Patent Description:
Due to the special structural constraints of leaky cables, at present, quick installation is seldom considered in the design of existing commercially available leaky cable connectors, and shells of a radio frequency leaky cable connector in the industry are usually screwed and fixed on a leaky cable by threads. In one method, a copper sheet of an external conductor of a leaky cable is flanged. An outer copper sheet on an end surface of the flanged leaky cable is clamped within a pressure surface of front and rear shells of the connector. The copper sheet is fixed by forces of the tightened front and rear shells, to transfer electrical properties. This mounting method is more complex. The separate rear shell needs to be mounted first, a flange is made on the structure of the rear shell, and then the front shell is mounted and tightened. This manner is non-integral mounting. In another method, a contact member structure with an embedded spring coil is used at a contact position of a copper sheet of a leaky cable. However, the spring coil is an elastic slotted structure and is prone to deformation. After coming into radial contact, the contact member with the spring coil and an external conductor of a cable cannot be compressed. A <NUM>-degree reliable contact cannot be achieved to obtain high contact pressure. The connection tends to fail. The stability of dynamic intermodulation is poor in special application environments. The contact member with the spring coil tends to deviate from the normal value and cannot be used repeatedly. After a mounting failure occurs, the spring coil is prone to damage when the contact member is pulled out and as a result can no longer be used. In still another method, a slotted cable clamp with a closed ring or a C-shaped opening is used. The method has low stability, and the connector tends to fall off.

Publication <CIT>, which discloses the preamble of independent claim <NUM>, shows a coaxial connector consisting of a back nut, outer and inner terminals, and an insulator. The back nut is made of a single tubular piece and does not enclose any further parts. In connecting a coaxial cable to the connector, the cable is inserted through the back nut, and a portion of the outer conductor at the end of the cable is flared and shaped along a tapered clamping face of the back nut. The back nut is then axially displaced, as by threading the back nut over the outer terminal, to clamp the flared end of the outer conductor of the coaxial cable between the outer terminal of the connector and the back nut thereof.

Publication <CIT> shows a connector for cables with a plurality of connector members including a first connector member, a second connector member, and a conductive pin. The connector members cooperate to engage an end of a cable.

Publication <CIT> shows a permanent connector that interconnects a hard-line coaxial cable to a connection housing. A contact is interconnected with and extends coaxially through a connector body. A collet one-piece with the contact receives a central conductor of the coaxial cable, while a sealing member and mandrel receive an outer conductor of the coaxial cable between them. A compression body positioned radially adjacent a portion of the connector body moves axially between first and second positions, wherein when the compression body is in its first position, the coaxial cable is removable from within the connector, and when the compression body is in its second position, the coaxial cable is not removable from within the connector. The compression body acts indirectly upon the sealing member so that an electrical connection is made between the sealing member and the outer conductor of the cable when the compression body is in its second position.

Therefore, a technical problem to be resolved by the present application is to provide a mounting structure for a leaky cable connector and a leaky cable connector that have reliable connection and adequate use performance to overcome the disadvantage that a leaky cable connector and a leaky cable in the prior art have low connection stability and tend to fall off to affect the use performance.

To resolve the foregoing technical problems, the present application provides a mounting structure for a leaky cable connector, including:.

Optionally, an end surface of at least one of the cable clamp or the first shell facing the gap is a tapered surface.

Optionally, an end surface of the cable clamp facing the gap is a tapered surface with an inner diameter gradually increasing from one end close to the second shell to the other end close to the first shell, and an end surface of the first shell facing the gap is formed by at least two partial inclined surfaces.

Optionally, a third limiting member and a fourth limiting member are disposed at an interval in an axial direction in the second shell, a first sealing member, a housing, and a pressure ring are sequentially disposed between the third limiting member and the fourth limiting member, the pressure ring abuts against the fourth limiting member, the first sealing member abuts against the third limiting member, and the housing abuts against both the first sealing member and the pressure ring.

Optionally, the housing is provided with a tapered surface matching the cable clamp, to apply a radial pressing force to the cable clamp under the action of an external force.

Optionally, an annular groove is provided in a contact surface between the first shell and the second shell, and a second sealing member is disposed inside the annular groove.

Optionally, the first shell and the second shell are assembled by interference fit.

Further provided is a leaky cable connector, including the mounting structure for a leaky cable connector of the present application.

The technical solution of the present application has the following advantages:.

