Methods and systems for assembling customizable solderless cables for direct current (DC) transmission of electricity to an electronic device. The systems and methods utilize shielded co-axial cable defining first and second opposed ends which may be cut to a desired length as selected by the user. Connectors, which may have a conventional 2.1 mm×5.5 mm DC plug design, include a barrel portion defining a threaded axial passageway. In use, the threaded passageway of the plug is twisted upon a respective end of the cable such that the end of the cable becomes threadedly seated thereinto and in electrical contact with the plug to form two dedicated electrical connections. A respective other plug is mounted on the other respective end of the cable in the same manner to thus define the customizable cable. A single length of cable or a plurality of wire segments and plugs may be sold as a pre-packaged unit for use in making a plurality of customizable DC cables.

A grommet for use in a cable fitting includes a body having a bore substantially therethrough and a resilient membrane located within the bore. The resilient membrane is elastically deformable from a receiving position before the cable is inserted into the bore, to an inserted position, after the cable is fully inserted into the bore. In the receiving position, the resilient membrane is substantially conically shaped having an apex substantially coincident with an insertion opening of the body, and, the resilient membrane is axially displaced during the insertion of the cable to an inverted position with respect to the receiving position where the apex is oriented away from the insertion opening. The resilient membrane has a thinner membrane portion extending from the apex towards the bore to provide a controlled tear during cable insertion. The body has an exit opening which comprises resilient gripping teeth projecting axially from the body with an axially extending resilient foldable membrane located between at least two adjacent resilient teeth and foldable therebetween when they are radially compressed. Once force is applied by the axial movement of the fitting assembly onto a tapered surface of the grommet, the flexible gripping members radially collapse towards an inserted cable. The combination of the resilient membrane and the axially extending teeth separated by a foldable membrane allow for an increased friction fit and sealing interface on the cable. The grommet may be assembled in a strain relief connector having a nut, a connector body and optionally an insert. The insert has a removed section longitudinally coincident with a gripping surface facilitating movement of the gripping surface towards the cable.

An electrical adapter is disclosed for connecting a connection contact of a circuit breaker with an associated contact piece of an electrical circuit along which the circuit breaker has to be inserted, including a hollow tubular element having a first end portion and a second end portion configured to be electrically connected to a connection contact and a contact piece, respectively, an inner cavity of the hollow tubular element having, at the first end portion, a first frusto-conical shape. A first connector having a hollow deformable body and configured to be accommodated inside the first end portion. A locking body configured to be securely placed along the inner cavity of the hollow tubular element. A second connector including a first connection portion configured to be accommodated inside the first end portion of the hollow tubular element.

An electrical adapter is disclosed for connecting a connection contact of a circuit breaker with an associated contact piece of an electrical circuit along which the circuit breaker has to be inserted, including a hollow tubular element having a first end portion and a second end portion configured to be electrically connected to a connection contact and a contact piece, respectively, an inner cavity of the hollow tubular element having, at the first end portion, a first frusto-conical shape. A first connector having a hollow deformable body and configured to be accommodated inside the first end portion. A locking body configured to be securely placed along the inner cavity of the hollow tubular element. A second connector including a first connection portion configured to be accommodated inside the first end portion of the hollow tubular element.

A cable locking device includes a first part and a second part. The first part includes a first cavity for receiving a first electrical wire and a second cavity. The second part includes a first cavity for receiving a second electrical wire and a projection. The projection is configured to be inserted into the second cavity of the first part. A first channel is formed within the second cavity of the first part and extends from an opening of the second cavity. A second channel is formed within the second cavity of the first part and is connected to the first channel and extends in a transverse direction of the first channel. A pin is formed on the projection of the second part and is configured to fit within the first channel and the second channel of the first part. The pin is configured to engage sidewalls of the second channel so as to frictionally hold into place the pin with respect to the second channel to connect the first part to the second part.

An electrical connection device comprises a cable, a ferrule, and a first electrical contact. The cable has an outer conductor surrounding an inner conductor. The ferrule is mechanically connected to the outer conductor. The first electrical contact is electrically connected to the inner conductor.

A connector for a photovoltaic cell includes a conductive portion and an insulating portion, wherein the conductive portion is wrapped with the insulating portion; the conductive portion includes a conductor and a cable line, and a retaining ring is arranged on the outer circumferential surface of the conductor; the insulating portion includes a shell body, a basket-shaped fastener and a front sleeve; a first inner step surface and a second inner step surface are arranged in an inner cavity of the shell body; the front sleeve has an annular head part which sleeves the conductor; a first outer step surface is arranged at a tail part of the front sleeve, and props against the first inner step surface; the inner diameter of the head part of the front sleeve is larger than the outer diameter of the conductor and less than the outer diameter of the retaining ring.

A connector for a photovoltaic cell includes a conductive portion and an insulating portion, wherein the conductive portion is wrapped with the insulating portion; the conductive portion includes a conductor and a cable line, and a retaining ring is arranged on the outer circumferential surface of the conductor; the insulating portion includes a shell body, a basket-shaped fastener and a front sleeve; a first inner step surface and a second inner step surface are arranged in an inner cavity of the shell body; the front sleeve has an annular head part which sleeves the conductor; a first outer step surface is arranged at a tail part of the front sleeve, and props against the first inner step surface; the inner diameter of the head part of the front sleeve is larger than the outer diameter of the conductor and less than the outer diameter of the retaining ring.

A strain relief connector assembly for flexible electrical wiring is provided that includes an adapter that is configured to form a sealed connection to the wiring and a connector and to form a connection with a strain relieving device, which can include an arc of bend control mesh.

A strain relief connector assembly for flexible electrical wiring is provided that includes an adapter that is configured to form a sealed connection to the wiring and a connector and to form a connection with a strain relieving device, which can include an arc of bend control mesh.