A vehicle wash system includes a manifold having pump compartments separated by dividers. The manifold is constructed of an electrically conductive material to shield electromagnetic fields. A pump is disposed within each compartment and configured to generate the electromagnetic fields when activated. A power connector is coupled to the manifold. The power connector is configured to power each pump and is a common ground for the manifold. An upper level sensor is proximate to the manifold. A lower level sensor is proximate to the manifold. The upper level sensor and the lower level sensor are configured to sense fluid level in a washer bottle.

Of moving directions of a piston, the direction in which high-pressure air is delivered is a delivery direction, and the direction in the opposite direction from the delivery direction is a force accumulation direction. The piston is moved in the force accumulation direction by the moving mechanism, and moved in the delivery direction by the biasing force of the biasing spring in response to the release of the moving force exerted by the moving mechanism. The cylinder is provided with: a piston supporting portion that supports the piston; and a connection protrusion that has a delivery path for delivering the high-pressure air to the nozzle. The inner surface of an end of the piston supporting portion in the delivery direction is formed as a closed surface. The delivery path is located further toward the force accumulation direction than the closed surface is.

An apparatus for preventing a build up of snow or dust. The apparatus includes a plurality of air nozzles positioned around a periphery of a target area to be kept clear of snow or dust. Each of the nozzles directs a stream of air away from the target area. A deflector is positioned around a periphery of the target area. The deflector deflects the stream of air from each nozzle across the target area, wherein an air curtain is formed preventing snow or dust from landing on the target area.

An apparatus for preventing a build up of snow or dust. The apparatus includes a plurality of air nozzles positioned around a periphery of a target area to be kept clear of snow or dust. Each of the nozzles directs a stream of air away from the target area. A deflector is positioned around a periphery of the target area. The deflector deflects the stream of air from each nozzle across the target area, wherein an air curtain is formed preventing snow or dust from landing on the target area.

In this vehicular imaging device, a positive electrode terminal for a heater and a negative electrode terminal for the heater, which are different from a heater film of a cover glass, are integrally formed with a bracket body of a bracket by insert molding. When the cover glass is disposed in the bracket body, a positive electrode side press-contact part of the positive electrode terminal for the heater and a negative electrode side press-contact part of the negative electrode terminal for the heater are brought into press contact with the heater film of the cover glass. Thus, the positive electrode terminal for the heater, the negative electrode terminal for the heater, and the heater film are electrically connected together.

A sensor protection apparatus includes a first sensor cover movable between a sensor covering position and a first cover waiting position; a second sensor cover movable between the sensor covering position and a second cover waiting position, wherein each of the first and second sensor covers is located at the sensor covering position for protecting the surface of the sensor from being contaminated by foreign matter; and an actuator configured to move the first and second sensor covers such that the first sensor cover and the second sensor cover are alternately located at the sensor covering positions thereof.

Provided herein is a headlamp assembly comprising a housing that encloses: a sensor that acquires data associated with a surrounding environment; a light source that illuminates a field of view comprising a portion of the surrounding environment; and one or more processors that analyze the acquired data and determine a direction, field of view, power, or an intensity of the illumination of the portion based on the analyzed data.

A heating device for off-vehicle information acquisition means, which has high heating efficiency, which is thin, and which has a high degree of freedom for layout of a heating element is provided. A heating device (100), which is arranged inside a vehicle, heats a window glass portion (Wa) located in an information acquisition path (5) of an off-vehicle information acquisition means (50) for acquiring information outside the vehicle. The heating device (100) comprises a hood (10) provided inside the vehicle below the information acquisition path (5) of the off-vehicle information acquisition means (50) and a heating element (20) provided on the surface of the hood (10) or inside the hood (10) and having a PTC heater layer (21).

The telescopic washing device comprises first and second telescopic members operable along a first linear path between retracted extended positions parallel to telescopic member longitudinal axis Z; a wiper element coupled to the second telescopic member such that the wiper element is movable according to a second path lying on a plane XY perpendicular to the longitudinal axis Z; a second guiding area associated with first telescopic member or wiper element and according to second path; and a guiding element associated with the other of the first telescopic member or the wiper element to slide to the second guiding area as the first and second telescopic members move to each other. As pressurized fluid is supplied to the first telescopic member, the wiper element is at least rotated according to the second path.

The invention relates to a device for wiping and cleaning a glazed surface (S) of an automotive vehicle, comprising at least: —one direct current electric motor (7) rotating in a single direction and capable of moving at least one “wiper arm” unit (BB) formed by a drive arm (1) and a wiper blade (2) by means of a linkage (14), said “wiper arm” unit being moved according to an angular reciprocating movement between a rest position (11) and an end position (12) opposite the rest position (11) in relation to an angular sector (13) on the glazed surface (S), —a device (15) for dispensing an active liquid on the glazed surface (S), the active liquid preferably being a de-icing liquid or an insect-removing liquid, —a control means (10) configured to control, on the one hand, the operation of the motor (7) in order to stop the “wiper arm” unit (BB) for a non-zero duration and, on the other hand, the dispensing of the active liquid by the dispensing device (15). The invention also relates to a wiping and cleaning method implementing such a device.