DE102016218741A1 - Electric machine with improved cooling - Google Patents

Abstract

The invention relates to the cooling of an electrical machine. For this purpose, a cooling system is provided, which has at least one heat pipe pair, which is in thermal contact with a stator of the machine. The heat pipe is further connected to a heat sink assembly, to which a heat absorbed at the stator can be dissipated. Another heat pipe is in thermal contact with the rotor as well as with the heat sink assembly. The two heat pipes of the heat pipe pair of the stator are arranged horizontally and antiparallel to each other, whereby it is achieved that different, the efficiency of these two heat pipes influencing force effects are compensated. The heat pipe of the rotor, in contrast, is designed as a heat pipe co-rotating with the rotor, which also has a conical shape. As a result, during rotation, the liquid phase of the working medium of the heat pipe is transported from the condensation section to the evaporation section.

Description

For mobile applications of electric drives such as for electric flying or electrically powered watercraft, etc. electric motors are required with high power densities. While power densities of up to 2kW / kg are sufficient for many technical applications, for example, for the electrification of aviation, i. H. intended for electric or hybrid electric powered aircraft, but also for other, especially mobile applications electrical machines with power densities of at least 20kW / kg.

Accordingly, high-power-density, electric motors are required for the aforementioned mobile applications, with higher demands on the cooling of the electrical machine being made with increasing power density. In the active components of the machine, d. H. In particular with the stator and / or rotor, a significant proportion of the heat arises, for example, within magnet coils of the stator winding due to the electrical resistance of the conductor and due to the skin effect. In addition, eddy current losses and magnetic hysteresis losses lead to additional heat development in the respective component of the electric machine. This leads to reduced performance. The same applies to permanent magnets possibly provided on the rotor, in which heating causes their magnetic field and thus the efficiency of the electric machine to be reduced. In addition to the efficiency-enhancing cooling of these active components, it is necessary to appropriately protect, in particular, the heat-sensitive components such as the electrical insulation of the conductors of the electric machine by suitable heat dissipation measures to prevent damage and failure of the machine.

Although direct convective cooling of the component to be cooled, for example the conductor, with the aid of liquid cooling media permits high efficiency, it is however expensive due to the complex design required and the comparatively complex maintenance and servicing. Furthermore, cooling systems with liquid cooling media adversely affect the overall weight of the assembly, resulting in reduced power density as a result. By contrast, direct convective cooling using the ambient air is frequently disadvantageous, in particular in mobile applications because of the possibly high humidity and because of foreign bodies possibly contained in the ambient air.

In the event that the active components of the electrical machine are not cooled directly convective, the resulting heat must, for example, be dissipated by utilizing the effect of heat conduction to a heat sink. Due to the less complex design, corresponding machine designs may be considerably lighter and also more robust than the machines with direct convective cooling. However, it can not be ruled out that the heat conducted via a path leading to the heat sink through various components of the machine can be broken down on this path and the like. heat-sensitive and possibly poorly heat-conductive components happens, which leads there to significant and possibly harmful increases in temperature. The said path leads from the heat-developing component, for example a conductor of a magnetic coil, over the insulation of the conductor, any existing additional paper insulation, not optimized for the heat conduction components and also not optimized for the heat conduction transitions between components. Especially with encapsulated electric machines without special, integrated cooling devices, as they are also used in the aforementioned mobile applications, so the heat must be removed via such paths with a variety of heat flow restricting properties. This leads to a possibly insufficient cooling effect.

It is therefore an object of the present invention to provide an alternative cooling option for an electrical machine.

This object is achieved by the electrical machine described in claim 1. The subclaims describe advantageous embodiments.

The electric machine comprises a first electromagnetically active component selected from a group of active components of the electric machine comprising a stator and a rotor, and a cooling system for cooling at least one of the active components. The active components are at least in the operating state of the electric machine rotatable relative to each other about a rotation axis. The stator comprises a first magnetic means, in particular a stator winding system, and the rotor comprises a second magnetic means, in particular a permanent magnet arrangement. In this case, the first and the second magnetic means are designed and arranged relative to one another such that they interact electromagnetically with one another in the operating state of the electric machine, so that the electric machine operates as an electric motor or as a generator depending on the operating state. This creates heat generated at the magnetic means in the operating state of the electrical machine.

The cooling system has a heat pipe arrangement with at least one first heat pipe with a thermal working medium. Each first heat pipe, in turn, has an evaporation section and a condensation section, wherein the respective evaporation section of the first heat pipe is thermally coupled to the selected first electromagnetically active component and in particular directly or indirectly to the first and second magnetic means of the selected first electromagnetically active component the respective condensation section of the first heat pipe is thermally coupled to a heat sink arrangement or coupled at least in the operating state, so that at least part of the heat generated in the operating state of the electrical machine on the magnetic means of the selected first electromagnetically active component heat can be dissipated via the first heat pipe to the heat sink assembly ,

The concept underlying the invention is therefore the use of heat pipes, via which a heat generated at a respective active component is dissipated to a heat sink. The proposed concept makes it possible to bridge the initially explained path of heat conduction between the heat source and the heat sink, which typically carries little thermally conductive components and junctions between components of the machine, without the complexity and weight of the assembly, especially in comparison with a system with pure liquid cooling, is significantly increased.

A heat pipe is known to be a closed system in which a thermal working medium can circulate, thereby changing its state of aggregation between a gaseous and a liquid state. The operation of a heat pipe is therefore based on a two-phase cooling, d. H. on a recognized comparatively efficient cooling method, which, for example, much more efficient than the pure convective cooling acts. Such a heat pipe has an evaporation section, which is thermally coupled to a component to be cooled, for example in the application presented here, a stator winding or a permanent magnet, so that heat from the respective component can reach the heat pipe via the evaporation section. This transfer of heat from the component into the heat pipe causes evaporation of the thermal working fluid in the heat pipe. The vaporized working fluid passes in the heat pipe to a condensation section of the heat pipe where it reverts to the liquid state, heat being dissipated to a heat sink thermally coupled to the condensation section. The liquid working medium passes through a dependent of the realization form of the heat pipe mechanism back to the evaporation section, where the cycle begins again. The result is that the coupled to the evaporation section component is cooled, the corresponding amount of heat is dissipated to the heat sink.

