EP2383761A1 - Switching device for direct current applications - Google Patents

Abstract

The switchgear has a housing with two side panels opposite to each other. Three holding areas are provided for conducting paths parallel to each other. The holding areas are arranged next to one another in the housing between the two side panels. The conducting paths are associated with assigned arc-unloading devices that are arranged in the housing between the two side panels.

Description

The invention relates to a switching device for DC applications, using components of switching devices for AC applications, eg. As circuit breaker, circuit breaker, switch disconnector and residual current circuit breaker is constructed.

To switch off short-circuit currents in consumer networks switching devices are usually used, which have one or more current paths, which in turn comprise fixed and movable switching contact elements. The movable switching contact elements are movable together between a closed position, in which the mutually associated movable and stationary switching contact elements, and an open position, in which forms an insulating gap between the mutually associated movable and stationary switching contact elements. As soon as the movable switching contact elements are moved under load, that is to say under the flow of current, into the open position, arcing occurs along the separating lines (switch-off). The duration of the arcs determines the switching time since the current flow between the switching contact elements is maintained. In addition, a large amount of heat is released by the arcs, which lead to the thermal destruction of the switching contact elements and thus to reduce the life of the switching device. It is therefore necessary to extinguish the arcs as quickly as possible, which can be done by arc quenching devices such as arc guide rails, arc splitter stacks or Deion packages. These arcing devices divide the arcs into individual partial arcs; if the arc voltages are higher than the driving voltages, the arcs are safely erased.

In AC applications, the arc extinction is facilitated by the current having a natural zero crossing. In the case of large (short-circuit) currents to be disconnected, however, after the current zero crossing, a flashback of the arcs may occur; However, the arcs forming at high currents generate in turn such a large intrinsic magnetic field that they are automatically deflected toward the arc quenching devices and finally extinguished.

In switching devices for DC applications, there is no automatic interruption of the arc as at the zero crossing of the alternating current. In the case of DC applications, therefore, so-called blowing magnets are used which generate a magnetic field with a strength and orientation which exert on the arcs a deflection force (Lorentz force) which deflects the arcs towards the arc quenching devices. In the extinguishing equipment, the arcs are stretched as known per se, cooled and divided into partial arcs and thereby extinguished.

Switching devices of the aforementioned type for AC applications are, for example, in DE 103 52 934 B4 . DE 10212 948 B4 . DE 20 2005 007 878 U1 . EP 1 594 148 A1 . EP 0 980 085 B 1 and EP 0 217 106 B1 described.

According to the prior art, there is a separation between AC and DC switching devices. While AC switchgear in one or more poles configuration can be produced inexpensively in very large quantities, DC switching devices are manufactured as one or two-pole switching devices in much smaller quantities. For this reason, DC switchgear, sometimes with a specified feed direction, is a special device. The use of renewable energy sources such as solar energy, fuel cells, battery banks, etc. increasingly requires switching devices with DC switching capacity and disconnector function in the small and medium current range at voltages up to about 1000 V.

DE 34 09 564 A1 discloses a DC contactor with receiving areas for three parallel current paths, each having two separation sections, with a magnetic drive for transferring the current paths associated movable switching contact elements in a closed or open position. The separation lines open into arc chambers without special arc extinguishing equipment. In a complex manner, a permanent magnet is mounted above each arc chamber, from the two end faces of two pole plates extend laterally next to the arc chamber. The permanent magnets and pole plates blow arcing occurring during separation of the switching contacts into the arcing chambers.

The object of the invention is to be able to produce switching devices with DC switching capability and DC disconnector function cost.

