DE966237C - Overvoltage protection device for telephone lines and devices - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUED JULY 18, 1957

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21c GROUP 72 INTERNAT. CLASS H 02d

K 22293VIIIb 12i c

Heinz Krone, Ludwigsburg (Württ), and ®r. ^ Ng. Heinrich Riedel, Darmstadt

have been named as inventors

Krone G.m.b.H., Ludwigsburg (Württ.)

Surge protection device for telephony lines and devices

Patented in the territory of the Federal Republic of Germany on May 20, 1954

Patent application published on August 2, 1956

Patent issued July 4, 1957

The invention relates to an overvoltage protection device for telephony leaders and -Devices.

The through neighboring power lines in telephone and other telecommunication lines Any overvoltages that occur are generally rendered harmless by surge arresters.

These surge arresters usually consist of a largely evacuated or gas-filled one

ίο Discharge vessel in which two electrodes meet one another face each other at a relatively short distance. The filling pressure of the arrester vessel and the The distance between the electrodes is such that a discharge occurs at a voltage of 100 to 300 V. between the electrodes, which can divert currents of several amps.

Around the discharge vessels against high currents to protect, such as in the event of thunderstorm overvoltages or even direct lightning strikes can occur in the lines, a coarse radio link is connected in parallel to the discharge vessel, which by appropriate choice of the

709 591/18

Their electrodes opposite one another in air had a response voltage of 1500 is set to 3000 V.

When operating such surge arresters, however, it has been shown that occasionally overvoltages can occur whose voltage value is not so high that the coarse protection spark gap responds, the energy content of which is nevertheless so great that the discharge vessel is overstressed or can even be destroyed. Especially with telephone lines that are in the immediate vicinity of high-voltage lines run, such energy peaks, which endanger the surge arrester, can occur. if short-circuit currents flow in the high-voltage lines.

In order to protect the discharge vessels against such overloads, one already has proposed to short-circuit the discharge vessels when larger leakage currents occur and to divert the high currents via the short circuit to earth. The one for this Purpose-used devices have a number of disadvantages. Either they are Short-circuit or bridging contacts arranged in the arrester vessel itself, then they do the The arrester is expensive to manufacture and difficult to monitor and control, or the bridging contacts are outside the arrester and are controlled by special control devices (e.g. relay) switched on when the current intensity in the gas discharge path increases has reached a certain value that is still harmless for the arrester.

In these known designs, it is more difficult to control the bridging contacts To be carried out in such a way that the contacts close quickly and again properly after the high arrester current has decayed be opened.

The invention has the purpose of eliminating the above-mentioned disadvantages of the known embodiments to avoid surge arresters and to create a protective device that is effective even at low Overvoltages respond properly and quickly, but if one is exceeded at will to be selected value of the arrester current through arranged parallel to the discharge path Switching contacts is bridged. The order should be made so that after the sinking of the arrester current to a value that is no longer dangerous for the gas discharge path can, the bridging is canceled and thus the initial state when the arrester responds is restored.

According to the invention, the object outlined above is achieved in that in a protective device of the type mentioned connected with a pole to the lines to be protected, as Discharge vessels acting on surge conductors are assembled with switching relays whose in Row with the discharge vessels connected and the second pole of the arrester vessel with each The windings connecting the earth consist of two winding parts connected in series, of the first many turns with a small cross-section and the second a few turns has a larger cross-section, while the switch contacts of the Re- ' lais the line to be protected with the junction of the two relay windings directly connect and thus the arrester vessel and the small cross-section with many turns Bridge part of the switching relay windings when the relay responds.

With a suitable design of the relay windings, you have the pick-up current in your hand of the relay to the value that the gas discharge vessels can safely withstand without being endangered by overload. The first part of the relay winding can be used for a relatively small amperage can be designed, as it is also through the bridging contacts the switching relay is protected from excessive stress; only the second part of the relay winding is to be dimensioned in such a way that it absorbs the currents flowing through the bridging contacts can endure safely and for a long time.

In the event of higher overvoltages on the line to be protected, the coarse protection spark gap speaks at; this ensures that an overload of the bridging contacts and the second part of the Relay winding is excluded.

