JPS6218098B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a power feeding structure for an optical submarine cable. In particular, it relates to the grounding structure of the feeder line of an optical submarine cable when route separation is performed.

〔overview〕

The present invention provides a power supply structure for an optical submarine cable that separates the routes of an optical submarine cable in which a plurality of optical fiber core wires and one power supply line are interposed. By configuring the return path for the power supply current, power can be supplied to the optical repeaters independently for each land station, making adjustment of the power supply voltage and installation easier.

[Conventional technology]

Conventionally, for example, submarine cables using coaxial cables simply connect two stations on land with one submarine cable, and do not have a structure in which the cable is separated into two routes midway through the route. . A vertical transmission path is configured by dividing one coaxial cable into a high frequency band and a low frequency band and performing bidirectional transmission. For this reason, transmission capacity is determined by the highest frequency of the system, and worldwide, the maximum capacity is several thousand telephone lines below 50MHz. in this way,
Long-distance submarine coaxial cables have a single core (inner and outer conductors 1
), and it is difficult to structurally separate the routes. Although electrical branching is possible, the technology for band division and aggregation is complex, and it is difficult to install the equipment required for this on the seabed, so a route separation structure on the seabed has not been adopted. .

On the other hand, optical submarine cables generally accommodate multiple optical fibers, so if some of them can be separated, system flexibility can be obtained, and transmission lines with the necessary capacity in the necessary sections can be used. can be realized economically.

However, in order to regenerate and repeat the attenuation of optical signals transmitted through optical fibers, it is necessary to supply power from a land station to an optical repeater inserted in the middle of an optical submarine cable. Power is supplied to the optical repeaters by connecting all the power supply units of the optical repeaters in series to a feeder line interposed in the optical submarine cable, and supplying constant current from the ground station.

Earth or seawater is usually used for this power supply return path.

FIG. 10 shows the power supply structure of this conventional optical submarine cable without route separation.

That is, in FIG. 10, 10 is land station A
11 is the power feeding device installed at land station B, 12 is the optical submarine cable, 1
3 is a power supply line inserted in the optical submarine cable, 15 is a repeater inserted in the middle of the optical submarine cable, 16
1 is a repeater unit for reproducing communication signals, and 17 is a constant voltage generation circuit for supplying a constant voltage to this repeater unit. In this Figure 10, 1
is the current that flows out from the land stations A and B and supplies power to drive the repeater 15, and the arrow indicates its direction.The value of this current I is controlled to be constant, and this return path is between the earth and the ocean floor or It's seawater.

FIG. 11 shows an equivalent circuit diagram when the power feeding method shown in FIG. 10 is implemented to feed power from three land stations A, B, and C to an optical submarine cable system whose routes are separated.

[Problem that the invention seeks to solve]

In Figure 11, the optical submarine cable from land station A to branch point M is interposed with two optical fiber core wires and one feeder line, and the same applies to the optical submarine cable from land station C to branch point M. Two optical fiber core wires and one power supply line are interposed between the land station B and the branch point, and four optical fiber core wires and one power supply line are interposed between the land station B and the branch point.
The optical fiber core wires of each book are separated into two at a branch point M. The feeder line is configured to branch at a branch point M, and each feeder line is I _A , I _B , I _C
The configuration is such that a constant current of 100 kW is supplied to each repeater.

As shown in FIG. 11, when the feeder line is branched, simply branching it out results in I _B = I _A + I _C . It is very difficult to set this so that each repeater operates correctly, ie, I _A = I _B = I _C.

To solve this problem, it would be extremely expensive to install three optical submarine cables and an additional cable for the earth electrode due to the deep sea installation method.

The present invention solves the above-mentioned drawbacks and improves the grounding structure of the optical submarine cable's power supply line, thereby facilitating the adjustment of the power supply from the land station of the optical submarine cable with route separation. The purpose is to provide a power supply structure.

[Means for solving problems]

The present invention provides a power supply structure for optical submarine cables that separates a single optical submarine cable into a plurality of optical submarine cables and is equipped with a separation box that accommodates the power supply lines interposed in each optical submarine cable. The present invention is characterized in that the optical submarine cable near the separation box is provided with an earth box for connecting the power supply line to the ground.

