A belted food warmer assembly is disclosed that includes a housing containing a heated rotating drum, a belt roller, and a belt. The belt is draped over a portion of the heated rotating drum and is configured to hold a flexible food product against the heated drum as the food product rotates with the heated drum.

A cooking appliance, such as a toaster or oven, has a lifting arm including ribs that form a support surface for a food product in a cooking cavity of the appliance. Each rib can include an opening configured to permit infrared radiation from a heating assembly to pass through the rib to the food product supported by the lifting arm and/or to reduce a thermal mass and capacitance of the lifting arm. The heating assembly can include a support and/or heating element with a curved shape having a concave side facing a cooking cavity. The support and/or heating element can have a planar shape when unstressed and a curved shape when stressed. The heating element may be coupled to the support so as to be slidably movable relative to the support, e.g., so the heating element can slide relative to the support.

A toaster includes a housing, a conveyor configured to support food products, a motor configured to drive the conveyor to move the food products through the housing, a heating element disposed adjacent the conveyor and configured to emit thermal energy toward the food products as the food products are moved through the housing, a temperature sensor configured to sense a temperature within the housing, and a controller operatively coupled to the temperature sensor and configured to control the motor to drive the conveyor at a conveyor speed. The controller is configured to store the sensed temperature within the housing as a function of time and calculate a derivative of the sensed temperature with respect to time. The controller is configured to vary the conveyor speed based on a value of the derivative.

A toaster (103) having a side wall (10) with a reflective surface (16) to reflect radiant heat towards a toasting chamber (13), and an external surface to which there is attached a sensor assembly (12). The sensor assembly (12) provides a source beam to illuminate part of the product and receives a reflected beam that is received by a sensor, with the sensor providing a signal indicative of a property of the reflected beam and therefore a chromatic property of the product.

A toaster heating assembly (55A, 55B) including: a frame (60); a panel (65) at least partly supported by the frame (60); a spacer (80) mounted to the panel (65); and an elongate heating element (93) having a plurality of spaced apart elongate heating element portions (95) supported by the spacer (80), so that the spacer (80) is located between the plurality of heating element portions (95) and the panel (65) to provide a gap (94) between the plurality of heating element portions (95) and the panel (65).

An autonomous apparatus for cooking food includes a support body, an openable lid, an internal container which can be extracted/inserted with respect to said support body and open at the top, at least a heating device, and one or more elements to generate a flow of air toward the inside of said container. The air flow generator element is connected to a return exit with a suction mouth made in correspondence with an internal wall of said support body and cooperating with a plurality of through holes made on at least one portion of the lateral wall of the internal container.

Automated replenishment of consumables is a growing area of interest for customers and businesses alike, in that it has the potential to both improve customer satisfaction and create a steady stream of orders for a consumable service or product. As recognized herein, kitchen appliances, including those for dispensing beverages, present specific challenges to integration with a replenishment service, especially where multiple packages or formats of consumables may be utilized by a single kitchen appliance. Aspects provided herein include methods, systems, and devices for tracking consumption of foodstuffs prepared by a kitchen appliance, including either counting discrete quantities of foodstuffs or estimating non-discrete quantities. A signal requesting replenishment of at least one foodstuff may be transmitted to a replenishment server based on the counting and/or estimating.

Automated replenishment of consumables is a growing area of interest for customers and businesses alike, in that it has the potential to both improve customer satisfaction and create a steady stream of orders for a consumable service or product. As recognized herein, kitchen appliances, including those for dispensing beverages, present specific challenges to integration with a replenishment service, especially where multiple packages or formats of consumables may be utilized by a single kitchen appliance. Aspects provided herein include methods, systems, and devices for tracking consumption of foodstuffs prepared by a kitchen appliance, including either counting discrete quantities of foodstuffs or estimating non-discrete quantities. A signal requesting replenishment of at least one foodstuff may be transmitted to a replenishment server based on the counting and/or estimating.

A toaster includes a rack within a toasting chamber. A lid is movable with the rack to selectively occlude an opening to the toasting chamber. A heating element within the toasting chamber is operable to direct IR energy to the bread product on the rack. An image capture device operates to acquire image data of the bread product on the rack. A controller receives the image data. The controller processor analyzes successive image data received from the image capture device. Based upon the analysis of the image data, the controller operates the heating element to achieve a predetermined toasting level of the bread product and then turn off the heating element.

A toaster includes a rack within a toasting chamber. A lid is movable with the rack to selectively occlude an opening to the toasting chamber. A heating element within the toasting chamber is operable to direct IR energy to the bread product on the rack. An image capture device operates to acquire image data of the bread product on the rack. A controller receives the image data. The controller processor analyzes successive image data received from the image capture device. Based upon the analysis of the image data, the controller operates the heating element to achieve a predetermined toasting level of the bread product and then turn off the heating element.