JP2011054431A - Coaxial cable connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connector for connecting a coaxial cable to a communication device or the like which does not require an attached component, such as a clamp ring, for fixing the coaxial cable to the connector, has a simple structure, and can be manufactured inexpensively and easily. <P>SOLUTION: The coaxial cable connector 10 installed on a case 20 includes cylindrical protrusion parts 12, 13 having a through hole for passing the coaxial cable 22. The protrusion parts have one or a plurality of notched holes. The coaxial cable 22 is passed through the through hole and the protrusion parts are compressed. A jacket of the coaxial cable positioned below the compressed protrusion parts is pressed in a direction of the notched holes, and intrudes in the cut hole and bulges. The bulge prevents the coaxial cable 22 from being removed from the through hole. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a connection terminal of a coaxial cable in a device for connecting a coaxial cable such as a signal branching device.

In a transmission system using a coaxial cable as a transmission line, there is a method of using a coaxial connector such as an F-type tangent as a method of connecting a coaxial cable to a device used for signal distribution / branching. However, the coaxial connector has a complicated structure and is expensive.
As a method for solving the above problem, there is a method in which a coaxial cable connection terminal is integrated with a device, as disclosed in JP-A-7-240245. In the configuration shown in the same document, a case of a device for connecting a coaxial cable is provided with a hole through which the core wire of the coaxial cable passes and a metal protrusion concentrically, and between the insulator and the braided wire of the coaxial cable. And the braided wire is caulked to the projecting portion together with the outer cover of the coaxial cable by using a caulking ring, and the core wire of the coaxial cable is introduced into the outer case.

In this configuration, it is necessary to perform a fine work of inserting the protruding portion between the outer sheath of the coaxial cable and the braided wire, and also a work of caulking the coaxial cable with a caulking ring.
One example of connecting a coaxial cable to a device without using a caulking ring is shown in FIG. A coaxial cable connection terminal 64 is integrated with the case 62 of the device 63. The coaxial cable connection terminal 64 has a cylindrical shape and has a cable through hole 65 through which the coaxial cable passes. The coaxial cable is inserted into the device 63 from the outside of the case 62 through the cable through hole 65 for a predetermined length, and then the cable through hole 65 is applied by caulking or squeezing by compressing force 66 from the outside of the coaxial cable connection terminal 64. The coaxial cable is pressed and fixed by the inner wall.
The coaxial cable connection terminal having the above configuration fixes the coaxial cable by a frictional force in which the inner wall of the cable through hole 65 presses the coaxial cable. Therefore, in order to prevent the coaxial cable from falling out of the through hole 65 when a force for pulling out the coaxial cable from the outside is applied, it is necessary to lengthen the length 67 of the through hole 65 and increase the frictional force. . The coaxial cable connection terminal 64 is made of metal, and in order to lengthen the through-hole 65, it is necessary to increase the thickness, resulting in a problem that the entire product becomes large and the manufacturing cost increases.

  As an example of solving the problem of the coaxial cable connection terminal shown in FIG. 5A, the configuration shown in FIG. 5B is known. FIG. 5A is a cross-sectional view of an example in which the coaxial cable connection terminal 70 is formed integrally with the case 72 of the device 71. The coaxial cable connection terminal 70 has a cylindrical protrusion 74 having a cable through hole 75 through which the coaxial cable passes. An uneven shape 73 is formed on the entire inner wall of the cable through hole 75. As shown in FIG. 5B, the coaxial cable 76 is inserted into the device 71 from the outside of the case 72 through the cable through hole 75. After the cable 76 is inserted for a predetermined length, a compressive force 77 is applied to the protrusion 74 from the outside and caulked or squeezed to press the uneven shape 73 of the inner wall of the cable through hole 75 against the coaxial cable 76. The convex portion is bitten into the jacket of the coaxial cable 76 (FIG. 5-2 (c)). The convex part of the inner wall of the cable through-hole 75 bites into the jacket of the cable 76, thereby preventing the coaxial cable 76 from falling off the coaxial cable connection terminal 70.

Japanese Patent Laid-Open No. 9-312181 Japanese Patent Laid-Open No. 7-240245

  The coaxial cable connection terminal shown in FIG. 5B increases the force for fixing the coaxial cable by the uneven shape provided on the inner wall of the cable through hole. In addition, a caulking ring is not required for fixing the coaxial cable, and the cable mounting operation is simplified. However, it is necessary for the connection terminal having such a configuration to form an uneven shape on the inner wall of the cable through hole, and there is a problem that a simple manufacturing method such as creation by a mold cannot be adopted and the cost is high.

