EP1074028A1 - Dry-type transformer having a generally rectangular, resin encapsulated coil - Google Patents

Dry-type transformer having a generally rectangular, resin encapsulated coil

Info

Publication number
EP1074028A1
EP1074028A1 EP98913227A EP98913227A EP1074028A1 EP 1074028 A1 EP1074028 A1 EP 1074028A1 EP 98913227 A EP98913227 A EP 98913227A EP 98913227 A EP98913227 A EP 98913227A EP 1074028 A1 EP1074028 A1 EP 1074028A1
Authority
EP
European Patent Office
Prior art keywords
coil
recited
power distribution
dry
distribution transformer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP98913227A
Other languages
German (de)
French (fr)
Inventor
David M. Nathasingh
D. Christian Pruess
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Honeywell International Inc
Original Assignee
AlliedSignal Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by AlliedSignal Inc filed Critical AlliedSignal Inc
Publication of EP1074028A1 publication Critical patent/EP1074028A1/en
Withdrawn legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/28Coils; Windings; Conductive connections
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/24Magnetic cores
    • H01F27/25Magnetic cores made from strips or ribbons
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/28Coils; Windings; Conductive connections
    • H01F27/2847Sheets; Strips
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/28Coils; Windings; Conductive connections
    • H01F27/2847Sheets; Strips
    • H01F2027/2857Coil formed from wound foil conductor

Definitions

  • the present invention relates to transformers; and more particularly, to a dry- type power distribution transformer having a wound ferromagnetic metal core and a generally rectangular resin encapsulated coil.
  • Conventional dry-type power distribution transformers have a round or toroidal open wound coil and a silicon steel or amorphous metal core of the wound or stacked variety.
  • the transformer core typically has a rectangular shape defining a rectangular window within which the coil is located.
  • the toroidal shape of the coil creates a mismatch between the core and coil insofar as the core window is concerned, i.e. the shape of the rectangular window does not match the shape of the section of the coil that is located therein.
  • This mismatch between the core and coil causes the size and cost of the transformer to be significantly larger than would be required if the transformer had more closely matched core and coil shapes.
  • Wound cores used in power distribution transformers are rectangular in cross-section and do not conform to the round shape of the coil.
  • Stacked silicon steel transformer cores may have a cruciform cross-section that can approximately match the coil ' s toroidal shape. Due to the high expense of casting or cutting an amorphous metal strip to a variety of widths, it is impractical to form a stacked amorphous metal core with a cruciform cross-section. For these reasons, in manufacture of dry-type power distribution transformers having ferromagnetic metal cores, whether wound or stacked, the cross-sectional shape of the core (i.e. rectangular) and the shape of the coil (i.e. round) do not match. Usage of coil material is uneconomical, and transformer sizes are too large.
  • Power distribution transformers may be installed in a variety of locations and subject to extreme environmental conditions such as. for example, particulate matter (dust. dirt. etc.). moisture, caustic substances, and the like, which adversely effect the life span and performance of the transformer. Open wound coils provide no protection against the effects of such the harsh environments.
  • the present invention provides a dry-type power distribution transformer having a wound ferromagnetic metal core and a generally rectangular, resin encapsulated coil.
  • the core has a generally rectangular cross-sectional shape that closely matches the generally rectangular shape of the resin encapsulated coil.
  • a dry-type ferromagnetic metal power distribution transformer that is less expensive to manufacture, less resistive and less lossy, in that less coil material is needed to wind the coil, and more compact than transformers having generally round or circular coils.
  • the dry-type dry- power distribution transformer includes a resin encapsulated generally rectangular coil having a substantially straight section and a ferromagnetic metal core, composed of amorphous metal or silicon steel, having a generally rectangular core window defined therein.
  • the coil and the core are sized and shaped such that the shape of the substantially straight section of the coil substantially conforms to the shape of the core window.
  • the substantially straight section of said coil is located within the core window.
  • the resin encapsulation protects the coil against harsh environmental conditions, protects the insulation system of the coil, improves the coil strength under short-circuit conditions, and improves the coil ' s cooling characteristics by providing a smooth, uniform surface about the coil ' s exterior over which air (either forced or convective) may smoothly and easily pass.
  • the dry-type power distribution transformer of the invention is durable and robust. Coil and core materials are utilized in a highly economical manner that significantly decrease manufacturing cost and transformer size. These features are especially desirable in power distribution transformers where size. cost, and performance govern market acceptance.
  • Fig. 1A is a frontal view of a shell-type single phase transformer constructed in accordance with the present invention with the coil partially cut-away:
  • Fig. I B is a cross-sectional view taken along line B-B of Fig. 1 A:
  • Fig. 2A is a frontal view of a core-type single phase transformer constructed in accordance with the present invention.
  • Fig. 2B is a cross-sectional view taken along line B-B of Fig. 2A;
  • Fig. 3A is a frontal view of a three phase transformer constructed in accordance with the present invention.
  • Fig. 3B is a cross-sectional view taken along line B-B of Fig. 3A:
  • Fig. 4 is a perspective view of a generally rectangular, low voltage coil wound about a rectangular mandrel in accordance with the present invention
  • Fig. 5 is a perspective view of a generally rectangular, high voltage coil wound about a rectangular mandrel in accordance with the present invention
  • Fig. 6 is a perspective view of an epoxy containment vessel configured for encapsulating a generally rectangular coil in accordance with the present invention
  • Fig. 7 is a top view of the epoxy containment vessel of Fig. 6 with a generally rectangular coil contained therein:
  • Fig. 8 is a block diagram of an encapsulation system for encapsulating a coil constructed in accordance with the present invention.
  • a shell-type single phase power distribution transformer (Fig. 1A); and a core-type single phase power distribution transformer (Fig. 2A).
  • Shell-type single phase transformer comprises a generally rectangular, resin encapsulated coil 40 and two ferromagnetic metal cores 20.
  • Core- type single phase transformer 10 comprises two generally rectangular, resin encapsulated coils 40 and a single ferromagnetic metal core 20.
  • a second embodiment of the invention is depicted in Fig. 3A. In that embodiment shell-type three-phase power distribution transformer 10 comprises three generally rectangular, resin encapsulated coils 40 and four ferromagnetic metal cores 20.
