KR920702043A - Bulkhead coaxial cable coupler - Google Patents

Abstract

A feedthrough coaxial cable connector includes a tubular mandrel body dimensioned to be pressed between a foil-bonded dielectric core and other elements of an outer conductor of the prepared end of the cable. The body has cable engagement surface which defines a knife edge projection therearound for engaging an outer conductor of the cable by creating shear stresses therein without actually shearing the outer conductor. A tubular shank portion extends from the cable engagement surface portion to a radial wall portion, and a jack engagement portion is coaxial about the exposed central conductor. The jack engagement portion achieves a tight friction fit upon a jack and may be formed as an inside compression collet. A radial compression providing structure causes an inside surface region of the outer conductor to bear directly against and bend over the knife edge portion. Preferably, a slideable shell is slideably positionable generally away from a connector end facing the outer surface of the jack to enable the jack engagement portion of the connector to slide over the outer surface of the jack, and slideably positionable toward the connector end so as to radially compress the radially diverging jack engagement portion against the outer surface of the jack to secure the connector thereto. A kit of parts including an expandable installation tool enables proper assembly of the cable connector without special skills or tools.

Description

Bulkhead coaxial cable coupler

Since this is an open matter, no full text was included.

1 shows an enlarged longitudinal cross-sectional view of a central axis of a part of a coaxial cable connector according to the invention, FIG. 2A shows an enlarged longitudinal cross-sectional view of a portion of an elastomeric snap ring element of the connector of FIG. 1, FIG. 2B is a side view of the inner collet structure of the mandrel body of the connector of FIG. 1, FIG. 2C is a half sectional view of the mandrel body with a helical spiral defined inside the collet structure of the connector of FIG. 1, and FIG. 2D is formed by parallel teeth. Side view of the inner collet structure where the finger is located, FIG. 2E is a half sectional view of the mandrel body of FIG. 2D, FIG. 2F is a front view of the outer shell of the connector of FIG. 1, FIG. 2G is a half sectional view of the outer shell of FIG. 2F, and third Fig. 1 is an exploded view of the connector of Fig. 1, showing a state immediately before the connector is installed.

Claims (77)

In a bulkhead coaxial cable connector connected to an end of a coaxial cable having an exposed center lead, a tubular mandrel body of conductive material dimensioned to be pressed between the insulating core of the cable end and the outer conductor, the outer conductor of the coaxial cable A cable engaging surface portion defining a protruding blade portion extending around it to be joined, a tubular shank portion extending from the cable engaging surface portion to a radial wall portion, and a central lead extending forwardly from the radial wall portion and exposed The mandrel body including a receptor coupling portion arranged concentrically and dimensionally adapted to be slidingly contacted with the outer surface of the receiving means used in conformity with the connector, and the coaxial portion of the blade portion of the cable coupling surface of the mandrel body Pressurize the inner surface of the outer conductor of the cable Over the outer conductor is a shear stress of about not shear as the means of the radial compression force on the outer conductor, the coaxial cable connector including said compression means including an elastically deformable elastomeric material. 2. The cable engagement surface of claim 1, wherein the cable engagement surface of the mandrel body comprises a generally truncated conical surface portion converging rearward and an annular edge extending substantially radially, wherein the truncated conical surface portion is relative to the longitudinal axis of the cable. A coaxial cable connector defined at a slight angle, wherein the annular edge portion extends outwardly to the truncated conical surface portion defining an annular blade portion. 3. The radial compression means according to claim 2, wherein the radial compression means includes a snap ring that is dimensioned to forcibly fit into a coaxial cable located at the blade portion, the snap ring comprising a portion of an elastically deformable elastomeric material. Wherein the portion extends radially by the truncated conical surface to snap the coaxial cable into the annular edge portion such that the outer conductor is bent and supported at the annular blade portion. 4. The coaxial of claim 3 wherein said portion of said snap-ring defines a spline with teeth, said spline being coupled by biting an outer insulation coating of a coaxial cable to pressurize said outer conductor so that it is supported on said annular blade portion. Cable connector. 2. The apparatus of claim 1, wherein said receptor binding portion further comprises a slidable shell means dimensioned radially apart from said radial wall portion and disposed at least over said receptor coupling portion of said mandrel body, Being slidably positioned away from the facing connector end such that the receptor coupling portion of the connector slides freely on the outer surface of the receptor, and the slidable shell means is slidably positioned toward the connector end and spread radially A coaxial cable connector for engaging the connector by pressing a receptor binding portion against the outer surface of the receptor. 