In a first embodiment, the selected first electromagnetically active component is the stator of the electrical machine, i. H. The cooling system is essentially a stator cooling system.

The magnetic means of the stator may be, for example, a stator winding system having one or a plurality of stator windings arranged one behind the other along a circumferential direction of the stator. Preferably, at least one first heat pipe is provided for each stator winding, wherein the evaporation section of each first heat pipe is thermally coupled to the respective stator winding. However, it may also be sufficient if such a first heat pipe is not provided for each individual stator winding but, for example, only for every second or third winding.

In a first embodiment of stator cooling, each first heat pipe of the heat pipe assembly is arranged to extend away from the stator in a first horizontal extension direction when the electric machine is in a predetermined standard orientation. The term "standard orientation" is defined in connection with the figures and explained in more detail. In anticipation of this, it should be noted that the orientation of the standard orientation is substantially related to the orientation of the axis of rotation of the rotor, where, for example, in a helicopter the standard orientation will be vertical, since the axis of rotation is vertically aligned, while the standard orientation in an aircraft Propeller drive will usually be horizontal. The essential point of the term of the standard orientation is only that it is always the same, d. H. independent of a current orientation of the electric machine, which ultimately depends on a current flight condition of the aircraft in which the engine is installed.

The direction of extension of a respective heat pipe is understood here and below to be the direction from the evaporation section to the condensation section of the respective heat pipe.

The first heat pipes preferably extend, when the electric machine is in the standard orientation, in a respective first horizontal direction away from the respective stator winding to which they are thermally coupled. The first horizontal direction may, for example, be oriented parallel to the axial direction of the electric machine. This typically applies to an electric machine installed in an aircraft, because there the axis of rotation of the electric motor and of the propeller are oriented horizontally. If the electric motor is installed in a helicopter, the axis of rotation can be oriented vertically. In this case, therefore, the horizontal direction would be oriented perpendicular to the axial direction.

The heat pipe arrangement preferably has, for each first heat pipe, a further heat pipe associated with the respective first heat pipe, with an evaporation section and a condensation section. The evaporation section of the respective further heat pipe is thermally coupled to the stator and in particular directly or indirectly coupled to the first magnetic means, so that at least a portion of the heat generated in the operating state of the electric machine to the first magnetic means via the respective further heat pipe to the heat sink assembly is deductible. In this case, the condensation section of the respective further heat pipe can be thermally coupled to the heat sink arrangement. The respective further heat pipe is arranged such that, when the electric machine is in the predetermined standard orientation, it extends away from the stator in a further horizontal extension direction, the first and the further horizontal extension direction of two heat pipes assigned to one another being opposite to one another.

The first heat pipe and the antiparallel, further heat pipe form a heat pipe pair, wherein the two heat pipes of a respective heat pipe pair are preferably thermally coupled to the same stator winding.

In the event that not only one, but a plurality of first heat pipes is provided, preferably for each of the first heat pipes, but ideally for each first heat pipe associated with the respective first heat pipe further heat pipe with an evaporation section and a condensation section would be present in each case a further heat pipe is assigned to a first heat pipe, so that they form a heat pipe pair. Preferably, the two heat pipes of a heat pipe pair are thermally coupled to the same stator winding. Furthermore, it would offer that each stator winding a heat pipe pair is provided.

The cooling concept of stator cooling therefore uses, for each stator winding, anti-parallel first and further heat pipes. The antiparallel, in the standard orientation horizontal arrangement of two heat pipes causes that the influence of gravity on the efficiency of the respective heat pipe is compensated. Both in ascent and descent and in the acceleration of the aircraft act gravitational forces and inertial forces on the heat pipes which influence the running in the respective heat pipe processes depending on the direction of action of the force supporting or inhibiting. Since with the antiparallel arrangement of two heat pipes and the intended flow directions of the liquid portions of the working media in the two heat pipes are antiparallel, the influences of said forces are compensated. The described arrangement thus causes such negative effects on the processes in a heat pipe to be compensated for by corresponding positive effects on the processes in an antiparallel arranged heat pipe, so that the cooling effect is largely independent of alignment or orientation of the machine and of accelerations, etc. ,

In a second embodiment of stator cooling, each first heat pipe of the heat pipe assembly is arranged such that, when the electric machine is in a predetermined standard orientation, the location of the thermal coupling of its condensation section with the heat sink assembly below, in particular vertically below, the location of the thermal coupling its evaporation section is located with the stator. In other words, in the standard orientation of the electric machine, the condensation section of the first heat pipe is below and in particular vertically below its evaporation section.

Generally, in the stator cooling, the evaporation section of the first heat pipe may be thermally coupled to the stator by means of a connector having a ceramic, electrically insulating and heat conductive material to realize the thermal coupling between the evaporation section of the respective first heat pipe and the stator. For example, AlN (aluminum nitride) or Al 2 O 3 (aluminum oxide) can be used as the material.

In a second embodiment, the selected first electromagnetically active component is the rotor of the electrical machine, i. H. the cooling system is essentially a rotor cooling. The rotor is non-rotatably connected to a shaft of the electric machine and each first heat pipe is in turn rotatably connected to the rotor and / or with the shaft so that it rotates with rotation of the rotor, so that upon rotation of the rotor and the shaft to a centrifugal force located in the respective heat pipe thermal working fluid of the heat pipe acts.

The magnetic means of the rotor has a plurality of magnetic field generating units, which are arranged one behind the other along a circumferential direction of the rotor, wherein preferably at least one first heat pipe is assigned to each magnetic field generating unit. In this case, the evaporation section of a respective first heat pipe is thermally coupled to the respective associated magnetic field generating unit. The magnetic field generating units may be, for example, permanent magnets or energizable coils.

In the case of rotor cooling, each first heat pipe is arranged and configured such that upon rotation the evaporation section of a respective first heat pipe describes a circle CV coaxial with the rotor and the condensation section of a respective first heat pipe describes a circle CK coaxial with the rotor. Here, the radius of the circle CV is greater than the radius of the circle CK and the intersections of the circles CK and CV with the axis of rotation are axially spaced from each other.

This geometry means that the centrifugal force acting upon rotation on the first heat pipe and on the thermal working fluid therein has a component that carries the working fluid from the condensation section toward the evaporation section.

