Aspects of the subject disclosure may include a generator that facilitates generation of an electromagnetic wave, a core, and a waveguide that facilitates guiding the electromagnetic wave towards the core to induce a second electromagnetic wave that propagates along the core. The core and/or the waveguide can be configured to reduce radiation loss of the second electromagnetic wave, propagation loss of the second electromagnetic wave, or a combination thereof. Other embodiments are disclosed.

A method for producing a current conducting device, a junction box for a vehicle battery, and a motor vehicle having a corresponding junction box. In the method, multiple busbars are positioned in a predetermined location in relation to one another and then enclosed using an electrically insulating plastic cladding. In this case, a respective opening of the plastic cladding is left open in a respective connection region, in each of which at least two of the busbars meet one another. The busbars are then welded to one another in a respective region of the opening.

A method for producing a current conducting device, a junction box for a vehicle battery, and a motor vehicle having a corresponding junction box. In the method, multiple busbars are positioned in a predetermined location in relation to one another and then enclosed using an electrically insulating plastic cladding. In this case, a respective opening of the plastic cladding is left open in a respective connection region, in each of which at least two of the busbars meet one another. The busbars are then welded to one another in a respective region of the opening.

Apparatuses, systems and methods associated with connector design for mating with integrated circuit packages are disclosed herein. In embodiments, a connector for mating with an integrated circuit (IC) package may include a housing with a recess to receive a portion of the IC package and a contact coupled to the housing and that extends into the recess. The contact may include a main body that extends from the housing into the recess and a curved portion that extends from an end of the main body, wherein the curved portion loops back and contacts the main body. Other embodiments may be described and/or claimed.

A terminal clamp including a contact cage including a cage ceiling, two cage side walls respectively adjoining the cage ceiling at a respective side and a cage floor, wherein the cage ceiling, the cage floor and the cage side walls form a portion of a cage jacket; a spring element which forms a clamping device together with a reaction bearing formed by the cage ceiling, the clamping device configured to support and electrically contact an electrical conductor; a conductor insertion opening arranged at a face of the contact cage upstream of the clamping device in a conductor insertion direction x; a cage jacket cutout in the cage jacket configured to provide access to the spring element for an opening tool configured to adjust a position of the spring element relative to the reaction bearing and to open the clamping device.

A connector system includes a connector body defining a terminal cavity and a first and second groove each extending along an outer surface of the connector body and a terminal retainer attached to the connector body and moveable from a pre-staged position to a staged position. The terminal retainer retains a terminal within the cavity in the staged position. The terminal retainer has a base, a pair of first cantilevered arms extending from the base, a crossbar extending between the first arms defining a first latch feature, and a second cantilevered arm extending from the crossbar. The second arm is between the pair of first arms and defines a second latch feature. The first latch feature engages the first groove in the pre-staged position and the second groove in the staged position. The second latch feature engages the first groove in the staged position.

Extension cable (EXC1, EXC2) for use in an ultrasound system. The extension cable includes a first electrical connector (FEC) for connecting to a corresponding ultrasound transducer connector (UTC), a second electrical connector (SEC) for connecting to a corresponding console connector (CC), an electrical circuit (ECCT), and an electrical cable (ECAB). The electrical circuit (ECCT) provides a multiple-state output (MSOP), the multiple states being voltage levels (V.sub.1, V.sub.2, V.sub.3) corresponding to each of i) the electrical circuit (ECCT) not being electrically connected to the console connector (CC), ii) the electrical circuit (ECCT) being electrically connected to the console connector (CC) and the ultrasound transducer connector (UTC) not being electrically connected to the first electrical connector (FEC), and iii) the electrical circuit (ECCT) being electrically connected to the console connector (CC) and the ultrasound transducer connector (UTC) being electrically connected to the first electrical connector (FEC).

Provided is a battery wiring module that can hold busbars until they are connected to a secondary battery. A busbar is configured to connect battery terminals of a plurality of battery cells to each other, and has a recess portion that is recessed in a Z direction, which is a stack direction in which a housing is stacked on the battery cells. The battery wiring module includes a busbar holding portion configured to be inserted into the recess portions, and engage with and hold the busbar in the stack direction in which the housing is stacked on the battery cells.

A connector has a detector (11) is provided in a housing (10) for movement in a front-rear direction, and can move from a standby position to a detection position when the housing (10) is connected properly to a mating housing (90). The detector (11) includes two side walls (53) arranged to face each other in a width direction with a lock arm (15) provided on the housing (10) therebetween. A detecting body (42) is assembled with the lock arm (15) between the side walls (53) and can tilt together with the lock arm (15). Couplings (59) have tilting fulcrums (66) configured to resiliently deform when the detecting body (42) is tilted. The couplings (59) extend in oblique directions intersecting the width direction from the side walls (53) to corresponding side surfaces of the detecting body (42).

Provided are terminal-free connectors for flexible interconnect circuits. A connector comprises a housing chamber defined by at least a first side wall and a second side wall oppositely positioned about the base. An edge support is positioned at each of the first side wall and the second side wall. The edge supports allow for precise placement of the flexible interconnect circuit inside the housing chamber. A cover piece is coupled to the base via a first hinge, and is configured to move between a released position and a clamped position. The cover piece includes a clamp portion securing the flexible interconnect circuit against the edge supports in the clamped position. A slider may be configured to move between an extended position and an inserted position within the housing chamber, and may include a convex upper surface configured to urge the flexible interconnect circuit upwards in the inserted position.