Priority is claimed to German Patent Applications No. DE 10 2012 112 774.3, filed on Dec. 20, 2012, and DE 10 2013 111 953.0, filed on Oct. 30, 2013, the entire disclosure of each of which is incorporated by reference herein.
The invention concerns a switching device for direct current operation that comprises at least one contact pair which contains a first contact and a second contact, where at least the second contact is movable relative to the first contact. The invention envisions an extinguishing device with an extinguishing chamber for extinguishing an arc produced between the contacts, a first guide rail arrangement for guiding the arc with a first direction of current in a first direction into said extinguishing chamber and a second guide rail arrangement for guiding the arc with a second direction of current in a second direction in the extinguishing chamber specified. Both guide rail arrangements each comprise a first guide rail and a second guide rail, where both first guide rails run starting from the first contact in opposite directions to each other, and the second guide rails run starting from the second contact in opposite directions to each other.
Switching devices with one or several current paths, which comprise fixed or movable contacts, are generally used for switching off currents in consumer networks. The movable contacts can be moved jointly between a closed position, where the movable and fixed contacts touch each other, and an open position, where there is a separating path established between the movable and fixed contacts, which are assigned to each other. When the movable contacts under load, i.e. under the current flow, are moved in the open position, arcs are formed along the separating paths. The burning time of the arc determines the switching time because the current flow is maintained between the contacts. Furthermore, the arcs produce a significant amount of heat, which cause the thermal destruction of the contacts and components of the switching chamber located near the contacts and thus result in reducing the useful life of the switching device. The arc must therefore be extinguished as quickly as possible by the arc extinguishing devices. The extinguishing devices separate the arcs, for example, into individual partial arcs. As soon as the arc voltages exceed the driving voltages, the arcs are securely extinguished.
The magnetic fields generated by the currents themselves are often used for extinguishing especially high currents to drive the forming switching arcs independently quickly away from the contacts toward the extinguishing devices, where they are finally extinguished.
In case of switching devices for direct current, the arc is not interrupted independently as in case of the zero passage of the alternating current. Therefore, in cases of direct current applications, blow magnets are used that generate a magnetic field with a given strength and orientation, which generates a deflecting force (Lorentz force) on the arcs that deflects the arcs to the arc extinguishing devices. In the extinguishing devices, the arcs are stretched, cooled, separated into partial arcs and extinguished in this manner.
Such a switching device as specified in the outset is known from EP 2 061 053 A2. For creating a switching device for direct current applications, it is recommended that the housing of a switching device for alternating current applications be used, where at least one magnet is provided in addition, which creates a magnetic field with field lines predominantly transverse to the isolation gaps of current paths of the alternating current switching device. There are three receiving regions in the housing for each single current path, where each current path is assigned a movable switching contact element as well as two fixed switching contact elements opposite to each other. The three movable switching contact elements can be moved together, between a closed position which corresponds to the switched-on state of the switching device, and an open position which corresponds to a switched-off state of the switching device. The individual current paths are each assigned two arc extinguishing devices in the form of extinguishing plates, arranged individually over one another and electrically insulated from each other. In addition, each current path has two separation sections which, when the movable switching contact elements are open, form between the ends of the movable switching elements and the first and second fixed switching elements which are allotted to the ends of the movable switching contact elements. On opening of the switching contact elements, an arc which can be extinguished with the help of arc extinguishing devices is formed along each separation section. In direct current applications, the arc cannot be extinguished at the zero current passage, as in alternating current applications, and therefore a magnetic field must be used in most direct current applications to drive the arc into an arc extinguishing device. This magnetic field is built up by permanent magnets, where a magnetic field is generated with field lines in a direction which runs transverse to the separation sections and creates a Lorentz force on the arcs that form along these separation sections which drives the arc in the direction of an arc extinguishing device. In this context, an arc between a first contact pair is driven in the direction of a first arc extinguishing device and the arc between a second contact pair is driven in the direction of the second arc extinguishing device. Since the movement of the arcs is dependent on the direction of the current, the switching device is only suitable for one current direction, i.e. polarity. If the switching device is operated in the opposite current direction, the arcs will not be driven into the arc extinguishing devices but in the opposite direction to a switching bridge. Even if the magnetic polarity of one of the arc extinguishing devices is reversed, one of the arcs would run towards a switching bridge, which would result in reduced lifetime, since the switching bridge or other part would be damaged or even destroyed in the long run.
