Wrapped film sealing system for electrical equipment

Information

  • Patent Grant
  • 6372994
  • Patent Number
    6,372,994
  • Date Filed
    Tuesday, January 11, 2000
    24 years ago
  • Date Issued
    Tuesday, April 16, 2002
    22 years ago
  • Inventors
  • Examiners
    • Reichard; Dean A.
    • Nino; Adolfo
    Agents
    • Fish & Richardson P.C.
Abstract
A wrapped film sealing system includes a conductive stud, a film layer wrapped around at least a portion of the length of the conductive stud, and a bushing including a channel passing between two open ends. The conductive stud passes through the channel and a seal is formed between the conductive stud, the film layer, and the bushing.
Description




TECHNICAL FIELD




This invention relates to a wrapped film sealing system for electrical equipment.




BACKGROUND




Many types of conventional electrical equipment contain a dielectric fluid for dissipating the heat that is generated by energized components of the equipment, and for insulating those components from the equipment enclosure and from other internal parts and devices. Examples of such equipment include transformers, capacitors, regulators, circuit breakers and reclosers. Transformers are used extensively in the transmission of electrical power, both at the generating end and at the load end of the power distribution system. A distribution transformer is one that receives electrical power at a first voltage and delivers it at a second, lower voltage.




A distribution transformer consists generally of a core and conductors that are wound about the core so as to form at least two windings. The windings (also referred to as coils) are insulated from each other, and are wound on a common core of magnetically suitable material, such as iron or steel. The primary winding or coil receives energy from an alternating current (AC) source. The secondary winding receives energy by mutual inductance from the primary winding and delivers that energy to a load that is connected to the secondary winding. The core provides a circuit or path for the magnetic lines of force (magnetic flux) which are created by the alternating current flow in the primary winding and which induce the current flow in the secondary winding. The core and winding are typically retained in an enclosure for safety and to protect the core and coil assembly from damage caused by weather or vandalism.




Transformers generate heat during operation through (1) electrical resistance in the conductors that constitute the windings, (2) alternating magnetic flux generating current flow in the core material as the flux passes through the core, and (3) hysteresis (i.e., the friction between the magnetic molecular particles in the core material as they reverse their orientation within the core steel, which occurs when the direction of the AC magnetic field reverses). The generated heat reduces transformer life by degrading the insulation of various internal components, which can lead to an internal fault or short circuit. To dissipate the heat, transformers may be filled with a dielectric coolant, which also functions to electrically insulate the transformer components from one another and from the enclosure.




An electrical connection is formed from the inside of the transformer to the outside using an electrical bushing, such as an insulated component bushing well or tri-clamp bushing. The bushing must provide a seal through an internal stud or components and an external flange. The external flange is sealed by additional gasket components or welding to the flanges.




SUMMARY




In one general aspect, a wrapped film sealing system includes a conductive stud, a film layer wrapped around at least a portion of the length of the conductive stud, and a bushing well including a channel passing between two open ends. The conductive stud passes through the channel and a seal is formed between the conductive stud, the film layer, and the bushing.




Embodiments may include one or more of the following features. For example, the conductive stud may include a knurled portion and the film layer may be wrapped around the knurled portion. The knurled portion may include knurled surfaces interspersed with smooth surfaces. The conductive stud may include a smooth portion and the film layer may be wrapped around a portion of the smooth portion. The film layer may include an adhesive layer, such as a heat shrinkable plastic. The film layer also may include a thermoplastic.




The bushing may include a thermoplastic, which may be a nylon. The bushing also may include a thermoset material. The bushing may be a bushing well or a tri-clamp bushing. The conductive stud in the channel in the bushing well may be a removable conductive stud.




In another general aspect, a method of sealing a stud in a bushing includes providing a conductive stud and a film. The film is wrapped around a circumference of the stud along at least a portion of a length of the stud, and the wrapped stud is inserted into a molding machine into which a plastic is then injected. The plastic defines a bushing having a channel through which the stud and film extend. The plastic also bonds to the film such that the film forms a seal in the channel between the stud and bushing.




Embodiments may include one or more of the following features. For example, the method may further include heating the film wrapped around the stud before inserting the stud into the molding machine, such that heating the wrapped film shrinks the wrapped film around the stud. The wrapped film may include an adhesive layer and a heat shrinkable plastic, such as a thermoplastic. The plastic also may include a thermoplastic, which may be nylon, or a thermoset material. The molding machine may be an injection molding machine or a transfer molding machine.




