A self-propelled windrow merger includes a motor and a chassis. At the front of the merger are a first pickup and transfer assembly, a second pickup and transfer assembly and a third pickup and transfer assembly. A cab is above and behind the second pickup and transfer assembly. A folding mechanism for moves each of the pickup and transfer assemblies between a first position wherein the first, second and third pickup and transfer assemblies are laterally aligned and a second position wherein the first and third pickup and transfer assemblies are positioned rear of the cab.

A self-propelled windrow merger includes a motor and a chassis. At the front of the merger are a first pickup and transfer assembly, a second pickup and transfer assembly and a third pickup and transfer assembly. A cab is above and behind the second pickup and transfer assembly. A folding mechanism for moves each of the pickup and transfer assemblies between a first position wherein the first, second and third pickup and transfer assemblies are laterally aligned and a second position wherein the first and third pickup and transfer assemblies are positioned rear of the cab.

Methods and systems for estimating volumes of agricultural crops are provided. A geographic position sensor provides positions of a harvesting machine as it gathers an agricultural crop and places the crop on the ground in a windrow. A speed of the harvesting machine is determined using the geographic position sensor. Signals are received from a sensor system disposed at a bottom of the harvesting machine. The signals are indicative of profiles of segments of the windrow on the ground. Cross-sectional areas of the windrow are estimated using the signals. Volumes of the agricultural crop are estimated using the speed of the harvesting machine and the estimated cross-sectional areas of the windrow.

Methods and systems for estimating volumes of agricultural crops are provided. A geographic position sensor provides positions of a harvesting machine as it gathers an agricultural crop and places the crop on the ground in a windrow. A speed of the harvesting machine is determined using the geographic position sensor. Signals are received from a sensor system disposed at a bottom of the harvesting machine. The signals are indicative of profiles of segments of the windrow on the ground. Cross-sectional areas of the windrow are estimated using the signals. Volumes of the agricultural crop are estimated using the speed of the harvesting machine and the estimated cross-sectional areas of the windrow.

The present invention relates to the general technical field of agricultural machinery. It concerns an agricultural device, in particular a haymaking device, which can be moved in a direction of advance and which includes a cutter bar equipped with cutting elements intended to cut a standing crop product. The device also comprises a conditioner positioned behind the bar, and a grouping device intended to move the product transversely to the direction of advance and located behind the bar, in an active position. A retraction actuator is configured to transpose the grouping device between the active position and a passive position in which the product is deposited at the rear of the device. A collecting device extends partially under and partially behind the conditioner in active position of the grouping device. The invention also concerns an agricultural machine equipped with such a device and a method for access between a conditioner and a grouping device belonging to such a device.

An agricultural vehicle and connected mower having a number of mowing units suitable for cutting a standing crop, including a front mowing unit and two lateral mowing units located behind and to the sides of the front mowing unit, each of the lateral mowing units having conveyor units to deposit cut crop as a swath. A control unit receives a plurality of signals, representing the location of the mower combination and a direction of operation of each of the conveyor units, compares the signals to a predetermined set of values and as required, adjusts the direction of operation of at least one conveyor unit based on the comparison.

An agricultural vehicle and connected mower having a number of mowing units suitable for cutting a standing crop, including a front mowing unit and two lateral mowing units located behind and to the sides of the front mowing unit, each of the lateral mowing units having conveyor units to deposit cut crop as a swath. A control unit receives a plurality of signals, representing the location of the mower combination and a direction of operation of each of the conveyor units, compares the signals to a predetermined set of values and as required, adjusts the direction of operation of at least one conveyor unit based on the comparison.

A converging drum for a crop mowing implement includes a body that extends along a central longitudinal axis. The body rotates about the central longitudinal axis in a defined rotational direction. At least one ramp feature extends radially outward from the body, relative to the central longitudinal axis. The ramp feature is arranged to form an acute angle relative to a reference plane. The acute angle may open toward the defined rotational direction to move cut crop downward, or the acute angle may open away from the defined rotational direction to move crop upward, to position the cut crop for a conditioning system. The converging drum may include a first group of ramp features near a second end of the body for moving cut crop downward, and/or a second group of ramp features near a first end of the body for moving cut crop upward.

An agricultural mounted implement for the cleaning of harvested material, which cleaning is mobile and operated on a vehicle, said implement having an implement frame, a fan, and a cleaning unit. The cleaning unit has a pick-up for picking the harvested material to be cleaned; a first air distributor base connected to the fan via an air conveying channel and has a first air passage; a conveyor unit via which the cleaned harvested material is ejected from the cleaning unit; and a drop sieve which is mounted on the implement frame so as to be congruently below the conveyor unit. During operation, the fan sucks in an air flow, guides it under the first air distributor base and blows it out through the first air passage counter to the force of gravity such that the harvested material picked by the pick-up is transported to the conveyor unit.

An agricultural mounted implement for the cleaning of harvested material, which cleaning is mobile and operated on a vehicle, said implement having an implement frame, a fan, and a cleaning unit. The cleaning unit has a pick-up for picking the harvested material to be cleaned; a first air distributor base connected to the fan via an air conveying channel and has a first air passage; a conveyor unit via which the cleaned harvested material is ejected from the cleaning unit; and a drop sieve which is mounted on the implement frame so as to be congruently below the conveyor unit. During operation, the fan sucks in an air flow, guides it under the first air distributor base and blows it out through the first air passage counter to the force of gravity such that the harvested material picked by the pick-up is transported to the conveyor unit.