The EP 0 789 372 B1 also shows a switching device of the type mentioned at the outset. A fixed contact is provided with a fixed arc runner which is circular arc-shaped. A movable arc runner is provided on a movable contact, where an arc can form between the two arc runners, which can be moved in different directions by the arc driver assembly in accordance with the direction of the current. In accordance with the direction of current, this is diverted around a center point, either in the first direction of rotation or in a second direction of rotation opposite to the first, where the center point corresponds to the center point of the fixed arc runner. An arc with the first direction of current is diverted into a first arc runner channel and an arc with a direction of current opposite to the first direction of current is diverted into the second arc runner channel. Both arc runner channels run around the center point and are arranged next to each other separated by an insulating wall. The arc runner channels are part of an extinguishing device for extinguishing the arc. Furthermore, the extinguishing devices comprise extinguishing plates which are radially oriented to the stationary arc channels. The extinguishing plates are arranged in such a way that they cover both the arc channels and, therefore, are part of both extinguishing devices.
In many known switching devices, the arc formed during switching is driven in a blowout field generated by a permanent magnet into an extinguishing chamber, for example, a deion extinguishing chamber, to be extinguished there. The guide rails of the arc guiding devices run from the contacts to the outside in diverging directions.
Depending on the polarity of the current, immediately after its creation, the switching arc is driven by the Lorentz force away from the switching contacts along one of the two guide rail arrangements, which run diametrically apart, in the direction of the extinguishing chamber, where the arc is normally quickly extinguished when reaching the driving voltage.
In switching arcs with high energy content, especially with a high inductive share in the current circuit, it can happen that the arc entering the extinguishing chamber only loses part of its energy in the chamber and is not completely extinguished. In that case, re-ignitions can occur after passing through the extinguishing chamber by the arc moving from the outside end of the extinguishing chamber to the end of the guide rail and in certain cases running again in the direction of the contacts. Depending on the geometry of the switching chamber, the arc can also burn steadily at certain locations, for example at the terminations of the guide rails, which causes an extension of the burning time of the arc and therefore a higher thermal load on the switching chamber, which can cause a reduction of the electrical useful life of the switching device.
In an embodiment, the invention provides a switching device for direct current operation. The device includes: a contact pair, which contact pair includes a first contact and a second contact, at least the second contact being movable relative to the first contact; and an extinguishing device including an extinguishing chamber configured to extinguish an arc produced between the first contact and the second contact. The extinguishing device includes a first guide rail arrangement configured to guide the arc with a first direction of current and a second guide rail arrangement configured to guide the arc with a second direction of current in said extinguishing chamber. Each of the guide rail arrangements includes a first guide rail and a second guide rail, wherein first guide rails, starting from the first contact, run in opposite directions. The second guide rails, starting from the second contact, run in opposite directions. The first guide rails are connected to each other in a conductive link forming a closed loop.
The present invention will be described in even greater detail below based on the exemplary figures. The invention is not limited to the exemplary embodiments. All features described and/or illustrated herein can be used alone or combined in different combinations in embodiments of the invention. The features and advantages of various embodiments of the present invention will become apparent by reading the following detailed description with reference to the attached drawings which illustrate the following:
An aspect of the invention provides a switching device for direct current operation, comprising at least one contact pair, comprising a first contact and a second contact, where at least the second contact is movable relative to the first contact. The invention also envisions an extinguishing device with at least one extinguishing chamber for extinguishing an arc produced between the contacts, a first guide rail arrangement for guiding the arc with one direction of current and a second guide rail arrangement for guiding the arc with the second direction of current into said extinguishing chamber. Both guide rail arrangements comprise each a first guide rail and a second guide rail, where both first guide rails starting from the first contact run in the opposite direction to each other, and the second guide rails starting from the second contact run in the opposite direction to each other. The first guide rails are connected with each other in an electrically conductive arrangement in the form of a closed loop. Preferably, the guide rails are connected in an electrically conductive arrangement on the side of the second contact facing away from the first contact.
The term “closed loop” means that there is a kind of closed electrical circuit that has an optional geometry, for example, a ring shape. In this case, the guide rails should be considered “closed”, when they have short interruptions, as long as the arcs can bridge these interruptions without any difficulty.
An aspect of this invention is to ensure that even arcs with a high energy content are kept in a continuous constant motion in the blowout field of the permanent magnet to ensure that the thermal load of different areas within the switching chamber is reduced significantly and the expected lifetime of the switching chamber is significantly increased accordingly. In an embodiment, the first guide rails on the side of the fixed contact connected to each other and thus closed. In this case, the outgoing ends of both guide rails are connected to each other, preferably with a connecting bracket. The terms switching chamber and switching device will be used below as synonyms of each other.
