BACKGROUND
It is desirable to maintain continuity through a coaxial cable connector, which typically involves the continuous contact of conductive connector components which can prevent radio frequency (RF) leakage and ensure a stable ground connection. For example, physical contact between a nut and a post of a coaxial cable connector extends a continuous, uninterrupted ground path through the connector when the connector is mated onto a port. An additional continuity member, such as a metal spring or a metal washer, disposed within the connector is typically required to extend electrical continuity through the connector. However, not all coaxial cable connectors come equipped with the additional component required to extend electrical continuity through the connector. The absence of a continuity member within the connector adversely affects signal quality and invites RF leakage with poor RF shielding when the connector is mated onto the port.
Thus, a need exists for an apparatus and method for a port that provides continuity through a standard coaxial cable connector not having an additional continuity member.
SUMMARY
One general aspect relates to a port comprising an outer housing having a first end and a second end, the outer housing configured to terminate a coaxial cable connector at one or both of a first end and a second end, and a biasing member disposed within the outer housing to bias a post of the coaxial cable connector into contact with a coupling member of the coaxial cable connector, wherein the contact between the post and the coupling member extends continuity between the post and the coupling member.
Another general aspect relates to a port comprising an outer housing having a first end and a second end, the outer housing configured to terminate a coaxial cable connector at one or both of a first end and a second end, and a biasing member disposed within the outer housing to bias against a post of the coaxial cable, wherein the contact between the post and the biasing extends electrical continuity between the coaxial cable connector and the port.
Another general aspect relates to a port comprising an outer housing having a first portion and a second portion, a first insulator disposed within the first portion of the outer housing, a collar operably attached to the first insulator, the collar having a flange, and a biasing member disposed between the collar and a second insulator body, the biasing member configured to exert a biasing force against the collar in a first direction and against a second insulator body in a second direction when being compressed.
Another general aspect relates to a port comprising an outer housing having a first portion and a second portion, a first insulator disposed within the first portion of the outer housing, wherein a collar is operably attached to the first insulator, and a biasing member disposed within the outer housing, the biasing member biasingly engaging the collar.
Another general aspect relates to a port comprising an outer housing having a first portion and a second portion, a first moveable insulator disposed within the first portion, wherein a first collar is operably attached to the first moveable insulator, a second moveable insulator disposed within the second portion, wherein a second collar is operably attached to the second moveable insulator, and a biasing member disposed within the outer housing, the biasing member biasingly engaging the first collar and the second collar.
Another general aspect relates to a port comprising an outer housing having a first end and a second end, the outer housing configured to terminate a coaxial cable connector at one or both of a first end and a second end, and a means to extend electrical continuity between a coupling member of the coaxial cable connector and a post of the coaxial cable connector, wherein the means is disposed within the outer housing.
Another general aspect relates to a method of providing continuity to a coaxial cable connector, comprising providing an outer housing having a first end and a second end, the outer housing configured to terminate a coaxial cable connector at one or both of a first end and a second end, disposing a biasing member within the outer housing to bias at least one collar, and advancing the coaxial cable connector onto the outer housing to bring a post of the coaxial cable connector into engagement with the at least one collar, wherein the engagement between the post and the at least one collar biases the post into a coupling member of the coaxial cable connector to extend electrical continuity through the connector.
Another general aspect relates to a port for a connector having a post and a coupler. The port comprises an outer housing having a first portion and a second portion, a collar having a flange configured to engage a post of a connector, and a first insulator body disposed within the first portion and having a mating edge configured to engage the flange. The port further comprises a second insulator body having a first end and a second end and disposed within the second portion. The port further comprises a biasing member at least partially surrounding the first insulator body and configured to engage the collar at a forward end and the first end of the second insulator body at a rearward end. Engagement of the port with the connector exerts a biasing force against the collar to contact the post and to bias the post into contact with a coupler to maintain physical and electrical contact between the post and the coupler.
Another general aspect relates to a port for coupling a cable connector having a post and a coupler. The port comprises a collar configured to contact a post, a first insulator body disposed within at least a portion of the collar, a second insulator body spaced axially from the collar, and a biasing member disposed between the first insulator body and the second insulator body. The biasing member is configured to exert a biasing force against the first insulator body in one direction and against the second insulator body in another direction. The biasing force exerted against the first insulator body is transferred to a post so as to bias the post into contact with a coupler to maintain physical and electrical contact between the coupler and the post.
