KR100979599B1 - High-speed differential transmission cable - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a flat high speed differential transmission cable composed of a plurality of signal line pairs with low loss without increasing the conductor thickness of the cable. A pair of signal lines [S (Sp, Sn)] for differential transmission using two electrical conductors 11 as a pair, a plurality of signal line pairs arranged in a flat shape, and an insulating resin extruded and coated to each other. The electrical conductors 11 which consist of a plurality of single-core wires or stranded wires are enumerated in parallel at predetermined intervals P, and integrally covered by an insulator 12 made of an insulating resin, and the outer circumference of the insulator 12 is covered with a metal foil tape. (13) is vertically attached and coated. Moreover, it is good also as a structure which coat | covered the outer periphery of the said metal foil tape 13 with the outer shell which consists of insulating resin. In addition, the ground line G is disposed between the signal line pairs S. FIG.

Description

High Speed Differential Transmission Cables {HIGH-SPEED DIFFERENTIAL TRANSMISSION CABLE}

The present invention relates to a flat high speed differential transmission cable used for transmitting digital data and the like at high speed.

When the digital data is to be transmitted at high speed, it is necessary to shorten the time (referred to as a shift time) until the data signal transitions from the high level to the low level (or low level to high level). In order to shorten the travel time, the signal amplitude may be reduced. However, when the signal amplitude is reduced, there is a problem of weakening to external noise. Therefore, a differential transmission method is known in which a signal of an antiphase is transmitted using a pair of signal lines, and the difference of the transmission signal is data on the data receiving side. This method outputs the difference of the antiphase signal on the receiving side of the transmission signal. This differential output doubles the signal amplitude at the receiving side even if the signal line width at the transmitting side is reduced. Noise introduced into the transmission path is canceled because it overlaps the pair of signal lines equally.

The signal transmission is called Low Voltage Differential Signaling (LVDS), and a data pair can be transmitted as a differential signal having a small voltage change by a pair of conductors to realize high speed, low power consumption, and low noise. . These signal transmission methods include HDMI (High-Definition Multimedia Interface), an integrated interface for transmitting video signals, audio signals, and control signals with one cable, and serial ATA (Advanced Technology Attachment), an interface for connecting a personal computer and a hard disk. It is said to be efficient to use.

In such applications, it is known to use a cable as disclosed in, for example, Patent Document 1, for transmitting a high speed differential signal. Some of these cables are called screen cables in which a plurality of differential cables as shown in FIG. 5 are arranged in a screen shape. The screen cable 9 encloses a differential cable 8 formed by shielding a pair of signal lines as shown in Fig. 5A, arranged in a plurality of parallel lines as shown in Fig. 5B, and adjacent to each other. Differential cables are formed by thermally bonding each other.

Each differential cable 8 covers the center conductor 1 with the dielectric layer 2, forms the skin layer 3 on the outer periphery thereof, and forms a signal line, and the two of the signal lines 4a and 4b are parallel to each other. It is formed by enumeration. Next, drain lines 5a and 5b are disposed on both outer sides of the signal lines 4a and 4b enumerated in parallel. And the outer conductor 6 which consists of a metal foil tape is wound around the outer periphery, maintaining this arrangement structure, Furthermore, the outer side is covered with the jacket layer 7, and it is comprised finally.

As the center conductor 1, 7 silver-plated interlocking wires are twisted, for example, and a stranded wire having an outer diameter of 0.609 mm (AWG 24) is used. The dielectric layer 2 is formed by coating a porous PTFE (tetrafluoroethylene resin) tape on the outer circumference of the center conductor 1 with a thickness of 0.37 mm. The skin layer 3 is formed of 0.09 mm FEP (tetrafluoride ethylene-hexafluoride propylene copolymer resin) of thickness, and coat | covers the outer surface of the dielectric layer 2.

The drain wires 5a and 5b are thinner than the center conductor 1, and stranded wires having an outer diameter of 0.306 mm (AWG 30) are twisted by twisting seven silver-plated interlocking wires. The outer conductor 6 is formed by winding a metal vapor deposition tape or the like in a spiral shape or a longitudinal attachment. The jacket layer 7 is formed of a nonhalogen flame retardant olefin resin having a thickness of 0.25 mm, has an outer diameter on the long axis side of 4.3 mm, enumerates it in a plurality of parallel lines, and fusions the side surfaces on the long axis side, I integrate it.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2002-304921

As the plasma display and the liquid crystal display become larger, the signal transmission cable used as the wiring material in the device also becomes longer. Currently, what is wired in length of about several tens of cm is going to be wired in length of 2 m or more, for example. In this case, there is a problem of transmission loss, and it is difficult to cope with simply lengthening the current cable. For example, when the signal transmission cable is used in the high frequency region, the dielectric loss of the dielectric layer covering the signal line also increases as the frequency increases. In particular, the use frequency of HDMI is 825 MHz or more, and the transmission loss in this case becomes a value which cannot be ignored.