Preferably, the extinguishing device comprises an extinguishing chamber, and the guide rail arrangements are arranged in a manner that the arcs are driven in the extinguishing chamber independent of the direction of current and the running direction of the arc.
For technical reasons of manufacturing, it can be advantageous when the guide rail arrangements consist of several parts, which are connected friction-locked during the assembly process. The two guide rails can be connected to each other by a connecting bracket. In an especially preferred embodiment, the connecting bracket has a cut where the cut runs approximately in the middle along the closed loop for centering the arc, that is, in the direction of movement of the base point of the arc. The base points of the arc preferably run along sharp, conductive edges. When the outside edges of the bracket are covered by the attaching housing walls, the arc is advantageously conducted on the edges of the middle cut. The arc is centered in this manner, displaced from the ideal middle position only by half the width of the gap. Additionally, the gases produced during the switching operation can be blown out through the cut.
It is generally advantageous, however, to avoid the number and/or size of the brackets or notches transverse to the direction of movement of the arc in the guide rail arrangement, because partial arcs can form in the respective areas and these cause a significantly increased wear on the components. In a preferred embodiment, both first guide rails make up an essentially U-shaped single conductive element, by preferably not having any joints. The conductive element can be an advantageously shaped component or produced cost-efficiently as a simple punched and bent part.
An especially preferred embodiment also provides that the first contact is arranged at the single-piece conductive element. In an alternative embodiment, the single-piece conductive element has a cut, and the conductive element can be placed on the fixed contact support in such a manner that the first contact sticks out through the cut. The edges of the cut, which preferably adjoin the sloped sides of the contact, and are preferably resilient, establish an electrical connection between the contact and the conductive element. In this arrangement, the arc does not have to overcome an insulating soldering material, as it can go easily from the contact to the conductive element.
The extinguishing chamber can be fit between the two first guide rails, to ensure that the arcs are driven efficiently into the extinguishing chamber. The extinguishing chamber is preferably designed as a deion extinguishing chamber with a multitude of conductive extinguishing plates that are electrically insulated from each other and arranged parallel to each other.
The two second guide rails can be connected with each other in an electrically conductive arrangement in the form of a closed loop. Preferably, the two second guide rails are connected in an electrically conductive arrangement on the side of the second contact facing away from the first contact. On the side of the movable contact, the terminations of the guide rails bent in the direction of the underside of the contact (soldered side) are extended in such a manner that they form a partially or completely closed loop, for example, shaped as a ring or an ellipsis. The second guide rails are then connected to each other in a ring shape and they are shaped as a single piece.
In a preferred embodiment, the second contact is arranged on a contact piece which is movable as compared with the first contact, and the second guide rails make up a shared separate integral component, which is connected to the contact piece.
Due to manufacturing considerations, the guide rail arrangement can be made preferably of two separate components of a simple geometry. During the device-mounting process, the components are connected securely to each other using the appropriate method. Besides the advantage of a more simple production process, a guide rail manufactured as a separate component can be made of a lighter, thermally more resistant material while avoiding the drawbacks of copper which despite its good conductive properties is relatively heavy and soft.
For the harmonious propagation properties of the arc, it is especially advantageous if the base points of the arc preferably run along the middle of the guide rails because the probability of transferring the arc from the sides of the guide rails in areas in the vicinity of the walls of the switching chamber is significantly reduced, where it could cause high thermal stress on the material.
For this purpose, at least one of the guide rails can have a ridge that is elevated against the other guide rail at least partly in the direction of propagation of the arc. The ridge can be manufactured by applying impressions on the arc guide rails which run in the middle of the guide rails for the entire length of the guide rail or in critical sections.
For generating the Lorentz force on the arc, there is at least one arc driver assembly provided, which generates a magnetic field at least in the area of the contact pairs.
The arc driver assembly can comprise an external pole element and an internal pole element, where both pole elements are designed as U-shaped sections, each with a base bridge and two pole plates jutting out from the base bridge.
The inner pole element is placed preferably within the outer pole element, where at least one permanent magnet is provided between the base bridges of both pole elements, and there is a contact pair between one pole plate of the external pole element and a pole plate of the internal pole element.
