A mower implement includes a cutter bar extending along a central bar axis. A rotating blade assembly is mounted on the cutter bar. The rotating blade assembly includes a disc rotatable about a disc rotation axis relative to the cutter bar, and at least one blade pivotably mounted to the disc. A blade sensor is mounted on the cutter bar. The blade sensor has a sensing field, and is positioned to detect movement of the at least one blade of the rotating blade assembly through the sensing field during each rotation of the disc about the disc rotation axis. A diagnostic controller receives the data signal from the blade sensor and is configured to analysis the blade signal and identify a fault in the rotating blade assembly. The diagnostic controller may then notify an operator of the identified fault.

A control panel, a self-propelled switch apparatus, and a power device (13). The control panel comprises a push rod (1) connected to a machine body and a panel assembly (2) reciprocatingly sliding on the push rod. The control panel further comprises lock assemblies (41, 42) connected to the panel assembly. The lock assemblies (41, 42) are adapted to lock the panel assembly on the push rod and unlock the control panel and the push rod, so that a device in which the control panel is disposed can be switched between a manual-power driving mode and a self-propelled driving mode. By means of the solution, a garden tool can walk in a self-propelled manner, and can also be pushed to walk.

An all-electric turf vehicle, wherein the vehicle comprises a chassis; a plurality of ground engaging wheels operatively connected to the chassis, wherein at least one of the ground engaging wheels is a steerable wheel; a plurality of electric wheel drive and tractions motors, wherein each electric wheel drive and tractions motor is operatively connected to a respective one of the plurality of ground engaging wheels and is structured and operable to deliver motive power to the respective ground engaging wheel; a plurality of turf cutting units; and an operator station. The operator station comprises a seat in which a vehicle operator can be seated; and a control and support arm pivotally movable so that the control and support arm can be positioned to not obstruct a line of sight of the vehicle operator to an outer edge of an outermost of the plurality of cutting units.

An all-electric turf vehicle, wherein the vehicle comprises a chassis; a plurality of ground engaging wheels operatively connected to the chassis, wherein at least one of the ground engaging wheels is a steerable wheel; a plurality of electric wheel drive and tractions motors, wherein each electric wheel drive and tractions motor is operatively connected to a respective one of the plurality of ground engaging wheels and is structured and operable to deliver motive power to the respective ground engaging wheel; a plurality of turf cutting units; and an operator station. The operator station comprises a seat in which a vehicle operator can be seated; and a control and support arm pivotally movable so that the control and support arm can be positioned to not obstruct a line of sight of the vehicle operator to an outer edge of an outermost of the plurality of cutting units.

Provided is electric power equipment that allows a battery to be installed and removed with ease. The electric power equipment (1) includes a main body (2) defining a battery receiving recess (40) having an open upper end, and a battery (20) configured to be received in the battery receiving recess, wherein an upper part of a front end part of the battery is provided with a projection (108) projecting in a forward direction, and a rear end part of the battery is provided with a grip, and wherein an upper edge of the front end part of the battery receiving recess is provided with a supporting surface (36) configured to support a lower surface of the projection at least when the battery is being removed from the battery receiving recess.

A method for operating a permanently excited synchronous motor of a hand-held working device includes the steps of: sensorlessly determining a position variable representative of a position of a rotor of the synchronous motor at a standstill; determining a direction variable for a continuous rotation of the rotor from standstill in a direction on the basis of the determined position variable such that an absolute value of an attainable torque that can be generated by the synchronous motor during its sensorless actuation for the rotation in the direction is greater than an absolute value of a breakaway torque limit of the working device; and sensorlessly actuating the synchronous motor on the basis of the determined direction variable for the rotation in the direction.

An electric working machine with an operating rod includes an electric motor on the base end of the operating rod, a working device on the head end of the operating rod, and a power transmission shaft passing through the inside of the operating rod to transmit power from the electric motor to the working device. The working device includes a blade member and is pivotally supported on the head end of the operating rod to be able to take a storage posture. A detection switch on the head end of the operating rod detects the storage posture. A controller on the base end of the operating rod controls the operation of the electric motor. A lead wire in the operating rod transmits a detection signal from the detection switch to the controller. The controller prevents the electric motor from being driven when the detection switch detects the storage posture.

An electric working machine with an operating rod includes an electric motor on the base end of the operating rod, a working device on the head end of the operating rod, and a power transmission shaft passing through the inside of the operating rod to transmit power from the electric motor to the working device. The working device includes a blade member and is pivotally supported on the head end of the operating rod to be able to take a storage posture. A detection switch on the head end of the operating rod detects the storage posture. A controller on the base end of the operating rod controls the operation of the electric motor. A lead wire in the operating rod transmits a detection signal from the detection switch to the controller. The controller prevents the electric motor from being driven when the detection switch detects the storage posture.

A reciprocating power tool comprising a first blade and a second blade, wherein the first blade is driven by a first shaft assembly, wherein the second blade is driven by a second shaft assembly, wherein the first and second blade assemblies are reciprocally driven by a cam shaft, wherein the first shaft assembly defines a first moment of inertia, wherein the second shaft assembly defines a second moment of inertia, and wherein the first and second moments of inertia are within 5% of one another.

A working machine may include: a first blade; a second blade overlapping with the first blade in an up-down direction; and a holding unit configured to hold the first blade and the second blade overlapping each other in the up-down direction. The first blade may be configured to reciprocate in a direction perpendicular to the up-down direction with respect to the second blade. The first blade may include a first elongated hole having a longitudinal direction along the reciprocating direction. The second blade may include a second elongated hole having a longitudinal direction along the reciprocating direction. The holding unit may include: a holding part inserted in the first elongated hole of the first blade and the second elongated hole of the second blade; and an outer sleeve having a cylindrical shape and supported by the holding part such that the outer sleeve is rotatable around the holding part.