Patent Grant
7078642
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
Patent 6,392,181, May 21, 2002, also assigned to Cleaveland/Price Inc., describes relevant background concerning use of high speed whips of all metal construction in arc extinguishing devices of switches and further describes such apparatus with whips comprising a nonmetallic material, such as a plastic polymer member, with a flexible conductive path. The patent describes embodiments capable of achieving faster separation (with less chance of arc restriking) of a whip with nonmetallic material as compared to an all metal whip that is otherwise similar.
All such description of the patent related to all metal whips of the background art and, also, whips with nonmetallic material newly presented in the patent, is incorporated herein by reference. Reference is also made to commonly assigned copending application Ser. No. 10/431,700, filed May 8, 2003 by one of the present inventors, that describes arc extinguishing devices with a metal matrix composite high speed whip.
The present invention is directed to apparatus generally like that of the above-mentioned patent, with a whip comprising a nonmetallic material, such as a plastic polymer, with a flexible conductive path, with newly disclosed embodiments of the whip itself and, in addition, of the latch or hook element that the whip makes conductive contact with during initial main contact separation.
Some of the various example embodiments of the invention include one or more of the following innovative features.
A whip in one form comprises a plurality of tapered nonmetallic rods that fit inside one another. For example, a first hollow rod has one or more additional tapered rods telescopically fit together inside the first rod forming a rod assembly. At least all but the final, inner, rod is hollow. Only the outermost rod needs to be provided with a conductive path. The plurality of rods can be of the same nonmetallic material and have the same taper dimensions. Fitting the rods together only requires a second rod to be inserted in the first rod to the extent the first and second rods' dimensions allow, generally with the tip of the second rod at least halfway through the length of the first, and the tip of a third, if any, at least halfway through the second. Most often the extent of the inserted rod is about 75% to 90% through the length of the adjacent outer rod. The assembled rods are terminated at a common blunt end. In some embodiments three or four rods have been so assembled and have exhibited good characteristics but the number of rods may be varied.
An assembly of multiple rods as described is considered to perform similar to a leaf spring with an increase in accelerating force, compared to use of a single rod like the first rod of the assembly, while still retaining flexibility. The multiple rods also can be more resistant to breakage than a single unitary rod of the same overall dimensions as the multiple rods.
Such an assembly of multiple rods is provided with a conductive path for engaging with a latch of an arc extinguishing device such as described in the above patent and in other descriptions below. For example, the outer surface of the first rod has some form of a conductor layer on it.
The conductive path on the outer rod of the rod assembly (or a single rod where only one is used) can be formed in numerous different ways to achieve desired conduction between the whip and the latch and between the latch contact point and the attachment of the whip to the switch contact arm, all while the nonmetallic rod supporting the conductive path still retains substantial flexibility so it can provide higher separation speed from the latch.
The forms described herein for the conductive path on the nonmetallic rod include, for example, at least one conductor selected from the group consisting of a metal braid (e.g., tubular metal braid held to the rod by its own elasticity), a metal foil (e.g., a wrapping of an adhesive backed thin foil layer), a metal sheath (e.g., a conductive tubular element into which the nonmetal rod fits securely), and a wound metal wire. Various examples, including combinations of some of the foregoing conductors, will be described, of which some are particularly designed to enhance the durability of the conductive path where arcing is initiated between the whip and the latch upon switch closing and also at the tip of the whip that finally separates from the latch.
Among embodiments of the invention are those in which a nonmetallic portion of a whip, such as a rod assembly with the multiple rods above described or a single nonmetallic rod, is assembled with an all metal base portion with the metal portion extending, for example, from a point of connection on a switch contact arm to a point above an area on the whip at which it first conducts when the switch contacts open and also where it first has a close air gap with the latch during switch closing. In such embodiments, the metal base portion can be like the base part of the prior art all metal whips. A whip with an all metal base can allow repeated switch operations with as much durability as prior whips entirely of metal. The whip portion with a nonmetallic rod plus a conductive path at the tip end of the whip can give favorable separation speed of the whip from the latch to minimize arcing on switch opening. The metal base portion can also contribute to increasing the separation speed by storing spring force during flexing of the whip.