  The present invention relates to a coaxial cable connection terminal for connecting a coaxial cable to a device such as a signal branching device, and includes a cylindrical projection portion that forms a through-hole into which the coaxial cable is inserted, and a cylindrical projection portion wall is provided. In the coaxial cable connection terminal for tightening and fixing the coaxial cable inserted into the through hole by caulking or squeezing, one or a plurality of cutout holes are provided in the wall of the cylindrical protrusion.

  With this configuration, when the coaxial cable inserted into the through hole is tightened by the wall of the through hole by caulking the cylindrical protrusion from the outside toward the center or by squeezing, the bottom of the wall The jacket of the coaxial cable is pressed by the wall. On the other hand, no tightening force is applied to the jacket of the coaxial cable located under the notch hole. As a result, the jacket of the coaxial cable positioned below the notch hole rises in the notch hole due to the pressure of the jacket of the coaxial cable pressed around the notch hole. In this state, when a force is applied to the coaxial cable to pull out the coaxial cable from the device, the drag force against the pulling force rises in the notch hole in addition to the frictional force between the inner wall of the through hole and the outer jacket of the coaxial cable. In addition, the resistance that the outer sheath of the coaxial cable receives from the end of the cutout hole is added, and the resistance to pulling out increases.

The figure of the 1st embodiment of the coaxial cable connection terminal concerning the present invention Caulking diagram 1 of the first embodiment Caulking diagram of the first embodiment, part 2 Caulking diagram of the first embodiment, part 3 Drawing of the first embodiment Drawing 1 of other notch holes in the first embodiment Drawing 2 of other notch holes in the first embodiment The figure of the 2nd embodiment of the coaxial cable connection terminal concerning the present invention Conventional example 1 of coaxial cable connection terminal Conventional example 2 of coaxial cable connection terminal

FIG. 1 is a view showing a first embodiment of a coaxial cable connection terminal according to the present invention. 1A is a perspective view of a coaxial cable connection device 20 such as a signal branching device and the coaxial cable connection terminal 10 provided in the case 21, and FIG. 1B is a cross-sectional view of the coaxial cable connection terminal 10. It is. Although the figure shows an example in which the coaxial cable connection terminal 10 is formed integrally with the case 21, a configuration in which the coaxial cable connection terminal is formed separately from the case and attached to the case is also possible.
The coaxial cable connection terminal 10 has a protruding portion 11 that protrudes from the case 21 to the outside. The protrusion 11 has a cylindrical shape having a through-hole through which the coaxial cable passes, and is made of a metal or the like that can be caulked or drawn. The coaxial cable 22 is passed through the through hole from the outside of the case into the case. One or a plurality of cutout holes are provided in the wall of the protruding portion 11. In FIG. 1, a notch hole 14 is formed on the upper side of the protruding portion 11, and a notch hole 15 is formed on the lower side facing the notch hole 14.
The position of the notch hole is arbitrary, but the tip side is desirable from the center of the protrusion 11 in order to reduce the force required for caulking or drawing. In the example shown in FIG. 1B, the length of the tip portion 12 is shorter than the length of the case side 13.

FIG. 2A shows a state in which a compression force 25 is applied from the outside to the entire length of the protruding portion 11 (FIG. 1) of the coaxial cable connection terminal 10 through which the coaxial cable 22 is passed and caulked. By caulking almost the entire region of the protruding portion 11 with the compressive force 25, the tip portion 12 of the protruding portion 11 compresses the portion 16 of the coaxial cable 22, and the case side 13 compresses the portion 17 of the coaxial cable 22. Cutout holes 14 and 15 are formed in the protrusion 11. Since the compression force 25 is not applied to these notches, the portion 18 of the coaxial cable 22 facing the notches is not compressed.
Since the outer cover of the coaxial cable 22 is made of a flexible resin or the like, the outer cover of the compressed portions 16 and 17 expands in a direction in which no compressive force is applied. As a result, the outer cover of the part 18 is pushed out to the outer cover of the part 16 and the part 17 and rises into the notches 14 and 15.
When a force for pulling out the coaxial cable 22 from the device 20 is applied, the drag force against the pulling force is added to the frictional force acting between the inner wall of the protrusion 11 and the outer cover of the compressed coaxial cable portions 16 and 17; A resistance force applied to the outer cover 18 of the coaxial cable raised in the cutout holes 14 and 15 from the end of the cutout hole is added, and resistance to pulling is increased.