In particular, each first heat pipe has at least one intermediate section which lies between the evaporation section and the condensation section of the respective first heat pipe and which is provided to at least in the operating state of the electric machine, the thermal working medium of the respective first heat pipe in substantially liquid form of its condensation section its evaporation section. In this case, each first heat pipe is arranged on the shaft such that at least a part of the intermediate section is oriented such that it encloses an angle A with 0 ° <A <90 ° with the axis of rotation, so that this part of the intermediate section upon rotation of the rotor and the shaft and the first heat pipe describes a mantle of an imaginary symmetrical truncated cone. The angle A may be, for example, 30 °, but ultimately depends on the operating conditions of the electric machine.

The rotating first heat pipe therefore rotates together with the shaft or with the rotor. Because the intermediate section Z encloses an angle of, for example, 30 ° with the axis of rotation, the centrifugal force or the component of the force resulting from the angle A in the flow direction can act on the liquid working medium in such a way that it is transported from the condensation section to the evaporation section , Furthermore, the centrifugal force or the corresponding component of the force acts in such a way that a mixing of the liquid and the gaseous phase of the working medium is reduced, so that the heat conductivity of the heat pipe increases.

The heat pipe assembly has, in a first embodiment of the rotor cooling, a plurality of first heat pipes arranged along a circumference of a first imaginary circle C1 coaxial with the rotor such that the evaporation sections of the first heat pipes are arranged along a circumference of the circle CV, the condensation sections the first heat pipes along a circumference of the circle CK are arranged.

Alternative:

The heat pipe assembly has only a first heat pipe in a second embodiment of the rotor cooling. The first heat pipe is arranged coaxially with the rotor and has a radially inner region and a radially outer region. The radially outer region of the first heat pipe forms at least one channel, via which, at least in the operating state of the electric machine, the thermal working medium of the first heat pipe is guided in a substantially liquid form from the condensation section to the evaporation section. At least in the operating state of the electric machine, the thermal working medium of the first heat pipe is guided in a substantially gaseous state from the evaporation section to the condensation section via the radially inner region.

Advantageously, the shaft has such a shape at least in a partial region between the location of the thermal coupling of the evaporation section of the first heat pipe or the shaft with the second magnetic means and the location of the thermal coupling of the condensation section of the first heat pipe and the shaft with the heat sink arrangement on, for example, the shape of a truncated cone whose axis of symmetry lies on the axis of rotation, that the channel at least partially encloses an angle A with 0 ° <A <90 ° with the axis of rotation.

The shaft and in particular its part formed as a first heat pipe portion may preferably be hollow. This should in particular include that there is no partition wall between the radially outer and the radially inner region.

As an alternative to using the shaft as a heat pipe, the then separate first heat pipes may be fastened to the shaft in the above-described form, so that they may rotate with it, and in particular the inclined intermediate section so that the centrifugal force acts on the liquid working medium.

In the second embodiment of the rotor cooling, each channel may be formed by a tubular conduit.

Alternatively, in the second embodiment of the rotor cooling system, each channel may be formed or delimited by two guide plates which are arranged one behind the other along the longitudinal extent of the shaft along a wall of the shaft and in the radial direction. In contrast to the variant with pipe-like lines is in the variant with baffles no physical separation between the inner region and the outer region of the first heat pipe.

Both in the case of rotor cooling and for stator cooling, the heat sink assembly may comprise at least one heat exchanger. The heat exchanger is arranged in a spatial region through which a secondary cooling medium, in particular air, can flow in the vicinity of the electrical machine. In an advantageous application, the electrical machine is configured as an electric motor in a nacelle of a propeller drive of an aircraft, the nacelle having a duct system for conducting ambient air into which an air flow, in particular an air flow generated at least partially by the propeller, is introduced, and wherein the heat exchanger is arranged in the channel system. Preferably, the heat sink assembly includes a plurality of heat exchangers disposed at suitable positions in the ducting system and thermally coupled to respective heat pipes to effect most efficient cooling of the stator or rotor.

Preferably, the cooling system is so pronounced that both the stator and the rotor are each cooled by means of the heat pipe arrangements described above. Thus, a second electromagnetically active component of the electrical machine is selected from the group of active components such that the first and second electromagnetically active components are different. The heat pipe assembly of the cooling system has at least a second heat pipe with a thermal working fluid, each second heat pipe having an evaporation section and a condensation section, wherein the respective evaporation section of the second heat pipe thermally couples with the selected second electromagnetically active component, and more particularly directly or indirectly with the magnetic means the selected second electromagnetically active component is coupled and the respective condensation section of the second heat pipe with the heat sink assembly is thermally coupled or at least coupled in the operating state, so that at least a portion of the heat generated in the operating state of the electric machine at the magnetic means of the selected second electromagnetically active component heat is dissipatable via the second heat pipe to the heat sink assembly.

In the preferred embodiment, the cooling system includes at least one of the heat pipe pairs described above, which is in thermal contact with the stator of the engine, and a rotating heat pipe for cooling the rotor. The two heat pipes of the heat pipe pair of the stator are arranged horizontally and antiparallel to each other, whereby it is achieved that different, the efficiency of these two heat pipes influencing force effects are compensated. The heat pipe of the rotor, in contrast, is designed as a heat pipe co-rotating with the rotor, which also has a conical shape. As a result, during rotation, the liquid phase of the working medium of the heat pipe is transported from the condensation section to the evaporation section.

Further advantages and embodiments will become apparent from the drawings and the corresponding description.

In the following the invention and exemplary embodiments will be explained in more detail with reference to drawings. Identical components are identified in different figures by the same reference numerals.

Show it:

1 a nacelle of an aircraft with an electric motor and a rotor cooling and with a stator cooling in a first embodiment,

2 the nacelle of the aircraft with electric motor and rotor cooling and with the stator cooling in a second embodiment,.

3 a first embodiment of a rotor cooling,

4 a cross section of a first variant of the first embodiment of the rotor cooling,

5 a cross section of a second variant of the first embodiment of the rotor cooling,

6 a second embodiment of a rotor cooling,

7 a variant of the first embodiment of the rotor cooling.

It should be noted that terms such as "axial" and "radial" refer to the shaft or axle used in the respective figure or in the example described in each case. In other words, the directions always relate axially and radially to an axis of rotation of the rotor.

