect to the horizontally extending axis A. The angle α is preferably in a range between 5° and 60°, more preferably in a range between 10° and 45°. The horizontally extending axis A is essentially parallel to a filling level 5 of the liquid 3 in the container device 2, 10, 11. In 6 a filling level 5 is shown, the height of which crosses both a first electrode element 6 and a second electrode element 6. Preferably, the horizontally extending axis A lies in the filling level plane FE. Accordingly, above the limit height, at least two first electrode elements 6 pass through the filling level plane FE. Accordingly, a first capacitance 8 and/or a change in the first capacitance 8 can be measured both by means of the first electrode element 6 and by means of the second electrode element 6.

In 11 a further embodiment is shown. The first electrode elements 6 are formed in a V-shape. These first electrode elements 6 are arranged one above the other along the height axis Z. The first electrode elements 6 are thus arranged nested within one another. The first electrode elements 6 are thus arranged on the outer wall 2a in such a way that above a limit height along the height axis Z at least two electrode elements 6 pass through the fill level plane FE at least once, in this case twice.

In 7 an embodiment is shown in which two container devices 2, 10, 11 are provided. At least one first electrode element 6 is provided on both a first container device 2, 10 and a second container device 2, 11. Of course, several first electrode elements 6 can also be provided on a container device 2, 10, 11 or on both container devices 2, 10, 11. The at least one first electrode element 6 is arranged on the outer walls 2a, 10a, 11a of the container devices 2, 10, 11. Furthermore, each of the container devices 2, 10, 11 is assigned at least one, preferably only one second electrode element 7. The two container devices 2, 10, 11 are arranged next to one another along the width axis Y. The second electrode elements 7 are arranged next to one another or parallel along the width axis Y. Furthermore, the container devices 2, 10, 11 can be designed according to the embodiments described above.

Also in 8 an embodiment is shown in which two container devices 2, 10, 11 are provided. At least one first electrode element 6 is provided on both a first container device 2, 10 and a second container device 2, 11. Of course, several first electrode elements 6 can also be provided on a container device 2, 10, 11 or on both container devices 2, 10, 11. The at least one first electrode element 6 is arranged on the outer walls 2a, 10a, 11a of the container devices 2, 10, 11. In contrast to the embodiment in 7 However, only a second electrode element 7 is provided seen. The two container devices 2, 10, 11 are arranged next to one another along the width axis Y and the second electrode element 7 is arranged centrally between the two container devices 2, 10, 11. The only one second electrode element 7 ensures shielding from external electrical interference both for the at least one first electrode element 6 of the first container device 2, 10 and for the at least one first electrode element 6 of the second container device 2, 11. Such a simple structure saves components and the level measuring device 4 can be manufactured more cheaply.

Also in 9 an embodiment is shown in which two container devices 2, 10, 11 are provided. At least one first electrode element 6 is provided on both a first container device 2, 10 and a second container device 2, 11. Of course, several first electrode elements 6 can also be provided on one container device 2, 10, 11 or on both container devices 2, 10, 11. The at least one first electrode element 6 is arranged on the outer walls 2a, 10a, 11a of the container devices 2, 10, 11. The container devices 2, 10, 11 are arranged next to one another along the width axis Y in such a way that the respective first electrode elements 6 are opposite one another. Accordingly, the at least one first electrode element 6 of the first container devices 2, 10 lies along the width axis Y opposite the first electrode element 6 of the second container device 2, 11. A first electrode element 6 of a first container device 2, 10 is operated in such a way that it is suitable and intended to shield external electrical interference from the first electrode element 6 of the second container device 2, 11 and vice versa. Thus, at a first point in time, a first electrode element 6 of a first container device 2, 10 would function as a second electrode element 7 for a first electrode element 6 of a second container device 2, 11. At a second point in time, a first electrode element 6 of the second container device 2, 11 would function as a second electrode element 7 for a first electrode element 6 of the first container device 2, 10. Such a simple structure saves components and the level measuring device 4 can be manufactured more cheaply.

The capacitive measuring method can be selected as desired. A possible measuring method is shown below. The at least one level measuring device 4 comprises a microcontroller 12 with at least two connections 12a, 12b. The two connections 12a, 12b are electrically connected to at least one capacitive element 13. The at least one capacitive element 13 is charged by the microcontroller 12 depending on the first capacitance 8.

In 10 a corresponding switching arrangement is shown. The at least one first electrode element 6 is connected in series with the at least one capacitive element 13. The at least one capacitive element 13 can be a single capacitor or a circuit with several capacitors. In the present case, without limiting the generality, a single capacitor is assumed. The capacitive element 13 comprises a first connection 13a and a second connection 13b. A first connection 12a of the microcontroller 12 is electrically connected to the first connection 13a of the at least one capacitive element 13. A second connection 12b of the microcontroller 12 is connected between the at least one capacitive element 13 and the at least one first electrode element 6. The second connection 12b of the microcontroller 12 is electrically connected to the second connection 13b of the at least one capacitive element 13 and the at least one first electrode element 6. The connections 6a, 6b of the microcontroller 6 are GPIO (General Purpose Input/Output) connections. A GPIO connection is a general digital connection of the microcontroller 12, which can be designated as an input or output connection by logical programming.

