KR101506502B1 - Block jig to support the micro-coaxial cable - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a block jig for supporting a micro coaxial cable, and more particularly, to a block jig for supporting a micro coaxial cable to support the micro coaxial cable for work such as inward and outward defoaming, cutting, The present invention relates to a block jig which can be mounted on a machine capable of cutting, cutting and soldering operations. The block jig supports the micro coaxial cable so as to perform operations such as inward, outward defoaming, cutting and soldering of the micro coaxial cable And the block jig is provided with a magnet so that the block jig can be mounted on each working facility, and the block jig is standardized for each working facility, so that the microjoint coaxial cable is subjected to internal and external piecing operation, cutting In the operation and soldering operation, the micro coaxial cable supported on the block jig is not separated The micro-coaxial cable of the present invention can minimize the defective rate of the operation of the micro-coaxial cable and is mounted on a device for performing the above-mentioned internal and external tapping work, cutting work, and soldering work by providing magnetic force to the block jig supporting the micro- You can increase productivity and efficiency of your work by keeping your position fixed.
And a block jig supporting the cross cable.

Description

{Block jig to support the micro-coaxial cable}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a block jig for supporting a micro coaxial cable, and more particularly, to a block jig for supporting a micro coaxial cable to support the micro coaxial cable for work such as inward and outward defoaming, cutting, To a block jig that can be mounted on a machine capable of cutting work and soldering work.

Generally, a coaxial cable has a structure in which an external conductor is formed on the coaxial axis of a central conductor for transmitting a signal. Many products have been developed for each size / type, and signals are transmitted to an antenna or a CATV Has been widely used for cable applications. The main development direction of conventional coaxial cables has been the continuing efforts to design structures between the center conductor and the outer conductor, to improve the dielectric properties, and to impart various functions outside the outer conductor, in order to reduce energy loss .

In recent years, with the advancement of highly information-oriented society, there has been an increasing demand for faster transmission speeds of information communication devices and semiconductor device testing and inspection devices applied to the devices, and medical devices such as portable multimedia devices and endoscopes Miniaturization of the micro coaxial cable has progressed, and studies for improving the performance of a micro coaxial cable having an outer diameter of 1 mm or less for driving them have been actively conducted.

The micro coaxial cable is a very thin coaxial cable having a thickness of 1/4 of a hair. The copper conductor is twisted and is insulated with a flame-retardant Teflon so that a large-capacity multimedia data It is used for portable multimedia devices such as mobile phones and digital cameras.

The micro-coaxial cable, like a general coaxial cable, is formed of a center conductor formed of a circular wire material made of copper or copper alloy having excellent electrical conductivity, an insulating layer formed between the central conductor and the metal shielding layer, And a jacket layer.

A typical coaxial cable is formed with a polymer insulating layer (dielectric layer) formed between an inner conductor and an outer conductor (metal shielding layer), an inner conductor and an outer conductor, and a protective cover layer formed on the outer periphery of the outer conductor, Is determined by the dielectric constant of the insulating layer. That is, the lower the dielectric constant of the insulating layer, the higher the transmission rate, and the lower the dielectric constant becomes as the degree of foaming of the insulating layer becomes higher.

Therefore, conventionally, a fluororesin having a low dielectric constant is used for the insulating layer, a supporter for adjusting the mixing ratio of the general resin, or a supporter for supporting the interval between the central conductor and the outer conductor so that the air layer with the lowest dielectric constant surrounds the central conductor To achieve a high level of transmission rate and to prevent loss. Particularly, recently, studies for lowering the dielectric constant by foaming a polymer material are mainly proceeding.

