An implement connection system for connecting an implement to a vehicle. The implement connection system includes a pin having a distal portion defining a distal end of the pin and a proximal portion defining a proximal end of the pin. The distal portion is adapted to be received by an implement connector. The implement connection system also includes a fastener extending into the pin for removably fastening the pin to a portion of the vehicle. The proximal end is disposed between the distal end and the portion of the vehicle when the pin is fastened to the portion of the vehicle.

An arm control system for a work vehicle includes a controller having a memory and a processor. The controller is configured to receive a signal indicative of a type of implement coupled to an arm of the work vehicle. The controller is also configured to enable movement of the arm between a lowered position and a raised position while the type of implement is an unrestricted-height implement. In addition, the controller is configured to enable movement of the arm between the lowered position and an intermediate position and to block upward movement of the arm beyond the intermediate position while the type of implement is a restricted-height implement.

A method for mounting a surface-formation equipment to a mobile unit includes an equipment-engaging support and has a traction point in contact with the ground. The method includes configuring the equipment-engaging support of the mobile unit at a minimum height; configuring the surface-formation equipment with respect to the mobile unit in a configuration wherein a lower surface of the surface-formation equipment is in a same plane as the traction point on the ground of the mobile unit. The surface-formation equipment mounts to the equipment-engaging support of the mobile unit with the equipment-engaging support being maintained at the minimum height and with the lower surface of the surface-formation equipment being in the same plane as the traction point on the ground of the mobile unit.

An implement mounting assembly for mounting a work implement to a vehicle is mountable and operable using a retractable cable operatively connected to the vehicle. The implement mounting assembly includes a frame having a work implement support end and a vehicle attachment end, the frame defining a cable routing space, an attachment point to which the cable extending through the cable routing space is attachable, the attachment point being connected at the work implement support end of the frame, and an auto-release cable management assembly disposed longitudinally between the attachment point and the vehicle attachment ends of the frame. The auto-release cable management assembly includes a hook and a gate positioned with respect to the hook to be movable between an open position in which the hook is accessible to the cable and a closed position in which the hook is inaccessible to the cable.

A connection system for coupling a working assembly to a work vehicle includes a frame having a mounting portion at a first longitudinal end of the frame. The mounting portion is configured to directly couple to a frame of the work vehicle. The connection assembly also includes a mounting assembly at a second longitudinal end of the frame of the connection system. Additionally, the connection system includes a receiver assembly movably coupled to the frame of the connection system. The receiver assembly is configured to rotate about a point of rotation positioned along the frame of the connection system. The receiver assembly is configured to couple to a connector assembly on an arm of the work vehicle. A top part of the receiver assembly is substantially longitudinally aligned with the point of rotation while the receiver assembly is in a receiving position.

A work vehicle comprising a frame supported by a ground engaging device. A boom assembly is coupled to the frame. An attachment coupler is coupled to the boom assembly. An electronic data processor is communicatively coupled to a boom actuator, an attachment coupler actuator, a boom sensor, an attachment coupler sensor, and an operator input device. A computer readable storage medium comprising machine readable instructions that, when executed by the processor, cause the processor to receive an operator input and for a tilt forward command, command the boom actuator to move the boom assembly to a frame contact position and then command the attachment coupler actuator to move the attachment coupler towards a lower position. For a tilt rearward command, command the attachment coupler actuator to move the attachment coupler towards an upper position and then command the boom actuator to move the boom assembly towards a raised position.

A ditch cutting and excavation spoil removal apparatus creates ditches and land contours while simultaneously removing excavation spoil from the banks of newly created ditches. The apparatus includes an excavation spoil collection box and an adjustable plow saddle that supports a plowshare. The spoil collection box has a vertically adjustable rectangular frame with an open front and bottom. The pivotally mounted plow saddle may be tilted upward and downward through the bottom of the excavation box frame for adjustment of the plowshare and, correspondingly, the depth of the ditch being cut. Excavation spoil is collected in the spoil collection box as the apparatus is moved along the ground surface and is removed by raising the spoil collection box.

A system for controlling the lateral traverse position of a front three-point hitch mounted side-shifting implement and a rear three-point hitch mounted side-shifting implement on a mobile machinery such as an agricultural tractor with an controllable automated steering device, while simultaneously controlling the position of the tractor relative to the positions of each of the two side-shifting implements. The system uses a controller to control the positions of the side-shifting-implements using information received from a position monitoring system communication with roving receivers mounted on the side-shifting-implements. The controller also controls the position of the mobile machinery using local relationship sensors mounted on the side-shifting-implement's position and on the mobile machinery's position. The relationship sensors allow the controller to use two roving data receivers instead of three roving data receivers to control both the position of the side shifting implements and the position of the mobile machinery.

A reconfigurable box blade includes a box frame that includes a left sidewall, a right sidewall, and a scraping blade that spans laterally between the left sidewall and the right sidewall. The reconfigurable box blade also includes a means for attaching the box frame to a vehicle. The reconfigurable box blade has a first configuration and a second configuration. The first configuration includes the scraping blade being in contact with a ground surface, and, a longest dimension of the box blade oriented substantially perpendicular to a longitudinal axis of the vehicle. The second configuration includes the scraping blade being out of contact with the ground surface and the longest dimension of the box frame being substantially aligned with the longitudinal axis of the vehicle.

A system for controlling the position of a rigidly attached side-shifting-implement mounted on a mobile machinery while simultaneously controlling the position of the mobile machinery allowing the side-shifting-implement and the mobile machinery to follow a predetermined or adjustable path. The system applies to three-point attachments as well as rack and rail attachments. The system uses a controller to control the position of the side-shifting-implement using information received from a position monitoring system communication with a roving receiver mounted on the side-shifting-implement. The controller also controls the position of the mobile machinery using local relationship sensors mounted on the side-shifting-implement and on the mobile machinery. The relationship sensors allow the controller to use one roving data receiver instead of two roving data receivers to control both the position of the side shifting implement and the position of the mobile machinery.