JPH0332312A - Coaxial cable, and terminating method and device therefor - Google Patents

Abstract

PURPOSE:To prevent loosening of coaxial cable, when the coaxial cable is carried or connector joint work is carried out, by bonding an outer conductor comprising a plurality of shield wires through conductive bond. CONSTITUTION:Outer coating of a coaxial cable 11 is cut off at a point set off by a predetermined length l1 from the end of the coaxial cable and the exposed outer conductor 41 is cut off at a position set off by a predetermined length l2 from the end of the coaxial cable. The exposed outer conductor 41 is applied uniformly with conductive bond such as solder or conductive adhesive, and a plurality of shield wires constituting the outer conductor 41 are bonded one another. Inner coating 31 is exposed from the cut end of the outer conductor 41 and cut off by a length l3 from the end of the coaxial cable and an inner conductor 21 is exposed.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to the terminal processing of coaxial cables, and particularly to coaxial cables that have been terminally processed for connecting electronic devices with connectors, and the terminal processing of the coaxial cables. The present invention relates to a method and a terminal processing device.

[Conventional technology]

The conventional coaxial cable termination method is
For example, it is described in Japanese Unexamined Patent Publication No. +1i57-168412, which will be explained with reference to FIG. Conventionally, as shown in FIG. 14(a), a desired range of the outer sheath 5 from the end of the two-coaxial cable 1 is removed using a cutter or the like to expose the outer conductor 4 made of a shielded wire, and then As shown in FIG. 14(b), the external conductor 4 is separated from the internal wave [3], and as shown in FIG. 14(c), the separated external conductor 4 is twisted with fingers to integrate, and then from the end A desired area of the inner sheath 3 is removed to expose the inner conductor 2 as shown in FIG. 14(d), and then the terminal 7 is connected to the inner conductor 2 of the coaxial cable 1 as shown in FIG. 14(e). After crimping and further inserting the terminal 7 into the connector 8 as shown in FIG. 14(f), solder is applied to the twisted outer conductor 4, and one terminal is connected to the grounding pad 10 made of a thin copper plate using a soldering iron or the like. 14th one by one
The coaxial cable was completed by soldering and terminal treatment as shown in Figure (g).

[Problem to be solved by the invention]

In the above conventional technology, after cutting and removing the outer sheath in a desired range, unraveling and twisting the outer conductor made of braided shield wire, and then cutting and removing the inner sheath leaving only the desired range, and then forming the terminal material. ing. After that, insert the required number of terminals into the connector, and connect the twisted outer conductor to the ground bar made of thin copper plate.
Soldering is done one book at a time, but the work is complicated and has been an obstacle to automating terminal processing.

Therefore, the first object of the present invention is to provide a coaxial cable terminal structure suitable for automation, and the second object is to provide a terminal processing method for automating the terminal processing. A third objective is to provide a terminal processing device that can automatically perform terminal processing.

[Means to solve the problem]

In order to achieve the above-mentioned first object, the present invention improves the terminal structure of a coaxial cable by removing a predetermined area of the outer coating from the end of the coaxial cable and applying a conductive and heat-melting adhesive to the exposed part. A coaxial cable with a terminal shape having an outer conductor fixed between shield wires, an inner sheathing having a predetermined range exposed from the fixed outer conductor, and an inner conductor having a predetermined range exposed from the inner sheath. The present invention is characterized in that it is constructed by providing a connector provided via a terminal member fixed to the internal conductor having the terminal shape, and a member for ground connection to the external conductor.

In order to achieve the second object, the present invention carries out the terminal treatment of a coaxial cable by half-stripping the outer sheathing in a predetermined range from the end of the coaxial cable, and then applying conductive fixation almost uniformly to the exposed outer conductor. After that, the fixed outer conductor and inner coating are cut and removed, leaving only a predetermined area of each, and a connector is connected to the exposed inner conductor via a terminal member, and the fixed wire is fixed. The present invention is characterized in that it is performed by a step of connecting the external conductor that has been connected to the ground connection member.