In recent years, miniaturization of portable multimedia devices, medical instruments such as endoscopes, and the like have progressed, and ultra-fine coaxial cables having a diameter of 1 mm or less have been developed for driving them. The finer coaxial cables also consist of internal conductors, insulation layers, external conductors, protective cladding layers, etc., which are almost identical to conventional coaxial cables. In this case, the 'skin effect' caused by the high-frequency transmission occurs, so that the dielectric constant of the polymer insulating layer surrounding the micro-coaxial cable is lower than that of the micro-coaxial cable. It is becoming an important factor. On the other hand, the polymer insulating layer formed so that the portion where the foamed cell and the portion without the cell of the microcrystalline coaxial cable cross each other may be locally varied in dielectric constant due to the 'skin effect', which may have a deleterious effect on the transmission characteristics . Accordingly, the 'uniformity of foaming' in the polymer insulating layer is a very important characteristic parameter. In the conventional general coaxial cable or large diameter coaxial cable, since the thickness of the insulation layer is sufficiently large at a level of 5 to 42 mm in diameter, a uniform outer diameter can be maintained even in the foaming process and a uniform foam size can be realized. There is a problem that bubbles grow abnormally or outer diameter imbalance occurs due to the structural characteristic that the total diameter is 1 mm or less. Particularly, since the thickness of the insulating layer is only about 0.05 mm, there is a problem that the unevenness of the insulation thickness leads to a local difference in the dielectric constant, thereby deteriorating the transmission characteristics.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a micro-coaxial cable having a block jig for supporting the micro coaxial cable, The present invention has been completed on the technical point that a magnet is provided so that the jig can be mounted on each work facility and the block jig is standardized according to each work facility.

According to an aspect of the present invention, there is provided a portable terminal comprising: a body having a square shape and having an upper portion opened to form a groove on an inner side and a recessed portion formed on an inner side corresponding portion of both sides of the groove, A fixing plate which is fixed to the upper surface of the protruding portions of the main body by bolts and is formed with a through hole at a central portion thereof and a through hole penetrating through the through hole of the fixing plate, And a vertical adjustment member connected to the coupling of the support and having a support groove formed under the shaft portion of the vertical adjustment member connected to the coupling.

According to the block jig for supporting the micro coaxial cable according to the present invention, the micro coaxial cable supported on the block jig is not detached from the micro jig during the internal and external tapping operation, cutting operation and soldering operation of the micro coaxial cable, It is possible to minimize the defective rate of the operation of the coaxial cable and to make the block jig supporting the micro coaxial cable to have magnetism so as not to be detached when installed in the equipment for performing the inner and outer sheathing, And the position is fixed so that the productivity and efficiency of the work can be improved.

1 is a perspective view showing a block jig to which the present invention is applied;
2 is a perspective view showing a main body of the present invention.
Fig. 3 is a perspective view showing a support in the structure of the present invention. Fig.
Fig. 4 is a perspective view and a front view showing the vertical adjustment member in the structure of the present invention
5 is a schematic view showing a connection of a block jig to which the present invention is applied.

1 to 5, the structure of the present invention will be described with reference to the drawings.

The block jig 10 supporting the micro-coaxial cable according to the present invention has a square shape and an open top to form a groove 120 on the inside and a recessed groove 120 is formed on a portion corresponding to the inside of the protruded portions on both sides of the groove 120, A support base 200 formed with a protrusion 210 which is seated in the groove 120 of the main body 100 and is fitted into the recess 110; A fixing plate 300 having a through hole 320 formed at its center and connected to the upper surface of the protruding portion of the fixing plate 300 by bolts 310 and a through hole 320 of the fixing plate 300, The upper and lower regulating member 400 is connected to the coupling hole 240 of the coupling member 240 and has a support groove 411 formed at a lower portion of the shaft 410 of the upper and lower regulating member 400, .

Referring to Figures 1, 2 and 5, the main body 100 will be described in more detail.

A groove 120 is formed on the inner side in the shape of a square and an upper part of the groove 120 is formed in the shape of a square and grooves 110 are formed at mutually opposing parts of both sides of the groove 120.

The protrusion 210 of the supporter 200 is inserted into an adjacent portion of the lead-in groove 110, which is formed adjacent to a certain portion of the protruded portion.

