JP6391786B1 - Coaxial cable connection structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a high shield when a plurality of coaxial cables having different diameters are connected. When an L-shaped coaxial plug 1 is assembled, a central contact 17 is inserted into a through hole of an insulator 16 from a central pin 17a and attached. The insulator 16 is accommodated in the rectangular tube portion 21 of the metal case 20. At this time, the center pin 17 a of the center contact 17 is disposed substantially on the center axis of the cylindrical portion 22. The first coaxial cable 30 or the second coaxial cable 31 is inserted through the insertion fitting 23 of the metal case 20 through the caulking metal fitting 14. Thereby, the metal tape comes into contact with the inner surface of the insertion portion 23 and is grounded. Further, the core wire introduced into the insulator 16 is disposed on the upper portion of the center contact 17, and by screwing the screw 18, the core wire is connected to the upper end of the center contact 17 by the pressing portion. [Selection] Figure 5

Description

  The present invention relates to a coaxial cable connection structure that can be connected with high shielding characteristics even if the diameter of the coaxial cable is varied.

  A receiver such as a television receiver or a tuner is provided with a coaxial connector to which a high-frequency signal such as a television signal is supplied, and a coaxial plug connected to the end of the coaxial cable is attached to the coaxial connector. Thus, a high-frequency signal such as a television signal is supplied to the receiver. The configuration of a conventional coaxial plug is shown in FIGS. The coaxial plug 100 shown in these drawings is a coaxial plug capable of connecting a plurality of coaxial cables having different diameters, and FIG. 40 connects a 4C coaxial cable having a core conductor thickness of about 4 mm. 41 is a cross-sectional view showing the configuration of the coaxial plug 100, FIG. 41 is a cross-sectional view showing the configuration of the coaxial plug 100 connected to a 3C coaxial cable having a core conductor thickness of about 3 mm, and FIG. It is sectional drawing which shows the structure of the coaxial plug 100 which connected the 5C coaxial cable whose thickness is about 5 mm.

  The conventional coaxial plug 100 is attached to the tip of the coaxial cable 150. The entire coaxial plug 100 is covered with a cover 110, and the cylindrical conductive member 111 is exposed from the tip thereof, and a contact pin 112 is disposed at the center of the cylindrical conductive member 111. The coaxial plug 100 to which the coaxial cable 150 is attached is attached to the coaxial connector. An insulator 113 is inserted into the cylindrical conductive member 111, and a contact pin 112 is inserted through the center of the insulator 113. Thereby, the contact pin 112 is arranged at the center of the cylindrical conductive member 111. A spring member 114 is provided inside the cylindrical conductive member 111. The spring member 114 is provided to ensure the connection when the cylindrical conductive member 111 is attached to the coaxial connector. An insulator 116 is fitted from the rear end of the cylindrical conductive member 111, and a lid 115 is attached to the rear end surface of the cylindrical conductive member 111. The front end of the cylindrical conductive member 119 is fitted into the opening formed in the cylindrical conductive member 111, and the cylindrical conductive member 111 and the cylindrical conductive member 119 are electrically connected. The cylindrical conductive member 111 and the cylindrical conductive member 119 are arranged orthogonally so as to be L-shaped.

  An insulator 118 is inserted into the cylindrical conductive member 119, and an attachment member 120 into which the core wire connection pin 121 is inserted is inserted into the insulator 118. The tip of the core wire connection pin 121 is inserted into the insertion hole formed in the contact pin 112, and electrical connection between the contact pin 112 and the core wire connection pin 121 is made. A pair of connection pieces 122 made of an elastic metal piece is provided at the tip of the core wire connection pin 121. The pair of connection pieces 122 are biased so as to contact each other. A ring member 123 is fitted to the inner periphery of the rear end of the cylindrical conductive member 119. The inner diameter of the ring member 123 is changed in, for example, three stages. The inner diameter of the upper stage of the ring member 123 corresponds to the diameter of the insulator around the core of the central conductor of the coaxial cable of 3C, for example, and the inner diameter of the middle stage is For example, the diameter of the insulator around the core of the central conductor of the 4C coaxial cable corresponds to the diameter of the insulator around the core of the center conductor of the coaxial cable of 5C, for example. A cable fixing bracket 124 is attached to the outer periphery of the cylindrical conductive member 119. The cable fixing bracket 124 includes an annular holding part, a crimping part having a crimping piece, and a connecting part that connects the holding part and the crimping part. The holding portion is engaged with the outer periphery of the cylindrical conductive member 119.

  When the coaxial cable 150 is attached to the coaxial plug 100, peeling processing is performed in advance so that the center conductor 151 and the outer conductor 152 of the coaxial cable 150 are exposed. And the front-end | tip of the coaxial cable 150 which gave the peeling process is inserted from the ring member 123. FIG. When the distal end of the coaxial cable 150 is inserted into the ring member 123, the central conductor 151 at the distal end comes into contact with the connection piece 122 of the core wire connection pin 121, and when the coaxial cable 150 is further pushed in, the central conductor 151 is connected to the pair of connection pieces 122. The center conductor 151 and the core wire connection pin 121 are electrically connected by being inserted between the pair of connection pieces 122. At this time, the front end 153 of the coaxial cable 150 is engaged in the ring member 123.

40 shows a state when a 4C cable is used as the coaxial cable 150, FIG. 41 shows a state when a 3C cable is used as the coaxial cable 150, and FIG. The state when a 5C cable is used is shown.
When a 4C cable is used as the coaxial cable 150, the front end 153 of the coaxial cable 150 is engaged in the middle stage of the ring member 123, as shown in FIG. When a 3C cable is used as the coaxial cable 150, the tip 153 of the coaxial cable 150 is engaged in the upper stage of the ring member 123 as shown in FIG. When a 5C cable is used as the coaxial cable 150, the tip 153 of the coaxial cable 150 is engaged in the lower stage of the ring member 123 as shown in FIG. Thus, even if the diameter of the coaxial cable 150 changes, the front end 153 of the coaxial cable 150 engages with any one of the upper, middle, and lower stages of the ring member 123.

  Then, the portion of the coaxial cable 150 where the outer conductor 152 is exposed is inserted between the crimping portions of the cable fixing bracket 124, and the crimping portion is crimped. By this caulking, the coaxial cable 150 is securely fixed to the coaxial plug 100, and the outer conductor 152 of the coaxial cable 150 and the cable fixing bracket 124 are electrically connected. As described above, in the conventional coaxial plug 100, the center conductor 151 of the coaxial cable 150 is inserted between the pair of connection pieces 122 to electrically connect the center conductor 151 and the contact pin 112. . Further, in the conventional coaxial plug 100, when the coaxial cable 150 is attached, the central conductor 151 of the coaxial cable 150 is located in the cylindrical conductive member 119. For this reason, noise from the outside is shielded by the cylindrical conductive member 119 and is prevented from jumping into the central conductor 151 of the coaxial cable 150.

JP 2006-12498 A

Recent coaxial plugs are required to have a structure capable of operating up to a high frequency band up to about 3.2 GHz exceeding the UHF band. Also in this case, a coaxial cable having a wide band, a low loss, and a high shield is used. In this coaxial cable, the core wire is insulated with an insulator having a circular cross section such as polyethylene foam, the insulator is wrapped with a metal tape such as aluminum foil, the outer periphery is covered with a net-like conductor called a tubular braided wire, and the outside thereof Is a coaxial cable with a wide band, low loss, and high shield. Such coaxial cables include “S-4C-FB” cables and “S-5C-FB”. In recent coaxial plugs, a broadband, low loss, high shield coaxial cable can be connected, and a high shield coaxial plug is required.
However, the conventional coaxial plug is not compatible with a broadband cable with low loss and high shield, and the outer conductor 152 of the coaxial cable 150 and the cable fixing bracket 124 are electrically connected. Since the conductor 152 is a braided wire, there is a problem that a high shield cannot be achieved. Further, the tip portion 153 of the coaxial cable 150 is an insulator, and a high-frequency signal leaks from a portion of the insulator portion and the ring member 123 that is not a conductor, so that a high shield cannot be achieved. there were.

  Accordingly, the present invention provides a coaxial cable connection structure that is compatible with a wide-band, low-loss, high-shielded coaxial cable and that can achieve high shielding when a plurality of coaxial cables having different diameters are connected. The purpose is that.

  The coaxial cable connection structure of the present invention includes at least a core wire and an insulator that is interposed between the core wire and the shield conductor to form a coaxial structure between the core wire and the shield conductor, and has a plurality of different outer diameters. A coaxial cable connection structure capable of introducing any of the types of coaxial cables, an insulator capable of holding a conductive core wire connection means for connecting the core wires of the coaxial cable, and an introduction in which the coaxial cable is introduced A metal case provided with a storage portion capable of storing the insulator, and a plurality of diameter portions corresponding to the diameter of the shield conductor of the coaxial cable to be introduced are formed in the introduction portion. And the coaxial cable introduced into the case is introduced into the introduction portion of the metal case, and the shield conductor of the coaxial cable is Inserted in the diameter portion of the introduction portion according to the diameter of the shield conductor, the shield conductor is grounded to the metal case, and the core wire of the coaxial cable is inserted into the insulator housed in the metal case The main feature is that it is connected to the core wire connecting means held by the insulator.

In the coaxial cable connection structure, the metal case is formed with a cylindrical portion to be attached to a coaxial connector, and the coaxial cable introduced into the introduction portion of the metal case by the core wire connection means. A core wire may be disposed in the cylindrical portion and electrically connected to a central contact that forms a coaxial structure with the cylindrical portion.
Further, in the coaxial cable connection structure, the metal case has two introduction portions, and one of the plurality of types of the coaxial cables is introduced into one introduction portion, and the other of the other Any one of a plurality of types of the coaxial cables is introduced into the introduction portion, and the core wire of the coaxial cable introduced into the one introduction portion of the metal case is introduced into the other introduction portion of the metal case by the core wire connecting means. You may make it electrically connect to the said core wire of the coaxial cable introduced into the part.

  The coaxial cable connection structure of the present invention is provided with a metal case so that the core wire connection means held by the insulator is accommodated in the metal case and is introduced at the introduction portion for introducing the coaxial cable into the metal case. The multi-stage diameter portion corresponding to the diameter of the shield conductor of the plurality of coaxial cables having different diameters is provided in multiple stages, and the shield conductor of the coaxial cable is inserted into the diameter portion corresponding to the diameter of the shield conductor in the introduction portion. The shield conductor is grounded to the metal case. As a result, even when a plurality of types of coaxial cables having different diameters are connected, a high shield can be realized in a wide band. The core wire of the coaxial cable introduced into the introduction portion is inserted into an insulator housed in the metal case and connected to the core wire connecting means held by the insulator.