Furthermore, in order to achieve a third object, the present invention provides a coaxial cable terminal processing device including means for gripping a coaxial cable, means for half-stripping a predetermined range of the outer coating from the end of the coaxial cable, and means for soldering the outer conductor exposed by the half-stripping to a substantially uniform thickness; means for removing the half-stripped outer sheath; and a portion of the soldered outer conductor for a predetermined length from the end. means for cutting and removing the inner conductor, means for removing the inner covering leaving a predetermined length of the inner conductor from the end, means for connecting a terminal member to the exposed inner conductor, and said terminal connected to the inner conductor. means for inserting the member into the connector;
The present invention is characterized in that it includes means for connecting a ground member to the soldered external conductor, and means for transporting a coaxial cable between these means.

[Effect]

In the coaxial cable according to claim 1 of the present invention, the outer covering, the outer conductor coated with a conductive adhesive, the inner covering, and the inner conductor are arranged in order from a portion at a predetermined distance from the end of the coaxial cable. Each of them is formed to have a predetermined length and be exposed toward the end. Therefore, unlike in the prior art, there is no need for a shape that would be impossible without manual work such as unraveling and soldering the external conductor, resulting in a terminal shape that is suitable for automation.

Further, in the coaxial cable according to claim 2, a connector is provided to the inner conductor of the coaxial cable having the terminal shape according to claim 1 via a terminal member, and a member is provided for ground connection to the outer periphery of the fixed outer conductor. However, the connection between the internal conductor and the terminal member and the pushing of the terminal member into the connector will not impede automation if the terminal member and connector are selected appropriately, and it is also possible to connect the internal conductor and the terminal member and push the terminal member into the connector. Since the structure is such that the ground connection member is simply provided on the outer periphery of the fixed external conductor, the ground member can also be bonded by thermocompression, which improves work efficiency compared to conventional methods, and makes it possible to manufacture coaxial cables that can be connected to connectors through automation. becomes possible.

In the coaxial cable terminal processing method according to claim 4 of the present invention, a predetermined range of the outer sheathing from the end is half-stripped to expose only the predetermined range of the outer conductor while the outer conductor is covered with the outer sheath. . Then, the outer conductor is removed by cutting off the exposed outer covering at a portion where the thickness is almost the same. Therefore, when applying the conductive adhesive, the outer conductor does not come loose, so workability is good, and when cutting the outer conductor, the shield wires are fixed to each other, so no uncut portions are left. In addition to this, the inner coating is then cut, the terminal member is connected to the inner conductor, the terminal member is connected to the connector, and the ground member is connected to the outer conductor. Since it is connected to the outer periphery of the conductor, methods such as thermocompression bonding can be used, and these processes can be automated.

In claim 4, the method of applying the conductive adhesive to a uniform thickness is to immerse the coaxial cable with the external conductor exposed in molten solder almost vertically, so that it is easy to make the thickness uniform. At the same time, the work space becomes narrower.

In the terminal processing apparatus according to the seventh aspect, each step of the terminal processing method according to the fourth aspect is automatically realized by each means.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 1 shows the end shape of a coaxial cable according to an embodiment of the present invention. As shown in FIG. 1, the same 11+ cable 11 includes an inner conductor 21 made of a plurality of conducting wires or a single wire, an inner sheath 31 made of an insulator that covers the outer periphery of the inner conductor 2, and a plurality of wires wrapped around the inner sheath 31. The outer conductor 41 is made of a shielded wire, and the outer sheath 51 is made of an insulating material that covers the outer periphery of the outer conductor 4.

The terminal shape of the coaxial cable 11 of the present invention is as shown in FIG.
The cable is cut at a predetermined length (Q2) from the end of the coaxial cable. That is, the outer conductor 41 is (Qt
Although the length of Q2) is exposed, the length of this exposed portion is required to provide a member for grounding the external conductor 41, which will be described later.

