1. Field
The disclosed concept pertains generally to electrical switching apparatus and, more particularly, to direct current electrical switching apparatus, such as, for example, direct current circuit breakers. The disclosed concept further pertains to direct current arc chambers.
2. Background Information
Electrical switching apparatus employing separable contacts exposed to air can be structured to open a power circuit carrying appreciable current. These electrical switching apparatus, such as, for instance, circuit breakers, typically experience arcing as the contacts separate and commonly incorporate arc chambers, such as arc chutes, to help extinguish the arc. Such arc chutes typically comprise a plurality of electrically conductive plates held in spaced relation around the separable contacts by an electrically insulative housing. The arc transfers to the arc plates where it is stretched and cooled until extinguished.
Known molded case circuit breakers (MCCBs) are not specifically designed for use in direct current (DC) applications. When known alternating current (AC) MCCBs are sought to be applied in DC applications, multiple poles are electrically connected in series to achieve the required interruption or switching performance based upon the desired system DC voltage and system DC current.
One of the challenges in DC current interruption/switching, especially at a relatively low DC current, is to drive the arc into the arc interruption chamber. Known DC electrical switching apparatus employ permanent magnets to drive the arc into arc splitting plates. Known problems associated with such permanent magnets in known DC electrical switching apparatus include unidirectional operation of the DC electrical switching apparatus, and two separate arc chambers each including a plurality of arc plates and a set of contacts must be employed to provide bi-directional operation. These problems make it very difficult to implement a permanent magnet design for a typical DC MCCB without a significant increase in size and cost.
There is room for improvement in direct current electrical switching apparatus.
There is also room for improvement in direct current arc chambers.
These needs and others are met by embodiments of the disclosed concept, which provide an electrical switching apparatus with a permanent magnet arrangement and single break operation to achieve bi-directional DC switching and interruption.
For example, two permanent magnet plates are employed along both sides of a single arc chamber including a single set of a plurality of arc plates and a permanent magnet or ferromagnetic center barrier to provide a dual arc chamber structure. The resulting magnetic field drives the arc into one side of the dual arc chamber structure and splits the arc accordingly depending upon the direction of the DC current.
In accordance with one aspect of the disclosed concept, a single direct current arc chamber comprises: a ferromagnetic base having a first end and an opposite second end; a first ferromagnetic side member disposed from the first end of the ferromagnetic base; a second ferromagnetic side member disposed from the opposite second end of the ferromagnetic base; a third ferromagnetic member disposed from the ferromagnetic base intermediate the first and second ferromagnetic side members; a first permanent magnet having a first magnetic polarity disposed on the first ferromagnetic side member and facing the third ferromagnetic member; and a second permanent magnet having the first magnetic polarity disposed on the second ferromagnetic side member and facing the third ferromagnetic member.
The first end of the ferromagnetic base and the first ferromagnetic side member disposed from the first end of the ferromagnetic base may define a first corner; the opposite second end of the ferromagnetic base and the second ferromagnetic side member disposed from the opposite second end of the ferromagnetic base may define a second corner; the single direct current arc chamber may define a magnetic field pattern; an arc may be struck between the first and second ferromagnetic side members; and the magnetic field pattern may be structured to drive the arc toward one of the first and second corners depending on a direction of current flowing in the arc.
The first and second ferromagnetic side members may have a first length; the third ferromagnetic member may have a second smaller length; and a ratio of the first length to the second smaller length may be greater than a predetermined value, which is greater than 1.0.
The predetermined value may be about 1.33.
As another aspect of the disclosed concept, a single direct current arc chamber comprises: a ferromagnetic base having a first end and an opposite second end; a first ferromagnetic side member disposed from the first end of the ferromagnetic base; a second ferromagnetic side member disposed from the opposite second end of the ferromagnetic base; a third ferromagnetic member disposed from the ferromagnetic base intermediate the first and second ferromagnetic side members; a first permanent magnet having a first magnetic polarity disposed on the first ferromagnetic side member and facing the third ferromagnetic member; a second permanent magnet having the first magnetic polarity disposed on the second ferromagnetic side member and facing the third ferromagnetic member; a third permanent magnet having an opposite second magnetic polarity disposed on the third ferromagnetic member and facing the first permanent magnet having the first magnetic polarity; and a fourth permanent magnet having the opposite second magnetic polarity disposed on the third ferromagnetic member and facing the second permanent magnet having the first magnetic polarity.
