An arc prevention system including a jack having a receptacle, a modular connector sized to be positioned in the receptacle of the jack, the modular connector including a plurality of contacts, with at least two of the contacts creating an energized electrical path with an external power source in electrical communication with the external power source, a latch extending from a top surface of the modular connector, a switching unit positioned on the latch, a plug unit positioned between the latch and the jack that prevents the modular connector from moving out of the receptacle, a control circuit in electrical communication with switch and the at least two energized contacts, where the electrical path between the control circuit and the switching unit is energized when the plug engages the switching unit on the latch, and the control circuit adjusts the energized electrical path to a predetermined electrical level.

An electrical connector assembly including an electrical connector and a circuit board is provided. The electrical connector has a metallic plate and a plurality of terminals. The metallic plate separates the terminals into two different areas. The metallic plate has a first lateral surface. The circuit board is assembled to the electrical connector. The circuit board has a plurality of pads, a second lateral surface, and top and bottom surfaces opposite to each other. The pads are disposed on the top and bottom surfaces respectively. The second lateral surface is boarded between the top and bottom surfaces. The circuit board further includes at least one grounding circuit exposed from the second lateral surface and facing toward the first lateral surface. The metallic plate is electrically conducted to the grounding circuit by the first lateral surface when the circuit board is assembled to the electrical connector.

A compensating receptacle connector and for terminating a cable assembly of a cabling category and comprising a plug mating zone, a cable mating zone and an intermediate zone. Each of the zones is such that Near End Cross Talk (NEXT) resulting from transmission of the high frequency signal across each zone is below a specified amount chosen such that NEXT introduced by a high frequency signal transmission between via all the zones is below a level as specified for the cabling category.

A male connector (100) includes a contact pad substrate (101) and a connector shell (102). The contact pad substrate (101) includes a linear array of contact pads (103a, 103b, 103c, 103d) that are adapted for aligning with corresponding contacts (103′a, 103′b, 103′c, 103′d) of a contact-bearing tongue (104′) of a corresponding female connector (100′) that conforms to a USB Series A receptacle contact pad pitch specification. The two outermost contact pads (103a, 103d) of the linear array are electrically connected together. The connector shell (102) is formed from an insulating material and comprises a tubular portion (102a) for insertion into the corresponding female connector (100′), and a handling portion (102b) for handling during insertion.

A separator and an electrochemical device including the same. The separator includes an adhesive layer including first adhesive resin particles having an average particle diameter corresponding to 0.8-3 times of an average particle diameter of the inorganic particles and second adhesive resin particles having an average particle diameter corresponding to 0.2-0.6 times of the average particle diameter of the inorganic particles, wherein the first adhesive resin particles are present in an amount of 30-90 wt % based on a total weight of the first adhesive resin particles and the second adhesive resin particles. The separator shows improved adhesion to an electrode and provides an electrochemical device with decreased increment in resistance after lamination with an electrode.

An electrical connector includes: an insulative housing having a front tongue with two opposite surfaces; an upper and lower rows of contacts with contacting portions exposed to the two opposite surfaces of the tongue; and a primary shell enclosing the insulative housing to together with the tongue define a mating chamber, wherein the insulative housing includes a pair of side steps and a pair of side protrusions; and the primary shell includes a pair of side wings sitting on the pair of side steps, each side wing having a notch engaging a corresponding side protrusion.

A terminal insertion device includes a chuck gripping a terminal, a housing holder holding a housing, an imaging unit to capture an image of the housing, a driving mechanism and a control unit. The control unit measures a distance from a reference point of a field of view of the imaging unit to a positioning target portion in the field of view based on an image obtained, measures a movement amount of a gripping point of the chuck when a measurement pin gripped by the chuck is aligned with the positioning target portion, calculates a reference distance between the gripping point and the reference point based on the distance and the movement amount, captures an image to identify a position of a cavity of the housing, drives the driving mechanism based on the calculated reference distance, and aligns and inserts the terminal into the identified cavity.

A female connector includes an insulating body, a terminal module, at least one elastic element and at least one lateral shell. At least one side of the insulating body defines an opening. A middle of the insulating body defines an accommodating space. The terminal module is mounted in the accommodating space. The terminal module includes a plurality of terminals. The at least one elastic element is mounted to a surface of the insulating body which is parallel to an extending direction of each terminal. The at least one elastic element has a clamping portion, and a transverse width of the clamping portion is equal to a distance between two inner surfaces of two sides of the insulating body. The at least one lateral shell is assembled to at least one side surface of the insulating body.

One variation of a portable radio system includes: a portable radio configured to transmit and receive audio communication, including a connector receptacle arranged on a rear face of the portable radio and a channel extending from the connector receptacle; a cable, configured to couple the portable radio to a secondary device, including a straight section configured to seat within the channel and defining a length greater than a length of the channel; a connector, coupled to the straight section of the cable, configured to seat within the connector receptacle to couple the cable to the portable radio in an upward and downward orientation; and a clip including a base section configured to transiently couple to the body over the connector and a clamp section configured to pivot relative the base section and to attach the portable radio to a user.

A method for manufacturing a power pin of a power interface is provided. The method may includes the steps of: providing a pin workblank, wherein the pin workblank includes a first surface and a second surface adjacent to each other; performing a fine blanking process for the first surface in a predetermined blanking direction, while burrs forming on the second surface; and adjusting a position of the pin workblank, performing another fine blanking process for the second surface in the predetermined blanking direction, to form a power pin of the power interface and to omit a process of removing the burrs on the second surface. Before the step of adjusting a position of the pin workblank, the method further includes a step of forming a chamfer or a round fillet at an edge of the second surface adjacent to the first surface of the pin workblank.