6. The slidable shell means of claim 5, wherein the slidable shell means further defines an inner frustoconical portion that coincides with the frustoconical surface portion of the mandrel body such that the slidable shell means is slidably positioned on the mandrel body such that the connector is connected to the And a coaxial cable connector for pressing a portion of the outer conductor of the coaxial cable against the frustoconical surface portion of the mandrel body when fastened onto the receiver. The coaxial cable connector according to claim 1, wherein a longitudinal slot is formed in the receptor coupling portion to form a slip ring slidably coupled to the outer surface of the receptor. 8. The jack of claim 7, wherein said receptor engagement portion comprises a plurality of slots to function as an extruded collet, such that said slidable shell means is fastened to the outer surface of said jack as it is positioned towards said connector end facing said receptor. Coaxial cable coupler. 4. The coaxial cable connector of claim 3 wherein the snap ring includes a cap portion loosely fitted to the receptor binding portion of the mandrel body to provide additional hoop strength to the receptor coupling portion. 10. The method of claim 9, wherein the receptor binding portion is dimensioned to radially open from the radial wall portion, and further comprises a slidable shell means disposed over at least the cap portion of the snap and the receptor coupling portion of the mandrel body. And the slidable shell means is slidably positioned away from the connector end facing the outer surface of the receptor such that the receptor binding portion of the linker is free to slide on the outer surface of the receptor, and the slidable shell means A coaxial cable connector slidably positioned towards a connector end to engage the connector by radially compressing the radially engaging jack coupling with respect to an outer surface of the receiver. 11. A coaxial cable connector according to claim 10, wherein said slidable shell means is used to guide said snap ring to a position on said coaxial cable end and mandrel body during installation of said connector at said cable end. 2. The cable engaging surface portion of claim 1, wherein the cable mating surface portion defines a protruding blade extension, the extension portion comprises a tubular structure comprising a helix, the helix protrudes upward from the structure, the helix defines an acute angle and the Coaxial cable connector with protruding blades. 13. The coaxial cable connector of claim 12, wherein the apex of the protruding blade portion is formed in a plane, and the transverse dimension of the plane is about 2 to 3 mils. 2. The cable engagement surface portion of claim 1, wherein the cable engagement surface portion has a plurality of longitudinal slots spaced apart and has an inner hole converging frustoconically toward the cable end, the slot comprising the cable engagement surface portion and the tubular shank. Extending through the portion, thereby defining the cable mating surface as collets of various diameters joining the cable ends, the cable ends having an insulated core within a predetermined dimension range having various core diameters. 15. The coaxial cable of claim 14, further comprising disposable ramping means slidably positioned over the exposed center lead of the cable to expand the collet of various diameters as the mandrel body is positioned over the cable end. coupler. A tubular mandrel body of a bulkhead coaxial cable connector, comprising: a tubular mandrel body of conductive material dimensioned to be placed manually between the insulating core of the cable end and the outer conductor, the tubular mandrel body extending around the mat to be coupled to the outer conductor of the coaxial cable A cable engaging surface defining a protruding blade portion, a tubular shank portion extending from the cable engaging surface portion to a radial wall portion, disposed concentrically about an exposed central conductor extending forwardly from the radial wall portion, A tubular mandrel body comprising a receptor coupling portion that is dimensioned to be slidingly contacted with an outer surface of the receiving means used in mating engagement. 17. The cable engaging surface of claim 16, wherein the cable mating surface comprises a generally truncated conical surface portion converging rearward and an annular edge portion extending substantially radially, wherein the truncated cone surface portion is defined at a small angle with respect to the longitudinal axis of the cable. And the annular edge portion extends outwardly to the truncated conical surface portion defining an annular blade portion, the blade portion being used to cooperate with fastening means of the cable connector slidably positioned over the cable end, the mandrel A tubular shank body of the body is tubular mandrel body mounted to the cable end. 18. The tubular mandrel body according to claim 17, wherein the microangle ranges between approximately 5 degrees and 20 degrees. 