Title of Invention

"STATOR AND O METHOD FOR HABRI CALING THE SCENE"

Abstract A stator (126) includes projecting portions (132) extending from an outer edge (154) of a plurality of stator laminations (148). The projecting portions (132) form a point (158). When the stator is inserted into a motor housing (102), the projecting portions scrape along an inner surface of the housing (102). The contact between the projecting portions and the housing (102) achieves a bond between the stator (126) and the housing (102).
Full Text STATOR BONDING NIB BACKGROUND OF THE INVENTION
This invention relates generally to dynamo electric machines and, more particularly, to a bonding nib extending from a stator of a dynamo electric machine.
Dynamo electric machines such as an electric motor or generator typically include a housing, a stator, and a rotor assembly. The housing includes a shell having a protective coating and two end shields, and houses at least a portion of the rotor assembly. The stator typically includes a core of magnetic material having an axially extending bore for receiving the rotor assembly. The rotor assembly includes a rotor core and a rotor shaft extending through the core. The rotor assembly extends through the stator opening and the two end shields.
The stator core typically is formed from a plurality of identical laminations coated with an insulating material, aligned, and arranged in a stack held together by clips or an interlock tab. Each lamination includes a plurality of teeth extending radially into the bore. Slots between each of the teeth extend radially outwardly from the bore. The ends of the teeth and the open ends of the slots define the periphery of the bore.
A plurality of coils formed from insulated conductive wire are inserted into selected core slots with portions of the coils at the ends of the core forming end turn regions. The coils are interconnected to form coil groups or poles. The conductive wires which form the coils, are sometimes referred to as stator windings. As an example, a single speed motor typically includes coil groups which establish at least one main winding and an auxiliary or start winding.

