SK285077B6 - Pluggable surge arrester - Google Patents

Abstract

A pluggable surge arrester comprising a lower part (22) with contact receptions (23), an upper part (24) with contact pins (9) inserted into the contact receptions (23) and an over-voltage conductor element (1), preferably a variable resistor, arranged between the contact pins. At least one soldering point (25) is arranged in the supply to the over-voltage conductor element (1), in which one of the soldered supply lead parts (11, 8) is connected with a spring (2) pretensioning said supply lead part (8) in the direction away from the soldered joint (25). The spring biased supply lead part (8) is formed by a bridge whose two ends (81, 82) are connected over soldering points with further supply parts (11). The conductor includes a lower part with contact receptions, an upper part (24) with contact pins (9) inserted into the contact receptions, and an over-voltage conductor element (1), preferably a variable resistor, arranged between the contact pins. pre-stressing the supply part (8) in direction away from the soldering point. The pre-stressed supply part is formed through a bridge, whose both ends (81, 82) are connected over soldering points (25) with the other supply lead parts (11).

Description

Technical field

BACKGROUND OF THE INVENTION The invention relates to a pluggable surge arrester comprising a lower contact housing portion and an upper contact pin contact portion plugged into a contact housing and an overvoltage protector element, preferably a varistor disposed between these contact pins, a location at which one of the brazed supply lines is connected to a spring biased away from the brazing location.

BACKGROUND OF THE INVENTION

Transient overvoltages, such as lightning strikes, have relatively high energy and can therefore cause major damage to electrical equipment. It is therefore necessary to provide for measures to increase such overvoltages. Voltage-dependent resistors which have a high resistance at low low voltages are suitable for this purpose, whereas they have a low resistance at high voltages, such as varistors, sparks, and the like. These components are connected between the two conductors whose voltage is to be controlled.

At normal voltage, the arrester acts as a non-conducting element, except for the leakage currents, as a short-circuit in the case of overvoltage, so that the conductor voltage is significantly reduced and the overvoltage energy is largely lifted to earth.

Once the overvoltage energy is exceeded, which exceeds the arrester's ability to dissipate such energy, this leads to damage to the arrester.

As a result, even at normal mains operating voltage, this arrester has a low resistance, so that an inadmissible high current flows continuously through it.

In order to prevent such fault currents, devices are connected in series with the surge arrester which cause the fault arrester to be completely and permanently disconnected from the mains.

One of the most common of these devices has a circular cable arranged inside the surge arrester housing which is movable and connected in series with the surge arrester and connects the two sections of the supply line to the surge arrester housed in its housing. This round cable is connected at one end to a first section of the supply line, for example by riveting or welding, and at its other end it has a plate of conductive material, for example copper, which is permanently connected to the ring tank by riveting or welding. that it is prestressed in the direction away from the brazing point.

Both the current flowing downstream of the arrester and the subsequent line current flowing when the downcomer is damaged cause the downcomer to heat up. This heat is propagated along the supply lines and also reaches the soldering point. Once the melting point of the solder has been reached in this heating process, the plate attached to the round cable can be torn off from the round cable due to the force of the spring, whereby the surge arrester is separated from the grid by one pole. A solder with a precisely defined melting point is used at said brazing point. This melting point shall be selected such that it is not attained at a thermal energy which cannot yet damage the surge arrester. The brazed connection remains disconnected and thus the surge arrester is able to perform its function, but disconnects at higher thermal energies.

However, the previously known round cable solutions have the fundamental drawback that they are very sensitive to shock currents.

The circular wire used must consist of a plurality of thin wires intertwined with one another in order to be sufficiently flexible for the necessary movement. At high inrush currents, the magnetic forces that are present cause shrinkage, i.e. j. reducing the cross-sectional area of the individual fibers, leading to tearing off. The ring cable itself is above the currents flowing through the surge arrester and which otherwise cannot endanger it. cause damage, destruction and erroneous shutdown. Moreover, such a round arrester is relatively expensive, which leads to high production costs of the entire surge arrester.

