JP2013171672A - Coaxial multicore cable - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coaxial multicore cable which has excellent electric characteristics and excellent slide resistance.SOLUTION: There is provided a coaxial multicore cable 1 having a plurality of coaxial cables 11a-26b, a shield layer 50 arranged outside the plurality of coaxial cables, and a protective coating layer 60 provided around an outer periphery of the shield layer, the coaxial multicore cable being characterized in that the plurality of coaxial cables are arranged in a plurality of cable layers, and the plurality of coaxial cables each include a plurality of pairs of coaxially twisted coaxial cables, the plurality of coaxial cables being twisted in the same direction and at the same pitch.

Description

  The present invention relates to a coaxial multi-core cable having a plurality of pairs of coaxial cables.

  It is known to differentially transmit digital signals using two pairs of signal lines. In differential transmission, a signal whose phase is inverted by 180 degrees is simultaneously input and transmitted to two signal conductors, and a differentially synthesized signal is output on the receiving side, so that the signal output is doubled on the receiving side. Can do. Further, since the noise received through the signal transmission path is equally applied to the two conductors, the noise is canceled when the signal is output as a differential signal on the receiving side. When transmitting a digital signal as a differential signal, a twinax cable having two signal conductors arranged in parallel is used.

  A multi-pair twinax cable is known in which a multi-pair twinax cable such as 8 pairs or 16 pairs is formed as one cable. The multi-pair twinax cable is used when serially differentially transmitting multi-bit signals based on a high-speed data transmission interface standard such as InfiniBand or 10GBASE-CX4 interface. The multi-pair twinax cable is also used as a camera link cable such as an HS link. Patent Document 1 describes a multi-core cable in which a plurality of core electric wires in which two insulated electric wires are arranged in parallel are twisted together.

  Patent Document 2 discloses a coaxial multi-core cable including a plurality of pairs of coaxial cables, and a plurality of pairs so as not to cause a transmission time difference between signals applied to the plurality of pairs of coaxial cables. A coaxial multi-core cable is described in which coaxial cables forming the same are twisted concentrically. By using the coaxial multi-core cable described in Patent Document 2, it becomes possible to transmit a digital signal without causing a transmission time difference between signals, and the sliding resistance of the coaxial multi-core cable is improved. improves. However, since the coaxial multi-core cable described in Patent Document 2 has a plurality of pairs of coaxial cables arranged as a single cable layer, when the number of coaxial cables increases, the diameter of the coaxial multi-core cable increases. Become. Therefore, it is conceivable to reduce the diameter of the coaxial multi-core cable by arranging a plurality of coaxial cables in a plurality of cable layers.

  Patent Document 3 describes a coaxial multi-core cable having a plurality of cable layers including a plurality of cables twisted concentrically. The coaxial multi-core cable described in Patent Document 3 is formed such that the twist direction of the first cable layer and the twist direction of the second cable layer formed on the outer periphery of the first cable layer are the same direction. . By adopting such an arrangement, coaxial cables arranged in different cable layers come into contact at a number of points in the longitudinal direction. As a result, there is no fear that the coaxial cables are point-contacted and bent at an acute angle, and the coaxial multicore cable described in Patent Document 3 has high mechanical reliability against repeated bending stress.

JP 2011-142070 A JP 2010-33879 A JP 2006-196289 A

  In order to execute processing necessary in the process, an industrial robot that moves the arm unit at high speed and repeatedly is known. A processing mechanism for performing processing is mounted on the tip of the arm portion of the industrial robot, and the arm portion of the industrial robot has many electrical connections between the control unit that controls the processing mechanism and the processing mechanism. The cable is routed. As processing steps become more sophisticated and complicated, a high-sensitivity camera is beginning to be mounted on the tip of an arm portion of an industrial robot in order to execute various controls with high accuracy. For this reason, there is a need to wire a cable capable of transmitting digital signals at high speed to the arm portion of an industrial robot.

