JP7392528B2 - Communication composite cable - Google Patents

Description

TECHNICAL FIELD The present invention relates to a composite cable, and particularly to a composite communication cable having a plurality of communication cables.

A communication composite cable having a plurality of communication cables with different transmission bands is known. As an example of such a communication composite cable, there is known a jumper cable for railway vehicles that includes two or more LAN (Local Area Network) cables with different transmission frequency bands.

Japanese Patent Application Publication No. 2017-188249

The inventor of the present invention has found that a value (peak value) exceeding a predetermined reference value occurs at a certain frequency with respect to return loss in a communication composite cable. As a result of conducting research based on this knowledge, it was confirmed that no abnormality was observed in the return loss of each individual communication cable included in the communication composite cable. Specifically, when the return loss was measured individually for multiple communication cables before the composite communication cable was manufactured, no peak value was observed. On the other hand, in a communication composite cable in which a plurality of communication cables were twisted, the occurrence of a peak value was confirmed in at least one communication cable.

Therefore, the present inventor conducted further research in order to realize a communication composite cable in which no return loss exceeding a predetermined standard value occurs in any communication cable, and finally completed the present invention.

An object of the present invention is to realize a communication composite cable in which no return loss exceeding a reference value occurs in any of the communication cables.

The communication composite cable of the present invention includes a plurality of communication cables twisted at a predetermined twisting pitch and having different transmission bands. The predetermined twisting pitch of the plurality of communication cables is P, the transmission band of the communication cable with the widest transmission band among the plurality of communication cables is f, and the insulation layer of the insulated wire included in the communication cable. When the dielectric constant of is ε and the speed of light in vacuum is c, the relationship P≦c/(√ε×f)×1/2 holds true.

In one aspect of the present invention, at least the communication cable having the widest transmission band includes a plurality of twisted wire pairs twisted in a direction opposite to the twisting direction of the plurality of communication cables including the communication cable, Each of the twisted wire pairs is composed of a plurality of twisted insulated wires.

In another aspect of the present invention, the communication composite cable includes five of the communication cables. The predetermined twist pitch of the five communication cables is 160 mm or less, the transmission band of three communication cables among the five communication cables is 600 MHz, and the transmission band of three communication cables among the five communication cables is 600 MHz. The transmission band of the two communication cables is 100 MHz, and the dielectric constant of the insulating layer of the insulated wire included in the three communication cables having a transmission band of 600 MHz is 2.3.

In another aspect of the present invention, the communication composite cable includes a tension member, five of the communication cables arranged around the tension member, and an interposition arranged around the tension member and the communication cables. has.

According to the present invention, a communication composite cable is realized in which no return loss exceeding a reference value occurs in any of the communication cables.

FIG. 1 is a sectional view showing an example of a communication composite cable of the present invention. FIG. 2 is an explanatory diagram schematically showing the twist pitch of a communication cable.

An example of an embodiment of the communication composite cable of the present invention will be described below. The communication composite cable according to this embodiment is a jumper cable laid across two railway vehicles. In addition, in the following description, the same reference numerals are used in principle for the same or substantially the same configurations and elements.

The jumper cable 1 shown in FIG. 1 includes a tension member 10, a plurality of communication cables 20, an interposer 30, a holding tape 40, and a sheath 50. Note that the number of communication cables 20 included in the jumper cable 1 according to this embodiment is five. In the following explanation, each of the five communication cables 20 shown in FIG. It is sometimes called and distinguished. That is, the five communication cables 20 included in the jumper cable 1 may be distinguished by codes. However, such a distinction is merely a distinction for convenience of explanation.

The tension member 10 is disposed at the center of the jumper cable 1 and includes a high tension wire 11 and an elastic intervening layer 12 provided around the high tension wire 11. The high tension wire 11 in this embodiment is a plurality of twisted piano wires.

The elastic intervening layer 12 is made of elastomer. Specifically, the elastic intervening layer 12 is formed of a polyolefin elastomer. More specifically, the elastic intervening layer 12 is formed by extruding a polyolefin elastomer made by mixing a polyolefin rubber such as ethylene propylene rubber with a resin such as polyethylene or polypropylene around the high tension wire 11. There is.

