JP2018137245A - Differential signal transmission cable and differential signal transmission assembly cable - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cable for differential signal transmission which is small in in-pair transmission delay time in a static state, compared with conventional cables, and also small in in-pair transmission delay time in a bent state or after cabling, and a cable assembly for differential signal transmission.SOLUTION: A cable 100 for differential signal transmission includes: a drain wire-provided twin-ax cable 103 in which two insulated wires 101 are arranged so as to be in parallel contact with each other and a drain wire 102 is arranged so as to be in contact with both of the two insulated wires 101 and in parallel with the two insulated wires 101; and a shield tape 104 which is wound around the drain wire-provided twin-ax cable 103. The apex angle ./SUB> of an isosceles triangle ABC with a line segment AB binding together centers A and B of the two insulated wires 101, in the cross sectional view, as the bottom side and with a center C of the drain wire 102 as the apex is 74 degrees or more and 90 degrees or less.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a differential signal transmission cable and a differential signal transmission aggregate cable for transmitting a high-frequency signal of several GHz or more in a differential manner.

  When transmitting a high-frequency signal of several GHz or more, there is a differential method in which two signals whose phases are inverted are transmitted by two insulated wires and the difference between the two signals is synthesized and output at the receiving end. It has been adopted. According to the differential method, since the direction of the current flowing through the two insulated wires is opposite, the electromagnetic waves radiated to the outside can be reduced, and noise is equally superimposed on the two insulated wires. Therefore, the influence of noise can be canceled at the receiving end.

  Conventionally, as a transmission path for transmitting a high frequency signal of several GHz or more in a differential manner, as shown in FIG. 3, two insulated wires 301 are disposed in parallel and two drain wires 302 are provided. A twinax cable with drain wire 303 that is in contact with both insulated wires 301 and arranged in parallel with the two insulated wires 301, and a shielding tape 304 wound around the twinax cable 303 with drain wires , A differential signal transmission cable 300 is known.

JP2011-090959A

  In order to transmit a high-frequency signal of about 10 GHz without being greatly attenuated, the difference in inward propagation delay time (inward skew) is required to be 10 ps / m or less. However, the differential signal transmission cable 300 according to the prior art is required. Since the inward propagation delay time difference in the stationary state varies in a wide range of approximately 7 ps / m or more and 12 ps / m or less, the differential signal transmission cable 300 having a small inward propagation delay time difference cannot be stably manufactured.

  Even if the differential signal transmission cable 300 has a difference in inward propagation delay time of 10 ps / m or less in a stationary state, when the cable is bent or a plurality of cables are assembled and cabling is performed, the difference in inward propagation delay time is about 15 ps / m. In some cases, it deteriorated to a range of m to 22 ps / m.

  Accordingly, an object of the present invention is to provide a differential signal transmission cable and a differential signal transmission cable that have a small inward propagation delay time difference in a stationary state and a small inward propagation delay time difference in a bent state or after cabling. It is to provide a collective cable.

  Invented to achieve this object, the present invention has two insulated electric wires having circular cross-sections arranged in contact with each other and one drain wire is in contact with both of the two insulated wires. A twinax cable with a drain wire arranged in parallel with the two insulated wires, and a shielding tape wound around the twinax cable with a drain wire. An apex angle of an isosceles triangle having a line connecting the centers of the electric wires as a base and an apex at the center of the drain wire is not less than 74 degrees and not more than 90 degrees, and the drain wires are respectively the two insulated electric wires. Is pressed against the insulated wire by the shield tape so that the respective distances between the center of the drain wire and the center of the drain wire are equal, and the apex angle of the isosceles triangle ( 4 degrees 90 degrees or less), the determined by the size of the outer diameter of the drain wire to the outer diameter of the circular cross section of the insulated wire, a differential signal transmission cable, characterized in that.

  The insulated wire has a signal line conductor and a solid insulation layer formed around the signal line conductor, and the solid insulation layer has a Shore hardness of D50 or more and D65 or less, and a dynamic friction coefficient of an outer surface. Is 0.1 MPa, 3 m / min or more and 0.3 MPa, 3 m / min or less.

  The drain wire may be formed by twisting a plurality of ground wire strands.

  The shield tape may be wound in a direction opposite to the twisting direction of the ground wire.