A further feature of the invention involves a modification of the latch of the device so it has a wheel that engages the whip during part of a switch opening. The rolling wheel surface is the final release point for the whip from the latch. It can reduce the sliding wear between the latch and the conductor on the whip surface. The wheel (or roller) rotates on a pin that is secured at one end to a rod portion of the latch. In some embodiments the other end of the pin for the wheel is joined with a cam bar to help make more sure that during switch opening the whip has final contact and arcing at its tip with the wheel on the latch and that during switch closing the whip does not engage the wheel in a manner likely to damage its conductive path.
Additional or alternative features of the invention include having a conductor on the nonmetallic rod with metal strands (e.g., a metal braid or a metal wire along or around the rod) that are bonded to the rod by an adhesive. Such a combination can aid in minimizing wear or tearing of the metal strands. The adhesive can be one with resinous material containing metal particles for a degree of conductivity that can be desirable. Since such an adhesive is likely not to have as high conductivity as the metal strands themselves, it is desirable to make the outermost surface of the strands substantially free of the adhesive where engagement with the latch occurs.
Also, the assembly of multiple rods, or a single nonmetallic rod, joined with an all-metal base portion of the whip can have greater strength to withstand and distribute the high stress on the rods, or rod, at the joint with the all-metal portion when the whip releases from the latch by having a metal spine in the inner hollow of the rod or rods in the region of the joint.
Arc extinguishing devices with whips that include a rod comprising a metal matrix composite (MMC) material, such as are disclosed in the above-mentioned copending application Ser. No. 10/431,700, filed May 8, 2003, can utilize features like those described for a whip comprising a nonmetal, such as FRP, with a conductive path on its surface.
These and other aspects of the present invention will be further understood from the entirety of the description, drawings and claims.
a pair of movable switch arms 12a and 12b;
contacts 13a and 13b on the respective arms 12a and 12b where, when switch 10 is closed, contact 13a fits within and engages contact 13b that is jaw-like;
pivotal or hinge-like arm supports 14a and 14b for the respective arms;
line terminals 16a and 16b respectively conductively connected to the switch arms 12a and 12b near the arm supports 14a and 14b;
insulators 18a and 18b respectively supporting each half of the switch 10; and
a switch operating mechanism (not shown) that is arranged at the lower ends of the insulator supports 18a and 18b to produce rotational motion of the supports 18a and 18b and the elements they support.
The basic elements of the switch 10 can, for example, be in accordance with prior air break switches such as a “V” Configuration Center Break Switch as described in Cleaveland/Price Bulletin DB-126A02 (issued 2002). The invention may also be practiced with other air break switches such as a center break switch with parallel (rather than “V” configured) support insulators as described in that Bulletin and, also, a vertical break switch as described in Cleaveland/Price Bulletin DB-106BH97 (issued 1997), both of the referred to Bulletins are herein incorporated by reference for their description of such switches.
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 12a. The device 30 also includes a latch (or hook) 36 conductively joined by a latch attachment 35 with the arm 12b. In this example, the latch 36 includes a rod extending up with a bend and with a loop portion at the free end. That represents a general form for the latch 36. Further discussion of forms of the latch 36 will be found below.
By the present invention, and also consistent with the above-mentioned U.S. Pat. No. 6,392,181, the geometry of the elements of the device 30, and their relation to the rest of the switch 30, can be generally like prior “quick break whips” but with a difference in the structure of the whip 32 itself from formerly used all metal whips. In
During an opening of the switch 10, by the mechanism associated with the support insulators 18a and 18b, the arms 12a and 12b swing toward the viewer, relative to their orientation in
In the second phantom view of
Normally in arc extinguishing devices 30 like that of
Switch 10 is of course merely an example of an air break switch with an arc extinguishing device 30 having an improved whip 32. Generally, such a device 30 can be adapted to any switch whose operation can present arcing problems, at least to the same extent as prior metal “quick break whips”. The above referred to product bulletins show examples of other switches. In a vertical break switch there is, as shown in the above-mentioned patent, normally one movable contact arm, having a whip attached to it, and a latch attached to a stationary contact.
As indicated on
In the drawings, similar elements will normally have the same last two digits.
In forming the rod assembly 40, the order of the insertions can be varied from the above, e.g., first insert the fourth rod 44 into the third rod 43, then that combination into the second rod 42, etc. In any case, when assembled, the inserted rods 42, 43, and 44 all end proximate the blunt end of the first, outer rod 41 (by either starting with the same length for all the rods prior to the insertions and cutting the assembly at the desired length after the insertions or cutting individual rods prior to the insertions so their length is correct afterward). At the blunt end of the rod assembly 40, all the rods are in direct contact, providing enhanced strength. At the tip end of the rod assembly, all the tip ends of the rods are spaced from each other.
