CA1140977A - Support structure for dynamoelectric machine stators spiral pancake winding - Google Patents
Support structure for dynamoelectric machine stators spiral pancake windingInfo
- Publication number
- CA1140977A CA1140977A CA000356779A CA356779A CA1140977A CA 1140977 A CA1140977 A CA 1140977A CA 000356779 A CA000356779 A CA 000356779A CA 356779 A CA356779 A CA 356779A CA 1140977 A CA1140977 A CA 1140977A
- Authority
- CA
- Canada
- Prior art keywords
- coil
- turns
- radially
- coils
- disposed
- 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.)
- Expired
Links
Classifications
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K3/00—Details of windings
- H02K3/04—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K3/00—Details of windings
- H02K3/46—Fastening of windings on the stator or rotor structure
- H02K3/47—Air-gap windings, i.e. iron-free windings
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K55/00—Dynamo-electric machines having windings operating at cryogenic temperatures
- H02K55/02—Dynamo-electric machines having windings operating at cryogenic temperatures of the synchronous type
- H02K55/04—Dynamo-electric machines having windings operating at cryogenic temperatures of the synchronous type with rotating field windings
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E40/00—Technologies for an efficient electrical power generation, transmission or distribution
- Y02E40/60—Superconducting electric elements or equipment; Power systems integrating superconducting elements or equipment
Abstract
48, 439 ABSTRACT OF THE DISCLOSURE
A support structure for unitizing coil turns into a single member and bracing each coil of a multi-coil stator dynamoelectric machine. Each stator coil includes several turns relatively concentrically disposed. Each coil turn constitutes two longitudinal conductor portions and two end turn conductor portions. One end turn portion serially connects two longitudinal portions and the re-maining end turn portion serially connects one of the longitudinal portions with a longitudinal portion of a concentrically adjacent coil. Each coil preferably lies in a plane defined by a portion of a cylinder and the coils are disposed in a cylindrical arrangement having a longitudinal axis therethrough such that one longitudinal portion of the outermost coil turn lies along the outer radial extent of the cylindrical arrangement and the remaining longitudinal portion of the outermost coil turn lies radially nearer the longitudinal axis of the cylin-drical arrangement. A rigid foundation member is situated in the plane of each coil within the concentrically inner-most turn. Turns of each coil are structurally connected either directly to the foundation member or indirectly to the foundation member by being intermediately joined to a turn already joined to the foundation member. The concen-tric turns of each coil are separated by a predetermined distance through the use of interposed spacer members situated at desired axial and circumferential locations.
Such coils present a spiral pancake appearance and are cooperatively disposed in the cylindrical arrangement 13 48,439 between radially inner and outer supporting structures.
Appropriately shaped wedges are disposed between selected coils and internal/external supporting members to account for the skewed or spiral manner in which each of the coils is arranged in the substantially cylindrical arrangement.
Radial tie rods extending between the radially internal and external support members structurally integrate those members so as to insure structural integrity of the cylin-drical arrangement. The radially external support member is preferably configured to extract load components from individual coil turns exposed at the cylindrical arrange-ment's outer periphery by either having radially inwardly directed struts extending between adjacent turns or having notches within which the radially outer conductor turns, when canted, are receivable.
A support structure for unitizing coil turns into a single member and bracing each coil of a multi-coil stator dynamoelectric machine. Each stator coil includes several turns relatively concentrically disposed. Each coil turn constitutes two longitudinal conductor portions and two end turn conductor portions. One end turn portion serially connects two longitudinal portions and the re-maining end turn portion serially connects one of the longitudinal portions with a longitudinal portion of a concentrically adjacent coil. Each coil preferably lies in a plane defined by a portion of a cylinder and the coils are disposed in a cylindrical arrangement having a longitudinal axis therethrough such that one longitudinal portion of the outermost coil turn lies along the outer radial extent of the cylindrical arrangement and the remaining longitudinal portion of the outermost coil turn lies radially nearer the longitudinal axis of the cylin-drical arrangement. A rigid foundation member is situated in the plane of each coil within the concentrically inner-most turn. Turns of each coil are structurally connected either directly to the foundation member or indirectly to the foundation member by being intermediately joined to a turn already joined to the foundation member. The concen-tric turns of each coil are separated by a predetermined distance through the use of interposed spacer members situated at desired axial and circumferential locations.
