Abstract: A bidirectional material source vehicle including a base unit and at least one material gathering device. The base unit is movable in a first travel direction and a generally opposite second travel direction. The at least one material gathering device is carried by the base unit. The at least one material gathering device is positioned at a first end of the base unit when the base unit is traveling in the first travel direction, and is positioned at a second end of the base unit when the base unit is traveling in the second travel direction.

Abstract: A grain cart capable of self-propulsion and receiving steering and propulsion inputs from a lateral extendable connector to a tractor for the grain cart so that the grain cart may be deployed close to the central chassis of a combine for unloading of grain.

Abstract: A material transfer system including a first vehicle, a second vehicle and at least one towed container. The first vehicle has a material discharge device. The second vehicle can move in a forward direction and a reverse direction. The at least one towed container includes a first towed container. The first towed container is coupled to the second vehicle such that the first towed container follows the second vehicle when the second vehicle moves in the forward direction. A control system is coupled to either the second vehicle or the at least one towed container.

Abstract: A method of operating an IC engine in an agricultural harvester includes the steps of: operating the IC engine in a normal mode with a base torque curve as a function of engine operating speed and engine power output, the base torque curve being generally isochronous at a rated operating speed over a power output range terminating at a rated power output; and operating the IC engine in a boost mode with a boost torque curve when a power boost is required above the rated power output, the boost torque curve having a power output which is above the base torque curve over a predefined range of the operating speed.

Abstract: An agricultural harvester (100) has a chassis (106) supported on a plurality of wheels (110) for travel over the ground; a harvesting implement (104) supported on the front of the chassis (106); an internal combustion engine (108) disposed on the chassis (106) behind the harvesting implement (104); a radiator (112) coupled to the internal combustion engine (108) to transfer heat from engine coolant to ambient air; a fan (109) disposed to draw a flow of cooling air through the radiator having a first flow rate; and a conduit (114) configured to conduct substantially the entire first flow rate of air to the radiator (112). The conduit defines a lower air-impermeable enclosure surrounding the inlet of the radiator fixed to an upper enclosure comprising a plurality of screen walls for passing substantially the entire flow of cooling air therethrough.

Abstract: A grain moving system providing for single point unloading of harvesters to a grain cart. There are a plurality of harvesting machines including a first harvesting machine and a second harvesting machine. The first harvesting machine being configured to deliver grain to the grain cart. The first harvesting machine receiving grain from the second harvesting machine. The first harvesting machine being configured for the coordination of grain transfer.

Abstract: A grain moving system providing for single point unloading of harvesters to a grain cart. There are a plurality of harvesting machines including a first harvesting machine and a second harvesting machine. The first harvesting machine being configured to deliver grain to the grain cart. The first harvesting machine receiving grain from the second harvesting machine. The first harvesting machine being configured for the coordination of grain transfer.

Abstract: An agricultural harvester includes a first power unit which is couplable with a first primary load. The first primary load includes a threshing system load. A second power unit has a threshold power output and is couplable with a second primary load. The second primary load includes a propulsion load. A first motor/generator is mechanically coupled with the first power unit. A second motor/generator is mechanically coupled with the second power unit. The second motor/generator and the first motor/generator are electrically coupled together. At least one electrical processing circuit is coupled with each of the first motor/generator and the second motor/generator. The at least one electrical processing circuit is configured for selectively transferring electrical power from the first motor/generator to the second motor/generator, when the second power unit is at or above the threshold power output.

Abstract: An agricultural vehicle including a plurality of engines, a plurality of loads, a plurality of electrical generators, at least one load sensor, at least one electrical energy storage device, and a controller. The plurality of engines include a first engine and a second engine. The plurality of loads include a first mechanical load, a second mechanical load, a first electrical load, and a second electrical load. The first mechanical load is coupled to the first engine and the second mechanical load is coupled to the second engine. The plurality of electrical generator include a first generator and a second generator. The first generator is coupled to the first engine and the second generator is coupled to the second engine. The first generator is electrically coupled to the first electrical load and the second generator is electrically coupled to the second electrical load.

Abstract: A work machine having dual compression ignition engines each driving motor generators providing a power output to selective loads. The compression ignition engines each have an exhaust aftertreatment device requiring regeneration in accordance with a selected parameters. A controller controls motor/generators or hydraulic pump/motors associated with the diesel engines to either transfer load between one or the other of the motor/generators or pump/motors to impose a load on one of the engines sufficiently high to produce passive regeneration. In the event that loads driven by the motor/generators or pump/motors are too low, one of the engines may be shut off or the loads increased.

Abstract: An agricultural harvester includes a first power unit which is couplable with a first primary load. The first primary load includes a threshing system load. A first motor/generator is mechanically coupled with the first power unit. A first clutch is mechanically coupled between the first power unit and the first primary load. A second power unit is couplable with a second primary load. The second primary load includes a propulsion load. A second motor/generator is mechanically coupled with the second power unit and electrically coupled with the first motor/generator. A second clutch is mechanically coupled between the second power unit and the second motor/generator.