  Although the multi-core cable described in Patent Document 1 can transmit high-speed digital signals, it has two insulated wires in which core wires are arranged in parallel, and therefore does not have sufficient sliding resistance.

  The coaxial multi-core cable described in Patent Document 2 can transmit high-speed digital signals and has sufficient sliding resistance. However, the coaxial multi-core cable described in Patent Document 2 has an increased transmission capacity, and when the number of cores increases, the aperture becomes thicker and larger than the aperture defined by a predetermined standard.

  The multi-core cable described in Patent Document 3 has high mechanical reliability against repeated bending stress, but does not have sufficient sliding resistance with respect to the operation of the arm portion of the industrial robot.

  Accordingly, an object of the present invention is to provide a coaxial multi-core cable capable of differentially transmitting a high-speed digital signal and having sufficient sliding resistance against the operation of an arm portion of an industrial robot. And

  In order to solve the above problems, a coaxial multicore cable according to the present invention includes a plurality of coaxial cables, a shield layer disposed outside the plurality of coaxial cables, and a protective coating layer provided on the outer periphery of the shield layer. Have. The plurality of coaxial cables are arranged in a plurality of cable layers, and each of the plurality of cable layers has a plurality of pairs of coaxial cables that are twisted concentrically, and the twist directions of the plurality of coaxial cables are the same direction And the twist pitch of a plurality of coaxial cables is the same pitch.

  Since the coaxial cable of the coaxial multi-core cable according to the present invention is arranged in a plurality of cable layers, the diameter of the coaxial multi-core cable according to the present invention can be reduced.

  The coaxial cable of the coaxial multi-core cable according to the present invention has the same twisting direction and the same twisting pitch regardless of the arranged cable layers, so that adjacent coaxial cables cross each other. There is no. For this reason, the coaxial multi-core cable according to the present invention has very high mechanical reliability against repeated bending stress.

  Further, the coaxial cable of the coaxial multi-core cable according to the present invention has the same twisting direction and the same twisting pitch, so that the force received by each coaxial cable from the cable external stress is uniform and the same direction. is there. For this reason, when the coaxial multi-core cable according to the present invention is bent, damage caused by rubbing between the internal coaxial cables is small. For this reason, the coaxial multi-core cable according to the present invention has good sliding resistance even in a movement in which the bending portion is continuously moved with the movement of the arm portion of the industrial robot.

  However, the coaxial cable of the coaxial multi-core cable according to the present invention has the same twisting direction and the same twisting pitch regardless of the cable layer to be arranged. The length is slightly different. For this reason, each of the plurality of cable layers of the coaxial multi-core cable according to the present invention has a plurality of pairs of coaxial cables twisted concentrically, and transmits a pair of signals such as a differential signal. Coaxial cables arranged on the same cable layer can be used.

  Furthermore, it is preferable that the shield layer has a shield layer metal wire that is laterally wound, and the horizontal winding direction of the shield layer metal wire is the same as the twist direction of the plurality of coaxial cables.

  When the horizontal winding direction of the shield layer metal wire is the same direction as the twist direction of the plurality of coaxial cables, the stress acts in the same direction when the plurality of coaxial cables and shield layer metal wires are bent, The coaxial cable is not tightened by the shield layer metal wire. For this reason, a sliding resistance characteristic improves rather than the case where the horizontal winding direction of the metal wire for shield layers is a direction opposite to the twist direction of a plurality of coaxial cables.

  Further, each of the plurality of coaxial cables includes a central conductor, a dielectric disposed on the outer peripheral side of the central conductor, an outer conductor disposed on the outer peripheral side of the dielectric, and an outer sheath disposed on the outer peripheral side of the outer conductor. The outer conductor preferably has a plurality of laterally wound metal wires for the outer conductor.

  This is because the outer conductor has a plurality of metal wires for outer conductors wound horizontally, and therefore has better sliding resistance than the case where the outer conductor metal wires are formed by braiding.

