EP0603503A1 - Method for switching a fused load-break switch and fused load-break switch - Google Patents

Abstract

The present invention relates to a switching method, in particular for switching on a fused load-break switch (1), in which three fuse links (4, 5, 6) which are arranged on an upper part (2) of the fused load-break switch are moved simultaneously substantially in parallel and at the same distance and are brought into or out of contact with backing contacts (7a,b; 8a,b; 9a,b) arranged on an underpart (3) of the fused load-break switch. In order to achieve a method for switching circuits using fused load-break switches as well as a corresponding fused load-break switch having the features mentioned in the introduction, wherein the dangers to the switching system and to the personnel when switching on a shorted circuit are considerably reduced, provision is made, according to the invention, for the circuit to be closed via the three fuse links (4, 5, 6) with a time delay, with the contacting of the first contact blade (3a, 4a, 5a) of each of the fuse links (3, 4, 5) occurring simultaneously or in any predeterminable chronological sequence, whilst at least for a first fuse link (3, 4), at least the contacting of its second contact blade (3b, 4b) with the corresponding backing contact (7b, 8b) occurs before the contacting of the second contact blades (3b, 5b or 4b, 5b) of the two other fuse links (3, 5 or 4, 5). <IMAGE>

Description

The present invention relates to a method for switching, in particular for switching on a fuse switch disconnector, in which three fuse inserts attached to an upper part of the fuse switch disconnector are moved simultaneously and essentially in parallel by the same distance and with mating contacts (access / outlet contacts) arranged on a lower part of the fuse switch disconnector. be brought into or out of engagement.

The present invention also relates to a fuse switch disconnector with inlet / outlet contacts arranged on a lower part, which can be connected to the three phases of an AC network, and with an upper part which has a holder for fuse links, the lower part and upper part being movable relative to one another such that the contact blades of the fuse links with the counter contacts, ie engage or disengage the lower part inlet / outlet contacts.

Such fuse switch disconnectors have been known for a long time. There are essentially two different types. In a first type, the upper part is displaced linearly relative to the lower part, so it maintains its relative position in space, with only the distance between the lower part and the upper part changing and the upper part taking the fuse links with them, so that the contact blades of the fuse links move in and out Intervention.

In another type, the upper part can be pivoted about an axis relative to the lower part, and the present invention can only be applied to those fuse switch disconnectors of the second type in which the fuse links are at substantially the same distance from the pivot axis of the upper part, since only with this Type the fuse links are moved simultaneously by the same distance in parallel.

In general, NH fuse switch disconnectors are switching devices in which the NH fuse link serves as a movable contact.

When switched on, the NH fuse link forms the overcurrent and / or short-circuit protection device for the connected circuit. When switched off, the NH fuse switch disconnector creates a safe, visible isolating gap between the connections, which also enables work on the switched-off circuit parts.

The switching process itself takes place at a speed dependent on the movement of the operator. This speed is sufficient to be able to interrupt a circuit under load with such a device. To better control the switching arcs, the devices can be provided in a known manner with extinguishing plates (so-called deion chambers) or hard gas quenching chambers. The previously mentioned versions of NH fuse-switch disconnectors have proven to be particularly advantageous, in which the contact piece (NH fuse link) is moved in such a way that its longitudinal axis moves parallel and both contact sides are opened or closed at the same time. This results in two partial arcs when switching off, which, if necessary by supporting two quenching chambers, doubles the arc length and thus also the effective switching speed. This version also has the advantage that after interrupting the circuit, the moving contact itself is no longer connected to the circuit voltage and accidental contact with live parts is avoided.

The simultaneous touching of both contact parts when switching on the device can also be disadvantageous, especially if there is a short circuit in the connected circuit.

The very high breaking capacity of the NH fuse links (100 kA) means that the switching devices described are used in circuits with ever increasing short-circuit power.

It is important to note that even accidentally turning on a shorted circuit is safe for the operator.

