DE1613402A1 - Liquid cooling of the damper windings of electrical machines - Google Patents

Description

Dlpl.-Ing. Dipl. Oee. publ. I) IETRICHLEWiNSKY _{1Rn / n} , PATENT Attorney I D I 4 H U 4

42 - Goitbordstr. 81 July 11, 1967

Telephone 561762

SociSte * GSnSrale de Constructions Electriques et I-Ie "caniques,

(ALSTHOM),
Paris lo ^ me, avenue KlSber 38 (France)

"Liquid cooling of the damper windings of electrical machines "

French priority of July 13, 1966 and March 24 1967 from the French patent applications iir. 2695 (Beifort) and No. 2743 (Beifort)

With an asynchronous start-up of a synchronous or asynchronous Electric motor creates a thermal in the damper winding Energy, the extent of which depends on the kinetic energy of the machine to be started and the force of the moment of resistance depends.

The proportion of heating due to the moment of resistance can generally be changed by a temporary change of the section modulus is reduced to a low value will. Is it an alternating current generator turbine in which the alternating current generator is used as the drive element and the Turbine is used as a pump, so you can, for example, a reduction in the moment of resistance either by a Disengagement of the alternator from the turbine a bypass connection of the liquid to be pumped or by draining the turbine wheel.

On the other hand, the heating component due to the moment of resistance cannot be reduced if it is Aggregates with large inertial masses, as this is the main

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is mainly the case with hydraulic pumping stations, where this warming would lead to excessive fourths, which would exclude the possibility of an asynchronous start-up.

The possibility of cooling the windings of electrical machines through constant circulation of liquid may well be known as provided v / earth. If this winding is on a part in -Dotation, this requires a cooling process the construction of a complicated device for the inflow and outflow of the liquid.

It is the object of the invention, a simple Ueise to create effective cooling of the damper windings of electrical machines at the moment of start-up.

~ The invention relates to a rotor, its damper winding has a thermal connection to the cooling channels, characterized in that a coolant container in the Central area of the rotor is arranged and that the container and cooling channel closures communicate with one another through connecting lines in such a way that a natural fluid circulation between the channels and the container when starting the as Drive element acting electrical machine can take place,

If the rotor is arranged vertically, this natural orbital movement can be performed using the Damper winding heating based on the principle of warm water heating take place. The connecting lines thus connect on the one hand the upper end of the cooling channels with the upper part of the container, on the other hand the lower end of the cooling channels with the lower part of the container.

To utilize the natural coolant circulation one can also make use of the dynamic effects

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nen that arise during the Urals or during the starting process of the rotor, for example the kinetic energy that from the difference between the tangential velocities of the Coolant container and this liquid itself is created. The connecting lines therefore open into the container, these being inclined and with the two Lnden of the cooling channels are in communication.

around the inertial force during the acceleration of the rotor This container can make the cooling liquid usable for the natural circulation of this liquid can also be divided into individual chimneys by radially arranged partitions. The connecting lines i.iun-Jen after penetrating this partition into these chambers in such a way that those of the connecting lines the uit one end of these cooling channels are connected to one The strings of this partition bulkhead open to the other end of the ilühlkanälc at the other end of this bulkhead flow out.

The rotor shaft of the machine can be hollow and a part of this irellenholilraums can form this container.

ioiwendungsbeispiele the invention should be based on the are described in more detail in the attached diagrams.

fig. 1 shows a section of a part of the vertical Motors r.iit circulating solvent in the Dcl: .ipfer winding under liutzbarraachung the irarm water heating effect.

2 and 3 show a part in a partial sectional view in elevation and in plan view according to section III-III of the rotor with coolant circulation in the outer damper winding, under the action of the relative tangential velocity of the liquid contained in the liquid container and this Container itself.

,,,.:, ■ ..-, .. "■ ■ ^ßAD ORIGINAL

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FIG. 4 shows a part of the rotor with cooling liquid circulation in a partial sectional view and top view in the damper winding under the influence of the inertial force of the coolant during acceleration of the rotor.

In the example of FIG. 1, a vertical hollow trowel 1 carries a rotor 2 with damper winding rails 3. A The space delimited by the bulkheads 4 and 5 in the interior of the hollow shaft 1 forms the coolant container 6. In the rails 3 run the cannula 7, which can be used directly as cooling channels, but in which the tubes 8 housed het. The lower ends of these tubes 3 open in a collecting container 9, the upper ends in the collecting container 10. The collecting container 9 is with the lower part of the Container 6 is connected via the lines 11 and the collecting container 10 is connected to the upper part of the container 6 via the Lines 12 connected.

