A cable assembly includes a flat flexible cable having a plurality of conductors embedded within an insulation material. A portion of each of the conductors is exposed via openings selectively formed in the insulation material, allowing for a crimping portion of an electrically conductive terminal to engage with the conductor within the opening. The crimping portion of the terminal includes a base defining at least one protrusion extending therefrom, and first and second sidewalls extending from the base. The base and the first and second sidewalls define an opening configured to receive the conductor therein. The first sidewall includes a first section attached to the base and a second section attached to the first section on an end opposite the base. In a crimped state of the terminal, the first sidewall rotated into the opening such that the first section at least partially surrounds the second section, and the second sidewall is rotated in a direction opposite the first section such that the first section at least partially surrounds the second section, for crimping the conductor within the opening and against the protrusion.

A plug connector for flexible conductor films having film-insulated conductors, having a plug connector housing, in which at least one plug contact element is arranged, and having a coupling region, in which blades electrically conductively connected to the at least one plug contact element penetrate and fix at least one film-insulating conductor by producing an electrical contact, wherein the plug connector housing comprises two housing parts that can be fitted together, whose first housing part supports the blades and the at least one plug contact element electrically conductively connected to them, and whose second housing part receives and supports the flexible conductor film and has the at least one blade receiver adjusted to the blades, whose boundary surfaces are formed in such a way that at least one part of the blades is bent when fitting the two housing parts together in the direction of the film-insulated conductor, wherein at least one part of the blades is formed flexibly.

A method of forming an electrical cable assembly includes providing a multiconductor flat cable comprising wires arranged in a coplanar fashion with each other and encased within a planar dielectric structure, cutting a slot in the planar dielectric structure intermediate the wires, thereby forming wing features in the dielectric structure extending from the wires, removing portions of the dielectric structure from ends of the wires, wherein portions of wing features remain, attaching the exposed wires to terminals, wherein the terminals define prongs, and attaching the portions of the wing features to by inserting the prongs within holes defined in the portions of the wing features, thereby retaining the wires to the terminals.

Electrical connector assemblies mountable on a tire of a wheel of a vehicle are described. An electrical connector assembly may include one or more electrical conductors, a respective electrical conductor extending from an inside surface of the tire to an outside surface of the tire. Tire assemblies including at least partially embedded electrical connector assemblies and wheel assemblies including such tire assemblies are also described.

Electrical connector assemblies mountable on a tire of a wheel of a vehicle are described. An electrical connector assembly may include one or more electrical conductors, a respective electrical conductor extending from an inside surface of the tire to an outside surface of the tire. Tire assemblies including at least partially embedded electrical connector assemblies and wheel assemblies including such tire assemblies are also described.

An array type connection structure is disclosed. The structure includes a support and connecting assemblies. There is no signal cable routing in the support. Each connecting assembly penetrates through the support; a first side of each connecting assembly has a connector interface including a plurality of first signal terminals, and the connector interface is configured to be connected to a first electronic component located on a first side of the support. A second side of each connecting assembly is directly connected to a plurality of cables, the plurality of cables are in a one-to-one correspondence with the plurality of second signal terminals of the connecting assembly, and the cable is configured to be connected to a second electronic component located on a second side of the support. The support is provided with a heat dissipation through hole, which is at least partially located between two adjacent connecting assemblies.

An array type connection structure is disclosed. The structure includes a support and connecting assemblies. There is no signal cable routing in the support. Each connecting assembly penetrates through the support; a first side of each connecting assembly has a connector interface including a plurality of first signal terminals, and the connector interface is configured to be connected to a first electronic component located on a first side of the support. A second side of each connecting assembly is directly connected to a plurality of cables, the plurality of cables are in a one-to-one correspondence with the plurality of second signal terminals of the connecting assembly, and the cable is configured to be connected to a second electronic component located on a second side of the support. The support is provided with a heat dissipation through hole, which is at least partially located between two adjacent connecting assemblies.

This disclosure provides connectors for smart windows and doors. A smart window or door may incorporate an optically switchable pane. In one aspect, a smart window or door includes an insulated glass unit including an optically switchable pane. One aspect pertains to connectors such as, e.g., detachable power transfer connectors for movable doors or windows.

Described embodiments provide a crimp connector with hooks to hold a flat flexible cable (FFC). The crimp connector includes a bottom body and multiple hooks protruding outward from and coupled to the bottom body to hold the FFC. The crimp connector also includes a top clasp hingably mounted to the bottom body having multiple barbs internally mounted therein. Each of the barbs correspond with an uninsulated flat conductor of the FFC. In response to the top clasp engaging with the bottom body such that a slotted wedge of the top clasp presses the corresponding one of the first and second uninsulated flat conductors against the corresponding barbs, the crimp connector makes an electrical connection between each of the barbs and the corresponding one of first and second uninsulated flat conductors.

Described embodiments provide a crimp connector with hooks to hold a flat flexible cable (FFC). The crimp connector includes a bottom body and multiple hooks protruding outward from and coupled to the bottom body to hold the FFC. The crimp connector also includes a top clasp hingably mounted to the bottom body having multiple barbs internally mounted therein. Each of the barbs correspond with an uninsulated flat conductor of the FFC. In response to the top clasp engaging with the bottom body such that a slotted wedge of the top clasp presses the corresponding one of the first and second uninsulated flat conductors against the corresponding barbs, the crimp connector makes an electrical connection between each of the barbs and the corresponding one of first and second uninsulated flat conductors.