Embodiments described herein provide a microwave coupler that utilizes a microwave shield within an interior of the microwave coupler to mitigate Radio Frequency (RF) leakage from an end of the microwave coupler. The microwave coupler includes a ramp section that is configured to mate to a microwave source, with the ramp section extending from an opening in a top wall of an enclosure. One end of the enclosure is configured to mate to a microwave waveguide, while an opposing end may be open or partially open. The microwave shield is located between the opposing end of the enclosure and the opening in the top wall, and extends from the top wall of the enclosure towards a bottom wall of the enclosure.

A microwave appliance, as provided herein, may include a cabinet, a magnetron, and a drawer liner. The cabinet may define a primary cooking chamber. The magnetron may be mounted within the cabinet in communication with the primary cooking chamber to direct a microwave thereto. The drawer liner may have a side wall joined to a base wall. The drawer liner may be slidably mounted to the cabinet to move along the vertical direction between a contracted position and an expanded position. The side wall may be received within the cabinet in the contracted position. The side wall may define a secondary cooking chamber with the base wall below the primary cooking chamber in the expanded position.

A continuous asphalt mix system for using a microwave heating vessel at the point of production that includes a microwave energy suppression tunnel with one or more mesh flaps for substantially reducing or preventing the leakage of microwave energy from a microwave system, while having a continuous flow of product through the vessel and suppression tunnels. The suppression tunnels are installed on the inlet and/or the outlet side of the system and are sized to suppress leakage.

A venting appliance for use with a cooking appliance including a cooktop with at least one cooking element disposed thereon, where the venting appliance may include: a housing configured to be positioned above the cooktop; a repositionable vent arm coupled to and extending below the housing; and a controller coupled to the repositionable vent arm and configured to determine that a first cooking element among at least one cooking elements is active, and in response thereto, automatically reposition the vent arm to be closer to the first cooking element.

A microwave oven has a cooking cavity and an electrical chamber, with a magnetron, a frequency converter assembly and a cooling fan arranged in the electrical chamber. The frequency converter assembly has a mounting support mounted on a bottom plate of the microwave oven, a mounting base obliquely mounted on the mounting support, a frequency converter circuit board mounted on the mounting base and obliquely arranged relative to the bottom plate of the microwave oven, and an air guide cover covering over the frequency converter circuit board for guiding cool air blown by the cooling fan to the frequency converter circuit board. The microwave oven can not only solve the problem that the mounting space for frequency converter circuit boards is not sufficient, but also effectively control the temperature rise of the frequency converter circuit boards.

An air circulation system includes an inlet filter support structure, a first side filter and a second side filter. The air circulation system is for an oven that has a cooking chamber configured to receive a food product and a radio frequency (RF) heating system configured to provide RF energy into the cooking chamber using solid state electronic components. The air circulation system is configured to provide air for cooling the solid state electronic components. The inlet filter support structure enables cooling air for cooling the solid state electronic components to be drawn therein prior to circulation by a cooling fan. The first side filter is supported by the inlet filter support structure. The first side filter is disposed below one of the sidewalls and disposed at an angle relative to the one of the sidewalls. The second side filter is supported by the inlet filter support structure. The second side filter is disposed below an opposing one of the sidewalls and disposed at the angle relative to the opposing one of the sidewalls.

A wireless power supply device includes a first housing, a transmitting coil assembly mounted in the first housing, a second housing, and a receiving coil assembly mounted in the second housing and electromagnetically coupled with the transmitting coil assembly. The first housing has a U-shaped outer contour and includes a first portion, a second portion, and a third portion. The second portion and the third portion extend perpendicularly to the first portion from opposite ends of the first portion. The second portion and the third portion form a recess between the second portion and the third portion. The second housing extends into the recess.

A venting appliance for use with a cooking appliance including a cooktop with at least one cooking element disposed thereon, where the venting appliance may include: a housing configured to be positioned above the cooktop; a repositionable vent arm coupled to and extending below the housing; and a controller coupled to the repositionable vent arm and configured to determine that a first cooking element among at least one cooking elements is active, and in response thereto, automatically reposition the vent arm to be closer to the first cooking element.

A venting appliance for use with a cooking appliance including a cooktop with at least one cooking element disposed thereon, where the venting appliance may include: a housing configured to be positioned above the cooktop; a repositionable vent arm coupled to and extending below the housing; and a controller coupled to the repositionable vent arm and configured to determine that a first cooking element among at least one cooking elements is active, and in response thereto, automatically reposition the vent arm to be closer to the first cooking element.

A microwave heating apparatus comprises: a housing, arranged to define a cavity; a semiconductor RF generator, configured to provide at least one RF signal; and a plurality of RF antennas, arranged in a distributed way within the cavity and configured to radiate the at least one RF signal from the semiconductor RF generator, such that items received in the cavity are dielectrically heated by the radiation.