Then, this exposed outer conductor 41 is coated with a conductive adhesive, such as a solder that has both heat-melting properties and conductivity, or a conductive adhesive with a substantially uniform thickness.
A plurality of shield wires constituting the outer conductor 41 are fixedly connected to each other. This conductive adhesive is used to prevent the outer conductor 41 from coming apart during transportation after the end shape of the coaxial cable is completed or when the connector is attached, and for pre-treatment to prepare the outer conductor 41. It is applied as.

The inner coating 31 is exposed from the cut end of the outer conductor 41. The inner sheath 31 is cut off at a predetermined length Qa from the end of the coaxial cable, that is, at a length necessary to expose the desired length of the inner conductor 21. Therefore, the inner covering 31 is (nzQs) - the inner conductor 2 is Qa
This means that the length is exposed.

The coaxial cable of the above embodiment enables automation of the terminal processing of the coaxial cable itself. It is also effective as a pretreatment for automatically providing a connector to the coaxial cable and automatically providing a ground connection member to the outer conductor 4. In carrying out this embodiment, if solder is used as the conductive adhesive, the inner coating 31 and the outer coating 51 need to be made of a material with high heat resistance, such as Teflon. When an adhesive is used, the inner coating 31 and the outer coating 5 may have low heat resistance.

Next, an embodiment according to claim 2 in which the coaxial cable 118 of the above embodiment is provided with a connector and a ground connection member will be described with reference to FIG. In Figure 2, coaxial cable 1
1 is a part whose details are omitted from illustration, and the internal conductor 21
A terminal (described later but omitted in FIG. 2) is provided, and the terminal is inserted into the connector 8. A ground par 9 is connected to the external conductor 41.

The connection between the external conductor 41 and the ground par 9 can be made by simply fixing the contacting parts on the same plane with solder or conductive adhesive. In particular, when the external conductor 41 is soldered, It is also possible to bond by thermocompression using a heater chip or the like, and as shown in the figure, many external conductors 41 can be automatically connected to the ground par 9 at the same time.
It is also possible to connect the twisted external conductor to the ground par 9 by soldering each aqua regia as in the past, which improves work efficiency.

Next, an embodiment of the coaxial cable terminal processing method according to the present invention will be described with reference to FIGS. 3 to 5.

First, the coaxial cable 11 is swung horizontally from diagonally upward as shown in FIG. 4, and then the cutter blade 211a,
211b as shown in FIGS. 5(a) and 5(b), cut the cutter blades 211a and 21.1b (or coaxial cables) to the required length in the direction of the arrow by making a cut in the outer coating 51. half-strip the outer covering 52. As a result, as shown in FIG. 3(a), a half-stripped outer covering shape can be obtained, the outer conductor 4] can be exposed only in the required range, and the outer conductor 41 can be separated from the end. can be prevented.

Next, a conductive adhesive having a substantially uniform thickness is applied to the exposed outer conductor 41 of the coaxial cable that has undergone the half-strip process. This is preferably done by dipping the exposed outer conductor 41 of the coaxial cable 1 into the molten solder 6, as shown in FIG. 3(b). The reason for this is that when the coaxial cable is pulled out from within the molten solder 6, the thickness of the solder becomes uniform at each part in the circumferential direction of the outer conductor 41, and this work space can be narrowed. .

After the soldering of the coaxial cable 11 has been completed, the soldered portions of the coaxial cable 11 are fluxed, and then the flux is cleaned. The reason for performing flux cleaning is to prevent corrosion defects due to residual flux. For the coaxial cable 11 that has been flux cleaned, remove the external N52 as shown in Fig. 3(c), and then attach four external conductors to a predetermined length from the tip as shown in Fig. 3(d). Then, as shown in Figure 3(e), the inner coating is further cut and removed by a predetermined length from the tip. The outer conductor 41 and the inner sheath 31 can be cut and removed in the same manner as the half-striping of the outer sheath described above.

