Disclosed are an anti-icing material with stealth function, a preparation method and use thereof. The anti-icing material with stealth function according to the disclosure includes an electrically insulating and thermally insulating layer, a patterned heating layer, an electrically insulating and thermally conducting layer, and a hydrophobic layer, that are disposed sequentially through stacking, wherein the patterned heating layer has a patterned hollowed-out structure.

A method for applying a heating system on a surface includes providing an imprint form including a basic form and an arm, tampon printing a plurality of heating elements on the surface with the imprint form such that each heating element has the basic form of the imprint form and is produced with a guide arm by the arm of the respective imprint form, where two adjacent heating elements are connected by the guide arm, and the heating elements are made from a conductive substrate including conductive particles, and connecting the heating elements to at least one heating conductor or heating segment.

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.

The present invention discloses an atomizer. The atomizer includes a concentrate reservoir volume that is in fluid communication with a concentrate vaporization assembly. The concentrate vaporization assembly includes a frit adapted to absorb concentrate from the concentrate reservoir volume. The concentrate vaporization assembly further includes a heating element adapted to heat the frit and absorbed concentrate. The atomizer further includes a vapor collection and discharge assembly including a vapor accumulation chamber in fluid communication with the frit and a vapor evacuation channel in fluid communication with the vapor accumulation chamber and in fluid communication with an egress port. The heating element is activated by a user control of a switch on a battery, which causes the concentrate contained within the frit filter to vaporize, and the user inhales resulting vapor by inhaling at the egress port of the vapor evacuation channel.

Laminated glass includes: an outer glass plate having a first side and a second side; an inner glass plate that is arranged opposing the outer glass plate and has substantially the same shape as a shape of the outer glass plate; and an intermediate layer arranged between the outer and the inner glass, wherein the intermediate layer has a heat-generating layer including: a first bus bar that extends along an end portion closer to the first side; a second bus bar that extends along an end portion closer to the second side; and a plurality of heating lines arranged so as to connect the first bus bar and the second bus bar to each other, and when a predetermined voltage is applied between the first and second bus bars, an amount of heat generated per unit length of each of the heating lines is 2.0 W/m or less.

Methods relating to and an apparatus including: a smart device and an integrated heating module are provided. The apparatus includes: a smart device having an electrically switchable material, a first transparent layer and a second transparent layer, wherein the electrically switchable material is retained between a first transparent layer and a second transparent layer; and an integrated heating module configured between the electrically switchable material and one of: the first transparent layer and the second transparent layer, wherein the integrated heating module is configured to provide resistant heating along at least a portion of the electrically switchable material.

A heater includes a base, a resistive heating body, and a terminal portion. The base is formed of ceramic and has a plate shape. The resistive heating body is located in the base. The terminal portion is electrically connected to the resistive heating body. The base includes a protruding portion surrounding the terminal portion, on a lower surface side. The protruding portion is formed of a ceramic member, and the terminal portion passes through a through hole formed in the ceramic member. The ceramic member is bonded to at least one of the lower surface of the base or the terminal portion.

A cooking appliance, such as a toaster or oven, has a lifting arm including ribs that form a support surface for a food product in a cooking cavity of the appliance. Each rib can include an opening configured to permit infrared radiation from a heating assembly to pass through the rib to the food product supported by the lifting arm and/or to reduce a thermal mass and capacitance of the lifting arm. The heating assembly can include a support and/or heating element with a curved shape having a concave side facing a cooking cavity. The support and/or heating element can have a planar shape when unstressed and a curved shape when stressed. The heating element may be coupled to the support so as to be slidably movable relative to the support, e.g., so the heating element can slide relative to the support.

A hose assembly defines a longitudinal axis and includes an inner core tube, a thermal distribution element, and a heating element. The thermal distribution element surrounds the inner core tube, the thermal distribution element including a metalized coated film. The heating element surrounds the inner core tube, the heating element being in thermal contact with the metalized coated film.

A board, including a first pad area, a second pad area, a first micro heater, a second micro heater, a first heater terminal pad, a second heater terminal pad, and a third heater terminal pad, is provided. The first pad area and the second pad area respectively include at least one pad. The first micro heater and the second micro heater are respectively disposed corresponding to the first pad area and the second pad area. The first heater terminal pad and the second heater terminal pad form a loop with the first micro heater by being electrically connected to an outside, so that the first micro heater generates heat. The second heater terminal pad and the third heater terminal pad form another loop with the second micro heater by being electrically connected to the outside, so that the second micro heater generates heat. A circuit board and a fixture are also provided.