  • the ferromagnetic metal of which core 20 is composed is formed either from silicon steel or an amorphous metal.
  • amorphous metal means a metallic alloy that substantially lacks any long range order and is characterized by X-ray diffraction intensity maxima which are qualitatively similar to those observed for liquids or inorganic oxide glasses.
  • Amorphous metal alloys are well suited for use in forming cores 20. because they have the following combination of properties: (a) low hysteresis loss: (b) low eddy current loss; (c) low coercive force; (d) high magnetic permeability: (e) high saturation value; and (f) minimum change in permeability with temperature.
  • Such alloys are at least about 50% amorphous, as determined by x-ray diffraction.
  • Preferred amorphous metal alloys include those having the formula M 60.90 T 0 ., 5 X l 0 _ 25 , wherein M is at least one of the elements iron, cobalt and nickel, T is at least one of the transition metal elements, and X is at least one of the metalloid elements of phosphorus, boron and carbon. Up to 80 percent of the carbon, phosphorus and/or boron in X may be replaced by aluminum, antimony, beryllium, germanium, indium, silicon and tin.
  • amorphous metal alloys Used as cores of magnetic devices, such amorphous metal alloys evidence generally superior properties as compared to the conventional polycrystalline metal alloys commonly utilized.
  • strips of such amorphous alloys are at least 80% amorphous, more preferably yet. at least 95% amorphous.
  • the amorphous alloys of cores 20 are preferably formed by cooling a melt at a rate of about 10 6 °C/sec.
  • a variety of well-known techniques are available for fabricating rapidly-quenched continuous amorphous metal strip.
  • the strip material of cores 20 When used in magnetic cores for amorphous metal transformers, the strip material of cores 20 typically has the form of a ribbon. This strip material is conveniently prepared by casting molten material directly onto a chill surface or into a quenching medium of some sort. Such processing techniques considerably reduce the cost of fabrication, since no intermediate wire-drawing or ribbon-forming procedures are required.
  • the amorphous metal alloys of which core 20 is preferably composed evidence high tensile strength, typically about 200,000 to 600,000 psi, depending on the particular composition. This is to be compared with polycrystalline alloys, which are used in the annealed condition and which usually range from about 40.000 to 80.000 psi.
  • a high tensile strength is an important consideration in applications where high centrifugal forces are present, since higher strength alloys prolong the service life of the transformer.
  • the amorphous metal alloys used to form core 20 evidence a high electrical resistivity, ranging from about 160 to 180 microhm-cm at 25 °C. depending on the particular composition. Typical prior art materials have resistivities of about 45 to 160 microhm-cm.
  • the high resistivity possessed by the amorphous metal alloys defined above is useful in AC applications for minimizing eddy current losses which, in turn, are a factor in reducing core loss.
  • a further advantage of using amorphous metal alloys to form core 20 is that lower coercive forces are obtained than with prior art compositions of substantially the same metallic content, thereby permitting more iron, which is relatively inexpensive, to be utilized in the core 20, as compared with a greater proportion of nickel, which is more expensive.
  • Each of the cores 20 is formed by winding successive turns onto a mandrel
  • the strip material of cores 20 is preferably in the range of 1 to 2 mils. Due to the relatively high tensile strength of the amorphous metal alloy preferred for use herein, strip material having a thickness of 1 -2 mils can be used without fear of breakage. It will be appreciated that keeping the strip material relatively thin increases the effective resistivity since there are many boundaries per unit of radial length which eddy currents must pass through.
  • a shell-type single phase, dry- type power distribution transformer 10 includes a core/coil assembly 12 comprised of two ferromagnetic metal cores 20 and an encapsulated, generally rectangular coil 40.
  • Transformer 10 also includes a bottom frame 30 and top frame 34, having bottom and top coil supports 32, 36, respectively, and within which the core/coil assembly 12 is supportedly mounted.
  • Each core 20 is preferably wound from a plurality of ferromagnetic metal strips or layers 28 having a generally rectangular cross-sectional shape (see Fig. I B).
  • Each core 20 has two long sides 24 and two short sides 26 that collectively define a generally rectangular core window 22 within which a substantially straight mid-section 52 of the generally rectangular coil 40 of the present invention is located.
  • the aspect ratio i.e. the relationship between the long and short sides 24, 26 of the core 20. is defined herein as the ratio of the window height ( i.e. long side 24) to window width (i.e. short side 26) and is preferably between approximately 3.5 to 1 and 4.5 to 1.
  • This preferred core construction ⁇ minimizes the number of wound strips or layers 28 of ferromagnetic metal required to construct the core 20 which, in turn, yields lower temperature gradients in the coil 40.
  • Layers of epoxy (not shown) are applied along the long sides 24 to support the height of the core 20.
  • the initial epoxy layer is preferably generally compliant and penetrates between the ferromagnetic metal strips or layers 28 that comprise the core 20.
  • Core 20 is preferably constructed from ferromagnetic metal ribbon having a nominal chemistry Fe 80 B, . Si 9 , which ribbon is sold by AlliedSignal Inc. under the trade designation METGLAS 8 alloy SA- 1.
  • the desired shape of the coil 40 of the present invention is generally rectangular. However, other geometric shapes are also considered within the scope of the present invention, provided, however, that such other geometric shapes include a substantially straight mid-section 52 that is sized and shaped to fit within the generally rectangular window 22 of the core 20.
  • the coil 40 may have rounded end sections 54 that are not located within the core window 22, and a generally straight mid-section 52 that passes through and is located within the core window, e.g. an oval with generally straight mid-sections.
  • the generally rectangular coil 40 of the present invention comprises a plurality of coil windings 42 wound along with an insulating material 44 and with selectively placed cooling duct spacers 46 (see Figs. 4 and 5).
  • the generally rectangular shape of the coil 40 is obtained by winding the coil components (e.g. windings 42 and insulation material 44) about a rectangular winding mandrel 60 (see Figs. 4 and 5), alternatingly winding coil windings 42 and insulating material 44 in a plurality of concentric layers.
  • insulating material 44 comprises the inner- and outer-most layers of the wound coil 40 and further provides electrical insulation between adjacently wound coil windings 42.
  • a substantially rectangular coil channel 56 is defined longitudinally through the coil 40 upon removal of the rectangular winding mandrel 60.