Reference numerals:
<NUM>. first shell; <NUM>. second shell; <NUM>. leaky cable; <NUM>. cable clamp; <NUM>. assembly space; <NUM>. protrusion; <NUM>. gap; <NUM>. first limiting member; <NUM>. second limiting member; <NUM>. jack socket; <NUM>. central conductor; <NUM>. riveting tube; <NUM>. insulator; <NUM>. first sealing member; <NUM>. housing; <NUM>. pressure ring; <NUM>. annular groove; and <NUM>. second sealing member.

<FIG> show a specific embodiment of a mounting structure for a leaky cable connector, including a first shell <NUM> and a second shell <NUM> that are sleeved with each other in an axial direction. The first shell <NUM> and the second shell <NUM> are assembled by interference fit. The first shell <NUM> is disposed inside. The second shell <NUM> is disposed outside. A mounting space allowing a leaky cable <NUM> to pass through is provided in each of the first shell <NUM> and the second shell <NUM>.

A cable clamp <NUM> is disposed at a connection between the first shell <NUM> and the second shell <NUM>. An inner circumference of the first shell <NUM> is formed with an assembly space <NUM> allowing insertion of the cable clamp <NUM> under the action of an external force. Correspondingly, the cable clamp <NUM> is formed with a protrusion <NUM> adapting to the assembly space <NUM>, and extends in a direction of the assembly space <NUM> away from the first shell <NUM>. A gap <NUM> allowing insertion of an external conductor of the leaky cable <NUM> is provided between a main body of the cable clamp <NUM> and the first shell <NUM>. When no leaky cable <NUM> passes through the mounting spaces in the first shell <NUM> and the second shell <NUM>, the other end of the cable clamp <NUM> opposite to the protrusion <NUM> is provided with a step used as a first limiting member <NUM>, and the first shell <NUM> is provided with a bump used as a second limiting member <NUM> matching the first limiting member <NUM>. Therefore, the cable clamp <NUM> is limited at a current position. When the leaky cable <NUM> and the mounting structure are assembled, that is, as the leaky cable <NUM> gradually passes through the mounting spaces in the second shell <NUM> and the first shell <NUM>, the first limiting member <NUM> climbs over the second limiting member <NUM> under the action of an external force to insert the protrusion <NUM> in the assembly space <NUM> for fastening, and at the same time the cable clamp <NUM> is subjected to a force to move toward the first shell <NUM> to fasten the external conductor of the leaky cable <NUM>.

A plurality of channels are provided in the cable clamp <NUM>, and a barb is disposed on an inner wall of the cable clamp <NUM>. When the cable clamp <NUM> is subjected to a force to fasten the external conductor of the leaky cable <NUM>, the barb is clamped in an outer sheath of the leaky cable <NUM>, thereby improving the stability of mounting. A stepped surface is provided on a side of the barb. During the mounting of the leaky cable <NUM>, the stepped surface abuts against the outer sheath of the leaky cable <NUM>, to limit a mounting size of the leaky cable <NUM>.

Specifically, an end surface of the cable clamp <NUM> facing the gap <NUM> is a tapered surface with an inner diameter gradually increasing from one end close to the second shell <NUM> to the other end close to the first shell <NUM>, and an end surface of the first shell <NUM> facing the gap <NUM> is formed by two partial inclined surfaces. The two partial inclined surfaces form an arc-shaped surface protruding outward away from the gap <NUM>.

A radial end surface of the first shell <NUM> located in the second shell <NUM> contacts an end surface of a foaming layer of the leaky cable <NUM>, to limit the movement of the leaky cable <NUM>. An internal conductor is disposed in an axial direction in the first shell <NUM>. The internal conductor includes a jack socket <NUM>, a central conductor <NUM>, and a riveting tube <NUM> that are sequentially disposed. A first step is disposed on one side of the central conductor <NUM> close to the riveting tube <NUM>. A blind hole is provided at a central position. A through hole matching the first step is provided in the riveting tube <NUM>. The blind hole is expanded to fasten the riveting tube <NUM> on the central conductor <NUM> in a riveting manner. The other side of the central conductor <NUM> close to the jack socket <NUM> is provided with a second step. The second step is provided with an insulator <NUM>, and the jack socket <NUM> and the central conductor <NUM> are fastened by interference fit. The jack socket <NUM> further limits the axial movement of the insulator <NUM>. The insulator <NUM> matches the first shell <NUM>, to fasten the internal conductor inside the first shell <NUM>.

