Hob having at least one inductor, at least one inverter and a switching apparatus

Abstract

A hob having at least one inductor, at least one inverter, a switching apparatus and a detection circuit for detection of cooking utensils. The switching apparatus is arranged in a circuit between the inductor and the inverter and switchable between a first switch position in which a connection between the inverter and the inductor is established and a second switch position in which the connection between the inverter and the inductor is interrupted. In order to allow an energy-saving detection mode, the switching apparatus is connected to the detection circuit such that the switching apparatus connects the inductor to the detection circuit when it is in the second switch position.

Claims

1. A hob, comprising: at least one inductor; at least one inverter; a switching apparatus arranged in a circuit between the inductor and the inverter and switchable between a first switch position in which a connection between the inverter and the inductor is established and a second switch position in which the connection between the inverter and the inductor is interrupted; and a detection circuit configured to detect a cooking utensil, said switching apparatus being connected to the detection circuit such that the switching apparatus connects the detection circuit to the inductor when the switching apparatus is in the second switch position and disconnects the detection circuit from the inductor when the switching apparatus is in the first switch position.

2. The hob of claim 1, wherein the switching apparatus comprises at least one electromechanical relay having at least two output terminals, the first output terminal being connected to the inverter and the second output terminal being connected to the detection circuit.

3. The hob of claim 1, further comprising a plurality of said inductors arranged in the form of a grid, said switching apparatus being configured to open and close connections between the individual inductors and the at least one inverter.

4. The hob of claim 1, wherein the detection circuit forms an oscillating circuit with the inductor, said oscillating circuit having a resonance frequency which is higher than a frequency of a heating current of the inductor.

5. The hob of claim 1, further comprising a control unit for reading out from the detection circuit.

6. The hob of claim 1, wherein the switching apparatus has a switch which is directly connected to the inductor.

7. The hob of claim 1, wherein a heating current transferred to the inductor in the first switch position is at least 1,000 times greater than a measurement current transferred to the inductor in the second switch position.

8. A cooktop comprising: an inductor; an inverter; a detector; and a switch between the inductor and the inverter and having a first switch position which connects the inverter to the inductor and disconnects the detector from the inductor and a second position which connects the detector to the inductor and disconnects the inverter from the inductor.

9. The cooktop of claim 8, wherein the detector detects a cooking utensil.

10. The cooktop of claim 8, wherein the switch comprises an electromechanical relay with a first output terminal connected to the inverter and a second output terminal connected to the detector.

11. The cooktop of claim 8, further comprising a plurality of said inductors arranged in a grid and wherein said switch opens and closes connections between the individual inductors and the inverter.

12. The cooktop of claim 8, wherein the detector forms an oscillating circuit with the inductor having a resonance frequency that is higher than a resonance frequency of an oscillating circuit comprising the inductor and the inverter.

13. The cooktop of claim 8, further comprising a controller that receives a detection signal from the detector and that controls the switch.

14. The cooktop of claim 8, wherein the switch is directly connected to the inductor.

15. The cooktop of claim 14, further comprising an inductor support that integrally combines with the inductor and the switch to form an inductor module.

16. The cooktop of claim 8, wherein a current through the inductor when the switch is in the first switch position is at least one thousand times greater than a current through the inductor when the switch is in the second switch position.

17. The cooktop of claim 8, wherein the switch comprises a double pole throw relay.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the diagrams,

(2) FIG. 1 is a schematic illustration of an induction hob with inductors arranged in a grid pattern, a switching apparatus and a plurality of inverters,

(3) FIG. 2 is a schematic illustration of an inductor with a switching apparatus which connects the inductor to an inverter when in a first switch position, and connects the inductor to a detection circuit when in a second switch position, and

(4) FIG. 3 shows an inductor module with an integrated switch of the switching apparatus.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS OF THE PRESENT INVENTION

(5) FIG. 1 shows an induction hob of the matrix type, having a plurality of inductors 10 arranged in a grid pattern. The inductors 10 form a rectangular grid and can be divided over several modules, each of which is supplied from different power supply units (not shown). The inductors 10 may be activated and deactivated selectively and individually, for which purpose a switching apparatus 14 may make or interrupt a connection between the inductors 10 and an inverter 12 assigned to the respective inductor 10.

