DE102010003686A1 - Electric machine i.e. air-cooled electric machine, has stator comprising winding system arranged in grooves, where winding system comprises cooling channels for cooling winding head that is formed at front ends of stator - Google Patents

Abstract

The machine (1) has a stator (3) comprising a winding system i.e. fed-in winding, arranged in grooves. The winding system forms a winding head (5) at front ends of the stator. The winding system has cooling channels for cooling the winding head. The cooling channels are formed by elements, where the elements are arranged between a coil of the winding system and a phase insulation or between two coils of different phase as the phase insulation. The elements are designed as partial conductor insulation and/or main insulation. An independent claim is also included for a method for manufacturing a stator of an electric machine.

Description

The invention relates to an electrical machine, in particular air-cooled electric machine with a stator having a winding system arranged in grooves, which forms a winding head on the end sides of the stator and a method for producing such a stator.

Electrical machines, in particular air-cooled electrical machines, have a winding system inserted into slots in a stator, which has a plurality of coils each having a number of turns per phase. By energizing this winding system and electromagnetic interaction with a rotor unfolds a torque.

The winding systems in the dynamoelectric machines form on the end faces of a stator winding heads, which essentially represents a reversal of direction of one or more coils whose Hinleiter comes from a groove and the return conductor is inserted into another groove.

The winding heads of Träufelwicklungen are extremely compact especially for larger electrical machines and thus almost impermeable to the respective cooling media, so that there is a much higher temperature in the interior of the winding heads for lack of sufficient heat dissipation compared to a mean winding temperature. These local hot spots are also referred to as hot spots.

This local temperature increase inside the winding head additionally increases the ohmic resistance, which leads to an additional overheating of the winding arrangement. Temperature monitoring devices therefore already respond to impermissible values, although the average winding heating is still within admissible limits.

The consequence of this is that the electric machine experiences a power reduction.

Proceeding from this, the object of the invention is to provide an electric machine, in particular an air-cooled electric machine, whose temperature increase in the winding head is avoided and thus an increase in the output of an electrical machine can be achieved.

The solution of the electrical task is achieved by an electric machine, in particular an air-cooled electric machine with a stator having a winding system arranged in grooves, which forms a winding head on the end sides of the stator, wherein the winding system is designed as a trickle winding and means for cooling having the winding head.

• – Stanzpaketieren eines Blechpakets,
• – Einlegung einer Träufelwicklung in Nuten wodurch sich Wickelköpfe an den Stirnseiten des Stators ausbilden,
• – Einsetzen von geeigneten Mitteln zur Kühlung in den Wickelkopf,
• – Komprimieren, Verschnüren und Imprägnieren des Wickelkopfes.

The solution of the electrical task is also achieved by a method for producing a stator of an electrical machine, in particular an air-cooled electric machine by the following steps:

• Punched packetizing a laminated core,
• Inserting a trickle winding in grooves, whereby winding heads are formed on the end faces of the stator,
• Inserting suitable means for cooling in the winding overhang,
• - Compressing, strapping and impregnating the winding head.

Due to the additional means for cooling, which are used in the interior of the winding head, in particular in a trickle winding an electrical machine, such hot spots are now avoided and thus the temperature of the winding head of a mean winding temperature adjusted so that the supervisory bodies of a dynamoelectric machine not address unnecessarily.

As cooling media for the electric machine while gas, for example, inert gas for electric machine in explosive environment or air are suitable. Likewise suitable as a cooling medium oil such as in an under-oil engine or an oil-filled engine. The circulation within the electrical machine is done by fans or suitable pumps.

These internal, in particular closed, primary cooling circuits of an electrical machine are recooled, for example, by the following secondary cooling media. Air, water, water / glycol or oil, which flows in each case in suitable cooling devices to the electric machine, for example in a cooling jacket.

This leads to a significant increase in performance compared to the previous concepts in dynamo-electric air-cooled machines.

The means are also designed as heat pipes whose heat source are the hot spots of the winding heads and the heat sink is provided outside the winding head in the region of a cooling flow.

Advantageously, the means for cooling are formed as channels in the winding head, which enforce this and leads together with a moving in the housing of the electric machine air flow to cool the winding head.

This cooling flow is generated by suitable means, such as, for example, third-party or self-ventilated or pumped and directed by suitable guide devices within the housing of the electrical machine in particular on the hot-spots to be cooled.

By this integration of the channels in the cooling concept of the electric machine no unnecessary additional cooling devices are specifically required for the winding head, but the winding head according to the invention adapts to the existing cooling concept of the electric machine, in particular that of an air-cooled electric machine.

Advantageously, the channels are formed by suitable elements, which are designed in their course such that they lead through the winding head. Ie. a coolant flow passing through these elements flows through the winding head in peripheral areas and / or centrally. There are definitely no blind holes that would allow no coolant flow. Advantageously, these elements are round, oval or star-shaped in their cross-section, so that the enlarged surface ensures increased heat transfer.

Advantageously, the elements between electrically active parts, such. B. between coils of the same or different phase as a sub-conductor insulation or main insulation provided in the winding head.

In a further embodiment, the elements are already designed as phase insulation with respect to their material. By a planar configuration of these elements, these elements are suitable as phase insulation and for the formation of cooling channels between adjacent coils of different phases in a winding head.

Advantageously, these elements are provided with a special coating or a thin shell and do not undergo mechanical bonding with an impregnating agent, such as resin or paint. Thus, connections with the surrounding insulating materials or copper wires are excluded. This is ensured in particular by the fact that z. As are the coatings of Teflon or a siliconized film. This is particularly suitable for the cases in which the elements are removed from the winding head again after impregnation.