The stator is typically interference press fit into the shell of the housing in an attempt to achieve a bond between the stator and the housing shell. Proper bonding between the stator and the housing shell provides adequate grounding of the stator with the housing shell to prevent the stator from arcing. However, as shell coatings and processes have improved to achieve desired corrosion resistance, achieving bond between the coated stator and the coated shell has become more problematic.
Accordingly, it would be desirable to provide a stator that adequately bonds to the housing shell and is durable enough to withstand being interference fit within the shell. In addition, it would be desirable for the stator to be cost effective and to be easy to fabricate.
BRIEF SUMMARY OF THE INVENTION
These and other objects may be attained by a stator that includes projecting portions extending from an outer edge of a plurality of stator laminations. The stator laminations include an outer diameter and the projecting portions form a tip that extends beyond the outer diameter. The stator laminations are stacked to form a stator core and include a coating of an insulating material that protects the stator from water damage.
The stator is inserted into a motor housing shell that includes an inner surface having a protective coating. The projecting portions scrape along the inner surface of the housing shell when the stator is inserted in the shell. The contact between the projecting portions and the shell removes the coating from the projecting portions and removes the coating from a portion of the housing shell. The contact achieves a bond between the stator and the housing reducing the probability of arcing occurring between the stator and the housing.
The projecting portion contacts the housing shell and grounds the stator to the housing. The grounding of the stator to the housing reduces the occurrence of arcing. The laminations are fabricated from known stamping methods with modified dies. The dies are modified to include notches that correspond to the projecting portions.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a schematic view of an electric motor;
Figure 2 is a schematic view of a stator lamination including a projecting portion; and
Figure 3 is a schematic view of portion A of the stator lamination shown in Figure 2.
DETAILED DESCRIPTION OF THE INVENTION
Figure 1 is a schematic view of an exemplary motor 100 including a housing 102 having a shell 104 with two ends 106,108. Although the present stator laminations are described herein in the context of an electric motor, it should be understood that the present invention is not limited to practice with any one particular motor. The present invention can be utilized in connection with other dynamo electric machines.
Shell 104 includes a protective coating that reduces the probability of shell 104 corroding. In one embodiment, the protective coating is a paint that covers substantially the entire surface of shell 104. An exemplary paint is a mixture of #CR-648 Powercron Resin and #CP-583 Powercron Paste available from PPG Industries, P.O. Box 127, Springdale, Pennsylvania 15144. A first end shield 110 is connected to end 106 and a second end shield is connected to end 108. End shields 110, 112 include supports 114, 116 for bearing assemblies 118, 120. A rotor shaft S is coaxially aligned with bearing
assemblies 118, 120 and extends through openings 122, 124 formed in end shields 110,112.
Motor 100 also includes a stator 126 having a stator core 128 and stator windings 130. Stator windings 130 include a start winding and at least one main winding. The main winding is wound to form a number of poles. The start winding is wound to form a number of poles equal to the number of poles of the main winding. Stator core 128 is formed from a plurality of stacked stator laminations (not shown). In one embodiment, the laminations are held together by an interlock tab (not shown) that is cut from each lamination and pressed into a slot on an adjacent lamination. Other forms of holding the laminations together include clips that attach to the stack or a strip that is welded to the outer edge of the laminations. The stator laminations include at least one projecting portion 132, e.g., a nib, extending radially outwardly as will be described below in greater detail. Stator core 128 includes an inner surface 134 and an outer surface 136. Inner surface 134 forms a rotor bore 138. Rotor shaft S is concentrically arranged with stator core 128, and a rotor core RC is positioned concentrically with rotor shaft S.
A switching unit 140, shown in phantom, is mounted to end shield 112. Switching unit 140 includes, in one form, a movable mechanical arm 142. A centrifugal force responsive assembly 144, also shown in phantom, is mounted to rotor shaft S and includes a push collar 146 which engages mechanical arm 142. Push collar 146 is sltdably mounted on rotor shaft S. Assembly 144 also includes a weighted arm and spring (not shown in detail) secured to rotor shaft S. The weighted arm is calibrated to move from a first position to a second position when the rotor speed exceeds a predetermined speed. When the weighted arm moves to the second position, push collar 146 also moves from a first position to a second position. As a result, mechanical arm 142 of switching unit 140 moves form a first position to a second position,
which causes switching unit 140 to switch from a first circuit-making position to a second circuit-making position. Switching unit 140 is utilized separately in some applications (without arm 142) and switching unit 140 and assembly 144 are utilized in combination in other applications. Alternatively, the switching unit can be a capacitor (not shown) as well known in the art.
In operation, and at motor start-up, the stator start winding and the main winding are energized. The magnetic fields generated by such windings induce currents in conductors C of motor rotor R, and the magnetic fields of such windings and conductors C couple and rotor R begins to rotate. Once rotor R has sufficient speed, the start winding is de-energized. When the rotor speed equals the synchronous speed, the magnetic fields of rotor permanent magnets M couple with, and "lock" into, the magnetic fields generated by the main winding. Rotor R then rotates at substantially the synchronous speed.
Figures 2 and 3 are schematic views of a stator lamination 148 including projecting portion 132. Stator lamination 148 also includes a top surface 150, a bottom surface (not shown), an inner edge 152, an outer edge 154, and a center 156. Stator lamination 148 is coated with a protective insulating coating. In one embodiment, the protective coating improves moisture resistance. An exemplary insulating coating is a varnish such as varnish # 413C123 available from Valspar Corporation, 202 West Jacobs Avenue, Fort Wayne, Indiana 46808.
Projecting portion 132 extends from outer edge 154 and forms at least one point 158. Stator lamination 148 includes an outer diameter 160 sized to fit within a motor housing shell (not shown) having an inner diameter (not shown). In one embodiment, stator lamination 148 is substantially circular and includes at least one flattened area 162. Of course, lamination 148 could be substantially circular without having a flattened area, or it could be square
with rounded corners. In addition, lamination 148 could have other shapes.
Projecting portion 132 may extend from either flattened area 162, or it may
extend from a rounded area of outer edge 154. Further, outer diameter 160 is
smaller than the inner diameter of the housing shell and point 158 projects
substantially radially away from center 156 of stator lamination 148 extending
beyond outer diameter 160. When stator laminations 148 are inserted
into the housing shell, projecting portion 132 contacts the inner surface of the housing shell. This contact removes the stator lamination coating as well as the housing shell coating at the contact points and provides a metal to metal contact. The removal of the coatings from the housing shell and stator laminations 148 enables stator lamination 148 to achieve an adequate bond with the housing shell and reduces the possibility of arcing between stator lamination 148 and the housing shell.
In operation, stator laminations 148 are stacked and held together to form a stator core (not shown). Outer edges 154 align to form a substantially continuous outer surface (not shown) of the stack. The outer surface includes a plurality of projecting portions that extend radially outwardly. Inner edges 152 include a plurality of slots 164 extending radially outwardly from center 156. Inner edges align to form a bore (not shown) extending through the stator core. The bore includes a plurality of axial slots (not shown) extending radially outwardly. A plurality of coils formed from insulated conductive wire is inserted into the slots. A portion of the coils form end turn regions. A protective coating is applied to the stator core and windings to provide moisture protection to the core and windings and also to hold the coils in place.
With respect to the manufacture and assembly of the stator (not shown), laminations 148 are stamped from steel with a die (not shown). The die includes notches that form projecting portions 132. As is well known,
each lamination may be annealed or otherwise treated so that a coating is formed thereon. Laminations 148 are then stacked to a desired height to form the stator core (not shown). Stator laminations 148 are stacked so that slots 164 are axially aligned to form a plurality of slots that extend radially outwardly. A plurality of coils formed from insulated conductive wire is inserted into the slots in the stack of stator laminations 148. A protective coating is applied to the stator core and windings. In one embodiment, the protective coating provides moisture protection to the core and windings and also holds the coils in place.
The stator is inserted in the motor housing so that projecting portions 132 contact an inner surface of the housing. In one embodiment, the stator is interference press fit into the housing. The contact removes the protective coating on both the projecting portion and on at least a portion of the housing. In one embodiment, the contact cuts through the paint on the housing inner surface and scrapes off the varnish on the point of the projecting portion. After the coatings are removed, the housing and projection portion 132 are in metal to metal contact.
The stator core includes projecting portions that extend beyond an outer diameter of the stator laminations and provide a bond between the stator and the housing shell. The bond grounds the stator to the housing shell and prevents arcing by the stator. The stator laminations are cost effective to manufacture since they can be fabricated by known methods with a modified die.
From the preceding description of various embodiments of the present invention, it is evident that the objects of the invention are attained. Although the invention has been described and illustrated in detail, it is to be clearly understood that the same is intended by way of illustration and example only
and is not to be taken by way of limitation. Accordingly, the spirit and scope of the invention are to be limited only by the terms of the appended claims.