  In addition, the present invention is a differential signal transmission aggregate cable in which a plurality of the differential signal transmission cables are aggregated.

  According to the present invention, a differential signal transmission cable and a differential signal transmission aggregate cable that have a smaller inward propagation delay time difference in a stationary state and a smaller inward propagation delay time difference in a bent state or after cabling, as compared with the prior art. Can be provided.

It is a cross-sectional schematic diagram which shows the cable for differential signal transmission which concerns on this invention. It is a cross-sectional schematic diagram which shows the aggregated cable for differential signal transmission which concerns on this invention. It is a cross-sectional schematic diagram which shows the cable for differential signal transmission concerning a prior art.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

  As shown in FIG. 1, a differential signal transmission cable 100 according to a preferred embodiment of the present invention has two insulated wires 101 arranged in contact with each other and two drain wires 102 are insulated. A twinax cable 103 with a drain wire which is in contact with both of the electric wires 101 and is arranged in parallel with the two insulated wires 101; and a shield tape 104 wound around the twinax cable 103 with a drain wire. ing.

  The insulated wire 101 includes a signal line conductor 105 and a solid insulating layer 106 formed around the signal line conductor 105.

  The signal line conductor 105 is made of, for example, a stranded wire formed by twisting seven signal line strands 107. As a result, the bending resistance can be improved as compared with the case where the signal line conductor 105 is made of a single wire, and the influence of the skin effect due to the transmission of the high-frequency signal can be reduced by increasing the surface area. .

  The solid insulating layer 106 preferably has a Shore hardness of D50 or more and D65 or less, and an outer surface dynamic friction coefficient of 0.1 MPa, 3 m / min or more and 0.3 MPa, 3 m / min or less. If the Shore hardness of the solid insulating layer 106 is less than D50, the solid insulating layer 106 may be crushed by the drain wire 102 when the drain wire 102 is pressed by the shield tape 104, and impedance matching may be lost. This is because if the Shore hardness of the layer 106 is higher than D65, the insulated wire 101 becomes hard as a whole and flexibility may be reduced. Further, when the dynamic friction coefficient of the outer surface of the solid insulating layer 106 is less than 0.1 MPa and 3 m / min, the drain wire 102 is displaced from a predetermined position, and the distance between the drain wire 102 and the two signal line conductors 105 is increased. If the dynamic friction coefficient of the outer surface of the solid insulating layer 106 is higher than 0.3 MPa, 3 m / min, the insulated wire may be bent when the differential signal transmission cable 100 is bent. This is because the stress applied to 101 cannot be dispersed well and disconnection or the like may occur. Examples of the material of the solid insulating layer 106 that satisfies these characteristics include tetrafluoroethylene-perfluoroalkyl vinyl ether copolymer (PFA), tetrafluoroethylene-hexafluoropropylene copolymer (FEP), or polytetrafluoro Examples thereof include fluorine resins such as ethylene (PTFE).

  Since the foamed insulating layer is easily crushed and deformed by the drain wire 102, it is not preferable to employ the foamed insulating layer as the insulating layer of the insulated wire 101.

  The drain wire 102 is preferably formed by twisting a plurality of (for example, seven) ground wire elements 108. Thereby, the frictional force between the drain wire 102 and the insulated wire 101 can be increased, and the drain wire 102 can be prevented from being displaced from a predetermined position.

  The shield tape 104 has an inner layer 109 made of metal and an outer layer 110 made of resin. Examples of the material of the inner layer 109 include copper foil.

  The shield tape 104 is preferably wound in a direction opposite to the twisting direction of the ground wire 108. As a result, the drain wire 102 can be reliably pressed against the insulated wire 101, and the drain wire 102 can be prevented from being displaced from a predetermined position.

  The outer layer 110 serves to reinforce the inner layer 109 having low mechanical strength, and firmly presses the drain wire 102 against the insulated wire 101 to prevent the drain wire 102 from being displaced from a predetermined position. The transmission cable 100 is protected.

  In the differential signal transmission cable 100 according to the present embodiment, the line segment AB connecting the centers A and B of the two insulated wires 101 is the bottom side and the center C of the drain wire 102 is the apex in the sectional view. The isosceles triangle ABC has an apex angle θ of 74 degrees or more and 90 degrees or less.