  • the coil winding material is typically supplied on a spool, the material may retain a bend radius after the coil 40 is wound, causing the coil 40 to bow or assume a generally oval shape due to the memory of the winding material.
  • This disadvantageous ⁇ increases the build dimension of the coil, especially in the mid-
  • coil windings 42 (and the coil 40) retains its generally rectangular shape after it is removed from the winding mandrel 60.
  • One solution provided by the present invention involves using epoxy-dotted kraft paper as the insulating material 44 between the coil windings 42. The epoxy adheres to the coil windings 42 and, upon curing, imparts rigidity to the windings 42 that counteracts the bowing tendency of the winding material.
  • a winding form 62 may include metal corners 64 that form corners in the coil windings 42 and the coil 40 is wound on the mandrel 60.
  • a third solution involves shaping the generally rectangular form of the coil 40 as the winding material is wound on the mandrel 60 such as. for example, using a wooden block and nylon hammer. Still another solution involves leaving the coil 40 on the winding mandrel 60 and pressing the long legs of the winding 40 between clamps after the coil 40 has been completely wound and prior to encapsulation. In addition to providing the generally rectangular form to the coil 40, this latter solution serves to further compress the long legs of the coil 40 thereby minimizing build-up among the windings 42 and insulating material 44 in the sections where build-up should be minimized, i.e. the substantially straight mid-sections 52.
  • the cooling duct spacers 46 are not placed (and the cooling ducts 58are not located) in the substantially straight mid-sections 52 of the coil. This provides a distinct advantage over round or toroidal coils that require circumferentially continuous cooling ducts.
  • a circumferentially discontinuous cooling duct which is defined by the selective placement of the spacers 46, is provided only in the end sections 54 of the substantially rectangular coil 40.
  • the insulating material 44 is interspersed between adjacent layers of coil windings 42 to provide electric isolation therebetween and forms the inner- and outer-most layers of the coil 40 (not considering the epoxy encapsulation described below).
  • the insulating material 44 comprises a sheet or sheets of aramid paper such as Dupont ' s Nomex® brand. It will be obvious to those skilled in the art that various other insulating materials may be provided without departing from the spirit or intent of the present invention.
  • the inner-most and outer-most sheets of insulating material 44 are preferably sized so as to extend approximately 12 mm beyond the longitudinal ends of the coil 40.
  • the insulating material 44 located on each side of the cooling duct spacers 46 also extends approximately 12 mm past the ends of the coil 40.
  • These sheets of extended insulation material 44 are sealed with a thick epoxy such as. for example, that made by Magnolia Co., part number 3126, A/B.
  • the epoxied extended sheets of insulation material 44 then serve to contain any uncured epoxy during the encapsulation process (described in more detail below) of the coil 40.
  • Cooling for dry-type power distribution transformers may be either convective or forced-air. Cooling ducts 58 are thus necessary between the coil windings to permit the passage of air therethrough.
  • the cooling duct spacers 46 may be inserted between coil windings 42 as the coil 40 is wound and are removed after the coil 40 has been encapsulated (as described in further detail below). Since it is desirable to control the wound dimensions of the coil 40 to ensure that it will fit within the core window 22 of the core 20, the cooling duct spacers 46 are advantageously inserted only in those sections of the coil 40 that will not be located within the core window 22 (i.e. at the longitudinally distal ends of the coil 40, as clearly shown in Fig. I B) in the assembled transformer 10.
  • the dimension of the coil 40 is controlled in the section that will be located within the core window 22 thereby providing smaller (i.e. narrower) coils 40 that, in turn, produce smaller power distribution transformers.
  • the generally rectangular shape of the coil of the present invention permits the use of cooling ducts 58 that are non-continuous about the circumference of the rectangular coil. The desirability of selectively locating the cooling ducts 58 and of providing circumferentially non-continuous cooling ducts 58 is clear considering the fact that the cooling ducts 58 increase the size of the coil — which is undesirable especially in the substantially straight mid-section 52 of the coil 40.
  • the generally rectangular shape of the coil 40 of the present invention provides four clearly delineated sides (which round or toroidal coils do not) which permit selective location of the cooling ducts 58 in the end sections 54 of the coil 40.
  • the coil winding 42 comprises a sheet or sheets of aluminum or copper (see Fig. 4).
  • the coil winding 42 comprises a cross-sectionally rectangular or circular copper wire (see Fig. 5).
  • the coil 40 is wound on a rectangular mandrel 60.
  • the substantially rectangular coil 40 of the present invention may comprise only a low voltage or a high voltage coil or, alternatively, it may comprise both low and high voltage coils.
  • the wound coil 40 is completely contained in and encapsulated by an epoxy resin layer 50. as described in more detail below.
  • Figs. 4 and 5 there is shown a generally rectangular coil 40 configured in accordance with the present invention for low voltage and high voltage applications, respectively.
  • the low voltage coil 40 shown in Fig. 4 is formed by winding a coil winding 42 such as, for example, a sheet of copper or aluminum, about a generally rectangular winding mandrel 60.
  • an insulating material 44 is interspersed therebetween.
  • the insulating material 44 comprises the inner- and outer-most layers of the wound coil 40.
  • Cooling ducts 58 are provided in the wound coil 40 by inserting cooling duct spacers 46 between the coil windings 42 as the coil 40 is wound. The spacers 46 are removed after the coil 40 is encapsulated and the cooling ducts 58 are thus defined by the cavity created by the removed spacer 46.
  • the high voltage coil 40 depicted in Fig. 5 is formed in a manner similar to that of the low voltage coil 40 of Fig. 4, except that the coil winding 42 comprises a rectangular or round copper wire that is spiral or disk wound about the rectangular mandrel 60.
  • the coil 40 of the present invention is encapsulated in an epoxy resin layer 50 using a containment vessel 70 as depicted in Fig. 6.
  • the vessel 70 comprises a vessel shell 72 having first and second halves 72a. 72b. a vessel core 74, and a vessel bottom 76.
  • the vessel core 74 may also comprise first and second halves 74a. 74b. or, alternatively, the vessel core 74 may comprise the rectangular winding mandrel 60 upon which the generally rectangular coil 40 of the present invention is wound and formed.
  • Brackets 78 provided on the first and second vessel halves 72a. 72b may be used to hold the two halves together during the encapsulation process.