It is a perspective view which shows the structure of the L-shaped coaxial plug which is 1st Example of this invention. It is a side view which shows the structure of the L-shaped coaxial plug which is 1st Example of this invention. It is a side view which shows the structure of the state which opened the case cover part of the L-shaped coaxial plug which is 1st Example of this invention. It is a perspective view which shows the structure of the state which opened the case cover part of the L-shaped coaxial plug which is 1st Example of this invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded view showing a configuration of an L-shaped coaxial plug according to a first embodiment of the present invention in a perspective view. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view, rear view, front view, bottom view, and enlarged view of part A showing the configuration of a metal case of an L-shaped coaxial plug according to a first embodiment of the present invention. It is the perspective view seen from the front which shows the structure of the metal case of the L-shaped coaxial plug which is 1st Example of this invention, and the perspective view seen from back. It is the rear view, front view, top view, and bottom view which show the structure of the case of the L-shaped coaxial plug which is 1st Example of this invention. It is the side view which shows the structure of the case of the L-shaped coaxial plug which is 1st Example of this invention, the perspective view seen from back, and the perspective view seen from the front. It is the front view, top view, and bottom view which show the structure of the insulator of the L-shaped coaxial plug which is 1st Example of this invention. It is the left view which shows the structure of the insulator of the L-shaped coaxial plug which is 1st Example of this invention, the right view, the perspective view seen from the upper direction, and the perspective view seen from the downward direction. It is the top view which shows the structure of the metal case cover part of the L-shaped coaxial plug which is 1st Example of this invention, a front view, the perspective view seen from upper direction, and the perspective view seen from the downward direction. It is the front view, side view, top view, and bottom view which show the structure of the center contact of the L-type coaxial plug which is 1st Example of this invention. It is the perspective view seen from the front which shows the structure of the center contact of the L-shaped coaxial plug which is 1st Example of this invention, and the perspective view seen from back. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a top view, a side view, a front view, a perspective view seen from above, and a perspective view seen from below showing a configuration of a caulking fitting of an L-shaped coaxial plug according to a first embodiment of the present invention. It is the front view which shows the structure of the spring part of the L-shaped coaxial plug which is 1st Example of this invention, a rear view, a top view, and the perspective view seen from upper direction. It is the rear view, bottom view, and B section enlarged view which show the structure of the L-type coaxial plug which is 1st Example of this invention. It is a rear view which abbreviate | omits and shows the case cover part which shows the structure of the L-shaped coaxial plug which is 1st Example of this invention. It is the front view and sectional view which show the processed composition of the 1st coaxial cable and the 2nd coaxial cable which are connected to the L type coaxial plug which is the 1st example of the present invention. It is the bottom view and aa sectional view showing the composition which connected the 2nd coaxial cable of the L type coaxial plug which is the 1st example of the present invention. It is the bottom view and bb sectional view showing the composition which connected the 1st coaxial cable of the L type coaxial plug which is the 1st example of the present invention. It is a figure which shows the leakage characteristic at the time of connecting the 2nd coaxial cable of the L-shaped coaxial plug which is 1st Example of this invention. It is a figure which shows the leakage characteristic at the time of connecting the 1st coaxial cable of the L-shaped coaxial plug which is 1st Example of this invention. It is the perspective view, top view, and side view which show the structure of the coaxial repeater which is 2nd Example of this invention. It is the top view and back view which show the structure of the state which opened the case cover part of the coaxial repeater which is 2nd Example of this invention. It is the side view which shows the structure of the state which opened the case cover part of the coaxial repeater which is 2nd Example of this invention, and the perspective view seen from upper direction. It is a disassembled assembly figure which shows the structure of the coaxial repeater which is 2nd Example of this invention with a perspective view. It is the top view, top view, and side view which show the structure of the case of the coaxial repeater which is 2nd Example of this invention. It is the rear view which shows the structure of the case of the coaxial repeater which is 2nd Example of this invention, the perspective view seen from upper direction, and the perspective view seen from the downward direction. It is the front view which shows the structure of the metal case of the coaxial repeater which is 2nd Example of this invention, a top view, a side view, and the C section enlarged view. It is the bottom view which shows the structure of the metal case of the coaxial repeater which is 2nd Example of this invention, the perspective view seen from upper direction, and the perspective view seen from the downward direction. It is the top view which shows the structure of the insulator of the coaxial repeater which is 2nd Example of this invention, a front view, a side view, and a rear view. It is the bottom view which shows the structure of the insulator of the coaxial repeater which is 2nd Example of this invention, the perspective view seen from upper direction, and the perspective view seen from the downward direction. It is the top view which shows the structure of the center conductor of the coaxial repeater which is 2nd Example of this invention, a front view, and a side view. It is the bottom view which shows the structure of the center conductor of the coaxial repeater which is 2nd Example of this invention, the perspective view seen from upper direction, and the perspective view seen from the downward direction. It is the top view, front view, and side view which show the structure of the metal case cover part of the coaxial repeater which is 2nd Example of this invention. It is the side view which shows the structure which abbreviate | omitted the case cover part of the coaxial repeater which is 2nd Example of this invention, the D section enlarged view, and cc sectional drawing. It is the side view which abbreviate | omits a case cover part and shows the structure which connected the 2nd coaxial cable to the coaxial repeater which is 2nd Example of this invention, and dd sectional drawing. It is the side view which abbreviate | omits a case cover part, and shows ee sectional drawing which shows the structure which connected the 1st coaxial cable to the coaxial repeater which is 2nd Example of this invention. It is sectional drawing which shows the structure which connected the coaxial cable of the conventional coaxial plug. It is sectional drawing which shows the structure which connected the other coaxial cable of the conventional coaxial plug. It is sectional drawing which shows the structure which connected the other coaxial cable of the conventional coaxial plug.

The coaxial cable connection structure of the present invention will be described with reference to an L-shaped coaxial plug which is a first embodiment to which the coaxial cable connection structure of the present invention is applied.
<First embodiment>
The configuration of an L-shaped coaxial plug 1 which is a first embodiment of the coaxial cable connection structure of the present invention is shown in FIGS. 1 is a perspective view showing the configuration of the L-type coaxial plug 1, FIG. 2 is a side view showing the configuration of the L-type coaxial plug, FIG. 3 is a side view showing the configuration with the case lid 12 open, and FIG. It is a perspective view which shows the structure of the state which opened the case cover part of the L-shaped coaxial plug. FIG. 5 is an exploded view showing the configuration of the L-shaped coaxial plug 1 in a perspective view.
As shown in these drawings, an L-shaped coaxial plug 1 which is a first embodiment of the coaxial cable connection structure of the present invention includes a resin case 10, and the case 10 is a box-shaped case whose rear surface is open. It is comprised from the main-body part 11 and the case cover part 12 which the front surface opened. The case body 11 and the case lid 12 are made by molding resin, and the upper edge of the opening surface of the case body 11 and the upper edge of the opening surface of the case lid 12 are hinges. It is connected by the part 11c. A pair of engagement pieces 11b are formed on both side surfaces of the case main body 11, and a pair of engagement grooves 12b with which the engagement pieces 11b are engaged are formed on both side surfaces of the case lid portion 12. When the hinge 11c is bent and the case lid 12 is fitted on the case main body 11, the pair of engaging pieces 11b engage with the pair of engaging grooves 12b, and the case lid 12 is connected to the case main body. The part 11 is openable and closable.

A space in the case 10 when the opening surface of the case body 11 is closed by the case lid 12 is defined as a storage space, and a coaxial cable is connected in this storage space. In the L-shaped coaxial plug 1 of the first embodiment, it is possible to connect two types of coaxial cables having different diameters as the coaxial cable. In the configuration shown in FIGS. A coaxial cable 30 is connected. The first coaxial cable 30 is, for example, “S-5C-FB”, and the second coaxial cable 31 described later can be an “S-4C-FB” cable.
As shown in FIGS. 4 and 5, the storage space in the case 10 stores a configuration for connecting a coaxial cable. Specifically, the caulking metal fitting 14, the spring portion 15, the insulator 16, the center contact 17, and the metal case 20 are accommodated in the case body 11, and the metal that closes the opening surface of the metal case 20 in the case lid 12. A case lid 13 is provided. The metal case 20 is formed with a cylindrical portion 22 which is a portion to be attached to the coaxial connector, and a space in which the insulator 16 is accommodated. A spring portion 15 bent in a cylindrical shape is fitted in the cylindrical portion 22. Further, the metal case 20 is formed with an insertion portion 23 into which the first coaxial cable 30 or the second coaxial cable 31 is inserted. The insulator 16 holds the center contact 17, and the core wire of the coaxial cable inserted from the insertion portion 23 is brought into contact with the center contact in the metal case 20 to electrically connect both. The center contact 17 is disposed substantially on the central axis of the cylindrical portion 22, and the cylindrical portion 22 and the center contact 17 form a coaxial structure. The caulking metal fitting 14 is fixed by caulking the coaxial cable inserted into the insertion portion 23, and is in electrical contact with the braided wire of the coaxial cable at this time.

<Metal case 20>
Before explaining the exploded view of the L-type coaxial plug 1 of the first embodiment shown in FIG. 5, each part constituting the L-type coaxial plug 1 will be explained with reference to FIGS.
FIG. 6A is a side view showing the configuration of the metal case 20 of the L-shaped coaxial plug according to the first embodiment, FIG. 6B is a rear view thereof, and FIG. The bottom view is shown in FIG. 6 (d), the enlarged view of part A of the bottom view is shown in FIG. 6 (e), the perspective view showing the configuration of the metal case 20 from the front is shown in FIG. The perspective view seen from the back which shows the structure of 20 is shown in FIG.7 (b).
The metal case 20 shown in these drawings has a function of shielding a portion where either the first coaxial cable 30 or the second coaxial cable 31 is connected to the L-type coaxial plug 1. The metal case 20 is formed, for example, by die-casting brass and nickel-plating, and a rectangular box-shaped rectangular tube portion 21 having a rear surface opened in which a space to be stored is formed is formed. ing. A cylindrical portion 22 that is a portion to be attached to the coaxial connector is formed so as to protrude from the front surface of the rectangular tube portion 21. Further, a pair of long and narrow rectangular protrusions 21 a are formed on the inner sides of the left and right side walls inside the rectangular tube portion 21. The rectangular tube portion 21 and the cylindrical portion 22 are communicated with each other through a through hole 22a. Further, a cylindrical insertion portion 23 is formed so as to extend downward from the lower surface of the rectangular tube portion 21. The insertion portion 23 is formed with a step in the middle of the cylinder so that the diameter on the lower side is larger than the upper side, and the inner diameter of the insertion hole 23a formed inside the insertion portion 23 is also formed on the lower side. .

  Specifically, as shown in the enlarged view of the A part in FIG. 6 (e), the upper side of the insertion hole 23a in the insertion part 23 is a small diameter part 23f with a reduced diameter, and the insertion hole 23a in the insertion part 23 is The lower side is a large-diameter portion 23e having a large diameter. A step portion 23c is formed between the small diameter portion 23f and the large diameter portion 23e. Further, four first protrusions 23g having a triangular cross section are formed at equal intervals so as to protrude from the inner peripheral surface of the large diameter portion 23e, and protrude from the inner peripheral surface of the small diameter portion 23f. Four second protrusions 23h having a triangular cross section are formed at equal intervals. When the first coaxial cable 30 or the second coaxial cable 31 is inserted into the insertion portion 23, the first protrusion 23g and the second protrusion 23h are securely bitten into the metal tape constituting the shield conductor of the coaxial cable. Has the function of grounding. Further, a flat plate portion 23 b that is substantially rectangular is formed on the front surface side of the insertion portion 23. On the front side of the flat plate portion 23b, bosses 23c having a substantially circular cross section are formed on both sides of the lower portion so as to protrude.

<Case 10>
Next, the configuration of the case 10 will be described with reference to FIGS. FIG. 8A is a rear view showing the configuration of the case 10 of the L-shaped coaxial plug 1 according to the first embodiment, FIG. 8B is a front view thereof, and FIG. The bottom view is shown in FIG. 8 (d), the side view showing the configuration of the case 10 is shown in FIG. 9 (a), the perspective view showing the configuration of the case 10 from the rear is shown in FIG. The perspective view seen from the front which shows the structure of is shown in FIG.9 (c). In these figures, the case lid 12 is opened from the case body 11.
The case 10 shown in these drawings has a function of accommodating a metal case 20 to which a spring portion 15 and a caulking metal fitting 14 are attached while an insulator 16 to which a center contact 17 and a screw 18 described later are attached is inserted. doing. Further, either the first coaxial cable 30 or the second coaxial cable 31 to be connected is introduced into the case 10. The case 10 is made by molding, for example, a weather-resistant polypropylene resin. The case 10 has a rectangular box-shaped case main body 11 with an open rear surface and a rectangular box-shaped case lid with an open front surface. 12. The upper end edge of the opening surface of the case body 11 and the upper end edge of the opening surface of the case lid 12 are connected to each other by a hinge 11c so that the case lid 12 can be bent by bending the hinge 11c. The case main body 11 can be opened and closed. In addition, a pair of engagement pieces 11b are formed so as to face the main body side wall portions 11a on both sides of the case main body portion 11, and a pair of engagement grooves 12b with which the engagement pieces 11b can be engaged are formed on the case lid portion 12. Are formed so as to face the inside of the lid side wall portions 12a on both sides. When the case lid portion 12 is rotated so that the hinge portion 11c is bent and fitted to the case main body portion 11, the pair of engaging pieces 11b engage with the pair of engaging grooves 12b, respectively. Thus, the case lid 12 is securely fitted to the case main body 11. The body side wall 11a of the case body 11 is formed in a stepped shape, the lid side wall 12a of the case lid 12 is formed in an inverted step shape, and when the case lid 12 is fitted on the case body 11 The lid side wall portion 12a is fitted into the main body side wall portion 11a without a gap. Further, the engaging piece 11b is formed by being extended from the stepped portion of the second step, and a kerf is formed between the stepped portion of the first step and the engaging piece 11b is a main body. It is formed so as to be elastically displaceable back and forth with respect to the side wall portion 11a.

  Pushing pieces 11e each having a long and narrow rectangular protrusion are formed on the lower portion of the main body side wall portion 11a of the pair of engaging pieces 11b formed on the main body side wall portion 11a. By pushing the pair of pushing pieces 11e from both sides, the pair of engaging pieces 11b can be elastically displaced inward to disengage the pair of engaging pieces 11b from the engaging grooves 12b. Thus, the case lid 12 can be opened from the case body 11. A substantially circular insertion hole 11c is formed in the upper part of the front surface of the case main body 11, and cut grooves 11d that give elasticity to the insertion hole 11c are formed at four positions at equal intervals around the insertion hole 11c. Further, a guide convex portion 11g made of a long and narrow rectangular protrusion is formed laterally on the front center and on both sides of the main body side wall portion 11a at the inner central portion of the case main body portion 11, and below the guide convex portion 11g. Guide ridges 11f are formed substantially parallel to the front inner side and the main body side wall 11a. Furthermore, two guide projections 11g having a thin rectangular section are formed in the lower part on the inner side of the front surface of the case main body 11 in the vertical direction substantially in parallel. A semicircular cable insertion portion 11 h is formed on the lower surface of the case body 11.

