An agricultural application implement for delivering particulate product to a field. The implement includes a frame, a bin to hold product, a pneumatic conveying system fixed to the frame, a metering system operably connected between the supply compartment and the pneumatic conveying system, and a bin lift system. The pneumatic conveying system includes an airflow source to provide an airflow, and a delivery line operably connected to the airflow source and to the bin. The delivery line includes a plurality of outlets. The metering system meters product with the airflow to result in a mixed flow of airflow and product for the delivery line. The bin lift system includes hydraulic cylinders coupling the bin to the frame, and a bin lift controller to control the hydraulic cylinders to raise or lower the bin.

An agricultural machine may include a first plurality of sensors configured to measure characteristics of product stored on the machine for use during the machine's operation. The machine may also include a second plurality of sensors configured to measure characteristics associated with operation of the machine, in particular, in the form of feedback from ground engaging mechanisms of the machine, such as row units and wheel assemblies coupled to a frame of the machine. Based on the measured characteristics of the stored product and the measured characteristics associated with the machine's operation, a controller may adjust actuators coupled between adjacent sections of the frame to transfer weight of the stored product between certain sections of the frame, which in turn optimizes the machine's operational characteristics.

Planting apparatus includes: (i) a housing that defines: a primary guide; and first and second opposed branch guides extending laterally from the primary guide; (ii) a first runner slidably secured to, and movable along the primary guide; (iii) a second runner securable to, and movable along a first branch guide; and (iv) a third runner securable to, and movable along a second branch guide. The first, second and third runners are configured such that: the second runner is receivable from the first branch guide on to the first runner; and the third runner is receivable from the second branch guide on to the first runner. Actuators move: (i) the second runner along the first branch guide and on to the first runner; (ii) the third runner along the second branch guide and on to the first runner; and (iii) the first runner, together with either of the second or third runners received thereon, along the primary guide.

A wheel assembly for an agricultural implement. The agricultural equipment includes a laterally-extending toolbar with one or more agricultural tools extending from the toolbar. The wheel assembly comprises a wheel configured to rotate along a ground surface. The wheel assembly additionally comprises a base bracket configured to be rigidly secured to the toolbar. The wheel assembly further comprises a wheel bracket adjustably engaged with the base bracket. Adjustment of the wheel bracket with respect to the base bracket causes a corresponding lateral shifting of the wheel with respect to the toolbar.

A linkage assembly for a trailing arm assembly includes a first coupling bracket configured for mounting to a planter or first sub-assembly of the trailing arm assembly, and a second coupling bracket configured for mounting with a second subassembly of the trailing arm assembly. The linkage assembly may further include a parallel linkage pivotally coupling the first coupling bracket and the second coupling bracket. The parallel linkage may be disposed on a center longitudinal plane of the linkage. The center longitudinal plane may bisect the first and second coupling bracket and the second coupling bracket. The linkage assembly may further include a biasing assembly coupled with the parallel linkage and manipulateable to selectively apply a down force to the second coupling bracket.

A planting implement including a first hollow support frame member having a first end and a first end plate connected to the first end. The first end plate has a first hole disposed therein. The planting implement also includes a second hollow support frame member configured for coupling to the first hollow support frame member. The second hollow support frame member has a second end and a second end plate connected to the second end. The second end plate has a second hole disposed therein. The planting implement further includes at least one spacer and at least one seal having an aperture. The at least one seal is configured to seal a connection between the first hollow support frame member and the second hollow support frame member such that a pneumatic pathway is established between the first hollow support frame member and the second hollow support frame member.

The present disclosure relates to a precision seeding apparatus with recesses on a caterpillar for arranging and distributing seeds against bottoms of seed furrows. The apparatus includes a frame; the frame is provided with a seed box with a seed distribution opening; a caterpillar for transporting seeds capable of being connected with a drive mechanism is arranged in the seed box; a lower part of the caterpillar for transporting seeds corresponds to the position of the seed distribution opening; the caterpillar is provided with at least one column of recesses in a lengthwise direction of the caterpillar; each group of recesses is connected through a seed unloading ditch; the seed unloading ditch is formed into a ring in a lengthwise direction of the caterpillar for transporting seeds; a lower part of the caterpillar for transporting seeds is provided with a comb sheet.

A system for controlling the operation of a row cleaning device of a seed-planting implement may include a row cleaning device, at least one row sensor, and a controller. The row cleaning device may move field materials away from a travel path of a component of a seed-planting implement, where the component is positioned aft of the row cleaning device along a direction of travel of the seed-planting implement. The at least one row sensor may generate data indicative of a composition of the field materials moved by the row cleaning device. The controller may be configured to receive the data from the at least one row sensor as the seed planting implement moves across the field, and to monitor the composition of the field materials moved by the row cleaning device based at least in part on the data received from the at least one row sensor.

A seeding apparatus includes an implement frame mounted on wheels and a plurality of furrow openers mounted on the implement frame. A primary air seeder cart is pivotally connected about a vertical implement pivot axis to an implement hitch on the implement frame, and an implement pivot limiting system is operative to limit a degree of pivoting of the primary air seeder cart about the implement pivot axis with respect to the implement frame to a selected degree chosen to reduce bending of conduits. A secondary air seeder cart can be pivotally connected to a cart hitch on the primary air seeder cart about a vertical cart pivot axis and an cart pivot limiting system is operative to limit the degree of pivoting of the secondary air seeder cart about the cart pivot axis.

A harvesting system includes a header pivotally attached to a combine. The header includes a center section to which a left wing and right wing are pivotally attached. A suspension system of the harvesting system includes first and second engageable states that enable dynamic wing behavior and reduce structural load. The first state corresponds to a harvesting configuration of the header in which the wings are allowed to pivot to allow the header to follow changes in terrain. The second state corresponds to a configuration in which the header is elevated relative to the ground. In the second state, the ability of the wings to pivot is minimized as compared to the first state, which allows the header to be maintained in a substantially flat configuration while minimizing the amount of dynamic load imparted by the header on the combine during non-harvesting transport of the header.