EP0012451B1 - Selective protection device - Google Patents

Abstract

1. Selective protective device for the selective disconnection of consuming devices, comprising at least one main circuit breaker (14) with a first tripping characteristic and at least one circuit breaker (26), associated with a group of consuming devices, with a second tripping characteristic which lies below the first tripping characteristic, in which the main circuit breaker (14) comprises a disconnecting point in its current path, which disconnecting point is opened by a percussion armature upon the occurrence of an excess or short-circuit current and can quickly be automatically closed again when the current falls below a certain value, a summing tripping device (48) being provided which, as a function of the short-circuit current or of the opening or closing operations of the main circuit breaker (14), acts on the switch latch (50, 104/106) when a predetermined total value is reached, which switch latch (50, 104/106) finally opens the disconnecting point, using thermal and magnetic tripping devices, characterised in that the summing tripping device (48) consists of the series connection or parallel connection or series and parallel connection of a branch, forming from the line current Intg i**2 dt, and a trip coil (54; 72), disposed in a parallel branch (44) to the current path (16; 18) of the main circuit breaker (14), into which parallel branch (44) the current is at least partially switched by a change-over device (40) arranged in the current path (16; 18) upon the occurrence of a short-circuit current.

Description

The invention relates to a selective protection device for selectively switching off consumers with at least one main circuit breaker with a first tripping characteristic, and with at least one circuit breaker assigned to a consumer group with a second tripping characteristic which is below the first tripping characteristic, the main circuit breaker having a disconnection point in its current path is opened by an impact anchor when an overcurrent or short-circuit current occurs and can quickly be automatically switched on again when the current drops below a certain value, a summing trigger device being specified which is a function of the short-circuit current or a function of the opening and closing processes of the Main circuit breaker acts upon reaching a predetermined total value on the switch lock, which finally opens the separation point, using thermal and magnetic tripping ser.

For overcurrent and short-circuit protection, in addition to fuses, circuit breakers have been used more and more frequently recently, which have a thermal release for tripping in the event of an overcurrent and a magnetic release for tripping in the event of a short-circuit current. A bimetal is usually used as a thermal trigger, which bends when an overcurrent occurs, thereby unlatching the switching mechanism and thus separating the contact lever or the movable contact piece from the fixed contact piece. This thermal release is a so-called delayed release because it only responds to an overcurrent due to the heating up after a certain time. As is known, a magnetic armature system is provided as the magnetic trigger, which responds practically without delay and without delay opens the contact point or unlatches the switch lock.

There are generally several possible uses for such a self-switch.

In a first application, the line circuit breaker can be connected downstream of a back-up fuse, whereby its triggering in the event of a short circuit in front of the consumer must take place in such a way that the back-up fuse does not respond either in the overcurrent range or in the short-circuit current range. With the triggers currently customary, one can generally achieve that an automaton is "selective" against a fuse whose rated current is two steps higher than that of the circuit breaker.

There is also the possibility (see FIG. 2) of using the circuit breaker or the circuit breaker as the main circuit breaker between the back-up fuse and a group of downstream circuit breakers as group protection, automatic circuit breaker or the like. Then there are basic difficulties for a selective tripping for this switch, since it has to trip at overcurrents that correspond to about ten times the nominal current in order to protect the line section downstream of it, but must not trip in the event of short-circuits in the consumer area , so that the selectivity of the switches upstream of the consumers compared to the switch downstream of the pre-fuse is preserved.

In order to achieve this, it has become known (DE-OS 2 525 192) to assign a trigger control and a quick opening device for the contacts to each switch, the opening device being designed in such a way that it quickly opens the switch contacts through which the overcurrent flows at the various stages. It is also designed in such a way that it enables the contacts to be switched on again quickly when the current value falls below a predetermined value. For the purpose of selectivity, the trigger control has a counter which counts the successive opening and closing sequences of the contacts and which can trigger the triggering after a predetermined number of sequences, so as to keep the contacts of the corresponding switch open after the predetermined number of sequences. This means that the switch that is directly assigned to the consumer opens after a single opening; the higher-order switch remains open after opening it twice and the higher-order switch after opening it three times and so on.