  On the inner surface of the rear surface of the case lid portion 12, two ridges are formed in the lateral direction from the center to the lower part, and one ridge in the vertical direction crossing almost the center of the ridge. A boss 12c is formed to protrude at two portions where the protrusions cross. Further, linear engagement grooves 12b with which the engagement pieces 11b can be engaged are formed on the inner surfaces at substantially the center on both sides of the lid side wall portion 12a of the case lid portion 12, respectively. Further, a semicircular cable insertion portion 12 d is formed on the lower surface of the case lid portion 12. When the case lid 12 is fitted to the case body 11, the cable insertion portion 11h and the cable insertion portion 12d form a substantially circular cable insertion hole through which the coaxial cable can be inserted.

<Insulator 16>
Next, the configuration of the insulator 16 will be described with reference to FIGS. FIG. 10A is a front view showing the configuration of the insulator 16 of the L-type coaxial plug 1 according to the first embodiment, FIG. 10B is a top view thereof, and FIG. 10C is a bottom view thereof. 11A is a left side view showing the structure of the insulator 16, FIG. 11B is a right side view thereof, and FIG. 11C is a perspective view of the structure of the insulator 16 as viewed from above. FIG. 11D shows a perspective view of the structure of the insulator 16 as viewed from below. In these drawings, a state in which the pressing portion 16b is opened from the main body portion 16a is shown.
The insulator 16 shown in these drawings holds a center contact 17 (described later) substantially on the central axis of the cylindrical portion 22 of the metal case 20 and also connects the core wire of the first coaxial cable 30 or the second coaxial cable 31 to the metal case 20. And electrically connecting to the center contact 17 while being insulated. The insulator 16 is made, for example, by molding a weather-resistant polypropylene resin, and has a quadrangular cylindrical shape having four side walls: a first side wall 16e, a second side wall 16f, a third side wall 16g, and a fourth side wall 16h. A molded body portion 16a and a flat pressing portion 16b are provided. The pressing portion 16b is connected to the main body portion 16a so as to be folded back by a bendable hinge portion 16c. The first side wall 16e to the fourth side wall 16h of the main body portion 16a are formed so that the lower side is slightly inclined inward, and the insulator 16 is formed in a shape that is slightly recessed downward. Thereby, when the insulator 16 is inserted into the metal case 20, the insulator 16 is securely fitted without coming out of the metal case 20. In addition, the four corners of the insulator 16 are cut out in a rectangular shape, and when the insulator 16 is inserted into the metal case 20, the four cutouts are formed on the inner surface of the rectangular tube portion 21. The four protrusions 21a are engaged, and the insulator 16 is positioned and inserted. Also, a horizontally long rectangular insertion hole 16m and a screw hole 16k are formed on the lower surface formed inside the insulator 16 in the downward direction. The insertion hole 16m is formed so as to penetrate the insulator 16, and a center contact 17 described later is inserted therethrough. When the insulator 16 is housed in the metal case 20, the center contact 17 that is inserted through the insertion hole 16 m is disposed substantially on the central axis of the cylindrical portion 22 of the metal case 20. The contact 17 forms a coaxial structure.

  A rectangular window 16 d is formed on the third side wall 16 g of the insulator 16. When the first coaxial cable 30 or the second coaxial cable 31 is connected to the L-shaped coaxial plug 1, the coaxial cable is introduced into the insertion portion 23 of the metal case 20. The core wire of the introduced coaxial cable is The insulator 16 is inserted through the rectangular window 16d. In addition, a slope 16n is formed on three sides of the rectangular window 16d, and a guide portion 16i having a long slope is formed on the remaining one side. The core of the coaxial cable introduced from the rectangular window 16d is sloped. 16n and the guide portion 16i are bent so as to be guided toward the insertion hole 16m, and the core wire of the coaxial cable is positioned on the center contact 17 inserted through the insertion hole 16m. On the other hand, a screw insertion groove 16j is formed in the pressing portion 16b, and a U-shaped protrusion 16p is formed around the screw insertion groove 16j. The pressing portion 16b is folded back by the hinge portion 16c and positioned in the main body portion 16a. In this case, the central portion of the fourth side wall 16h is notched, and the hinge portion 16c is positioned in this notch. Then, when the screw 18 is inserted into the screw insertion groove 16j and screwed into the screw hole 16k, the core wire positioned on the center contact 17 is crimped to the upper surface of the center contact 17, and the core wire is electrically connected to the center contact 17. Will be connected to. At this time, since the U-shaped protrusion 16p is positioned around the screw 18 and is electrically insulated from the screw 18 and the core wire, the characteristic impedance of the coaxial cable is not disturbed. The screw 18 is preferably a tapping screw.

<Metal case lid 13>
Next, the configuration of the metal case lid 13 will be described with reference to FIG. FIG. 12A is a top view showing the configuration of the metal case cover 13 of the L-shaped coaxial plug 1 according to the first embodiment, FIG. 12B is a front view thereof, and FIG. FIG. 12C shows a perspective view seen from above, and FIG. 12D shows a perspective view seen from below showing the configuration of the metal case lid 13.
The metal case lid portion 13 shown in these drawings has a function of securely shielding the metal case 20 by closing the rectangular rear surface where the metal case 20 is opened. The metal case lid 13 is formed by processing, for example, a phosphor bronze plate, and an obtuse angle from four edges of the rectangular upper surface plate 13f and the upper surface plate 13f that are substantially the same as the rectangular rear surface of the metal case 20 that is opened. The first side surface portion 13b, the second side surface portion 13c, the third side surface portion 13d, and the fourth side surface portion 13e bent downward are provided. Two round fitting holes 13a are formed side by side on the upper surface plate 13f. Two bosses 12c formed in the case lid 12 are inserted into the fitting hole 13a, respectively, and the boss 12c protruding from the fitting hole 13a when being inserted is crimped so as to crush the metal. The metal case lid 13 can be attached to the case lid 13. When the opening surface of the case main body 11 is fitted with the case lid portion 12 to which the metal case lid portion 13 is fixed, the metal case lid portion 13 is fitted to the opening surface of the metal case 20 and closed. The At this time, the outer surfaces of the first side surface portion 13b to the fourth side surface portion 13e of the metal case lid portion 13 are in pressure contact with the four inner peripheral surfaces of the rectangular tube portion 21 of the metal case 20, respectively. The surface will be reliably occluded. In addition, since the 1st side surface part 13b-the 4th side surface part 13e are formed at the obtuse angle with respect to the upper surface board 13f, the press contact force at the time of press contact improves, and the metal case 20 is shielded reliably. It becomes like this.

<Center contact 17>
Next, the configuration of the center contact 17 will be described with reference to FIGS. FIG. 13A is a front view showing the configuration of the center contact 17 of the L-type coaxial plug 1 of the first embodiment, FIG. 13B is a side view thereof, and FIG. 13C is a top view thereof. FIG. 13 (d) shows a bottom view thereof, FIG. 14 (a) shows a perspective view showing the configuration of the center contact 17 and FIG. 14 shows a perspective view showing the configuration of the center contact 17 from the rear. Shown in (b).
The center contact 17 shown in these drawings is made of, for example, nickel-plated copper, and is disposed on substantially the central axis of the cylindrical portion 22 of the metal case 20 so that the central contact 17 and the cylindrical portion 22 have a coaxial structure. It has the function which constitutes. The center contact 17 includes a center pin 17a having a pointed circular cross section and a main body portion 17b formed on the upper portion of the center pin 17a. The main body portion 17b has a rectangular shape with a horizontally long cross section, and has a wide upper width, and an upper end portion is bent into an L shape to form an L-shaped portion 17c. When the center contact 17 is inserted into the insertion hole 16m of the insulator 16 from the center pin 17a, the center contact 17 is inserted into the insertion hole 16m leaving the upper end surface of the L-shaped portion 17c. As a result, the upper end surface of the L-shaped portion 17 c is exposed on the lower surface of the insulator 16. The core wire of the coaxial cable is brought into contact with the exposed surface of the L-shaped portion 17c so that both are electrically connected. The center pin 17a is arranged on the substantially central axis of the cylindrical portion 22.

<Caulking metal fitting 14>
Next, the structure of the caulking metal fitting 14 will be described with reference to FIG. FIG. 15 (a) is a top view showing the structure of the caulking fitting 14 of the L-shaped coaxial plug according to the first embodiment, FIG. 15 (b) is a side view thereof, and FIG. 15 (c) is a front view thereof. FIG. 15D is a perspective view showing the configuration of the caulking metal fitting 14 from above, and FIG. 15E is a perspective view showing the configuration of the caulking metal fitting 14 viewed from below.
The caulking metal fitting 14 shown in these drawings is formed by, for example, processing a brass flat plate and plating it with nickel, and the first coaxial cable 30 or the second coaxial cable 31 connected to the L-type coaxial plug 1 is It has a function of fixing so as not to come out of the L-shaped coaxial plug. The caulking metal fitting 14 includes a flat fixing portion 14a and an arc-shaped caulking portion 14b formed to be connected to one end of the fixing portion 14a. Both sides of the other end side of the fixing portion 14a are bent downward at approximately 90 ° to form a bent piece 14c, and formed so that the width is narrowed slightly toward one end and then widened. Yes. Circular fitting holes 14c are formed on both sides of the widened portion. Both sides of the caulking portion 14b formed at one end of the fixing portion 14a are bent upward in an arc shape, and a plurality of first sawtooth protrusions 14e are formed at the opposite ends, and second sides are formed on both side surfaces. A plurality of serrated protrusions 14g are formed. The second serrated protrusion 14g is bent approximately 90 ° toward the inside. Further, the caulking portion 14b is processed so that the concave portion is formed almost entirely in the circumferential direction so that it is difficult to bend. The caulking metal fitting 14 is fixed to the metal case 20, but when fixed, the fixing portion 14a is disposed on the front side of the flat plate portion 23b of the metal case 20, and is formed on the front side of the flat plate portion 23b. Two fitting holes 14c are respectively inserted into the two bosses 23c. Then, the caulking fitting 14 is fixed to the metal case 20 by caulking the boss 23c protruding from the fitting hole 13a. When the metal case 20 is stored in the case main body 11, the caulking metal fitting 14 integrated with the metal case 20 is also stored in the case main body 11.

<Spring part 15>
Next, the configuration of the spring portion 15 will be described with reference to FIG. FIG. 16A is a front view showing the configuration of the spring portion 15 of the L-shaped coaxial plug according to the first embodiment, FIG. 16B is a rear view thereof, and FIG. FIG. 16D is a perspective view showing the configuration of the spring portion 15 as viewed from above.
The spring portion 15 shown in these drawings is created by processing a nickel-plated copper plate or phosphor bronze plate, for example. When creating the spring portion 15, a horizontally long rectangular alloy flat plate is prepared, and a plurality of slits 15b are formed at substantially equal intervals, and all portions between the slits 15b are bent in an arc shape. As a result, the bulging portion 15c is formed. Next, the whole body is bent into a cylindrical shape to form a cylindrical main body portion 15a. Both ends of the main body portion 15a are opposed to each other, and a gap 15d is generated therebetween, so that the bulging portion 15c bulges inward. The spring portion 15 is inserted into the cylindrical portion 22 of the metal case 20 while being held so that the diameter thereof is reduced. Get in touch. Thus, when the cylindrical portion 22 is attached to the coaxial connector, the spring portion 15 elastically holds the outer peripheral surface of the coaxial connector.

<Assembly of L-shaped coaxial plug 1>
Returning to FIG. 5, an exploded view of the L-shaped coaxial plug 1 of the first embodiment will be described. When the L-shaped coaxial plug 1 is assembled, first, the center contact 17 is inserted into the insertion hole 16m of the insulator 16 from the center pin 17a, and the center contact 17 is attached to the insulator 16. The insulator 16 is accommodated in the rectangular tube portion 21 of the metal case 20. At this time, the insulator 16 is positioned by the four protrusions 21 a and is inserted into the rectangular tube portion 21, and the center pin 17 a of the center contact 17 inserted through the insertion hole 16 m is substantially the center axis of the cylindrical portion 22. Placed on top. Next, the spring portion 15 is inserted into the cylindrical portion 22 with the diameter reduced, and when this state is released, the diameter expands due to its own elasticity and comes into contact with the inner peripheral surface of the cylindrical portion 22. Further, the pressing portion 16b of the insulator 16 is folded back, and the screw 18 is inserted into the screw insertion groove 16j and screwed into the screw hole 16k. Furthermore, the caulking metal fitting 14 is integrated with the metal case 20 by disposing the caulking metal fitting 14 on the front side of the flat plate portion 23b of the metal case 20, inserting the boss 23c into the fitting hole 14f, and caulking the boss 23c. It sticks to.

