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| United States Patent | 4402129 |
| Link to this page | http://www.wikipatents.com/4402129.html |
| Inventor(s) | Kreuzer; Helmut (Schwieberdingen, DE);
Frister; Manfred (Schwieberdingen, DE) |
| Abstract | The stator of a three phase AC generator is wound automatically. A first
set of partial windings consitutes the first winding. Each of the partial
windings has at least one turn. The first partial winding is wound in
slots 1 and 4 in the clockwise direction, the second in slots 7 and 4 in
the counterclockwise direction, etc. Before the second partial winding of
the first set is wound, the first partial windings of the second and third
phase are wound in slots 2 and 5 and 3 and 6, respectively. Similarly,
after the counterclockwise winding in slots 4 and 7, the second partial
windings of the second and third phase are wound in the counterclockwise
direction in slots 8 and 5 and 9 and 6, respectively. This procedure is
repeated until all slots are filled. If the same winding profile is to be
maintained throughout, the part of the first partial windings associated
with the first, second and third phase to be inserted in slots 1, 2, 3,
respectively, is left out of the slots until the last partial winding of
the phases has been wound. The loose ends of the first partial windings
are then pushed into the respective slots. After the partial windings are
connected to each other to form the first, second and third main windings,
the winding starts and the winding ends of these main windings are
connected together to form the desired electrical configuration. In this
connection, the start and end of the second winding are electrically
interchanged, to create the required 120.degree. phase difference between
all the windings. |
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Title Information  |
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Drawing from US Patent 4402129 |
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Method for winding the stator of a three phase generator |
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| Publication Date |
September 6, 1983 |
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| Filing Date |
March 4, 1981 |
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| Priority Data |
Mar 04, 1980[DE]3008212 |
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Title Information |
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References |
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U.S. References |
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Other References |
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Other References |
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References |
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Public's "Guesstimation" of Royalty Value
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Market Review |
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Technical Review |
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Claims |
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We claim:
1. Method for winding a first, second and third (40,41,42) winding,
respectively, associated with the first, second and third phase of a
three-phase a-c generator on a stator having a plurality of slots,
comprising the steps of
winding a first partial winding (43) of a first phase, forming part of said
first winding (40), in a first direction (clockwise) in a first and fourth
slot (1, 4) of the stator, leaving empty second and third intervening
slots (2, 3);
then winding a first partial winding (44) of a second phase and forming
part of the second winding (41) in the first direction in the second and a
fifth slot (2, 5);
then winding a first partial winding (45) of a third phase and forming part
of the third winding (42) in the first direction in the third slot (3) and
a sixth slot (6);
then continuing to wind the first winding (40) by winding, in opposite
direction (counterclockwise), and starting from the seventh slot back to
the fourth slot, the second partial winding (46) of said first winding
(40);
then continuing, in like manner, winding the second partial windings of
each of the second and third windings (41, 42) in said opposite direction,
backwardly, from respectively the eighth and ninth slots to the fifth and
sixth slots;
and connecting the winding starts and winding ends of said first, second
and third windings to each other to form a prdetermined three-phase
configuration.
2. Method according to claim 1, wherein said step of connecting said
winding starts and ends of said first, second and third windings comprises
connecting the winding end (Z) of said second winding (41) to the winding
starts (X, Y) of said first and third windings (40, 42).
3. Method according to claim 1, wherein each of the last partial windings
of the respective first, second and third windings is placed underneath
one of said first partial windings of the first, second and third
windings.
4. Method according to claim 1, wherein each of said first partial windings
includes a first and second leg, to be inserted, respectively, into a
first, lower-numbered and a second, higher-numbered slot;
and wherein the first leg is pushed into the first, lower-numbered slot
only after winding of the last partial winding has been completed to
provide for overlap of said first leg of the first partial winding over
the last-wound last partial winding. |
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Claims |
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Description |
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CROSS-REFERENCE TO RELATED APLICATIONS AND PUBLICATIONS
U.S. application Ser. No. 937,913 filed Aug. 30, 1978, now U.S. Pat. No.
4,351,102, Grozinger, assigned to the assignee of this application.
The present invention relates to a winding method for the stator of a three
phase AC generator and, more particularly, to automatic winding of such a
stator.
BACKGROUND OF THE INVENTION
The space available in the slots of a stator of a three phase AC generator
is more highly utilized than in either a wave or a lap winding when a
winding method disclosed in the referenced U.S. Pat. No. 4,351,102,
Grozinger, is used. An even better space utilization factor can be
achieved by manual winding of wires in the slots of two layers.
THE INVENTION
It is an object to provide an automatic winding method achieving a higher
space utilization factor than any of the well known automatic methods. It
is a particular objective of the present invention to achieve this optimum
space utilization factor while using relatively small partial windings.
