EP2642500A1 - DC circuit without arcing chambers - Google Patents

Abstract

The switch has current sub-conductors (10,11) that conduct load current. An electrically conductive connection is provided between sub-conductors, while the switch is in on-state. The electrically conductive connection is interrupted, while the switch is in off-state. The permanent magnets (41,42,45,46) are provided for generating magnetic field for influencing an arc caused by interruption of electrically conductive connection between sub-conductors. The current sub-conductor (10) is arranged around a coil (31) provided as a guided device for arc influenced by magnetic field.

Description

The invention relates to a switch, in particular with extinguishing chamber-free switching chamber to achieve a high electrical life, wherein the switch, which is provided in particular for a DC operation, two current partial conductor for guiding a load current, wherein in an on state, an electrically conductive connection between the two current divider conductors is provided, which is interrupted in an off state. A magnetic field is provided for influencing an arc caused by the interruption of the electrically conductive connection between the two current dividing conductors.

Electrical switches are components in a circuit that establish or disconnect an electrically conductive connection by means of internal, electrically conductive contacts. With a live connection to be cut, current flows through the contacts until they are separated. When a circuit is disconnected by a switch, the current flow does not reduce immediately to zero, so that an arc can form between the contacts. The arc is a gas discharge by a per se non-conductive medium, such as air. In alternating current (AC) switches, arcs usually erase at the zero crossing of the alternating current. Since such a zero crossing of the current in switches with DC operation (DC) is missing, stable arcing can occur when disconnecting the contacts. If the circuit is operated with sufficient current and voltage, for example, more than about one ampere and more than 50 volts, the arc does not automatically go out. For this reason, in such switches, the extinction of the arc is accelerated by the use of a magnetic field that is poled to exert a driving force on the arc toward a quenching chamber. To generate a strong magnetic field permanent magnets are used as a rule. The so-called magnetic blowing field is either externally over Permanent magnet system or via a generated in the switch own magnetic field, caused by suitable structural design of the current paths in the switching device, generates and drives the switching arc in an extinguishing system, for example in the form of a so-called Deion chamber, where by dividing into several partial arcs with simultaneous cooling through the chamber walls a rapid increase in the arc voltage occurs, so that the switching arc extinguished at the latest when reaching the driving voltage and thus a permanent interruption of the electrical current is effected. Such a switch is for example in the document EP 2 061 053 A2 described.

Depending on the energy content of the arc, this results in a different thermal load on the one hand the contact arrangement, associated with a certain burnup of contact material by evaporation or Verspratzen; The switching chamber walls and the extinguishing chambers continue to be thermally stressed, which results in an additional limitation of the electrical life of the switching device. The thermal stress of the switch during the switching process is particularly high in the case of high arc performance and in the absence or low mobility of the arc, which has a comparatively high contact erosion and locally high thermal loads on the materials in the area of the contacts and the switching chamber result. Likewise, switching arcs with a high energy content often cause flashbacks. This results in a volume range of the switching path, the electrical conductivity has been significantly reduced by deionization of the surrounding gases, to a renewed ignition of the arc, associated with an abrupt collapse of the arc voltage. Repeated flashbacks can significantly increase the overall burn time of the switching arc, resulting in increased thermal stress on the switchgear. Considered over many circuits, this means a shortening of the electrical life of the switch.

Object of the present invention is to realize a switch, preferably for DC currents, in which it by continuous energy extraction at At the same time only low thermal load of the switch components to a fast extinction of the switching arcs comes.

The object is achieved by the switch according to claim 1. In the dependent claims preferred embodiments and advantageous developments are given.

The switch according to the invention has two current part conductors for guiding a load current, wherein in an on state an electrically conductive connection between the two current part conductors is provided, which is interrupted in an off state. A magnetic field is provided for influencing an arc caused by the interruption of the electrically conductive connection between the two current dividing conductors. According to the invention, a coil is arranged around at least one of the current partial conductors, wherein the coil is provided as a guide device for the arc. A coil in the sense of the invention is to be understood as meaning a device made of material which is conductive at least on the surface and which is suitable for guiding the arc along and simultaneously around the current conductor. The coil consists of a single layer turns, the turns do not touch. Alternatively, a designation as a helical or helical coil would be appropriate for the arc guide device.

