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.

This disclosure relates to the field of cooking ovens for the preparation of foodstuffs in an enclosed environment including a visual flame along with a rotating cooking plate upon which foodstuffs are placed and are transported through various cooking regions before being removed from the cooking oven for consumption.

This disclosure relates to the field of cooking ovens for the preparation of foodstuffs in an enclosed environment including a visual flame along with a rotating cooking plate upon which foodstuffs are placed and are transported through various cooking regions before being removed from the cooking oven for consumption.

The present invention relates to a small, lightweight, portable or easily removable high temperature oven with a rotating floor, designed to bake one pizza at a time, and operate between 300 and 1400° F., with mechanisms to independently regulate the temperature of the dome and the floor of the oven, using thermocouples, infrared sensors, other temperature sensors, industrial oven controllers, other programmable logic controllers, solenoid gas valves, or proportional response gas valves, baffles and ventilation systems and other heat sources, control sensing and regulation systems, to imitate the baking conditions of a heavy ceramic traditional Italian cupola oven. Different embodiments include portable catering ovens, food truck ovens, very small pizzeria ovens, and residential ovens with automatic controls, that are approximately conventional residential countertop depth.

The present invention relates to a small, lightweight, portable or easily removable high temperature oven with a rotating floor, designed to bake one pizza at a time, and operate between 300 and 1400° F., with mechanisms to independently regulate the temperature of the dome and the floor of the oven, using thermocouples, infrared sensors, other temperature sensors, industrial oven controllers, other programmable logic controllers, solenoid gas valves, or proportional response gas valves, baffles and ventilation systems and other heat sources, control sensing and regulation systems, to imitate the baking conditions of a heavy ceramic traditional Italian cupola oven. Different embodiments include portable catering ovens, food truck ovens, very small pizzeria ovens, and residential ovens with automatic controls, that are approximately conventional residential countertop depth.

An oven uses at least one infrared sensor located outside of the oven baking chamber to measure infrared light emissions from an oven floor, and includes apparatuses that defend infrared sensors and light sources from heat damage using for example baffles, shutters, remote location of the sensor from heat sources and powered ventilation, temperature control systems for ovens using at least one infrared sensor to control the temperature of an oven floor, and powered ventilation systems to keep oven walls cool.

An oven uses at least one infrared sensor located outside of the oven baking chamber to measure infrared light emissions from an oven floor, and includes apparatuses that defend infrared sensors and light sources from heat damage using for example baffles, shutters, remote location of the sensor from heat sources and powered ventilation, temperature control systems for ovens using at least one infrared sensor to control the temperature of an oven floor, and powered ventilation systems to keep oven walls cool.

Food preparation apparatus and associated methods. In one method, dough is proofed in an oven compartment and then baked in the same oven compartment. Temperature and/or humidity can be controlled during proofing and/or baking cycles. A blower may be used, for example, to exhaust gas to ambient to reduce heat and/or moisture in the compartment. For example, the blower may be used between proofing and baking cycles to prepare an environment in the oven compartment for the baking cycle.

Food preparation apparatus and associated methods. In one method, dough is proofed in an oven compartment and then baked in the same oven compartment. Temperature and/or humidity can be controlled during proofing and/or baking cycles. A blower may be used, for example, to exhaust gas to ambient to reduce heat and/or moisture in the compartment. For example, the blower may be used between proofing and baking cycles to prepare an environment in the oven compartment for the baking cycle.

A temperature-regulating unit includes a base, a resonant tank, and a controller. The base is configured to support a pan. The resonant tank includes a coil and a capacitor. The resonant tank has a resonant frequency that is affected by a material of the pan and a temperature of the pan. The controller is configured to receive a temperature setting, monitor the resonant frequency, determine the material of the pan based on the resonant frequency, determine the temperature of the pan based on the resonant frequency, and adaptively control a thermal element based on the temperature of the pan, the material of the pan, and the temperature setting.