An induction heating and wireless power transmitting apparatus includes a first group of working coils including a first working coil and a second working coil connected to each other in parallel, a first inverter that supplies resonant currents to at least one of the first working coil or the second working coil by performing a switching operation, a first semiconductor switch connected to the first working coil configured to turn on and turn off the first working coil, a second semiconductor switch connected to the second working coil and configured to turn on and turn off the second working coil, an auxiliary power supply configured to supply power to the first semiconductor switch and the second semiconductor switch, and a controller that controls the first inverter, the first semiconductor switch, and the second semiconductor switches.

The induction heating apparatus includes a current conversion circuit, a first working coil whose one end is connected to the current conversion circuit, a second working coil whose one end is connected to the current conversion circuit or the other end of the first working coil, a working coil base that accommodates the first working coil and the second working coil, a resonance capacitor that connects to the other end of the second working coil, a first relay that adjusts a connection between the other end of the first working coil and the resonance capacitor, a second relay that selectively connects one end of the second working coil to any one of the other end of the first working coil and the current conversion circuit, and a controller that controls the first relay's and the second relay's connections.

An induction heating apparatus may determine a required power value of a heating zone, based on a power level set for the heating zone, detect a container by using an inner working coil and an outer working coil, determine a working coil to be driven, based on results of the detection of the container, determine a driving mode of the working coil to be driven, based on the required power value, and provide a control signal, based on the driving mode.

Systems and methods are provided for an induction cooking hob. The induction cooking hob includes at least three induction coils each comprising a first shape. The induction cooking hob includes a fourth induction coil arranged lateral to the three induction coils. The fourth induction coil includes a second shape. The induction cooking hob includes one or more generators. The induction cooking hob includes a control unit that is configured to control the one or more generators to supply power to the at least three induction coils and the fourth induction coil.

A method is provided for controlling average power delivered to coils of a flexible induction cooktop having a plurality of coils that are arranged adjacent to one another in a non-overlapping manner to form an array. The method includes: a) identifying a group of the plurality of coils that are underlying one or more cookware items; b) providing power to at least one coil of the group of coils underlying one or more cookware items; and c) at the same time, not providing power to coils of the group of coils underlying the cookware items that are adjacent to the at least one coil to which power is provided to prevent interaction between adjacent coils of the group of coils.

Provided is an under-induction range system including a top plate unit, an induction unit fixedly disposed at a lower side of the top plate unit and configured to heat a heating target container positioned in a space above the top plate unit using a magnetic field generated by a circular coil, a Hall sensor unit disposed in a central portion of the circular coil disposed in an inner space of the induction unit, a control unit electrically connected to the Hall sensor unit, and a multi-support unit which controls operation of the induction unit according to a measurement value detected by the Hall sensor unit when a magnetic member buried therein is positioned at a matching area of a top surface of the top plate unit and on which the heating target container is seated.

A method for operating a drink maker within a vehicle. The method includes placing a cup on a seating associated with a heating mechanism, the cup containing a liquid and an essence, wherein the liquid and the essence are separated by a ring-shaped partition, automatically sensing a presence of the cup on the seating, turning on a heating mechanism for warming the liquid, sensing a temperature relating to the temperature of the liquid, and turning off the heating mechanism upon sensing a first predetermined temperature, mixing the liquid and the essence and inserting a stirrer through the ring upon warming to a second predetermined temperature lower than the first predetermined temperature, stirring the liquid with the stirrer, and removing the cup from said seating.

A controller may measure resonance current of a working coil, measure driving voltage of a switching element included in an inverter circuit that supplies current to the working coil, and generates a phase margin pulse based on the resonance current and the driving voltage. The controller may compare the phase margin pulse with a switching signal and determine a driving state of the induction heating apparatus, and control driving of the working coil based on the driving state of the induction heating apparatus. Additionally, when it is determined that a driving frequency of the working coil is included in a capacitive area, the induction heating apparatus stops from operating, or a driving frequency of the working coil is set again.

A heating cooker system according to the present invention includes: an induction cooker including a first coil configured to produce a first high-frequency magnetic field for induction heating, a first inverter circuit configured to supply a first high-frequency current to the first coil, a second coil configured to produce a second high-frequency magnetic field, and a second inverter circuit provided independently of the first inverter circuit and configured to supply a second high-frequency current to the second coil; and a cooking device including a power receiving coil configured to wirelessly receive supply of electric power from the second high-frequency magnetic field when the power receiving coil is positioned in the second high-frequency magnetic field, and a cooking unit configured to be driven by the electric power received by the power receiving coil.

A cooking hob includes at least one heating power transferring element with multiple concentrically arranged windings, one or more heating power energy units for powering the windings, a control unit that controls the heating power energy units, and detection means that determines the coverage of the windings by a cookware item. The control unit balances the heat provided to the cookware item by determining a rescaled electric power for the windings based on power requests and information regarding the coverage of the windings and establishes an operating cycle by determining a duty cycle for one or more windings. The duty cycle defines the activation time of the respective winding and is chosen such that the mean electric power provided to the respective winding within the operating cycle is equal or essentially equal to the rescaled electric power associated with the winding.