In this manner, the metal case 20 including the insulator 16, the center contact 17, the screw 18, the spring portion 15, and the caulking metal fitting 14 is accommodated in the case main body portion 11. When stored, the end surface of the crimping metal piece 14 bent piece 14c comes into contact with the inner surface of the case body 11, and the upper end surfaces of the guide protrusion 11f and the plurality of guide projections 11g are brought into contact with the lower surface of the caulking metal fitting 14 so that the The case 20 and the caulking metal fitting 14 are inserted into predetermined positions. Further, the rectangular tube portion 21 of the metal case 20 is fitted and inserted between the upper surface of the case main body 11 and the engagement piece 11b so that the cylindrical portion 22 is inserted into the insertion hole 11c of the case main body 11. Become. And it protrudes from the insertion hole 11 c of the case body 11. At this time, the cylindrical portion 22 is reliably held in the insertion hole 11c by the insertion hole 11c having elasticity by the action of the cut groove 11d.
Further, the metal case lid 13 is fixed in the case lid 12 by inserting the boss 12 c of the case lid 12 into the fitting hole 13 a of the metal case lid 13 and crimping the boss 12 c.
Next, the first coaxial cable 30 or the second coaxial cable 31 positioned below the case body 11 is inserted through the insertion portion 23 of the metal case 20 through the arcuate portion 14 d of the caulking metal fitting 14. In this case, as will be described later, the coaxial cable to be inserted is processed as shown in FIG. 19 so that the core wire is exposed from the tip, and the metal tape constituting the shield conductor is exposed below the core cable. When the coaxial cable to be connected is inserted through the insertion portion 23, the core wire is introduced into the insulator 16, and the metal tape comes into contact with the inner surface of the insertion portion 23 to be grounded. Then, caulking is performed on the arcuate portion 14d so as to wrap the braided wire folded on the jacket. Since the braided wire is also a shield conductor, the shield conductor of the coaxial cable can be grounded to the metal case 20 also by this. Further, the core wire introduced into the insulator 16 is disposed above the center contact 17 inserted through the insertion hole 16m, and the screw 18 is screwed into the screw hole 16k, whereby the core wire is connected to the center contact 17 by the pressing portion 16b. And are electrically connected to each other. Finally, when the case lid portion 12 including the metal case lid portion 13 is folded back and fitted into the case main body portion 11, the engagement piece 11 b is engaged with the engagement groove 12 b and the L-shaped coaxial plug 1 is assembled. The metal case lid portion 13 is fitted into the opening surface of the rectangular tube portion 21 of the metal case 20 to be shielded.

<Details of the first embodiment>
A detailed description of the L-type coaxial plug 1 which is the first embodiment of the coaxial cable connection structure of the present invention will be described with reference to FIGS.
17A is a rear view showing the configuration of the L-shaped coaxial plug 1, FIG. 17B is a bottom view thereof, FIG. 17C is an enlarged view of a portion B in the bottom view, and FIG. It is a rear view which abbreviate | omits and shows the case cover part 12 which shows the structure. In these drawings, the configuration of the L-type coaxial plug 1 in a state where the coaxial cable is not connected is shown.
As shown in these drawings, the L-type coaxial plug according to the first embodiment is an L-type in which a cylindrical portion 22 protrudes from the front surface of a vertically long rectangular parallelepiped case 10. On the lower surface of the case 10, a slightly elliptical hole is formed through which the coaxial cable is inserted through the cable insertion portion 11h of the case main body 11 and the cable insertion portion 12d of the case lid portion 12. As shown in FIG. 17 (c), the arcuate portion 14 d of the caulking metal fitting 14, the first serrated projection 14 e, and the second serrated projection 14 g face the hole, and the insertion portion 23 of the metal case 20 faces the hole. The large-diameter portion 23e, the small-diameter portion 23f, the first protrusion 23g, and the second protrusion 23h that are the insertion holes 23a face each other. Further, the inclined surface 16n and the guide portion 16i formed in the rectangular window 16d of the insulator 16 face the small diameter portion 23f.
Further, as shown in FIG. 18, the case main body 11 houses a metal case 20 and a caulking metal fitting 14 integrated with the metal case 20, and four pieces are provided in the rectangular tube portion 21 of the metal case 20. The insulator 16 positioned by the protrusion 21a is inserted.

The first coaxial cable 30 or the second coaxial cable 31, which are two types of coaxial cables having different outer diameters, can be connected to the L-shaped coaxial plug 1 shown in FIGS. When connecting, the coaxial cable is processed. 19A is a front view showing the processed configuration of the first coaxial cable 30, FIG. 19B is a cross-sectional view thereof, and FIG. 19C is a front view showing the processed configuration of the second coaxial cable 31. FIG. 19D is a cross-sectional view thereof.
As shown in FIGS. 19 (a) and 19 (b), the first coaxial cable 30 has a core wire 30e disposed on the center axis, and the core wire 30e is insulated by an insulator 30d having a circular cross section such as foamed polyethylene. A metal tape 30c, which is a shield conductor such as an aluminum foil, is wound around the outer surface of the metal tape, the outer periphery of the metal tape 30c is covered with a net-like shield conductor called a tubular braided wire 30b, and the outer side of the metal tape 30c is an outer surface such as vinyl The structure covered with the covering 30a is a wide-band, low-loss, high-shielded coaxial cable.
The characteristic impedance Z (Ω) of the coaxial cable is expressed by the following equation.
Z = (138 / √ε) log ₁₀ (m / n)
Where ε is the relative dielectric constant of the insulator, m is the outer diameter of the core wire, and n is the inner diameter of the metal tape. The first coaxial cable 30 is, for example, “S-5C-FB” and has a relative dielectric constant ε of about 1.5, an outer diameter m of the core wire 30e is 1.05 mm, and an outer diameter n of the metal tape 30c is 5.0 mm. The characteristic impedance Z is about 75Ω.

Although the outer diameter of the second coaxial cable 31 is smaller than that of the first coaxial cable 30, it has the same configuration. As shown in FIGS. 19C and 19D, a core wire 31e is disposed on the central axis, and the core wire 31e. Is insulated by an insulator 31d having a circular cross section such as foamed polyethylene, and a metal tape 31c used as a shield conductor such as aluminum foil is wound around the outer surface of the insulator 31d, and the outer periphery of the metal tape 31c is a braid with a cylindrical shape. The cable 31b is covered with a net-like shield conductor called wire 31b, and the outer side thereof is covered with a jacket 31a made of vinyl or the like to form a wideband, low loss, high shielded coaxial cable.
The second coaxial cable 31 is, for example, “S-4C-FB” and has a relative dielectric constant ε of about 1.5, an outer diameter m ′ of the core wire 31a is 0.8 mm, and an outer diameter n ′ of the metal tape 31c is 3. 0.7 mm and the characteristic impedance Z is about 75Ω.

  Since the processing for connecting the first coaxial cable 30 and the second coaxial cable 31 to the L-type coaxial plug 1 is the same, the first coaxial cable 30 will be described. The jacket 30a of the first coaxial cable 30 is removed by a predetermined length, and the braided wire 30b is folded back onto the jacket 30a. Next, the core wire 30e is exposed by a predetermined length by removing the metal tape 30c and the insulator 30d by a predetermined length. This state is shown in FIG. The processing for connecting the second coaxial cable 31 to the L-shaped coaxial plug 1 is performed in the same manner.

The configuration of the L-shaped coaxial plug 1 in a state where the coaxial cable is connected is shown in FIGS. 20A is a bottom view showing a configuration in which the second coaxial cable 31 is connected to the L-shaped coaxial plug 1, FIG. 20B is a cross-sectional view along the line aa in the bottom view, and FIG. The bottom view which shows the structure which connected the 1st coaxial cable 30 to the type | mold coaxial plug 1, FIG.21 (b) is bb sectional drawing in a bottom view.
As shown in FIGS. 20A and 20B, when the second coaxial cable 31 is connected to the L-shaped coaxial plug 1, the outer surface 31 a of the second coaxial cable 31 is placed in the arcuate portion 14 d of the caulking metal fitting 14. The braided wire 31b folded back is positioned, the arcuate portion 14d is crimped, the braided wire 31b is electrically connected to the caulking metal fitting 14, and the second coaxial cable 31 is fixed. Since the metal tape 31c provided on the insulator 31d of the second coaxial cable 31 has a small diameter, the metal tape 31c is inserted into the small diameter portion 23f of the insertion portion 23 of the metal case 20, and the second protrusion 23h is formed on the metal tape 31c. It bites in and is securely grounded to the metal case 20. Further, when the second coaxial cable 31 is inserted from the insertion portion 23, the core wire 31 a is inserted from the rectangular window 16 d of the insulator 16, is guided by the guide portion 16 i, and is bent. It arrange | positions on the character-shaped part 17c. Then, by screwing the screw 18, the core wire 31 a is crimped by the pressing portion 16 b, and the core wire 31 a is electrically connected to the center contact 17. In this case, since the U-shaped protrusion 16p is positioned around the screw 18 and the screw 18 and the core wire 31a are insulated, the characteristic impedance Z of the second coaxial cable 31 is not disturbed. When the second coaxial cable 31 is “S-4C-FB”, the inner diameter of the small diameter portion 23f is about 4.05 mm.

  Further, as shown in FIGS. 21A and 21B, when the first coaxial cable 30 is connected to the L-shaped coaxial plug 1, the jacket of the first coaxial cable 30 is placed in the arcuate portion 14d of the caulking metal fitting 14. The folded braided wire 30b is positioned on 30a, the arcuate portion 14d is crimped, the braided wire 30b is electrically connected to the caulking metal fitting 14, and the first coaxial cable 30 is fixed. Since the metal tape 30c provided on the insulator 30d of the first coaxial cable 30 has a large diameter, the metal tape 30c is inserted into the large diameter portion 23e of the insertion portion 23 of the metal case 20, and the first protrusion 23g is inserted into the metal tape 30c. The metal case 20 is securely grounded. Further, when the first coaxial cable 30 is inserted from the insertion portion 23, the core wire 30 e is inserted from the rectangular window 16 d of the insulator 16, guided by the guide portion 16 i, and bent. It arrange | positions on the character-shaped part 17c. Then, by screwing the screw 18, the core wire 30 e is crimped by the pressing portion 16 b, and the core wire 30 e is electrically connected to the center contact 17. In this case, since the U-shaped protrusion 16p is positioned around the screw 18 and the screw 18 and the core wire 30e are insulated, the characteristic impedance Z of the first coaxial cable 30 is not disturbed. When the first coaxial cable 30 is “S-5C-FB” and the second coaxial cable 31 is “S-4C-FB”, the small diameter portion 23f has an inner diameter of about 4.05 mm and a large diameter. The inner diameter of the portion 23e is about 5.4 mm. In this case, the core wire 30e is located on the central axis of the small diameter portion 23f, and its characteristic impedance is about 81Ω, but the characteristic impedance Z is not disturbed as much as possible in the L-type coaxial plug 1.

In the L-shaped coaxial plug 1 described above, the metal tape and the braided wire constituting the shield conductor of the coaxial cable are grounded to the metal case 20 regardless of whether the first coaxial cable 30 or the second coaxial cable 31 is connected. Is done. Thereby, the L-shaped coaxial plug 1 according to the present invention can realize a high shield even when a plurality of coaxial cables having different diameters are connected.
FIG. 22 shows the frequency characteristics of the leakage electric field strength on the lower surface of the L-type coaxial plug 1 when the second coaxial cable 31 is connected to the L-type coaxial plug 1. 22A shows the frequency characteristics of the leakage electric field strength when both the metal tape 31c and the braided wire 31b are grounded to the metal case 20, and FIG. 22B shows the frequency characteristic of the metal tape 31c grounded to the metal case 20. However, the braided wire 31b is a frequency characteristic of the leakage electric field intensity when it is not grounded. FIG. 22 (c) shows that the metal tape 31c is not grounded, but the braided wire 31b is grounded to the metal case 20. FIG. 22D shows the frequency characteristics of the leakage electric field strength when both the metal tape 31c and the braided wire 31b are not grounded. In these drawings, the solid line indicates the electric field intensity of horizontal polarization, and the broken line indicates the electric field intensity of vertical polarization.

