최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
DataON 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Edison 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0173355 (2014-02-05) |
등록번호 | US-9595776 (2017-03-14) |
발명자 / 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 | 피인용 횟수 : 0 인용 특허 : 538 |
A connector includes, in one embodiment, a post, a coupling element configured to engage the post, and a connector body configured to engage the post. The connector body, in one embodiment, is configured to produce a biasing force.
1. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a post comprising a first end, a second end, and a flange, wherein the post is configured to receive the center conductive strand;a coupling ele
1. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a post comprising a first end, a second end, and a flange, wherein the post is configured to receive the center conductive strand;a coupling element configured to engage the post and configured to move between a first position, where, as the coupling element is tightened onto an interface port, the post does not contact the interface port, and a second position, where, as the coupling element is tightened onto the interface port, the post contacts the interface port, the second position being axially spaced from the first position, the coupling element comprising a first end, a second end, and an inward lip; anda connector body configured to engage the post and receive a coaxial cable when the connector is in an assembled state, the connector body comprising: an integral body biasing element comprising a coupling element contact portion configured to extend from the connector body when the connector is in the assembled state; andan annular groove configured to allow the integral body biasing element to deflect along an axial direction,wherein the integral body biasing element is configured to exert a biasing force against the coupling element sufficient to axially urge the inward lip of the coupling element away from the connector body and toward the flange of the post at least until the post contacts the interface port as the coupling element is tightened on the interface port, so as to improve electrical grounding reliability between the coupling element and the post, even when the post is not in contact with the interface port,wherein the coupling element is rotatable relative to the post while the biasing force is being exerted against the coupling element,wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port,wherein the inward lip of the coupling element comprises an inward protrusion of the coupling element,wherein the connector body comprises a second component of the connector that is securable to the post at a first connector body end of the connector body and is configured to receive a first portion of the coaxial cable at a second connector body end of the connector body,wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force,wherein the integral body biasing element comprises an integral portion of the connector body that is configured to constantly exert the spring force by pushing against the coupling element, the integral body biasing element being formed of a single, unitary structure with the connector body,wherein the coupling element contact portion of the integral body biasing element comprises a second portion of the integral body biasing element that is configured to engage the coupling element,wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the coupling element in a direction toward the flange of the post,wherein the annular groove comprises a narrow, ring-shaped channel formed by the connector body that is configured to allow: (a) the integral body biasing element to be deflected within the narrow, ring-shaped channel; and (b) the integral body biasing element to exert the constantly exerted spring force, andwherein the improving of the electrical grounding reliability between the coupling element and the post comprises helping to maintain a reliable ground path through the coupling element and the post. 2. The connector of claim 1, wherein the connector body comprises a first part located rearward of the annular groove, the connector body being configured to enable the deflection without causing deformation of the first part of the connector body. 3. The connector of claim 1, wherein the connector body is configured to enable the deflection of the integral body biasing element without causing destruction of the connector body. 4. The connector of claim 1, wherein the integral body biasing element comprises a spring characteristic. 5. The connector of claim 1, wherein the dielectric is surrounded by the outer conductor, and the dielectric comprises an insulation material. 6. The connector of claim 1, wherein the coupling element contact portion is configured to enable rotation of the coupling element relative to the post while the biasing force is being exerted against the coupling element. 7. The connector of claim 1, wherein the integral body biasing element comprises a surface that projects axially to engage the coupling element, the surface projecting toward the coupling element. 8. The connector of claim 1, wherein the integral body biasing element is configured to constantly exert the biasing force against the coupling element, and the integral body biasing element is integrally formed with the connector body. 9. The connector of claim 1, wherein the integral body biasing element is made of a substantially non-metallic, non-conductive material. 