A method of operating cooking appliance includes activating a motor to rotate a turntable within a cooking cavity defined in a casing of the cooking appliance. The methods also includes activating a cooking lamp in response to the turntable reaching a first angular position after activating the motor to rotate the turntable and deactivating the cooking lamp in response to the turntable reaching a second angular position after the first angular position.

A continuous-belt baking system having a pair of upper rollers rotatably mounted in frame and spaced at a first distance, a pair of lower rollers rotatably mounted in frame and spaced at a second distance, a continuous thermally-conductive belt passing over the upper rollers, a continuous thermally conductive belt passing over the lower rollers, and two arrays of radiant heating elements. The radiant arrays include a first group of heating elements above a lower run of the upper belt between said upper rollers and a second opposing group of heating elements below an upper run of the bottom belt between the lower rollers. Each heating element may be separately controlled insofar as its ON/OFF state or in accordance with temperature, to provide more localized baking capabilities.

A continuous-belt baking system having a pair of upper rollers rotatably mounted in frame and spaced at a first distance, a pair of lower rollers rotatably mounted in frame and spaced at a second distance, a continuous thermally-conductive belt passing over the upper rollers, a continuous thermally conductive belt passing over the lower rollers, and two arrays of radiant heating elements. The radiant arrays include a first group of heating elements above a lower run of the upper belt between said upper rollers and a second opposing group of heating elements below an upper run of the bottom belt between the lower rollers. Each heating element may be separately controlled insofar as its ON/OFF state or in accordance with temperature, to provide more localized baking capabilities.

A cooking appliance (400) including: a body (402) providing a floor (404), a ceiling (406) and an intermediate wall (408) located between the floor (404) and ceiling (406), the floor (404), ceiling (406), and wall (408) at least partly surrounding a cooking cavity (410), the body (402) having an opening (412) via which product to be cooked can be moved relative to the cavity (410); a heating element (420) located in the cavity (410) to deliver radiant energy to cook the product; a cooling system (434) coupled to the body (402), the cooling system (434) including an airflow channel (436) communicating with a cold pin section (424) of the heating element (420), the airflow channel (436) configured to direct airflow to the cold pin section (424) to selectively cool the cold pin section (424); and a shield (444) positioned relative to the cold pin section (424) to shield the cavity (410) from at least a portion of the airflow.

A cooking appliance (400) including: a body (402) providing a floor (404), a ceiling (406) and an intermediate wall (408) located between the floor (404) and ceiling (406), the floor (404), ceiling (406), and wall (408) at least partly surrounding a cooking cavity (410), the body (402) having an opening (412) via which product to be cooked can be moved relative to the cavity (410); a heating element (420) located in the cavity (410) to deliver radiant energy to cook the product; a cooling system (434) coupled to the body (402), the cooling system (434) including an airflow channel (436) communicating with a cold pin section (424) of the heating element (420), the airflow channel (436) configured to direct airflow to the cold pin section (424) to selectively cool the cold pin section (424); and a shield (444) positioned relative to the cold pin section (424) to shield the cavity (410) from at least a portion of the airflow.

A heating appliance includes a housing defining a food product compartment having at least a front door and a rear wall opposite the front door. The heating appliance also includes a rack configured to support a food product within the food product compartment. The heating appliance also includes a heating assembly disposed within the food product compartment and an elongate heating device having a first length, and an angled heat distribution member having a second length disposed between the heating device and the rack. The heat distribution member includes a pattern of apertures and the heat distribution member is configured to prevent infrared radiation produced by the heating device from directly reaching the rear wall of the housing, except for infrared radiation that passes through the apertures of the heat distribution member.

A heating appliance includes a housing defining a food product compartment having at least a front door and a rear wall opposite the front door. The heating appliance also includes a rack configured to support a food product within the food product compartment. The heating appliance also includes a heating assembly disposed within the food product compartment and an elongate heating device having a first length, and an angled heat distribution member having a second length disposed between the heating device and the rack. The heat distribution member includes a pattern of apertures and the heat distribution member is configured to prevent infrared radiation produced by the heating device from directly reaching the rear wall of the housing, except for infrared radiation that passes through the apertures of the heat distribution member.

The cooking module for a linear tunnel oven for bakery products includes a cooking chamber having a hearth, in the form of a conveyor belt, that is mobile and permeable to a gaseous heat-transfer fluid, a roof, and a heating device in the hearth and on the roof to cook the products. The heating device in the hearth includes a plurality of orifices for blowing the fluid. The belt is mobile above a sliding surface having openings for the fluid to pass through, and is mobile between two positions, a convection position where the openings coincide with the orifices to let the fluid pass through, and a second position known as a radiation position, where openings are offset from these orifices, the surface forming a screen for the fluid blown through the orifices.

The cooking module for a linear tunnel oven for bakery products includes a cooking chamber having a hearth, in the form of a conveyor belt, that is mobile and permeable to a gaseous heat-transfer fluid, a roof, and a heating device in the hearth and on the roof to cook the products. The heating device in the hearth includes a plurality of orifices for blowing the fluid. The belt is mobile above a sliding surface having openings for the fluid to pass through, and is mobile between two positions, a convection position where the openings coincide with the orifices to let the fluid pass through, and a second position known as a radiation position, where openings are offset from these orifices, the surface forming a screen for the fluid blown through the orifices.

A cooking oven has a cooking cavity and a steam generating system. The steam generation system includes a water reservoir received and support in a reservoir-receiving space of a reservoir rack inside the cooking cavity. Thermal energy is provided to the water reservoir by a heater inside the cooking cavity. The heater can include thermal block made of a thermally conductive material in thermal communication with a heating element. The heater can be positioned such that it intimately contacts the water reservoir to deliver thermal energy thereto to convert water contained therein to steam, which can be used to cook a food item inside the cooking cavity.