  For example, the predetermined value of the leakage electric field intensity can be set to 34 dBμV / m or less. Referring to these drawings, if the metal tape 31c is grounded to the metal case 20, as shown in FIGS. 22 (a) and 22 (b), regardless of whether the braided wire 31b is grounded, the horizontal polarization As for the leakage electric field strength in the vertically polarized wave, a good leakage electric field strength characteristic of about 10 dBμV / m or less is obtained in the band of 1000 MHz to 3225 MHz. On the other hand, when the metal tape 31c is not grounded to the metal case 20 and only the braided wire 31b is grounded to the metal case 20, as shown in FIG. For waves, the maximum is about 35 dBμV / m, and for vertically polarized waves, the maximum is about 40 dBμV / m. Further, when the metal tape 31c and the braided wire 31b are not grounded to the metal case 20, as shown in FIG. 22 (d), the maximum is about 43 dBμV / m in the horizontal polarization and the maximum in the vertical polarization as shown in FIG. It becomes about 58 dBμV / m.

  FIG. 23 shows the frequency characteristics of the leakage electric field strength on the lower surface of the L-type coaxial plug 1 when the first coaxial cable 30 is connected to the L-type coaxial plug 1. FIG. 23A shows the frequency characteristics of leakage electric field strength when both the metal tape 30c and the braided wire 30b are grounded to the metal case 20, and FIG. 23B shows the metal tape 30c grounded to the metal case 20. However, the braided wire 30b is a frequency characteristic of the leakage electric field strength when it is not grounded. FIG. 23 (c) shows that the metal tape 30c is not grounded, but the braided wire 30b is grounded to the metal case 20. FIG. 23D shows the frequency characteristics of the leakage electric field strength when both the metal tape 30c and the braided wire 30b are not grounded. In these drawings, the solid line indicates the electric field intensity of horizontal polarization, and the broken line indicates the electric field intensity of vertical polarization.

Referring to these drawings, if the metal tape 30c is grounded to the metal case 20, as shown in FIGS. 23 (a) and 23 (b), regardless of whether the braided wire 30b is grounded, horizontal polarization As for the leakage electric field strength in the vertically polarized wave, a good leakage electric field strength characteristic of about 11 dBμV / m or less is obtained in the band of 1000 MHz to 3225 MHz. Further, even when the metal tape 30c is not grounded to the metal case 20 and only the braided wire 30b is grounded to the metal case 20, as shown in FIG. 23 (c), 0 dBμV in the horizontal polarization in the band of 1000 MHz to 3225 MHz. / M or less, and a good leakage electric field strength characteristic of about 4 dBμV / m at the maximum is obtained in vertical polarization. On the other hand, when the metal tape 30c and the braided wire 30b are not grounded to the metal case 20, as shown in FIG. 23 (d), the maximum is about 30 dBμV / m in the horizontal polarization in the 1000 MHz to 3225 MHz band. In a wave, the maximum is about 40 dBμV / m.
As described above, in the L-type coaxial plug 1 according to the first embodiment of the present invention, if the metal tape connected to the L-type coaxial plug 1 is grounded to the metal case 20, a good broadband leakage field strength characteristic is obtained. Further, it can be seen that the frequency characteristic extends to 3.2 GHz. In the L-shaped coaxial plug 1 of the first embodiment, the metal tape of the coaxial cable can be grounded to the metal case 20 by inserting the end of the coaxial cable to be connected after performing the processing shown in FIG. The L-shaped coaxial plug 1 according to the present invention can realize a high shield in a wide band even when a plurality of types of coaxial cables having different diameters are connected.

Next, the coaxial cable connection structure of the present invention will be described using a coaxial repeater that is a second embodiment to which the coaxial cable connection structure of the present invention is applied.
<Second embodiment>
The configuration of the coaxial repeater 2 which is the second embodiment of the coaxial cable connection structure of the present invention is shown in FIGS. 24A is a perspective view showing the configuration of the coaxial repeater 2, FIG. 24B is a top view thereof, FIG. 24C is a side view thereof, and FIG. FIG. 25B is a rear view showing the configuration of the coaxial repeater 2 in the opened state, and FIG. 26A shows the configuration of the coaxial repeater 2 with the case lid 42 opened. FIG. 27B is a side view showing the configuration of the coaxial repeater 2 as seen from above. FIG. 27 is an exploded view showing the configuration of the coaxial repeater 2 in a perspective view.
As shown in these drawings, the coaxial repeater 2 as the second embodiment of the coaxial cable connection structure of the present invention includes a resin case 40, and the case 40 has a box-like case body with an upper surface opened. It is comprised from the part 41 and the case cover part 42 which the upper surface opened. The case main body 41 and the case lid 42 are formed by molding a resin, and a long edge on one side of the opening surface of the case main body 41 and a length on one side of the opening surface of the case lid 42. The edge is connected by a hinge portion 43. Then, the engaging portion 42 b is formed by extending upward from the long edge on the other side of the opening surface of the case lid portion 42, and the engaging step portion 41 c with which the engaging portion 42 b engages is the other of the case body portion 41. Formed on the outer surface of the side wall, and when the case lid 42 is closed by the hinge body 43 and the case lid 42 is closed to the case main body 41, the engaging portion 42b engages with the engaging step portion 41c. 42 is openable and closable with respect to the case main body 41.

The space inside the case 40 when the opening surface of the case body 41 is closed by the case lid 42 is a storage space, and the shield conductors and core wires of the two coaxial cables inserted from both sides are connected to each other in this storage space. Is done. In the coaxial repeater 2 of the second embodiment, it is possible to connect two types of coaxial cables having different diameters as coaxial cables in any combination. In the configuration shown in FIG. The coaxial cable 30-1 and the first coaxial cable 30-2 having a large diameter are connected. The first coaxial cables 30-1 and 30-2 are, for example, “S-5C-FB”, and the second coaxial cables 31-1 and 31-2 having a small diameter, which will be described later, are “S-4C-FB” cables. It can be.
As shown in FIGS. 24 to 26, in the housing space in the case 40, the metal case 50 and the metal case cover part for constructing the configuration in which the shield conductors and the core wires of the first coaxial cables 30-1 and 30-2 are connected to each other. 56, the insulator 60, the central conductor 70, the first caulking fitting 80, and the second caulking fitting 81 are accommodated. The metal case 50 houses the first cylindrical portion 52a into which the first coaxial cable 30-1 is inserted from one side, the second cylindrical portion 52b into which the first coaxial cable 30-2 is inserted from the other side, and the insulator 60. A long cylindrical portion 51 having a space formed therein is provided between the first cylindrical portion 52a and the second cylindrical portion 52b. The upper surface of the long cylinder part 51 is opened, and the metal case cover part 56 is fitted in this opening. The insulator 60 holds the central conductor 70 that connects the cores of the inserted first coaxial cables 30-1 and 30-2, and the first coaxial cable 30-1 inserted from the first cylindrical portion 52a. The core wire and the core wire of the first coaxial cable 30-1 inserted from the second cylindrical portion 52 b are electrically connected by the central conductor 70 held by the insulator 60. The center conductor 70 is held by the insulator 60 so as to be disposed on the substantially central axis of the long cylindrical portion 51. The first caulking metal fitting 80 is fixed by caulking the first coaxial cable 30-1 inserted into the first cylindrical portion 52a. At this time, the braid is one of the shield conductors of the first coaxial cable 30-1. It is in electrical contact with the wire. The second caulking metal fitting 81 is fixed by caulking the first coaxial cable 30-2 inserted into the second cylindrical portion 52b. At this time, one of the shield conductors of the first coaxial cable 30-2. It is in electrical contact with a braided wire.

<Case 40>
Before explaining the exploded view of the coaxial repeater 2 of the second embodiment shown in FIG. 27, each part constituting the coaxial repeater 2 will be explained with reference to FIGS.
The case 40 will be described with reference to FIGS. 28 and 29. FIG. 28A is a top view showing the configuration of the case 40 of the coaxial repeater 2 according to the second embodiment, FIG. 28B is a top view thereof, and FIG. 28A is a side view thereof. FIG. 29A is a rear view showing the configuration of the case 40, FIG. 29B is a perspective view showing the configuration of the case 40, and FIG. 29B is a perspective view showing the configuration of the case 40 viewed from below. It is shown in 29 (c). In these drawings, a state in which the case lid 42 is opened from the case main body 41 is shown.
The case 40 shown in these drawings has a function of housing a metal case 50 in which an insulator 60 holding a later-described center conductor 70 is inserted. Further, the first coaxial cable 30-1 or the second coaxial cable 31-1 to be connected is introduced from one side of the case 40, and either the first coaxial cable 30-2 or the second coaxial cable 31-2 is introduced from the other side. Is inserted. The case 40 is made by molding, for example, a weather-resistant polypropylene resin. The case 40 has a substantially rectangular box-shaped case main body 41 having an upper surface opened, and a substantially rectangular box-shaped case having an upper surface opened. It is comprised from the cover part 42. FIG.

A long edge on one side of the body side wall 41a of the case body 41 and a long edge on one side of the lid side wall 42a of the case lid 42 are connected to each other by a hinge 43 so that the hinge 43 can be bent. The case lid 42 can be opened and closed with respect to the case body 41 by bending. In addition, a horizontally long rectangular engaging portion 42b having an engaging piece 42c formed at the tip is formed to extend upward from the center of the long edge on the other side of the lid side wall portion 42a of the case lid portion 42. An engaging step portion 41 c with which the mating piece 42 c can be engaged is formed on the outer surface of the case main body 41 on the other side of the main body side wall 41 a. The engaging step portion 41 c is formed in a recess 41 b formed on the outer surface of the central portion on the other side of the main body side wall portion 41 a of the case main body portion 41. Then, when the case lid portion 42 is rotated so that the hinge portion 43 is bent and fitted to the case main body portion 41, the engaging portion 42b of the case lid portion 42 is fitted into the concave portion 41b of the case main body portion 41. Thus, the engagement piece 42c is engaged with the engagement step portion 41c, and the case lid portion 42 is securely fitted to the case main body portion 41. The engagement piece 42c has a wedge-shaped cross-sectional shape, and an inclined surface whose width becomes narrower as it goes upward is formed. The lower end of the inclined surface is a step that engages with the engaging step portion 41c.
The shape of the opening surface of the case main body 41 and the shape of the opening surface of the case lid 42 are substantially the same, and when the case lid 42 is fitted on the case main body 41, the main body side wall 41a. The upper edge of the lid side wall part 42 a is brought into contact with the upper edge of the case without gaps, and the opening surface of the case body 41 is closed by the opening surface of the case lid part 42. The engaging portion 42b is formed so as to be elastically displaceable back and forth. When the case lid portion 42 is fitted on the case main body portion 41, the engaging piece 42c at the upper end of the engaging portion 42b and the main body A gap is formed between the side wall 41a and the side wall 41a. This gap is a gap for separating the engagement piece 42 c from the engagement step portion 41 c and opening the case lid portion 42 from the case main body portion 41.

Guide ridges 41f made of ridges having a rectangular cross section are formed on both sides of the lower surface of the case main body 41 so as to protrude in the short axis direction, and bosses having a circular cross section are formed at both ends of the guide ridges 41f. 41h protrudes. A standing piece 41g is formed near the center substantially parallel to the two guide protrusions 41f, and a pair of standing pieces 41g made of short protrusions having a rectangular cross section are formed in the major axis direction at both ends of the lower surface. Each is formed. In addition, a semicircular first insertion portion 41d and a second insertion portion 42e are formed on both side surfaces of the case main body portion 41, respectively.
An engagement portion 42b is formed which extends upward from the center portion of the other long edge of the lid side wall portion 42a of the case lid portion 42 and includes an engagement piece 42c at the tip. In addition, a semicircular first insertion portion 42d and a second insertion portion 42e are formed on both side surfaces of the case lid portion 42, respectively. When the case lid 42 is fitted to the case main body 41, the first insertion portion 41d and the first insertion portion 42d form a substantially circular cable insertion hole through which the first coaxial cable can be inserted. The second insertion portion 41e and the second insertion portion 42e form a substantially circular cable insertion hole through which the second coaxial cable can be inserted.

