Shelves or other fixtures may be used to support items at a facility. Weighing modules including load cells may be used at the fixtures to acquire weight data indicative of changes to the fixture as items are added or removed from the fixture. Accessories such as trays, bins, hangers, and so forth may be attached to the load cells, allowing the fixtures to be easily reconfigured to accommodate items of different sizes.

In a specific embodiment, a connector 100 is disclosed. The connector 100 comprises an insulative housing 102 defining a rear opening 108 for receiving a plurality of electrical wires 110 and a front opening 106 and a circuit board 104 disposed in the housing 102 and comprising a mating section 112 for mating with a corresponding mating section of a mating connector. The mating section 112 protrudes outwardly from the front opening 106 and terminates at a front edge 118 disposed between opposing side edges 114,116 of the mating section 112. The connector 100 further comprises opposing side arms 128,130 extending forwardly from opposing lateral sides 124,126 of the front opening 106 along, adjacent and beyond corresponding side edges 114,116 of the mating section 112 with a maximum separation between each side edge 114,116 and the corresponding side arm 128,130 being sufficiently small so that when the connector 100 mates with a mating connector, no portion of the mating connector can be inserted between the side edge 114,116 and the corresponding side arm 128,130. Other exemplary embodiments are also disclosed.

A converter board, comprising: a printed circuit board, wherein the printed circuit board includes a cutout to form two opposing sides and an end; a guiderail attached to each opposing end, the guiderails to accept an option card; an end connector attached to the end, the end connector to connect to the option card when the option card is fully inserted into the cutout; and an edge connector to connect the converter board to a system, wherein the edge connector is connected to the end connector.

A method of making an electrical connector includes: forming an upper row of contacts each connected between a primary carrier strip and a secondary carrier strip and stamping a selected one of the upper contacts to have a front extension thereof leveled at a lowest position; insert-molding the upper row of contacts with an upper insulator to form an upper terminal module unit; forming a lower row of contacts each connected between another primary carrier strip and another secondary carrier strip and stamping a selected one of the lower contacts to have a front extension thereof leveled at a highest position; insert-molding the lower row of contacts with a lower insulator to form a lower terminal module unit; bringing the front extensions of the selected upper and lower contacts to be in touch with each other. The primary and secondary carrier strips are then severed and an over-mold applied.

According to one embodiment, a semiconductor storage device includes a housing, a plurality of terminals, signal terminals, a controller, signal wiring, and a memory. The housing has a first face and a second face opposite to the first face. The plurality of terminals is exposed to the first face, extends in a first direction, and is spaced apart in a second direction intersecting with the first direction. A signal terminal included in the plurality of terminals has a first end in the first direction, and a second end opposite to the first end in the first direction, the second end being closer to a contact position with a socket contact than the first end. The controller is located in the housing. The signal wiring extends from the first end in the housing and electrically connects the first end and the controller. The memory is electrically connected to the controller in the housing.

The disclosure relates to a plug connection, including a plug socket and a clamp plug, for the electrical contacting of a circuit board located in an inner space of a field device. The plug socket is arranged on the circuit board and has at least one web and a first guiding arrangement. The clamp plug includes a second guiding arrangement, which is complementary to the first guiding arrangement, and further includes at least one clamping apparatus. The plug connection also includes an electrical cable that is clampable onto the web.

A connector assembly and a jumper connector thereof are provided. The jumper connector includes a first jumper connector body case for being coupled to a first board edge connector, a second jumper connector body case for being coupled to a second board edge connector, and conductive terminals. The first and second jumper connector body cases are coupled to each other to form an internal receiving space for accommodating the conductive terminals, and the conductive terminals are movable to correspond in position to the first and second board edge connectors respectively. By such structural design, even if circuit boards incur problems like poor processing quality or position offset, the jumper connector according to the present invention can still effectively bridge and join the board edge connectors on the circuit boards, thereby desirably accomplishing electrical connection between multiple circuit boards on electronic equipment.

An electrical connector (100) includes an insulative housing (1), a plurality of contacts received in the insulative housing, and a first conductive member (24). The contacts include a pair of first grounding contacts (212) for transmitting grounding signal, and a pair of first signal contacts (211) for transmitting a differential signal. The pair of first grounding contacts and the pair of first signal contacts are arranged in a first row. The pair of first signal contacts is disposed between the pair of first grounding contacts. The first conductive member is electrically connected with both of the first grounding contacts in at least two different locations.

A connector assembly and a jumper connector thereof are provided. The jumper connector includes a first jumper connector body case for being coupled to a first board edge connector, a second jumper connector body case for being coupled to a second board edge connector, and conductive terminals. The first and second jumper connector body cases are coupled to each other to form an internal receiving space for accommodating the conductive terminals, and the conductive terminals are movable to correspond in position to the first and second board edge connectors respectively. By such structural design, even if circuit boards incur problems like poor processing quality or position offset, the jumper connector according to the present invention can still effectively bridge and join the board edge connectors on the circuit boards, thereby desirably accomplishing electrical connection between multiple circuit boards on electronic equipment.

An electrical contact includes a planar main body, a supporting arm extending upwardly from an upper edge thereof, and a spring arm extending curvedly and upwardly from a lower edge thereof with a contacting region at a free end region. The spring arm will contact the supporting arm when the spring arm is downwardly pressed by the CPU. A connecting part extends from an upper portion of the main body for connecting to a carrier strip, and includes a first connecting section coplanar with the main body, and a second connecting section perpendicular to the first connecting section wherein the carrier strip is connected to an upper edge of the second connecting section so as to be spaced from the corresponding spring arm and supporting arm, thus avoiding improper coating thereupon when the gold coating is applied to the self-contacting regions of the spring arm and supporting arm.