The invention relates to a cooking apparatus for simultaneous cooking of a plurality of food items. The apparatus has a control unit (1) with a conductor (7) arranged to be connected to an electric energy supply and has switching means 10. According to the invention the control unit (1) is provided with a plurality of electrical connection means (2a, 2b, 2c, 2d). Each connection means (2a, 2b, 2c, 2d) is arranged to be connectable to a cooking pot (4a, 4b, 4c, 4d) for supply of electric energy to a respective cooking pot (4a, 4b, 4c, 4d). The control unit (1) is arranged to allow simultaneous supply of electric energy through the plurality of 1 connection means (2a, 2b, 2c, 2d). The invention also relates to a cooking pot (4a, 4b, 4c, 4d) with heating means (3a, 3b, 3c) to supply heat to a food item (5a, 5b, 5c, 5d). The cooking pot (4a, 4b, 4c, 4d) has an electric connection unit (9a, 9b, 9c, 9d). The connection unit (9a, 9b, 9c, 9d) is arranged to be connected to either one of a plurality of 20 connection means (2a, 2b, 2c, 2d) of a control unit (1). The invention also relates to a corresponding method for cooking.

A fryer includes: an oil tank; and a heater, the fryer being configured to heat a frying oil stored in the oil tank by the heater so as to fry a food material put into the oil tank, the oil tank including an upper oil tank in which the heater is arranged and the food material is to be fried, and a lower oil tank provided below the upper oil tank so as to be continuous with the upper oil tank, and configured to sink and collect moisture and fried scraps released from the food material into the upper oil tank, the heater including a side heater partitioning an inside of the upper oil tank into one or a plurality of cooking areas, and surrounding the one or the plurality of cooking areas, and a lower heater provided at a bottom of the one or the plurality of cooking areas.

A cooking system in the form of a fryer is provided to reduce and/or optimize the amount of cooking medium required to operate the fryer, while improving the reliability of movement of food product through the cooking system during a cooking process. To this end, the cooking vat of the system is designed with one or more heating elements positioned to avoid generation of turbulent flow in the cooking medium. Moreover, the movement of food product along the cooking vat and/or out of the cooking vat is done reliably and in such a manner to avoid turbulent flow in the cooking medium. The automatic cooking system provides improved cooking medium life span as well as reduced overall oil volume use.

An air fryer system is disclosed which comprises a base having a heating source and an air source located therein, both sources being supplied power for operation by an AC power cord. A cooking chamber is defined within the base and a cooking drawer fits securely within the cooking chamber to substantially seal the chamber against heat loss during use. A handled food basket which detachably secures to the cooking drawer is configured to facilitate even distribution of heated air within the cooking chamber. A digital, touch screen user interface attached to a surface of the base is electronically coupled to a controller for powering on the fryer system and setting cooking conditions. The preferred system also includes infrared heating, time and temperature controls, and an automatic safety shutoff mechanism.

A capacitive sensor and control system is configured to detect the presence (or absence) of fluid within a container. Configured in a vat or frypot of a deep fryer, the sensor determines when a level of liquid within the frypot is at or above the level of the sensor. The sensor is in communication with the control system and the sensor sends a signal to the control system representative of the presence or absence of liquid within the frypot and at the level of the sensor. The controller receives the signal from the sensor, and allows operation of the one or more heat sources for heating the frypot when the signal received from the sensor is representative of liquid being disposed within the frypot at or above the level of the sensor, and prevents operation of the one or more heat sources when the signal received from the sensor indicates that liquid is not disposed within the frypot at or above the level of the sensor.

The invention provides a cooking device comprising a heating chamber (10), a heating element (12) for heating a cooking medium in the heating chamber, a temperature sensor (14) for monitoring a temperature of the cooking medium over time, and a mass sensor (16) for monitoring a mass of a food item to be cooked in the heating chamber over time. The cooking device also comprises a controller (18) for processing information from the mass sensor and temperature sensor to provide a prediction of the food item core temperature and to control a cooking process in dependence on the predicted food item core temperature.

A cooking apparatus may include a cooking chamber, a heating mechanism, a microwave generator, and a waveguide. The cooking chamber may hold cooking media. The heating mechanism may be disposed at the cooking chamber and may heat the cooking media. The microwave generator may produce microwave energy. The waveguide may be disposed on the cooking chamber and may transmit the microwave energy from the microwave generator to the cooking chamber. The microwave generator may be mounted to the waveguide at one end portion of the waveguide. An opening may be formed in an opposite end portion of the waveguide through which the microwave energy may enter the cooking chamber. The opposite end portion of the waveguide may be opposite to the one end portion of the waveguide.

This identification apparatus is for identifying the degree of degradation of oil and includes a sensor that detects a substance arising from oil contained in an oil tank and a controller that determines the degree of degradation of the oil based on information related to the substance detected by the sensor and the distance from the oil tank containing the oil to the sensor.

Systems and methods for delivering a cooking medium in a cooking apparatus are disclosed. A delivery system includes a rotary valve having a rotary inlet and a plurality of rotary outlets. The rotary inlet is configured to be in fluid communication with a source of cooking medium and the plurality of rotary outlets are configured to be in fluid communication with a corresponding plurality of receptacles. A rotary position sensor generates a signal, having continuous angular position resolution, based on an angular position of the rotary valve. A controller receives the signal generated by the rotary position sensor and selectively places the rotary inlet in fluid communication with one of the plurality of rotary outlets based on the signal generated by the rotary position sensor. The rotary position sensor may include a Hall-effect sensor that functions at elevated operating temperatures associated with the cooking medium.

Disclosed is a device including a sensor configured to measuring an electrical characteristics of oil; a main body having the sensor in a sideward-facing orientation at one end of an elongated shape thereof; and a sensor cover having a base part configured to be attached to the main body; a tip head part having an arcuate shape or an annular shape being greater in size in a radial direction with respect to the sensor, disposed in a manner protruding at a tip side of the main body with respect to the sensor; and a connection part including a first connecting pillar connecting the base part and the tip head part and a second connecting pillar having a width smaller than a width the first connecting pillar.