18. A tubular mandrel body according to claim 17, wherein an engagement portion of the frustoconical surface portion forming the blade portion and the substantially radially extending annular portion defines an acute angle of 90 degrees or less. 17. The apparatus of claim 16, wherein the jack coupling portion located coaxially with the exposed center lead comprises a plurality of fingers, the fingers defining a collet closure means of the connector and a cooperative inner collet structure, And a collet closure means is slidably positioned on the collet structure towards the jack to fasten the collet structure to the jack to be coupled with the connector. 21. A tubular mandrel body according to claim 20, wherein the plurality of fingers are formed by a plurality of radial slots extending longitudinally along the collet structure and spaced apart from each other. 21. A tubular mandrel body according to claim 20, wherein said plurality of fingers are formed by a plurality of slots, said slots formed by parallel cutting means for manipulating said collet structure in a single direction. 17. The jack of claim 16, wherein the jack coupling defines a low helical spiral, the helical spiral having a pitch that mates with an outer threaded surface of the jack, wherein the outer threaded surface of the jack is after the jack coupling is coupled to the jack. The portion in which the connector is to be used is a tubular mandrel body. 17. A tubular mandrel body according to claim 16, wherein the cross section of each finger defines a wall, the thickness of the wall being thicker in the open hole portion of the collet structure than the radial wall portion. 17. A tubular mandrel body according to claim 16, wherein a longitudinal slot is formed in the jack coupling portion to allow the slip ring to be slidably engaged on the outer surface of the jack. 17. The cable engagement surface of claim 16, wherein the cable engagement surface defines a protruding blade extension, the extension comprises a tubular structure comprising helix, the helix protrudes upward from the structure, the helix defines an acute angle and the Tubular mandrel body providing a protruding blade. 27. The tubular mandrel body according to claim 26, wherein the apex of the protruding blade portion is formed in a plane, and the transverse dimension of the plane is about 2 to 3 mils. 17. The cable engagement surface portion of claim 16, wherein the cable engagement surface portion has a plurality of longitudinal slots spaced apart and has an inner aperture converging frustoconically toward the cable end, the slot comprising the cable engagement surface portion and the tubular shank. Extending through the portion to define the cable mating surface as a collet of various diameters joining the cable ends, the cable end having an insulating core within a predetermined dimension range having various core diameters. 17. A tubular mandrel body according to claim 16 formed by die casting. 17. The tubular mandrel body of claim 16, wherein the tubular mandrel body is formed from an alloy selected from the group consisting of copper, zinc, and tin. 17. The tubular mandrel body of claim 16, wherein the mandrel body comprises a plate that improves lubrication properties. 31. A tubular mandrel body according to claim 30, wherein the mandrel body comprises a plate made of a material comprising tin to improve lubrication properties. A component kit assembled with a bulkhead coaxial cable connector connected to an end of a coaxial cable having an exposed center lead, comprising: a tubular mandrel body of conductive material dimensioned to be pressed between the insulating core of the cable end and an outer conductor, the coaxial A cable engagement surface portion defining a protruding blade portion extending around the engagement portion with the outer conductor of the cable, a tubular shank portion extending from the cable engagement surface portion to the radial wall portion, and extending forwardly and exposed from the radial wall portion. The mandrel body including a receptor coupling portion arranged in a concentric relation with a center conductor and dimensioned to be in contact with the outer surface of the receiving means used to mate with the connector and to be in a sliding fit engagement; and a cable engaging surface of the mandrel body Outside the coaxial cable at the blade The degree not to press the inner surface of the body being the outer conductor are shear the shear stress as a means of radial compression applied to the outer conductor, kit of parts comprising said compression means including an elastically deformable elastomeric material. 34. The cable engagement surface of claim 33, wherein the cable engagement surface of the mandrel body comprises a generally truncated conical surface portion converging rearward and an approximately radially extending annular edge portion, wherein the truncated conical surface portion is relative to the longitudinal axis of the cable. A part kit, defined by a small angle, wherein the annular edge portion extends outwardly to the truncated conical surface portion defining an annular blade portion. 