Inserting the stud into the molding machine may include inserting the stud into a mold and placing the mold in the molding machine. The portion of the length of the stud may include a knurled section, with the film being wrapped around the knurled section. The knurled section may include knurled surfaces interspersed with smooth surfaces. The bushing may be a bushing well or a tri-clamp bushing.




The wrapped film sealing system provides considerable advantages. For example, the system may be used to provide a seal between a conductive stud and a bushing to prevent leakage of dielectric fluid. The wrapped film layer can compensate for the difference in thermal expansion between the conductive stud and the plastic bushing, which improves the reliability of the seal.




Conventionally, the seal is provided by spraying an adhesive on the conductive stud and then the bushing is injection molded around the stud. The adhesive may include a solvent that contains potentially environmentally harmful organic solvents that are released into the atmosphere during the spraying step. After the adhesive is applied to the stud, it is baked to cure the adhesive and bond the adhesive to the stud. The wrapped film sealing system advantageously avoids use of potentially harmful solvents, and also avoids the time and expense of baking, thereby resulting in a less complex and much cleaner process.




Other features and advantages will be apparent from the following description, including the drawings, and from the claims.











DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of an electrical transformer.





FIG. 2

is a perspective view showing a core and coil assembly mounted within the transformer of FIG.


1


and connected to secondary terminals.





FIGS. 3-6

are cross-sectional front views of a conductive stud in a tri-clamp bushing.





FIGS. 7 and 8

are cross-sectional front views of a conductive stud in a bushing well.





FIG. 9

is an enlarged cross-section front view showing a seal between the conductive stud and bushing of

FIGS. 7 and 8

.





FIG. 10

is a flow chart of the steps used to form the seal between a conductive stud and bushing.





FIGS. 11-14

are front and end views of a conductive stud wrapped with a film layer before and after application of heat to the conductive stud and film layer.





FIG. 15

is a flow chart of the steps used to form the seal between a conductive stud and bushing when a separate heat treatment step is omitted.





FIGS. 16-19

are front views of conductive studs having various configurations of knurled and smooth section to which a film layer is wrapped.











DESCRIPTION




Referring to

FIG. 1

, a transformer


5


includes a core and coil assembly


10


(shown schematically in FIG.


1


), an enclosure


15


, a high voltage bushing


20


, low voltage bushings


25


,


26


,


27


, and a ground lug


30


. The core and coil assembly


10


is positioned within enclosure


15


and includes a primary winding


35


and a secondary winding


40


. A dielectric fluid


45


fills enclosure


15


and surrounds the core and coil assembly


10


. Bushings


20


and


25


-


27


may be made of an insulative material, such as a polymer.




Referring also to

FIG. 2

, a transformer primary lead


50


interconnects primary winding


35


with high voltage bushing


20


, which is sealingly mounted to enclosure


15


through an aperture


52


in the enclosure. Low voltage bushings


25


,


26


,


27


are constructed and sealingly attached to enclosure


15


. Bushings


25


,


26


,


27


include insulative bodies


55


-


57


, which extend through apertures


60


-


62


in the enclosure


15


. Bushings


25


,


26


,


27


further include conductive studs


65


-


67


and terminal end caps


70


-


72


. Secondary leads


75


-


77


connect the secondary winding


40


to conductive studs


65


-


67


.




Referring to

FIGS. 3 and 4

, the low voltage bushings


25


,


26


,


27


can be implemented, for example, as tri-clamp bushings.

FIGS. 3 and 4

illustrate one example of a tri-clamp bushing design. A tri-clamp bushing


80


includes a channel


83


and a mounting flange


85


. The tri-clamp bushing


80


is mounted through one of apertures


60


-


62


(FIG.


2


), and forms a seal between mounting flange


85


and the edge of the aperture through which it is mounted. A conductive stud passes through channel


83


and forms a seal with the tri-clamp bushing. A conductive stud


87


differs from a conductive stud


88


in the configuration of the outside end. Stud


87


has a round end


90


whereas stud


88


has a flat end


92


. The outside end is connected to a wire that delivers high voltage electricity to the transformer


5


.




The tri-clamp bushing


94


of

FIGS. 5 and 6

differs from the tri-clamp bushing


80


of

FIGS. 3 and 4

in the configuration of a channel


96


that has a reduced diameter to accommodate a narrow diameter stud. Like studs


87


and


88


, narrow diameter studs


97


and


98


differ in their outside ends. Stud


97


has a round outside end whereas stud


98


has a flat end. Conductive studs


87


,


88


,


97


and


98


are mounted in tri-clamp bushings


83


and


96


, respectively, such that a seal between the stud and tri-clamp bushing prevents the dielectric fluid from leaking out of the transformer enclosure


15


through the channel in the tri-clamp bushing.