  According to the present invention, in the coaxial multi-core cable, a plurality of coaxial cables are arranged in a plurality of cable layers, and each of the plurality of cable layers has a plurality of pairs of coaxial cables that are twisted concentrically. Furthermore, according to the present invention, the twisting directions of the plurality of coaxial cables are the same, and the twisting pitches of the plurality of coaxial cables are the same pitch. For this reason, according to the present invention, a coaxial multi-core cable capable of serial transmission of multi-bit digital signals and having sufficient sliding resistance necessary for high-speed movement of an arm portion of an industrial robot is provided. It became possible to do.

It is sectional drawing of a multi-pair twinax cable and a twinax cable. It is sectional drawing of the coaxial multi-core cable of a single layer structure, and a coaxial cable. It is sectional drawing of the coaxial multi-core cable of a two-layer structure. It is a figure which shows the twisting of the coaxial multi-core cable of a two-layer structure. It is a sectional view of a multi-pair twinax cable. It is a figure which shows a cable sliding test apparatus. It is a figure which shows the sliding test result of the coaxial multi-core cable of a two-layer structure. It is a figure which shows the sliding test result of the coaxial multi-core cable of a two-layer structure. It is sectional drawing of the coaxial multi-core cable of a two-layer structure.

  First, before describing the coaxial multi-core cable according to the present invention, a conventional multi-pair twinax cable and a coaxial multi-core cable will be briefly described.

  FIG. 1A is a cross-sectional view of an 8-pair twinax cable 200. The eight-pair twinax cable 200 includes eight pairs of twinax cables 210, a first tape layer 230, a second tape layer 240, an outer shield layer 250, and a sheath layer 260.

  FIG. 1B is a cross-sectional view of the twinax cable 210. The twinax cable 210 includes a first signal line 211a, a second signal line 211b, a shield layer 214, a drain line 215, and a jacket 216. The first signal line 211a includes an inner conductor 212a and a dielectric layer 213a disposed on the outer periphery of the inner conductor 212a. The second signal line 211b includes an inner conductor 212b and a dielectric layer 213b disposed on the outer periphery of the inner conductor 212b.

  In general, the inner conductors 212a and 212b are often formed of silver-plated annealed copper wire. However, the inner conductors 212a and 212b have a core material made of a magnetic material having a relatively large specific resistance such as iron and a specific resistance such as silver, copper, gold, or aluminum. It is preferably formed of a conductor or the like having a coating layer formed of a relatively small highly conductive metal and disposed around the core material. The dielectric layers 213a and 213b are formed of a fluororesin such as porous polytetrafluoroethylene (expanded polytetrafluoroethylene, ePTFE).

  The shield layer 214 has a metallized tape generally referred to as Alpet. Alpet is formed in a tape shape by laminating aluminum foil and polyethylene tefphthalate formed by rolling through polyvinyl chloride (PVC) or the like.

  The drain wire 215 is formed of a silver-plated annealed copper wire, and is arranged in parallel with the shield layer 214 so that one end of the outer periphery of the shield layer 214 is in contact. The jacket 216 is formed of a fluororesin such as FEP or PVC, and is disposed so as to cover the outer side of the shield layer 214 and the drain line 255.

  The first tape layer 230 has ePTFE and is wound around the outside of the eight pairs of twinax cables 210. The second tape layer 240 has an alpet and is wound around the outer periphery of the first tape layer 230 to function as an auxiliary shield. The outer shield layer 250 is formed of braided annealed copper and is disposed on the outer periphery of the second tape layer. The sheath layer 260 has PVC and is disposed on the outer periphery of the outer shield layer 250.

  FIG. 2A is a cross-sectional view of a single layer coaxial multi-core cable (8 pairs 16-core coaxial cable) 300. The single-layer coaxial multi-core cable 300 includes eight pairs of coaxial cables 11, a first tape layer 330, a second tape layer 340, a shield layer 350, a sheath layer 360, and an interposition 370. The eight pairs of coaxial cables 11 are twisted in the right direction.