The problem here is that a resettable counting device is required for the implementation, which means that one has to develop and provide a mechanical or complicated electronic counting device with a network-independent, mechanical or electronic energy store.

This effort is particularly problematic when the switches are to be used very cheaply and in large quantities. In addition, the device described in DE-OS is initially only intended for fuse-free installations.

The object of the invention is to provide a selective protection device of the type mentioned, in which the main circuit breaker optimally supports the downstream circuit breaker with a considerably simplified and less expensive structure, in which an impact armature opens a separation point when an overcurrent or short-circuit current occurs, and even triggers when a certain Ji2 dt is reached.

This object is achieved in that the summing trigger device from the series connection or parallel connection or series and parallel connection of a branch forming the line current ∫ i ² dt and a trip coil which lies in a parallel branch to the current path of the main circuit breaker, in which a switching device arranged in the current path commutates the current at least partially when a short-circuit current occurs.

A particularly advantageous embodiment is that the switching process of the switching device is controlled by the opening movement of the separation point. The switchover device can have an auxiliary isolating point, which is opened mechanically and / or electrically when the isolating point is opened, and at least partially commutates the current on the parallel branch, the parallel branch being connected in parallel with the auxiliary isolating point. The auxiliary separation point can be in series with the separation point or a further auxiliary separation point can be connected in parallel in the parallel branch to the auxiliary separation point, switching when the separation point is opened, the further auxiliary separation point closing when the separation point is opened and, when triggered via a lever linkage, both the separation point as well as the auxiliary disconnect points are movable in the off position.

A further advantageous embodiment of the invention can be such that the branch forming the line current fi ² dt contains an NTC resistor which is connected in series with the coil.

It is also possible to connect a PTC resistor in series with the coil and the NTC resistor.

A further embodiment of the invention can go that the branch forming the line current, fi ² dt is formed by a thermobimetal which forms a current path parallel to the auxiliary disconnection point, a contact being attached to the bending-out end of the thermobimetal, which together with the End of the coil forms a contact point which is open in the de-energized state and is closed when an overcurrent flows through it, so that at least part of the current then flows through the coil to trigger the switch lock.

To delay the opening movement of the thermobimetal, a retarding mass can be attached to it. This retarding mass can be produced from soft iron in order to accelerate the triggering process at very high short-circuit currents and can be arranged in the region of attraction of an iron yoke through which the current of the main current path flows.

A particularly advantageous embodiment of the invention can be such that two miniature circuit breakers are arranged next to one another, each of which has a magnetic release and the separation points of which are in series with one another, a thermobimetal being connected in parallel with the coil of the first miniature circuit breaker, and that an intermediate part is provided, which has the branch from the line current J i ² dt, which branches parallel to the separation point of the first circuit breaker.

The invention and further advantageous refinements of the invention are to be explained and described in more detail with reference to the drawing, in which some exemplary embodiments of the invention are shown.

In particular, the operation of the invention will be explained in more detail with reference to the drawing.

• Figur 1 ein Durchlaßdiagramm für eine erfindungsgemäße Anordnung,
• Figur 2 die Anordnung eines Selbstschalterkaskaden-Netzes,
• Figur 3 eine Prinzipskizze der erfindungsgemäßen Ausgestaltung,
• Figuren 4a bis 4d verschiedene Varianten eines Bauteiles der Anordnung nach Fig. 3,
• Figuren 5a, 5b und c weitere Varianten verschiedener Ausgestaltungen,
• Figur die elektrische Schaltung in einem Hauptleitungsschutzschalter gemäß der Erfindung, Erfindung,
• Figur 7 ein Detail in vergrößerter und herausgezogener Darstellung und
• Figur eine weitere Ausgestaltung der Erfindung.
• Es sei zunächst Bezug genommen auf die Figur 2.

