Control electronics may control power amplifier electronics associated with application of RF energy generated using solid state electronic components. The power amplifier electronics may be configured to control application of RF energy in an oven according to a cooking recipe at least in part based on a learning procedure that generates a power cycling between high and low powers when the learning procedure is executed. The control electronics may include processing circuitry configured to employ a thermal stress mitigation technique to control thermal stresses on the power amplifier electronics associated with the power cycling.

A heat sink apparatus for a microwave magnetron includes a thermal conduction seat, a first heat-fin set, and at least one first heat pipe. One end of the first heat pipe protrudes into the thermal conduction seat, while another end of the first heat pipe protrudes into the first heat-fin set. An antenna of the microwave magnetron is to penetrate through the thermal conduction seat.

A solid-state radio frequency (SSRF) water heating apparatus is disclosed. In embodiments, the SSRF water heater includes a water tank, SSRF generator array and RF sensors enclosed within an RF-shielded cage. The SSRF array synthesizes RF signals in the microwave range and transmits the RF energy through the water tank, exciting and heating the water molecules without direct contact. The RF sensors at the opposite end of the tank sense residual RF energy not absorbed by the water. Control processors regulate the generation and transmission of the RF energy based on the sensed residual energy. The heated water and/or generated steam is piped to hot water dispensers, beverage makers, or steam ovens.

A microwave generator for a microwave device includes a single component carrier for control components and power components, which includes a continuous carrier material. Two power regions and one control region are provided on the component carrier. In the control region, electrically functional components are arranged on both flat sides of the component carrier, while in the power regions, electrically functional components with at least one power switch are arranged only on an upper flat side, heat sinks being arranged on the lower flat side. An RF substrate is provided in regions on the upper flat side of the power region.

A pull-out guide for a microwave cooking appliance or an industrial oven includes a body rail and a running rail, that is able to move relative thereto, for depositing a carrier, and a microwave shield for shielding the pull-out guide from microwaves. The running rail is only partially shielded.

An air cleaning system for an oven that includes a cooking chamber configured to receive a food product includes a catalytic converter, an input array and a preheater. The catalytic converter may be configured to clean air expelled from the cooking chamber. The input array may include perforations through which cleaned air that has been processed by the catalytic converter is provided into the cooking chamber. The preheater may be disposed proximate to the cooking chamber to use heat generated by the cooking chamber to preheat the cleaned air prior to entry of the cleaned air into the cooking chamber through the input array.

In a microwave heating device of the present disclosure, inverter unit drives first and second microwave generators. Cooling unit cools first and second microwave generators and inverter unit. First and second waveguides supplies, to cavity, microwaves generated by first and second microwave generators. First and second microwave generators are disposed side by side in a right-left direction below a bottom surface of cavity. Inverter unit and cooling fan are disposed from the first and second microwave generators toward a front side in order, and first and second waveguides are provided so as to extend in a front-back direction from first and second microwave generators, respectively. According to the present disclosure, the microwave heating device can be further downsized in a right-left direction.

A portable microwave oven that includes an outer housing comprising a plurality of outer walls, wherein one outer wall includes a vent opening; an inner structure comprising a plurality of inner walls that define a heating chamber; a door rotatable relative to the outer housing to access the heating chamber; a heating element configured to heat the heating chamber; and a heat handling system comprising: an intake duct fluidly connecting the vent opening to an electronics chamber housing the heating element; an exhaust duct fluidly connecting the electronics chamber to the vent opening; and at least one fan that is configured to draw air in through the intake duct or push air out through the exhaust duct; wherein the microwave oven is operable in a first orientation, in which the door is forward facing, and a second orientation, in which the door is upward facing.

A microwave heat treatment apparatus includes: a processing vessel configured to accommodate a substrate therein; a support member configured to rotatably support the substrate in the processing vessel; a microwave introduction device configured to generate a microwave for processing the substrate and introduce the microwave into the processing vessel; a first cooling gas introduction part installed to face a main surface of the substrate supported by the support member, the main surface being a target to be processed; a second cooling gas introduction part installed in a lateral side of the substrate supported by the support member; and a control unit configured to independently control the introduction of a cooling gas from the first cooling gas introduction part and the introduction of the cooling gas from the second cooling gas introduction part.

A heating cooker includes heating chamber configured to house a food, through-hole formed in a wall surface of heating chamber, an imager configured to capture an image in heating chamber through through-hole, air blower configured to blow air on an outside of heating chamber, and wind guide configured to guide wind generated by air blower. Thus, wind guide is disposed so that the wind from air blower forms an air curtain passing through space between the imager and through-hole.