METHOD FOR BALANCING ROTORS OF ELECTRICAL MACHINES

Abstract

A method for balancing rotors (10) of electrical machines, where each rotor (10) has a shaft (11) and at least one laminated core (12) arranged on the shaft. The method includes providing a rotor (10) that is to be balanced, providing blanks (13), with a length (l) that is smaller than an outside diameter (d) of the laminated core (12) of the rotor (10), ascertaining a magnitude and orientation of an initial unbalance of the rotor (10) and processing the blanks (13) by making a recess (15) in the respective blank (13) outside the center of gravity depending on the magnitude of the ascertained initial unbalance. The blank (13) can be mounted by fitting the recess (15) on the shaft (11) of the rotor (10) and mounting the processed blank (13) on the rotor (11) in an angular position that is dependent on the orientation of the ascertained initial unbalance.

Claims

1. A method for balancing rotors of electrical machines, the rotors having a shaft and at least one laminated core arranged on the shaft, the method comprising: providing a rotor of an electrical machine, providing blanks with a length that is smaller than an outside diameter of the laminated core of the rotor, ascertaining a magnitude and an orientation of an initial unbalance of the rotor that is to be balanced, processing the blanks by making a recess in the respective blank outside the center of gravity depending on the magnitude of the ascertained initial unbalance, mounting the respective blank by means of the recess on the shaft of the rotor is to be balanced, and fixing the processed blanks on the rotor in an angular position that is dependent on the orientation of the ascertained initial unbalance.

2. The method of claim 1, wherein a respective magnitude and a respective orientation of the initial unbalance of the rotor that is to be balanced are ascertained with respect to two axial ends of the laminated core, a respective blank is processed individually depending on the respective magnitude of the initial unbalance and individually mounted depending on the orientation of the initial unbalance for each axial end.

3. The method of claim 2, wherein a distance of a center point of the recess to be made in the respective blank from the center of gravity of the respective blank is ascertained depending on the magnitude of the initial unbalance of the rotor which is to be balanced.

4. The method of claim 1, wherein a length of the blanks is between 60% and 90% of the outside diameter of the laminated core.

5. The method of claim 1, wherein a thickness of the blanks is between 0.3 mm and 1.0 mm.

6. The method of claim 1, wherein the blanks are composed of a metal material.

7. The method of claim 1, wherein the blanks are composed of a paramagnetic, metal material.

8. The method of claim 1, wherein the blanks are mounted on the rotor that is to be balanced by fitting the blanks onto the shaft by way of their recess and then connecting the blanks to the laminated core.

9. The method of claim 8, wherein the processed blanks are connected in a materially bonded manner to the laminated core by adhesive bonding or welding or baking.

10. The method of claim 9, wherein the processed blanks are connected in an interlocking manner to the laminated core by latching or clipping.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] FIG. 1 is a diagram for illustrating the method for balancing rotors of electrical machines.

DETAILED DESCRIPTION

[0021] The invention relates to a method for balancing rotors of electrical machines, in particular rotors of electrical machines of the kind that rotate at rotation speeds of more than 15,000 rpm, in particular of more than 17,000 rpm, during operation. Electrical machines of this kind are electrical machines which are used as drive assemblies in high-power vehicles.

[0022] The method for balancing rotors of electrical machines is described below with reference to FIG. 1, wherein various steps of the method according to the invention are shown by I, II, III, IV, V and VI in FIG. 1.

[0023] In a first step I, a rotor 10, which is to be balanced, of an electrical machine is initially provided.

[0024] A rotor 10 of this kind that is to be balanced has a shaft 11 and also a laminated core 12 that is arranged on the shaft 11 (a plurality of, for example four to eight, laminated cores can typically be provided). The laminated core 12 has magnet pockets in which magnets are accommodated.

[0025] In a second step II, blanks 13 are provided, and a blank 13 of this kind is shown schematically in FIG. 1.

[0026] The blank 13 of one embodiment is manufactured from a paramagnetic and metal material, for example from paramagnetic steel. The blanks 13 have a length l that is smaller than an outside diameter d of the laminated core 12 of the rotor 10. A width b of the blanks 13 is smaller than the length l thereof. The length l of the blanks 13 is preferably between 60% and 90%, preferably between 60% and 80%, of the outside diameter d of the laminated core 12 of the rotor 10 which is to be balanced. A thickness of the blanks 13 is typically between 0.3 mm and 1.0 mm.

[0027] After providing the rotor 10 that is to be balanced, in the first step I and after providing the blanks 13 in the second step II, an initial unbalance of the rotor 10 that is to be balanced is determined in a third step III.

[0028] To ascertain the initial unbalance of the rotor 10 that is to be balanced, the rotor is driven in rotation on an unbalance test stand in accordance with the arrows 14. The magnitude and the orientation of the initial unbalance are ascertained here.

[0029] In this case, a magnitude and an orientation of the initial unbalance of the rotor 10 that is to be balanced are ascertained with respect to the two axial ends 12a, 12b of the laminated core 12.

