SU884037A1 - Electric machine rotor - Google Patents

Description

one

The invention relates to electrical engineering, in particular to direct-cooled turbogenerators: winding of the rotor with gas.

A rotor of an electric machine with direct gas cooling of an excitation winding, for example for a turbo generator, comprising an excitation winding equipped with internal radial channels for the passage of gas is known. The radial channels are connected with the subphase channels, and the gas is supplied to the winding channels from the sub-channel channels.

The disadvantage of this design is that the cooling intensity significantly depends on the full length of the rotor, so this design is used for low and medium power bipolar turbogenerators and for four-pole turbogenerators, in which

relatively larger section than bipolar; turbine generators.

Closest to the invention is the rotor of an electric machine, e.g. a turbo-generator, comprising a core, an excitation winding placed in the grooves of the cores, with gas passageways arranged in two rows along the groove width and inclined to the rotor axis in opposite directions one row in relation to the channels of the other row and in pairs communicating with each other in the lower zone of the winding coil, the slot wedges holding the winding and have "5 input and output openings oriented in opposite directions and communicating with winding channels and sub-slot insulation tsiyuf2J. ,

20

Claims (2)

; The negative voltage of this structure is the dependence of the temperature of the incoming cooling gas in the rotor winding on the gas temperature in the gap between the rotor and the stator, which is higher than the cold gas temperature. Moreover, this temperature increases with increasing use of turbine generators and, accordingly, with increasing power. In addition, the length of the cooled section in the field winding with such a rotor design is approximately two times longer than in a rotor with sub-channel channels. The purpose of the invention is to increase the intensity of cooling of the rotor excitation winding. The purpose is achieved by the fact that in the known rotor of the electric machine the core is made with sub-phase channels communicating with a part of the inclined winding channels through the holes made in the sub-insulation, and the number of inclined channels n communicating with sub-channel channels, is selected from a ratio of 1 to 75-TU5ts where t1 is the area of the sub-channel channel; 5ts - the area of the inclined channel. Inclined winding channels communicating with the sub-channel channels can be placed at the ends of the rotor core or arranged alternately along the length of the rotor core with the other inclined channels. FIG. 1 schematically shows a longitudinal section of the proposed rotor in FIG. 2 is a view of C in FIG. one; in FIG. a cross-section A-A in Fig. 1; in fig. 4 is a cross-sectional view BB of FIG. one; in fig. 5 schematically shows a longitudinal section of the rotor of another variant of the proposed design of the rotor; in fig. 6 is a cross-sectional view BB in FIG. 5. In the core of the rotor 1 (Fig. 1), grooves were inserted into which are laid on the hank 2 of excitation. Under the slots of the name (with the podpazovy channels 3, profiled from the ends of the rotor core B to the excitation winding 2 for passage of gas, inclined toward the sleeves 4 and 5 are arranged, located two rows along the width of the groove and inclined to the rotor axis in opposite directions in the same row (solid line) in relation to channels in another row (dotted line). Inclined channels 4, having opposite inclinations, communicate in pairs at the bottom of the groove in pairs, inclined channels 5, having opposite inclinations, communicate in pairs at the bottom of the groove between themselves and with podpazovy channels. With The tracks indicate the direction of gas supply to the winding channels from the air gap and from the sub-channel channels The location of the holes in the copper of the excitation winding is shown in Fig. 2. In the slots above the winding there are a wedge 6 (Fig. 3 and 4), under which the subclinic insulation 7 is located In the wedges and in the under-wedge insulation, there are holes that communicate with the respective inclined channels. The inclined channels 4 are connected at the bottom of the groove between each other. The wedges located in the zone of these channels have 8 inlet ports and 9 outlet openings oriented along and against the direction of rotation of the rotor. The inclined channels 5 communicate with the sub-channel channel 3 through a hole in the insulation 10 at the bottom of the groove. The wedges located in the zone of these channels have only outlet openings 9 oriented against the direction of rotation of the rotor. The gas supply zones into the winding from the gap into the channels 4, communicating in the zone of the lower turn of the winding, and the gas supply zones into the channels 5 through the sub-channel channels 3 can alternate with each other along the rotor length (Fig. 5). In this case, the podzapovye channels are cut-out across the entire length of the rotor barrel. The width and alternation of zones, as well as the number of inclined channels in the zones, are determined by the required intensity of the cooling of the excitation winding. The inclined channels connected to the sub-channel channels are separated from them by a sub-insulator (Fig. B). ; When the rotor rotates, gas captured from the gap under the action of the ventilating head of the rotating rotor by the inlet holes 8 passes through the channels 4 and is ejected back into the gap through the outlet holes 9. Another part of the gas is fed from the end of the rotor core to the sub-channel channels 3 and through the holes in the isolator 10 enters the channels 5, then 5 through the outlet of the hole 9 is ejected into the gap between the rotor and the valve. The most favorable from the point of view of heating the number of inclined channels connected to the sub-channel channel is that amount which gives the total area of the inclined channels connected to the sub-channel channel ranging from equal to twice the size of the sub-channel channel. The proposed rotor design allows to increase the gas flow through the rotor winding and feed cooler gas through the slotted channels into the rotor winding and thereby reduce its temperature without increasing the number of inclined channels in the winding, Invention I. The rotor of an electric machine, for example , a turbogenerator, containing a core, placed in the slots of the core, an excitation winding with a length of two rows across the width of the pas behind the channels for the passage of gas, inclined to the rotor axis in opposite directions in one row along the to the channels of another row and pairwise communicating with each other in the zone of the lower turn of the winding, groove wedges holding the winding and having inlet and outlet openings oriented in opposite directions, communicating with the winding channels, and sub-phase insulation, characterized in that increasing the intensity of cooling of the excitation winding, the core is made with sub-phase channels communicating with a part of the inclined winding channels through holes made on the sub-phase insulation, and the number of inclined to The channels n connected to the sub-channel channels are selected from the ratio S, p (0.5-1) $ n where the area of the sub-channel channel; the area of the inclined channel, 2. The rotor of claim 1, characterized in that the inclined winding channels communicating with the sub-groove channels are located at the ends of the rotor core. 3. A rotor according to claim 1, characterized in that the inclined winding channels communicating with the sub-channel channels are alternated along the length of the rotor core with the other inclined channels. Sources of information taken into account in the examination 1.Dombrovsky V.V. and others. Fundamentals of the design of AC electrical machines. L., Energie, 1974, p. 194, fig. 7-23. 2. USSR author's certificate number 122529, cl. H 02 K 9/16, 1961. t ft, tl tf U II, 11 It tt  V4X -W -XX, V X V xx v .A LA UU UHWW LH. F Well .%BUT. -L / H Phil. one 884037 ta ee c se se se FIG. 2 Phage 8 | I I 5 | lUtl it Video Fi.6