  FIG. 2B shows that the compressive force 26 is applied from the outside to the tip portion 12 of the projecting portion 11 (FIG. 1) of the coaxial cable connection terminal 10 through which the coaxial cable 22 is passed and the case side portion 13 ′. It shows the state. As in the case shown in FIG. 2A, the jackets 16 and 17 ′ expand in the direction of the notches 14 and 15 due to the compressive force applied to the coaxial cable 22 below the tip 12 and the portion 13 ′. The outer cover 18 'located below the notch is raised in the notch. Compared with FIG. 2-1, although the frictional force of the portion 17 'and the drag of the outer casing 18' raised in the notch hole are inferior, the force required for caulking is small, and the caulking work is facilitated. Therefore, the method can be used according to the usage status of the device 20.

  FIG. 2-3 shows a state in which a compressive force 27 is applied from the outside to the distal end portion 12 of the protruding portion 11 (FIG. 1) of the coaxial cable connection terminal 10 through which the coaxial cable 22 is passed and caulked. Since the outer cover 16 of the distal end portion 12 is contracted by a compressive force, a step is generated in the outer cover 18 '' of the distal end portion 12 and the cutout holes 14 and 15. When a force for pulling out the coaxial cable 22 from the device 20 is applied due to the step, a resistance against the pulling works due to the step. When the case of FIG. 2-3 is compared with the case of FIG. 2-2, although the resistance against pulling out of the coaxial cable 22 is inferior, the force required for caulking is small and can be used according to the usage state of the device 20.

As shown in FIGS. 2A to 2C, the method of compressing the protruding portion 11 of the coaxial cable connection terminal 10 includes a method of “caulking” in which pressure is applied to the protruding portion 11 from a specific direction. A method using “aperture” is also possible in which pressure is applied from around 11 to reduce the diameter of the cylinder.
FIG. 2-4 is a diagram in which the diaphragm 29 is performed over the entire length of the protrusion 11. As in the case of “caulking” in FIG. 2A, the distal end portion 12 and the entire case side 13 of the protruding portion 11 are squeezed to reduce the diameter, thereby compressing the outer cover of the portion 16 and the portion 17 and The cover is pushed out into the cutout holes 14 and 15 and raised. When the coaxial cable 22 is pulled out, a frictional force between the jackets of the portions 16 and 17 and a drag force of the jacket raised in the notch hole are generated.
Similarly to the “caulking” shown in FIGS. 2-2 and 2-3, the portion to be “squeezed” may be the tip 12 of the protrusion 11 and a part of the case side 13, or only the tip 12. Is possible.

The configuration example shown in FIGS. 1 to 2-4 is an example in which the cutout holes 14 and 15 are provided on the upper side and the lower side of the projecting portion 11. The position of the cutout hole can be set to an arbitrary position or orientation with respect to the device. FIG. 3A is an example in which cutout holes 32 and 33 are provided in the lateral direction of the protrusion 31.
The number of the cutout holes can be appropriately selected depending on the resistance against the force of pulling out the required coaxial cable. FIG. 3-2 is an example in which two pairs of cutout holes (a total of four cutout holes) are provided in the protrusion 35, and two cutouts are provided above the protrusion 35 of the coaxial cable connection terminal. A pair of cutout holes are provided on the lower side of the holes 36 and 37 (not shown). By caulking or squeezing the protruding portion 35, the outer cover of the coaxial cable 34 rises into the four cutout holes, which is a great resistance against the force of pulling out the coaxial cable 34.

  FIG. 4 is a view showing a second embodiment of the coaxial cable connection terminal according to the present invention. A configuration is often employed in which a case of a device used for a transmission system or the like is made of metal, and a metal braided wire provided on the inner side of a coaxial cable jacket is connected to the case. The configuration shown in FIG. 4 can fix the coaxial cable to the connection terminal by caulking or squeezing the protruding portion of the coaxial cable connection terminal, and can securely connect the braided wire of the coaxial cable to the case. To do.

FIG. 4A is a cross-sectional view of the coaxial cable connection terminal according to the second embodiment. A metal connection terminal 40 is provided on the metal case 41. The cylindrical protruding portion of the connection terminal 40 has a through hole 54 into which a coaxial cable is inserted, and a pair of cutout holes 44 are formed.
The front end portion 43 of the projecting portion, the cutout hole 44, and the through hole 54 of the front portion 42 on the case side have a diameter capable of easily inserting the coaxial cable. The through hole 54 is tapered in the vicinity of the opening 56 into the case 41, and the diameter of the opening 56 is large enough to prevent the coaxial cable from peeling off the jacket and exposing the braided wire from penetrating. That's it. Therefore, when the coaxial cable exposing the braided wire at the tip is inserted into the through hole 45 from the outside of the case toward the inside of the case, the braided wire is formed in a tapered shape and comes into contact with the inner wall of the through hole 45.

