Fractal flow distribution system

The invention claimed is: 1. A flow distribution system for distributing and dividing the flows of at least two separate fluids, the flow distribution system comprising: a three-dimensional nested structure of at least two fluid transporting fractals comprising at least a first fluid transporting fractal and a second fluid transporting fractal, each fluid transporting fractal having a respective fluid inlet which bifurcates to a plurality of fluid outlets, each fluid transporting fractal being configured to facilitate a flow therethrough independent from a flow in the other fluid transporting fractal, each fluid transporting fractal extending along and about a central axis between the fluid inlet and the plurality of fluid outlets; wherein each fluid transporting fractal comprises of a series of recursive bifurcation units assembled in a selected number of stages, each bifurcation unit comprising a Y-shaped bifurcated element which is fluidly connected to two successive bifurcation units, each successive bifurcation unit being rotated relative to the central axis by an angle of between 60 and 120 degrees relative to a previous stage; each fluid transporting fractal is intertwined with another fluid transporting fractal; each fluid transporting fractal is positioned offset from another fluid transporting fractal about the central axis and is arranged such that each fluid outlet from one of the fluid transporting fractals is located adjoining a fluid outlet of another fluid transporting fractal, and each fluid transporting fractal is centered about a flow axis which is laterally inclined relative to the central axis from greater than 0 to 20 degrees from the central axis and longitudinally inclined relative to the central axis from greater than 0 to 20 degrees from the central axis. 2. A flow distribution system according to claim 1 , wherein the flow axis of each fluid transporting fractal is spaced offset from the central axis. 3. A flow distribution system according to claim 1 , wherein the flow axis of each fluid transporting fractals is laterally offset and longitudinally spaced apart about the central axis relative to the central axis. 4. A flow distribution system according to claim 3 , wherein the lateral offset C of the flow axis of each fluid transporting fractal from the central axis is between - S j 2 ≤ c t u ≤ S j 2 wherein S j is the bifurcation unit spacing. 5. A flow distribution system according to claim 3 , wherein the longitudinal spacing C of the flow axis of each fluid transporting fractal from the central x between - S j 2 ≤ C t v ≤ S j 2 wherein S j is the bifurcation unit spacing. 6. A flow distribution system according to claim 1 , wherein each fluid transporting fractal is centered about the flow axis which is laterally inclined relative to the central axis from between 4 and 10 degrees from the central axis and longitudinally inclined relative to the central axis between 4 and 10 degrees from the central axis. 7. A flow distribution system according to claim 6 , wherein the respective inclines of each fluid transporting fractal are mirrored about the central axis. 8. A flow distribution system according to claim 1 , wherein each fluid outlet is located in an outlet plane orientated relative to the central axis, preferably-perpendicular to the central axis and each fluid transporting fractal includes a transition conduit configured to direct and realign a path of the flow path therethrough of each transporting fractal into the outlet plane. 9. A flow distribution system according to claim 1 , wherein a layout of a path of the flow therethrough of each fluid transporting fractal is symmetric relative to the central axis and flow axis of each respective fluid transporting fractal. 10. A flow distribution system according to claim 1 , wherein each successive bifurcation unit is rotated relative to the central axis between 70 and 110 degrees relative to a previous stage. 11. A flow distribution system according to claim 1 , wherein the fluid outlets are arranged in a square aspect ratio, in an even number array. 12. A flow distribution system according to claim 1 , having a flow area transfer ratio equal to 1 through each of the stages of the flow distribution system. 13. A flow distribution system according to claim 1 , wherein the fluid outlets have a distribution density ranging from 10000 to 15000 outlets per m 2 . 14. A flow distribution system according to claim 1 , having a downturn ratio of at least 50. 15. A flow distribution system according to claim 1 , wherein each Y-shaped bifurcated element comprises an inlet channel and two outlet channels which provide a curved fluid flow path between the inlet and outlets thereof. 16. A flow distribution system according to any-preceding claim 1 , wherein two fluidly connected and adjoining said bifurcation units form an H-shaped fractal unit. 17. A flow distribution system according to claim 1 , wherein each bifurcation unit has a bifurcation angle θ j of between 30 and 60 degrees. 18. A flow distribution system according to claim 1 , having a bifurcation unit spacing S j (the perpendicular projection length between the center of the inlet and outlet diameters of each bifurcation unit) is conserved when transitioning between an odd and even stage index, and halved when transitioning between even and odd stages. 19. A flow distribution system according to claim 1 , further including a mixer in which at least one fluid outlet front the first fluid transporting fractal is mixed with the fluid from at least one fluid outlet of the second fluid transporting fractal. 20. A method of designing a flow distribution system for distributing and dividing the flows of at least two separate fluids comprising a three-dimensional nested structure, the method comprising: determining number of flow distribution system stages; selecting a recursive bifurcation unit, comprising a Y-shaped bifurcated element which is fluidly connected to two successive bifurcation units to be assembled in the selected flow split stages; and assembling each successive bifurcation unit into two fluid transporting fractals having the selected number of flow distribution system stages, each fluid transporting fractal extending along and about a central axis between a fluid inlet and a plurality of fluid outlets, such that: each successive bifurcation unit is orientated so that