(6) In a first switch position of the switching apparatus 14 the inverter 12 is connected to the inductor 10, so that an alternating current with a frequency of a few kilohertz up to a maximum of approx. 75 or 100 kilohertz and operated by a voltage amplitude of several hundred volts flows through the inductors 10. The inductors 10 generate a strong, high-frequency magnetic field, which partially permeates the base of a cooking utensil 18 when a cooking utensil 18 with a ferromagnetic base is placed on the induction hob. The alternating magnetic field causes eddy currents, which heat up the base, to be generated in a ferromagnetic base of the cooking utensil 18.

(7) FIG. 1 is a schematic diagram which does not reflect the actual arrangement of the inductors 10 with regard to the switching apparatus 14 and the inverter 12. The switching apparatus 14 may be mounted on a common board with the inverters 12, or form a structurally separate unit.

(8) FIG. 2 schematically shows a random inductor 10 of the induction hob from FIG. 1 with the inverter 12 assigned to this inductor 10 and a detection circuit 16. The detection circuit 16 can also be mounted with the switching apparatus 14 and/or the inverters 12 on a common board, or alternately be provided as separate modules.

(9) A switching element of the switching apparatus 14, embodied as an electromechanical relay 20, is arranged between the inductor 10 and the inverter 12. The electromechanical relay 20 comprises two output terminals 24, 26. The first output terminal 24 is connected to the inverter 12 and the second output terminal 26 to the detection circuit 16. The electromechanical relay 20 is embodied as a double pole double throw (DPDT) relay with two parallel-switched working contacts. A control unit 22 reads out from the detection circuit 16 and is connected via a control cable 28 to the coil of an electromagnet 29 in the relay 20. The control unit 22 may be a microcontroller or a freely programmable arithmetic unit, which operatesin addition to the inductors 10, the switching apparatus 14 and the detection circuit 16further electronic modules of the hob, for example a user interface with a display or the like. The result of the cooking utensil detection can then be shown on the display.

(10) In the second switch position, in which the switch contacts of the relay 20 connect the second output terminal 26 of the relay 20 to the inductor 10, the inductor 10, with the detection circuit 16, forms a Colpitts oscillator in which two capacitors and the inductor 10 determine the oscillation frequency. The feedback necessary for the oscillation is generated via a voltage divider between the two capacitors (not shown).

(11) The detection circuit 16 has a low-power alternating voltage applied to it, which generates an alternating measurement voltage of approx. 10 or 12 volts in the corresponding inductor 10 and results in measurement currents of a few milliamperes. The inductor 10 is used as a measuring probe in this operating state. The inductor 10 forms an oscillating circuit together with two capacitors. The placement of the cooking utensil 18 causes the inductivity of the overall system consisting of the inductor 10 and the cooking utensil 18 to be reduced compared to the inductivity of the free inductor 10, whereby the resonance frequency of the oscillating circuit is increased by approximately 10%. The detection circuit 16 or the control unit 22 measures the resonance frequency of this overall system and indicates the presence of the cooking utensil 18 from the increased resonance frequency.

(12) FIG. 3 shows an inductor module comprising the inductor 10 and the switching element of the switching apparatus 14 embodied as a relay 20, in a conceivable embodiment of the invention. The relay 20 is attached directly to an underside of an inductor support 30, so that it forms a manageable module with the inductor 10. Corresponding connection cables to the inverters 12 and/or the detection circuit 16 can be plugged directly into the output terminals 24, 26 of the relay when the inductor module is connected.

REFERENCE CHARACTERS

(13) 10 Inductor 12 Inverter 14 Switching apparatus 16 Detection circuit 18 Cooking utensils 20 Relay 22 Control unit 24 Output terminal 26 Output terminal 28 Control cable 29 Electromagnet 30 Inductor support