RU125779U1 - RADIO FREQUENCY COAXIAL CONNECTOR - Google Patents

Abstract

1. An RF coaxial connector comprising an element for attaching an external cable conductor located in the housing, a clamping sleeve with a thread on the outer surface, a fixing element, characterized in that a dielectric insulator is pressed inside the housing, which is rigidly fixed in its inner cavity of the socket with a flange for desoldering the central core of the coaxial cable, at least two insulating elements installed between the socket for desoldering the central core of the coaxial cable For the connection of the external conductor of the cable, the fixing element is placed between the socket for desoldering the central core of the coaxial cable and the insulating element, as well as the insulating gasket and the clamping metal washer installed between the element for connecting the external conductor of the cable and the clamping metal sleeve with thread on the outer surface, while on two opposite sides of the flange of the socket for desoldering the central core of the coaxial cable parallel to the axis of rotation Slices. 2. The radio frequency coaxial connector according to claim 1, characterized in that the dielectric insulator is made underreported under the flange of the socket for desoldering the central core of the coaxial cable. The radio frequency coaxial connector according to claim 1, characterized in that the housing comprises a flange on which holes are made for attaching the radio frequency coaxial connector to the panel of the device.

Description

The utility model relates to electromechanical devices and is intended for mechanical and electrical connections of the antenna-feeder path.

A coaxial connector chemically fixed is known in the prior art (Patent RU No. 2398320, published August 27, 2010, IPC: H01R 9/05 (2006.01, H01R 13/52 (2006.01). The coaxial connector includes a tubular outlet, a coupling, a housing an element having a cylindrical sleeve and one or more tanks. The tanks consist of casings containing chemical components located between the output and the cylindrical sleeve. The chemical component is completely inside the casing. Coaxial cable is inserted into the connector the tank, releases the chemical component and secures the cable sheathing inside the cylindrical sleeve. The chemical component may include adhesive, an expanding material and / or substance that causes the cable sheath to swell. Two or more chemical components may be stored in two or more adjacent tanks.

The disadvantages of this coaxial connector include insufficient fixation of the central core of the coaxial cable.

A plug socket is known (Utility Model Patent No. 90268, published December 27, 2009, IPC: H01R 13/20 (2006.01), H01R 4/10 (2006.01). The plug socket is made in the form of a sleeve with a step transition on the outer surface and with In this case, that part of the surface of the hole that has a larger diameter is located in the part of the sleeve having a larger diameter of the outer surface. at least one ring ledge.

The disadvantages of this utility model include the fact that the design of the plug socket is crimpable and cannot be used for fixing by soldering the RF cable PK50-1.5-22.

Closest to the proposed technical solution is a node for connecting a coaxial cable to a connector (USSR Author's Certificate No. 1014076, published 04/23/1983, IPC: H01R 24/02, H01R 11/11. H02G 15/02) containing an element located in the housing for attaching an external cable conductor, a clamping sleeve with a thread on the outer surface and a retaining element in the sheath retaining cable from longitudinal movement. At the same time, the element for attaching the external cable conductor is made in the form of a sleeve installed with an interference fit and having a longitudinal slot of a sleeve made with a protrusion on its outer surface. The locking element is located in the cavity of the element for connecting the external conductor and the clamping sleeve, interacting with each other using a threaded connection. The outer conductor is fixed to the protrusion, and the length of the slot of the sleeve is equal to the distance from the end of the sleeve to the protrusion.

The disadvantages of this coaxial connector include insufficiently reliable fixation of the central core of the coaxial cable, since it allows fixing the central core only in the longitudinal direction.

The technical result of the proposed technical solution is to increase the reliability of fixing the central core of the coaxial cable by eliminating the possibility of scrolling the cable around the central axis of the socket of the radio-frequency coaxial connector.

The technical result is achieved in that the radio-frequency coaxial connector comprises an element located in the housing for attaching an external cable conductor, a clamping sleeve with a thread on the outer surface, a fixing element. Moreover, it differs from the prototype in that a dielectric insulator is pressed inside the casing, made with the possibility of rigid fixation in its inner cavity of the socket with a flange for desoldering the central core of the coaxial cable, at least two insulating elements installed between the socket for desoldering the central core of the coaxial cable and an element for attaching an external conductor of the cable, as well as an insulating gasket and a clamping metal washer installed between the element for attaching an external cable conductor and clamping metal sleeve with thread on the outer surface. In this case, the fixing element is placed between the socket for desoldering the central core of the coaxial cable and the insulating element. Slices are made on two opposite sides of the flange of the socket for desoldering the central core of the coaxial cable parallel to the axis of rotation, which allow the socket to be fixed in the insulator, protecting the socket from rotation inside the insulator, thereby preventing twisting of the coaxial cable core relative to the axis of the socket and ensuring reliable mechanical and electrical contact . The dielectric insulator of the radiofrequency coaxial connector is made with understatement under the flange of the socket for desoldering the central core of the coaxial cable, and the housing contains a flange on which holes are made for attaching the radiofrequency coaxial connector to the panel of the device.

The essence of the utility model is illustrated by drawings of Fig.1 - Fig.2, where

Figure 1 - General view of the radio frequency coaxial connector;

Figure 2 - section aa in figure 1.

An example of a specific use of a radio frequency coaxial connector is its use in an antenna-feeder path for connecting an antenna to a transceiver path using a small diameter radio frequency coaxial cable PK50-1.5-22.