  In order to reduce the apex angle θ of the isosceles triangle ABC, it is necessary to increase the outer diameter of the drain wire 102 relative to the outer diameter of the insulated wire 101, but the apex angle θ of the isosceles triangle ABC is set to 74. If it is less than this degree, the buried depth D of the drain wire 102 becomes too shallow and the drain wire 102 may be displaced from a predetermined position.

  Further, in order to increase the apex angle θ of the isosceles triangle ABC, it is necessary to reduce the outer diameter of the drain wire 102 with respect to the outer diameter of the insulated wire 101, but the apex angle θ of the isosceles triangle ABC. Is larger than 90 degrees, the buried depth D of the drain wire 102 becomes deep, but the protruding height H of the drain wire 102 becomes too low to firmly press the drain wire 102 against the insulated wire 101. There is a possibility that the drain wire 102 is displaced from a predetermined position.

  As described above, in the differential signal transmission cable 100, since the apex angle θ of the isosceles triangle ABC is set to 74 degrees or more and 90 degrees or less, the drain wire 102 is not easily displaced from a predetermined position, and is stationary compared to the conventional case. It is possible to reduce the inward propagation delay time difference in the state, and also to reduce the inward propagation delay time difference after being bent or after cabling.

  For example, the differential signal transmission cable 300 according to the related art has an inward propagation delay time difference of about 7 ps / m or more and 12 ps / m or less in a stationary state, and an inward propagation delay time difference after bending or cabling of about 15 ps / m. The differential signal transmission cable 100 has an inward propagation delay time difference of about 5 ps / m to 6 ps / m in a stationary state, and is inward in a bent state or after cabling. The propagation delay time difference can be about 5 ps / m or more and 7 ps / m or less, and the inward propagation delay time difference hardly changes between the stationary state and other states.

  Therefore, in the differential signal transmission cable 100, as compared with the differential signal transmission cable 300 according to the prior art, the attenuation curve indicating the change in loss due to the signal frequency becomes a gentle curve without suckout, and is about 10 GHz. It is possible to suitably transmit the high frequency signal.

  Since the differential signal transmission cable 100 has a small difference in inward propagation delay time after cabling as described above, a plurality of (for example, eight) differential signal transmission cables as shown in FIG. 100 is assembled (for example, twisted together with another cable 201) to form a differential signal transmission collective cable 200, so that the differential signal transmission collective cable 200 having a smaller difference in inward propagation delay time compared to the prior art can be obtained. Can be obtained.

100 Cable for differential signal transmission 101 Insulated wire 102 Drain wire 103 Twinax cable with drain wire 104 Shield tape 105 Signal line conductor 106 Solid insulation layer 107 Signal wire strand 108 Ground wire strand 109 Inner layer 110 Outer layer 200 Differential signal transmission Collective cable 201 Other cables

Claims (5)

Two insulated electric wires having a circular cross section are arranged in contact with each other in parallel, and one drain wire is arranged in parallel with the two insulated wires in contact with both of the two insulated wires. A twinax cable with a drain wire;
A shield tape wound around the drain wire-attached twinax cable;
With
The vertical angle of an isosceles triangle having a line connecting the centers of the two insulated wires in a cross-sectional view as a base and having the drain wire center as a vertex is 74 degrees or more and 90 degrees or less,
The drain wire is pressed against the insulated wire by the shield tape so that the distance between the center of each of the two insulated wires and the center of the drain wire is equal,
The apex angle (74 degrees or more and 90 degrees or less) of the isosceles triangle is determined by the size of the outer diameter of the drain wire with respect to the outer diameter of the insulated electric wire having a circular cross section.
A differential signal transmission cable characterized by that.   The insulated wire has a signal line conductor and a solid insulation layer formed around the signal line conductor, and the solid insulation layer has a Shore hardness of D50 or more and D65 or less, and a dynamic friction coefficient of an outer surface. 2. The differential signal transmission cable according to claim 1, wherein is 0.1 MPa, 3 m / min or more and 0.3 MPa, 3 m / min or less.   The differential signal transmission cable according to claim 1, wherein the drain wire is formed by twisting a plurality of ground wire strands.   The differential signal transmission cable according to claim 3, wherein the shield tape is wound in a direction opposite to a twisting direction of the ground wire.   5. A differential signal transmission aggregate cable, comprising a plurality of differential signal transmission cables according to claim 1 assembled together.

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