Method for connecting two unitary elements of a conduit for transporting fluids by means of a sleeve

The invention claimed is: 1. A method of connecting together two unit elements of a fluid transport pipe, each unit pipe element being made of metal alloy and being covered in an outer insulating coating made of a thermoplastic material, with the exception of an end portion that does not have an outer insulating coating, the method comprising: a step of welding together two unit pipe elements abutting at their end portions not having any outer insulating coating so as to form an annular cut-back; a step of applying an anti-corrosive barrier to a surface of the annular cut-back; a step of, after applying the anti-corrosive barrier, positioning an annular sleeve around the cut-back and the anti-corrosive barrier, and in part around the outer insulating coatings of the two unit pipe elements, the annular sleeve being made of a thermoplastic material; a step of fastening the annular sleeve in sealed manner by weld bonding on the outer insulating coatings of the two unit pipe elements; and a step of applying an external pressure on the annular sleeve to enable it to be deformed plastically and match the shape of the respective end portions of the two unit pipe elements; wherein the step of positioning the annular sleeve includes sliding the annular sleeve along one of the unit pipe elements. 2. The method according to claim 1 , wherein the step of fastening the annular sleeve in sealed manner on the outer insulating coatings of the two unit pipe elements is performed by laser-bonded coating using a laser. 3. The method according to claim 2 , wherein the thermoplastic material constituting the annular sleeve is transparent or translucent at a laser wavelength of a magnitude sufficient to allow the laser beam produced by the laser at such wavelength to pass through the annular sleeve to surfaces to be bonded together, the laser-bonded coating of the annular sleeve optionally including positioning films of material that is absorbent at the laser wavelength between the contacting surfaces of the annular sleeve and of the outer insulating coatings of the two unit pipe elements. 4. The method according to claim 2 , wherein the external pressure applied on the annular sleeve lies in the range 1 bar to 2 bars. 5. The method according to claim 2 , wherein the external pressure is applied on the annular sleeve before, during, and after the step of fastening the annular sleeve in sealed manner by weld bonding. 6. The method according to claim 1 , wherein the step of fastening the annular sleeve in sealed manner on the outer insulating coatings of the two unit pipe elements is performed by fusion-bonded coating. 7. The method according to claim 6 , wherein the annular sleeve includes at least one electrical resistance at an internal surface that, during the step of positioning the annular sleeve, is put into contact with the portions of the outer insulating coatings of the unit pipe elements that are covered by said annular sleeve and that is connected to a source of electricity in order to cause the surface of the material constituting the annular sleeve to melt so as to provide sealed fastening of the annular sleeve on the outer insulating coatings of the unit pipe elements. 8. The method according to claim 6 , wherein the external pressure applied on the annular sleeve lies in the range 1 bar to 2 bars. 9. The method according to claim 6 , wherein the external pressure is applied on the annular sleeve before, during, and after the step of fastening the annular sleeve in sealed manner by weld bonding. 10. The method according to claim 1 , wherein the external pressure applied on the annular sleeve lies in the range 1 bar to 2 bars. 11. The method according to claim 1 , wherein the external pressure is applied on the annular sleeve before, during, and after the step of fastening the annular sleeve in sealed manner by weld bonding. 12. The method according to claim 1 , wherein the anti-corrosive barrier is a polymer coating: in liquid form, in powder form, or as a heat-shrinkable anti-corrosive sleeve.