A radiant heater is disclosed. The radiant heater includes a heating layer, with a first elongated conductor configured to receive electricity and a second elongated conductor disposed parallel to the first conductor. A continuous sheet of resistive material adapted to produce heat in response to electrical current is disposed between the first and second elongated conductor. The heater also includes a transparent layer and a non-transparent functional layer that is disposed between the heating layer and the transparent layer. In a preferred aspect, the invention is in the form of a heating mirror.

There is provided a near-infrared sensor cover to be applied to a near-infrared sensor including a transmitting unit that transmits near-infrared radiation and a receiving unit that receives near-infrared radiation reflected by an object. The near-infrared sensor cover includes a cover main body portion disposed with a thickness direction thereof to be coincide with a transmission and reception direction of the near-infrared radiation and covering the transmitting unit and the receiving unit, and a heater wire disposed on the cover main body portion to generate heat when energized. The heater wire includes plural straight line portions that extend in parallel to each other and plural connection portions that connect end portions of adjacent straight line portions. An interval between adjacent straight line portions ranges from 3 mm to 10 mm, and a diameter of the heater wire ranges from 0.01 mm to 0.2 mm.

The present invention relates to a production method of a conductive structure-containing film with a substrate film, the production method comprising: a step (1) of forming a resin layer (X) by coating a thermoplastic resin composition (A) containing at least one thermoplastic resin selected from the group consisting of a polyvinyl acetal resin, an ionomer resin, and an ethylene-vinyl acetate copolymer resin on one side of a substrate film; and a step (2) of forming a conductive structure on the resin layer (X).

A bathroom management apparatus may be capable of dehumidifying and defrosting a mirror installed at a door. The bathroom management apparatus may include a cabinet having a front side that is open, a door configured to open/close the open front side of the cabinet, a mirror provided at a front surface of the door, and a heater configured to heat the mirror. The heater may be disposed behind the mirror to heat the mirror.

In an embodiment, the present disclosure is directed to an assembly for preventing condensation on a surface of an object. The assembly may include a condensation mitigation device; a surface temperature sensor configured to sense a temperature; an ambient temperature sensor configured to sense an ambient temperature; and a humidity sensor configured to sense a humidity. The condensation mitigation device may be operably coupled to the surface temperature sensor, the ambient temperature sensor, and the humidity sensor. The condensation mitigation device may be configured to calculate a dewpoint temperature based on the ambient temperature and the humidity; repeat the calculation of the dewpoint temperature for different times; calculate a linear regression for the calculated dewpoint temperatures; and transmit a control signal to begin activating the condensation mitigation device based on the surface temperature, the current dewpoint temperature, and the linear regression for the calculated dewpoint temperatures.

A display device, particularly for an exterior mirror of a motor vehicle, comprising a display means that comprises a lighting means, characterized in that the display device comprises a moisture detection apparatus comprising a sensor device, the moisture detection apparatus being designed to at least partially detect light emitted by the display means and light reflected by moisture.

According to one embodiment, there is provided a sensor for a vehicle, which includes: a vehicle glass; a substrate disposed on the vehicle glass; a transparent sensing electrode disposed on the substrate; and a wire electrode connected to the sensing electrode, wherein the sensing electrode comprises a first sensing electrode and a second sensing electrode spaced apart from the first sensing electrode.

A portable heated mirror includes a mount subassembly that includes a mount housing and a mount member that is configured to releasably attach the heated mirror to a support surface. The heated mirror also includes a mirror subassembly that is pivotally attached to the mount subassembly by a ball-in-socket arrangement. The mirror subassembly includes a mirror housing that contains a mirror and a flexible heating element in the form of a flexible heat film that contains heating elements and is secured to a rear surface of the mirror for heating the mirror when the flexible heat film is actuated. A battery power source is operatively connected to a printed circuit board that is contained within the mirror housing.

A side mirror structure includes: a substrate; a mirror glass that is disposed above the substrate; a heat generation circuit that is provided at a first area on a top surface of the substrate, and transmits heat to the mirror glass; and a light emission circuit that is provided at a second area on the top surface of the substrate, and displays a signal on the mirror glass.

There is provided a near-infrared sensor cover to be applied to a near-infrared sensor including a transmitting unit that transmits near-infrared radiation and a receiving unit that receives near-infrared radiation reflected by an object. The near-infrared sensor cover includes a cover main body portion disposed with a thickness direction thereof to be coincide with a transmission and reception direction of the near-infrared radiation and covering the transmitting unit and the receiving unit, and a heater wire disposed on the cover main body portion to generate heat when energized. The heater wire includes plural straight line portions that extend in parallel to each other and plural connection portions that connect end portions of adjacent straight line portions. An interval between adjacent straight line portions ranges from 3 mm to 10 mm, and a diameter of the heater wire ranges from 0.01 mm to 0.2 mm.