According to another known solution based on the same functional principle, instead of a round cable, a copper plate is used, which is again permanently connected at one end to the first section of the supply line and by its other end soldered to the section of the second supply line. A spring is applied to this copper plate at a distance from its first end, which, after disconnecting the brazing point, cuts the plate away from it. To allow this copper plate to be cut off, it must be made of sufficiently thin copper plate. However, this has a small cross-section and, as a result, a relatively high resistance, and thus also exhibits a strong heating at the current flow, which, even at a small current size and duration, can lead to the deposition of the plate. As with the round conductor, there is little shock current resistance.

It is furthermore known to use a leaf spring instead of a copper plate, which in itself biases away from the brazing point and which, therefore, without the action of an additional spring, moves at its other end away from the brazing point when the brazing point is disengaged.

Materials that are suitable for the production of leaf springs, such as steel, have a relatively high specific resistance, so that there is also a problem of low impact current resistance.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a plug-in surge arrester of the aforementioned type which, in a simple, functionally reliable construction, is insensitive to shock currents.

According to the invention, this object is achieved in that the resiliently prestressed part of the supply line is formed by a bridge, both ends of which are connected to other parts of the supply line by means of soldered places.

This solution completely dispenses with the flexible, flexible part of the supply line and the problems associated with it.

The movable part of the supply line is rigid in itself and can therefore be manufactured with a relatively large cross-section and a well conductive material such as copper. The impact resistance of the movable part of the supply line is thus particularly high.

In addition, two crushing points are provided, which in particular causes a reliable disconnection of the surge arrester from the mains. In addition to being very fast and reliably feasible in itself, the disconnection process can create two series-connected electric arcs. These have a higher holding voltage than one electric arc and as a result they go out sooner.

In one embodiment of the invention, a bridge having a double L-shaped cross-section is provided.

As a result, the two sections of the supply line connected by the bridge can be arranged far apart from each other, yet only a slight distance from the closed position to the open position can be traversed in this way.

Another feature is that at one end the bridge is provided with a yoke formed integrally with the bridge on which the spring is mounted.

Helical springs, as will be explained below, are particularly advantageous embodiments of the spring, since they are mounted in a particularly simple manner, namely by suspension, on the yoke.

In a further embodiment of the invention, the first end of the bridge is connected by soldering to the contact pin.

Thus, the supply line suffices with a minimum number of individual parts, namely a contact pin, a bridge and a connection to the surge arrester. The supply line is preferably formed in an uninterrupted manner, thereby eliminating the need to manufacture connection points, which is very costly and impairs conductivity.

A further development of the invention consists in that the spring is formed by a helical spring, preferably a tension spring.

Such springs are simple and small in size, but with sufficient forces for the purposes of the invention.

According to a particularly preferred embodiment of the invention, the bridge is arranged directly adjacent to the bottom plate of the upper part, which has a through hole formed in the direction of movement of the bridge and that a cradle operating the auxiliary contact is pivoted in the base of the lower part. through hole.

When the bridge is released, the defective upper part needs to be replaced, in which case the bridge can be easily disconnected by a simple signal.

In connection with this arrangement, provision can be made for the bridge in the open state to cover the through hole at least in the region of the cradle in the open state.

Thus, it is not possible for the upper part which is already defective to be inserted into the lower part, since in this experiment the cradle of the lower part would hit the bridge and thus prevent the upper part from fitting correctly.

Another feature of the invention is that the cradle is connected to a resilient component biasing it in the direction of its rest position.

This automatically adjusts the cradle back to its rest position as soon as the defective upper part is removed from the lower part.

In this connection, it is also proposed that the resilient component bias the cradle in both directions of its pivoting in the rest position.

In this way, none of the directions of movement of the bridge are predetermined by the lower part, since each pivoting allows the cradle to return to its rest position.

