Arc extinguishing device with a metal matrix composite high speed whip

Information

  • Patent Grant
  • 6753492
  • Patent Number
    6,753,492
  • Date Filed
    Thursday, May 8, 2003
    21 years ago
  • Date Issued
    Tuesday, June 22, 2004
    20 years ago
Abstract
Rapid arc extinguishing devices for air break switches have a whip with at least an end portion of a metal matrix composite (MMC) material. The MMC whip is applied in embodiments similar to those of prior disclosed fiber reinforced plastic (FRP) whips without need for application of another conductor on the surface for conductivity from end to end.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




This invention relates to arc extinguishing devices for electrical switchgear such as air break disconnect switches used in transmission and distribution lines.




2. Related Art




Arc extinguishing devices that include an all-metal whip element are known to the prior art for the purpose of helping minimize arcing upon switch opening.




More recently, disclosure has been made in U.S. Pat. No. 6,392,181, issued May 21, 2002, and in copending application Ser. No. 10/342,035, filed Jan. 14, 2003, by the present inventor and others, both of which are assigned to the present assignee, of arc extinguishing devices including a whip element comprising a nonmetal, such as a fiber reinforced plastic (FRP) material, with a conductive path of various forms on its surface.




All of the description of prior art all metal whips and the more recently disclosed whips including a nonmetal of the above-mentioned patent and copending application is incorporated herein by reference.




In the materials art, there is a class of materials referred to as metal matrix composites (or MMCs) that have been long known and have been applied to and/or are of interest for structures in automotive and other applications. Such composite materials and prior known intended uses are described, for example, in an article by Hunt et al., “Automotive Applications of Metal-Matrix Composites”, pp. 1029-1032; and an article by Sain, “Engineering Composites”, pp. 1-20, at www.unb.calweb/p&p centre/engcomp/engcomp.htm.




SUMMARY OF THE INVENTION




The present invention is directed to arc extinguishing devices with a whip that comprises (at least a tip portion that flexes in contact with a latch of the device and is last to separate and spring away from the latch) a metal matrix composite (MMC), which is a term embracing composite members of a metal matrix containing reinforcing fibers, such as, but not limited to, alumina fiber reinforced aluminum (sometimes referred to as FRA) as described in the aforementioned publications, which are incorporated by reference herein for their description of practices with such materials.




Other features and characteristics of arc extinguishing devices of the present invention may, singly or in various combinations, be in accordance with or similar to those of the above copending application including, for example, the combination in a whip of an MMC rod with an all-metal base rod that is first to engage the latch of the device upon switch opening and switch closing; an MMC rod that is a tapered tube and, in a further embodiment, has another MMC rod disposed within it; and having a wheel on the latch with which the MMC rod makes sliding conductive contact during switch opening.




The invention offers alternatives to whips that are all uniform metal throughout (referred to as “all-metal”) and also to whips that comprise fiber reinforced plastic. MMC materials have high specific strength (strength in relation to density). While some known MMC materials are characterized by high hoop strength, because that is favorable for the structures previously intended, the strength can be subject to the orientation of the reinforcing fibers, e.g., by having the fibers run lengthwise through an MMC whip rod, rather than laterally or circumferentially, greater bending strength can result. Further, an MMC whip element does not necessitate a conductor to be applied to it for adequate conduction over the entire whip length, as is generally the case with FRP whips. However, an MMC whip may have a further conductor on it if desired for any propose purpose, such as a brazing alloy, if one is used to consolidate MMC sheets or tapes into a desired rod configuration, or a more durable metal part to enhance arc resistance.




Consequently, embodiments of the invention are believed attractive in facilitating achievement of high speed separation for rapid arc extinguishing, relative to all-metal whips, and avoiding the need for an applied conductor for sliding engagement with a latch as generally is needed with FRP whips. Regardless of the reasons for adopting the inventive apparatus, it provides the art with further alternatives not previously known.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a front elevation view, partly broken away, of a switch with a high speed whip type of arc extinguishing device; and





FIG. 2

is a side elevation view, partly in section and partly broken away, of one embodiment of a whip for an arc extinguishing device such as that of FIG.


1


.