Another general aspect relates to a port for a connector having a post and a coupler. The port comprises a collar configured to contact a post, an insulator body spaced axially from the collar, and a biasing structure having a first end and a second end. The second end is configured to exert a biasing force against the insulator body and the first end is configured to exert a biasing force from the collar to the post of a connector when the connector is coupled to the port so as to biasingly maintain physical and electrical contact between the post and a coupler.
Still another general aspect relates to a port for biasingly maintaining an electrical ground path in a connector having a post and a coupler when the connector is coupled to the port. The port comprises a collar, an insulator body, and a biasing member configured to biasingly maintain a post and a coupler of a connector in electrical contact with one another during operation of the connector and when the connector is coupled to the port.
The foregoing and other features of construction and operation will be more readily understood and fully appreciated from the following detailed disclosure, taken in conjunction with accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Some of the embodiments will be described in detail, with reference to the following figures, wherein like designations denote like members, wherein:
FIG. 1 depicts a perspective view of a first embodiment of a port;
FIG. 2 depicts a cross-section view of the first embodiment of the port;
FIG. 3 depicts a cross-section view of the first embodiment of the port having an embodiment of an alternative biasing member;
FIG. 4 depicts a cross-section view of the first embodiment of the port having an embodiment of an alternative biasing member;
FIG. 5 depicts a cross-section view of the first embodiment of the port having an embodiment of an alternative biasing member;
FIG. 6 depicts a cross-section view of the first embodiment of the port in an original position;
FIG. 7 depicts a cross-section view of the first embodiment of the port in a compressed or advanced position; and
FIG. 8 depicts a cross-section view of a second embodiment of a port.
DETAILED DESCRIPTION
A detailed description of the hereinafter described embodiments of the disclosed apparatus and method are presented herein by way of exemplification and not limitation with reference to the Figures. Although certain embodiments are shown and described in detail, it should be understood that various changes and modifications may be made without departing from the scope of the appended claims. The scope of the present disclosure will in no way be limited to the number of constituting components, the materials thereof, the shapes thereof, the relative arrangement thereof, etc., and are disclosed simply as an example of embodiments of the present disclosure.
As a preface to the detailed description, it should be noted that, as used in this specification and the appended claims, the singular forms “a”, “an” and “the” include plural referents, unless the context clearly dictates otherwise.
Referring to the drawings, FIG. 1 depicts an embodiment of a port 100. Embodiments of port 100 may terminate a coaxial cable connector, and may be configured to extend continuity through a standard coaxial cable by biasing the post into contact with the nut when the connector is terminated at the port. Terminating a coaxial cable connector may occur when the connector is mated, threadably or otherwise, with port 100. Embodiments of port 100 may be a two-sided port, such as found in a splice, a one-sided equipment port, such as found on a cable box, an equipment port, such as found on a cell tower, or any conductive receptacle configured to mate with a coaxial cable connector and/or receive a center conductive strand of a coaxial cable. Embodiments of the port 100 may include a first end 1 and a second end 2, and may have an inner surface 3 and an outer surface 4. An annular flange portion 9 of the port 100 may be positioned between the first end 1 and the second end 2, wherein the annular flange portion 9 may be a bulkhead or other physical portion that provides separation from a first portion 10 and a second portion 20 and also may provide an edge having a larger outer diameter than the outer surface 4 of the port 100. For example, the annular flange portion 9 may separate a first portion 10, or first side, and a second portion 20, or second side. Embodiments of the first portion 10 of the port 100 may be configured to matably receive a coaxial cable connector, such as connector 1000 shown in FIG. 2. The outer surface 4 (or a portion thereof) of the port 100 may be threaded to accommodate an inner threaded surface of a coupling member 1030 of connector 1000. However, embodiments of the outer surface 4 of the port 100 may be smooth or otherwise non-threaded. In further embodiments, the second portion 20 of the port 100 may also matably receive a coaxial cable connector, such as connector 1000. It should be recognized that the radial thickness and/or the length of the port 100 and/or the conductive receptacle may vary based upon generally recognized parameters corresponding to broadband communication standards and/or equipment. Moreover, the pitch and depth of threads which may be formed upon the outer surface 4 of the coaxial cable interface port 100 may also vary based upon generally recognized parameters corresponding to broadband communication standards and/or equipment. Furthermore, it should be noted that the port 100 may be formed of a single conductive material, multiple conductive materials, or may be configured with both conductive and non-conductive materials corresponding to the port's 100 electrical interface with a coaxial cable connector, such as connector 1000. Further still, it will be understood by those of ordinary skill that the port 100 may be embodied by a connective interface component of a communications modifying device such as a signal splitter, a cable line extender, a cable network module and/or the like.
