A baling machine including a bale-forming chamber for receiving plant matter and forming it into a bale. The bale-forming chamber includes one or more rotatable, bale-forming rollers and a feed mechanism for feeding a flexible wrapping material into the bale-forming chamber for wrapping a bale therein. The baling machine further includes an acoustic or vibration sensor that is configured for generating an output. The acoustic or vibration sensor generates an output signal that is characteristic of operation of the baling machine while wrapping material is being fed into the bale-forming chamber. The status of the output signal indicates whether the wrapping material is being wrapped onto the bale or around the one or more rotatable, bale-forming rollers.

An agricultural machine includes: a machine frame; and a feeder system coupled with the machine frame and including a windguard assembly, the windguard assembly being configured for selectively occupying a first position and a second position, the first position being associated with a normal flow direction of a crop material relative to the feeder system, the second position being associated with a reversal of the normal flow direction of the crop material.

An accumulator contents detection system for a harvester includes an accumulator, a plurality of metering rollers, and at least one sensor. The accumulator accumulates crop material. The plurality of metering rollers receives crop material from the accumulator. The plurality of metering rollers includes a drive metering roller. The at least one sensor detects a load transmitted to the drive metering roller.

A cotton harvester estimates the mass of cotton as it is harvested using sensor devices and compares the mass of each module against the estimated mass of the module as determined by the sensors so that a calibration factor may be determined and actively updated for more accurate crop yield determination. The mass flow for a specific module is accumulated and processed during harvesting using a base calibration factor and the module is weighed and compared against the expected mass using the base calibration factor to develop a candidate updated calibration factor. The base calibration factor is selectively replaced by the candidate updated calibration factor for processing a subsequent module based on machine feedback information relating to the operation of the harvester. Harvested crop data determined using the calibration factor is used to generate highly accurate yield maps.

A cotton harvester estimates the mass of cotton as it is harvested using sensor devices and compares the mass of each module against the estimated mass of the module as determined by the sensors so that a calibration factor may be determined and actively updated for more accurate crop yield determination. The mass flow for a specific module is accumulated and processed during harvesting using a base calibration factor and the module is weighed and compared against the expected mass using the base calibration factor to develop a candidate updated calibration factor. The base calibration factor is selectively replaced by the candidate updated calibration factor for processing a subsequent module based on machine feedback information relating to the operation of the harvester. Harvested crop data determined using the calibration factor is used to generate highly accurate yield maps.

A sensor arrangement located on a baler for detecting rotation of a dispensing reel of wrapping material and including a rotary element having a textured surface and a sensor mounted on a displaceable mounting bracket wherein the rotary element is rotated by the dispensing reel during baling.

A round baler includes a first roller and a second roller that define a gap therebetween and are arranged to position forming belts immediately adjacent to a baling chamber. A third roller is arranged to position the forming belts radially outward of the baling chamber. The forming belts move along a belt path in sequence from the first roller, to the third roller, and then to the second roller, such that the baling chamber is not bounded by the forming belts in the gap between the first roller and the second roller. A net guide is radially supported by both the first roller and the second roller and laterally positioned between an adjacent pair of the forming belts. The net guide extends across the gap to guide a net material across the gap and prevent the net material from following the forming belts away from the baling chamber.

A method for controlling, through a mobile device, wrapping operations in a wrapper for wrapping a round bale with a film, comprises the following steps, performed by a processor of the mobile device: coupling the mobile device to a control unit of the wrapper, by sending a coupling signal to the control unit; receiving control inputs from a user, through an interaction of the user with the mobile device; elaborating the control inputs and generating, based on the control inputs, a command message; sending the command message to the control unit of the wrapper; receiving, at the processor of the mobile device, operation data from the control unit of the wrapper, the operation data being representative of operations performed by the wrapper.

A round baler and a method for operating a round baler are disclosed. The round baler has a variable diameter and is bounded by an endlessly rotating pressing means. The pressing means is guided by a plurality of rollers, wherein a loop of the pressing means is guided by a first clamping arm mounted on the housing side and by a second clamping arm mounted on the housing side. The first and second clamping arms are adjusted by actuators so that at least one compaction pressure is generated with which the pressing means acts to form a round bale. A control unit automatically controls the actuators depending on a compaction power curve, accounting for operating parameters and/or environmental parameters of the round baler, thereby maintaining a substantially stable operating point during the shaping process, in which the required compaction power and the available drive power are substantially equal.

A round baler and a method for operating a round baler are disclosed. The round baler has a variable diameter and is bounded by an endlessly rotating pressing means. The pressing means is guided by a plurality of rollers, wherein a loop of the pressing means is guided by a first clamping arm mounted on the housing side and by a second clamping arm mounted on the housing side. The first and second clamping arms are adjusted by actuators so that at least one compaction pressure is generated with which the pressing means acts to form a round bale. A control unit automatically controls the actuators depending on a compaction power curve, accounting for operating parameters and/or environmental parameters of the round baler, thereby maintaining a substantially stable operating point during the shaping process, in which the required compaction power and the available drive power are substantially equal.