Pressure-resistant buoys

The invention claimed is: 1. A subsea buoy, comprising an external shell that is rigid and watertight extending continuously around an internal space that is sealed and fully enclosed by the external shell, wherein the external shell is supported by a foraminous internal structure within the internal space, formed integrally with the external shell, wherein the foraminous internal structure is formed of aluminium and comprises structural members extending within the internal space and cavities disposed between the structural members, the structural members being in an array comprising an outer tier of the structural members extending inwardly from the external shell into the internal space and at least one inner tier of the structural members disposed within the outer tier, wherein the structural members of the outer tier are spaced closer together than the structural members of the inner tier. 2. The subsea buoy of claim 1 , wherein the cavities are discrete spaces that are isolated from each other. 3. The subsea buoy of claim 2 , wherein the cavities are generally ellipsoidal or spheroidal voids, each surrounded by webs of a continuous matrix that defines the structural members. 4. The subsea buoy of claim 1 , wherein the cavities are conjoined spaces that communicate with each other. 5. The subsea buoy of claim 4 , wherein the foraminous internal structure is skeletal. 6. The subsea buoy of claim 5 , wherein the structural members are struts that cooperate to form trusses. 7. The subsea buoy of claim 1 , wherein the structural members are arranged in a lattice. 8. The subsea buoy of claim 1 , wherein the cavities are generally polyhedral. 9. The subsea buoy of claim 8 , wherein the cavities are substantially tetrahedral or octahedral. 10. The subsea buoy of claim 1 , wherein the structural members of the outer tier are in fractal relation to the structural members of the inner tier. 11. The subsea buoy of claim 1 , wherein the outer tier extends parallel to a wall of the external shell from which the structural members of the outer tier extend inwardly into the internal space. 12. The subsea buoy of claim 1 , wherein the structural members of the inner tier are thicker than the structural members of the outer tier. 13. The subsea buoy of claim 1 , wherein the cavities of the inner tier are larger than the cavities of the outer tier. 14. The subsea buoy of claim 1 , wherein each structural member of the inner tier divides into two or more structural members of the outer tier. 15. The subsea buoy of claim 1 , wherein the outer tier is narrower than the inner tier. 16. The subsea buoy of claim 1 , wherein the cavities of the foraminous internal structure have an aggregate volume of at least 63% of the external volume of the external shell. 17. The subsea buoy of claim 16 , wherein the cavities of the foraminous internal structure have an aggregate volume of up to 83% of the external volume of the external shell. 18. The subsea buoy of claim 1 , wherein the external shell is formed of aluminium. 19. The subsea buoy of claim 1 , wherein the foraminous internal structure and the external shell are formed of differing materials. 20. The subsea buoy of claim 1 , further comprising an external anti-corrosion jacket extending continuously around the external shell. 21. The subsea buoy of claim 1 , further comprising at least one sacrificial anode mounted on the external shell. 22. The subsea buoy of claim 1 , wherein the geometry of the foraminous internal structure and/or the external shell has been determined by an optimisation algorithm. 23. A method of making a subsea buoy, comprising: using an additive manufacturing process to form a foraminous internal structure of aluminium; and simultaneously, using the additive manufacturing process to form a rigid continuous watertight external shell that is rigid, continuous and watertight around and integral with the foraminous internal structure, which external shell, when completed, seals and fully encloses the foraminous internal structure; wherein the method further comprises progressively adding material to form structural members of the foraminous internal structure that are integral with the external shell and to define cavities of the foraminous internal structure between the structural members, so that the structural members are arranged in an array comprising an outer tier of the structural members extending inwardly from the shell into the internal space and at least one inner tier of the structural members disposed within the outer tier, wherein the structural members of the outer tier are spaced closer together than the structural members of the inner tier. 24. The method of claim 23 , wherein the additive manufacturing process is selected from a group comprising direct metal laser sintering, electron beam melting, selective heat sintering, selective laser melting, selective laser sintering, indirect metal printing, directed energy deposition, and fuse deposition modeling. 25. The method of claim 23 , comprising forming the external shell from aluminium. 26. The method of claim 23 , comprising forming the foraminous internal structure and the external shell from differing materials. 27. The method of claim 23 , comprising determining a geometry of the foraminous internal structure and/or the external shell using an optimization algorithm.