  FIG. 2B is a cross-sectional view of the coaxial cable 11. The coaxial cable 11 includes a center conductor 101, a dielectric layer 103, an outer conductor 104, and a jacket 105.

  The center conductor 101 has 19 silver-plated copper alloy wires (not shown) twisted in the right direction and functions as a main signal path during signal transmission. The diameter of the twisted silver-plated copper alloy wire is 0.102 mm. The center conductor 101 is formed of a silver-plated copper alloy wire, but may be formed of tin-plated copper, silver-plated copper, or coarse copper.

  The dielectric layer 103 includes an ePTFE layer and a tetrafluoroethylene-hexafluoropropylene copolymer (FEP) layer, and functions to hold the central conductor 101 at the center of the structure. The outer diameter of the dielectric layer 103 is 1.17 mm. The dielectric layer 103 may be formed of other dielectrics such as polyethylene or Teflon (registered trademark).

  The external conductor 104 has 45 tin-plated copper alloy wires (not shown) horizontally wound in the right direction as external conductor metal wires, and functions as a return path during signal transmission. The diameter of the horizontally wound tin-plated copper alloy wire is 0.08 mm. The outer conductor 104 is formed of a tin-plated copper alloy wire, but may be formed of tin-plated copper, silver-plated copper, or coarse copper.

  The jacket 105 has an FEP and is a jacket that is wound around the outer periphery of the outer conductor 104. The thickness of the jacket 105 is 0.1 mm. The jacket is formed of FEP, but may be formed of other fluororesin or PVC.

  The first tape layer 330 has ePTFE and is wound around the outer side of the eight pairs of coaxial cables 11. The thickness of the first tape layer 330 is 0.1 mm. The second tape layer 340 has an alpet and is wound around the outer periphery of the first tape layer 330 to function as an auxiliary shield. The thickness of the second tape layer 340 is 0.035 mm.

  The shield layer 350 has 208 tin-plated copper alloy wires (not shown) that are laterally wound in the right direction. The diameter of the laterally wound tin-plated copper alloy wire is 0.1 mm. The shield layer 350 is formed of a tin-plated copper alloy wire, but may be formed of tin-plated copper, silver-plated copper, crude copper, or the like.

  The sheath layer 360 is a protective coating layer that has PVC and is disposed on the outer periphery of the shield layer 350. The thickness of the sheath layer 360 is 0.85 mm.

  The single layer coaxial multi-core cable 300 has better sliding resistance than the 8-pair twinax cable 200. This is because the coaxial multi-core cable 300 having a single layer configuration uses the coaxial cable 11 having excellent sliding resistance characteristics instead of the twinax cable 210. Further, since the coaxial multi-core cable 300 having a single layer configuration is arranged with eight pairs of coaxial cables 11 in one layer, all the cable lengths of eight pairs, that is, sixteen coaxial cables 11 can be made equal. The transmission time difference is not caused in the signals applied to the 16 coaxial cables 11.

  However, the coaxial multi-core cable 300 having a single layer structure has a large diameter and cannot be connected to a predetermined connector. Specifically, in the 8-pair twinax cable 200, when the 8-pair twinax cable 200 having a cross-sectional length of 1.49 mm and a longitudinal length of 2.99 mm is used, The outer diameter of the 8-pair twinax cable 200 is 9.9 mm. On the other hand, the diameter of the coaxial multi-core cable 300 having a single layer structure is 11.6 mm.

  Next, the coaxial multi-core cable (8 pairs 16-core coaxial cable) 1 according to the present invention will be described with reference to FIGS.

  FIG. 3 is a cross-sectional view of the coaxial multi-core cable 1 having a two-layer configuration. FIG. 4 is a diagram showing a twisting direction and a twisting pitch of the coaxial multi-core cable 1 having a two-layer structure.

  The coaxial multi-core cable 1 having a two-layer configuration includes first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b. Have. The coaxial cable multicore 1 having a two-layer configuration further includes a first tape layer 30, a second tape layer 40, a shield layer 50, a sheath layer 60, and first to fifth interpositions 70 to 74.