While normal load switching with hand-operated NH fuse-switch disconnectors can be carried out within the limits specified by the usage category without endangering the operator, switching to a short-circuited circuit with very high short-circuit powers is associated with greater risks. The reasons for this are, on the one hand, the switching speed specified by the operator and, on the other hand, the fact that the relatively loose suspension of the formwork element (NH fuse link) means that the first contact is made practically without any significant contact pressure.

As a guideline for the switching speed, the upper limit of 0.5 m / s specified on the handle for attempts to switch on such devices in the European standard (EN 60947-3) can be assumed. Taking into account a usual leverage ratio between the handle distance and the contact distance to the pivot point, the contact speed at the time of the first contact is about half the actuation speed. The knife contact (e.g. 3a, b) of the NH fuse link (3) therefore moves at a speed of approximately 0.25 m / s into the V-shaped inlet area of the receiving contact (e.g. 7a, b).

As soon as the circuit is closed, the short-circuit current in the connected circuit develops regardless of the level of the contact pressure. Because of the lack of contact pressure, the current heats the touching metal surfaces so strongly that they first melt and then even evaporate. The short-circuit current can ultimately only flow in the form of an arc between the knife contact (3a, b) and the receiving contact (7a, b). This process is comparable to the process of arc welding. The extremely steep rise in the short-circuit current leads to an explosive emission of metal vapor, which can electrically close adjacent live parts, generate an arcing fault and destroy an entire switchgear.

If the short-circuit current remains limited to the connected circuit, it is switched off by the fuse links within a few milliseconds. At a closing speed of 0.25 m / s, corresponding to 0.25 mm / ms, the knife contact (e.g. 3a, b) of the NH fuse link (3) generally does not reach the contact surfaces under spring pressure during this time the contact (7a, b). The possibility of a defined contact and thus the suppression of a switch-on arc is practically excluded for the type of device described.

The occurrence of a switch-on arc with the short-circuit current-dependent metal vapor emission must therefore be regarded as a system-inherent property for NH fuse-switch disconnectors. As a result of the current-limiting effect of the NH fuse link, this metal vapor emission is also relatively uncritical as long as it does not trigger secondary short-circuits in neighboring circuits or even in the pre-fuse area. A short-circuit current limited by fuse links at most leads to damage to the switching device concerned and to a fault in the circuit, which is in any case faulty. A busbar short circuit, on the other hand, leads to failure or even destruction of the entire switchgear.

The harmful effect on neighboring circuits, in particular on the busbar system, can be limited by large distances between the metal parts or by partitions and insulation. However, these measures lead to larger dimensions of the switchgear or cause increased costs and / or thermal problems due to disabled heat dissipation.

From DE-OS 1816 938 and DE-OS 1918 473 a solution is known in which the formation of an arc is to be prevented by means of insulating material on the knife contact or receiving contact when switching on hand-operated devices.

In this solution, the receptacle contacts are provided with insulating material attachments, which spread the contact surfaces when the knife contact is inserted, contact being made only after the knife contact has been completely immersed between the receptacle contact halves. On the one hand, it is doubtful that the contact knife can be guided so precisely during the switching process when using commercially available NH fuse links that premature contact and thus premature triggering of the short-circuit current can be excluded. On the other hand, the contact arrangement described has the serious disadvantage that the opening contact is opened during switch-off operations under load while the contact knife has not yet moved out of the contact area.

Due to the low switching speed of hand-operated devices, the switching arc burns long enough between the contact surfaces to destroy them. Even if this contact arrangement according to the invention should show more favorable properties when switching on a short circuit, the disadvantageous properties when switching off load currents mean that it is unsuitable for use in NH fuse-switch disconnectors. Especially since switching off is one of the normal, frequently recurring functions of the fuse switch disconnector, while switching on for a short circuit is an exceptional situation, which however must be mastered in terms of safety.

From P 40 08 869.3 an improved version is known, which the above. Does not have disadvantages. But even with this solution, two switch-on arcs are created when the switching element is guided in parallel. Both solutions use more complex receptacle contacts to which additional insulating parts have to be mounted.

