A method for determining information (Info) about a state (Z) of a drive motor system (2) and/or of a drive battery pack (11) of a gardening, forestry and/or construction device (1), includes the steps of: acquiring at least one sensor temperature (TS) of at least one temperature component (3) of the drive motor system (2) and/or of the drive battery pack (11) by way of at least one component temperature sensor (4) at the same time as and/or at a time after operation of the drive motor system (2) and/or of the drive battery pack (11) and/or of a heater (300) and/or of a cooler (310) and/or of a fan (320) for heating and/or for cooling the drive battery pack (11), wherein the temperature component (3) heats up or cools down due to the operation; ascertaining operating data (BD) of the operation, wherein the operating data (BD) are of a different kind than the sensor temperature (TS); comparing the acquired sensor temperature (TS) or a variable based on the sensor temperature and the ascertained operating data (BD) or a variable (TM) based on the operating data (BD) by way of a temperature model (MOD), wherein the temperature model (MOD) is based on at least one model state (AZyes) of the drive motor system (2) and/or of the drive battery pack (11); and determining the information (Info) on the basis of a result of the comparison.

An outdoor tool includes a powerhead, a tool unit powered by the powerhead, and a shaft assembly extending between the powerhead and the tool unit. The tool unit includes a transmission housing, a support plate, a guide bar adjustably supported by the support plate, a drive gear, and a chain circumscribing a portion of the drive gear and a portion of the guide bar, the drive gear operatively coupled to the powerhead. The tool unit further includes a tension adjustment mechanism for adjusting a position of the guide bar relative to the drive gear to increase and decrease a tension in the chain. The tension adjustment mechanism includes an adjustment screw, a threaded adjustment bolt, at least one adjustment gear, and a member coupled to the adjustment bolt and the guide bar. Rotation of the adjustment screw causes translation of the guide bar relative to the drive gear.

A cutting apparatus including a plurality of laser beams for cutting vegetation. The apparatus comprises a housing including an electrically powered laser cutting device which is positioned centrally within the housing. The laser cutting device generates at least one laser beam that is directed outwards from the housing wherein the laser is absorbed by a plate attached to a metal guide at the end of the effective cutting length of the laser.

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.

A mobile, self-powered, horticultural processing unit capable of facilitating the processing of a large number of plants, is disclosed. In particular a modular unit with a multi-level configuration and a compact footprint capable of performing a variety of different horticultural operations is the subject of present embodiments. The unit may utilize a wheel and suspension assembly attached to a hydraulic lift and towing hardware which permits the unit to be towed as a trailer. The unit may comprise a plurality of conveying platforms which permit access by a forklift, as to allow many plants to be input and removed from the unit at once. The unit may assist in the fully or partially automated pruning, canning, fertilizing, treating, and spacing of plants potted in individual containers. Collectively, the cost and labor involved with growing and maintaining plants in the field may be greatly reduced.

A mobile, self-powered, horticultural processing unit capable of facilitating the processing of a large number of plants, is disclosed. In particular a modular unit with a multi-level configuration and a compact footprint capable of performing a variety of different horticultural operations is the subject of present embodiments. The unit may utilize a wheel and suspension assembly attached to a hydraulic lift and towing hardware which permits the unit to be towed as a trailer. The unit may comprise a plurality of conveying platforms which permit access by a forklift, as to allow many plants to be input and removed from the unit at once. The unit may assist in the fully or partially automated pruning, canning, fertilizing, treating, and spacing of plants potted in individual containers. Collectively, the cost and labor involved with growing and maintaining plants in the field may be greatly reduced.

Electric pruning shears include: a first blade including a first blade portion that cuts an object to be cut and a first support base portion extended in a direction different from the first blade portion as viewed from the pivot portion; and the second blade including a second blade portion that cuts the object to be cut by sandwiching the object to be cut together with the first blade portion and a second support base portion extended in a direction different from the second blade portion as viewed from the pivot portion. The first blade portion is a convex curved blade with an intermediate portion from the pivot portion side to a distal end convexed, and the second blade portion is a concave curved blade with an intermediate portion from the pivot portion side to a distal end concaved. A bevel angle of the second blade portion gradually becomes obtuse from the pivot portion side to the distal end. At least one of the first support base portion and the second support base portion is connected to a power transmitter that transmits power from a drive source that is electrically driven. With this configuration, electric pruning shears capable of satisfactorily performing cutting without blade slippage even when the object to be cut is a thick branch, thereby making it possible to improve user’s satisfaction.

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 invention provides a working device, comprising a working portion and a grip portion. The working portion comprises a driving component and a working component driven by the driving component. The driving component comprises an electric motor and an electric motor housing. The electric motor housing comprises a housing body and a connecting portion located on a rear side of the housing body. At least one air intake hole is formed in the connecting portion, and is in communication with an inner cavity of the housing body. In the working device of the present invention, the driving component is provided with an air intake hole to allow air for cooling an electric motor to enter the interior of the driving component. Further, the working portion can be rotated with respect to the grip portion so as to have an increased working angle, and it can also be ensured that at least one air intake hole is always in communication with the outside when the working portion is in any angular position, so that the use efficiency of the electric motor can be ensured under any use condition.

A field-configurable apparatus for different aerial applications is provided. The field-configurable apparatus attaches to an aerial boom on a mobile carrier. The apparatus can perform rapid semi-precise cutting of vegetation. Additionally, the apparatus can perform more precise trimming of one or more areas (e.g., limbs) and optionally use a limb clamp to prevent cut limbs/vegetation from arbitrarily falling on objects below the cutting area. Still further, the apparatus can have a grapple or similar device attached to the end of the boom for use in relocating debris or for loading debris. Other industrial applications are also possible (e.g., commercial water blasting, deicing of planes, etc.). In each configuration, the apparatus comprises one or more rotatable or pivoting couplings to allow for rotation about one or more axis and therefore allow precise manipulation of an aerial tool assembly from an operator in the vehicle or on the ground.