<Metal case 50>
Next, the configuration of the metal case 50 of the coaxial repeater 2 according to the second embodiment will be described with reference to FIGS. 30 and 31. FIG. FIG. 30 (a) is a front view showing the configuration of the metal case 50 of the coaxial repeater 2 of the second embodiment, FIG. 30 (b) is its top view, and FIG. 30 (c) is its side view. FIG. 30 (d) is an enlarged view of a C portion of the side view showing the configuration of the metal case 50, and FIG. 31 (a) is a bottom view showing the configuration of the metal case 50. FIG. 31B shows a perspective view of the metal case 50, and FIG. 31C shows a perspective view of the configuration of the metal case 50 viewed from below.
The metal case 50 shown in these drawings is a connection between the first coaxial cable 30-1 or the second coaxial cable 31-1 and the first coaxial cable 30-2 or the second coaxial cable 31-21 connected in the coaxial repeater 2. It has the function of shielding the part. The metal case 50 is made, for example, by die-casting brass and nickel-plating, and includes a long box portion 51 that is long in a rectangular box shape with an upper surface 51a. A step portion 51c is formed at the upper end of the side wall of the long cylindrical portion 51 forming the opening 51a, and the inside of the side wall is formed one step lower. A storage space 51b is formed in the long cylindrical portion 51 by the opening 51a. The storage space 51b of the long cylindrical portion 51 is a storage space in which the insulator 60 is stored, and protrusions having a rectangular cross section are formed in the four corners of the storage space 51b in the vertical direction, and the widths at both ends in the longitudinal direction. Insertion portions 51d that are narrowed by one step are formed. Both ends of the insulator 60 are fitted and attached to the fitting portion 51d.

  The metal case 50 includes a first cylindrical portion 52a formed integrally with one end of the long cylindrical portion 51 in the longitudinal direction, and a second cylindrical portion 52b formed integrally with the other longitudinal end of the long cylindrical portion 51. And. The long cylindrical portion 51 and the first cylindrical portion 52a are communicated with each other through the first through hole 52c, and the long cylindrical portion 51 and the second cylindrical portion 52b are communicated with each other through the second through hole 52d. The configuration of the first through hole 52c is shown in an enlarged view of a C portion in FIG. As shown in this figure, the inner side of the first through hole 52c is a small diameter part 55b whose diameter is reduced, and the outer side of the first through hole 52c is a large diameter part 55a whose diameter is increased. Yes. A step portion 55c is formed between the large diameter portion 55a and the small diameter portion 55b. Further, four first protrusions 55e having a triangular cross section are formed at equal intervals so as to protrude from the inner peripheral surface of the large diameter portion 55a, and protrude from the inner peripheral surface of the small diameter portion 55b. In addition, four second protrusions 55d having a triangular cross section are formed at equal intervals. Here, when the first coaxial cable 30-1 is inserted into the first through hole 52c, the metal tape 30c, which is the shield conductor of the first coaxial cable 30-1, has a large diameter, and thus comes into close contact with the large diameter portion 55a. Inserted like so. Then, the first protrusion 55e bites into the metal tape 30c, and the metal tape 30c is electrically and reliably grounded to the large diameter portion 55a. When the second coaxial cable 31-1 is inserted into the first through hole 52c, the metal tape 31c, which is a shield conductor of the second coaxial cable 31-1, is inserted so as to be in close contact with the small-diameter portion 55b. Is done. Then, the 2nd protrusion 55d bites into metal tape 31c, and metal tape 31c is electrically connected to small diameter part 55b reliably. This ensures that the metal tape of the coaxial cable is securely grounded to the metal case 50 regardless of whether the first coaxial cable 30-1 or the second coaxial cable 31-1 is inserted into the first through hole 52c. Become.

The second through hole 52d has the same configuration as the first through hole 52c, and is a shield conductor of the first coaxial cable 30-2 when the first coaxial cable 31-1 is inserted into the second through hole 52d. Since the metal tape 30c has a large diameter, the metal tape 30c is inserted into close contact with the large diameter portion 55a. Then, the first protrusion 55e bites into the metal tape 30c, and the metal tape 30c is electrically and reliably grounded to the large diameter portion 55a. When the second coaxial cable 31-2 is inserted into the second through hole 52d, the metal tape 31c, which is the shield conductor of the second coaxial cable 31-2, is inserted so as to be in close contact with the small-diameter portion 55b. Is done. Then, the 2nd protrusion 55d bites into metal tape 31c, and metal tape 31c is electrically connected to small diameter part 55b reliably. This ensures that the metal tape of the coaxial cable is securely grounded to the metal case 50 regardless of whether the first coaxial cable 30-2 or the second coaxial cable 31-2 is inserted into the first through hole 52c. Become.
In addition, a first flat plate portion 53a that is substantially rectangular integrally is formed under the first cylindrical portion 52a, and a second flat plate portion 53b that is substantially rectangular is formed under the second cylindrical portion 52b. Yes. The front end side of the first flat plate portion 53a is narrowed by one step, and first bosses 54a having a circular cross section projecting downward are formed on both sides of the lower surface. Further, the rear side of the first flat plate portion 53a is wider by one step, and a substantially circular first engagement hole 53c is formed on each side thereof. The second flat plate portion 53b has the same configuration, the tip side is narrower by one step, and second bosses 54b having a circular cross section projecting downward are formed on both sides of the lower surface. Further, the rear side of the second flat plate portion 53b is wider by one step, and a substantially circular second engagement hole 53d is formed on each side thereof.

<Insulator 60>
Next, the structure of the insulator 60 will be described with reference to FIGS. 32 and 33. FIG. FIG. 32 (a) is a top view showing the configuration of the insulator 60 of the coaxial repeater 2 of the second embodiment, FIG. 32 (b) is a front view thereof, and FIG. 32 (c) is a side view thereof. A rear view thereof is shown in FIG. 32 (d), a bottom view showing the configuration of the insulator 60 of the coaxial repeater 2 is shown in FIG. 33 (a), and a perspective view showing the configuration of the insulator 60 as viewed from above is shown in FIG. FIG. 33C is a perspective view showing the configuration of the insulator 60 as viewed from below, in FIG. In these drawings, a state in which the insulating lid 62 is opened from the insulating main body 61 is shown.
The insulator 60 shown in these drawings has a substantially cylindrical shape and has a function of holding a center conductor 70 to be described later along substantially the central axis in the longitudinal direction of the long cylindrical portion 51 of the metal case 50. . The insulator 60 is made, for example, by molding a weather-resistant polypropylene resin, and has a horizontally long insulating main body 61 having a semicircular cross section with an open top surface and a semi-cross section with an open top surface. It is comprised from the horizontally long insulation cover part 62 made into circular shape. A disk-shaped first insertion portion 61a into which the core wire of the first coaxial cable 30-1 or the second coaxial cable 31-1 is inserted is formed on one side of the insulator 60, and on the other side of the insulator 60. A disc-shaped second insertion portion 61b into which the core wire of the first coaxial cable 30-2 or the second coaxial cable 31-2 is inserted is formed. The core wire of the coaxial cable inserted into the first insertion portion 61 a and the core wire of the coaxial cable inserted into the second insertion portion 61 b are insulated from the metal case 50 by the center conductor 70 held by the insulator 60 and are electrically Connected.

At both ends of the insulating main body 61, circular insertion cylinders 61h are formed, and a first insertion part 61a and a second insertion part 61b are formed by the insertion cylinders 61h, respectively. A long edge on one side in the longitudinal direction of the insulating main body 61 and a long edge on one side in the longitudinal direction of the insulating lid 62 are connected by a hinge part 63 so as to be bent. By bending the hinge 63, the insulating lid 62 can be opened and closed with respect to the insulating main body 61. Also, a horizontally elongated engagement piece 62d is formed extending upward from substantially the center of the long edge on the other side of the insulating lid 62, and an engagement step 61c to which the engagement piece 62d can be engaged is formed. It is formed on the outer surface of the wall portion below the long edge on the other side of the insulating main body 61. The engagement step portion 61 c is formed by the upper edge of a rectangular window portion 61 d formed on the outer surface of the wall portion below the long edge on the other side of the insulating main body portion 61. Then, when the insulating lid 62 is rotated so that the hinge 63 is bent and fitted to the insulating main body 61, the engaging piece 62 d of the insulating lid 62 is engaged with the engaging step 61 c of the insulating main body 61. Thus, the insulating lid 62 is securely fitted to the insulating main body 61. The engaging piece 62d has a wedge-shaped cross-sectional shape, and an inclined surface whose width becomes narrower as it goes upward is formed. The lower end of the inclined surface is a step that engages with the engaging step portion 61c.
The shape of the insulating lid 62 is substantially the same as the shape of the opening of the insulating main body 61. When the insulating lid 62 is fitted on the insulating main body 61, the opening of the insulating main body 61 is The cylindrical insulator 60 is configured by being closed by the insulating lid 62. Further, the engaging piece 62c is formed so as to be elastically displaceable back and forth, and when the insulating lid 62 is fitted on the insulating main body 61, the engagement piece 62c is positioned between the upper end of the engaging piece 62d and the window 61d. There will be a gap in the gap. This gap is a gap for separating the engagement piece 62d from the engagement step portion 61c and opening the insulating lid portion 62 from the insulating main body portion 61.

A projecting piece 61g made of a protrusion having a rectangular cross section and a flat tip is formed in the center of the lower surface of the insulating main body 61 so as to protrude upward. The disc-shaped first insertion portion 61a and second insertion portion 61b formed at both ends of the insulating main body 61 have the same configuration, and are circular insertion holes into which the core wire of the coaxial cable formed at the center is inserted. 61e, a tapered portion 61f having a conical shape so as to guide the core wire of the coaxial cable to the insertion hole 61e formed around the insertion hole 61e, and a short cylindrical fitting tube portion 61h formed around the tapered portion 61f It is composed of
A position restricting piece 62c made of a protrusion having a rectangular cross section is formed on the lower surface of the insulating cover 62 so as to protrude upward. On the lower surface of the insulating lid 62 on both sides of the position restricting piece 62c, a pair of rectangular cross-sections are formed so that a vertically long guide piece 62d is opposed to form a gap in the center. In addition, a pair of rectangular cross-sections and vertically long holding pieces 62a are formed on the lower surface of the insulating lid 62 outside the guide piece 62d so that a gap is formed at the center. The four guide pieces 62d and the four holding pieces 62a hold the central conductor 70 substantially on the central axis in the longitudinal direction of the insulator 60, and the upper ends of the holding pieces 62a on the opposite surface side approach the tip. A slope having a narrow width is formed, and a wedge-shaped cross-sectional shape in which a lower end of the slope is a step is formed. Further, when the center conductor 70 is held by the four guide pieces 62d and the four holding pieces 62a, the position restricting piece 62c is inserted into the center conductor 70 to restrict the position of the core wire of the coaxial cable.

<Center conductor 70>
Next, the configuration of the center conductor 70 will be described with reference to FIGS. FIG. 34 (a) is a top view showing the configuration of the center conductor 70 of the coaxial repeater 2 of the second embodiment, FIG. 34 (b) is a front view thereof, and FIG. 34 (c) is a side view thereof. A bottom view showing the configuration of the central conductor 70 is shown in FIG. 35A, and a perspective view showing the configuration of the central conductor 70 is viewed from the front, and FIG. A perspective view is shown in FIG.
The center conductor 70 shown in these drawings is formed by processing, for example, a nickel-plated copper plate or phosphor bronze plate, and the coaxial cable core line inserted from one side of the coaxial repeater 2 and the coaxial repeater 2. It has a function of electrically connecting the core wire of the coaxial cable inserted from the other side. The center conductor 70 is formed at the distal end of the central portion 71, a first intermediate portion 72a extending from the central portion 71 to one side, a second intermediate portion 72b extending to the other side, and the first intermediate portion 72a. The first sandwiching piece 73a and the second sandwiching piece 73b formed at the tip of the second intermediate portion 72b are provided.

The central portion 71 is composed of two metal plates having an arcuate cross-section facing each other, the two metal plates are connected to each other by a folded portion 71a and bent so as to face each other, and a gap 71b is formed between the upper ends. Has been. On both sides of the two metal plates at the upper end of the central portion 71, a pair of bent portions 71c bent in a U-shape are formed to face each other. The first intermediate part 72a and the second intermediate part 72b are formed so that two metal plates face each other from both sides of the central part 71, and have an arcuate cross-sectional shape. It is processed so as to approach each other and come into contact with each other at the tip to eliminate the gap 71b. The first sandwiching piece 73a and the second sandwiching piece 73b are formed such that two metal plates are stretched and faced from the tip where the gap 71b between the first intermediate part 72a and the second intermediate part 72b disappears. The arc-shaped cross-sectional shape is formed by being bent into an arc shape so as to be farther away from each other, and the core wire of the coaxial cable is easily inserted.
The center conductor 70 is held by the insulator 60, and the core wire of the coaxial cable inserted into the first insertion portion 61 a of the insulator 60 is inserted into the first holding piece 73 a and elastically held. The core wire of the coaxial cable inserted into the second insertion portion 61b is inserted into the second holding piece 73b and held elastically, and the core wires are electrically connected.