The magnet 130 is embedded in the bottom surface of the groove 120 of the main body 100. The magnetic force of the magnet 130 can be used to move the block jig 10 of the present invention into and out of the groove, And the block jig 10 is prevented from being detached when mounted on a facility device for soldering work.

A connection groove 140 is formed on the upper side of the protruding portions of the groove 120 so that a bolt 310 connected through the through hole 330 of the fixing plate 300 can be connected Respectively.

Referring to FIGS. 1, 3 and 5, the support 200 will be described in more detail.

The support base 200 is seated in the groove 120 of the main body 100 and the protrusion 210 of the support base 200 is fitted into the lead-in groove 110 of the main body 100.

The protrusion 210 is inserted into the insertion groove 110 of the main body 100 and is formed so as to be adjacent to a certain portion of the protrusion of the main body 100 in the protrusion of the main body 100, So that the support base 200 is not separated from the groove 120 when the support base 200 is seated in the groove 120.

A coupling hole 240 is formed at an upper center of the supporter 200. The coupling hole 240 penetrates through the through hole 320 of the fixing plate 300 and is inserted into the up and down adjusting member 400 Respectively.

A coupling groove 230 is formed on one side of the coupling hole 240 and the axial support 200. The coupling groove 230 is connected to the vertical adjustment member 400 connected to the coupling hole 240, The fixing member 500 is connected to the support groove 411 formed in the shaft 410 of the upper and lower regulating member 400 to strengthen the binding force of the up and down regulating member 400.

A support member 220 is formed at a lower portion of the support table 200. This supports the micro coaxial cable positioned between the support table 200 and the bottom surface of the groove 120 of the main body 100, And the support member 220 includes a support member 200 made of a material to be buffered to prevent damage to the micro-coaxial cable.

Referring to FIGS. 1 and 5, the fixing plate 300 will be described in more detail.

The fixing plate 300 is connected to the upper portion of the protruded portion of the main body 100 so as to prevent the support 200 mounted on the groove 120 of the main body 100 from being detached, A through hole 330 is formed in the connection groove 140 formed on the protruded portion so that the bolt 310 can be connected to the connection groove 140 ).

A through hole 320 is formed at the center of the fixing plate 300 so that the upper and lower adjusting member 400 connected to the supporting table 200 can pass therethrough.

The support plate 200 mounted on the groove 120 of the main body 100 is not separated from the open upper side of the main body 100 by the structure of the fixing plate 300, 100, respectively, or may be integrally formed.

Referring to FIGS. 1, 4 and 5, the vertical adjustment member 400 will be described in more detail.

The upper and lower regulating member 400 is fixedly connected to the coupling hole 240 of the supporting base 200 through the through hole 320 of the fixing plate 300 and is connected to the shaft 410 of the upper and lower regulating member 400 And a support groove 411 is formed on the lower side.

The support grooves 411 may be formed only on one side portion, or may be formed on a whole lower side portion of the shaft 410 as shown.

When the upper and lower regulating member 400 is connected to the coupling hole 240, the fixing member 500 connected to the coupling groove 230 of the supporting base 200 is caught in the supporting groove 411 So that the up-and-down adjustment member 400 is prevented from being detached from the coupling hole 240.

The operation of the block jig for supporting the micro coaxial cable will be described with reference to FIGS. 1 to 5 as follows.

First, a micro-coaxial cable is prepared for internal and external grooving, cutting, and soldering operations, and then the micro-coaxial cable is supported on the block jig 10 before mounting the micro-coaxial cable on each of the installation devices.

The support of the block jig 10 is positioned on the bottom surface of the groove 120 of the main body 100 and then the support 200 inserted into the groove 120 is inserted into the groove 120 of the main body 100 So that the micro-coaxial cable is supported. At this time, the support member 220 of the support member 200 supports the micro-coaxial cable to prevent damage to the micro-coaxial cable.

