Method and device for improving the component quality of objects manufactured by an additive manufacturing process

The invention claimed is: 1. A computer-aided method for providing control data to an additive manufacturing device for manufacturing a three-dimensional object, wherein the object is manufactured by the additive manufacturing device by applying a building material layer by layer and by solidifying the building material by supplying radiation energy to locations in each of a plurality of layers corresponding to a cross-section of the object in a respective one of the layers by scanning the locations with at least one beam bundle according to a set of energy introduction parameter values along a number of solidification paths, the method for providing control data comprising: accessing computer-based model data of at least a portion of the object to be manufactured; generating at least one data model of a region of a building material layer to be selectively solidified for manufacturing the at least one object portion, wherein the data model specifies solidification of the building material by moving at least one beam bundle along at least one solidification path, the solidification path extending from a starting point to an end point of the solidification path, and the end point being a section of the solidification path within which solidification of the building material is effected; specifying a set of energy introduction parameter values for the end point of the at least one solidification path, the set of energy introduction parameter values causing a reference value for the radiation power per unit area in the radiation impact area of the beam bundle on the building material to be lower than the reference value for the radiation power per unit area at other locations of the solidification path; and providing control data corresponding to the at least one data model generated in the step of generating, the control data generating a control data set for the additive manufacturing device. 2. The method according to claim 1 , wherein the reference value for the radiation power per unit area in the radiation impact area on the building material at the end point of a solidification path is less than or equal to 50% of the reference value for the radiation power per unit area at the other locations of the solidification path. 3. The method according to claim 1 , wherein the energy introduction parameter values in the radiation impact area at the end point of a solidification path are determined in such a way that a heat conduction welding process takes place when the radiation acts on the building material, wherein a deep penetration welding process takes place at at least one other location of the solidification path when the radiation acts on the building material. 4. The method according to claim 3 , wherein the energy introduction parameter values in the radiation impact area within a section of the solidification path adjacent to the end point are determined in such a way that a heat conduction welding process takes place when the radiation is applied to the building material, wherein a maximum extension of the section corresponds to at most twenty times the maximum extension of the radiation impact area. 5. The method according to claim 1 , further comprising specifying a greater or equal maximum extension of the radiation impact area perpendicular to the direction of movement of the beam bundle than at the other locations of the solidification path and/or a different distribution of radiation intensity per unit area within the radiation impact area for the end point and/or a section of the at least one solidification path adjoining the end point. 6. The method according to claim 1 , further comprising performing a periodic or irregular movement in the working plane having an amplitude which is less than five times a maximum extension of the radiation impact area in the working plane at the end point and/or within a section of the at least one solidification path adjacent to the end point. 7. The method according to claim 1 , wherein the energy introduction parameter values of the beam bundle are specified for a period immediately after the beam is directed to the end point of the solidification path, so that a reference value for the radiation power per unit area in the radiation impact area of the beam bundle on the building material is less than or equal to 50% of the reference value for the radiation power per unit area at the end point. 8. The method according to claim 1 , wherein the energy introduction parameter values are specified in such a way that within the section of the solidification path adjacent to the end point the reference value for the radiation power per unit area decreases in the radiation impact area of the beam bundle. 9. The method according to claim 1 , wherein the beam bundle is directed onto the solidification path so that the speed of movement of the radiation impact area of the beam bundle in the working plane within a section adjacent to an initial point of the solidification path increases by at least 10% and/or decreases within the section of the solidification path adjacent to the end point by at least 20%. 10. The method according to claim 1 , wherein the speed of movement of the radiation impact area of the beam bundle in the working plane within a section of the solidification path adjacent to a starting point and/or within the section adjacent to the end point of the solidification path is varied together with the reference value for the radiation power per unit area in the radiation impact area in such a way that at least at one location the percentage change in the reference value for the radiation power per unit area per unit time is greater than the percentage change in the speed of the movement per unit time. 11. An additive manufacturing method for the manufacturing of a three-dimensional object, wherein the object is manufactured by an additive manufacturing device by applying a building material layer by layer and by solidifying the building material by supplying radiation energy to locations in each of a plurality of layers corresponding to a cross-section of the object in a respective one of the layers by scanning the locations with at least one beam bundle according to a set of energy introduction parameter values along a number of solidification paths, wherein the flow of the additive manufacturing process is controlled by a control data set generated using a method according to claim 1 . 12. A device for providing control data for an additive manufacturing device for manufacturing a three-dimensional object, wherein the object is manufactured by the additive manufacturing device by applying a building material layer by layer and by solidifying the building material by supplying radiation energy to locations in each of a plurality of layers corresponding to a cross-section of the object in a respective one of the layers by scanning the locations with at least one beam bundle according to a set of energy introduction parameter values along a number of solidification paths, wherein the device for providing control data comprises: a data access unit adapted to access computer-based model data of at least a portion of the object to be manufactured; a data model generation unit adapted to generate at least one data model of a region of a building material layer to be selectively solidified for manufacturing the at least one object portion, wherein the data model specifies solidification of the building material by moving at least one beam bundle along at least one solidification path, the solidification path extending from a starting point to an end point of the solidification path, and the end point being a section of the solidification path w