The invention relates to a coated multilayer metal cooking vessel compatible with induction heating, comprising a metal body having a heating face bearing a protective coating and a cooking face bearing a non-stick coating forming a cooking surface.

According to the invention, the metal body comprises an aluminum sheet which is metallurgically bonded to a double-faced aluminized low-carbon ferromagnetic steel sheet forming the heating face, the double-faced aluminized low-carbon ferromagnetic steel sheet comprising a low-carbon ferromagnetic steel substrate having on each of its two faces an outer layer comprising an aluminum-based matrix, an intermediate layer comprising iron/aluminum intermetallic compounds which are arranged between the low-carbon ferromagnetic steel substrate and the outer layer, and, at least on the bottom of the heating face, the outer layer has a thickness of less than 27 gm, preferably less than 20 μm, and more preferably less than 18 μm.

The invention also relates to a cookware article, an electrical cooking appliance and a method for obtaining a coated metal cooking vessel.

The invention relates to a coated metal cooking rack compatible with induction healing, comprising a metal body including a heating face bearing a protective coating and a cooking face bearing an anti-adhesive coating forming a cooking surface.

According to the invention, the metal body is made of two-sided aluminized ferromagnetic low-carbon steel sheet comprising a ferromagnetic low-carbon steel substrate having on each of its two faces an outer layer comprising an aluminum-based matrix, an intermediate layer comprising iron/aluminum intermetallic compounds being arranged between the ferromagnetic low-carbon steel substrate and the outer layer, and at least on the bottom of the heating face the outer layer has a thickness of less than 27 μm, preferably less than 20 μm, and even more preferably less than 18 μm.

The invention also relates to a culinary article, an electric cooking appliance and a method of obtaining a coated metal cooking rack.

Cookware has both as copper and a stainless steel mesh embedded in the exterior facing surface of the bottom of the base. The embedding process work hardens the bottom of an aluminum cooper vessel. A ferromagnetic stainless steel is embedded into the cooper mesh, forming portion of the exterior bottom surface of the cookware to render the cookware compatible with induction cooking heat sources.

A heating article includes a substrate having two opposite surfaces, at least one of which is opaque, and a heat-stable coating arranged on the opaque surface. The heat-stable coating includes an at least two-color decoration having continuous tones and being provided in the form of a continuous or discontinuous layer.

An apparatus and method for controlling the movement of liquids into and out of a container is described. The cleanable, portable, fully automated apparatus includes a main container for holding the food product, a liquid inlet container having a liquid inlet and inlet valve for controllably providing liquid into the main container and a liquid outlet container receiving liquid drained from the main container. A heater automatically heats the main container and a motor rotates or otherwise moves the main container from a receiving position for receiving fresh liquid from the inlet container to a drainage position for draining waste liquid via gravity from the main container into the outlet container. This rotation/movement of the main container can be used repeatedly to add fresh liquid and remove waste liquid during multiple fully automated cycles (e.g., sprouting, rinsing, soaking, cooking, etc.) that do not require user interaction.

A sealed oxygen-tight cooking device for food comprising a first layer (6) with means for preventing inflation by warm moist air during cooking, a second layer impervious to grease and liquid from the food, a fat-absorbing support layer (1) between the first layer and the second layer, wherein the fat-absorbing support layer (1) has openings (3) there through, said fat-absorbing support layer is adapted to support a food thereon, and the food (5) placed on the fat-absorbing support layer (1), wherein the first layer, the second layer and the fat-absorbing support layer are made from materials suitable for use in an oven.

A cooking device having an arch to expand partially sliced food, such as food sliced by accordion or Hasselback techniques, during the cooking process. The device must comprise at least one arch with a convex section having a food expansion support. In a preferred consumer embodiment, the device is a pan insert with the required arch and food expanding support surface. A fanning plate for a baked potato also provides an arched top surface to fan out the slices of a Hasselback potato during the seasoning and baking process, allowing the potato slices to crisp properly. The fanning plate includes raised rims and endcaps to keep the seasoning contained and prevent a mess. Multiple plates may be used at once and when not in use may be stacked atop one another for storage.

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 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.

A machine for processing liquid or semi-liquid food products, comprising: a container for processing liquid or semi-liquid food products and provided with walls and an outlet; a stirrer, made at least partly from ferromagnetic material and disposed inside the processing container, the stirrer rotating about a mixing axis to mix the product to be dispensed; an actuator connected to the stirrer to set the stirrer in rotation about the mixing axis, the machine being characterized in that it comprises an induction element comprising one or more wound conductors for generating a magnetic field when an electric current flows through them, the induction element being disposed outside the processing container so that the magnetic field generated passes through at least part of the walls of the processing container to reach the stirrer and causes heating by magnetic induction.