• einem Gehäuse, das zwei einander gegenüberliegende Seitenwände aufweist,
• mindestens drei Aufnahmebereichen für zueinander im wesentlichen parallele Strombahnen mit Trennstrecken, wobei die Aufnahmebereiche in dem Gehäuse zwischen dessen Seitenwänden nebeneinanderliegend angeordnet sind und mindestens zwei der Aufnahmebereiche mit jeweils einer Strombahn versehen sind und jede Strombahn mindestens ein feststehendes Schaltkontaktelement nd ein bewegbares Schaltkontaktelement aufweist, das zum Kontaktieren des feststehenden Schaltkontaktelements in eine Schließstellung und zur Bildung der Trennstrecke in eine Öffnungsstellung bewegbar ist, in der ein sich längs der Trennstrecke erstreckender Lichtbogen ausbildbar ist, wobei sämtliche bewegbaren Schaltkontaktelemente gemeinsam aus ihren Öffnungsstellungen in ihre Schließstellungen und umgekehrt bewegbar sind,
• wobei permanente Magnete zur Ausbildung von Magnetfeldern mit im wesentlichen quer zu den Trennstrecken verlaufenden Feldlinien und einer Ausrichtung zur Erzeugung von auf die Lichtbögen wirkenden Ablenkkräften verwendet werden, weiterhin mit
• Lichtbogenlöscheinrichtungen, die als mit übereinander angeordneten Löschblechen versehene Löschkammern ausgebildet sind, den Strombahnen zugeordnet und ebenfalls nebeneinanderliegend in dem Gehäuse zwischen dessen beiden Seitenwänden angeordnet sind,
• in dem Gehäuse beidseitig der Paare aus jeweils einem bewegbaren und einem feststehenden Schaltkontaktelement ausgebildete Aufnahmeräume für Magnetfeldverstärkungselemente zur Verstärkung des Eigenmagnetfeldes eines sich längs der Trennstrecke ausbildenden Lichtbogens und
• einem in mindestens einem der Aufnahmeräume angeordneten permanenten Magneten mit einem die Lichtbögen zu den Lichtbogenlöscheinrichtungen ablenkenden Magnetfeld.

To solve this problem, a switching device for DC applications according to claim 1 is proposed according to the invention

• a housing having two opposing side walls,
• at least three receiving areas for mutually substantially parallel current paths with separating lines, wherein the receiving areas are arranged side by side in the housing between the side walls and at least two of the receiving areas are each provided with a current path and each current path at least one fixed switching contact element nd a movable switching contact element having the Contacting the fixed switching contact element into a closed position and for forming the separating line into an open position in which an arc extending along the separating line can be formed, all movable switching contact elements being movable together from their open positions into their closed positions and vice versa,
• wherein permanent magnets are used to form magnetic fields with substantially transverse to the separation lines extending field lines and an orientation for generating bending forces acting on the arcs, further with
• Arc quenching devices, which are formed as provided with superposed erase plates extinguishing chambers, associated with the current paths and are also arranged side by side in the housing between the two side walls,
• in the housing on both sides of the pairs of a respective movable and a fixed switching contact element formed receiving spaces for magnetic field enhancement elements for amplifying the intrinsic magnetic field of an arc forming along the separation distance and
• a permanent magnet arranged in at least one of the receiving spaces with a magnetic field which deflects the arcs to the arc-extinguishing devices.

The switching device according to the invention for DC applications is based on the idea of resorting to the manufacture of the switching device on the housing of a switching device for AC applications to adapt this housing in a simple manner and with little effort for the DC application. This means that the housing of the switching device for AC applications must be supplemented by a permanent magnet. This magnet is integrated in a special housing of the housing of the switching device for AC applications, in which normally a ferromagnetic magnetic field amplifying element for amplifying the intrinsic magnetic field of the arc is housed.

An advantageous development of the invention is that in addition to the aforementioned at least one arranged in the special receiving space permanent inner magnet at least one permanent outer magnet is externally attached to at least one of the two side walls of the housing. It is expedient if at least one outer magnet is arranged on both side walls. Internal and external magnets, together with their field lines, penetrate the adjacent separating sections of the individual current paths within the housing for increased deflection of arcing.

A special feature of the switching device according to the invention for DC applications is that the DC switching capacity of conventional AC switching devices is considerably increased by the introduction of internal magnets. In this case, it is not necessary for each separating section and each extinguishing device to be assigned a single magnet, as is the case in known DC switching devices.

