Compression connector for coaxial cable

A compression connector for smooth walled, corrugated, and spiral corrugated coaxial cable includes an insulator disposed within the body, wherein the insulator contains a central opening therein which is dimensioned smaller than a collet portion, or second clamp, which seizes a center conductor of the coaxial cable. The connector also includes a first clamp disposed inside the body as well as a compression sleeve assembly. The body includes a transitional surface separating the body into two regions of different inside diameter. When an axial force is applied to the compression sleeve, the clamp is forced by the transitional surface into the body region having a smaller diameter, causing the clamp to squeeze onto an outer conductor layer of the coaxial cable. At approximately the same time, the collet portion is forced through the central opening, causing the collet portion to squeeze onto the center conductor.

FIELD OF THE INVENTION

This invention relates generally to the field of coaxial cable connectors, and more particularly to a compression connector for smooth walled, corrugated, and spiral corrugated coaxial cable.

BACKGROUND OF THE INVENTION

Coaxial cable is installed on a widespread basis in order to carry signals for communications networks such as cable television (CATV) and computer networks. The coaxial cable must at some point be connected to network equipment ports. In general, it has proven difficult to make such connections without requiring labor intensive effort by highly skilled technicians.

These generalized installation problems are also encountered with respect to spiral corrugated coaxial cable, sometimes known as “Superflex” cable. Examples of spiral corrugated cable include 50 ohm “Superflex” cable and 75 ohm “coral” cable manufactured by Andrew Corporation (wwv.andrew.com). Spiral corrugated coaxial cable is a special type of coaxial cable that is used in situations where a solid conductor is necessary for shielding purposes, but it is also necessary for the cable to be highly flexible. Unlike standard coaxial cable, spiral corrugated coaxial cable has an irregular outer surface, which makes it difficult to design connectors or connection techniques in a manner that provides a high degree of mechanical stability, electrical shielding, and environmental sealing, but which does not physically damage the irregular outer surface of the cable. Ordinary corrugated, i.e., non-spiral, coaxial cable also has the advantages of superior mechanical strength, with the ability to be bent around corners without breaking or cracking. In corrugated coaxial cables, the corrugated sheath is also the outer conductor.

When affixing a cable connector to a corrugated coaxial cable, it is necessary to provide good electrical and physical contact between the cable connector and the center and outer conductors of the cable. It is also desirable to connect the center and outer conductors without having to reposition the cable connector within a connecting tool during the connection operation. Compression connectors for coaxial cable are known which require dual stage compression to independently activate both inner conductor and outer conductor mechanisms, thus requiring a complex compression tool to accomplish the compression when installing the compression connector onto the coaxial cable.

SUMMARY OF THE INVENTION

Briefly stated, a compression connector for smooth walled, corrugated, and spiral corrugated coaxial cable includes an insulator disposed within the body, wherein the insulator contains a central opening therein which is dimensioned smaller than a collet portion which seizes a center conductor of the coaxial cable. The connector also includes a clamp disposed inside the body as well as a compression sleeve assembly. The body includes a transitional surface separating the body into two regions of different inside diameter. When an axial force is applied to the compression sleeve, the clamp is forced by the transitional surface into the body region having a smaller diameter, causing the clamp to squeeze onto an outer conductor layer of the coaxial cable. At approximately the same time, the collet portion is forced through the central opening of the insulator, causing the collet portion to squeeze onto the center conductor. The collet portion can be designed to be simultaneously squeezed onto the center conductor at the same time the clamp compresses the outer conductor layer, or the engagement of the collet portion with the center conductor can be designed to be delayed.

According to an embodiment of the invention, a compression connector for a coaxial cable, wherein the coaxial cable includes a center conductor surrounded by a dielectric, which dielectric is surrounded by a conductor layer, includes a connector body having a first end and a second end and a central passageway therethrough; an insulator disposed within the central passageway at the first end of the body; the insulator having an opening therein; a compression sleeve assembly connected to the second end of the body; first clamp means, disposed in the central passageway, for clamping onto the conductor layer; and second clamp means, disposed within the central passageway, for clamping onto the center conductor, whereby upon axial advancement of the compression sleeve assembly from the second end to the first end, the first and second clamp means are radially compressed inwardly.