Such coils present a spiral pancake appearance and are cooperatively disposed in the cylindrical arrangement 13 48,439 between radially inner and outer supporting structures.
Appropriately shaped wedges are disposed between selected coils and internal/external supporting members to account for the skewed or spiral manner in which each of the coils is arranged in the substantially cylindrical arrangement.
Radial tie rods extending between the radially internal and external support members structurally integrate those members so as to insure structural integrity of the cylin-drical arrangement. The radially external support member is preferably configured to extract load components from individual coil turns exposed at the cylindrical arrange-ment's outer periphery by either having radially inwardly directed struts extending between adjacent turns or having notches within which the radially outer conductor turns, when canted, are receivable.
Description
~ 48~439 SUPPORT STRUCTURE FOR DYNAMOELECTRIC
MACHINE STATORS SPIRAL PANCAKE WINDING
BACKGROUND OF THE INVENTION
Field of the Inventi _ mis invention relates to support structures for dynamoelectric machine stator coils~ and more particular-ly, to support structures for spiral pancake stator coils.
Description of the Prior Art Air gap stator winding~ were developed andadapted for use in a varlety of dynamoelectric machines includlng generators having a superconductine field wlnd-ing~ Spiral pancake stator winding configurations utilizelndivldual colls which spiral outwardly from a radially lnner ~tator boundary to a radially outer stator boundary.
Such winding configuration has certaln advantages and is particularly effective in providing radial and tangential securement for each of the electrlcal coils. Such wind-ings are illustrated in Austrian Patent 329,670 having an effective date of May 25, 1976, and United States Patent 4,151,433, issued April 24, 1979 in the name of Mr. C. Flick and a~signed to the as~ignee of the present invention. In addition to the relative coil disposition in ~he spiral pancake stator winding the latter patent illu~trates a liqutd cooling ~cheme particularly adapted to .~uch spiral pancake wlnding.
Through a serles of wedges distributed ad~acent the colls and interposed between radially inner and outer structural members, the coils, as separate units, were effectively mechanically supported. Individual coil sides ,X
MACHINE STATORS SPIRAL PANCAKE WINDING
BACKGROUND OF THE INVENTION
Field of the Inventi _ mis invention relates to support structures for dynamoelectric machine stator coils~ and more particular-ly, to support structures for spiral pancake stator coils.
Description of the Prior Art Air gap stator winding~ were developed andadapted for use in a varlety of dynamoelectric machines includlng generators having a superconductine field wlnd-ing~ Spiral pancake stator winding configurations utilizelndivldual colls which spiral outwardly from a radially lnner ~tator boundary to a radially outer stator boundary.
Such winding configuration has certaln advantages and is particularly effective in providing radial and tangential securement for each of the electrlcal coils. Such wind-ings are illustrated in Austrian Patent 329,670 having an effective date of May 25, 1976, and United States Patent 4,151,433, issued April 24, 1979 in the name of Mr. C. Flick and a~signed to the as~ignee of the present invention. In addition to the relative coil disposition in ~he spiral pancake stator winding the latter patent illu~trates a liqutd cooling ~cheme particularly adapted to .~uch spiral pancake wlnding.
Through a serles of wedges distributed ad~acent the colls and interposed between radially inner and outer structural members, the coils, as separate units, were effectively mechanically supported. Individual coil sides ,X
2 48,439 or turns are serially connected and concentrically ar-ranged to form the coils. Such individual coil turns are sometimes subjected to continuous vibration in addition to high electromagnetic forces during fault condition opera-tion. Exposure of individual coils to such forces neces-sitate uniform support for each of the coils as a unit and for each of the coil turns individually. In section 3 of an article entitled "New Solutions For The Design Of Large Turbo Generators Up To 2GVA, 60KV" by Aichholzer, Eingelangt, 9-25-74, the following was included: ..... "the naturally occurring space in the center of each concentric pancake coil can be partially filled with ferromagnetic material, which leads to a reduction of the effective gap and thus to reduced excitation requirements." As stated, the ferromagnetic material was disposed in the center of each pancake coil in an unspecified manner so as to reduce excitation requirements. Forming the coils of a stator winding into a monolithic structure by injecting impreg-nating and bonding resins thereamong has also been sug-gested for stiffening the coils and supporting individualconductor turns. While such resins may, under appropriate circumstances, effectively brace the individual coil turns, monolithic structures subjected to extended service in dynamoelectric machines having high mechanical and electromagnetic force levels have not proven highly suc-cessful.
