FI88555B - OEVERSPAENNINGSSKYDD FOER LAONGSTRAECKT KOPPLINGSPLINT MED FLERA KOPPLINGSELEMENT - Google Patents

Description

1 88555 Overvoltage protection for elongated terminal block with multiple connection elements

TECHNICAL FIELD The present invention relates to the technical field of surge protection for terminal blocks. The invention relates to an overvoltage protection for such a terminal block having several interconnecting elements for connecting a plurality of electrical conductors, the overvoltage protection comprising at least one earth electrode and a plurality of protective electrodes, which electrodes are provided. isolated from each other and with intermediate air gap gaps. The surge protector is useful as box protection for cable networks with a surge voltage of the order of 10 kV or more.

The state of the art

It is common to use surge protectors of various kinds to protect cable networks and connected equipment against surges caused by, among other things, lightning strikes. Several 20 different types of surge protectors for connection to different connection points in connection cabinets apply surge protectors with a plurality of noble gas tubes 1 cassettes. Such overvoltage protection generally works well and can have a nominal ignition voltage of the order of 300-600V. A disadvantage of such surge protectors is that in certain contexts they can be comparatively expensive.

Since a very long time, it has been known to provide air spark gaps in surge protectors. These can be manufactured at a low price at least if the tolerances are not too tight and the air gap gaps are not too short.

In telephone contexts, it is common to use pairs of conductors to transmit signals. In pairs of conductors of substantially the same distance, overvoltages can occur either simultaneously on both conductors of the pair in relation to ground or between the two conductors of the pair.

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Therefore, it is desirable that an overvoltage protection device connected to the conductor pair protects against overvoltage on either of the conductors in the relative to ground and protects against overvoltages on either conductor relative to the other conductor in the pair.

Cable terminals in cable networks are normally designed to electrically connect a plurality of first conductors to each of a plurality of second plurality of second conductors. For example, in the telephone context there are elongated connecting terminals with row-arranged connecting elements for connecting 10 pairs of incoming conductors to 10 pairs of outgoing conductors. In this case, overvoltages may occur between nearby conductors in different pairs, which overvoltages the terminal block and other equipment may need to be protected against. Disclosure of the Invention

It has hitherto been a simple and inexpensive manufacture of reliable overvoltage protectors for such terminal blocks which have several insulated connectors for the connection of a plurality of electrical conductors, which overvoltage protectors have had a substantially lower ignition voltage than the voltage at which transfers normally occur in the terminal block. Overvoltage protection with noble gas pipes has in some contexts been considered to be too expensive, while overvoltage protection with air spark gap has become too unreliable and difficult and / or expensive to manufacture. The invention aims to solve this problem and create an overvoltage protection that is sufficiently reliable and simple and inexpensive to manufacture as well as well adapted to modern terminals and cables.

What is characteristic of an overvoltage protection according to the invention and preferred embodiments thereof are stated by the independent and the independent claims respectively. Somewhat simplified, it can be said that the surge protector comprises at least one ground electrode for connection to an earth conductor and a plurality of protective electrodes for connection to the coupling terminal's coupling elements, which ground electrode and which protector electrodes in the surge protector second are provided and with intermediate air gaps, which air gaps determine the nominal ignition voltage of the surge protector. Accordingly, according to the invention, the earth electrode and protective electrodes are designed and disposed in such a manner relative to each other in the overvoltage protection that the nominal ignition voltage between the earth electrode and an arbitrary protective electrode is substantially equal to the nominal ignition voltage between the protective electrode and the protective electrode.

Preferably, for at least the most protective electrodes, the nominal ignition voltage between a protective electrode and an earth electrode is substantially equal to the nominal ignition voltage between the protective electrode and each of two other protective electrodes, substantially higher.

In a preferred embodiment of overvoltage protection, the protective electrodes are arranged in a row, the nominal ignition voltage between two arbitrary consecutive protective electrodes being substantial. . 25 equal to the nominal ignition voltage between the protective electrode and the ground electrode.

In a preferred embodiment of overvoltage protection for elongated connecting terminals with radially arranged connecting elements, the earth electrode is elongated with its longitudinal direction in the longitudinal direction of the connecting terminal, the protective electrodes being on the same side of the earth electrode as seen in the earth electrode length.

Preferably, the earth electrode and the protective electrodes are made of a metal alloy, which metal alloy has at least in the areas of the electrodes where coating <88555 can be coated with nickel, on which coating a tin layer is applied.

Preferably, the air gap between the ground electrode and the protective electrodes and the air gap between the protective electrodes have a minimum length of 0.6-0.8 mm. Preferably the nominal ignition voltage is about 4 kV.

