DE19825321C1 - Hob with control unit for specifying the power level and method for setting the power level of a heating element of a hob - Google Patents

Abstract

A hob is known with a hotplate with at least one cooking zone, which can be heated by a heating element arranged below the hotplate, with an operating unit for specifying a desired power level of the heating element for heating a cooking appliance placed on the hotplate. In order to simplify the operation of the hob, the cooking appliance itself serves as an operating unit, the hob being assigned a detection device which derives the desired power level from a position or change in position of the cooking appliance in the region of the cooking zone.

Description

The present invention relates to a hob according to the preamble of the claim 1 and a method for setting the power level of a hob according to the upper Concept of claim 8.

Such a hob is known from the document DE 32 09 260 A1, each Cooking area at least three proximity switches or sensors are assigned, the au are arranged offset from each other by 120 ° outside the heating surface of the hotplate. There each of the three sensors has three make contacts for closing the circuits for the heating device of the hotplate. By moving the cookware in the area the cooking zone is all the power levels of a known seven-cycle switch by appropriately activating part or all of the sensors switchable.

Another hob is known from the document DE 40 07 680 A1, a heater plate of a glass ceramic electric cooker with several cooks lying close together field elements. These can be switched on separately via sensors. A Control of the heating plate ensures that always exactly as many of the hob elements are switched, such as from a cookware placed on the hob, for example wise a pot, covered or almost covered. In addition, the Heizlei Stung the cooktop elements set differently that by a shift Cooking utensils, for example, from cooking at the highest temperature to one lower or very low set temperature is changed. The user so there is no need to operate a switch to change the cooking temperature accordingly change, because this is via the sensors and the mentioned setting of the control of the heating plate happens automatically. To change the temperature of the cookware, it must ver only on the surface of the glass ceramic plate to other hob elements be pushed. These are already controlled by a central control of the cooker wanted different temperature set. For example, the front hob elements elements of the heating plate set to full temperature, the middle to medium temperature  and the rear hob elements to a low temperature. Then you have to concern him in this example, just move the saucepan from the front over the middle to the back and then goes through the three cooking stages mentioned, namely parboiling, continued cooking and warm hold. A particular disadvantage of this hob is that the desired temperature ren continue to adjust the central control of the cooker, and that the place required on the hob for the different temperature ranges directly from the number depends on the feasible cooking levels. Another disadvantage is that with a clear Changing the cooking level to move the cooking device over a relatively large distance is.

The object of the present invention is in a cooktop according to the preamble of Claim 1 to simplify the setting of the heating power level, and an ent to provide a speaking setting procedure.

According to the invention this is achieved in that with a hob according to the preamble of claim 1, the detection device two in the edge area Cooking zone arranged and essentially opposite sensor elements points. These detect and determine the presence or absence of the cooking device depending on the time of this presence or absence of the cooking device on site the desired performance level. Prin Zip pot known elements serve, such as capacitive, in ductive or optical elements. The pot is used to adjust the power level pulled away from one of the two pan detection elements, for example, and thus on pushed the other pan detection element. This assumes that the distance of the Pot detection elements is larger than the diameter of the bottom of the pot. From the Rich the movement of the pot and the length of time the pot remains above one or the other another sensor element, a control unit of the hob determines the desired lei level of the corresponding cooking zone. Alternatively, the position detection of the Pot of these two sensor elements and the hob only a correspondie sensor element. However, specially designed pots are required for this. The The inventive method for setting the power level is thereby ge indicates that the power level from the duration of the presence of the cooking appliance in the selected position is determined. For setting the desired power level the saucepan is only to be moved in the area of a cooking zone, i.e. with limited space Despite the short displacement paths for the saucepan, there is a fine-graded power rating for example possible in nine performance levels. For one  the power level, the pot is at most slightly out of the concerned Heating zone can move and after setting the desired power level can be quickly moved back to heat transfer technology optimally above the heating element posi arranged in or below the hotplate to be dated.

In addition, it is also possible that the respective distance from the cooking device ( 21 ) is detected in order to determine the desired power level.

According to a preferred embodiment, the detection device has a touch effortlessly working sensor element that is arranged below the hotplate. According to the technology for pot detection, a reliable detection of the Desired power level possible without disruptive elements above the cook plate.

To meet the thermal requirements for the sensor elements of the detection device To be able to reduce, these are below the hotplate outside of a heat iso lation of a known heating element of the cooking zone arranged. Still is in this area ensures that when using a glass hob ceramic material due to the lower temperatures in this area than Non-conductor applies. Therefore, in this case, additional insulation is a metallic Measuring electrode of a capacitive pot detector, for example, as additional electri protective measure is not required.  

In order to rule out incorrect operation of the hob, the detection device indicates a test facility, the short-term and / or unintended positions recognizes the cooking appliance as such and the power level is not changes. The same is also achieved if the test device is operated for a long time term and / or unintended positions of the cooking device as such recognizes and leaves the power level unchanged. Typically, a correct one Actuation or setting of the heating level by the cooking device for longer than about one se customer and shorter than about ten seconds. This also provides protection against Incorrect operation when wiping for cleaning purposes via the sensor system of the detection equipment and when unintentionally putting down a cutlery, for example siert.

An exemplary embodiment of the described hob of the invention.

Show it:

Fig. 1 in a highly schematic side view of the hob according to the first embodiment, and

FIG. 2 is a greatly simplified top view of the representation according to FIG. 1.

