An electric composite heat oven provided with a sight window of a transparent planar heating element is provided. Since the electric composite heat oven has a structure in which a heater heating element is installed, being lower than the upper end of a cooking container, on the front and rear sidewalls of a cooking chamber of an enclosure and a transparent planar heating element is installed over an opening of the cooking chamber of the enclosure, radiant heat may actively control various disturbances that occur during cooking depending on a place where the oven is installed and a change in temperature, whereby there is an effect of providing the optimum heat power depending on a cooking material and also shortening cooking time.

An electric composite heat oven provided with a sight window of a transparent planar heating element is provided. Since the electric composite heat oven has a structure in which a heater heating element is installed, being lower than the upper end of a cooking container, on the front and rear sidewalls of a cooking chamber of an enclosure and a transparent planar heating element is installed over an opening of the cooking chamber of the enclosure, radiant heat may actively control various disturbances that occur during cooking depending on a place where the oven is installed and a change in temperature, whereby there is an effect of providing the optimum heat power depending on a cooking material and also shortening cooking time.

An electric heater includes a substrate (an insulating material capable of forming a conductor pattern on a surface of an insulating substrate), a first plane heating element formed on one surface of the substrate, and a second plane heating element formed on one surface of the substrate to be located outside the first plane heating element. The first plane heating element includes a first pattern portion connecting a start point with an end point located in a first zone, a pair of first electrodes located outside the first zone, and a pair of first connectors connecting the first pattern portion with the first electrodes. The second plane heating element includes a second pattern portion located in a second zone surrounding the first zone and connecting a start point with an end point, and at least some of the first connectors are located in the second zone.

A toaster heating assembly (55A, 55B) including: a frame (60); a panel (65) at least partly supported by the frame (60); a spacer (80) mounted to the panel (65); and an elongate heating element (93) having a plurality of spaced apart elongate heating element portions (95) supported by the spacer (80), so that the spacer (80) is located between the plurality of heating element portions (95) and the panel (65) to provide a gap (94) between the plurality of heating element portions (95) and the panel (65).

A toaster heating assembly (55A, 55B) including: a frame (60); a panel (65) at least partly supported by the frame (60); a spacer (80) mounted to the panel (65); and an elongate heating element (93) having a plurality of spaced apart elongate heating element portions (95) supported by the spacer (80), so that the spacer (80) is located between the plurality of heating element portions (95) and the panel (65) to provide a gap (94) between the plurality of heating element portions (95) and the panel (65).

A method for operating a cooking system includes receiving information from a powered cooking accessory positioned within an interior cavity of an oven. The powered cooking accessory includes a body receivable within an interior of the oven, a first electronic device coupled with the body, and a device coupling extending from the body. The method further includes determining at least one characteristic of the powered cooking accessory and providing electrical power to the electronic device by an electrical coupling between the device coupling and a connection port within the interior cavity of the oven at a predetermined output level based on the at least one characteristic thereof.

A method for operating a cooking system includes receiving information from a powered cooking accessory positioned within an interior cavity of an oven. The powered cooking accessory includes a body receivable within an interior of the oven, a first electronic device coupled with the body, and a device coupling extending from the body. The method further includes determining at least one characteristic of the powered cooking accessory and providing electrical power to the electronic device by an electrical coupling between the device coupling and a connection port within the interior cavity of the oven at a predetermined output level based on the at least one characteristic thereof.

A cooking apparatus includes a heating device intended to be placed opposite a cooking chamber, and a ventilation member arranged to generate a flow of hot air, the flow of hot air is heated by the heating device wherein the heating device includes a first heating member and a second heating member, the apparatus having a processing unit configured to propose an operating mode of the cooking apparatus in which at least one of the first heating member and the second heating member and the ventilation member are activated simultaneously to perform a function of cooking food placed in the cooking chamber, and to propose another operating mode in which only one of the first heating member or the second heating member is activated to perform a function of grilling or browning food disposed in the cooking chamber, and the ventilation member is deactivated.

The present disclosure relates to a rotary roaster capable of uniformly heating the entire surface of a grill by means of an induction heating method. According to one embodiment, a rotary roaster operating on an induction heating device comprises a supporter, a grill rotatably coupled to the supporter, a motor configured to rotate the grill and a receiving coil provided on a bottom surface of the supporter and configured to provide a power induced by a working coil of the induction heating device to the motor.

A temperature-regulating appliance includes a top portion, a base, a temperature sensor, and a mounting adapter. The top portion has an upper surface and a lower surface. The base includes a housing defining an internal compartment and a thermal element disposed within the internal compartment of the housing. The temperature sensor is positioned outside of the internal compartment, between the housing and the lower surface of the top portion. The mounting adapter extends between the top portion and the housing. The mounting adapter detachably couples the base to the top portion.