In accordance with the present invention, each of the phase windings, e.g.,
the first, second and third winding for the first, second and third phase
of the AC generator comprise, respectively, a first, second and third
plurality of partial windings. The first partial winding of the first
phase is wound in clockwise direction and consists of one loop, two empty
slots being left between the slots filled by the loop. The next partial
winding of the first phase is wound in counterclockwise direction from the
seventh back to the fourth slot.
In accordance with a feature of the invention, the first partial windings
of the second and third phase are wound in clockwise direction in slots 2
and 5, and 3 and 6, respectively, before the second partial winding of the
first phase is wound. After the winding of the second partial winding of
the first phase in counterclockwise direction, the second partial winding
of the second and third phases are wound in like manner in
counterclockwise direction in slots 8 and 5, and 9 and 6, respectively.
This winding method is continued until the second partial winding of each
phase has been wound. The winding starts and the winding ends of each of
the main windings constituted by all of the associated partial windings
are then connected together so that the desired electrical configuration
such as, for example, a star connection is formed, as is well known.
DRAWINGS DESCRIBING A PREFERRED EMBODIMENT
FIG. 1 is a schematic diagram illustrating the winding method of the
present invention;
FIG. 2 shows the winding profile, i.e., the position of the partial
windings in the slot in which the phase winding for phase 1 is shown
blank; the phase winding for phase 2 is shown stipped; and the phase
winding for phase 3 is shown lined;
FIG. 3 illustrates the electrical configuration of the AC generator; and
FIG. 4 illustrates the position of the partial windings in the slot in the
prior art arrangement.
DESCRIPTION OF THE PREFERRED EMBODIMENT
In the winding scheme shown in FIG. 1, a twelve pole AC stator having
thirty-six slots is assumed. This results in twelve partial windings per
phase. For the sake of simplicity, only slots 1-14 and slots 33-36 are
shown. Further, in order to simplify the presentation, only one winding 40
of one phase is shown, in clear in FIG. 2 in its entirety. The other two
windings, 41 and 42, stippled and lined in FIG. 2 which are associated
with the two remaining phases are illustrated by broken lines indicating
their start and their end only. The winding process proceeds as follows:
It is started with first winding 40. A first partial winding 43 is wound
into slots 1 and 4 in clockwise direction. Thereafter, the first partial
windings 44 and 45 of the two windings 41 and 42, respectively, are wound
into slots 2 and 5, and 3 and 6, respectively. Thereafter, the second
partial winding 46 of winding 40 is wound into slots 4 and 7 in that
order, i.e. in the counterclockwise direction. The corresponding partial
windings of windings 41 and 42 are then correspondingly wound. This
process continues, that is, for each winding, partial windings are
alternately wound in the clockwise and counterclockwise direction, the
three corresponding partial windings associated with the three phases
being wound one after the other. For simplifying the illustration, each
partial winding is shown with only one turn. The number of turns, of
course, is arbitrary and depends upon the electrical as well as the space
requirements. The above-described winding method results in the
arrangement of the partial windings shown in FIG. 2, that is, these
partial windings lie next to each other at a slant, overlapping, so that a
very good space utilization factor results.
The winding starts of windings 40-42 are denoted by U,Z and V,
respectively, the respective ends being denoted by X,W,Y. The individual
windings are then connected in a well known manner, for example in the
star connection shown in FIG. 3. It is customary to connect the winding
ends X,Y,Z to the common point of the star. By electrically interchanging
the winding end and winding start of the second winding, namely winding 41
which starts in slot 2, an electrical angle of 120.degree. is created
among all three windings. The center point of the star thus consists of
the winding start of the second and the winding ends of the third and
first windings.
The same overlapping shingled winding profile can be maintained throughout
in this manner. Specifically, at the start of the winding process, the
first partial windings 43-45 are only inserted into slots 4 and 6. The
opposite sides of these partial windings are at first left outside of
slots 1-3. After the winding of the last partial windings 76-78 (FIGS.
1,2) has been completed, the free sides of partial windings 43-45,
previously left out of the slots, are pushed into the slots above the
partial windings 76-78, in a anner well known for winding multi-layer
windings. The winding profile will then be the same throughout. If a small
variation in the profile can be tolerated, then the winding method can be
simplified somewhat by inserting only one side of winding 43 or of
windings 43 and 44.
FIG. 4 illustrates the winding arrangement resulting from a known winding
method. It is clear that the space utilization factor is poor. A generator
wound by the conventional method would thus require a greater volume for
the same power output.
Various changes and modifications may be made within the scope of the
inventive concepts.
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Description |
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