CLAIMS:
1. A stator 126 for mounting within a motor housing102, said
stator comprising:
at least one stator lamination 148 including a bore, an inner edge 152, and an outer edge 154, said outer edge having an outer diameter 160, said stator including at least one projecting portion 132 that extends beyond said outer diameter.
2. A stator 126 in accordance with Claim 1 wherein said at least
one stator lamination 148 comprises a plurality of stacked stator laminations,
said outer edges 154 align to form a substantially continuous surface, said
inner edges!52 align to form a bore and a plurality of slots 164 that extend
radially outwardly from said bore, wherein said outer edge comprises at least
one flattened area 162.
3. A stator 126 in accordance with Claim 1 wherein said projecting
portion 132 forms a point 158 that extends beyond said outer diameter 160,
said projecting portion is a nib.
4. A stator 126 in accordance with Claim 2 further comprising a
plurality of coils formed from insulated conductive wire inserted into said
slots 164, said coils forming end rum regions.
5. A stator 126 in accordance with Claim 2 wherein said plurality
of stacked laminations 148 includes a protective coating that is removed from
at least a portion of the projecting portion 132 when said stator is inserted into
the housing 102.
6. A stator 126 in accordance with Claim 1 wherein the housing
102 includes a coating, said projecting portion 132 configured to remove the

