An actuator primarily activated by transversal acceleration arising from rotational acceleration of a rotatable object is presented. The object is rotatable in a plane of rotation (P) about an object pivot point in the plane of rotation (P). The actuator comprises at least two bodies adapted to be rotatably, in or parallel to the plane of rotation (P), coupled to the object at a body pivot point of each body. The body pivot point and/or the body is arranged such that a mass distribution of the body is nonuniform about the body pivot point. Due to said nonuniform mass distribution about the body pivot point, the actuator is configured to transition to an activated state, in response to rotational acceleration of the object, by said at least two bodies rotating about their respective body pivot points in a direction opposite to a direction of said rotational acceleration of the object.

Safety brake for multi-segment telescopic mast of the type used in masts of lighting, surveillance or communication towers, having at least one retractable reel fixed jointly on the top of an external segment of the telescopic mast of the lighting, surveillance or communication tower, in which a tape, or rope is wound, terminated by its free end in a fixing piece, fixed jointly on the inner lower part of an internal segment of the telescopic mast, passing the tape, or rope in the gap between both segments, providing the retractable reel for winding and unwinding the belt, or rope, having to detect an acceleration greater than a preset in the removal of the tape, or rope, and having to block the tape, or rope in case of acceleration greater than a preset in the removal of the tape, or rope.

Safety brake for multi-segment telescopic mast of the type used in masts of lighting, surveillance or communication towers, having at least one retractable reel fixed jointly on the top of an external segment of the telescopic mast of the lighting, surveillance or communication tower, in which a tape, or rope is wound, terminated by its free end in a fixing piece, fixed jointly on the inner lower part of an internal segment of the telescopic mast, passing the tape, or rope in the gap between both segments, providing the retractable reel for winding and unwinding the belt, or rope, having to detect an acceleration greater than a preset in the removal of the tape, or rope, and having to block the tape, or rope in case of acceleration greater than a preset in the removal of the tape, or rope.

Described herein is a system, method of use and Self Retracting Lifeline (SRL) apparatus using a system that governs a dynamic response between members causing a halt in relative motion between the members. Magnetic interactions, eddy current drag forces and centrifugal and/or inertial forces may provide various mechanisms of governing movement.

Described herein is a system, method of use and Self Retracting Lifeline (SRL) apparatus using a system that governs a dynamic response between members causing a halt in relative motion between the members. Magnetic interactions, eddy current drag forces and centrifugal and/or inertial forces may provide various mechanisms of governing movement.

The invention relates to a braking mechanism (10) for an electric drive motor (1), in particular a drive motor (2) comprising an armature shaft (5) that protrudes from a motor housing (2); the braking mechanism (10) comprises at least one braking element (17) and an energy store, the energy store permanently applying a braking power to a frictional surface of the braking element. The braking mechanism (10) is characterized in that the energy store and the braking element (17) are made of the same material as a single piece.

The invention relates to a braking mechanism (10) for an electric drive motor (1), in particular a drive motor (2) comprising an armature shaft (5) that protrudes from a motor housing (2); the braking mechanism (10) comprises at least one braking element (17) and an energy store, the energy store permanently applying a braking power to a frictional surface of the braking element. The braking mechanism (10) is characterized in that the energy store and the braking element (17) are made of the same material as a single piece.

A rotary actuator has a stop module configured to mechanically link two gear stages travelling at different rotational speeds when an end-of-stroke travel limit is reached, thereby causing the rotary actuator to bind because relative motion between the gear stages is impeded.

A rotary actuator has a stop module configured to mechanically link two gear stages travelling at different rotational speeds when an end-of-stroke travel limit is reached, thereby causing the rotary actuator to bind because relative motion between the gear stages is impeded.

A brake system for use in shaft and inclined conveyor systems in mining, with several brake channels for releasing or applying brake force generators to provided braking surfaces (2), wherein a first main pressure control path and a second secondary pressure control path, which is activated in the event of a fault in the main pressure control path, are provided for each brake channel and wherein a plurality of, preferably safe, central processing units (CPUs) with associated signal and voltage supply are provided for redundant control of the main and secondary pressure control paths of the several brake channels, wherein each, preferably safe, CPU is provided for controlling the main pressure control path of at least one brake channel associated therewith, as well as a secondary pressure control path of at least one other of the plurality of brake channels.