According to an embodiment, an electric range includes a core frame. The core frame includes a withdrawal portion on a top surface thereof, formed by removing a portion of a guide rail. The withdrawal portion is configured to guide withdrawal of a working coil to outside of the core frame. A portion of the working coil is disposed on the withdrawal portion. Thus, the number of windings of the working coil around the guide rail of the core frame, a total winding length of the working coil, and a winding range of the working coil is easily adjusted.

A hob comprises a hob plate, heating devices therebelow and a flat, two-dimensional carrier plate for the heating devices which runs parallel to the hob plate and has an upper face, said carrier plate bearing the heating devices on said upper face and fixedly holding said heating devices in position. Holding means are provided on the upper face of the carrier plate for each heating device. Each heating device has at least one laterally protruding holding tab, wherein each holding tab has latching means and the holding means have counter latching means for a latching connection with these latching means. The latching connection has clearance in the direction perpendicular to the surface of the carrier plate. The holding means are fastened to the upper face of the carrier plate with a releasable fastening in the direction perpendicular to the surface of the carrier plate and with a positive connection in the direction parallel to the surface of the carrier plate, wherein the holding tab runs above the carrier plate.

An electric range includes a heating part configured to heat an object based on an electromagnetic interaction. The heating part may include a core frame having a plurality of channels disposed radially on a lower surface thereof and a plurality of ferrite cores mounted onto the channels and disposed under the core frame. The core frame include a plurality of air gaps disposed between the plurality of channels. The plurality of air gaps are disposed radially, and the plurality of air gaps connect a center of the core frame and an edge of the core frame.

An induction heating type cooktop includes a case, a cover plate that is connected to an upper end of the case and that has an upper surface configured to support an object to be heated, a working coil disposed inside the case, a thin layer disposed at the cover plate and configured to be heated by the working coil through induction, and a working coil cooling fan configured to blow air toward the working coil.

The present disclosure provides an induction cooking device for heating a cooking vessel. The induction cooking device comprises a cooking surface comprising a cooking hob, an induction coil, a driving circuit electrically coupled to the induction coil, and a coil mount that is arranged under cooking hob. The induction coil is arranged on the coil mount and the coil mount is configured to dynamically adapt the distance between the induction coil and the cooking surface based on a temperature of the induction coil and/or at least a component of the driving circuit. The coil mount is configured to increase the distance between the induction coil and the cooking surface with increasing temperature of the induction coil and/or the at least one component of the driving circuit. Further, the present invention provides a respective method.

An induction cooking apparatus including a coil beam assembly, an inverter assembly, and a heatsink. The coil beam assembly includes one or more induction coils. The inverter assembly includes a first circuit board that is electrically connected to the induction coil(s) such that the inverter assembly is configured to supply electricity to the induction coil(s). The heatsink has a beam-like structure and is attached to both the coil beam assembly and the inverter assembly. The heatsink is positioned above the inverter assembly and below the coil beam assembly such that the heatsink is the sole support structure for the inverter assembly. A method for assembling the induction cooking apparatus is also described.

An induction heating cooking device includes a cooking table having an auxiliary slit; an induction coil for generating a magnetic field so as to inductively heat a cooking container placed on the cooking table; multiple light sources disposed at the outside of the induction coil; and a main slit through which light emitted from the light sources passes. The induction heating cooking device forms a virtual flame image on the cooking container, thereby enabling the heating state of the induction heating cooking device to be intuitively checked.

An induction cooking apparatus includes a plurality of induction coils arranged in an array. The induction coils include conductive windings and at least one foil. The at least one foil includes magnetically permeable material extending beneath the plurality of induction coils.

An induction heating cooking device includes a cooking table having an auxiliary slit through which light passes; an induction coil for generating a magnetic field so as to inductively heat a cooking container placed on the cooking table; at least one light source disposed at the outer edge of the induction coil; an optical member for changing the traveling direction of light emitted the light source and concentrating the light, and a main slit through which light emitted from the optical member passes so as to form a flame image on the cooking container. The induction heating cooking device forms a virtual flame image on the lower surface of a cooking container at the time of operation of the induction coil, thereby enabling the heating state of the cooking container to be easily recognized.

A first component, such as a hub of a gas turbine engine is assembled or disassembled from a second component, such as a shaft by induction heating, using a flexible heating jacket that is wrapped about an outer circumferential surface of the hub. The jacket includes an electrically conductive, flexible cable, having a plurality of loops. The jacket is selectively opened and closed with a plurality of electrical connectors coupled to each respective loop of the cable. A power source passes current through the respective cable loops, which heats the hub. The induction heating is applied to the mating components in the engine, in order to create a sufficient temperature differential that permits assembly or disassembly of the hub and shaft. A controller regulates power applied to the hub and shaft and monitors their temperature with temperature sensors.