Referring still to FIG. 1, and with additional reference to FIG. 2, embodiments of port 100 may include an outer housing 90, a first insulator body 50, a second insulator body 60, an electrical contact 30, a collar 70, and a biasing member 80. Embodiments of port 100, 300 may include an outer housing 90, 390 having a first end 91, 391 and a second end 92, 392, the outer housing 90, 390 configured to terminate a coaxial cable connector 1000 at one or both of a first end 91, 391 and a second end 92, 392, and a biasing member 80, 180, 280, 380 disposed within the outer housing 90, 390 to bias a post 1040 of the coaxial cable connector 1000 into contact with a coupling member 1030 of the coaxial cable connector 1000, wherein the contact between the post 1040 and the coupling member 1030 extends continuity between the post 1040 and the coupling member 1030. Further embodiments of port 100, 300 may include an outer housing 90, 390 having a first portion 10, 310, and a second portion 320, a first insulator 50, 350 disposed within the first portion 10, 310 of the outer housing 90, 390, wherein a collar 70, 370a is operably attached to the first insulator 50, 350, and a biasing member 80, 180, 280, 380 disposed within the outer housing 90, 390, the biasing member 80, 180, 280, 380 biasingly engaging the collar 70, 370a. Even further embodiments of port 100 may include an outer housing 90 having a first portion 10 and a second portion 20, a first insulator 50 disposed within the first portion 10 of the outer housing 90, a collar 70 operably attached to the first insulator 50, the collar having a flange 75, and a biasing member 80, 180, 280 disposed between the collar 70 and a second insulator body 60, the biasing member 80, 180, 280 configured to exert a biasing force against the collar 70 in a first direction and against a second insulator body 60 in a second direction when being compressed.
FIG. 2 depicts an embodiment of a coaxial cable connector 1000. Embodiments of coaxial cable connector 1000 may be any standard coaxial cable connector which does or does not include an additional component or special structure to effectuate continuous grounding through the connector 1000. More particularly, the coaxial cable connector 1000 may be an F connector, a 75 Ohm connector, a 50 Ohm connector, a connector used in wireless applications for attachment to an equipment port on a cell tower, a connector used with broadband communications, and the like. Moreover, embodiments of a coaxial cable connector 1000 may be operably affixed to a coaxial cable 10, wherein the coaxial cable includes a center conductor 18 being surrounded by a dielectric 16, which is surrounded by an outer conductive strand 14, which is surrounded by a protective cable jacket 12. Embodiments of the coaxial cable connector 1000 may include a coupling member 1030, a post 1040, a connector body 1050, and other various components, such as a fastener or cap member. The coupling member 1030 may be operably attached to the post 1040 such that the coupling member 1030 may rotate freely about the post and ultimately thread onto or otherwise mate with the port 100. Embodiments of the coupling member 1030 can be conductive; for example, can be comprised of metal(s) to extend continuity between the post 1040 and/or the outer threads of the port 100. Other embodiments of the coupling member 1030 may be formed of plastic or similar non-metal material because electrical continuity may extend through contact the post 1040 and the port 100 (e.g. post 1040 to collar 70 or conductive insulator body 50). The post 1040 may be configured to receive a prepared end of the cable 10 as known to those skilled in the art, and may include a flange 1045 and a mating edge 46; the mating edge 46 may be configured to engage a collar 70 as the connector 1000 is threadably or otherwise advanced onto the port 1000. The connector body 1050 can be operably attached to the post and radially surround the post 1040, as known to those having skill in the art.