Designing a surge protector according to the invention provides advantages from a cost, manufacturing and reliability point of view, each of which being particularly prominent in preferred embodiments. The primary and perhaps most important advantage is that the air gap that determines the nominal ignition voltage can be made comparatively Large in relation to the maximum allowable voltage between pairs of conductors in the connector, about 0.6-0.8 mm at about 4 kV . This is because the spark air gap between adjacent protection electrodes, which are connected to adjacent coupling elements in the terminal block, is substantially as large as the spark air gap between the earth electrode and the respective protection electrode, whereby the single-circuit overvoltage protection occurs protective electrodes as between a protective electrode and an earth electrode.

The comparatively large air gaps allow the manufacture and mounting of the electrodes with comparatively high tolerance. Manufacturing and mounting the electrodes in a surge protector with comparatively large air gap gaps and large tolerances is significantly cheaper than the corresponding manufacturing at air spark gaps that are small or have small tolerances. If the earth electrode is elongated and the protective electrodes are arranged with the air gap determining the air gap to the electrodes only on one side of the earth electrode, the earth electrode and the protective electrodes can be given a design which is particularly simple and inexpensive to manufacture.

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The comparatively large air gap gaps reduce the risk of short-form bridges being formed over the air gap of material from the electrodes in conjunction with the breakdown. This risk becomes particularly small if the electrodes are made of a metal alloy with a coating of nickel, on which coating a tin layer is applied. As a result, the reliability of the surge protector is increased.

Further advantages of an surge protector according to the invention will be appreciated by those skilled in the art after studying the following description of preferred embodiments of surge protectors.

Figure Description

Figure 1 illustrates a terminal block mounted on a grounded terminal block to which terminal terminal an overvoltage protection according to the invention is connected.

Figure 2 illustrates how protective electrodes in an overvoltage protection can be electrically connected to coupling elements in a terminal block of Figure 1.

Figure 3 illustrates a preferred configuration and preferred arrangement of an elongated earth electrode and protective electrodes in an elongated overvoltage protection as seen in the longitudinal direction of the overvoltage protection.

Figure 4 illustrates a preferred design and preferred arrangement of a single-elongated earth electrode and protective electrodes in an elongated surge protector seen from one longitudinal side of the surge protector.

Figure 5 illustrates a preferred configuration and preferred arrangement of an elongated ground electrode and protective electrodes in an elongated surge protector 30 seen from the top, seen from the top, i.e. in the direction of the terminal block.

Embodiments Figure 1 illustrates a terminal block 1, which is attached to a grounded terminal block 2. The terminal block is of the known type marketed by Ericsson Network 6 88555

Engineering under the designation NER 25101 or described in Swedish patent application 8702766-0. The plinth holder is of the type marketed by Ericsson Network Engineering under the designation NBH 12301.

5 An overvoltage protection 3 is connected to the terminal block. The overvoltage protection has an elongated surface three shape with approximately the outer dimensions of a known overvoltage protection which is marketed by Ericsson Network Engineering under the type designation NFD 25111. When connecting the overvoltage protection 3, the underside of the overvoltage protection is inserted in the connection terminal similar to the above terminal block. known overvoltage protection NFD 25111.

the surge protector comprises an elongated earth electrode 4 and a plurality of protective electrodes 5 mounted in a protective body of electrically insulating plastic. On the upper side of the protective body, the surge protector has a plastic cap 7. For connection of the grounding electrode to the earth conductor or the terminal holder, the surge protector has two contact means 8, which contact members protrude from the protective body at the bottom at each end of the surge protector. The contact means 8 are thus located in a similar manner to the corresponding contact means of the known surge protector NFD 25111.

In Figures 2-5, the protective body or cover is not shown, but only the earth electrode and the protective electrodes to more clearly show the shape, position and orientation of the electrodes relative to each other. The earth electrode 4 is elongated and has frayed its end portions substantially the shape of a straight ribbon of rectangular cross-section. At each end, the earth electrode has end portions including the contact member 8.

The terminal block 1 is intended for connection of up to 20 incoming conductors 9 to each of up to 20 outgoing conductors 10. The terminal block has arranged in series 7 68555 isolated elements 11 for connecting the conductors. Each coupling element consists of two parts, 11a and 11b, respectively. the surge protector has 20 protective electrodes 5 designed for connection to each of its coupling elements by abutting against opposite sides of a shank of the part 11a.

The protective electrodes are the same between each other. Each protective electrode comprises a substantially disc-shaped elongate portion 12 extending transversely through the protective body. In the elongate portion there is a slot for the shank of the terminal block part 11a. Each protective electrode also includes a substantially U-shaped portion 13 having substantially the same wall thickness as the elongate portion. The U-shaped portion 13 connects to the elongate portion 12 at one of its legs 14. Preferably, the U-shaped portion shape has been achieved by bending a straight strip-shaped portion.

