Turbo generator with a rotor with direct gas cooling

Electrical generator or motor structure – Dynamoelectric – Rotary

Reexamination Certificate

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Details

C310S058000, C310S260000, C310S270000, C310S262000

Reexamination Certificate

active

06657330

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to the field of turbo generators for generating electrical energy, and more particularly to cooling turbo generators.
BACKGROUND OF THE INVENTION
In order to cool a rotor or remove its electrical heat losses in a generator, a (mostly gaseous) cooling medium flows through the rotor (see, for example, EP-A1-0 854 559). An important factor for good cooling is hereby the inflow geometry at the front faces of the rotor. A known inflow geometry is shown in
FIGS. 1A and 1B
, whereby
FIG. 1B
shows an unwound view of the rotor front face, and
FIG. 1A
the section through the (not unwound) rotor front face in the plane A—A of FIG.
1
B. The rotor
10
of a generator (
13
) comprises a central, cylindrical rotor body
18
, around which one or more rotor winding(s)
14
is/are provided on the outside. The rotor winding
14
passes through the rotor active part
11
in several conductor bundles parallel to the rotor axis and makes a turn-around of 180° in the rotor winding head
12
between two conductor bundles. The widening space is closed off on the front face by an annular cap plate
19
(
22
in
FIG. 2
of EP-A1-0 854 559). End spacer plates
16
with the shape of a ring segment are provided between the cap plate
19
and the rotor winding
14
. Cold cooling gas for cooling the rotor
10
flows into ring gap segments
33
.
34
between the cap plate
19
and the rotor body
18
. The ring gap segments
33
,
34
are bordered when seen in circumferential direction, on sides in each case by the section
16
′ of the end spacer plate
16
provided between the cap plate
19
and the rotor winding
14
, whereby this section
16
′ is projecting into the ring gap. The section of the end spacer plates
16
, whereby said section is projecting into the ring gap between the rotor winding
14
and rotor body
18
, forms a continuous dividing wall together with two each axial chamber walls
15
,
15
′, separating a cold gas chamber
25
and a warm gas chamber
32
with a gas inlet
21
and a gas outlet
22
(via corresponding ventilation grooves
20
) from each other. The end spacer plate
16
is hereby used as a holder for the chamber walls
15
,
15
′. In most cases, this results in an overhang
24
that reaches into the cold gas chamber
25
. In unfavorable cases, this overhang
24
even has an extension
23
.
The sharp-edged termination of the overhang
24
or its extension
23
towards the adjoining cold gas chamber
25
is responsible for a strong contraction associated with separations of the stream. These stream separations (eddies
27
) result in an uneven coolant supply to the rotor winding(s) (
14
) at the circumferential speed of the rotor
10
. The resulting speed w of the coolant stream relative to the rotor
10
is hereby created according to the velocity triangle
26
in
FIG. 1C
by the vectorial overlapping of the axial flow speed c and the circumferential speed u of the rotor
10
.
In order to avoid such separations, the initially mentioned EP-A 1-0 854 559 already suggested to provide a gas guide ring (GGR) in the form of a two-stage flow grate in the inlet area of the cold gas between the cap plate
19
and the rotor body
18
. The GGR principally solves the ventilation technology problem, but has several disadvantages: on the one hand, the additional installation of such a GGR is associated with significant expenditure. On the other hand, its function is threatened as soon as significant changes are made in the cooling gas stream (e.g., for a shorter generator or lower performance). Finally, the function of the GGR depends on the rotation direction, so that the desired effect does not exist when the rotation direction is reversed.
SUMMARY OF THE INVENTION
It is therefore the objective of the invention to design the rotor cooling of a generator of the initially mentioned type in such a way that the supply of the rotor with cooling gas is improved without major additional expenditure, and that, in particular, when the cooling gas enters the rotor, undesired eddies or eddy separations are substantially avoided in the cooling gas stream, and that the flow resistance is reduced.
The core of the invention consists of avoiding separations of the cooling gas stream when the latter flows into the ring gap segments by providing a design with favorable flow characteristics for the sections of the end spacer plates, whereby said sections are projecting into the ring gap.
A first preferred embodiment of the invention is characterized in that, when seen in circumferential direction, the side edges of the sections of the end spacer plates, whereby said sections are projecting into the cooling gas stream, are provided with either a bevel or bezel, or a curvature adapted to the flow with one or more curvature radii. The bevels or curvatures essentially prevent separations of the inflowing cooling gas in the edge area, and the flow resistance is reduced, thus improving the rotor cooling decisively under otherwise identical underlying conditions. In addition, essentially insignificant eddies are dissolved by the acceleration of the coolant between the curvature and the segment cross-section. It is hereby especially advantageous that the end spacer plates with the beveled or curved sections close off a warm gas chamber bordered on the sides by two axial, parallel chamber walls at the front, and the beveled or curved sections end flush with the chamber walls.
A second preferred embodiment of the invention is characterized in that in the flow direction, upstream from the sections of the end spacer plates, one each additional gas guidance element is provided that deflects the cooling gas stream around the section. Independently from the curvature of the edges of the sections, the flow around these sections can be further homogenized and improved by the upstream gas guidance segments, whereby the separate gas guidance segments permit additional design and optimization possibilities.
The suppression of separating eddies is yet improved further, when the gas guidance segment, according to a preferred further development, is provided upstream from the section, separated from it by a gap, and is provided with a convex curved outside that faces towards the cooling gas stream, and that the section of the end spacer plate and of the upstream gas guidance segment are designed so that cooling gas is pressed from the inlet side into the gap against the rotation direction of the rotor. The cooling gas flowing through the gap additionally prevents the formation of eddies when it flows out. In order to prevent interfering influences on the gap flow, it is hereby advantageous if the gas guide segment is constructed at its edge that is in the rear in the rotation direction of the rotor in such a way that the cooling gas stream flowing through the gap is added to the cooling gas stream flowing into the adjoining ring gap segment essentially without a transition.


REFERENCES:
patent: 2712085 (1955-06-01), Willyoung
patent: 2833944 (1958-05-01), Willyoung
patent: 4379975 (1983-04-01), Kitajima
patent: 4395816 (1983-08-01), Pangburn
patent: 4922147 (1990-05-01), Sismour, Jr. et al.
patent: 5483112 (1996-01-01), Biseli et al.
patent: 6097116 (2000-08-01), Hess et al.
patent: 6252318 (2001-06-01), Kazmierczak
patent: 6417586 (2002-07-01), Jarczynski et al.
patent: 34 08 986 (1985-09-01), None
patent: 88 11 379 (1988-12-01), None
patent: 3807277 (1989-09-01), None
patent: 694 08 797 (1998-10-01), None
patent: 199 05 540 (2000-08-01), None
patent: 0 849 859 (1998-06-01), None
patent: 0 854 559 (1998-07-01), None
patent: 1 091 468 (2001-04-01), None
Salamah et al., Jun. 27, 2002, U.S. patent application Publication US 2002.0079784 A1.

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