After completing the above steps, the terminal 7 is connected to the exposed internal conductor 21 of the coaxial cable 11. This terminal 7 is the inner conductor 3
It is convenient to automate this process by using a crimp terminal, for example, a crimp terminal. In addition,
It is also necessary to select this terminal 7 on the condition that it is of a type that can be inserted into a connector.

Next, the terminal 7 connected to the coaxial cable 1 is inserted into the connector 8. A number of coaxial cables 11 are inserted into the connector 8 according to the purpose of use, for example, as shown in Fig. 3(g).
It becomes as shown in .

Next, as shown in FIG. 3(f), the exposed outer conductor 41 of the coaxial cable 11 and the bar 9 are connected. The connection between the external conductor 41 and the ground par 9 is made using the external conductor 41.
This is done by thermocompression bonding the ground par 9 and the ground par 9 using the heater chip 20. According to this connection method, multiple coaxial cables can be connected to the ground bar at one time, and automation is possible. In addition, as the gland par 9, a conductive member plated with solder is used in order to carry out thermocompression bonding as described in 1. This plastic plate 9a and this plastic plate 9a
Copper plating 9b applied to the top and solder plating 9c applied on top of the copper plating 9c can be used to reduce the weight of the device in cases where a large number of coaxial cables are used, such as ultrasonic diagnostic equipment. In addition to being effective in reducing the size of the ground bar, it is also easy to form the ground bar from a long piece and cut it to a required length for use. It goes without saying that the plastic plate 9a, which is the base of the gland par 9, must have characteristics that can withstand the heating temperature during thermocompression bonding.

Next, a terminal processing device that automatically processes the terminals of the coaxial cable will be described. This embodiment will be described with reference to FIGS. 6 to 12 for a case where the target coaxial cable is a multicore coaxial cable in which a large number of coaxial cables having the configuration shown in FIG. 1 are bundled together.

As shown in FIG.
-4, O] is held by a cable holder 511 fixed to a stand 391 supported by an inversion frame 381 that can be inverted around the axis 521 of a base 321 attached to an X-axis table 301 mounted on . A large number of coaxial cables 11 of the multicore coaxial cable 15 are separated into one main body and held by a wire holder 601, as shown in FIG.

On the coaxial cable] is a wire stripper 80 having coated cutter blades 211a and 211b as shown in FIG.
1, before processing, it is set to face diagonally upward as shown in FIG. This position is determined by pulling the wire holder 601 with a spring 61 and applying the wire holder 601 to the collar 631.

Half-stripping and removing the outer sheath of the coaxial cable 11 by the wire stripper 801-, cutting the outer conductor,
When performing terminal processing such as cutting the inner coating, the wire holder 601 is attached to the lifting rod 46 of the actuator 471.
As shown in FIG.

As a result, the coaxial cable 11, which was in the diagonally upward direction at the time of CERA1~, becomes in the water N11 state.

The wire stripper 801 has a cutter 211a as shown in FIGS. 4 and 5, although the details of the inside are omitted.
, 211b and a mechanism for moving them in the directions of arrows B and C in the figure. cutter blade 21], a, 21
．． When the half-stripping of the outer sheath 41 of the coaxial cable 11 at the end of the multiple coaxial cables 11 set in step 1b is completed, the X-axis table 301 is set so that the coaxial cables 11 are separated by the pitch Q (see Fig. 9). The outer coating 41 is sequentially half-stripped. When the half stripping of the outer coating 41 is completed as shown in FIG. 3(a), the parts 1 to 401 are moved by a moving mechanism using a roller chain or the like and a guide mechanism 41 such as rails and rollers to spread the flux as shown in FIG. 10. Attached is device 90. For soldering, use device 92. They are sequentially transported to a flux cleaning device 94 and soldered.

Flux cleaning is performed. In this case, coaxial cable 1
1 is held vertically.

For this reason, as shown in FIG. 8, normally FIG.

Reversing frame 3 whose position is regulated as shown in Fig. 7
81 is inverted around axis 521. This reversing operation is performed by the pusher receiver 661 attached to the reversing frame 381.
The lifting rod 621 of the actuator 681゜691,
671.