10. The connector of claim 1, wherein the integral body biasing element operates with the annular groove to permit the deflection so as to bias the coupling element against the post. 11. The connector of claim 1, wherein the flange of the post comprises a second surface, the integral body biasing element biasing the inward lip of the coupling element against the second surface. 12. The connector of claim 1, wherein the connector is in a partially tightened position when the coupling element is in the first position, and wherein the connector is in a fully tightened position when the coupling element is in the second position. 13. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a post comprising a first post end, a second post end, and a flange, wherein the post is configured to receive the center conductive strand;a coupling element configured to engage the post and configured to move between a first position, where, as the coupling element is tightened onto an interface port, the post does not contact the interface port, and a second position, where, as the coupling element is tightened onto the interface port, the post contacts the interface port, the second position being axially spaced from the first position, the coupling element comprising a first end, a second end, and an inward lip; anda connector body configured to engage the post and receive the coaxial cable when the connector is in an assembled state, the connector body comprising: an integral body biasing element comprising a coupling element contact portion configured to extend from the connector body when the connector is in the assembled state; andan annular groove configured to allow the integral body biasing element to deflect along an axial direction,wherein the integral body biasing element is configured to exert a biasing force against the coupling element sufficient to axially urge the inward lip of the coupling element away from the connector body and toward the flange of the post at least until the post contacts the interface port as the coupling element is tightened on the interface port, so as to improve electrical grounding reliability between the coupling element and the post, even when the post is not in contact with the interface port, andwherein the coupling element is rotatable relative to the post while the biasing force is being exerted against the coupling element. 14. The connector of claim 13, wherein the integral body biasing element and the coupling element are configured to cooperate to enable the coupling element to rotate relative to the post while the biasing force is being exerted against the coupling element. 15. The connector of claim 13, wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port. 16. The connector of claim 13, wherein the inward lip of the coupling element comprises an inward protrusion of the coupling element. 17. The connector of claim 13, wherein the connector body comprises a second component of the connector that is securable to the post at a first connector body end of the connector body and is configured to receive a first portion of the coaxial cable at a second connector body end of the connector body. 18. The connector of claim 13, wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force. 19. The connector of claim 18, wherein the integral body biasing element comprises an integral portion of the connector body that is configured to constantly exert the spring force by pushing against the coupling element, the integral body biasing element being formed of a single, unitary structure with the connector body. 20. The connector of claim 13, wherein the coupling element contact portion of the integral body biasing element comprises a second portion of the integral body biasing element that is configured to engage the coupling element. 21. The connector of claim 13, wherein the coupling element comprises a plurality of threads. 22. The connector of claim 13, wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the coupling element in a direction toward the flange of the post. 23. The connector of claim 19, wherein the annular groove comprises a narrow, ring-shaped channel formed by the connector body that is configured to allow: (a) the biasing element to be deflected within the narrow, ring-shaped channel; and (b) the integral body biasing element to exert the constantly exerted spring force. 24. The connector of claim 13, wherein the improving of the electrical grounding reliability between the coupling element and the post comprises helping to maintain a reliable ground path through the coupling element and the post. 25. The connector of claim 13, wherein the connector body comprises a first part located rearward of the annular groove, the connector body being configured to enable the deflection without causing deformation of the first part of the connector body. 26. The connector of claim 13, wherein the connector body is configured to enable the deflection of the integral body biasing element without causing destruction of the connector body. 27. The connector of claim 13, wherein the integral body biasing element comprises a spring characteristic. 28. The connector of claim 13, wherein the dielectric is surrounded by an outer conductor of the coaxial cable, and the dielectric comprises an insulation material. 29. The connector of claim 13, wherein the coupling element contact portion is configured to enable rotation of the coupling element relative to the post while the biasing force is being exerted against the coupling element. 30. The connector of claim 13, wherein the integral body biasing element comprises a surface that projects axially to engage the coupling element, the surface projecting toward the coupling element. 