Method for laser melting with at least one working laser beam

The invention claimed is: 1. A method for laser melting to form a component in layers in a bed of powder, the method comprising: melting particles forming the bed of powder using a working laser beam; directing a respective centerpoint each of a plurality of auxiliary laser beams, each auxiliary laser beam having a power density too low to melt the particles, onto at least one of a cooling molten pool formed by the melted particles and a cooling zone on the component, adjacent the molten pool after a centerpoint of the working laser beam has moved away to a new working position; guiding the plurality of auxiliary laser beams in a pattern of movement to form a heat influencing area having one of a crescent shape and a horseshoe shape, open in a direction of movement of the working laser beam; wherein the respective centerpoints of the plurality of auxiliary laser beams are spaced apart from each other and from the centerpoint of the working laser beam at any point in time; controlling the power density of the at least one auxiliary laser beam in dependence upon a volume of the component, already produced, surrounding the cooling zone; and cooling the molten pool until solidified to form a solidified layer of the component, while at least one of reducing the power density and gradually switching off auxiliary laser beams as less of the volume of the component is available for heat removal. 2. The method as claimed in claim 1 , further comprising guiding the centerpoint of at least one of the plurality of auxiliary laser beams with a time delay based on a pattern of movement coinciding with the working laser beam so that the centerpoint of the at least one auxiliary laser beam reaches an area the working laser beam has previously melted after the centerpoint of the working laser beam has moved away to the new working position. 3. The method as claimed in claim 1 , wherein the at least one auxiliary laser beam is a plurality of auxiliary laser beams produced from one laser beam by a beam splitter. 4. The method as claimed in claim 1 , further comprising beam widening of at least one of the plurality of auxiliary laser beams. 5. The method as claimed in claim 1 , wherein said directing directs at least one of the plurality of auxiliary laser beams onto an edge of the molten pool. 6. The method as claimed in claim 1 , wherein said directing directs at least one of the plurality of auxiliary laser beams onto a part of the solidified layer in the cooling zone. 7. The method as claimed in claim 1 , wherein the power density of at least one of the plurality of auxiliary laser beams is over 50% of a melting power density required for melting the particles. 8. The method as claimed in claim 1 , wherein the power density of at least one of the plurality of auxiliary laser beams is over 70% of a melting power density required for melting the particles. 9. The method as claimed in claim 1 , wherein the power density of at least one of the plurality of auxiliary laser beams is over 30% of a working power density of the working laser beam. 10. The method as claimed in claim 1 , wherein the power density of at least one of the plurality of auxiliary laser beams is over 50% of a working power density of the working laser beam. 11. The method as claimed in claim 1 , wherein the respective centerpoints of the plurality of auxiliary laser beams are spaced at different distances from the centerpoint of the working laser beam. 12. The method as claimed in claim 11 , wherein the plurality of auxiliary laser beams at increasing distances from the working laser beam are operated with respectively lower power densities. 13. The method as claimed in claim 1 , further comprising preheating the particles, before said melting by the working laser beam, using at least one of the plurality of auxiliary laser beams having a low power density too low to melt the particles. 14. The method as claimed in claim 1 , wherein the particles are formed of a heat-resistant metal alloy. 15. The method as claimed in claim 1 , wherein the particles are formed of a heat-resistant steel. 16. The method as claimed in claim 1 , wherein the particles are formed of a heat-resistant nickel-based alloy. 17. A method for laser melting to form a component in layers in a bed of powder, the method comprising: melting particles forming the bed of powder by a working laser beam; directing a centerpoint of a first auxiliary laser beam, having a power density too low to melt the particles, onto at least one of a cooling molten pool formed by the melted particles and a cooling zone on the component, adjacent the molten pool after a centerpoint of the working laser beam has moved away to a new working position; wherein the centerpoint of the working laser advances along a working laser path in a movement direction, and the centerpoint of the first auxiliary laser beam simultaneously advances along a first auxiliary laser path that is parallel to the working laser path but offset from the working laser path in a direction perpendicular to the movement direction; and cooling the molten pool until solidified to form a solidified layer of the component, while at least one of reducing the power density and gradually switching off the first auxiliary laser beam as less of the volume of the component is available for heat removal. 18. The method as claimed in claim 17 , comprising directing a plurality of auxiliary laser beams including the first auxiliary laser beam, each having a power density too low to melt the particles, onto at least one of the cooling molten pool formed by the melted particles and the cooling zone on the component. 19. The method as claimed in claim 18 , wherein the plurality of auxiliary laser beams includes a second auxiliary laser beam having a centerpoint that advances along the working laser path in the movement direction. 20. A method for laser melting to form a component in layers in a bed of powder, the method comprising: melting particles forming the bed of powder by a working laser beam; directing a centerpoint of a first auxiliary laser beam, having a power density too low to melt the particles, onto at least one of a cooling molten pool formed by the melted particles and a cooling zone on the component, adjacent the molten pool after a centerpoint of the working laser beam has moved away to a new working position; wherein the centerpoint of the first auxiliary laser beams is spaced apart from the centerpoint of the working laser beam; wherein the first auxiliary laser beam is widened, as compared with the working laser beam, such that a surface area impinged by the first auxiliary laser beam is larger than a corresponding surface area impinged by the working laser beam; and cooling the molten pool until solidified to form a solidified layer of the component, while at least one of reducing the power density and gradually switching off the first auxiliary laser beam as less of the volume of the component is available for heat removal. 21. The method as claimed in claim 17 , comprising directing a plurality of auxiliary laser beams including the first auxiliary laser beam and a second auxiliary laser beam, each having a power density too low to melt the particles, onto at least one of the cooling molten pool formed by the melted particles and the cooling zone on the component; wherein the second auxiliary laser beam is widened to a different extent than the first auxiliary laser beam, such that surface area impinged by the second a