Terms such as "top", "bottom", "above", "below" etc. refer to the direction of the gravitational effect, which is symbolized in the figures where necessary with an arrow marked "g". An object located "above" is therefore located at a greater distance from the earth's surface than an object "below". Analogously, the terms "vertical" and "horizontal" refer to the direction of the gravitational effect.

Finally, the term "standard orientation" of the electric machine and in particular of the rotor and the stator of the electric machine designates the orientation in which the electric machine is aligned when it or the entire system in which it is installed is not in operation, for example. during or immediately after installation of the machine in the overall system. The standard orientation is usually horizontal or vertical and can be defined, for example, with the aid of the orientation of the axis of rotation of the rotor. Accordingly, with horizontal or vertical orientation of the axis of rotation, the standard orientation is substantially horizontal or vertical. The standard orientation may differ from a current orientation of the electric machine, for example when the electric machine is installed in an aircraft. While, for example, the current orientation of the electric machine permanently installed in the aircraft changes when cornering, climbing or descending, the defined standard orientation remains unaffected. In this case, the standard orientation may, for example, be the orientation of the electric machine or the axis of rotation when the aircraft is stationary on the ground. It is neglected that an aircraft or its longitudinal axis is often inclined when the plane is stationary on the ground or only on the ground, slightly inclined to the horizontal.

Preferably, the standard orientation is that orientation in which the electric machine is predominantly located during a typical flight and during normal use. Experience shows that this is a horizontal orientation for an aircraft and a vertical orientation for a helicopter.

In the following it is assumed in all figures that the electrical machine is in the standard orientation, even if this is not explicitly mentioned in connection with the respective figure.

The 1 shows by way of example and simplified a cross section of a part of a nacelle 10 a not further shown aircraft. The gondola 10 has a propeller 11 on, with the help of a wave 130 is set in rotation. In the gondola 10 is also a channel system 12 formed, which can be flowed through by ambient air. In particular, the propeller 11 and the channel system 12 designed and arranged to one another such that a by rotation of the propeller 11 generated airflow 13 at least partially into the sewer system 12 passes and flows through this. The channel system 12 can also be at the gondola 10 be arranged that the airflow 13 in the canal system 12 is at least partially generated due to movement of the aircraft relative to the surrounding air, ie, as a kind of wind.

The propeller 11 or the wave 130 is formed by an electric motor designed as an electric motor 100 driven. It should be noted that the electric machine 100 basically can be operated as a generator in a similar structure. It should also be noted that the structure of the machine described below is purely exemplary. It can be assumed as known that depending on the design of the electric machine as a generator or as an electric motor and / or as, for example. Radial or axial flow machine with a formed as an internal or external rotor rotor, etc., the various components of the machine may be arranged differently can.

The electric motor 100 has a stator 110 and a rotor formed as an inner rotor 120 on, with the rotor 120 inside the stator 110 is arranged and in the operating state of the electrical machine 100 rotated about a rotation axis R. The rotor 120 is rotatable with the shaft 130 connected, leaving a rotation of the rotor 120 over the wave 130 on the propeller 11 of the aircraft is transferable.

The stator 110 has a first magnetic means 111 which may, for example, include a plurality of stator windings. Each of the windings 111 is formed by an electrical conductor, which is in the operating state of the electric machine 100 an electric current flows through it, so that magnetic fields are generated. The stator windings 111 are in a circumferential direction of the stator 110 seen consecutively.

The rotor 120 has a second magnetic means 121 on which, for example, a plurality of permanent magnets or excited or can include excitable windings. In the following, it is assumed by way of example that they are permanent magnets 121 is. The permanent magnets 121 are in a circumferential direction of the rotor 120 seen consecutively.

The first and the second magnetic means 111 . 121 or the stator windings 111 and the permanent magnets 121 are formed and arranged to each other that they are in the operating state of the electrical machine 100 electromagnetically interact with each other, so that the machine 100 depending on the configuration works as an electric motor or as a generator. This concept including the conditions for the formation and arrangement of the magnetic means 111 . 121 or from Stator 110 and rotor 120 are known per se and are therefore not explained in detail below. It is merely mentioned that for operating the electric machine 100 as an electric motor, the stator windings 111 be subjected to an electric current by means of a power source, not shown, which causes the windings 111 generate corresponding magnetic fields, which with the magnetic fields of the permanent magnets 121 of the rotor 120 in electromagnetic interaction. As is known, this results in that, with suitable design and arrangement of said components relative to one another, the rotor 120 and with it the wave 130 as well as the propeller 11 be set in rotation.

In the operating state of the electric machine 100 is applied both to the stator windings 111 as well as the permanent magnet 121 Heat is generated. The electric machine 100 therefore has a cooling system 140 for cooling the stator 110 and / or the rotor 120 or for cooling the respective magnetic means 111 respectively. 121 ,

In a first embodiment of a stator cooling system, the cooling system 140 for cooling the stator 110 and the stator windings 111 a heat pipe assembly having at least a first heat pipe 141 with an evaporation section V and a condensation section K, whose evaporation section V is thermally connected to a stator winding 111 is coupled. Although due to the typically high thermal conductivity of such stator windings 111 electrical conductors used assume that it is using only one heat pipe 141 to a sufficient homogenization of the heat distribution in the stator windings 111 comes, but is preferably not just one, but each stator winding 111 with at least a first heat pipe 141 thermally coupled. In the in 1 illustrated embodiment, the heat pipe assembly in extension of this basic idea for each stator winding 111 two such first heat pipes 141 which are radially spaced from each other at the respective stator winding 111 are arranged.

Preferably, the heat pipe arrangement in the first embodiment of the stator cooling at least one further heat pipe 142 which also has an evaporation section V and a condensation section K, the evaporation section V of the further heat pipe 142 also thermally with one of the stator windings 111 is coupled. Preferably, however, not only one but each stator winding is also here 111 with at least one other heat pipe 142 thermally coupled. In the in 1 illustrated embodiment, the heat pipe assembly in extension of this basic idea for each stator winding 111 two such further heat pipes 142 on, which may also be arranged radially spaced from each other.