It is also possible, when using a housing for AC switching devices as a switching device for DC applications at least one of the current paths (and in particular at least one of the movable switching contact elements), as required for the AC application, not provided. In fact, while AC switching devices are generally three- or four-pole, you need in DC switching devices at most two-pole versions. This makes it possible to dispense with the construction of a DC switching device based on the housing for an AC switching device on the third or the fourth current path. This also reduces the manufacturing cost of the DC switching device. However, it is also possible to maintain the current paths of an AC switchgear housing and to connect at least two of the current paths in series in order to use such a switching device for possibly single-pole shutdown in DC applications using multiple isolation links.

If at least one current path and in particular at least one movable switching contact element is not present in a three- or four-pole AC switching device housing, the corresponding receiving region of the switching device housing can be used to accommodate an additional (blowing) magnet.

The switching devices according to the invention can be designed as ON-OFF switching devices (so-called load switch) or as a power or circuit breaker, the addition of a load switch with an additional functionality, namely the automatic detection and shutdown in the case of a short-circuit current or the like, are provided.

• Figur 1: eine Seitenansicht eines dreipoligen Wechselstrom-Schaltgerätgehäuses bei in ihren Schließstellungen befindlichen bewegbaren Schaltelementen;
• Figur 2: eine Seitenansicht ähnlich der gemäß Fig. 1, jedoch bei in den Öffnungsstellungen befindlichen bewegbaren Schaltkontaktelementen;
• Figur 3: eine Draufsicht auf das Gleichstrom-Schaltgerät mit einem Schaltgerätgehäuse gemäß den Fign. 1 und 2 bei entferntem Oberteil, das in erfindungsgemäßer Weise für die Verwendung als Gleichstrom-Schaltgerätgehäuse modifiziert ist, und
• Figur 4: eine Draufsicht auf ein weiteres Ausführungsbeispiel eines Wechselstrom-Schaltgerätgehäuses, welches für die Nutzung als Gleichstrom-Schaltgerät modifiziert ist.

The invention will now be described with reference to two embodiments and with reference to the drawings. In detail, they show:

• FIG. 1 a side view of a three-pole AC switchgear housing in its closed positions located movable switching elements;
• FIG. 2 : a side view similar to that according to Fig. 1 but with movable switch contact elements in the open positions;
• FIG. 3 FIG. 2: a plan view of the DC switching device with a switching device housing according to FIGS FIGS. 1 and 2 with the top removed, which is modified according to the invention for use as a DC switching device housing, and
• FIG. 4 : A top view of another embodiment of an AC switchgear housing, which is modified for use as a DC switching device.

In the FIGS. 1 to 3 a first embodiment of a switching device 10 according to the invention for DC applications is shown, which is constructed on the basis of a switching device for AC applications. The switching device 10 has a switching device housing 12 by two receiving areas 16,18,20 are arranged side by side between two opposite (outer) side walls 14, wherein in each receiving space a flow path 22 is located. In this case, each current path 22 comprises a movable switching contact element 24 and two mutually opposite stationary switching contact elements 26, 28, which are each provided with connection terminals 30. The three movable switching contact elements 24 are in common between a closed position ( Fig. 1 ) and an open position ( Fig. 2 ), with the aid of a trained in this embodiment as toggle switch 31 actuator 32, which in the usual way with a switching mechanism 34 for locking the movable Switching contact elements 24 cooperates in their closed positions and for common release of the movable switching contact elements 24. The individual current paths 22 are each associated with two arc-quenching devices 36, 38, which are each in the form of individual stacked quenching plates 40, as is known per se. In addition, each flow path 22 has two separating sections 42, 43 which, when the movable switching contact elements 24 are open, form between their ends and the first and second stationary switching contact elements 26, 28 associated with these ends (see FIG Fig. 2 ). Along these separation lines 42,43 form when opening the three-pole switching device 10 under load arcs, which must be deleted with the help of the arc quenching devices 36,38.

