Systems and methods for implementing three dimensional (3D) object, part and component manufacture including locally laser welded laminates

We claim: 1. An object manufacturing system, comprising: a laminate cutter for cutting two-dimensional (2D) slices from sheets of material, each of the 2D slices constituting an individual layer among a plurality of layers forming an in-process three-dimensional (3D) object; a transport mechanism for transporting each of the cut 2D slices from the laminate cutter to a 3D object build platform to form the plurality of layers of the in-process 3D object; a laser welding system associated that sequentially laser welds each of the 2D slices in sequence to form the plurality of layers of the in-process 3D object; and a surface finishing device that surface finishes the in-process 3D object to produce a finished 3D object. 2. The system of claim 1 , further comprising a processor that is programmed to: reference 3D object modeling data; parse the referenced 3D object modeling data into instructions for controlling the laminate cutter for cutting each of the 2D slices from the sheets of material; control a layer by layer 2D slice cutting, transporting and adhering process to produce the in-process 3D object from the plurality of layers; and control the surface finishing device to finish the surface of the in-process 3D object. 3. The system of claim 2 , further comprising a data storage memory medium storing the 3D object modeling data for reference by the processor. 4. The system of claim 1 , further comprising a material input component that stores the sheets of material as at least one of stacked sheet of material or rolled sheets of material. 5. The system of claim 1 , the laminate cutter comprising one of a laser cutter, a mechanical milling cutter, a mechanical blade cutter and a waterj et cutter. 6. The system of claim 1 , the transport mechanism comprising a robotic pick and place device. 7. The system of claim 1 , the surface finishing device comprising a multi-axis Computer Numerical Control (CNC) milling machine. 8. The system of claim 1 , the sheets of material being formed of infra-red (IR) transparent materials, the laser welding system forming a plurality of IR absorbers on a surface of at least one of a pair of 2D slices such that when the pair of 2D slices are brought together the formed plurality of IR absorbers are sandwiched between the pair of 2D slices as a formed assembly; and scanning the formed assembly with laser energy to weld the 2D slices together at the positions of the IR absorbers. 9. The system of claim 8 , the IR absorbers being formed by the laser welding system in one of a fused deposition modelling and a multi-jet modelling process executed by components of the laser welding system. 10. The system of claim 1 , wherein: the sheets of material are formed of IR absorbing materials, the laminate cutter is employed to additionally cut a plurality of through features in a next 2D slice, the next 2D slice is transported and stacked on already processed 2D slices as a next layer in the in-process 3D object; and laser energy from the laser welding system is directed at corners formed by the through features or other features of the next 2D slice interacting with the already processed 2D slices in a directed laser welding process to form weld beads locally at the corners. 11. The system of claim 10 , further comprising a material deposition unit that applies additional material in one of a fused deposition modelling and a multi-jet modelling process to fill remaining cavities in the next 2D slice or a top 2D slice remaining of the through features after the directed laser welding process. 12. The system of claim 1 , the sheets of material being formed of a material comprising a thermoplastic.