  • the encapsulation process will now be discussed in detail and with reference to Figs. 6. 7 and 8.
  • the wound coil 40 is placed in the containment vessel 70 which preferably extends beyond the top of the coil 40 by approximately 100 mm to allow for any shrinkage in the epoxy after curing.
  • the vessel 70 and coil 40 are then loaded into a vacuum chamber 80 that is connected to a vacuum source 82 and an epoxy source 84.
  • the chamber 80 is then evacuated by the vacuum source 82 to approximately 150 torr.
  • a low viscosity epoxy such as a bisphenol A epoxy resin of the type sold by Magnolia Co. as part number 1 1 1-047, A/B, is introduced into and completely fills the containment vessel 70.
  • the vacuum chamber 80 is further evacuated to approximately 20 torr.
  • the generally rectangular, resin encapsulated coil 40 may now be used together with a wound ferromagnetic metal core 20 having a generally rectangular cross-section and a generally rectangular core window 22.
  • the substantially straight section 52 of the coil 40 is located within the core window 22 and substantially matches the size and shape of the window 22.
  • the present invention provides a dry-type power distribution transformer having a wound ferromagnetic metal core having a generally rectangular cross- sectional shape and a generally rectangular resin encapsulated coil.
  • the encapsulation protects the coil against harsh environmental conditions, protects the insulation system of the coil, improves the coil strength under short-circuit conditions, and improves the coifs cooling characteristics by providing a smooth, uniform surface about the coil's exterior over which air (either forced or convective) may smoothly and easily pass.
  • the present invention provides a dry-type ferromagnetic metal power distribution transformer that is less expensive to manufacture, is less resistive and thus less lossy (less coil material is needed to wind the coil), and that is more compact than prior art transformers having generally round or circular coils.
  • the present invention thus provides a durable and robust dry-type power distribution transformer that uses the transformer materials in a more economical manner thereby reducing manufacturing costs and overall transformer size.

Abstract

A dry-type power distribution transformer (10) has a generally rectangular, wound ferromagnetic metal core (20) and a resin encapsulated, generally rectangular coil (40). The core has a generally rectangular core window (22) within which is located a substantially straight section of the coil. When assembled to form a power distribution transformer, the shape of the coil's substantially straight section conforms to the shape of the core window. The transformer is inexpensive to manufacture, exhibits low resistivity and low core loss, and is lightweight, compact and reliable in operation.

Description

DRY-TYPE TRANSFORMER HAVING A GENERALLY RECTANGULAR, RESIN ENCAPSULATED COIL
BACKGROUND OF THE INVENTION
1. Field Of The Invention
The present invention relates to transformers; and more particularly, to a dry- type power distribution transformer having a wound ferromagnetic metal core and a generally rectangular resin encapsulated coil.
2. Description Of The Prior Art
Conventional dry-type power distribution transformers have a round or toroidal open wound coil and a silicon steel or amorphous metal core of the wound or stacked variety. The transformer core typically has a rectangular shape defining a rectangular window within which the coil is located. Frequently, the toroidal shape of the coil creates a mismatch between the core and coil insofar as the core window is concerned, i.e. the shape of the rectangular window does not match the shape of the section of the coil that is located therein. This mismatch between the core and coil causes the size and cost of the transformer to be significantly larger than would be required if the transformer had more closely matched core and coil shapes.
Wound cores used in power distribution transformers, whether silicon steel or amorphous metal, are rectangular in cross-section and do not conform to the round shape of the coil. Stacked silicon steel transformer cores, on the other hand, may have a cruciform cross-section that can approximately match the coil's toroidal shape. Due to the high expense of casting or cutting an amorphous metal strip to a variety of widths, it is impractical to form a stacked amorphous metal core with a cruciform cross-section. For these reasons, in manufacture of dry-type power distribution transformers having ferromagnetic metal cores, whether wound or stacked, the cross-sectional shape of the core (i.e. rectangular) and the shape of the coil (i.e. round) do not match. Usage of coil material is uneconomical, and transformer sizes are too large.
Power distribution transformers may be installed in a variety of locations and subject to extreme environmental conditions such as. for example, particulate matter (dust. dirt. etc.). moisture, caustic substances, and the like, which adversely effect the life span and performance of the transformer. Open wound coils provide no protection against the effects of such the harsh environments.
SUMMARY OF THE INVENTION
The present invention provides a dry-type power distribution transformer having a wound ferromagnetic metal core and a generally rectangular, resin encapsulated coil. The core has a generally rectangular cross-sectional shape that closely matches the generally rectangular shape of the resin encapsulated coil. By matching the shape of the coil to that of the core's cross-section, there is provided a dry-type ferromagnetic metal power distribution transformer that is less expensive to manufacture, less resistive and less lossy, in that less coil material is needed to wind the coil, and more compact than transformers having generally round or circular coils. Generally stated, the dry-type dry- power distribution transformer includes a resin encapsulated generally rectangular coil having a substantially straight section and a ferromagnetic metal core, composed of amorphous metal or silicon steel, having a generally rectangular core window defined therein. The coil and the core are sized and shaped such that the shape of the substantially straight section of the coil substantially conforms to the shape of the core window. When the coil and core are assembled to form a power distribution transformer, the substantially straight section of said coil is located within the core window. The resin encapsulation protects the coil against harsh environmental conditions, protects the insulation system of the coil, improves the coil strength under short-circuit conditions, and improves the coil's cooling characteristics by providing a smooth, uniform surface about the coil's exterior over which air (either forced or convective) may smoothly and easily pass.