It is preferably provided that the magnetic field acts on the arc in such a way that it is conducted along the coil. By the thus achieved continuous movement of the switching arc, the thermal load of the switch is minimized. On the one hand, only a comparatively small proportion of contact material is melted and evaporated by the rapid magnetic "blowing away" of the arcs from the contacts, the contact erosion is correspondingly low. On the other hand, the arcs have due to the blowing forces acting no way to remain in the same place and thereby damage the switch components by heat. Furthermore, the arc front moves in this way continuously through a gas environment that is still in the cold state and in the previously no ionization of Gas particles is done. As a result, the arc undergoes a constant energy withdrawal by cooling and in addition a significantly reduced tendency to reignition. Due to the continuous energy withdrawal, the arc current decreases steadily, at the same time the burning voltage experiences a rapid increase, which at the latest when reaching the driving voltage to extinguish the arc and thus leads to permanent interruption of the switching path. By the present invention, a reduction of the thermal arc effect on the components of the switching chamber is realized. As a result, this leads to an increase in the electrical life of the switch.

According to a preferred embodiment, a double-breaking bridge contact piece is provided for making and interrupting the electrically conductive connection between the two current divider conductors, wherein a coil is arranged around each of the two current divider conductors as an arc guiding device. In the following, the invention will be described mainly with reference to this double interrupting version of the two-coil switch. However, it is expressly understood that an application to a single coil is possible.

According to a further preferred embodiment, it is provided that the current partial conductors have a substantially cylindrical shape and are arranged along a longitudinal axis. At mutually facing ends, the current partial conductors on the circumference in each case preferably have a peripheral contact region, in particular of erosion-resistant contact material, for contacting corresponding contact pieces of a bridge contact element. Thus, the contacting takes place on the circumference of the current partial conductor, where the arcs initially arise, which are also performed over the circumference of the current partial conductor. In particular, the current partial conductors have a bead-like thickening, which in each case extends helically around a longitudinal axis on the circumference. A slope of the helices of the bead-like thickening corresponds to a slope of the helical coils, so that the thickening faces the arc conductor everywhere. In such a Arrangement extend the arc bases advantageously along the apex line of the bead-like thickening.

According to a further preferred embodiment it is provided that mutually remote ends of the coils are interconnected. As a result, the current flow through the two antiparallel arcs and over the connected coils can be achieved with a double-breaking switching bridge. Alternatively, only one coil whose end be conductively connected to the current divider of the opposite pole. Even with two coils, this alternative design possibility, wherein the distal ends of the two coils are each conductively connected to the current divider of the opposite pole.

Mutually facing dropouts of the coils preferably extend into the interior of the coil such that the bridge contact is located between the current dividers and the dropouts, thereby facilitating passage of the arc from the bridge contact to the coils. This further assists in when the bridge switch is positioned in the off state immediately adjacent to the dropouts, and more particularly when the bridge switch has recesses that partially surround the dropouts in the off state. Another variant is that the remotely located ends of the coils are not interconnected and instead in the off state, an electrically conductive contact is made by physical contact between the dropouts and the bridge contactor. The person skilled in the art recognizes that, even with an arc presence, a continuous electrically conductive connection between the power connections always has to be realized - until the current is interrupted by the extinction of at least one of the arcs.

According to a further preferred embodiment, a permanent magnet arrangement is provided, each with two subassemblies, wherein each two substantially parallel aligned permanent magnets form a subassembly, wherein a first subassembly generates substantially parallel to the current part conductors extending field lines, ie at the front ends the deflection coils is arranged, and wherein a second subassembly generates field lines extending substantially orthogonal to the current subconductors. In particular, the second subassembly generates field lines parallel to the dropouts. The actually resulting field lines of the permanent magnet arrangement are the result of a superposition of magnetic fields, so that the aforementioned parallel field lines do not occur on their own. The permanent magnet arrangement is preferably equipped with permanent magnets made of rare earth materials, for example Nd-Fe-B or Sa-Co, for obtaining a high magnetic field strength. Particularly preferably, the magnetic poles of the permanent magnets are suitably connected to U-shaped pole plates to obtain a magnetic field of high homogeneity. Further preferably, the switch in each case has a plate of insulating material, preferably of ceramic or thermosetting plastic, which is arranged between the located at the front ends of the deflection coils permanent magnets or their pole plates and the outer ends of the deflection coils to protect the permanent magnetic assembly from arcing, especially in the case of overcurrents.

