A control system for an implement associated with a machine, the machine operating on a work surface lying in a surface plane, is disclosed. The system includes a base plate attached to the machine, the base plate establishing a plate plane and the orientation of the plate plane alters with changes in orientation of the base plate. The system may further include an orientation leveling system which includes an orientation sensor, one or more plate actuators for altering orientation of the base plate, and an electronic controller. The electronic controller is configured to determine if the plate plane is substantially parallel with the surface plane and actuate the one or more actuators to alter orientation of the base plate to position the base plate such that the plate plane is substantially parallel with the surface plane, if the plate plane is not substantially parallel with the surface plane.

A mounting arrangement for a seat of a machine is disclosed. The mounting arrangement includes a first plate adapted to couple to a support member of the seat. The mounting arrangement includes a second plate slidably coupled to the first plate. The mounting arrangement includes a first pair of rails disposed between the first plate and the second plate. The first pair of rails includes a first rail disposed at a first predefined distance and a second rail disposed at a second predefined distance with respect to a central axis of the seat. The mounting arrangement further includes a second pair of rails disposed between the first plate and the second plate. The second pair of rails includes a third rail disposed at a third predefined distance with respect to the central axis and a fourth rail disposed at a fourth predefined distance with respect to the central axis.

An apparatus for automated machining, such as grinding, cutting and/or deburring, of workpieces, in particular of cast components, e.g., of wind turbines. For this purpose, the apparatus comprises a motor spindle for machining the workpiece, the motor spindle having a tool interface for receiving a tool for the machining operation. Moreover, the motor spindle is designed, in particular, to change a tool automatically. In addition, the apparatus comprises a robot for holding and guiding the motor spindle, and a control unit for controlling the motor spindle and the robot. The disclosure additionally relates to a method for automated machining of workpieces.

An apparatus for automated machining, such as grinding, cutting and/or deburring, of workpieces, in particular of cast components, e.g., of wind turbines. For this purpose, the apparatus comprises a motor spindle for machining the workpiece, the motor spindle having a tool interface for receiving a tool for the machining operation. Moreover, the motor spindle is designed, in particular, to change a tool automatically. In addition, the apparatus comprises a robot for holding and guiding the motor spindle, and a control unit for controlling the motor spindle and the robot. The disclosure additionally relates to a method for automated machining of workpieces.

A device for the maintenance of an overhead line system of a track has a handling device and a displacement device. The displacement device serves to displace the handling device between a transport position and a working position. In the working position, the handling device reaches the overhead line system and is able to perform maintenance work by way of a tool. At least one sensor serves for controlling and/or monitoring the handling device. The device thus enables a simple, efficient and safe maintenance of the overhead line system.

A device for the maintenance of an overhead line system of a track has a handling device and a displacement device. The displacement device serves to displace the handling device between a transport position and a working position. In the working position, the handling device reaches the overhead line system and is able to perform maintenance work by way of a tool. At least one sensor serves for controlling and/or monitoring the handling device. The device thus enables a simple, efficient and safe maintenance of the overhead line system.

A system and method for operation of an autonomous vehicle (AV) yard truck is provided. A processor facilitates autonomous movement of the AV yard truck, and connection to and disconnection from trailers. A plurality of sensors are interconnected with the processor that sense terrain/objects and assist in automatically connecting/disconnecting trailers. A server, interconnected, wirelessly with the processor, that tracks movement of the truck around and determines locations for trailer connection and disconnection. A door station unlatches/opens rear doors of the trailer when adjacent thereto, securing them in an opened position via clamps, etc. The system computes a height of the trailer, and/or if landing gear of the trailer is on the ground and interoperates with the fifth wheel to change height, and whether docking is safe, allowing a user to take manual control, and optimum charge time(s). Reversing sensors/safety, automated chocking, and intermodal container organization are also provided.

This invention provides a system and method for reliably interconnecting a native gladhand on a trailer with an AV truck, in which the gladhand can vary in placement and type on the trailer front. A visually guided robot manipulator arm accesses the trailer front. The arm includes an end effector assembly that is arranged to visually navigate to the gladhand and engage the gladhand by latching onto a gladhand using a connection tool that includes a hinged gladhand/wedge capture assembly and a pressurized clamping connection plate that selectively engages the trailer gladhand seal. The capture assembly is arranged to accommodate different gladhand geometries in latching thereonto. The connection tool includes a hinge that is spring-loaded in both a locked and unlocked bistable state, and sensors monitor the state. The system can include passive or active compliance elements that accommodate moderate misalignment between the engaged gladhand and the robotic arm/connection tool.

A refuse collection vehicle includes a grabber that is operable to engage a refuse container, a lift arm that is operable to lift a refuse container, at least one sensor that is arranged to collect data indicating an angular position of the grabber, at least one sensor that is arranged to collect data indicating a relative positioning of the lift arm, a first controller for adjusting the angular position of the grabber, and a second controller adjusting the relative positioning of the lift arm. The adjustment of the angular position of the grabber is coordinated with the adjustment of the relative positioning of the lift arm.