Extruded aliphatic polyketone permeation barrier for spoolable composite pipes

The invention claimed is: 1. A non-metallic spoolable composite pipe for oil and gas flowlines, comprising: an inner extruded tubular liner configured to be in direct contact with a fluid comprising hydrocarbons flowing through the spoolable composite pipe; a polymer reinforcement layer surrounding the inner extruded tubular liner; and an outer extruded tubular cover surrounding the reinforcement layer; where the inner extruded tubular liner comprises an aliphatic polyketone having the formula (I) [[—CH 2 CHR 1 (C═O)—] n [—CH 2 CHR 2 (C═O)—] m ] p ,  (I) where R 1 and R 2 are independently from one another the same or different, where R 1 is selected from the group consisting of hydrogen and an alkyl group, and where R 2 is an alkyl group, and where n is less than 0.5 and n+m=1, where p is an integer between 500 and 5000, where structural units [—CH 2 CHR 1 (C═O)—] and [—CH 2 CHR 2 (C═O)—], are randomly distributed, blocked or both, and where the spoolable composite pipe is configured to operate at temperatures of up to about 110° C. and to carry hydrocarbons having an aromatic content of up to about 35% by volume based on the total hydrocarbons content. 2. The non-metallic spoolable composite pipe of claim 1 configured to carry hydrocarbons having an aromatic and cyclo-aliphatic content of up to about 50% by volume of the total hydrocarbons content. 3. The non-metallic spoolable composite pipe of claim 1 configured to operate in a dry gas environment having a hydrogen sulfide partial pressure of up to 10 barg. 4. The non-metallic spoolable composite pipe of claim 1 , where the spoolable composite pipe is configured to operate at temperatures of from about 80° C. to about 110° C. 5. The non-metallic spoolable composite pipe of claim 1 , where the inner extruded tubular liner is a monolayer extruded tube. 6. The non-metallic spoolable composite pipe of claim 1 , where the aliphatic polyketone is co-extruded with one or more thermoplastic polymer to provide the inner extruded tubular liner having a multilayer system comprising an inner aliphatic polyketone layer and a thermoplastic polymer layer surrounding the aliphatic polyketone layer. 7. The non-metallic spoolable composite pipe of claim 1 , where the spoolable composite pipe is unbonded, semi-bonded, or bonded. 8. The non-metallic spoolable composite pipe of claim 1 , where the polymer reinforcement layer comprises a material selected from the group consisting of dry glass fibers, aramid fibers, carbon fibers, steel fibers or strips, glass-reinforced epoxy laminates, and unidirectional thermoplastic composite tapes. 9. The non-metallic spoolable composite pipe of claim 1 , further comprising a bonding layer between the liner and the reinforcement layer. 10. The non-metallic spoolable composite pipe of claim 1 , further comprising a bonding layer between the reinforcement layer and the cover. 11. A method of producing the non-metallic spoolable composite pipe for oil and gas flowlines of claim 1 , the method comprising: extruding the aliphatic polyketone having the formula (I) to form the inner tubular liner; forming the polymer reinforcement layer over the inner extruded tubular liner to form the non-metallic spoolable composite pipe; and providing the outer extruded tubular cover over the thermoplastic-based reinforcement layer. 12. A method of transporting a hydrocarbon fluid having an aromatic content of up to about 35% by volume based on the total hydrocarbons content, the method comprising: providing the non-metallic spoolable composite pipe for oil and gas flowlines of claim 1 ; and introducing the hydrocarbon fluid in the non-metallic spoolable composite pipe. 13. An internally lined pipe for oil and gas flowlines, comprising: an inner extruded tubular liner configured to be in direct contact with a fluid comprising hydrocarbons flowing through the internally lined pipe; and a carbon steel pipe surrounding the inner extruded tubular liner; where the inner extruded tubular liner comprises an aliphatic polyketone having the formula (I) [[—CH 2 CHR 1 (C═O)—] n [—CH 2 CHR 2 (C═O)—] m ] p ,  (I) where R 1 and R 2 are independently from one another the same or different, where R 1 is selected from the group consisting of hydrogen and an alkyl group, and where R 2 is an alkyl group, and where n is less than 0.5 and n+m=1, where p is an integer between 500 and 5000, where structural units [—CH 2 CHR 1 (C═O)—] and [—CH 2 CHR 2 (C═O)—], are randomly distributed, blocked or both, and where the internally lined pipe is configured to operate at temperatures of up to about 110° C., and to carry hydrocarbons having an aromatic content of up to about 35% by volume of the total hydrocarbons content. 14. The internally lined pipe of claim 13 configured to carry hydrocarbons having an aromatic and cyclo-aliphatic content of up to about 50% by volume of the total hydrocarbons content. 15. The internally lined pipe of claim 13 configured to operate in a dry gas environment having a hydrogen sulfide partial pressure of up to 10 barg. 16. The internally lined pipe of claim 13 , where the internally lined pipe is configured to operate at temperatures of from about 80° C. to about 110° C. 17. The internally lined pipe of claim 13 , where the internally lined pipe has a permeability of less than about 2×10 −7 cm 3 (STP)·cm/cm 2 ·s·bar when exposed to a dry gas environment comprising hydrogen sulfide, carbon dioxide, and methane. 18. The internally lined pipe of claim 17 , where the dry gas environment comprises about 10% hydrogen sulfide, 10% carbon dioxide, and 80% methane. 19. A method of producing the internally lined pipe for oil and gas flowlines of claim 13 , the method comprising: extruding the aliphatic polyketone having the formula (I) to form the inner tubular liner; and internally lining the carbon steel pipe with the inner tubular liner. 20. A method of transporting a hydrocarbon fluid having an aromatic content of up to about 35% by volume based on the total hydrocarbons content, the method comprising: providing the internally lined pipe for oil and gas flowlines of claim 13 ; and introducing the hydrocarbon fluid in the internally lined pipe.