DE1006465B - Device for message transmission systems for automatic monitoring, fault location and switching from operational amplifiers to replacement amplifiers in unmanned amplifier stations - Google Patents

Description

The invention relates to a device for automatic monitoring and fault location and switching in transmission systems with unmanned repeater stations, in particular for submarine cable systems with underwater amplifiers. With 5 submarine cable connections, land connections appear opposite Due to the special conditions of these systems there are additional problems, which are mainly due to this arise that the amplifier stations necessary for long connections in one housing must be housed, which can be routed with the cable. As the underwater amplifier As a result, with the cable located on the ocean floor, one would become necessary Repairs that make the departure of a cable ship necessary cause significantly higher costs than with land stations. These are always available, even if they are for reasons of personnel savings not occupied, accessible. With underwater amplifiers, the lifespan of everyone has to be electrical Parts of the amplifier station are subject to high demands. Also are as comprehensive and as possible automatically working monitoring measures for fault location and switching over to replacement units necessary, which in turn, because of the requirement to have the amplifier together with the cable to be able to lay out, should not take up a lot of space. In contrast to the land amplifier, which is practical only offers electrical problems, underwater amplifiers are electrical and mechanical Problems closely related.

Various monitoring and switching devices for underwater amplifiers are already known, but all of which either require a large amount of filters and frequencies or not a complete one Enable monitoring of all electrical parts with automatic switchover to reserve units.

It is also a device for monitoring, fault location and switching of operational amplifiers on replacement amplifiers in unmanned amplifier stations has been proposed that works fully automatically with relatively little effort on filters and frequencies. she is but only for two-wire systems with bidirectional amplifiers applicable, since the frequency transmitted by an end station for checking in a transmission band arriving in the repeater station under investigation implemented and in the opposite running transmission belt back to the end station is returned.

In the case of submarine cable connections, however, four-wire systems are often used in which each transmission direction own cable available facility

for communication systems

for automatic monitoring,

Fault location and switching

of operational amplifiers

on replacement amplifier
in unmanned amplifier stations

Applicant:
Feiten & Guilleaume Carlswerk

Corporation,
Cologne-Mülheim, Schanzenstr. 24

Dr. phil. Hans Krupp, Cologne trinkets,
has been named as the inventor

in which there are unidirectional amplifiers. In such a system, the above-described arrangement for monitoring and switching cannot be used, since it is not possible to convert and return the checking frequency. Monitoring devices for four-wire operation with unidirectional amplifiers are already known, in which a pilot frequency takes over the ongoing monitoring. To locate faults, each unmanned amplifier station is also assigned its own test frequency, which runs through this station alone, while the other test frequencies are routed around the station or the amplifier on bypass routes that are constantly switched on. This method has the disadvantage that with η amplifiers there must also be η test frequencies that are lost to the useful band. Furthermore, η - 1 test frequencies must be routed on the bypass routes around each amplifier. This requires complex filters that have to cover different frequency ranges in each station. In another known monitoring principle, in the negative feedback circuit of each amplifier by means of a selective element, for. B. quartz filter, the negative feedback made ineffective for a certain frequency assigned to this amplifier, so that this frequency compared to the other in the receiving end

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station has a larger amplitude. However, these known monitoring devices have the Disadvantage that the individual amplifier stations in their structure because of the different Differentiate the frequency position of the filters from one another. It also uses a large number of frequencies required, which in turn require a considerable amount of filtering. Also is the definition of the disturbed station is not always clear and can

Fault location and switching from operational amplifiers to replacement amplifiers in unmanned amplifier stations, especially with submarine cable connections with

also in multi-wire operation with unidirectional amplifiers is applicable and manages with a low expenditure of filters and monitoring frequencies. He-

The pilot frequency sent out to check A reaches end station B via all amplifiers by being routed around it and into the amplifier by means of the path s that bridges the bandstop filter.

