A vehicle has a frame, at least one seat, an engine, a plurality of ground engaging members, a windshield, and a wiper assembly connected to the upper portion of the windshield. The wiper assembly has a wiper motor, a reservoir, a wiper arm pivotally connected to the upper portion of the windshield, a wiper blade connected to the wiper arm, and a sprayer connected to the wiper arm and fluidly connected to the reservoir. The wiper motor selectively pivots the wiper arm and the wiper blade between a stowed position and a pivoted position. The wiper blade has a first side and a second side. The first side is above the second side in the stowed position. The sprayer is configured for spraying a fluid only on the surface of the windshield away from the first side of the wiper blade. A method for wiping a windshield is also disclosed.

A window assembly for a vehicle includes a window panel having an electrically conductive element disposed thereat. An electrical connector is attached at the window panel and is electrically conductively connected to the electrically conductive element. The electrical connector includes a ferromagnetic material. The electrical connector is attached at the window panel via solder, and the electrical connector is held in place via an electromagnet during the soldering process.

An imaging system mounted on a vehicle is proposed. The imaging system includes: an imager configured to capture an image of the outside of a vehicle through a glass of the vehicle; a heater configured to heat at least an imaging region of a windshield included in an imaging range of the imager; an image processer configured to detect a fogging level of an image captured by the imager; and a controller configured to adjust the output of the heater based on a detected fogging level and allow the heater to heat the imaging region of the windshield.

A window glass system includes a window glass to be attached to a moveable body, an anti-fog film to be provided on a cabin-side surface of the window glass, a temperature sensor configured to detect a glass temperature of the vehicle cabin-side surface of the window glass, a temperature-and-humidity sensor configured to detect a temperature and a humidity of a cabin of the moveable body, drying means configured to vaporize water attached to the anti-fog film, and a processing circuitry configured to estimate a time duration Ts, based on the glass temperature detected by the temperature sensor and the temperature and the humidity of the cabin detected by the temperature-and-humidity sensor, the time duration Ts being a duration of time until fogging occurs on the anti-fog film, and activate the drying means based on the time duration Ts.

An anti-fogging film, an anti-fogging component, an adjustment method therefor and a vehicle-mounted device, the anti-fogging film including: a conversion film layer and an excitation film layer, which is located on the conversion film layer; the conversion film layer carries out reversible conversion between a hydrophilic state and a hydrophobic state according to characteristic parameters of the excitation film layer.

An air-guiding element for arrangement in an interior compartment, which is at least partially enclosed by windows, of a motor vehicle is provided. The air-guiding element is designed to generate a turbulent flow downstream of the air-guiding element when an air flow impinges on the air-guiding element. A motor vehicle having said air-guiding element is also described.

An electrical connection structure according to the present disclosure includes a glass plate, a power supply part formed on the glass plate, a connection terminal including a base part facing the glass plate, and a spring member disposed between the power supply part and the base part and configured to electrically connect the power supply part to the base part. The spring member includes a fixing part, a curved part, and contact parts. The curved part includes branch parts branched by a slit. The contact part is disposed at each of end parts of the branch parts. The contact parts are in contact with the base part independently of each other. The curved part is in contact with the power supply part at a part protruding toward the glass plate.

A backdoor includes a resin outer panel having an opening; a resin inner panel; a metal reinforcement arranged between the outer panel and the inner panel; and a rear glass covering the opening. The rear glass includes a defogger, and an antenna conductor capable of receiving radio waves in an AM band. The antenna conductor includes a power feeding part, and an antenna element having a predetermined length and connected to the power feeding part. The antenna element includes a proximity part extending along an outer edge among upper, lower, left, and right outer edges of the defogger, and having a predetermined spacing from the outer edge. The antenna element is positioned to be separated from the reinforcement by a predetermined spacing, or positioned on a side with respect to the outer edge where the reinforcement is not present in plan view of the rear glass.

A composite pane includes a first pane and a second pane joined to one another via at least one thermoplastic intermediate layer and a functional inlay element arranged between the first pane and the second pane. The functional inlay element includes a carrier layer and at least one electrically conductive element.

Glass for a vehicle includes a glass plate; a test-region A demarcated in the glass plate, the test-region A being specified in JIS R3212; a shielding layer provided more outwardly than the test-region A in a plan view; an information transmission/reception region demarcated within an opening portion provided in the shielding layer, and through which a device mounted in the vehicle transmits/receives information; and an infrared reflective layer positioned peripheral to the information transmission/reception region in a plan view, the infrared reflective layer having a portion that overlaps with the shielding layer in a plan view, wherein a solar direct transmittance of the test-region A is 60% or less and a solar direct reflectance of a region in which the infrared reflective layer is provided peripheral to the information transmission/reception region is greater than a solar direct reflectance of the test-region A by at least 5%.