34. The method of claim 33, wherein the radial compression means comprises a snap-ring dimensioned to forcibly fit into a coaxial cable located at the blade portion, the snap-ring comprising a portion of an elastically deformable elastomeric material. And the portion is radially extended by the truncated conical surface so as to snap into the annular edge portion of the coaxial cable so that the outer conductor is bent and supported by the annular blade, but the shear stress is such that the conductor is not sheared. Spare parts kit. 34. The apparatus of claim 33, wherein the jack coupling further comprises sliding shell means dimensioned to extend radially from the radial wall portion and disposed over at least the jack coupling portion of the mandrel body. A slidingly spaced position away from the facing connector end allows the jack coupling of the coupling device to slide freely on the outer surface of the jack, and the slidable shell means is slidably positioned toward the connector end and radially And a component kit for engaging the connector by pressing the jack coupling portion to be opened against the outer surface of the receptor. 36. The kit of claim 35, wherein said portion of said snap-ring defines a spline with teeth, said spline being coupled by biting an outer insulation coating of a coaxial cable to pressurize said outer conductor to be supported on said annular blade portion. part. 34. The cable engagement surface of claim 33, wherein the cable mating surface portion of the tubular mandrel body comprises a generally truncated conical surface portion and a radially extending annular wall portion converging rearwardly, wherein the truncated cone surface portion is minute with respect to the longitudinal axis of the cable. And the annular wall portion extends to the frusto-circular surface portion defining an annular blade portion and the slidable shell means further defines an inner frusto-conical portion that coincides with the frusto-conical surface portion of the mandrel body. And a slidable shell means for pressing a portion of the outer conductor of the coaxial cable against the truncated conical surface portion of the mandrel body when the slidable shell means is slidably positioned on the mandrel body. 34. The kit of claim 33, wherein a longitudinal slot is formed in the jack coupling portion to form a slip ring slidably coupled to the outer surface of the jack. 37. The jack of claim 36, wherein the jack coupling includes a plurality of slots to function as a compression collet, such that the slidable shell means engages on an outer surface of the jack as the sliding shell means is positioned toward the connector end facing the jack. Parts kit. 37. The kit of claim 36, wherein said snap ring includes a cap portion loosely fitted to said jack engagement portion of said mandrel body to provide additional hoop strength to said jack engagement portion. 42. The method of claim 41, wherein the jack coupling is dimensioned to radially open from the radial wall portion, and further comprises a slidable shell means disposed over at least the cap portion of the snap ring and the jack coupling portion of the mandrel body. And the slidable shell means is slidably positioned away from the connector end facing the outer surface of the jack such that the jack coupling portion of the connector slides freely on the outer surface of the jack, and the slidable shell means is connected to the connector end. A component kit slidably positioned toward and engaging the connector by compressing the radially extending jack coupling portion by pressing against the outer surface of the jack. 43. The kit of parts of claim 42, wherein said slidable shell means is used to guide said snap ring into position over said coaxial cable end and mandrel body while installing said connector at said cable end. 44. The apparatus of claim 43, further comprising an installation tool for attaching the mandrel body with snap ring and slidable shell means, wherein the cable end is fitted with respect to the mandrel body as the cable is pressed against the laying tool. Parts kit that may be pressurized. 45. The component kit of claim 44, wherein the installation tool enables visual observation of the position of the cable end relative to the mandrel body after the cable end is pressed against the mandrel body. 34. The jack of claim 33, wherein the jack coupling defines a low helical spiral, the helical spiral having a pitch that mates with an outer threaded surface of the jack, wherein the outer threaded surface of the jack is after the jack coupling is coupled to the jack. A parts kit wherein the assembled connector is to be used. 34. The tubular mandrel body of claim 33, wherein the cable engagement surface portion of the tubular mandrel body defines a protruding blade extension, the extension comprising a tubular structure including helix, the helix protrudes upward from the structure, the helix A part kit defining an acute angle and providing the protruding blade portion. 48. The kit of claim 47, wherein the apex of the protruding blade portion is formed in a plane, and the transverse dimension of the plane is about 2 to 3 mils. 34. The cable engagement surface portion of claim 33, wherein the cable engagement surface portion has a plurality of longitudinal slots spaced apart and has an inner hole converging frustoconically toward the cable end, the slot comprising the cable engagement surface portion and the tubular shank. Extending through the part, thereby defining the cable mating surface as a collet of various diameters joining the cable ends, the cable end having an insulating core within a predetermined dimension range having various core diameters. 34. The kit of parts of claim 33, wherein the mandrel body is formed by die casting. 