The present disclosure generally relates to flexible circuits and, more particularly, to an electrical connector for connecting to flat-wire conductors of a flexible circuit.
Flat-wire, flexible circuits (FCs) provide a lighter and cheaper alternative to traditional wire harnesses for interconnecting electrical circuits of a vehicle. These FCs may consist of flat-wire conductors that are protected by an insulating body. Conventional methods used to create an electrical connection between a device and the FC include mechanically crimping, welding, soldering, or stitching a terminal of the device to the FC. Although such methods create an effective electrical connection, they require discrete leads that are separately terminated or spliced together.
This document describes an electrical connector for connecting to flat-wire conductors of a flexible circuit (FC). These techniques include an electrical connector having an elongated body between a split-blade terminal and a spring terminal. The split-blade terminal has two prongs separated by a distance and is configured to interface with an electrical terminal of an electrical device. The spring terminal is configured to mate with one or more of the flat-wire conductors within a connection area of the FC.
In other aspects, a system includes a housing that surrounds a portion of an FC. The system also includes a plurality of flat-wire conductors of the FC that have an exposed section at a connection area of the FC that is positioned within the housing. In addition, the system includes a plurality of electrical connectors supported within the housing. The plurality of electrical connectors each have a spring terminal at a first end and a split-blade terminal positioned at a second end that is opposite the first end along a longitudinal axis. One or more of the plurality of spring terminals abut the exposed section of one or more of the flat-wire conductors based on a compression force. Also, the split-blade terminal has two prongs separated by a distance and is configured to interface with an electrical terminal of an electrical device.
This summary is provided to introduce simplified concepts for an electrical connector for connecting to flat-wire conductors of a flexible circuit, which is further described below in the Detailed Description and Drawings. This summary is not intended to identify essential features of the claimed subject matter, nor is it intended for use in determining the scope of the claimed subject matter.
The details of one or more aspects of an electrical connector for connecting to flat-wire conductors of a flexible circuit are described in this document with reference to the following drawings. The same numbers are used throughout the drawings to reference like features and components:
The details of one or more aspects of an electrical connector for connecting to flat-wire conductors of a flexible circuit (FC) are described below. While flexible printed circuits (FPCs) are primarily discussed and shown herein, it will be appreciated that the present disclosure is directed to any type of FC. The conductive circuit traces or “flat-wire conductors” of an FC could be applied, for example, using any suitable deposition process, including, but not limited to, deposition processes (physical/chemical vapor deposition, sputtering, etc.) and printing processes (screen printing, lithography, inkjet, etc.). An automobile may include many FCs that connect to various types of vehicle circuits, such as lighting systems, climate control systems, automated or assistive driving systems, sensor systems, electrical drive systems, engine control systems, and any other electrical component that connects to a flexible circuit in a vehicle. These FCs include flat-wire conductors made from aluminum or tin-plated copper. The flat-wire conductors are protected by an insulating body formed around the flat-wire conductors.
The insulating body exposes the flat-wire conductors at specific connection areas of the FC. These connection areas are shaped to accommodate an electrical connector. Seating the electrical connector onto a connection area of a FC couples connector terminals of the electrical connector to a vehicle circuit through one or more of the flat-wire conductors of the FC. Maintaining a physical connection sufficient for transferring electrical current can be challenging where vibration, misalignment, and/or debris are present.
An electrical connector for connecting to flat-wire conductors of a FC is described. The electrical connector includes a spring terminal positioned at a first end of an elongated body. The spring terminal is configured to mate with a flat-wire conductor of the FC based on a compression force along a longitudinal axis of the elongated body. The spring terminal may have bifurcated contacts to improve electrical performance when contaminants are in a contact area between the spring terminal and the flat-wire conductor. The spring terminal may also include one or more protrusions or indentations on a surface that abuts the flat-wire conductor to improve the physical connection at the contact area. In some aspects, the spring terminal has a substantial obround shape that flexes in a direction of the longitudinal axis. The spring terminal may also flex in one or more of roll, pitch, and yaw directions relative to the longitudinal axis. The spring terminal also promotes contact wipe when mated to the FC at an acute angle relative to the longitudinal axis.
The structure of the electrical connector allows flexion in multiple degrees of freedom, which can improve alignment and reduce adverse effects caused by vibration. The structure of the spring terminal promotes a strong pressure contact between the spring terminal and the FC, and also compensates for micro movement of the FC or relaxation of a housing that presses the FC onto the spring terminal. Further, the structure of the electrical connector enables easy automation. The electrical connector can be used in a multi-drop apparatus having multiple electrical connectors that can be connected to any location along the FC that has exposed flat-wire conductors.
The wiring 106 is illustrated as substantially flat wire, such as a flexible circuit (FC) with a plurality of flat-wire conductors 108 that are exposed at a contact area to enable physical contact with one or more electrical connectors 110. The electrical connectors 110 supply electrical continuity between the wiring 106 and an electrical component (not shown). Contact portions of the electrical connectors 110 may have an arcuate shape, which is described in further detail below. The wiring 106 (e.g., FC) includes one or more substantially flat wires (e.g., flat-wire conductors 108) that are generally rectangular and encased in a non-conductive, flexible, plastic insulation to provide a cross-section aspect ratio of at least 2:1 with respect to width and height. As used herein, “generally rectangular” includes any shape having a width greater than its height in cross section and may include rectangular, parallelogram, trapezoid, oval, obround, and elliptical shapes. In some embodiments, the aspect ratio may be at least 3:1. In other embodiments, the aspect ratio may be at least 5:1. The flat-wire conductor 108 may be provided by non-stranded electrically conductive material, such as a flat copper wire plated with tin. Adjacent wires may be interconnected with insulation material that forms a webbing, which provides structural integrity to the wiring 106 during handling.