According to a further preferred embodiment, it is provided that a diameter of the coils expands spirally starting from the dropouts. In this way, the switching arcs are continuously extended during their spiral rotation, which increases the resistance of the arc column and thus the arc voltage steadily. Compared to a similarly sized switching arrangement with deflection coils of cylindrical shape, a faster extinction of the switching arc is effected.

Coils of metal U-profile can be used particularly advantageously, wherein a rounded web portion of the U-profile faces the coil interior. In such an arrangement, the arc bases advantageously extend along the apex line of the U-profile.

According to a further preferred embodiment, the switch is hermetically sealed and with a switching gas of hydrogen or a strong filled hydrogen-containing gas mixture. By significantly improved compared to the conventional atmospheric air arc cooling the arc burning time is considerably shortened, which allows a comparatively compact design of the switching arrangement.

The invention will now be described by way of example with reference to the accompanying drawings. The statements are exemplary and do not limit the general idea of the invention.

• Figur 1 eine erste Ausführungsform des erfindungsgemäßen Schalters,
• Figur 2 eine zweite Ausführungsform des erfindungsgemäßen Schalters,
• Figuren 3 und 4 Details der Ausführungsbeispiele aus den Figuren 1 und 2.

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• FIG. 1 a first embodiment of the switch according to the invention,
• FIG. 2 a second embodiment of the switch according to the invention,
• FIGS. 3 and 4 Details of the embodiments of the FIGS. 1 and 2 ,

The FIG. 1 shows the basic structure of a first embodiment of the switch according to the invention. It is shown a largely concentric switching arrangement, in the longitudinal axis X, two axially aligned, cylindrical current partial conductor 10, 11 are arranged to guide a load current. In the switched case, an electrical connection, preferably by contacting with an electrically conductive bridge contact piece 20, which is mounted in a movable switching bridge 25, made with two contact pieces 21 of a preferably burn-and welded contact material at the end between the two sub-conductors 10, 11 , The bridge switch piece 20 is, for example, mechanically connected to a magnetic drive (not shown), which causes movement of the bridge switch piece 20 perpendicular to the longitudinal axis X of the cylindrical current conductor 10, 11, which is represented by the double arrow P. When switching on, the two contact pieces 21 of the bridge contact piece 20 contact the mutually facing ends of the cylindrical Stromteilleiter 10, 11 on the circumference, in particular directly in a region behind the end faces. The peripheral region 12 affected by the contacting likewise consists, analogously to the bridge contacts 21, of a preferably burn-off and welded contact material.

The two cylindrical current partial conductors 10, 11 are coaxially surrounded by two axially aligned in the axial direction X arranged coils 31, 32, which consist at least on the surface of electrically conductive material and which further consist of a single layer turns, which do not touch mechanically. The two outer ends of these so-called deflection coils are electrically connected to each other. Two inside dropouts 35, 36 of these coils 31, 32 are each angled towards the inside of the coil, wherein the bridge switching piece 20 is positioned in each case between the dropout 35, 36 and the peripheral region 12 of the current partial conductor 10, 11. Further preferably, the two dropouts 35, 36 parallel to each other, offset in the axial direction X, wherein the offset substantially corresponds to a length of the bridge contact piece 20. By the arrangement described it comes in the open switching state to a near-contact between the dropouts 35, 36 of the deflection coils 31, 32 and the two ends of the bridge switching piece 20 on the side facing away from the bridge contacts 21, which in the FIG. 4 is shown in detail. The bridge switch piece 20 is positioned in the off state immediately adjacent to the dropouts 35, 36 and in particular has a recess which partially surrounds the dropouts 35, 36 in the off state.

An unillustrated variant is that the remotely located ends of the coils are separated and instead, in the off state, an electrically conductive contact is made by physical contact between the dropouts 35, 36 and the bridge contactor 20.

