A port interface for a pneumatic distribution system includes a first flow passage configured to receive fluidized particulate material from an outlet port of a header and to output the fluidized particulate material to an outlet line. The port interface also includes a second flow passage configured to receive a purging airflow and to output the purging airflow to the outlet line. In addition, the port interface includes a knife valve having a blade with a first opening and a second opening. The blade is configured to move between a first position in which the first opening is substantially aligned with the first flow passage and the second opening is substantially aligned with the second flow passage, and a second position in which the first opening is substantially aligned with the second flow passage and a solid portion of the blade is substantially aligned with the first flow passage.

A sectional control device controls the flow of particulate material from a meter assembly to a primary manifold of an air seeding system. The sectional control device includes a plate assembly having particulate openings extending between the meter assembly and the primary manifold and a shut-off mechanism configured to control the flow of the particulate material through the particulate openings. The shut-off mechanism includes a gate configured to slide between an open position, where particulate material can flow through the particulate opening, and a closed position, where particulate material is prevented from flowing through the particulate opening. The shut-off mechanism also includes an actuator configured to drive the gate between the open position and the closed position.

An agricultural seeder (10) for research plots includes a front gang (21) of planting units (22) and a rear gang (23) of planting units (24) spaced a distance behind the front gang. Metering systems (14) are provided for metering seed to the planting units (22, 24) of the front and rear gangs (21, 23). A tripping system (27) is used to start and stop the seed metering systems (14) and to change seed between plots while planting. A programmable logic controller (28) is programmed with the distance between the front and rear gangs (21, 23) and is used to delay the tripping of the metering system (26) for the rear gang (23) relative to the metering system (25) for the front gang (21) until the seeder (10) has traveled the distance (L) between the front and rear gangs (21, 23). The delayed tripping for the rear gang (23) keeps the planted rows and alleyways created by the front gang planting units (22) laterally aligned with those created by the rear gang planting units (24).

A port interface for a pneumatic distribution system includes a first flow passage configured to receive fluidized particulate material from an outlet port of a header and to output the fluidized particulate material to an outlet line. The port interface also includes a second flow passage configured to receive a balancing airflow and to output the balancing airflow to an external environment. In addition, the port interface includes a knife valve having a blade with an opening. The blade is configured to move between a first position in which the opening is substantially aligned with the first flow passage and a solid portion of the blade is substantially aligned with the second flow passage, and a second position in which the opening is substantially aligned with the second flow passage and the solid portion of the blade is substantially aligned with the first flow passage.

A distribution tower of an agricultural distribution machine for spreading granular material comprises a riser pipe supplying a flow of distribution goods to a ring-shaped distributor head for dividing the flow into a multitude of flows of distribution goods along the circumference of the distributor head. At least one of the outflows has a shut-off device. The shut-off device has a track switch by means of which the flow of distribution goods can be guided toward a seed tube or toward a return section. A return device connects to and surrounds the riser pipe. Openings in the riser pipe serve to receive the returned distribution goods. The return section, as well as the seed tube connection, are permanently, pneumatically connected. A method is also provided where it is possible to shut off an optional number of outflows without any resulting major change of the lateral distribution.

An agricultural machine includes a product bin configured to store particulate material; a conveyor configured to draw the particulate material from the product bin; a distribution plate including a plurality of apertures; and a sectional control funnel box mounted on the distribution plate. The sectional control funnel box is configured to receive particulate material from the conveyor, and has a plurality of chutes extending therethrough and connecting the sectional control funnel box to the distribution plate. Distribution lines are configured to receive particulate material from a single aperture of the distribution plate and provide the particulate material to a distribution point of the distribution line. A system controller is configured to individually control a flow of the particulate material to each distribution line based on a location of the agricultural machine. Related systems and methods are also disclosed.

Systems, methods and apparatus are provided for entraining seed into a plurality of seed supply lines. Some embodiments enable selective prevention of seeds from entering a subset of seed supply lines. Some embodiments enable improved flow of seed through an entrainer by angled surfaces provided on blocking members disposed to selectively block seed from entering seed supply lines.

An agricultural seeding machine includes a metering system and a damper arrangement. The metering system for the seeding machine includes selectively powered metering sections operable to individually allow or restrict seed dispensation. The damper arrangement is included so that pneumatic conveying of the particulate within the machine is consistently maintained when particulate flow is varied between the metering sections.

A sectional control apparatus and method prompts the operator of an implement when the implement, or portion thereof, is traversing over land that has already been seeded and/or disturbed. The apparatus includes a GPS or GNSS receiver that communicates with a GPS or GNSS system and a controller that maps movement of the implement so that real-time positional data for the implement can be compared to the movement map. When the position of the implement, or portion thereof, is detected as moving over previously seeded and/or disturbed land, the controller activates an alert mechanism in the operator cab of the implement to notify the operator that sectional control, i.e., shutting down metering of product or raising the tool bar, needs to be implemented.

An agricultural seeder has furrow opener assemblies spaced along a width of the implement frame. Each furrow opener assembly has an opener arm pivotally attached to the implement frame, and a furrow opener attached to the opener arm. A product delivery system delivers agricultural products to the furrow opener assemblies, and a product control controls the product delivery system such that agricultural products are delivered only to active furrow opener assemblies. A bias force system is operative, when activated in a transport mode, to exert an upward bias force on the active and idle furrow opener assemblies, and operative, when activated in an operating mode, to exert a downward bias force on the active furrow opener assemblies, and to exert substantially no force on the idle furrow opener assemblies.