SUMMARY OF THE INVENTION
In accordance with the present invention an improved dynamoelectric machine is provided in which individual turns of each coil in a stator winding are structurally integrated with other coil turns of the same coil to effectively resist local displacement and vibra-tion thereof induced by mechanical and electromagnetic forces. The invention generally comprises a frame and a stator structure supported in the frame with the stator structure including a plurality of electrical coils each of which has a plurality of concentric turns, foundation means situated within the concentrically innermost turn of 1~4~)~77
SUMMARY OF THE INVENTION
In accordance with the present invention an improved dynamoelectric machine is provided in which individual turns of each coil in a stator winding are structurally integrated with other coil turns of the same coil to effectively resist local displacement and vibra-tion thereof induced by mechanical and electromagnetic forces. The invention generally comprises a frame and a stator structure supported in the frame with the stator structure including a plurality of electrical coils each of which has a plurality of concentric turns, foundation means situated within the concentrically innermost turn of 1~4~)~77
3 48,439 each coil for structurally supporting the turns, and means for structurally connecting the electrical conductor turns of each coil with the supporting foundation means of each coil. Each coil lies in a plane which generally spirals outwardl~ about a longitudinal axis extending through the stator structure. The foundation means of each coil preferably comprises a support member lying in a Ccur~
plane corresponding to the spiral shape of the associated coil. The structural connecting means preferably includes a series of bands in engagement with the conductor turns and the support member. An additional series of bands preferably engage two conductor turns on circumferentially opposite sides of the turns. Means are provided for maintaining a predetermined separation between adjacent turns of the same coil. In a preferred embodiment of the present invention support means are provided for structur-ally integrating radially internal and external support means relative to the interposed stator coils. Means are also provided for extracting from each coil turn a com-ponent of load transmitted through the coil.
BR~EF ~ESCRIPTION THE DRAWINGS
The in~ention will be more fully understood fromthe following detailed description of a preferred embodi-ment, taken in connection with the accompanying drawings, in which:
Figure l is a transverse sectional view of an exemplary turbine generator;
Figure 2 is an axial sectional view of the turbine generator of Figure l;
Figure 3 is a perspective view of the relative disposition of coils in the turbine generator's stator;
Figure 4 is a perspective view of a coil illus-trated in Figure 3 and a support scheme for integrating individual coil turns into a rigid coil structure;
Figure 5 illustrates a portion of Figure 2 and includes means for radially integrating support structures associated with the stator coils; and Figures 6 and 7 each illustrate a portion of the
plane corresponding to the spiral shape of the associated coil. The structural connecting means preferably includes a series of bands in engagement with the conductor turns and the support member. An additional series of bands preferably engage two conductor turns on circumferentially opposite sides of the turns. Means are provided for maintaining a predetermined separation between adjacent turns of the same coil. In a preferred embodiment of the present invention support means are provided for structur-ally integrating radially internal and external support means relative to the interposed stator coils. Means are also provided for extracting from each coil turn a com-ponent of load transmitted through the coil.
BR~EF ~ESCRIPTION THE DRAWINGS
The in~ention will be more fully understood fromthe following detailed description of a preferred embodi-ment, taken in connection with the accompanying drawings, in which:
Figure l is a transverse sectional view of an exemplary turbine generator;
Figure 2 is an axial sectional view of the turbine generator of Figure l;
Figure 3 is a perspective view of the relative disposition of coils in the turbine generator's stator;
Figure 4 is a perspective view of a coil illus-trated in Figure 3 and a support scheme for integrating individual coil turns into a rigid coil structure;
Figure 5 illustrates a portion of Figure 2 and includes means for radially integrating support structures associated with the stator coils; and Figures 6 and 7 each illustrate a portion of the
4 48,439 stator illustrated in Figure 2 and exemplify means for transmitting load from individual coil turns to the radi-ally integrating support structures.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The present invention is concerned primarily with structurally integrating individual coil turns of each stator coil in a dynamoelectric machine so as to reduce internal stresses and local displacements induced by mechanical vibration and electromagnetic forces.
