The present disclosure relates to an integrated control apparatus for an autonomous driving vehicle, in which operation for accelerating, braking, and steering of a vehicle is implemented through one integrated lever and buttons for starting and shifting of a vehicle are disposed on one case together with the integrated lever. Accordingly, the integrated control apparatus can be easily used for an autonomous driving vehicle.

The present disclosure relates to an integrated control apparatus for an autonomous driving vehicle, in which operation for accelerating, braking, and steering of a vehicle is implemented through one integrated lever and buttons for starting and shifting of a vehicle are disposed on one case together with the integrated lever. Accordingly, the integrated control apparatus can be easily used for an autonomous driving vehicle.

An acceleration and braking mechanism kit autonomously controls a vehicle brake pedal and a vehicle accelerator pedal. The kit includes a support bracket and bell crank supported on the support bracket for connection with an acceleration pedal or a brake pedal of the vehicle. An actuator is connected to the bell crank for moving the bell crank. A first base bracket is configured to mount to a first vehicle. A second base bracket is configured to mount to a second vehicle. The first base bracket and the second base bracket each include a mounting feature. The support bracket includes a mounting base alternately engageable with the mounting feature of the first base bracket and the mounting feature of the second base bracket such that the support bracket may be mounted to the first base bracket in the first vehicle or to the second base bracket in the second vehicle.

An automated guided vehicle system including at least one automated guided vehicle (AGV) for following predetermined magnetic paths on a ground surface to carry cargo to selected points on the paths. The AGV includes a chassis, top plate mounted on the chassis for receipt of cargo, a pair of driving wheels coupled to driving motors, and plural passive omni-wheels. Control and navigation circuitry is provided to operate the motors to drive the driving wheels to cause the AGV to follow a desired one of the paths. The AGV provides illumination indicating its direction of travel and status. It also includes laser scanners for obstacle detection.

A moving body includes a travel drive section, and a transporting section that is disposed above the travel drive section (a drive housing and a power housing). In the moving body, the transporting section has a substantially rectangular shape and is provided with a vertical bumper at any of corner portions in top view, the vertical bumper extending in a height direction.

A wireless remote controlled rotorcraft tug assembly and method of maneuvering a rotorcraft positions a rotorcraft, of the type having skids, through use of a remote controlled low-profile tug vehicle that maneuvers in a tight 360 motion to maneuver the rotorcraft to a desired location, and operates multiple arms to raise, lower, and support the rotorcraft. A forward support arm and at least one lever arm are selectively movable through hydraulic or electrical means to engage the undercarriage of the fuselage for raising, lowering, and supporting the rotorcraft. A lateral arm connects to the skids from free ends to raise and lower the rotorcraft by the skids. A motor advances the tug vehicle by powering a drive wheel. A guide wheel attaches to a steering mechanism and enables 360 turns and precise maneuverability. A radio receiver and transmitter work to remotely control the motor and the arm control subassembly.

Disclosed is an automated guided vehicle system including at least one AGV for following predetermined magnetic paths on a ground surface to carry cargo to selected points on the paths. The AGV includes a chassis, top plate mounted on the chassis for receipt of cargo, a pair of driving wheels coupled to driving motors, and plural passive omni-wheels. Control and navigation circuitry is provided to operate the motors to drive the driving wheels to cause the AGV to follow a desired one of the paths. The AGV provides illumination indicating its direction of travel and status. It also includes laser scanners for obstacle detection.

The present disclosure relates to an integrated control apparatus for an autonomous driving vehicle, in which operation for accelerating, braking, and steering of a vehicle is implemented through one integrated lever and buttons for starting and shifting of a vehicle are disposed on one case together with the integrated lever. Accordingly, the integrated control apparatus can be easily used for an autonomous driving vehicle.

A ball mount for measuring tongue weight of a trailer is disclosed. The ball mount can comprise a ball portion for interfacing with a ball configured to couple with a tongue of a trailer, a hitch portion for interfacing with a hitch receiver associated with a vehicle, and a load measurement device associated with the hitch portion. The hitch portion can be configured to pivot relative to the hitch receiver about a fulcrum in response to a downward force on the ball, with the hitch receiver resisting rotation of the hitch portion about the fulcrum thereby inducing a load on the hitch portion. The load measurement device can be configured to determine a magnitude of the downward force on the ball based on the load on the hitch portion.

A magnetically adhering robot has a body and a first travelling assembly configured to move the body in a first direction. A second travelling assembly is provided which is configured to move the body in a second direction, orthogonal to the first direction. An elevator assembly is provided which moves the second travelling assembly between a raised position and a lowered position. In the lowered position, the second travelling assembly is lower than the first travelling assembly and solely supports the body. In the raised position, the second travelling assembly is above the first travelling assembly, with the first travelling assembly solely supporting the body. At least one magnetic assembly is provided for magnetically adhering the body to the surface.