Securing device and method for fixing an electric machine to a component

What is claimed is: 1. A fastening device comprising an electric machine ( 12 ) and a fastening plate ( 10 ) for fixing the electric machine ( 12 ) to a component ( 30 ), said fastening plate having a central through-going orifice ( 14 ) configured to receive a round bearing sleeve ( 16 ) of the electric machine ( 12 ), wherein the bearing sleeve ( 16 ) receives a bearing body ( 40 ) of at least one of a rotor shaft and an output shaft ( 38 ), wherein the through-going orifice ( 14 ) comprises an approximately polygonal shape ( 15 ) having lateral surfaces ( 18 ) that come to lie against the bearing sleeve ( 16 ), wherein the fastening plate ( 10 ) comprises fastening orifices ( 22 ) in a radially outer region ( 20 ), the fastening orifices being configured to have the electric machine ( 12 ) fastened to the component ( 30 ) by means of said fastening orifices. 2. The fastening device as claimed in claim 1 , characterized in that the polygonal shape ( 15 ) is embodied as a triangle or as a rectangle or as a pentagon or as a hexagon. 3. The fastening device as claimed in claim 1 , characterized in that the lateral surfaces ( 18 ) are embodied as planar surfaces ( 19 ) that lie in a linear manner in an axial direction ( 50 ) against the bearing sleeve ( 16 ). 4. The fastening device as claimed in claim 1 , characterized in that precisely three lateral surfaces ( 18 ) of the through-going orifice ( 14 ) lie with linear-shaped contact regions ( 44 ) against the bearing sleeve ( 16 ). 5. The fastening device as claimed in claim 1 , characterized in that deformation cut-outs ( 24 ) are arranged radially spaced apart from the lateral surfaces ( 18 ) of the through-going orifice ( 14 ) and as a result of this arrangement the lateral surfaces ( 18 ) comprise regions that are embodied as radially deformable connecting pieces ( 26 ). 6. The fastening device as claimed in claim 5 , characterized in that a radial width ( 28 ) of the connecting pieces ( 26 ) corresponds approximately to an axial thickness ( 32 ) of the fastening plate ( 10 ). 7. The fastening device as claimed in claim 5 , characterized in that the deformation cut-outs ( 24 ) are longer in a tangential direction ( 52 ) than in a radial direction ( 54 ). 8. The fastening device as claimed in claim 1 , characterized in that the fastening orifices ( 22 ) are embodied as eyelets ( 23 ) that lie radially outside an approximately circular basic shape of the fastening plate ( 10 ) and in an assembled state lie radially outside the electric machine ( 12 ). 9. The fastening device as claimed in claim 1 , characterized in that through-going passages ( 34 ) are embodied for electrical contacts ( 35 ) of the electric machine ( 12 ) in the fastening plate ( 10 ). 10. A drive unit ( 70 ), comprising a fastening device ( 60 ) as claimed in claim 1 , wherein the electric machine ( 12 ) includes an output element ( 42 ). 11. The fastening device as claimed in claim 1 , characterized in that the polygonal shape ( 15 ) is embodied as a triangle or as a rectangle or as a pentagon or as a hexagon that is punched out from the fastening plate ( 10 ) that is embodied as a planar metal sheet. 12. The fastening device as claimed in claim 1 , characterized in that the lateral surfaces ( 18 ) are embodied as planar surfaces ( 19 ) that lie in a linear manner in an axial direction ( 50 ) against the bearing sleeve ( 16 ) and form a press-fit with the bearing sleeve ( 16 ). 13. The fastening device as claimed in claim 1 , characterized in that precisely three lateral surfaces ( 18 ) of the through-going orifice ( 14 ) lie with linear-shaped contact regions ( 44 ) against the bearing sleeve ( 16 ), wherein the contact regions ( 44 ) are arranged distributed uniformly over a periphery. 14. The fastening device as claimed in claim 5 , characterized in that a radial width ( 28 ) of the connecting pieces ( 26 ) corresponds approximately to an axial thickness ( 32 ) of the fastening plate ( 10 ) and is in a region between 0.5 to 3.0 mm. 15. The fastening device as claimed in claim 5 , characterized in that a radial width ( 28 ) of the connecting pieces ( 26 ) corresponds approximately to an axial thickness ( 32 ) of the fastening plate ( 10 ) and is approximately 1.0 mm. 16. The fastening device as claimed in claim 5 , characterized in that the deformation cut-outs ( 24 ) extend approximately parallel to the lateral surfaces ( 18 ). 17. The fastening device as claimed in claim 1 , characterized in that two through-going passages are embodied for electrical contacts ( 35 ) of the electric machine ( 12 ) in the fastening plate ( 10 ) and the fastening plate ( 10 ) comprises an anti-rotation device ( 36 ) that engages in a corresponding mating receiving device ( 37 ) of the electric machine ( 12 ) in order to fix the rotational position of the fastening plate ( 10 ) with respect to the electric machine ( 12 ). 18. The fastening device ( 60 ) as claimed in claim 1 , wherein the bearing body ( 40 ) is a ball bearing, and the bearing sleeve ( 16 ) is embodied as one piece with a bearing lid ( 17 ) of the electric machine ( 12 ), as a punched-out and deep drawn metal part. 19. A method for fastening an electric machine ( 12 ) to a component ( 30 ), wherein a fastening plate ( 10 ) is pressed in an axial manner onto an axially protruding round bearing sleeve ( 16 ) of the electric machine ( 12 ), wherein the fastening plate ( 10 ) includes a central through-going orifice ( 14 ) configured to receive the round bearing sleeve ( 16 ), wherein the through-going orifice ( 14 ) comprises an approximately polygonal shape ( 15 ) having lateral surfaces ( 18 ) that come to lie against the bearing sleeve ( 16 ), and wherein the fastening plate ( 10 ) comprises fastening orifices ( 22 ) in a radially outer region ( 20 ), the fastening orifices ( 22 ) being configured to have the electric machine ( 12 ) fastened to the component ( 30 ) by means of said fastening orifices, wherein the lateral surfaces ( 18 ) of the through-going orifice ( 14 ) deform radially in at least one of an elastic manner and a plastic manner at contact spots ( 44 ) of said through-going orifice on the bearing sleeve ( 16 ), and subsequently the fastening orifices ( 22 ) of the fastening plate ( 10 ) are connected to the component ( 30 ), as a result of which an output element ( 42 ) of the electric machine ( 12 ) is positioned relative to the component ( 30 ).