Additive manufacturing method using focused light heating source

The invention claimed is: 1. A method of manufacturing a metallic component by additive manufacturing, the method comprising: providing a work surface on which the component is to be manufactured, providing at least one deposition material being at least one wire from which the component is to be composed, advancing the at least one deposition material to a localized deposition area where the at least one deposition material is added to the component being manufactured, focusing light emitted from at least one light source in the localized deposition area so that the at least one deposition material is deposited for building up the component, wherein the at least one light source is one or more high power electrical lamps or one or more Light Emitting Diodes (LEDs), wherein the at least one focused light has a focused spot size of between 0.5 to 4 mm in the localized deposition area, and mutually moving the work surface and/or the focused light and the at least one deposition material in a way that results in the additive manufacturing of the component, the method being characterized in that the at least one light source emits incoherent light, and in that at least one light focusing mirror and/or lens is used to focus the incoherent light in the localized deposition area, wherein the at least one wire comprises a material selected from the group consisting of pure aluminium, alloyed aluminium, magnesium, titanium, beryllium, steel, nickel, cobalt, copper, solder, brazing alloys and alloys of these materials. 2. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one wire is fed from variable positions around the component being manufactured. 3. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one wire is vertically fed towards the localized deposition area. 4. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one deposition material is a plurality of wires made from different materials which are adapted to be fed independently and simultaneously to the localized deposition area to enable in-situ alloying. 5. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one light beam is focused onto one or more of the following positions in the localized deposition area: an area of the component onto which the at least one deposition material is to be deposited prior to deposition for pre-heating of the component, and the at least one deposition material to be deposited for pre-heating a region of the at least one deposition material prior to contact with the component. 6. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the component being manufactured is moved to variable positions along three-dimensional paths. 7. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one deposition material becomes a molten pool during deposition onto the component being manufactured. 8. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one deposition material remains solid and is deformed and then diffusion bonded or sintered onto the component being manufactured. 9. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one deposition material becomes semi-solid or thixotropic during deposition onto the component being manufactured. 10. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the manufacturing takes place within a vacuum or inert gas chamber. 11. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein an edge forming tool is arranged adjacent one or more outer surfaces of the component being manufactured to obtain a desired shape and/or surface roughness of outer surfaces of the component. 12. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein, while advancing the at least one deposition material, the work surface is located on a space station, on a space craft or on parabolic flights for testing. 13. The method of manufacturing a component by additive manufacturing according to claim 4 , wherein light is focused onto one or more of the following positions in the localized deposition area: an area of the component onto which material is to be deposited prior to deposition for pre-heating of the component, and the at least one deposition material to be deposited for pre-heating a region of the at least one deposition material prior to contact with the component. 14. The method of manufacturing a component by additive manufacturing according to claim 13 , wherein the component being manufactured is moved to variable positions along three-dimensional paths. 15. The method of manufacturing a component by additive manufacturing according to claim 14 , wherein an edge forming tool is arranged adjacent one or more outer surfaces of the component being manufactured to obtain a desired shape and/or surface roughness of outer surfaces of the component. 16. The method of manufacturing a component by additive manufacturing according to claim 4 , wherein the different materials are constitutive metals. 17. The method of manufacturing a component by additive manufacturing according to claim 1 , wherein the at least one light beam generates heat in excess of the melting point of the selected wire in the localized deposition area.