The transplanter is designed to harness power from a walk-behind tractor to help small farmers transplant (among other things) seedling vegetables. As a farmer guides the walk-behind tractor, a movable feeder tube assembly comprising a plurality of feeder tubes moves latterly back and forth. When a feeder tube aligns with a pivotable transfer tube, a seedling in the feeder tube is deposited in the transfer tube so that the seedling descends down the transfer tube into a furrow for planting. The transfer tube then pivots so that a kicker panel on the bottom of the transfer tube pushes the seedling rearwardly and thereby helps to enable the seedling to remain vertical.

A sectioned metering system and method is provided. One metering system for distributing an agricultural product in a field includes a drive input and a rotary shaft assembly coupled to the drive input and configured to be driven in rotation by the drive input. The metering system also includes a first metering section driven by the rotary shaft assembly and at least two additional metering sections. Each additional metering section is selectively engageable to drive the respective additional metering section by the rotary shaft assembly. Each additional metering section is also selectively disengageable to interrupt driving of the respective additional metering section by the rotary shaft assembly while the first metering section remains driven.

A sectioned metering system and method is provided. One metering system for distributing an agricultural product in a field includes a drive input and a rotary shaft assembly coupled to the drive input and configured to be driven in rotation by the drive input. The metering system also includes a first metering section driven by the rotary shaft assembly and at least two additional metering sections. Each additional metering section is selectively engageable to drive the respective additional metering section by the rotary shaft assembly. Each additional metering section is also selectively disengageable to interrupt driving of the respective additional metering section by the rotary shaft assembly while the first metering section remains driven.

A twin row seed distributor body group is provided that enables twin sowing with a single seed distributor body of pneumatic sowing machines utilized in the agricultural industry. The twin row seed distributor body group contains at least one twin row seed distributor body provided for each sowing unit enabling synchronized sowing on two different sowing rows, at least one right and one left seeding disc, at least one shaft bearing group enabling the movement of seeding discs, at least one seeding disc motion shaft enabling the synchronized movement of the seeding discs, at least one modular main body inner bearing cover that enables fast mounting and maintenance of the disc shaft motion gear and disc motion gears operating inside the seed distributor body and also that forms a bearing for the seeding disc motion shaft, and a hinged seed discharge gate.

The transplanter is designed to harness power from a walk-behind tractor to help small farmers transplant (among other things) seedling vegetables. As a farmer guides the walk-behind tractor, a movable feeder tube assembly comprising a plurality of feeder tubes moves latterly back and forth. When a feeder tube aligns with a pivotable transfer tube, a seedling in the feeder tube is deposited in the transfer tube so that the seedling descends down the transfer tube into a furrow for planting. The transfer tube then pivots so that a kicker panel on the bottom of the transfer tube pushes the seedling rearwardly and thereby helps to enable the seedling to remain vertical.

An air clutch cover for an air clutch assembly of an agricultural planter is provided. The air clutch cover includes a shell which may be removably installed onto the air clutch assembly. The shell has an opening sized to sealingly receive an air cylinder of the air clutch assembly therethrough. Sidewalls of the shell include cut-outs for allowing portions of the air clutch assembly to protrude outwardly from the air clutch cover.

An air clutch cover for an air clutch assembly of an agricultural planter is provided. The air clutch cover includes a shell which may be removably installed onto the air clutch assembly. The shell has an opening sized to sealingly receive an air cylinder of the air clutch assembly therethrough. Sidewalls of the shell include cut-outs for allowing portions of the air clutch assembly to protrude outwardly from the air clutch cover.

An assembly includes first and second shafts and first and second sprockets. The first shaft has a first and second ends and a first longitudinal axis of rotation. The first sprocket is attached to the first shaft proximate the first end of the first shaft. The first sprocket rotates with the first shaft. The second shaft is spaced from the first shaft by a distance, the second shaft having a first end spaced from the first end of the first shaft by the distance, a second end spaced from the second end of the first shaft by the distance, and a second longitudinal axis of rotation substantially parallel to the first longitudinal axis of rotation. The second sprocket is attached to the second shaft proximate the second end of the second shaft. The second sprocket rotates with the second shaft. The distance is adjustable.

An apparatus includes a shaft, a first barrel, and a second barrel. The shaft has a first end, a second end, and a longitudinal axis of rotation. The first barrel surrounds a first portion of the shaft and is fixed to the shaft to rotate therewith. The second barrel surrounds a second portion of the shaft and is configured to rotate about the axis independent of a rotation of the shaft.

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.