DE102019217680A1 - Air supply device - Google Patents

Abstract

The invention relates to an air supply device (1) with an electric motor drive (2) which comprises a rotor (3) with at least one magnet (9), and with a cooling device (13) To improve its efficiency and / or its service life, the cooling device (13) on the outside of the magnet (9) has a cooling channel geometry through which a cooling medium flows.

Description

The invention relates to an air supply device with an electromotive drive which comprises a rotor with at least one magnet, and with a cooling device.

State of the art

From the American patent US 10,069,154 B2 an air supply device with an electromotive drive is known, which comprises a rotor with a magnet section which is arranged between two shaft bearing sections, and with a cooling device.

Disclosure of the invention

The object of the invention is to improve an air supply device with an electromotive drive, which comprises a rotor with at least one magnet, and with a cooling device, in particular with regard to its efficiency and / or its service life.

In the case of an air supply device with an electric motor drive, which comprises a rotor with at least one magnet, and with a cooling device, the object is achieved in that the cooling device has a cooling channel geometry through which a cooling medium flows on the outside of the magnet. The air supply device is preferably a compressor which is driven by an electric motor in order to supply air to a fuel cell in a fuel cell system. The air supply device comprises at least one impeller with which air is compressed. The impeller is attached to one end of the rotor. The impeller driven by the rotor can be rotated about an axis of rotation. The axis of rotation of the rotor with the impeller defines an axial direction. The term axial used in the following refers to this axis of rotation. Axial means in the direction or parallel to the axis of rotation. Analog means radial across the axis of rotation. The cooling medium is preferably air. The cooling channel geometry comprises at least one cavity which is delimited radially on the inside by the magnet. This can significantly improve the rotor cooling. Via the cooling channel geometry, the cooling medium can be brought into areas in which an undesirably large amount of heat is generated during operation of the air supply device. By optimizing the cooling, the thermal load on the electric motor drive can be reduced. As an alternative or in addition, the electrical current permissible during operation of the air supply device can be increased by the more efficient cooling.

A preferred exemplary embodiment of the air supply device is characterized in that the cooling channel geometry comprises at least one axial cooling channel for guiding the flow of the cooling medium along the magnet. The cooling channel can run along the outside of the magnet in the axial direction. However, the cooling channel can also run obliquely and / or curved on the outside of the magnet, deviating from the exact axial direction. A plurality of axial cooling channels are particularly advantageously arranged distributed uniformly over a circumference of the magnet.

Another preferred exemplary embodiment of the air supply device is characterized in that the cooling channel is delimited by a recess which is provided on the outside of the magnet. In this way, efficient cooling of the rotor can be ensured in a simple manner without great design or manufacturing effort. The recess has the shape of an arc of a circle, for example in cross section.

Another preferred exemplary embodiment of the air supply device is characterized in that the cooling channel is delimited by a recess which is provided on the inside of a bandage which surrounds the magnet. The bandage has, for example, essentially the shape of a straight circular cylinder jacket. The recess on the inside of the bandage has, for example, the shape of an arc in cross section. In this way, an effective cooling channel geometry can be created with little constructional and manufacturing effort.

Another preferred embodiment of the air supply device is characterized in that the bandage is connected at its axial ends to rotor shaft sections. The rotor shaft sections together with the bandage represent a rotor shaft. The magnet is arranged between the rotor shaft sections within the bandage. A rotor coil, for example, is arranged outside the drum. The connection between the bandage and the rotor shaft sections is advantageously designed to be coolant-tight.

Another preferred exemplary embodiment of the air supply device is characterized in that the rotor shaft sections each comprise at least one cooling medium channel which is fluidically connected to the cooling channel geometry. The cooling medium channel is designed, for example, as a central bore in the respective rotor shaft section. Sufficient cooling medium, in particular air, can be transported to and from the cooling channel geometry via the central cooling medium channel with little manufacturing effort.