As another aspect of the disclosed concept, a bi-directional, direct current electrical switching apparatus comprises: separable contacts; an operating mechanism structured to open and close the separable contacts; and a single direct current arc chamber comprising: a ferromagnetic base having a first end and an opposite second end, a first ferromagnetic side member disposed from the first end of the ferromagnetic base, a second ferromagnetic side member disposed from the opposite second end of the ferromagnetic base, a third ferromagnetic member disposed from the ferromagnetic base intermediate the first and second ferromagnetic side members, a first permanent magnet having a first magnetic polarity disposed on the first ferromagnetic side member and facing the third ferromagnetic member, and a second permanent magnet having the first magnetic polarity disposed on the second ferromagnetic side member and facing the third ferromagnetic member.
The first end of the ferromagnetic base and the first ferromagnetic side member disposed from the first end of the ferromagnetic base may define a first corner; the opposite second end of the ferromagnetic base and the second ferromagnetic side member disposed from the opposite second end of the ferromagnetic base may define a second corner; the single direct current arc chamber may define a magnetic field pattern; opening of the separable contacts may cause an arc to be struck between the first and second ferromagnetic side members; and the magnetic field pattern may be structured to drive the arc toward one of the first and second corners depending on a direction of current flowing between the separable contacts.
A magnetic field strength of the magnetic field pattern may be at least about 30 mT.
A full understanding of the disclosed concept can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:
As employed herein, the term “number” shall mean one or an integer greater than one (i.e., a plurality).
As employed herein, the statement that two or more parts are “connected” or “coupled” together shall mean that the parts are joined together either directly or joined through one or more intermediate parts. Further, as employed herein, the statement that two or more parts are “attached” shall mean that the parts are joined together directly.
The disclosed concept is described in association with a three-pole circuit breaker, although the disclosed concept is applicable to a wide range of electrical switching apparatus having any number of poles.
Referring to
Also referring to
Here, unlike
Referring to
The magnetic field can be increased by increasing the thickness of the permanent magnets 70,72,74,76 and increasing the thickness of the ferromagnetic members 64,66,68. If the ferromagnetic members are magnetically saturated, then the magnetic field can be increased by increasing the thickness of the ferromagnetic members 70,72,74,76 alone. If the ferromagnetic members are not magnetically saturated, then the magnetic field can be increased by increasing the thickness of the permanent magnets 70,72,74,76 alone.
The separable contacts 102 include a movable contact 108 and a fixed contact 110. The operating mechanism 104 includes a movable contact arm 112 carrying the movable contact 108 with respect to the single direct current arc chamber 106.
Referring again to
The ferromagnetic bases 18 and 58 and the respective first, second and third ferromagnetic members 24,26,28 and 64,66,68 form E-shaped ferromagnetic structures.
The E-shaped ferromagnetic structures of Example 5 are made of soft magnetic steel (e.g., without limitation, 1010 steel).
The first and second permanent magnets 4,6 and 70,72 are selected from the group consisting of high energy permanent magnets (e.g., without limitation, a Neodymium Iron Boron (Sintered) N2880 material, and a Samarium Cobalt (Sintered) S2869 material).
The third and fourth permanent magnets 74,76 are selected from the group consisting of high energy permanent magnets (e.g., without limitation, a Neodymium Iron Boron (Sintered) N2880 material, and a Samarium Cobalt (Sintered) S2869 material).
A magnetic field strength of the magnetic field pattern 34 of
The following discusses the causes of directing an arc to one side of the single DC arc chamber 8 for one DC polarity, and directing the arc to the other side of the single DC arc chamber 8 for the other opposite DC polarity. Here, the positive or negative current direction interacts with the established magnetic fields.
Referring to
When Lo is at about 0.8″, the magnetic field points towards the arc chamber direction. In this case, the magnetic field pattern 34 at the contact location will look like the magnetic field pattern close to the corners 250 and 252. This magnetic field will drive the arc towards either corner 250 or corner 252 depending on the current direction.
However, when Lo is above about 1″, the magnetic field points away from the arc chamber direction. In this case, the magnetic field pattern 34 at the contact location will look like what is shown in
Hence, the ratio of Lo/Li has to be large enough. In
In summary, the ratio of Lo/Li has to be greater than a predetermined value. The magnetic field value is preferably in the range of 30 mT or higher so that it can drive the arc at relatively low current levels.
A DC electric arc in
While specific embodiments of the disclosed concept have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the disclosed concept which is to be given the full breadth of the claims appended and any and all equivalents thereof.