A system for operating a harvester may include an elevator extending between a proximal end and a distal end, with the elevator being configured to carry harvested crops between its proximal and distal ends. The system may also include a storage hopper positioned adjacent to the distal end of the elevator, with the storage hopper defining a volume configured to receive the harvested crops discharged from the distal end of the elevator. In addition, the system may include a rotary spreader positioned within the storage hopper. The rotary spreader may be configured to be rotated within the storage hopper to disperse the harvested crops received from the elevator across at least a portion of the volume.

A bearing coupler assembly that has a bearing housing sized to at least partially receive a bearing assembly, the bearing housing defining a bearing axis therethrough, a shaft positioned at least partially through the bearing housing along the bearing axis, the shaft defining a shaft lip and a fastener end, the bearing assembly coupling the shaft to the bearing housing so the shaft can rotate about the bearing axis relative to the bearing housing, a fastener configured to be coupled to the fastener end of the shaft, a tone wheel positioned axially along the bearing axis between the fastener and the bearing assembly, the tone wheel having at least one indicator, a sensor coupled to the bearing housing and configured to identify when the indicator passes thereby.

A bearing coupler assembly that has a bearing housing sized to at least partially receive a bearing assembly, the bearing housing defining a bearing axis therethrough, a shaft positioned at least partially through the bearing housing along the bearing axis, the shaft defining a shaft lip and a fastener end, the bearing assembly coupling the shaft to the bearing housing so the shaft can rotate about the bearing axis relative to the bearing housing, a fastener configured to be coupled to the fastener end of the shaft, a tone wheel positioned axially along the bearing axis between the fastener and the bearing assembly, the tone wheel having at least one indicator, a sensor coupled to the bearing housing and configured to identify when the indicator passes thereby.

An extractor is disclosed for a sugarcane harvester that chops stalks of sugarcane into billets. The extractor comprises a fan and a leaf shredder. The fan comprises fan blades mounted for rotation about an axis of rotation to induce a flow of air to extract leaf material from billets produced by the sugarcane harvester. The leaf shredder comprises shredding knives mounted for rotation about the axis of rotation to shred leaf material prior to its ejection from the extractor. The leaf shredder is positioned below the fan or upstream from the fan relative to the flow of air.

An extractor is disclosed for a sugarcane harvester that chops stalks of sugarcane into billets. The extractor comprises a fan and a leaf shredder. The fan comprises fan blades mounted for rotation about an axis of rotation to induce a flow of air to extract leaf material from billets produced by the sugarcane harvester. The leaf shredder comprises shredding knives mounted for rotation about the axis of rotation to shred leaf material prior to its ejection from the extractor. The leaf shredder is positioned below the fan or upstream from the fan relative to the flow of air.

An extractor is disclosed for a sugarcane harvester that chops stalks of sugarcane into billets. The extractor comprises a housing, a fan positioned within the housing and comprising fan blades mounted for rotation in a rotational path about an axis of rotation to induce a flow of air to extract leaf material from billets produced by the sugarcane harvester, and a leaf shredder positioned within the housing and comprising shredding knives fixed against rotation about the axis of rotation, the shredding knives offset axially from the fan blades relative to the axis of rotation in proximity to the rotational path of the fan blades such that the fan blades and the shredding knives cooperate to shred leaf material by shearing action as the fan blades rotate past the shredding knives about the axis of rotation.

An extractor is disclosed for a sugarcane harvester that chops stalks of sugarcane into billets. The extractor comprises a housing, a fan positioned within the housing and comprising fan blades mounted for rotation in a rotational path about an axis of rotation to induce a flow of air to extract leaf material from billets produced by the sugarcane harvester, and a leaf shredder positioned within the housing and comprising shredding knives fixed against rotation about the axis of rotation, the shredding knives offset axially from the fan blades relative to the axis of rotation in proximity to the rotational path of the fan blades such that the fan blades and the shredding knives cooperate to shred leaf material by shearing action as the fan blades rotate past the shredding knives about the axis of rotation.

An agricultural system for automatically determining losses for harvesting operations includes a loss sensor supported on an agricultural harvester and having a field of view directed toward a portion of a field aft of a base cutter of the agricultural harvester, where the loss sensor is configured to generate data indicative of ground losses. Additionally, the agricultural system includes a computing system communicatively coupled to the loss sensor. The computing system is configured to identify non-height related ground losses during a harvesting operation of the agricultural harvester based at least in part on the data generated by the loss sensor. Additionally, computing system is configured to initiate a control action in response to the non-height related ground losses.

An agricultural system for automatically determining losses for harvesting operations includes a loss sensor supported on an agricultural harvester and having a field of view directed toward a portion of a field aft of a base cutter of the agricultural harvester, where the loss sensor is configured to generate data indicative of ground losses. Additionally, the agricultural system includes a computing system communicatively coupled to the loss sensor. The computing system is configured to identify non-height related ground losses during a harvesting operation of the agricultural harvester based at least in part on the data generated by the loss sensor. Additionally, computing system is configured to initiate a control action in response to the non-height related ground losses.

A cleaning arrangement for separating a billet material from an extraneous plant matter in a sugarcane harvester includes a cleaning chamber defining an inlet for the billet material and the extraneous plant matter, a first outlet for the extraneous plant matter, and a second outlet for the billet material. A fan is positioned within the cleaning chamber and configured to generate an airflow to direct the extraneous plant matter toward the first outlet. A billet deflector is located between the inlet and the first outlet and configured to direct the billet material toward the second outlet. An actuation mechanism is coupled to the billet deflector and is controllable to adjust the position of the billet deflector. A sensor is configured to generate a signal. A controller is programmed to activate the actuation mechanism to adjust the position of the billet deflector based on the signal.