A connector for a flat flexible cable includes a housing and a terminal disposed in the housing. The housing has a base and a cover. The base has a closed section with a receiving passageway and an open section extending from the closed section. The cover encloses the open section in a closed position of the cover. The cover has a main body with a pressing surface and a latch extending from the main body. The latch engages a catch of the base in the closed position. The terminal is disposed in the receiving passageway and has a tab extending into the open section. The pressing surface abuts the tab and presses the tab toward the base in the closed position.

Provided are terminal-free connectors for flexible interconnect circuits. A connector for connecting to a flexible interconnect circuit comprises a base comprising a housing chamber defined by at least a first side wall and a second side wall that are oppositely positioned about the base. A circuit clamp is coupled to the base via a first hinge, and is configured to move between a released position and a clamped position. A cover piece is coupled to the base via a second hinge, and is configured to move between an open position and a closed position. The circuit clamp is configured to secure the flexible interconnect circuit between the base and the circuit clamp in the clamped position. One or more protrusions on the circuit clamp are each configured to interface with a socket within the first or second side wall to secure the circuit clamp in the clamped position.

Junction box for connecting a multi-wire flat cable to several terminals of a connection. The junction box comprises a support surface for a multi-wire flat cable to be contacted, and several contact blades for contacting the cable on one side without stripping the insulation. In addition, the junction box comprises several terminals, and several terminal rails adjoining the terminals, wherein each terminal rail has at least one hole, wherein a contact pin is inserted through a respective hole in a terminal rail. In each case, a contact pin is provided for a wire-to-terminal contact. The assignment of contact pins to the holes in the terminal rails defines which wire of the flat cable is connected to which terminal. An electrical contact is established between contact blades and terminal rails via one or more contact pins.

A socket actuation mechanism for package insertion and package-socket alignment, including: a socket frame comprising a plurality of first hinge portions; a carrier frame comprising: a center portion comprising one or more package interlocks; and a tab extending from a first end of the carrier frame, the tab comprising a second hinge portion couplable with the plurality of first hinge portions to form a hinge coupling the carrier frame to the socket frame.

A socket actuation mechanism for package insertion and package-socket alignment, including: a socket frame comprising a plurality of first hinge portions; a carrier frame comprising: a center portion comprising one or more package interlocks; and a tab extending from a first end of the carrier frame, the tab comprising a second hinge portion couplable with the plurality of first hinge portions to form a hinge coupling the carrier frame to the socket frame.

Terminals have a retained portion located forwardly of a receiving space and retained in a housing, and a contact arm portion that extends toward the rear from the retained portion; a contact arm portion has a contact portion that protrudes toward the receiving space in the connector thickness direction perpendicular to the forward-backward direction and the terminal array direction and is capable of contacting the counterpart connect body; a contact portion faces the interior surface of the receiving space across a gap in the connector thickness direction; the terminals have an extension portion located forwardly of the contact portion; the extension portion has a reflective portion in the rear end portion thereof; the reflective portion has a rear end face within a range that includes the protruding end of the contact portion when viewed from the rear; and the rear end face is formed as a reflecting surface.

A flexible printed circuit board includes a base film having an insulating property and a conductive pattern laminated on one surface of the base film, and has a terminal connecting area toward one end edge of the conductive pattern, the flexible printed circuit board including a reinforcement member laminated on an opposite surface of the base film and situated at least at a position opposite the terminal connecting area, wherein the reinforcement member has one or more lines of hollow holes aligning with a width direction thereof.

A printed circuit board includes a first transmission line provided on an insulating base, a first ground conductor, a notch portion that exposes a part of the first ground conductor, a conductor provided in the notch portion and electrically connected to the first ground conductor, and a first electrode exposed on a main surface of the insulating base facing a flexible board and electrically connected to the first transmission line. The flexible board includes a second transmission line provided on an insulating sheet, a second ground conductor, a second electrode exposed on a main surface of the insulating sheet facing the printed circuit board and connected to the second transmission line, and a third electrode exposed on the main surface of the insulating sheet and connected to the second ground conductor. The conductor and the third electrode are connected by solder.

A burn-in board for testing the operational integrity of memory devices includes local heating elements for each memory device under test. Each socket on the burn-in board may include a pair of opposed latch heads which move between open positions allowing a memory device to be mounted in the socket, and closed positions where the latch heads rest against the memory device to secure the device in the socket. Local heating elements may be integrated into the latch heads to ensure even heating of each memory device in the burn-in board.

A burn-in board for testing the operational integrity of memory devices includes local heating elements for each memory device under test. Each socket on the burn-in board may include a pair of opposed latch heads which move between open positions allowing a memory device to be mounted in the socket, and closed positions where the latch heads rest against the memory device to secure the device in the socket. Local heating elements may be integrated into the latch heads to ensure even heating of each memory device in the burn-in board.