Lighting device for a motor vehicle headlight

The invention claimed is: 1. A lighting device ( 1 ) for a motor vehicle headlight and/or for a rear light of a motor vehicle and/or for a signal light for a motor vehicle for generating at least one light distribution (LV 1 , LV 2 ) or a partial light distribution, the lighting device ( 1 ) comprising: one or more imaging units ( 2 ), wherein each imaging unit ( 2 ) is configured to generate an intermediate light image in an imaging plane (ZBE, ZBE′) specific for the respective imaging unit, wherein each imaging unit ( 2 ) is composed of a light source ( 3 ) and a collimator optics ( 4 ) or comprises a light source ( 3 ) and a collimator optics ( 4 ), wherein the collimator optics ( 4 ) consist in each case of a body ( 4 A) which is formed from a transparent, light-guiding material, wherein the body ( 4 A) has a light coupling region ( 41 A), a delimiting surface ( 41 B), and a light exit surface ( 41 C), and wherein light coupled into the body ( 4 A) via the light coupling region ( 41 A) is partly propagated directly in the direction of the light exit surface ( 41 C) and is partly directed to the delimiting surface ( 41 B), on which it is reflected in the direction of the light exit surface ( 41 C), preferably totally reflected, and wherein the collimator optics ( 4 ) of each imaging unit ( 2 ) are designed in such a way that the light emitted by the light source ( 3 ) of the respective imaging unit ( 2 ) in the imaging plane (ZBE, ZBE′) specific for the respective imaging unit ( 2 ) is imaged as an intermediate light image, and wherein the lighting device ( 1 ) comprises at least one projection device ( 5 ), having an optical axis (X), which at least one projection device ( 5 ) has a focal plane (BE), wherein at least one of the imaging units ( 2 ) is configured as a convergence imaging unit ( 2 ), the at least one convergence imaging unit ( 2 ) being characterized in that the body ( 4 A) of the collimator optics ( 4 ) is designed such that that part of the light, which is coupled into the body ( 4 A) via the light coupling region ( 41 A) and propagates directly in the direction of the light exit surface ( 41 C), as well as the other part of the coupled light which is reflected on the delimiting surface ( 41 B), in particular totally reflected, form a collimator body light bundle (KLB, KLB′) converging into a common virtual intermediate light image plane (VBE, VBE′), the light exit surface ( 41 C) being concavely curved and the virtual intermediate light image plane (VBE, VBE′) lying in front of the specific imaging plane (ZBE, ZBE′) of the at least one convergence imaging unit ( 2 ) in the direction of light propagation, the virtual imaging plane being a plane in which a real intermediate image would only be generated if the light beams were not deflected on the light exit surface ( 41 C) of the body ( 4 A), and the light exit surface ( 41 C) of the body ( 4 A) being designed in such a way that when the collimator body light bundle (KLB, KLB′) exits from the body ( 4 A), the light beams are deflected at the light exit surface ( 41 C) and are formed into an exit light bundle (ALB, ALB′) such that the light beams of the exit light bundle (ALB, ALB′) form the intermediate light image in the imaging plane (ZBE, ZBE′), the imaging plane (ZBE, ZBE′) being inclined to the focal plane (BE) and intersecting the focal plane, preferably in the region of the optical axis (X) or above or below the optical axis (X), and the intermediate light image lying in the imaging plane being imaged by the projection device ( 5 ) into a region in front of the lighting device ( 1 ) as a light distribution or part of a light distribution. 2. The lighting device according to claim 1 , wherein all light beams of the exit light bundle (ALB, ALB′) of the at least one convergence imaging unit ( 2 ) converge, wherein the light beams of the exit light bundle (ALB, ALB′) converge less than the light beams of the collimator body light bundle (KLB). 3. The lighting device according to claim 1 , wherein the virtual intermediate light image plane (VBE, VBE′) of the at least one convergence imaging unit ( 2 ) lies in the light propagation direction after the light exit surface ( 41 C). 4. The lighting device according to claim 1 , wherein an aperture device ( 6 ) is provided between the at least one convergence imaging unit ( 2 ) and the projection device ( 5 ), having at least one aperture edge ( 61 ), which at least one aperture edge ( 61 ) lies substantially in the focal plane (BE) of the projection device ( 5 ). 5. The lighting device according to claim 4 , wherein the aperture device ( 6 ) which is a horizontal aperture ( 60 ), which is reflective on its upper side ( 60 A) and/or on its underside ( 60 B). 6. The lighting device according to claim 4 , wherein the at least one convergence imaging unit ( 2 ) comprises two or more convergence imaging unit ( 2 ) and wherein a plurality of or all of the convergence imaging units ( 2 ) together are configured to generate a first light distribution (LV 1 ) on one side, above or below, of the aperture device ( 6 ). 7. The lighting device according to claim 6 , wherein the at least one convergence imaging unit ( 2 ) comprises two or more convergence imaging unit ( 2 ) and wherein a plurality of or all of the convergence imaging units ( 2 ) together are configured to generate a second light distribution (LV 2 ) on one side, below or above, of the aperture device ( 6 ), which is on the other side than that side on which the first light distribution (LV 1 ) is generated. 8. The lighting device according to claim 4 , wherein the at least one convergence imaging unit ( 2 ) comprises two or more convergence imaging unit ( 2 ) and a plurality of the convergence imaging units ( 2 ) on one side of the aperture device ( 6 ) are arranged in one plane. 9. The lighting device according to claim 8 , wherein the one plane is a plane parallel to the aperture device ( 6 ). 10. The lighting device according to claim 4 , wherein in the case of a plurality of convergence imaging units ( 2 ) on one side of the aperture device ( 6 ), these convergence imaging units ( 2 ) are rotated horizontally and/or vertically with respect to one another, in particular in such a way that the intermediate light images generated by the convergence imaging units ( 2 ) in the imaging plane (ZBE, ZBE′) at least partially overlap or adjoin the immediately adjacent intermediate light images in each case. 11. The lighting device according to claim 4 , wherein the aperture device ( 6 ) is a horizontal, flat aperture ( 60 ), which has the aperture edge ( 61 ) in a front region facing the projection device ( 5 ). 12. The lighting device according to claim 1 , wherein the lighting device ( 1 ) has a plurality of imaging units, and wherein at least two of the imaging units ( 2 ) are configured as convergence imaging units ( 2 ). 13. The lighting device according to claim 1 , wherein a plurality of or all of the convergence imaging units ( 2 ) jointly generate a first light distribution (LV 1 ). 14. The lighting device according to claim 13 , wherein the first light distribution (LV 1 ) is a low beam distribution. 15. The lighting device according to claim 13 , wherein a plurality of or all of the convergence imaging units ( 2 ) jointly generate a second light distribution (LV 2 ) or jointly generate a part of a second light distribution (LV 2 ), which part together with the first light distribution (LV 1 ) results in the second light distribution. 16. The lighting device according to claim 15 , wherein the second light distribution (LV 2 ) is a high beam distr