DE102018215573A1 - Electric machine with stator cooling - Google Patents

Abstract

Electrical machine with a stator, which has a laminated core and stator windings, a respective winding head of the stator windings being arranged at axial ends of the laminated core, characterized in that at least one of the winding heads is accommodated in a cooling cap, which only accommodates the at least one winding head and for this purpose is designed to bring the at least one end winding into direct fluidic contact with a cooling fluid.

Description

The present invention relates to an electrical machine with a stator, which has a laminated core and a stator winding, and with a cooling device for a winding head of the stator windings.

When an electrical machine, such as a generator or an electric motor, is operating, heat is generated which leads to heating in the conductor windings. This heating in the conductor windings in turn results in greater resistances and consequently leads to greater losses. It is therefore necessary to cool the electrical machine in its operation. This cooling can take place, for example, via liquid cooling.

For example, in the DE 10 2015 215667 proposed to thermally connect the stator winding heads with a housing through which liquid flows. For this purpose, the winding heads are embedded in a thermally conductive material that is thermally in contact with the housing surrounding the electrical machine. The housing itself is in turn cooled by liquid cooling, so that the stator head can also be cooled.

A disadvantage of this prior art, however, is that the material in which the stator heads are embedded must be electrically insulating but thermally conductive. Such materials are difficult to find and very expensive. On the other hand, two thermal contact resistances in the form of the embedding material and the housing must be overcome between the winding head and the cooling medium, so that the possible cooling capacity is reduced.

Alternatively, it has also been proposed not only to introduce cooling air via cooling ducts into the interior of the electrical machine, but also to lead it directly past the stator heads. Air cooling, however, does not provide as good a cooling performance as, for example, liquid cooling.

The object of the present invention is therefore to provide an efficient liquid cooling of the winding heads.

This object is achieved by an electrical machine according to claim 1.

An electrical machine with a cooled stator is presented below, the stator having a laminated core and stator windings and winding heads of the stator windings being arranged at axial ends of the laminated core. Since not only the stator core, but also the winding heads should be cooled for a particularly effective cooling, it is proposed that at least one of the winding heads is accommodated in a cooling cap, which receives only the at least one winding head and is designed to hold the at least one winding head in to bring direct fluidic contact with a cooling fluid. It is also conceivable to apply a ring filled with cooling liquid to the winding heads, so that all winding heads can be cooled.

With this cooling device, the winding head / the winding heads is specifically cooled, whereby further cooling devices can of course be present on the stator, which, however, are independent of the cooling of the stator winding head.

It is particularly advantageous if the cooling cap is closed to an environment. As a result, cooling fluid is only supplied directly to the stator winding head, and a closed cooling circuit can be provided for the cooling fluid of the stator winding head.

According to a further advantageous exemplary embodiment, the at least one winding head accommodated in the cooling cap is at least partially immersed in a fluid. This allows the cooling fluid to act directly on the winding overhang, which enables particularly effective cooling.

It is also advantageous if the cooling cap has a cooling fluid inlet and a cooling fluid outlet, each of which is connected to a heat exchanger which cools heated cooling fluid emerging from the cooling fluid outlet and makes it available again to the cooling fluid inlet. This closed cooling circuit enables direct and very effective cooling of the stator and thus of the electrical machine.

According to a further advantageous exemplary embodiment, a pump device is provided between the cooling fluid inlet and the heat exchanger. This pump device enables a particularly good and effective throughput of cooling fluid in the cooling cap of the stator winding head.

According to a further advantageous exemplary embodiment, the cooling fluid is a liquid dielectric cooling fluid. Liquid dielectric cooling fluids are well known and provide particularly good cooling of the stator winding head and do not affect the electrical properties of the stator.

In addition, the cooling fluid can be a dielectric cooling fluid that changes into a gaseous state when heated and that surrounds the at least one winding head in liquid form. This Dielectric cooling fluid evaporates when it comes into contact with the end winding, and due to the resulting vapor pressure, it can be routed to a heat exchanger, in particular to the condenser, via a laxative connection. There the cooling fluid condenses again and can be fed back to the winding head as a liquid cooling fluid.

By directly applying the cooling fluid to the end windings, the cooled surface and in particular the heat transfer are maximized compared to the prior art and an increased cooling capacity is achieved.

In addition, the evaporation of the fluid improves the heat dissipation from the winding head, since the rising of the bubbles leads to the temperature boundary layer being torn off, as a result of which the heat transfer is significantly improved. The reason for this is that due to the rising of the gaseous cooling fluid, basically cool liquid fluid reaches the stator windings and non-heated fluid adheres to them. This can also improve the cooling effect.

Further possible implementations of the invention also include combinations of features or embodiments described above or below with reference to the exemplary embodiments that are not explicitly mentioned. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the invention.

Further advantages and advantageous embodiments are specified in the description, the drawings and the claims. In particular, the combinations of the features specified in the description and in the drawings are purely exemplary, so that the features can also be present individually or in a different combination.

The invention is to be described in more detail below with reference to exemplary embodiments illustrated in the drawings. The exemplary embodiments and the combinations shown in the exemplary embodiments are purely exemplary and are not intended to define the scope of the invention. This is defined solely by the pending claims.

• 1: eine schematische Darstellung eines bevorzugten Ausführungsbeispiels der elektrischen Maschine.

Show it:

• 1 : A schematic representation of a preferred embodiment of the electrical machine.