According to an embodiment of the invention, a method for installing a compression connector onto a coaxial cable, wherein the coaxial cable includes a center conductor surrounded by a dielectric, which dielectric is surrounded by a conductor layer, includes the steps of (a) providing a connector body having a first end and a second end and a central passageway therethrough; (b) providing an insulator disposed within the central passageway at the first end of the body; (c) providing an opening within the insulator; (d) connecting a compression sleeve assembly to the second end of the body; (e) providing a first clamp for clamping onto the conductor layer, the first clamp being disposed in the central passageway; (f) providing a second clamp for clamping onto the center conductor, the second clamp being disposed in the central passageway; and (g) transmitting a force in a longitudinally axial direction of the body from the compression sleeve assembly to both the first and second clamps, wherein an axial movement of the compression sleeve assembly from the second end to the first end causes both the first and second clamps to radially compress inwardly.

According to an embodiment of the invention, a method for manufacturing a compression connector for a coaxial cable, wherein the coaxial cable includes a center conductor surrounded by a dielectric, which dielectric is surrounded by a conductor layer, includes the steps of (a) forming a connector body having a first end and a second end, and a central passageway therethrough; (b) forming an insulator for placement within the central passageway at the first end of the body, wherein the insulator includes an opening therein; (c) forming a compression sleeve assembly for connection to the second end of the body; (d) forming a clamp having an outer diameter and a transition surface disposed on an inside of the body; wherein the shoulder separates the body into a first portion having a first inner diameter and a second portion having a second inner diameter; wherein the outer diameter of the clamp is substantially the same as the first inner diameter, but greater than the second inner diameter; and wherein forcing the clamp in the longitudinally axial direction causes the outer diameter of the clamp to reduce in size as the clamp is forced from the first portion of the body to the second portion of the body; and (e) forming a conductive pin having a collet portion at one end thereof, wherein an outer diameter of the collet portion is greater than a diameter of the opening in the insulator, such that forcing the conductive pin in the longitudinally axial direction causes the outer diameter of the collet portion to reduce in size as the collet portion is forced into the opening, wherein an axial movement of the compression assembly causes both the clamp and the collet portion to clamp inwardly.

According to an embodiment of the invention, a connector for coupling an end of a coaxial cable, the coaxial cable having a center conductor surrounded by a dielectric and the dielectric surrounded by a conductor layer, includes a connector body having a first end and a second end, the connector body extending along a longitudinal axis and having defined therein an internal passageway, the first end having a first outer diameter and a first inner diameter; a first clamp positioned within the first inner diameter and having a first clamp central passageway configured for receiving the conductor layer, the first clamp further having an outer surface for engagement with a first surface on the central passageway configured to radially inwardly compress the first clamp; an insulator axially positioned within the second end of the connector body and having an insulator passageway; a second clamp assembly positioned along the longitudinal axis of the connector body between the first clamp and the insulator and having a second clamp central passageway for receiving the center conductor; the second clamp assembly having a surface portion extending into the insulator passageway; and a compression assembly positioned at the first end of the connector body for engagement with the first clamp, the compression assembly having a compression assembly passageway for receiving the coaxial cable, wherein axial advancement of the compression assembly moves the first clamp member toward the first surface to compress the first clamp radially inwardly to engage the conductor layer of the coaxial cable, and wherein further axial advancement of the compression assembly moves the second clamp assembly surface portion towards the insulator passageway, whereby the second clamp central passageway is radially inwardly compressed to engage the center conductor of the coaxial cable.

According to an embodiment of the invention, a connector for coupling an end of a coaxial cable, the coaxial cable having a center conductor surrounded by a dielectric and the dielectric surrounded by an outer conductor, includes a connector body extending along a longitudinal axis, the connector body having defined therein a connector body central passageway, the connector body having a first end and a second end, the first end having a first end internal diameter and a first end outer diameter; a compression member assembly configured to axially slidably engage the first end outer diameter; a first clamp located within the connector body passageway, the first clamp having a first clamp central passageway, the first clamp central passageway having an internal surface configured to receive the outer conductor of the coaxial cable; a mandrel located within the connector body central passageway for engagement with the first clamp, the mandrel configured to receive the center conductor; a second clamp located within the connector body central passageway, the second clamp having a second clamp central passageway configured to receive the center conductor; and an insulator located within the connector body central passageway, the insulator configured to receive a portion of the second clamp, wherein axial advancement of the compression member assembly along the longitudinal axis of the connector body compresses the first clamp radially inwardly to engage the outer conductor, and wherein further axial advancement of the compression member assembly along the longitudinal axis of the connector body causes movement of the mandrel toward the second clamp, whereby the insulator receives a portion of the second clamp which compresses the second clamp radially inwardly to engage the center conductor.