Accordingly, in the description which follows, the inven-tion is shown embodied as a large tubine generator.
Figure 1 illustrates turbine generator 10 which includes rotor 12 which is rotatable about longitudinal axis 14, stator structure 16) and frame structure 18.
Stator structure 16 is disposed about rotor 12 and is structurally connected to frame structure 18 through radially projecting ribs 20. Stator structure 16 consti-tutes stator winding 22, flux shield 24, and internal support tubes 26 and 28. Although two internal support tubes are illustrated, it is to be understood that any nualber may be used will equal facility with the present invention.
Coolant is translnitted from inlet manifold 30 through switable conduits 32 and into water connection headers 34 which are in fluid communication with internal cooling passages disposed within stator winding 22. The coolant headers 34 and their relative disposition within stator structure 16 are best illustrated in Figu-re 2.
An expanded axial end view of Figure l's stator structure 16 is illustrated in Figure 2 and is substan-tially cylindrical in shape. Radially internal support tubes 26 and 2~ preferably ~nstitwte glass fiber rein-forced epoxy such as Micarta and define a radially inner boundary for stator winding 22. F:Lux shield 2~ generally includes a plurality of thin plates or laminae which are approximately l/50th of an inch in thickness and by exam-ple constitute magnetic material such as silicon iron.
Flux shield 24 functions both as a radially external ~4C~
.
48,439 support means for stator winding 22 and flux constraint for channeling magnetic flux emanating from a field wind-ing back to the field winding disposed, in the case of the illustrated generator, on rotor 12. Stator winding 22 in-A5 cludes a plurality (~ in this case) of coils 36 which - spiral radially outwardly from the support tubes 26 and 28 to protective members 38 which preferably constitute laminated glass fiber reinforced epoxy. Laminate protect-ive members 38 are disposed radially between coils 36 and flux shield 24 and are secured in position by longitudin-ally tapered wedges 40. Protective members 38, which constitute a portion of the radially external support means, are interposed between coils 36 and flux shield 24 to protectively buffer the coils and to prevent coil damage by the flux shield laminations 24 during insertion and assembly of the coils 36 within the flux shield 24.
Each stator coil 36 has a spiral pancake~,con-figuration and comprises a plurality (illustrated as ~) of concentrically disposed, serially connected coil turns 42 which constitute interconnected longitudinal and end turn portions. Since the number of coil turns 42 is primarily related to the voltage in the coils, it is to be under-stood that any number of coil turns could be used (instead of the illustrated five) with the present invention.
Stator winding 22 and its included stator coils 36 are better illustrated in Figure 3 which provides an exploded perspective view thereof. The concentrically innermost turn 42 bounds an opening or coil window 44. Rigid found-ation means is disposed in each coil window 44 to provide an anchoring structural support for the conductor turns of each coil 36. Such foundation means preferably constitute glass fiber reinforced epoxy impregnated laminated mate-rial that may be pressed and cured to the proper contour to conform to the basic spiral geometry of the coils 36.
Figure 2 illustrates sol~d foundation means or strongback 46, but ladder structure strongback 46', as illustrated in Figure 4, is an acceptable substitute therefor. Design constraints such as the magnitude of the electromagnetic 6 48,439 forces experienced by the coils may dictate the percentage of open area 48 of strongback 46'. Strongbacks 46 and 46' lie in curved planes and have thicknesses perpendicular to the curved planes not greater than the thickness of coil turns 42 which lie coplanar therewith.
As shown in Figure 4, structural connecting means such as bands 50 structurally connect coil turns 42 with strongback 46' at desired axial and circumferential locations. Bands 50 preferably protrude through openings 52 formed in strongback 46' and extend to the circumferen-tially and axially remote sides (relative to strongback 46') of the longitudinal and end turn portions respective-ly of the individual coil turns 42. A second set of structural connecting bands 50' are disposed so as to structurally connect relatively inner and outer concentric coil turns 42. Such structural connection of concentric coil turns 42 to one another is sometimes necessary to avoid connection interference pro'blems such as spacial constraints where 'bands 50 are joined to strongback ~6'.