It shows

• FIG. 1 shows a flow diagram for an arrangement according to the invention,
• FIG. 2 shows the arrangement of a self-switch cascade network,
• FIG. 3 shows a schematic diagram of the configuration according to the invention,
• 4a to 4d different variants of a component of the arrangement according to FIG. 3,
• FIGS. 5a, 5b and c further variants of different configurations,
• Figure the electrical circuit in a main circuit breaker according to the invention, invention,
• Figure 7 shows a detail in an enlarged and extracted representation and
• Figure a further embodiment of the invention.
• Reference is first made to FIG. 2.

A mains transformer 10 can be seen, to which a back-up fuse 12 and a main circuit breaker 14 are connected. The electrical line in which the three components are located and which is designated by reference number 16 branches at point 18 for current distribution: circuit distribution into a first branch 20 and a second branch 22, the first branch 20 being a circuit breaker 26 and a consumer 28 and a circuit breaker 30 and a consumer 32 are arranged in the second branch 22. If an embodiment according to the invention is used as the main circuit breaker, then a pass characteristic is obtained, as shown in FIG. 1. The following curves can be seen in FIG. 1:

K ₁₂ denotes the characteristic of fuse 12, K ₁₄ the characteristic of main circuit breaker 14 and K ₂₆ that of circuit breaker 26, the characteristic of circuit breaker 30 being identical to line K ₂₆ . The characteristic curve K _{26 of} the circuit breaker 26, which has a thermal bimetal and a magnetic release, is composed of the characteristic curve of the thermal bimetal K ₂ a _T and the characteristic curve of the magnetic release K _26MA . In the range between 1 = O and I = I _MA26 only the thermal _bimetal responds, since only an overcurrent occurs here; at a current greater than I _MA26 at the circuit breaker 26, the magnetic release responds. The characteristic curve K ₁₄ , which is only considered for the time being, is composed of a thermo bi-metal of the main circuit breaker 14 Area K _14T and an area K _14MA , which is assigned to the magnetic release or the magnetic release of the main _{circuit breaker} . In the range from I = O to I = I _MA14, the thermal release of the circuit breaker 14 acts, and in the area I greater than I _MA14, the magnetic release, which only becomes effective when Q = ∫ i ² dt = Q _{14 has been} exceeded. The area K _MA14 runs approximately horizontally, whereas the further area, as will be explained in more detail below, similarly as the area K _{MA26 follows} a curved course.

• 1. Im Bereich A tritt ein Kurzschluß auf. Dann fließt der Strom durch den Transformator 10, die Vorsicherung 12, den Leitungsschutzschalter 14 und den Leitungsschutzschalter 26. Ist der Strom kleiner noch als I_MA26, dann spricht lediglich das Thermobimetall des Leitungsschutzschalters 26 an und löst aus ohne daß die Sicherung 12 anspricht und ohne daß der Leitungsschutzschalter 14 auslöst. Liegt der Strom zwischen den Werten I_MA26 und I_MA14, so spricht der Magnetauslöser des Leitungsschutzschalters 26 an und löst aus, ohne daß die Sicherung 12 und der Leitungsschutzschalter 14 ansprechen. Liegt der Strom oberhalb I_MA14, so spricht ebenfalls der Magnetauslöser des Leitungsschutzschalters 26 an und löst diesen aus. Der Leitungsschutzschalter 14 öffnet zwar kurzzeitig unter der Einwirkung des Kurzschlußstromes, fällt aber nach Abschalten des Stromes durch den Leitungsschutzschalter 26 wieder in den geschlossenen Zustand zurück. Dabei wird die strombegrenzende Wirkung des Leitungsschutzschalters 26 durch die in dem Leitungsschutzschalter 14 aufgebaute Bogenspannung unterstützt, so daß sich eine Durchlaßkennlinie ergibt, die doppelt gezeichnet mit K₂₆ + K₁₄ bezeichnet ist.
• 2. Sowie ein Kurzschluß am Punkt B auftritt, fließt der Strom lediglich durch die Vorsicherung 12 und den Leitungsschutzschalter 14 hindurch. Im Bereich zwischen I = 0 und I = I_MA14 löst das Bimetall des Leitungsschutzschalter 14 aus, im Bereich darüber kann dagegen der magnetische Auslöser gemäß der Durchlaßkennlinie K14 erst auslösen, nachdem ein Stromquadratintegral durch den Schalter hindurchgeflossen ist, welches größer ist als Q₁₄. Aufgrund der erfindungsgemäßen Anordnung kann nämlich der Leitungsschutzschalter 14 kurzunterbrechend öffnen und wegen der besonderen Ausgestaltung wieder auf Kurzschluß schließen, und dieses Spiel solange wiederholen, bis das Stromquadratintegral Q₁₄ überschritten ist. Erst dann kann erfindungsgemäß der Auslöser des Leitungsschutzschalters 14 ansprechen und diesen Schalter endgültig unterbrechen.
• 3. Befindet sich der Kurzschluß bei Punkt C, also zwischen der Vorsicherung und dem Hauptleitungsschutzschalter 14, dann löst ausschließlich die Sicherung 12 aus.