The protrusions 210 of the supporter 200 are inserted into the recesses 110 formed in the main body 100 of the supporter 200 so that the supporter 200 is positioned on the bottom surface of the grooves 120 of the main body 100 .

A cushioning member 220 is provided under the support 200 contacting the micro-coaxial cable to protect the micro-coaxial cable.

The fixing plate 300 is seated on a protruding portion of the main body 100 when the supporting table 200 is seated in the groove 120 of the main body 100. [

The bolt 310 is fixed to the connection groove 140 of the main body by using the bolt 310 after the fixing plate 300 is mounted, (330) and is fixedly connected to the connection groove (140).

When the fixing plate 300 is connected to the fixing plate 300, the upper and lower adjusting member 400 penetrates through the through hole 320 of the fixing plate 300, 200 to the coupling port 240 of the main body 200.

When the up-and-down adjusting member 400 is connected to the coupling hole 240 of the support table 200, the fixing member 500 is connected to the coupling groove 230 formed on one side of the support table 200, (500) is fitted into the support groove (411) of the vertical adjustment member (400).

When the fixing member 400 is connected, the preparation of the block jig 10 supporting the micro-coaxial cable of the present invention is completed. In order to support the micro-coaxial cable to be supported, the up- The micro-coaxial cable is positioned in the space secured by securing a space between the lower surface of the support member 200 and the upper surface of the groove 120 by rotating the support table 200.

When the micro-coaxial cable is positioned, the up-and-down regulating member 400 is rotated in the other direction to lower the supporter 200 to support the micro-coaxial cable.

When the support 200 is lifted and lowered to support the micro-coaxial cable as described above, the vertical adjustment member 400 is rotated in one direction or the other direction. At this time, A fixing member 500 connected to the coupling groove 230 of the support table 200 is inserted into the support groove 411 of the upper and lower adjustment member 400 to prevent detachment.

The block jig 10 supporting the micro coaxial cable is placed on the inner and outer peripheries to be used, the cutting device, and the soldering device. At this time, The block jig 10 is not detached due to the bush 130.

When the block jig for supporting the micro coaxial cable according to the present invention is used, the micro coaxial cable supported on the block jig is not separated from the micro jig during the inner and outer perforation work, cutting operation and soldering operation of the micro coaxial cable, It is possible to minimize the defective rate of the operation of the micro-coaxial cable and to prevent the micro-coaxial cable from being damaged when the micro-coaxial cable is magnetically mounted on the block jig supporting the micro coaxial cable, And the position was fixed.

10: Block jig
100: main body 110: inlet groove
120: groove portion 130: magnet 140: connection groove
200: support member 210: protrusion 220: support member
230: coupling groove 240: coupling hole
300: Fixing plate 310: Bolt
320: through hole 330: through hole
400: upper and lower adjustment member 410: shaft 411: support groove
500: Fixing member

Claims (5)

A main body having a square shape and an upper portion opened to form a groove portion on an inner side and a recessed groove formed in an inner corresponding portion of both side projecting portions of the groove portion; And a fixing plate having a through hole formed at its center,
A support table 200 mounted on the groove 120 of the main body and having protrusions 210 fitted in the recesses 110;
A lower portion of the shaft 410 of the upper and lower regulating member 400 connected to the coupling hole 240 of the supporting table 200 through the through hole 320 of the fixing plate and connected to the coupling hole 240 And a vertical adjustment member 400 having grooves 411 formed therein,
And a support member (220) is formed below the support base (200).
delete The method according to claim 1,
Wherein a magnet (130) is formed in a bottom surface of the groove (120) of the main body (100)
The method according to claim 1,
And a coupling groove (230) is formed at a side center portion of the support base (200). The micro jig
5. The method of claim 4,
And a fixing member (500) which is fixed to the support groove (411) of the upper and lower regulating member (400) through the coupling groove (230) of the support base (200)

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