An agricultural harvesting machine for harvesting sugar cane, with means for working coupled to a tractor or any self-propelling machine, by using mechanic power (TDP) converted into hydraulic power (pump) to activate different devices of a set, so that it may form a wire cutting front for lanes of plants which are cut and thrown behind over the soil and organized in rows for later collecting and processing.

A plant stalk stomper assembly is operable to be mounted relative to a toolbar of a row crop header for advancement over the ground in a forward travel direction. The stomper assembly includes a frame and an elongated stomper skid plate operable to engage the ground as the stomper assembly is advanced in the forward travel direction. The skid plate presents an attachment section along which the skid plate is mounted relative to the frame. At least part of the skid plate includes a unitary plate element that depends below the attachment section to present a lowermost ground-engaging margin. The unitary plate element includes a deformation region located between the attachment section and the ground-engaging margin, with the unitary plate element operable to bend along the deformation region in response to relative movement between the attachment section and the ground-engaging margin.

An agricultural harvester includes a plurality of controllable subsystems and a forward-looking crop sensor that detects a characteristic of the crop in front of the harvester. The forward-looking sensor generates a first sensor signal indicative of the detected characteristic. The harvester further includes a component sensor that detects a characteristic of a component of the agricultural harvesting machine and generates a second sensor signal indicative of the detected characteristic. Adaptation logic receives the first and second sensor signals and determines a sensor conversion factor intermittently during operation of the agricultural harvester. Recommendation logic receives the conversion factor and generates a recommendation to change operation of a controllable subsystem, based in part on the calculated conversion factor and a value received from the forward-looking crop sensor. A control system controls the controllable subsystem based on the generated recommendation.

An agricultural harvester includes a plurality of controllable subsystems and a forward-looking crop sensor that detects a characteristic of the crop in front of the harvester. The forward-looking sensor generates a first sensor signal indicative of the detected characteristic. The harvester further includes a component sensor that detects a characteristic of a component of the agricultural harvesting machine and generates a second sensor signal indicative of the detected characteristic. Adaptation logic receives the first and second sensor signals and determines a sensor conversion factor intermittently during operation of the agricultural harvester. Recommendation logic receives the conversion factor and generates a recommendation to change operation of a controllable subsystem, based in part on the calculated conversion factor and a value received from the forward-looking crop sensor. A control system controls the controllable subsystem based on the generated recommendation.

Mowing systems include a mower and, optionally, a remote control unit such as a handheld unit, between which may be provided 1- or 2-way communications. Components and features are included in the mower, the remote control unit, or both to enhance the safety, functionality, or user experience of the system's user/operator. One aspect relates to monitoring a tilt angle of the mower, and defining or executing different system responses as a function of different first and second conditions that relate to the tilt angle. Another aspect relates to automatic adjustment of a speed setting of the mower's drive system as a function of a power takeoff (PTO) unit of the mower.

Mowing systems include a mower and, optionally, a remote control unit such as a handheld unit, between which may be provided 1- or 2-way communications. Components and features are included in the mower, the remote control unit, or both to enhance the safety, functionality, or user experience of the system's user/operator. One aspect relates to monitoring a tilt angle of the mower, and defining or executing different system responses as a function of different first and second conditions that relate to the tilt angle. Another aspect relates to automatic adjustment of a speed setting of the mower's drive system as a function of a power takeoff (PTO) unit of the mower.

A pivotably adjustable attachment apparatus for an agricultural vehicle includes an attachment connected to a mounting structure. The mounting structure is operatively connected to an adapter assembly in communication with a feed device for moving a crop from the attachment to a feed device for further processing of the crop. A frame supports the feed device over an uneven surface. An apparatus is positioned between the mounting structure and the adapter assembly. The apparatus provides a substantially non-sliding contact between the mounting structure and the adapter assembly in response to the mounting structure being directed to a pivotable movement with respect to the mounting structure, thereby providing a pivotable movement of the attachment in response to encountering the uneven surface.

A pivotably adjustable attachment apparatus for an agricultural vehicle includes an attachment connected to a mounting structure. The mounting structure is operatively connected to an adapter assembly in communication with a feed device for moving a crop from the attachment to a feed device for further processing of the crop. A frame supports the feed device over an uneven surface. An apparatus is positioned between the mounting structure and the adapter assembly. The apparatus provides a substantially non-sliding contact between the mounting structure and the adapter assembly in response to the mounting structure being directed to a pivotable movement with respect to the mounting structure, thereby providing a pivotable movement of the attachment in response to encountering the uneven surface.

An apparatus and method for distributing crop material onto a cleaning sieve of an agricultural combine. The method includes providing at least one sensor configured and operable for sensing information representative of at least one of a quantity of grain associated with the crop material distributor and an inclination angle associated with the crop material distributor, and outputting signals representative thereof. The method includes providing a crop material distributor disposed between a threshing system of the combine and the sieve, for distributing crop material from the threshing system generally evenly onto the sieve. The method includes providing an apparatus operably associated with the distributor for controllably distributing crop material onto the sieve. The method includes controlling a position of the apparatus as a function of signals from the at least one sensor.

A combine harvester has an inclination module coupled to the straw walker control system. The inclination module provides information on the inclination of the combine harvester. The straw walker control system is further configured to control the controllable frequency of the oscillating movement in function of the information on the inclination of the combine harvester.