31. The connector of claim 13, wherein the integral body biasing element is configured to constantly exert the biasing force against the coupling element, and the integral body biasing element is integrally formed with the connector body. 32. The connector of claim 13, wherein the integral body biasing element is made of a substantially non-metallic, non-conductive material. 33. The connector of claim 13, wherein the integral body biasing element operates with the annular groove to permit the deflection so as to bias the coupling element against the post. 34. The connector of claim 13, wherein the flange of the post comprises a second surface, the integral body biasing element biasing the inward lip of the coupling element against the second surface. 35. The connector of claim 13, wherein the connector is in a partially tightened position when the coupling element is in the first position, and wherein the connector is in a fully tightened position when the coupling element is in the second position. 36. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a post comprising a flange, the post configured to receive the center conductive strand;a coupling means for coupling to an interface port, engaging the post, and axially moving between a first position, where the post does not engage the interface port, and a second position, where the post engages the interface port, the second position being axially spaced from the first position, the coupling means comprising an inward lip, the coupling means also comprising a contact means facing a rearward direction; anda body means for engaging the coaxial cable when the connector is in an assembled state, the body means comprising: a resilient biasing means for biasing the contact means of the coupling means when the connector is in the assembled state; anda deflection space means for allowing the resilient biasing means to flexibly deflect along an axial direction and exert a biasing force against the contact means of the coupling means sufficient to axially move the inward lip of the coupling means toward the flange of the post when the coupling means axially moves between the first position and the second position so as to improve electrical grounding continuity between the coupling means and the post even when the coupling means is not fully tightened relative to the interface port,wherein the coupling means is rotatable relative to the post while the biasing force is being exerted against the coupling means,wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port,wherein the coupling means comprises a part selected from the group consisting of: (a) a nut; and (b) another element configured to allow the connector to be attached to the interface port,wherein the inward lip of the coupling means comprises an inward protrusion of the coupling means,wherein the contact means of the coupling means comprises a surface of the coupling means that the resilient biasing means pushes against,wherein the body means comprises a second component of the connector that is securable to the post at a first body means end of the body means and is configured to receive a first portion of the coaxial cable at a second body means end of the body means,wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force,wherein the resilient biasing means comprises an integral portion of the body means that is configured to constantly exert the spring force by pushing against the coupling means,wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the coupling means in a direction toward the flange of the post,wherein the deflection space means comprises a narrow, ring-shaped channel formed by the body means that is configured to allow: (a) the resilient biasing means to be deflected within the narrow, ring-shaped channel; and (b) the resilient biasing means to exert the constantly exerted spring force, andwherein the improving of the electrical grounding continuity between the coupling means and the post comprises helping to maintain a reliable ground path through the coupling means and the post. 37. The connector of claim 36, wherein the body means comprises a first part located rearward of the deflection space, the body means being configured to enable the deflection without causing deformation of the first part of the body means. 38. The connector of claim 36, wherein the body means is configured to enable the deflection of the resilient biasing means without causing destruction of the body means. 39. The connector of claim 36, wherein the resilient biasing means comprises a spring characteristic. 40. The connector of claim 36, wherein the dielectric is surrounded by the outer conductor, and the dielectric comprises an insulation material. 41. The connector of claim 36, wherein the resilient biasing means is configured to enable rotation of the coupling means relative to the post while the biasing force is being exerted against the coupling means. 42. The connector of claim 36, wherein the resilient biasing means comprises a surface that projects axially to engage the coupling means, the surface projecting toward the coupling means. 43. The connector of claim 36, wherein the resilient biasing means is configured to constantly exert the biasing force against the coupling means, and the resilient biasing means is integrally formed with the body means. 44. The connector of claim 36, wherein the resilient biasing means is made of a substantially non-metallic, non-conductive material. 45. The connector of claim 36, wherein the coupling means comprises a wall extending along an axial direction and toward the rearward direction, and wherein the contact means of the coupling means is substantially perpendicular to the wall of the coupling means. 