In order to avoid an increase in the transmission loss of the signal transmission cable, it is necessary to increase the thickness of the center conductor or the like, but with the screen cable disclosed in FIG. 5, the cable diameter becomes large. For this reason, flexibility falls and handling property worsens, and the problem of wiring space also arises.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described situation, and an object thereof is to provide a flat high speed differential transmission cable composed of a plurality of signal line pairs having a low loss without increasing the cable diameter.

A high speed differential transmission cable according to the present invention is a pair of signal lines for differential transmission using two sets of electrical conductors, a plurality of the signal line pairs are arranged in a flat shape, and the high speed differential transmission cable is formed by extruding an insulating resin. Electrical conductors composed of a plurality of single-core wires or stranded wires are enumerated in parallel lines at predetermined intervals and integrally covered by an insulator made of an insulating resin, and the outer circumference of the insulator is coated by vertically attaching a metal foil tape. Moreover, it is good also as a structure which coat | covered the outer periphery of the said metal foil tape with the outer shell which consists of insulating resin.

A ground line is arranged between each pair of the signal lines to reduce coupling between the signal line pairs. Further, the drain wire is placed in electrical contact with the metal foil tape to facilitate the ground connection of the metal foil tape. In addition, the space | interval of a some electrical conductor is set to narrow pitch of 0.5 mm or less so that predetermined | prescribed transmission characteristic may be acquired. Further, the insulator and the metal foil tape are adhered by an adhesive, and an adhesive for this is applied to the insulator or the metal foil tape in the form of a steel sheet.

In addition, the metal foil tape is wound 1.5 times or more on an insulator to give flame retardancy. When the outer periphery of the metal foil tape is covered with the outer shell, the outer shell is formed of a mixed resin of a polyurethane resin and an ethylene vinyl acetate copolymer resin to give flame retardancy.

In addition, 0.4 wt% to 0.6 wt% of carbon black is added to the insulator to facilitate the processing of the metal foil by the YAG laser. In addition, it is good also as a structure which the bending control member of the bending radius larger than the minimum bending radius in which a metal foil tape is not cut | disconnected was attached to the location where a cable is bent.

According to the present invention, a low-loss high-speed differential transmission cable can be realized without increasing the diameter of the signal line, and even when the wiring distance between the electronic devices or the electronic devices becomes long, the increase in the loss is suppressed and the signal transmission at high speed is efficiently performed. You can run

Embodiments of the present invention will be described with reference to the drawings. 1 shows a cross section of a cable without a sheath, and FIG. 2 shows a cross section of a cable with a sheath. In the figure, 10a and 10b are high-speed differential transmission cables, 11 is an electrical conductor, 12 is an insulator, 13 is a metal foil tape, 14 is a drain wire, 15 is a sheath, Sp, Sn is a signal line, S is a signal line pair, and G is a ground. Indicates a line.

As shown in FIG. 1, the high speed differential transmission cable 10a of the present invention is formed by enumerating a plurality of electrical conductors 11 in parallel lines at predetermined intervals. These electric conductors 11 are coat | covered with the insulator 12 which consists of insulating resin, and the metal foil tape 13 as a shield conductor is vertically attached and wound up in the cable longitudinal direction on the outer side. Moreover, as needed, the drain wire 14 is arrange | positioned between the insulator 12 so that it may electrically contact the metal foil tape 13. Moreover, it is preferable that this drain line 14 is arrange | positioned in the one or both side edge parts of a cable.

The electrical conductor 11 can use the single conductor wire or stranded wire which tin-plated or silver-plated to electrical conductors, such as copper and aluminum, or these. It is preferable that the electrical conductor 11 has an annular linear shape whose external shape is substantially the same in length and width. Although parallel conductors are used for flat cables, the coupling between signals to be differentially transmitted can be strengthened by using an annular conductor. In addition, by strengthening the coupling between signals, the eddy current induced in the shield conductor (metal foil tape 13) and the joule loss due to this can be reduced to reduce the decay.