A third limiting member and a fourth limiting member are disposed at an interval in an axial direction in the second shell <NUM>. The third limiting member and the fourth limiting member are respectively stepped surfaces formed in the middle of the second shell <NUM> and at an end of the second shell <NUM> away from the first shell <NUM>. A first sealing member <NUM>, a housing <NUM>, and a pressure ring <NUM> are sequentially disposed between the third limiting member and the fourth limiting member. The pressure ring <NUM> abuts against the fourth limiting member, to position the pressure ring <NUM>, and the pressure ring <NUM> is assembled with the second shell <NUM> by interference fit. The first sealing member <NUM> abuts against the third limiting member. The housing <NUM> abuts against both the first sealing member <NUM> and the pressure ring <NUM>. The pressure ring <NUM> limits that the first sealing member <NUM> and the housing <NUM> can only move between the third limiting member and a left end of the pressure ring <NUM>. It is avoided that the housing <NUM> moves rightward in a free state to apply a force to the cable clamp <NUM>, and as a result the gap between the cable clamp <NUM> and the first shell <NUM> is reduced to affect the insertion of the external conductor of the leaky cable <NUM>. When moving in a direction away from the first shell <NUM>, the housing <NUM> presses the first sealing member <NUM> to implement sealing and waterproofing.

To further improve the stability of the connection, an end surface of the cable clamp <NUM> away from the axis of the first shell <NUM> is also a tapered surface. The housing <NUM> is provided with a tapered surface matching the cable clamp <NUM>, to apply a radial pressing force to the cable clamp <NUM> under the action of an external force, so that the diameter of the cable clamp <NUM> decreases, and the barb inside is clamped in the outer sheath of the leaky cable <NUM>, to further lock the leaky cable <NUM>.

To further improve the sealing and waterproof performance, an annular groove <NUM> is provided in a contact surface between the first shell <NUM> and the second shell <NUM>, and a second sealing member <NUM> is disposed inside the annular groove <NUM>.

Further provided is a leaky cable connector, including the mounting structure for a leaky cable connector.

Before the leaky cable <NUM> is assembled, the connector is preassembled to form a whole. The leaky cable <NUM> requires foaming and coring. During mounting, the prepared leaky cable <NUM> is inserted in the connector from the second shell <NUM>, until the leaky cable <NUM> abuts against the first shell <NUM> and can be no longer pushed. With the unique design of the first shell <NUM>, the second shell <NUM>, and the cable clamp <NUM>, the leaky cable <NUM> may be smoothly inserted in the connector, and does not cause the movement of any part. After the leaky cable <NUM> is pushed to position, an assembly is placed in a dedicated fixture for press fit. With the press fit, the slotted position of the cable clamp <NUM> is pressed to deform, and the barb is clamped in the outer sheath of the leaky cable <NUM>. The external conductor of the leaky cable <NUM> is pressed on the tapered surfaces of the cable clamp <NUM> and the first shell <NUM>, to complete mounting.

In an alternative embodiment, end surfaces of the cable clamp <NUM> and the first shell <NUM> facing the gap <NUM> may also be tapered surfaces. In this case, the cable clamp <NUM> and the first shell <NUM> form the annular gap <NUM>.

Claim 1:
A mounting structure for a leaky cable connector, comprising:
a first shell (<NUM>) and a second shell (<NUM>) that are sleeved with each other, wherein the first shell (<NUM>) is disposed inside, the second shell (<NUM>) is disposed outside, and a mounting space allowing a leaky cable (<NUM>) to pass through is provided in each of the first shell (<NUM>) and the second shell (<NUM>); and
a cable clamp (<NUM>), disposed at a connection between the first shell (<NUM>) and the second shell (<NUM>), wherein a gap (<NUM>) allowing insertion of an external conductor of the leaky cable (<NUM>) is provided between the cable clamp (<NUM>) and the first shell (<NUM>), and when the leaky cable (<NUM>) is inserted in the mounting spaces, the cable clamp (<NUM>) is subjected to a force to move toward the first shell (<NUM>) to fasten the external conductor of the leaky cable (<NUM>),
characterized in that the
first shell (<NUM>) is formed with an assembly space (<NUM>) allowing insertion of the cable clamp (<NUM>) under the action of an external force, and correspondingly, the cable clamp (<NUM>) is formed with a protrusion (<NUM>) adapting to the assembly space (<NUM>),
and in that the other end of the cable clamp (<NUM>) opposite to the protrusion (<NUM>) is provided with a first limiting member (<NUM>), the first shell (<NUM>) is provided with a second limiting member (<NUM>) matching the first limiting member (<NUM>), and the first limiting member (<NUM>) climbs over the second limiting member (<NUM>) under the action of an external force to insert the protrusion (<NUM>) into the assembly space (<NUM>) for fastening.