Embodiments presented herein generally relate to electrical switches, and more particularly to current interrupters for electrical switches.
The use of direct current (DC) power distribution has expanded during the last decade, involving application spaces such as, for example, data centers, solar farms, aviation, and rail. However, there is presently a dearth of suitable DC circuit protection technologies, including DC circuit breakers. Current DC circuit breakers are often based on solid state switches, magnetic switches, and/or de-rated alternating current (AC) circuit breakers. All of these devices tend to be relatively bulky and expensive, as well as possessing a limited short circuit capability and poor contact reliability.
In one aspect, an apparatus, such as an electrical system, is provided. The electrical system can include a pair of conductors across which an arc is sporadically supported, the arc including load current from a load circuit. The electrical system can also include an energy source that is separate from the load circuit and configured to selectively charge (e.g., selectively provides a high voltage pulse to) an electrode assembly. The conductors and electrode assembly can be configured such that the arc, when present, will be lengthened due to the charge on the electrode assembly. For example, the electrical system can include an indication device operatively coupled to the energy source, with the energy source being configured to charge the electrode assembly in response to receiving from the indication device an indication of the arc being established the indication.
In some embodiments, the electrode assembly can include a pair of electrodes disposed on opposing sides of a gap defined between the conductors. In some embodiments, the electrode assembly can include an electrode that is centered along, and laterally offset from, an axis defined between the conductors.
The conductors may be configured to move into and out of contact with one another so as to respectively close or open at least a portion of the load circuit. In some embodiments, the electrical system can include a pair of contacts configured to move into and out of contact with one another so as to respectively close or open at least a portion of the load circuit. Each of the conductors can be electrically connected to a respective one of the contacts, and the conductors can be configured to receive therebetween the arc from the contacts subsequent to the arc being established between the contacts. An arc transfer device, such as one including an ablative plasma gun, can be configured to urge the arc from the contacts to the conductors.
In another aspect, an apparatus, such as an electrical system, is provided. The electrical system can include a pair of conductors across which an arc is sporadically supported. An energy source can be configured to selectively charge an electrode assembly so as to establish an electric field in the vicinity of the arc that is constant in time. The conductors and electrode assembly can be configured such that the arc, when present, will be lengthened or constricted due to the electric field. For example, the electrical system can include an indication device that is operatively coupled to the energy source, the indication device providing an indication that the arc will be imminently established. The energy source can be configured to charge the electrode assembly in response to receiving the indication.
The following detailed description should be read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Example embodiments are described below in detail with reference to the accompanying drawings, where the same reference numerals denote the same parts throughout the drawings. Some of these embodiments may address the above and other needs.
Referring to
Referring to
While the above describes a process for opening and closing the switch 106, in practice, the current in the load circuit may not be modulated directly upon opening and closing of the switch. Rather, if the switch 106 is in a closed position and a current is passing through the load circuit 114 (e.g., the current ILOAD in
Referring to
Referring again to
Referring to
The voltage source 128 can be configured to provide a high voltage pulse when the arc 122 is present. For example, the system 100 may include an indication device 132 operatively coupled to the voltage source 128. The indication device 132 may be configured to provide an indication of the arc 122 being established. For example, the indication device 132 may include a current monitor 134 and/or an optical sensor 136 that, respectively, monitor current through the conductors 110 (indicating the presence of the arc 122) and optically monitor the gap 112 for the presence of the arc. In response to detecting the arc 122, the indication device can provide the indication of the arc to the voltage source 128 so as to initiate charging of the electrode assembly 126. Alternatively, the indication device 132 may be excluded, and the switch controller 116 may communicate with the voltage source 128 to initiate charging of the electrode assembly 126, for example, at a predetermined time after opening of the switch 106.
In another embodiment, the voltage source 128 can be configured to selectively charge the electrode assembly 126 so as to establish an electric field in the vicinity of the arc 122 that is substantially constant in time. For example, the arc 122 may be shielded from the electrode assembly 126 during the time that the electrode assembly is being charged (e.g., while the voltage from the voltage source 128 is ramping). Alternatively, the system 100 can be configured such that the voltage source 128 applies a charge to the electrode assembly 126 prior to formation of the arc 122. For example, the switch controller 116 may be configured to send a signal to the voltage source 128 indicative of an impending need to open the switch 106, and the voltage source can initiate charging prior to switch opening, such that the charge on the electrode assembly 126 reaches a steady state before the arc 122 is formed.
Referring to
Applicants have experimentally determined that configurations of the electrode assembly 126 consistent with the above discussion may, when charged in the vicinity of conductors 110 supporting an arc 122, significantly reduce the instantaneous current associated with the arc (for example, by 65-70%) relative to a situation where the charged electrode assembly is not present. Referring to
Without being bound to any particular theory, the charged electrode assembly 126 establishes an electric field {right arrow over (E)} in the vicinity of the arc 122. The electrons defining the arc 122 travel through the field {right arrow over (E)}, and as a result, a force {right arrow over (F)}E acts on the electrons. Due to the influence of both the force {right arrow over (F)}E and the magnetic field {right arrow over (B)} that is established by the movement of the electrons of the arc 122, the electrons assume a helical trajectory. The helical trajectory can be thought of as the superposition of a circular motion around a point. called the “guiding center,” and a relatively slower drift of the guiding center. If the velocity of the guiding center is {right arrow over (ν)}G, then some portion of the velocity {right arrow over (ν)}G can be attributed to the force {right arrow over (F)}E. This electric field-induced guiding center velocity {right arrow over (ν)}F is described by
From Equation (1), it is apparent that the electrons (and, thus, the arc 122) will, on average, have a component of velocity perpendicular to both the electric field {right arrow over (E)} and the magnetic field {right arrow over (B)}. The arc 122 may therefore be urged into a configuration other than that in which the constituent electrons follow the path of lowest impedance between the conductors 110. It is noted that, as the electrode assembly 126 is charged, the configuration of the arc 122 may also be affected by the magnetic field induced by the varying electric field.
Referring to
The system 200 can also include an electrode assembly 226 that may selectively charged by an energy source, such as the voltage source 228. As discussed previously, a current passing through the switch 206 may not halt immediately upon opening the switch, but may continue in the form of an arc 222 that spans the gap 212. The electrode assembly 226 may be disposed relative to the conductors 210 such that, when the arc 222 is present across the conductors, the configuration of the arc will be modified due to the charge on the electrode assembly so as to increase the overall impedance of (and ultimately extinguish) the arc. As such, the arc 222 need not be moved to from the conductors 210 to another set of conductors before being extinguished.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. For example, while the electrical systems described herein have involved electric fields that are utilized to increase the impedance of an arc, the systems may additionally include permanent or electromagnets that also serve to modify the configuration of an arc so as to increase the impedance thereof. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
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Number | Date | Country | |
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20120181253 A1 | Jul 2012 | US |