'Ln other words, if each coil turn 42 were directly struc-turally connected to strongback 46' then connecting bands 50 may be of swch substantial number as to interfere with each other at their connection with strongback 46'.
Additionally, if the illustrated connecting techniqwe (openings 52) with strong'back 46' were utilized, strong-back 46' could weaken and lose the rigidity necessary to structurally support the individual coil turns 42.
Separating means such as conforma'ble spacer blocks 53 are disposed between adjacent coil turns ~2 at desired axial and circumferential locations 'between longi-t-wdinal and end twrn portions, respectively, to maintain predetermined spacial relationships there'between. Spacer blocks 53, when wsed in com'bination with bands 50 and 50', enable effective securement and structural integrat:ion of the coil turns 42 into a single coil wnit which is highly resistant to vibration and can be readily supported as an entirety. Spacer blocks 53 also prevent rubbing between adjacent coil turns 42 and so avoid damage resulting 9~7 7 48,439 therefrom.
Figure 5 is a cut away axial view of a portion of stator 16. Radial structural integration means such as rods 54 interconnect the radially internal and external support means for stator winding 22 so as to provide additional rigidity and augment the mechanical strength of the internal support -tubes 26 and 28. Radially disposed rods 54 extend radially across the illustrated coil window 44. Strongback 46 and 461 have been removed from Figure 5 to provide greater clarity, but it is to be understood that such radial support rods 54 could protrude through openings in those strongbacks.
Figures 6 and 7 illustrate 60 segments of stator structure 16 and show alternative means for trans-mitting circumferential load components from coil turns 42disposed radially adjacent laminate protective members 38.
The scheme of Figure 6 for transmitting load components from individual coil turns 42 includes a plurality of struts 56 which protrude substantially radially inwardly from the protective members 38 and pass between adjacent coil twrns ~2 such that circumferential forces exerted by and transmitted through coils 36 are transferred piecemeal thro-ugh struts 56 to protective members 38 so as to avoid force accumulation and possible deformation of individual coil turns ~2. The scheme of Figure 7 for transmitting load from individual coil twrns 42 to protective members 38 includes notches 58 formed in the radially inner sur-face of protective members 38 for receiving canted or angularly displaced coil turns ~2 therein. As can be seen, coil turns 42 which are radially separated from protective members 38 are not canted so as to minimize the radial size of stator structure 16~
It will now be apparent that an improved dynamo-electric machine stator strwcture has been provided in which spiral pancake coils are securely swpported and the individual coil turns thereof are structurally integrated to form a coil structure of substantial rigidity. Various configurations utilizing structurally integrated coils are 7~7 8 48,439 also provided for preventing circumferential force accumu-lation and possible coil turn deformation by individually transmitting load from the various coil turns. As such, a stiffer stator winding having high resistance to vibration and electromagnetic displacement obtains.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The present invention is concerned primarily with structurally integrating individual coil turns of each stator coil in a dynamoelectric machine so as to reduce internal stresses and local displacements induced by mechanical vibration and electromagnetic forces.
Accordingly, in the description which follows, the inven-tion is shown embodied as a large tubine generator.
Figure 1 illustrates turbine generator 10 which includes rotor 12 which is rotatable about longitudinal axis 14, stator structure 16) and frame structure 18.
Stator structure 16 is disposed about rotor 12 and is structurally connected to frame structure 18 through radially projecting ribs 20. Stator structure 16 consti-tutes stator winding 22, flux shield 24, and internal support tubes 26 and 28. Although two internal support tubes are illustrated, it is to be understood that any nualber may be used will equal facility with the present invention.
Coolant is translnitted from inlet manifold 30 through switable conduits 32 and into water connection headers 34 which are in fluid communication with internal cooling passages disposed within stator winding 22. The coolant headers 34 and their relative disposition within stator structure 16 are best illustrated in Figu-re 2.
An expanded axial end view of Figure l's stator structure 16 is illustrated in Figure 2 and is substan-tially cylindrical in shape. Radially internal support tubes 26 and 2~ preferably ~nstitwte glass fiber rein-forced epoxy such as Micarta and define a radially inner boundary for stator winding 22. F:Lux shield 2~ generally includes a plurality of thin plates or laminae which are approximately l/50th of an inch in thickness and by exam-ple constitute magnetic material such as silicon iron.