Referring again to FIG. 1, with continued reference to FIG. 2, embodiments of port 100 may include an outer housing 90. Embodiments of the outer housing 90 may include a generally axial opening therethrough to accommodate one or more components within the outer housing 90. The components disposed within the outer housing 90 may be moveable within the opening of the outer housing 90 in a generally axial direction. The outer housing 90 may have exterior threaded surface portions 94 that may correspond to a threaded inner surface of a coupler member 1030 of a coaxial cable connector 1000. The outer housing 90 may also include a first portion 10, a second portion 20, and an annular flange portion 9 that can separate the first portion 10 and the second portion 20. Embodiments of the first portion 10, the second portion 20, and the annular flange portion 9 may be structurally integral with each other forming a single, one-piece conductive component. Moreover, the outer housing 90 may include an annular recess 95 along an inner surface 93 of the outer housing 90. The annular recess 95 may be a portion of the inner surface 93 that is recessed a distance, forming an edge 96. Proximate or otherwise near the distal end of the second portion 20 (distal from the annular flange portion 9), a radially inwardly extending portion 98 may act as a stopper or other physical edge to restrain axial movement of a second insulator body 60 when biasing forces are exerted onto the second insulator body 60 during mating of the connector 1000 onto port 100. Furthermore, embodiments of outer housing 90 may include an inner annular shoulder 97, as depicted in FIG. 6. The shoulder 97 may protrude a distance from the inner surface 93 of the outer housing 90 to provide an edge for the biasing member 80 to rest on, make contact with, or bias against. The contact between the flat face of the shoulder 97 and the biasing member 80 may eliminate any grounding concerns by ensuring sufficient contact between the biasing member 80 and the outer housing 90. The outer housing 90 should be formed of metals or other conductive materials that would facilitate a rigidly formed outer shell. Manufacture of the outer housing 90 may include casting, extruding, cutting, turning, drilling, knurling, injection molding, spraying, blow molding, component overmolding, or other fabrication methods that may provide efficient production of the component.
Referring still to FIGS. 1 and 2, embodiments of the port 100 may include a first insulator body 50. Embodiments of the first insulator body 50 may be a generally annular or cylindrical tubular member, and may be disposed or otherwise located within the generally axial opening of the outer housing 90, proximate or otherwise near the first end 1 of the port 100. In other words, the first insulator body 50 may be disposed within the first portion 10 of the outer housing 90. The first insulator body 50 may include a first end 51, a second end 52, an inner surface 53, and an outer surface 54. Proximate the first end 51, the first insulator body 50 may include a first mating edge 57 which is configured to physically engage a flange 75 of a collar 70 that may be disposed around the first insulator body 50. Proximate or otherwise near the opposing second end, the first insulator body 50 may include a second edge 58. The first insulator body 50 may have an outer diameter that is smaller than the diameter of the opening of the outer housing 90 to allow the collar 70 to fit within the opening of the outer housing 90. Moreover, the first insulator body 50 may include an inner opening 55 extending axially from the first end 51 through the second end 52; the inner opening 55 may have various diameters at different axial points between the first end 51 and the second end 52. For example, the inner opening may be initially tapered proximate or otherwise near the first end 51 and taper inward to a constant diameter and then taper outward to a larger diameter proximate or otherwise near the second end 52. The inner opening 55 may be sized and dimensioned to accommodate a portion of an electrical contact 30, and when a coaxial cable connector 1000 is mated onto the port 100, the inner opening 55 may accommodate a portion of a center conductor 18 of a coaxial cable. Furthermore, the first insulator body 50 should be made of non-conductive, insulator materials. Manufacture of the first insulator body 50 may include casting, extruding, cutting, turning, drilling, compression molding, injection molding, spraying, or other fabrication methods that may provide efficient production of the component.
Embodiments of port 100 may also include a second insulator body 60. Embodiments of the second insulator body 60 may be a generally annular or cylindrical tubular member, and may be disposed or otherwise located within the generally axial opening of the outer housing 90, proximate or otherwise near the second end 2 of the port 100. In other words, the second insulator body 60 may be disposed within the second portion 20 of the outer housing 90. The second insulator body 60 may include a first end 61, a second end 62, an inner surface 63, and an outer surface 64. Proximate or otherwise near the first end 61, the second insulator body 60 may include a first edge 67 which is configured to physically engage a biasing member 80. For instance, the first edge 67 may be a surface of the second insulator body 60 that physically contacts the biasing member 80. Proximate or otherwise near the second end 62, the second insulator body 60 may include a second edge 68 that is configured to engage the inwardly radially extending portion 98 (e.g. a stopper) of the outer housing 90; the engagement of the second edge 86 and portion 98 can maintain a stationary position of the second insulator body 60 which provides a normal or otherwise reactant force against the biasing force of the biasing member 80 to facilitate the compression and/or biasing of the biasing member 80. The second insulator body 60 may have an outer diameter that is sized and dimensioned to fit within the opening of the outer housing 90. For example, the second insulator body 60 may be press-fit or interference fit within the opening of the outer housing 90. Moreover, the second insulator body 60 may include an inner opening 65 extending axially from the first end 61 through the second end 62; the inner opening 65 may have various diameters at different axial points between the first end 61 and the second end 62. For example, the inner opening may be initially tapered proximate or otherwise near the second end 62 and taper inward to a constant diameter and then taper outward to a larger diameter proximate or otherwise near the first end 61. The inner opening 65 may be sized and dimensioned to accommodate a portion of an electrical contact 30. Furthermore, the second insulator body 60 should be made of non-conductive, insulator materials. Manufacture of the second insulator body 60 may include casting, extruding, cutting, turning, drilling, compression molding, injection molding, spraying, or other fabrication methods that may provide efficient production of the component.
