In one aspect, a cooking device includes independently controllable cooking zones. In one aspect, a cooking device includes a first cooking zone with heated air configured to move horizontally there through in a first direction and a second cooking zone with heated air configured to move horizontally there through in a second direction different than the first direction. In one aspect, the first and second directions are opposite directions. In one aspect, the heated air flows from one side of the cooking device.

A thermal processing apparatus (20) includes a spiral conveyor system (22) configured into an ascending spiral stack (26). An air balance tunnel (40) includes a tunnel housing (76) positioned inside of a thermal processing chamber adjacent an outlet opening (36). A conveyor belt (24) travels through the housing on its way out of the processing chamber. An air pervious ejector assembly (78) is positioned within the housing at an elevation above the conveyor belt (24). An air pervious evacuation sheet (80) is located within the housing at a location beneath the conveyor belt (24). An air pervious cover assembly (150) is positioned over the conveyor belt (24) at a location just before the conveyor belt enters the air balance tunnel (40). The cover sheet (150) is connectable to the ejector assembly (78) so as to remove the ejector assembly from the tunnel housing (76) by manually moving the cover assembly (150).

Tunnel oven for the industrial production of baked goods; having a baking chamber with an air-permeable, endlessly circulating conveyor belt, which is set up for conveying baked goods in a conveying direction through the baking chamber; a plurality of bottom-heat air outlet nozzles, which are arranged below the conveyor belt and are directed towards the underside of the conveyor belt, wherein the bottom-heat air outlet nozzles generate a bottom-heat inlet air flow directed directly towards the underside of the conveyor belt; a plurality of bottom-heat air inlets, which are distributed in a planar manner below the conveyor belt, in order to discharge bottom-heat exhaust air below the conveyor belt; wherein the bottom-heat exhaust air is sucked off by means of a fan and is supplied heated by thermo oil as the bottom-heat inlet air flow, so that a bottom-heat convection circuit is generated.

Tunnel oven for the industrial production of baked goods; having a baking chamber with an air-permeable, endlessly circulating conveyor belt, which is set up for conveying baked goods in a conveying direction through the baking chamber; a plurality of bottom-heat air outlet nozzles, which are arranged below the conveyor belt and are directed towards the underside of the conveyor belt, wherein the bottom-heat air outlet nozzles generate a bottom-heat inlet air flow directed directly towards the underside of the conveyor belt; a plurality of bottom-heat air inlets, which are distributed in a planar manner below the conveyor belt, in order to discharge bottom-heat exhaust air below the conveyor belt; wherein the bottom-heat exhaust air is sucked off by means of a fan and is supplied heated by thermo oil as the bottom-heat inlet air flow, so that a bottom-heat convection circuit is generated.

An oven includes upper and lower assemblies, a fire box and a heat absorbing and emanating device. The upper assembly forms a cooking chamber and has a front side with an open entry to the cooking chamber. The lower assembly is located below the upper assembly and has an internal cavity. The fire box is located within the internal cavity and includes a heat source. The device is located between the upper and lower assemblies and absorbs heat from the heat source and emanates heat into the cooking chamber of the upper assembly. The upper assembly includes inner and outer dome assemblies. The inner dome is located within the outer dome and forms first and second airflow pathways.

An oven includes upper and lower assemblies, a fire box and a heat absorbing and emanating device. The upper assembly forms a cooking chamber and has a front side with an open entry to the cooking chamber. The lower assembly is located below the upper assembly and has an internal cavity. The fire box is located within the internal cavity and includes a heat source. The device is located between the upper and lower assemblies and absorbs heat from the heat source and emanates heat into the cooking chamber of the upper assembly. The upper assembly includes inner and outer dome assemblies. The inner dome is located within the outer dome and forms first and second airflow pathways.

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.

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.

An oven with an enhanced structure to keep a cooking space clean includes a main body, a cooking chamber formed inside the main body and including a bottom wall, a burner provided at an outer lower part of the cooking chamber to heat up the cooking chamber, a door arranged to open or close the cooking chamber, a bottom plate coupled to the bottom wall of the cooking chamber with a gap from the bottom wall such that the bottom plate is located inside the cooking chamber, and an outlet for heated air formed between one end of the bottom plate facing the door and the bottom wall of the cooking chamber such that heated air generated from the burner is supplied to the door.

An oven with an enhanced structure to keep a cooking space clean includes a main body, a cooking chamber formed inside the main body and including a bottom wall, a burner provided at an outer lower part of the cooking chamber to heat up the cooking chamber, a door arranged to open or close the cooking chamber, a bottom plate coupled to the bottom wall of the cooking chamber with a gap from the bottom wall such that the bottom plate is located inside the cooking chamber, and an outlet for heated air formed between one end of the bottom plate facing the door and the bottom wall of the cooking chamber such that heated air generated from the burner is supplied to the door.