The present invention relates to a collecting apparatus for round bales. The collecting apparatus has a frame device and a conveying device, which is designed to convey a plurality of round bales relative to the frame device in a conveying direction. The conveying device comprises at least two traction members, which are spaced apart from one another transversely to the conveying direction and are designed to rotate about a front deflection axis and a rear deflection axis and have a conveying run and a return run. The conveying device also comprises at least two conveying elements, which are arranged offset to one another in the conveying direction, extend longitudinally between the conveying runs of the traction members transversely to the conveying direction, are attached to the traction members, and in each case have a conveying section arranged centrally between the traction members.

A feeder housing shaft sprocket segment comprising: a sprocket segment body (300) extending in a circumferential direction around a center axis (A) from a leading edge (304) to a trailing edge (306), wherein the leading edge (304) and trailing edge (306) subtend a segment angle about the center axis (A), the segment angle being a first unit fraction of 360; an outer sprocket perimeter (308) comprising a plurality of teeth (310) evenly arranged in the circumferential direction about the center axis (A) with each tooth (310) spaced by a tooth angle from each adjacent tooth (310), the tooth angle being a second unit fraction of 360; and a plurality of engagement surfaces (312) extending towards the center axis (A) and facing in the circumferential direction (C), the plurality of engagement surfaces (312) being asymmetrical relative to a plane (P) defined by the center axis (A) and a radial projection from the center axis (A) that bisects the sprocket segment body (300) midway between the leading edge (304) and the trailing edge (306).

A feeder housing shaft sprocket segment comprising: a sprocket segment body (300) extending in a circumferential direction around a center axis (A) from a leading edge (304) to a trailing edge (306), wherein the leading edge (304) and trailing edge (306) subtend a segment angle about the center axis (A), the segment angle being a first unit fraction of 360; an outer sprocket perimeter (308) comprising a plurality of teeth (310) evenly arranged in the circumferential direction about the center axis (A) with each tooth (310) spaced by a tooth angle from each adjacent tooth (310), the tooth angle being a second unit fraction of 360; and a plurality of engagement surfaces (312) extending towards the center axis (A) and facing in the circumferential direction (C), the plurality of engagement surfaces (312) being asymmetrical relative to a plane (P) defined by the center axis (A) and a radial projection from the center axis (A) that bisects the sprocket segment body (300) midway between the leading edge (304) and the trailing edge (306).

A feederhouse for an agricultural vehicle includes a frame including opposing side walls, openings disposed in each of the side walls, and an assembled driveshaft including a shaft and a plurality of sprockets that are rotationally fixed to the shaft. The assembled driveshaft is positioned within an interior region of the frame. At least one opening of said openings is sized such that the driveshaft can pass in a transverse direction through the at least one opening.

A chain guide for a wall of a grain elevator of an agricultural vehicle. The chain guide includes an elongated body. A rib extends from a surface of the elongated body, the rib being configured to engage with a chain of the grain elevator. A mating surface is either formed on or in the body, and the mating surface is configured to be connected to the wall of the grain elevator.

A chain guide for a wall of a grain elevator of an agricultural vehicle. The chain guide includes an elongated body. A rib extends from a surface of the elongated body, the rib being configured to engage with a chain of the grain elevator. A mating surface is either formed on or in the body, and the mating surface is configured to be connected to the wall of the grain elevator.

A combine harvester including a grain elevator for transporting and elevating harvested grain. The grain elevator includes a paddle loop, a driver, an elevator housing, and a sensor assembly. The paddle loop has a plurality of paddles for carrying the harvested grain. The driver is arranged for driving the paddle loop and thereby moving the paddles upward at a first side of the paddle loop and downward at a second side of the paddle loop. The elevator housing encompasses at least a portion of the paddle loop. The sensor assembly comprises a NIR sensor for detecting properties of the harvested grain and a sensor window arranged for enabling infrared light to travel between the NIR sensor and the harvested grain. The sensor window is embedded in the elevator housing, adjacent the first side of the paddle loop.

A combine harvester including a grain elevator for transporting and elevating harvested grain. The grain elevator includes a paddle loop, a driver, an elevator housing, and a sensor assembly. The paddle loop has a plurality of paddles for carrying the harvested grain. The driver is arranged for driving the paddle loop and thereby moving the paddles upward at a first side of the paddle loop and downward at a second side of the paddle loop. The elevator housing encompasses at least a portion of the paddle loop. The sensor assembly comprises a NIR sensor for detecting properties of the harvested grain and a sensor window arranged for enabling infrared light to travel between the NIR sensor and the harvested grain. The sensor window is embedded in the elevator housing, adjacent the first side of the paddle loop.