In addition, from the flexible point, the electric conductor 11 is more preferably stranded than the single-core wire, and for example, twisted wires having seven outer diameters of 0.06 mm (corresponding to AWG 34, outer diameter of 0.18 mm) can be used. The electrical conductors are enumerated in parallel on the same plane at a predetermined pitch P, and are integrally covered by the insulator 12 by extrusion molding of the insulating resin to form a flat multicore insulated cable.

The insulator 12 electrically insulates the electrical conductors 11 and functions as a capacitor for forming an electrostatic bond between the electrical conductors 11 and the metal foil tape for use in the high frequency region. . For this reason, the insulator 12 is also called a dielectric, and its dielectric tangent tan δ and relative dielectric constant epsilon are also parameters that determine the characteristics of the transmission cable. The smaller the dielectric loss tangent of the insulator 12 is, the smaller the dielectric loss is, and the smaller the dielectric constant is preferable in order to reduce the cable diameter.

Therefore, it can be said that any of the dielectric loss tangent and relative dielectric constant of the insulator 12 has a lower transmission loss and can efficiently transmit a high frequency signal. However, it is also necessary to secure a predetermined characteristic impedance in connection with the device, and it is necessary to consider the shape combination with the dielectric material.

In this invention, polyolefin resin is used for the insulating resin which forms this insulator 12, for example, polyethylene resin etc. can be used. The polyethylene resin has a dielectric loss tangent of about 4 × 10 ⁻⁴ , and a relative dielectric constant of 2.3 to 2.4, which is smaller than a polyester resin (for example, dielectric loss tangent of about 2 × 10 ⁻³ and relative dielectric constant of 2.9 to 3.0). It can be said that it is a preferable material. Moreover, it is preferable that this insulator 12 is extrusion-molded using the extruder with respect to the some electrical conductor 11 arrange | positioned at predetermined space | intervals.

In the case of extrusion molding the insulator 12, it is preferable that the upper and lower planes of the insulator 12 are formed in a flat surface so that no depression occurs between the electrical conductors 11. Thereby, the space | interval of the metal foil tape 13 wound by the outer periphery of each electrical conductor 11 and the insulator 12 can be made constant, and it can be set as uniform characteristic impedance.

As described above, the metal foil tape 13 forms a predetermined capacitance distribution between the signal lines in the electric conductor 11 so as to obtain a predetermined characteristic impedance. In addition, the metal foil tape 13 has a function as a shield conductor that covers the outer circumference of the insulator 12 and prevents intrusion of noise signals (noise signals) from the outside or leakage of signals to the outside.

The metal foil tape 13 is formed by adhering or depositing a metal foil 13a such as aluminum or copper to a plastic substrate 13b such as polyethylene terephthalate (PET). As for the metal foil 13a and the plastic base material 13b, the thing of several micrometers-several tens of micrometers can be used, The thickness of the metal foil tape 13 as a whole is 0.01 mm-0.05 mm. For example, a copper foil having a thickness of 9 µm is used as the metal foil 13a, and a PET having a total thickness of 15 µm can be used using PET having a thickness of 6 µm as the tape base material 13b.

The metal foil tape 13 is vertically attached to the insulator 12 with its metal foil surface inside, and bent to the width of the insulator 12, and at least the overlapped portion thereof is adhesively fixed by the adhesive 13c. By making the metal foil surface of the metal foil tape 13 inward, since the metal foil is not exposed to the outer surface of the cable, it is possible to provide a certain range of durability as a cable even without the outer skin. In addition, since the metal foil tape 13 needs to match impedance with the electrical conductor 11, the distance from the electrical conductor 11 needs to be constant. For this purpose, when the outer periphery of the metal foil tape 13 is not covered with the outer shell 15, the metal foil tape 13 is preferably attached to the insulator 12 reliably. However, it is not necessary for the adhesive to be applied without a gap on the whole surface, and as will be described later, if the metal foil tape 13 is attached so as not to lift from the insulator 12, the adhesive is partially applied in a stripe shape or the like. It may be.