The design of the radio frequency coaxial connector used for desoldering a coaxial cable of small diameter is shown in FIG.

The RF coaxial connector includes the following parts: a metal housing 1, inside of which a dielectric insulator 2 is placed, a metal socket 3 for desoldering the central core of the coaxial cable, an element for attaching an external cable conductor 4, insulating elements 5, 7 and a fixing element 6 installed between the socket 3 and an element for attaching an external conductor of the cable 4, an insulating gasket 8 and a clamping metal washer 9 installed between the element for attaching an external conductor a cable clamp 4 and the metallic sleeve 10 threaded on the outer surface. In this case, the housing 1 contains a flange 11, on which holes 12 are made for attaching a radio-frequency coaxial connector to the instrument panel, and on two opposite sides of the flange of the socket 3, sections (flats) 13 are made parallel to the axis of rotation (Figure 2).

A dielectric insulator 2 is pressed into the metal housing 1. A metal socket 3 with a flange is tightly installed in the insulator 2. The design of the socket allows you to solder to it the inner core of the cable. The split design of the spring part of the socket allows the pin of the external connector 3 mm in diameter.

The insulator 2 (Figure 2) is made underreported under the flange of the socket 3. The dimensions of the insulator 2 are selected so that after it is pressed in, the possibility of moving and turning the insulator inside the housing is excluded. Insulator 2 secures the cable with the cut off external conductor inside the housing.

To ensure reliable fixation of the socket 3 in the insulator 2 on two opposite sides of the flange of the socket 3, cuts (flats) are made parallel to the axis of rotation, which protect the socket 3 from rotation inside the insulator 2, preventing the cable core from twisting relative to the axis of the socket 3 and providing reliable mechanical and electrical contact.

The element for attaching the outer conductor of cable 4 is made in the form of a sleeve onto which the external conductor of the cable is soldered.

The insulating elements 5, 7 and the insulating gasket 8, made of insulating material, protect the solder from moisture and corrosion, providing reliable electrical contact. The locking element 6 fixes the cable with a cut off outer conductor inside the housing. The clamping washer 9 and the clamping sleeve 10 with a thread on the outer surface provide fixation of the parts inside the housing, increasing the reliability of contact between the input housing and the external cable conductor.

The outer surface of the housing allows you to connect to the radio-frequency coaxial connector plugs with mounting dimensions of type IV (GOST 20265-83, drawing 9). Four holes 12 with a diameter of 3.4 mm on the flange 11 of the housing 1 allow you to fix the RF coaxial connector on the instrument panel (Figure 2).

The assembly of the RF coaxial connector is as follows. The insulator 2 is pressed into the housing 1. The dimensions of the insulator are selected so that, after pressing in, the possibility of moving and turning the insulator inside the housing is excluded. A clamping sleeve 10, a clamping washer 9, an insulating gasket 8, an element for attaching an external cable conductor 4 are installed on the coaxial cable to be connected. The outer cable conductor is cut at a distance of 9 mm from the edge. The inner insulation of the cable is cut at a distance of 4.5 mm from the edge of the outer conductor of the cable. The insulating elements 7, 6, 5 are installed on the inner insulation of the cable. The inner conductor of the cable is inserted into the socket 3 so that the insulating element 6 fits snugly on the flange of the socket 3 and soldered through the mounting hole of the socket. The element for attaching the outer conductor of cable 4 is pushed close to the insulating element 7, eliminating the gaps between parts 3, 6, 7 and 4. Then, the external conductor of the cable is soldered around the perimeter of the tail of the element for attaching the outer conductor of cable 4. Insert socket 3 into the insulator 2, The flange of the socket is oriented relative to the understatement in the insulator 2. Tighten the sleeve 10 in the housing 1.

Longitudinal sections on the flange of socket 3 and an understatement under the flange in insulator 2 provide reliable fixation of socket 3 in insulator 2, protecting the socket from rotation inside the insulator, and the central core of the cable from twisting relative to the axis of socket 3. This ensures reliable electrical contact.

Thus, the proposed design of the radio-frequency coaxial connector allows to increase the reliability of fixing the central core of the coaxial cable by eliminating the possibility of scrolling the cable around the central axis of the socket of the radio-frequency coaxial connector, which allows the use of a coaxial cable of small cross section (for example, PK50-1.5-22).

Claims (3)

1. An RF coaxial connector comprising an element for attaching an external cable conductor located in the housing, a clamping sleeve with a thread on the outer surface, a fixing element, characterized in that a dielectric insulator is pressed inside the housing, which is rigidly fixed in its inner cavity of the socket with a flange for desoldering the central core of the coaxial cable, at least two insulating elements installed between the socket for desoldering the central core of the coaxial cable For the connection of the external conductor of the cable, the fixing element is placed between the socket for desoldering the central core of the coaxial cable and the insulating element, as well as the insulating gasket and the clamping metal washer installed between the element for connecting the external conductor of the cable and the clamping metal sleeve with thread on the outer surface, while on two opposite sides of the flange of the socket for desoldering the central core of the coaxial cable parallel to the axis of rotation we have slices. 2. The radio-frequency coaxial connector according to claim 1, characterized in that the dielectric insulator is made with understatement under the flange of the socket for desoldering the central core of the coaxial cable. 3. The RF coaxial connector according to claim 1, characterized in that the housing comprises a flange on which holes are made for attaching the RF coaxial connector to the panel of the device.

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