An article for coupling bands, cords, straps and the like to bundle items. The coupling article comprises a body having at least two end sections each having a cutout and passage means formed therethrough to removably retain a portion of a tensile line. A user may use an end section of the coupling article to engage a first portion of a closed-loop tensile line, encircle one or more objects, and engage a remaining portion of the closed-loop tensile line with an opposing end section, thus holding the objects together. A user may also secure objects using the coupling article in combination with an open-loop tensile line by wrapping the tensile line around a first end section, within the cutout and securing with a knot. With the remaining open-loop tensile line, the user would encircle one or more objects, and then wrap the open-loop tensile line around a second end section, within the cutout and secure with a knot. The coupling article may be constructed of plastic, metal, or other rigid material to meet the needs of the application. The dimensions of the coupling article may be of varying size depending on the desired compressive force needed on the objects, and the size and strength of the tensile line.

A strap tie includes a body including a receiving channel and a strap engagement member. The receiving channel extends through the body. The receiving channel is configured to receive a remote strap. The engagement member is configured to engage a movement restriction member of the remote strap to prevent translation of the remote strap away from the body. The strap extends from the body. The strap includes a proximal end attached to the body, a distal end opposite the proximal end, and a plurality of movement restriction members. The rotational element of the body is configured to removably couple to a base to allow the strap tie to rotate relative to the base.

This document describes a saddle that adjusts to a bundle diameter. In some aspects, the saddle is a component of a cable-tie mounting assembly and forms a mounting surface, which is flexible to support a bundle. The saddle includes an aperture for receiving a cable tie. The saddle also includes at least one laterally-extending distal flexible tab that is flexible to conform to a bundle diameter based on a force applied by the cable tie disposed within the aperture and tensioned around the bundle to secure the bundle to the mounting surface of the saddle. The flexibility of the saddle surface to adjust into mating contact with the bundle (i) significantly reduces gaps created between the bundle, the cable tie, and the distal flexible tab and (ii) provides side support, preventing rotation and lateral movement of the secured bundle and reducing the likelihood of damage to the bundle.

A flexible strap connector is disclosed. The connector comprises a strap having a buckle head at one end and a tongue at the opposite end. Ratchet teeth extend on one side of the strap and the ratchet teeth cooperate with the buckle head to permit movement of the strap in a first direction and to prevent movement of the strap in a second direction. A second slot is formed in the strap itself and it is a non-locking slot. When the strap is in the second slot, the strap is free to move further into the slot and free to be withdrawn from the slot. Embodiments where the buckle head and ratchet teeth are replaced with hook and loop fasteners are also disclosed.

A flexible strap connector is disclosed. The connector comprises a strap having a buckle head at one end and a tongue at the opposite end. Ratchet teeth extend on one side of the strap and the ratchet teeth cooperate with the buckle head to permit movement of the strap in a first direction and to prevent movement of the strap in a second direction. A second slot is formed in the strap itself and it is a non-locking slot. When the strap is in the second slot, the strap is free to move further into the slot and free to be withdrawn from the slot. Embodiments where the buckle head and ratchet teeth are replaced with hook and loop fasteners are also disclosed.

A flush cut tie device facilitates flush trimming of excess after securing a tie device. The device includes a tie and a channel coupled to a first end of the tie. A projection is positioned in an interior of the channel. A plurality of ridges is positioned in spaced relationship along a length of the tie wherein one of the ridges is engaged by the projection when a second end of the tie is extended through the channel. A pair of grooves extends into opposite exterior faces of the channel wherein the grooves are positioned for facilitating engagement of clippers to the channel and cutting an end portion of the channel and the tie from a main portion of the channel. Thus, a cut end of the tie is flush with the main portion of the channel when the end portion of the channel is clipped.

A restraint may include a longitudinal body having a first end and a second end. The restraint may also include a plurality of engagement features distributed between the first end and the second end. A dimension of at least one of the longitudinal body and the plurality of engagement features may vary along at least a portion of a length of the longitudinal body. The restraint may further include a head disposed at the first end of the longitudinal body. The head may define an aperture and may include a pawl that configured to individually engage the plurality of engagement features. The dimension may vary incrementally or continuously along at least the portion of the length of the longitudinal body from the first end to the second end.

A securing device (10) for securing a first object (320) relative to a second object (322), the securing device (10) being configured to frictionally maintain its position relative to the objects and to itself, includes a device body (12) having a first end (12A), an opposed second end (12B), and a cross-sectional area. The device body (12) is formed from a material so that the device body (12) exhibits tensile strength of greater than four thousand five hundred kPa and less than nine thousand three hundred kPa. The material that forms the device body (12) has an average coefficient of static friction of greater than 0.75 and less than 1.75 relative to itself. A ratio of the tensile strength (in kPa) to the cross-sectional area (in square millimeters) is greater than 40:1 and less than 100:1. The material that forms the device body (12) can include thermoplastic elastomers, and can further include styrene.

An apparatus, system, and method that relate to a self-locking tie with one or more elastomeric features are disclosed. A strap of the self-locking tie includes one or more features that physically anchor the strap to a base of a mold during a multi-stage molding process. These features may include one or more recesses. Side walls of the one or more recesses may be sloped, as defined by anchors with undercut regions that physically engage material of the strap to prevent movement of the strap within a mold cavity of the base as the strap cools and as the strap is exposed between its formation and formation of one or more elastomeric features thereon.

Injection molded parts with a small dimension that exhibit high heat resistance are described. Thermoplastic compositions that can be utilized to form the injection molded parts are described. The thermoplastic composition includes a polyarylene sulfide and a crosslinked impact modifier. The thermoplastic composition can also include siloxane polymers, thermoplastic elastomers, or other additives that can further improve the characteristics of the injection molded parts.