Furthermore, embodiments of port 100 may include an electrical contact 30. Embodiments of the electrical contact 30 may be a conductive element/member that may extend or carry an electrical current and/or signal from a first point to a second point. Contact 30 may be a terminal, a pin, a conductor, an electrical contact, and the like. Electrical contact 30 may include a first end 31 and an opposing second end 32. Portions of the electrical contact 30 proximate or otherwise near the first end 31 may be disposed within the inner opening 55 of the first insulator body 50 while portions of the electrical contact 30 proximate or otherwise near the second end 32 may be disposed within the inner opening 65 of the second insulator body 60. Moreover, embodiments of the electrical contact 30 may include a first socket 35a proximate or otherwise near the first end 31 of the contact 30 to receive, accept, collect, and/or clamp a center conductive strand 18 of a coaxial cable connector 1000. Likewise, embodiments of the electrical contact 30 may include a second socket 35b proximate or otherwise near the second end 32. The sockets 35a, 35b may be slotted to permit deflection to more effectively clamp and/or increase contact surface between the center conductor 18 and the socket 35a, 35b. The electrical contact 30 may be electrically isolated from the collar 75 and the conductive outer shell 90 by the first and second insulator bodies 50, 60. Embodiments of the electrical contact 30 should be made of conductive materials.
With continued reference to FIGS. 1 and 2, embodiments of the port 100 may further include a collar 70. Embodiments of the collar 70 may be a generally annular member having a generally axial opening therethrough. The collar 70 may be operably attached to the first insulator body 50. For instance, the collar 70 may be disposed around the first insulator body 50, proximate or otherwise near the first end 51. The collar 70 may be press-fit or interference fit around the first insulator body 50. Moreover, the collar 70 may include a first end 71, a second end 72, an inner surface 73, and an outer surface 74. Embodiments of the collar 70 may include a flange 75 proximate or otherwise near the first end 71; the flange 75 can be a radially inward protrusion that may extend a radial distance inward into the general axial opening of the collar 70. The flange 75 may physically engage the mating edge 57 of the first insulator body 50 while operably configured, and may prevent axial movement of the collar 70 toward the second end 2 of the port 100 that is independent of the first insulator body 50. In other words, when the collar 70 is engaged and displaced by a coaxial cable connector 1000 as the connector 100 is being threaded or otherwise inserted onto the first portion 10 of the outer housing 90, the mechanical engagement between the flange 75 of the collar 70 and the mating edge 57 of the first insulator body 50 can allow the first insulator body 50 and the collar 70 to move/slide axially within the general opening of the outer housing 90 and engage the biasing member 80. Furthermore, the collar 70 may include a mating edge 76 proximate or otherwise near the second end 72 of the collar 70. The mating edge 76 may be configured to biasingly engage the biasing member 80. Embodiments of the mating edge 76 of the collar 70 may be tapered or ramped to deflect/direct the deformation of the biasing member 80 towards the outer surface 54 of the first insulator body 50. The degree of tapering, the direction of the taper, and the presence of a tapered mating edge 76 may be utilized to alter or control the amount of spring force exerted onto the internal component(s) of the port 100. The collar 70 may be formed of metals or other conductive materials that would facilitate a rigidly formed cylindrical tubular body. Manufacture of the collar 70 may include casting, extruding, cutting, turning, drilling, knurling, injection molding, spraying, blow molding, component overmolding, or other fabrication methods that may provide efficient production of the component.