So much for the basic understanding of the three curves. Reference is now made to the figure again. 2. The following three cases should now be considered:

• 1. A short circuit occurs in area A. Then the current flows through the transformer 10, the back-up fuse 12, the circuit breaker 14 and the circuit breaker 26. If the current is less than I _MA26 , then only the _{bimetallic element of} the circuit breaker 26 responds and trips without the fuse 12 responding and without that the circuit breaker 14 trips. If the current is between the values I _MA26 and I _MA14 , the magnetic release of the circuit breaker 26 responds and trips without the fuse 12 and the circuit breaker 14 responding. If the current is above I _MA14 , the magnetic release of the circuit breaker 26 also responds and triggers it. The circuit breaker 14 opens briefly under the influence of the short-circuit current, but falls back into the closed state after the current is switched off by the circuit breaker 26. The current-limiting effect of the line circuit breaker 26 is supported by the arc voltage built up in the line circuit breaker 14, so that there is a pass characteristic which is shown twice as K ₂₆ + K ₁₄ .
• 2. As soon as a short circuit occurs at point B, the current only flows through the back-up fuse 12 and the circuit breaker 14. In the range between I = 0 and I = I _MA14 , the bimetal of the circuit breaker 14 triggers, in the range above, on the other hand, the magnetic release according to the pass characteristic K14 can only trip after a current _{square integral has flowed} through the switch, which is larger than Q ₁₄ . Because of the arrangement according to the invention, the circuit breaker 14 can open briefly and, due to the special design, close the short circuit again, and repeat this game until the current square integral Q _{14 is} exceeded. Only then can the trigger of the circuit breaker 14 respond and finally interrupt this switch.
• 3. If the short circuit is at point C, ie between the back-up fuse and the main circuit breaker 14, then only the fuse 12 trips.

In the case of point 2, the following conditions must also be observed, which are realized by the arrangement according to the invention. The fi ² dt value = Q _{14 that is} allowed through until the circuit breaker 14 has tripped must not trigger the pre-fuse 12, which is achieved in that the value Q14 lies below the characteristic curve of the fuse. Furthermore, the miniature circuit breaker must not be overloaded and damaged by repeated switching on.

The figure shows the main current path 16, in which a switchover device 40 and the main disconnection point 42 of the circuit breaker 14 are located. A parallel branch 44 is connected to the switching device 40 and opens into the main current path between the switching device 40 and the separation point. In this parallel branch, a series resistor 46 and a tripping device 48 are switched on, which acts on a switching lock 50, which causes the separation point 42 to open via the line of action 52. The triggering device 48 is shown in FIGS. 4a, 4b, c and d. It consists of a conventional tripping coil 54 with a tripping pin, not shown, which acts on the switching mechanism 50 and in series with an NTC resistor 56. A PTC resistor 58 can also be connected in parallel with the coil 54 (cf. FIG. 4b) or a PTC resistor can be connected in parallel with the coil 54 and an NTC resistor 56 in series with the coil (see FIG. 4c).