That is, when the reversing frame 381 is configured as shown in FIG.
Push up 61. Then, the reversing frame 381 becomes the axis 52
1, and continues to rotate counterclockwise by the action of the spring 701 and the movement of the center of gravity of the reversing frame 381, and the stopper 481 attached to the reversing frame z, 381 stops the screw 33.
1, it stops and is positioned.

While the multicore coaxial cable 15 is held vertically, the fluxing device 90 moves up in the D direction as shown in FIG. 8, and solders the half-stripped outer conductor 41 as shown in FIG. 3(b). Apply flux only to the required length. The nozzle 96 of the flux application device 90 is designed to allow flux to overflow in order to maintain a constant coating level, and also to allow flux to circulate (not shown). When the flux application is completed, the flux application device 90 is lowered by an actuator 9 as shown in FIG. 10(a).

Similarly, the coaxial cable 15 is held vertically and is conveyed by the conveyor 42↓ to the next soldering process device 92 and flux cleaning device 94, as shown in FIG. 10(b).
Soldering and flux cleaning are performed as shown in C). For soldering and flux cleaning, the coaxial cable 5 is placed in the molten solder, and for flux cleaning, the coaxial cable 15 is placed in the cleaning liquid, as shown in Figure 8. , respectively, by immersion for a predetermined length.

The reason why the flux cleaning device is installed in the water treatment equipment is not only to prevent the corrosion failure described above, but also to prevent the flux adhering to the coaxial cable 11 during stripping from transferring to the cutter blades 211a and 211b, causing the coating to deteriorate. The waste is the cutter blade 211a.

This is to prevent terminal processing failure due to adhesion to 211b.

In this way, fluxing and soldering.

After flux cleaning, actuator 681.
The lifting rods 62], 671 of 691 are interlocked to return the reversing frame 381 to the position shown in FIG.

After applying a uniform thickness of pick-up solder and hardening the outer conductor 41 made of a shielded wire with solder, the outer covering 52 is removed as shown in FIG. 3(c), and then the outer covering 52 is removed as shown in FIG. 3(d). Cut and remove the external conductor 41 from a predetermined portion as shown in FIG.
), the western sheathing 31 is removed from a predetermined portion, but such a wire swipe i~lip is
The pallet 401 is connected to the ryasu 1 to 80 equipped with a cutter blade and its moving mechanism similar to that shown in FIG.
2,803,804 are arranged in parallel, and the wire stripper 802
, the outer conductor is removed by the ryasu 1 - ripper 803 , and the inner coating is cut and removed by the ryasu 1 - ripper 804 .

A crimper 805 is arranged next to the wire stripper 804. The crimper 805 is used to attach the terminals as shown in FIG.
an anvil 10 supporting a crimp terminal 7 having a shaped crimp portion;
21 and insulation crimper 1001. Crimper holder 110 that moves the wire crimper 1011 up and down
1. To connect the crimp terminal 7 and the coaxial cable 11, set the coaxial cable 11 on the crimp terminal 7 from diagonally above, move the crimper holder 1101 downward, and connect the crimp terminal 7 and the internal conductor 21 with the wire crimper 1011. And insulation crimper 1.0 O
1, the crimp terminal 7 and the inner covering 31 are caulked and crimped. The purpose of crimping the crimp terminal 7 and the inner sheath 31 is to prevent the terminal portion from being bent or damaged.

The terminal-attached multicore coaxial cable 15 is pushed into the connector 9 by a terminal insertion device 806 shown in FIG. 12, as shown in FIG. 10(g). Although the terminal insertion device 806 is not shown, the coaxial cable 11
The connector 8 may be moved and inserted while the crimp portion of the crimp terminal 7 is held or pressed with a mold. The terminals may be inserted into the coaxial cables 11 one by one, or may be inserted into a plurality of coaxial cables at the same time.