A hob 1 according to Fig. 1 comprises a cooking plate 3 made of glass ceramic having a circular cooking zone 4. To mark the cooking zone 4 , a known zone decor is printed on the hotplate 3 . A pot-shaped heating element 5 known per se is arranged below the hotplate 3 in the area of the cooking zone 4 . This has a heating wire 9 arranged in an insulation pot 7 . The heating wire 9 can be connected to the mains voltage via a switch 10 . The hob 1 has a control unit 11 to control the heating power or to set the desired heat setting. Furthermore, the control unit 11 is connected to a main switch 12 , by means of which, as required by the relevant safety regulations, the hob 1 or all of its electrical consumers can be switched from the mains. The hob 1 has display elements 13 , which show in the form of seven segments, are in a known manner below the hotplate 3 in the hob 1 angeord net. According to Fig. 1 of the hob 1 is a power level "8" is set and displayed by the seven-segment display 13 for the cooking zone 4. Outside of the isolation pot 7 , a first sensor element 15 and a second sensor element 17 are arranged opposite one another in the form of metallic electrodes directly below the hotplate 3 . The two sensor elements 15 and 17 are fed via a sensor circuit 19 or the control circuit 11 and their capacities are evaluated. In the area of the cooking zone 4 , a pot 21 is placed on the hotplate according to FIG. 1 exactly above the heating element 5 . The setting of the desired power level of the heating element 5 takes place according to FIG. 2 as follows:

The position of the pot 21 according to FIG. 1 is shown in solid lines in FIG. 2. In this position, the heating position, the pot 21 is exactly above the heating element 5 . Both sensor elements 15 and 17 provide the information that there is no pot 21 in their area. The previously set power level "8" remains unchanged. By moving the pot 21 into the position in which the pot is shown with broken lines, the selection position, he detects the sensor element 15 that the pot 21 is not present. The sensor element 17, however, detects that the pot 21 is present. The pot 21 is therefore in the selection position. With the first detection of the pot 21 in the selection position, a time counter of the control unit 11 starts. The cooking level is increased by one cooking level every 0.5 seconds and the increase is visualized by the display element 13 . If the operator agrees with the displayed heating level, he pushes the pot 21 back into the heating position according to FIG. 1. If one of the two sensor elements 15 or 17 detects a presence of the pot 21 of less than about one second or longer than about ten seconds, the blinking of the display element 13 shows the operator an error and at the same time the heating power of the corresponding cooking zone 4 is switched off.

Alternatively, the two sensor elements 15 and 17 can also be arranged in the interior of the insulation pot 7 of the heating element 5 below the saucepan 21 . In the pot position according to FIG. 1, the heating position, both sensor elements 15 and 17 would then first detect the presence of the pot 21 and leave the power level unchanged. As soon as one of the sensor elements 15 or 17 detects the removal of the pot and the other detects its presence at the same time, the power level would be increased or decreased accordingly depending on the direction of movement of the pot 21 in accordance with the above-described process. In addition, an additional conventional control unit, not shown, can be provided for dishes whose presence or position is very difficult to prove, for example for a glass vessel.

Claims (8)

1. Hob ( 1 ) with a hotplate ( 3 ) with at least one cooking zone ( 4 ) which can be heated by a heating element ( 9 ) arranged in or below the hotplate, with an operating unit for specifying a desired power level of the heating element for heating a the cooking appliance ( 21 ) placed on the hotplate, the cooking appliance itself serving as the operating unit, and the cooking zone being assigned a detection device which derives the desired power level from a position of the cooking appliance ( 21 ) in the region of the cooking zone ( 4 ), characterized in that the detection device has two sensor elements ( 15 , 17 ) which are arranged in the edge region of the cooking zone ( 4 ) and are essentially opposite one another and which detect the presence of the cooking appliance ( 21 ) and depending on the time of presence or absence of the Determine the cooking device ( 21 ) at the location of the sensor elements the desired performance level. 2. Hob according to claim 1, characterized in that the respective distance from the cooking appliance ( 21 ) is additionally detected to determine the desired power level. 3. Hob according to claim 1 or 2, characterized in that the detection device has a non-contact sensor element ( 15 , 17 ) which is arranged below the hotplate ( 3 ). 4. Hob according to one of the preceding claims, characterized in that the sensor elements ( 15 , 17 ) of the detection device un below the hotplate ( 3 ) outside a thermal insulation ( 13 ) of the heating element ( 5 ) of the cooking zone ( 4 ) are arranged. 5. Hob according to one of the preceding claims, characterized in that the detection device has a test device ( 7 ) which recognizes short-term and / or unintentional positions of the cooking device ( 21 ) as such and leaves the power level unchanged. 6. Hob according to one of the preceding claims, characterized in that the detection device has a test device ( 7 ) which recognizes long-term and / or unintentional positions of the cooking device ( 21 ) as such and leaves the power level unchanged. 7. Hob according to one of the preceding claims, characterized in that a selection position of the cooking device ( 21 ) in which the desired power level is derived, slightly laterally offset to egg heating position of the cooking device ( 21 ) in which the cooking device ( 21 ) stands on or above the heating element ( 5 ), is provided on the hotplate ( 3 ). 8. Method for setting the power level of a heating element Hob to heat one in a cooking zone on a hotplate provided cooking device, the cooking device on the hotplate in the area the cooking zone is pushed into selected positions, and out of the on presence of the cooking device at these positions the desired lei is determined, characterized in that the performance level fe from the duration of the presence of the cooking appliance in the selected one Position is determined.