The electrical switching device 1 comprises a total of two poles, i.e. two current paths, that is, a first current path 2 and a second current path 3. Basically, more than two current paths can be provided, where preferably two current paths in pairs are provided as described below. Both the current paths 2, 3 are each provided with a switching arrangement, as described in detail below, and can thus be electrically cut off. Both the current paths 2, 3 can each be integrated into a direct current circuit and can be used to interrupt a current flow.
The switching device 1 includes a housing 6, in which the switching arrangements are incorporated as described below. Current paths 2, 3 run next to each other from the first side 16 of the switching device 1 to a second side 17 of the switching device 1. The first current path 2 includes a first connection 4 and a second connection 5 for the purpose of connecting the first current path 2 with connections of a direct current circuit. Both the connections 4, 5 are located on opposite sides of the switching device 1 and protrude out of the housing 6. Correspondingly, the second current path 3 has a first connection 4′ and a second connection 5′, where the first connection 4′ is located on the same connection side as the first connection 4 of the first current path 2. The second connection 5′ of the second current path 3 is arranged on the same connection side as the second connection 5 of the first current path 2. In the description which follows, the first current path 2 will be described in more detail and is representative of both current paths 2, 3, where the second current path 3 is identically constructed, unless otherwise stated.
The first connection 4 leads to a first contact pair 7, which is arranged in the first switching chamber 13 of the housing 6. The second connection 5 leads to a second contact pair 8, which is arranged in the second switching chamber 14 of the housing 6. Both the switching chambers 13, 14 are electrically insulated from each other in the housing 6 and arranged in a direction from the first connection 4 to the second connection 5 in sequence and covering each other. The first connection 4 is electrically connected to a contact support in the form of a fixed contact support 11 on which a first contact 9 of the contact pair 7 is arranged. A second contact 9 is arranged movable relative to the first contact 18. The second contact 18 as shown in the
The second connection 5 leads to a first contact 10 of the second contact pair 8, which is arranged on another contact support in the form of a stationary contact support 12. A second contact 19 is kept movable relative to the first contact 10 of the second contact pair 8, which is also arranged on the bridging contact member 15 and is electrically connected to the second contact 18 of the first contact pair 7. Thus, both contact pairs 7, 8 can be opened or closed by adjusting the bridging contact member 15.
The fixed contact supports 11, 12 of both current paths 2, 3 are arranged in such a way that the first contacts (fixed contacts) are aligned on a common axis, where the axis runs parallel to a main direction of both current paths 2, 3
When switching the switching bridge 20 into an opened position, arcs that must be extinguished can form between the contacts 9, 18, 10, 19. An extinguishing device 21, 22 each is provided on the side of the first contacts 9, 10 facing away from the second contact 18, 19 for this purpose, where both extinguishing devices 21, 22 of both contact pairs 7, 8 are identically built. Here, a first extinguishing device 21 is assigned to the first contact pair 7 and a second extinguishing device to the second contact pair 8. Both extinguishing devices encompass extinguishing plates 23, which are electrically insulated from one another, arranged parallel to each other and are themselves electrically conducting. Thus, they form a deion extinguishing chamber.
An arc driver assembly 24 (
The exact setup can also be seen on
The individual pole plates 29, 30, 31, 32 are arranged transverse to the current paths 2, 3 and generate a Lorentz force to act on an arc which forms between the contacts 9, 10, 18, 19, so that the arc can be driven into the extinguishing devices 21, 22.
The closed guide rail arrangement 41, 42, starting from the movable second contact 18, is arranged on the side of the fixed contact, eccentric on the inside of the closed guide rail arrangement 39, 40, and in two areas the guide rail arrangement 39, 40 on the side of the fixed contact run in parallel with the guide rail arrangement 41, 42 on the side of the movable contact. In the area of the two contacts 9, 18, there is a minimum distance between the guide rails, and the distance is significantly higher within the parallel area located opposite to the first, where the extinguishing chambers are nested in.
Due to the formation of a homogenous magnetic field with field lines from one of the first pole plates 29 to the other of the first pole plates 30, the magnetic field lines are perpendicular to the arc, so that a Lorentz force acts on it and drives the arc sideways away from the contact pair 7. The arc is then driven to the right or left, depending on the direction of current in accordance with
The first guide rail 39 of the first guide rail arrangement 37 in
The second guide rail arrangement 38 is constructed as an identical mirror-image of the first.