Since, in DC applications, arc erasure can not be facilitated due to the zero crossing of the current, DC application of the switching device 10 requires provision of first and second permanent magnets 44, 46 inside the switching device housing 12 Fig. 3 are arranged.

The housing 12 has receiving spaces 56 which are assigned to the separating lines 42, 43 and are arranged on both sides of these separating lines. These receiving spaces 56 are used in an AC switching device of recording own magnetic field boosting elements, as required for AC switching devices with smaller short-circuit currents to divert the arc in the arc quenching device 36 and 38, where it then comes to extinguish the arc. For the application or for the adaptation of the AC switching device housing 12 for DC applications, the magnetic field strengthening elements are removed, so that the receiving spaces 56 are now free to accommodate the permanent magnets 44,46. It is possible that, unlike in Fig. 3 shown, for example, the middle current path 22 is removed, so that the switching device 10 can be used as a two-pole DC switching device.

The first magnets 44 have a magnetic field with field lines in an orientation, which extend transversely to the first separation lines 42 and generate a Lorentz force on arcs along these separation lines 42, which drive the arcs toward the first erasing devices 36. The second magnets 46 in turn generate a magnetic field lines and an alignment, which extend transversely to the second separation lines 43 and generate a Lorentz force on arcs forming along these second separation lines 43, which deflect the arcs in the direction of the second erasers 38. In this case, the first magnets 44 are aligned in a line to the adjacent first separation lines 42, while the second magnets 46 are arranged in a line to the adjacent second separation lines 43. In this way, the three-pole, originally intended for AC applications switching device 10 can now be used for DC applications, with its DC Abschaltvermögen compared to the DC switching capacity of an AC switching device is significantly improved, without requiring significant structural changes ,

It should be noted that in principle a first or a second magnet, that is to say for all the first separating sections 42 and for all second separating sections 43, a single magnet 44 or 46 is required in each case. Likewise, it should be mentioned at this point that it is not absolutely necessary for the realization of the invention to provide a switching device 10 which has two separating sections per current path. The adaptation of an AC switchgear for use in DC applications is also possible with AC switchgear housings which have one single isolating path per current path 22, ie have a movable switching contact element and a single fixed switching contact element per current path 22, so that then for all isolating sections only a single magnet is required.

Fig. 4 shows a plan view of the housing 12 'of another for DC applications modified switching device 10'. As far as the individual components of the device according to Fig. 4 equal or functionally identical to the individual components of Switching device 10 of FIGS. 1 to 3 are, they are in Fig. 4 with the same reference numerals as in the FIGS. 1 to 3 Mistake. The in the Fig. 3 shown inner magnets 44,46 are in Fig. 4 not drawn, but to be regarded as available.

Basically, the housing 12 'according to Fig. 4 constructed as in the FIGS. 1 to 3 played. In addition, each two first and second permanent outer magnets 44 ', 46' are provided, which in the embodiment according to Fig. 4 are arranged outside on the side walls 14 and are held by disc-shaped holding elements 48,50. The first outer magnets 44 'have a magnetic field with field lines in an orientation which extend transversely to the separating lines 42,43 and generate a Lorentz force on arcs forming this separating lines 42,43 which directs the arcs in the direction of the first erasing devices 36 float. The second outer magnets 46 'in turn generate a magnetic field lines and an alignment, which extend transversely to the second separation sections 43 and generate a Lorentz force on arcs along these second separation sections 43, which deflect the arcs in the direction of the second erasers 38. In this case, the first outer magnets 44 'are aligned with the first separating lines 42, while the second outer magnets 46' are arranged in extension of the adjacent second separating lines 43. In this way, can now together with the first and second inner magnets 44,46 from Fig. 3 the three-pole, originally intended for AC applications switching device 10 'after Fig. 4 in relation to the embodiment according to Fig. 3 use even more improved for DC applications, its DC breaking capacity over the DC switching capacity of an AC switching device is significantly improved, without the need for significant structural changes.