Note that the separation box and the earth box can be formed integrally.

Furthermore, an optical repeater can be built into the separation box.

[Effect]

When separating routes on the seabed, multiple optical fiber cores are connected to one cable, so it is sufficient to simply separate them at branch points. Each optical submarine cable has only one feeder wire interposed therein. For this reason, the return path of the feeder line is grounded at the branch point. Specifically, an earth box is provided near a separation box that separates the routes of optical submarine cables, and the return path of the power supply line is grounded at this point.

As a result, a constant power supply current flows through the power supply circuit of each optical submarine cable, and each return path is grounded.

By grounding with this separation box,
Since the power supply circuit for each grounded cable becomes independent, the power supply current from the land station where the optical submarine cable is accommodated only needs to be controlled to a constant value, and there is no need to install a special power supply return line. It will no longer be necessary.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 6 is a diagram showing an example of a system configuration to which the present invention is applied, and FIG. 7 is an example of another system configuration.

The system shown in FIG. 6 has transmission paths using optical submarine cables between land stations A and B and between land stations A and C, respectively, and a separation box _S1 of the present invention.
This is an example in which optical fiber core wires are separated by.
Four optical fiber core wires are interposed between land station A and separation box _S1 . Two optical fiber core wires are interposed between the separation box _S1 and the land station C, respectively. However, each cable has only one power supply wire interposed therebetween. Power is supplied to the optical repeaters R ₁ to _{R 3} in series from land station A using the power feed line in this cable, and the return route is through the separation box.
It is connected to the underwater ground E ₁ via the external housing of S ₁ and returns to the power supply of land station A via the ground. optical repeater
Power is supplied to _R4 to _R6 from land station B and connected to underwater ground _E1 . Power is similarly supplied to the optical repeaters R ₇ to R ₉ from the land station C, and the ground E ₁ is the return route. Since the underwater grounding _E1 has a low grounding resistance, power can be supplied to each of the above sections independently. Current I ₁ flowing through each cable,
I ₂ and I ₃ can be controlled by each land station A, B, and C, respectively, so that I ₁ =I ₂ =I ₃ .

In the system shown in FIG. 7, optical submarine cable feeders are connected in series from land station A to station B, and a current I ₁ is consistently passed through, returning from the ground of station B to the ground of station A. In addition, the power supply current I ₂ from the C station is connected to the underwater ground E ₁ by a separation box S ₁ ,
The feed current I ₃ from station D is connected to the underwater ground E ₂ by a separation box S ₂ . In this case, the feeder line interposed in the submarine cable between A station and B station is
Separation boxes S ₁ and S ₂ are not connected to anything at all. Therefore, power supply for each section can be controlled independently.

FIG. 8 is a detailed connection diagram of the system shown in FIG. 6. That is, a vertical optical transmission path is formed between land stations A and B using two optical fiber cores FB, and optical repeaters R ₁ to _{R 6} and separation box S ₁ are inserted in the middle. ing. Also, between A station and C station, two similar optical fiber core wires are used.
A vertical optical transmission path is formed by the FB.
Then, in the separation box _S1 , the feeder lines PL of each optical submarine cable are commonly connected and connected to the underwater ground _E1 via the casing. Power is supplied by connecting optical repeaters in series from land stations A, B, and C, and returning through the sea from underwater ground _E1 .

The equivalent circuit of FIG. 8 is shown in FIG.

As shown in Figure 9, the power supply from each land station A, B, and C is connected to the underwater ground at separation box _S1.
Since it is grounded to E ₁ , the optical repeaters R ₁ to _{R 3} in Figure 8
Power is supplied from land station A to optical repeaters _R4 to _R6 , power is supplied from land station C to optical repeaters _R7 to _R9 , and power is supplied independently from land station A to optical repeaters R4 to R6. Become.

FIG. 1 is a configuration diagram showing an embodiment of the present invention. This figure shows the specific structure of the grounding of the above-mentioned separation box _S1 .