The at least one capacitive element 13 has a predetermined second capacitance 14. The second capacitance 14 is preferably larger than the first capacitance 8 by a factor of 100 to 10,000.

A predetermined voltage value is assigned to a predetermined charge of the second capacitance 14. The charging of this predetermined second capacitance 14 by the microcontroller 12 requires a certain number of charging cycles, the number of which depends on the first capacitance 8. It would also be conceivable that the first capacitance can be determined from the number of charging cycles. However, this would require a value of the parasitic capacitance to be determined.

A measuring cycle comprises several charging cycles. In a charging cycle, the microcontroller 12 introduces electrical charge into the first capacitor 8 and the second capacitor 14. The amount of charge introduced in a charging cycle is limited by the first capacitor 9. In each charging cycle, a voltage is measured at the second capacitor 14 by the microcontroller 12. If the measured voltage essentially matches the predetermined voltage value, the measuring cycle is terminated. A change can then be made from the number of charging cycles. the first capacitance 8 can be determined. From this change in the first capacitance 8, the fill level of the liquid 3 in the container device 2 can in turn be determined. In this case, it is thus measured whether a liquid 3 or air is present at a height Z within the container device 2. The height Z can preferably be determined via the respective arrangement of the first electrode element 6. It would also be conceivable that the first capacitance 8 is determined from the number of charge cycles and the predetermined second capacitance 14. The fill level of the liquid 3 in the container device 2 can then be determined from the first capacitance 8 or the change in the second capacitance 14.

The advantageous basic principle of such a level measurement is a cyclic change of the resistances and potentials by the microcontroller in order to achieve a sequential charging of the second capacitance.

According to a further advantageous embodiment, the fill level measuring device 4 comprises a measuring device which is designed as an electrical oscillator. The first capacitance 8 is advantageously provided as a frequency-determining capacitance of the electrical oscillator. A fill level 5 or a change in the fill level 5 of the liquid 3 in the at least one container device 2 can preferably be determined from a change in the oscillation frequency of the oscillator.

According to one embodiment, a first subset of first electrode elements 6 is used in a fill level measurement and a second subset of first electrode elements 6 is not used. The second subset of first electrode elements 6 is operated in such a way that it acts as a shield from external electrical interference and constant potentials for the first subset of first electrode elements 6. The second subset of first electrode elements 6 is connected to ground or to the same electrical potential V ₀ of the second electrode element 7.

In 13 an embodiment is shown in which a higher-level measuring cycle exists. This comprises a predetermined number of level measurements. The number of level measurements corresponds to the number of first electrode elements 6. The third electrode element 9 is advantageously always connected to ground. For a level measurement, a first subset of first electrode elements 6, in this case a first electrode element 6, is used. This is in 13 a) visible. The other first electrode elements 6 arranged above along the height axis Z belong to the second subset, which act as a shield against external electrical interference and constant potentials for the first subset of first electrode elements 6. In the present case, the first electrode elements 6 of the second subset are connected to ground. In a further level measurement, another first electrode element 6 is used, which lies along the height axis Z above the previously used first electrode element 6. The remaining unused first electrode elements 6 now belong to the second subset, which act as a shield against external electrical interference and constant potentials for the first subset of first electrode elements 6. These are the first electrode elements 6 placed along the height axis Z above and below the first electrode element 6 used. This is in 13b) shown. For the further level measurements, a further first electrode element 6 is used, which lies along the height axis Z above the previously used first electrode element 6. The first electrode elements 6 not used in each case are then assigned to the second subset. This is shown in the 13c) and 13d) It would also be conceivable that several first electrode elements 6 are used for a level measurement, so that the first subset comprises several first electrode elements 6. It would also be conceivable that the first electrode elements 6 are used along the height axis Z from top to bottom within the measuring cycle. In the higher-level measuring cycle described above, the first electrode elements 6 of the second subset, which act as a shield against external electrical interference and constant potentials for the first subset of first electrode elements 6, are connected to ground. However, this is only to be understood as one possible embodiment. It would also be conceivable for the first electrode elements 6 to be connected to the same electrical potential V ₀ of the second electrode element 7.

The applicant reserves the right to claim all features disclosed in the application documents as essential to the invention, provided that they are new individually or in combination compared to the prior art. It is also pointed out that the individual figures also describe features that can be advantageous in themselves. The person skilled in the art will immediately recognize that a particular feature described in a figure can also be advantageous without adopting further features from this figure. The person skilled in the art will also recognize that advantages can also arise from a combination of several features shown in individual or different figures.