It is particularly preferred that the resilient component is formed by a coil spring extending about the axis of rotation of the cradle, since such a spring is space-saving and its assembly is very simple.

In this context, an embodiment of the invention is advantageous in which the coil spring is formed by a coil spring, both ends of which run parallel to the axis of rotation and abut the side surfaces of the cradle and the stops formed on the lower part and flush with these side surfaces.

In particular, helical springs are easy to manufacture with the forces required for the desired purpose. Moreover, their insertion into the lower part is carried out by placing both ends of the spring on the stops formed in the lower part without any further fastening, thus saving one production operation.

A further preferred embodiment may include optical fault signaling comprising a through hole on the front side of the upper part of the arrangement and a lever movably mounted within the upper part which is arranged from the through hole area up to the bridge travel path and whose first end is located in the region. The borehole carries a signaling plate which, on its surface facing the borehole, is provided with a typical "OFF" operating state mark. This mark is the movement of the lever caused by the bridge during its opening movement from the position in which it is not visible through the opening to the visible position. Alternatively, the signaling plate, on its surface facing the through hole, is provided with a sign typical of the 'ON' operating state, the sign which, by means of the lever movement caused by the bridge during its opening movement, is brought out of .

With such signaling, the arrester status can be marked easily and in a comprehensible form for everyone.

The preferred embodiment may be arranged such that the lever is pivotably mounted and that the signaling plate typical of the " OFF " operating condition is in the closed state of the bridge below the face area adjacent the through hole and by pivoting the lever caused by the bridge during its opening movement. swings under the through hole. If the signaling plate mark, typical of the "ON" operating state, is below the through hole in the closed state of the bridge, then it is pivoted below the area of the front side adjacent to the through hole by swinging the lever caused by the bridge during its opening movement. hole.

This construction is sufficient for signaling faults with a single structural accessory, namely the lever itself. Due to the use of only one component, there is only a slight mechanical friction, thus ensuring operational reliability and low production costs.

In this context, a further feature of the invention may be that a further plate, fixed immovably in the upper part, is arranged below the signaling plate mounted on the lever.

This also clearly indicates the operating state in which the signaling plate is invisible by means of a correspondingly fixed plate.

According to another embodiment, the signaling plate is provided with a mark typical of both the "ON" and "OFF" operating states.

Thereby, the plate fixed immovably in the upper part can be omitted, which, as an additional component, requires additional manufacturing costs.

In this case, it may be advantageous for the other end of the lever extending into the path of movement of the bridge to be provided with a notch into which the bridge yoke extends, since this lever secures the bridge and is held by the bridge itself in its rest position. In this way, any special components that are required for this can be saved.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail below with reference to the accompanying drawings.

In FIG. 1a, 1b shows a first embodiment of the upper part of the surge arrester according to the invention in a top and side view, each with the top cover or side wall removed.

In FIG. Ic, 1d show a second embodiment of the upper part in the same views as in FIG. First

In FIG. 2a, a particularly preferred top view of the top cover is shown.

In FIG. 1b shows the upper part according to FIG. 2a in a side view.

In FIG. 2c is a cross-sectional view taken along line A-A of the upper part of FIG. 2a, 2b.

In FIG. 2d shows the upper part according to FIG. 2b in the same view with another embodiment of the optical fault signaling.

In FIG. 3 is a top view of FIG. 2 is inserted into the lower part, both parts being shown without the upper cover.

In FIG. 4a, 4b, 4c, the lower part according to FIG. 3 in a top view without the top cover respectively. side view, respectively. in plan view.

In FIG. 4d is shown in detail the cradle arranged in the lower part.

In FIG. 4e is a detailed illustration of FIG. 4d, with a particularly preferred embodiment of the coil spring biasing the cradle in the direction of its rest position.

In FIG. 5a, 5b show two possible embodiments of a switching device comprising an auxiliary contact.