  The first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, and 26b are coaxial as shown in FIG. The configuration is the same as that of the cable 11.

  The first to fourth coaxial cables 11a, 11b, 12a, and 12b are twisted in the right direction concentrically around the first intervention 70 together with the second to fifth interventions 71 to 75 to form the first cable layer 10. To do. Since the first to fourth coaxial cables 11a, 11b, 12a, and 12b are twisted in the same direction concentrically, the cable lengths are equal to each other.

  The first coaxial cable 11a and the second coaxial cable 11b form a first cable pair, and the third coaxial cable 12a and the fourth coaxial cable 12b form a second cable pair, and are different from each other. A dynamic signal is transmitted.

  The fifth to sixteenth coaxial cables 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b are twisted concentrically in the right direction around the first cable layer 10, Two cable layers 20 are formed. The second cable layer 20 is twisted so as to be the same twist pitch as the twist pitch of the first cable layer 10. The fifth to sixteenth coaxial cables 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b are concentrically twisted in the same direction, so the cable lengths are equal to each other. .

  The fifth coaxial cable 21a and the sixth coaxial cable 21b form a third cable pair, the seventh coaxial cable 22a and the eighth coaxial cable 22b form a fourth cable pair, and the ninth coaxial cable 23a The tenth coaxial cable 23b forms a fifth cable pair. The eleventh coaxial cable 24a and the twelfth coaxial cable 24b form a sixth cable pair, the thirteenth coaxial cable 25a and the fourteenth coaxial cable 25b form a seventh cable pair, and the fifteenth coaxial cable 26a. The sixteenth coaxial cable 26b forms an eighth cable pair.

  The first tape layer 30, the second tape layer 40, and the sheath layer 60 are the first tape layer 330 and the second tape layer described with reference to the single-layer coaxial multi-core cable 300 shown in FIG. 340 and the sheath layer 360 have the same configuration.

  The shield layer 50 has 192 tin-plated copper alloy wires (not shown) horizontally wound in the right direction as a shield layer metal wire. The diameter of the laterally wound tin-plated copper alloy wire is 0.1 mm. The shield layer 50 is formed of a tin-plated copper alloy wire, but may be formed of tin-plated copper, silver-plated copper, crude copper, or the like.

  The first to fifth interpositions 70 to 74 are each formed of cotton. The first interposition 70 is formed by twisting cotton into a string shape, and is arranged at the center of the coaxial multi-core cable 1 having a two-layer structure. The second interposition 71 is disposed between the first coaxial cable 11a and the second coaxial cable 11b, and the third interposition 72 is disposed between the second coaxial cable 11b and the third coaxial cable 12a. The fourth interposition 73 is disposed between the third coaxial cable 12a and the fourth coaxial cable 12b, and the fifth interposition 74 is disposed between the fourth coaxial cable 12b and the first coaxial cable 11a.

  Next, a manufacturing method of the coaxial multi-core cable 1 having a two-layer structure will be described. A method for manufacturing the coaxial cable 11a will be described. First, 19 silver-plated copper alloy wires are twisted rightward to form the center conductor 101. Next, a dielectric layer 103 is formed by extruding a dielectric having ePTFE and FEP on the outer periphery of the center conductor 101 by an extruder (not shown). Next, the outer conductor 104 is formed by horizontally winding 45 tin-plated copper alloy wires to the right at a certain angle around the outer periphery of the dielectric layer 103. Then, the jacket 105 is formed by extruding FEP on the outer periphery of the outer conductor 104.

  Next, with the first interposition 70 as the center, the first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b, The 2nd-5th intervention 71-75 is twisted together simultaneously. Here, the first to fourth coaxial cables 11a, 11b, 12a, 12b and the second to fifth interpositions 71 to 75 forming the first cable layer 10 are twisted rightward so as to be arranged concentrically. Also, the 5th to 16th coaxial cables 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b forming the second cable layer 20 are arranged in the right direction so as to be concentrically arranged. Twisted together. Further, the first cable layer 10 and the second cable layer 20 are twisted so that the twist pitch is equal.

