Abstract: A row-based electrical connector includes a connector housing that supports a plurality of electrical contacts that define broadside coupled differential signal pairs along a row direction. The electrical connector further includes conductive ground shields disposed between adjacent differential signal pairs, and a conductive plate in electrical communication with the ground shields and electrically isolated from the differential signal pairs.

Abstract: An electrical connector includes a connector housing and at least one electrical contact supported by the connector housing, the at least one electrical contact configured to mate with a complementary electrical contact of a complementary electrical connector. The electrical connector further includes a latch assembly that includes an actuator and a latch body. The actuator has an actuator portion and at least one arm extending from the actuator portion. The arm includes a proximal end connected to the actuator portion, an opposed distal end, and an intermediate portion. The intermediate portion is retained by the connector housing at a location below the distal end. The latch body is connected to the connector housing so as to rotate about a pivot axis. The latch body includes a latch member at one side of the pivot axis, and a spring disposed at a second opposite side of the pivot axis. The spring provides a spring force that biases the latch member toward a latched position.

Abstract: An inspection kit including a portable container adapted to be moved by a user; user protection equipment adapted to be stored in the container; and conveyance inspection equipment adapted to be stored in the container with the user protection equipment. The user protection equipment includes safety equipment adapted to be worn by a user to protect the user. The conveyance inspection equipment includes equipment adapted to be used by the user to inspect an article transport apparatus. The portable container is configured to house both the user protection equipment and the conveyance inspection equipment for transport by a user as a unitary assembly to the apparatus for inspection.

Abstract: In accordance with one embodiment, an electrical connector includes a housing that supports a plurality of electrical contacts. Each electrical contact defines a mating end and an opposing mounting end, and a plurality of mounting terminals disposed at the mounting end. The mounting terminals of each contact are arranged in at least one column extending along a longitudinal direction, such that each column is spaced along a lateral direction, and the mounting terminals of adjacent contacts are longitudinally offset.

Abstract: An electrical connector is provided having an electrically insulative connector housing that supports a plurality of signal contacts, as well as a plurality of ground contact networks. The ground contact networks include a conductive ground coupling bar supporting a plurality of ground contacts along a pair of columns that are spaced apart along a row direction.

Abstract: An electrical connector system includes a first electrical connector having a mounting interface and a mating interface, wherein the mounting interface is configured to electrically connect to an electrical component, and the mating interface is configured to electrically connect to a complementary electrical connector along a forward insertion direction. The electrical connector system further includes a heat sink disposed forward of the first electrical connector, the heat sink defining an engagement surface configured to contact the complementary electrical connector when the first electrical connector is mated with the complementary electrical connector. The heat sink is movably supported in a direction substantially perpendicular with respect to the insertion direction so as to maintain the engagement surface in thermal contact with the complementary electrical connector.

Abstract: An electrical connector may include a first connector with electrically-conductive contacts. The contacts may have blade-shaped mating ends, and may be arranged in a centerline. The electrical connector may include a second connector with electrically-conductive receptacle contacts, which may also be arranged in a centerline. The connectors may be mated such that the mating portion of a first contact in the second connector may physically contact of a corresponding blade-shaped mating end of a contact in the first connector.

Abstract: An electrical power connector can include a connector housing having a front end defining a mating interface that includes a receptacle defined by opposing first and second surfaces. The interface can further include a plurality of first dividers that extend from the first surface and into the receptacle, and a plurality of second dividers that extend from the second surface and into the receptacle. The connector can further include a first row of contact beams and a second row of contact beams supported by the housing. Each contact beam of the first and second rows extends at least partially into the receptacle. The contact beams of the first row are separated from each other by the first dividers, and the contact beams of the second row are separated from each other by the second dividers such that a minimum creep distance between adjacent contact beams is greater than 1.0 mm.

Abstract: An electrical power connector comprises a housing having a mounting interface and a mating interface. The mating interface defines a plurality of receptacles spaced apart in more than one direction. A plurality of electrical contacts is supported by the housing. These electrical contacts define respective mounting ends that are configured to electrically connect with an electrical component at the mounting interface, and opposed mating ends. At least one of the electrical contacts defines a common contact beam disposed within at least a select one of the receptacles. This common contact beam is configured to be electrically connected to a pair of adjacent electrical contacts of a mated electrical connector.

Abstract: An electrical connector includes a dielectric housing, a plurality of electrical signal contacts carried by the dielectric housing, and a ground plate carried by the dielectric housing. The electrical signal contacts are arranged along a first plane, wherein the signal contacts define signal pairs such that a respective gap is disposed between adjacent signal pairs. The signal contacts further define respective mating and mounting ends. The ground plate includes a ground plate body oriented in a second plane that is substantially parallel to the first plane and offset from the first plane. The ground plate body defines first and second opposed surfaces. The ground plate includes at least one rib that defines first and second opposed surfaces, wherein the first surface of the rib projects from the first surface of the ground plate body in a direction toward the gap, and the second surface is recessed into the second surface of the ground plate body.

Abstract: An electrical power connector is provided that is configured to mate with a complementary electrical connector. The electrical power connector includes a connector housing that retains both electrical signal contacts and electrical power contacts. The electrical power connector includes an engagement assembly that includes 1) at least one polarization member configured to mate with a polarization member of the complementary electrical connector only when the electrical power connector is in a desired orientation relative to the complementary electrical connector, and 2) a securement member configured to releasably engage a securement member of the complementary electrical connector.

Abstract: An electrical contact is provided having an eye-of-the-needle (EON) mounting terminal that has a reduced stub capacitance with respect to conventional eye-of-the-needle mounting terminals.