DETAILED DESCRIPTION OF THE INVENTION

Components of the surge arrester, such as varistors, suppressors, or the like, can be destroyed by the electrical energy conducted by them at the surge lead. It is therefore advantageous to incorporate them, like fuses, into the overvoltage protection circuit so that they can be easily replaced. Analogously to the fuses, the lower part 22 is permanently connected to the current circuit, which is provided with a contact arrangement 23. The surge protector element 1 itself, which in this invention is formed by a varistor, is arranged in the upper part 24. It has contact pins 9 which are retractable The contact pins 9 are connected with a surge protector element 1. The overvoltage arrester is thus pluggable and retractable into the current circuit and thus easily replaceable.

In order to accommodate this switchgear surge arrester, which is generally mounted in switchgear cabinets, to other switchgear devices, such as line circuit breakers, F1-circuit breakers and the like, the lower part 22 is U-shaped and the upper part 24 is cuboid, see fig. . 4. However, these geometric shapes are not essential to the invention and can be varied at will.

In order to be able to detach the surge arrester element 1 from the mains after its failure, independent of the ejection of the upper part 24, at least one soldering point 25 is arranged inside the upper part 24 in the supply line to the surge arrester element 1 at which one of the parts 8, 11 of the supply line, namely the connection part 8 of the supply line, is connected by a spring 2 biasing it in the direction away from the soldering point 25. As explained above, this soldering point 25 is heated by both leakage currents induced by overvoltage and mains with the currents and when the melting point of the solder is reached, said soldered part of the supply line is torn away from the soldering point 25, which results in the separation of the surge arrester element 1 from the mains.

According to the invention, the spring-loaded part 8 of the supply line is formed by a bridge whose two ends 81, 82 are connected to the other part 11 of the supply line by means of soldered places 25. A first possibility of a specific embodiment of this principle is shown in FIG. la, lb. The upper part 24 shown here has a lower box-shaped cover 4, inside which the surge arrester element 1, the contact pins 9, the supply lines 10, 11 are arranged. This lower cover 4 is closed by a plate-shaped upper cover 7, The views of the upper part 24 are omitted.

The bridge 8 is a planar plate, the first end 81 of which is directly connected to the contact pin 9 and the second end 82 of which is connected by soldering to a portion 11 of the supply line leading to the first connection of the surge arrester element 1. The connection by soldering the bridge 8 directly to the contact pin 9 is advantageous since the wiring can be saved. Within the scope of the invention, the connection of the contact pin is also firmly connected to a part of the supply line, for example by invitation, and the bridge 8 can be soldered to another part of the supply line. A spring 2 formed as a helical spring and acting as a tension spring is fixed by one end to the projection 3 of the lower housing 4 and the other end fixed to the yoke 83 formed on the bridge 8 thereby bending the bridge in a direction perpendicular to the plug-in direction. by heating the brazing points 25 to their temperature, possibly above their melting point, the bridge 8 is displaced in the direction of its bias by the spring 2 and its contact with the contact pin 9 and the lead-in part 11 is broken.

Another possible way of forming and arranging the bridge 8 is shown in FIG. lb, lc. Here, the bridge 8 is designed in the form of a double L-shaped cross-section. The contact pin 9 and the lead-in part 11 to which it is connected by soldering are spaced apart from one another. The spring 2 is arranged such that it extends in the insertion direction of the upper part 24 so that the direction of movement of the bridge 8c is perpendicular to the direction of FIG. la, lb.

In both of these embodiments, the movement of the bridge 8 performed to separate the surge arrester element 1 is used to conduct optical fault signaling. This comprises a through hole 27 arranged on the front side 26 of the upper part 24 and a lever 5 movably movable inside the upper part 24, which is arranged from the area of the through hole 27 up to the path of the bridge 8. At its first end located on the area of the through hole 27, carries a signaling plate 50 which, on its surface facing the through hole 27, is provided with a symbol 53 typical of the " OFF " operating state. This mark 53 is over the entire surface of the signal plate 50 having approximately the size of the through hole 27. the movement of the bridge 8 is transferred to the lever 5, which, according to FIG. 1 and FIG. 2, the lever 5 rests directly on the bridge 8. The symbol 53, typical for the "OFF" operating state, is brought from a position not visible through the through-hole 28 to a visible position. Red marking, inscriptions such as "FAILURE", "DEFECT" and the like can be considered as the symbol 53 typical for the "OFF" operating state.

