An agricultural implement system includes a tow bar configured to couple to a hitch assembly. The agricultural implement system also includes a tool bar pivot hinge assembly comprising two pivot points. The agricultural implement system additionally includes a first tool bar member mechanically coupled to a second tool bar member via the tool bar pivot hinge assembly; the first tool bar member extending transversely from the tow bar, wherein the tool bar pivot hinge assembly provides for an axis of rotation of the second tool bar member about the first tool bar member and additionally provides for an extension of the second tool bar member away from the first tool bar member.

An agricultural implement system includes a tow bar configured to couple to a hitch assembly. The agricultural implement system also includes a tool bar pivot hinge assembly comprising two pivot points. The agricultural implement system additionally includes a first tool bar member mechanically coupled to a second tool bar member via the tool bar pivot hinge assembly; the first tool bar member extending transversely from the tow bar, wherein the tool bar pivot hinge assembly provides for an axis of rotation of the second tool bar member about the first tool bar member and additionally provides for an extension of the second tool bar member away from the first tool bar member.

The present disclosure includes an agricultural system having first and second product meters configured to meter product to first and second lines, respectively. First and second motors are coupled to the first and second product meters and configured to drive them at first and second metering rates, respectively. An air source is configured to provide first and second airflows to the first and second lines, respectively. A controller electrically coupled to the first and second motors is configured to receive first and second inputs indicative of first and second numbers of first and second outlets fluidly coupled to the first and second lines, respectively. The controller is configured to instruct the first and second motors to drive the first and second product meters at the first and second metering rates, respectively, based on the first and second inputs, and to instruct the air source to provide the first and second airflows with first and second dynamic pressures or first and second velocities.

A predictive map is obtained by an agricultural material application system. The predictive map maps predictive weed values at different geographic locations in a field. A geographic position sensor detects a geographic locations of an agricultural material application machine at the field. A control system generates a control signal to control the agricultural material application machine based on the geographic locations of the agricultural material application machine and the predictive map.

A product distribution system mounting assembly includes at least one bracket that is rigidly coupled to a frame of an air cart and at least one crossbar that supports at least one component of a product distribution system of the air cart. The at least one crossbar is slidingly coupled to the at least one bracket, thereby enabling the product distribution system of the air cart to move along a vertical axis relative to the at least one bracket and relative to the frame of the air cart as the air cart moves in a direction of travel through a field.

An implement for dispensing agricultural product. The implement comprises a bin for holding agricultural product, with the bin including a plurality of product openings for dispensing agricultural product from the bin. The implement additionally includes a plurality of metering devices secured to a bottom of the bin and configured to receive agricultural product from the bin through the product openings. The implement further includes a plurality of flow tents positioned within the bin. Each flow tent is positioned between a pair of the product openings. The flow tents extend upward from an interior side of the bottom of the bin so as to guide agricultural product towards the product openings.

A seeding device system is presented for use with helicopters and other vehicles. The system includes a bulk seed container, a feed tube that connects the seed container to a metering device that precisely meters out seed, a flow control system that controls operation of the metering device, and a blower connected to a venturi that blows the seed outward from the helicopter. When seed is metered out of the metering device, the seed is sucked into the venturi and blown outward. The seed container is held in the back seat or cargo area of the helicopter and the blower, venturi and metering device are positioned exterior to the helicopter. This arrangement does not adversely affect the operational characteristics or aerodynamic properties of the helicopter. In addition, all components of the system are rigidly connected to the helicopter thereby increasing safety and control of the helicopter.

A system for detecting the operational status of a seed-planting implement. The system includes a row unit including a frame and a residue removal device coupled to the frame. The residue removal device is configured to remove residue from a path of the row unit. The system further includes a sensor configured to capture data indicative of at least one of a position or an acceleration of the residue removal device. The system further includes a controller configured to monitor the data received from the sensor and compare at least one monitored value associated with the at least one of the position or the acceleration of the residue removal device to a predetermined threshold value set for the residue removal device. The controller is further configured to identify the residue removal device as being plugged when the at least one monitored value differs from the predetermined threshold value.

A system for detecting the operational status of a seed-planting implement. The system includes a row unit including a frame and a residue removal device coupled to the frame. The residue removal device is configured to remove residue from a path of the row unit. The system further includes a sensor configured to capture data indicative of at least one of a position or an acceleration of the residue removal device. The system further includes a controller configured to monitor the data received from the sensor and compare at least one monitored value associated with the at least one of the position or the acceleration of the residue removal device to a predetermined threshold value set for the residue removal device. The controller is further configured to identify the residue removal device as being plugged when the at least one monitored value differs from the predetermined threshold value.

A method for adjusting operating parameters of an agricultural implement during a product-dispensing operation may include monitoring a location of the agricultural implement while performing a product-dispensing pass across a field. The method may further include determining that the agricultural implement will encounter an operating parameter boundary prescribing a change in an operating parameter of the agricultural implement. Moreover, the method may include determining a transition boundary along the product-dispensing pass based at least in part on a propagation delay for the prescribed change, where the agricultural implement will cross the transition boundary before the operating parameter boundary. Additionally, the method may include initiating the change in the operating parameter when the agricultural implement reaches the transition boundary such that the prescribed change in the operating parameter is complete when the agricultural implement reaches the operating parameter boundary.