A heat blanket system including a blanket including a first sub-area and a second sub-area. The heat blanket system also includes heating elements printed on the blanket. First spacings between first ones of the heating elements in the first sub-area varies relative to second spacings between second ones of the heating elements in the second sub-area. The first spacings and the second spacings vary according to a design. The design is configured for use on a uniquely defined rework area on a uniquely defined composite material object including a third area including a heat sink region and a fourth area including a non-heat sink region. The first sub-area is sized and dimensioned to be placed over the third area. The second sub-area is sized and dimensioned to be placed over the fourth area.

The invention concerns a conductive pattern sheet for use in a glazing, comprising a substrate, a conductive pattern arranged on the substrate, wherein the conductive pattern comprises first and second busbars arranged at opposing edges of the conductive pattern for connecting a power supply thereto, a plurality of conductive lines each conductive line arranged between the first and second busbars, wherein at least a portion of the plurality of conductive lines is configured to have a transition region wherein a change from a first resistance per unit length (R1) at a first end of the transition region to a second resistance per unit length (R2) at a second end of the transition region occurs over a predetermined length (L) of the transition region wherein a rate of change of resistance per unit length (R1-R2)/L is from 1 to 16,000 ohms per centimetre squared and the substrate is a polymer sheet.

A method for fabricating a multilayered metal nanowire array including providing a metal seed layer, stacking a plurality of porous templates on the seed layer so that a gap forms between each adjacent pair of templates, depositing by electroplating a metal in the pores so that the metal produces nanowires in the templates and lateral interposers in the gaps between the templates, and dissolving the templates so as to produce the multilayered nanowire array including the lateral interposers. The layers between the interposers can have the same or different thicknesses, the diameter and density of the pores in each layer can be the same or different and the metal deposited in the pores of the layers can be the same or different.

The application relates to food preparation apparatus with an electrical heating device comprising at least two electrical PTC thermistors for heating a food in a food preparation space, wherein the electrical PTC thermistors are electrically connected in parallel. The parallel-connected PTC thermistors are electrically connected to each other by one or more electrical bridges.

Using designs in accordance with the present application, local heating during the preparation of a food may be avoided.

Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

A heater of the present invention includes jointed heat generating resistors having a positive temperature characteristic of resistance and provided between a first conductive element and a second conductive element on a substrate in a longitudinal direction of the substrate, and a plurality of heating blocks provided in the longitudinal direction, each of which is a set of the first conductive element, the second conductive element, and the heat generating resistor, and power supplied to at least one of the plurality of heating blocks can be controlled independent of other heating blocks.

A vaporizer includes: an ultrasonic vaporization assembly having: a liquid inlet surface and a first support surface surrounding an edge of the liquid inlet surface, the first support surface and the liquid inlet surface being located on a same side of the ultrasonic vaporization assembly such that liquid enters the ultrasonic vaporization assembly from the liquid inlet surface to be vaporized to form liquid vapor; and a heating assembly attached to the first support for preheating liquid reaching near the liquid inlet surface.

An electrostatic chuck includes a ceramic dielectric substrate; a base plate; and a heater unit which heats the ceramic dielectric substrate. The heater unit includes a first heater element. The first heater element has a plurality of sub-zones. The sub-zones include a first sub-zone. The first sub-zone includes a sub-heater line generating heat by allowing a current to flow, a first sub-power feeding portion feeding a power to the sub-heater line, and a second sub-power feeding portion feeding a power to the sub-heater line. The first sub-zone has a central region located centrally in the first sub-zone and an outer peripheral region located outside the central region when viewed along a Z-direction perpendicular to the first major surface. At least one of the first sub-power feeding portion and the second sub-power feeding portion is provided in the central region.

Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

A multilayered metal nanowire array including a plurality of stacked and separated nanowire array layers each including a plurality of vertically aligned metal nanowires, and a lateral interposer positioned in a gap between each pair of adjacent nanowire array layers and being thermally coupled to the nanowires in the adjacent layers so that the lateral interposers provide thermal conduction between the nanowire array layers and laterally across each nanowire array layer. The nanowire array layers between the interposers can have the same or different thicknesses, the diameter and density of the nanowires can be the same or different, and the nanowire metal can be the same or different.