Abstract: A power system including an engine, a first heat transfer circuit, and a second heat transfer circuit. The first heat transfer circuit includes a first heat exchanger that cools a first circuit fluid. The first circuit fluid cools a block and a head of the engine. The second heat transfer circuit includes a second heat exchanger that cools a second circuit fluid. The second circuit fluid cools a lube oil cooler.

Abstract: A method for controlling a fan. The method includes determining an actual air flow over an engine of a vehicle at a current time, and determining a necessary air flow over the engine for maintaining an appropriate engine coolant temperature. The actual air flow is associated with the vehicle traveling in a first direction. The method further includes estimating a future air flow over the engine that is associated with the vehicle travelling in a second direction. The method also includes controlling a fan operating characteristic based on the actual, necessary, and future air flows.

Abstract: A method for controlling a fan. An ECU estimates the time for an engine to reach a substantially decreased engine load relative to a current engine load. The ECU determines whether the time to reach the substantially decreased engine load is within a threshold. And the ECU controls a fan operating characteristic based on whether the time is within the threshold.

Abstract: A sugarcane harvester and related method are disclosed for powering various sugarcane harvester operations. An energy storage device may be configured to receive electrical power from one or more electric machines for storage. The energy storage device may be configured to provide electrical power to the one or more electric machines to power operation of the one or more electric machines. An operating state of the sugarcane harvester may be identified, wherein the operating state is associated with one or more of a power requirement, a torque requirement, and an engine speed requirement for the sugarcane harvester. Based upon identifying the operating state, the one or more electric machines may be caused to receive electrical power from the energy storage device for conversion by the one or more electric machines to mechanical power, in order to power an operation of the sugarcane harvester.

Abstract: A sugarcane harvester and related method are disclosed for powering various sugarcane harvester operations. An energy storage device may be configured to receive electrical power from one or more electric machines for storage. The energy storage device may be configured to provide electrical power to the one or more electric machines to power operation of the one or more electric machines. An operating state of the sugarcane harvester may be identified, wherein the operating state is associated with one or more of a power requirement, a torque requirement, and an engine speed requirement for the sugarcane harvester. Based upon identifying the operating state, the one or more electric machines may be caused to receive electrical power from the energy storage device for conversion by the one or more electric machines to mechanical power, in order to power an operation of the sugarcane harvester.

Abstract: A power system including an intake gas cooler and aftercooler positioned gaseously downstream thereof. The intake gas cooler is configured to receive a fresh intake gas for combusting in an engine and a recirculated exhaust gas expelled by the engine for re-combusting therein.

Abstract: A power system including an engine, a first heat transfer circuit, and a second heat transfer circuit. The first heat transfer circuit includes a first heat exchanger that cools a first circuit fluid. The first circuit fluid cools a block and a head of the engine. The second heat transfer circuit includes a second heat exchanger that cools a second circuit fluid. The second circuit fluid cools a lube oil cooler.

Abstract: An arrangement for providing an aftertreatment device housing with air comprises a combustion air intake (100) disposed receive combustion air for combustion in an internal combustion engine (118); a first supercharger (104) disposed to receive combustion air from the combustion air intake (100); a first conduit (106) disposed to receive the combustion air compressed in the first supercharger (104); a second conduit (110) coupled to the first conduit (106) to receive a first portion of the combustion air compressed in the first supercharger (104) from the first conduit (106); and a third conduit (112) coupled to the first conduit (106) to receive a second portion of the combustion air compressed in the first supercharger (104), wherein the third conduit (112) is configured to convey the second portion into the aftertreatment device housing (113) which substantially surrounds an aftertreatment device (114).

Abstract: A steering control system is disclosed for a vehicle train with a tow vehicle, a first towed vehicle with at least one ground-engaging member, and a second towed vehicle. A steering assembly may be configured to control steering of the at least one ground-engaging member. One or more sensing devices may be configured to determine orientation information for one or more of the tow vehicle, the first towed vehicle, and the second towed vehicle, during operation of the vehicle train. A steering correction may be determined for the second towed vehicle based upon the determined orientation information. The steering correction may be applied for the second towed vehicle by controlling the steering assembly to steer the first towed vehicle.

