A lawnmower cutting deck (1) is disclosed, wherein the cutting deck (1) is configured to be moved in a forward direction (d1) over a ground surface (5) to cut grass. The cutting deck (1) comprises at least a first cutter shaft (7.1) and at least one cutting unit (9) arranged on the first cutter shaft (7.1). The first cutter shaft (7.1) is configured to rotate around a first rotational axis (ax1) extending substantially parallel to the ground surface (5) to rotate the at least one cutting unit (9) in a first rotational plane (p1). The first rotational plane (p1) is angled in relation to the forward direction (d1). The present disclosure further relates to a lawnmower (3, 3) comprising a lawnmower cutting deck (1) and a method (100) of mowing a lawn.

A lawnmower cutting deck (1) is disclosed, wherein the cutting deck (1) is configured to be moved in a forward direction (d1) over a ground surface (5) to cut grass. The cutting deck (1) comprises at least a first cutter shaft (7.1) and at least one cutting unit (9) arranged on the first cutter shaft (7.1). The first cutter shaft (7.1) is configured to rotate around a first rotational axis (ax1) extending substantially parallel to the ground surface (5) to rotate the at least one cutting unit (9) in a first rotational plane (p1). The first rotational plane (p1) is angled in relation to the forward direction (d1). The present disclosure further relates to a lawnmower (3, 3) comprising a lawnmower cutting deck (1) and a method (100) of mowing a lawn.

An autonomous mobile work system (20) includes a drive wheel (34) that is connected to a frame (24) and a rotating blade assembly (36). The rotating blade assembly (36) includes a blade assembly axis of rotation (38) and is connected to the frame (24) within a housing (26). The mobile work system (20) further includes a single motor (40) operably connected to the blade assembly (36). The motor (50) includes a motor output shaft (44) and the motor output shaft (44) includes an output shaft axis of rotation (46). The mobile work system (20) still further includes a gear box (50) operably connected to the drive wheel (34) and the motor output shaft (44). The single motor (50) urges rotation of both the rotating blade assembly (36) and the drive wheel (34). The gear box (50) can include a planetary gear set (104) including a ring gear (110) defining cavities (120) at its outside diameter (124). A locking shaft (126) can rotate between an engaged position and a disengaged position with one of the cavities (120).

A harvesting machine is disclosed along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate of the frame for cutting the stems of the plants and forming a movable web. First and second moisture removal mechanisms are positioned downstream of the cutting mechanism, and each includes a suction roll and a press roll. A moving belt forms a closed loop around the pair of suction and press rolls, and has a plurality of apertures formed therethrough. The moving belt forms first and second nips between each pair of suction and press rolls for squeezing moisture out of said stems as the movable web is routed through the first and second nips.

A harvesting machine along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate for cutting the stems of the plants. A crimper mechanism is positioned downstream of the bottom plate and is capable of compacting the cut stems into a moving web. A moisture removal mechanism is positioned after the crimper mechanism to lower the moisture in the cut stems. A crop converging mechanism is located downstream of the moisture removal mechanism and reduces the width of the moving web into a ribbon. A chopper then chops the ribbon into small pieces so that they can be blown into a storage wagon for transport.

An autonomous mobile work system (20) includes a drive wheel (34) that is connected to a frame (24) and a rotating blade assembly (36). The rotating blade assembly (36) includes a blade assembly axis of rotation (38) and is connected to the frame (24) within a housing (26). The mobile work system (20) further includes a single motor (40) operably connected to the blade assembly (36). The motor (50) includes a motor output shaft (44) and the motor output shaft (44) includes an output shaft axis of rotation (46). The mobile work system (20) still further includes a gear box (50) operably connected to the drive wheel (34) and the motor output shaft (44). The single motor (50) urges rotation of both the rotating blade assembly (36) and the drive wheel (34). The gear box (50) can include a planetary gear set (104) including a ring gear (110) defining cavities (120) at its outside diameter (124). A locking shaft (126) can rotate between an engaged position and a disengaged position with one of the cavities (120).

The present invention relates to an apparatus for towing behind a vehicle, the apparatus comprising a body portion, a wheel, and a mounting member connecting the wheel to the body portion, wherein the mounting member comprises a hinge portion, and wherein the wheel is movable from a first position substantially behind the body portion to a second position substantially adjacent to the body portion via actuation of the hinge portion. Use of the apparatus is also described.

A harvesting machine is disclosed along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate for cutting the stems of the plants. A crimper mechanism is positioned downstream of the bottom plate and is capable of compacting the cut stems into a moving web. A moisture removal mechanism is positioned after the crimper mechanism to lower the moisture in the cut stems. A crop converging mechanism is located downstream of the moisture removal mechanism and reduces the width of the moving web into a ribbon. A chopper then chops the ribbon into small pieces so that they can be blown into a storage wagon for transport.

An agricultural mowing device includes a linkage assembly for attaching to a towing vehicle, and a shaft having an upper end coupled to the linkage assembly for being towed in a field between two adjacent rows of planted matter. The device further includes a primary cutting device mounted to a lower end of the shaft for cutting shorter plant material, and a secondary cutting device mounted near the upper end of the shaft for cutting taller plant material. The device also includes a sensor for sensing a desired cutting height of the planted matter and being communicatively coupled to the primary cutting device or the secondary cutting device, the sensing causing an adjustment along the shaft of the respective one of the primary cutting device or the second cutting device to cut the planted matter at the desired cutting height.

A sapling reducing implement for reducing a sapling generally includes a drum, a plurality of reducing elements, a plurality of shields, and a pair of skids. The drum is configured to be rotatably driven and to carry the reducing elements thereon. The shields at least partially surround the drum and reducing elements. The reducing elements are configured to extend within an inch of the ground during a downward portion of the drum's rotational cycle. The shields define, at least in part, a tree entrance opening to receive the sapling. The ground skids are respectively attached to the side shields and can engage the ground during travel.