DE19716758C2 - Housing-free electrical machine with several axial cooling channels with direct fluid flow - Google Patents

Description

The invention relates to an electrical machine without a housing with several axial cooling channels through which fluid flows directly len in the corner areas of the stator core from approximately quad ratical stand plates and with external pressure plates for and removal of a cooling medium.

The performance and aging resistance of an elec trical machine is essentially different from that at Energieum change occurring heat loss, the temperature resistant speed of the materials used and the intensity of the cooling certainly. The effort to always be strong with the same size to develop kere machines, or with the same ones Performance to reduce the size of the machine therefore depends directly on the efficiency of the cooling system. This is it not only necessary, the cooling channels in the laminated core are optimal to design, but also according to the designed Aus to apply cooling medium to the machine. The he invention describes an improvement in the design for a Machine of the type described above.

According to the DD 144 484 are both in the circular stand package as well as radially extending circumferentially in the rotor package Stamped cooling channels, which are used to enlarge the cooling surface are wavy or serrated. Through the cooling channels is off finally led cooling air.

From JP 59-59034 is an approximately square, itself supporting stator core package known, in the circumferential radial extending cooling air channels are stamped, the Cooling air ducts in the corner areas are longer than on the sides tenflächen.

DE 30 26 892 A1 is a square, self-supporting  Stand plate package for an air-cooled three-phase machine be knows, in the staggered layered in the corner areas Sheet metal packs are arranged smaller recesses that either as a breakthrough for the stator core Tending tie rods, as functionally identical die-cast channels or as Axial channels are used for an additional internal cooling circuit. However, the cooling effect is due to the low cooling air rate due to the comparatively very small cooling channels limited.

In an electrical machine according to EP 0 145 903 A1, the Air cooling of the stand package the corner area several small, round, axial channels, with the supply of cooling air to the Stand package exclusively from other machine parts len separate cooling channels. In the area of the end faces the cooling channels have a counter to increase the heat density enlarged over the remaining sections of the cooling channels, ins special star-shaped or oval heat exchange surface and / or reduced flow cross section. The invention should enable cooling close to the place of origin, without that dust and moisture reach live machine parts chen.

Another square stator core according to EP 0254 930 A1 has two closed openings in the corner areas and a slot-like one open to the outer surface Recess. The breakthroughs form eight the stator laminated core Air guiding channels penetrating in the axial direction. The Mon tor also has a fan cover with cooling fins.

In the German utility model DE 92 18 066 U1 a stator core package for caseless three-phase machines be wrote, in the cooling air windows of the corner areas whose outer edge formed by the opening of the press frame is arranged, longitudinal and cross cooling bars, which at least at least three sides are ribbed to the available Enlarge cooling surface.  

From DE 296 11 039 U1 and JP 59-59034 (A) are stands for caseless three-phase machines with cooling air ducts in the Known corner areas or over the entire outdoor area, the have approximately the same size, rib-free flow cross-sections, the by V-shaped, essentially radial webs are separated from each other. The cooling medium is used exclusively Air.

An electrical machine is described in EP 0 726 635 A1, smooth into the rounded corner areas of the stand package walled cooling air ducts except for a small material web approach leads. The space usable for cooling purposes is full used, but not used intensively, because too Additional measures to increase the surface area of the cooling channels as well as optimized cooling bars are missing. The cooling takes place only with air.

According to EP 0 503 093 A1, JP 6-121490 (A), JP 61-121728 (A) and JP 61-121729 (A) it is known to be more caseless in the stator corners electrical machines directly axial cooling channels for a Provide liquid cooling, the cooling channels for bes seren heat dissipation can also be profiled. An additional che gas cooling, in particular an optional application of Existing cooling channels with cooling gas is not provided.

DE 43 15 280 A1 describes an external rotor machine combined gas / liquid cooling. Inside the massive The stator is at least one through which coolant flows Cooling jacket arranged. Furthermore, the massive stand still further inside at least one cooling channel, which is from egg circulating internal cooling medium, preferably air is pouring. Due to the coolant in the cooling jacket Heat dissipation from the subsequent stator core reached as well as cooling the internal cooling air flow in the Cooling channels of the massive stand. Runner or stand plate packages are not directly traversed by cooling channels. Also due to the design, it can be subjected to any application the cooling paths with cooling medium, in particular with one  Once the basic structure of the machine has been specified, no individual le Use and division of the cooling paths possible.