The thermal coupling of the first and the other heat pipes 141 . 142 or their evaporation sections V to the respective stator winding 111 done with the help of connectors 149 , The connectors 149 have ideally a ceramic material which is electrically insulating and in particular thermally conductive. Suitable materials are, for example, AlN (aluminum nitride) or Al 2 O 3 (aluminum oxide). The connectors 149 are in direct thermal contact with the stator windings 111 and with the evaporation section V of the respective first and further heat pipe 141 . 142 to which they are thermally coupled.

The condensation sections K of the first heat pipes 141 are thermal with first heat exchangers 151 a heat sink assembly 150 coupled so that at least part of the heat from the respective first heat pipe 141 via its evaporation section V from the stator winding 111 was received, via the condensation sections K to the heat sink assembly 150 or to the first heat exchanger 151 can be dissipated. Analogously, the condensation sections K of the further heat pipes 142 thermally with other heat exchangers 152 the heat sink assembly 150 coupled so that at least part of the heat from each other's heat pipe 142 via its evaporation section V from the stator winding 111 was received, via the condensation sections K to the heat sink assembly 150 or to the other heat exchanger 152 can be dissipated. As mentioned in the introduction, the working fluid condenses in the respective heat pipe 141 . 142 and returns to the evaporation section V. The heat exchanger 151 . 152 can be designed as a plate heat exchanger and in the duct system 12 the gondola 10 be arranged so that they are from the typically cool airflow 13 in the channel system 12 flows around and cooled accordingly.

The first heat pipes 141 For example, in the first embodiment of stator cooling, they are preferably arranged to be in the standard orientation of the electric machine 100 each in a first horizontal, axial extension direction from the stator 110 or of the respective stator winding 111 extend away. It is used as extension direction of a respective heat pipe 141 . 142 the direction from the evaporation section V to the condensation section K of the respective heat pipe 141 . 142 Understood. The evaporation section V and the condensation section K of a respective heat pipe 141 are therefore spaced apart in the axial direction.

The other heat pipes 142 For their part, they are arranged in such a way that they move when the electric machine 100 is in the predetermined standard orientation, in a further horizontal, axial extension direction from the stator 110 extend away. It is particularly true that the first and the further horizontal direction of the extension are mutually opposed or antiparallel to each other.

The cooling concept of the first embodiment of the stator cooling thus used for each stator winding 111 antiparallel arranged first and further heat pipes 141 . 142 , The antiparallel, in the standard orientation horizontal arrangement of two heat pipes 141 . 142 causes the influence of gravity on the efficiency of the respective heat pipe to be compensated. Both in ascent and descent and in the acceleration of the aircraft gravitational forces and inertial forces act on the heat pipes 141 . 142 that in each heat pipe 141 . 142 depending on the direction of action of the force positive or negative influence. This is how the processes and thus the efficiency of a heat pipe become 141 . 142 In particular, it is adversely affected when the direction of action of the force is oriented counter to the direction of flow of the liquid working medium defined by the arrangement of evaporation section V and condensation section K. Because with the antiparallel arrangement of two heat pipes 141 . 142 also the intended flow directions of the liquid working media in the two heat pipes 141 . 142 are antiparallel, the influences of these forces are compensated. The described arrangement thus causes such negative effects on the processes in a heat pipe 141 . 142 by corresponding positive effects on the processes in an antiparallel arranged heat pipe 142 . 141 be compensated.

A second embodiment of the stator cooling, which in the 2 is different from the first embodiment, in particular in the arrangement of the heat pipes of the heat pipe assembly.

Also in the second embodiment of the stator cooling, the cooling system 140 for cooling the stator 110 and the stator windings 111 a heat pipe assembly having at least a first heat pipe 141 with an evaporation section V and a condensation section K, whose evaporation section V is thermally connected to a stator winding 111 is coupled. Although this is due to the typically high thermal conductivity for such stator windings 111 electrical conductors used assume that it is using only one heat pipe 141 to a sufficient homogenization of the heat distribution in the stator windings 111 comes, but is preferably not just one, but each stator winding 111 with at least a first heat pipe 141 thermally coupled, again the already described connector 149 Find use.

The condensation sections K of the first heat pipes 141 are in turn thermal with first heat exchangers 151 the heat sink assembly 150 coupled so that at least part of the heat from the respective first heat pipe 141 via its evaporation section V from the stator winding 111 was received, via the condensation sections K to the heat sink assembly 150 or to the first heat exchanger 151 can be dissipated. The example. Designed as a plate heat exchanger heat exchanger 151 can in the channel system 12 the gondola 10 be arranged so that they are from the typically cool airflow 13 in the canal system 12 flows around and cooled accordingly.

In contrast to the first embodiment of the stator cooling, the first heat pipes extend 141 however, if the electric machine 100 in the standard orientation, in the vertical direction from the location of the thermal coupling of the evaporation section K with the stator winding 111 to the heat exchanger 151 ie the heat pipes 141 are arranged such that the evaporation section V of a respective heat pipe 141 located above its condensation section K. Accordingly, the heat exchanger 151 below the stator 110 arranged.

As in the first embodiment of the stator cooling, further heat pipes can also be used in the second embodiment 142 be provided. These also extend in the vertical direction and their condensation sections K are thermal with the heat exchangers 151 coupled. by virtue of the substantially same orientation or extension direction of the first and the further heat pipes 141 . 142 Although in the second embodiment does not result in the advantageous effect of the compensation of negative influences of different force effects. The vertical alignment of all heat pipes 141 . 142 However, it has a positive effect on the efficiency of the processes taking place in the heat pipes. Furthermore, additionally provided, further heat pipes 142 However, one effect with the number of available heat pipes 141 . 142 increasing cooling capacity.

Additionally or alternatively, in connection with the two embodiments in the 1 and 2 described cooling of the stator 110 can also be the rotor 120 be cooled by means of a heat pipe arrangement. This rotor cooling is shown in both figures in substantially the same way, the following description being based essentially on the 1 refers.