46. The connector of claim 45, wherein the contact means of the coupling means is located axially rearward from the wall of the coupling means. 47. The connector of claim 46, wherein the connector is in a partially tightened position when the coupling means is in the first position, and wherein the connector is in a fully tightened position when the coupling means is in the second position. 48. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a post comprising a flange, the post configured to receive the center conductive strand;a coupling means for coupling to an interface port, engaging the post, and axially moving between a first position, where the post does not engage the interface port, and a second position, where the post engages the interface port, the second position being axially spaced from the first position, the coupling means comprising an inward lip, the coupling means also comprising a contact means facing a rearward direction; anda body means for engaging the coaxial cable when the connector is in an assembled state, the body means comprising: a resilient biasing means for biasing the contact means of the coupling means when the connector is in the assembled state; anda deflection space means for allowing the resilient biasing means to flexibly deflect along an axial direction and exert a biasing force against the contact means of the coupling means sufficient to axially move the inward lip of the coupling means toward the flange of the post when the coupling means axially moves between the first position and the second position so as to improve electrical grounding continuity between the coupling means and the post even when the coupling means is not fully tightened relative to the interface port,wherein the coupling means is rotatable relative to the post while the biasing force is being exerted against the coupling means. 49. The connector of claim 48, wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port. 50. The connector of claim 48, wherein the coupling means comprises a part selected from the group consisting of: (a) a nut; and (b) another element configured to allow the connector to be attached to the interface port. 51. The connector of claim 48, wherein the inward lip of the coupling means comprises an inward protrusion of the coupling means. 52. The connector of claim 48, wherein the contact means of the coupling means comprises a surface of the coupling means that the resilient biasing means pushes against. 53. The connector of claim 48, wherein the body means comprises a second component of the connector that is securable to the post at a first body means end of the body means and is configured to receive a first portion of the coaxial cable at a second body means end of the body means. 54. The connector of claim 48, wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force. 55. The connector of claim 54, wherein the resilient biasing means comprises an integral portion of the body means that is configured to constantly exert the spring force by pushing against the coupling means. 56. The connector of claim 48, wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the coupling means in a direction toward the flange of the post. 57. The connector of claim 55, wherein the deflection space means comprises a narrow, ring-shaped channel formed by the body means that is configured to allow: (a) the resilient biasing means to be deflected within the narrow, ring-shaped channel; and (b) the resilient biasing means to exert the constantly exerted spring force. 58. The connector of claim 48, wherein the improving of the electrical grounding continuity between the coupling means and the post comprises helping to maintain a reliable ground path through the coupling means and the post. 59. The connector of claim 48, wherein the body means comprises a first part located rearward of the deflection space, the body means being configured to enable the deflection without causing deformation of the first part of the body means. 60. The connector of claim 48, wherein the body means is configured to enable the deflection of the resilient biasing means without causing destruction of the body means. 61. The connector of claim 48, wherein the resilient biasing means comprises a spring characteristic. 62. The connector of claim 48, wherein the dielectric is surrounded by an outer conductor of the coaxial cable, and the dielectric comprises an insulation material. 63. The connector of claim 48, wherein the resilient biasing means is configured to enable rotation of the coupling means relative to the post while the biasing force is being exerted against the coupling means. 64. The connector of claim 48, wherein the resilient biasing means comprises a surface that projects axially to engage the coupling means, the surface projecting toward the coupling means. 65. The connector of claim 48, wherein the resilient biasing means is configured to constantly exert the biasing force against the coupling means, and the resilient biasing means is integrally formed with the body means. 66. The connector of claim 48, wherein the resilient biasing means is made of a substantially non-metallic, non-conductive material. 67. The connector of claim 48, wherein the coupling means comprises a wall extending along an axial direction and toward the rearward direction, and wherein the contact means of the coupling means is substantially perpendicular to the wall of the coupling means. 68. The connector of claim 67, wherein the contact means of the coupling means is located axially rearward from the wall of the coupling means. 69. The connector of claim 68, wherein the connector is in a partially tightened position when the coupling means is in the first position, and wherein the connector is in a fully tightened position when the coupling means is in the second position. 70. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a threaded nut configured to engage an interface port and move between a first position, where the threaded nut is partially threaded on the interface port, and a second position, where the threaded nut is fully threaded on the interface port, the threaded nut comprising an inward lip, the threaded nut also comprising a radial contact surface facing away from the interface port when the threaded nut is engaged with the interface port;a post rotatably attached to the threaded nut, the post comprising a flange; anda connector body configured to engage the post when the connector is in an assembled state, the connector body comprising: an integral biasing structure comprising an integral body biasing element, the integral biasing structure comprising a first surface extending a radial distance with respect to a general axis of the connector, wherein the integral biasing structure is configured to facilitate biasing engagement with the radial contact surface of the threaded nut when the connector is in the assembled state; anda groove located axially rearward of the integral biasing structure and configured to permit axial deflection of the integral biasing structure to provide a biasing force against the radial contact surface of the threaded nut sufficient to move the inward lip of the threaded nut toward the flange of the post until the threaded nut is fully threaded onto the interface port and the post makes constant, physical and electrical contact with the interface port,wherein the threaded nut is rotatable relative to the post while the biasing force is being exerted against the threaded nut,wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port,wherein the inward lip of the threaded nut comprises an inward protrusion of the threaded nut,wherein the radial contact surface of the threaded nut comprises a surface of the threaded nut that the integral biasing structure pushes against,wherein the connector body comprises a component of the connector that is securable to the post at a first connector body end of the connector body and is configured to receive a first portion of the coaxial cable at a second connector body end of the connector body,wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force,wherein the integral biasing structure comprises an integral portion of the connector body that is configured to constantly exert the spring force by pushing against the threaded nut, the integral biasing structure being formed as a single, unitary structure with the connector body,wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the threaded nut in the direction of the flange of the post, andwherein the groove comprises a narrow, ring-shaped channel formed by the connector body that is configured to allow: (a) the integral biasing structure to be deflected within the narrow, ring-shaped channel; and (b) the integral biasing structure to constantly exert the spring force. 71. The connector of claim 70, wherein the connector body comprises a first part located rearward of the groove, the connector body being configured to enable the deflection without causing deformation of the first part of the connector body. 72. The connector of claim 70, wherein the connector body is configured to enable the axial deflection of the integral biasing structure without causing destruction of the connector body. 73. The connector of claim 70, wherein the integral biasing structure comprises a spring characteristic. 74. The connector of claim 70, wherein the dielectric is surrounded by the outer conductor, and the dielectric comprises an insulation material. 75. The connector of claim 70, wherein the integral biasing structure is configured to enable rotation of the threaded nut relative to the post while the biasing force is being exerted against the threaded nut. 76. The connector of claim 70, wherein the integral biasing structure comprises a surface that extends axially to engage the threaded nut, the surface extending toward the threaded nut. 77. The connector of claim 70, wherein the integral biasing structure is configured to constantly exert the biasing force against the threaded nut and the integral biasing structure is integrally formed with the connector body. 78. The connector of claim 70, wherein the integral body biasing element is made of a substantially non-metallic, non-conductive material. 79. The connector of claim 70, wherein the first surface of the integral biasing structure projects along an axial distance to engage the threaded nut. 80. The connector of claim 70, wherein the threaded nut comprises a wall extending along an axial direction and toward a rearward direction, and wherein the radial contact surface of the threaded nut is substantially perpendicular to the wall of the threaded nut. 81. The connector of claim 80, wherein the radial contact surface of the threaded nut is located axially rearward from the wall of the threaded nut. 82. The connector of claim 80, wherein the integral biasing structure is configured to constantly exert the biasing force against the radial contact surface of the threaded nut when the connector is in the assembled state and when the threaded nut moves between the first position and the second position. 