The visibility of the signaling plate mark 53 previously considered in the abstract is shown in FIG. In particular, the lever 5 is pivotally mounted on the pin-shaped projection 51 of the lower housing 4 and is shaped such that the signaling plate 50, when the bridge 8 is closed, is below the area of the front side 26, adjacent the through hole 27. as a result of the opening movement of the bridge 8, the second end of the lever 5 extending into the path of movement of the bridge 8 swivels in the clockwise direction and thereby moves the signaling plate 50 below the through hole 27. is provided with a notch 52 into which a second projection 84 of the bridge 8 extends.

Below the signaling plate 50, another plate 6 is immovably positioned in the upper part 24. In the operating state of the upper part 24, in which the signaling plate is not visible, it is now possible to see this plate 6 through the through hole 27. "ON" operating status, such as green paint, or "OK" and the like.

In FIG. 1c is an optical fault indication based on another functional principle. The lever 5 is not pivotally mounted, but is displaceably disposed in the direction of movement of the bridge 8. The signaling plate 5 is still located below the through hole 27, only its distance from the through hole decreases due to the movement of the bridge 8. In order to ensure that the signaling plate 50 and hence the mark 53 will not be visible in the idle state of the bridge 8, opaque flexible legs 28 are arranged between it and the through hole 27 and are fixed in the upper part 24 only at its ends facing away from the signaling plate. 50. When the jumper 8 is moved, the signaling plate 50 pierces these uprights 28 and thus the mark 53, typical of the "OFF" operating state, is visible through the through hole 27.

The mark 53 typical for the "ON" operating state is to be affixed to the spring plungers 28 in this type of construction.

The embodiment of FIG. 2 to 4 is particularly preferred. Again, the bridge 8 is double-L-shaped, as best seen in FIG. 2c and is connected only by soldering to the contact pin 9 and to the supply line part 11. Their longitudinal axis and the spring 2 are arranged, respectively. they extend perpendicularly to the insertion direction of the upper part 24, and are arranged next to the plate 29 of the upper part 24, see FIG. 2a and FIG. At the other end 82 of the bridge 8, a yoke 83 is provided for fastening the spring 2, which yoke 83 is integrally formed with the bridge 8.

The optical fault signaling is almost identical to that of FIG. la, so it is not necessary to explain the function. However, there are differences in the following two points. First, there is a yoke 83 which serves to fasten the spring 2 to the notch 51, so that a separate projection 84 in FIG. la falls away. The second difference lies in the location of the through hole 27. Here, compared to the embodiment of FIG. 1a, which is displaced approximately by the width of the signaling plate 50 to the left, so that the signaling plate 50 lies in the closed state of the bridge 8 below the through hole 27.

Due to the pivoting of the lever 8 following the opening of the bridge 8, the signaling plate 50 swivels from a visible position through the through hole 27 to a position where it cannot be seen, namely below the area of the face 21 adjacent to the through hole. The mark 54 typical for the "ON" operating state must be placed here on the signaling plate 50, while for the "OFF" operating state on the stationary plate 6.

In FIG. 2d, finally, a third possibility of positioning the marks 53, 54 for the "OFF" and "ON" operating states is shown. The signaling plate 50 is here made approximately twice as wide as in FIG. 1a and 2a, and is provided with markings 53, 54, typical of both the "ON" and "OFF" operating states, which are formed as adjacent strips. Therefore, when the lever 5 is pivoted, the "OFF" sign 53 from the position not visible through the through hole 27 is brought into the visible position, and at the same time the "ON" sign 54 is moved from the visible position through the through opening 27 to the not can be seen.