The opening movement of the separation point 42 controls the switching of the switching device via the line of action 60 in such a way that at least part of the current is switched to the parallel branch 44 when the separation point 42 opens. The switching device 40 will therefore commutate the current to the tripping device 48 when a short-circuit current occurs and thus when the disconnection point 42 opens, with the effect of the resistors 56 and 58, respectively, Fig. 4a, b and c only after a certain fi ² dt value has passed due to the changes in resistance, the current through the trigger coil 54 is increased to such an extent that triggering is possible. In other words, by providing the individual current-variable resistors 56, 58, a change in the tripping characteristic K _{14 is} achieved in such a way that the lower tip region (...- drawn) is cut off and replaced by the horizontal region K _14MA . In this area, the magnetic release can only trigger when a certain value Q ₁₄ = i2 dt has flowed through the respective resistor and has heated it up to such an extent that its resistance value changes in a suitable manner and the current commutates sufficiently strongly to the associated coil . Only then does the magnetic trigger trip.

In the case of Fig. 4a, the current increase of the trip coil 54 takes place in that the NTC-Wi the state 56 becomes sufficiently low-resistance due to heating and the current flow through the coil is thereby increased. In the case of FIG. 4b, it takes place in that the PTC resistor 56 becomes sufficiently high-resistance by heating and thus commutates the current into the coil. In the case of FIG. 4c, both effects are combined with one another. The resistance-changing effect of the PTC or NTC resistors can also be achieved according to FIG. 4d by a bimetal 53, on the one free end of which a contact 55 is attached, which interacts with a fixed contact 57. In the case of FIG. 4d, the bimetal 53 bends out and opens the contact point at 55 and 57; the circuit can also be designed such that the bimetal 53 bends and closes a contact point (not shown).

The switching device 40 is now designed in principle as shown in FIGS. 5a, b, c. In FIGS. 5a and b, an auxiliary contact point 61 is used as the switching device, the triggering device 48 of the auxiliary contact point 61 being connected in parallel in 5a and a closing auxiliary contact point 62 in the embodiment according to FIG. 5b (the auxiliary contact points and auxiliary disconnection points are referred to below), which is connected in series with the tripping device 48, the series connection of tripping device or tripping device 48 and auxiliary disconnection point 62 of the auxiliary disconnection point 61 being connected in parallel. The operative connection between the main separation point 42 and the auxiliary separation point 62 can be made mechanically, in a suitable manner, which is not to be shown further here. As soon as the main separation point is opened by simply opening it with an impact anchor, the auxiliary separation point 62 also closes at the same time, as a result of which part of the current is commutated to the tripping device 48 (FIG. 5b). The mechanical coupling of the main separation point 42 and the auxiliary separation point 62 is such that both the main separation point 42 and the auxiliary separation point 62 are opened after the switching lock 50 has been triggered. This can be achieved, for example, with an additional lever device (not shown further) on which the switching lock acts.

In Fig. 5c, the switching device 40 is practically realized by tapping one of the quenching plates of the arc quenching plate stack 64, which is assigned to the separation point 42, and utilizing the arc current when switching off. After the separation point 42 has been opened, the arc current commutates at least partially onto the tripping device 48; as well as after two or possibly multiple tripping or opening of the contact and current flow through the tripping device the transmission value Q ₁₄ (fi ² · dt) is reached, the tripping device 48 finally releases the switching lock 50 and the separation points remain open.

Further special circuit arrangements, which can be constructed from the elements shown so far, are shown in FIGS. 6 to 8.

The main separation point 42 can be seen in the figure, which is connected via the line of action 60 to the auxiliary separation point 61 forming the switching device 40 of FIG. 3. The main separation point 42 and the auxiliary separation point 61 are opened by an impact anchor system 70, of which only the coil is shown. The parallel branch 44 is connected in parallel with the auxiliary isolating point 61 and contains the series resistor 46, which in the embodiment according to FIG. 6 is designed as a PTC resistor. The tripping device 48 has a tripping coil 72 and a thermobimetal 76 parallel to the tripping coil. The thermobimetal is clamped in place at point 78 and can bend in the direction of arrow F under the action of a current. The free end of the thermobimetal 76 is designed as a contact point 79, which can interact with the free end 82 of the coil 72, which is also designed as a contact point 80 (see dashed line 84 in FIG. 6).

