A method, system and apparatus for a modular multipurpose machine or vehicle, including a modular scalable frame with battery incorporated into on the scalable frame; a modular electric drive system; and modular attachments or components for configuring the machine or vehicle for a plurality of maintenance or transportation functions. The modular electric drive system includes a power train with respective drive units for each of the front and rear wheels, each drive unit includes a planetary gear, and servo motor for each of the front and rear wheels. The power train includes steerable or non-steerable wheel power units, housing the respective drive units, and including respective servo controllers for each of the front and rear wheels. The wheel power units are configured for single, double or triple wheel configurations.

A method, system and apparatus for a modular multipurpose machine or vehicle, including a modular scalable frame with battery incorporated into on the scalable frame; a modular electric drive system; and modular attachments or components for configuring the machine or vehicle for a plurality of maintenance or transportation functions. The modular electric drive system includes a power train with respective drive units for each of the front and rear wheels, each drive unit includes a planetary gear, and servo motor for each of the front and rear wheels. The power train includes steerable or non-steerable wheel power units, housing the respective drive units, and including respective servo controllers for each of the front and rear wheels. The wheel power units are configured for single, double or triple wheel configurations.

A method, system and apparatus for a modular multipurpose machine or vehicle, including a modular scalable frame with battery incorporated into on the scalable frame; a modular electric drive system; and modular attachments or components for configuring the machine or vehicle for a plurality of maintenance or transportation functions. The modular electric drive system includes a power train with respective drive units for each of the front and rear wheels, each drive unit includes a planetary gear, and servo motor for each of the front and rear wheels. The power train includes steerable or non-steerable wheel power units, housing the respective drive units, and including respective servo controllers for each of the front and rear wheels. The wheel power units are configured for single, double or triple wheel configurations.

A drive system for self-propelling harvester is disclosed. The harvester includes a drive motor, a transfer case driven by the drive motor and having an output pulley arranged on a driveshaft of the transfer case and driving, using a main drive belt, at least one main pulley of a rotating cutter drum arranged on the end of a cutter drum shaft, a conditioning apparatus, an ejection accelerator, and a hydraulic pump for hydraulically driving an attachment and/or a feed device. The output pulley, the main drive belt and the main pulley form a main drivetrain for driving the cutter drum, the conditioning apparatus, and the ejection accelerator, and the attachment and the feed device are each driven by a separate drivetrain. At least one prop shaft, on the side of the main drivetrain, is arranged or positioned to lie in a common vertical plane with the main drive belt.

A drive system for self-propelling harvester is disclosed. The harvester includes a drive motor, a transfer case driven by the drive motor and having an output pulley arranged on a driveshaft of the transfer case and driving, using a main drive belt, at least one main pulley of a rotating cutter drum arranged on the end of a cutter drum shaft, a conditioning apparatus, an ejection accelerator, and a hydraulic pump for hydraulically driving an attachment and/or a feed device. The output pulley, the main drive belt and the main pulley form a main drivetrain for driving the cutter drum, the conditioning apparatus, and the ejection accelerator, and the attachment and the feed device are each driven by a separate drivetrain. At least one prop shaft, on the side of the main drivetrain, is arranged or positioned to lie in a common vertical plane with the main drive belt.

A drive arrangement for the reciprocating drive of a cutter bar comprises a hydraulic gear motor with a housing and a gearwheel, which is set in motion around a first axis by a hydraulic medium, and an eccentric drive, which comprises an eccentric element that can be rotatably driven by a gearwheel around a second axis parallel to the first axis, and a drive element connected to the eccentric element, which is, or can be, connected to the cutter bar.

A drive arrangement for the reciprocating drive of a cutter bar comprises a hydraulic gear motor with a housing and a gearwheel, which is set in motion around a first axis by a hydraulic medium, and an eccentric drive, which comprises an eccentric element that can be rotatably driven by a gearwheel around a second axis parallel to the first axis, and a drive element connected to the eccentric element, which is, or can be, connected to the cutter bar.

A sorghum cutting header and a sorghum harvester with large feed volume and multiple reeling pans includes a reeling header, a rod crushing device, and a reciprocating cutter device. The rod crushing device is located under the reeling header. The reeling header includes reeling pans, frame rods, bearing seats, reeling pan shafts, tandem shafts, and tandem shaft bearing seats. The reeling pan shafts are installed in parallel on the frame rod through bearing seats. The adjacent reeling pan shafts are in transmission connection, and at least one reeling pan shaft is in transmission connection with the power device. An inner part of any reeling pan shaft penetrates the tandem shafts. Both ends of the tandem shafts are supported on the frame rods, and one end of the tandem shafts is fixed on the tandem shaft bearing seats. The reeling pans are mounted on any reeling pan shaft.

A concave section for a harvester includes a concave body having an upstream side, a downstream side, a leading end and a trailing end. The concave body defines an arcuate crop engagement face facing radially inwardly. A plurality of crop passage openings are defined through the arcuate crop engagement face. A cover is configured to at least partially cover at least some of the crop passage openings. The cover is carried by the concave body and is movable thereon between at least two different positions to adjust a degree of openness of at least some of the crop passage openings.

An agricultural machine capable of sensing a harvested crop load includes a mower or mower conditioner implement, which may be referred to as a crop cutting implement, and a retractable linear device such as a spring or linear actuator. The crop cutting implement includes a flexible drive assembly with an endless loop, such as a belt, that is driven and supported by rollers. The retractable linear device resists movement of a first roller relative to a second roller. With this arrangement various characteristics of the agricultural machine, all of which are proxies for the position of the first roller relative to the second roller, may be measured by a crop load sensor to determine the quantity or load of harvested crop being processed by the flexible drive assembly of the agricultural machine.