A cooking appliance includes a cabinet that defines a cooking chamber. A magnetron is mounted within the cabinet and is in communication with the cooking chamber to direct a microwave thereto. An induction heating coil is mounted within the cabinet and is in communication with the cooking chamber to direct a magnetic field thereto. A turntable is rotatably mounted in the cooking chamber above the induction heating coil. A motor is operatively coupled to the turntable and is mounted within the cabinet outside of the cooking chamber below and adjacent to the induction heating coil. The motor is operatively coupled to the turntable by a non-magnetic rotation hub extending through the induction heating coil.

A cooking appliance according to an embodiment of the present invention may comprise: a case in which a cooking chamber is formed; a door for opening or closing the front opening of the case; a steam generating device mounted to the outer surface of the case; and a steam supply tube for connecting the steam generating device to the cooking chamber, wherein the steam generating device includes: a housing fixed to the case; a drawer which can be pushed into and pulled out of the housing and is filled with water for steam generation; and an induction unit installed at the bottom of the housing so as to heat water filled in the drawer by using electromagnetic induction.

A cooking appliance includes a housing that defines a cavity therein, a door connected to the housing and configured to open and close the cavity, a microwave (MW) heating module configured to emit microwaves into the cavity, and an induction heating (IH) module configured to emit a magnetic field towards the cavity. The IH module includes a working coil that is configured to generate the magnetic field and a thin film that is disposed between the cavity and the working coil.

The present invention relates to a composite cooker having a plurality of heat sources. The cooker, according to one embodiment of the present disclosure, may comprise: a housing having a cavity formed therein; door connected to the housing so as to open/close the cavity; a MW heating module for radiating microwaves to the cavity; an IH heating module for radiating a magnetic field toward the cavity; and a shielding member for enabling the magnetic field generated by the TH heating module to pass through, while blocking the microwaves radiated from the MW heating module. The shielding member may comprise carbon fiber.

A cooking appliance includes a housing that defines a cavity therein, a door connected to the housing and configured to open and close the cavity, a microwave (MW) heating module configured to emit microwaves into the cavity, and an induction heating (IH) module configured to emit a magnetic field towards the cavity. The IH module includes a working coil that is configured to generate the magnetic field and a thin film that is disposed between the cavity and the working coil.

Embodiments disclosed herein include methods and systems for melting or augmenting a melt rate of material in a melter using electromagnetic radiation with a frequency between 0.9 GHz and 10 GHz. In some examples, a power and/or frequency of radiation used may be selected so as to control a temperature of a cold cap in the melter while maintaining emissions from the melter below a threshold level. In this manner, examples described herein may provide for efficient and safe melting and vitrification of radioactive wastes.

Methods and systems for melting or augmenting a melt rate of material in a melter using electromagnetic radiation with a frequency between 0.9 GHz and 10 GHz. In some examples, a power and/or frequency of radiation used may be selected so as to control a temperature of a cold cap in the melter while maintaining emissions from the melter below a threshold level. In this manner, examples described herein may provide for efficient and safe melting and vitrification of radioactive wastes.

A cooking appliance includes a cabinet that defines a cooking chamber. A magnetron is mounted within the cabinet and is in communication with the cooking chamber to direct a microwave thereto. An induction heating coil is mounted within the cabinet and is in communication with the cooking chamber to direct a magnetic field thereto. A turntable rotatably mounted in the cooking chamber at a center of the turntable. A motor is operatively coupled to the turntable and is mounted within the cabinet outside of the cooking chamber and adjacent to the induction heating coil. The motor is offset from the center of the turntable, as a result of the offset the motor is positioned outside of the magnetic field from the induction heating coil.

A cooking appliance having a casing with a cavity formed therein, a first heat source module arranged at a side surface of the casing to emit microwaves to the cavity, a second heat source module arranged at a bottom surface of the casing to emit magnetic fields to the cavity, and a third heat source module is arranged at an upper portion of the casing to emit radiant heat to the cavity, whereby the second heat source module in an induction heating manner rapidly heats a bottom surface of a bowl thereby improving cooking speed of the cooking appliance together with other heat sources.

A cooking appliance is proposed. A casing (100, 200) may have a cavity (S) therein, and of which a front surface may have an air inlet part (242) and an air outlet part (243) at different heights. A plurality of heat sources modules may be arranged at different surfaces of the casing (100,200). A this point, a cooling fan module (810, 850) may be arranged in a first electric chamber (ES1) provided behind the air inlet part (242), and transfer suctioned air into a second electric chamber (ES2) provided behind the air outlet part (243). Accordingly, the air suctioned by the cooling fan module (810, 850) may be discharged after circulating to through the first electric chamber (ES1) and the second electric chamber (ES2), and in this process, the plurality of heat sources may be cooled.