Examples are disclosed herein that relate to a cooking system having multiple heating elements for heating a cooking surface. One example provides a cooking system, comprising a continuous cooking surface comprising a plurality of individually controllable heating zones, and for each heating zone, a temperature sensor configured to detect a temperature for the heating zone separately from the temperatures of other heating zones, and a heating element disposed beneath the heating zone and configured to provide heat to the heating zone. The cooking system further comprises a controller configured to individually control the heating element of each heating zone.

A grilling apparatus for use in a cooking chamber of an oven, wherein the apparatus comprises: a panini press which comprises: an upper grill comprising a pair of oppositely disposed downwardly facing first guide rails; a lower grill comprising a pair of oppositely disposed upwardly facing guide surfaces; wherein the upper grill is reciprocally movable in a vertical direction towards and away from the lower grill by a pair of oppositely disposed alignment devices connected to opposing sides of the upper grill and disposed within a respective pair of upwardly facing guide surfaces connected to lower grill; and a paddle for holding at least one food product, which paddle comprises: a base portion, and a pair of oppositely disposed upward facing second guide rails which align with their respective the first guide rails, such that when the paddle enters the cooking chamber the second guide rails contact their respective the first guide rails which causes the upper grill to move upwardly away from the lower grill, thereby allowing the food product to be disposed between a lower surface of the upper grill and an upper surface of the lower grill; wherein upon removal of the paddle, the upper grill moves toward the food product and applies sufficient pressure to condense and impress grill marks on the food product during a cooking process.

A griddle includes a griddle plate, a heating element, a frame, and a plurality of nuts. The heating element provides heat to the griddle plate when the griddle is used. The frame includes a plurality of walls, a flange that extends from top edges of the plurality of walls, a plurality of studs mounted to extend upward from the flange, and a bottom wall that extends from bottom edges of the plurality of walls toward an interior of the plurality of walls. The heating element is mounted to the bottom wall. A nut of the plurality of nuts is mounted on each stud of the plurality of studs. A bottom surface of the griddle plate is mounted to abut each nut of the plurality of nuts to define an air gap around a perimeter of the griddle plate between the flange and the bottom surface of the griddle plate.

A grill includes a base structure, a first platen assembly connected to the base structure, and a second platen assembly connected to the base structure. At least the second platen assembly is movable between a first position and a second position. A latch mechanism is operable to selectively retain the upper platen assembly in the second position. The latch mechanism includes a first portion and a second portion. The second portion further comprises a retaining ring movable to receive and cooperate with the first portion when the first portion and the second portion of the latch mechanism are misaligned.

A grill includes a base structure, a first platen assembly connected to the base structure, and a second platen assembly connected to the base structure. At least the second platen assembly is movable between a first position and a second position. A latch mechanism is operable to selectively retain the upper platen assembly in the second position. The latch mechanism includes a first portion and a second portion. The second portion further comprises a retaining ring movable to receive and cooperate with the first portion when the first portion and the second portion of the latch mechanism are misaligned.

A food cooking appliance which utilizes both steam and heat for rapidly cooking food products is disclosed. The food products are disposed within a food cooking housing and a steam generator is provided within a steam generator housing so as to generate steam which is fluidically conducted into the food cooking housing. In this manner, the food products are cooked as a result of the steam being conducted into upper regions of cooking chambers defined within the food cooking housing while the heat generated from the heated grills or platens impart heat to the lower regions of the cooking chambers thereby cooking the food in an accelerated manner which is extremely desirable by commercial fast-food establishments. The steam generator housing is wholly separate and apart from the food cooking housing but fluidically connected to the food cooking housing by a fluid conduit which may rigid or flexible. In this manner, the food cooking housing and the steam generator housing may be located at different locations within a kitchen facility in order that the kitchen facility be capable of accommodating both the food cooking housing and the steam generator housing. The steam generator housing may also be provided with multiple fluid conduits such that a single steam generator can supply steam to a plurality of different appliances.

A cooktop appliance includes a top panel. A griddle is positioned on the top panel. The griddle includes a cooking plate. A cover is rotatable relative to the cooking plate between a closed configuration and an open configuration. The cover is positioned over a top surface of the cooking plate in the closed configuration of the cover. A splatter shield is rotatable relative to the cover between a closed configuration and an open configuration. The splatter shield is positioned over the top surface of the cooking plate in the open configuration of the splatter shield.

A cooking apparatus includes a base, a cover with a hot air system, an inner pot, an upper temperature sensor located in the lid, and a lower temperature sensor located in the base. A processor is configured to operate in one of multiple cooking modes, and for each of the cooking modes the processor is configured to measure an upper and a lower temperature using the upper and the lower temperature sensor, respectively; compare the upper and the lower temperature to an upper and a lower temperature sensor setting, respectively; when the upper temperature differs from the upper temperature sensor setting, adjust power to the hot air heating element such that the upper temperature approaches the upper temperature sensor setting; and when the lower temperature differs from the lower temperature sensor setting, adjust power to the heating plate such that the lower temperature approaches the lower temperature sensor setting.

A stepless temperature control method for an air fryer includes the steps of detecting and analyzing an air temperature in an air frying chamber of the air fryer in a real-time manner to obtain a temperature change in the air frying chamber, modulating a parameter of a stepless control signal according to a preset target temperature and the temperature change, and, in response to the modulated stepless control signal, adjusting a heating power of the air heater of the air fryer in a stepless manner, so as to maintain the air temperature in the air frying chamber between an upper limit and a lower limit of the preset target temperature.

A method for operating a connected oven based on subjective user feedback, wherein the connected oven includes a set of in-cavity sensors configured to monitor the foodstuff throughout a cooking session; the method comprising: executing a cooking session according to an initial set of operation instructions to achieve a target food output condition; collecting subjective feedback values from the user for the resulting food output condition of the foodstuff after the cooking session; and updating the initial set of operation instructions based on the feedback values from the user.