A cable gland for securing a cable to a box comprises a tightening element configured to surround the cable, the tightening element having at least two connecting ends mutually approachable to tighten the tightening element on the cable, and a gland body extending along an axial direction between a first end and a second end, the gland body defining a passing through channel extending along the axial direction between the first end and the second end and configured to receive the cable passing through the first and second ends, the gland body surrounding at least partially the tightening element. The cable gland comprises a first locking arrangement configured to lock along the axial direction the gland body relative to the tightening element.

A cable gland for securing a cable to a box comprises a tightening element configured to surround the cable, the tightening element having at least two connecting ends mutually approachable to tighten the tightening element on the cable, and a gland body extending along an axial direction between a first end and a second end, the gland body defining a passing through channel extending along the axial direction between the first end and the second end and configured to receive the cable passing through the first and second ends, the gland body surrounding at least partially the tightening element. The cable gland comprises a first locking arrangement configured to lock along the axial direction the gland body relative to the tightening element.

An apparatus includes a strain relief formed in helical shape and formed with a U-shaped channel. The strain relief can be used around a cable of a component or a spool extension of a fiber tray.

An electrical conductor assembly for a rotor blade includes a substrate and at least one electrical conductor. The substrate includes an inboard end portion and an outboard end portion. The at least one electrical conductor is attached to the substrate and extends between the inboard end portion and the outboard end portion. The at least one electrical conductor is configured to transmit electricity along a length of the rotor blade. The inboard end portion and the outboard end portion are structured such that when the electrical conductor assembly is installed within the rotor blade, the inboard end portion is securable relative to the rotor blade and the outboard end portion is movable relative to the rotor blade.

An electrical conductor assembly for a rotor blade includes a substrate and at least one electrical conductor. The substrate includes an inboard end portion and an outboard end portion. The at least one electrical conductor is attached to the substrate and extends between the inboard end portion and the outboard end portion. The at least one electrical conductor is configured to transmit electricity along a length of the rotor blade. The inboard end portion and the outboard end portion are structured such that when the electrical conductor assembly is installed within the rotor blade, the inboard end portion is securable relative to the rotor blade and the outboard end portion is movable relative to the rotor blade.

An electrical junction box comprises an electrically conductive housing and at least one cable end wherein an everted braided shield section of the cable end is received in a retainer section of the housing and an electrically conductive adhesive is provided.

A wire harness including: a wire; a ring-shaped electromagnetic wave absorber including a through hole through which the wire passes; and a fixing member for fixing the electromagnetic wave absorber to the wire, wherein: an inner circumferential surface of the through hole opposes an outer circumferential surface of the wire, in a view of the electromagnetic wave absorber along a central axis of the through hole, the inner circumferential surface of the through hole has a first portion and a second portion arranged at a position point-symmetrical to the first portion with respect to the central axis of the through hole, and the fixing member fixes the electromagnetic wave absorber to the wire such that the wire is in contact with the first portion and is separated from the second portion.

The present disclosure discloses a protective sleeve used for matching with a cable of a cable connector. The protective cover is used to be fixed on the cable to prevent the cable from being excessively bent. The present disclosure also discloses a cable connector assembly having the protective sleeve. Compared with the prior art, the present disclosure is capable of preventing the cable from being excessively bent by providing the protective cover fixed on the cable.

Provided are load bearing universal adaptors for connecting electrical cables in a watertight configuration. The mechanical advantage associated with wedges in a tapered cavity ensures that load is appropriately transferred to the walls of the wedge housing. In this manner, a load applied to the electrical cable is at least partially provided to the walls of the system rather than acting to pull the cable out of the adaptor, and the object to which the adaptor is connected, such as a terminal block.

A poke-in terminal includes a main body, a tab terminal socket at a mating end, and a wire socket at a terminating end. The tab terminal socket includes walls forming a tab terminal receptacle configured to receive a tab terminal. Upper and lower beam contacts extend into the tab terminal receptacle to interface with the tab terminal. The wire socket includes walls forming a wire receptacle configured to receive a wire. Poke-in retention beams extend into the wire receptacle to interface with the wire when poked into the wire socket. The wire socket includes a wire release element configured to be actuated to release the poke-in retention beams from the wire.