In addition to optical fault signaling, this embodiment of the invention also has electrical fault signaling. Its most important component is the cradle 12, pivoted in the base of the lower part 22, which extends from the base in the direction of the upper part 24 and extends into it and which, when swiveled, actuates the auxiliary contact 40. By this auxiliary contact it can close the power circuit of the alarm , such as signal bulbs, sirens or the like, whereby the person in charge of the maintenance of these devices can be informed of the failure, even though they would have to check the individual surge arresters.

The auxiliary contact 40 is not arranged in the lower part 22 of the surge voltage arrester, but is located in the switchgear 41 arranged in the switch cabinet immediately next to the lower part 22. To transmit the pivoting movement of the cradle 12 to the auxiliary contact 40, the cradle 12 has recess 37. The switch apparatus 41 is provided with a shaft 42 extending beyond its housing, the end of which extends into the recess 37, and is exerted by its pivoting movement of the cradle 12. This shaft 42 is mechanically coupled to the auxiliary contact 40 and closes it with corresponding pivoting.

A possible embodiment of such a switching device 41 is shown in FIG. 5a, 5b. In FIG. 5a, the auxiliary contact 40 is formed as a break contact and comprises two leaf spring carriers 43 which are fastened in their housing by their first ends and whose second ends carry contacts 44 and a slide 45. On the shaft 42 engaged with the cradle 12, a handle 46 is formed. The contacts 44 abut one another in the rest position of the handle 46. The auxiliary contact 40 is closed.

When the cradle 12 is pivoted, the handle 46 assumes one of the positions 46, the tip of which deflects one of the contact carriers 43 and separates the contacts 44 from one another. As is clear from the figures, the handle 46 can swivel both clockwise and counterclockwise to open the auxiliary contact 40.

According to the embodiment shown in FIG. 5b, the auxiliary contact 40 is formed as a changeover contact. There are two fixed contacts 47, 48 and only one movable contact 44, which is fastened to the free end of the leaf carrier 43 in the form of a leaf spring.

When the handle 46 is pivoted counterclockwise, the contact carrier 43 is deflected as shown in FIG. 5 a. This separates the movable contact 44 from the first fixed contact 45 and engages the second fixed contact 45.

This swiveling is only feasible when the cradle 12 is swiveled counterclockwise.

To pivot the cradle 12, a bridge 8 is used, with the aim that a through hole 30 is formed on the bottom plate 29 of the top panel 24 in the region of movement of the bridge 8. The cradle 12 passes through this through hole 30 in its rest position as shown in the drawing. The upper part 24 is mounted on it and is thus moved inside the movement path of the bridge 8. During the opening movement, the yoke 83 or the lower part of the bridge is lowered. more specifically, the projection 85 formed on the caliper 83 extending into the through hole 30 on the cradle 12 and carries it, as well as the solder 5 with each other, see in particular FIG. 3 and FIG. 2c.

In order to keep the cradle 12 in its rest position when the upper part 24 is seated, it is provided with a resilient component that preloads it in the rest position. Possibilities of a particular embodiment of this component are shown in FIG. 4d.

Dotted spring 32 is shown, fixed with its first end in the lower part 22 and its second end on the cradle 12 spaced from its pivot axis 31. This arrangement is conditional on the bridge 8 being able to move only in the direction shown in FIG. 3, but not in the reverse direction. Indeed, the opposite direction of movement would open when the cradle 8 is pivoted counter-clockwise, in which the tension spring 32 could not ensure its return to its initial position. In order to ensure that the cradle 12 is returned even when swiveling in the clockwise direction, a second tension spring 33 acting in the reverse direction can be connected.

However, it would be advantageous to arrange only a single component which would bias the cradle 12 in both pivoting directions. This component could be, for example, a resilient strip 34 which is secured by its first end in the lower part 22 and its second end on the cradle 12 spaced from the pivot axis 31 and extending perpendicular to the pivot direction.