DETAILED DESCRIPTION OF THE INVENTION





FIG. 1

shows a generally known type of air break switch


10


incorporating a form of the present invention. The switch


10


is a “center break” switch shown in its closed position. The elements include:




a pair of movable switch arms


12




a


and


12




b


(in general, switches in accordance with the invention have switch arms of which at least one is movable);




contacts


13




a


and


13




b


on the respective arms


12




a


and


12




b


(in this example, contact


13




a


fits within jaw-like contact


13




b


);




pivotal or hinge-like arm supports


14




a


and


14




b


for the respective arms;




line terminals


16




a


and


16




b


respectively conductively connected to the switch arms


12




a


and


12




b


near the arm supports


14




a


and


14




b;






insulators


18




a


and


18




b


respectively supporting each half of the switch


10


; and




a switch operating mechanism (not shown) that is arranged at the lower end of the insulator supports


18




a


and


18




b


to produce rotational motion of the insulators


18




a


and


18




b


and the supported arms and contacts.




In addition, this example switch includes an arc extinguishing device


30


with similarities to those previously described but also with a significant inventive modification. The device


30


includes a whip


32


and, in this example, an attachment (e.g., a clamp)


34


fastening the whip


32


at its lower end to the arm


12




a.


The device


30


also includes a latch (or hook)


36


conductively joined by a latch attachment


35


with the arm


12




b.


In this example, the latch


36


, which is all conductive, includes a rod


36




a


with a loop portion


36




b


at its free end and, just prior to the loop


36




b,


a small wheel


36




c


rotatable about a pin secured to the rod


36




a.






In contrast to previously known whips, the whip


32


comprises a metal matrix composite (MMC). In one example, the entire whip


32


from the attachment


34


to the free or tip end


31


includes an MMC material. In another form, the whip includes MMC from an intermediate division


33


out to the tip end


31


with an all-metal portion from the division


33


to the attachment


34


.




In the latter described example, and as shown, the division occurs above the point at which the whip


32


is most proximate the latch


36


when closed. Therefore, initial contact on opening of the switch and, also, upon closing of the switch occurs between the all-metal whip portion and the latch. That contact also normally occurs in the closed switch position.




The switch


10


opens with the whip


32


making sliding conductive engagement with the latch


36


, with increased flexing, until the arms


12




a


and


12




b


have moved enough for the whip


32


to spring away from the latch. As further described in the copending application, a latch wheel


36




c


may optionally be included and arranged as the part of the latch


36


against which the whip slides and finally separates from.




The MMC whip


32


(or MMC portion of whip


32


, where a base portion below division


33


is all-metal) has a metal matrix containing fibers, for reinforcement, of a composition differing from that of the metal matrix. For example, and without exclusion of others, the metal matrix can be selected from a group consisting essentially of titanium, titanium alloys, aluminum, and aluminum alloys. These are examples offering good low weight and high strength characteristics. The fibers within a selected metal matrix can, for example and without exclusion of others, be selected from a group consisting essentially of fibers of carbon, KEVLAR (trademark for some known compositions of man-made fibers for generalized use in the industrial arts), and alumina, either singly or in mixtures of the mentioned fibers.




An MMC material that has had substantial development and may be one of the most readily available is one with a metal matrix of aluminum and fibers of alumina.




In general, the MMC rod of whip


32


can be tapered or not tapered. Presently, a tapered rod is preferred for greater speed. Also, in general the MMC rod can be solid or tubular, with the latter presently preferred for greater speed. These preferences are believed to enhance arc extinguishing characteristics of the device


30


but it is recognized that the form of readily available and economically manufacturable MMCs can influence the design and the alternatives are not excluded.




The cross-sectional configuration of the MMC rod can be various; circular is a convenient choice in most cases.




The known MMC art can be applied to manufacture the MMC rod of whip


32


, preferably, but not necessarily, with some modification to achieve preferred spring qualities. In the whip rod


32


its length and tapering may be enough to achieve a desired spring force for high speed separation. Where maximum strength and spring force is desired, techniques of MMC manufacture may include orientation of the reinforcing fibers so they run substantially longitudinally within the metal matrix in the direction of the length of the rod. This is a known practice for making strong articles of fiber reinforced plastic (FRP) materials with spring characteristics, such as fishing rods, which can be applied to whips of FRP. Techniques for MMC fabrication can, in general, be similar to those for fiber reinforced plastics.




