A heating apparatus includes a heating element which converts electrical power to heat energy, a heatable element having a first surface and a second surface, and a dielectric laminate layer between the heating element and the first surface of the heatable element, wherein the dielectric laminate layer is thermally conductive to transfer heat energy from the heating element to the heatable element, and wherein the second surface of the heatable element is configured heat a liquid in a container.

A heater component has a substrate part and a thin coating heater which is equipped outside this substrate part and generates heat by power supply. The thin coating heater is formed of a thermal sprayed coating. The thin coating heater has a heater body and a heater extension part. The heater body is arranged on a first end face of the substrate part. The heater extension part is extended from the heater body to a second end face of the substrate part through a side surface of the substrate part. A tip part of the heater extension part is a heater power supplying part for supplying electric power to the heater body.

The invention relates to a method for the application of heating mats (10) on a wing/blade of a wind power station or other devices for the purpose of achieving deicing also during operation when necessary. Temperature measurement and de-icing take place by means of pulsed current to the heating mat (10). The invention also relates to an arrangement.

The invention relates to a method for the application of heating mats (10) on a wing/blade of a wind power station or other devices for the purpose of achieving deicing also during operation when necessary. Temperature measurement and de-icing take place by means of pulsed current to the heating mat (10). The invention also relates to an arrangement.

Provided is a heater substrate that includes an insulating substrate having a first surface and a second surface that is on an opposite side from the first surface, a heater wire located inside the insulating substrate, and an adjustment part that is electrically connected to the heater wire. The adjustment part includes a pair of adjustment terminals that are located on the second surface and are respectively electrically connected to two ends of a partial section of the heater wire, and an adjustment conductor that is located on the second surface and is connected to the pair of adjustment terminals. Also provided are a probe card substrate and a probe card that include the heater substrate.

Provided is a heater substrate that includes an insulating substrate having a first surface and a second surface that is on an opposite side from the first surface, a heater wire located inside the insulating substrate, and an adjustment part that is electrically connected to the heater wire. The adjustment part includes a pair of adjustment terminals that are located on the second surface and are respectively electrically connected to two ends of a partial section of the heater wire, and an adjustment conductor that is located on the second surface and is connected to the pair of adjustment terminals. Also provided are a probe card substrate and a probe card that include the heater substrate.

A heater substrate has an insulating substrate having a first surface and a second surface on the opposite side relative to the first surface and at least one heating element of spiral shape including plural heater wire pieces and positioned in or on the insulating substrate. The heating element of spiral shape has at least one adjustment section including a turn of all or some of the plural heater wire pieces. The plural heater wire pieces include a first heater wire piece and a second heater wire piece adjacent to the inner side of the first heater wire piece. In the adjustment section, the length of the first heater wire piece is smaller than the length of the second heater wire piece.

A ceramic heater includes a ceramic plate having a wafer mounting surface and having a resistive heating element embedded in the plate; and a ceramic tubular shaft having a tubular shape and bonded to a back surface of the plate. The plate has a circular recess with a bottom in the back surface thereof. The tubular shaft has a plate-side flange extending radially outward from an outer peripheral surface of a plate-side end portion. An entire end surface of the plate-side end portion of the tubular shaft is bonded to a bonding region of the back surface of the plate outside the circular recess. The opening diameter d1 of the plate-side end portion of the tubular shaft, the inner diameter d2 of the plate-side flange of the tubular shaft, and the diameter D1 of the circular recess of the plate satisfy d2≥d1≥D1.

A heating-wire device. The heating-wire device includes at least one heating wire, a heating region, which comprises the at least one heating wire embedded therein and can be heated by the heating wire; a current source, which is connected to the heating wire and is configured to apply a current to the heating wire and heat it; a controller, using which the current source can be controlled; a first adhesion-promoting layer, which is arranged on a surface of the heating wire and surrounds the surface thereof, wherein the heating region surrounds the first adhesion-promoting layer.

A heater for a stovetop heater unit is disclosed. The heater may reduce false detections of an overheat condition, minimize an impact of radiative heat from a heating element of the heater on temperature measurements of the heater, and accurately measure a temperature of an object placed on the heater. Thus, the heater may reduce an amount of time required to heat an object placed on the heater.