Abstract: A fan unit for an agricultural machine includes a fan housing configured to define a plurality of fan chambers. Each fan chamber of the plurality of fan chambers has a respective air inlet port and a respective air outlet port. A shaft is rotatably mounted to the fan housing. The shaft has an axis of rotation that intersects the plurality of fan chambers. A plurality of fans is attached to the shaft for rotation with the shaft. Each fan of the plurality of fans is located in a separate respective fan chamber of the plurality of fan chambers.

Abstract: A method of operating an internal combustion engine including the steps of detecting, determining, and switching. The detecting step detects a load on the engine. The determining step determines if the load is below a predetermined value. The switching step switches the engine to operate at a selected one of a plurality of torque power curves, dependent upon the determining step.

Abstract: An internal combustion engine having an engine block for internal combustion, a turbocharger for delivering pressurized intake air to the engine block, a turbogenerator for recovering heat energy from the exhaust gas downstream of the turbocharger to generate electricity, and an exhaust gas recirculation (EGR) system comprising an EGR-pump drawing exhaust gas from an EGR inlet located between the turbocharger and the turbogenerator, wherein the EGR-pump controllably delivers exhaust gas to an EGR mixer in the pressurized intake air stream at a location between the turbocharger and the engine block. An electronic control unit (ECU) is adapted to command the EGR-pump to deliver a desired EGR flow-rate to the engine block based on look-up tables and either open-loop and/or closed-loop control algorithms.

Abstract: A work vehicle operating in a highly contaminated environment has a radiator with a rotary screen debris removal device upstream of the radiator. The debris thus removed passes through a fan for disposal away from the work machine. The engine is an air breathing fuel consuming engine and has a pre-cleaner for removing larger particles of air delivered to the engine for combustion. A conduit extends from the intake air pre-cleaner to a venturi device adjacent to and upstream of the fan for continuously and effectively removing particles from the engine air pre-cleaner.

Abstract: An agricultural harvester includes a first power unit which is couplable with a first primary load. The first primary load includes a threshing system load. A second power unit has a threshold power output and is couplable with a second primary load. The second primary load includes a propulsion load. A first motor/generator is mechanically coupled with the first power unit. A second motor/generator is mechanically coupled with the second power unit. The second motor/generator and the first motor/generator are electrically coupled together. At least one electrical processing circuit is coupled with each of the first motor/generator and the second motor/generator. The at least one electrical processing circuit is configured for selectively transferring electrical power from the first motor/generator to the second motor/generator, when the second power unit is at or above the threshold power output.

Abstract: A method of controlling a multiengine harvester including the steps of operating the harvester in a first mode, operating the harvester in a second mode, and selecting less than all of the power absorbing loads to be driven. In the first mode, the harvester is operated using a first engine and a second engine to drive the plurality of power absorbing loads. In the second mode, the harvester is operated with the second engine being uncoupled from all of the power absorbing loads. In the selecting step, less than all of the power absorbing loads are selected to be driven dependent upon the sensed load on the first engine while operating in the second mode. The first engine is incapable of driving all of the power absorbing loads.

Abstract: An agricultural vehicle including a plurality of engines, a plurality of loads, a plurality of electrical generators, at least one load sensor, at least one electrical energy storage device, and a controller. The plurality of engines include a first engine and a second engine. The plurality of loads include a first mechanical load, a second mechanical load, a first electrical load, and a second electrical load. The first mechanical load is coupled to the first engine and the second mechanical load is coupled to the second engine. The plurality of electrical generator include a first generator and a second generator. The first generator is coupled to the first engine and the second generator is coupled to the second engine. The first generator is electrically coupled to the first electrical load and the second generator is electrically coupled to the second electrical load.

Abstract: An agricultural harvester includes a first power unit which is couplable with a first primary load. The first primary load includes a threshing system load. A first motor/generator is mechanically coupled with the first power unit. A first clutch is mechanically coupled between the first power unit and the first primary load. A second power unit is couplable with a second primary load. The second primary load includes a propulsion load. A second motor/generator is mechanically coupled with the second power unit and electrically coupled with the first motor/generator. A second clutch is mechanically coupled between the second power unit and the second motor/generator.

Abstract: A method of operating an IC engine in an agricultural harvester includes the steps of: operating the IC engine in a normal mode with a base torque curve as a function of engine operating speed and engine power output, the base torque curve being generally isochronous at a rated operating speed over a power output range terminating at a rated power output; and operating the IC engine in a boost mode with a boost torque curve when a power boost is required above the rated power output, the boost torque curve having a power output which is above the base torque curve over a predefined range of the operating speed.