Although a fuse switch disconnector is already known which does not have the disadvantages mentioned above, and in which the fuse links are fastened in a row one behind the other to an upper part which is pivotable about an axis, the row of fuse links extending from the axis. However, this type of safety glass isolator has the major disadvantage that the upper part must be pivoted very far away from the lower part, so that the fuse link closest to the axis is also separated from its counter contacts. In a disadvantageous manner, live parts are very easily accessible, particularly in the areas further away from the axis. In addition, this type of fuse load doors nern the disadvantage that because of unfavorable leverage when switching off under load arcs on the contacts of the fuse link closest to the axis remain very long, which sooner or later lead to the destruction of the contact surfaces. With this non-generic fuse switch disconnector, the fuse links are not moved in parallel or by the same distance,

Compared to the aforementioned prior art, the present invention has for its object to provide a method for switching circuits by means of fuse switch disconnectors and a corresponding fuse switch disconnector with the features mentioned in the introduction, in which the dangers for the switchgear and for operators when switched on to a short-circuited Circuit are significantly reduced.

With regard to the method, the object on which the invention is based is achieved in that the power supply via the three fuse links occurs at different times, in that the contacting of the first contact blades of each of the fuse links takes place simultaneously or in any predetermined time sequence, while at least for a first fuse link the contacting of his second contact blade with the associated counter contact takes place before the contacting of the second contact blade of the other two fuse links. The switch-off process is preferably carried out in the reverse order.

A method or a procedure is preferred in which the second contact blades mentioned come into contact with their corresponding counter-contacts in succession at a time interval of approximately one to five milliseconds.

Due to the time shift in the contacting of the second contact blades of the fuse links, the number of switch-on arcs can be limited to a single contact in the best case, while in the otherwise preferred embodiment according to the technology with parallel shiftable fuse links when switched on to a short circuit 6 arcs could occur simultaneously. If, in unfavorable cases and in the case of a non-symmetrical circuit, two or three arcs occur in the method according to the invention, the risk of secondary short-circuits due to corresponding metal vapor emissions is nevertheless reduced because these arcs do not occur at the same time but with a time delay and therefore the metal vapor concentration does not occur at any time becomes so large that a secondary short circuit can occur.

In an expedient embodiment of the invention, the second contact blade of the first fuse link is contacted after the first contact blade of the first fuse link has been contacted. This embodiment is particularly preferable when the circuit of the consumer supplied via the fuse switch disconnector is not symmetrical.

In the case of a symmetrical consumption circuit, however, an embodiment of the invention is preferred in which the contact blades of the first fuse contact can (can) be inserted into their corresponding counter-contacts at the same time, while at least the second contact blade of the second fuse link timed after the contacts of the first fuse link were closed and also timed the first contact of the second fuse link is closed. The terms "first", "second" and "third" fuse link and "first", "second" contact or "first" and "second" contact blade refer to the chronological order of contacting, i.e. the first fuse link is the one in which both contacts are closed before both contacts are closed on any of the other fuse links and the second contact blade is never brought into contact with the corresponding counter contact in front of the first contact blade, although the above terms in principle also include one Do not rule out simultaneous contact as long as this is not expressly requested by specifying the chronological order.

In the last example specifically mentioned, for example, both contacts of the first fuse link and also the first contact of the second fuse link (optionally also the first contact of the third fuse link) can be switched simultaneously. Only the switching of the second contact of the second fuse link then takes place at different times and finally the switching of the second contact of the third fuse link takes place again at a different time after the switching of the second contact of the second fuse link. With symmetrical circuits, current only flows when at least two fuse links or their contact blades are engaged with their respective counter contacts. This means that the contacting of both contact blades of the first fuse link takes place without current, as does the contacting of the first contact blades of the second and third fuse links. Only the contact of the second contact blade of the second fuse link takes place under short-circuit conditions on the consumer side Electric arc. The short-circuit current flowing is switched off within one to two ms (milliseconds) by the first and second fuse link. If, finally, the contacting of the second contact blade of the third fuse link takes place with a corresponding delay, this takes place again without current, since the two other phases are now already switched off. So there is only a single arc, clearly on the second contact blade of the second fuse link and the corresponding mating contact, so that by choosing the fuse link that switches as the second one (closes both contacts in succession), you can clearly determine at which point the arc is generated becomes. You will choose a contact that has the lowest risk of a secondary short circuit to the other phases or even to the busbars due to its spatial position in the fuse link. The time sequence of contacting the first contact blades of the fuse links is largely arbitrary. Thus, the first contact blades can optionally be switched simultaneously, while the second contact blades of the fuse links have the order of contacting described above, however, the first contact blades can also be brought into engagement with their corresponding counter-contacts at different times.

