DE1001394B - Combined liquid and air cooling for dynamo-electric machines - Google Patents

Description

Combined liquid and air cooling for dynamo-electric machines In the case of fully enclosed machines, it is well known that the mechanical and electrical Losses are only diverted by the air flowing around the surface of the machine. In order to improve the heat dissipation, the outer surface is mostly inside and outside still provided with cooling fins. Furthermore,. inside for good circulation ventilation and on the outside, a fan ensures that the surface area is well blown out.

Since in AC machines the losses (iron and winding copper) mainly concentrated in the stator is the heat dissipation of these losses relative to the housing surrounding the stator laminations as a metallic intermediate carrier Well. In contrast, with DC machines, where the losses are mainly in the rotor, must first of all to the air surrounding the rotor and then from there on the outer surface are released. The heat dissipation of the inside of a DC machine generated losses is more difficult for these reasons because of the air as an intermediate carrier, and all the more so since, in addition to the losses mentioned, those generated in the commutator Losses are added.

For cooling electrical machines, it is known to be axial Provide cooling channels that penetrate the rotor body, the cooling air flow is deflected laterally through radial openings in the center of the rotor body. Further arrangements are also known in which the rotor itself has liquid-cooled waveguides be provided, with the ends of these waveguides at the same machine end are performed and the cooling liquid is supplied at one end of the conductor and is discharged at the other end of the conductor. For the supply and discharge of the coolant Corresponding annular spaces and channels are also necessary in the rotor body for the waveguides. However, these known cooling arrangements are not combined Liquid and air cooling for completely enclosed machines.

The purpose of the invention is now a combined liquid and Air cooling for dynamo-electric machines of the enclosed type, in particular DC machines to create, in which the dissipation of the heat loss is more effective than with the previous encapsulated machines. According to the invention this is achieved in that the massive rotor body of the machine with a central Bore and a large number of evenly distributed on the outer circumference of the rotor body Longitudinal channels for liquid cooling is provided, the cooling liquid at one end of the rotor via a bore in the rotor shaft stub of the rotor bore is supplied and via the longitudinal channels and an annular space via the same stub shaft flows back again, and that further between the central bore and the longitudinal channels further uniformly distributed continuous longitudinal channels are provided for the cooling liquid through which the air circulated inside the machine housing flows.

The invention is explained in more detail with reference to the drawing, namely Fig. 1 shows as an embodiment of the same a direct current motor in longitudinal section. while FIG. 2 shows a cross section through the rotor body.

In the drawing, 1 means the rotor body designed as a drum, made of a material with high thermal conductivity, for example silumin alloy, Bronze, etc., and is worked out from one solid piece. In the immediate In the vicinity of the rotor laminations 2, there are axial longitudinal channels 3 on the outer circumference of the rotor 1 intended. These longitudinal channels 3 are used for liquid cooling of the rotor, for example water cooling, and are through radial holes 4 and 4 'at the ends of the rotor connected to the inner cavity of the rotor body. The water supply takes place via the bore 6 provided in the stub shaft 5 through the rotor body 1 passes through the water to the radial holes 4, while the water passes through the radial holes 4 ', the cavity 7 and the annular space 8 over the same shaft end flows off again. Except for the longitudinal channels 3 for the water supply are furthermore in the rotor body 1 the longitudinal channels 9 provided with cooling fins for the Passage of the air of the internal circulation ventilation provided. The circulation of the Air inside the machine is indicated by the dashed arrows and is achieved by the fan 10.

In the arrangement described, the one generated inside the machine Heat loss, including the heat loss in the stator, essentially from one with water and air flowing through the rotor body and absorbed by means of water as Heat transfer medium discharged to the outside. The dissipation of the heat losses generated in the stator can still be supported by attaching an outdoor fan 11, the directs a flow of cooling air along the cooling fins 12 of the jacket outer surface.

This compressed air and water cooling enables a very substantial one Improvement of the heat emission with encapsulated machines and is a matter of course not limited to DC machines, although their advantages are with these types of machines are greatest.

Claims (1)

PATENT CLAIM: Dynamoelectric machine of the completely encapsulated design with a combined liquid and air cooling, in particular a DC machine, characterized in that the massive rotor body of the machine is provided with a central bore and a plurality of longitudinal channels evenly distributed on the outer circumference of the rotor body for the liquid cooling, whereby the cooling liquid is supplied to the rotor bore at one end of the rotor via a bore in the rotor shaft stub and flows back via the longitudinal channels and an annular space via the same shaft stub, and further evenly distributed continuous longitudinal channels are provided between the central bore and the longitudinal channels for the cooling liquid through which the air circulated inside the machine housing flows. Considered publications: German Patent Nos. 227 651, 236 800, 237 404, 433 209, 520 471, 578 658, 632 919, 647 316, 702 901, 836 060; German patent application p 10890 VIII d1211 D; Austrian Patent No. 74 896; Swiss Patent No. 281252; British Patent No. 596,604; French patent specification No. 516 866.