The drain wire 14 is not necessarily required when the ground connection is easy with the metal foil tape 13 itself. However, by using the drain wire 14, the ground connection of the metal foil tape 13 can be made easy, and it is provided as needed. This drain line 14 is arrange | positioned separately from the electrical conductor 11 mentioned above, and is arrange | positioned so that it may fit between the insulator 12 and the metal foil tape 13 in one or both side edge parts of a cable. In addition, although the same thing as the electrical conductor 11 may be used for the drain line 14, it may be thinner or thicker than the electrical conductor 11. As shown in FIG. For example, you may use what twisted 7 conducting wires of 0.08mm in outer diameter (corresponding to AWG 32, 0.24mm in outer diameter).

FIG. 2 shows the high speed differential transmission cable 10b in which the outer surface of the metal foil tape 13 is covered with the outer shell 15 with respect to the outer skinless high speed differential transmission cable 10a on which the above-described metal foil tape 13 is wound. It is. Since the high speed differential transmission cable 10b can be made substantially the same as the structure demonstrated in FIG. 1 in the parts other than the structure covered with the outer shell 15, detailed description is abbreviate | omitted.

The outer shell 15, also called a jacket, is provided for protection of the entire cable including the metal foil tape 13. The outer shell 15 can be formed by extrusion molding a polyvinyl chloride, polyethylene or a mixed resin of a polyurethane resin and an ethylene vinyl acetate copolymer resin described later using an extruder or by winding a resin tape. The outer shell 15 electrically insulates and protects the metal foil tape 13, reinforces its mechanical strength, and further strengthens the strength to withstand bending and the like.

When the outer periphery of the metal foil tape 13 is coat | covered with an outer sheath, the metal foil tape 13 may be wound so that the metal foil surface may become an outer side. In this case, it is protected by covering with the outer shell 15, and can be made durable. In addition, when the metal foil tape 13 is wound so that a metal foil surface may become an outer side, the drain wire 14 is arrange | positioned outside the metal foil tape 13. Then, the outer shell 15 is pressed against the metal foil surface. When the metal foil tape 13 is covered with the outer shell 15, the metal foil tape 13 may not necessarily be adhered to the insulator 12.

In the high-speed differential transmission cables 10a and 10b according to the present invention, a pair of multi-core cables formed as described above is used as a pair of two electrical conductors 11 adjacent to each other to form one signal line pair. As shown in FIG. 1 and FIG. 2, the signal line pair has at least two or more plurality (for example, five pairs of S1 to S5). One of the signal lines Sp1 to Sp5 forming these signal line pairs is used for the signal of the potential potential, and the other signal lines Sn1 to Sn5 are used for the signal of the opposite negative potential. In addition, when the number of electrical conductors 11 is sufficient, the electrical conductor between each signal line pair S is used as the ground line G, and coupling | bonding of the signal between adjacent signal line pairs S is reduced. It is also possible to prevent cross talk from occurring.

In the transmission path using the above-mentioned high speed operation transmission cables 10a and 10b, on the transmission side, for example, the signal line pair S1 transmits a (+ V1) signal having a positive polarity to the signal line Sp1, The negative polarity (-V1) signal is transmitted to the signal line Sn1. And on the receiving side, the 2V1 level signal can be received by taking the difference "(+ V1)-(-V1)" of both signal levels. In addition, the external noise signal invading in the transmission path is applied to the signal lines Sp1 and Sn1 in the same phase, but is removed by taking the difference signal on the receiving side. The signal line pair S is provided in a form in which the plurality is arranged in parallel lines, and each signal line pair S1 to S5 may transmit different signals individually.

The ground line G disposed between each signal line pair S is referred to as ground potential. It is preferable that the ground line G is arranged between both sides of each signal line pair S1 to S5 and has an arrangement state in which the ground lines G are electrically and physically balanced with respect to both of the signal lines Sp and Sn. However, the outside of the signal line pairs S1 and S5 located at both ends of the cable may be omitted from the absence of the signal line pair S. In addition, a power line or the like may be provided where the distance of several times the arrangement pitch of the signal line group is provided, for example, in a form that does not affect the signal line pair S. FIG.

The arrangement pitch P of the electrical conductors 11 forming the signal lines Sp and Sn and the ground line G is a distance which can ensure electrical insulation, and also between the signal lines Sp and Sn. In consideration of the coupling degree, when the outer diameter of the electrical conductor 11 is 0.18 mm (corresponding to AWG 34), it may be about 0.5 mm. The covering width D1 of the insulator 12 is selected in consideration of the dielectric constant of the insulator 12 so that the characteristic impedance becomes a predetermined value (for example, 100?). In addition, in the case of having the sheath 15, the sheath width D2 of the sheath is about 0.2 mm, depending on the thickness of the inner electrical conductor 11 and the sheath thickness of the insulator 12, but is 1.0 mm or more. It is about 3.0mm.