• a) mindestens ein Teil der Kontakte eine unterschiedliche Kontakthöhe hat und/oder
• b) die Sicherungseinsätze in unterschiedlicher Höhe oder relativ zueinander geneigt am Oberteil des Sicherungslasttrenners aufgehängt sind, wobei die unterschiedliche Kontakthöhe bzw. die Neigung der Sicherungseinsätze relativ zueinander so gewählt ist, daß beim Aufeinanderzubewegen von Oberteil und Unterteil des Sicherungslasttrenners der Stromschluß über beide Kontakte an einem der Sicherungseinsätze zeitlich vordem Stromschluß über die Kontakte derzweiten und dritten Sicherungseinsätze erfolgt. Der Begriff "Höhe der Kontakte" bezieht sich dabei auf eine Ebene, die im Moment der ersten Berührung eines der Kontaktmesser mit seinem entsprechendem Gegenkontakt senkrecht zur Bewegungsrichtung des Oberteils gegenüber dem Unterteil verläuft.

With regard to the device mentioned in the introduction, the object on which the invention is based is achieved in that either

• a) at least some of the contacts have a different contact height and / or
• b) the fuse links are suspended at different heights or inclined relative to one another on the upper part of the fuse switch disconnector, the different contact height or the inclination of the fuse links relative to one another being selected such that when the upper part and lower part of the fuse switch disconnector are moved towards one another, the current shorting over both contacts on one the fuse links occur before the power is closed via the contacts of the second and third fuse links. The term “height of the contacts” refers to a plane that runs perpendicular to the direction of movement of the upper part relative to the lower part when one of the contact blades with its corresponding counter-contact is touched.

In the case of an inclination of the fuse links relative to one another, the term inclination naturally refers to the longitudinal axis of the fuse links passing through the fuse links and the two opposite contact knives, with then at most one of the fuse links in one plane or parallel to a plane perpendicular to the direction of movement of the fuse links at the moment of the first Contact between a contact knife and the mating contact, while the other two fuse links are inclined relative to this plane, and thus also to the first-mentioned fuse link. With such a configuration, all counter contacts can have the same height, whereby of course both solutions can also be combined with one another, i.e. Both the counter contacts on the lower part can have different heights, while the fuse links are also inclined relative to one another and, at least partially, also with respect to the plane perpendicular to the direction of movement. It goes without saying that the inclination of the fuse links and the different height of the contacts must not be chosen so that the effect of the inclination and the different contact height cancels out. In principle, the condition applies to each arrangement that it must be carried out in such a way that the two-sided contact closure on the first fuse link is earlier than the two-sided contact closure of the other two fuse links, and their complete contact closure is also staggered in time. Since the contact closure is only fully established when both contact blades of a fuse link are in engagement with their corresponding mating contacts, it is sufficient to consider the contacting of the respective second contact blade of the fuse links, the first contact blade at most simultaneously, preferably before the second contact blade is brought into engagement with its corresponding counter contact.

Preferred configurations of the fuse switch disconnector according to the invention correspond to the preferred method steps described above. A fuse switch disconnector is particularly preferred, in which the upper part is displaced parallel and essentially linearly with respect to the lower part, so that all the fuse inserts execute the same linear movement and the contacting sequence is effected only by the height of the contacts and / or the relative inclination of the fuse inserts to one another a plane perpendicular to the direction of movement is determined.

