A torque limiter and no-back assembly comprises an input shaft, an output shaft, a torque limiter provided between the input shaft and the output shaft, the torque limiter comprising a torque sensing element; and a no-back device arranged to brake the output shaft when the torque sensing element senses levels of torque above a threshold level between the input shaft and the output shaft, characterised in that the torque sensing element comprises a torsion spring having ends which are coupled to the input shaft and the output shaft for rotation therewith.

A torque limiting device comprises rotationally mounted input and output shafts, an intermediate drive element rotationally coupled to the input shaft and a plurality of jammer elements mounted between the intermediate drive element and the output shaft. A spring mechanism is connected between the input shaft and the intermediate drive element for aligning the intermediate drive element and the input shaft in a driving configuration in which rotation of the input shaft at a torque below a predetermined threshold is transmitted to the output shaft via the jammer element, but in which torque above the predetermined threshold moves the input shaft rotationally relative to the intermediate drive element against the force of the spring mechanism so as to disengage that jammer elements from driving engagement with the output shaft.

An adaptive centrifugal brake assembly is disclosed. The adaptive centrifugal brake assembly controls rotational speed of a shaft. The brake assembly is adaptive and changes braking force based at least in part on torque applied to the shaft and/or the speed of rotation of the shaft. In some embodiments, the adaptive centrifugal brake assembly includes an adaptive mechanism such as a leaf spring that enables the assembly to be adaptive.

An adaptive centrifugal brake assembly is disclosed. The adaptive centrifugal brake assembly controls rotational speed of a shaft. The brake assembly is adaptive and changes braking force based at least in part on torque applied to the shaft and/or the speed of rotation of the shaft. In some embodiments, the adaptive centrifugal brake assembly includes an adaptive mechanism such as a leaf spring that enables the assembly to be adaptive.

Systems and methods for an improved walker are provided. The inventive walker allows for greater control over the speed of the walker. More specifically, wheels having specific characteristics may be used to control the speed of rotation of the wheels. For instance, the wheel may include an inner wheel assembly including a coil or coils, and an outer wheel assembly including a magnet or magnets. A magnetic field may be created using current through the coils, which in turn limits the speed with which the outer wheel assembly can be rotated relative to the inner wheel assembly. The present invention also includes a control system used to control the speed and other characteristics of the walker. The present invention may also collect associated data and display of the same which can help determine future activities associated with the walker.

Systems and methods for an improved walker are provided. The inventive walker allows for greater control over the speed of the walker. More specifically, wheels having specific characteristics may be used to control the speed of rotation of the wheels. For instance, the wheel may include an inner wheel assembly including a coil or coils, and an outer wheel assembly including a magnet or magnets. A magnetic field may be created using current through the coils, which in turn limits the speed with which the outer wheel assembly can be rotated relative to the inner wheel assembly. The present invention also includes a control system used to control the speed and other characteristics of the walker. The present invention may also collect associated data and display of the same which can help determine future activities associated with the walker.

Electric power tools with safety brakes that include impulse solenoids and methods of operating the electric power tools. The electric power tools include an implement holder configured to hold an implement, which is configured to perform an operation on a workpiece. The electric power tools also include a motor, which is configured to actuate the implement holder to move the implement, and a safety brake. The safety brake includes a brake assembly configured to be transitioned between a disengaged configuration, in which the brake assembly permits motion of the implement, and an engaged configuration, in which the brake assembly resists motion of the implement. The safety brake also includes an actuator assembly configured to selectively provide a motive force to transition the brake assembly from the disengaged configuration to the engaged configuration. The actuator assembly includes an impulse solenoid and solenoid drive circuitry.

Electric power tools with safety brakes that include impulse solenoids and methods of operating the electric power tools. The electric power tools include an implement holder configured to hold an implement, which is configured to perform an operation on a workpiece. The electric power tools also include a motor, which is configured to actuate the implement holder to move the implement, and a safety brake. The safety brake includes a brake assembly configured to be transitioned between a disengaged configuration, in which the brake assembly permits motion of the implement, and an engaged configuration, in which the brake assembly resists motion of the implement. The safety brake also includes an actuator assembly configured to selectively provide a motive force to transition the brake assembly from the disengaged configuration to the engaged configuration. The actuator assembly includes an impulse solenoid and solenoid drive circuitry.

A fall protection device includes a frame, a rotatable member being pivotally connected to the frame, a safety belt winding around the rotatable member, a braking plate, and a plurality of braking parts. A side surface of the frame has a connecting hole located on a center of the frame and a plurality of stoppers. The braking plate has a driven shaft passing through the connecting hole to be coaxially connected to the rotatable member. A number of the braking parts is the same as a number of the stoppers. The braking parts are pivotally connected to an inner surface of a plate body of the braking plate. When the braking parts are located at a locking position, an abutting portion of each of the braking parts is located at a position corresponding to one of the stoppers and abuts against one of the stoppers at the same time.

A fall protection device includes a frame, a rotatable member being pivotally connected to the frame, a safety belt winding around the rotatable member, a braking plate, and a plurality of braking parts. A side surface of the frame has a connecting hole located on a center of the frame and a plurality of stoppers. The braking plate has a driven shaft passing through the connecting hole to be coaxially connected to the rotatable member. A number of the braking parts is the same as a number of the stoppers. The braking parts are pivotally connected to an inner surface of a plate body of the braking plate. When the braking parts are located at a locking position, an abutting portion of each of the braking parts is located at a position corresponding to one of the stoppers and abuts against one of the stoppers at the same time.