Pipe for control and forced circulation of corrosion-inhibiting fluids in the annulus thereof

The invention claimed is: 1. A pipe for control and forced circulation of corrosion-inhibiting fluids in an annulus thereof, the annulus being located between an inner pressure barrier and an outer cover of the pipe and containing a number of layers, the pipe comprising: two layers of tensile armor within the annulus; at least one injection pipe laid helicoidally on a longitudinal extension of the pipe; at least one return pipe laid helicoidally on the longitudinal extension of the pipe; and a ventilation layer within the annulus, the ventilation layer comprising ventilation tape providing longitudinal channels relative to a longitudinal axis of the pipe to facilitate a flow of fluids longitudinally through the annulus of the pipe. 2. The pipe according to claim 1 , wherein the ventilation tape is laid helicoidally on at least part of the longitudinal extension of the pipe. 3. The pipe according to claim 2 , wherein the ventilation tape comprises grooves across a width of the ventilation tape. 4. The pipe according to claim 3 , wherein the ventilation tape is laid such that the grooves are aligned, forming the longitudinal channels relative to the longitudinal axis of the pipe. 5. The pipe according to claim 2 , wherein the ventilation tape comprises holes through a width of the ventilation tape. 6. The pipe according to claim 5 , wherein the ventilation tape is laid such that holes are aligned to form the longitudinal channels relative to the longitudinal axis of the pipe. 7. The pipe according to claim 2 , wherein the ventilation tape is made of one of: cloth; metal; polymer; aramid threads; glass filaments; extruded material; and helicoidally braided tapes. 8. The pipe according to claim 1 , further comprising a layer of anti-swelling or anti-extrusion tape applied helicoidally on the inner pressure barrier, wherein the tape is applied as successive overlapping loops, and wherein the tape contains holes to allow fluid to pass through. 9. The pipe according to claim 1 , wherein the ventilation layer is positioned between two layers of anti-friction tape, the two layers of anti-friction tape being positioned between the two layers of tensile armor. 10. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe are positioned as replacements for wires of the tensile armor. 11. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe are arranged helicoidally within a filling layer, consisting of structural elements that protect the at least one injection pipe and the at least one collecting pipe from radial compression. 12. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe are positioned on the outer cover of the pipe. 13. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe comprise a cross-sectional shape selected from: round; oval; and rectangular. 14. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe comprise metal coated with a polymer layer. 15. The pipe according to claim 1 , wherein at least one injection pipe and at least one collecting pipe are of a hose type that is resistant to hydrostatic collapse. 16. The pipe according to claim 1 , wherein the ventilation layer is configured to increase an area of voids in a cross-section of the annulus of the pipe. 17. A riser formed by connecting a plurality of pipes according to claim 1 . 18. A method of constructing a pipe, the pipe being for control and forced circulation of corrosion-inhibiting fluids in an annulus thereof, the annulus being located between an inner pressure barrier and an outer cover of the pipe and containing a number of layers, the method comprising: providing two layers of tensile armor within the annulus; providing at least one injection pipe laid helicoidally on a longitudinal extension of the pipe; providing at least one return pipe laid helicoidaily on the longitudinal extension of the pipe; and providing a ventilation layer comprising ventilation tape within the annulus to increase an area of voids in a cross-section of the annulus of the pipe, the ventilation layer being configured to provide longitudinal channels relative to a longitudinal axis of the pipe to facilitate a flow of fluids longitudinally through the annulus of the pipe. 19. A method of inhibiting corrosion in a pipe having an annulus, the annulus being located between an inner pressure barrier and an outer cover of the pipe and containing a number of layers, the method comprising: providing corrosion-inhibiting fluid to the pipe annulus via at least one injection pipe laid helicoidaily on a longitudinal extension of the pipe; circulating the corrosion-inhibiting fluid within the annulus of the pipe, including through longitudinal channels relative to a longitudinal axis of the pipe formed in ventilation tape of a ventilation layer provided within the annulus to increase an area of voids in a cross-section of the annulus; and removing corrosion-inhibiting fluid from the pipe annulus via at least one return pipe laid helicoidally on the longitudinal extension of the pipe.