In another embodiment, in which the upper part can be pivoted about an axis and the fuse links are arranged next to one another at the same distance from the axis, for geometrical reasons the contact knives closest to the axis are first brought into engagement with their mating contacts. The amount of the second Counter contacts can then be staggered in a suitable manner, an embodiment of the invention being preferred for symmetrical circuits in which the middle counter contact is highest.

The contact heights of the mating contacts and / or the inclinations of the fuse links are preferably selected so that the moment the first contact of the second contact knife comes into contact, the distance of the second contact knife coming into engagement with its counter contact is still approximately two to five millimeters. while the distance between the last contact knife that comes into engagement is a further two to five millimeters larger.

The height difference between the two first-mentioned mating contacts or the inclination between the first and second fuse link is expediently chosen to be sufficiently large so that the second mating knife, which comes into engagement first, already bears against the corresponding mating contact surfaces with essentially the full contact pressure when the contact of the next comes into engagement second contact knife with its counter contact, an arc being generated in the event of a short circuit. The difference in height to the last counter contact or the different height between the penultimate and last contact blades, which engage with their counter contacts, need only be so large in the case of a symmetrical circuit that the typical time that passes before the last Contact knife comes into contact with its mating contact during a normal switch-on operation, is longer than the switching time of the fuse links, so that the first and second fuse links have already interrupted the circuit and thus the contacts of the third fuse link remain de-energized.

• Figur 1 bis c verschiedene Ansichten eines Sicherungslasttrenners mit linearer Parallelführung der Sicherungseinsätze.
• Figur 2a und b jeweils drei nebeneinander angeordnete Kontaktmesser und Gegenkontakte, welche eine gewünschte Schaltreihenfolge haben.

Further advantages, features and possible uses of the present invention will become clear from the following description of the figures, which show embodiments of fuse links or parts thereof, by means of which the principle of the present invention is realized. Show it:

• Figure 1 to c different views of a fuse switch disconnector with linear parallel routing of the fuse links.
• 2a and b each have three contact knives and counter-contacts arranged next to one another, which have a desired switching sequence.

In Figure 1, a fuse switch disconnector can be seen in a side view, lateral housing parts are omitted. The fuse switch disconnector consists of a lower part 2 and an upper part 1, which is only indicated by dashed lines. The lower part 2 is mounted on three busbars S1, S2 and S3, access lines 10, 11, 12 each having one of the busbars S1, S2, S3 with access contacts 7a, 8a and 9a connect. Outgoing contacts 7b, 8b and 9b are assigned to the access contacts 7a, 8a and 9a, which are spaced apart from the access contacts. The inlet / outlet contacts generally have the lyre shape shown in FIG. 1 c and known in the prior art. Extinguishing chambers 16 can also be seen above the inlet / outlet contacts, which primarily serve to avoid or extinguish arcs when the NH fuse-switch disconnector is switched off under load. Three fuse links 3, 4, 5 are suspended on the upper part 1, the exact suspension or fastening of the fuse links 3, 4, 5 on the upper part 1 being reproduced only chemically. The upper part can be moved towards or away from the lower part 2 in the direction of the double arrow 17, all securing inserts 3, 4, 5 executing the same movement in parallel.

As can easily be seen from the auxiliary lines drawn in, the inlet / outlet contacts 7a, 7b, 8a, 8b, 9a, 9b have a total of three different heights, the contacts 7a, 7b and 8a being of the same height and of all contacts being the highest while the Contacts 8b and 9a end somewhat lower and finally contact 9b ends again somewhat lower than contact 9a.

For this fuse switch disconnector to function optimally, it is assumed that a symmetrically switched consumer is to be supplied via this system. This means that when both contacts of a fuse link are completely closed, no current can initially flow, since in such a circuit at least two fuse links must be fully contacted before a current flows through the contacts.

It can be seen from FIG. 1 a that the contacts 7a, 7b and 8a are arranged higher by an amount Ax or extend further up towards the upper part 1 than the contacts 8b, 9a, which in turn are higher by the amount Ay , as the last contact 9b, or its upper edge.

