A cable gland and method for earthing, bonding, and electromagnetic capability with armored, metal-clad, and metallic-sheathed cable types. The cable gland includes compressible fingers with the ability to compress or expand about a cable inserted in and through the cable gland, and an adjustable earthing coil arranged internally inside a part of the cable gland that secures around a cable inserted in the cable gland. When fully coiled, the adjustable earthing coil is relaxed and as the adjustable earthing coil is expanded it generates a restoring force. An earthing strap attached to the adjustable earthing coil in the cable gland, provides grounding capabilities to the cable gland.

Cable gland for guiding a cable through a wall opening, comprising a body element extending along a longitudinal axis and having an internal cable duct extending along the longitudinal axis, a clamping portion arranged on the body element and having a plurality of clamping elements, a tubular sealing element arranged inside the cable duct and connected to the body element, and a cap nut having an axial opening at one end which is mechanically coupled with the body element, wherein the body element is formed from a first material and the cap nut is formed from a second material, wherein the first material and the second material are injection moulded on to one another.

In some embodiments, a lanyard organizing tool is provided comprising a plurality of retainer dust caps connected to an organizing chord, with reach retainer dust cap being releasably connectable to a terminating connector of a fiber optic cable. The retainer dust caps may be formed with release components that can be manually squeezed, or depressed, by an operator using one hand to release a connector from the chord conveniently, in order to connect the connector to an intended receiving port. Methods of using the lanyard organizing tool are also provided.

The present invention provides, in various embodiments, a push on cap for an electrical cable that can be both temporary and permanent. The cap includes an extension that can be folded back for temporary installation of the cap on the cable, and unfolded onto the cable for permanent installation.

An assembly system includes a feeding mechanism configured to feed a heat shrinkable tube, a cutting mechanism adapted to cut off a segment of heat shrinkable tube from the heat shrinkable tube, a robot adapted to grip the segment of heat shrinkable tube, and a vision system adapted to visually guide the robot to assemble the segment of heat shrinkable tube onto a wire of an electrical product.

A holding structure with an insulation cap includes a corrugated tube which sheathes a trunk included in a wire harness and which has an outer circumference provided with a recess and a protrusion alternately arranged in a longitudinal direction. The insulation cap is attached to an end of a branch included in the wire harness and is provided with a protrusion which fits in the recess of the corrugated tube. The protrusion of the insulation cap is engaged with the recess of the corrugated tube, and a tape is wound around the insulation cap and the corrugated tube.

A waterproofing structure 20 for a core wire exposed portion of an electrical wire includes: an electrical wire 10 that includes a core wire exposed portions 12a; an internal waterproofing portion 21 that encloses the core wire exposed portion 12a to waterproof the core wire exposed portion 12a; and an exterior member 30 that forms a space S that is separated from an external space, around the internal waterproofing portion 21.

A cap is provided that is designed to facilitate the guidance of one or simultaneously more elongated elements, such as cables, hoses or conduits, which can be at least partially loaded in shear, through a hose, pipe or duct. The cap has an elongated sleeve-shaped section and a closed and at least externally rounded head section. The sleeve-shaped section and the head section have an inner wall defining a cavity that is open on a side opposite the head section. The cavity has a clamping section in which the cross-section of the inner wall tapers toward the head section. The cross-section of the cavity widens in a step-like manner at the end of the clamping section where this section is at its smallest diameter. This forms a circumferential clamping edge at which the elongated elements jam when they are inserted into the cavity.

The present invention provides, in various embodiments, a push on cap for an electrical cable that can be both temporary and permanent. The cap includes an extension that can be folded back for temporary installation of the cap on the cable, and unfolded onto the cable for permanent installation.

While laying a subsea cable, an exposed cut off end of the cable is exposed to water prior to permanently sealing off this cable end. To prevent damage to the cable due to contact with the often salt water, due to for example oxidation, a temporarily watertight seal is to be applied to the cut off end. A method for applying this seal is provided which comprises applying a mouldable sealant to the exposed end wherein the sealant acts as a watertight barrier between the water and the cut off end of the cable. The sealant may comprise an intermediate layer between the cut off end and a watertight outer layer arranged to increase adhesion between the cut off end and the outer layer. This allows a broader range of outer layer materials to be used as the outer layer material does not need to adhere directly with the cable.