A riser system (202) comprises a riser (204) to be secured between a floating body (206) and a subsea location (209). The riser comprises a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix. In use, the riser (204) comprises an upper porti
A riser system (202) comprises a riser (204) to be secured between a floating body (206) and a subsea location (209). The riser comprises a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix. In use, the riser (204) comprises an upper portion (214) extending from the floating body (206) and having a region arranged to be in tension, a lower portion (216) extending from the subsea location (209) and having a region arranged to be in tension, and an intermediate portion (218) located between the upper and lower portions (214, 216) and having a region arranged to be in compression. A flow-line jumper (302, 402) configured to be secured between two subsea locations, a flow-line jumper arrangement comprising a flow-line jumper (302, 402) and a method of forming a flow-line jumper 302, 402 are also disclosed.
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1. A riser system comprising a riser to be secured between a floating body and a subsea location, the riser comprising a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix, wherein, in use, the riser comprises an upper portion extending fro
1. A riser system comprising a riser to be secured between a floating body and a subsea location, the riser comprising a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix, wherein, in use, the riser comprises an upper portion extending from the floating body and having a region arranged to be always in tension, a lower portion extending from the subsea location and having a region arranged to be always in tension, and an intermediate portion located between the upper and lower portions and having a region arranged to be in compression;wherein, the riser comprises a pipe having a pipe wall comprising the composite material, wherein the pipe wall comprises or defines a local variation in construction of a local region of the intermediate portion to provide a local variation in a property of the pipe such that the riser bends in a predetermined manner such that the riser bends at a predetermined axial position or over a predetermined axial portion or bend in a predetermined plane; andwherein the local variation in construction comprises one or more of the following a local variation in the composite material, a local variation in the matrix, and a local variation in the one or more reinforcing elements. 2. The riser system according to claim 1, wherein the riser provides a predetermined tension in the upper or lower portions or a predetermined compression in the intermediate portion. 3. The riser system according to claim 2, wherein the density or geometry of the riser provide the predetermined tension in the upper or lower portions and the predetermined compression in the intermediate portion. 4. The riser system according to claim 1, wherein at least a portion of the riser defines a non-linear spatial arrangement to accommodate motion of the floating body relative to the subsea location. 5. The riser system according to claim 1, wherein the intermediate portion defines a non-linear spatial arrangement. 6. The riser system according to claim 1, wherein the upper portion of the riser extends generally linearly from the floating body towards the intermediate portion. 7. The riser system according to claim 1, wherein the lower portion of the riser extends generally linearly from the subsea location towards the intermediate portion. 8. The riser system according to claim 1, wherein a spatial arrangement of the riser comprises a point of inflection. 9. The riser system according to claim 1, comprising weights or buoyancy elements attached to the riser. 10. The riser system according to claim 1, wherein the riser is secured to a fluid port at the subsea location. 11. The riser system according to claim 1, wherein the composite material permits axial or bending strains of up to 6%, up to 4%, up to 2% or up to 1%. 12. The riser system according to claim 1, wherein the composite material is selected to ensure that a thermally induced strain in the riser for a predetermined temperature change constitutes a smaller proportion of a maximum permitted strain in the riser than for a steel riser. 13. The riser system according to claim 1, wherein the composite material is selected to ensure that a thermally induced strain in the riser for a temperature change of up to 500° C., a temperature change of up to 200° C., a temperature change of up to 100° C. or a temperature change of up to 80° C. constitutes a smaller proportion of a maximum permitted strain in the riser than for a steel riser. 14. The riser system according to claim 1, wherein the matrix comprises a polymer material. 15. The riser system according to claim 1, wherein the matrix comprises a thermoplastic material or a thermoset material. 16. The riser system according to claim 1, wherein the matrix comprises at least one of a polyaryl ether ketone, a polyaryl ketone, a polyether ketone (PEK), a polyether ether ketone (PEEK), a polycarbonate, a polymeric resin and an epoxy resin. 17. The riser system according to claim 1, wherein the reinforcing elements comprise at least one of fibres, strands, filaments and nanotubes. 18. The riser system according to claim 1, wherein the reinforcing elements comprise at least one of polymeric element, aramid element, non-polymeric element, carbon elements, glass elements and basalt elements. 19. The riser system according to claim 1, wherein the riser system comprises a device for providing additional axial compliance to that provided by the riser connected between the floating body and the subsea location. 20. The riser system according to claim 19, comprising a compliant bellows connected between the floating body and the subsea location. 21. The riser system according to claim 1, wherein the riser comprises one or more fibre optic strain sensors. 22. The riser system according to claim 1, wherein the riser comprises the upper portion extending from the floating body and having the region arranged to be always in tension, the lower portion extending from the subsea location and having the region arranged to be always in tension, and the intermediate portion located between the upper and lower portions and having the region arranged to be in compression, in use under static load conditions. 23. The riser system according to claim 1, wherein the local variation in construction provides a local variation in a property of the pipe so as to facilitate bending in localised regions such that, in use, the riser defines a non-linear spatial arrangement, such that the composite material and the non-linear spatial arrangement accommodate motion of the floating body relative to the subsea location. 24. A riser system comprising a riser to be secured between a floating body and a subsea location, the riser comprising a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix, said riser, in use, defining a non-linear spatial arrangement, such that the composite material and the non-linear spatial arrangement accommodate motion of the floating body relative to the subsea location; and the riser comprises a pipe having a pipe wall comprising the composite material, wherein the pipe wall comprises or defines a local variation in construction of a local region of the intermediate portion to provide a local variation in a property of the pipe such that the riser bends in a predetermined manner such that the riser bends at a predetermined axial position or over a predetermined axial portion or bend in a predetermined plane, wherein the local variation in construction comprises one or more of the following, a local variation in the composite material, a local variation in the matrix, and a local variation in the one or more reinforcing elements. 25. A flow-line jumper for securing between two subsea locations, said jumper comprising a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix and said flow-line jumper defining a non-linear spatial arrangement configured to provide compliance for the jumper between the two subsea locations; and a riser comprises a pipe having a pipe wall comprising a composite material, wherein the pipe wall comprises or defines a local variation in construction of a local region of the intermediate portion to provide a local variation in a property of the pipe such that the flow-line jumper bends in a predetermined manner such that the riser bends at a predetermined axial position or over a predetermined axial portion or bend in a predetermined plane, wherein the local variation in construction comprises one or more of the following, a local variation in the composite material, a local variation in the matrix, and a local variation in the one or more reinforcing elements. 26. The flow-line jumper according to claim 25, wherein the flow-line jumper has a non-linear portion. 27. The flow-line jumper according to claim 25, wherein the flow-line jumper defines at least one of a pig-tail shape, an omega shape, a coil, a helix and a spiral. 28. A method for providing a riser between a floating body and a subsea location, comprising: connecting a riser between the floating body and a subsea location, wherein the riser comprises a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix, wherein the riser comprises a pipe having a pipe wall comprising the composite material, wherein the pipe wall comprises or defines a local variation in construction of local region of the intermediate portion to provide a local variation in a property of the pipe such that the riser bends in a predetermined manner such that the riser bends at a predetermined axial position or over a predetermined axial portion or bend in a predetermined plane, wherein the local variation in construction comprises one or more of the following, a local variation in the composite material, a local variation in the matrix, and a local variation in the one or more reinforcing elements;configuring at least a region of an upper portion of the riser extending from the floating body to be always in tension;configuring at least a region of a lower portion of the riser extending from the subsea location to be always in tension; andconfiguring at least a region of an intermediate portion of the riser located between the upper and lower portions to be in compression.
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