The arrangement thus described is located in the interior of a permanent magnet arrangement, consisting of two individual sub-assemblies, each with two mutually parallel permanent magnets. In the in Fig. 1 illustrated embodiment, one of these two sub-assemblies consists of two individual, located behind the outer end faces of the deflection and arranged parallel to each other, plate-shaped permanent magnets 41, 42 which build up an approximately homogeneous magnetic field inside the deflection coils 31, 32, wherein the field lines parallel to the two axially oriented cylindrical flow part conductors 10, 11 extend. Alternatively, this magnetic field can also be formed by a system of two plane-parallel, magnetically highly conductive sheets, which are connected to a permanent magnet in such a way that there is an approximately homogeneous magnetic field between these pole plates.

A second permanent magnetic subassembly is formed in such a way that outside the circumference of the deflection coils 31, 32 at the level of the two dropouts 35, 36 there are two further permanent magnets 45, 46 which are perpendicular to the longitudinal axis X in the area of the switching contacts, in particular parallel to the dropouts 35, 36 form an approximately homogeneous magnetic field, which is perpendicular to the magnetic field of the first subassembly 41, 42.

When switched on, the two axially aligned current partial conductors 10, 11 are connected to one another by the bridge contact piece 20, so that the load current flows through the two current partial conductors 10, 11 and the bridge contact piece 20 in full length. When switching off, between the opening bridge contact piece 20 and the two peripheral regions 12 at the ends of the current partial conductors 10, 11, two parallel switching arcs with opposite current flow direction are formed. Due to the two permanent magnetic arrangements 41, 42, 45, 46 act on both partial arcs at the place of their origin magnetic fields with vectorial components both in the direction parallel to the longitudinal axis X of the current conductor 10, 11, as well as orthogonal thereto, parallel to the dropouts 35, 36th As a result of this, due to the effective Lorentz forces, a magnetic blowing action is produced which, when the switch is correctly polarized, causes both partial arcs to rotate in a spiral, oppositely directed outward direction. In this case, first commute resting on the bridge contacts 21 foot points of the two partial arcs on the immediately adjacent arranged inner dropouts 35, 36 of the deflection coils 31, 32, to then diametrically opposite due to the magnetic blowing effect on the insides of the Deflection coils 31, 32, following the spiral structure, outwardly to move away from each other. The on the current dividers 10, 11 progressive base points of the arcs make the same spiral motion on the cylindrical surface. As a result, the arc column undergoes a permanent spiral rotary motion caused by the magnetic field generated by the permanent magnets 41, 42 located at the end faces of the deflection coils. In addition, the magnetic field generated by the two other permanent magnets 45, 46 causes a force component, which moves the two partial arcs in each case along the longitudinal axis X from each other to the outside. In this way, on the one hand, a very fast commutation of the two arc base points of the bridge contact piece 20 on the dropouts 35, 36 of the deflection coils 31, 32 achieved, on the other hand is determined by this Lorentz force component of the spiral structure of the deflection coils 31, 32, in the direction of the outer End faces directed movement supported.

By the thus achieved continuous movement of the two switching arcs, the thermal load of the switch is minimized. On the one hand, only a comparatively small proportion of contact material is melted and evaporated by the rapid magnetic "blowing away" of the arcs from the contacts, the contact erosion is correspondingly low. On the other hand, the arcs have due to the blowing forces acting no way to remain in the same place and thereby damage the switch components by heat. Furthermore, the arc front moves in this way continuously through a gas environment that is still in the cold state and in the previously no ionization of gas particles is done. As a result, the arc undergoes a constant energy withdrawal by cooling and in addition a significantly reduced tendency to reignition. Due to the continuous withdrawal of energy, the arc current decreases steadily, at the same time the burning voltage experiences a rapid increase, which at the latest when reaching the driving voltage leads to the extinction of the arc and thus to a permanent interruption of the switching path.

The dimensions of the described switching arrangement and the magnetic field strengths of the permanent magnetic arrangements are dimensioned so that the switching arcs always extinguish in the rated current operation before they reach outer ends of the deflection coil 31, 32. To protect the permanent magnetic arrangement 41, 42 at the end faces of the deflection coils 31, 32 against arcing in the case of overcurrents is between the permanent magnet 41, 42 or the pole plates and the outer ends of the deflection coils 31, 32 each have a plate of insulating material 50, preferably made of ceramic or a thermosetting plastic.