In the above configuration, in order to increase the characteristic impedance, the diameter of the electrical conductor 11 is reduced or the thickness of the insulator 12 is increased, but in particular, it is preferable to increase the thickness of the insulator 12. Do. On the contrary, in order to make characteristic impedance small, it is preferable to make the diameter of the electrical conductor 11 thick, or to reduce the thickness of the insulator 12, but to increase the thickness of the electrical conductor 11 characteristically.

In addition, as a cable transmission loss, up to 5.0 dB / length of use is normally allowed. At 2m of use, 2.5dB / m is allowed. In addition, although the transmission loss varies depending on the frequency of use, for example, at an operating frequency of 825 MHz of HDMI, the conductor pitch (P) corresponds to an electric diameter of seven wires of 0.18 mm (corresponding to AWG 34) at seven twisted pairs. ) Is 0.5 mm and the thickness D1 of the insulator 12 is 0.5 mm which is equal to the conductor pitch P. When polyethylene is used for the insulator 12, the transmission loss is estimated to be 1.5 dB / m to 2.0 dB / m.

On the other hand, in a screen cable using an ultra-fine coaxial structure as shown in FIG. 5, in order to form the conductor pitch as described above with 0.5 mm and to obtain a predetermined characteristic impedance, the thickness of the center conductor is 0.03 mm in outer diameter. It is necessary to have a thin diameter of 7 stranded wires (corresponding to AWG No. 40 and outer diameter of 0.09 mm). As a result, the transmission loss at the use frequency of 825 MHz as described above is 4 dB / m to 5 dB / m, which is twice as much as the case of the present invention. On the other hand, in the conventional structure, in order to achieve a transmission loss equivalent to that of the present invention, the width and thickness of the screen cable increase, the wiring space increases, and the handleability also decreases.

It is a figure explaining embodiment concerning adhesion | attachment of a metal foil tape. Fig. 3 (A) is a view for explaining an example of the provision form of the adhesive according to the present invention, Fig. 3 (B) is a diagram for explaining the electrical contact and bonding state between the drain wire and the metal foil tape, and Fig. 3 (C) is the metal foil tape. Is a figure explaining the bonded part and the non-bonded part of the same. In the figure, 16 is an adhesive stripe, 16a, 16b is a short bar-shaped adhesive stripe, 17 is a space | gap, 18 is an adhesion surface, and 19 is a non-adhesion surface.

As described in the structural examples of FIGS. 1 and 2, the metal foil tape 13 has a constant separation distance between the metal foil of the metal foil tape 13 and the electrical conductor 11, and the characteristic impedance is maintained over the cable length. It is preferable to be uniform. When the outer shell 15 is absent, it is preferable that the metal foil tape 13 and the insulator 12 adhere to each other and are integrated. For this purpose, an adhesive is given to the bonding surface of either the metal foil tape 13 or the insulator 12. As the adhesive, for example, a polyester adhesive can be used.

The adhesion of the metal foil tape 13 and the insulator 12 does not have to be the same in its entirety. For this reason, an adhesive agent can be apply | coated to the adhesive surface in various forms, such as a zebra pattern, a grid | lattice form, a droplet form, and a high steel plate form, and can adhere | attach. However, depending on these application shapes and application conditions, various problems may occur. For example, when using the drain wire 14 shown in FIG. 1, FIG. 2, it is preferable to fix with the adhesive agent so that the drain wire 14 may not move or move. However, when the adhesive is applied to the metal tape 13 side, since the adhesive is usually electrically insulating, there is a fear that the electrical contact between the metal tape 13 and the drain line 14 is damaged.

FIG. 3B shows the form in which the drain wire 14 is in contact with the metal foil surface of the metal foil tape 13. As shown in this figure, the drain wire 14 is bonded and held by the width a of the adhesive stripe 20 generated by the application of the adhesive. The space | gap 17 of the space | interval b arises between the adhesive stripes 20, and the drain line 14 is bent so that it may enter into this space | gap 17, and it contacts with the metal foil tape 13 electrically. Therefore, when the space | interval b of the space | gap 17 is narrow, the contact state of the drain line 14 and the metal foil tape 13 will fall. Moreover, it turned out that there is no problem as long as the width | variety a of the adhesive stripe 20 and the space | interval b of the space | gap 17 are a / b <= 2.