Referring to

FIGS. 7 and 8

, high voltage bushing


20


(

FIG. 1

) can be implemented, for example, as a bushing well.

FIGS. 7 and 8

illustrate two different bushing well designs.

FIG. 7

illustrates a bushing well


100


that includes a conductive stud


105


passing through a channel


110


in the bushing well. Bushing well


100


is mounted through aperture


52


(FIG.


1


), and forms a seal between mounting flange


115


and the edge of the aperture through which it is mounted. The seal prevents dielectric fluid


45


from leaking out of the transformer enclosure


15


. Referring also to

FIG. 8

, another design of a bushing well


200


includes a conductive stud


205


passing through a channel


210


in the bushing well. Like bushing well


100


, bushing well


200


is mounted through aperture


52


, and forms a seal between a mounting flange


215


and the edge of the aperture through which the bushing well


200


is mounted to prevent dielectric fluid


45


from leaking out of the transformer enclosure


15


. Bushing well


200


differs from bushing well


100


in that the mounting flanges


115


and


215


differ, the bushing wells are designed to receive conductive studs of different shapes, and the stud


105


of the bushing well


100


is fixed whereas the stud


205


of the bushing well


200


is removable.




Conductive studs


105


and


205


are mounted into bushing wells


100


and


200


, respectively, such that a seal between the stud and the bushing well prevents the dielectric fluid from leaking out of the transformer enclosure


15


through the channel in the bushing well. Referring to

FIG. 8

for exemplary purposes, a seal


220


is formed between a knurled portion


225


of the conductive stud


205


and the channel


210


. Similar seals are formed in tri-clamp bushings


83


and


94


between the respective studs and channels.




Referring also to

FIG. 9

, seal


220


includes a film layer


230


surrounding the knurled portion


225


and contacting the inner diameter of channel


210


. The film layer is bonded to the bushing well and may be bonded and/or tightly adhered to the conductive stud. The film compensates for the difference in thermal expansion between the stud and the bushing well to maintain the integrity of the seal during the different transformer environmental conditions that occur within the transformer during its use. Although

FIG. 9

shows the film layer


230


surrounding only the knurled portion


225


, the film layer


230


can surround other portions of the conductive stud, and can be bonded or adhered to the channel.




Referring to

FIG. 10

, film layer


230


is attached to the stud


205


and the seal


220


is formed in a multi-step fabrication process


300


. As illustrated in

FIGS. 11 and 12

, the film layer


230


is wrapped at least once around the entire diameter of the conductive stud


205


at knurled portion


225


(step


305


). The film layer


230


may overlap itself and be wrapped more than once around the conductive stud


205


. Referring also to

FIGS. 13 and 14

, heat is optionally applied to the film layer


230


to cause it to shrink down around the stud


205


(step


310


), which reduces the outer diameter of the film layer


230


and creates a seal between the tape and stud. Heat may be applied to shrink the film by using a heat gun or other heat device. Heating the film also may cause the film to bond to the conductive stud, which improves the seal between the tape and the stud.




The conductive stud


205


then is inserted into an injection mold or transfer mold (step


315


), which is placed into an injection or transfer molding machine. A plastic or thermoset material then is injected into the mold around the conductive stud


205


and film layer


230


to form the bushing well


200


(step


320


). Injection molds, transfer molds and the processes of injection and transfer molding are well-known in the art. The molded plastic bonds to the film layer and, because the molded plastic heats the film layer, bonds the film layer to the stud. Consequently, the film layer creates the seal


230


between the stud and bushing well


200


to prevent dielectric fluid


45


from passing through channel


210


. After the plastic has cooled sufficiently, the bushing well


200


can be removed from the mold (step


325


) and installed in the transformer enclosure


15


.




The process


300


of

FIG. 10

typically is applicable for using film layers in which neither side has an adhesive backing. By heating and shrinking the film around the conductive stud, the film is adhered to the stud so that it can be further processed without the concern that the tape may unwind and separate from the stud before the bushing well (or tri-clamp bushing) is formed around it. If, on the other hand, the film includes an adhesive backing on one or both sides, there is less concern that the tape will loosen and separate from the stud in the later processing steps. With such a tape, the heating step can be omitted, as illustrated in a process


400


of FIG.


15


.




In process


400


, the film layer is wrapped around the conductive stud (step


405


) as described above with respect to step


305


except that the tape adheres to the stud. The conductive stud and tape then are inserted into the injection mold (step


410


), which is inserted into the injection molding machine and a plastic material injected into the mold (step


415


). As described above with respect to the process


300


, the film layer is heated by the injection molded plastic. Because the film layer has not been shrunk around the conductive stud in process


400


, the heat of the injection molded plastic causes the film layer to shrink around the conductive stud and potentially bond to the stud.




