A temporary cable horizontal lifeline (HLL) kit for fall protection includes a wire cable and a ratchet tensioner with adjustable length webbing that includes a first end portion with a first carabiner and a second end portion with a second carabiner. The kit further includes a first energy absorber, a first clamp and a second clamp, a first shackle and a second shackle, and a first end anchorage connector and a second end anchorage connector.

In an illustrative embodiment, systems and methods for verifying safety compliance of a worker positioned on a building structure utilize a motion detector module (MDM) for attaching to a wearable safety harness, where the harness has a lifeline attachment feature for connecting the safety harness to a lifeline anchored to the building structure. The MDM may include a motion sensor for detecting movement of the worker and processing circuitry for detecting, from signals provided by the motion sensor, significant movement indicative of the safety harness being properly worn by the worker and/or proper attachment of the safety harness to a lifeline, and translating the significant movements into compliance information. The MDM may include a proximate sensor for detecting contact between the attachment feature on the harness and a fastener on the lifeline for verifying the compliance information.

The invention is a rapidly adjustable, inherently safe, mobile climbing tree stand with harness of the type used by hunters to ascend and descend a tree and to furthermore remain seated in a fall protected mode while at height in a tree. The inherently safe tree stand has redundant fail safe fall protection and utilizes ANSI standard arborists ge

A harnesses for fall protection and methods of manufacturing the same are provided. The harness includes a horizontal connecting webbing with a force receiving mechanism. The horizontal connecting webbing including a first horizontal receiving loop at a first end of the horizontal connecting webbing. The harness also includes a first upper webbing configured with a upper webbing loop that is engaged with the first horizontal receiving loop at the first end of the horizontal connecting webbing. The harness further includes a first lower webbing configured with a lower webbing loop that is engaged with first horizontal receiving loop at the first end of the horizontal connecting webbing. The first upper webbing and the first lower webbing are independent of one another. A corresponding method of manufacturing the harness is also provided so as to withstand various large forces during operation.

Various embodiments are directed to safety device connector apparatuses for use with a wearable safety harness. A safety device connector apparatus may comprise a base portion operable to attach to a strap of the wearable safety harness, the base portion comprising a base attachment pin fixedly secured thereto; a connector element configured to be detachably coupled to the base portion via a connector element detachable base interface comprising a connector interface opening and configured to engage the base attachment pin, wherein engaging the base attachment pin comprises receiving the base attachment pin within the connector interface opening; wherein the connector interface opening comprises an angled notch configuration configured to facilitate a movement of the base attachment pin relative to the connector interface opening; and wherein the connector element is configured to detach from the base portion based at least in part on a load force acting on the connector element.

Apparatus and associated methods relate to fall-protection safety connector having alignment indicators located on both a static end and a dynamic end of a deformable energy-absorbing device that when deformed visually presents the alignment indicators as misaligned. In an illustrative embodiment, the fall-protection safety connector may be configured to securely connect to a securement member. In some embodiments, a user may connect to the fall-protection safety connector by attaching a lanyard to an aperture coupled to the dynamic end of the deformable energy-absorbing device. Before using the fall-protection safety connector, the user may visually inspect the alignment of the alignment indicators to ascertain the readiness of the connector. Misaligned alignment indicators may advantageously indicate to the user that the remaining energy-absorbing deformation capability of the connector may be below a predetermined specification.

A carabiner for carrying equipment is disclosed. The carabiner includes a hook assembly including a generally C-shaped body having an opening which is closed by an openable gate. It further includes a mounting assembly, which includes a mounting boss to which the body is releasably connected, and one or more fasteners to connect the mounting boss to a base component. The mounting boss may include a bore through which the body passes, the body being a close fit in the bore, such that the body can pivot respect to the boss about an axis of the bore. Control components may be provided that serve to resist movement of the body within the bore. The carabiner may be installed in a harness, by connecting the base to a component of the harness for example by passing a fastener through a hole in the component.

A fall protection cable system configured for installation of a roof on a steel building includes a starting support post, a final support post, and a support cable. The starting support post is configured for attachment to a first side of the steel building and has a bottom starting end configured to attach to the first side of the steel building and a top starting end extending above the roof. The final support post is configured for attachment to a second side of the steel building and has a bottom final end configured to attach to the second side of the steel building and a top final end extending above the roof on the second side. The support cable is configured to be connected at an elevated position above the roof of the steel building between the top starting end and the top final end.

The present disclosure relates to a portable device for hoisting/lowering/storing a rope from a tall structure, such as a wind turbine. The device is formed of an assembly of a rope storage container and a rope driver reversibly connected thereto. The rope storage container defines a rope storage volume bound between a bottom surface and an outer side wall. The rope driver is reversibly connectable to the container and comprises a rope passage having a dimension matching a diameter of the rope. The passage is formed between a pair of adjacent rollers or between a drive coil and a clamp. The rope is driven (hoisted and stored or provided and lowered) by an electric motor arranged to drive at least one of the rollers or the drive coil.

A bridge rope assembly includes a main body comprising a rope that has a first end and a second end. The rope has a splice therein to form an eye loop in the main body. The eye loop is configured to engage a first bridge loop of a harness. The main body comprises a first portion including the first end and a second portion including the second end. The first portion extends through the second portion of the main body such that the first end is positioned adjacent to the second end. A distance between the first and second ends is less than 2.0 inches.