Further combined gas / liquid cooling arrangements for elec tical machines show DE 27 16 184 A1, DE-GM 18 03 987 or DE-GM 18 13 190, here also the cooling tube systems Determine the type of coolant to be passed. It also acts not to worry about housingless machines with immediate cooling channels in the stator core.  

According to EP 0 581 966 A1, a housing-free electrical Ma machine with several axial cooling channels through which fluid flows the corner areas of the stator core, where the All cooling channels according to the design of the machine for guiding a gaseous or a liquid medium serve. A machine upgrade for the intended Operating conditions are therefore not particularly flexible, but is limited to gas or liquid cooling.

The invention has for its object a housingless electrical machine with axia through which fluid flows directly len cooling channels in the corner areas of the stator core create, which, depending on the design, without changing the Stator sheet package can cool optimally.

This object is achieved by the features specified in claim 1. Further advantageous embodiments show the sub-claims 2 to 4 .

According to the stand sheets are according to the Ausle the machine for cooling with a gaseous medium or with a liquid cooling medium or with a gaseous one and a liquid cooling medium can be used, the Auftei development and management of the cooling media through the arrangement of the Cooling channels in the stator core package as well as through the configuration tion of the supply and discharge channels and distribution in the outer ren pressure plates is specified, whereby the cooling channels of the Stand sheet metal package in a row, parallel or in a combination ned series / parallel arrangement are connectable.

The invention is based on an embodiment and the associated drawing will be explained in more detail. In the drawing shows:

Fig. 1 a symmetrical quadrant of a proper stator lamination Invention of a rotating electrical machine rule,

Fig. 2 shows a section through a rotating electrical Ma machine in a closed, fully laminated construction with approximately square stator core.

In the corner areas 1 of a substantially square laminated core 2 cooling channels 3 are introduced by punching out the individual stator laminations so that between them Kühlrip pen 4 extend in an approximately radial direction to the edge region of the laminated core 2 . On either side thereof, two further openings 5 are arranged, through the not shown in detail after the stacking of the stator plates to the plate package 2 clamping bolt for bracing the stator plates 2 under Zuhil fenahme of outside pressure plates (Fig. 2) go. The cooling media are guided through the cooling channels 3 during operation of the machine. The cooling channels 3 or the cooling fins 4 , which comes to the same thing, are greatly enlarged by a knob profile 6 surface. Instead of the knob profile 6 , other profile shapes can of course also be used, for example a tooth or wave profile. The knob profile 6 runs over the entire length of the cooling fins 4 , which results in an excellent overall heat exchange between the stand iron and the cooling media used. The cooling channels 3 are formed in the example from larger cooling channels divided by separating ribs, which are arranged in the corner regions and extend in the radial direction.

Of course, according to other embodiments of the inven tion, the cooling channels 3 according to FIG. 1 can also be formed by individual round, square, star-shaped, among other things, smaller cooling channels.

Depending on the desired type of cooling, cooling gas, cooling liquid or - in separate cooling channels - flow through the cooling channels 3 from both cooling media. With mixed ter cooling, the inner, small ren cooling channels 3 are acted upon with cooling liquid, which leads to the best cooling results. By means of distributions in the pressure plates ( FIG. 2), series, parallel or series-parallel arrangements of the cooling channels 3 can be produced, which determines where cooling gas and where cooling liquid is to be passed through. The cooling flows can thus be optimally adapted to the expected operating conditions of a machine.

In Fig. 2 a housingless, rotating electrical machine ne is shown in half section. A rotor 9 is seated on a motor shaft 8 , the sheet metal core of which is crossed with axial cooling channels 10 . With 11 his short-circuit rings are designated. The rotor 9 rotates within the stator winding provided with a stator 13th The winding heads 12 of the stator winding are shown. There is a very fine air gap 14 between the rotor 9 and the stator 13 . The laminated core of the stand 13 is clamped ver by means of pressure plates 15 .