Embodiments of the port 100 may further include a biasing member 80. Embodiments of a biasing member 80 may be any component that is compressible and can exert a biasing force against an object (in a direction opposing the inward direction that the biasing member 80 is being compressed) to return to its original shape. For example, embodiments of the biasing member 80 may be a spring, a coil spring, a compression spring, a rubber gasket, one or more O-rings, rubber bushing(s), spacer(s), spring finger(s), and the like, that has a combination of rigidity and elasticity to compress/deform in a manner that exerts a biasing force against the collar 70, in particular, against the mating edge 76 of the collar 70. Furthermore, embodiments of the biasing member 80 may be disposed between the collar 70 and the second insulator body 60 within the general axial opening of the outer housing 90. For instance, the biasing member 80 may biasingly engage the collar 70 at a first end 81 of the biasing member 80 and biasingly engage the second insulator body 60 at a second end 82 of the biasing member 80. When a connector 1000 is threaded or otherwise inserted onto port 100, the biasing member 80 can compress between the collar 70 and the second insulator body 60, exerting a biasing force against the collar 70, which can ultimately force the post 1040 back into contact with the coupling member 1030 to extend electrical continuity through the connector 1000 and continue through the port 100. Additionally, the biasing of the collar 70 against the post 1040 can extend electrical continuity between the post 1040, or mating edge of the post 1046, and the collar 70. For example, a mating edge 1046 (flat face of post flange) of the post can physically contact the flat mating edge (front face of collar) of the collar 70, wherein contact is ensured due to biasing of the biasing member 80. The biasing member 80 can be formed of conductive materials, such as metals, or non-conductive materials. For example, the biasing member 80 may be made of steel, beryllium copper, stainless steel, silicone, high-carbon wire, oil-tempered carbon wire, chrome vanadium, and the like. Further still, embodiments of the biasing member 80 may include the collar 70 integrally attached such that the biasing member 80 and the collar 70 are one piece that is configured to compress in response to a connector 1000 being threaded or axially advanced onto port 100.
Further embodiments of port 100 may not include a separate component to provide the biasing force, but rather the first insulator body 50 and/or the second insulator body 60 may include an integral biasing member. For instance, the first and/or second insulator bodies 50, 60 may include a projection of the plastic (or conductively coated plastic or conductive elastomer) that may act as biasing member. Embodiments of an integral biasing member may include the insulator body 50, 60 having an integral portion that is coiled to provide resilient properties to the insulator body 50, 60. FIG. 3 depicts an embodiment of biasing member 800, wherein metal deposition techniques are used to form an insulator having metal traces and a built in spring to provide biasing and continuity.
Referring now to FIG. 4, embodiments of port 100 may include a biasing member 180. Embodiments of biasing member 180 may share the same or substantially the same function as biasing member 80; however, biasing member 180 may be disposed between the first insulator body 50 and the second insulator body 60, and configured to compress when a connector 1000 is threaded or otherwise inserted onto the port 100. For instance, embodiments of biasing member 180 may biasingly engage the second edge 58 of the first insulator body 50 at a first end 181 and may biasingly engage the first edge 67 of the second insulator body 60. Embodiments of biasing member 180 may be one or more resilient fingers disposed between the first and second insulator bodies 50, 60. When a connector 1000 is threaded or otherwise inserted onto port 100, the biasing member 180 can compress between the first insulator body 50 and the second insulator body 60, exerting a biasing force against the first insulator body 50, which can ultimately force the post 1040 back into contact with the coupling member 1030 to extend electrical continuity through the connector 1000 and continue through the port 100. The biasing member 180 can be formed of conductive materials, such as metals, or non-conductive materials. For example, the biasing member 80 may be made of steel, stainless steel, beryllium copper, silicone, high-carbon wire, oil-tempered carbon wire, chrome vanadium, and the like.
With reference now to FIG. 5, embodiments of port 100 may include a biasing member 280. Embodiments of biasing member 280 may share the same or substantially the same function as biasing member 80; however, biasing member 280 may be disposed between the first insulator body 50 and the second insulator body 60, and configured to compress when a connector 1000 is threaded or otherwise inserted onto the port 100. For instance, embodiments of biasing member 280 may biasingly engage the second edge 58 of the first insulator body 50 at a first end 181 and may biasingly engage the first edge 67 of the second insulator body 60. Embodiments of biasing member 180 may be a rubber gasket, a rubber collar, or any generally cylindrical member that is elastic and can compress between the first and second insulator bodies 50, 60 and exert a biasing force against the components. When a connector 1000 is threaded or otherwise inserted onto port 100, the biasing member 280 can compress between the first insulator body 50 and the second insulator body 60, exerting a biasing force against the first insulator body 50, which can ultimately force the post 1040 back into contact with the coupling member 1030 to extend electrical continuity through the connector 1000 and continue through the port 100. The biasing member 280 should be formed of non-conductive materials, such as rubber or similarly elastic material.