A rod assembly of multiple rods for the whip 132 need not consist of four rods, for example two or three rods, or even more than four rods might be used in some embodiments.
It has been found that a multiple rod assembly, such as assembly 40, can increase the speed of a whip with reduced chance of breakage as compared to a whip with just one rod (such as rod 41). An explanation, although not necessary to the successful practice of this aspect of the invention, is that the addition of the mass of the conductor 50 reduces the whip speed compared to the speed of a single rod without a conductor but that reduction in speed is offset by an inserted rod or rods. It is believed the rod assembly 40 acts much like an automotive leaf spring, still exhibits a high degree of flexibility, increases the accelerating force on the tip of the outer rod 41 and is strong and less likely to break than a single rod of the same wall thickness as the multiple rod assembly. A multiple rod assembly 40 allows a wide choice of the conductor 50. The strength of rod assembly 40 can facilitate supporting a heavier conductor for good arc resistance.
Example dimensions for a single rod given in the above patent are also relevant in the embodiments here, such as for rod 41, 42, 43 or 44. With a multiple rod assembly, the extent of an inserted rod is likely to be about 75% to about 90% of the distance to the tip of the next adjacent outer rod, where the rods have the same basic dimensions.
While it is not presently preferred to have a variety of rod shapes in the rod assembly 40, requiring a multiplicity of different parts to be procured, the intention is not to preclude that possibility. Likewise, it is convenient, but not essential, that the multiple rods all have the same nonmetallic material composition. Also, it is evident that the innermost rod of the assembly, the fourth rod 44 in
In
A further variation is shown in
The conductor 50 has characteristics to allow the nonmetallic rods of a multiple rod assembly, or a single rod, to have a conductive path along its length while retaining a substantial flexibility. Also, the conductor 50 is chosen to withstand numerous instances of arcing that will inherently occur in operation, at least at certain areas along its length.
Referring again to
In the above mentioned patent, various suitable conductors were disclosed including, for example, metal deposited by electroplating or vapor deposition, perhaps over a layer of conductive paint. Other examples will now be described.
The conductor 50 of
A metal sheath for the conductor 50 could be formed (e.g., into tubular form) before being fitted on the rod surface. The conductors referred to need not be continuous along the length of a whip as long as there is conductive continuity. For example, a whip 32 could have a layer of metal foil over its length and have limited areas of metal sheath at the areas mentioned above where it can be desirable to have enhanced arc resistance. The metal of a sheath may be chosen, for example, from conductors such as copper, aluminum, stainless steel or, for even greater arc resistance, titanium.
As the metal braid is stretched over the rod, openings between strands of the braid can occur exposing the surface of the rod. For some installations, where exposure to sunlight might be deleterious to the nonmetal material of the rod, the rod can have an outer surface that is not homogeneous with the inner material and is more sunlight (UV) resistant. Avoiding sunlight effect on the rod is also taken care of by the example of
From these examples, it can be seen that a conductive path on a nonmetal rod for a whip can be of various forms and combinations, including those shown and others. The example conductors particularly show how the conductive path on a nonmetal rod surface can comprise, in addition to the examples of the above patent, at least one conductor selected from the group consisting of a metal braid, a metal foil, a metal sheath, and a wound metal wire. From the variety of available conductors and rod constructions, one has choices in order to attain sufficient arc resistance, particularly in areas of greater concern, while retaining strength and flexibility for high speed separation.
A further form of the invention is shown in
Suitable compositions for the metal part 832b include, for example, beryllium-copper, stainless steel, and others used in prior metal whips. Generally, metal part 832b need not be solid; it could be tubular but solid metal rods, either tapered or of uniform cross-section are often more readily available and less expensive.
In
In the example of
Examples such as are shown in
An example of a further variation or optional feature for a “quick break whip” type of arc extinguishing device is shown in
An arrangement like that of
Embodiments such as
The wheel 936b can be of a metal such as brass or copper. Also, carbon can be used for lubricity and added life to the wearing surface of the whip.
The device 1030 includes a whip 1032, that is of some form of the previously discussed whips, a latch 1036, and an additional part referred to here as a bumper rod 1033.