One particular embodiment of the resilient component may consist in its design as a helical spring 13 extending about the pivot axis 31 of the cradle 12.

This coil spring 13 could be formed as shown in FIG. 4d is shown as a resilient ring which is cut in the region of the cradle 12, the two ends 35, 36 of which are thereby produced are bent outwards and supported on the cradle

12th

According to a particularly preferred embodiment shown in FIG. 4e, the coil spring 13 is formed by a coil spring. Its two ends 130, 131 extend parallel to the pivot axis 31 and then pass by means of sections 132, 133 extending radially with respect to the pivot axis 31 into the abbreviated spring body 134, again running about the pivot axis 3.

The ends 130, 131 now abut on both side surfaces 120, 121 of the cradle 12 and at the same time on the stops 122, 123 formed on the lower part 22 and licensing with these side surfaces 120, 121, which are seen in FIG. 4e are located below the cradle 12 and are therefore shown in dotted lines.

When the cradle 12 is pivoted counterclockwise, the first end 130 of the spring is carried along by the side surface 120 of the cradle 12, the second end 131 of the spring remains at the stop 123. The helical spring 13 is thereby rotatably tensioned and restores the cradle 12 in its rest position. .

This happens when the cradle 12 is pivoted in the clockwise direction. The second spring end 131 is carried away by the side face of the cradle 12, and the first spring end 130 presses against the stop 120, thereby also exerting restoring forces on the cradle 12.

In addition to the electrical fault signaling, the cradle 12 in combination with the bridge 8 is further used to ensure that only the intact upper parts 24 fit into the lower parts 22. As a result of the immediately adjacent arrangement of the bridge 8 on the plate 29, respectively. at its through hole 30 in relation to its geometrical dimensions, it is achieved that the bridge 8, more precisely its projection 85 formed on the yoke 83, covers the through hole 30 at least in the open position at least in the region of the cradle 12 in its rest position. When attempting to fit the defective upper part 24 into the lower part 22, the cradle 12 engages the projection 85, thereby preventing the contact pins 9 from being inserted into the contact receptacle 23. The lower part 22 comprises a lower cover 21 and an upper cover 20. In addition to the cradle 12 already explained in detail, this lower part 22 has connection terminals for overvoltage. They consist of a frame 16 mounted on a lower part 22, in which the cabinets 17 are displaceably mounted, which are by means of clamping screws 19 which extend through the frame 16 and engage the threads of the cabinets 17 which are moved therethrough. Connected to the fixed frame 16 are feed lines 18, preferably made of copper, which terminate at the base of the lower part 22, and at these ends are provided with 23 contact bearings. These contact receptacles 23 are formed as central slots formed on the supply lines 18, the two end sections thus formed at each supply line 18 being held together by one spring 14 at a time.

The lower side of the base, as is usual with the switchgear, is designed to snap onto the rail. Two locking sliders 15 are provided for this purpose. The lower part 22 thus becomes quite symmetrical with respect to its height axis, as a result of which its lower cover 21 and the upper cover 20 are exactly the same, so that only one type of cover is to be manufactured.

In order to ensure that the upper part 24 can fit into the lower cover 22 only in particular, a pin 38 is provided on the outside of the bottom plate plate 29 of the upper part 24 and its corresponding opening 39 in the base of the lower part 22.

