1. Field of the Invention
This invention relates in general to terminating a coaxial cable end in an angled connector and more specifically to using parts of an electrical terminal device within and extending from the connector to mechanically and electrically connect the cable end to the connector.
2. Discussion of Related Art
The traditional ferrule used with coaxial cable connectors is a simple, loose tube. To terminate a coaxial cable, an end of the cable is stripped in three stages to expose a center conductor, inner insulation layer, and outer conductive sheath or braid. The ferrule is then assembled over the prepared coaxial cable end. Care must be taken not to damage the exposed conductors as the ferrule is slid past onto an outer jacket of the cable. The braid is flared outward and the inner insulation layer and center conductor are inserted into a tubular part of a connector. The braid is then folded around an outer surface of the tubular part and then the ferrule is slid over the braid and tubular part. Finally, the ferrule is crimped in place. This provides a good electrical and mechanical connection of the braid to the connector suitable for automotive applications. Co-pending, commonly-owned U.S. patent application Ser. No. 11/016,919, filed Dec. 21, 2004, for example, makes use of a loose ferrule of this type. However, the process is time consuming, difficult to automate and therefore expensive to use.
Another method attempts to do away with the loose-piece ferrule and a wire stripping stage. The method uses a ferrule attached to the connector body and does not require the coaxial cable outer jacket to be stripped. The ferrule has a sharp leading edge that wedges between the outer jacket and conductive braid. The jacket and ferrule are then crimped, crushing the jacket into the crimp area and compromising the electrical and mechanical performance of the crimp to a degree not acceptable for automotive use. In addition, both of these described methods traditionally require expensive screw-machining technology to fabricate the parts of the connector.
There are also terminals known in the art, such as those described in U.S. Pat. Nos. 3,828,298 and 6,206,727, having arms directly crimped on the conductive sheaths of coaxial cables. However, these terminals do not address the assembly issues involved in terminating coaxial cables in angled connectors with inner terminal devices.
Accordingly, it is an object of this invention to provide an angled connector in which the ferrule for gripping the coaxial cable is part of the terminal device within the connector, eliminating the need for a loose ferrule and the associated assembly steps.
Another object of the invention is to enable the assembly and termination of the coaxial cable in the connector to be completely automated.
A further object of the invention is to design the connector such that it can be produced in a stamping and forming process to reduce manufacturing costs.
In carrying out this invention in the illustrative embodiment thereof, a connector housing has a main section for receiving a terminal device and a barrel section extending at a right angle from the main section. The barrel section has a sharp-edged end distal from the main section. The terminal device includes an inner terminal and an outer socket or contact physically and electrically isolated from the inner terminal by a dielectric member. The inner terminal has insulation displacement blades positioned near a cable-receiving end of the main section. The outer contact has a ferrule portion arranged to extend out of an aperture in the housing and part-way around the barrel section. The ferrule portion has fingers or appendages with serrations on their inner surfaces.
The preparation of a coaxial cable end for termination in the connector housing requires only a single step. A conductive sheath and outer jacket of the cable is stripped back from an inner insulation layer and center conductive core a predetermined or specific distance. The core and inner insulation layer are inserted into the barrel section. The edge of the barrel section slides between the inner insulation layer and the conductive sheath.
The automated process for terminating and securing the cable to the connector comprises crimping the ferrule appendages around the outer jacket and conductive sheath of the cable and the barrel section. The serrations on the appendages cut through the outer jacket and contact the conductive sheath. The inner terminal is pressed toward the cable end within the main section and the insulation displacement blades cut through the inner insulation layer and contact the core of the cable.
This design does not require separate stripping of the outer jacket, pre-assembly of the ferrule onto the cable, flaring of the braid to fit over the barrel section, and folding the braid around the barrel section after the inner insulation layer and core are inserted in the barrel section. The connector housing can be manufactured using stamped and formed technology instead of the prior art screw-machined technology. The method is easily automated and significantly cheaper than the traditional manual coaxial cable braid termination methods. The typical loose piece tube ferrule and the connector body-integrated ferrule are replaced with a ferrule providing a more secure and efficient termination of the cable.
By surrounding the inner insulation layer and cable core, the barrel section eliminates any chance for penetration of conductive material into the cable inner insulation layer when the crimp is applied. Such penetration could impact the radio frequency (RF) performance or dielectric withstanding capabilities of the end product. The barrel section also prevents the cable dielectric (inner insulation layer) from being crushed when the braid is crimped. Crushing the inner insulation layer could introduce a low impedance area and adversely affect the RF performance. The mechanical strength of the termination can be maximized due to the all metal to metal crimp termination.
This invention, together with other objects, features, aspects and advantages thereof, will be more clearly understood from the following description, considered in conjunction with the accompanying drawings.
Referring now to
The connector body or housing 24 may be stamped and formed in two pieces from an electrically conductive metal or material such as zinc or a zinc-aluminum alloy. The housing 24 has a generally hollow, cylindrical, first main section 26 with a first, open terminal mating end 28 and a second, dome-shaped cable receiving end 30. The main section 26 diverges outward approximately mid-way between the ends to form two inner chambers of different diameter, a wider mating connector receiving chamber 32 adjacent the terminal mating end 28 and a narrower chamber 34 leading to the cable receiving end 30.