Another preferred exemplary embodiment of the air supply device is characterized in that the rotor shaft sections each comprise at least one passage opening for the cooling medium at their ends facing away from one another. Cooling medium is advantageously supplied via one of the passage openings. Cooling medium is advantageously discharged via the other passage opening. In this way, a sufficient flow of cooling medium through the rotor shaft sections and the cooling channel geometry can be ensured in a simple manner.

Another preferred embodiment of the air supply device is characterized in that the magnet is arranged in the axial direction between two disk bodies, each of which includes at least one through hole that is in fluid connection with the cooling channel geometry. This enables the cooling medium to be transported quickly between the rotor shaft sections and the cooling channel geometry on the outside of the magnet. The disk bodies are arranged in the axial direction between the magnet and the rotor shaft sections. The bandage is arranged radially outside the disc body.

Another preferred exemplary embodiment of the air supply device is characterized in that the fluid connection comprises at least one shoulder on a surface of one of the disk bodies facing the magnet. This ensures the transport of the cooling medium from the at least one through hole in the disk bodies to the cooling channel geometry on the outside of the magnet.

The invention further relates to a magnet, a bandage, a rotor shaft section and / or a disk body for an air supply device described above. The named parts can be traded separately.

The invention optionally also relates to a fuel cell system with an air supply device described above.

Further advantages, features and details of the invention emerge from the following description, in which various exemplary embodiments are described in detail with reference to the drawing.

Figure list

• 1 eine Luftzuführvorrichtung mit einem elektromotorischen Antrieb, der einen Rotor mit Magneten umfasst, im Längsschnitt;
• 2 einen Querschnitt durch den Magneten und einer diese umgebenden Bandage mit einer Kühlkanalgeometrie gemäß einem ersten Ausführungsbeispiel;
• 3 eine ähnliche Darstellung wie in 2 mit einer Kühlkanalgeometrie gemäß einem zweiten Ausführungsbeispiel; und
• 4 einen Scheibenkörper der Luftzuführvorrichtung aus 1 alleine in einer Seitenansicht.

Show it:

• 1 an air supply device with an electric motor drive which comprises a rotor with magnets, in longitudinal section;
• 2 a cross section through the magnet and a surrounding bandage with a cooling channel geometry according to a first embodiment;
• 3 a similar representation as in 2 with a cooling channel geometry according to a second exemplary embodiment; and
• 4th a disk body of the air supply device 1 alone in a side view.

Description of the exemplary embodiments

In 1 is an air supply device 1 with an electric motor drive 2 shown in longitudinal section. The air supply device 1 serves in a fuel cell system (not shown) to supply air to a fuel cell. Fuel cell systems are known per se, for example from the German Offenlegungsschrift DE 10 2012 224 052 A1 . The air supply device 1 is designed in particular as an air compressor.

The electric motor drive 2 the air supply device 1 includes a rotor 3 with a rotor shaft 4th . The rotor shaft 4th comprises two rotor shaft sections 5 , 6th , at the ends facing away from each other an impeller 7th , 8th is appropriate. Depending on the design of the air supply device 1 are the two wheels 7th , 8th designed as compressor wheels. But it is also possible that only one of the wheels 7th , 8th is designed as a compressor, whereas the other impeller 7th , 8th is designed as a turbine impeller.

The rotor shaft 4th includes between the two rotor shaft sections 5 , 6th a magnet 9 . The magnet 9 is together with the rotor shaft sections 5 , 6th and the wheels 7th , 8th around an axis of rotation 14th rotatably driven. The magnet is radially outside 9 from a bandage 10 surround. The bandage 10 has the shape of a straight circular cylinder jacket. At their opposite ends is the bandage 10 firmly to the rotor shaft sections 5 , 6th connected.

A disc body 11 is in the axial direction between the rotor shaft section 5 and the magnet 9 arranged. A disc body 12th is in the axial direction between the magnet 9 and the rotor shaft section 6th arranged. The disk bodies are in the radial direction 11 , 12th inside the bandage 10 arranged.

A cooling device 13th serves to cool the rotor 3 . The cooling device 13th includes in a space 17th between the magnet 9 and the bandage 10 a cooling channel geometry 20th ; 30th that are in the 2 and 3 is shown.

