A multi-sensored smart cooking apparatus includes a setting module for setting at least one of a cooking time and a cooking temperature, a sensing module comprising at least one of a temperature sensor, a weight sensor, and a water level sensor, a controller coupled to the setting module and the sensing module, a cooking module coupled to the sensing module and the controller, where the controller is configured to adjust at least one of the cooking time and the cooking temperature in response to one or more sensed signals from the sensing module. The multi-sensored smart cooking apparatus is configured to turn off, when a sensed temperature of the cooking module is above a temperature threshold, when a sensed weight on the cooking module is below a weight threshold, or when a sensed water level is below a water level threshold.

Examples are disclosed herein that relate to a cooking system having multiple heating elements for heating a cooking surface. One example provides a cooking system, comprising a continuous cooking surface comprising a plurality of individually controllable heating zones, and for each heating zone, a temperature sensor configured to detect a temperature for the heating zone separately from the temperatures of other heating zones, and a heating element disposed beneath the heating zone and configured to provide heat to the heating zone. The cooking system further comprises a controller configured to individually control the heating element of each heating zone.

A burner element for a cooktop includes a heat source for providing heat to a cooking zone positioned above the heat source and an automatic thermostat switch in communication with the cooking zone and the heat source. The automatic thermostat switch senses an actual temperature of the cooking zone, and when the actual temperature reaches a predetermined maximum temperature the automatic thermostat switch moves to an open position defined by the automatic thermostat switch at least partially impeding the heat source. The open position of the automatic thermostat switch is further defined by a decrease in the actual temperature of the cooking zone from approximately the predetermined maximum temperature to a control temperature. When the actual temperature of the cooking zone reaches the control temperature the automatic thermostat switch defines a closed position, wherein the automatic thermostat switch is substantially free of impeding the heat source.

There is provided a placement position determining part that calculates a rising gradient of an output value of the infrared sensor every after passage of a first predetermined time and performs a placement position determining operation of determining that a placement position of a cooking vessel is improper when the rising gradient is smaller than a first threshold value, and the placement position determining part performs the placement position determining operation after a lapse of a second predetermined time from the start of heating, thereby accurately determining that the cooking vessel is improperly placed on a top plate and preventing overheating of the cooking vessel.

A device for heating an object adapted to be heated by magnetic induction and comprising a thermally insulating spacer to be placed between the heat-retaining object and a support. The device also includes a control and induction heating unit, which includes an inductor, a temperature sensor for detecting the temperature of the support, and an inductor control unit connected to the temperature sensor for controlling the inductor, such that the electromagnetic field is induced according to the readings from the sensor. The inductor control unit limits the magnitude of the electromagnetic field when the detected temperature reaches a predetermined threshold lower than a degradation temperature of the support.

An induction device includes an induction unit including a sensor unit which is arranged above the induction unit in a mounted position and includes a plurality of activity sensor elements arranged in a distributed manner and configured to detect a sensor parameter in the form of an activity parameter of the induction unit. A control unit is provided to analyze the sensor parameter.

A cooking appliance may include a holder disposed in an induction heating element provided below a cover plate, and a supporter disposed inside the holder that supports a sensor inserted into the holder to contact the sensor to the cover plate.

Temperature measurement systems (20) include a temperature sensor (22) and an electronic signal interrogator (24). The temperature sensor (22) has a transponder (26) equipped with an antenna (28), and a separate parasitic antenna (32) with a temperature-sensitive transducer (34, 68-74, 78a-84a), while the interrogator (24) has a transmitter (42) and antenna (40). The sensor (22) is designed to be placed in thermal contact with an object to be temperature-measured, with the interrogator (24) placed in proximity to the object. The systems (20) may be used with food servingware domes (88, 114), which can be preheated and placed over a food-bearing plate to maintain the temperature of the food.

A hob device, in particular an induction hob device, includes a variable cooking surface, a user interface and a control unit which in the presence of a heating type divides the cooking surface into a plurality of heating zones in at least one dividing direction, associates heating parameter to each of the heating zones, in a manner dependent on location, for heating at least one cooking pot placed on the heating zone, and forms a cooking zone that is associated with the cooking pot and is heated using the heating parameter. In the event of a request of the heating type for the cooking pot, the control unit is provided to wait for at least one operating action by a user by way of the user interface.

A stove guard arrangement includes sensors for detecting events on a stove and for providing detection data, and a programmable processing component for analysing the detection data and for providing exceptional situation data in response to the detection data indicating an exceptional situation defined in the programming of the processing component. The stove guard arrangement comprises a receiver connected to the processing component and arranged to receive radio-frequency interference and to provide corresponding reception data. The processing component is arranged to recognize regular changes in said reception data and derive, on the basis of the recognized regular changes, a conclusion that the stove is an induction stove.