Electronic printed circuit board assembly for high-power components

The invention claimed is: 1. An electronic module ( 40 ) comprising at least one printed circuit board of a first generic type (“printed circuit board A”), if appropriate populated on both sides, which is populated in an overlapping manner with at least one printed circuit board of a second generic type (“printed circuit board B”), wherein the printed circuit board B is populated with at least one electronic component with specific requirements ( 19 ), and the printed circuit boards A and B, which are connected to one another, form a stepped printed circuit board composite ( 100 , 200 , 300 , 400 , 500 ), wherein the stepped printed circuit board composite is delimited, at least in certain regions, by end regions ( 16 ), which are formed by sections of the at least one printed circuit board A, and the stepped printed circuit board composite is placed on a heat sink ( 20 ), wherein a fastening side ( 15 ) of the at least one printed circuit board B rests flat on a contact surface ( 21 ) of the heat sink, wherein the contact surface of the heat sink is dimensioned and positioned in such a manner that it extends at least partially laterally beyond the fastening side of the at least one printed circuit board B in each case in the direction of the end regions formed by the sections of the at least one printed circuit board A, wherein support elements, for mechanically supporting the end regions formed by the sections of the at least one printed circuit board A, are constructed on the contact surface of the heat sink, and wherein washers ( 24 , 26 ) made from printed-circuit-board-B material are applied as the support elements on the contact surface of the heat sink in the region of the end regions of the printed circuit board composite formed by the sections of the at least one printed circuit board A, and the end regions of the printed circuit board composite sit on the washers and are supported by the washers, wherein the printed-circuit-board-B material for the washers is chosen from the same batch from which the printed-circuit-board-B material for the at least one printed circuit board B originates. 2. The electronic module according to claim 1 , wherein the at least one printed circuit board A has at least one recess ( 10 ) and the at least one printed circuit board B is connected in an overlapping manner to the at least one printed circuit board A such that in each case, a printed circuit board B in each case covers a recess ( 10 ) of the printed circuit board A at least in certain regions. 3. The electronic module according to claim 2 , wherein the at least one recess ( 10 ) is essentially window-shaped. 4. The electronic module according to claim 1 , wherein the at least one printed circuit board A has alignment holes ( 22 ), and the washers ( 26 ) are positioned on the contact surface of the heat sink below the alignment holes of the at least one printed circuit board A, so that surface regions ( 26 a ) of the respective washers ( 26 ) are exposed by the alignment holes ( 22 ). 5. The electronic module according to claim 1 , wherein the support elements are set up to dissipate thermal energy from the at least one printed circuit board A to the heat sink and/or to enable a potential equalization between the at least one printed circuit board A and the heat sink. 6. The electronic module according to claim 1 , wherein the at least one printed circuit board A and the at least one printed circuit board B are contacted with one another in their overlap region ( 501 ) by means of ball grid array (BGA) technology. 7. An illumination device for a motor vehicle, particularly a motor-vehicle headlamp, comprising an electronic module ( 40 ) according to claim 1 . 8. The use of an electronic module according to claim 1 in an illumination device for a motor vehicle. 9. A method for producing an electronic module in a component placement line, the electronic module comprising a stepped printed circuit board composite having at least one electronic component with specific requirements and a heat sink, wherein the method comprises: populating at least one printed circuit board of a first generic type (“printed circuit board A”), if appropriate populated or to be populated on both sides, in an overlapping manner with at least one printed circuit board of a second generic type (“printed circuit board B”), wherein the printed circuit board B is populated with at least one electronic component with specific requirements, to obtain a stepped printed circuit board composite, wherein the stepped printed circuit board composite is delimited, at least in certain regions, by end regions, which are formed by sections of the at least one printed circuit board A, and placing the stepped printed circuit board composite obtained onto the heat sink in such a manner that a fastening side of the at least one printed circuit board B rests flat on a contact surface of the heat sink, wherein the contact surface of the heat sink is dimensioned and positioned in such a manner that it extends at least partially laterally beyond the fastening side of the at least one printed circuit board B in each case in the direction of the end regions formed by the sections of the at least one printed circuit board A, and wherein support elements, for mechanically supporting the end regions formed by the sections of the at least one printed circuit board A, are constructed on the contact surface of the heat sink, wherein washers made from printed-circuit-board-B material are applied as the support elements on the contact surface of the heat sink in the region of the end regions of the printed circuit board composite formed by the sections of the at least one printed circuit board A, and the end regions of the printed circuit board composite sit on the washers and are supported by the washers, wherein the printed-circuit-board-B material for the washers is chosen from the same batch from which the printed-circuit-board-B material for the at least one printed circuit board B originates. 10. The method for producing an electronic module according to claim 9 , wherein the method comprises the steps: a) providing at least one printed circuit board B with a placement side (top) and a fastening side (bottom), facing away from the placement side, and providing at least one electronic component with specific requirements, b) placing (top-up) and fixing the at least one electronic component with specific requirements on the placement side of the at least one printed circuit board B and subsequently turning the printed circuit board B, c) providing at least one printed circuit board A with a first placement side (top) and a second placement side (bottom), facing away from the first placement side, and providing electronic component elements, d) placing (top-up) and fixing electronic component elements on the first placement side of the at least one printed circuit board A and subsequently turning the printed circuit board A, e) placing (bottom-up) and fixing electronic component elements on the second placement side of the at least one printed circuit board A and placing (bottom-up) and fixing the at least one populated printed circuit board B from step b) on the second placement side of the at least one printed circuit board A in an overlapping manner, to obtain a stepped printed circuit board composite, wherein the stepped printed circuit board composite is delimited at least in certain regions by end regions, which are formed by sections of the at least one printed circuit board A, and f) placing the stepped printed circuit board composite obtained onto the heat sink in such a manner that the fastening side of the at least one printed circuit board B rests flat on a contact