The operation of this arrangement is as follows: Due to a short-circuit current in area A, the isolating point 42 opens together with the isolating point 61 and the circuit breaker 14 in order to support the latter in a current-limiting manner. As soon as the circuit breaker 26 has switched off, there is no current at the circuit breaker 16 (arrangement according to FIG. 6) and after the disconnection points 42 and 61 have closed again, no short-circuit current is registered and the switch 14, ie the disconnection points 42 and 61 remain closed. During the opening time, a certain part of the current has already been commutated via the main current path to the secondary current path 44. The latter has heated the bimetal 76, but not yet so far that it touches the contact 80 and can switch on the trigger coil 72. If the short-circuit current is still present in the case of a short-circuit in area B, the isolating points 42 and 61 switch on to the short-circuit current again after a first opening and the isolating points 42 and 61 are opened again, so that the current again flows at least partially via the bimetal 76 got to. The still warm or warmed bimetal warms and bends further until it closes contacts 79 and 80. A portion of the current in the secondary or parallel branch now flows through the trip coil 72, so that the switching lock 50 is thereby released and causes the final opening of the disconnection point 42. There is of course also the possibility that this process only occurs after the separation points 42 and 61 have been opened several times. It is only important that the bimetal 76, which is designed for a certain transmission value, switches on the trigger coil 72 in the shunt circuit 44 when this transmission value is reached. The series resistor 46, which is advantageously designed here as a PTC resistor, serves to limit the current in the parallel branch 44 and to protect the sensitive bimetal 76 against overload, since the series resistor 46 is open due to the influence of electricity heat increases its resistance.

In order to delay the bending of the thermobimetal 76 in the event of small short-circuit currents, a delay mass 86 can be provided (see FIG. 7). In order to accelerate bending at high short-circuit currents, this mass can consist of soft iron in the case of the embodiment according to FIG. 7. Then in the main current path, which is designated 18, a soft iron yoke 88 is switched on, which, at very high short-circuit currents, magnetically accelerates the switching or thermal bending of the bimetal and thus the closing of the contacts 78 and 90, so that after a single opening operation the Isolation points 42 and 61 the switch lock 50 is released.

Another configuration is shown in FIG. The main current path 18 can be seen again, in which two isolating points 90 and 92 connected in series are switched on. Furthermore, there are a first coil 94 and a second coil 96 in the main current path 18, each of which acts on the contact points or separating points 90 and 92, respectively, via an impact armature shown as the effective line 98 and 100, respectively. In parallel to the separation point 92, the trigger device 48 is again connected, which is designed in the form that is similar to the embodiment according to FIG. In addition, a thermobimetal 102 which is matched to the nominal current is connected in parallel with the coil 96 and can also be connected in series with the coil 94 (but not here), which acts on a first switching mechanism 104. The coil 72 of an arrangement according to FIG. 4b also acts simultaneously on this first switching lock. In comparison to the illustration according to FIG. 4b, the PTC resistor in FIG. 8, which lies parallel to the coil 72, is again designated with the reference number 74 in order to show the similarities. A PTC resistor in series with the coil has the reference number 46 and the secondary branch has the reference number 44.

The circuit arrangement according to FIG. 8 has a further switch lock 106 which is mechanically coupled to the switch lock 104 and can act on the separation point 90 (via the line of action 108) and 92 (via the line of action 110 and 112, respectively). In the cold state, the PTC resistor 74 has a low resistance to the coil 72, so that it carries the major part of the total shunt current IN when the contact or the isolating point 92 has opened. As soon as the resistor 74 has heated up sufficiently (possibly after switching the disconnection points 92 and 90 again if necessary), it becomes high-resistance so that a sufficient current can flow through the coil 72 so that it responds, triggers the switch locks 104 and 106 and avoids further heating of the resistor 74. The two separation points 90 and 92 can be seen. While the separation point 92 practically acts as a switching device, the separation point 90 has the task of opening in a current-interrupting and - particularly importantly - current-limiting manner. In the event of a trip, the disconnection point must also open and, triggered by the switch lock 106, must remain open in order to switch off the current which still flows via the coil 72 when the disconnection point 92 is open.