If the rotor begins to rotate without the rails 3 being heated, then there is no fluid circulation in the system instead and the pressures created in lines 11 and 12 by the centrifugal force cancel each other out. If, however, the rails 3 heat up, as in the case of the start-up of the ilotors, then the convection causes an increase in the heated liquid in the tubes 8 leading to the collecting container 10 and the pressure gradient between the liquid Lines 12 and the fluid of the lines 11 creates an active fluid circulation between the tubes 8 of the Rails 3 and the container 6. A liquid movement in the opposite direction would depend on the temperature result in a pressure change that would be opposite to that of the water.

If the losses in the rails 3 are sufficiently large and they run very quickly to the liquid in the tubes

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Bringing it to the boil in certain areas creates the development of steam in the tubes 12 a water vapor mixture of significantly lower density than that of the liquid in the lines 11, whereby the pressure difference between the lines 11 and 12 increases considerably and the circulation is increased. The thus regionally generated vapor condenses in the container 6 and gives off its heat to the liquid contained in the container, whose average temperature thus increases.

The system can now be designed so that the temperature increase the liquid in the container 6 is not sufficient to reach the boiling point under normal pressure. A large container with a low-pressure bulkhead is used for this. The system can also be designed for a lower liquid reserve, in which the Boiling temperature would be exceeded. For this purpose, a container with bulkheads, which is designed for a higher temperature, is used are. Finally, a significantly lower liquid reserve can be provided, assuming a boiling point temper a door of the liquid contained in the container and a release of the vapor to the outside air. With this arrangement the container must be refilled at certain intervals.

The value of the thermal insulation for such a damper winding is thus much higher and allows the asynchronous Start-up of large inertial masses without the unit heating up excessively.

In the example of FIGS. 2 and 3, the hollow shaft 1 is shaped in accordance with the cylinder 13 which holds the coolant container 14 forms. Acting as cooling channels for the damper winding As in the example of FIG. 1, tubes 8 open into the collecting containers 9 and 10, which are connected to the container via lines 11 and 12 14 are in connection, Fig. 3 contains the Selena for the counter-inclination of the ends 15 of the lines 12 for the collecting container 10 and the ends 16 of the lines for the collecting container

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ter 9. If the rotor is set in rotation, the inner surface of the cylinder also rotates the coolant through friction. However, since the viscosity additive this liquid is relatively low, its angular velocity is significantly below that of the cylinder 13. The kinetic energy due to the differential angular velocity between the cooling liquid and the holder thus creates an overpressure in line 11 and an underpressure in line 12, resulting in cooling liquid circulation in the tubes 3 leads.

In Fig. 4, on each of which the same parts are the same Carrying reference numerals v / ie in FIG. 3, a cylinder 13 is shown which passes through the radially extending bulkheads 17 is divided, the ends 15 and 16 open on both sides of this bulkhead. When the Rotors, the coolant flows as a result of its own iniquity in the damper housing v / ie shown in Fig. 3. These dividing bulkheads 17 can either be over the entire height of the container 14 or just opposite ends 15 and 16.

As already shown in FIG. 2, the liquid is circulated in the tubes 8 under the dynamic effects of the rotor starting process in the same direction as in the case v / o the damper windings were heated, but circulation in the opposite direction can also be provided.

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Claims (5)

11.7. 1967 SociStS Ge "n £ rale de Constructions Electriques et ZleOaniques, (ALSTHOi 1), Paris l'6Srae, 38, Avenue KlSber (France) Pat tans priiche: 1. Liquid cooling of the damper windings of electrical machines council help of a rotor rait damper winding, which rait the cooling channels in warning conductive connection, characterized in that a cooling liquid container (6) in the emitting area of the rotor (1) is arranged and connection lines (11,12 ) connect the container (6) and the ends of the cooling channels (8), whereupon a natural fluid circulation takes place between the channels (8) and the container (6) when the unit, which functions as a motor, starts up. 2. Rotor according to claim 1, characterized in that this rotor (1) is arranged vertically, the connecting lines (11, 12) on the one hand the upper end of the cooling channels (8) on the upper part of the container (6), on the other hand the lower end Connect the end of these cooling channels (8) to the lower part of the container (6). 3. Rotor according to claim 1, characterized in that these connecting lines (11, 12) open into the container (6) and are connected to the two ignition points of the cooling channels (8). 4. Rotor according to claim 2, characterized in that the container (6) is delimited by radially extending separating bulkheads (4,5) and the connecting lines (11,12) opening there BATHROOM ORIGINAL - ₂ - 0 0 9 8 8 3/0623 end there and those of the connecting lines (11, 12) which are connected to one end of the cooling channels (8)
one side of this bulkhead (4,5), the one with the other
Part of the cooling channels (8) open out verbunderm on the other side of the bulkheads (4,5). 5. Rotor according to claim 1, characterized in that the shaft (1) this rotor is hollow, part of this shaft (1) forming the container (6). 009883/06 2 3