The rotation with the shaft 130 connected rotor 120 has magnetic means 121 on, for example, a plurality of circumferentially of the rotor 120 seen consecutively arranged permanent magnets 121 , For cooling the rotor 120 or the magnetic means 121 has the cooling system 140 a heat pipe assembly with at least one heat pipe 143 on which rotatably with the rotor 120 or with the wave 130 is connected, so that it rotates by rotor 120 and wave 130 co-rotated, which is why it can be called a "rotating heat pipe". The heat pipe 143 has an evaporation section V, a condensation section K, and an intermediate section Z located between the evaporation section V and the condensation section K. The evaporation section V is thermal at a corresponding location with the magnetic means 121 of the rotor 120 or with a permanent magnet 121 coupled. The condensation section K is in turn at a corresponding location thermally with a heat exchanger 153 the heat sink assembly 150 coupled. The intermediate section Z is provided to at least in the operating state of the electric machine 100 the (not shown) thermal working fluid of the heat pipe 143 in substantially liquid form from the condensation section K to the evaporation section V to lead.

The heat pipe 143 is arranged and configured such that the location of the thermal coupling of the evaporation section V of the heat pipe 143 with the permanent magnet 121 or with the corresponding connector 149 during rotation of the shaft 130 with the heat pipe 143 describes a circle CV, while the location of the thermal coupling of the condensation section K of the heat pipe 143 with the heat sink assembly 150 or the heat exchanger 153 on rotation describes a circle CK. The radius RCV of the circle CV is greater than the RCK of the circle CK, ie RCV> RCK. Furthermore, the two mentioned places of the thermal coupling of the heat pipe 143 at the permanent magnets 121 or to the heat exchanger 153 , ie the intersections of the circles CK and CV with the axis of rotation R, spaced apart in the axial direction. This arrangement and formation of the heat pipe 143 causes the heat pipe 143 like that on the wave 130 is arranged, that at least a part of the intermediate section Z is oriented such that it forms an angle A with 0 ° <A <90 °, for example. A = 30 °, with the rotation axis R, so that this conical part of the intermediate section Z at Rotation of the rotor 120 and the wave 130 and consequently the heat pipe 143 describes a coat of an imaginary symmetrical truncated cone or painted over. The axis of symmetry of the truncated cone lies on the axis of rotation R.

The particularly advantageous effect of the described arrangement and in particular the angled portion of the intermediate section results from the fact that the centrifugal force occurring during the rotation of the heat pipe 143 and in particular to the liquid working medium located therein so as to convey, due to the geometry of said liquid working medium, to the vaporizing section V.

A first embodiment of a rotor cooling is in 3 shown. There are in the 3 only the wave 130 with the rotor 120 as well as the heat pipe 143 while other components such as the stator and parts of the nacelle are not shown. The heat pipe 143 has in the intermediate section Z a variety of example. Tube-like lines 143 ' each formed to the thermal working fluid in liquid form from the condensation section K of the first heat pipe 143 to transport to its evaporation section V. This advantageously affects the described shape of the heat pipe 143 from, since the liquid working medium due to the arranged with respect to the rotation axis R at the angle A portion of the intermediate section Z by the action of centrifugal force through the lines 143 ' is transported. The at the evaporation section V of the heat pipe 143 vaporized working medium is over another line 143 '' led back to the condensation section K, the further line 143 '' in the radial direction within the arrangement of lines 143 ' lies, ie in the radially inner region 134 of the heat pipe 143 ,

The pipe-like pipes 143 ' are in a radially outer area 133 of the heat pipe 143 arranged, for example, inside a radial outer wall 132 of the heat pipe 143 , This is in the in 4 shown cross section indicated on the in 3 with "X" is referenced. The liquid working fluid moves in the heat pipes 143 from the condensation sections K to the evaporation sections V, while the gaseous working medium extends over a radially inner region 134 of the heat pipe 143 and there over the line 143 '' moved from the evaporation sections V to the condensation sections K.

Preferably several or even all of the permanent magnets 121 each with such a first line 143 ' of the single heat pipe 143 thermally coupled to the first embodiment of the rotor cooling, ie, the heat pipe assembly comprises a plurality of lines 143 ' each having an evaporation section V, a condensation section K and an intermediate section Z. However, ideally, it is just another common conduit 143 '' intended.

Upon rotation of the shaft 130 is due to the density ratios of the gaseous or liquid thermal working medium of the liquid state located in the proportion of the working medium in the radially outer region 133 of the heat pipe 143 pressed, ie to the wall 132 , In contrast, the part of the working medium in the gaseous state automatically becomes in the radially inner region 134 are located. It can therefore in a variant on a partition o.ä. between the areas 133 . 134 be dispensed with gaseous or liquid working fluid, ie the lines 143 ' do not have to be tube-like. The wires 143 ' On the other hand, they can act as channels in the radially outer area 133 be formed over the at least in the operating state of the electric machine 100 the thermal working medium of the first heat pipe 143 is conducted in a substantially liquid form from the condensation section K to the evaporation section V. Over the radially inner area 134 passes the thermal working medium of the first heat pipe 143 in a substantially gaseous state from the evaporation section V back to the condensation section K. To the liquid working medium in the respective channel 143 ' along the wall 132 lead to, for example, corresponding baffles 144 be provided, each extending in the axial and in the radial direction, so that the channels 143 ' no closed pipes or similar form. This is in the in 5 shown cross section indicated on the in 3 with "X" is referred to, for the sake of clarity, only a few of the baffles 144 are provided with reference numerals. The difference between the two in the 4 and 5 indicated variants of the first embodiment of the rotor cooling is therefore that the lines 143 ' in the first variant actually tube-like are formed, while the thermal working medium circulates freely in the second variant and in particular manages without closed in the radial direction tubes. There are in the second variant only optional the baffles described 144 used the local channels 143 ' Limit in the circumferential direction and thus avoid any shear flow interactions between the liquid and gaseous phase of the working medium. The in the 4 and 5 indicated dashed lines symbolize the transition between the inner region 134 and the outer area 133 of the heat pipe 143 ,

In one in the 6 indicated second embodiment of the rotor cooling is a plurality of first heat pipes 143 intended. These are so along a circumference of a first imaginary, to the rotor 120 arranged coaxial circuit C1, that their evaporation sections V along a circumference of the already introduced circle CV and their condensation sections K along a circumference of the circle CK are arranged, the circles CV, CK are again axially spaced from each other and different radii RCV, RCK with RCV> RCK have. Unlike the wires 143 ' The first embodiment of the rotor cooling is every first heat pipe 143 a closed system, ie in every heat pipe 143 circulates a thermal working medium, wherein in different first heat pipes 143 circulating working media do not come into contact with each other. In contrast to the first embodiment of the rotor cooling, the vaporized working medium does not reach beyond the radially inner region 134 back to the condensation section K, but over there respective heat pipe 143 even.

