Provided is a system and method for heating an item in a microwave oven. The method includes capturing, with at least one electromagnetic field sensor, at least one electromagnetic field measurement of a microwave chamber, each electromagnetic field measurement of the at least one electromagnetic field measurement corresponding to a region in the microwave chamber, generating an electromagnetic field map of the microwave chamber based on the at least one electromagnetic field measurement, capturing, with at least one sensor, a plurality of thermal measurements of the item being heated in the microwave chamber, each thermal measurement of the plurality of thermal measurements corresponding to a region on the item, and controlling at least one of a position of the item and the electromagnetic field while the item is being heated in the microwave chamber based on the electromagnetic field map and the plurality of thermal measurements.

Provided is a system and method for heating an item in a microwave oven. The method includes capturing, with at least one electromagnetic field sensor, at least one electromagnetic field measurement of a microwave chamber, each electromagnetic field measurement of the at least one electromagnetic field measurement corresponding to a region in the microwave chamber, generating an electromagnetic field map of the microwave chamber based on the at least one electromagnetic field measurement, capturing, with at least one sensor, a plurality of thermal measurements of the item being heated in the microwave chamber, each thermal measurement of the plurality of thermal measurements corresponding to a region on the item, and controlling at least one of a position of the item and the electromagnetic field while the item is being heated in the microwave chamber based on the electromagnetic field map and the plurality of thermal measurements.

A microwave cooking appliance for increasing visibility into the cooking cavity. The microwave cooking appliance may include a door. The door may include a conductive mesh layer. The door may include a frame supporting the conductive mesh layer. The door may include a conductive and/or sealing engagement between the conductive mesh layer and the frame. The door may include a leak detection device. The leak detection device may be adjacent the conductive and/or sealing engagement. The door may include a user interface display and/or a touch screen.

A microwave cooking appliance for increasing visibility into the cooking cavity. The microwave cooking appliance may include a door. The door may include a conductive mesh layer. The door may include a frame supporting the conductive mesh layer. The door may include a conductive and/or sealing engagement between the conductive mesh layer and the frame. The door may include a leak detection device. The leak detection device may be adjacent the conductive and/or sealing engagement. The door may include a user interface display and/or a touch screen.

A door for a microwave oven is provided. The door (34) include a door frame (44) having a first side and a second side, an outer glass (40) coupled with the first side of the door frame (44), and a glass assembly (52) coupled with the second side of the door frame (44). The glass assembly (52) includes a first substantially transparent glass substrate (70), a second substantially transparent glass substrate (72), and an electrically conductive mesh layer (74) between the first and second substantially transparent glass substrates (70,72). The mesh layer (74) includes a plurality of wires having a diameter less than 0.04 mm, The shielding performance of the door (34) is improved.

A microwave oven is provided including a cooking cavity for receiving food to be cooked, at least one microwave source for generating microwave energy inside the cooking cavity, and a supplemental heating system positioned to heat the food. The supplemental heating system includes at least one IR radiation source for generating IR radiation and a metallic mesh screen placed between the at least one IR radiation source and the cooking cavity for spatially distributing the IR radiation to uniformly project into the cooking cavity and minimizing microwave energy field losses. The metallic mesh screen includes a plurality of hexagonal apertures arranged in a honeycomb pattern. The distance between parallel sides of each one of the hexagonal apertures is Ax and the distance between each hexagonal aperture and each adjacent hexagonal aperture is Bx where Ax is less than or equal to about 3 times Bx.

A microwave oven is provided including a cooking cavity for receiving food to be cooked, at least one microwave source for generating microwave energy inside the cooking cavity, and a supplemental heating system positioned to heat the food. The supplemental heating system includes at least one IR radiation source for generating IR radiation and a metallic mesh screen placed between the at least one IR radiation source and the cooking cavity for spatially distributing the IR radiation to uniformly project into the cooking cavity and minimizing microwave energy field losses. The metallic mesh screen includes a plurality of hexagonal apertures arranged in a honeycomb pattern. The distance between parallel sides of each one of the hexagonal apertures is Ax and the distance between each hexagonal aperture and each adjacent hexagonal aperture is Bx where Ax is less than or equal to about 3 times Bx.

In an apparatus for hazardous chemical detection in a microwave oven, a microwave oven comprises an electromagnetic wave shielding material, at least one chemiresistor, a microcontroller, and a digital display, wherein the at least one chemiresistor is overlaid by the electromagnetic wave shielding material, and the microcontroller is electronically coupled to the digital display. In an approach to detect the release of a hazardous chemical during a cooking cycle in a microwave oven, a processor receives a reading from at least one chemiresistor, wherein the at least one chemiresistor is configured to detect a chemical. A processor determines whether a pre-set threshold is met. In response to the pre-set threshold being met, a processor sends an alert.

A pulsed electromagnetic irradiation system for water treatment including raw water supply unit in fluid communication with a reaction vessel, a multimode cavity in which the reaction vessel is partially positioned. A magnetron generator is positioned adjacent the multimode cavity and is electromagnetically coupled with liquid within the reaction vessel. A stirring motor is positioned adjacent a bottom surface of multimode cavity and operatively coupled with the reaction vessel to stir the liquid within reaction vessel. A parabolic arm air cooled condenser is terminally connected to the reaction vessel to be in fluid communication with the reaction vessel. A gravity vacuum funnel, where the gravity vacuum funnel is in communication with a first air/water cooled condenser. The first air/water cooled condenser outputs fresh water to a fresh water storage unit.

A pulsed electromagnetic irradiation system for water treatment including raw water supply unit in fluid communication with a reaction vessel, a multimode cavity in which the reaction vessel is partially positioned. A magnetron generator is positioned adjacent the multimode cavity and is electromagnetically coupled with liquid within the reaction vessel. A stirring motor is positioned adjacent a bottom surface of multimode cavity and operatively coupled with the reaction vessel to stir the liquid within reaction vessel. A parabolic arm air cooled condenser is terminally connected to the reaction vessel to be in fluid communication with the reaction vessel. A gravity vacuum funnel, where the gravity vacuum funnel is in communication with a first air/water cooled condenser. The first air/water cooled condenser outputs fresh water to a fresh water storage unit.