A method, system and apparatus for a lawn or turf care maintenance machine, including at least one of fully electric operation; multi-purpose operation; and overnight, silent operation. The machine can be configured for at least one of golf course maintenance, turf care, landscaping, outdoor work, and transportation.

A harvesting and sowing integrated compound operation machine, including a combine harvester, a stubble cleaning device, a topsoil loosening device, a fertilization device, a rotary tillage and ditching device, a sowing device, a detection device, a first driving device, a second driving device and a control device, wherein the stubble cleaning device is mounted below a header of the combine harvester; and the topsoil loosening device, the fertilization device, the rotary tillage and ditching device and the sowing device are mounted at a rear of a chassis of the combine harvester.

A harvesting and sowing integrated compound operation machine, including a combine harvester, a stubble cleaning device, a topsoil loosening device, a fertilization device, a rotary tillage and ditching device, a sowing device, a detection device, a first driving device, a second driving device and a control device, wherein the stubble cleaning device is mounted below a header of the combine harvester; and the topsoil loosening device, the fertilization device, the rotary tillage and ditching device and the sowing device are mounted at a rear of a chassis of the combine harvester.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating a flexible auger in a bin and in a curved or angled part of a tube to convey a granular treatment material toward harvested forage moving in a chute to mix the material with the harvested forage. The system can include a flexible auger having a helical blade that extends around an auger central passageway. The auger rotates and augers the granular treatment material with the blade out of the bin. The auger can extend into a curved portion of the tube, taking on a curved configuration extending into the curved portion so that the auger extends along a curvilinear axis and includes a curvilinear portion that is rotationally constrained in the tube.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating a flexible auger in a bin and in a curved or angled part of a tube to convey a granular treatment material toward harvested forage moving in a chute to mix the material with the harvested forage. The system can include a flexible auger having a helical blade that extends around an auger central passageway. The auger rotates and augers the granular treatment material with the blade out of the bin. The auger can extend into a curved portion of the tube, taking on a curved configuration extending into the curved portion so that the auger extends along a curvilinear axis and includes a curvilinear portion that is rotationally constrained in the tube.

A system and related method of applying forage treatment material to harvested forage is provided. The system can include a mobile forage harvester having a chute, a vacuum source that produces a vacuum, and a bin that stores granular treatment material for dispensation. The chute can be joined with a catch tube having a catch opening. A tube can extend from the bin toward the catch tube, but can be separated from the catch opening by an open gap. The material can be dispensed from the tube into the open gap, and drawn across the open gap and into the catch opening with the vacuum so the material mixes with the harvested forage moving along the pathway in the chute under force of the vacuum. The bin, tubes and the open gap can be located in an interior compartment to protect them from the elements. A related method is provided.

A system and related method of applying forage treatment material to harvested forage is provided. The system can include a mobile forage harvester having a chute, a vacuum source that produces a vacuum, and a bin that stores granular treatment material for dispensation. The chute can be joined with a catch tube having a catch opening. A tube can extend from the bin toward the catch tube, but can be separated from the catch opening by an open gap. The material can be dispensed from the tube into the open gap, and drawn across the open gap and into the catch opening with the vacuum so the material mixes with the harvested forage moving along the pathway in the chute under force of the vacuum. The bin, tubes and the open gap can be located in an interior compartment to protect them from the elements. A related method is provided.

A system for an agricultural operation includes a harvester configured to separate crop material into a harvest material and a non-harvest material. A crop material sensor is operably coupled with the harvester and is configured to capture crop material data. A positioning device is configured to generate location data to geolocate the crop material data relative to a field. A computing system is communicatively coupled with the crop material sensor and the positioning device. The computing system is configured to classify objects within the crop material data as harvest material or non-harvest material generate a map based on the harvest material and the non-harvest material.

A system for an agricultural operation includes a harvester configured to separate crop material into a harvest material and a non-harvest material. A crop material sensor is operably coupled with the harvester and is configured to capture crop material data. A positioning device is configured to generate location data to geolocate the crop material data relative to a field. A computing system is communicatively coupled with the crop material sensor and the positioning device. The computing system is configured to classify objects within the crop material data as harvest material or non-harvest material generate a map based on the harvest material and the non-harvest material.

A self-moving gardening robot, including a positioning module, a control module, a material cavity, and a working module. The positioning module of the self-moving gardening robot is configured to perform path planning, and the control module controls the self-moving gardening robot to travel according to planned path; and the working module performs a corresponding work when the self-moving gardening robot travels. When the material cavity contains different materials, the self-moving gardening robot may finish different functional tasks based on a same control procedure. In one of embodiments, the self-moving gardening robot is further provided with an accessory interface. By connecting different functional accessories through the accessory interface, the self-moving gardening robot implements multiple functions.