Flux shield 24 functions both as a radially external ~4C~
.
48,439 support means for stator winding 22 and flux constraint for channeling magnetic flux emanating from a field wind-ing back to the field winding disposed, in the case of the illustrated generator, on rotor 12. Stator winding 22 in-A5 cludes a plurality (~ in this case) of coils 36 which - spiral radially outwardly from the support tubes 26 and 28 to protective members 38 which preferably constitute laminated glass fiber reinforced epoxy. Laminate protect-ive members 38 are disposed radially between coils 36 and flux shield 24 and are secured in position by longitudin-ally tapered wedges 40. Protective members 38, which constitute a portion of the radially external support means, are interposed between coils 36 and flux shield 24 to protectively buffer the coils and to prevent coil damage by the flux shield laminations 24 during insertion and assembly of the coils 36 within the flux shield 24.
Each stator coil 36 has a spiral pancake~,con-figuration and comprises a plurality (illustrated as ~) of concentrically disposed, serially connected coil turns 42 which constitute interconnected longitudinal and end turn portions. Since the number of coil turns 42 is primarily related to the voltage in the coils, it is to be under-stood that any number of coil turns could be used (instead of the illustrated five) with the present invention.
Stator winding 22 and its included stator coils 36 are better illustrated in Figure 3 which provides an exploded perspective view thereof. The concentrically innermost turn 42 bounds an opening or coil window 44. Rigid found-ation means is disposed in each coil window 44 to provide an anchoring structural support for the conductor turns of each coil 36. Such foundation means preferably constitute glass fiber reinforced epoxy impregnated laminated mate-rial that may be pressed and cured to the proper contour to conform to the basic spiral geometry of the coils 36.
Figure 2 illustrates sol~d foundation means or strongback 46, but ladder structure strongback 46', as illustrated in Figure 4, is an acceptable substitute therefor. Design constraints such as the magnitude of the electromagnetic 6 48,439 forces experienced by the coils may dictate the percentage of open area 48 of strongback 46'. Strongbacks 46 and 46' lie in curved planes and have thicknesses perpendicular to the curved planes not greater than the thickness of coil turns 42 which lie coplanar therewith.
As shown in Figure 4, structural connecting means such as bands 50 structurally connect coil turns 42 with strongback 46' at desired axial and circumferential locations. Bands 50 preferably protrude through openings 52 formed in strongback 46' and extend to the circumferen-tially and axially remote sides (relative to strongback 46') of the longitudinal and end turn portions respective-ly of the individual coil turns 42. A second set of structural connecting bands 50' are disposed so as to structurally connect relatively inner and outer concentric coil turns 42. Such structural connection of concentric coil turns 42 to one another is sometimes necessary to avoid connection interference pro'blems such as spacial constraints where 'bands 50 are joined to strongback ~6'.
'Ln other words, if each coil turn 42 were directly struc-turally connected to strongback 46' then connecting bands 50 may be of swch substantial number as to interfere with each other at their connection with strongback 46'.
Additionally, if the illustrated connecting techniqwe (openings 52) with strong'back 46' were utilized, strong-back 46' could weaken and lose the rigidity necessary to structurally support the individual coil turns 42.
Separating means such as conforma'ble spacer blocks 53 are disposed between adjacent coil turns ~2 at desired axial and circumferential locations 'between longi-t-wdinal and end twrn portions, respectively, to maintain predetermined spacial relationships there'between. Spacer blocks 53, when wsed in com'bination with bands 50 and 50', enable effective securement and structural integrat:ion of the coil turns 42 into a single coil wnit which is highly resistant to vibration and can be readily supported as an entirety. Spacer blocks 53 also prevent rubbing between adjacent coil turns 42 and so avoid damage resulting 9~7 7 48,439 therefrom.
Figure 5 is a cut away axial view of a portion of stator 16. Radial structural integration means such as rods 54 interconnect the radially internal and external support means for stator winding 22 so as to provide additional rigidity and augment the mechanical strength of the internal support -tubes 26 and 28. Radially disposed rods 54 extend radially across the illustrated coil window 44. Strongback 46 and 461 have been removed from Figure 5 to provide greater clarity, but it is to be understood that such radial support rods 54 could protrude through openings in those strongbacks.