The protective device according to the invention can advantageously be simplified by that the two discharge vessels intended for the protection of a pair of lines, which are connected to their one pole is connected to one of the two lines of the line pair, with the other Pole together on the part of the wick that has many turns with a small cross section ment of a switching relay can be connected, which actuates a double contact that connects the two lines at the same time directly connects to the junction of the two relay windings, when the relay responds.

With such a design, two discharge paths are required for a line pair to be protected, but only a double-pole switching relay is necessary. This has the advantage that the space requirement the protective device is relatively small and the parts assemble tightly but clearly permit.

It is possible in this way, a protective device of the type described, which consists of several consists of individual surge arresters designed to protect a pair of lines, assemble in a relatively small common housing and to a common To connect the earth rail.

The clarity in the housing is achieved in that the protection of a pair of lines The necessary parts are combined in an installation unit, the two connection terminals for the line connections, two coarse

protective spark gaps, two discharge vessels and a double-pole switching relay with subdivided relay winding includes.

On the basis of detailed tests it has been found that for the design of the individual parts of the protective device, the following response or load values are most advantageous:

Response voltage of the discharge vessel approx. 230 V, response current of the relay 1.5 A, highest Load current of the bridging contacts 20 to 30 A, response voltage of the coarse protection spark gap around 2000 B.

A protective device designed according to this data can be used both for protection of overhead lines as well as for the protection of cables can be used successfully without any Changes or settings to the devices are required. As discharge vessels (Surge conductors) can be completely normal small ones. for temporarily occurring peak currents of A few ampere sized vessels are used, the dimensions of which are small and their price is extremely low. You get there - because the switching relay is only relatively small Has dimensions ■ - too closely assembled protective units, which - even if it is The protection of a multi-core cable or a multi-core air line is too remarkable small dimensions of the housing required to accommodate the protective device to lead.

In the drawing, the invention is shown for example; it shows

Fig. Ι a basic circuit diagram of the protective device, how it is used to protect a two-wire telephone line,

FIGS. 2 and 3 show the assembly of the parts shown in the circuit diagram of FIG. 1, in elevation and supervision.

The two cores to be protected 1 and 2 of a telephone line are each over a coarse protection spark gap 3 or 4 connected to earth 5. These coarse protection spark gaps are at a response voltage of about 2000 V and are used to dissipate very high overvoltages like them can occur during thunderstorms and other atmospheric invitations.

The two gas-filled surge arresters 6 and 7, for a response voltage of about 230 V are designed to protect cables 1 and 2 against overvoltages moderate altitude to protect. The vessels 6 and 7 are each connected to one pole with the lines 1 and 2, with the other pole connected to the winding 8 of a common relay 9. The relay 9 is a Scbaltrelais, the double-pole switching contacts 10 and 11 closes. The winding 8 of the relay 9 is in two different winding parts divided, namely the consisting of many turns of thin wire Winding part 8 'and the winding part 8 "comprising a few turns of thicker wire. Both winding parts are connected in series tet and establish the connection between the surge conductors 6 and 7 and the earth 5. The double-pole switch contacts already mentioned above 10 and 11 of the relay 9 are on the one hand with each one wire 1 or 2 of the line to be protected connected, on the other hand with the connection point between the two series-connected relay windings 8 'and 8 ".

When an overvoltage occurs on lines 1 and 2 to be protected, it initially becomes apparent in the surge arrester! 6 and 7 a glow discharge (if only small surges) or an arc discharge (in the case of larger overvoltage energy). Reaches the strength of the diverted current a value of 1.5 A, the relay 9 is excited so far via the windings 8 'and 8 "that it attracts its armature and thus the double-pole switching contacts 10 and 11 closes. By the When these contacts are closed, lines 1 and 2 are connected to the junction of the windings 8 ' and 8 ″ in relay 9 and thus the two surge arresters 6 and 7 and the thin-wire one Winding part 8 'bridged. The amounts of electricity present on lines 1 and 2 can now use the double-pole Switching contacts ι ο and '11 and, the winding part 8 " of the relay 9 flow to earth without the surge arresters 6 and 7 and the thin-wire Winding part 8 'of the relay 9 are unacceptably loaded. Does the leakage current that flows back through the contacts 10 and 11, so the excitation of the relay by the winding part is sufficient 8 "no longer to hold the armature of the relay; the armature falls off, and the double-pole Contacts 10 and 11 are opened. The holding force of the relay is adjusted so that the after opening contacts 10 and 11 again Residual leakage current flowing through the surge arrester, which also flows through the winding 8 'of the Relay flows, not enough to make the Rflais respond again, so that a "pumping" is excluded. After the overvoltage has been discharged, the protective device is back in place in the initial state; it is then ready for any overvoltage that may occur again derive. no

The assembly of the parts of a protective device shown in FIGS. 2 and 3 shows only a selected arrangement of these parts. It is of course possible to have the parts in any other way to assemble.