  Next, the first tape layer 30 is formed by winding an ePTFE tape so as to surround the outside of the second cable layer 20. Next, the second tape layer 40 is formed by winding an alpet so as to surround the outer periphery of the first tape layer 30. Next, the shield layer 50 is formed by twisting 192 tin-plated copper alloy wires in the right direction on the outer periphery of the second tape layer 40. Then, the sheath layer 60 is formed by extruding and covering PVC using an extruder so as to surround the outer periphery of the shield layer 50.

2. Description of the Related Art Conventionally, in a coaxial multi-core cable having a two-layer structure, a second cable layer is provided in order to make the cable lengths uniform so as not to cause a transmission time difference between the coaxial cable of the first cable layer and the coaxial cable of the second cable layer. In comparison, the coaxial cable of the first cable layer has been twisted at a fine pitch. In this configuration, a portion where the coaxial cable of the first cable layer and the coaxial cable of the second cable layer cross each other is generated, and the portion is greatly damaged by rubbing when sliding.
On the other hand, in the coaxial multi-core cable 1 having the two-layer configuration of the present invention, the first cable layer 10 and the second cable layer 20 have the same twist direction and the same twist pitch. That is, the first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b are twisted in the same direction and The twist pitch is the same pitch. For this reason, the adjacent coaxial cables such as the first coaxial cable 11a and the fifth coaxial cable 21a do not cross each other. Therefore, the coaxial multi-core cable 1 having the two-layer configuration is a machine that is extremely high in bending stress. Reliable. Also, the first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b slide with each other when bent. Damage caused by rubbing is small. For this reason, the coaxial multi-core cable 1 having a two-layer configuration has good sliding resistance.

  Since the cable lengths of the first to fourth coaxial cables 11a, 11b, 12a, and 12b forming the first cable layer 10 are equal to each other, they are applied to the first to fourth coaxial cables 11a, 11b, 12a, and 12b. Does not cause a transmission time difference in the signal.

  The cable lengths of the fifth to sixteenth coaxial cables 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, and 26b forming the second cable layer 20 are equal to each other. For this reason, a transmission time difference is not caused in the signals applied to the fifth to sixteenth coaxial cables 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, and 26b.

  Since the twist direction of the shield layer 50 is the same as the twist direction of the first cable layer 10 and the second cable layer 20, the sliding resistance of the coaxial multi-core cable 1 having a two-layer structure is further improved. Since the coaxial cable of the first cable layer 10 and the second cable layer 20 and the shield layer metal wire of the shield layer 50 are subjected to stress in the same direction when bent, the coaxial cable is tightened by the shield layer metal wire. It is because it is not done.

  The outer conductor 104 forming the first to sixteenth coaxial cables 11a, 11b, 12a, 12b, 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b is wound horizontally. Therefore, the sliding resistance of the coaxial multi-core cable 1 having a two-layer structure is further improved.

  The diameter of the coaxial multi-core cable 1 having a two-layer configuration is 9.6 mm, which is smaller than the diameter of the 8-pair twinax cable 200 which is 9.9 mm.

  Next, referring to FIGS. 5 to 8, measurement of the sliding resistance of the coaxial multi-core cable 1 of the two-layer configuration according to the present invention and the sliding resistance of the 16-pair twinax cable 400 according to the prior art is performed. The results will be described.

  FIG. 5 is a cross-sectional view of the 16-pair twinax cable 400. The 16-pair twinax cable 400 includes 16 pairs of twinax cables 410, a first tape layer 430, a second tape layer 440, an outer shield layer 450, and a sheath layer 460.

  The first tape layer 430 has ePTFE and is wound around the 16 pairs of twinax cables 410. The thickness of the first tape layer 430 is 0.1 mm. The second tape layer 440 includes an alpet and is wound around the outer periphery of the first tape layer 430 and functions as an auxiliary shield. The thickness of the second tape layer 440 is 0.035 mm.