Advantageously, the dry-type power distribution transformer of the invention is durable and robust. Coil and core materials are utilized in a highly economical manner that significantly decrease manufacturing cost and transformer size. These features are especially desirable in power distribution transformers where size. cost, and performance govern market acceptance. BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be more fully understood and further advantages will become apparent when reference is had to the following detailed description and the accompanying drawings, wherein like reference numerals denote similar elements throughout the several views and in which:
Fig. 1A is a frontal view of a shell-type single phase transformer constructed in accordance with the present invention with the coil partially cut-away:
Fig. I B is a cross-sectional view taken along line B-B of Fig. 1 A:
Fig. 2A is a frontal view of a core-type single phase transformer constructed in accordance with the present invention;
Fig. 2B is a cross-sectional view taken along line B-B of Fig. 2A;
Fig. 3A is a frontal view of a three phase transformer constructed in accordance with the present invention;
Fig. 3B is a cross-sectional view taken along line B-B of Fig. 3A:
Fig. 4 is a perspective view of a generally rectangular, low voltage coil wound about a rectangular mandrel in accordance with the present invention;
Fig. 5 is a perspective view of a generally rectangular, high voltage coil wound about a rectangular mandrel in accordance with the present invention;
Fig. 6 is a perspective view of an epoxy containment vessel configured for encapsulating a generally rectangular coil in accordance with the present invention; Fig. 7 is a top view of the epoxy containment vessel of Fig. 6 with a generally rectangular coil contained therein: and
Fig. 8 is a block diagram of an encapsulation system for encapsulating a coil constructed in accordance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Referring to Figs. 1A and 2A of the drawings, there is shown two variations of a first embodiment of the present invention: a shell-type single phase power distribution transformer (Fig. 1A); and a core-type single phase power distribution transformer (Fig. 2A). Shell-type single phase transformer comprises a generally rectangular, resin encapsulated coil 40 and two ferromagnetic metal cores 20. Core- type single phase transformer 10 comprises two generally rectangular, resin encapsulated coils 40 and a single ferromagnetic metal core 20. A second embodiment of the invention is depicted in Fig. 3A. In that embodiment shell-type three-phase power distribution transformer 10 comprises three generally rectangular, resin encapsulated coils 40 and four ferromagnetic metal cores 20. While the following detailed description is directed to the shell-type single phase embodiment, it will be understood by those skilled in the art that such description is also applicable to the core-type single phase and to the shell-type three phase transformer embodiments depicted in Figs. 2A. 2B, 3A and 3B. Furthermore, it will be obvious to persons skilled in the art that the present invention and the detailed description thereof provided below applies to various other dry-type power distribution transformer configurations and designs. Thus, the description provided below for a shell-type single phase transformer is should be interpreted as illustrative and not in a limiting sense.
As noted above, the ferromagnetic metal of which core 20 is composed is formed either from silicon steel or an amorphous metal. As used herein, the term "amorphous metal" means a metallic alloy that substantially lacks any long range order and is characterized by X-ray diffraction intensity maxima which are qualitatively similar to those observed for liquids or inorganic oxide glasses. Amorphous metal alloys are well suited for use in forming cores 20. because they have the following combination of properties: (a) low hysteresis loss: (b) low eddy current loss; (c) low coercive force; (d) high magnetic permeability: (e) high saturation value; and (f) minimum change in permeability with temperature. Such alloys are at least about 50% amorphous, as determined by x-ray diffraction. Preferred amorphous metal alloys include those having the formula M60.90 T0.,5 Xl 0_25, wherein M is at least one of the elements iron, cobalt and nickel, T is at least one of the transition metal elements, and X is at least one of the metalloid elements of phosphorus, boron and carbon. Up to 80 percent of the carbon, phosphorus and/or boron in X may be replaced by aluminum, antimony, beryllium, germanium, indium, silicon and tin. Used as cores of magnetic devices, such amorphous metal alloys evidence generally superior properties as compared to the conventional polycrystalline metal alloys commonly utilized. Preferably, strips of such amorphous alloys are at least 80% amorphous, more preferably yet. at least 95% amorphous.
The amorphous alloys of cores 20 are preferably formed by cooling a melt at a rate of about 106 °C/sec. A variety of well-known techniques are available for fabricating rapidly-quenched continuous amorphous metal strip. When used in magnetic cores for amorphous metal transformers, the strip material of cores 20 typically has the form of a ribbon. This strip material is conveniently prepared by casting molten material directly onto a chill surface or into a quenching medium of some sort. Such processing techniques considerably reduce the cost of fabrication, since no intermediate wire-drawing or ribbon-forming procedures are required.
The amorphous metal alloys of which core 20 is preferably composed evidence high tensile strength, typically about 200,000 to 600,000 psi, depending on the particular composition. This is to be compared with polycrystalline alloys, which are used in the annealed condition and which usually range from about 40.000 to 80.000 psi. A high tensile strength is an important consideration in applications where high centrifugal forces are present, since higher strength alloys prolong the service life of the transformer.
In addition, the amorphous metal alloys used to form core 20 evidence a high electrical resistivity, ranging from about 160 to 180 microhm-cm at 25 °C. depending on the particular composition. Typical prior art materials have resistivities of about 45 to 160 microhm-cm. The high resistivity possessed by the amorphous metal alloys defined above is useful in AC applications for minimizing eddy current losses which, in turn, are a factor in reducing core loss. A further advantage of using amorphous metal alloys to form core 20 is that lower coercive forces are obtained than with prior art compositions of substantially the same metallic content, thereby permitting more iron, which is relatively inexpensive, to be utilized in the core 20, as compared with a greater proportion of nickel, which is more expensive. Each of the cores 20 is formed by winding successive turns onto a mandrel
(not shown), keeping the strip material under tension to effect a tight formation. The number of turns is chosen depending upon the desired size of each core 20. The thickness of the strip material of cores 20 is preferably in the range of 1 to 2 mils. Due to the relatively high tensile strength of the amorphous metal alloy preferred for use herein, strip material having a thickness of 1 -2 mils can be used without fear of breakage. It will be appreciated that keeping the strip material relatively thin increases the effective resistivity since there are many boundaries per unit of radial length which eddy currents must pass through.