Figures 6 and 7 illustrate 60 segments of stator structure 16 and show alternative means for trans-mitting circumferential load components from coil turns 42disposed radially adjacent laminate protective members 38.
The scheme of Figure 6 for transmitting load components from individual coil turns 42 includes a plurality of struts 56 which protrude substantially radially inwardly from the protective members 38 and pass between adjacent coil twrns ~2 such that circumferential forces exerted by and transmitted through coils 36 are transferred piecemeal thro-ugh struts 56 to protective members 38 so as to avoid force accumulation and possible deformation of individual coil turns ~2. The scheme of Figure 7 for transmitting load from individual coil twrns 42 to protective members 38 includes notches 58 formed in the radially inner sur-face of protective members 38 for receiving canted or angularly displaced coil turns ~2 therein. As can be seen, coil turns 42 which are radially separated from protective members 38 are not canted so as to minimize the radial size of stator structure 16~
It will now be apparent that an improved dynamo-electric machine stator strwcture has been provided in which spiral pancake coils are securely swpported and the individual coil turns thereof are structurally integrated to form a coil structure of substantial rigidity. Various configurations utilizing structurally integrated coils are 7~7 8 48,439 also provided for preventing circumferential force accumu-lation and possible coil turn deformation by individually transmitting load from the various coil turns. As such, a stiffer stator winding having high resistance to vibration and electromagnetic displacement obtains.
Claims (7)
1. A dynamoelectric machine comprising:
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means, disposed within the concentrically innermost turn of each coil, for structurally supporting the turns of each coil, and comprising a support member lying in a curved plane which cor-responds to the spiral shape of the asso-ciated coil, said member's plane thickness perpendicular to said spiral being less than or equal to said associated coil's conductor's thickness perpendicular to said spiral, and means for structurally connecting said turns of each coil with said suppor-ting foundation means of each coil inclu-ding a first plurality of bands protruding through said support member and in engage-ment with said turns, said engagement being 48,439 on said turn's remote side relative to said support member, said bands being disposed at selected axial and circum-ferential locations.
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means, disposed within the concentrically innermost turn of each coil, for structurally supporting the turns of each coil, and comprising a support member lying in a curved plane which cor-responds to the spiral shape of the asso-ciated coil, said member's plane thickness perpendicular to said spiral being less than or equal to said associated coil's conductor's thickness perpendicular to said spiral, and means for structurally connecting said turns of each coil with said suppor-ting foundation means of each coil inclu-ding a first plurality of bands protruding through said support member and in engage-ment with said turns, said engagement being 48,439 on said turn's remote side relative to said support member, said bands being disposed at selected axial and circum-ferential locations.
2. A dynamoelectric machine in claim 1 further comprising:
means for maintaining separation spaces between said turns of each coil.
means for maintaining separation spaces between said turns of each coil.
3. me dynamoelectric machine in claim 2, said conductor turn separation means comprising:
a plurality of blocks disposed between adjacent turns at selected axial and circumferential locations.
a plurality of blocks disposed between adjacent turns at selected axial and circumferential locations.
4. The dynamoelectric machine in claim 1, said structural connecting means further comprising:
a second plurality of bands wherein each band provides securing engagement for two turns, said engage-ment being on opposite sides of said engaged turns.
a second plurality of bands wherein each band provides securing engagement for two turns, said engage-ment being on opposite sides of said engaged turns.
5. A dynamoelectric machine comprising:
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means disposed within the concentrically innermost turn of each coil for structurally supporting the turns of each coil, means for structurally connecting said turns of each coil with said supporting foundation means of each coil, means disposed radially inside said electrical coils for radially internally supporting said plurality of coils; and 11 48,439 means disposed radially outside said electrical coils for radially externally supporting said plurality of coils comp-rising a plurality of struts supported by said radially external support means, said struts protruding substantially ra-dially inwardly between adjacent turns for extracting load components from indi-vidual turns.