83. A connector attachable to a coaxial cable, the coaxial cable comprising a center conductive strand surrounded by a dielectric, the connector comprising: a threaded nut configured to engage an interface port and move between a first position, where the threaded nut is partially threaded on the interface port, and a second position, where the threaded nut is fully threaded on the interface port, the threaded nut comprising an inward lip, the threaded nut also comprising a radial contact surface facing away from the interface port when the threaded nut is engaged with the interface port;a post rotatably attached to the threaded nut, the post comprising a flange; anda connector body configured to engage the post when the connector is in an assembled state, the connector body comprising: an integral biasing structure comprising an integral body biasing element, the integral biasing structure comprising a first surface extending a radial distance with respect to a general axis of the connector, wherein the integral biasing structure is configured to facilitate biasing engagement with the radial contact surface of the threaded nut when the connector is in the assembled state; anda groove located axially rearward of the integral biasing structure and configured to permit axial deflection of the integral biasing structure to provide a biasing force against the radial contact surface of the threaded nut sufficient to move the inward lip of the threaded nut toward the flange of the post until the threaded nut is fully threaded onto the interface port and the post makes constant, physical and electrical contact with the interface port,wherein the threaded nut is rotatable relative to the post while the biasing force is being exerted against the threaded nut. 84. The connector of claim 83, wherein the post comprises a first component of the connector configured to make electrical contact with an outer conductor of the coaxial cable and the interface port when the connector is fully tightened onto the interface port. 85. The connector of claim 83, wherein the inward lip of the threaded nut comprises an inward protrusion of the threaded nut. 86. The connector of claim 83, wherein the radial contact surface of the threaded nut comprises a surface of the threaded nut that the integral biasing structure pushes against. 87. The connector of claim 83, wherein the connector body comprises a component of the connector that is securable to the post at a first connector body end of the connector body and is configured to receive a first portion of the coaxial cable at a second connector body end of the connector body. 88. The connector of claim 83, wherein the biasing force comprises a force selected from the group consisting of a spring force and a pushing force. 89. The connector of claim 88, wherein the integral biasing structure comprises an integral portion of the connector body that is configured to constantly exert the spring force by pushing against the threaded nut, the integral biasing structure being formed as a single, unitary structure with the connector body. 90. The connector of claim 83, wherein the sufficiency of the biasing force comprises an adequate force to push the inward lip of the threaded nut in a direction toward the flange of the post. 91. The connector of claim 88, wherein the groove comprises a narrow, ring-shaped channel formed by the connector body that is configured to allow: (a) the integral biasing structure to be deflected within the narrow, ring-shaped channel; and (b) the integral biasing structure to constantly exert the spring force. 92. The connector of claim 83, wherein the connector body comprises a first part located rearward of the groove, the connector body being configured to enable the deflection without causing deformation of the first part of the connector body. 93. The connector of claim 83, wherein the connector body is configured to enable the axial deflection of the integral biasing structure without causing destruction of the connector body. 94. The connector of claim 83, wherein the integral biasing structure comprises a spring characteristic. 95. The connector of claim 83, wherein the dielectric is surrounded by an outer conductor of the coaxial cable, and the dielectric comprises an insulation material. 96. The connector of claim 83, wherein the integral biasing structure is configured to enable rotation of the threaded nut relative to the post while the biasing force is being exerted against the threaded nut. 97. The connector of claim 83, wherein the integral biasing structure comprises a surface that extends axially to engage the threaded nut, the surface extending toward the threaded nut. 98. The connector of claim 83, wherein the integral biasing structure is configured to constantly exert the biasing force against the threaded nut and the integral biasing structure is integrally formed with the connector body. 99. The connector of claim 83, wherein the integral body biasing element is made of a substantially non-metallic, non-conductive material. 100. The connector of claim 83, wherein the first surface of the integral biasing structure projects along an axial distance to engage the threaded nut. 101. The connector of claim 83, wherein the threaded nut comprises a wall extending along an axial direction and toward a rearward direction, and wherein the radial contact surface of the threaded nut is substantially perpendicular to the wall of the threaded nut. 102. The connector of claim 101, wherein the radial contact surface of the threaded nut is located axially rearward from the wall of the threaded nut. 103. The connector of claim 101, wherein the integral biasing structure is configured to constantly exert the biasing force against the radial contact surface of the threaded nut when the connector is in the assembled state and when the threaded nut moves between the first position and the second position.
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