The interposer 30 is arranged in the gap between the tension member 10 and the communication cable 20 or in the gap around the communication cable 20 so that the cross-sectional shape of the assembly of the tension member 10, the communication cable 20, and the interposer 30 is circular or approximately circular. has been done. As the interposition 30, for example, a fibrous interposition or thread-like interposition made of plastic, jute, or the like is used.

The five communication cables 20a, 20b, 20c, 20d, and 20e shown in FIG. 1 are twisted in the same direction around the tension member 10 at a predetermined twisting pitch (160 mm in this embodiment). Here, the twist pitch of the communication cable 20 refers to the crests (valleys) and crests (valleys) of the communication cable 20 in the longitudinal section of the jumper cable 1 (in a section perpendicular to the section shown in FIG. 1). is the straight line distance between. The twist pitch of such a communication cable 20 is schematically shown in FIG. As a result of the five communication cables 20a, 20b, 20c, 20d, and 20e being twisted at a predetermined pitch around the tension member 10, within the cross section of the jumper cable 1 (within the cross section shown in FIG. 1), Communication cables 20a, 20b, 20c, 20d, and 20e are arranged around the tension member 10 at equal or substantially equal intervals along the circumferential direction of the tension member 10. In the following description, the twisting direction of the communication cable 20 included in the jumper cable 1 may be referred to as a "first twisting direction."

Among the five communication cables 20 shown in FIG. 1, communication cables 20a, 20b, 20d, and 20e have the same basic structure. Specifically, the communication cables 20a, 20b, 20d, and 20e include four twisted wire pairs 21, and an inner sheath 22 and a shielding layer 23 provided around the twisted wire pairs 21. However, in the communication cable 20a, an inner sheath 22 is provided on the outside of the four twisted wire pairs 21, and a shielding layer 23 is provided on the outside of the inner sheath 22. On the other hand, in the communication cables 20b, 20d, and 20e, a shielding layer 23 is provided on the outside of the four twisted wire pairs 21, and an inner sheath 22 is provided on the outside of the shielding layer 23.

The four twisted wire pairs 21 included in the communication cables 20a, 20b, 20d, and 20e are twisted at a predetermined pitch, and the two insulated wires 24 constituting each twisted wire pair 21 are also twisted at a predetermined pitch. ing. Further, the insulated wires 24 constituting each twisted wire pair 21 include a conductor 25 and an insulating layer 26 provided around the conductor 25.

In the following explanation, the twisting direction of the four twisted wire pairs 21 included in the communication cables 20a, 20b, 20d, and 20e will be referred to as the "second twisting direction", and the two twisted wire pairs 21 making up each of the twisted wire pairs 21 will be The direction in which the insulated wires 24 are twisted may be referred to as a "third twist direction." In this embodiment, the twisting direction (second twisting direction) of the twisted wire pairs 21 provided in the three communication cables 20b, 20d, and 20e is the same as that of the five communication cables 20 including these communication cables 20b, 20d, and 20e. This is the opposite direction to the twisting direction (first twisting direction). Further, a shielding tape 27 is wrapped around each twisted wire pair 21 included in the communication cables 20b, 20d, and 20e, but no shielding tape is wrapped around each twisted wire pair 21 included in the communication cable 20a. do not have.

The communication cable 20c shown in FIG. 1 includes four twisted insulated wires 24. Each insulated wire 24 includes a conductor 25 and an insulating layer 26 provided around the conductor 25. A shielding layer 23 is provided around the four insulated wires 24 , and an inner sheath 22 is provided around the shielding layer 23 .

As the conductor 25 of the insulated wire 24 included in the communication cable 20 shown in FIG. 1, a twisted wire made of twisted metal wires made of copper or copper alloy can be used. From the viewpoint of flexibility, it is preferable to use an annealed copper wire as the metal wire. Further, it is preferable that the metal wire is plated with tin plating or the like. It is preferable to use a material with a low dielectric constant as the material of the insulating layer 26 of the insulated wire 24 included in the communication cable 20 shown in FIG. The rate is 2.3.

