A mobile platform biomass harvester has a header, a biomass processor, a storage container, a guidance system, an engine, an electric generator, and a guidance system. The header harvests biomass. The biomass processor includes a shredder, a press, a dryer, and a densifier. The densifier compacts the biomass into a multitude of compressed biomass pieces. The storage container receives compressed biomass pieces from the biomass processor. The guidance system guides the mobile platform at a speed determined by the operating capacity of the mobile platform. The engine generates shaft power. The electrical generator converts the shaft power to electricity to power the guidance system.

A header for stalk crop has a multi-part cutter bar with oscillatingly driven cutter bar parts. Cutter bar knives of the cutter bar interact with counter knives connected to header frame. A drive shaft ends in a first plane inside a gear housing arranged behind the cutter bar. An eccentric shaft supported in the gear housing carries a gear wheel arranged in a second plane above or below the first plane. The drive shaft drives the gear wheel through a bevel gear. First and second eccentric discs, arranged in third and fourth planes, respectively, are connected to the eccentric shaft; first and second eccentric levers are correlated therewith. First and second pivot levers are connected to the first and second eccentric levers and connected to stationarily supported pivot shafts. Crank arms connected to the pivot shafts, respectively, transmit their pivot movement to the cutter bar parts.

A header for stalk crop has a multi-part cutter bar with oscillatingly driven cutter bar parts. Cutter bar knives of the cutter bar interact with counter knives connected to header frame. A drive shaft ends in a first plane inside a gear housing arranged behind the cutter bar. An eccentric shaft supported in the gear housing carries a gear wheel arranged in a second plane above or below the first plane. The drive shaft drives the gear wheel through a bevel gear. First and second eccentric discs, arranged in third and fourth planes, respectively, are connected to the eccentric shaft; first and second eccentric levers are correlated therewith. First and second pivot levers are connected to the first and second eccentric levers and connected to stationarily supported pivot shafts. Crank arms connected to the pivot shafts, respectively, transmit their pivot movement to the cutter bar parts.

A harvesting machine includes a harvesting header with a header frame, a cutterbar assembly attached to the header frame along the length thereof and configured to cut a crop, and a draper assembly positioned behind the cutterbar assembly and operable to receive severed crop material from the cutterbar assembly. The draper assembly includes a center draper that delivers crop material to a feeder house of the harvesting machine and oppositely spaced side drapers that deliver crop material to the center draper. The harvesting header is operable to flex and thereby follow an uneven terrain.

A harvesting machine includes a harvesting header with a header frame, a cutterbar assembly attached to the header frame along the length thereof and configured to cut a crop, and a draper assembly positioned behind the cutterbar assembly and operable to receive severed crop material from the cutterbar assembly. The draper assembly includes a center draper that delivers crop material to a feeder house of the harvesting machine and oppositely spaced side drapers that deliver crop material to the center draper. The harvesting header is operable to flex and thereby follow an uneven terrain.

An agricultural harvester is provided which includes a chassis and harvesting wheels, transport wheels and windrow shields connected to the chassis. The transport wheels are deployed in concert with the windrow shields in order to avoid damage to the windrow shields during placement of the transport wheels into an operative, ground contacting position. A first actuator opens and closes the windrow shields for field and transport operations and windrow shield positioning mechanisms are configured to dispose the windrow shields in a plurality of cut crop opening widths when the windrow shields are in an open position. The first actuator is operated remotely in-cab to eliminate need for the harvester operator to dismount the harvester and open and close the windrow shields for field and road transport operations. The windrow shield positioning mechanisms may be manually adjusted or automatically adjusted in-cab.

An agricultural harvester is provided which includes a chassis and harvesting wheels, transport wheels and windrow shields connected to the chassis. The transport wheels are deployed in concert with the windrow shields in order to avoid damage to the windrow shields during placement of the transport wheels into an operative, ground contacting position. A first actuator opens and closes the windrow shields for field and transport operations and windrow shield positioning mechanisms are configured to dispose the windrow shields in a plurality of cut crop opening widths when the windrow shields are in an open position. The first actuator is operated remotely in-cab to eliminate need for the harvester operator to dismount the harvester and open and close the windrow shields for field and road transport operations. The windrow shield positioning mechanisms may be manually adjusted or automatically adjusted in-cab.

A pull-type crop engaging machine such as a rotary mower comprises a frame mounted on transversely spaced field ground wheels for movement with a hitch arm extending to a tractor and a transport assembly attached behind the frame for moving downwardly to a transport position so that in the transport position the hitch arm extends from one end of the frame generally in the transverse direction for towing the machine in the transverse direction. The transport includes a transport ground wheel which acts to raise the frame to pass underneath the crop engaging system to support the machine on the wheel, on a second wheel behind the frame and on the hitch. The movement of the hitch and the wheel is connected and started at a position of the hitch so that the machine remains balanced. A shield behind the frame includes a portion which moves with the transport wheel.

A pull-type crop engaging machine such as a rotary mower comprises a frame mounted on transversely spaced field ground wheels for movement with a hitch arm extending to a tractor and a transport assembly attached behind the frame for moving downwardly to a transport position so that in the transport position the hitch arm extends from one end of the frame generally in the transverse direction for towing the machine in the transverse direction. The transport includes a transport ground wheel which acts to raise the frame to pass underneath the crop engaging system to support the machine on the wheel, on a second wheel behind the frame and on the hitch. The movement of the hitch and the wheel is connected and started at a position of the hitch so that the machine remains balanced. A shield behind the frame includes a portion which moves with the transport wheel.

A crop lifter apparatus has a base member attached to a selected guard finger of a cutting header. A front lifting finger extends forward and downward from the base member at a first angle downward from horizontal, and a rear lifting finger extends rearward and upward from the base member at second angle upward from horizontal, where the second angle is greater than the first angle. A front end of the front lifting finger is at a front vertical location that is a first distance below a top surface of the table, and a rear end of the rear lifting finger is at a rear vertical location that is a second distance above the top surface of the table, and the second distance is at least twice the first distance.