  The shield layer 450 is formed of a braided tin-plated copper alloy wire. (Not shown) The diameter of the tin-plated copper alloy wire forming the braid is 0.08 mm.

  The sheath layer 460 is a protective coating layer that has PVC and is disposed on the outer periphery of the shield layer 450. The thickness of the sheath layer 460 is 0.85 mm.

  FIG. 6A shows a cable sliding test device 90. The cable sliding test device 90 includes a fixed portion 91, a movable portion 92, and first and second cable fixed portions 93 and 94. The fixing portion 91 is fixed to a wall surface of the building by a fixing member. The movable portion 92 is moved in the longitudinal direction by a driving device (not shown). The first cable fixing portion 93 fixes one end of the sample cable 95 to the fixing portion, and the second cable fixing portion 94 fixes the other end of the sample cable 95 to the movable portion 92. An arrow 2R in FIG. 6A indicates the bending diameter of the sample cable 95. In this test, the bending radius was 30 mm. That is, the bending diameter 2R in this test is 60 mm.

  The sample cable 95 is a cable to be tested, and the length of the sample cable 95 is 1.0 m. In this measurement, the coaxial multi-core cable 1 or the 16-pair twinax cable 400 having a two-layer configuration is used.

  FIG. 6B is a diagram illustrating a state in which the movable portion 92 of the cable sliding test device 90 has moved most. An arrow S in FIG. 6B indicates a movable stroke. In this test, the movable stroke S was 200 mm. The sliding speed was 100 times / minute.

  Table 1 is a table | surface which shows the test result of the cable sliding test about the coaxial multi-core cable 1 of 2 layer structure. The cable sliding test for the coaxial multi-core cable 1 having a two-layer configuration was performed on three cables of Samples 1 to 3. The change rate of the characteristic impedance shown in Table 1 is the maximum value of the change rate of the characteristic impedance in the first to eighth cable pairs of the coaxial multi-core cable 1 having a two-layer configuration. The value shown in the “maximum value” column shown in Table 1 is the maximum value of the change rate of the characteristic impedance of the three samples 1 to 3.

  FIG. 7 is a diagram showing the rate of change of the characteristic impedance shown in Table 1. As shown in FIG. 7, the maximum value of the change rate of the characteristic impedance was 4.54%, which is a value when the number of sliding of sample 1 is 2 million times. Also, the rate of change in characteristic impedance increases after 1,500,000 slides.

  FIG. 8 is a diagram showing a TDR (Time Domain Reflectometry) waveform of the characteristic impedance of Sample 3 after 3 million sliding tests. Arrow A corresponds to the input end of the cable, and arrow B corresponds to the end of the cable.

  Table 2 is a table showing the test results of the cable sliding test for the 16-pair twinax cable 400. The cable sliding test on the 16-pair twinax cable 400 was performed on one cable. The characteristic impedances shown in Table 2 are values before and after the 1000 sliding tests of the twin-nax cables 1 to 16 in which 16 pairs of twin-nax cables 410 are respectively numbered.

  In the 16-pair twinax cable 400, 14 pairs of twinax cables among 16 pairs of twinax cables 1 to 16 were disconnected by a sliding test with a sliding count of 1000 times. In the two twinax cables 5 and 9 that are not disconnected, the drain line was disconnected.

  As a result of these sliding tests, the coaxial multi-core cable 1 having a two-layer structure shows no significant change in characteristic impedance even when the number of sliding times is 1.5 million, whereas the 16-pair twinax cable does not slide. It is shown that the wire is disconnected even when the number of times is 1000.

  Although the configuration and function of the coaxial multi-core cable 1 having the two-layer configuration has been described above, other embodiments will be described below.

  FIG. 9 is a cross-sectional view of a coaxial multi-core cable (16-pair 32-core coaxial cable) 2 having a two-layer configuration.

