A control assembly provides autonomous control of various functions of a grain cart and/or provides guidance to an operator of the grain cart during the unloading of a grain cart. The control assembly collects input from one or more sensors including a speed sensor to monitor speed of a PTO that drives the unloading auger of the grain cart, a height sensor that measures the height of material discharged from the grain cart into a receptacle such as a grain truck, and/or a boundary sensors that measure lateral position of the grain cart relative to the receptacle or grain truck. Based on the input, the control assembly may vary the position of the discharge gate of the grain cart, or provide guidance to the operator to steer and position the grain cart relative to an adjacent grain truck.

A telescoping rotatable tool includes a first shaft and a second shaft. The first shaft has a first material-engaging element extending from an exterior surface of the first shaft. The second shaft has a second material-engaging element extending from an exterior surface of the second shaft. The second shaft is configured to extend from and retract within an interior space presented by the first shaft. The first shaft includes at least one helical-shaped groove extending along an interior surface of the first shaft. The second shaft includes at least one guide element extending from the exterior surface of the second shaft. The guide element is configured to engage with the groove, such that as the second shaft extends from and retracts within the first shaft, the second shaft is configured to rotate with respect to the first shaft.

A telescoping rotatable tool includes a first shaft and a second shaft. The first shaft has a first material-engaging element extending from an exterior surface of the first shaft. The second shaft has a second material-engaging element extending from an exterior surface of the second shaft. The second shaft is configured to extend from and retract within an interior space presented by the first shaft. The first shaft includes at least one helical-shaped groove extending along an interior surface of the first shaft. The second shaft includes at least one guide element extending from the exterior surface of the second shaft. The guide element is configured to engage with the groove, such that as the second shaft extends from and retracts within the first shaft, the second shaft is configured to rotate with respect to the first shaft.

A system is provided for carrying, receiving and unloading loads and goods for motor vehicles and to a vehicle in which the system is installed. The system allows a maximally variable and simultaneously ideal cuboidal loading area by combining a foldable loading area on the lower face of the vehicle with a rail system, which is positioned on the vehicle lower base in order to receive a wide variety of transport goods and carrier systems and a level-regulating function. Thus, a reduction of the environmental impact of the motor vehicle equipped with the system according to the invention can be combined with a versatile use, whether as a car-sharing concept or private or logistical applications, and excellent loading ergonomics. Additionally, the rail system, the folding mechanism and the transported goods to be conveyed are weatherproofed.

A system is provided for carrying, receiving and unloading loads and goods for motor vehicles and to a vehicle in which the system is installed. The system allows a maximally variable and simultaneously ideal cuboidal loading area by combining a foldable loading area on the lower face of the vehicle with a rail system, which is positioned on the vehicle lower base in order to receive a wide variety of transport goods and carrier systems and a level-regulating function. Thus, a reduction of the environmental impact of the motor vehicle equipped with the system according to the invention can be combined with a versatile use, whether as a car-sharing concept or private or logistical applications, and excellent loading ergonomics. Additionally, the rail system, the folding mechanism and the transported goods to be conveyed are weatherproofed.

A dual auger grain cart includes a horizontal auger assembly, a vertical auger assembly, and a drive assembly operatively connected to the horizontal and vertical auger assemblies. The horizontal and vertical auger assemblies each include an auger shaft and flighting disposed on the auger shaft. The drive assembly includes a first member operatively connected to the horizontal auger shaft, a second member operatively connected to the vertical auger shaft, and a power input device operatively connected to the first and second drive members to drive rotation of the horizontal and vertical auger shafts. The arrangement of the first and second members allow the longitudinal axes of the horizontal and vertical auger shafts to be coplanar and the vertical auger flighting to extend at least in part below the longitudinal axis of the horizontal auger shaft.

A dual auger grain cart includes a horizontal auger assembly, a vertical auger assembly, and a drive assembly operatively connected to the horizontal and vertical auger assemblies. The horizontal and vertical auger assemblies each include an auger shaft and flighting disposed on the auger shaft. The drive assembly includes a first member operatively connected to the horizontal auger shaft, a second member operatively connected to the vertical auger shaft, and a power input device operatively connected to the first and second drive members to drive rotation of the horizontal and vertical auger shafts. The arrangement of the first and second members allow the longitudinal axes of the horizontal and vertical auger shafts to be coplanar and the vertical auger flighting to extend at least in part below the longitudinal axis of the horizontal auger shaft.

A method for controlling network congestion, including overlaying an overlay network packet header on an encapsulation outer layer of a transmit packet, where the overlay network packet header includes an outer Internet Protocol (IP) header, and an explicit congestion notification (ECN) identifier of an ECN is set in the outer IP header, decapsulating the overlay network packet header for an encapsulated reply packet, where an inner congestion identifier that is based on the ECN identifier is obtained from an IP header of the decapsulated reply packet through matching, and if the decapsulated reply packet is a User Datagram Protocol (UDP) packet, forwarding the UDP packet to a preset slow channel.

A farm implement includes a frame, a container mounted on the frame, an intake housing rotatably connected to a front wall of the container proximate to a discharge opening, a first auger assembly, and a second auger assembly. The first auger assembly is disposed in the container and conveys agricultural material through the discharge opening. The second auger assembly is rotatably connected to an outlet of the intake housing and includes an inlet that receives agricultural material from the intake housing and an outlet that discharges agricultural material. The farm implement further includes a first mounting assembly and a second mounting assembly disposed along the front wall. The second auger assembly is mounted on one of the first and second mounting assemblies at an operating position, without being mounted to the other one of the first and second mounting assemblies.

A farm implement includes a frame, a container mounted on the frame, an intake housing rotatably connected to a front wall of the container proximate to a discharge opening, a first auger assembly, and a second auger assembly. The first auger assembly is disposed in the container and conveys agricultural material through the discharge opening. The second auger assembly is rotatably connected to an outlet of the intake housing and includes an inlet that receives agricultural material from the intake housing and an outlet that discharges agricultural material. The farm implement further includes a first mounting assembly and a second mounting assembly disposed along the front wall. The second auger assembly is mounted on one of the first and second mounting assemblies at an operating position, without being mounted to the other one of the first and second mounting assemblies.