The communication cables 20a, 20c and the communication cables 20b, 20d, 20e have different transmission bands. Specifically, the communication cable 20a is a category 5 LAN cable (0.5 mm ² ×4P), and the transmission band is 100 MHz (according to IEC61156-6). On the other hand, the communication cables 20b, 20d, and 20e are category 7 LAN cables (AWG24×4P), and have a transmission band of 600 MHz (according to IEC61156-6). Furthermore, the communication cable 20c is a category 5 LAN cable (0.5 mm ² ×4C), and the transmission band is 100 MHz (according to IEC61156-6). That is, the jumper cable 1 is an Ethernet (registered trademark) communication composite cable including two CAT5 LAN cables and three CAT7 LAN cables. Further, among the plurality of communication cables 20 included in the jumper cable 1, the communication cables with the widest transmission band are the communication cables 20b, 20d, and 20e, and the transmission band is 600 MHz.

The thickness of the inner sheath 22 in each communication cable 20 is adjusted so that the outer diameters of the five communication cables 20 are the same or substantially the same. Here, the expression that the outer diameters of the five communication cables 20 are the same or substantially the same means that the difference in the outer diameter of each communication cable 20 with respect to the average value of the outer diameters of the five communication cables 20 is within a range of ±0.5 mm. It means that.

The inner sheath 22 of each communication cable 20 is extruded from polyolefin resin. The outermost layer (inner sheath 22 or shielding layer 23) of each communication cable 20 is in contact with the elastic intervening layer 12 of the tension member 10.

As described above, the jumper cable 1 according to the present embodiment includes a plurality of communication cables 20 having different transmission bands, and the twisting pitch of the communication cables 20 is 160 mm. Further, among the plurality of communication cables 20 included in the jumper cable 1 according to the present embodiment, the communication cables 20b, 20d, and 20e having the widest transmission band have a transmission band of 600 MHz. Furthermore, the dielectric constant of the insulating layer 26 of the insulated wire 24 included in the communication cables 20b, 20d, and 20e is 2.3.

Then, in the jumper cable 1 according to the present embodiment, the twist pitch of the plurality of communication cables 20 is P, the transmission band of the communication cables 20b, 20d, 20e having the widest transmission band is f, and these communication cables 20b, 20d, 20e When the dielectric constant of the insulating layer 26 of the insulated wire 24 is set to ε, and the speed of light in vacuum is set to c, the relationship shown in the following (Equation 1) holds true.
P≦c/(√ε×f)×1/2...(Formula 1)
Specifically, when the speed of light c is 299792458 m/s, √ε is 1.5166, and the transmission band f is 600×10 ⁶ Hz, c/(√ε×f)×1/2 is 0.1648 m (= 164.8mm). In addition, for numerical values with 5 or more digits after the decimal point, the fifth decimal place was rounded off. Therefore, in the jumper cable 1 according to the present embodiment in which the twisting pitch of the plurality of communication cables 20 is 160 mm, the relationship shown in the above (Formula 1) is established.

As a result of measuring the return loss of the communication cable 20 included in the jumper cable 1 of this embodiment, a peak value exceeding a predetermined reference value was detected in a band higher than 600 MHz, while a peak value exceeding a predetermined reference value in a band lower than 600 MHz was detected. No peak values exceeding . Specifically, when we measured the return loss when transmitting an electrical signal of a predetermined frequency using each of the communication cables 20 included in the jumper cable 1, it was found that the return loss was lower than 600 MHz in any of the communication cables 20. No return loss exceeding the standard value was detected in the band.

For comparison, a communication composite cable was prepared in which only the twist pitch of the communication cable was different from the jumper cable 1 of this embodiment, and similar measurements were performed. The twist pitch of the communication cable in the prepared communication composite cable was 230 mm. As a result, in a communication cable with a transmission band of 600 MHz, a return loss exceeding the standard value was detected near 430 MHz.

