The present invention relates to the technical field of cooking utensils, and in particular, to a nonstick utensil and its method of manufacturing. The nonstick utensil comprises a utensil substrate and a nonstick layer covering an inner surface of the utensil substrate; the material of the nonstick layer comprises black titanium dioxide. In these method of the present invention, an inner surface of a substrate of the nonstick utensil is covered with a material comprising black titanium dioxide by means of hot spraying, cold spraying or plasma spraying, so that a black titanium dioxide nonstick layer is formed. Compared to the prior art, instead of using a coating material, the present invention achieves the objective of nonstickness by forming nonstick layer comprising black titanium dioxide on a surface of a substrate, thanks to the low surface energy characteristic of black titanium dioxide.

Provided is an article of cookware and a method of making the same. The cookware has a multi-layer bonded composite wall structure having an inner metal layer and an outer metal layer, and a core layer between the inner layer and the outer layer. The core layer has at least two perforated graphite plates, each plate having a plurality of spaced-apart holes formed therethrough, and at least one intermediate metal element disposed between the at least two perforated graphite plates and extending through the plurality of spaced-apart holes of each of the at least two perforated graphite plates. The at least one intermediate metal element is metallurgically bonded to the inner layer and the outer layer at least through the plurality of spaced-apart holes.

Provided is an article of cookware and a method of making the same. The cookware has a multi-layer bonded composite wall structure having an inner metal layer and an outer metal layer, and a core layer between the inner layer and the outer layer. The core layer has at least two perforated graphite plates, each plate having a plurality of spaced-apart holes formed therethrough, and at least one intermediate metal element disposed between the at least two perforated graphite plates and extending through the plurality of spaced-apart holes of each of the at least two perforated graphite plates. The at least one intermediate metal element is metallurgically bonded to the inner layer and the outer layer at least through the plurality of spaced-apart holes.

According to one example, a system includes a computing device having a processor that is operable to display a first portion of a cooking recipe. The system further includes a heat source system having a heat source operable to provide an amount of energy to be used to cook a food item in accordance with the cooking recipe, and a processor operable to adjust the amount of energy provided by the heat source based on one or more communications with the computing device. The system further includes an auxiliary button system having an interface operable to receive an instruction to move from a first step of the cooking recipe to a second step, and a processor operable to transmit, via a second communication link with the computing device, an indication of the instruction.

The invention relates to a handle for a cooking vessel that includes at least one thermoelectric generator thermally connected to a heat sink. The invention is characterised in that the handle has an inner cavity that extends longitudinally over at least one third of the length of the handle, and the heat sink extends longitudinally inside the cavity through at least two thirds of the length thereof.

Disclosed are a control circuit of a banana slice frying machine and a control method therefor. The control circuit comprises a MCU, a material cutting module and a processing module, wherein the material cutting module and the processing module are both connected with the MCU, the material cutting module comprises a slicer motor and a range sensor, and the processing module comprises an X-axis driving motor, a Y-axis driving motor, a Z-axis motor and a temperature control module. Signals from the range sensor and the temperature control module are received by the MCU, then feedback information is transmitted to a working element, and the MCU drives the slicer motor to perform automatic cutting and control a heating temperature of an oil pan to realize a full automatic working process from cutting to frying, so that a conventional semi-automatic working manner is abandoned, and result in great convenience.

A divided cooking device with a lid including a base having at least one side wall rising vertically from the base. The base and the at least one sidewall create an interior volume. A plurality of dividers is located within the interior volume such that each divider rises vertically from the base. The dividers connect to the at least on sidewall and create a plurality of different cooking sections. The different cooking sections have a combination of different cooking surfaces and cooking materials. The device has a lid that is configured to fit around the top edge of the at least one side wall.

A set of nestable and stackable cookware, for example, a set of pots and pans, is maintained in a stable configuration by stops attached to the outer walls of the cookware. Each stacked and nested item of cookware is supported on the rim of the lower item by two stops attached to its outer wall, on opposite sides of the item, so that the wall and base of the item is not contacting the lower item. Either or both of the stops include a handle extending outwardly from the stop.

A set of nestable and stackable cookware, for example, a set of pots and pans, is maintained in a stable configuration by stops attached to the outer walls of the cookware. Each stacked and nested item of cookware is supported on the rim of the lower item by two stops attached to its outer wall, on opposite sides of the item, so that the wall and base of the item is not contacting the lower item. Either or both of the stops include a handle extending outwardly from the stop.

A cooking device includes a base, a housing, a lid, a control module, a heating module and an exhaust module. The heating module includes bottom heating units disposed at different locations inside a storage compartment of the housing. The exhaust module includes an air-filled element, an air-extraction element, an inlet passage, and an exhaust passage used to exhaust fog or oil flume generated in an inner pot(s). An inner surface of the lid is provided with multiple first sealing units, a second sealing unit and a third sealing unit. The third sealing unit is arranged corresponding to an opening of the storage compartment. The second sealing unit is connected with the third sealing unit to divide a region surrounded by the third sealing unit into sub-regions with different sizes. The first sealing units are arranged corresponding to the bottom heating units and in the sub-regions with different amounts.