Machine component cladding strategy

What is claimed is: 1. A method of cladding a machine component comprising the steps of: splitting an incident laser beam into a cleaning beam and a welding beam; directing the cleaning and welding beams toward a machine component such that the cleaning and welding beams impinge upon a surface of the machine component; moving the machine component relative the cleaning and welding beams such that the welding beam trails behind the cleaning beam along a common travel path upon the surface; decontaminating the surface along the common travel path via the cleaning beam; and melting a cladding material via the welding beam such that the melted cladding material contacts the decontaminated surface along the common travel path and upon solidifying bonds to material of the machine component forming the surface, wherein the surface is substantially cylindrical and defines a center axis, and the step of moving includes axially advancing the machine component relative the cleaning and welding beams, wherein the material forming the surface includes a base material of the machine component and cladding material in the form of a previously deposited bead, such that the melted cladding material upon solidifying forms a newly deposited bead overlapping the previously deposited bead, and wherein the step of moving further includes circumferentially advancing the machine component relative the cleaning and welding beams such that the newly deposited bead is helical. 2. The method of claim 1 further comprising repeating the decontaminating and melting steps a plurality of times so as to circumferentially coat the entire surface with a plurality of overlapping helical beads. 3. The method of claim 1 wherein: the step of decontaminating includes volatilizing contaminants from the base material and the cladding material of the previously deposited bead; and the step of melting further includes melting the cladding material such that the melted cladding material contacts the decontaminated surface in a molten state prior to recontamination of the surface. 4. The method of claim 3 further comprising a step of pulsing the cleaning beam such that the impingement of the cleaning beam is discontinuous. 5. The method of claim 1 wherein the step of melting further includes melting the cladding material such that the melted cladding material upon solidifying metallurgically bonds to a base material of the machine component and previously deposited cladding material together forming the surface. 6. The method of claim 5 wherein the step of moving further includes moving the machine component such that beam spots of the cleaning and welding beams synchronously advance along the common travel path. 7. The method of claim 6 wherein the common travel path is helical. 8. A method of remanufacturing a machine component comprising the steps of: receiving a machine component after service in a machine system and having been machined to remove material of the machine component having a defect therein; directing a cleaning beam and a welding beam each split from an incident laser beam toward a surface of the machine component formed at least in part via the machining, such that the cleaning and welding beams impinge upon the surface; moving the machine component relative the cleaning and welding beams such that the welding beam trails behind the cleaning beam along a common travel path upon the surface; decontaminating the surface along the common travel path via the cleaning beam; and melting a cladding material via the welding beam such that the melted cladding material contacts the decontaminated surface along the common travel path and upon solidifying forms a coating bonded to the machine component in place of the removed material, wherein the surface of the machine component includes a cylindrical surface reduced in diameter from a specification via the machining, and further comprising a step of restoring the diameter to the specification via the coating and wherein the step of melting further includes melting the cladding material such that the melted cladding material upon solidifying forms the coating in the form of a helical bead overlapping a previously deposited helical bead of cladding material. 9. The method of claim 8 wherein the machine component includes an engine shaft and the cylindrical surface includes a bearing surface of the engine shaft. 10. The method of claim 8 wherein the step of melting further includes melting the cladding material in contact with the decontaminated surface such that upon solidifying the coating is metallurgically bonded to base material of the machine component and to the previously deposited cladding material. 11. The method of claim 10 wherein the step of decontaminating further includes volatilizing contaminants from the base material and the previously deposited cladding material such that the coating is nonporous. 12. The method of claim 11 wherein the step of moving includes synchronously moving the machine component at a speed relative the cleaning and welding beams and at a spacing of the cleaning and welding beams such that melted cladding material contacts the surface prior to oxide recontamination of the base material and the previously deposited cladding material.