A single arm telescoping mirror apparatus comprising a mirror base and mirror head. In one embodiment, a mirror base having a wear plate secured to a single support arm which frictionally engages a single telescoping tube of the mirror head. Furthermore, a mirror base having a roller assembly which frictionally engage the inner wall of a single telescoping tube of the mirror head. Frictional forces created minimize the telescopic or vibrational movement of the mirror head during use of a vehicle. In another aspect, a wear plate is secured to a single telescoping tube while, roller assemblies are attached to a support arm which frictionally engage ridges of the telescoping tube.

An exterior camera lens cleaning system for a vehicle may include: a base unit fixed to the vehicle; a housing unit configured to be rotatable with respect to the base unit; a camera unit including a camera module, the camera unit at least partially inserted into the housing unit and configured to move in a longitudinal direction of the housing unit; a wiper disposed on an inside surface of the housing unit so as to face the camera module; and a control unit configured to receive video data through the camera module, to control a rotation operation of the housing unit based on a state of the vehicle, and to control an extension operation of the camera unit. The camera unit may be interlocked with the housing unit, and when the housing unit is rotated by the control unit, the camera unit may be configured to move horizontally in the longitudinal direction of the housing unit.

Various techniques related to a sensor for use with autonomous driving and/or navigation of a vehicle. The techniques can include use of an elongated threaded member, an intermediate threaded member, and a tertiary member. The members can be operable to extend or retract a vehicle sensor on a platform. The members can also enable the sensor to retract upon application of a force external to the vehicle.

The present invention relates to a holder for a vehicle, which can stably hold various portable devices, such as a cell phone and IT goods, by being firmly fixed to a grille of an air blowing hole by enabling four fixing bars to mechanically rotate according to the forward and backward movement of a pressurizing member such that one ends of the four fixing bars gather together or are separated from each other. The holder for a vehicle of the present invention comprises: a housing having a through hole formed in the center of a front plate; four fixing bars, each of the four fixing bars having one end which protrudes to the front surface of the housing through the through hole so that the four fixing bars are inserted into a vehicle air blowing hole and are supported on an air blowing hole grille, and the other end which has an arm that is outwardly curved so that one side thereof is rotatably coupled to the inside of the front plate of the housing; a pressurizing member which is coupled to the rear surface of the housing so as to be movable in a forward and backward direction; and a holding part which is separably coupled to the housing in order to fix a portable device. A pressurizing part is formed on the rear side of an outer end of the arm or on the front surface of the pressurizing member such that as the pressurizing member moves forward, the pressurizing part pressurizes the arm and the fixing bars are rotatable.

An adjustable assembly for use in a vehicle, including a table element and an adjustment device for power-operated adjustment of the table element. The table element defines a table surface on which at least one object can be deposited. The table element is adjustable in a power-operated way by means of the adjustment device along a longitudinal axis extending substantially parallel to the table surface between a retracted position and an extended position and is pivotable about a pivot axis extending substantially perpendicularly to the longitudinal axis.

A holding mechanism prevents a device at a back side of a held object from being hidden by the object. Even if a large smartphone is held, clamping with a fixed clamping part and a movable clamping part prevents the fixed part from being moved, wherein a device located back of the smartphone and at the side of the fixed clamping part cannot be hidden by the smartphone. Due to the movable clamping part being movable farther from a rotation axis than the fixed clamping part, a middle portion of the smartphone in the clamping direction substantially coincides with the rotation axis when holding a smartphone with a specified width, wherein the smartphone cannot be easily moved in a Y- and Z-direction when rotating a holding part to change orientation, and also at the back side, a device located at the side of the clamp cannot be easily hidden.

A vehicle camera telemetry system has a remotely mountable camera apparatus which has a stem having a magnet for magnetic affixation to a metallic body of a vehicle in use. The apparatus further comprises a camera device connected from the distal end of the stem by an adjustable coupling. The stem may further be telescopic for length adjustment so as, for example, extend the length of the stem from less than 22 cm to greater than 29 cm. The camera device has an image sensor and a wireless transmitter for transmitting image data obtained therefrom to a connected mobile device using a wireless connection, such as Wi-Fi or Bluetooth. As such, in use, the camera apparatus may be affixed to various parts of a vehicle and/or an associated trailer, caravan or the like.

A handle with a mounting track includes a handle section. One or more legs extend from the handle section and are attachable to a surface. When the leg is attached to the surface, the handle section forms a graspable handle. A mounting track is formed along at least a portion of the handle section. The mounting track includes a base, two vertical rails extending opposite each other from the base, and two horizontal beams each extending from a different one of the vertical rails over the base toward the other horizontal beam. The horizontal beams are laterally spaced apart from each other by a first distance. The vertical rails and the horizontal beams define a track within which a retention element of a mount assembly can move.

A single arm telescoping mirror apparatus comprising a mirror base and mirror head. In one embodiment, a mirror base having a wear plate secured to a single support arm which frictionally engages a single telescoping tube of the mirror head. Furthermore, a mirror base having a roller assembly which frictionally engage the inner wall of a single telescoping tube of the mirror head. Frictional forces created minimize the telescopic or vibrational movement of the mirror head during use of a vehicle. In another aspect, a wear plate is secured to a single telescoping tube while, roller assemblies are attached to a support arm which frictionally engage ridges of the telescoping tube.

An unmanned aerial vehicle (UAV) for landing and perching on a curved ferromagnetic surface is provided. The UAV includes a plurality of articulated legs. Each articulated leg includes: a magnet configured to magnetically attach to the curved ferromagnetic surface; and a magnetic foot for housing the magnet and configured to magnetically articulate towards and attach to the curved ferromagnetic surface using the magnet in a perpendicular orientation with respect to the curved ferromagnetic surface, in response to the UAV approaching the curved ferromagnetic surface, in order to land the UAV on the curved ferromagnetic surface and for the UAV to perch on the curved ferromagnetic surface after the landing. The magnetic foot is configured to remain magnetically attached to the curved ferromagnetic surface while the UAV is perched on the curved ferromagnetic surface.