Composite tubular structure

The invention claimed is: 1. A composite tubular structure comprising: an elongate composite member having: a first end and a second end; a first inwardly tapered section adjacent the first end; a second inwardly tapered section adjacent the second end; a main body portion extending from the first inwardly tapered section to the second inwardly tapered section; and a first nut and a second nut for forming connections with other components, the first nut being retained in the first end by being embedded within the first inwardly tapered section, and the second nut being retained in the second end by being embedded within the second tapered section; wherein the first inwardly tapered section has a first inner surface which follows a first tapered outer surface of the first nut, the first inwardly tapered section narrowing the elongate composite member in a first longitudinal direction towards the first end so as to provide a first constriction which retains the first nut within the elongate composite member; wherein the second inwardly tapered section has a second inner surface which follows a second tapered outer surface of the second nut, the second inwardly tapered section narrowing the elongate composite member in a second longitudinal direction towards the second end so as to provide a second constriction which retains the second nut within the elongate composite member; and wherein the main body portion of the elongate composite member is of constant internal radius between the first inwardly tapered section and the second inwardly tapered section. 2. The composite tubular structure as claimed in claim 1 , wherein the composite tubular structure includes a connector comprising a rod engaging the first nut, the engagement occurring within the first inwardly tapered section, an annular wedge configured to urge against an outer surface of the first inwardly tapered section, and a tensioner provided to exert a clamping force on the first inwardly tapered section via the annular wedge. 3. The composite tubular structure as claimed in claim 1 , wherein the first and second inwardly tapered sections each have a taper angle of between 5 to 25° to an axis of the composite tubular structure. 4. The composite tubular structure as claimed in claim 1 , further comprising a liner within the composite member. 5. The composite tubular structure as claimed in claim 4 , wherein the liner is retained and remains intact within the elongate composite member during service. 6. The composite tubular structure as claimed in claim 4 , wherein the liner is one or more of impervious to fluid or electrically conductive. 7. A method for manufacturing the composite tubular structure of claim 1 , comprising: attaching the first nut to a first axial end of a liner and a second nut to a second axial end of the liner to provide a surface for depositing filaments over, the first nut being arranged so that the first tapered outer surface tapers in a first direction away from the liner and the second nut being arranged so that the second tapered outer surface tapers in a second direction opposite to the first direction away from the liner; depositing filaments around the liner and the attached first and second nuts to form the elongate composite member having the main body portion and the first inwardly tapered section at the first end and the second inwardly tapered section at the second end, such that the first inwardly tapered section has an inner surface which follows the tapered outer surface of the nut. 8. The method as claimed in claim 7 , wherein the liner is subsequently retained within the composite tubular structure. 9. The method as claimed in claim 7 , wherein the liner is subsequently removed from within composite the tubular structure by melting, dissolving, burning, peeling, unraveling, fragmentation, UV degradation or another removal process. 10. The method as claimed in claim 7 , wherein the method comprises pressurising the liner during a winding and/or forming and/or curing operation, and/or in subsequent service of the composite tubular structure. 11. The method of claim 7 , wherein the step of depositing filaments comprises a filament winding process. 12. The method of claim 11 , wherein a winding angle of the filaments is varied to take account of variations in the internal radius of the composite member. 13. The method of claim 7 , wherein the liner is supported between two parts of a mandrel while the filament deposition is taking place. 14. The method as claimed in claim 13 , wherein the two parts of the mandrel each screw into the first and second nuts of the composite tubular structure to seal internal threads of the first and second nuts during the filament deposition process. 15. The method of claim 13 , wherein each part of the mandrel further comprises: an inward radial step, such that a portion of the mandrel has a larger diameter and a portion of the mandrel has a smaller diameter; and an annular sacrificial layer of material disposed about a part of the smaller diameter portion of the mandrel; wherein once the winding has been completed and the mandrel is to be removed, a cut is made in a radially inward direction through the composite member and the sacrificial material layer, and the mandrel and any excess filament windings are removed. 16. A composite tubular structure comprising: an elongate composite member including: a first end and a second end; a first inwardly tapered section adjacent the first end; a second inwardly tapered section adjacent the second end; a main body portion extending from the first inwardly tapered section to the second inwardly tapered section; and a first nut and a second nut for forming connections with other components, the first nut being retained in the first end by being embedded within the first tapered section, and the second nut being retained in the second end by being embedded within the second tapered section; wherein the first inwardly tapered section has a first inner surface which follows a first tapered outer surface of the first nut, the first inwardly tapered section narrowing the elongate composite member in a first longitudinal direction towards the first end so as to provide a first constriction which retains the first nut within the elongate composite member; wherein the second inwardly tapered section has a second inner surface which follows a second tapered outer surface of the second nut, the second inwardly tapered section narrowing the elongate composite member in a second longitudinal direction towards the second end so as to provide a second constriction which retains the second nut within the elongate composite member; and wherein an internal radius of the main body portion varies by increasing toward a middle of the elongate composite member from the first end and from the second end of the elongate composite member. 17. The composite tubular structure as claimed in claim 16 , wherein a wall thickness of the composite member is varied such that the composite member has a thinner wall where the internal radius of the tubular structure is larger compared to a thicker wall where the radius of the tubular structure is smaller. 18. The composite tubular structure as claimed in claim 16 , wherein the composite tubular structure includes a connector comprising a rod engaging the first nut, the engagement occurring within the first inwardly tapered section, an annular wedge configured to urge against an outer surface of the first inwardly tapered section, and a tensioner provided