Preferably, several or even all of the permanent magnets 121 each with one of the heat pipes 143 thermally coupled to the second embodiment of the rotor cooling.

During the evaporation sections V of the heat pipes 143 heat from the permanent magnets via the thermal couplings 121 can accommodate the condensation section K of the heat pipes 143 in both embodiments, the rotor cooling again thermally with one or more first heat exchangers 153 the heat sink assembly 150 coupled, so that at least part of the heat from the respective heat pipe 143 via its evaporation section V from the thermally coupled permanent magnet 121 was received, via the condensation sections K to the heat sink assembly 150 or to the heat exchanger 153 can be dissipated. The heat exchangers 153 are as well as the heat pipes 143 rotatably with the shaft 130 connected, rotate during rotation of the shaft 130 so with. The example. Designed as a plate heat exchanger heat exchanger 153 can, as in the 1 and 2 shown in the channel system 12 the gondola 10 be arranged so that they are from the typically cool air flow in the duct system 12 flows around and cooled accordingly. In addition, the co-rotating heat exchangers 153 advantageously be arranged and shaped so that they cause a suction on rotation, the air flow 13 in the canal system 12 supported or even generated.

Both in the first and in the second embodiment of the rotor cooling, the heat pipe arrangement for cooling the rotor 120 as part of the wave 130 be educated. This is exemplary in the 7 illustrated for the first embodiment of the rotor cooling. This is the wave 130 in a corresponding area 131 designed as a hollow shaft. The area 131 the wave 130 acts as the first heat pipe 143 , according to the first embodiment of the rotor cooling, or the area 131 includes the large number of heat pipes 143 , according to the second embodiment of the rotor cooling. Only exemplary is this variant of the wave 130 in 7 illustrated for the first embodiment of the rotor cooling.

As shown in some of the figures, the heat pipe assembly may include both heat pipes 141 . 142 for cooling the stator 110 as well as heat pipes 143 for cooling the rotor 120 exhibit. This combined cooling for rotor 120 and for Stator 110 represents the preferred embodiment, since both active components 110 . 120 can be cooled efficiently. However, it is also conceivable only the stator 110 or just the rotor 120 with the help of heat pipes 141 . 142 . 143 to cool and use a different cooling method for cooling the other component.

In connection with the figures was the operation of the electric machine 100 described as an electric motor. However, it is conceivable that explained cooling concept with heat pipes on a working as a generator electric machine 100 to transfer, as mentioned in principle generator and electric motor are basically the same. To operate the electric machine 100 as generator the rotor becomes 120 over the wave 130 set in rotation by means of a drive, not shown in the figures. The magnetic fields of the second magnetic means 121 or the permanent magpie 121 of the rotor 120 rotate with the rotor 120 and relative to the stator windings 111 of the stator 110 , This is known to cause in the stator windings 111 electrical voltages are induced, which are finally not shown electrical consumers fed.

Claims (16)

