A hand-guided motorized working apparatus and an operating device for the apparatus are provided. The operating device has a handle shank configured to be hand-gripped, an operating element receiving region adjoining the handle shank, and an operating unit which acts on the apparatus operation and includes an operating element which is held movably on the operating element receiving region for actuation by a finger of a hand gripping the handle shank, and has a finger rest region extending along an outer side of the operating element receiving region. In the operating device, the operating element is a pivot operating lever which is held on the operating element receiving region so as to be pivotable about a pivot axis, wherein the pivot axis extends with a main direction component perpendicular to a shank longitudinal axis of the handle shank, and wherein the finger rest region, in a longitudinal extension along the outer side of the operating element receiving region, has a bent and/or angled course with a circumferential direction component and an axial direction component.

The present invention relates to an intelligent gardening system, for monitoring and controlling gardening apparatuses in a gardening area, including: multiple sensors that collect environmental information of the gardening area; one or more gardening apparatuses that perform gardening work according to a control instruction; and a control center that generates the control instruction based on the environmental information; wherein the sensors, the gardening apparatuses and the control center communicate with each other to form an Internet of Things.

The present disclosure generally relates to a system and method for providing individualized management for a plurality of plants. An exemplary system comprises a plurality of drones including a first drone, a docking station, and a server. The first drone is in assigned to a first plant of the plurality of plants and is configured to accommodate a plurality of combinations of drone attachments. The docking station comprises a plurality of drone attachments. The server includes a database related to the plurality of plants. The database includes location information associated with the first plant. The first drone is further configured to: make a plurality of visits to the first plant, gather plant-specific information associated with the first plant, obtain a prescription based on the plant-specific information, wherein the prescription is associated with one or more requirements, based on the prescription, provide care to the first plant.

A crop management apparatus for selectively severing plant items from a plurality of plants. The apparatus comprises: a sensor unit for sensing aspects of the plurality of plants and generating data indicative thereof; a control unit for processing the data to determine a location of a target plant item suitable for severing; a cutter unit comprising at least one selectively deployable cutter for severing the target plant item from its respective plant; and a prime mover for moving the sensor unit and the at least one selectively deployable cutter across the plurality of plants. The control unit outputs a control signal to deploy the at least one selectively deployable cutter at least in part based on the determined location of the target plant item. When the at least one selectively deployable cutter is in a deployed state, severance of the target plant item occurs at least in part based on movement of the prime mover.

An extension rod for a power tool may include a plurality of rod portions, with a first connector and a second connector connecting two of the rod portions. The second connector has a sleeve and a primary fastener. The first connector has a guide rod sized for insertion into the sleeve. The first connector also has a secondary fastener engaging with the primary fastener. A first guide ring, a second guide ring, and a third guide ring are located between the guide rod and the sleeve. The first guide ring, the second guide ring, and the third guide ring each include respective conical faces. At least one of the first, second, and third guide rings defines a notch.

An extension rod for a power tool may include a plurality of rod portions, with a first connector and a second connector connecting two of the rod portions. The second connector has a sleeve and a primary fastener. The first connector has a guide rod sized for insertion into the sleeve. The first connector also has a secondary fastener engaging with the primary fastener. A first guide ring, a second guide ring, and a third guide ring are located between the guide rod and the sleeve. The first guide ring, the second guide ring, and the third guide ring each include respective conical faces. At least one of the first, second, and third guide rings defines a notch.

A pruning system includes a cutting head comprising upper and lower cutting rings positioned along a bottom portion of one or more tubes. At least one of the cutting rings is adapted to rotate in a circular motion, while the other cutting ring may be adapted to remain stationary. A vacuum may be applied to suction target plant material, and the cutting head may be lowered toward the target plant material. As adjacent blades from the upper and lower cutting rings are separated in an open position, plant material may be collected in the opening defined by the adjacent blades of the cutting rings. As the blades converge, the opening may close, and plant material collected in the opening may be severed from the plant. System variables, such as blade orientation, vacuum speed, blade rotation speed, barrel size, and the cutting mechanisms, may be adjusted to accommodate different types of plant material. The pruning system may be installed on a vehicle and used with a vision system to remove materials from plant beds in a field.

The present invention relates to a cutting device (1) for fitting on an unmanned aerial vehicle (10) for the high-level pruning of vegetation in areas close to power distribution lines, which comprises at least one system for attachment (200) to the aerial vehicle (10) having a central beam (230), at least four arms (210) having connection points (12) to rods of the unmanned aerial vehicle, oriented toward motors of the aerial vehicle (10) for attachment to the aerial vehicle and a system for releasing (220) at least one cutting tool (300) whilst in use, and at least one cutting tool (300), made up of a plurality of saws each driven by a motor (310), a cutting rod (330) for attaching the plurality of saws and an automatic leveling system (320) for the cutting rod (330), which maintains said rod (330) in a horizontal position during the cutting process.

A vine or cane pruning apparatus, comprising a toothed wheel for guiding the pruning apparatus over vegetation in use, the wheel comprising a multiplicity of generally radially projecting teeth distributed about the periphery of the wheel for catching vegetation between gaps of the teeth, and wherein the wheel rotates by consequence of its engagement with the vegetation and vine or cane posts as the apparatus is driven along a row of vines or canes for pruning; and a driven rotary cutter mounted co-axially to the wheel for cutting vegetation caught between the teeth, the cutter being configured such that its effective cutting area falls within the diameter of the wheel.

A cannabis trimming assembly includes a pair of conveyors for transporting a cannabis plant. A trimming housing is positioned between the pair of conveyors to receive the cannabis plant. A pair of trap doors is each movably integrated into the trimming housing. A plurality of cameras is each integrated into the trimming housing to view the cannabis plant. A plurality of laser emitters is each integrated into the trimming housing and each of the laser emitters is guided by the cameras to trim shade leaves and buds from the cannabis. A grapping claw is integrated into the trimming housing to hang the cannabis plant in the trimming housing during trimming.