A ribbon cord containment and identifying adaptor can be adaptively anchored or fixed to or removed from a ribbon type cord or ribbon cord of a set of earphones by hand via an anchor slot of the adaptor. The anchor slot can have a frame or structure that has an entrapment chamber and a path leading to a cord entrapment chamber where the entrapment chamber is slanted with respect to the path leading to the entrapment chamber. The structure of the entrapment chamber and path help anchor the adaptor on the ribbon type cord segment to prevent inadvertent dislodgement of the adaptor from the cord segment. The structure of the anchor slot is rigid and serves to firmly grip or compress cord segments positioned between gapped-apart opposing sidewalls within the anchor slot. When a cord containment adaptor is anchored via the anchor slot, ribbon type cord segments can be gripped into slots in a manner that helps prevent the adopter from dislodging from the ribbon cord. When positioned on cord segments, the adaptors can serve as identifying objects or adaptors.

A cable tensioning system including: a body defining a balance point; a cable receiving area having gripping elements configured to grip and bias a cable relative to the cable tensioning system; and a sensor configured to sense changes to a balance of the body about the balance point, wherein the cable tensioning system is configured to maintain the cable within a preset range of tensions.

The utility model patent discloses an electric vehicle charger with a retractable wire. The electric vehicle charger includes a storage box, a winding wheel and a wire; one end of the wire is connected with the charger; the winding wheel is mounted in the storage box; a coil spring and a sliding ring are provided in the winding wheel; and the sliding ring has a conducting ring and a conducting strip. When the winding wheel is rotated, the conducting strip rotate synchronously with the winding wheel; and furthermore, when the conducting strip slides on an outer surface of the conducting ring, the conducting strip and the conducting ring are kept in electric contact. The electric vehicle charger further includes a pull-stop structure; the pull-stop structure includes a limiting gear and a latch; the latch selectively limits the limiting gear; and the limiting gear is an incomplete gear.

A system and method are provided for controlling retraction of a charging cable of a charge cable management system for charging an electric vehicle. The retraction is only allowed after certain conditions are met. These conditions correspond to the end of a charging session, and may relate to determining a connection of a charge plug on a cable used for the charging session with a charge plug dock of the cable management system, determining a release of a charge plug on a cable used for the charging session from a vehicle inlet socket of the vehicle that was being charged, determining a retraction state of the cable, receiving a user input related to ending the charging session or any combination thereof.

A reeling device for the controlled coiling and uncoiling of a cable has a first end that is fixed and a second end that is movable relative to the first end. The cable is unbroken between its first and second ends. The reeling device includes first and second reels about which the cable is coiled. The first and second reels are coaxial. The first reel is fixed against rotation and axial movement, and the second reel is rotatable about the axis with such rotation causing axial movement of the second reel relative to the first reel.

A multi-core cable core aligning device is composed of a temporary holding mechanism, which is configured to arrange tips of a plurality of cores exposed at one end of a multi-core cable in a row along a predetermined arranging direction, and temporarily hold each one of the plurality of cores in such a manner as to be movable along the predetermined arranging direction, a transferring mechanism, which is configured to transfer the plurality of cores one by one while separating the plurality of cores held by the temporary holding mechanism one by one from other ones of the plurality of cores, and an aligning mechanism, which is configured to align and hold the plurality of cores with a predetermined space between adjacent ones of the plurality of cores while holding the plurality of cores transferred by the transferring mechanism one by one at spaced intervals.

The invention relates to an energy chain for receiving and guiding cables, having pivotal chain links which adjoin one another in the longitudinal direction and each of which has cross members and comprises two side pieces lying opposite each other in a direction (q) transverse to the longitudinal direction (I), wherein the energy chain (5) includes a plurality of sections, each of which is designed in the form of two strand (7, 8) that are connected together by a deflecting region (6) extending about a deflecting arc. The energy chain can be moved about the deflecting arc, and each deflecting region (6) of the plurality of sections is guided on the inner face and the outer face thereof through guide elements (10) extending in an arc-shaped manner about the respective axis of the deflecting arc.

Techniques are disclosed for systems and methods for providing a wired connection between a ground-based robot and a controller. A cable handling system for a robot may include a base housing, a cable cartridge removably connected to the base housing, a control cable housed at least partially within the cable cartridge, and an outfeed assembly coupled to the base housing and configured to deploy the control cable from the cable cartridge. The control cable may be deployable from the cable cartridge to maintain a wired connection between the robot and a controller. The outfeed assembly may be configured to couple to a drive mechanism of the robot such that movement of the drive mechanism deploys the control cable from the cable cartridge. The outfeed assembly may be configured to deploy the control cable from the cable cartridge regardless of the direction of movement of the drive mechanism.

A method of controlling operation of equipment that spools cable on and off a rotatable drum, in one or more embodiments, includes obtaining video data of a position of the cable on the rotatable drum. The method can also include feeding data into a trained artificial neural network and processing the data fed into the trained artificial neural network to determine at least one of a calculated position of the cable on the rotatable drum, a calculated fleet angle, or both. The method can also include actuating the rotatable drum to one of spool cable on and off the rotatable drum.

A rotary wire-receiving rack includes a winding structure, a shaft, a first handle, a lid, a locking slider, and a second handle. The winding structure includes two bars arranged longitudinally in parallel and two rods arranged horizontally in parallel for winding cables. Both ends of the two rods are linked to the bars respectively. The shaft is arranged parallel to and located between the rods. The shaft is pivoted on the bars. The first handle and the lid are respectively fixed at the two ends of the shaft. The lid has a locking hole, and the locking slider is slidably installed on the shaft near the locking hole. The locking slider is formed with a locking pin that cooperates with the locking hole. The second handle is pivoted at the end of the bar which closing to the locking hole and having a recess for clamping a cable.