The system 100 also includes one or more seals, such as seal 112 and seal 114, supported by the first and second housing portions 102, 104, respectively, and arranged on opposing sides of the wiring 106 to provide weatherproofing.
The second housing portion 104 includes and encloses a sensor 116. The sensor 116 can include any suitable sensor, including an ultrasonic distance sensor, a temperature sensor, a pressure sensor, a voltage sensor, a current sensor, a camera, a radar sensor, or other electronic sensor. In this manner, the sensor 116 is integrated into the system 100 and forms part of the housing. The housing of the system 100 may vary from the configuration depicted, particularly the second housing portion 104, which may be integrated with an electrical component such as a lighting device, the sensor 116, or other electrical device.
At the second end, the electrical connector 110 includes a spring terminal, such as the spring terminal 204. The spring terminal 204 is a type of leaf spring and may have a substantially obround, or stadium, shape. The shape of the spring terminal 204 provides longitudinal flexion along the longitudinal axis 304 when abutting the wiring 106 based on a compression force along the longitudinal axis 304 between the electrical connector 110 and the first housing portion 102. The substantial obround, or stadium, shape of the spring terminal 204 also includes a contact surface 308 for contacting the flat-wire conductors 108 (from
The translational movement of the end 402 of the spring terminal 204 may occur in the y-direction based on the longitudinal compression force. The rotational movement (e.g., roll, pitch, or yaw) of the end 402 of the spring terminal 204 may occur based on the spring terminal 204 being compressed against an uneven surface, such as wiring with debris (e.g., dust particles, grain of sand or dirt, piece(s) of the wiring insulation, metal shavings, plastic, or any other object not intended to be between the spring terminal 204 and the wiring 106, or between the wiring 106 and the first housing portion 102 (e.g., on the opposite side of the wiring 106 from the spring terminal 204). The translational movement and/or the rotational movement of the end 402 of the spring terminal 204 may also occur based on the contact surface 308 of the spring terminal 204 being pressed against a surface, such as surface 406, which defines a plane 408 that forms an acute angle 410 relative to a plane 412 defined by the contact surface 308 of the spring terminal 204. The acute angle can also be defined relative to the longitudinal axis 304 of the electrical connector 110, such as acute angle 414 formed between the plane 408 of the surface 406 and the longitudinal axis 304 of the electrical connector 110. Any suitable acute angle can be used to promote contact swipe when the spring terminal 204 is pressed against the surface 406. Example acute angles between the plane 412 and the plane 408 may include any angle within a range of 5 to 20 degrees.
The elongated body 302 of the electrical connector 110 also includes one or more bends and/or notches to provide additional movement in multiple degrees of freedom. For example, the electrical connector 110 includes a bend 416 proximate (within a predefined distance) to a longitudinal midpoint of the elongated body 302. The bend 416 rotates an upper portion 418 of the electrical connector 110 relative to a lower portion 420 of the electrical connector 110 by approximately 90 degrees about the longitudinal axis 304.
Because the electrical connector 110 is formed from a flat metal strip, the lower portion 420 may flex about the z-axis, and the upper portion 418 may flex about the x-axis. This flexibility may allow for improved alignment over conventional, rigid connectors. In addition, the elongated body 302 may also include one or more notches, such as notch 422, which may enable additional rotational movement of the upper portion 418 relative to the lower portion 420 about the z-axis. The notches may also be used to receive a protrusion on the housing (not shown) of the system 100 in
As described above, the split-blade terminal 202 has two prongs 306. The prongs 306 are separated by a predefined distance 424 such that, when the split-blade terminal 202 is connected to an electrical contact, such as a flat-blade terminal (e.g., 0.8 mm blade) or a pin terminal (e.g., 0.64 mm pin), the prongs 306 pinch the electrical contact to provide a physical connection for electrical continuity. The split-blade terminal 202 may also mate with other types of electrical contacts. Accordingly, the split-blade terminal 202 may be used as a multi-use terminal, such that it can interface with multiple different types of terminals.
The bifurcated contacts 502 each include an outer edge 506 and an inner edge 508 that contribute to maintaining contact with the wiring 106. The inner edges 508 are separated by the predefined distance 504 of the space between the bifurcated contacts 502.
One or both of the bifurcated contacts 502 may include one or more protrusions 510 (e.g., bumps, darts, knurls, ridges, serrations, etc.) configured to improve electrical connection with the wiring 106 by increasing the surface area of the contact surface 308. Additionally or alternatively, the bifurcated contacts 502 may include one or more indentations (e.g., notches, grooves, slots, channels, etc.) configured to improve electrical connection with the wiring 106 by increasing the surface area of the contact surface 308.
The electrical connector 110 can be manufactured using common methods of progressive metal forming. For example, a rectangular strip of metal can be stamped, cut, and bent to shape the electrical connector 110. First, an appropriately-sized strip of metal can be stamped or cut to create the split-blade terminal 202, the notches 422, the protrusions 510, and the space between the bifurcated contacts 502. Then, the elongated body 302 can be bent to create the bend 416 and the spring terminal 204.
The present application claims the benefit of U.S. Provisional Application No. 62/956,903, filed on Jan. 3, 2020. The disclosure of this application is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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20210210882 A1 | Jul 2021 | US |
Number | Date | Country | |
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62956903 | Jan 2020 | US |