To equalize the temperature, the elements are distributed in the most equidistant intervals in and / or on the winding head and are aligned with the direction of the cooling medium circulating in the electric machine. This results in alignments of the elements in the axial and / or radial direction in the winding head - depending on the flow direction of the moving in the electric machine cooling medium.

In a further embodiment, the elements are designed as a thin possibly flexible tube, which remains in the winding head. Alternatively, also elements are conceivable, which can be reached by prolonged exceeding a certain temperature z. B. 150 °, which is set during curing, mostly dissolve or volatilize and thus "leave" only one channel. This is achieved for example by elements of metal with extremely low melting point z. B. bismuth or Wood's metal, the z. B. melt from 80 ° and optionally subsequently worked up and thus can be reused.

The embodiment of the invention is of course also for winding heads of slip-ring motors, in which the rotor winding is formed as a trickle winding.

The invention and further advantageous embodiments of the invention will be explained in more detail with reference to exemplary embodiments illustrated in the drawing. Show:

1 Longitudinal section of an air-cooled electric machine,

2 View of the front of an air-cooled electric machine,

3 . 4 . 5 Embodiments,

6 Winding head design with phase intermediate layers,

7 to 10 Exemplary embodiments of phase intermediate layers.

1 shows a side view of the basic structure of an air-cooled electric machine 1 in a housing 2 is arranged. The housing 2 is over camp 6 on a wave 7 supported. On the wave 7 is a rotor core 4 rotatably arranged, z. B. Shrunk, that via an air gap 8th with a stator 3 that with a winding system 15 is provided, electromagnetically interacts and thus a rotation of the shaft 7 caused.

The relationships and statements presented below also apply to electrical machines with the previously mentioned cooling media (gas or liquid) and design principles (primary and secondary cooling circuit).

At the end faces of the stator 3 forms the winding system 15 winding heads 5 out. The winding heads 5 form due to their compact arrangement areas with local temperature increases. Through cooling holes 17 in Stator 3 and rotor 4 will be inside the case 2 a circular stream of air 18 generated by a radial fan 12 is supported. A re-cooling of this air flow takes place for example via the wall of the housing 2 or via a separate secondary cooling circuit.

According to the invention are in the winding head 5 cooling channels 9 provided, in particular in a cooling flow path as in 1 principally shown the winding head 5 on both sides of the stator 3 Pull through radially.

2 shows in side view the air-cooled electric machine 1 that also has the cooling holes 17 in the stator 3 and rotor 4 shows. It is also the winding head 5 shown, as viewed in the circumferential direction, as a torus at the level of the front sides of the stator 3 is formed, so that continues the stator bore 19 for the installation and removal of a rotor 4 remains free.

3 shows a cooling channel 9 in the winding head 5 the electric machine 1 is arranged, and has an orientation, the one to the shaft 7 parallel air flow in particular from the grooves 14 and / or the cooling holes 17 receives. Advantageously, therefore, the air flow occurs axially out of the stator 3 from and in the axial extension arranged cooling channel 9 one. As a result, the winding overhang not only flows around but also flows through and thus contributes to the cooling of the winding overhang 5 at. Advantageously, this cooling channel runs 9 between a top layer 10 and a pad 11 of the winding system 15 ,

4 shows a different course of the cooling channel 9 within the winding head 5 , which is particularly advantageous when a cooling air flows axially to the winding head or radially from the outside on the winding head 5 blown.

5 shows a course of the cooling channel 9 within the winding head 5 , which is particularly advantageous when a cooling air flows axially to the winding head or radially from the inside, for example, by radial fan on the winding head 5 is directed.

In another embodiment, the cooling elements are formed with corresponding materials as phase intermediate layers. They thus serve as phase insulation between coils of the winding system and at the same time form cooling channels 9 from, which also serve to cool the winding head.

In 6 While these elements are wavy, but they can, like the 7 to 10 show, for example, cuboid, chain-shaped, triangular shape and serve as a phase insulation.

Claims (8)

Electric machine, in particular air-cooled electric machine ( 1 ) with a stator ( 3 ), one in grooves ( 14 ) arranged winding system ( 15 ), which at the end faces of the stator ( 3 ) each have a winding head ( 5 ), characterized in that the winding system ( 15 ) is formed as a trickle winding and means for cooling the winding head ( 5 ) having. Electric machine ( 1 ) according to claim 1, characterized in that the means for cooling as channels ( 9 ) in the winding head ( 5 ) are formed which a cooling flow through the winding head ( 5 ) enable. Electric machine ( 1 ) according to claim 2, characterized in that the channels ( 9 ) by appropriate elements ( 16 ) are formed. Electric machine ( 1 ) according to claim 3, characterized in that the elements ( 16 ) between a coil of the winding system ( 15 ) and a phase insulation or between two coils of different phase are arranged as phase insulation. Electric machine ( 1 ) according to claim 3, characterized in that the elements ( 16 ) are designed as a sub-conductor insulation and / or main insulation. Electric machine ( 1 ) according to one of the preceding claims, characterized in that the orientation of the elements ( 16 ) takes place on the coolant flow within the electrical machine. Method for producing a stator ( 3 ) an electric machine ( 1 ), in particular an air-cooled electric machine by the following steps: - stamping a laminated core, - inserting a trickle winding in grooves ( 14 ) whereby winding heads ( 5 ) on the end faces of the stator ( 3 ), - insertion of suitable means for cooling in the winding overhang ( 5 ), - compressing, lacing and impregnating the winding head ( 5 ) Method according to claim 7, characterized in that the elements ( 16 ) in the winding head ( 5 ) melt or volatilize when a temperature is exceeded for a predetermined period during the manufacturing process.

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