A system for controlling a sun blocking structure in a vehicle is disclosed. The system can automatically move/position the sun blocking structure between ambient light from the sun and a person located in the vehicle. Also, the sun blocking structure can be located in the vehicle such that the system automatically drives the sun blocking structure in a manner that avoids contact between the person and the sun blocking structure. The system includes a GPS unit that provides location information of the vehicle as well as current time and date information to a controller. The controller uses this information to determine a location of the ambient light incident on the vehicle, and provides instructions that cause a motor to move the sun blocking structure to a location between the ambient light and the person's eyes, thereby blocking the person's eyes from direct ambient light.

A sliding sun visor for use in a vehicle is disclosed. The sun visor includes a first and second visor body shell. The visor also comprises a pivot rod and a carrier slidingly arranged over the pivot rod. The first shell of the visor body includes a monorail arranged on an inside surface thereof. The carrier is slidingly engaged with the first shell wherein the carrier is arranged within or on the monorail. The carrier contacts a top portion of the monorail and a bottom portion of the monorail. The carrier is hence slidingly secured to the monorail and only connected to one of the shells used to engage to form a visor body. The visor bodies are secured via a press fit between a first boss arranged on a first shell and a second boss arranged on the second shell thus creating a secure connection that does not need screws to secure the visor halves to one another.

An adjustable vehicle visor. The adjustable vehicle visor includes a track securable to a vehicle ceiling, wherein an actuator is slidably disposed within the track. A motor is connected to the actuator and can move the actuator along the track when the motor is actuated. An arm having a longitudinal aperture extending between opposing ends thereof is affixed to the actuator along the longitudinal aperture, such that the arm can rotate about the actuator when the motor is actuated. A visor is pivotally affixed to the arm, the visor having a telescopic panel therein that can selectively move between an extended position and a retracted position. A remote device is in wireless communication with the motor, wherein the remote device can transmit a control signal to actuate the motor.

A sun visor actuation system including an attachment apparatus configured to attach to an automobile structure, an arm member rotatably attached to the attachment apparatus, a body member attached to the arm member, and an actuation system. The actuation system is operable to at least one of rotate the body member and prevent the rotation of the body member responsive to an indication of an imminent collision.

A sliding sun visor for use in a vehicle is disclosed. The sun visor includes a first and second visor body shell. The visor also comprises a pivot rod and a carrier slidingly arranged over the pivot rod. The first shell of the visor body includes a monorail arranged on an inside surface thereof. The carrier is slidingly engaged with the first shell wherein the carrier is arranged within or on the monorail. The carrier contacts a top portion of the monorail and a bottom portion of the monorail. The carrier is hence slidingly secured to the monorail and only connected to one of the shells used to engage to form a visor body. The visor bodies are secured via a press fit between a first boss arranged on a first shell and a second boss arranged on the second shell thus creating a secure connection that does not need screws to secure the visor halves to one another.

An adjustable vehicle visor. The adjustable vehicle visor includes a track securable to a vehicle ceiling, wherein an actuator is slidably disposed within the track. A motor is connected to the actuator and can move the actuator along the track when the motor is actuated. An arm having a longitudinal aperture extending between opposing ends thereof is affixed to the actuator along the longitudinal aperture, such that the arm can rotate about the actuator when the motor is actuated. A visor is pivotally affixed to the arm, the visor having a telescopic panel therein that can selectively move between an extended position and a retracted position. A remote device is in wireless communication with the motor, wherein the remote device can transmit a control signal to actuate the motor.

A device for articulably mounting a sun shield within a motor vehicle includes a mounting member, a sun shield holder and a connecting member. The mounting member releasably secures the device to a visor of the sun motor vehicle. The sun shield holder attaches the device to the sun shield. The connecting member connects the mounting member and the sun shield holder. In one embodiment the connecting member defining at least one ball and socket joint. In another embodiment, the connecting member defines a single pivot axis about which the sun shield may rotate relative to the mounting member in a plane of the planar sun shield.

A sliding sun visor for use in a vehicle is disclosed. The sun visor includes a first and second visor body shell. The visor also comprises a pivot rod and a carrier slidingly arranged over the pivot rod. The first shell of the visor body includes a monorail arranged on an inside surface thereof. The carrier is slidingly engaged with the first shell wherein the carrier is arranged within or on the monorail. The carrier contacts a top portion of the monorail and a bottom portion of the monorail. The carrier is hence slidingly secured to the monorail and only connected to one of the shells used to engage to form a visor body. The visor bodies are secured via a press fit between a first boss arranged on a first shell and a second boss arranged on the second shell thus creating a secure connection that does not need screws to secure the visor halves to one another.

An adjustable sun visor apparatus having: a bar received into an open-pipe arm; an auxiliary visor panel; a ball; a plug; a tension spring; a ball compartment configured to house the ball and the plug and pivot around the ball; a vertical clip configured to receive a portion of the ball and to grip a sun visor; a bend-resistant spring configured to receive the plug and the open-pipe arm; a twin capsule configured to receive the ball and the tension spring; wherein the tension spring biases the bend-resistant spring downwards; such that a movement of the sun visor causes the bar to move within the open-pipe arm and thus prevents a movement of the auxiliary visor panel; such that the sun visor blocks light from the front and the auxiliary visor panel blocks light from the side in a vehicle.

Disclosed herein are accessory devices and systems for vehicles including: a base plate assembly comprising a base plate and an articulating bracket, the base plate configured to be fixedly secured to a portion of a vehicle and the articulating bracket configured to be releasably secured to the vehicle using the base plate at a plurality of locations; and at least one auxiliary visor panel or accessory connected to the base plate assembly. Also disclosed herein are method of using the disclosed devices and systems for interchangeably moving the base plate assembly with connected auxiliary visor panel or accessory between vehicles.