In addition, as shown in FIG.3 (C), when the adhesive surface 18 and the non-adhesion surface 19 of the metal foil tape 13 and the insulator 12 are adhere | attached in the inclined stripe shape, it is non-adhesive, for example. When bent along the surface 19 (NN line), the metal foil tape will be excited on the non-adhesive surface 19, and the impedance of the cable will change. Moreover, when it bends repeatedly in this state, there exists a possibility that folded gold may generate | occur | produce and fracture may occur in metal foil.

In consideration of the above matters, when there is no outer skin and there is a drain wire, as an application form of the adhesive, a high steel sheet known as a non-slip steel sheet as shown in Fig. 3A (checked plate ( It is proved that it is desirable to apply in the form of [checked plate]. FIG. 3 (A) shows an example in which the adhesive stripe 16 is formed in the form of a steel sheet on the adhesive surface of the developed metal foil tape 13. In addition, when there is no sheath 15 and there is no drain wire 14, the entire surface of the portion where the metal foil tape 13 and the insulator 12 contact each other may be bonded to each other. good.

When the metal foil tape 13 is covered with the outer shell 15, the outer shell 15 presses the metal foil tape 13, so that the metal foil tape 13 may or may not be adhered to the insulator 12. good. In this case, as shown in FIG. 3A, the high-strength sheet-like adhesive stripe 16 may be in the form of being adhered to one surface of the insulator or may be formed over the entire surface.

In the form of such a high steel plate, the adhesive stripe 16a, 16b of orthogonal short bar shape is alternately arrange | positioned, and the whole is inclined in the longitudinal direction or the width direction. For example, the width of one side of the adhesive stripes 16a and 16b is about 0.5 mm and the length is about 4.5 mm, and it is applied to the adhesive surface on the insulator or metal foil tape side at an arbitrary density. By using this high-strength adhesive stripe, it is possible to make "a / b" described in FIG. 3 (B) about "1/8", for example, and can fully contact a drain wire and a metal foil by this. In addition, the linear non-adhesive surface 19 as described in FIG. 3 (C) can be prevented from occurring, and the metal foil tape 13 does not rise to the tendon shape.

Moreover, in recent years, the request of the cable with a flame retardance is high, and the flame-retardant cable of the hardness which passes the vertical combustion test VW-1 of UL standard is calculated | required.

4 is a view showing a configuration example of increasing the flame retardancy of the cable according to the present invention. In the cable without a sheath shown in FIG. 1, the overlapping part which the metal foil tape 13 was vertically attached and wound up is formed in narrow overlapping amount of the grade which maintains a winding state by adhesion | attachment. However, if there is little overlap amount of the winding of the metal foil tape 13, the adhesive agent of an overlap part will fuse | melt by combustion. The polyethylene resin inside the tape vaporizes and leaks from this overlapping portion, which burns and promotes combustion of the cable.

Therefore, as shown in FIG. 4, it is preferable to enlarge the overlapping part of the winding of the metal foil tape 13. As a result of the test, leakage of the combustion gas was suppressed by winding the metal foil tape 13 in 1.5 layers. Therefore, it is preferable that the metal foil tape 13 is wound by 1.5 or more layers on the outer periphery of an insulator, and makes the overlapping part of winding into 0.5 turn or more.

In addition, in the case of aluminum foil, the metal foil of the metal foil tape 13 rejected the flame retardancy test by making a hole in 7 micrometers, and required thickness of 10 micrometers or more. In the case of copper foil, it passed the flame retardancy test by thickness of 7 micrometers. Therefore, in order to improve flame retardancy, it is preferable to use copper foil tape.

In the cable having the sheath of FIG. 2, the flame retardancy can be improved by using a flame retardant for the sheath material. As flame retardant sheaths, flame retardant polyethylene and polyvinyl chloride resins to which halogen-based flame retardants are added have been conventionally used. However, the demand for halogen-free flame retardant cables containing no halogens is increasing due to environmental problems. In the present invention, the flame retardant of the cable is used as a shell of the cable using a mixed resin of a polyurethane resin and an ethylene-vinyl acetate copolymer (EVA) resin (see, for example, Japanese Unexamined Patent Application Publication No. 2008-117609). It is realized. In the case where the metal foil tape 13 is covered with a flame retardant sheath, the metal foil tape 13 only needs to be partially overlapped.