• Im Falle eines normalen Überstromes im Bereich I = 0 bis I = I_MA14 (vergl. Fig. 1) löst das thermische Auslöseelement, d. h. das Thermobimetall 102 aus. Sowie ein Kurzschlußstrom im Bereich B auftritt, der größer ist als I_MA14, läuft der Auslösevorgang in der Weise ab, wie oben beschrieben. Die Trennstelle 92 öffnet (gegebenenfalls mehrmals) und kommutiert den Strom auf den Nebenzweig 44. Sowie nach ein- oder mehrmaligem Öffnen der Widerstand 74 (ein PTC-Widerstand gleich dem Widerstand 58 der Fig. 4b) und auch der Widerstand 46 (ein NTC-Widerstand gleich dem Widerstand 58 der Fig. 4a) infolge Erreichen eines Wertes Q₁₄ = ∫ i² dt ausreichend heiß sind und damit ihren Widerstandwert entsprechend geändert haben, spricht der Auslöser (Spule 72) an und wirkt auf das Schaltschloß 104 zur endgültigen Öffnung der Trennstelle 92 und damit auf das Schaltschloß 106 zur endgültigen Öffnung der Trennstelle 90. Dieser Vorgang läuft dann ab, wenn der Kurzschlußstrom in dem Bereich liegt, der durch die horizontale Linie K_14MA begrenzt wird. Bei höheren Kurzschlußströmen lösen die Auslöser 96 und 94 praktisch sofort.

In general, the mode of operation of the arrangement according to FIG. 8 is as follows:

• In the case of a normal overcurrent in the range I = 0 to I = I _MA14 (cf. FIG. 1), the thermal tripping element, ie the thermobimetal 102, triggers. As _soon as a short-circuit current occurs in area B which is greater than I _MA14 , the _{tripping process} proceeds in the manner described above. The separation point 92 opens (possibly several times) and commutates the current to the secondary branch 44. As well as after opening one or more times the resistor 74 (a PTC resistor equal to the resistor 58 in FIG. 4b) and also the resistor 46 (an NTC Resistance equal to the resistance 58 of Fig. 4a) due to reaching a value Q ₁₄ = ∫ i ² dt are sufficiently hot and thus have changed their resistance value accordingly, the trigger (coil 72) responds and acts on the switch 104 to finally open the Disconnection point 92 and thus on the switching lock 106 for the final opening of the separation point 90. This process takes place when the short-circuit current lies in the area which is limited by the horizontal line K _14MA . At higher short-circuit currents, triggers 96 and 94 release practically immediately.

If there is a short circuit in area A, this is interrupted by the circuit breaker 26 before the triggering device responds. If a short circuit current occurs in region B that is greater than I _MA14 , the _{tripping process} proceeds in the manner described above.

The arrangement of Fig. 8 can be practically divided into three parts.

A total of three framed elements can be seen, a dashed I, a dash-dotted III and a part II .. - ruling. The dashed part is designated I and practically forms a first automatic circuit breaker with thermobimetal, while the - .. framed part forms a second automatic circuit breaker without thermobimetal and is identified with II. The dash-dotted section III is to be regarded as an intermediate part, which corresponds to the triggering device 48 (see FIG. 3).

It should be added that the horizontal range (Q ₁₄ I K14MA) only runs in the so-called ideal case, similar to the downward-pointing peaks in I _MA26 . In reality, the curves are somewhat more rounded, although K _{14 has} a much flatter area than K ₂₆ .

6 is to be briefly stated that the free end of the bimetallic 76, that is in the region of the contact 79, connected to the line of the parallel branch 44 by means of a wire 77 is so that the bimetal 76 can move freely.

