This patent application claims priority to German Patent Application No. 10 2015 200 507.0, filed 15 Jan. 2015, the disclosure of which is incorporated herein by reference in its entirety.
Illustrative embodiments relate to a switching and protection device for high-voltage onboard electrical systems, in particular for high-voltage onboard electrical systems in a motor vehicle.
Switching and protection devices for high-voltage onboard electrical systems are used to manage the nominal current and a potential temporary overcurrent of the high-voltage onboard electrical system. All poles of the high-voltage onboard electrical system may be disconnected via the switching device during each switch-off process. However, the protection device is used for disconnecting a high-voltage battery in the case of fault currents which are larger than the overcurrents. The protection devices are generally designed as fuses. The switching devices may be designed as DC-voltage switches, for example, a relay. In the case of disconnections of all poles, disclosed embodiments are also possible in which one switching device is designed as a relay and one switching device is designed as a power semiconductor.
The fuses generally used are hermetically sealed fuses having ceramic or plastic housings in which multiple fusible elements having defined narrow sections are connected in parallel. Optionally, the housings are also filled with an extinguishing medium, for example, sand.
In addition to the resulting non-negligible installation space for the fuses, the requirements in a high-voltage onboard electrical system for motor vehicles place high demands in particular with respect to the triggering characteristics. For example, the allowable overcurrents may be relatively high. In addition, due to the parallel connection, manufacturing-related component tolerances must be considered, thus increasing the break times to be achieved.
Disclosed embodiments provide a switching and protection device which requires less installation space.
Disclosed embodiments are explained in greater detail below with reference to the drawings.
The switching and protection device for high-voltage onboard electrical systems comprises a DC-voltage switch and a fuse. The DC-voltage switch includes a housing, at least two fixed contacts, and a bridge, wherein the bridge is designed to be movable relative to the fixed contacts, wherein the bridge, for example, is moved against a spring with the aid of a rod. In this case, the housing may be designed in a hermetically sealed manner, i.e., a gas-tight manner. The bridge is formed from an electric insulator, wherein two contacts are arranged on the bridge which are arranged on the bridge in such a way that, during a movement of the bridge in the direction of the fixed contacts, the contacts make contact with the fixed contacts, wherein the two contacts on the bridge are connected to each other via the fuse. Due to this design, the fuse is integrated into the switching device, which results in a slight increase in the installation space of the switching device, which, however, results in overall decreased installation space due to the omission of the external fuse with its hermetic housing. The triggering characteristics of the integrated fuse may be more accurately adjusted, so that reduced break times are also achievable. Optionally, the contacts are screwed or molded or injected to the bridge.
In at least one disclosed embodiment, the fuse is designed as a wire which is arranged above the bridge between the contacts. For example, the wire is made of copper. If the wire is overloaded during a fault current flow, the wire vaporizes in an explosive manner. The pressure waves and changes in the conductivity of the wire or the resulting switching arc thus occurring due to the explosion process result in a voltage jump or an ignition peak of the arc voltage. If the jump or the ignition peak of the arc voltage exceeds the driving voltage, this results in an extinguishment of the switching arc in the case of ohmic loads or ohmic-inductive loads.
Alternatively, the fuse may also be formed on the bridge as a succession of conductor paths.
In an additional disclosed embodiment, the fuse is partially or completely embedded in the bridge. In this case, completely embedded means that the fuse is completely enclosed by the insulating material of the bridge (with the exception of the contacting points to the contacts). The embedding in the insulating material of the bridge thus allows a more compact design. Various additional measures are possible for ensuring the extinguishment of the switching arc.
In at least one disclosed embodiment, the bridge is made of a material which is strongly outgassing at the melting temperature of the fuse, optionally a material such as Plexiglas or polyoxymethylene. This results in a sharp pressure increase due to the gas formation, as well as a simultaneous cooling via the chemical decomposition processes in the switching device, which causes the triggering process.
Alternatively, the bridge may be made of a ceramic, or more generally, of a combustion-proof, electrically insulating, thermally conductive material. In this case, the basic idea is to remove thermal energy from the arc via the thermal conductivity of the material of the bridge, to cause it to extinguish.
In another disclosed embodiment, which may be used if the fuse is only partially embedded, electrically conductive guide rails are arranged in parallel with the fixed contacts, between which an insulator is arranged which has a gap opposite each of the guide rails. In this case, the basic principle is analogous to the strongly outgassing material. Due to the guide rail, the arc is forced into the narrow gap, where extends along it and strongly heats the insulator locally. Therefore, outgassing results, in which case the rising pressure results in an extinguishment of the arc.
In this case, conducting structures, optionally wedge-shaped structures, may be arranged on the bridge, which are formed in such a way that they direct the arc between the guide rail and the insulator to accelerate the extinguishment.
