DE102021121438A1 - Rotor and method of balancing a rotor - Google Patents

Abstract

The invention relates to a rotor (1) of an electric machine, with a rotor shaft (2) on which a laminated core (3) is arranged, which comprises magnets (11-14) with a defined shape, which are spaced apart from one another in a defined arrangement and are relatively are positioned relative to one another, and with at least one plug-in mass (6) which has at least one tab (17,18) with a mass which is specifically changed during a balancing process and which is attached to an end face (10) of the laminated core (3) in a defined angular position is applied to the rotor (1). In order to improve the balancing of the rotor (1) in terms of production technology and/or functionality, the tab (17, 18) of the plug-in mass (6) is shaped in such a way that it is adapted to an intermediate magnet space (15, 16 ) adapted between two magnets (11-14) and arranged in the space between the magnets (15,16) in such a way that the two magnets (11-14) are not covered by the tab (17,18) with the adapted shape in an axial plan view .

Description

The invention relates to a rotor of an electric machine, with a rotor shaft on which a laminated core is arranged, which comprises magnets with a defined shape, which are spaced apart from one another and positioned relative to one another in a defined arrangement, and with at least one plug-in compound, which has at least one tab with a mass which is changed in a targeted manner during a balancing process and which is applied to the rotor at a front side of the laminated core in a defined angular position. The invention also relates to a method for balancing such a rotor.

The German Offenlegungsschrift DE 10 2019 123 277 A1 discloses a method for balancing rotors of electrical machines, each rotor having a shaft and a laminated core arranged on the shaft, with at least the following steps: providing a rotor to be balanced, providing plug-in mass blanks, determining an amount and an orientation of an initial imbalance of the rotor to be balanced, Processing the plug-in mass blanks by cutting off a section of defined length from the respective plug-in mass blank depending on the amount of the determined initial imbalance, forming plug-in masses with an outer contour that has been changed compared to the plug-in mass blank, namely shortened, mounting the machined plug-in mass blanks and thus the plug-in masses on the runner to be balanced in one of the orientation of the determined initial imbalance-dependent angular position, the plug-in mass blanks for the plug-in masses having a base body which has diametrically opposite sections below has material cutouts of different sizes, and which in the area of the larger material cutout has a tab that protrudes in the circumferential and radial direction relative to the larger material cutout, the sections of defined length depending on the amount of the determined initial imbalance are separated from the plug-in mass blanks in the area of the tabs machined plug-in mass blanks and thus the plug-in masses are mounted on the rotor to be balanced in an angular position dependent on the orientation of the determined initial unbalance, with one plug-in mass being arranged on each side of the laminated core. Other methods for balancing rotors or rotors of electrical machines are from the German Offenlegungsschrift DE 10 2018 121 645 A1 and the American patent U.S. 5,780,945 known.

The object of the invention is to provide a rotor of an electric machine, with a rotor shaft on which a laminated core is arranged, which comprises magnets with a defined shape, which are spaced apart from one another and positioned relative to one another in a defined arrangement, and with at least one plug-in mass, which has at least one tab with a mass that is changed in a targeted manner during a balancing process and that is applied to the rotor at a front side of the laminated core in a defined angular position, to improve production technology and/or functionality.

The task is in the case of a rotor of an electric machine, with a rotor shaft, on which a laminated core is arranged, which comprises magnets with a defined shape, which are spaced apart from one another and positioned relative to one another in a defined arrangement, and with at least one plug-in mass, which has at least one Has a lug with a mass that is changed in a targeted manner during a balancing process and that is applied to the end face of the laminated core in a defined angular position on the rotor is arranged in the space between the magnets in such a way that the two magnets in an axial plan view are not covered by the tab which is adapted in their shape. The term axial refers to an axis of rotation of the rotor. Axial means towards or parallel to the rotor. In the axial plan view, one looks at a face of the rotor, from which a stub shaft of the rotor shaft protrudes. Conventional plug masses, such as those from the German Offenlegungsschrift DE 10 2019 123 277 A1 are known to have rectangular tabs that are shortened when balancing. Due to the rectangular shape of the tabs, it can happen that the tab of a mounted plug-in mass covers at least one magnet in an axial plan view. In the case of the claimed rotor, this is avoided by the tab, which is adapted in shape to the space between the magnets between two magnets. The matched shape, in combination with the targeted arrangement of the shape-matched tab in the magnet space, also allows the use of non-magnetizable materials for the plug-in masses. This simplifies the production of the mating compound. In addition, in particular the processing, for example machining, of the tab on the plug-in compound is considerably simplified. The tab on the mating mass, which is optimized in terms of its shape and arrangement, prevents the electromagnetics of the balanced rotor from being impaired by the mating mass in a simple manner. Apart from the optimized shape and arrangement of the tab of the plug-in mass, the rotor can be as or something similar to that in the German Offenle letter DE 10 2019 123 277 A1 revealed runners to be executed.