The latch 1036 is generally similar to the latch 36 of
The bumper rod 1033 is an example of another element in an arc extinguishing device 1030 for a center break switch. In this example, bumper rod 1033 is substantially rigid like the latch rod 1036a (i.e., compared to the whip 1032) and is attached to the contact arm 12a by an attachment 1034 that can be the same location as the attachment for the whip 1032. The rod 1033 extends up from the arm 12a, past the location where the whip 1032 and the latch 1036 contact each other, to a laterally extending portion 1033a with a bumper 1033b on it following which there is a loop 1033c of the rod.
The loop 1033c of the rod 1033 is to reduce voltage stress. The bumper 1033b is located so that after an opening of the switch, and the tip of the whip 1032 has released from the latch 1036, the whip's motion away from the latch is limited in magnitude by the bumper (
The latch 1036 of
As the switch recloses from its fully open position (not shown), the whip and latch come together and make contact before the main switch contacts meet. First the whip 1032 meets the loop 1036c of the latch. The whip proceeds to slide around the surface of the loop until it passes onto the rod 1036a. It is not necessary for the wheel 1036b to play a role in the reclosing process; it should be in a position to perform its role in switch opening and to be where it does not hold up or interfere with the travel of the whip between the loop 1036c and the rod 1036a during switch closing.
Where a two part whip 832 like those of
From the foregoing it is believed innovative whips, and whip and latch combinations, for arc extinguishing devices can be made in forms including those with high speed operation capable of interrupting large currents at high voltage (e.g., up to at least 138 kV). Current levels at least twice that of those interrupted by prior all metal whips can be achieved. This improved performance, along with long life, can be provided relatively economically, i.e., with no substantially greater cost of manufacture than prior art devices. Typically, in the past when all metal whips have been inadequate for a particular application, it has been necessary to avoid use of an air break switch with a quick break whip and instead use a much more costly vacuum switch.
One of the advantages of the apparatus innovations presented is that they can be applied substantially as straightforward replacements for prior whips and latches and achieve improved results. However, these innovations also open up new opportunities for arc extinguishing devices that are modified to take even greater advantage of the increased unit strength and flexibility of the improved whips and latch.
The illustrated, and presently preferred, embodiments involve use of tapered whip elements. However, non-tapered elements can also be suitable in embodiments such as those otherwise like
In embodiments such as
In the description of various embodiments, for example,
While various forms of the invention herein can be practiced with a unitary whip having a member of material (e.g., nonmetal, such as FRP, with an applied surface conductor) over the whole length of the whip, two-part whips have the extra qualities described above and further expand the opportunity for achieving a desired level of performance characteristics from a wider choice of materials. For example, as one general form of whip, one may have a base portion, the part with attachment to a switch contact or contact arm, of a first composition and a tip portion, that being the part last to separate from the latch or hook of the arc extinguishing device, of a second composition. Both portions include a conductive surface but the composition of the first portion (e.g., an all-metal, such as a copper beryllium alloy) is chosen to have an appreciably greater durability in withstanding arcing between it and a latch upon initial switch opening and closing than the second composition might have. Also, the composition of the second portion (e.g., FRP with an applied conductor) is chosen that has an appreciably greater specific strength (defined in materials engineering as the strength to weight ratio of the material) than the first composition in order to achieve the benefit of higher separation speed with less chance of arc restrikes when the tip of the whip springs away from the latch. A lower density for the second composition, compared to the first composition, is also a general characteristic in such whips.
An MMC material, with or without an applied conductor, is also an example of a material that can meet the criteria mentioned for the second composition, even though it is at least partially of metal in its interior.
Additional embodiments of the invention include those illustrated in
The sectional view of
The adhesive 853, for example, includes a resinous material such as at least one selected from the group consisting of epoxy resin, urethane resin, and silicone resin. Also, in this example, the adhesive 853 contains metal particles 853a, however, an adhesive 853 without metal particles can be acceptable. Such resinous adhesives with varying amounts of metal particles contributing to conductivity are widely commercially available.
An embodiment can, for example, include a braid 850′ of a commercially available tubular metal braid as previously described. More generally, the strands 851 can be of a wire or multiple wires, individually or overlappingly disposed around or along the rod assembly 840.