When a predetermined number of coaxial cables are pushed into the connector 8, the pallet 401 is moved to a thermocompression bonding device 807. As shown in FIG. 3(h), the thermocompression bonding device 807 has heater chips 201 and 202, and is equipped with a ground bar insertion mechanism (not shown). First, the copper plating is applied to the plastic plate 9a by the ground bar insertion mechanism. 9b and solder plating 9c was applied on top of that.
Push the ground par 9 shown in Fig. 3 into the position where it contacts the external conductor 4]. Then, the heater chip 201 is moved in the direction of arrow E to heat and suppress the external conductor 41, thereby applying thermal pressure to the external conductor 41 and the ground bar 9.

The device configuration and its functions have been described above. According to this terminal processing device, it is possible to perform automatic processing from the terminal formation process of the coaxial cable itself to the connector connection, and the manual work required in the past can be omitted. Therefore, work efficiency can be greatly improved, and product quality and reliability can be significantly improved.

〔effect〕

As described above, the present invention provides the following effects. That is, according to claim 1, since the outer conductor consisting of a plurality of shielded wires is hardened with a conductive adhesive, it can be prevented from coming apart during transportation or connector connection work. Also, the terminal shape is simply an outer covering and an outer conductor.

Since it is formed by simply cutting and removing the inner coating in sequence, it can be automated.

The adhesive that fixes the external conductor has conductivity and heat melting properties. Therefore, the connection between the external conductor and the ground bar can be made by simply bringing them into contact and heating them, eliminating the need for manual soldering as in the past. It is possible to connect automatically instead of automatically. Furthermore, by appropriately selecting a connector and a terminal, a coaxial cable that can be connected to a connector can be automatically manufactured.

According to the third aspect, when applying the conductive adhesive to the outer conductor, the outer conductor is covered with the outer coating at the end portion thereof, so that the outer conductor does not come apart.

Furthermore, since the outer conductor can be cut at the portion hardened with the conductive adhesive, there will be no uncut portion.

Furthermore, as in claim 2, the connector connection and the connection between the external conductor and the ground bar can also be automated.

According to the fourth aspect, since the coaxial cable is vertically immersed in the molten solder to solder the outer conductor, it is easy to solder to a uniform thickness, and the work space can be reduced.

According to claim 5, after soldering the outer conductor, flux cleaning is performed to remove the flux, so that no flux remains between the outer conductor and the outer covering and the outer conductor, so that corrosion defects can be prevented. .

According to claim 6, once the coaxial cable is set in the apparatus, the coaxial cable can be automatically transferred between each processing step by the conveying means, and a coaxial cable that can be automatically connected to a connector can be manufactured.

Therefore, since the manual process required in the past is eliminated, work efficiency is significantly improved, and quality is made uniform and reliability is also improved.

[Brief explanation of drawings]

Fig. 1 is a perspective view showing the terminal shape of the coaxial cable of the present invention, Fig. 2 is a perspective view showing the terminal shape of the coaxial cable with the connector of the present invention, and Fig. 3 is the present invention shown in Fig. 2. Figures 4 and 5 are diagrams showing a method for half-splitting the outer sheath of a coaxial cable according to the present invention, and Figure 6 is a diagram showing a method for half-splitting the outer sheath of a coaxial cable according to the present invention in order of steps.
11b A side view showing a coaxial cable holding part in a cable end processing device, FIG. 7 is a side view showing a state in which the device shown in FIG. 6 half-rips the outer coating, and FIG. 8 is a side view showing the device shown in FIG. 9 is a plan view of the apparatus shown in FIG. 6, and FIG. 10 is a flux application device and a soldering device. Fig. 11 is a perspective view showing the terminal attachment part of the coaxial cable end processing device, Fig. 12 is a diagram showing the arrangement of each process unit of the coaxial cable end processing method, and Fig. 13 is a diagram showing the arrangement of the ground bar. Diagram showing the composition partially in cross section, 1st
FIG. 4 is a diagram showing a conventional coaxial cable terminal processing method in the order of steps. Soil, 1]・Coaxial cable, 2, 21...Inner conductor, 3
．． 3]--Inner coating, 4,41 Outer conductor, 5゜51
- External coating, 7 Crimp terminal, 8 - Connector, 9... Plan Mil Bar, 90 Equipment for fluxing, 92... Equipment for soldering, 94 Flux cleaning equipment, 201. ．．
202... Heater chip, 211... To cutter play 1, 301... X-axis table, 321 Base, 381
・-Reversal frame, 4.01 ・Pallet Z/ 511 ・・Cable holder, 601 ・Wire holder, 801~804 ・Riyasu 1~Ritzper, 805...
- Crimper, 806...terminal pushing device, 807 thermocompression bonding device. JP-A-3 32312 (10) 4-+ b