Note that the above reference value (dB) is a value calculated by the following (Equation 2) when the frequency of the electrical signal to be transmitted is f (MHz).
25-8.6log(f/20) (however, 20≦f<600)...(Formula 2)
From the above measurement results, it can be seen that in the jumper cable 1 of this embodiment in which the twist pitch of the plurality of communication cables 20 is shorter than that of the comparative example, the frequency at which return loss exceeding the reference value occurs shifts to a higher frequency. confirmed. It has also been confirmed that by setting the twist pitch of the communication cable 20 to 160 mm or less, it is possible to shift the frequency at which a return loss exceeding the reference value occurs to a frequency higher than 600 MHz.

Furthermore, from the above measurement results, if the transmission band of a communication composite cable having multiple communication cables is wider than 600MHz, by making the twist pitch of the communication cable shorter than 160mm, the return exceeding the predetermined standard value can be achieved. It is presumed that the frequency at which the loss occurs can be shifted outside the transmission band of the communication composite cable. For example, if the transmission band of a communication cable with the widest transmission band among the communication composite cables is 800 MHz, and the twist pitch of multiple communication cables including the communication cable is 123.5 mm or less, the above (formula 1) ) holds true. In this case, it is presumed that the frequency at which a return loss exceeding a predetermined reference value occurs is shifted to a frequency higher than 800 MHz.

Note that the holding tape 40 shown in FIG. 1 is a resin tape, and the shielding tape 27 is a PET tape on which aluminum is vapor-deposited. Further, the sheath 50 forming the outermost layer of the jumper cable 1 is made of a polyolefin elastomer.

The present invention is not limited to the above-described embodiments, and can be modified in various ways without departing from the gist thereof. For example, the number and types of communication cables included in the communication composite cable of the present invention can be changed as appropriate. For example, in the above embodiment, the twisted wire pairs 21 of the three communication cables 20b, 20d, and 20e are twisted in the opposite direction to the five communication cables 20 including these communication cables 20b, 20d, and 20e. . However, the communication composite cable of the present invention also includes a communication composite cable in which the plurality of twisted wire pairs of at least one communication cable are twisted in the opposite direction to the plurality of communication cables including the communication cable. included.

The high tension wire 11 shown in FIG. 1 can be replaced with a steel wire other than piano wire. Further, the elastic intervening layer 12 can be formed of a polyolefin elastomer having a composition different from the above composition, and the elastic intervening layer 12 and the sheath 50 can also be formed of materials other than the polyolefin elastomer.

1 jumper cable 10 tension member 11 high tension wire 12 elastic intervening layer 20, 20a, 20b, 20c, 20d, 20e communication cable 21 twisted wire pair 22 internal sheath 23 shielding layer 24 insulated wire 25 conductor 26 insulating layer 27 shielding tape 30 intervening 40 Presser tape

Claims (4)

A communication composite cable having a plurality of communication cables with different transmission bands twisted at a predetermined twisting pitch,
The predetermined twisting pitch of the plurality of communication cables is P,
Among the plurality of communication cables, the transmission band of the communication cable with the widest transmission band is f, the dielectric constant of the insulating layer made of polyethylene of the insulated wire included in the communication cable is ε,
Let c be the speed of light in vacuum,
When the value of the speed of light c is 299792458 m/s and the value of the transmission band f is 600×10 ⁶ Hz,
P≦c/(√ε×f)×1/2
A communication composite cable that establishes the following relationship. The communication composite cable according to claim 1,
The communication cable having at least the widest transmission band includes a plurality of twisted wire pairs twisted in a direction opposite to the twisting direction of the plurality of communication cables including the communication cable,
Each of the twisted wire pairs is composed of a plurality of twisted insulated wires,
Communication composite cable. The communication composite cable according to claim 1 or 2,
having five said communication cables,
The predetermined twist pitch of the five communication cables is 160 mm or less,
The transmission band of three communication cables among the five communication cables is 600MHz,
The transmission band of two communication cables among the five communication cables is 100MHz,
A communication composite cable, wherein the dielectric constant of the insulating layer of the insulated wire of the three communication cables having a transmission band of 600 MHz is 2.3. The communication composite cable according to claim 3,
tension member and
the five communication cables arranged around the tension member;
and an interposer disposed around the tension member and the communication cable.