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means disposed within the concentrically innermost turn of each coil for structurally supporting the turns of each coil, means for structurally connecting said turns of each coil with said supporting foundation means of each coil, means disposed radially inside said electrical coils for radially internally supporting said plurality of coils; and 11 48,439 means disposed radially outside said electrical coils for radially externally supporting said plurality of coils comp-rising a plurality of struts supported by said radially external support means, said struts protruding substantially ra-dially inwardly between adjacent turns for extracting load components from indi-vidual turns.
6. The dynamoelectric machine in claim 5 further comprising:
intermediate support means for structurally integrating said radially internal and external support means, said integrating support means being radially disposed between said internal and external support means.
intermediate support means for structurally integrating said radially internal and external support means, said integrating support means being radially disposed between said internal and external support means.
7. A dynamoelectric machine comprising:
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means disposed within the concentrically innermost turn of each coil for structurally supporting the turns of each coil, means for structurally connecting said turns of each coil with said supporting foundation means of each coil, means disposed radially inside said electrical coils for radially internally supporting said plurality of coils; and means disposed radially outside said electrical coils for radially externally 11a 48,439 supporting said plurality of coils compri-sing wherein coil turns radially adjacent said external support means are canted so as to be receivable in notches on said radially adjacent external support means.
a frame structure; and a substantially cylindrical stator structure having a longitudinal axis, said stator structure being supported by said frame, said stator structure comprising a plurality of electrical coils, each of which comprise an electrical conductor formed in a plurality of concentric turns which are serially electrically connected, said turns in each coil spiraling outwardly about the longitudinal axis, rigid foundation means disposed within the concentrically innermost turn of each coil for structurally supporting the turns of each coil, means for structurally connecting said turns of each coil with said supporting foundation means of each coil, means disposed radially inside said electrical coils for radially internally supporting said plurality of coils; and means disposed radially outside said electrical coils for radially externally 11a 48,439 supporting said plurality of coils compri-sing wherein coil turns radially adjacent said external support means are canted so as to be receivable in notches on said radially adjacent external support means.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US06/066,732 US4292558A (en) | 1979-08-15 | 1979-08-15 | Support structure for dynamoelectric machine stators spiral pancake winding |
US066,732 | 1993-05-27 |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1140977A true CA1140977A (en) | 1983-02-08 |
Family
ID=22071334
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000356779A Expired CA1140977A (en) | 1979-08-15 | 1980-07-23 | Support structure for dynamoelectric machine stators spiral pancake winding |
Country Status (7)
Country | Link |
---|---|
US (1) | US4292558A (en) |
JP (1) | JPS5631345A (en) |
CA (1) | CA1140977A (en) |
CH (1) | CH658345A5 (en) |
DE (1) | DE3028777A1 (en) |
GB (1) | GB2058480B (en) |
SE (1) | SE8005709L (en) |
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US4164672A (en) * | 1977-08-18 | 1979-08-14 | Electric Power Research Institute, Inc. | Cooling and insulating system for extra high voltage electrical machine with a spiral winding |
DE2737959C3 (en) * | 1977-08-23 | 1985-04-04 | Kraftwerk Union Ag, 4330 Muelheim | Arrangement for tensioning an air gap winding in the stator of an electrical machine |
-
1979
- 1979-08-15 US US06/066,732 patent/US4292558A/en not_active Expired - Lifetime
-
1980
- 1980-07-23 CA CA000356779A patent/CA1140977A/en not_active Expired
- 1980-07-29 DE DE19803028777 patent/DE3028777A1/en not_active Ceased
- 1980-08-07 CH CH6002/80A patent/CH658345A5/en not_active IP Right Cessation
- 1980-08-12 GB GB8026297A patent/GB2058480B/en not_active Expired
- 1980-08-13 SE SE8005709A patent/SE8005709L/en not_active Application Discontinuation
- 1980-08-14 JP JP11116880A patent/JPS5631345A/en active Pending
Also Published As
Publication number | Publication date |
---|---|
US4292558A (en) | 1981-09-29 |
JPS5631345A (en) | 1981-03-30 |
SE8005709L (en) | 1981-02-16 |
CH658345A5 (en) | 1986-10-31 |
GB2058480A (en) | 1981-04-08 |
GB2058480B (en) | 1983-12-07 |
DE3028777A1 (en) | 1981-03-26 |
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