According to an embodiment of the invention, a method of attaching a connector having an internal passageway to a coaxial cable, the coaxial cable having a center conductor surrounded by an outer conductor, and wherein the connector includes a first clamp, a second clamp, a mandrel and an insulator located within the internal passageway, includes the steps of (a) inserting an end of the coaxial cable into the connector; (b) threading the outer conductor of the coaxial cable into the first clamp of the connector; (c) inserting the center conductor of the coaxial cable into the mandrel and the second clamp; (d) axially advancing the first clamp along a longitudinal axis of the connector body to compress the first clamp radially inwardly to engage the outer conductor; and (e) axially advancing the first clamp further to cause axial movement of the mandrel to advance the second clamp toward the insulator to compress the second clamp radially inwardly to engage the center conductor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring toFIG. 1A, a spiral corrugated coaxial cable10is shown prepared for installation onto a compression connector20(FIG. 2). A jacket12is cutaway to expose a portion of a spiral corrugated conductor layer14. Layer14is also known as the ground or outer conductor layer. Both corrugated conductor layer14and a dielectric16are cutaway from a center conductor18. Preparation of corrugated coaxial cable10for installation is well known in the art.

Referring toFIG. 1B, a spiral corrugated coaxial cable10′ is shown prepared for installation onto a compression connector60(FIG. 6). In addition to jacket12being cutaway to expose a portion of spiral corrugated conductor layer14, dielectric16is cored out leaving a hollow58after both corrugated conductor layer14and dielectric16are cutaway from center conductor18. Preparation of corrugated coaxial cable10′ for installation is well known in the art.

Referring toFIG. 1C, a non-spiral corrugated coaxial cable10″ is shown prepared for installation onto a compression connector. The preparation of cable10″ is well known in the art, and is the same as previously described with respect toFIG. 1A. Note that corrugated conductor layer14″ is non-spiral, but still corrugated. The basic steps of preparing a corrugated coaxial cable are known in the prior art, such as removing a portion of the cable jacket or coring the dielectric foam. For example, it is known to cut away the corrugated outer conductor in a “valley” to ensure enough of the “peak” is left for outer conductor seizure. However, the present invention allows the outer conductor to be cut in either the “peak” or a “valley” because of the configuration of the inner surface of the outer conductor clamp.

Referring toFIG. 1D, a smooth walled coaxial cable10′″ is shown prepared for installation onto a compression connector. The preparation of cable10′″ is well known in the art, and is the same as previously described with respect toFIG. 1A. Note that conductor layer14′″ is non-spiral and non-corrugated, i.e., smooth walled.

Referring toFIG. 1E, a smooth walled coaxial cable10″″ is shown prepared for installation onto a compression connector. In addition to jacket12being cutaway to expose a portion of conductor layer14″, dielectric16(FIG. 1D) is cored out leaving a hollow58after both conductor layer14and dielectric16are cutaway from center conductor18. Preparation of coaxial cable10″″ for installation is well known in the art.

Referring also toFIG. 2, compression connector20, shown in a partially compressed position, includes a body22with a nut24connected to body22via an annular flange26. An insulator28positions and holds a conductive pin30within body22. Conductive pin30includes a pin portion32at one end and a collet portion34at the other end. A drive insulator or mandrel36is positioned inside body22between and end of collet portion34and a clamp38. Clamp38has an interior annular surface which is geometrically congruent to the spiral of spiral corrugated conductor layer14. Clamp38preferably includes a plurality of slots39(FIG. 4) in an outer annular portion of the clamp, so that clamp38can be compressed or squeezed inward. A part of a compression sleeve40fits over an end42of body22. A drive portion44of compression sleeve40fits against an annular flange46of a drive ring48. An elastomer seal50fits against jacket12of corrugated coaxial cable10during installation to prevent external environmental influences (moisture, grit, etc.) from entering connector20as well as to provide strain relief and increase cable retention.

When prepared corrugated coaxial cable10is inserted into an opening54of connector20, cable10is twisted as it is inserted so that the spirals on conductor layer14fit into the spirals in clamp38, while center conductor18fits into collet portion34. When compressive force is applied to compression sleeve40in the direction indicated by an arrow a, drive portion44of compression sleeve40drives drive ring48against clamp38, forcing clamp38against a transition surface52of body22, which transition surface52is configured to radially inwardly squeeze clamp38against conductor layer14, while continuing to move clamp38axially in the direction of arrow a. Clamp38thus forces mandrel36to move in the direction of arrow a, and mandrel36forces collet portion34of conductive pin30through an opening56in insulator28. Opening56may take various forms, including convex, concave, or radial. Collet portion34also has a collet transition surface35configured to compress collet portion34radially inwardly upon advancement of conductive pin30into opening56of insulator28. Because a diameter of opening56is smaller than an outer diameter ramped surface35of collet portion34, collet portion34is squeezed onto and seizes center conductor18of corrugated coaxial cable10. During the clamping process, it is noted that center conductor18, now located within conductive pin30, does not move relative to pin30during the clamping process. With the transition surface as shown inFIG. 2, the collet portion34is simultaneously compressed radially inwardly at the same time clamp38is compressed radially inwardly. The transition surface35however, can be designed to have a portion of surface35consistent with the diameter of opening56. In this instance, the squeezing of collet portion34is delayed until a greater advancement of compression sleeve40.