<Metal case cover 56>
Next, the configuration of the metal case lid 56 will be described with reference to FIG. FIG. 36 (a) is a top view showing the configuration of the metal case cover 56 of the coaxial repeater 2 of the second embodiment, FIG. 36 (b) is a front view thereof, and FIG. 36 (c) is a side view thereof. Shown in
The metal case cover part 56 shown in these drawings has a function of closing the rectangular opening 51 a of the long cylindrical part 51 in the metal case 50 and securely shielding the metal case 50. The metal case lid part 56 is constituted by a main body part 56 a having an elongated rectangular shape that is substantially the same as the opening 51 a on the upper surface of the long cylindrical part 1 of the metal case 50. The metal case cover part 56 is press-fitted into the opening 51a of the long cylindrical part 51 of the metal case 50, so that the opening 51a of the metal case 50 is reliably closed and shielded.

<First caulking metal fitting 80, second caulking metal fitting 81>
Since the first caulking metal fitting 80 and the second caulking metal fitting 81 have the same configuration as the caulking metal fitting 14 in the L-type coaxial plug 1 of the first embodiment shown in FIG. 15, detailed description thereof is omitted. The first caulking metal fitting 80 and the second caulking metal fitting 81 are made, for example, by processing a flat plate of brass and plating with nickel, and the first caulking metal fitting 80 is inserted into one of the coaxial repeaters 2. The second caulking metal fitting 81 has a function of fixing the coaxial cable 30-1 or the second coaxial cable 31-1 so as not to come out, and the second caulking fitting 81 is inserted from the other end of the coaxial repeater 2. 2 or the second coaxial cable 31-2 so as not to come out. The first caulking metal fitting 80 and the second caulking metal fitting 81 include a flat plate-like fixing portion and an arc-shaped caulking portion formed to be connected to one end of the fixing portion. A circular fitting hole for attachment is formed in the fixed portion. Both sides of the caulking portion are bent upward in an arc shape, and a plurality of saw-tooth projections are formed on the front end and both side surfaces facing each other. The first caulking metal fitting 80 is fixed by the first boss 54a formed on the first flat plate portion 53a of the metal case 50 being crimped to the fitting hole of the fixing portion, and the second caulking metal fitting 81 is fixed to the metal case 50. The second boss 54b formed on the second flat plate portion 53b is fixed by being crimped to the fitting hole of the fixing portion. When the metal case 50 is stored in the case main body 41, the first caulking metal fitting 80 and the second caulking metal fitting 81 integrated with the metal case 50 are also stored in the case main body 41.

<Assembly of coaxial repeater 2>
Returning to FIG. 27, an exploded view of the coaxial repeater 2 of the second embodiment will be described. When assembling the coaxial repeater 2, first, between the two pairs of guide pieces 62 b composed of a pair of opposed insulating cover portions 62 in the insulator 60 and the two pairs of holding pieces 62 a formed of a pair opposed to each other. The center conductor 70 is inserted from above. The center conductor 70 is positioned by the two sets of guide pieces 62d and is fixed by the two sets of holding pieces 62a so as not to come out of the insulating lid 62. At this time, the position restricting piece 62 c is inserted into the gap 71 b of the center conductor 70. Next, the insulating lid portion 62 is rotated so as to bend the hinge portion 63, and the insulating lid portion 62 is fitted on the insulating main body portion 61. At this time, the lower surface of the folded portion 71a of the central conductor 70 is brought into contact with the upper surface of the protruding piece 61g, and the arrangement of the central conductor 70 is determined, and the engaging piece 62d is engaged with the engaging step portion 61c, The insulating main body 61 and the insulating lid 62 are fixed. Thus, the cylindrical insulator 60 in which the center conductor 70 is housed is housed in the long tube portion 51 of the metal case 50. At this time, the fitting cylinder portions 61h protruding from both ends of the insulator 60 are respectively fitted into fitting portions 51d formed inside the long cylinder portion 51 and at both ends in the longitudinal direction. It is positioned and inserted into the long tube portion 51. At this time, the central conductor 70 is disposed on the central axis of the long cylindrical portion 51. And the metal case cover part 56 is press-fit in the opening 51a so that the opening 51a of the upper surface of the long cylinder part 51 may be obstruct | occluded. The first boss 54a of the first flat plate portion 53a of the metal case 50 is inserted into the fitting hole of the fixing portion of the first caulking metal fitting 80 and is fixed by crimping, and the second flat plate portion 53b is fixed. The second boss 54b is inserted into the fitting hole of the fixing portion in the second caulking metal fitting 81, and is crimped and fixed.

In this manner, the insulator 16 containing the central conductor 70 is housed, and the metal case 50 having the first caulking metal fitting 80 and the second caulking metal fitting 81 is housed in the case main body 41. When stored, the lower surfaces of the fixing portions of the first caulking metal fitting 80 and the second caulking metal fitting 81 are brought into contact with the guide protrusions 41 f formed on the inner surface of the case main body 41 and the upper surfaces of the plurality of standing pieces 41 g. At this time, each pair of two pairs of bosses 41 h formed on the inner surface of the case main body portion 41 and facing each other is a pair of first engagements formed on the first flat plate portion 53 a of the metal case 50. The metal case 50 is fixed to the case main body 41 by being inserted into a pair of second engaging holes 53d formed in the hole 53c and the second flat plate portion 53b and crimping two sets of bosses 41h.
Next, the first coaxial cable 30-1 or the second coaxial cable 31-1 positioned on one side in the longitudinal direction of the case main body 41 is passed through the first insertion portion 41 d and the arcuate portion of the first caulking fitting 80. The metal case 50 is inserted through the first cylindrical portion 52a. In this case, the coaxial cable to be inserted is processed as shown in FIG. 19, and the core wire is exposed from the tip, and the metal tape constituting the shield conductor is exposed below the core cable. When the coaxial cable to be connected is inserted through the first cylindrical portion 52a, the core wire is introduced into the insulator 60 and the metal tape comes into contact with the inner surface of the first cylindrical portion 52a to be grounded. Then, caulking processing is performed on the arc-shaped portion so as to wrap the braided wire folded on the jacket. Since the braided wire is also a shield conductor, the shield conductor of the coaxial cable can be grounded to the metal case 50 also by this. Finally, when the case lid portion 42 is folded back and fitted into the case main body portion 41, the engagement piece 42c is engaged with the engagement step portion 41c, and the coaxial repeater 2 is assembled.

<Details of Second Embodiment>
A detailed description of the coaxial repeater 2 which is the second embodiment of the coaxial cable connection structure of the present invention will be described with reference to FIGS.
37 (a) is a side view showing a configuration in which the case lid portion 42 of the coaxial repeater 2 is omitted, FIG. 37 (b) is an enlarged view of the D portion, and FIG. 37 (c) is a cc line in the side view. It is cc sectional drawing cut | disconnected by. In these drawings, the configuration of the coaxial repeater 2 in a state where the coaxial cable is not connected is shown.
As shown in these drawings, the coaxial repeater 2 according to the second embodiment includes a rectangular parallelepiped case 40 that is long in the lateral direction. On one side of the case 40 in the longitudinal direction, there is a first insertion hole having a slightly elliptical shape through which the coaxial cable is inserted through the insertion portion 41d of the case main body portion 41 and the first insertion portion 42d of the case lid portion 42. Is formed. Further, in the other side of the case 40 in the longitudinal direction, the second insertion portion 41e of the case body portion 41 and the second insertion portion 42e of the case lid portion 42 are inserted into the coaxial cable, and the second shape having a slightly elliptical shape is inserted. The insertion hole is formed. The configuration of the second insertion hole is shown in the enlarged view of part D in FIG. 37 (c). The arcuate portion of the second caulking fitting 81, the first sawtooth projection, and the second sawtooth projection face the metal. The large diameter portion 55a, the small diameter portion 55b, the first protrusion 55e, and the second protrusion 55d, which are the second through holes 52d of the second cylindrical portion 52b of the case 50, face each other. Further, the insertion hole 61e of the insulator 60 where the central conductor 70 faces faces the small diameter portion 55b. The configuration of the first insertion hole is the same as the configuration of the second insertion hole shown in the enlarged view of the D part.

  The coaxial repeater 2 shown in FIG. 37 is different in outer diameter from the first coaxial cable 30-1 or the second coaxial cable 31-1 having different outer diameters so as to relay two types of coaxial cables having different outer diameters. The first coaxial cable 30-2 or the second coaxial cable 31-2 can be connected. In the case of connection, the first coaxial cables 30-1 and 30-2 and the second coaxial cables 31-1 and 31-2 are processed as shown in FIG. The first coaxial cables 30-1 and 30-2 are, for example, “S-5C-FB” and have a relative dielectric constant ε of about 1.5, the outer diameter m of the core wire 30e is 1.05 mm, and the outside of the metal tape 30c. The diameter n is 5.0 mm and the characteristic impedance Z is about 75Ω. The second coaxial cables 31-1, 31-2 are, for example, “S-4C-FB”, the relative dielectric constant ε is about 1.5, the outer diameter m ′ of the core wire 31a is 0.8 mm, and the metal tape 31c The outer diameter n ′ is 3.7 mm, and the characteristic impedance Z is about 75Ω. A combination of the first coaxial cable 30-1 or the second coaxial cable 31-1 relayed by the coaxial repeater 2 and the first coaxial cable 30-2 or the second coaxial cable 31-2 can be an arbitrary combination. .

38 and 39 show the configuration of the coaxial repeater 2 with the coaxial cable connected thereto. 38A is a side view showing a configuration in which the second coaxial cable 31-1 and the second coaxial cable 31-2 are relayed by the coaxial repeater 2, and FIG. 38B is a sectional view taken along line dd in the side view. 39 (a) is a side view showing a configuration in which the first coaxial cable 30-1 and the first coaxial cable 30-2 are relayed by the coaxial repeater 2, and FIG. 39 (b) is an e- in the side view. FIG.
As shown in FIGS. 38A and 38B, when the second coaxial cable 31-1 and the second coaxial cable 31-2 are relayed by the coaxial repeater 2, the first caulking fitting 80 has a cylindrical portion. A folded braided wire is positioned on the outer sheath of the second coaxial cable 31-1, the cylindrical portion is crimped, and the braided wire is electrically connected to the first caulking metal fitting 80, thereby the second coaxial cable 31-1. Is fixed. Since the metal tape provided on the insulator of the second coaxial cable 31-1 has a small diameter, the metal tape is inserted into the small diameter portion 55b of the first cylindrical portion 52a of the metal case 50, and the second protrusion 55d is formed of the metal tape. The metal case 50 is securely grounded. When the second coaxial cable 31-1 is inserted from the first cylindrical portion 52a, the core wire is guided by the taper portion 61f of the insulator 60 and inserted from the insertion hole 61e. 1 is clamped by being pressed into the clamping piece 73a. As a result, the core wire is electrically connected to the central conductor 70. In this case, since the center conductor 70 is disposed on substantially the center axis of the long cylindrical portion 51 and has a coaxial structure, the characteristic impedance Z of the second coaxial cable 31-1 is not disturbed. When the second coaxial cable 31-1 is “S-4C-FB”, the inner diameter of the small diameter portion 55b is about 4.05 mm.

  In addition, the braided wire folded over the outer cover of the second coaxial cable 31-2 is located in the cylindrical portion of the second caulking metal fitting 81, and the cylindrical portion is crimped so that the braided wire is electrically connected to the second caulking metal fitting 81. Are connected and the second coaxial cable 31-2 is fixed. Since the metal tape provided on the insulator of the second coaxial cable 31-2 has a small diameter, the metal tape is inserted into the small diameter portion 55b of the second cylindrical portion 52b of the metal case 50, and the second protrusion 55d is the metal tape. The metal case 50 is securely grounded. When the second coaxial cable 31-2 is inserted from the second cylindrical portion 52b, the core wire is guided by the taper portion 61f of the insulator 60 and inserted from the insertion hole 61e. 2 It is press-fitted into the clamping piece 73b and clamped. As a result, the core wire is electrically connected to the central conductor 70. Also in this case, the characteristic impedance Z of the second coaxial cable 31-2 is not disturbed.