End shields 17 seal the engine interior from the outside and support the bearings 18 , 19 for the motor shaft 8 . Inside the machine sits on the motor shaft 8, a ventila tor 20 for internal ventilation. The stand 13 is gene in the vicinity of the outer edge of several axial cooling channels 21 , 22 , two of which are shown in the example visible. In the pressure plates 15 channels 16 are embedded, which determine the assignment of the cooling channels 21 , 22 to each other. In addition, the pressure plates 15 for the gas supply and gas discharge into the gas-cooled cooling channels 21 are provided with openings 23 and with nozzles 24 which lead out of the machine from the liquid-cooled cooling channels 22 for an external cooling liquid.

In operation, the machine is cooled by cooling medium which flows un indirectly through the channels 21 , 22 . Three operating modes can be specified:

• 1. Pure gas cooling takes place.
• 2. Pure liquid cooling takes place.
• 3. There is a combined cooling with cooling gas and  Coolant.

The latter operating mode will be described in more detail.

Coolant liquid is passed through the nozzle 24 from the outside through the cooling channels 22 , the distribution within the cooling channels 22 being determined by the type of pressure plates 15 used, for example a plurality of cooling channels 15 are connected in series by deflections 16 . After passing the last cooling channel 22 provided for liquid cooling, the cooling liquid is led out of the machine again and z. B. passed through an external cooler, not shown, before it flows through the machine again. In addition, internal gas cooling is built up, in that internal gas is driven by the fan 20 through the axial cooling channels 21 located in the outer stator core package. When passing through the cooling channels 21 , heat is given to the cooling liquid in the cooling channels 22 and is dissipated to the outside thereof. The now cooling te cooling gas leaves through the openings 23, the stator 13 and flows through a first winding head 12 , via the cooling channels 10 in the rotor 9 and a second winding head 12 of the stator 13 , where it absorbs heat, back to the fan 20 . A small proportion also flows through the air gap 14 between the rotor 9 and the stator 13 . The fan 20 can circulate in a manner known per se, the cooling gas with both positive and negative pressure in the inner cooling circuit. For example, air or inert gas can be considered as the cooling gas.

reference numeral

1

corner

2

Stator core

3

cooling channel

4

cooling fin

5

breakthrough

6

stud profile

7

separating rib

8th

motor shaft

9

runner

10

Cooling channel in the rotor

11

Short ring

12

winding

13

stand

14

air gap

15

printing plates

16

redirection

17

end shield

18

camp

19

camp

20

fan

21

cooling channel

22

cooling channel

23

breakthrough

24

Support

Claims (4)

1. Housing-free electrical machine with several directly fluid-flowed axial cooling channels in the corner areas of the stator core from approximately square stator plates and with external pressure plates for supplying and removing a cooling medium, characterized in that the stator plates according to the design of the machine for cooling with a gaseous cooling medium or ver can be used with a liquid cooling medium or with a gaseous and a liquid cooling medium, the distribution and guidance of the cooling media by the arrangement of the cooling channels ( 3 ; 21 , 22 ) in the stator core ( 2 ) and the configuration of the supply and discharge channels and distribution in the outer pressure plates ( 15 ) is given, whereby the cooling channels ( 3 ; 21 , 22 ) can be connected in series, in parallel or in a combined series / parallel arrangement. 2. Electrical machine according to claim 1, characterized in that the cooling channels ( 3 ; 21 , 22 ) extend directly to the outer edge of the stator core ( 2 ) and are divided in the radial direction into a plurality of smaller cooling channels ( 3 ; 21 , 22 ). 3. Electrical machine according to claim 2, characterized in that with simultaneous guidance of a gaseous and egg nes liquid cooling medium, the liquid-flowed cooling channels ( 3 ; 22 ) to the heat source and the gas-flowed cooling channels ( 3 ; 21 ) to the outer edge of the stator core ( 2 ) lying down. 4. Electrical machine according to one of the preceding claims, characterized in that the cooling channels ( 3 ; 21 , 22 ) are profiled to increase the surface area.