Processes


300


and


400


can be modified in various manners. For example, although processes


300


and


400


are described and illustrated in terms of wrapping the film layer around the knurled portion of the conductive stud, the film layer may be wrapped around other portions of the conductive stud. The position of the film layer must be such that the injection molded plastic will contact and bond with the film layer. In general, it is easier to wrap the film around a smooth surface on the conductive stud but the film fills the crevices formed in a knurled surface, potentially providing a better bond between the film and stud.




Although the conductive stud illustrated above included a knurled section only, various configurations are possible. Referring to

FIGS. 16-19

, the surface to which the film is to be applied may have a number of configurations of smooth and knurled sections. For example, referring to

FIG. 16

, stud


505


has a surface


510


that is a combination of longitudinal knurled sections


515


and smooth sections


520


. As explained above, typically the film layer will be easier to apply to the smooth sections


520


but will fill the crevices in the knurled sections


515


. Referring to

FIG. 17

, a stud


530


has a surface


535


that is a combination of a circumferential smooth section


540


between a pair of circumferential knurled sections


545


. Referring to

FIG. 18

, in a related configuration, a stud


550


has a surface


555


with multiple circumferential smooth sections


560


separated by multiple circumferential knurled sections


565


. Finally, referring to

FIG. 19

, a stud


570


has a surface


575


with alternating helical smooth sections


580


and knurled sections


585


.




With respect to the selection of materials, typically, the injection or transfer molded plastic will be a thermoplastic, such as Zytel HTN™, a high temperature polyphthalamide; Crastin™, a polybutylene terephthalate; or Rynite™, a polyethylene terephthalate. Each of these thermoplastic materials is sold by E.I. Du Pont de Nemours & Co. of Wilmington, Del. The injection or transfer molded plastic also may be a thermoset plastic, such as E8353-706R or E8398, which are epoxidized novolac molding compounds sold by Rogers Corporation of Rogers, Conn.




The film typically also will be a thermoplastic, such as the film sold under the trade name Surlyn™, which is marketed by E.I. Du Pont de Nemours & Co. of Wilmington, Del. The film also may be a polytetrafluoroethylene film or tape, such as the PTFE tapes and films sold by 3M and E.I. Du Pont de Nemours & Co. The tape may be formed with or without glass fibers and adhesive backings. The dimensions of the film, for example, may be one inch wide, five inches long, and have a thickness of approximately 2.0 mils. The film also may be an adhesive thermoplastic tape that adhesively bonds to the conductive stud. The conductive stud may be made from any electrically conductive material, such as copper or aluminum.




Other embodiments are within the scope of the following claims.



Claims
  • 1. A wrapped film sealing system comprising:a conductive stud; a film layer wrapped around at least a portion of the length of the conductive stud; and a bushing including a channel passing between two open ends, wherein the conductive stud passes through the channel and a seal is formed between the conductive stud, the film layer, and the bushing.
  • 2. The wrapped film sealing system of claim 1, wherein the conductive stud includes a knurled portion and the film layer is wrapped around the knurled portion.
  • 3. The wrapped film sealing system of claim 2, wherein the knurled portion comprises knurled surfaces interspersed with smooth surfaces.
  • 4. The wrapped film sealing system of claim 1, wherein the conductive stud includes a smooth portion and the film layer is wrapped around a portion of the smooth portion.
  • 5. The wrapped film sealing system of claim 1, wherein the film layer comprises an adhesive layer.
  • 6. The wrapped film sealing system of claim 1, wherein the film layer comprises a heat shrinkable plastic.
  • 7. The wrapped film sealing system of claim 1, wherein the film layer comprises a thermoplastic.
  • 8. The wrapped film sealing system of claim 1, wherein the bushing comprises a thermoplastic.
  • 9. The wrapped film sealing system of claim 8, wherein the thermoplastic comprises nylon.
  • 10. The wrapped film sealing system of claim 1, wherein the bushing comprises a thermoset material.
  • 11. The wrapped film sealing system of claim 1, wherein the bushing comprises a tri-clamp bushing.
  • 12. The wrapped film sealing system of claim 1, wherein the bushing comprises a bushing well.
  • 13. The wrapped film sealing system of claim 12, wherein the conductive stud in the channel in the bushing well comprises a removable conductive stud.
Parent Case Info

This appln claims benefit of Prov. No. 60/110,526 filed Dec. 1, 1998.

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Provisional Applications (1)
Number Date Country
60/110526 Dec 1998 US