[0030] Accordingly, the unbalance ascertaining operation produces four measurement values, specifically, for the axial end 12a of the laminated core 12, a first magnitude and a first orientation and, for the second end 12b of the laminated core 12, a second magnitude and a second orientation of the initial unbalance of the rotor 10 that is to be balanced.

[0031] In a subsequent fourth step IV of the method, the blanks 13 are processed depending on the magnitude of the respective ascertained initial unbalance.

[0032] The blanks 13 are processed by way of a recess 15 that is outside the center of gravity being made in the respective blank 13, in particular by punching. The respective blank 13 can be mounted on the shaft 11 of the rotor 10 that is to be balanced by means of this circular recess 15 that is outside the center of gravity.

[0033] The diameter of the recess 15 that is made in the blank 13 during the processing in step IV is matched to the diameter of the shaft 11 of the rotor 10 that is to be balanced in such a way that the respective blank 13 can be arranged on the shaft 11 of the rotor 10 that is to be balanced, with a defined clearance fit.

[0034] FIG. 1 shows, in step IV, the center of gravity S of the blank 13 and also a center point M of the recess 15 that is made in the blank 13, preferably by punching. In this case, the distance x between the center of gravity S and the center point M is dependent on the magnitude of the respective ascertained initial unbalance of the rotor 10 which is to be balanced. The greater the magnitude of the initial unbalance of the rotor 10 that is to be balanced, the greater said distance x.

[0035] The distance x between the center of gravity S and the center point M is determined depending on the magnitude of the respective initial unbalance and the recess 15 is made in the respective blank 13, preferably by punching, depending on the distance.

[0036] As already stated, there may be a different magnitude of the unbalance in the region of the two ends 12a, 12b of the laminated core 12 of the rotor 10 that is to be balanced, so that, for each end 12a, 12b, an individual recess 15 with an individual distance x of the center point M of the respective recess 15 from the center of gravity S of the respective blank 13 then is made in the blank 13 that is to be positioned at the respective end 12a, 12b.

[0037] Following the processing of the blanks 13 in step IV depending on the magnitude of the respective ascertained initial unbalance, in a fifth step V the processed blanks 13 are mounted on the rotor 10 in an angular position that is dependent on the orientation of the ascertained initial unbalance. Since not only the magnitude of the initial unbalance but rather also the orientation of the initial unbalance can be different at the two axial ends 12a, 12b, the respective blank 13 can be mounted in an individual angular position on the rotor 10 in the region of each axial end 12a, 12b.

[0038] The blanks 13 are mounted on the axial ends 12a, 12b of the laminated core 12 of the rotor 10 by fitting the blanks 13 onto the shaft 11 at the respective end of the rotor 10 by way of their respective recess 15 and then by connecting the blanks 13 to the laminated core 12 at the respective axial end 12a, 12b of said laminated core. The connection is made in a materially bonded and/or interlocking manner. Materially bonded connection can be made by adhesive bonding or welding or baking. Interlocking connection can be made by latching or clipping. The blank can consist of a sheet-metal cutting or can be designed as a forged part.

[0039] In a further step VI, the result of the balancing can be checked by a repeated balancing process analogously to step III, but with blanks 13 mounted.

[0040] Accordingly, it lies within the scope of the invention to balance a rotor 10 of an electrical machine by way of initially measuring the initial unbalance of the rotor 10 that is to be balanced to determine a magnitude and an orientation of the initial unbalance, specifically with respect to the axial ends 12a, 12b of the laminated core 12 of the rotor 10 in each case. Depending on the magnitude of the respective initial unbalance, blanks 13 are processed, specifically by way of a recess 15 that is outside the center of gravity being made in said blanks and by means of which the respective blank 13 is later threaded onto the shaft 11. The distance x of the center point M of the respective recess 15 from the center of gravity S of the respective blank 13 is dependent on the magnitude of the ascertained initial unbalance. A blank 13 that is processed individually in respect of the magnitude of the initial unbalance is mounted on each axial end 12a, 12b of the laminated core 12 of the rotor 10 that is to be balanced depending on the respective orientation of the initial unbalance in a defined angular position.

[0041] An adaptive procedure of this kind for balancing rotors of electrical machines is suitable for balancing rotors that rotate at a rotation speed of more than 15,000 rpm, in particular more than 17,000 rpm during operation, within short cycle times during industrial manufacture of said rotors.

[0042] The method of the invention is suitable for an extremely wide variety of rotors of electrical machines. It is only necessary to correspondingly adapt the shape or contour and/or the thickness of the respective blank 13 depending on the magnitude of the unbalance.

[0043] Provision may optionally be made for the blank 13 to be positioned in the region of that end which is at a distance from the recess 15 that is made in the blank 13, that is to say on the opposite side of the center of gravity S of the blank 13 to the recess 15, to keep ready an increased mass. This can be done, for example, by radial projections at the respective end of the blank 13.

[0044] Balancing disks can be dispensed with. Balanced rotors of electrical machines with a low weight and a low axial structural length can be provided.