With continued reference to Figs. 1A and I B, a shell-type single phase, dry- type power distribution transformer 10 includes a core/coil assembly 12 comprised of two ferromagnetic metal cores 20 and an encapsulated, generally rectangular coil 40. Transformer 10 also includes a bottom frame 30 and top frame 34, having bottom and top coil supports 32, 36, respectively, and within which the core/coil assembly 12 is supportedly mounted. Each core 20 is preferably wound from a plurality of ferromagnetic metal strips or layers 28 having a generally rectangular cross-sectional shape (see Fig. I B). Each core 20 has two long sides 24 and two short sides 26 that collectively define a generally rectangular core window 22 within which a substantially straight mid-section 52 of the generally rectangular coil 40 of the present invention is located. The aspect ratio, i.e. the relationship between the long and short sides 24, 26 of the core 20. is defined herein as the ratio of the window height ( i.e. long side 24) to window width (i.e. short side 26) and is preferably between approximately 3.5 to 1 and 4.5 to 1. This preferred core construction ώ minimizes the number of wound strips or layers 28 of ferromagnetic metal required to construct the core 20 which, in turn, yields lower temperature gradients in the coil 40. Layers of epoxy (not shown) are applied along the long sides 24 to support the height of the core 20. The initial epoxy layer is preferably generally compliant and penetrates between the ferromagnetic metal strips or layers 28 that comprise the core 20. Subsequent epoxy layers are generally more rigid so as to impart the desired strength to the long sides 24 of the core 20. Core 20 is preferably constructed from ferromagnetic metal ribbon having a nominal chemistry Fe80B, . Si9, which ribbon is sold by AlliedSignal Inc. under the trade designation METGLAS8 alloy SA- 1. The desired shape of the coil 40 of the present invention is generally rectangular. However, other geometric shapes are also considered within the scope of the present invention, provided, however, that such other geometric shapes include a substantially straight mid-section 52 that is sized and shaped to fit within the generally rectangular window 22 of the core 20. For example, the coil 40 may have rounded end sections 54 that are not located within the core window 22, and a generally straight mid-section 52 that passes through and is located within the core window, e.g. an oval with generally straight mid-sections.
As shown more clearly in Fig. I B, the generally rectangular coil 40 of the present invention comprises a plurality of coil windings 42 wound along with an insulating material 44 and with selectively placed cooling duct spacers 46 (see Figs. 4 and 5). The generally rectangular shape of the coil 40 is obtained by winding the coil components (e.g. windings 42 and insulation material 44) about a rectangular winding mandrel 60 (see Figs. 4 and 5), alternatingly winding coil windings 42 and insulating material 44 in a plurality of concentric layers. In a preferred embodiment. insulating material 44 comprises the inner- and outer-most layers of the wound coil 40 and further provides electrical insulation between adjacently wound coil windings 42. A substantially rectangular coil channel 56 is defined longitudinally through the coil 40 upon removal of the rectangular winding mandrel 60.
Since the coil winding material is typically supplied on a spool, the material may retain a bend radius after the coil 40 is wound, causing the coil 40 to bow or assume a generally oval shape due to the memory of the winding material. This disadvantageous^ increases the build dimension of the coil, especially in the mid-
7 section 52 which is preferably substantially straight, and may result in coils being too large to fit on the cores 20. It is thus necessary to ensure that coil windings 42 (and the coil 40) retains its generally rectangular shape after it is removed from the winding mandrel 60. One solution provided by the present invention involves using epoxy-dotted kraft paper as the insulating material 44 between the coil windings 42. The epoxy adheres to the coil windings 42 and, upon curing, imparts rigidity to the windings 42 that counteracts the bowing tendency of the winding material. Alternatively, a winding form 62 (see Figs. 4 and 5) may include metal corners 64 that form corners in the coil windings 42 and the coil 40 is wound on the mandrel 60. A third solution involves shaping the generally rectangular form of the coil 40 as the winding material is wound on the mandrel 60 such as. for example, using a wooden block and nylon hammer. Still another solution involves leaving the coil 40 on the winding mandrel 60 and pressing the long legs of the winding 40 between clamps after the coil 40 has been completely wound and prior to encapsulation. In addition to providing the generally rectangular form to the coil 40, this latter solution serves to further compress the long legs of the coil 40 thereby minimizing build-up among the windings 42 and insulating material 44 in the sections where build-up should be minimized, i.e. the substantially straight mid-sections 52.
To further minimize the size of the finished coil 40, the cooling duct spacers 46 are not placed (and the cooling ducts 58are not located) in the substantially straight mid-sections 52 of the coil. This provides a distinct advantage over round or toroidal coils that require circumferentially continuous cooling ducts. Thus, a circumferentially discontinuous cooling duct, which is defined by the selective placement of the spacers 46, is provided only in the end sections 54 of the substantially rectangular coil 40.
The insulating material 44 is interspersed between adjacent layers of coil windings 42 to provide electric isolation therebetween and forms the inner- and outer-most layers of the coil 40 (not considering the epoxy encapsulation described below). In a preferred embodiment, the insulating material 44 comprises a sheet or sheets of aramid paper such as Dupont's Nomex® brand. It will be obvious to those skilled in the art that various other insulating materials may be provided without departing from the spirit or intent of the present invention. The inner-most and outer-most sheets of insulating material 44 are preferably sized so as to extend approximately 12 mm beyond the longitudinal ends of the coil 40. In addition, the insulating material 44 located on each side of the cooling duct spacers 46 also extends approximately 12 mm past the ends of the coil 40. These sheets of extended insulation material 44 are sealed with a thick epoxy such as. for example, that made by Magnolia Co., part number 3126, A/B. The epoxied extended sheets of insulation material 44 then serve to contain any uncured epoxy during the encapsulation process (described in more detail below) of the coil 40.
