An agricultural vehicle is operable in a first state for transport and in a second state for field work and includes a frame supported by a plurality of tires. A processor is operable to receive a signal generated as a result of the agricultural vehicle transitioning from the first state to the second state or from the second state to the first state. A gas system is operable to modify the tire pressure of the plurality of tires of the agricultural vehicle in response to the signal.

A cotton picker unit lift structure having a first frame, a second frame slidably coupled to the first frame about a pivot axis with a plurality of sliding joints. Wherein, the pivot axis is spaced from the second frame and extends in a fore-aft direction and the second frame is pivotal about the pivot axis in a first direction and a second direction relative to the first frame.

A cotton picker unit lift structure having a first frame, a second frame slidably coupled to the first frame about a pivot axis with a plurality of sliding joints. Wherein, the pivot axis is spaced from the second frame and extends in a fore-aft direction and the second frame is pivotal about the pivot axis in a first direction and a second direction relative to the first frame.

A power transmission system is disclosed for infinitely variable speed capability. The power transmission system includes a pair of power units, each configured to deliver a rotational torque to drive an output element. A transmission arrangement receives the rotational torques from the power units and delivers a resulting torque to the output element. The transmission arrangement includes a gear set coupling the one power unit to the output element to deliver torque through a mechanical meshing engagement that is continuously effected between the first power unit and the output element.

A power transmission system is disclosed for infinitely variable speed capability. The power transmission system includes a pair of power units, each configured to deliver a rotational torque to drive an output element. A transmission arrangement receives the rotational torques from the power units and delivers a resulting torque to the output element. The transmission arrangement includes a gear set coupling the one power unit to the output element to deliver torque through a mechanical meshing engagement that is continuously effected between the first power unit and the output element.

An agricultural vehicle is operable in a first state for transport and in a second state for field work and includes a frame supported by a plurality of tires. A processor is operable to receive a signal generated as a result of the agricultural vehicle transitioning from the first state to the second state or from the second state to the first state. A gas system is operable to modify the tire pressure of the plurality of tires of the agricultural vehicle in response to the signal.

A module builder includes a wrap floor system including a wrap floor belt wrapped around a front belt sheave and a first drive system coupled to the wrap floor system. The first drive system includes a main drive belt coupled to a rear belt sheave and the front belt sheave, wherein in an engagement mode of operation the main drive belt is tensioned to rotate the rear belt sheave, and in a disengagement mode of operation the main drive belt loses tension to cease rotation of the rear belt sheave. The builder includes a second drive system coupled to a baler belt to drive the baler belt into a module forming chamber. The first drive system further includes one or more of a rear lower gate roller, friction wheel, wrap box roller, electric clutch, or motor to engage and drive the main drive belt.

A system for sampling of plant product is provided that comprises a mobile platform, at least one primary bin, and a harvesting subsystem connected to the mobile platform. The harvesting subsystem harvests the plant product as the system traverses a plot and projects it across the length of the primary bin(s) against a back wall of the primary bin(s), whereby the separated plant products collides with the back wall and falls into the primary bin. The system additionally includes at least one sample volumizer connected to the back wall of each primary bin. Each sample volumizer has a specified fixed volume and receives and collects a sample of the plant product, wherein each collected sample collected has the specified fixed volume. The system further includes at least one sample receiving subsystem structured and operable to receive and collect a sample from a respective sample volumizer.

A cotton harvester with a hydraulic manifold and at least one hydraulic motor mechanically coupled to a drum and fluidly coupled to the hydraulic manifold, the hydraulic motor configured to selectively rotate the drum. Wherein, the hydraulic manifold is configured to selectively provide any one of a braking force and a torque to the drum through the at least one hydraulic motor.

A cotton harvester having a prime mover providing power to the cotton harvester, a controller monitoring a load on the prime mover and storing a load threshold, a drum rotatable about a first axis at a drum speed, a plurality of spindles for harvesting cotton, the plurality of spindles rotatable at a spindle speed and a doffer assembly rotatable about a second axis at a doffer speed. Wherein, when the controller detects a load on the prime mover greater than the load threshold, the spindle speed is reduced.