An air seeder apparatus has a frame and a plurality of furrow opener assemblies spaced across a width of the frame at a narrow row spacing, and a plurality of bulk product containers and a bulk meter mounted on each, one of which dispenses seeds through a distribution network to a seed tube on each furrow opener assembly. A plurality of singulating meter is provided, each dispensing singulated seeds to the furrow opener on one of the furrow opener assemblies. During singulating operation seeds are delivered to the singulating furrow opener assemblies only by the singulating seed meter, and during conventional operation seeds are delivered to the singulating furrow opener assemblies only by the bulk meter. A lift system, when in a singulating mode, maintains idle conventional furrow opener assemblies in the transport position while moving singulating furrow opener assemblies between the operating position and the transport position.

A manifold system for balancing particle delivery from multiple discharge outlets includes a diverter subassembly movably mounted in a manifold for balancing discharge from the outlets. The manifold system is disclosed in an agricultural air seeder application, with the particles comprising tubes and the discharge outlets being connected to ground-engaging tools for depositing seeds in space, subsurface locations in a crop field. Automated and manually-adjustable embodiments are disclosed.

The present disclosure relates to the field of artificial honeycombs, in particular to an artificial nest for solitary bees and an application method of the artificial nest. The artificial nest comprises a main enclosure tube, hanging rings, a plurality of trapping hollow tubes and tightening mechanisms used for clamping the trapping hollow tubes. The hanging rings are arranged at an outer sidewall of the main enclosure tube. The tightening mechanisms are annularly arranged at an inner sidewall of the main enclosure tube, and the trapping hollow tubes are fixed in a ring of each tightening mechanism in an axis direction of the main enclosure tube. Each tightening mechanism comprises a connecting steel wire and fastening springs. The sidewall of the main enclosure tube is provided with fixing holes for fixing the tightening mechanisms.

In a method of operating a seed cart, a compartment is provided defining a volume for receiving a commodity. A distribution manifold is provided including two sets of passages, the distribution manifold being associated with the compartment to selectively receive a commodity in one or both of the two sets of passages. A fan is operated to create an air stream. The air stream from the fan is divided into a plurality of primary tubes. An inlet divider plenum is provided having two outlets in communication with each one of the primary tubes. The flow of air from each of the plurality of primary tubes is divided amongst the two corresponding outlets with a corresponding movable vane within the inlet divider plenum such that an airflow ratio between the two sets of passages is controlled in response to the position of the vane.

A manifold apparatus for an air seeder includes a manifold housing defining a output ports equally spaced around a perimeter thereof. An input port is defined in a bottom side of the manifold housing, and an input conduit extends downward therefrom. A distributor component is formed by a bottom side of a top plate of the manifold housing above the input port and directs product granules moving upward in an air stream in the manifold interior outward toward the perimeter of the manifold housing. A relative lateral position of the distributor component with respect to the input port is adjustable, and interference members extend an adjustable distance into the input conduit and/or manifold interior to contact the particles and change their flow path. The variables are manipulated to achieve positions where a rate of product flow through each output port is within a selected range.

A pneumatic system of an agricultural implement includes a radial fan coupled with a plenum. The plenum contains outlets which distribute the airflow into a plurality of product distribution lines for application to a field. An airflow deflector plate has a back face fixed on a sidewall of a region interconnecting the fan outlet and plenum inlet to modify the airflow pattern and obtain an airflow that is at a uniform pressure and flow rate for each product distribution line. The deflector plate is tapered with a narrow edge pointed upstream and includes front face having at least one generally rectangular groove with a bottom surface extending generally parallel to the deflector back face.

In a method of operating a seed cart, a compartment is provided defining a volume for receiving a commodity. A distribution manifold is provided including two sets of passages, the distribution manifold being associated with the compartment to selectively receive a commodity in one or both of the two sets of passages. A fan is operated to create an air stream. The air stream from the fan is divided into a plurality of primary tubes. An inlet divider plenum is provided having two outlets in communication with each one of the primary tubes. The flow of air from each of the plurality of primary tubes is divided amongst the two corresponding outlets with a corresponding movable vane within the inlet divider plenum such that an airflow ratio between the two sets of passages is controlled in response to the position of the vane.

An air seeder apparatus has a frame and a plurality of furrow opener assemblies spaced across a width of the frame at a narrow row spacing, and a plurality of bulk product containers and a bulk meter mounted on each, one of which dispenses seeds through a distribution network to a seed tube on each furrow opener assembly. A plurality of singulating meter is provided, each dispensing singulated seeds to the furrow opener on one of the furrow opener assemblies. During singulating operation seeds are delivered to the singulating furrow opener assemblies only by the singulating seed meter, and during conventional operation seeds are delivered to the singulating furrow opener assemblies only by the bulk meter. A lift system, when in a singulating mode, maintains idle conventional furrow opener assemblies in the transport position while moving singulating furrow opener assemblies between the operating position and the transport position.

An air seeder distribution apparatus has seed and fertilizer tanks, and a like plurality of metering devices mounted on each product tank. A manifold set comprises a like plurality of product manifolds and each manifold is separately fed from one metering device on each of the seed and fertilizer tanks. A control selectively starts and stops rotation of the feed roller of each metering device to feed product from either tank, or both tanks to the connected manifold. The weight of each tank can be displayed on a weight indicator. Balancing of the pressure in each supply conduit can be provided. A remote opener exerts downward force on the tank lid to maintain interior pressure.

An agricultural product flow sensor and a flow sensor system for delivery tubes in an air seeder is provided. The flow sensor can include a particulate material sensor for sensing agricultural product passing through a delivery tub, a radio node for transmitting and receiving wireless signals and a wireless power source. The sensor system can use the flow sensors by attaching the flow sensors inline with delivery tubes and near a working tool. The flow sensors can monitor the flow of agricultural product through the delivery tube and transmit flow information to a person operating the air seeder.