Referring still to the drawings, FIG. 6 depicts an embodiment of port 100 in an original, rest position. The original rest position may refer to when the connector 1000 has not contacted the port 100, and thus no deflection or compression of the components of port 100 has taken place. FIG. 7 depicts an embodiment of port 100 in a compressed position. The compressed position may refer to the position where the connector 1000 has been fully or substantially advanced onto port 100. For instance, the biasing member 80 is more compressed than in the position shown in FIG. 2, and a stronger biasing force is being exerted against the collar 70, and thus electrical continuity can be established and maintained between the post 1040 and the collar 70. In the compressed position, the post 1040 of the connector 1000 is also forced/compressed/biased against the coupling member 1030. However, those having skill in the art should appreciate that the post 1040 is biased against the coupling member 1030 prior to the fully compressed position, such as a position prior to full or substantial advancement on the port 100, as shown in FIG. 2.
With reference to FIGS. 1-7, the manner in which the port 100 extends continuity through a standard coaxial cable connector, such as connector 1000, when the connector 100 is threaded or otherwise inserted onto the port 100 will now be described. In an original position (shown in FIG. 6), the biasing member 80, 180, 280 may be in a position of rest, and the collar 70 and a portion of the first insulator body 50 may extend a distance from the first end 91 of the outer housing 90 so that the post 1040 contacts the collar 70 prior to the coupling member 1030 threadably engaging the outer housing 90, or after only a few revolutions of the coupling member 1030 onto the port 100. However, embodiments of the port 100 in the original position may include the collar 70 at various axial distances from the first end 91 of the outer housing 90, including embodiments where the collar 70 and the first insulator 50 are within the general opening of the outer housing 90 and not extending a distance from the first end 91. As a connector 1000 is initially threaded or otherwise inserted (e.g. axially advanced) onto the first portion 10 of the outer housing 90, the mating edge 1046 of the post 40 can physically engage the flange 75 of the collar 70, as shown in FIG. 2. Continuing to thread or otherwise axially advance the connector 1000 onto the port 100 can cause the collar 70 and the first insulator body 50 to displace further and further axially towards the second end 2 of the port 100 and compress the biasing member 80, 180, 280. Any compression/deformation of the biasing member 80, 180, 280 caused by the axial movement of the collar 70 and/or the first insulator body 50 results in a biasing force exerted against the collar 70 and/or the first insulator body 50 in the opposing direction while the biasing member 80, 180, 280 constantly tries to return to its original shape/rest position. The biasing force exerted onto the collar 70 and/or first insulator body 50 by the biasing member 80 transfers to a biasing force against the post 1040 in the same opposing direction (i.e. opposing the axial direction of the connector moving onto the port 100) which extends continuity between the connector 1000 and the port 100. Additionally, the biasing force exerted against the post 1040 can axially displace and/or bias the post 1040 in the same opposing direction into physical contact with the coupling member 1030. The physical contact between the post 1040 and the coupling member 1030, if the coupling member 1030 is conductive, extends electrical continuity between the post 1040 and the coupling member 1030, thereby providing a continuous grounding path through the connector 1000. The connector 1000 may be threaded or otherwise axially advanced onto the post 100 until the compressed position, as shown in FIG. 7; the biasing member 80, 180, 280 can constantly exert a biasing force while in the fully compressed position, thereby, in addition to establishing, the compressed biasing member 80, 180, 280 may maintain continuity through the connector 1000 which improves signal quality and afford improved RF shielding properties.
In another embodiment, the port 100 can extend electrical continuity through the connector 1000 and onto the port 100 without the need for collar 70. For instance, the first insulator body 50 and/or the second insulator body 60 may be formed of a conductive rubber, or conductive material may be applied to the first and second insulators 50, 60. Accordingly, contact between the conductive insulators 50, 60 and the post 1040 may extend electrical continuity therebetween. Those having skill in the art should appreciate that a conductive coating may be applied to the entire outer body, just a front face/edge, or the front face/edge and the outer surfaces of the first and second insulators 50, 60, (whichever insulator 50, 60 will contact a post of a coaxial cable connector may be conductively coated).
