Method of and a welding station for laying a pipeline, with pipe section welded together by internal and external welding

The invention claimed is: 1. A method of laying an undersea pipeline, in which pipe sections are welded together to form the pipeline, wherein the method includes the following steps: providing a pipe section to be welded to the end of an undersea pipeline, the pipeline being in the form of a multi-layer pipeline, having one metallic layer which is made from a metal different from that of an adjacent layer, arranging the pipe section adjacent to the end of the pipeline thereby defining a circumferential joint to be welded, performing an external weld pass on the root of the joint to be welded during which a plurality of separate welding heads simultaneously deposit weld material in the root at different circumferential positions around the pipes, thereby forming a root weld, and performing an internal weld pass on the root weld using plasma welding equipment during which the root weld is melted and re-shaped. 2. A method according to claim 1 , wherein the step of performing the external weld pass on the root weld is performed by using a consumable electrode. 3. A method according to claim 1 , wherein the step of performing the external weld pass on the root of the joint produces a root weld which on the internal surface of the pipes has a rough shape, and the step of performing the internal weld pass on the root weld remelts and reshapes the root weld so that on the internal surface of the pipes the root weld has a smoother shape. 4. A method according to claim 1 , wherein the step of performing the external weld pass on the root of the joint produces a root weld which is not fully fused to the pipes, and the step of performing the internal weld pass on the root weld remelts the root weld so that it becomes fully fused to the pipes. 5. A method according to claim 1 , wherein the method includes a step of performing an external cap weld pass on the cap of the joint to be welded during which weld material is deposited on the cap of the joint to be welded, thereby forming a cap weld, and the step of performing the internal weld pass on the root weld is performed before the completion of the step of performing an external cap weld pass. 6. A method according to claim 1 , wherein after the step of performing the internal weld pass on the root weld, a step of non-destructive testing is performed, during which the quality of root weld is inspected by means of one or more cameras inside the pipes. 7. A method according to claim 1 , wherein the method includes performing a plurality of internal weld passes per weld joint. 8. A method according to claim 1 , wherein the pipeline is a carbon steel pipeline with a corrosion resistant alloy interior, and at least one of the steps of (i) performing the external weld pass on the root of the joint and (ii) performing the internal weld pass on the root of the joint, includes adding weld material having the same composition both to carbon steel material in the pipeline and to corrosion resistant alloy material in the pipeline. 9. A welding station for use in a method of laying an undersea pipeline, in which pipe sections are welded together to form the pipeline being in the form of a multilayer pipeline, having one metallic layer which is made from a metal different from that of an adjacent layer, wherein the welding station includes: exterior welding apparatus including a plurality of welding heads and external guiding apparatus, each head having at least one welding torch, the welding heads being arranged to simultaneously weld the pipe sections together from outside the pipe sections to form a weld joint and to be guided along the joint to be welded at least partly by the exterior guiding apparatus, an internal line-up clamp for holding the aligned pipe sections in place, and interior welding apparatus having at least one welding head having a plasma welding torch, the welding head being arranged to remelt a weld joint formed by the exterior welding apparatus and to be guided along the joint by means of internal guiding apparatus, wherein the exterior welding apparatus is arranged to be able to operate simultaneously with the interior welding apparatus. 10. A welding station according to claim 9 , wherein the welding heads of the exterior welding apparatus are consumable-electrode welding heads. 11. A welding station according to claim 9 , wherein the internal line-up clamp also holds non-destructive testing equipment for performing non-destructive testing on the root weld from inside the pipe sections. 12. A welding station according to claim 9 , wherein the internal line-up clamp includes an umbilical assembly, and the interior welding apparatus defines a central open region accommodating said umbilical assembly. 13. A welding station according to claim 9 , wherein the internal line-up clamp holds the internal guiding apparatus. 14. A welding station according to claim 9 , wherein the interior welding apparatus is provided on a carriage that is moveable independently of the internal line-up clamp. 15. A pipe-laying vessel arranged to lay an undersea pipeline in the form of a multi-layer pipeline, having one metallic layer which is made from a metal different from that of an adjacent layer, the pipeline laying vessel including a plurality of welding stations arranged in series in the pipe-laying direction, wherein at least one of the welding stations is a welding station, which includes: exterior welding apparatus including a plurality of welding heads and external guiding apparatus, each head having at least one welding torch, the welding heads being arranged to simultaneously weld the pipe sections together from outside the pipe sections to form a weld joint and to be guided along the joint to be welded at least partly by the exterior guiding apparatus, an internal line-up clamp for holding the aligned pipe sections in place, and interior welding apparatus having at least one welding head having a plasma welding torch, the welding head being arranged to remelt a weld joint formed by the exterior welding apparatus and to be guided along the joint by means of internal guiding apparatus, wherein the exterior welding apparatus is arranged to be able to operate simultaneously with the interior welding apparatus. 16. A method of laying an undersea pipeline, in which pipe sections are welded together to form the pipeline, wherein the method includes the following steps: providing a multi-layer pipe section to be welded to the end of a multi-layer pipeline, the multi-layers of each of the pipe section and of the pipeline having one metallic layer which is made from a metal different from that of an adjacent layer, and each of the pipe section and the pipeline having an end which is beveled; arranging the beveled end of the pipe section adjacent to the beveled end of the pipeline thereby defining a circumferential joint to be welded, performing a plurality of external weld passes to form a substantially full penetration weld, including an external weld pass on the root of the joint to be welded during which weld material is deposited in the root of the joint to be welded, thereby forming a root weld, and performing an internal weld pass on the root weld using plasma welding equipment during which the root weld is melted and re-shaped. 17. A method according to claim 16 , wherein the pipeline is a carbon steel pipeline with a corrosion resistant alloy interior, and at least one of the steps of (i) performing the external weld pass on the root of the joint and (ii) performing the internal weld pass on the root of t