The protective electrodes are secured to the protective body of plastic so that their elongate portions extend substantially parallel to each other and so that the elongate portions are arranged in a row in the longitudinal direction of the surge protector on one side of the earth electrode. Furthermore, the protective electrodes are attached to the plastic body so that the U-shaped portions are free and are arranged in a row 25 in the longitudinal direction of the surge protector with substantially parallel legs 14 and substantially perpendicular to the longitudinal direction of the voltage protection. The bonding portions 16 of the U-shaped portions 16 between the legs are generally straight and oriented substantially parallel to each other 30 and the ground electrode 4 on one side of the ground electrode.

The smallest distance between two adjacent protective electrodes is the distance between the one leg of one protective electrode 14 and the leg of the other protective electrode 15. This distance is essentially the same for all the protective electrodes. The smallest distance between the ground electrodes and the portion of a protective electrode not fully covered by the protective body is the distance between the bonding portion 16 and the ground electrode. This distance is substantially the same for all protective electrodes and substantially equal to the minimum distance between two adjacent protective electrodes and may preferably amount to 0.6-0.8 mm. The nominal ignition voltage between the earth electrode and any protective electrode is therefore substantially equal to the nominal ignition voltage between the protective electrode and at least one other protective electrode. The nominal ignition voltage may preferably be about 4 kV.

The protective electrodes and the ground electrodes preferably have a slightly rounded shape at opposite sides of each other to avoid tip effects. To reduce the risk of electrode material splashing and forming bridges between the electrodes, the electrodes are made of a tin bronze alloy, which is nickel-plated and provided with a tin coating at least in those areas of the electrodes where the distance between the electrodes is at least. Preferably, however, the entire electrodes are nickel-plated and coated with a tin layer.

For fixing the distance of the U-shaped portions to the ground electrode, the U-shaped portions may have recesses 17 at their upper edge and the cover 7 has a guide flange 25 on its underside, which rigid flange is designed for engagement with the recesses.

The invention is not limited to overvoltage protection which fully corresponds to Figures 1-5 or to overvoltage protection which can only be used in the known coupling ring NER 25101. Overvoltage protection according to the invention can advantageously also be used with other longitudinal coupling terminals with arranged in a row for a plurality of conductors.

Claims (9)

Surge protector (3) for a connection base (1) having a plurality of isolated switching elements (11) for connecting a plurality of electrical conductors (9, 10), the overvoltage protection comprising at least one ground electrode (4) for connection to a ground conductor and a plurality of protection electrodes ( 5) for connection to the switching elements of the switching base, which ground electrode and which protection electrodes in the overvoltage protection are arranged in isolation from each other and at mutual air gaps, which air gaps are dominant for the nominal overvoltage protection 15 with respect to each other in the surge protector, that the nominal ignition DC voltage between the ground electrode and the arbitrary protection electrode is substantially equal to that between the ignition DC voltage protection electrode and the at least one other protection electrode. Surge protector according to claim 1, characterized in that for at least most protection electrodes the nominal supply voltage between the protection electrode and the ground electrode is substantially equal to the nominal ignition DC voltage between the protection electrode and each of the two other protection electrodes while the nominal ignition voltage between the two protection electrodes. between the protective electrodes is substantially higher. Surge protector according to Claim 1 or 2, characterized in that the nominal ignition DC voltage is approximately 4 kV. Surge protector according to Claim 1 or 2, characterized in that the air gap between the ground electrode and the protective electrode and the mutual air gap between the protective electrodes are at least 0.6 to 0.8 in length. mm. 12 38555 Surge protector according to Claim 3 or 4, characterized in that the ground electrode and the protective electrodes are made of a metal alloy, which metal alloy has a nickel coating on which at least the areas of the electrodes in which the excess occurs occur. Surge protector according to Claim 1 or 2, characterized in that the protective electrodes are arranged in rows, the nominal ignition DC voltage between two arbitrary successive protective electrodes in one row being substantially equal to the nominal ignition DC voltage between the protective electrodes and the ground electrode. Surge protector according to Claim 1 or 2 for an elongate switching base (1) with connecting elements (11) arranged in rows therein, characterized in that the ground electrode (4) is elongate in its longitudinal direction in the longitudinal direction of the switching base and that the ignition electrodes (5) are grounded. 20 trods on the other side as viewed in the longitudinal direction of the ground electrode. Surge protector according to Claim 1 or 2, characterized in that the ignition electrodes are substantially similar to one another and each comprise an elongate part (12) and an elongate substantially U-shaped part (13) connected to the other end, with U the shaped part has two substantially parallel branches (14, 15) and a substantially flat connecting part (16) between the branches. Surge protector according to Claim 8, characterized in that the elongate part has a slot for inserting the coupling element (11) into the coupling base. I,,