Welding process

The invention claimed is: 1. A method for welding a first component to a second component, the method comprising: positionally calibrating a scanning head within a localised work envelope, the work envelope being defined by boundaries surrounding the first component and the second component, the positional calibration being referenced to at least one datum feature within the work envelope; scanning profiles of the first component and the second component within the work envelope using the calibrated scanning head; generating, from the scanned profiles, a cloud point data image of defined coordinate positions of surfaces and edges of the first component and the second component to be welded within a space envelope, the space envelope being larger than the work envelope, which is located inside the space envelope; scanning an electrode tip of a robotic welding torch using the calibrated scanning head to determine a defined coordinate position of the electrode tip within the space envelope, the electrode tip of the robotic welding torch being located outside of the work envelope at a time of scanning the electrode tip; and welding the first component to the second component using the robotic welding torch, movement of the robotic welding torch being controlled using the cloud point data image and the defined coordinate position of the electrode tip, such that the electrode tip is held at a plurality of pre-determined stand-off positions around the first component and the second component within the work envelope during the welding. 2. The method of claim 1 , wherein the scanning head is positionally calibrated along x, y, z linear orthogonal axes within the localised work envelope. 3. The method of claim 1 , further comprising, before positionally calibrating the scanning head, positioning the scanning head by reference to a master theoretical model of the position of the first component and the position of the second component within the space envelope. 4. The method of claim 1 , wherein the scanning head is attached to a robotic arm having a first orientation for scanning profiles of the first component and the second component, and a second orientation for scanning the electrode tip. 5. The method of claim 1 , further comprising determining, from the cloud point data image of surfaces and edges to be welded, whether predetermined weld joint characteristics are satisfied, such that the welding of the first component to the second component is stopped in response to determining that the predetermined weld joint characteristics are not satisfied. 6. The method of claim 1 , wherein the scanning head includes a 3D optical visualiser. 7. The method of claim 1 , wherein the welding is tungsten inert gas (TIG) welding. 8. A computer control system programmed to control the scanning head and the robotic welding torch to perform the method of claim 1 . 9. An apparatus for welding the first component to the second component, the apparatus comprising: the scanning head; the robotic welding torch; and the computer control system of claim 8 . 10. A non-transitory computer readable storage medium storing a computer program to be executed on a computer, causing the computer to control the scanning head and the robotic welding torch to perform the method of claim 1 . 11. An apparatus for welding a first component to a second component, the apparatus comprising: a scanning head; a robotic welding torch; and a computer control system programmed to: positionally calibrate the scanning head within a localised work envelope, the work envelope being defined by boundaries surrounding the first component and the second component, the positional calibration being referenced to at least one datum feature within the work envelope; control the scanning head to scan profiles of the first component and the second component within the work envelope using the calibrated scanning head; generate, from the scanned profiles, a cloud point data image of defined coordinate positions of surfaces and edges of the first component and the second component to be welded within a space envelope, the space envelope being larger than the work envelope, which is located inside the space envelope; control the scanning head to scan an electrode tip of the robotic welding torch to determine a defined coordinate position of the electrode tip within the space envelope, the electrode tip of the robotic welding torch being located outside of the work envelope at a time of scanning the electrode tip; and control the robotic welding torch to weld the first component to the second component, movement of the robotic welding torch being controlled by the control system using the cloud point data image and the defined coordinate position of the electrode tip, such that the electrode tip is held at a plurality of pre-determined stand-off positions around the first component and the second component within the work envelope during the welding.