That is, the separation box 1 and the earth box 2 are connected by a relatively short distance, and the power feed line 7 interposed between the optical submarine cables 4 and 3 is connected to the outer casing of the earth box 2. The optical submarine cables 3 and 4 may be continuous and integrally formed cables, and may have a structure in which a power feed line 7 interposed in the cables is connected to the external casing of the earth box 2. In either case, the power supply line 7 and the connecting conductor with the external housing must be insulated and protected from seawater inside the earthing box 2, and must be grounded to the seawater via the outer surface of the external housing of the earthing box 2. There is. This separation box 1 separates four optical fiber core wires 6 from an optical submarine cable 3 into two fibers each and connects them to the optical submarine cable 5, respectively. Further, the power supply line 7 of the optical submarine cables 5 and 3 is connected to each other.

FIG. 2 shows another embodiment of the invention. In this example, the separation box 1 and the earth box 2 of the embodiment shown in FIG. 1 are integrally formed to constitute a separation box 1'. The separation box 1' separates the optical fiber core wire 6, and commonly connects the feeder line 7 of each cable to an external housing. In this case, the outer casing of the separation box 1' is made of metal, and is required to have a suitable anti-corrosion structure and coating to prevent electrical corrosion of the metal parts. Contact with seawater is made through the outer surface of the outer casing or a ground plate (not shown) connected to the outside of the outer casing.

Figure 3 shows a similar separation box 1"
An embodiment in which an optical repeater 9 is built in is shown. In this example, since it also serves as an optical submarine repeater, there is no need for an independent separation box, and the number of boxes inserted into the cable is reduced, which is economical.
It is also advantageous in terms of installation.

FIG. 4 is an external view of the embodiment shown in FIG. 1, which has a structure in which a separation box 1 and an earth box 2 are connected by an optical submarine cable 3.

FIG. 5 is an external view of the embodiment shown in FIG. 2.

〔Effect of the invention〕

As explained above, in the present invention, the optical fiber core wires are separated by the separation box, and the power supply lines are connected to the ground by the earth box, so that the power supply circuits are connected to their respective return paths by the earth box. By doing so, each cable becomes independent. Therefore, by appropriately separating the routes of the optical submarine cable, it is possible to realize a transmission path of any capacity between three or more land stations.

Furthermore, since power can be supplied independently from each land station, it is easy to adjust the supplied current. Furthermore, since the power supply section is shortened, the voltage will be lower, making it possible to lay optical submarine cables at a lower cost.

Furthermore, since the power feeding section is independently operated, it is easy to isolate the faulty section, and the fault point can be located in a short time and with high precision.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram showing an embodiment of the present invention. Second
The figure is a configuration diagram showing another embodiment of the present invention. FIG. 3 is a diagram showing an embodiment incorporating an optical repeater. FIG. 4 is an external view of the embodiment shown in FIG. 1. FIG. 5 is an external view of the embodiment shown in FIG. 2. FIG. 6 is a diagram showing an example of a system configuration to which the present invention is applied. FIG. 7 is a diagram showing an example of another system configuration to which the present invention is applied.
FIG. 8 is a detailed explanatory diagram of the system shown in FIG. 6.
FIG. 9 is an equivalent circuit diagram of FIG. 8. 10 is an explanatory diagram of a conventional optical submarine cable system. 11 is an equivalent circuit diagram of a system to which the conventional example is applied. 1, 1', 1''...separation box, 2...
Earthbox, 3-5... Optical submarine cable, 6...
Optical fiber core wire, 7... Power supply line, 8... Undersea grounding, 9
...Optical repeater, 10, 11...Land station, 12...Optical submarine cable, 13...Power line, 15...Optical repeater, 16
...Optical repeater unit, 17... Constant voltage generation circuit,
A, B, C, D...land station, _R1 to _R9 ...optical repeater,
S ₁ ~ _{S 2} ...Separation box, FB...Optical fiber, PL...Power line.

Claims (1)

[Claims] 1. A power supply structure for an optical submarine cable that separates a single optical submarine cable into a plurality of optical submarine cables and includes a separation box that accommodates a power supply line interposed in each optical submarine cable. A power supply structure for an optical submarine cable, characterized in that the optical submarine cable near the separation box is provided with an earth box for connecting the power supply line to ground. 2. The power supply structure for an optical submarine cable according to claim 1, wherein the separation box and the earth box are integrally formed. 3. A power supply structure for an optical submarine cable according to claim 1 or 2, in which an optical repeater is built in a separation box.