When locating the fault, current always flows through the relay R ₁ in the station in which the stepping _{mechanism rw Y is} on the blind contact 4, so that the

may cause great difficulties when 10 switch T ₁ flips down. It thus switches on the special makes undesired whistling a section in which the bandpass filter Bp is located. controlled monitoring and switching impossible. This means that the amplifier V is now also

The present invention seeks to bridge and pilot frequency drawbacks around them the known monitoring devices. Wasn't the station just checked to avoid and a device for messaging 15 is disturbed, it will be based on the state of the transmission system for automatic monitoring, transmission system do not change anything as the pilot frequency

is prevented from continuing in one of the following stations, where the fault must lie. So there follows another impulse, which initiates the review of the underwater amplifiers, which both in the next 20 amplifier station. Simultaneously two wire operation with bidirectional amplifiers, as if the switch T ₁ switches off the line with the bandpass filter at the previous station, so that the pilot frequency runs through the amplifier V again. If the check is carried out at the disturbed station according to the invention, in the event of a disturbance with a 25, the error is bypassed by switching on the line with any number of unmanned amplifiers - the bandpass filter. The pilot frequency stations provided transmission system for fault location by means of the pilot frequency by direct current pulses one after the other in each amplifier station
or two switched off during normal operation 30
tete verification facilities switched on, which the
Route the pilot frequency around the amplifier under test so that the pilot frequency reappears
in the receiving end station indicates that the
bypassed station is disturbed.

The invention is explained in more detail below with reference to the drawing.

1 shows the basic circuit diagram of a repeater station with one-way traffic in four-wire operation.

The transmission direction runs from A to B. 40 _{rw oJ} is in each station with the step-switching The transmission circuit consists of the band-stop filter werkrwj coupled so that it is only open , Bsp, the band-pass filter Bp and the amplifier V. It is when in the station in question just blind through the capacitors C ₁ and C _? DC contact 4 is switched on. It is achieved separately from the supply and switching circuit. by the fact that only in the currently checked station,

The arrangement of the supply and switching circuit 45 in which the error is located, the rotary selector DW is already flowed through and hit by reversed direct current for two-way systems and is therefore only briefly discussed here with its switch dw for switching to the action will. A reserve amplifier can be operated for ongoing monitoring. In all other stations from the end station A , the rotary selector is sent through the closed station, which is received by the end station B. 50 switch rw _ül short-circuited. In the event of a malfunction, the failure to switch to the reserve amplifier causes the feed

comes back to the end station B. There your reappearance indicates that the station currently being checked must be disturbed.

When the pilot frequency reappears, the polarity reversal of the direct current supply is automatically reversed in the manner already proposed. The polarized relay P ₁ responds to this polarity reversal in all stations, whereby its switch P ₁ switches off the relay selector RWi and switches on the circuit with the rotary selector DW. This operates its switch dw, which switch to the next reserve amplifier, which is indicated with its switching elements by the index II in the drawing. The desk

Pilot frequency in station B automatically breaks down the direct current feed into pulses in the manner already proposed. The relay selector RW, which advances the stepping mechanism TW ₁ by one step, is actuated by each pulse in all amplifier stations. The indexing mechanism is formed in the previously proposed way, so that in each \ ⁷ another erstärkerstation the contacts from 0 to 5

DC reverse polarity, so that again the relay selector with the stepping mechanism to the supply circuit connected.

The circle with the glow lamp G _1, the delayed relay · E ₁ and the switch e _x is used in a conventional manner to switch on one of the operating Heizfadenbruch tubes rö _h because in such a case of supply and switching circuit is interrupted. That

is executed blind (in Fig. 1 contact 4). Each sta- 60 ignition and extinguishing of the glow lamp replaces the tion is therefore assigned a number of pulses at which direct current pulses and, like this, the switch of the stepping mechanism on which the switching of the stepping mechanisms rw _v is in blind contact. In this case the end stations are registered so that this is always the short circuit k interrupted. The feeders are informed about which station was disturbed. Direct current flows through the relay .R ₁ , whereby its 65 and has been switched.