With continued reference to the drawings, FIG. 8 depicts an embodiment of port 300. Embodiments of port 300 may share the same or substantially the same structure and function as port 100. However, embodiments of port 300 can be used specifically for two-sided ports to provide continuity to two connectors, such as at a splice connection. For example, both the first and the second insulator bodies 350, 360 are moveable within the axial opening of the outer housing 390 in response to the biasing force exerted by the biasing member 380 to axially displace and/or bias the post 1040 of a connector 1000 into physical contact with the coupling member 1000 as the connector is threaded or axially advanced onto the port 300. The manner in which the port 300 provides continuity through the connector 1000 is the same or substantially the same as described above in association with port 100. Moreover, the connectors configured to be threaded or axially advanced onto the port 300 may be the same or substantially the same as connector 1000; those skilled in the art should appreciate that a connector mated onto one end of port 300 can be of a different size, quality, standard, performance level, etc. than the connector mated onto the other end of the port 300.
Embodiments of port 300 may include an outer housing 390, a first insulator body 350, a first collar 370a, a second insulator body 360, a second collar 370b, an electrical contact 330, and a biasing member 380. Embodiments of the outer housing 390, the first insulator 350, the first and second collars 370a, 370b, the electrical contact 330, and the biasing member 380 may share the same or substantially the same structure and function as the outer housing 90, the first insulator 50, the collar 70, the electrical contact 30, and the biasing member 80, 180, 280, respectively. However, embodiments of the biasing member 380 may biasingly engage the first collar 370a at one end 381 and a second collar 370b at a second end 382. Further embodiments of port 300 may include an outer housing 390 having a first portion 310 and a second portion 320, a first moveable insulator 350 disposed within the first portion 310, wherein a first collar 370a is operably attached to the first moveable insulator 350, a second moveable insulator 360 disposed within the second portion 320, wherein a second collar 370b is operably attached to the second moveable insulator 360, and a biasing member 380 disposed within the outer housing 390, the biasing member 380 biasingly engaging the first collar 370a and the second collar 370b.
However, embodiments of port 300 may include a second insulator body 360 that is moveable within the general opening of the outer housing 90, just as the first insulator body 350. For instance, the second insulator body 360 may be a generally annular or cylindrical tubular member, and may be disposed or otherwise located within the generally axial opening of the outer housing 90, proximate or otherwise near the second end 2 of the port 300. Proximate the first end 361, the second insulator body 360 may include a first mating edge 367 which is configured to physically engage a flange 375b of the second collar 370b that may be disposed around the second insulator body 360. Proximate or otherwise near the opposing second end, the second insulator body 360 may include a second edge 368. The second insulator body 360 may have an outer diameter that is smaller than the diameter of the opening of the outer housing 390 to allow the second collar 370b to fit within the opening of the outer housing 390. Moreover, the second insulator body 360 may include an inner opening 365 extending axially from the first end 361 through the second end 362; the inner opening 365 may have various diameters at different axial points between the first end 361 and the second end 362. For example, the inner opening may be initially tapered proximate or otherwise near the second end 362 and taper inward to a constant diameter and then taper outward to a larger diameter proximate or otherwise near the first end 361. The inner opening 365 may be sized and dimensioned to accommodate a portion of an electrical contact 330, and when a coaxial cable connector 1000 is mated onto the port 300 on the second end 2 of the port 300, the inner opening 365 may accommodate a portion of a center conductor 18 of a coaxial cable 10. Furthermore, the second insulator body 360 should be made of non-conductive, insulator materials. Manufacture of the second insulator body 360 may include casting, extruding, cutting, turning, drilling, compression molding, injection molding, spraying, or other fabrication methods that may provide efficient production of the component.
With reference to FIGS. 1-8, embodiments of a method of providing continuity through a coaxial cable connector 1000 may include the steps of providing an outer housing 90, 390 having a first end 91, 391 and a second end 92, 392, the outer housing 90, 390 configured to terminate a coaxial cable connector 1000 at one or both of a first end 91, 391 and a second end 92, 392, disposing a biasing member 80, 180, 280, 380 within the outer housing 90, 390 to bias at least one collar 70, 370a, 370b and advancing the coaxial cable connector 1000 onto the outer housing 90, 390 to bring a post 1040 of the coaxial cable connector 1000 into engagement with the at least one collar 70, 370a, 370b, wherein the engagement between the post 1040 and the at least one collar 70, 370a, 370b biases the post 1040 into a coupling member 1030 of the coaxial cable connector 1000 to extend electrical continuity through the connector 1000.
While this disclosure has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the present disclosure as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention, as required by the following claims. The claims provide the scope of the coverage of the invention and should not be limited to the specific examples provided herein.