Multiple beam additive manufacturing

What is claimed is: 1. A method for multiple beam additive manufacturing of a three-dimensional structure formed by a plurality of build layers, the method comprising: providing an array of light sources and an array of optical fibers coupled to the array of light sources, respectively, and an optical head including output ends of the optical fibers; delivering powder layers of powder material on a powder bed support system that moves vertically and incrementally to accommodate each of the powder layers; and forming build layers of the three-dimensional structure in each of the powder layers of powder material, wherein forming each of the build layers includes performing multiple beam distributed exposures on different regions of each powder layer to selectively fuse corresponding regions of the powder material, wherein performing each of the multiple beam distributed exposures includes simultaneously generating light from selected light sources in the array of light sources such that beams of light are emitted from the output ends of the optical fibers coupled to the selected light sources and directed to the corresponding regions of each powder layer to form a distributed exposure pattern including spaced beam spots and performing the multiple beam distributed exposures on each of the powder layers includes scanning the optical head with an interleaved scan pattern across the powder layer using the distributed exposure pattern, wherein the beams of light are directed with a power and duration sufficient to melt the powder material in the corresponding regions such that the powder material in the corresponding regions fuses to form fused regions, wherein the beam spots in each of the multiple beam distributed exposures are spaced sufficiently in a non-contiguous array to separate the fused regions formed by each of the multiple beam distributed exposures and are interleaved to fill spaces between the spaced beam spots, wherein each of the fused regions corresponds to a voxel of the three-dimensional structure and wherein the fused regions of the powder material in each of the powder layers collectively form each of the respective build layers of the three-dimensional structure. 2. The method for multiple beam additive manufacturing of claim 1 wherein the light sources include laser diodes. 3. The method for multiple beam additive manufacturing of claim 1 wherein the light sources include fiber lasers. 4. The method for multiple beam additive manufacturing of claim 1 wherein the output ends of the optical fibers are arranged in a one-dimensional array in the optical head. 5. The method for multiple beam additive manufacturing of claim 1 wherein the output ends of the optical fibers are arranged in a two-dimensional array in the optical head. 6. The method for multiple beam additive manufacturing of claim 1 wherein performing multiple beam distributed exposures on different regions of the powder layer includes moving the optical head relative to the powder layers to different locations for each of the multiple beam distributed exposures. 7. The method for multiple beam additive manufacturing of claim 6 wherein the optical head performs multiple beam distributed exposures on the powder layer as the powder layer is being delivered. 8. The method for multiple beam additive manufacturing of claim 1 wherein the output ends of the optical fibers are arranged in a two-dimensional staggered array such that a beam spot produced by one of the output ends overlaps a beam spot produced by an adjacent one of the output ends in a previous multiple beam distributed exposure. 9. The method for multiple beam additive manufacturing of claim 1 wherein the optical head is configured to produce beam spots having a size in a range of 50 to 300 μm and a spacing in a range of 150 to 600 μm. 10. The method for multiple beam additive manufacturing of claim 1 wherein performing the multiple beam distributed exposures includes scanning the beams of light using scanning optics. 11. The method for multiple beam additive manufacturing of claim 1 wherein the powder material includes a metal powder. 12. The method for multiple beam additive manufacturing of claim 11 wherein the metal powder includes particles having a particle size greater than 30 μm microns and particles having a particle size less than-5 μm. 13. The method for multiple beam additive manufacturing of claim 11 wherein the metal powder includes particles having a particle size greater than 50 μm. 14. The method for multiple beam additive manufacturing of claim 1 wherein the optical head includes imaging optics. 15. The method for multiple beam additive manufacturing of claim 14 further comprising controlling a size and spacing of the beam spots in the distributed exposure pattern by defocusing the beams relative to a processing surface. 16. The method for multiple beam additive manufacturing of claim 1 further comprising adjusting at least one of beam spot size and power to adjust a resolution of voxels at different regions of at least one of the build layers. 17. The method of claim 1 wherein the spaced beam spots in each of the multiple beam distributed exposures produce corresponding melt balls having a smaller size than the beam spots, and wherein the multiple beam distributed exposures are overlayed such that the melt balls overlap to fill the spaces between the melt balls formed by a previous one of the distributed exposures. 18. A method for multiple beam additive manufacturing of a three-dimensional structure formed by a plurality of build layers, the method comprising: delivering a powder layer of powder material to a powder bed support system, wherein the powder material includes a metal powder and wherein the metal powder includes particles having asymmetric particle sizes including particles having a particle size greater than 30 μm microns and particles having a particle size less than 5 μm; forming a build layer of the three-dimensional structure in the powder layer of powder material, wherein forming the build layer includes performing multiple beam distributed exposures on different regions of the powder layer to selectively fuse corresponding regions of the powder material in the powder layer, wherein performing each of the multiple beam distributed exposures includes simultaneously directing light beams to the corresponding regions of the powder layer to form a distributed exposure pattern including spaced beam spots, wherein the beams of light are directed with a power and duration sufficient to melt the powder material in the corresponding regions such that the powder material in the corresponding regions fuses to form fused regions, wherein the beam spots in each of the multiple beam distributed exposures are spaced sufficiently to separate the fused regions formed by each of the multiple beam distributed exposures, and wherein the fused regions of the powder material formed by the multiple beam distributed exposures collectively form the build layer; and repeating the delivering a powder layer and the forming a build layer in the powder layer to form each of the build layers of the three-dimensional structure and wherein each of the fused regions corresponds to a voxel of the three-dimensional structure. 19. The method for multiple beam additive manufacturing of claim 18 wherein the beams of light form a one dimensional array of beam spots. 20. The method for multiple beam additive manufacturing of claim 18 wherein the beams of light form a two-dimensional ar