A preferred exemplary embodiment of the rotor is characterized in that the tab, which is adapted in shape, has bevels facing the magnets, which extend parallel to the magnets. The existing space between the magnets between the two magnets can thus be used for arranging the tab without the electromagnetic properties of the rotor being impaired during operation of the electric machine.

A further preferred exemplary embodiment of the rotor is characterized in that magnetic areas are deliberately omitted in the shape of the tab, which is adapted in shape. Among other things, this provides the advantage that the choice of material for the representation of the plug-in mass with the tab is independent with regard to magnetizability.

A further preferred exemplary embodiment of the rotor is characterized in that the tab, which is adapted in terms of its shape, is formed from a magnetizable material. Materials can thus advantageously be used which are lighter and therefore less expensive to machine for balancing the rotor.

A further preferred exemplary embodiment of the rotor is characterized in that the plug-in compound has at least two tabs whose shape is matched. This simplifies rotor balancing. In a particularly advantageous manner, the plug-in mass has precisely two tabs whose shape is matched. The tabs themselves are advantageously arranged in the spaces between the magnets between two magnets in each case. In turn, two magnets are advantageously arranged between the tabs.

A further preferred exemplary embodiment of the rotor is characterized in that the two tabs, which are adapted in their shape, enclose a V-shaped tab space between them in a circumferential direction, in which space two magnets are arranged. In this way, an undesired overlapping of the magnets in an axial plan view is advantageously prevented here as well.

A further preferred exemplary embodiment of the rotor is characterized in that the shape-matched tab or the shape-matched tabs are integrally connected to a base body with which the plug-in mass is placed on the rotor shaft. The main body of the plug-in mass can be designed in the same way or something similar to that in the German Offenlegungsschrift DE 10 2019 123 277 A1 disclosed runner is described.

In a method for balancing a rotor as described above, the above-mentioned object is alternatively or additionally achieved in that the tab with the adapted shape is applied to the rotor in such a way that the two magnets do not deviate from the tab with the adapted shape in an axial top view be covered. In this case, it is accepted that the plug-in mass with the tab that has been adapted in terms of its shape may only be mounted on the rotor shaft in defined steps.

A preferred exemplary embodiment of the method is characterized in that the bracket, which is adapted in shape, is only mounted on the rotor shaft in defined steps. This ensures that the tab, which is adapted in its shape, is always only arranged in the space between the magnets, without covering the two magnets.

The invention also relates to a plug-in compound with at least one tab, the shape of which is adapted, for a rotor described above. The plug-in mass can be traded separately.

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

The only enclosed figure shows a perspective view of a rotor with an optimized mating mass.

1 shows a perspective view of a rotor 1 of an electric machine. The rotor 1 comprises a rotor shaft 2 on which a laminated core 3 is arranged. A stub shaft 4 of the rotor shaft 2 protrudes from the laminated core 3 .

The stub shaft 4 of the rotor shaft 2 is equipped with teeth 5 . A plug-in mass 6 is arranged on a mounting shoulder 8 of the rotor shaft 2 . The plug-in compound 6 comprises a base body 7 with a flat area 9.

In the laminated core 3 magnets 11, 12, 13, 14 are arranged. at a 1 Visible end face 10, the magnets 11 to 14 are spaced apart in a defined arrangement and positioned relative to one another. A magnet gap 15 results between the magnets 11, 12. A magnet gap 16 results between the magnets 13, 14.