By an arrow 15th is in 1 indicated that a cooling medium, in particular in the form of air, is supplied for cooling purposes. The air supplied passes through a passage opening 18th at the in 1 left end of the rotor shaft 4th into a cooling medium channel 19th in the rotor shaft section 5 .

The cooling medium channel 19th extends from the passage opening 18th down to a central cavity 54 at the in 1 right end of the rotor shaft section 5 . About the disc body 11 the supplied air enters the space 17th with the cooling channel geometry.

About the disc body 12th the air then enters a central cavity 55 at the in 1 left end of the rotor shaft section 6th . A cooling medium channel 59 extends from the central cavity 55 to a passage opening 58 at the in 1 right end of the rotor shaft 4th . By an arrow 16 the exiting air, which is the cooling medium, is indicated.

In the 2 and 3 are two exemplary embodiments of a cooling channel geometry 20th ; 30th shown. The two in the 2 and 3 cooling channel geometries shown 20th ; 30th can also be combined with each other.

In the 2 in cross section through the magnet 9 and the bandage 10 cooling channel geometry shown 20th comprises a total of eight recesses 21 that are radially outward on the magnet 9 are provided. The recess 21 has the shape of an arc of a circle. The total of eight recesses 21 serve to form eight cooling channels 22nd . The cooling channels 22nd are radially outside of the drum 10 limited.

In the 3 in cross section through the magnet 9 and the bandage 10 cooling channel geometry shown 30th comprises a total of four recesses 31 inside of the bandage 10 . The recess 31 has the shape of an arc of a circle.

The total of four recesses 31 serve to represent a total of four cooling channels 32 . The cooling channels 32 are radially inward of the magnet 9 limited.

In 4th is the disc body 12th out 1 shown in a side view. In the side view you can see that the disc body 12th a total of four through holes 41 includes, which allow the passage of cooling medium, in particular air. The through holes 41 are, as are the cooling channels 22nd , 32 the cooling channel geometry 20th ; 30th as in the 2 and 3 is shown, arranged evenly distributed over a circumference. At theirs the magnet 9 facing sides of the disc body 11 , 12th enables one paragraph at a time 40 the passage of fluid, as shown in 1 sees.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely 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

• US 10069154 B2 [0002]
• DE 102012224052 A1 [0017]

Claims (10)

Air supply device (1) with an electromotive drive (2) which comprises a rotor (3) with at least one magnet (9), and with a cooling device (13), characterized in that the cooling device (13) is on the outside of the magnet (9 ) has a cooling channel geometry (20; 30) through which a cooling medium flows. Air supply device according to Claim 1 , characterized in that the cooling channel geometry (20; 30) comprises at least one axial cooling channel (22; 32) for guiding the flow of the cooling medium along the magnet (9). Air supply device according to one of the preceding claims, characterized in that the cooling channel (22) is delimited by a recess (21) which is provided on the outside of the magnet (9). Air supply device according to one of the preceding claims, characterized in that the cooling channel (32) is delimited by a recess (31) which is provided on the inside of a bandage (10) which surrounds the magnet (9). Air supply device according to Claim 4 , characterized in that the bandage (10) is connected at its axial ends to rotor shaft sections (5, 6). Air supply device according to Claim 5 , characterized in that the rotor shaft sections (5, 6) each comprise at least one cooling medium channel (19; 59) which is fluidically connected to the cooling channel geometry (20; 30). Air supply device according to Claim 6 , characterized in that the rotor shaft sections (5, 6) each comprise at least one passage opening (18; 58) for the cooling medium at their ends facing away from one another. Air supply device according to one of the preceding claims, characterized in that the magnet (9) is arranged in the axial direction between two disk bodies (11, 12), each of which includes at least one through hole (41) which is in fluid connection with the cooling channel geometry (20; 30 ) stands. Air supply device according to Claim 8 , characterized in that the fluid connection comprises at least one shoulder (40) on a surface of one of the disk bodies (11, 12) facing the magnet (9). Magnet (9), bandage (10), rotor shaft section (5, 6) and / or disk body (11, 12) for an air supply device (1) according to one of the preceding claims.

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