Cooling for dry-type power distribution transformers may be either convective or forced-air. Cooling ducts 58 are thus necessary between the coil windings to permit the passage of air therethrough. The cooling duct spacers 46 may be inserted between coil windings 42 as the coil 40 is wound and are removed after the coil 40 has been encapsulated (as described in further detail below). Since it is desirable to control the wound dimensions of the coil 40 to ensure that it will fit within the core window 22 of the core 20, the cooling duct spacers 46 are advantageously inserted only in those sections of the coil 40 that will not be located within the core window 22 (i.e. at the longitudinally distal ends of the coil 40, as clearly shown in Fig. I B) in the assembled transformer 10. Thus the dimension of the coil 40 is controlled in the section that will be located within the core window 22 thereby providing smaller (i.e. narrower) coils 40 that, in turn, produce smaller power distribution transformers. The generally rectangular shape of the coil of the present invention permits the use of cooling ducts 58 that are non-continuous about the circumference of the rectangular coil. The desirability of selectively locating the cooling ducts 58 and of providing circumferentially non-continuous cooling ducts 58 is clear considering the fact that the cooling ducts 58 increase the size of the coil — which is undesirable especially in the substantially straight mid-section 52 of the coil 40. The generally rectangular shape of the coil 40 of the present invention provides four clearly delineated sides (which round or toroidal coils do not) which permit selective location of the cooling ducts 58 in the end sections 54 of the coil 40. For low voltage coils, such as those typically used as the secondary winding of a power distribution transformer, the coil winding 42 comprises a sheet or sheets of aluminum or copper (see Fig. 4). For high voltage coils, such as those typically used as the primary winding of a power distribution transformer, the coil winding 42 comprises a cross-sectionally rectangular or circular copper wire (see Fig. 5). For both low and high voltage coils, the coil 40 is wound on a rectangular mandrel 60. preferably in conjunction with a winding form 62 having metal corners 64 having a predefined angular configuration. The substantially rectangular coil 40 of the present invention may comprise only a low voltage or a high voltage coil or, alternatively, it may comprise both low and high voltage coils. The wound coil 40 is completely contained in and encapsulated by an epoxy resin layer 50. as described in more detail below. Referring to Figs. 4 and 5, there is shown a generally rectangular coil 40 configured in accordance with the present invention for low voltage and high voltage applications, respectively. The low voltage coil 40 shown in Fig. 4 is formed by winding a coil winding 42 such as, for example, a sheet of copper or aluminum, about a generally rectangular winding mandrel 60. To electrically isolate adjacent layers of windings 42, an insulating material 44 is interspersed therebetween. The insulating material 44 comprises the inner- and outer-most layers of the wound coil 40. Cooling ducts 58 are provided in the wound coil 40 by inserting cooling duct spacers 46 between the coil windings 42 as the coil 40 is wound. The spacers 46 are removed after the coil 40 is encapsulated and the cooling ducts 58 are thus defined by the cavity created by the removed spacer 46. The high voltage coil 40 depicted in Fig. 5 is formed in a manner similar to that of the low voltage coil 40 of Fig. 4, except that the coil winding 42 comprises a rectangular or round copper wire that is spiral or disk wound about the rectangular mandrel 60.
The coil 40 of the present invention is encapsulated in an epoxy resin layer 50 using a containment vessel 70 as depicted in Fig. 6. The vessel 70 comprises a vessel shell 72 having first and second halves 72a. 72b. a vessel core 74, and a vessel bottom 76. The vessel core 74 may also comprise first and second halves 74a. 74b. or, alternatively, the vessel core 74 may comprise the rectangular winding mandrel 60 upon which the generally rectangular coil 40 of the present invention is wound and formed. Brackets 78 provided on the first and second vessel halves 72a. 72b may be used to hold the two halves together during the encapsulation process. The encapsulation process will now be discussed in detail and with reference to Figs. 6. 7 and 8. The wound coil 40 is placed in the containment vessel 70 which preferably extends beyond the top of the coil 40 by approximately 100 mm to allow for any shrinkage in the epoxy after curing. The vessel 70 and coil 40 are then loaded into a vacuum chamber 80 that is connected to a vacuum source 82 and an epoxy source 84. The chamber 80 is then evacuated by the vacuum source 82 to approximately 150 torr. A low viscosity epoxy such as a bisphenol A epoxy resin of the type sold by Magnolia Co. as part number 1 1 1-047, A/B, is introduced into and completely fills the containment vessel 70. When the vessel 70 is filled to the top with epoxy, the vacuum chamber 80 is further evacuated to approximately 20 torr. Additional epoxy is fed into the containment vessel 70 if the epoxy level therein drops during the above-described pressure changes within the chamber 80. Once the containment vessel 70 is completely filled with epoxy and the epoxy level is stabilized within the vessel 70, the epoxy is cured to produce an epoxy resin layer 50 the completely surrounds and encapsulates the coil 40. After the epoxy has cured, the coil 40 is removed from the containment vessel 70 and the cooling duct spacers 46 are removed from the coil 40.
The generally rectangular, resin encapsulated coil 40 may now be used together with a wound ferromagnetic metal core 20 having a generally rectangular cross-section and a generally rectangular core window 22. The substantially straight section 52 of the coil 40 is located within the core window 22 and substantially matches the size and shape of the window 22.
Thus, the present invention provides a dry-type power distribution transformer having a wound ferromagnetic metal core having a generally rectangular cross- sectional shape and a generally rectangular resin encapsulated coil. The encapsulation protects the coil against harsh environmental conditions, protects the insulation system of the coil, improves the coil strength under short-circuit conditions, and improves the coifs cooling characteristics by providing a smooth, uniform surface about the coil's exterior over which air (either forced or convective) may smoothly and easily pass. In addition, by matching the shape of the coil to that of the core's cross-section, the present invention provides a dry-type ferromagnetic metal power distribution transformer that is less expensive to manufacture, is less resistive and thus less lossy (less coil material is needed to wind the coil), and that is more compact than prior art transformers having generally round or circular coils. The present invention thus provides a durable and robust dry-type power distribution transformer that uses the transformer materials in a more economical manner thereby reducing manufacturing costs and overall transformer size.
Having thus described the invention in rather full detail, it will be understood that such detail need not be strictly adhered to, but that various changes and modifications may suggest themselves to one skilled in the art, all falling within the scope of the invention, as defined by the subjoined claims.
Λ

Claims

What is claimed is:
1. A dry-type power distribution transformer comprising: a resin encapsulated generally rectangular coil having a substantially straight section; and a ferromagnetic metal core having a generally rectangular core window defined therein; said coil and said core being sized and shaped such that the shape of said substantially straight section of said coil substantially conforms to the shape of said core window, said substantially straight section of said coil being located within said core window when said coil and said core are assembled to form said power distribution transformer.
2. A dry-type power distribution transformer as recited in claim 1 , wherein said coil further comprises: a plurality of generally rectangular concentric layers comprising a conductive coil winding and an insulating material providing electric isolation between adjacent concentric layers of said coil; and a resin layer that encapsulates said coil.
3. A dry-type power distribution transformer as recited in claim 2, wherein said coil further comprises a plurality of cooling ducts defined between adjacent ones of said plurality of concentric layers, said cooling ducts being circumferentially non-continuous about said generally rectangular coil and being located in a part of said coil that does not comprise said substantially straight section.
4. A dry-type power distribution transformer as recited in claim 2. wherein said coil winding is constructed of a material selected from the group of materials consisting of aluminum and copper.
5. A dry-type power distribution transformer as recited in claim 2. wherein said resin layer comprises a low viscosity epoxy resin.