If the upper part 1 is now moved downwards in the direction of the arrow 17, the contact blades 3a, 3b, 4a first engage with their respective counter-contacts 7a, 7b, 8a, while the second contact blade 4b of the second fuse link 4 only comes with a time delay his mating contact 8b engages, this time delay corresponding to the speed of movement of the upper part 1 along the double arrow 17 for the path Ax. Similarly, the contact between the contact knife 5b and the counter contact 9b is only established after a time has elapsed compared to the contact between the contact knife 5a and the mating contact 9a, which can be calculated from the switching speed, specifically the speed of movement along arrow 17, and the distance Ay.

Figure 1 is a schematic top plan view of the lower part 2 of the fuse link. The busbars S1, S2 and S3 as well as the input / output contacts 7a, 7b, 8a, 8b, 9a, 9b can also be seen in this illustration. According to the switching sequence shown in FIG. 1, an arc can at most occur between contacts 4b and 8b. It goes without saying that, for example, the contacts 7a, 7b, more precisely only their height, can also be exchanged with the contacts 8a, 8b. Alternatively one could switch the contacts 7a, 8a, 9a to the contacts 7b, 8b, 9b. As you can easily see, in this way you can select a specific knife contact and counter contact, on which the said arc can or must occur. If the contact heights of the contacts 7a, 7b are exchanged with those of the contacts 8a, 8b, for example, the arc would occur between the contact knife 3b and the mating contact 7b.

As can also be seen, outgoing lines 13, 14 each extend from contacts 7b and 8b to connecting contacts 15 for the consumer connected via the fuse switch disconnector. It goes without saying that the single arc should be moved as far as possible where the slightest risk of arcing or secondary arcing from the contact in question to one of the other contacts, the outgoing lines 13 or 14 or even the busbars S1, S2, S3 could occur. Depending on the height of the outgoing line 13, a corresponding flashover from the contact 8b to the closely adjacent outgoing line 13 cannot be completely ruled out, an arrangement would be most sensible in which the only arc occurs at the contacts 7b or 7a when the fuse switch disconnector is underneath Short circuit conditions is switched on.

If desired, the heights of all access / exit contacts can also be different.

In FIG. 1 c, which only shows schematically the components of the fuse switch disconnector (without upper part 1 and without quenching chambers 16) that can be seen from the right in FIG. 1, both the V-shaped leading edge of the contact knife 3a and the V-shaped one can be seen Inlet area of the lyre contact 7a. It can be seen that with a relatively slow switch-on movement, the inclined surfaces of the leading edge of the knife and the V-shaped inlet area of the contact 7a come into contact relatively loosely, so that an arc is inevitable in the event of a short circuit as a load behind the contacts.

The height differences Ax and Ay shown in FIG. 1 a are of the order of 5 millimeters (mm) for Ax and of about 2-3 millimeters for Δy. These differences in height are sufficient to obtain the desired time sequence of the contacts without causing multiple arcs at the same time. At the same time, this different contact height or the different contact spacing has no negative influence on the switch-off process under load. Even during a normal switch-off process under load, arcs are drawn between the contact blades 3a, 3b, 4a, 4b, 5a, 5b and the contact surfaces of the lyre contacts 7a, 7b, 8a, 8b, 9a, 9b. This creates a double arc on each of the fuse links 3, 4, 5, the total voltage being distributed over the two arcs of each of the fuse links and thus being able to be extinguished relatively easily and quickly with the additional action of the arcing chambers 16. Since the typical arc length is a multiple of the height differences Ax and Ay, these height differences have no significant influence on the voltage drop across the arcs and the extinguishing of the arcs. The advantages resulting from the occurrence of the double arcs and when the contacts are disconnected under load, of the simpler and faster extinguishing of the arcs in such a fuse switch disconnector with linear parallel guidance of the fuse links 3, 4, 5, are therefore fully retained.

