A microwave heating device includes at least two radiating portions that are adapted to radiate microwaves to the heating chamber and can be operated according to a plurality of operational configurations that differ in frequency and/or in phase shift(s) between the radiated microwaves. Data of energy efficiency, as a function of operational configurations, can be obtained for a product in the heating chamber. For example, energy efficiency data are obtained through a learning procedure. The obtained data can be processed to select one or more operational configurations ranking high in energy efficiency and a heating procedure for the product inside the heating chamber can be executed by operating the at least two radiating portions according to the selected one or more operational configurations.

Aspects of the subject disclosure may include, for example, a method including detecting, by a controller coupled to an array of elements, an object having a plurality of portions, and analyzing a selected portion to determine its volume and density, to determine parameters of radio frequency thermal excitation for the selected portion. The method also includes selecting radiation emitters from the array elements according to the parameters; each of the array elements is separately selectable and controllable. The method also includes controlling the radiation emitters according to the parameters to perform the thermal excitation of the selected portion. The controlling includes causing interference of waves emitted from separate radiation emitters. The method also includes forming a three-dimensional thermal image of the selected portion, analyzing the thermal image, adjusting the parameters according to the analyzing, and detecting movement into a space irradiated by the radiation emitters. Other embodiments are disclosed.

The present invention relates to a processing apparatus, in which a flying oil is heated, disinfected and/or pasteurized, sterilized. The present invention further relates to a method to treat a flying oil with radio-frequency wave

An oven may include a cooking chamber, a user interface, a first energy source, a second energy source and a cooking controller. The cooking chamber may be configured to receive a food product. The user interface may be configured to display information associated with processes employed for cooking the food product. The first energy source may provide primary heating of the food product placed in the cooking chamber. The second energy source may provide browning for the food product. The cooking controller may be operably coupled to the first and second energy sources. The cooking controller may include processing circuitry configured to enable an operator to make a browning control selection via the user interface by providing operator instructions to a selected control console rendered at the user interface. The selected control console may be selected based on a cooking mode of the oven. The browning control selection may provide control parameters to direct application of heat to the food product via the second energy source.

The present invention relates to a solid-state cooking apparatus. The present invention further relates to a field applicator for applying an electromagnetic wave, preferably to a cooking cavity of a solid-state cooking apparatus. The field applicator comprises a quadrature coupler for splitting a radiofrequency signal over a pair of antenna elements. The isolated port of the quadrature coupler is connected to a predefined load. The solid-state cooking apparatus is operable in at least one of a first mode and second mode, wherein, in the first mode, the predefined load equals an RF short or an RF open, and, in the second mode, the predefined load equals a dummy load configured to dissipate the signal received at the isolated port of the quadrature coupler.

A method of coherently controlling irradiation of an object in an enclosed cavity by at least two radio frequency (RF) feeds includes setting an amplitude, a phase and a frequency for each of the RF feeds; actuating all of the RF feeds with the respectively set amplitudes, phases and frequencies to irradiate the object; measuring a reflected power at each of the RF feeds; characterizing a complete scattering parameter matrix of the enclosed cavity while the object is being irradiated; and adjusting the power, the phase and the frequency for each of the RF feeds based on the complete scattering parameter matrix and values of the power, the phase and the frequency of the RF feeds before adjusting.

An autoclave for welding thermoplastic composite parts comprises a sealed process chamber, a pressure source, a microwave source and a workpiece supporting member configured to support at least two thermoplastic composite parts which contact each other in an abutting section within the process chamber. The pressure source is configured to generate positive pressure in the process chamber which is higher than an ambient pressure surrounding the process chamber while the microwave source emits microwaves towards the abutting section in order to locally melt the thermoplastic composite parts and weld them together in the region of the abutting section.

Disclosed are RF power modules, and RF ovens, each having one or more RF power modules. In particular, a disclosed RF power module may include a printed circuit board (PCB) having a trace; and a radiating element having a first end portion and a second end portion. The first end portion is in electrical communication with the trace of the of PCB, and the second end portion in operable communication with a microwave cavity, and the radiating element is disposed and soldered in parallel to the trace.

A high frequency energy generator system includes a plurality of high frequency energy generator heads. Each head includes a respective magnetron; a common drive unit for producing power for the plurality of magnetrons; and a connector arrangement connecting each of the plurality of heads to the common drive unit to supply power to the magnetrons. At least one of the heads is located remote from the common drive unit.

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.