MMC members are sometimes fabricated using a brazing alloy after individual layers (tapes or sheets) of MMC material have been assembled in the desired form to consolidate the layers into a permanent structure. That is a technique that may be used for the MMC whip in which the brazing alloy may remain on the MMC surface. However, where the MMC is formed without brazing, such as by casting, there is generally no necessity to apply a conductor to the MMC surface for the sake of conductivity, as is usually needed on an FRP whip, as the MMC material is substantially conductive on and through the metal matrix; so the additional weight of an applied conductive layer can be avoided. If one desires for any reason (e.g., even greater conductivity or greater arc durability than the MMC material provides) techniques such as described in the above patent and copending application can be used on the MMC whip, continuously along the whip or just where arcing is likely to be most severe.




Referring to

FIG. 2

, a more particular example of an MMC whip


132


is shown. In this example, the whip


132


is in two parts secured together at a securement or coupling


133


with a tip part


132




a


of MMC and a base part


132




b


of all-metal, as generally described in connection with FIG.


1


. Also, the example is one with tapering of both parts


132




a


and


132




b


and the MMC part


132




a


being in the form of a tube.




Similar to FRP whips as described in the above application, the blunt base portion of the MMC tube


132




a


can have within it additional material such as by inserting an additional (one or more) piece of MMC tapered rod or tube (not shown in the drawing).




The securement


133


of the MMC part


132




a


with the all-metal part


132




b


in this example is similar to a way of securing two part whips in the copending application. The end of the all-metal whip part


132




b


has an axial bore or socket into which the blunt end of the whip part


132




a


is inserted. Bonding with an adhesive, preferably conductive, is optional. The principal mechanical securement and achievement of conductive continuity is by the bore wall material of the all-metal part


132




b


being crimped into close contact with the surface of the MMC part


132




a.






In this example, no additional conducive layer on most of the MMC part


132




a


is shown but there is a cap


131


at the extremity of part


132




a


This is an option to enhance durability of the tip of part


132




a


where arcing can occur upon separation of the whip from a latch, such as latch


36


of FIG.


1


. The cap


131


may be variously shaped. For example, it can, but need not be, formed to extend beyond the tip of part


132




a


a deliberate distance greater than needed to cover the tip of part


132




a;


also, it can be tapered to a finer or less fine point. Conveniently, the cap


136


may be crimped onto the tip end of part


132




a.






Without limitation, materials suitable for the all-metal part


132




b


include beryllium-copper, stainless steel, and others used in prior all-metal whips; materials suitable for the MMC part


132




a


include those previously described herein; and the cap


136


, if used, is of a highly arc resistant, light weight, conductor.




By way of further example, a whip


132


as shown in

FIG. 2

can consist essentially of an all-metal part


132




b


of stainless steel, an MMC tube


132




a


of alumina fiber reinforced aluminum (FRA), and a cap


131


of titanium.




The present invention and its related patent and copending application show a wide spectrum of design possibilities for a whip in a quick-break whip arc extinguishing device for an air break switch where the whip is, or includes, a flexible rod with a combination of metal and nonmetal material, such as an MMC rod or an FRP rod with an applied metal surface.




Variations and additional examples of the invention will be apparent from the foregoing description and the following claims.