34. The kit of parts of claim 33, wherein the tubular mandrel body is formed of an alloy selected from the group comprising copper, zinc, and tin. 34. The kit of parts of claim 33, wherein the tubular mandrel body includes a plate that improves lubrication properties. 53. The kit of parts of claim 51, wherein said tubular mandrel body comprises a plate material comprising a material comprising tin to improve lubrication properties. 48. The jack assembly of claim 47, wherein the jack coupling includes a plurality of slots to function as a compression collet, such that the slidable shell means engages on an outer surface of the jack as the sliding shell means is positioned towards the end of the facing facing the jack. And an installation tool for attaching the mandrel body and the snap ring and the slidable shell means in a fitted state, wherein the installation tool has fixing means for fixing the plurality of slots so that the cable is connected to the installation tool. And a component kit for allowing the installation tool and mandrel body to rotate over the cable end as it is pressed against the cable end. 56. The cable of claim 54, wherein the installation tool includes a central plug portion defining an inner wall and an opening defined through the inner wall, wherein the opening includes a central lead at the cable end and an insulating core at the cable end. The insulating wall formed by the inner wall is dimensioned so as not to enter, and the insulating wall is used to contact the inner wall of the central plug portion of the installation tool, thereby separating the fixing means from the plurality of slots so that the mandrel body Component kit for releasing the installation tool when rotated a predetermined distance from the end of the cable. 55. The apparatus of claim 54, further comprising an installation tool for attaching the mandrel body with snap ring and slidable shell means such that the cable end is fitted with respect to the mandrel body as the cable is pressed against the installation tool. Component kit that may be pressurized. 50. The kit of claim 49, further comprising disposable ramping means that can be slidably positioned over an exposed center lead of the cable to expand the collet of variable diameter as the mandrel body is positioned at the cable end. A method of assembling a bulkhead-type coaxial cable connector component kit at an end of a coaxial cable, the method comprising: peeling a first cylinder of an outer insulation coating by a first length to expose an outer braid / foil layer, the outer braid / foil layer and A preliminary step of cable end exposing the center metal conductor end by peeling the insulating material arranged in an equiaxed relationship by a second length shorter than the first length, and dimensioned to be pressed between the insulating core of the cable end and the outer conductor. A preformed tubular mandrel body of conductive material, the preformed mandrel body comprising a cable mating surface portion defining a protruding blade extension, a tubular shank portion extending from the cable mating surface portion to a radial wall portion, and the radial wall portion Extending forward from the center of the coaxial relationship with respect to the exposed center conductor And a coaxial jack coupling that is dimensioned so that the prefabricated connector slides on and touches the outer surface of the jack into which the prefabricated connector is fitted. A radial compression member for pressing the inner surface of the outer conductor of the coaxial cable to the blade portion of the tubular mandrel body. Providing a kit of parts by preforming a component, sliding the radial compression member in a direction spaced therefrom on the cable end, installing the mandrel body on the cable end, and radially compressing member. And sliding the over the cable end installed in the mandrel body to press the inner surface of the outer conductor of the coaxial cable onto the blade portion of the tubular mandrel body. 59. The method of claim 58, wherein preforming a tubular mandrel body comprises: a back converging frustoconical surface portion defined at a small angle with respect to the longitudinal axis of the cable, and up to the truncated conical surface portion defining the annular blade portion. Forming an externally extending first radially extending wall portion. 59. The method of claim 58, wherein forming the radial compression means is performed by forming a snap-ring dimensioned to fit snugly on the coaxial cable at the blade portion comprising a portion made of an elastic bottle-like elastomeric material. Sliding the snap-ring over the end of the cable installed on the mandrel body causes the elastic deformation of an elastomeric material to extend radially by the truncated conical surface toward the coaxial cable towards the radial wall. By means of snapping so that the outer conductor is supported by the blade portion. 61. The method of claim 60, wherein the method of forming the snap-ring comprises forming the elastomeric portion into a toothed spline, wherein the step of causing the snap-ring to slide over the cable end comprises: And biting the outer insulation sheath of the coaxial cable so that the outer conductor is supported at the blade. 