It should be noted that the three current paths of the switching devices 10 and 10 'can be connected in series (by external electrical conductors, not shown in the figure) to act as a single-pole DC switching device with a total of six separation sections. But it is also conceivable that of the potential possible three current paths only two are used to realize a two-pole DC switching device. In the case of a four-pole AC switchgear, which is to be modified for DC applications, all four current paths can be connected in series or only two of the current paths can be used as a two-pole DC switching device.

The advantages of the invention provided for using conventional AC switching devices for DC applications are the small modification of conventional, in large quantities and thus inexpensive to produce AC switchgear and the associated cost-effective production of DC switching devices (low time and development effort for the modification and avoidance of an independent development for a pure DC switching device) to see.

Claims (4)

Switching device for DC applications, - With a housing (12) having two opposing side walls (14), - With at least three receiving areas (16,18,20) for mutually substantially parallel current paths (22) with separating lines (42,43), wherein the receiving areas (16,18,20) in the housing (12) between the side walls (14 ) are arranged side by side and at least two of the receiving areas (16,18,20) are each provided with a current path (22) and each current path (22) at least one fixed switching contact element (26,28) and a movable switching contact element (24), the for contacting the fixed switching contact element (26, 28) into a closed position and for forming the isolating section (42, 43) in an open position, in which an arc extending along the isolating section (42, 43) can be formed, wherein all the movable switching contact elements (24) are movable together from their open positions to their closed positions and vice versa, using permanent magnets for the formation of magnetic fields with field lines extending substantially transversely to the separating lines (42, 43) and an orientation for generating deflecting forces acting on the arcs, characterized, - that arc quenching devices (36, 38), which are designed as extinguishing chambers (40) provided with extinguishing plates, are assigned to the current paths (22) and are also arranged side by side in the housing (12) between the two side walls (14), - That in the housing (12) on both sides of the pairs of a movable (24) and a fixed switching contact element (26,28) receiving spaces (56) provided for magnetic field enhancement elements for amplifying the intrinsic magnetic field of an along the separation distance (42,43) forming arc are and - That in at least one of the receiving spaces (56) a permanent magnet (44,46) is arranged with a the arcs to the arc quenching devices (36,38) deflecting magnetic field. Switching device according to claim 1, characterized in that each current path (22) has a movable switching contact element (24) and two opposite first and second fixed switching contact elements (26,28), wherein in the open position between the first stationary switching contact element (26) and the movable switching contact element (24) forms a first separating path (42) and between the second stationary switching contact element (28) and the movable switching contact element (24) forms a second separating path (43) and wherein each first separating path (42) comprises a first arc quenching device (36) and each second separation path (43) is associated with a second arc quenching device (38), and that on both sides of each first pair of each of the one end of the movable switching contact element (24) and the first fixed switching contact element (26) associated therewith a first receiving space (56) for a magnetic field enhancement element and every two on both sides n pair of each of the other end of the movable switching contact element (24) and the second movable switching contact element (24) is formed a second receiving space (56) for a magnetic field enhancement element, wherein in at least one of the first and in at least one of the second receiving spaces (56 ) is arranged in each case a permanent magnet (44,46) for generating deflecting forces acting on along the first and second separating lines (42,43) forming arcs and these to the first and second arc quenching devices (36,38) out distracted. Switching device according to one of claims 1 or 2, characterized by at least one outside on at least one of the side walls (14) of the housing (12) arranged permanent outer magnet (44 ', 46'), wherein the at least one outer magnet (44 ', 46') and a permanent inner magnet (44, 46) arranged in at least one of the receiving spaces (56) of the housing (12) together forms a total magnetic field with field lines substantially transverse to the separating lines (42,43) and form an orientation for generating deflecting forces acting on arcs along the parting lines (42, 43) and deflecting them towards the arc quenching devices (36, 38). Switching device according to one of claims 1 to 3, characterized by a switching mechanism for simultaneous operation and locking of the movable switching contact elements (24).

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