coating from at least a portion of the housing when said stator is inserted into the housing.
7. A stator 126 configured to be inserted within a motor housing
102, said stator comprising:
a plurality of stacked laminations 148, said laminations including an inner edge 152 having a plurality of slots 164 and an outer edge 154 including at least one projection 132 for contacting the motor housing.
8. A stator 126 in accordance with Claim 7 further comprising:
a bore, wherein said inner edges 152 align to form said bore; and
a plurality of coils formed from insulated conductive wire inserted into said slots 164.
9. A stator 126 in accordance with Claim 7 wherein said projecting
portion 132 is a nib including a point 158 configured to contact the motor
housing 102.
10. A stator 126 in accordance with Claim 7 wherein said stator
includes a protective coating configured to be removed from at least a portion
of the nib 132 when said stator is inserted into the housing 102, and wherein
the housing includes a coating, said nib configured to remove the coating
from at least a portion of the housing when said stator is inserted into the
housing.
11. A stator 126 in accordance with Claim 7 wherein said stator
laminations 148 are substantially circular.
12. A stator 126 in accordance with Claim 7 wherein said stator
laminations 148 are substantially square with rounded corners.
13. An electric motor 100 comprising:
a motor housing 102 comprising a shell 104 with first and second ends 106, 108, a first end shield 110 mounted to said first shell end, and a second end shield 112 mounted to said second shell end, said first and second end shields comprising bearing supports 114, 116 having bearings 118, 120 therein;
a stator 126 positioned within said shell, said stator including a plurality of stacked laminations 148 comprising an inner edge 152, an outer edge 154, and an outer diameter 160, said outer edge including a projecting portion 132 extending radially beyond said outer diameter and forming a point 158, said stacked laminations forming a stator core 128 including an inner surface 134 forming a bore 138 extending through said stator core and an outer surface; and
a rotor assembly including a rotor shaft S, said rotor assembly positioned within said stator bore, said rotor shaft extending through said end shields and rotatably supported by said bearings.
14. A motor 100 in accordance with Claim 13 wherein said stator
126 includes a means for holding together said plurality of stacked
laminations 148 so that said lamination inner edges 152 align to form said
bore 138 extending through said stator core 128.
15. A motor 100 in accordance with Claim 13 wherein said outer
edgel54 comprises at least one flattened area 162 and said projecting portion
132 is a nib, said housing shell 104 including an inner diameter, said stator
lamination outer diameter 160 smaller than said housing shell inner diameter, said point 158 of said nib extending radially beyond said outer diameter.
16. A motor 100 in accordance with Claim 13 wherein said stator
core inner surface 134 comprises a plurality of slots 164 that extend toward
said outer surface 136, said stator further comprising a plurality of wire coils
inserted into said slots and forming end turn regions.
17. A motor 100 in accordance with Claim 13 wherein said plurality
of stator laminations 148 include a first coating to improve moisture
resistance, wherein said first coating is removed from at least a portion of said
projecting portion 132 when said stator 126 is inserted into said housing shell
102, said housing shell includes an inner surface 134 having a second coating,
said second coating removed from at least a portion of said housing shell
when said stator is inserted into said housing shell.
18. A method of assembling a stator 126 into a motor housing 102,
the stator including a plurality of stacked laminations 148 that include an
inner edge 152, an outer edge 154, and an outer diameter 160, the outer edge
includes a projecting portion 132 that forms a point 158 extending beyond the
outer diameter, said method including the steps of:
applying a first protective material to a surface of the stator laminations;
applying a second protective material to a surface of the motor housing; and
inserting the stator into the motor housing.
19. A method in accordance with Claim 18 wherein said step of
inserting the stator 126 further comphses the step of pressing the stator into
the housing 102 and contacting a housing inner surface with the projecting portion 132.
20. A method in accordance with Claim 19 wherein said step of contacting the housing inner surface comprises the steps of:
removing the protective material from a portion of the housing; and
removing the protective material from the projecting portion 132 to provide metal to metal contact between the stator and the housing.
21. A stator for mounting within a motor housing substantially as herein
described with reference to and as illustrated by the accompanying
drawings.
22. An electric motor substantially as herein described with reference to
and as illustrated by the accompanying drawings.
23. A method of assembling a stator into a motor housing substantially as
herein described with reference to and as illustrated by the
accompanying drawings.

Documents:

IN-PCT-2000-00026-DEL-Abstract.pdf

IN-PCT-2000-00026-DEL-Claims.pdf

IN-PCT-2000-00026-DEL-Correspondence-Others.pdf

IN-PCT-2000-00026-DEL-Correspondence-PO.pdf

IN-PCT-2000-00026-DEL-Description (Complete).pdf

IN-PCT-2000-00026-DEL-Drawings.pdf

IN-PCT-2000-00026-DEL-Form-1.pdf

IN-PCT-2000-00026-DEL-Form-19.pdf

IN-PCT-2000-00026-DEL-Form-2.pdf

IN-PCT-2000-00026-DEL-Form-3.pdf

IN-PCT-2000-00026-DEL-Form-5.pdf

IN-PCT-2000-00026-DEL-GPA.pdf

IN-PCT-2000-00026-DEL-PCT-101.pdf

in-pct-2000-00026-del-pct-210.pdf

in-pct-2000-00026-del-pct-304.pdf

IN-PCT-2000-00026-DEL-Petition-137.pdf

in-pct-2000-00026-del-petition-138.pdf


Patent Number 233160
Indian Patent Application Number IN/PCT/2000/00026/DEL
PG Journal Number 13/2009
Publication Date 27-Mar-2009
Grant Date 27-Mar-2009
Date of Filing 24-Apr-2000
Name of Patentee GENERAL ELECTRIC COMPANY
Applicant Address ONE RIVER ROAD, SCHENECTADY, NEW YORK 12345, U.S.A.
Inventors:
# Inventor's Name Inventor's Address
1 CAMPBELL ELZA LEE 265 PERSIMMON ROAD, OZARK, MISSOURI, 65721, U.S.A.
2 CAREY TIMOTHY WILBUR 12313 BAY HEIGHTS BOULEVARD, GRABILL, INDIANA 46741, U.S.A.
3 DILLS JAMES CHARLES 3240 SOUTH ROANOKE, SPRINGFEILD, MISSOURI 65807, U.S.A.
PCT International Classification Number H02K 1/18
PCT International Application Number PCT/US99/20813
PCT International Filing date 1999-09-09
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 09/151,005 1998-09-10 U.S.A.