A second, relatively smaller, barrel section 36 extends at a right angle from the main section 26 adjacent the cable receiving end 30. The angle is illustrated as being a right angle, but could be a different angle depending on the requirements of the environment in which the connector is used. The barrel section 36 has a tapered-inward portion 38 distal from the main section 26 that forms a narrow or sharp-edged end 40. An aperture 42 in the main section 26 partially surrounds an underside 44 of the barrel section where it extends from the main section. The barrel section 36 has an inner diameter sized to receive only the inner insulation layer 18 and center conductive core 20 of the stripped cable end.
The connector includes a terminal device 46 for receipt in the main section 26 and assembly with the housing 24 and the coaxial cable end 22. The terminal device 46 comprises an inner center contact terminal 48, an outer, concentric female socket or contact 50, and a dielectric insert or member 52 sandwiched between the terminal and socket and electrically isolating them from each other.
The inner center contact terminal 48 has a first end formed as a female terminal part 56, a second end or part comprising insulation displacement surfaces or blades 60, and an intermediate part including sets of retention barbs 62 for securing the terminal 48 in the dielectric member 52. The terminal 48 is stamped or otherwise manufactured in one piece from an electrically conductive metal such as brass or stainless steel. The female terminal part 56 could alternatively be formed as a male terminal, depending on the type of terminal the connector housing 24 is meant to mate with.
The dielectric member 52 has a channel 64 of varying diameter for receiving and securing the terminal 48. The dielectric member may be made from a material such as Nylon, Teflon, polybutylene-terephalate or any of a variety of extruded plastics. It includes an opening 66 for receiving the cable end 22 and a stop surface 68 against which the cable end 22 abuts. A longitudinal guide groove 70 extends along its outer periphery. The dielectric member 52, inner center contact terminal 48, their assembly together and engagement to the cable end 22 and core 20 are described in detail in commonly-owned U.S. Pat. No. 7,070,440, herein incorporated by reference.
The outer female socket or contact 50 is constructed to accept a standard male connector (not shown) for mating with the inner center contact terminal 48. Like the terminal 48, it may be stamped and bent or otherwise manufactured in one piece from a conductive metal such as brass or stainless steel. The contact 50 has a ring element 72. Spring fingers 74 extend from the ring element 72 for receiving the male connector through a mating end 76. The ring element 72 has an inner annular surface 78 and an outer surface 80. The outer surface 80 is sized to fit snugly and securely within the chamber 34 of the housing main section 26 in a press-fit. The ring element 72 has an inner guide projection 82 for sliding along the groove 70 in the outer periphery of the dielectric member 52 when the dielectric member is inserted into the contact 50. This guides the dielectric member into the ring element 72 until it reaches an assembled position, with bent inward segments 84 of the ring element holding the dielectric member within the ring element. This assembly structure and process are also disclosed in more detail in the incorporated patent.
The outer female socket or contact 50 according to the present invention has a partially tubular or cradle-like extension or ferrule 86 extending at a right angle from the ring element 72 at an end 88 opposite the mating end 76. Again, the angle could be different than ninety degrees depending on the connector environment requirements. The ferrule 86 has a first end 90 integral with the ring element 72 and a second, free end 92 distal from the ring element. The second end 92 is formed into wire crimp tabs 94. The ferrule has two longitudinal edges 96 between the end 90 and the crimp tabs 94. Fingers or appendages 98 angle outward from the ferrule edges, initially in a v-shape. Four appendages (as best seen in
In the coaxial cable termination process made possible by the present invention, the inner contact terminal 48 is inserted into the dielectric member 52 in a pre-set position illustrated by
The insulation layer 18 and conductive core 20 of the stripped cable end 22 is then inserted into the barrel section 36 of the housing 24, as best illustrated in
The completed assembly is received in a plastic, electrically non-conductive housing (not shown). The ferrule 86 and outer contact 50 act as electrical grounds and shields for the inner terminal 48 and the terminated end 22 of the cable.
The crimp ferrule fingers or appendages 98 and serrations 102 illustrated and described could be replaced with other structure performing the same function. Substitutes, for example, could include: traditional insulation displacement blades; shears formed in the appendages and ferrule to provide teeth-like features; widely spaced fingers that when crimped penetrate the jacket material, the spaces in between the fingers allowing the excess jacket material to move; raised ridges in the ferrule that penetrate through the jacket when crimped; or a wire spiral wrapped under high tension and then spot-welded in place. The assembly process could be rearranged to electrically connect the terminal 48 with the cable core 20 prior to crimping of the appendages and tabs (in whatever order or simultaneously), depending on the reliability of the separate component retaining features.
Since minor changes and modifications varied to fit particular operating requirements and environments will be understood by those skilled in the art, this invention is not considered limited to the specific examples chosen for purposes of illustration. The invention is meant to include all changes and modifications which do not constitute a departure from the true spirit and scope of this invention as claimed in the following claims and as represented by reasonable equivalents to the claimed elements.
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