An intelligent cooktop has at least a first, if not multiple burners in proximity to at least a first sensor, respectively, wherein the first sensor provides an input to a processor which evaluates a burner performance characteristic selected from the group of least one of flame level, temperature rise, time lag, and temperature level using the first sensor compared to an anticipated performance characteristic of the first burner based on the valve position; and then provides a burner performance output to a user identifying a condition of the first burner.

A burner head of a burner for a gas cooktop, a burner, and a gas cooktop are provided. The burner head includes a plurality of supports, where each support includes a support surface for supporting a cooking utensil, the support is further provided with a plurality of gas ports from which gas flows out and forms a flame, and each support has a first working position and a second working position. When the supports are in the first working position, the burner head has a flat upper surface, and the support surfaces of the supports constitute the upper surface, and when the supports are in the second working position, the burner head has a concave surface, and the support surfaces of the supports constitute the concave surface. The shape of the burner head is changeable, so as to adapt to cooking utensils having different bottom outlines.

A cooktop appliance or griddle assembly may include a cooking platter, a spring-loaded platform, and a sensor body. The cooking platter may define a top surface and a bottom surface. The spring-loaded platform may be mounted below the cooking platter. The sensor body may be attached to the spring-loaded platform in biased conductive engagement with bottom surface.

A gas burner of a cooktop appliance includes an annular burner body extending along the circumferential direction with an annular fuel plenum defined within the annular burner body. A plurality of ports are defined in the annular burner body. Each port of the plurality of ports extends from the annular fuel plenum inward towards a center of the gas burner assembly. The gas burner assembly also includes a vortex shield inward of the annular burner body along the radial direction. The vortex shield is positioned and configured to redirect a flow of unignited fuel from the ports away from the center of the gas burner assembly.

Cooking appliances and methods for operating cooking appliances are provided. In one exemplary embodiment, a method for operating a cooking appliance is provided. The method includes providing power to the heating source according to a first control mode; determining whether to transition from the first control mode to a second control mode and, if so, then providing power to the heating source according to the second control mode. The method further includes determining whether to transition to the first control mode and, if so, then returning to providing power to the heating source according to the first control mode. The cooking appliances and methods include features for limiting cooking utensil temperatures using dual control modes.

An outdoor gas cooking system having multiple burners in which, if the individual manual control valves for all of the burners are placed on a high heat setting or some other specified or recognized activation position, a single electronic master control valve can be activated to control the total gas fuel rate to all of the burners in the cooker based, for example, upon a cooking or operational control set point or upon a target flow rate equaling the sum of the design flow rates of all of the burners at the current operating set points of the manual valves.

The present invention provides wireless temperature control turkey fryer which relates to the field of cooking apparatus technologies; the main technical scheme comprises a fryer body, a fryer lid matching the fryer body and an outer ring seat supporting the fryer body. A stove body for heating the bottom of the fryer body is disposed inside the outer ring seat. The stove body is provided with a gas disconnecting piece for cutting off a gas passage. The fryer lid is provided with an electronic thermometer. The electronic thermometer is provided with a temperature insertion pin for being inserted into the fryer body for temperature monitoring. The temperature insertion pin is in communication connection with the gas disconnecting piece such that the gas disconnecting piece is enabled to start and cut off the gas passage when a temperature in the fryer body exceeds a set threshold, achieving convenient temperature control effect.

A knob assembly includes a front panel, a knob located at a front side of the front panel and configured to rotate based on operation by a user, a knob shaft that is coupled to the knob and that extends through the front panel, a supporting pipe that receives the knob shaft and that supports the knob shaft, the supporting pipe being configured to maintain a position relative to the front panel, a valve configured to control supply of gas to the appliance, a valve shaft connected to the valve and configured to control the valve to adjust a flow rate of gas based on rotation of the valve shaft, and a joint that couples the knob shaft to the valve shaft and that is configured to transfer at least one of a rotational motion or a linear motion of the knob shaft to the valve shaft.

A temperature detecting apparatus is provided. The temperature detecting apparatus includes a movable carrier and a thermal sensor. The movable carrier includes a control module, and is movable in a working place according to a designated command. The thermal sensor is assembled to the movable carrier and is electrically coupled to the control module. When the movable carrier is moved according to the designated command, the thermal sensor is configured to detect the working place so as to generate an immediate temperature distribution of the working place. Moreover, when the immediate temperature distribution generated from the thermal sensor has an abnormal temperature value, the control module is configured to emit a warning signal to an external apparatus.

A knob assembly for a gas cooktop may include a knob configured to control a flow of gas from a burner of a cooktop starting at an off position, a knob mechanism arranged between the knob and the cooktop, the knob mechanism including a first part arranged below an underside of the knob, and a second part connected to the first part via a spring mechanism, where the first part is fixed to the knob and configured to rotate with the knob and the spring mechanism is configured to bias against the rotation.