List of reference symbols

1

Household appliance

2

Container equipment

2a

Outer wall of the container device

2b

lower section of the outer wall

3

liquid

4

Level measuring device

5

Fill level

6

first electrode element

6a

first electrode area

7

second electrode element

7a

second electrode surface

8

first capacity

9

third electrode element

10

first container device

10a

Outer wall of the first container device

10b

lower section of the outer wall

11

second container device

11a

Outer wall of the second container device

11b

lower section of the outer wall

12

Microcontroller

12a

first connection

12b

second connection

13

capacitive element

13a

first connection

13b

second connection

14

second capacity

15

Dosing device

16

Control device

17

Indication device

18

Pumping device

19

Electrode level

20

Electrode level

A

axis

X

Longitudinal axis of the container device

Y

Width axis of the container device

Z

Height axis of the container device

α

angle

Claims (12)

Household appliance (1) with at least one container device (2, 10, 11) in which a liquid (3) can be stored, characterized in that at least one fill level measuring device (4) is provided, by means of which a fill level (5) in the at least one container device (2, 10, 11) can be detected, wherein at least one first electrode element (6) is provided which can be used in a capacitive measurement of a fill level (5) of the liquid (3) in the container device (2, 10, 11), wherein at least one second electrode element (7) is provided which is suitable and intended for shielding external electrical interference and constant potentials from the at least one first electrode element (6). Household appliance (1) by Claim 1 characterized in that the at least one first electrode element (6) is arranged on or near an outer wall (2a) of the at least one container device (2, 10, 11), wherein the at least one second electrode element (7) is spaced from the at least one first electrode element (6) along a width axis (Y). Household appliance (1) by Claim 1 characterized in that the outer wall (2a, 10a, 11a) of the at least one container device (2, 10, 11) consists of an electrically weakly or non-conductive material, wherein the liquid (3) in the container device (2, 10, 11) is an electrically conductive liquid, wherein the at least one first electrode element (6) and the liquid (3) in the at least one container device (2, 10, 11) form a first capacitor (8). Household appliance (1) by Claim 1 or 2 characterized in that an electrical potential (V ₀ ) of the same magnitude is applied to the at least one second electrode element (7) and the at least one first electrode element (6), or the at least one second electrode element (7) is connected to ground. Household appliance (1) according to one of the preceding claims, characterized in that at least one third electrode element (9) is provided, which is arranged on or near the outer wall (2a, 10a, 11a), wherein the at least one third electrode element (9) is located along a height axis (Z) in a lower section (2b) of the outer wall (2a, 10a, 11a), wherein the at least one third electrode element (9) is connected to ground, wherein the at least one first electrode element (6) is arranged along the height axis (Z) above the at least one third electrode element (9). Household appliance (1) according to one of the preceding claims, characterized in that a plurality of first electrode elements (6) are provided, which are arranged at a distance from one another along the height axis (Z) on or near the outer wall (2a) of the container device (2, 10, 11), wherein an extension of the at least one second electrode element (7) along the height axis (Z) corresponds at least to the extension of the first electrode elements (6). Household appliance (1) according to one of the preceding claims, characterized in that the first electrode elements (6) are arranged parallel to a horizontally extending axis (A) or enclose an angle (α) with the horizontally extending axis (A), wherein the angle (α) lies in a range between 5° and 60°, preferably in a range between 10° and 45°, wherein the horizontally extending axis (A) is substantially parallel to a fill level (5) of the liquid (3) in the container device (2). Household appliance (1) according to one of the preceding claims, characterized in that two container devices (2, 10, 11) are provided, wherein at least one first electrode element (6) is provided on each of the container devices (2, 10, 11), wherein the at least one first electrode element (6) is arranged on the outer walls (2a, 10a, 11a) of the container devices (2, 10, 11), wherein each of the container devices (2, 10, 11) is assigned at least one second electrode element (7). Household appliance (1) according to one of the preceding Claims 1 until 7 characterized in that two container devices (2, 10, 11) are provided, wherein at least one first electrode element (6) is provided on each of the container devices (2, 10, 11), wherein the at least one first electrode element (6) is arranged on the outer walls (2a, 10a, 11a) of the container devices (2, 10, 11), wherein only a second electrode element (7) is provided, which is arranged between the two container devices (2, 10, 11). Household appliance (1) according to one of the preceding Claims 1 until 7 characterized in that two container devices (2, 10, 11) are provided, wherein at least one first electrode element (6) is provided on each of the container devices (2, 10, 11), wherein the at least one first electrode element (6) is arranged on the outer landings (2a, 10a, 11a) of the container devices (2, 10, 11), wherein the container devices (2, 10, 11) are arranged next to one another along the width axis (Y) such that the respective first electrode elements (6) are opposite one another, wherein a first electrode element (6) of a first container device (2, 10) is operated in such a way that it is suitable and intended to shield external electrical interference from the first electrode element (6) of the second container device (2, 11). Household appliance (1) according to one of the preceding Claims 6 until 10 characterized in that, in a level measurement, a first subset of first electrode elements (6) is used and a second subset of first electrode elements (6) is not used, wherein the second subset of first electrode elements (6) is operated such that it acts as a shield from external electrical interference and constant potentials for the first subset of first electrode elements (6), wherein the second subset of first electrode elements (6) are connected to ground or are connected to the same electrical potential (V ₀ ) of the second electrode element (7). Household appliance (1) according to one of the preceding claims, characterized in that the level measuring device (4) and the container device (2, 10, 11) are part of an automatic dosing device (15) of the household appliance (1).

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