Claims (16)

PATENT CLAIMS A pluggable surge arrester comprising a lower contact housing portion and an upper portion with contact pins plugged into a contact housing and an overvoltage protector element, preferably a varistor disposed between these contact pins, wherein at least one brazing point is provided in the supply line to the overvoltage protector element. in which one of the parts of the connected supply line is connected to a spring biased in a direction away from the soldering point, characterized in that the spring-biased supply line part (10) is formed by a bridge (8), both ends (81, 82) of which connected via soldered places (25) to the second supply line part (11). Plug-in surge arrester according to claim 1, characterized in that the bridge (8) has a double L-shaped cross-section. Pluggable surge arrester according to claim 1 or 2, characterized in that the bridge (8) has at its one end (82) a yoke (83) formed integrally with the bridge (8) on which the spring (2) is fastened. Pluggable surge arrester according to claim 1, 2 or 3, characterized in that the first end (81) of the bridge (8) is connected by soldering to the contact pin (9). Plug-in surge arrester according to one of claims 1 to 4, characterized in that the spring (2) is formed by a helical spring, preferably a tension spring. Plug-in surge arrester according to one of the preceding claims 1 to 5, characterized in that the bridge (8) is arranged immediately adjacent to the bottom plate (19), that the bottom plate (19) is provided in the direction of movement of the bridge (8). ) through the opening (30) and that in the base of the lower part (22) there is a pivotably mounted cradle (12) for operating the auxiliary contact (20), which passes through the through opening (30) in the state when the upper part (24) is correctly fitted; it can be swiveled by the bridge (8) during its opening movement. The overvoltage arrester according to claim 6, characterized in that the bridge (8) in the open state overlaps the through hole (30) at least in the region in which the cradle (12) is in its rest position. Plug-in surge arrester according to one of Claims 6 to 8, characterized in that the cradle (12) is connected to a resilient component biasing it in the direction of its rest position. The overvoltage protector according to claim 8, characterized in that the resilient component biases the cradle (12) in both pivoting directions to its rest position. 10. The overvoltage arrester according to claim 9, wherein the elastic and / or the elastic arresters are in accordance with the invention. the resilient component is formed by a coil spring (13) arranged around the pivot axis (31) of the cradle (12). The overvoltage protector according to claim 10, characterized in that the coil spring (13) is formed by a coil spring whose two ends (130, 131) extend parallel to the pivot axis (31) and abut against the side surfaces (120, 121). the cradles (12) and the stops (122, 123) formed on the lower part (22) which are aligned with these side surfaces (120, 121). Pluggable surge arrester according to one of claims 1 to 11, characterized in that the optical fault signaling comprises a through hole (27) arranged on the front side (26) of the upper part (24) and a movably mounted lever (5) inside the upper part. which is arranged from the region of the through hole (27) up to the path of movement of the bridge (8), the first end of which is located on the area of the through hole (27) carrying a signaling plate (50) which is on its surface facing the through hole (27) provided with a mark (53) typical of the "OFF" operating state, mark (53) is indicated by the movement of the lever (5) caused by the opening movement of the bridge (8) from a position not visible through the through hole (27) to a visible position, or which signaling plate (50), which has on its surface facing the through-hole, is provided with a mark (54) typical of the "ON" state, the mark (54) is movement of the lever (5) induced by the bridge (8) during its opening movement, brought from a position invisible through the opening (27) to a visible position. Pluggable surge arrester according to claim 6, characterized in that the lever (5) is pivoted and that the signaling plate mark (53), typical of the "ON" state, lies below the area in the closed state of the bridge (8). the front side (26) which is adjacent to the through hole (27) and which by pivoting the lever (5) caused by the bridge (8) during its opening movement is pivoted below the through hole (27) or that the signaling plate (54) 50), typical of the "ON" operating state, lies in the closed state of the bridge (8) below the through hole (27) and by pivoting the lever (5) caused by the bridge (8) during its opening movement is pivoted below with through hole (27). Pluggable surge arrester according to claim 13, characterized in that a further plate (6) is displaceably mounted on the upper part (24) below the signaling plate (50) mounted on the lever (5). Pluggable surge arrester according to claim 14, characterized in that the signaling plate (50) is provided with a mark typical for both the "ON" and "OFF" operating states. The overvoltage arrester according to claim 13, 14 or 15, characterized in that the second end of the lever (5) extending into the travel path of the bridge (8) is provided with a notch (52) into which the yoke (83) of the bridge (8) extends. ).