In the FIG. 2 a second embodiment of the switch according to the invention with deflection coils 31, 32 is shown of conical shape 60, wherein an outer diameter of the coils 31, 32 increases continuously from the dropouts 35, 36 in the axial direction in each case towards the outside. In this way, the switching arcs are continuously extended during their spiral rotation, which increases the resistance of the arc column and thus the arc voltage steadily. Compared to a similarly sized switching arrangement with deflection coils of cylindrical shape, a faster extinction of the switching arc is effected.

The in the FIGS. 1 and 2 recognizable bead-like thickening 15 along the power dividers 10, 11 are in the FIG. 3 shown schematically in detail. The current partial conductor 10 has the bead-like thickening 15, which extends helically around the longitudinal axis X on the circumference. A pitch of the helices of the bead-like thickenings 15 corresponds to a pitch of the helical coils 31, 32, so that the thickening 15 faces the arc conductor everywhere. In such an arrangement, the arc root points advantageously extend along the apex line of the bead-like thickening 15.

Claims (15)

Switch with two current part conductors (10, 11) for guiding a load current, wherein in an on state, an electrically conductive connection between the two current part conductors (10, 11) is provided, which is interrupted in an off state, wherein a magnetic field for influencing a through the interruption of the electrically conductive connection between the two current partial conductors (10, 11) caused arc is provided, characterized in that at least one of the current partial conductor (10) around a coil (31) is arranged, wherein the coil (31) as a guide device for the Arc is provided. Switch according to Claim 1, characterized in that the magnetic field acts on the arc in such a way that it is conducted along the coil (31). Switch according to one of the preceding claims, characterized in that a double-interrupting bridge contact element (20) is provided for the production and interruption of the electrically conductive connection between the two current part conductors (10, 11), whereby each of the two current part conductors (10, 11) around a coil (31, 32) is arranged as Lichtbogenleitvorrichtung. Switch according to one of the preceding claims, characterized in that the current partial conductors (10, 11) have a substantially cylindrical shape and are arranged along a longitudinal axis. Switch according to one of the preceding claims, characterized in that the current partial conductors (10, 11) at mutually facing ends on the circumference each have a peripheral contact region (12) for contacting corresponding contact pieces (21) of a bridge switching piece (20). Switch according to one of the preceding claims, characterized in that the current partial conductors (10, 11) have a bead-like thickening (15), which in each case extends helically around a longitudinal axis on the circumference. Switch according to claim 6, characterized in that a pitch of the helices of the bead-like thickenings (15) corresponds to a pitch of the helical coils (31, 32). Switch according to one of claims 3 to 7, characterized in that remote from each other ends of the coils (31, 32) are interconnected. Switch according to one of Claims 3 to 8, characterized in that mutually facing dropouts (35, 36) of the coils (31, 32) extend into the interior of the coil in such a way that the bridge contact element (20) lies between the current part conductors (10, 11). and the dropouts (35, 36) is arranged. A switch according to claim 9, characterized in that the bridge switching piece (20) in the off state immediately adjacent to the dropouts (35, 36) is positioned. Switch according to claim 10, characterized in that the bridge switching piece (20) has recesses which partially surround the dropouts (35, 36) in the switched-off state. Switch according to one of the preceding claims, characterized in that a permanent magnet arrangement is provided with two sub-assemblies, wherein each two parallel aligned permanent magnets form a subassembly, wherein a first sub-array parallel to the current part conductors (10, 11) extending field lines generated and a second Partial array generated orthogonal to the power dividers (10, 11) extending field lines. Switch according to Claim 12, characterized in that the second subassembly generates field lines running parallel to the dropouts (35, 36). Switch according to one of claims 9 to 13, characterized in that a diameter of the coils (31, 32) extends from the dropouts (35, 36) starting spiraling. Switch according to one of the preceding claims, characterized in that coils (31, 32) of metal U-profile are used, wherein a rounded web portion of the U-profile faces the coil interior.

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