Switch T ₁ in the checking device U ₁ actuated. FIG. 2 shows an example of how the device according to

will. of the invention is used in two-wire operation.

In the present case, according to FIG. 1, the switching system is known T ₁ in the transmission circuit is drawn upwards in such transmission systems. borrowed a cable used in both directions, whereby this position corresponds to normal operation. The 70 are the transmission belts of the two directions

differ in their frequency position. The amplifier V must be effective for both directions, which is achieved in a known manner by the high-pass and low-pass filters H and T. Because of the two transmission bands, the system can be monitored from both end stations in two-wire operation. For one direction, the pilot frequency f _{t is} transmitted by the end station A and received by the end station B. For the other direction, the pilot frequency / _{2 is} transmitted by the end station B and received by A. Corresponding to the two frequencies, there must also be two checking devices U ₂ and U ₃ , which differ only in the frequency range of their bandstop filter Bsp and their bandpass filter Bp . Otherwise, the mode of operation is exactly the same as with unidirectional amplifiers in four-wire operation. The only difference is that will be operated by the relay R ₁ corresponding to the two pilot frequencies Z ₁ and / _{2 are} two switches T _1, the over-checking device for each direction U ₂ and U _s turn. Of course, even with two-wire systems, monitoring and fault location can only be carried out from one terminal station. In this case, only one checking device is required in each repeater station. For the sake of clarity, the supply and switching circuit below the capacitors C ₁ and C _{2 is} not shown in FIG. 2, since it corresponds exactly to that of FIG.

The indirect method used according to the invention for fault location in transmission systems, where continuous monitoring and switching to reserve units is necessary, has the great advantage that it works completely independently of the structure of the circuit structure to be examined, because it sequentially removes every element in question from the system and thus determines the location of the fault. So it is unchanged for all types of transmission systems usable and solves its task with a minimum of filters and switching elements, so that the device according to the invention when placed in underwater booster stations takes up little space. In addition, it has the same structure in all stations of a system on, so that there is a stock of ready-to-use replacement stations that are sent to the for repair Cable ship must be available, much simplified.

Claims (4)

Patent claims: 1. Equipment for communication systems for automatic monitoring, fault location and switching from operational amplifiers to replacement amplifiers in unmanned amplifier stations, especially in the case of submarine cable connections with underwater amplifiers, in which one End station a pilot frequency is continuously transmitted, the absence of which in the other end station automatically locates the fault in the transmission system by sending out direct current pulses initiates and when the fault is detected in the disturbed station, the switchover is effected on the reserve amplifier by automatic polarity reversal of the direct current supply, characterized in that in the event of a fault with any number of unmanned repeater stations equipped transmission system for fault location by means of the pilot frequency by the direct current pulses one after the other in each Amplifier station one or two checking devices switched off during normal operation can be switched on, which check the pilot frequency bypassing the amplifier under test so that the pilot frequency reappears in the receiving end station indicates that the station being bypassed is disturbed. 2. Device according to claim 1, characterized in that the checking devices from a switched circuit transmission in front of the amplifier (V) band-stop filter (BSP) and a switchable parallel to bandpass filter (bp) consist of the pilot frequency. 3. Device according to claim 1 and 2, characterized in that in normal operation, the band-stop filter (BSP) through a conduit (s) responsive to a rest contact (r {), one at the fault location in the currently checked station relay (R ₁₎ bridged is. 4. Device according to claim 1 to 3, characterized in that when checking the amplifier station, the bandstop filter (Bsp) and the amplifier (V) through the series connection of the contact (r _r ) of the addressed relay (R ₁ ), the bandpass filter (Bp) and the line (s) are bridged. Considered publications:
U.S. Patent No. 2,018,851. 1 sheet of drawings © 609 869/291 4.57