A benefit that can be attained from embodiments like that of
For these purposes, the conductor such as braid 850′ can be applied directly to the surface of the nonmetal material, such as FRP, of the rod assembly 840. While the presence of some conductive or nonconductive adhesive layer directly under the braid is an option, it is not considered necessary and might itself be damaged (e.g., partially wiped off) during the placement of the rod assembly 840 into the tubular braid. A convenient but effective assembly method is to put a rod assembly 840 with a bare surface into a tubular metal braid 850′, crimp the braid ends at the ends of the rod, and apply (e.g., by painting) the adhesive over the braid 850′ with some of the adhesive 853 reaching the rod surface to bond the strands 851 to the surface.
Metal particles 853a, if used in the adhesive 853, can be favorable to the conductivity of the overall combination but even so such an adhesive 853 normally has lower conductivity than the braid 850′. Consequently, after the above-mentioned steps in forming the assembly, it is also favorable to go over the outermost surface of the braid 850′ with a lightly applied solvent to make the braid surface substantially free of the adhesive 853 (yet having the adhesive retained in the gaps 852 as shown).
An additional benefit can be obtained from the combination of the strands 851 and the adhesive 853. The strands wear from their contact with the latch in operation of a switch, and are reduced in thickness as a result. The adhesive 853 between strands can make some sliding contact with the latch that helps provide an increased bearing surface to relieve the bearing force of the latch on the strands 851. This factor can contribute to achieving a greater number of switch operations, in addition to the adhesive reducing tearing of the strands.
The described bonding of metal strands (e.g. metal braid) to a nonmetal rod surface is of benefit for a whip that has a nonmetal with a surface conductor over its entire length as well as for a two part (all-metal portion 832b and nonmetal portion 832a′) whip with a joint between the portions.
Referring again to
Conductors on the rod assembly 840 in a joint 858 as shown in
The metal spine 860 has been found favorable to use in combinations of metal and nonmetal whip portions 832b and 832a or (832a′) for increased strength of the nonmetal portion 832a at the blunt end joined to the metal portion 832b, particularly at an axial position 833a where the nonmetal portion 832a exits the socket 858. At that location there is a high stress when the two-part whip 832′ releases from the latch of an arc extinguishing device, such as latch 36, 1036, 1136, or 1236 in the illustrated embodiments. A metal spine 860 considerably enhances the durability of the whip 832′ and makes it considerably less likely for breakage of the whip to occur in operation. The spine 860 helps to distribute the stress. The metal spine 860 is, thus, intended for mechanical durability and does not need to play an electrically conductive role in the structure.
A metal spine is also desirable to use in joints like that of
By way of further example, the metal spine 860 can be a piece of spring steel, such as a music wire; and the socket 833 can be a tubular piece of conductive metal, such as stainless steel or copper-beryllium alloy. The socket 833 is formed with thin front and back edges 833a and 833b in this example so a latch sliding over the joint 858 can smoothly transition onto and off of the socket. In its manufacture, the socket 833 is formed with an internal stop or shoulder 833c. To assemble the parts, an assembly pin (not shown) is inserted into the socket 833, from the right end in
Continuing with the example of assembly, after the rod 832b and socket 833 are so joined, the assembly pin is removed from the socket and the blunt end of the whip portion 832a′ is inserted, including the rod assembly 840, conductor 850′, and spine 860, with bonding as shown in
The device 1130 also includes a second contact element (latch or hook) 1136 with a rod portion 1137 at one end of which is joined an end of a pin 1138 on which a roller (or wheel) 1136b with an outer rim 1139 (e.g., with a circumferential groove) is located and is free to rotate, a second end of the pin 1138 being joined with a cam bar 1140. All the parts of the latch 1136 are conductive. For example, the rod 1137, the pin 1138 and the cam bar 1140 can be of stainless steel or copper-beryllium alloy while the roller 1136b can be of any such metal or, at least its rim portion 1139, of a conductor such as carbon for its self-lubrication and arc resistance properties.
