Self-centering flexible coupling

The invention claimed is: 1. A shaft system for torque transmission, the shaft system comprising: a first shaft; a second shaft; a third shaft; and a first coupling comprising: a cup-shaped portion formed integral with a first end of said first shaft; a first end of said second shaft being positioned within said cup-shaped portion; and a biasing means positioned between said first and second shafts, such that said biasing means is in contact with both of said first and second shafts; wherein: said first shaft extends longitudinally along a first shaft axis; said second shaft extends longitudinally along a second shaft axis; the first shaft axis is coaxial with the second shaft axis in an equilibrium position; and said biasing means is arranged so as to compress in response to angular misalignment away from the equilibrium position between the first and second shaft axes and to compress in response to relative axial movement of the first and second shafts towards each other away from the equilibrium position; the shaft system further comprising: a second coupling being provided between said third shaft and a second end of said first shaft ( 12 ), wherein said second coupling is identical to the first coupling; wherein the biasing means of the second coupling is located in an internal cavity of a given one of the first shaft and third shaft, wherein the given one of the first and third shafts does not have the cup-shaped portion; wherein the second shaft is connected to a frame, wherein the third shaft is connected to a movable part that is connected to the frame, wherein the first shaft floats freely between the second and third shafts such that the first shaft is only connected to the frame via the first and second couplings. 2. The shaft system of claim 1 , wherein at least one of said first and second shafts comprises an internal cavity, and wherein said biasing means is provided within said cavity. 3. The shaft system of claim 1 , wherein said biasing means is a spring. 4. The shaft system according to claim 1 , wherein an internal surface of said cup-shaped portion comprises inwardly extending radial splines and an external surface of said portion of said second shaft that is positioned within said cup-shaped portion comprises radially extending splines; wherein said first shaft extends longitudinally along a first shaft axis and said second shaft extends longitudinally along a second shaft axis; and wherein the splines are configured to allow relative axial movement of between the two shafts; and/or wherein the splines are configured to allow relative axial misalignment between the axes of the two shafts. 5. The shaft system according to claim 4 , wherein the splines on the first shaft are arranged around an inner circumference of said cup-shaped portion and wherein the splines of the second shaft extend radially outward from the portion of said second shaft that is positioned within said cup-shaped portion. 6. The shaft system according to claim 1 , wherein the biasing means is physically connected to one or both of the first and second shafts. 7. The shaft system according to claim 1 , wherein the biasing means is at least partially located in a cavity of the second shaft and/or wherein the biasing means is at least partially located in a cavity of the first shaft. 8. The shaft system according to claim 1 , wherein the biasing means is a spring and wherein the spring constant of the spring is selected such that, in use, the spring will return the shafts to an equilibrium position when the torque being transmitted across the shafts is below a predetermined value. 9. The shaft system according to claim 1 , wherein the shafts are arranged such that there is a preload in the biasing means at the equilibrium position, or wherein the shafts are arranged such that there is no preload in the biasing means at the equilibrium position. 10. A method of coupling a first shaft, a second shaft and a third shaft together for torque transmission, the method comprising: providing said first shaft having a first end with a cup-shaped portion integrally formed with the first shaft, and positioning a portion of a first end of said second shaft within said cup-shaped portion of said first shaft; and providing a first biasing means between said first and second shafts so that said biasing means contacts both of said first and second shafts; wherein: said first shaft extends longitudinally along a first shaft axis; said second shaft extends longitudinally along a second shaft axis; the first shaft axis is coaxial with the second shaft axis in an equilibrium position; and said first biasing means is arranged so as to compress in response to angular misalignment away from the equilibrium position between the first and second shaft axes and to compress in response to relative axial movement of the first and second shafts towards each other away from the equilibrium position, the method further comprising: coupling a second end of the first shaft to the third shaft; providing a second biasing means between said first and third shafts so that said second biasing means contacts both of said first and third shafts; wherein the second biasing means are located in an internal cavity of a given one of the first shaft and third shaft, wherein the given one of the first and third shafts does not have the cup-shaped portion; wherein the second shaft is connected to a frame, wherein the third shaft is connected to a movable part that is connected to the frame, wherein the first shaft floats freely between the second and third shafts such that the first shaft is only connected to the frame via the first and second couplings.