FIG. 3shows the position of the driven and compressed elements of connector20after connector20is installed onto corrugated coaxial cable10.

Referring toFIG. 4, an exploded view is shown of the components of connector20. During preferred assembly of the components of connector20, conductive pin30is inserted into insulator28, after which the combination is inserted into body22, followed by mandrel36, clamp38, and drive ring48. Seal50is positioned inside compression sleeve40, after which the combination is slid onto/into body22after nut24is slid over the outside of body22.

Referring now toFIGS. 5-6, and referring back toFIG. 1B, a compression connector60is similar to compression connector20ofFIGS. 2-4, but with a mandrel76having an extended portion98which fits into hollow58of corrugated coaxial cable10′ during installation of connector60onto cable10′. Extended portion98provides support to the spiral corrugated conductor layer14during compression. Another difference between embodiments is that a body62of connector60is shaped somewhat differently to accommodate an O-ring100which provides sealing with a portion102of a compression sleeve80when connector60is installed onto cable10′. The remainder of the components of connector60interoperate the same way as the components of the embodiment of connector20and are not described further herein.

Referring toFIG. 7, an exploded view is shown of the components of connector60. During preferred assembly, an O-ring100is placed onto body62. A conductive pin70is inserted into insulator68, after which the combination is inserted into body62, followed by mandrel76, a clamp78, and a drive ring88. A seal90is positioned inside compression sleeve80, after which the combination is slid onto/into body62after nut64is slid over the outside of body62. During compression, an inner diameter of seal90decreases, thus forming a seal around jacket12. This provides strain relief on the cable and also aids in cable retention.

Referring toFIGS. 8-10, a compression connector110is shown which is similar to the previous embodiments, but which includes a spacer112between a mandrel114and a clamp116. The addition of spacer112may assist in better impedance matching. During installation of connector110onto corrugated coaxial cable10(FIG. 1A), clamp116forces spacer112against mandrel114instead of acting directly against mandrel114. It should be obvious to one of ordinary skill in the art that such variations are within the scope of the invention. The remainder of the components of this embodiment interact in the same manner as the previous embodiments, so that further description is omitted.

Referring toFIG. 11, transition surface52may take various forms, including a shoulder, a ramped or tapered surface, or various shapes such as convex, concave or radial.FIG. 11Ashows a shoulder,FIG. 11Bshows a convex surface,FIG. 11Cshows a ramped surface, andFIG. 11Dshows a concave surface.

Referring toFIG. 12, a coaxial cable connector110′ is shown which is similar to cable connector110(FIG. 8) but which is intended for installation on smooth-walled coaxial cable10′″ (FIG. 1D). Note that clamp116′, unlike clamp116ofFIG. 8, does not contain valleys and ridges corresponding to the valleys and ridges of corrugated coaxial cable in order to provide greater gripping surface.

During installation of any of these embodiments onto spiral corrugated coaxial cable10(FIG. 1A), non-spiral corrugated coaxial cable10″, and smooth walled coaxial cable10′″, connectors20,60,110have to be relatively immovable while compressive force is applied to the respective compression sleeves in the direction of arrow a (FIG. 2). The preferred design of a compression connector tool to accomplish the installation would, while applying the compressive force in the direction of arrow a, stabilize the connector in the opposing direction, thus ensuring that the compressive force was sufficient to squeeze the respective clamps around the conductor layer of the corrugated coaxial cable and squeeze the respective collet portions onto the center conductor. Although the squeezing of the respective clamps begins slightly before the squeezing of the respective collet portions, the squeezing of the respective clamps and collet portions mainly happens simultaneously, unlike with prior art embodiments which require a two-stage operation.

While the present invention has been described with reference to a particular preferred embodiment and the accompanying drawings, it will be understood by those skilled in the art that the invention is not limited to the preferred embodiment and that various modifications and the like could be made thereto without departing from the scope of the invention as defined in the following claims.