Claims (12)

1. Selective protective device for the selective disconnection of consuming devices, comprising at least one main circuit breaker (14) with a first tripping characteristic and at least one circuit breaker (26), associated with a group of consuming devices, with a second tripping characteristic which lies below the first tripping characteristic, in which the main circuit breaker (14) comprises a disconnecting point in its current path, which disconnecting point is opened by a percussion armature upon the occurrence of an excess or short-circuit current and can quickly be automatically closed again when the current falls below a certain value, a summing tripping device (48) being provided which, as a function of the short-circuit current or of the opening or closing operations of the main circuit breaker (14), acts on the switch latch (50, 104/106) when a predetermined total value is reached, which switch latch (50, 104/106) finally opens the disconnecting point, using thermal and magnetic tripping devices, characterised in that the summing tripping device (48) consists of the series connection or parallel connection or series and parallel connection of a branch, forming from the line current i2 dt, and a trip coil (54 ; 72), disposed in a parallel branch (44) to the current path (16 ; 18) of the main circuit breaker (14), into which parallel branch (44) the current is at least partially switched by a change-over device (40) arranged in the current path (16 ; 18) upon the occurrence of a short-circuit current.

2. Selective protective device according to claim 1, characterised in that the change-over operation of the change-over device (40) is controlled by the opening movement of the disconnecting point (42).

3. Selective protective device according to claim 2, characterised in that the change-over device (40) comprises an auxiliary disconnecting point (61) which, when the disconnecting point (42) is opened, is controlled by the latter so as to be mechanically and/or electrically opened and switches the current at least partially to the parallel branch, which is connected in parallel with the auxiliary disconnecting point (figure 5a).

4. Selective protective device according to claim 3, characterised in that the auxiliary disconnecting point (61) is connected in series with the disconnecting point (42).

5. Selective protective device according to one of claims 1 to 3, characterised in that the parallel branch (44) is connected in parallel with the auxiliary disconnecting point (61), and a further auxiliary disconnecting point (62) is arranged in the parallel branch, the further auxiliary disconnecting point closing when the auxiliary disconnecting point opens and both the disconnecting point and the auxiliary disconnecting points being movable into an off position when tripping takes place by way of a lever bar.

6. Selective protective device according to one of the preceding claims, characterised in that the parallel branch (44) is connected at one end to one of the arc quenching plates (64) of the main circuit breaker (14).

7. Selective protective device according to one of the preceding claims, characterised in that the branch forming from the line current i² dt comprises a NTC resistor which is connected in series with the coil.

8. Selective protective device according to one of claims 1-7, characterised in that the branch forming from the line current ∫ i² dt is formed from a PTC resistor (58) connected in parallel with the coil (54) of the magnetic trip and possibly with the NTC resistor (56).

9. Selective protective device according to one of claims 1-6, characterised in that the branch forming from the line current J i2 dt is formed by a thermostatic bimetal (53) which forms a current path parallel to the auxiliary disconnecting point, a contact (55) being attached to the outwardly bent end of the thermostatic bimetal and forming, together with the end of the coil (54), a contact point (55, 57) which is open at zero load and closed during the passage of an excess current, so that at least some of the current then flows through the coil in order to trip the switch latch.

10. Selective protective device according to claim 9, characterised in that a time-delay mass (86) is mounted on the thermostatic bimetal (76) in order to delay the opening movement of the latter.

11. Selective protective device according to claim 10, characterised in that, in order to accelerate the tripping operation in the case of very high short-circuit currents, the time-delay mass (86) is made of soft iron and is disposed in the sphere of attraction of an iron yoke (88) through which current of the main current path (18) flows.

12. Selective protective device according to one of the preceding claims, characterised in that two circuit breakers (I, II) are arranged next to one another, each of which comprises a magnetic trip and the disconnecting points (92, 90) of which are arranged in series, a thermostatic bimetal (102) being connected in parallel with the coil (96) of the first circuit breaker, and in that an intermediate part (III) is provided and comprises the branch forming from the line current J i2 dt and disposed parallel to the disconnecting point of the first circuit breaker (I).

Images