A sushi maker kit having a frame member with first, second, third, fourth side walls and a ledge capturing portion is provided. The first, second, third and fourth side walls define an open region. The ledge capturing portion extends upwardly from the first, second, and third side walls proximate to a first end of the frame member. The sushi maker kit further includes an insert member having a plate portion and a keel portion. The keel portion is coupled to and extends from the plate portion in a first direction. The plate portion has a ledge portion at a first end thereof. The ledge portion is removably received in the ledge capturing portion such that the keel portion extends into the open region of the frame member when the insert member is in a first operational position relative to the frame member.

A sushi maker kit having a frame member with first, second, third, fourth side walls and a ledge capturing portion is provided. The first, second, third and fourth side walls define an open region. The ledge capturing portion extends upwardly from the first, second, and third side walls proximate to a first end of the frame member. The sushi maker kit further includes an insert member having a plate portion and a keel portion. The keel portion is coupled to and extends from the plate portion in a first direction. The plate portion has a ledge portion at a first end thereof. The ledge portion is removably received in the ledge capturing portion such that the keel portion extends into the open region of the frame member when the insert member is in a first operational position relative to the frame member.

The invention relates to method for preparing a foodstuff in a food processing system (100), the system comprising solid state radio frequency cooking means (51) that transmits an electromagnetic wave to a food substrate and a cavity where the food is cooked, the method monitoring the return power losses, which are the difference between the power emitted by the solid state radio frequency cooking means (51) and the reflected power in the cavity, for optimising the delivery of the radio frequency power to the food substrate by controlling and adjusting at least two parameters: the emitted frequency of the solid state radio frequency cooking means (51) and the distance of the cooking means (51) to the food substrate. In the method of the invention, the dielectric properties, the water content and/or the compaction of the food substrate are monitored throughout the preparation method.

The invention relates to method for preparing a foodstuff in a food processing system (100), the system comprising solid state radio frequency cooking means (51) that transmits an electromagnetic wave to a food substrate and a cavity where the food is cooked, the method monitoring the return power losses, which are the difference between the power emitted by the solid state radio frequency cooking means (51) and the reflected power in the cavity, for optimising the delivery of the radio frequency power to the food substrate by controlling and adjusting at least two parameters: the emitted frequency of the solid state radio frequency cooking means (51) and the distance of the cooking means (51) to the food substrate. In the method of the invention, the dielectric properties, the water content and/or the compaction of the food substrate are monitored throughout the preparation method.

A method of producing a multicoated edible snack product comprising providing an edible core, applying a first layer over the outer surface of the edible core. The first layer is cooked to form a hardened first layer over the edible core. A second layer is applied over the hardened first layer, and cooked to form an expanded second layer. The hardened first layer provides a crunchy aspect to the snack product and the expanded second layer provides a soft exterior to the snack product when biting into the snack product.

Disclosed are 3D printing equipment, a system, and a method for food design and production. The 3D printing equipment has a bipolar microwave heating antenna for focusing heating on a material in an extrusion nozzle. The extrusion nozzle is between the anode antenna and the cathode antenna of the bipolar microwave heating antenna. The anode antenna and the cathode antenna limit a microwave electric field between them, thereby implementing focused heating on the material.

A cartridge assembly, a cartridge device, a food forming module, and a cooking apparatus capable of using three-dimensional (3D) printing technology to form and cook food are provided. The cooking apparatus includes a main body, a cooking compartment is provided in the main body, and a cartridge assembly is installed in the cooking compartment to be capable of linear motion and rotational motion. The cartridge assembly includes a cartridge body having cartridge mounts formed therein, cartridge cases are mounted on the cartridge mounts, and cartridges are disposed in the cartridge cases and include food ingredients that are accommodated therein.

A cooking system is provided. The cooking system includes a user equipment and one or more cooking apparatuses. The user equipment may include a user interface configured to receive an input of a food model including at least one of a shape, an ingredient, or a color of a food in accordance with a touch input of a user, a first transceiver configured to transmit information on the food model to the one or more cooking apparatuses, and a first processor configured to transmit information of the food model to the plurality of cooking apparatuses via the first transceiver. Each of the one or more cooking apparatuses may include a second transceiver configured to receive information on the food model from the user equipment, a food shaping device configured to discharge food ingredients, a food heating device, and a second processor.

A user equipment is provided. The user equipment includes a user interface, a transceiver and a processor. The user interface may receive an input of a food model including at least one of a shape, an ingredient, or a color of a food in accordance with a touch input of a user. The transceiver may transmit information of the food model to a cooking apparatus capable of shaping and heating the food. The processor may transmit the information of the food model to the cooking apparatus via the transceiver to allow the cooking apparatus to shape the food according to the food model. Further, the user interface may display an automatic cooking button, a draw button, a cooking method button, and an output button.

The present invention relates to a spring roll making apparatus comprising: a supply unit for supplying rice paper; a moving unit for moving the rice paper supplied by the supply unit; a softening unit for inducing softening of the rice paper moved by the moving unit; an application unit for applying a filling onto the rice paper softened by the softening unit; a folding unit for folding the rice paper on which the filling placed; and a rolling unit for rolling up the rice paper folded by the folding unit, whereby spring rolls can be mass-produced.