A lanyard assembly for an evacuation system may comprise a lanyard body and a pin housing. The lanyard body may comprise an actuator connect portion, a pin housing connect portion, and a center member extending between the actuator connect portion and the pin housing connect portion. The pin housing may be slidably coupled to the pin housing connect portion of the lanyard body.

Lacing engine systems, apparatus, and methods of operation are discussed. In an example, a lacing engine apparatus can include a housing, a drivetrain, and a lace take-up mechanism for retracting a length of lace cable upon activation. The drivetrain can include various reduction gears to reduce rotational speed out of the motor and power the lace take-up mechanism. The lace take-up mechanism can include structures such as a double-yoke, a radial pulley including an outer rotating disc and an inner stationary disc, a variable take-up spool, or a zip-strip mechanism.

The specification discusses various lacing engine configurations for use in an automated footwear platform. For example, lacing engines with mechanisms to detect lace cable position and/or lace cable tensions are discussed. In an example, the lacing engine can include a housing, a lace spool and a detection mechanism. The lace spool can be at least partially disposed within the housing, and be adapted to collect a portion of the lace cable in response to rotation in a first direction during tightening of the footwear platform. The detection mechanism can detect a state of the lace cable manipulated by the lacing engine.

In an example, a lacing engine apparatus can include a housing and a drivetrain. The housing can be securable within a footwear article. The drivetrain can include a motor, a sun gear, a planet gear, a rotating ring gear, and a spool. The spool can be secured to the ring gear and can be rotatable therewith. The spool can be configured to control a lace of the footwear article and can be configured to wind the lace as the ring gear rotates in a first direction.

A length adjusting device includes: a body having sides extending in spaced relation to one another, the sides defining respective planes; a first cam operably assembled in relation to the body and having a first proximal cam end positioned between the sides; a second cam operably assembled in relation to the body and having a second proximal cam end positioned between the sides and adjacent to the first proximal cam end; an axle that rotatably attaches the second cam to the body; a channel formed by a space between the cam ends; a handle attached to the body and rotatable from a first position to a second position about a rotation point upon application of a first force; wherein the body is configured to rotate with respect to the second cam to expand the size of the channel upon the application of the first force exerted on the handle.

A cleat includes two cams (36) comprising mutually opposed convex surfaces rotatable about parallel axes which extend vertically in a rope-trapping position of the cleat, to bring the arcuate surfaces together and apart. The cams (36) are urged towards each other to trap a rope (66) therebetween. Each cam is also mounted to a horizontal cylinder (2) for rotation about an axis of the cylinder, in order to allow the rope (66) to rotate the arcuate surfaces by pulling in a line above this horizontal axis and to free the rope.

An apparatus for securely joining ropes for rope suspension or payload tie down. The apparatus includes a two substantially identical channel assemblies configured having a first bend to form a rope groove on one end and a second bend to form a cam channel on the other end, the cam channel having a rivet hole and a pin therethrough to enable a cam to rotate therein, and an attachment mechanism to secure the channel assemblies back-to-back thereto. By opening the cam of either assembly, a rope may be threaded through the rope grove, then again on the opposite assembly. The rope can be pulled from its end away from the assemblies to tighten prior to closing the cam(s) upon the ropes. The rope can further be secured by continuing to pull after the cam has been closed, or by using an optional tightening mechanism and method. A method of tying down cargo or rope suspension using the apparatus of the disclosure for uses such as general-purpose camping, hiking, and other general-purpose tie-down and/or suspension uses of ropes. A method of tightening one or more ropes using the tie-down apparatus disclosed.

A tissue button includes a body, a door, and a cross-pin that secures the door to the body. The door pivots relative to the body between an open position and a closed position. A first portion of a suture can be pulled when the door is in the open position, and a second portion of the suture cannot be pulled when the door is in the closed position. A cross-section of the cross-pin taken perpendicular to a longitudinal axis is non-circular.

A cord stopper for moving along a length of cord and releasably engaging the cord includes a body delimiting a channel for passing the cord through the body. The channel defines a first path and a second path for the cord, with the paths being selectable by rotating the body relative to the cord. A cord engagement portion provided along the first path is configured to engage the cord such that movement of the cord stopper along the cord is restricted when the first path is selected. A cord passing portion in the channel is configured to permit the cord stopper to move along the length of the cord when the second path is selected. Further provided are a cord stopper assembly including the cord stopper and the cord, and methods. Methods of using and manufacturing the cord stopper.

An article of footwear comprises an upper defining an interior void, a sole structure attached to the upper, a cable attached to the upper and moveable in a tightening direction to decrease a volume of the interior void of the upper and in a loosening direction to increase a volume of the interior void of the upper, and a locking device operable between a locked state to prevent movement of the cable and an unlocked state to permit movement of the cable, the locking having a housing attached to one of the upper and the sole structure and receiving the cable therethrough. The housing includes a pulley rotatably disposed therein, whereby the pulley is engaged by the cable and configured cooperate with the housing to provide audible or tactile feedback when the pulley is rotated by cable.