In terminal formation for connector connection etc., it is preferable to cut the metal foil which is a shield conductor using a YAG laser. In addition, a CO ₂ laser is usually used for cutting the insulator portion. However, if the insulator is transparent to natural color, the conductor inside the insulator can be deteriorated when the shield conductor is cut by the YAG laser. On the other hand, if the insulator is colored and the YAG laser is difficult to penetrate, this time, the insulator is difficult to be cut by the CO ₂ laser.

In this invention, it is preferable to add carbon black to an insulator, and to make the color of an insulator light black. In addition, it is preferable that the addition amount of carbon black shall be about 0.5 wt% (0.4 weight%-0.6 weight%). With this addition amount of carbon black, only the metal foil tape can be cut without the YAG laser affecting the conductor inside. In addition, the insulator can ensure cutting by a CO ₂ laser.

In addition, in a flat cable having a shielded conductor, with or without an outer sheath, if extremely bent (bending below a minimum bending radius), the metal foil of the metal foil tape forming the shielded conductor may be cracked or cut. . For this reason, it is preferable to be equipped with the bending control means to make a bending radius larger than the minimum bending radius which a metal foil tape does not cut so that a cable may not be bent to the radius below a predetermined bending radius.

In the present invention, a bending restricting member is formed in a place where bending is assumed in advance by bonding or the like so that the cable is not bent below a predetermined bending radius. The bending restricting member can be formed of a rod-shaped member of a cylinder, a cylinder, a semi-cylinder, or a semi-cylinder. The radius of curvature of these bending restricting members can be, for example, about a bending radius of about 1.5 mm for a 90 ° bending of the cable and about 2.5 mm for a bending of 180 °.

BRIEF DESCRIPTION OF THE DRAWINGS The figure explaining the structural example of the high speed differential transmission cable (without an outer jacket) which concerns on this invention.

2 is a view for explaining a configuration example of a high speed differential transmission cable (with an outer jacket) according to the present invention;

3 is a view for explaining an embodiment of the adhesion of the metal foil tape in the present invention;

4 is a diagram illustrating flame retardation of a high speed differential transmission cable according to the present invention;

5 is a view for explaining the prior art;

Explanation of symbols for the main parts of the drawings

10a, 10b: high speed differential transmission cable 11: electrical conductor

12: insulator 13: metal foil tape

14 drain line 15 sheath

16: adhesive stripes

16a, 16b: adhesive bar-shaped adhesive stripes

17: void 18: adhesive surface

19: non-bonded surface Sp, Sn: signal line

S: Signal line pair G: Ground line

Claims (11)

In a high-speed differential transmission cable in which two electrical conductors are used as a pair and a signal line pair for differential transmission, a plurality of the signal line pairs are arranged in a flat shape, and the insulating resin is extruded and coated. Electrical conductors composed of a plurality of single-core wires or stranded wires are enumerated in parallel in a predetermined interval and integrally covered by an insulator made of an insulating resin, and the outer circumference of the insulator is coated with a metal foil tape vertically. High speed differential transmission cable. The method of claim 1, The outer circumference of the metal foil tape is covered with an outer shell made of an insulating resin. High speed differential transmission cable. The method of claim 1, A ground line is arranged between each pair of signal lines. High speed differential transmission cable. The method of claim 1, A drain wire is disposed in electrical contact with the metal foil tape. High speed differential transmission cable. The method of claim 1, The spacing of the plurality of electrical conductors is characterized in that 0.5mm High speed differential transmission cable. The method of claim 1, The insulator and the metal foil tape are bonded to each other. High speed differential transmission cable. The method of claim 6, An adhesive is applied to the insulator or the metal foil tape in the form of a high steel sheet. High speed differential transmission cable. The method of claim 6, The metal foil tape is wound in the insulator 1.5 ply or more, characterized in that High speed differential transmission cable. The method of claim 2, The outer shell is formed of a mixed resin of a polyurethane resin and ethylene vinyl acetate copolymer resin, characterized in that High speed differential transmission cable. The method of claim 1, Carbon black is added to the insulator by 0.4 to 0.6% by weight, characterized in that High speed differential transmission cable. The method of claim 1, A bending restraint member having a bending radius larger than the minimum bending radius at which the metal foil tape is not cut is attached to the bending portion at least at one place. High speed differential transmission cable.

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