6. A dry-type power distribution transformer as recited in claim 5, wherein said low viscosity resin is a bisphenol A epoxy resin.
7. A dry-type power distribution transformer as recited in claim 1 , wherein said core is a wound core.
8. A dry-type power distribution transformer as recited in claim 1. wherein said core is made from an amorphous metal alloy having the formula M60.90 T0.,5 X 0.2$, wherein M is at least one of the elements iron, cobalt and nickel. T is at least one of the transition metal elements, and X is at least one of the metalloid elements phosphorus, boron and carbon, and wherein up to 80 percent of the carbon, phosphorus and boron content may be replaced by aluminum, antimony, beryllium, germanium, indium, silicon and tin.
9. A dry-type power distribution transformer as recited in claim 1 , wherein said core window defines an aspect ratio of greater than approximately 3.5 to 1.
10. A dry-type power distribution transformer as recited in claim 1. wherein said core window defines an aspect ratio of between approximately 3.5 to 1 and 4.5 to 1.
1 1. A dry-type power distribution transformer as recited in claim 1. wherein said coil is a low voltage coil.
12. A dry-type power distribution transformer as recited in claim 1. wherein said coil is a high voltage coil.
18. A dry-type power distribution transformer as recited in claim 17. wherein said low viscosity resin is a bisphenol A epoxy resin.
19. A dry-type power distribution transformer as recited in claim 14, wherein said core is a wound core.
20. A dry-type power distribution transformer as recited in claim 14, wherein said core is made from an amorphous metal alloy having the formula
MOO-90 To-,, X|o-25> wherein M is at least one of the elements iron, cobalt and nickel, T is at least one of the transition metal elements, and X is at least one of the metalloid elements phosphorus, boron and carbon, and wherein up to 80 percent of the carbon, phosphorus and boron content may be replaced by aluminum, antimony, beryllium, germanium, indium, silicon and tin.
21. A dry-type power distribution transformer as recited in claim 14, wherein said core window defines an aspect ratio of greater than approximately 3.5 to 1.
22. A dry-type power distribution transformer as recited in claim 14. wherein said core window defines an aspect ratio of between approximately 3.5 to 1 and 4.5 to 1.
23. A dry-type power distribution transformer as recited in claim 14. wherein said coil is a low voltage coil.
24. A dry-type power distribution transformer as recited in claim 14. wherein said coil is a high voltage coil.
25. A dry-type power distribution transformer as recited in claim 14. wherein said coil comprises a low voltage coil and a high voltage coil.
7 O 99/49481
13. A dry-type power distribution transformer as recited in claim 1. wherein said coil comprises a low voltage coil and a high voltage coil.
14. A dry-type power distribution transformer comprising: a resin encapsulated generally rectangular coil having a substantially straight section and being formed by alternatingly winding a conductive material and an insulating material on a rectangular winding form to form a plurality of generally rectangular concentric layers of insulating and conductive material and by thereafter forming an encapsulating resin layer that encapsulates said coil; and a generally rectangular ferromagnetic metal core having a generally rectangular core window defined therein; said coil and said core being sized and shaped such that the shape of said substantially straight section of said coil substantially conforms to the shape of said core window, said substantially straight section of said coil being located within said core window when said coil and said core are assembled to form said power distribution transformer.
15. A dry-type power distribution transformer as recited in claim 14, wherein said conductive material is selected from a group of materials consisting of aluminum and copper.
16. A dry-type power distribution transformer as recited in claim 14. wherein said coil further comprises a plurality of cooling ducts defined between adjacent ones of said plurality of concentric layers, said cooling ducts being circumferentially non-continuous about said generally rectangular coil and being located in a part of said coil that does not comprise said substantially straight section disposed within said core window when said coil.
17. A dry-type power distribution transformer as recited in claim 14. wherein said resin layer comprises a low viscosity epoxy resin.
26. A generally rectangular resin encapsulated coil having a substantially straight section, said coil comprising: a plurality of generally rectangular concentric layers comprising a conductive coil winding and an insulating material providing electric isolation between adjacent concentric layers of said coil; and a resin layer that encapsulates said coil.
27. A generally rectangular resin encapsulated coil as recited in claim 26, wherein said coil further comprises a plurality of cooling ducts defined between adjacent ones of said plurality of concentric layers, said cooling ducts being circumferentially non-continuous about said generally rectangular coil and being located in a part of said coil that does not comprise said substantially straight section.
28. A generally rectangular resin encapsulated coil as recited in claim 26, wherein said coil winding is selected from a group of materials consisting of aluminum and copper.
29. A generally rectangular resin encapsulated coil as recited in claim 26. wherein said resin layer comprises a low viscosity epoxy resin.
30. A generally rectangular resin encapsulated coil as recited in claim 29, wherein said low viscosity resin is a bisphenol A epoxy resin.
31. A generally rectangular resin encapsulated coil as recited in claim 26, wherein said coil is a low voltage coil.
32. A generally rectangular resin encapsulated coil as recited in claim 26, wherein said coil is a high voltage coil.
33. A generally rectangular resin encapsulated coil as recited in claim 26. wherein said coil comprises a low voltage coil and a high voltage coil.
/7 PAGE IS MISSING UPON FILING.
37. A method of making a dry-type power distribution transformer as recited in claim 36. wherein said predetermined pressure of said step (h) is approximately 150 torr.
38. A dry-type power distribution transformer as recited by claim 8. wherein said core is made from an amorphous metal alloy having the formula Fe80B| ,Si9.
39. A dry-type power distribution transformer as recited by claim 20. wherein said core is made from an amorphous metal alloy having the formula Fe80BMSi9.
<V
EP98913227A 1998-03-27 1998-03-27 Dry-type transformer having a generally rectangular, resin encapsulated coil Withdrawn EP1074028A1 (en)

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CN109215950B (en) * 2018-11-06 2021-03-12 江西北斗变电科技有限公司 Supporting structure for improving short-circuit resistance of transformer and implementation method
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CN1292925A (en) 2001-04-25
CA2326328A1 (en) 1999-09-30
KR100549558B1 (en) 2006-02-08
BR9815771A (en) 2004-04-13
AU6782998A (en) 1999-10-18
JP2002508585A (en) 2002-03-19
CN1241215C (en) 2006-02-08
WO1999049481A1 (en) 1999-09-30

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