59. The method of claim 58, wherein forming the part kit comprises forming the jack coupling portion of the mandrel body radially apart from the radial wall portion, and securely coupling at least the entire jack coupling portion of the mandrel body. Forming a slidable shell means, wherein the slidable shell means is installed by sliding the shell means away from the cable end just before the sliding of the radial compression means over the cable end. And transferring the radial compression means over a cable end installed in the mandrel body by sliding the slidable shell means toward the cable end. 63. The method of claim 62, wherein forming the slidable shell means comprises defining an inner frusto conical portion that coincides with the truncated conical surface portion of the mandrel body, wherein the slidable shell means comprises: And sliding toward the inner frustoconical surface portion includes forcing a portion of the outer conductor of the coaxial cable against the frustoconical surface portion of the mandrel body. 63. The method of claim 62, wherein forming the jack coupling is performed by forming a slot along its length, and wherein the outer shell means to slide over the mandrel body is such that the jack coupling is mated with the connector. How to force compression on the jack. 59. The method of claim 58, further comprising: sliding the radial compression means over the cable end in a direction away from it, installing the mandrel body over the cable end, and installing the radial compression means to the mandrel body. And providing an installation tool to facilitate the step of slipping over the end of the cable to compress the inner surface of the outer conductor of the coaxial cable onto the blade portion of the tubular mandrel body. 67. The method of claim 65, wherein providing the installation tool includes inserting the mandrel body and radial compression means into the tool and using the tool as a finger grip, such that the mandrel body and the cable end are coupled to the mandrel body. Receiving, aligning and supporting the radial compression means. 66. The method of claim 65, comprising preassembling the mandrel body and the radial compression means in the installation tool to supply the installer / user with the step of providing the installation tool. 69. The method of claim 68, wherein forming the cable mating surface of the tubular mandrel body comprises forming a protruding blade extension that projects upwardly at an acute angle from the mating surface, and providing the protruding blade portion. How to. 69. The connector of claim 68, wherein forming the jack coupling comprises forming a plurality of slots such that the jack coupling portion functions as a compression collet such that the slidable shell means faces the jack. The installation tool and the mandrel body on the cable end as the cable is pressed against the disposable installation tool, including fastening means for fastening to the outer surface of the jack as positioned toward Forming the installation tool to be rotated together, the step of aligning the mandrel body, the snap ring and the slidable shell means into the installation tool, the step of installing the mandrel body at the cable end. The installation tool and the mandrel body over the cable end Rotating. 70. The method of claim 69, wherein forming the installation tool includes forming a central plug portion defining an inner wall and an opening through the inner wall, wherein the opening passes through a central lead of the cable end. And the insulating wall formed by the insulating core of the cable end is dimensioned so as not to pass through, and the step of rotating the installation tool causes the insulation wall to contact the inner wall of the central plug portion of the installation tool so that the mandrel body Removing said securing means from said plurality of slots and releasing said installation tool when rotated over a cable end by a predetermined length. 70. The method of claim 69, wherein forming the installation tool comprises rotating the installation tool with respect to the cable end of the mandrel and then using the transparent material to visually observe the location of the cable relative to the position of the mandrel. Forming. 59. The method of claim 58, wherein forming the cable mating surface portion of the mandrel body comprises forming a generally frustoconical inner hole that converges towards the cable end, wherein the cable mating surface portion and the tubular shank portion are formed. Forming a plurality of longitudinal slots extending through and spaced apart from each other, thereby defining the cable ends with variable diameter collets that engage cable ends having insulating cores of various core diameters within a predetermined range. 73. The method of claim 72, further comprising: forming a disposable ramping means, slidably positioning the ramping means on an exposed center lead of the cable, and passing the variable diameter collet by the ramping number of the mandrel body. Expanding the diameter as it is installed at the cable end, and removing the ramping means from the assembled cable connector. 59. The method of claim 58, wherein forming the mandrel body is performed by die casting the mandrel body with a suitable metal material. 75. The method of claim 74, wherein the suitable metal material is selected from the group comprising copper, zinc and tin. 59. The method of claim 58, wherein forming the tubular mandrel body comprises flattening the mandrel body to include a flat plate to improve lubrication properties. 77. The method of claim 76, wherein said planarization step is performed with a material comprising tin. ※ Note: The disclosure is based on the initial application.