FIGS. 2a, b again show two possible variants for achieving the desired switching sequence of the second contact blades of fuse links. The side-by-side arrangement of the Lyra contacts belonging to the three phases L1, L2 and L3 can be found in practice in fuse switch disconnectors, the upper part of which can be pivoted about an axis and carries three fuse links arranged side by side at the same distance from the pivot axis. However, the three lyre contacts arranged side by side here can also be understood as a schematic representation of the contacts 7b, 8b and 9b arranged one behind the other in FIG. 1.

Figure 2a shows a variant in which all three second contact blades 3b, 4b, 5b are arranged at the same height on an upper part (not shown) and can be moved up and down along the double arrow 17, e.g. by swiveling the upper part about an axis that runs horizontally at a distance behind the paper plane and parallel to the paper plane.

The three contacts 7b, 8b. 9b are mounted on the lower part 2 (also not shown in greater detail) at a slightly different height, so that the contact 8b is raised by an amount A x compared to the contact 7b, while the contact 9b is lowered by an amount Ay compared to the contact 7b. It is clear that when the three contact knives 3b, 4b, 5b are simultaneously lowered in parallel, the knife 4b first engages with the lyre contact 8b, and in the case of a symmetrical switching of the consumer, this switching-on operation is again without current. For the rest, it is assumed here that the respective first contact blades 3a, 4a and 5a are already in engagement with their corresponding counter contacts 7a, 8a and 9a before the second contact blades come into contact with their counter contacts.

In the event of a short circuit on the consumer side, an arc can then occur between the contact knife 3b and the lyre contact 7b when the contact knives are further lowered in the direction of the counter contacts, but this arc is relatively far away from the remaining phase L3. The short-circuit current is interrupted by the fuse links 3, 4, which belong to the contact blades 3b, 4b, within a time that is shorter than the time it takes for the contact blade 5b to cover the remaining distance Ay.

The mounting of the lyre contacts 7b, 8b, 9b according to FIG. 2a of different heights, in contrast to a conceivably different length of the respective contact legs, has the advantage that identical lyra contacts can be used, which also ensure the same contact pressure and the same contact conditions . At the same time, of course, this has manufacturing advantages, since no different types of Lyra contacts have to be manufactured.

The second variant, shown in FIG. 2b, shows lyre contacts 7b, 8b, 9b, which are all mounted at the same height. In contrast, the fuse links are either mounted at different heights or mounted inclined relative to each other, so that the contact blades 3b, 4b, 5b have a different distance from their corresponding counter contacts in the position shown. If, in the same way as described in connection with FIG. 2a, the fuse links and thus the contact blades 3b, 4b, 5b are simultaneously lowered at the same speed in the direction of the double arrow, the contact blade 5b first comes into engagement with the counter contact 9b, then, after a further lowering by the amount Ay, the contact knife 3b and finally, after a further lowering by the amount Ax, also the contact knife 4b with the counter-contact 8b. Compared to the version shown in connection with FIG. 2a, only phases L2 and L3 have reversed their roles.

It can be seen that all of the above-mentioned embodiments have the advantage over the prior art that in the event of a short circuit on the consumer side when switching on, significantly fewer arcs and, in the best case, only a single arc, while up to 6 arcs in the prior art at the same time, which could release a lot of energy in a short period of time and on a relatively small volume and thus also trigger secondary short-circuits, which could represent a great danger for an operator and which could also lead to the destruction of significant parts of the entire switchgear . By reducing the number of arcs and the energy thus released and the resulting reduction in metal vapor emissions, the fuse switch disconnector according to the invention can be constructed without complex additional measures to prevent secondary shorts and can therefore also be produced relatively compact and inexpensive.