Claims
  • 1. An arc extinguishing device for use in combination with an air break switch, comprising:a whip element and a latch element each secured to a respective conductive contact of a switch; the whip element comprising a tip part of a metal matrix composite rod and a base part of an all-metal rod having an end conductively secured with an end of the metal matrix composite rod; and the whip and latch elements being arranged so that the all-metal rod of the whip element is first to engage the latch element upon switch opening and switch closing and the metal matrix composite rod of the whip element is last to separate and spring away from the latch element upon switch opening.
  • 2. The device of claim 1 where:the metal matrix composite rod comprises a metal matrix containing fibers of a composition differing from that of the metal matrix.
  • 3. The device of claim 2 where:the metal matrix is selected from a group consisting essentially of titanium, titanium alloys, aluminum, and aluminum alloys.
  • 4. The device of claim 2 where:the fibers are selected from a group consisting essentially of carbon fibers, KEVLAR fibers, alumina fibers, and mixtures thereof.
  • 5. The device of claim 2 where:the metal matrix composite consists essentially of fiber reinforced aluminum.
  • 6. The device of claim 5 where:the fiber reinforced aluminum includes fibers of alumina.
  • 7. The device of claim 1 where:the metal matrix composite rod is a tapered rod.
  • 8. The device of claim 1 where:the metal matrix composite rod is a tubular rod.
  • 9. The device of claim 1 where:the metal matrix composite rod is a tubular, tapered rod.
  • 10. The device of claim 1 where:the metal matrix composite rod consists essentially of a metal matrix containing reinforcing fibers extending substantially in the direction of the length of the rod.
  • 11. The device of claim 9 further comprising:at least one additional tapered rod disposed within the first mentioned rod.
  • 12. The device of claim 1 further comprising:consolidating brazing alloy on the metal matrix composite rod.
  • 13. The device of claim 1 where:the latch element comprises a conductive rod having a conductive wheel on a pin secured thereto.
  • 14. An air break switch comprising:a pair of main switch contacts each with a line terminal for connection with segments of an electrical line; a switch operating mechanism for opening and closing the main switch contacts; an arc extinguishing device including a whip element attached in electrical contact with one of the main switch contacts and a latch element attached in electrical contact with the other of the main switch contacts; the whip element comprising, at least in a tip portion at the extremity away from the one contact a rod comprising a metal matrix composite; the whip element further comprising an all-metal rod having an end conductively secured with an end of the metal matrix composite rod; and the latch and whip elements are arranged so that upon initial opening of the switch contacts the latch and the all-metal rod of the whip are in contact prior to sliding conductive engagement of the metal matrix composite rod with the latch after which the metal matrix composite rod springs away from the latch and, during a closing operation of the switch operating mechanism, the all-metal rod makes initial contact with the latch.
  • 15. The switch of claim 14 where:the whip comprising a metal matrix composite includes a metal matrix providing continuous electrical conductivity over the rod surface without additional material added for conductivity to the rod surface.
  • 16. The switch of claim 14 where:the latch element comprises a conductive rod having a conductive wheel rotatable about a pin secured to the conductive rod of the latch; and the whip and latch elements are further arranged so that sliding conductive engagement of the metal matrix composite rod with the latch wheel occurs during an opening operation of the switch operating mechanism with flexing of the metal matrix composite rod of the whip until separation of the whip from the latch wheel.
  • 17. The switch of claim 14 where:the all-metal rod has a socket at the end secured to the metal matrix composite rod with a wall crimped onto the end of the metal matrix composite rod; and the unsecured opposite end of the metal matrix composite rod has an all-metal tip crimped over it.
  • 18. The switch of claim 17 where:the all-metal rod consists essentially of stainless steel; the metal matrix composite rod consists essentially of alumina fiber reinforced aluminum; and the all metal tip consists essentially of titanium.
US Referenced Citations (9)
Number Name Date Kind
3217115 Kaplan Nov 1965 A
3938964 Schmidt Feb 1976 A
3955303 Outlaw et al. May 1976 A
4243854 Pahl Jan 1981 A
5079099 Prewo et al. Jan 1992 A
5359167 Demissy et al. Oct 1994 A
5369234 Demissy Nov 1994 A
5746267 Yun et al. May 1998 A
6392181 Cleaveland et al. May 2002 B1
Foreign Referenced Citations (1)
Number Date Country
2357453 May 2002 CA
Non-Patent Literature Citations (5)
Entry
Hunt et al., “Automotive Applications of Metal-Matrix Composites”, pp. 1029-1032, (no date).
Sain, “Engineering Composites”, pp. 1-20, www.unb.ca/web/P&P Centre/engcomp/engcomp.htm, (no date).
3M Innovation, “3M Composite Conductors”, 2 pp, Copyright 2000, (no month).
3M, “Metal Matrix Composites-continuous Wire”, 2 pp., Copyright 1995-2000, www.3M,com/market/industrial/mmc/continuous wire.htm, (no month).
U.S. patent application Ser. No. 10/342,035, Kowalik et al., filed Jan. 14, 2003.