  FIG. 4B is a diagram showing a state where the coaxial cable 50 exposing the signal wire 52 at the tip and the braided wire 51 having a predetermined length at the tip is inserted into the through hole 54 of the connection terminal 40. Since the diameter in the vicinity of the opening 56 into the case 41 is smaller than the diameter of the coaxial cable that exposes the braided wire, the tip of the exposed braided wire 51 stops in contact with the tapered portion 45 of the through hole 54. .

FIG. 4C is a view showing a state in which the projecting portion is caulked or squeezed by applying a compression force 46 from the outside to the connection terminal 40 in the state shown in FIG. At the bottom of the front end portion 43 of the protruding portion and the front portion 42 on the case side, the outer cover of the coaxial cable 50 is compressed by the inner wall of the through hole 54, and the outer cover 47 below the notch hole 44 is placed in the notch hole 44. It gets excited. With this configuration, similar to the configuration shown in FIG. 2-1 or FIG. 2-2, when a force for pulling out the coaxial cable 50 from the case 41 is applied, the space between the inner wall of the protrusion and the outer cover of the compressed coaxial cable is applied. In addition to the frictional force, a resistance force received from the end of the cutout hole 44 by the outer cover 47 of the coaxial cable raised in the cutout hole is added, and the resistance to pulling out increases.
When compressive force 46 is applied to the connection terminal 40 by caulking or drawing, the front end portion 43 and the case-side front portion 42 press the coaxial cable, and at the same time, the braided wire in which the tapered portion 45 of the through hole 54 is exposed. The connection terminal 40 and the braided wire 51 are firmly connected by pressing the 51.
The coaxial cable connection terminal according to the second embodiment is obtained by adding a simple configuration in which the through hole in the vicinity of the opening 56 into the case is tapered 45 in the first embodiment. At the same time as fixing to the coaxial cable connection terminal, the braided wire 51 of the coaxial cable can be reliably connected to the case.

The present invention relates to a connection terminal for connecting a coaxial cable to a device such as a signal branching device, and more specifically, a cylindrical coaxial cable formed integrally with or attached to a case so as to protrude from the case. This relates to the connection terminal. One or a plurality of cutout holes are provided in the cylindrical protrusion of the coaxial cable connection terminal according to the present invention.
The coaxial cable is passed through the through hole in the cylindrical protrusion, and pressure is applied from the outside with a tool or jig to caulk or squeeze the protrusion, so that the inner wall in the through hole is pressed against the coaxial cable and compressed. The jacket of the flexible coaxial cable is pushed out into the cutout hole by the compressive force and rises.
When a force to pull out the coaxial cable from the device is applied from the outside, in addition to the frictional force between the coaxial cable and the inner wall in the through hole, the outer cover of the coaxial cable raised in the notch hole hits the edge of the notch hole. Generates resistance against pulling. By applying these forces, the coupling force between the coaxial cable and the device is increased, and the coaxial cable can be prevented from falling off the connection terminal.

The coaxial cable connection terminal according to the present invention has a configuration in which one or a plurality of cutout holes are provided in a cylindrical protrusion. In addition, it is possible to manufacture at low cost by a simple method such as manufacturing using a mold without the need for accessory parts such as a caulking ring.
The coaxial cable is attached by inserting the coaxial cable into the through hole of the protruding portion, and fixing the protruding portion by caulking or squeezing with a tool or a jig. It is possible to obtain a large fixing force by a simple operation such as caulking with a tool or a jig or squeezing without requiring other parts such as a caulking ring for fixing.
By increasing the number of cutout holes provided in the protrusion, the number of coaxial cable jackets rises in the cutout holes, and it is possible to increase the force with which the coaxial cable resists dropping from the connection terminal. .

The shape of the through hole in the protruding portion is tapered toward the opening in the case, and when the coaxial cable exposing the braided wire at the tip is inserted into the through hole, the braided wire has a tapered shape in the protruding portion. It is possible to have a configuration in contact with the wall. The coaxial cable is fixed by caulking the projecting portion with a tool or jig, or by squeezing, and the tapered inner wall and the braided wire of the coaxial cable come into firm contact with each other for electrical connection.
With this configuration, the coaxial cable can be fixed to the connection terminal and the braided wire of the coaxial cable and the connection terminal can be reliably connected by a simple operation such as caulking with a tool or a jig, or drawing.

Claims (2)

Coaxial cable connection terminal installed in the case of signal equipment,
The coaxial cable connection terminal has a cylindrical protrusion having a through hole through which the coaxial cable passes,
The protrusion has one or more cutout holes,
A coaxial cable connection terminal, wherein the outer cover of the coaxial cable rises in the cutout hole by compressing the protrusion. The coaxial cable connection terminal according to claim 1,
The coaxial cable connection terminal according to claim 1, wherein the through hole has a tapered shape whose diameter decreases in a case direction.

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