The whip 1132 and the latch 1136 are respectively conductively attached to first and second relatively movable electrically conductive parts (e.g., switch contacts 1113a and 1113b on respective contact arms 1112a and 1112b) in a combination in which (in the case of a center break switch 1110) the switch arms 1112a and 1112b are movable from a first, closed, switch position (as shown in
The sliding conductive engagement includes, during a switch operation from closed to open positions, engagement of the conductive path on the whip 1132 with the rim 1139 of the roller 1136b of the latch 1136, as illustrated in
In some preferred forms, the whip 1132 includes parts 1132a (such as of a nonmetal having a conductive surface) and an all-metal base portion 1132b (solid or tubular) such as the two part whips shown in
With such a two-part whip in a device 1130, in going from an open to a closed position of the switch, there is contact first by the metal portion 1132b with the cam bar 1140 (as shown in
The arc extinguishing device 1130 also includes, as an optional feature, a bumper rod 1133 with a bumper 1133b that lessens rebounding of the whip 1132 in the manner described in connection with
The device 1130, as shown in this example, does not include voltage stress relieving loops at the ends of the latch 1136 and the bumper rod 1133 like those shown (elements 1036c and 1033c) in
In the general case, a whip 1132 with two parts 1132a and 1132b can best utilize parts of contrasting properties. The base portion 1132b is preferably chosen for high durability against arcing encountered upon initial switch opening and closing. An all-metal composition as formerly used for whips is satisfactory for that purpose. The tip portion 1132a need not have as high a degree of durability (e.g., it may have materials more subject to wear if it were subjected to the same arcing conditions as the base part 1132b) and can be selected for lower density and higher specific strength than the base part 1132b for the sake of higher separation speeds. The configuration of the latch 1136 with the cam bar 1140 opposite the rod 1137, with the roller 1136b inbetween, is a way in which the wear on the tip portion 1132a can be minimized, in addition to the benefits of having bonded conductor strands 851, as in the example of
The whip 1232 has parts 1232a and 1232b, corresponding generally to the parts of whip 1132 in the preceding embodiment, with a joint 1258. The latch 1236 has parts 1237, 1236b and 1240 (best seen in
Although, in contrast to the center break switch, relative motion of the contacts 1213a and 1213b is by movement of just one contact arm 1212a, the whip 1232 and latch 1236 of
The solid lines show the elements in a closed position of the switch 1210.
When the switch 1210 is fully open, normally the contact arm 1212a is perpendicular to its original closed position. In a switch closing, the arm 1212a is moved down back to the closed position shown with the whip portion 1232b contacting, first, the cam bar 1240 of the latch 1236 and, upon further movement, the rod portion 1236 of the latch. During the closing operation, the bumper 1233b helps to press the whip portion 1232b against the latch elements (as does the bumper 1133b of the preceding embodiment).
The embodiments disclosed are merely some examples of the various ways in which the invention can be practiced.
This application is a continuation-in-part application of application Ser. No. 10/342,035, filed Jan. 14, 2003 now U.S. Pat. No. 6,762,385, by P. Kowalik et al.
| Number | Name | Date | Kind |
|---|---|---|---|
| 2750460 | Kast | Jun 1956 | A |
| 2769063 | Lingal | Oct 1956 | A |
| 2849578 | Hart | Aug 1958 | A |
| 2873325 | Kelly | Feb 1959 | A |
| 3005063 | Zemels et al. | Oct 1961 | A |
| 3032632 | Beach et al. | May 1962 | A |
| 3217115 | Kaplan | Nov 1965 | A |
| 3244825 | Killian et al. | Apr 1966 | A |
| 3862509 | Petersen, Jr. | Jan 1975 | A |
| 3955303 | Outlaw et al. | May 1976 | A |
| 4080643 | Cline | Mar 1978 | A |
| 4170014 | Sully | Oct 1979 | A |
| 4238800 | Newington | Dec 1980 | A |
| 4243854 | Pahl | Jan 1981 | A |
| 4379298 | Vincent et al. | Apr 1983 | A |
| 4860481 | Christenson | Aug 1989 | A |
| 4945333 | Stroud et al. | Jul 1990 | A |
| 5186315 | Koppe et al. | Feb 1993 | A |
| 5359167 | Demissy et al. | Oct 1994 | A |
| 5369234 | Demissy | Nov 1994 | A |
| 5728988 | Meinherz et al. | Mar 1998 | A |
| 6392181 | Cleaveland et al. | May 2002 | B1 |
| 6791504 | Miller et al. | Sep 2004 | B1 |
| Number | Date | Country | |
|---|---|---|---|
| 20040173576 A1 | Sep 2004 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 10342035 | Jan 2003 | US |
| Child | 10788961 | US |
