A heater structure includes a heating unit, a power supply holder, a second conducting element, a locking component, a docking component, a printed circuit board and an identification circuit. The heating unit includes a heating container, a first conducting element and a locking component. The power supply holder has a housing. The housing is connected with an extending wall. The housing is cooperated with the extending wall to define an inner space for accommodating the heating unit. A peripheral wall of the housing is recessed downward and sideward to form a locking groove. The second conducting element is mounted in the inner space. The second conducting element is connected with the first conducting element. The locking component is locked in the locking groove. The docking component is disposed in the inner space. The printed circuit board is mounted to a bottom of the power supply holder.

Improved steam ovens and methods for operating steam ovens include selectively operating a gas heating element below a water reservoir at the bottom of a cooking cavity with water present therein, a convection heating element in the cooking cavity, and a convection fan adjacent the cooking cavity in order to achieve and maintain a predetermined cooking temperature within the cooking cavity. Alternatively, where there is no heating element below a water reservoir in the cooking cavity, a convection system can be operated in order to direct heated air such that it impinges directly on water in the water reservoir, thereby converting the water to steam

The present invention relates to a connecting element (10) for connecting an induction coil (24) to a coil carrier (26) of an induction cooking hob. The connecting element (10) is made of an elastic material and formed as a single-piece part. The connecting element (10) includes a first snap-fit portion (12) connectable to a cut-out of the induction coil (24), so that the snap-fit portion (12) and the cut-out form a snap-in mechanism. The connecting element (10) includes a spring portion (14) arrangeable between the induction coil (24) and the coil carrier (26), so that the spring portion (14) provides a distance between the induction coil (24) and the coil carrier (26). The connecting element (10) includes at least one groove (16) enclosing at least partially the connecting element (10). The groove (16) is engageable with the cut-out of the induction coil (24). The connecting element (10) includes a second snap-fit portion (18) extending opposite to the first snap-fit portion (12). The second snap-fit portion (18) is connectable to a cut-out (32) of the coil carrier (26), so that the second snap-fit portion (18) and the cut-out (32) form a snap-in mechanism.

A cooking grill utilizes at least one resistive heating element below a cooking grate and radiating heat to the cooking grate when a voltage is applied thereto. A first power source provides an alternating current, and a second power source provides a direct current. First and second power sources provide voltage to the at least one resistive heating element individually or simultaneously.

An electric cooking appliance includes a glass-ceramic substrate having a top surface for supporting cookware for heating thereon, and a bottom surface opposite the top surface. The electric cooking appliance includes a plurality of thermoresistive heating elements disposed and spaced apart on the bottom surface of the glass-ceramic substrate, with each of the plurality of thermoresistive heating elements including graphene nanoparticles embedded in a ceramic matrix for generating heat upon application of electric current to the respective thermoresistive heating element. Each thermoresistive heating element is electrically connected to a power supply such that one or more of the plurality of thermoresistive heating elements are selectively activated to receive electric current to heat localized areas of the glass-ceramic substrate.

A heating apparatus includes a body, a chamber, and a thermal plate. The chamber is defined by the body. The chamber includes an upper region and a lower region. The thermal plate provides heat to the chamber. The thermal plate includes a coating. The coating includes a thermo-resistive layer. The thermo-resistive layer includes a polymeric portion and a nanostructure portion. The thermal plate is positioned in at least one location chosen from the upper region and the lower region of the chamber.

The invention relates to a combination of an electrical heating element and a heat dissipater to be heated thereby; the heating element comprises a substrate, an insulating layer located on the substrate and a thick film conductor located on the insulating layer, wherein the second side of the metallic substrate is in contact with the heat dissipater, comprising a layer of metallic material on its face towards the heater and wherein the substrate is brazed to the heat dissipater and the surface of the heating element over which the thick film conductor extends, is substantially equal to the surface of the heat dissipater. The brazing leads to a permanent contact between the heating element and the heat dissipater, so that the possible tendency for warping as caused by the heating and cooling cycles will be withstood.

A cooktop appliance or heating coil assembly may include a heating element, a shroud cover, a thermostat, and a spring bracket. The shroud cover may be disposed within the heating element. The shroud cover may include a top wall defining an upper surface and a lower surface. The thermostat may extend vertically between a distal end and an interior end below the distal end. The distal end may be disposed against the shroud cover at the lower surface. The thermostat may be connected in series between the first and second coil sections of the spiral wound sheathed heating element. The spring bracket may be disposed against the shroud cover at the lower surface and bias the shroud cover upward.

An electric heater includes a substrate; and a plane heating element disposed on one surface of the substrate. The plane heating element includes a pattern portion including a start point and an end point, which are located at an outermost side of the pattern portion, the pattern portion including a plurality of tracks having an arc shape, which are spaced apart from each other and are formed to have a length increasing from an innermost side to the outermost side of the pattern portion, and a plurality of bridges connecting the plurality of tracks in series. The plurality of bridges are formed on both sides of the pattern portion with respect to a reference line passing through a center of the pattern portion, and an innermost gap between the pair of bridges located at the innermost side of the pattern portion is narrower than an outermost gap between a pair of bridges located at the outermost side of the pattern portion.

An electric heater includes a substrate; and a first plane heating element disposed on one surface of the substrate, in which the first plane heating element includes a first track; a second track spaced apart from the first track; and a third track spaced apart from the second track. At least a portion of the second track is located between the first track and the third track, and the first track and the second track are connected by a first bridge, where the first bridge includes a first outer protrusion protruding toward the third track. The third track is formed with a curved portion which protrudes in an outward direction, and the first outer protrusion faces an inside of the curved portion in the outward direction and is spaced apart from the curved portion.