Systems and methods for providing lifting workers up cell towers are disclosed. The system is useful on stealth cellular towers that do not have external ladders or climbing pegs for aesthetic reasons. The system can include a cable, a system of pulleys, and an internal or external winch. The cable can include a counterweight to enable the cable to be paid out from a storage position at the top of the tower down to the ground under its own weight. Workers can attach a harness or a basket to the cable. The winch can then pull the cable, worker, and/or basket to the top of the tower. The winch can be installed on site or can be provided by an on-site service vehicle. The system can also include a fall arrest system to prevent falls in the event of a component failure.

A safe access system, comprising: a main body configured to attach to mounting hardware on a structure to be accessed; a first connector attached to the main body and configured for connecting to a vertical lifeline; and a second connector attached to the main body and configured for connecting to a power ascender line.

Methods and apparatus for an emergency descent system according to various aspects of the present technology may comprise a cable connector non-slidably connected to an emergency escape cable and a housing connected to the cable connector and configured to enclose a controlled descent system and at least a portion of a length of rope. The housing may comprise an outer protective layer, an inner wall section substantially enclosed by the outer protective layer forming an open interior portion, and a cover configured to be selectively attached to an upper portion of the outer protective layer. The cover may be configured to be selectively attached to an upper portion of the outer protective layer. The cover may be configured to cover at least a portion of the controlled descent system and protect the open interior portion from environmental conditions.

Methods and apparatus for an emergency descent system according to various aspects of the present technology may comprise a cable connector non-slidably connected to an emergency escape cable and a housing connected to the cable connector and configured to enclose a controlled descent system and at least a portion of a length of rope. The housing may comprise an outer protective layer, an inner wall section substantially enclosed by the outer protective layer forming an open interior portion, and a cover configured to be selectively attached to an upper portion of the outer protective layer. The cover may be configured to be selectively attached to an upper portion of the outer protective layer. The cover may be configured to cover at least a portion of the controlled descent system and protect the open interior portion from environmental conditions.

A safety restraint anchor system may include, but is not limited to: a pole portion; a circumferential frame portion disposed about an axis of the pole; and at least one safety line anchor.

A rope-climbing device has an upper assembly with planar side plates spaced apart by a roller, such that the side plates rotate relative to one another about a roller axis, a spine unit comprising planar links of common width each of half the plate spacing, the links pivoted at a central point, and a lower assembly comprising third and fourth side plates spaced apart by a clamp element such that the third and fourth side plates are enabled to rotate relative to one another about the clamp axis, and the clamp element is enabled to clamp a rope between the plates. The device may be opened by aligning pivot points, a rope inserted, and closed on the rope. Engaged on the rope, the device may be set to slide on the rope, or clamp to the rope by action of a user.

A rope-climbing device has an upper assembly with planar side plates spaced apart by a roller, such that the side plates rotate relative to one another about the roller axis, a spine unit comprising planar links of common width each of half the plate spacing, the links pivoted at a central point, and a lower assembly comprising third and fourth side plates spaced apart by a clamp element such that the third and fourth side plates are enabled to rotate relative to one another about the clamp axis, and the clamp element is enabled to clamp a rope between the plates. The device may be opened by aligning pivot points, a rope inserted, and closed on the rope. Engaged on the rope the device may be set to slide on the rope, ar clamp to the rope by action of a user.

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.

A rope control device a main body defining a central opening and first and second side portions, projections extending from the main body, an end recess defined by the first and second projections, an end friction surface formed at a juncture of a projection and the main body, and a bar. With the bar in a first position, the first rope portion is extended through the central opening and at least partly around the bar. With the bar in a second position, the main body and the bar define first and second opening portions of the central opening and the first rope portion is extended through the first and second opening portions and at least partly around the bar. The second rope portion is arranged within the first end recess such that, when the rope is under tension, the second rope portion frictionally engages the first end friction surface.