A sample holder includes: a ceramic body including a one main surface, and a sample holding surface on the one main surface; a heat-generating resistor disposed on an other main surface of the ceramic body; and a plurality of grooves arranged in a lattice on a surface of the heat-generating resistor, the plurality of grooves having extending directions that are different on different portions of the surface of the heat-generating resistor.

There is disclosed a fluid-transfer article which is suitable for use as part of an aerosol-generating system of a type which may be used as a smoking substitute. The fluid-transfer-article comprises a first region for holding an aerosol precursor and for transferring said aerosol precursor to an activation surface of a second region of said article. The activation surface is disposed at an end of said article configured for thermal interaction with a heater of an aerosol-generation apparatus. At least the second region of the fluid-transfer article is formed from a polymeric wicking material.

The ceramic heater includes: a ceramic base body made of ceramic and having an upper surface on which an object to be heated is to be placed; a heating resistor included in the ceramic base body; and a cylindrical shaft made of ceramic and connected to a center part of a lower surface of the ceramic base body. The heating resistor includes six heating resistor element groups each including one or more connected heating resistor elements. Among these, three heating resistor element groups each have both ends each connected to the corresponding end of another one of the heating resistor element groups. Power feed terminals which respectively supply powers to a total of three ends composed of these both ends are connected to the total of three ends.

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 mist removing device, a controlling method thereof a mist removing system and a control element are provided, which relate to the field of mist removing technology. The mist removing device includes power supply module, electrode array and insulating layer. Electrode array and insulating layer are arranged on substrate in stacked manner in direction away from substrate. Orthographic projection of insulating layer onto substrate covers orthographic projection of electrode array onto substrate. Power supply module is connected with electrode array. Power supply module is configured to supply power to electrode array such that electrode array forms electric field to cause droplets in mist to converge under action of electric field, where mist is formed on side of insulating layer away from substrate. Mist on surface of substrate can be effectively removed.

A window glass for a vehicle includes a glass plate for window of the vehicle, a defogger on the glass plate, and an antenna on the glass plate. The defogger includes a pair of bus bars extending in a height direction of the glass plate, a first defogging area formed by a plurality of first heating wires connected between the pair of bus bars and extending in a widthwise direction of the glass plate, and a second defogging area formed by at least a second heating wire connected to the pair of bus bars or to the first defogging area and extending in a protruding manner to one side in the height direction to surround a wiring-prohibited area. The antenna is provided in at least one of areas that are an area on left of the second defogging area and an area on right of the second defogging area.

A laminated glass includes a pair of glass plates facing each other, a pair of intermediate adhesive layers positioned between the pair of glass plates and in contact with the respective glass plates, a wiring positioned between the pair of intermediate adhesive layers, and one set of bus bars connected to the wiring. The wiring includes conductive thin wires arranged in parallel with each other between the bus bars. The bus bars are arranged alongside a same edge of the glass plates. In an area corresponding to at least a part of a principal face of the glass plates, the conductive thin wires are arranged as one aggregation and include at least one turnaround. A resistance value of each of the conductive thin wires is within a range of 10% or less with respect to an average value of resistance values of the conductive thin wires.

A heating device has a support and a heating element arranged on it, the heating element having two electrical terminals and a multiplicity of heating conductors that are electrically connected to one another. Starting from the one terminal, the heating element is divided into a number of heating conductors parallel to one another and in series one behind the other toward the second terminal. In this case, at least three heating conductors are connected in parallel next to one another and at least three heating conductors are connected in series one behind the other. Series-connected heating conductor groups can be formed, heating conductors being parallel within a heating conductor group.

A digital PCR device comprising: a discrete heating area made of a heat conductive material disposed on a surface that is electrically non-conductive, the discrete heating area comprising a plurality of integral wells configured to contain and partition a DNA sample therein; and at least one conductive trace configured to be connected to a dc voltage source and to heat the plurality of integral wells to a uniform temperature when connected to the dc voltage source, the at least one conductive trace disposed on the surface in an undulating configuration at least partially around the discrete heating area.

A lamp cover adapted for mounting to a vehicle lamp having an optical axis includes a light-transmissible cover body, an electrically-conductive film being light-transmissible and being formed on the cover body, and an electrode unit being electrically connected to the electrically-conductive film. The electrically-conductive film is adapted for converting electrical energy provided by the electrode unit into thermal energy to heat the cover body.