In the following, identical or functionally equivalent elements are identified with the same reference symbols.

The 1 schematically shows an embodiment of an electrical machine 1 with a stator 2nd and a rotor 4th taken in an interior 6 of a housing 8th are arranged. The rotor 4th still has a rotor shaft 10th on that is hollow and made of bearings 12th , 14 that on walls 16 , 18th of the housing are attached, is stored.

The stator 2nd itself has a sheet stack 20th with electrical conductor windings (not shown) on the axial ends 22 , 24th of the laminated core of stator winding heads 26 , 28 form. Usually used for cooling the stator 2nd a cooling fluid is introduced into the stator core, which is the stator core 20th and thus cools the windings. The stator winding heads 26 , 28 remain uncooled. However, cooling them would significantly improve the cooling performance of the stator cooling.

For this purpose, a cooling device is attached directly to at least one stator winding head 26 , 28 intended.

As in 1 is shown on a winding head 26 , 28 of the stator 2nd a cooling cap 32 arranged the winding head 26 , 28 completely surrounds. There is a preferably liquid cooling fluid in the cooling cap 34 provided that at least partially the stator winding head 26 , 28 surrounds and is in direct thermal contact with it. Preferably, the cooling cap 32 to the stator 2nd to and from the interior 6 of the electrical machine 1 completed so that's in the cooling cap 32 existing cooling fluid 34 cannot escape uncontrolled.

How 1 the winding head can be seen 32 completely of the cooling fluid 34 surround. The cooling fluid 34 is preferably a dielectric fluid which, when heated, that is to say when it comes into contact with the heating winding heads 26 , 28 , evaporates. This evaporated cooling fluid 36 collects in an upper area 38 in the cooling cap 32 . From there it can independently generate steam pressure from a cooling fluid outlet 40 and via one with the cooling fluid outlet 40 connected coolant line 41 to a capacitor 42 be transferred. Of course, can of course in the cooling fluid line 40 a conveying device, such as a fan or a pump, may also be provided.

In the condenser 42 the gaseous cooling fluid condenses 36 in its liquid form 34 and will have one with a cooling fluid inlet 44 the cooling cap 42 connected cooling fluid supply line 45 back in the cooling cap 32 introduced. A pump device in particular can be used for such a transport 46 in the cooling fluid line 44 be arranged.

By directly applying the cooling fluid to the winding heads 26 , 28 the cooled area is maximized and the cooling capacity is increased. Due to the phase transition of the liquid cooling fluid 34 into a gaseous cooling fluid 36 is also the exchange of cool cooling fluid on the winding head 26 , 28 Improved, because warmed parts of the cooling fluid are removed by the rising of the bubbles and cool cooling fluid is provided in liquid form on the winding head.

In addition, the energy requirement of the phase transition increases the cooling capacity, since the energy required for the environment and thus for the stator winding heads 26 , 28 is withdrawn.

Overall, the cooling of the stator winding heads presented by means of directly applying cooling fluid to the windings of the stator heads can improve the cooling capacity of the electrical machine and make the heat dissipation from the winding heads more efficient. This can reduce the losses and any increases in resistance of the electrical machine.

Reference list

1

Electrical machine

2nd

stator

4th

rotor

6

Interior of the electrical machine

8th

casing

10th

Rotor shaft

12, 14

camp

16, 18

Partitions

20th

Stator laminated core

22, 24

axial ends of the stator

26, 28

Stator winding heads

32

Cooling cap

34

liquid cooling fluid

36

gaseous cooling fluid

38

upper area of the cooling cap

40

Cooling fluid outlet

41

Cooling fluid line (gaseous)

42

capacitor

44

Cooling fluid inlet

45

Cooling fluid line (liquid)

46

pump

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102015215667 [0003]

Claims (9)

Electrical machine (1), comprising a stator (2) having a laminated core (20) and stator windings at axial ends, a respective winding of the laminated core (20) (26; 28) of the stator windings is arranged, characterized (22 24) characterized in that at least one of the winding heads (26; 28) is accommodated in a cooling cap (32) which is designed to bring the at least one winding head (26; 28) into direct fluidic contact with a cooling fluid (34; 36). Electrical machine (1) after Claim 1 The cooling cap (32) is closed off from an environment (6), in particular an interior (6) of the electrical machine (1). Electrical machine (1) after Claim 1 or 2nd , wherein the cooling cap (32) has a cooling fluid inlet (44) and a cooling fluid outlet (40), each of which is connected to a heat exchanger (42) which cools heated cooling fluid (36) emerging from the cooling fluid outlet (40) and the cooling fluid inlet ( 44) provides. Electrical machine (1) after Claim 3 , wherein the heat exchanger is a condenser. Electrical machine (1) after Claim 3 or 4th A pump device (46) is provided between the cooling fluid inlet (44) and the heat exchanger (42). Electrical machine (1) according to one of the preceding claims, wherein the cooling fluid is a liquid dielectric cooling fluid. Electrical machine (1) according to one of the preceding claims, wherein the cooling fluid is a dielectric cooling fluid that changes into a gaseous state when heated, and surrounds the at least one winding head in liquid form. Electrical machine (1) after Claim 6 or 7 The at least one winding head (26; 28) accommodated in the cooling cap (32) is at least partially immersed in the cooling fluid (34; 36). Electrical machine (1) according to one of the preceding claims, wherein the cooling cap (32) is annular and accommodates all winding heads.

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