The most essential parts in Figs. 2 and 3 are denoted by the same numerals as that corresponding parts in the circuit diagram according to FIG. The two lines, not shown are attached to the in a common base i «o 12 seated clamping screws 13 and 14 connected. The two coarse protection spark gaps 3 and 4 are in surge arrester bases 15 and

16 arranged in a row with the surge arresters 6 and 7 supporting bases

17 and 18 are arranged. The relay 9 is in the

Housing 19 housed, the cover of which after removal of the screw plug 20 can be pulled up to make the relay contacts accessible for the purpose of checking.
The surge arrester base and the clamping screws are mounted on a frame 21, on the underside of which the connecting lines 22 are laid. The earth rail 23 is also located within this frame 21.

2 and 3 show a section of a larger housing in which a number of Protective devices for telephone lines are built in. The protective devices are in the common housing arranged close to one another; for each double line there is a device group provided, as shown in FIGS. 2 and 3. The earth rail 23 runs through all of them Groups of the housing through it, it is via an earth connection with a particularly good earth tied together.

Such housings containing a large number of individual protective devices can z. B. for overhead lines at the top of an overhead line mast and for cable lines or smaller telephone exchanges be housed in a switching device or the like.

For the purpose of monitoring the functioning of the protective devices, it is advisable to use one or the other protective device with a counter, e.g. B. a step counter, to be provided, that - depending on the setting of its sensitivity - either every response of the arrester counts or the counter only advances when the relay 9 is addressed and the discharge vessels has short-circuited. Such registration is useful when making an investigation about the causes of the overvoltages occurring on the telephone lines. For a time definition of the frequency of response of the protective device, it should be in a recommend in such cases to build in a writing device that, depending on the time, the Disturbances, d. H. the respective response of the protective device is registered.

Claims (6)

PATENT CLAIMS: i. Surge protection device for telephone lines and devices, which from one of the number of coarse and fine protection devices corresponding to the number of lines to be protected, z. B. spark gaps and discharge vessels, characterized in that the one pole to the protective lines are connected and acting as surge arresters are assembled with switching relays, their connected in series with the discharge vessels and each the second pole of the arrester vessel windings connecting to earth consist of two winding parts connected in series, the first of which many turns of small cross-section and the second a few turns of larger cross-section has, while the switch contacts of the relays, which are designed as on / off switches, have to Connect the protective line directly to the junction of the two relay windings and so the arrester vessel and the small cross-section with many turns Bridge part of the switching relay windings when the relay responds. 2. Overvoltage protection device according to claim 1, characterized in that the for the protection of a pair of lines, two discharge vessels, which with one Pole are each connected to one of the two lines of the line pair, with their other Pole together on the part of the having many turns with a small cross section Switching relay winding are connected and the switching relay actuates a double contact, of the two lines at the same time with the junction of the two relay windings connects immediately when the relay responds. 3. Overvoltage protection device according to claim 1 or 2, characterized in that the individual go Surge arrester assembled in a common housing and connected to a common Earth rails are connected. 4. Overvoltage protection device according to claims 1 to 3, characterized in that that the parts necessary for the protection of a pair of lines to a built-in unit are summarized, the two terminals for the line connections, two coarse protection spark gaps, two discharge vessels and a double-pole switching relay with a split relay winding. 5. Overvoltage protection device according to claim 1 or one of the following claims, characterized in that the surge arresters are designed for a response voltage of around 230 V and the response current for the relay is about 1.5 A. 6. Overvoltage protection device according to claim 1 or one of the following claims, characterized in that the switching contacts of the relay for a current of about 20 to 30 A. 1 sheet of drawings © 609 577/370 7.56 (709 591/1 «. 7.57)