A locking mechanism includes a lock housing and an activation shaft. The lock housing defines first and second axes, each being different than the other. The lock housing includes an inner mechanism housing wall, a hollow conduit defined by the inner mechanism housing wall, and a channel. The channel is defined by a portion of the inner mechanism housing wall and has first and second portions, where the first portion extends along the first axis and the second portion extends along the second axis. The activation shaft is at least partially surrounded by the hollow conduit and includes a shoulder protruding from the activation shaft towards the channel of the inner mechanism housing wall. In an unlock position, the shoulder is freely manipulatable within the first portion of the channel along the first axis, and in a lock position the shoulder is prevented from moving along the first axis.

A pivoting hose support system for use with an agricultural implement is provided that includes a guide through which a hose(s) extends and that is arranged to pivot at an articulation point defined at connections between components that are movable through relatively large ranges of motion with respect to each other. The guide and the movable component may pivot about a common rotational axis and may be arranged upon different portions of a common pivot pin to which the guide may be axially fixed.

An agricultural work vehicle is operable to be advanced along the ground to sever a swath of standing forage plants and to lay the severed forage material into a windrow. The agricultural work vehicle includes a powered chassis, a harvesting header, and a quick-attachment header adapter. The header adapter is shiftably supported by the powered chassis and is configured to selectively support the harvesting header. The header adapter includes an adapter frame, having end supports and a center support, and a selectively actuatable latch assembly supported on the adapter frame. The latch assembly is associated with at least one of the supports to releasably secure the harvesting header to the adapter frame when the latch assembly is engaged and permit disconnection from the adapter frame when the latch assembly is disengaged.

During coordinated operation of multiple different modular traction power units (MPUs), a desired change in relative tractive effort contributed by each of the MPUs is identified. Relative distances between a connection point for each MPU and an implement hitch point is determined, in order to identify a hitch bar target position that will achieve the identified relative tractive effort contribution. The hitch bar is adjusted to make distance adjustments, based on the target position, to achieve the identified relative tractive effort for the MPUs.

A multi-coupling component (20) includes a plurality of fluid couplers (22, 24, 26, 28) that are fluidly connected to a plurality of corresponding fluid flow pathways (80, 84), and a case drain fluid coupler (32) that is fluidly connected to a low pressure drain fluid pathway (88); and a pressure relief mechanism (40) that is configured to be moved between a disconnected state, a partially connected state, and a fully connected state. The pressure relief mechanism is configured such that in the partially connected state the fluid flow pathways and drain fluid pathway are fluidly connected to perform a pressure relief function, and in the disconnected state and the connected state the drain fluid pathway is isolated from the fluid flow pathways. The pressure relief mechanism includes a pressure relief button, wherein the pressure relief button is depressed to move the pressure relief mechanism from the disconnected state to the partially connected state and to the connected state. The pressure relief mechanism may be operated manually by hand for the subsequent connection of individual fluid couplers, or automatically when a second multi-coupling component is attached to the multi-coupling component that has the pressure relief mechanism.

Embodiments relate to apparatuses, methods and computer programs for controlling a machine. The apparatus is suitable for a mobile communication device for providing a sensor input signal to a machine control entity to control a machine. The apparatus comprises one or more sensor modules for providing first user input sensor data and second user input sensor data. The apparatus further comprises a control module configured to determine the sensor input signal based on the first user input sensor data and the second user input sensor data. The control module is further configured to provide the sensor input signal for sensor data processing to the machine control entity to control the machine via an interface.

A planter system includes a planter having an unloading valve and a controller. The unloading valve is fluidly coupled between an inlet and an outlet of a pump. The unloading valve is configured to receive a fluid at a supply pressure, to supply a first portion of the fluid from the inlet to a hydraulic planter system at an unloading pressure less than the supply pressure, and to recirculate a remainder of the fluid to the pump via the outlet. The controller is communicatively coupled to the unloading valve and to the pump. The controller is configured to control the pressure of the fluid supplied to the inlet and to control the unloading pressure of the first portion supplied to the hydraulic planter system.

A planter system includes a planter having an unloading valve and a controller. The unloading valve is fluidly coupled between an inlet and an outlet of a pump. The unloading valve is configured to receive a fluid at a supply pressure, to supply a first portion of the fluid from the inlet to a hydraulic planter system at an unloading pressure less than the supply pressure, and to recirculate a remainder of the fluid to the pump via the outlet. The controller is communicatively coupled to the unloading valve and to the pump. The controller is configured to control the pressure of the fluid supplied to the inlet and to control the unloading pressure of the first portion supplied to the hydraulic planter system.

A device for implement localization on an agricultural tractor includes a first tractor-side transponder and a second tractor-side transponder. The first tractor-side transponder includes a first transmission and reception region corresponding with a first mechanical implement interface located on the agricultural tractor, and the second tractor-side transponder includes a second transmission and reception region corresponding with a second mechanical implement interface located on the agricultural tractor. An implement-side transponder is in communication with the first and second tractor-side transponders. Each of the first and second tractor-side transponders transmits a separate position identifier to the implement-side transponder via one of the first or second transmission and reception region, and the position identifier is transmitted back to the respective first or second tractor-side transponder.

An agricultural implement includes a frame and an adjustment system on the frame. The adjustment system includes a first component and a second component connected by a trunnion connection. The trunnion connection includes first and second opposed confronting trunnion blocks, each defining a hole therethrough, the holes being aligned one with the other. A trunnion shaft is disposed in the holes of the trunnion blocks and has ends extending beyond outer surfaces of the trunnion blocks. At least one end of the trunnion shaft defines an opening therethrough. End stops are provided at each end of the trunnion shaft, at least one of the end stops having a portion insertable into the opening. The end stops are larger than the aligned holes to prevent withdrawal of the trunnion shaft from the trunnion blocks.