In a further disclosed embodiment, arc splitters are arranged above the bridge which may be arranged in parallel. Furthermore, the arc splitters may be made of brass or iron, which then form so-called magnetic arc splitter stacks. Due to the magnetization, they draw the arc between the splitters, which results in a series circuit made up of multiple arcs, which then force the current to be disconnected to zero due to the overall higher arc-burning voltage. In this case, the relatively cool arc splitters additionally remove heat energy from the arcs, which results in an increase in resistance of the arcs. This results in a more rapid extinguishment of the arcs.
In an additional disclosed embodiment, an insulator is arranged in such a way that it is moved between the contacts during the melting of the fuse, to interrupt the arc. In this case, the insulator may be wedge-shaped. The movement of the insulator may, for example, be triggered with the aid of a pyrotechnic propellant. Alternatively, a pre-stressed spring may be used, which is released during the melting of the fuse.
The wire 11 is sized in such a way that it is able to carry the nominal current as well as the operation-related overcurrent; however, in the case of fault currents greater than a threshold value above the overcurrents, it vaporizes in an explosive manner. In this case, the triggering characteristics of the wire 11 may be adjusted very easily in comparison to the related art, so that the triggering may occur more rapidly and more reliably. During regular operation, for example, a coil (not shown) associated with the rod 6 is supplied with current, and the rod 6 is moved upward against a spring force due to a magnetic force. If the contacts 8 and the fixed contacts 3 then touch, the electrical connection is established between the fixed contacts 3. If a fault current then results, the wire 11 vaporizes, wherein a resulting arc is extinguished with the aid of the increase in pressure due to the explosive vaporization. In this case, the contacts 8 and the fixed contacts 3 may remain in contact so as not to form another arc.
The contact element 7 again includes a contact 8 and base element 10 which, for example, are riveted or soldered to each other, as indicated by the dashed lines. Alternatively, they may be formed in one piece, or the contact 8 is inserted into the base element 10. The base element 10 may be screwed to the bridge 5, as also indicated by the dashed lines. The fuse 12, which is partially embedded in the bridge 5 (also indicated by dashed lines), is situated between the two base elements 10. The connection between the fuse 12 and the base elements 10 is, for example, a plug connection. The bridge 5 may be made of a strongly outgassing material, for example, Plexiglas or POM (polyoxymethylene).
In the case of a fault current, the fuse 12 melts, wherein the bridge 5 also outgasses due to the generated heat. This results in a pressure increase in the hermetic housing 2, so that an arc occurring between the base elements 10 is extinguished.
An insulator 14 is arranged between the guide rails 13 which has a gap on each of the sides opposite the guide rails 13. The gap runs in parallel with the guide rails 13. The insulator 14 is made of a strongly gassing material such as Plexiglas or POM. The insulator 14 is, for example, screwed to the housing 2. Two conducting structures 15 are furthermore arranged at the base elements 10, between which the fuse 12 extends. The conducting structures 15 are wedge-shaped and are, for example, screwed to the base elements 10. As a result, an arc occurring during the melting of the fuse 12 is routed via the conducting structure 15 into a channel 16 between the guide rail 13 and the insulator 14 having the gap. The arc running in the narrow gap heats the insulator 14, which then begins to outgas. The resulting pressure increase causes the arc to extinguish.
Switching and protection devices for high-voltage onboard electrical systems are used to manage the nominal current and a potential temporary overcurrent of the high-voltage onboard electrical system. All poles of the high-voltage onboard electrical system may be disconnected via the switching device during each switch-off process. However, the protection device is used for disconnecting a high-voltage battery in the case of fault currents which are larger than the overcurrents. The protection devices are generally designed as fuses. The switching devices may be designed as DC-voltage switches, for example, a relay. In the case of disconnections of all poles, disclosed embodiments are also possible in which one switching device is designed as a relay and one switching device is designed as a power semiconductor.
The fuses generally used are hermetically sealed fuses having ceramic or plastic housings in which multiple fusible elements having defined narrow sections are connected in parallel. Optionally, the housings are also filled with an extinguishing medium, for example, sand.
In addition to the resulting non-negligible installation space for the fuses, the requirements in a high-voltage onboard electrical system for motor vehicles place high demands in particular with respect to the triggering characteristics. For example, the allowable overcurrents may be relatively high. In addition, due to the parallel connection, manufacturing-related component tolerances must be considered, thus increasing the break times to be achieved.
DE 20 2012 013 107 U1 discloses an arc extinguishing device for an electric installation switching device, wherein the installation switching device comprises a contact point formed from a fixed and a movable contract piece. In this case, the arc extinguishing device comprises an arc splitter stack including multiple arc splitter plates.
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