The present specification discloses wheel mounts for personal vehicles, such as skateboards and scooters. Wheel mount embodiments disclosed herein provide for the interchangeable mounting of wheels having differently shaped wheel cores. The present invention allows users to forego the previous limitation of having a specific wheel mount that only provides for the mounting a specific wheel having one specific wheel core geometry. Embodiments can be utilized on motorized personal vehicles, such as motorized skateboards and scooters that utilize various motors, such as direct drive or belt drive motors.

Embodiments of the present disclosure include a wireless remote control or remote control application for controlling the lighting of an electronic personal transportation vehicle. Embodiments can solve problems related to sharing electronic personal transportation vehicles by uniquely identifying a user, and allowing that user to control the lighting of the electronic personal transportation vehicle. In this manner, other users can control the lighting at different times, depending on the specific person that is using the electronic personal transportation vehicle at any given time.

A system for lighting a volleyball court has four corner light assemblies, two side center light assemblies, and four mid-court light assemblies. Each corner light assembly has an upper light fixture adapted to emit light outward and downward at a level generally below a player's eye level and a lower light element mounted in a manner to emit light outwards and upwards. Each side center light assembly has two lower light fixtures adapted to emit light outward and downward at a level generally below a player's eye level and an upper light assembly adapted to emit light outwards and upwards at a level generally above a player's eye level. Each mid-court light assembly has a light fixture adapted to emit light outward and downward at a level generally below a player's eye level. By ensuring that no light is emitted at a player's eye level, glare is significantly reduced.

Snow vehicle is disclosed. The snow vehicle includes a pair of runners configured to support the snow vehicle travelling over snow and/or ice, an electric motor, and a traction wheel, powered by the electric motor, and configured to cause a propulsion for the snow vehicle while rolling in contact with the snow and/or the ice. The traction wheel is positioned in front of the pair of runners.

A device (1) for covering a surface is provided. The device includes: (a) a cover (10) of which each longitudinal edge is provided with a bead (12); (b) a rotatably mounted drum (2) capable of winding or unwinding the cover, movable on rails placed on either side of said surface; and (c) a system for continuously locking/unlocking the bead in the rails during the translation of the drum.

Disclosed is a bionic electric power-driven shoe, comprising a shoe sole (1), wherein a plurality of rotating wheels (2) are arranged below the shoe sole (1); an electric motor (3) is further provided at a lower part of the shoe sole (1); an output end of the electric motor (3) is connected to a transmission device in driving connection with the rotating wheels (2); and the shoe sole (1) comprises a heel part (11) and a sole part (12), the heel part (11) and the sole part (12) being in rotational connection.

Disclosed is an anti-reverse rotation device of a power-driven shoe device, the power-driven shoe device comprising a shoe sole (1), wherein a group of front wheels (2) and a group of rear wheels (3) are arranged on a lower side surface of the shoe sole (1); and the front wheels (2) are connected to an anti-reverse rotation mechanism for preventing the front wheels (2) from rotating in reverse. The anti-reverse rotation mechanism can prevent the front wheels (2) from rotating in reverse, and as such, when the front wheels (2) are independently in contact with the ground and a certain included angle is formed between a shoe body and the ground, the situation of the front wheels (2) applying a certain pressure to the ground and the front wheels (2) rotating in reverse, such that a lifted foot moves backwards, thereby causing a person to fall down, is avoided, and walking safety is improved.

An electrical balance car comprises pedals. Each pedal has a convex part located on the edge, and a concave part located in the middle and used to restore the pedal after the pedal descends under the effect of acting force. The electrical balance car can be controlled steadily and is ingenious in structure, easy to assemble and durable.

An electric balance car comprises a left car body, a right car body, a rotation mechanism and wheels, wherein the left car body is connected to the right car body through the rotation mechanism, the wheels are mounted on the left car body and the right car body, the axes of axles of the wheels are lower than the axis of a rotary shaft in the rotation mechanism. The electric balance car can be controlled steadily and is ingenious in structure, easy to assemble and durable.

A line striper having a spray control system includes a spray gun, a lever, first and second cables, a manual actuator, and an assisted control. The lever is configured to move between a spray position and an inactive position. The first cable is mechanically linked to the lever. The manual control is mechanically linked to the first cable and configured to pull the first cable rearward to move the lever into the spray position. The second cable is mechanically linked to the lever. The assisted control is configured to pull the second cable rearward to move the lever into the spray position. The lever is independently moveable relative to the first and second cables such that movement of the lever caused by the first cable does not compress the second cable and movement of the lever caused by the second cable does not compress the first cable.