The plug-in mass 6 comprises two tabs 17, 18 which extend from the base body 7. The lugs 17, 18 are designed and arranged in such a way that the lug 17 is arranged in the intermediate magnet space 15 without covering the magnets 11, 12 in the end face 10. Analogously, the lug 18 is arranged in the space 16 between the magnets in such a way that the magnets 13, 14 in the end face 10 are not covered by the lug 18.

The two tabs 17, 18 enclose a V-shaped tab gap 19 between them. The two magnets 12, 13 are arranged in the intermediate space 19 between the tabs.

At least one of the tabs 17, 18 is shortened during balancing, depending on the imbalance of the rotor 1 to be balanced, and applied to the rotor 1 in a corresponding angular position. Due to the optimized geometry of the tabs 17, 18, magnetic areas in the end face 10 of the laminated core 3 are deliberately left out.

The tabs 17, 18 of the mating mass 6 for balancing the rotor 1 are preferably machined, for example by milling or drilling. Before the actual balancing process, an amount and an orientation of an initial imbalance of the rotor 1 to be balanced are determined. The balancing process is preferably carried out in a manner similar to that described in the German Offenlegungsschriften DE 10 2019 123 277 A1 and DE 10 2018 121 645 A1 is revealed.

Reference List

1

rotor

2

rotor shaft

3

laminated core

4

stub shaft

5

gearing

6

plug-in mass

7

body

8th

mounting heel

9

flattening

10

face

11

magnet

12

magnet

13

magnet

14

magnet

15

magnet gap

16

magnet gap

17

tab

18

tab

19

flap clearance

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited 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

• DE 102019123277 A1 [0002, 0004, 0010, 0022]
• DE 102018121645 A1 [0002, 0022]
• US5780945 [0002]

Claims (10)

Rotor (1) of an electric machine, with a rotor shaft (2) on which a laminated core (3) is arranged, which comprises magnets (11-14) with a defined shape, which are spaced apart from one another in a defined arrangement and positioned relative to one another, and with at least one plug-in mass (6) which has at least one lug (17,18) with a mass which is specifically changed during a balancing process and which is attached to the rotor at a front side (10) of the laminated core (3) in a defined angular position (1) is applied, characterized in that the tab (17,18) of the plug-in compound (6) is adapted in shape to an intermediate magnet space (15,16) between two magnets (11-14) and is thus fixed in the intermediate magnet space (15 ,16) is arranged in such a way that the two magnets (11-14) are not covered by the tab (17,18), which is adapted in shape, in an axial plan view. rotor after claim 1 , characterized in that the lug (17, 18) adapted in its shape has bevels facing the magnets (11-14) which extend parallel to the magnets (11-14). Rotor according to one of the preceding claims, characterized in that magnetic areas are deliberately omitted in the shape of the strap (17, 18) whose shape is adapted. Rotor according to one of the preceding claims, characterized in that the lug (17, 18) whose shape is adapted is formed from a magnetizable material. Rotor according to one of the preceding claims, characterized in that the plug-in compound (6) has at least two lugs (17, 18) of matching shape. rotor after claim 5 , characterized in that the two lugs (17, 18) of matching shape enclose a V-shaped lug space (19) between them in a circumferential direction, in which space two magnets (12, 13) are arranged. Rotor according to one of the preceding claims, characterized in that the shape-matched tab (17,18) or the shape-matched tabs (17,18) are connected in one piece to a base body (7) with which the plug-in mass (6 ) is plugged onto the rotor shaft (2). Method for balancing a rotor (1) according to any one of the preceding claims, characterized in that the tab (17,18) adapted in shape is applied to the rotor (1) in such a way that the two magnets (12,13) in their axial plan view are not covered by the shape of the adjusted tab (17,18). procedure after claim 8 , characterized in that the lug (171, 81) adapted in its shape is mounted on the rotor shaft (1) only in defined steps. Plug-in compound (6) with at least one tab (17,18) adapted in shape for a rotor (1) according to one of Claims 1 until 7 .

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