Claims (1)

[Claims] 1. An inner conductor made of a single wire or a plurality of conductive wires, an inner sheath made of an insulator that covers the outer periphery of this inner conductor, an outer conductor made of a plurality of shielded wires wound around the outer periphery of this inner sheath, and A predetermined area of the outer sheath is removed from the end of the coaxial cable, and a conductive adhesive of approximately uniform thickness is applied to the exposed portion to shield the outer conductor. A coaxial cable having a terminal shape consisting of an outer conductor fixed between the wires, an inner sheathing with a predetermined range exposed from the fixed outer conductor, and an inner conductor with a predetermined range exposed from the inner sheath. . 2. An inner conductor made of a single wire or multiple conductors, an inner sheath made of an insulator that covers the outer periphery of this inner conductor, an outer conductor made of a plurality of shielded wires wound around the outer periphery of this inner sheath, and an outer periphery of this outer conductor. A predetermined area of the outer sheath is removed from the end of a coaxial cable, which consists of an outer sheath made of an insulating material, and a conductive and heat-fusible adhesive is applied to the exposed portion to a substantially uniform thickness. an outer conductor fixed between the shielded wires, an inner sheathing having a predetermined range exposed from the fixed outer conductor, an inner conductor having a predetermined range exposed from the inner sheathing, and an inner conductor fixed to the inner conductor. A coaxial cable connectable to a connector, comprising: a connector provided through a terminal member; and a member for ground connection to the outer periphery of the external conductor. 3. An inner conductor consisting of a single wire or a plurality of conductive wires, an inner sheath made of an insulator that covers the outer periphery of this inner conductor, an outer conductor consisting of a plurality of shielded wires wound around the outer periphery of this inner sheath, and an outer periphery of this outer conductor. A predetermined area of the outer sheath is half-stripped from the end of the coaxial cable, which consists of an outer sheath made of an insulating material, and then a conductive adhesive is applied to the exposed outer conductor with an approximately uniform thickness to connect the shield wires. A coaxial cable in which the outer conductor and inner coating are cut and removed, leaving only a predetermined range of each, and a member is provided for connecting the exposed inner conductor with a connector via a terminal and grounding the outer periphery of the outer conductor. terminal processing method. 4. The coaxial cable terminal processing method according to claim 3, wherein the conductive adhesive is molten solder, and the half-stripped outer conductor portion is dipped substantially perpendicularly into the molten solder to apply pick-up solder. 5. The coaxial cable terminal processing method according to claim 3 or 4, further comprising the step of cleaning the external conductor portion to which the pick-up solder has been applied with flux. 6. means for gripping a coaxial cable; means for half-stripping a predetermined range of the outer sheath from the end of the coaxial cable; means for substantially uniformly soldering the outer conductor exposed by the half-strip; and the half-strip. means for removing the soldered outer conductor; means for cutting and removing the soldered outer conductor; means for removing the inner sheath leaving an inner conductor; means for connecting a terminal member to the exposed inner conductor; A coaxial device comprising means for inserting the terminal member connected to the conductor into the connector, means for connecting the ground member to the soldered external conductor, and means for transporting the coaxial cable between these means. Cable terminal processing equipment.