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: A hybrid drive system for a combine includes a control wherein the hybrid system control determines a battery pack state-of-charge of the battery pack, and the hybrid system control also receives the current engine load estimate and engine speed from the engine control. Depending upon these variables, the hybrid control sends a torque command to a motor/generator control to provide a desired composite speed-torque curve from the engine and the motor/generator. In cases where the battery pack can be charged, an engine fuel curve is set by engine control to provide maximum engine power at isochronous speed, and when the battery pack is fully charged, the engine fuel curve is reduced to be shaped so that battery electric assist is not engaged until engine speed falls.

Abstract: A combine harvester (102) drive system switches between a first isochronous operating curve (622) and a second isochronous operating curve (628) of an isochronously governed engine (126) when a load on the combine harvester engine (126) reaches one or more threshold load conditions.

Abstract: Disclosed is a power system comprising an internal combustion engine. A fan is associated with the engine and configured for providing an air flow. The power system further comprises an EGR system having an air cooled, HT EGR cooler configured for cooling recirculated exhaust gas, wherein the HT EGR cooler is positioned downstream of the internal combustion engine. The HT EGR cooler is further positioned such that the air flow travels across the outside of the HT EGR cooler. The EGR system further comprises an air cooled, LT EGR cooler is configured for further cooling at least a portion of the recirculated exhaust gas, wherein the LT EGR cooler is positioned downstream of the HT EGR cooler. The LT EGR cooler is further positioned such that the air flow travels across the outside of the LT EGR cooler.

Abstract: A method for powering a system in a vehicle, the method including the steps of mechanically coupling, driving and controlling. The mechanically coupling step includes coupling a power unit with at least one primary load, the at least one primary load including a propulsion load. The driving step includes driving a cleaning fan and a cleaning shoe with at least one power source, the at least one power source being mechanically independent from the power unit. The controlling step includes controlling a speed of the at least one power source independent of a speed of the power unit.

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: Disclosed is a power system comprising an internal combustion engine. A fan is associated with the engine and configured for providing an air flow. The power system further comprises an EGR system having an air cooled, HT EGR cooler configured for cooling recirculated exhaust gas, wherein the HT EGR cooler is positioned downstream of the internal combustion engine. The HT EGR cooler is further positioned such that the air flow travels across the outside of the HT EGR cooler. The EGR system further comprises an air cooled, LT EGR cooler is configured for further cooling at least a portion of the recirculated exhaust gas, wherein the LT EGR cooler is positioned downstream of the HT EGR cooler. The LT EGR cooler is further positioned such that the air flow travels across the outside of the LT EGR cooler.

Abstract: A vehicle arrangement includes a tow vehicle and a towed vehicle. The towed vehicle includes at least two wheels and at least one motor, with each motor being coupled with a corresponding wheel. A load sensing hitch between the tow vehicle and the towed vehicle provides an output signal representing a sensed load on the load sensing hitch. An electrical processing circuit is coupled with the load sensing hitch. The electrical processing circuit actuates at least one motor, dependent upon the output signal.

Abstract: A vehicle arrangement includes a tow vehicle and a towed vehicle. The towed vehicle includes at least two wheels and at least one motor, with each motor being coupled with a corresponding wheel. A load sensing hitch between the tow vehicle and towed vehicle senses a lateral load and provides an output signal representing the sensed lateral load. An electrical processing circuit is coupled with the load sensing hitch, and actuates at least one motor, dependent upon the output signal.

Abstract: A vehicle arrangement includes a tow vehicle and a towed vehicle. The towed vehicle includes at least two wheels and at least one motor, with each motor being coupled with a corresponding wheel. An indicator associated with an amount of material carried onboard the towed vehicle provides an output signal representing the amount of material. An electrical processing circuit is coupled with the indicator and actuates at least one motor, dependent upon the output signal.

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.