  A coaxial multi-core cable 2 having a two-layer configuration includes a first cable layer 110 formed of six pairs of coaxial cables, a second cable layer 120 formed of ten pairs of coaxial cables, and a first tape layer. 130, a second tape layer 140, a shield layer 150, a sheath layer 160, and a first interposition 170.

  The first cable layer 110 is twisted concentrically so that six pairs of coaxial cables have the same twist direction and the same twist pitch. The second cable layer 120 is twisted concentrically so that ten pairs of coaxial cables have the same twist direction and the same twist pitch as the first cable layer 110.

  The coaxial multi-core cables 1 and 2 having the two-layer configuration are arranged in the first cable layers 10 and 110 and the second cable layers 20 and 120, respectively, but may be arranged in three or more cable layers. . Even when coaxial cables are arranged in three or more cable layers, the twist directions of all the coaxial cables are the same regardless of the arranged cable layers, and the twist pitches of all the coaxial cables are the same pitch. It is.

  The coaxial multi-core cables 1 and 2 having the two-layer structure are all twisted in the right direction, but may be all twisted in the left direction. In this case, the twist pitches of all the coaxial cables are the same regardless of the cable layers arranged.

  The first to eighth cable pairs of the coaxial multi-core cable 1 having a two-layer configuration are each formed in adjacent coaxial cables, but the cable pairs only need to be formed of coaxial cables arranged in the same layer. For example, a first cable pair is formed by the first coaxial cable 11a and the third coaxial cable 12a arranged at opposite positions, and a second cable pair is formed by the second coaxial cable 11b and the fourth coaxial cable 12b. May be.

  The coaxial multi-core cables 1 and 2 of the two-layer configuration have 8 pairs and 16 pairs of coaxial cables, respectively, but the number of coaxial cables such as 24 pairs or 32 pairs is different. A multi-core cable may be used.

  Although the embodiment has been described above, all examples and conditions described herein are described for the purpose of helping understanding of the concept of the invention applied to the invention and the technology. It is not intended to limit the scope of the invention, and the construction of such examples in the specification does not indicate the advantages and disadvantages of the invention. Although embodiments of the invention have been described in detail, it should be understood that various changes, substitutions and modifications can be made without departing from the spirit and scope of the invention.

1 Two-layer coaxial multi-core cable (16 pairs coaxial cable for 8 pairs)
2 Double-layer coaxial multi-core cable (16-pair 32-core coaxial cable)
10 First cable layer 11a, 11b, 12a, 12b Coaxial cable 20 Second cable layer 21a, 21b, 22a, 22b, 23a, 23b, 24a, 24b, 25a, 25b, 26a, 26b Coaxial cable 30, 40, 130, 140 Tape layer 50, 150 Shield layer 60, 160 Sheath layer 70, 71, 72, 73, 74, 170 Intervening

Claims (3)

Multiple coaxial cables,
A shield layer disposed outside the plurality of coaxial cables;
A protective coating layer provided on the outer periphery of the shield layer;
A coaxial multi-core cable having
The plurality of coaxial cables are arranged in a plurality of cable layers,
Each of the plurality of cable layers has a plurality of pairs of coaxial cables twisted concentrically,
The coaxial multi-core cable, wherein the twist directions of the plurality of coaxial cables are the same, and the twist pitches of the plurality of coaxial cables are the same pitch. The shield layer has a shield layer metal wire wound horizontally,
The coaxial multi-core cable according to claim 1, wherein a horizontal winding direction of the shield layer metal wire is the same as a twist direction of the plurality of coaxial cables. Each of the plurality of coaxial cables is disposed on a central conductor, a dielectric disposed on the outer circumferential side of the central conductor, an outer conductor disposed on the outer circumferential side of the dielectric, and an outer circumferential side of the outer conductor. Having a jacket,
The coaxial multi-core cable according to claim 1 or 2, wherein the outer conductor includes a plurality of laterally wound metal wires for outer conductor.

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