A comparatively low-energy arc will lose so much energy in the first extinguishing device 21 in the form of a deion extinguishing chamber due to forming several partial arcs and due to the cooling effect of the extinguishing plates 23 that it reaches the driving voltage quickly and, therefore, the arc is extinguished. In case of an arc with comparatively high energy content, for example in a strong inductive circuit, it can happen that the arc loses only part of its energy after entering the extinguishing chamber 21, and under the force of the blowout field generated by the permanent magnets, the partial arcs run through the entire length of the extinguishing chamber 21, and then finally they transfer to the connection base of the guide rails 39, 40 on the side of the fixed contact. Due to the continuous effect of the blowout field, an arc bridge is finally formed between the external (longer) plate of the extinguishing chamber 21 and the side section of the guide rails 39, 40 located on the side of the fixed contact, directly opposite to the extinguishing chamber, and hence the arc runs again in the direction of contacts 9, 18. After “passing” contacts 9, 18, the arc can run again along the guide rails 39, 40, 41, 42 in the direction of the extinguishing chamber 21. If the arc has sufficient energy remaining, one or several cycles of arc propagations can form until the arc loses so much energy that it extinguishes. Even if the arc voltage drops again for a short time after running through the extinguishing chamber 21 and transferring to the guide rail 39, 40 located on the fixed contact side, this voltage drop is quickly compensated due to the continuous forward movement of the arc and re-entry in the extinguishing chamber 21, and the arc voltage increases steadily until the arc finally extinguishes. However, the continuous thermal load generated by the arc causes a higher total load on the switching chamber for a longer period due to its continuous forward movement, the arc does not “burn into” the different areas of the switching chamber in this manner, which would cause a significant reduction of the lifetime of the switching device.
As presented in
For the harmonious propagation properties of the arc, it is especially advantageous if the base points of the arc are preferably running along the middle of the guide rails 39, 40, 41, 42, because the probability of transferring the arc from the sides of the guide rails to areas in the vicinity of the walls of the switching chamber is significantly reduced, where it could generate increased thermal stress on the material. The above effect can be obtained in construction, as presented in
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. It will be understood that changes and modifications may be made by those of ordinary skill within the scope of the following claims. In particular, the present invention covers further embodiments with any combination of features from different embodiments described above and below. Additionally, statements made herein characterizing the invention refer to an embodiment of the invention and not necessarily all embodiments.
The terms used in the claims should be construed to have the broadest reasonable interpretation consistent with the foregoing description. For example, the use of the article “a” or “the” in introducing an element should not be interpreted as being exclusive of a plurality of elements. Likewise, the recitation of “or” should be interpreted as being inclusive, such that the recitation of “A or B” is not exclusive of “A and B,” unless it is clear from the context or the foregoing description that only one of A and B is intended. Further, the recitation of “at least one of A, B, and C” should be interpreted as one or more of a group of elements consisting of A, B, and C, and should not be interpreted as requiring at least one of each of the listed elements A, B, and C, regardless of whether A, B, and C are related as categories or otherwise. Moreover, the recitation of “A, B, and/or C” or “at least one of A, B, or C” should be interpreted as including any singular entity from the listed elements, e.g., A, any subset from the listed elements, e.g., A and B, or the entire list of elements A, B, and C.
Number | Date | Country | Kind |
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10 2012 112 774 | Dec 2012 | DE | national |
10 2013 111 953 | Oct 2013 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
2150564 | Rowe | Mar 1939 | A |
4656446 | Chien et al. | Apr 1987 | A |
4743720 | Takeuchi et al. | May 1988 | A |
4963849 | Kowalczyk et al. | Oct 1990 | A |
5004874 | Theisen et al. | Apr 1991 | A |
5130504 | Moldovan et al. | Jul 1992 | A |
5138122 | Moldovan et al. | Aug 1992 | A |
5818003 | Moldovan | Oct 1998 | A |
5969314 | Rakus et al. | Oct 1999 | A |
6417474 | Rakus et al. | Jul 2002 | B1 |
7915985 | Schmitz et al. | Mar 2011 | B2 |
8368492 | Theisen et al. | Feb 2013 | B1 |
Number | Date | Country |
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1186125 | Jan 1965 | DE |
1202378 | Oct 1965 | DE |
2423660 | Dec 1974 | DE |
0789372 | Aug 1997 | EP |
2061053 | May 2009 | EP |
741678 | Feb 1933 | FR |
Entry |
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Machine translation DE1202378 (Orig. doc. published Oct. 7, 1965). |
Number | Date | Country | |
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20140175057 A1 | Jun 2014 | US |