Claims (12)

1. A method for switching, in particular for switching on a fuse switch disconnector (1), in which three fuse inserts (4, 5, 6) attached to an upper part (2) of the fuse switch disconnector are simultaneously moved essentially parallel and by the same distance and with a lower part (3) of the fuse switch disconnector arranged counter-contacts (7a, b; 8a, b; 9a, b) are brought into or out of engagement, characterized in that the power supply via the three fuse links (4, 5, 6) occurs at different times by the contacting of the first contact blades (3a, 4a, 5a) of each of the fuse links (3, 4, 5) takes place simultaneously or in any time sequence that can be predetermined, while at least for a first fuse link (3,4) at least the contacting of its second contact blade ( 3b, 4b) with the associated mating contact (7b, 8b) before the contacting of the second contact blades (3b, 5b or 4b, 5b) of the other two fuse links (3.5 or 4,5). 2. The method according to claim 1, characterized in that the contacting of the second contact knife (3b) of the first fuse link (3) after contacting the first contact knife (3a) of the first fuse sentence (3). 3. The method according to claim 1, characterized in that the contacting of the second contact (4b) of the second fuse link in time after contacting the first contact blade (4a) of the second fuse link (4) and in time after contacting both contact blades (3a, 3b) the first fuse link (3) 4. The method according to any one of claims 1 to 3, characterized in that all second contact blades (3b, 4b, 5b) are brought into engagement with their corresponding counter-contacts (7b, 8b, 9b) one after the other. 5. The method according to claim 4, characterized in that all first contact blades (3a, 4a, 5a) with their corresponding counter-contacts (7a, 8a, 9a) are brought into engagement before a second contact blade (3b, 4b, 5b) with his corresponding counter contact (7b, 8b, 9b) is brought into engagement. 6. NH fuse switch disconnector with on a lower part (2) arranged inlet and outlet contacts (7a, b; 8a, b; 9a, b), of which the access contacts can be connected to the phases of a multi-phase AC network, each with a pair of Zu - / Outgoing contacts is bridged by a fuse link, which has contact blades (3a, b; 4a, b; 5a, b) for engagement with the incoming / outgoing contacts, and at least such fuse links are attached to an upper part (1) and lower part ( 2) and the upper part (1) can be moved relative to one another in such a way that the contact blades of the fuse links come into engagement with the inlet / outlet contacts of the lower part (2), characterized in that (a) at least some of the inlet / outlet contacts (7a, b; 8a, b; 9a, b;) have a different contact height and / or (b) at least two securing inserts (3, 4, 5) are hung on the upper part (1) at different heights or inclined relative to one another,
The different contact height or different suspension or inclination of the fuse links is guaranteed so that when the lower part (2) and the upper part (1) are moved towards one another, the current is closed via a first of the fuse links before the current is closed via the other fuse links. 7. Fuse switch disconnector according to claim 6, characterized in that at least the access / output contacts of the first fuse link have a different height. 8. Fuse switch disconnector according to claim 6, characterized in that at least the inlet / outlet contacts (8a, b) for the second fuse link (4) or its contact blade (4a, b) are arranged at different heights. 9. Fuse switch disconnector according to one of claims 6 to 8, in which the upper part (1) can be displaced in parallel in the direction of the lower part (2), characterized in that the second contact point of the first fuse link and / or the second contact point of the second fuse link is one have the greatest possible distance to components that are at a different potential or have a different phase than the second contact point. 10. Device according to one of claims 6 to 9, characterized in that the height difference of the second contact point of a fuse link to the first contact point is between one and ten millimeters, preferably between two and five millimeters. 11. Fuse switch disconnector according to one of claims 6 to 8, characterized in that the upper part is pivotable relative to the lower part about an axis, with all three fuse links being substantially the same distance from the pivot axis and the inlet / outlet contacts of the fuse links arranged substantially side by side are characterized in that the second contacts have a different height, the middle of the second contacts preferably having the greatest height. 12. Fuse switch disconnector according to one of claims 6 to 8, in which the upper part can be pivoted relative to the lower part about an axis and the fuse links are at substantially the same distance from the pivot axis and, like the inlet / outlet contacts, are arranged essentially next to one another, characterized in that that the fuse links are suspended in different inclinations on the upper part (1), so that their contact blades, which are the most distant from the axis of rotation, project to different degrees in the direction of the mating contacts, the middle contact preferably being furthest protrudes.

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