Electric machine ( 100 ) with a first electromagnetically active component ( 110 . 120 ), which consists of a stator ( 110 ) and a rotor ( 120 ) comprehensive group of active components of the electric machine ( 100 ) and with a cooling system ( 140 ) for cooling at least one of the active components ( 110 . 120 ), - wherein the stator ( 110 ) a first magnetic means ( 111 ) and the rotor ( 120 ) a second magnetic means ( 121 ), the first ( 111 ) and the second ( 121 ) magnetic means are formed and arranged to each other, that they in the operating state of the electrical machine ( 100 ) interact electromagnetically with each other, and wherein at the magnetic means ( 111 . 121 ) in the operating state of the electrical machine ( 100 ) Heat is generated, and - whereby the cooling system ( 140 ) a heat pipe arrangement with at least one first heat pipe ( 141 . 143 ) having a thermal working medium, each first heat pipe ( 141 . 143 ) has an evaporation section and a condensation section, wherein the respective evaporation section is thermally connected to the first electromagnetically active component ( 110 . 120 ) and in particular directly or indirectly with the magnetic means ( 111 . 121 ) of the first electromagnetically active component ( 110 . 120 ) and the respective condensation section with a heat sink arrangement ( 150 ) is thermally coupled, so that at least a part of the operating state of the electrical machine ( 100 ) at the magnetic means ( 111 . 121 ) of the first electromagnetically active component ( 110 . 120 ) generated heat over the first heat pipe ( 141 . 143 ) to the heat sink assembly ( 150 ) is dissipatable. Electric machine ( 100 ) according to claim 1, characterized in that the selected first electromagnetically active component of the stator ( 110 ). Electric machine ( 100 ) according to claim 2, characterized in that each first heat pipe ( 141 ) of the heat pipe assembly is arranged such that, when the electric machine ( 100 ) is in a predetermined standard orientation, in a first horizontal extension direction from the stator ( 110 ) extends away. Electric machine ( 100 ) according to claim 3, characterized in that the heat pipe arrangement ( 140 ) a first heat pipe ( 141 ) associated further heat pipe ( 142 ) having an evaporation section and a condensation section, wherein - the evaporation section of the further heat pipe ( 142 ) thermally with the stator ( 110 ) and in particular directly or indirectly with the first magnetic means ( 111 ) is coupled, so that at least a part of the operating state of the electrical machine ( 100 ) on the first magnetic means ( 111 ) resulting heat over the further heat pipe ( 142 ) to the heat sink assembly ( 150 ) is dissipatable, the condensation section of the further heat pipe ( 142 ) with the heat sink arrangement ( 150 ) is thermally coupled, - the further heat pipe ( 142 ) is arranged such that, when the electric machine is in the predetermined standard orientation, in a further horizontal extension direction from the stator ( 110 ), wherein the first and the further horizontal extension direction of the associated heat pipes ( 141 . 142 ) are opposite to each other. Electric machine ( 100 ) according to claim 2, characterized in that each first heat pipe ( 141 ) of the heat pipe assembly is arranged such that when the electric machine ( 100 ) in a given standard orientation, the location of the thermal coupling of its condensation section with the heat sink arrangement ( 150 ) below, in particular vertically below, the location of the thermal coupling of its evaporation section with the stator ( 110 ) is located. Electric machine ( 100 ) according to one of claims 2 to 5, characterized in that the evaporation section of the first heat pipe ( 141 ) by means of a connector ( 149 ) with a ceramic, electrically insulating and heat-conducting material with the stator ( 110 ) is thermally coupled to the thermal coupling between the evaporation section of the respective first heat pipe ( 141 ) with the stator ( 110 ) to realize. Electric machine ( 100 ) according to claim 1, characterized in that the selected first electromagnetically active component of the rotor ( 120 ), wherein - the rotor ( 120 ) rotatably with a shaft ( 130 ) of the electric machine ( 100 ) and - every first heat pipe ( 143 ) rotatably with the rotor ( 120 ) and / or with the shaft ( 130 ) and upon rotation of the rotor ( 120 ) co-rotated. Electric machine ( 100 ) according to claim 7, characterized in that each first heat pipe ( 143 ) is arranged and configured such that - during rotation, the evaporation section of a respective first heat pipe ( 143 ) one to the rotor ( 120 ) describes the coaxial circuit CV, - in rotation, the condensation section of a respective first heat pipe ( 143 ) one to the rotor ( 120 ) describes coaxial circle CK, wherein - the radius of the circle CV is greater than the radius of the circle CK and - the intersections of the circles CK and CV are axially spaced from each other with the axis of rotation. Electric machine ( 100 ) according to one of claims 7 to 8, characterized in that each first heat pipe ( 143 ) has at least one intermediate section, which between the evaporation section and the condensation section of the respective first heat pipe ( 143 ) and - which is provided to at least in the operating state of the electric machine ( 100 ) the thermal working medium of the respective first heat pipe ( 143 ) in substantially liquid form from its condensation section to its evaporation section, wherein - each first heat pipe ( 143 ) is arranged such that at least a part of the intermediate section encloses an angle A with 0 ° <A <90 ° with the axis of rotation, so that this part of the intermediate section upon rotation of the rotor ( 120 ) and the first heat pipe ( 143 ) describes a mantle of an imaginary symmetrical truncated cone. Electric machine ( 100 ) according to one of claims 7 to 9, characterized in that the heat pipe arrangement a plurality of first heat pipes ( 143 ), which in such a way along a circumference of a first imaginary, to the rotor ( 120 ) are arranged coaxial circle C1, that - the evaporation sections of the first heat pipes ( 143 ) are arranged along a circumference of the circle CV, - the condensation sections of the first heat pipes ( 143 ) are arranged along a circumference of the circle CK. Electric machine ( 100 ) according to one of claims 7 to 9, characterized in that the first heat pipe ( 143 ) coaxial with the rotor ( 120 ) is arranged and a radially inner region ( 134 ) and a radially outer area ( 133 ), wherein - the radially outer region ( 133 ) of the first heat pipe ( 143 ) at least one channel ( 143 ' ) forms over the at least in the operating state of the electric machine ( 100 ) the thermal working medium of the first heat pipe ( 143 ) in substantially liquid form from the condensation section to the evaporation section of the first heat pipe ( 143 ), and - over the radially inner region ( 134 ) at least in the operating state of the electric machine ( 100 ) the thermal working medium of the first heat pipe ( 143 ) in a substantially gaseous state from the evaporation section to Condensation section of the first heat pipe ( 143 ) to be led. Electric machine ( 100 ) according to claim 11, characterized in that the shaft ( 130 ) at least in a subarea ( 131 ) between the location of the thermal coupling of the evaporation section of the first heat pipe ( 143 ) with the second magnetic means ( 121 ) and the location of the thermal coupling of the condensation section of the first heat pipe ( 143 ) with the heat sink arrangement ( 150 ) has a shape such that the channel ( 143 ' ) at least partially encloses an angle A with 0 ° <A <90 ° with the axis of rotation. Electric machine ( 100 ) according to one of claims 11 to 12, characterized in that each channel ( 143 ' ) is formed by a tubular conduit ( 143 ' ). Electric machine ( 100 ) according to one of claims 11 to 12, characterized in that each channel ( 143 ' ) is formed by two in the circumferential direction of the shaft arranged one behind the other, along the longitudinal extent of the shaft along a wall of the shaft and in the radial direction extending baffles ( 144 ). Electric machine ( 100 ) according to one of claims 1 to 14, characterized in that the heat sink arrangement ( 150 ) at least one heat exchanger ( 151 . 152 . 153 ), in each case in one of a secondary cooling medium, in particular air, through-flowable space in the vicinity of the electrical machine ( 100 ), wherein the electric machine ( 100 ) in a gondola ( 10 ) of a propeller drive of an aircraft, wherein the nacelle ( 10 ) a channel system ( 12 ) for conducting ambient air into which a stream of air ( 13 ), in particular an at least partially from the propeller ( 11 ) generated air stream ( 13 ), and wherein the heat exchanger ( 151 . 152 . 153 ) in the channel system ( 12 ) is arranged. Electric machine ( 100 ) according to one of claims 1 to 15, characterized in that a second electromagnetically active component ( 120 . 110 ) of the electric machine ( 100 ) of the group of active components ( 110 . 120 ) is selected, that the first ( 110 . 120 ) and the second ( 120 . 110 ) Electromagnetically active component are different, wherein the heat pipe arrangement of the cooling system ( 140 ) at least a second heat pipe ( 143 . 141 ) having a thermal working medium, each second heat pipe ( 143 . 141 ) has an evaporation section and a condensation section, wherein the respective evaporation section is thermally connected to the second electromagnetically active component ( 120 . 110 ) and in particular directly or indirectly with the magnetic means ( 121 . 111 ) of the second electromagnetically active component ( 120 . 110 ) and the respective condensation section with the heat sink arrangement ( 150 ) is thermally coupled, so that at least a part of the operating state of the electrical machine ( 100 ) at the magnetic means ( 121 . 111 ) of the second electromagnetically active component ( 110 . 120 ) generated heat via the second heat pipe ( 143 . 141 ) to the heat sink assembly ( 150 ) is dissipatable.

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