  Further, as shown in FIGS. 39A and 39B, when the first coaxial cable 30-1 and the first coaxial cable 30-2 are relayed by the coaxial repeater 2, the cylindrical shape of the first caulking fitting 80 is obtained. The braided wire that is folded back on the jacket of the first coaxial cable 30-1 is located in the portion, the cylindrical portion is crimped, and the braided wire is electrically connected to the first caulking metal fitting 80 so that the first coaxial cable 30 is connected. -1 is fixed. Since the metal tape provided on the insulator of the first coaxial cable 30-1 has a large diameter, the metal tape is inserted into the large-diameter portion 55a of the first cylindrical portion 52a of the metal case 50, and the first protrusion 55e is made of metal. The metal case 50 is securely grounded by biting into the tape. Further, when the first coaxial cable 30-1 is inserted from the first cylindrical portion 52a, the core wire is guided by the tapered portion 61f of the insulator 60 and inserted from the insertion hole 61e. 1 is clamped by being pressed into the clamping piece 73a. As a result, the core wire is electrically connected to the central conductor 70. In this case, since the center conductor 70 is disposed substantially on the central axis of the long cylindrical portion 51 and has a coaxial structure, the characteristic impedance Z of the first coaxial cable 30-1 is not disturbed. When the first coaxial cable 30-1 is "S-5C-FB" and the second coaxial cable 31-1 is "S-4C-FB", the inner diameter of the small diameter portion 55b is about 4. The inner diameter of 05 mm and the large diameter portion 55a is about 5.4 mm. In this case, the core wire is located on the central axis of the small diameter portion 55b, and the characteristic impedance thereof is about 81Ω, but the characteristic impedance Z is not disturbed as much as possible in the coaxial repeater 2.

  Further, the braided wire folded over the outer cover of the first coaxial cable 30-2 is located in the cylindrical portion of the second caulking metal fitting 81, and the cylindrical portion is crimped so that the braided wire is electrically connected to the second caulking metal fitting 81. And the first coaxial cable 30-2 is fixed. Since the metal tape provided on the insulator of the first coaxial cable 30-2 has a large diameter, the metal tape is inserted into the large-diameter portion 55a of the second cylindrical portion 52b of the metal case 50, and the first protrusion 55e is made of metal. The metal case 50 is securely grounded by biting into the tape. Further, when the first coaxial cable 30-2 is inserted from the second cylindrical portion 52b, the core wire is guided by the tapered portion 61f of the insulator 60 and inserted from the insertion hole 61e. 2 It is press-fitted into the clamping piece 73b and clamped. As a result, the core wire is electrically connected to the central conductor 70. Also in this case, the characteristic impedance Z of the first coaxial cable 30-2 is not disturbed, and the characteristic impedance Z is not disturbed as much as possible in the coaxial repeater 2.

In the coaxial repeater 2 described above, the first coaxial cable 30-1 or the second coaxial cable 31-1 and the first coaxial cable 30-2 or the second coaxial cable 31-2 are relayed in any combination. In addition, the metal tape and the braided wire constituting the shield conductor of the coaxial cable are grounded to the metal case 50. Thereby, the coaxial repeater 2 concerning this invention can implement | achieve a high shield even if it relays the coaxial cable with the same diameter or different.
As the frequency characteristic of the leakage electric field strength of the coaxial repeater 2 of the second embodiment according to the present invention, substantially the same characteristic as that of the L-type coaxial plug 1 of the first embodiment is obtained. In other words, in the coaxial repeater 2 of the second embodiment of the present invention, if the metal tape of the coaxial cable relayed in the coaxial repeater 2 is grounded to the metal case 50, good leakage electric field strength characteristics can be obtained in a wide band. In addition, the frequency characteristic extends to 3.2 GHz. Also in the coaxial repeater 2 of the second embodiment, the metal tape of the coaxial cable can be grounded to the metal case 50 by inserting and processing the end of the coaxial cable to be relayed as shown in FIG. The coaxial repeater 2 according to the present invention can realize a high shield in a wide band even when a plurality of types of coaxial cables having the same diameter or different diameters are connected.

The coaxial cable connection structure of the present invention described above is not limited to the L-type coaxial plug of the first embodiment and the coaxial repeater of the second embodiment, but the coaxial plug, the coaxial connector, and the coaxial cable into which the coaxial cable is introduced. The present invention can be applied to a coaxial cable connection structure in an electronic device to which is connected.
The coaxial cable connection structure of the present invention described above can connect either the first coaxial cable or the second coaxial cable having different outer diameters, but is not limited to this, and there are three or more types of outer diameters. Different coaxial cables may be connected. In this case, the inner diameter in the insertion portion in the L-shaped coaxial plug of the first embodiment and the inner diameters of the first cylindrical portion and the second cylindrical portion in the coaxial repeater of the second embodiment are set to the number of types of coaxial cables to be connected. The number of multistages may be set according to the number, and the inner diameter of each of the multistages may be approximately equal to the outer diameter of the metal tape of each coaxial cable.
Further, in the L-type coaxial plug of the first embodiment and the coaxial repeater of the second embodiment to which the coaxial cable connection structure of the present invention is applied, a core wire connecting means that is provided with a metal case and is held by an insulator. In the metal case, and in the introduction part for introducing the coaxial cable into the metal case, a plurality of steps corresponding respectively to the outer diameters of the metal tapes constituting the shield conductors of the plurality of coaxial cables having different outer diameters to be introduced. A plurality of inner diameters are provided, and the metal tape of the coaxial cable is inserted into the inner diameter step corresponding to the outer diameter of the metal tape in the introduction portion, and the shield conductor is grounded to the metal case. As a result, in the L-type coaxial plug of the first embodiment and the coaxial repeater of the second embodiment to which the coaxial cable connection structure of the present invention is applied, even if a plurality of types of coaxial cables having different diameters are connected, it is highly broadband. A shield can be realized.
In the L-shaped coaxial plug of the first embodiment and the coaxial repeater of the second embodiment to which the coaxial cable connection structure of the present invention is applied, the metal case is made of a metal material. The metal case may be formed by molding and applying metal plating to the entire outer surface or applying a conductive paint.

1 L-type coaxial plug, 2 coaxial repeater, 10 case, 11 case body, 11a case side wall, 11b engaging piece, 11c hinge, 11c insertion hole, 11d kerf, 11e pushing piece, 11f guide ridge, 11g guide convex part, 11h cable insertion part, 12 case lid part, 12a lid side wall part, 12b engagement groove, 12c boss, 12d cable insertion part, 13 metal case lid part, 13a fitting hole, 13b first side part, 13c 2nd side surface part, 13d 3rd side surface part, 13e 4th side surface part, 13f Top plate, 14 caulking metal fitting, 14a fixed part, 14b caulking part, 14c fitting hole, 14c bent piece, 14d arcuate part, 14e 1st serrated protrusion, 14f fitting hole, 14g 2nd serrated protrusion, 15 spring part, 15a body part, 15b slot, 15c bulging part, 1 5d gap, 16 insulator, 16a body part, 16b holding part, 16c hinge part, 16d rectangular window, 16e first side wall, 16f second side wall, 16g third side wall, 16h fourth side wall, 16i guide part, 16j Screw insertion Groove, 16k screw hole, 16m insertion hole, 16n slope, 16p U-shaped projection, 17 center contact, 17a center pin, 17b body part, 17c L-shaped part, 18 screw, 20 metal case, 21 square tube part, 21a Ridge, 22 cylindrical portion, 22a through hole, 23 insertion portion, 23a insertion hole, 23b flat plate portion, 23c boss, 23c stepped portion, 23e large diameter portion, 23f small diameter portion, 23g first protrusion, 23h second protrusion, 30 , 30-1, 30-2 first coaxial cable, 30a jacket, 30b braided wire, 30c metal tape, 30d insulator, 30 Core wire, 31, 31-1, 31-2 Second coaxial cable, 31a jacket, 31a core wire, 31b braided wire, 31c metal tape, 31d insulator, 31e core wire, 40 case, 41 case main body, 41a main body side wall 41b Recessed portion, 41c Engagement step portion, 41d First insertion portion, 41e Boss, 41e Second insertion portion, 41f Guide protrusion, 41g Standing piece, 41h Boss, 42 Case lid portion, 42a Lid side wall portion, 42b Joint part, 42c engagement piece, 42d first insertion part, 42e second insertion part, 43 hinge part, 50 metal case, 51 long cylinder part, 51a opening, 51b storage space, 51c step part, 51d insertion part, 52a first part 1 cylindrical portion, 52b second cylindrical portion, 52c first through hole, 52d second through hole, 53a first flat plate portion, 53b second flat plate portion, 53c first engagement hole 53d second engagement hole, 54a first boss, 54b second boss, 55a large diameter portion, 55b small diameter portion, 55c stepped portion, 55d second projection, 55e first projection, 56 metal case lid, 56a body portion , 60 Insulator, 61 Insulating body part, 61a First insertion part, 61b Second insertion part, 61c Engagement step part, 61d Window part, 61e Insertion hole, 61f Taper part, 61g Projection piece, 61h Insertion cylinder part, 62 Insulation lid, 62a holding piece, 62b guide piece, 62c position regulating piece, 62c engagement piece, 62d guide piece, 62d engagement piece, 63 hinge part, 70 center conductor, 71 center part, 71a folded part, 71b gap, 71c Bent part, 72a 1st intermediate part, 72b 2nd intermediate part, 73a 1st clamping piece, 73b 2nd clamping piece, 80 caulking metal fitting, 81 caulking metal fitting, 100 Shaft plug, 110 cover, 111 cylindrical conductive member, 112 contact pin, 113 insulator, 114 spring member, 115 lid, 116 insulator, 118 insulator, 119 cylindrical conductive member, 120 mounting member, 121 core wire connection pin, 122 Connection piece, 123 ring member, 124 cable fixing bracket, 150 coaxial cable, 151 center conductor, 152 outer conductor, 153 tip

Claims (8)

Core wire and a shield conductor, comprising at least a coaxial insulator coaxial structure is formed by the intervening has been the core wire between the core wire and the shield conductor and the shield conductor, a plurality of types having different outer diameters coaxially A coaxial cable connection structure capable of introducing any of the cables,
An insulator capable of holding a conductive core wire connecting means for connecting the core wire of the coaxial cable;
An insertion portion into which the coaxial cable is introduced, a plurality of diameter portions corresponding to the diameter of the shield conductor of the introduced coaxial cable being formed in the insertion portion, and a storage portion capable of storing the insulator A metal case provided at least ,
When the coaxial cable is introduced into the insertion portion of the metal case, the shielding conductor of the coaxial cable is inserted into the diameter corresponding to the diameter of the shield conductor of the insertion portion, the shield conductor wherein Rutotomoni is grounded to the metal case, the core wire shield conductor exposed by removing the coaxial cable is inserted into the insulator accommodated in the metal case, the core wire connection held by the insulator A coaxial cable connection structure characterized by being connected to a means. The metal case is formed with a cylindrical portion to be attached to a coaxial connector, and the core wire of the coaxial cable introduced into the insertion portion of the metal case by the core wire connecting means is disposed in the cylindrical portion. The coaxial cable connection structure according to claim 1, wherein the coaxial cable connection structure is electrically connected to a central contact that forms a coaxial structure with the cylindrical portion. The center contact is inserted and held in an insertion hole formed in the insulator, thereby forming a coaxial structure with the cylindrical portion, and the insertion portion of the metal case is formed by the core wire connecting means. The coaxial cable connection structure according to claim 2, wherein the core wire of the coaxial cable introduced into is electrically connected to one end of the center contact.   When the core wire of the coaxial cable is inserted into the insulator housed in the metal case, it is guided by a slope formed on the insulator so as to be electrically connected to one end of the center contact. The coaxial cable connection structure according to claim 3. It is further equipped with an insulating case,
The insulating case includes a case main body in which the metal case is housed, said housing section metal casing lid casing lid attached to the opening occluded by a shielding said metal case of said metal case The opening of the said accommodating part is obstruct | occluded by the said metal case cover part, when this case cover part is covered by this case main-body part. Coaxial cable connection structure. A first cylindrical portion for introducing a coaxial cable from one side that is the insertion portion is formed in the metal case, and a second cylindrical portion for introducing the coaxial cable is formed from the other side that is the insertion portion. And one of the plurality of types of coaxial cables is introduced into the first cylindrical portion, and one of the plurality of types of coaxial cables is introduced into the second cylindrical portion. The core wire of the coaxial cable introduced into the first cylindrical portion of the case is electrically connected to the core wire of the coaxial cable introduced into the second cylindrical portion of the metal case. The coaxial cable connection structure according to 1. The core wire connecting means is formed with a first holding piece for holding the core wire of the coaxial cable introduced into the first cylindrical portion of the metal case at one end, and the second cylindrical portion of the metal case. A second holding piece for holding the core wire of the coaxial cable introduced into the other end is formed at the other end, and the core wire of the coaxial cable introduced into the first cylindrical portion of the metal case is formed by the core wire connecting means. The coaxial cable connection structure according to claim 6, wherein the coaxial cable connection structure is electrically connected to the core wire of the coaxial cable introduced into the second cylindrical portion of the metal case. It is further equipped with an insulating case,
The insulating case is coaxial of claim 6 or 7, characterized in that said metal casing is composed of a case body which is housed, the case lid portion and which is fitted to the metal casing Cable connection structure.

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