Mechanical system having high rotation flexure bearing

The invention claimed is: 1. A mechanical system, comprising: a first mechanical element, a second mechanical element, and a flexure bearing that movably couples the first and second mechanical elements; wherein the flexure bearing comprises: a first sleeve and a second sleeve, wherein each sleeve includes: an inside wall having a cylindrical inner surface; a first pillar having three sides, wherein a first end of the first pillar is attached to the inside wall of the sleeve, and a second end of the first pillar projects outwardly from the sleeve parallel to an axis of the sleeve; a second pillar having three sides, wherein a first end of the second pillar is attached to the inside wall of the sleeve, and a second end of the second pillar projects outwardly from the sleeve such that the second pillar is parallel to and diametrically opposed to the first pillar; a plurality of blind holes, each blind hole near each of the first end and the second end of each pillar, wherein each pillar comprises a first side shaped to conform to a sector of the inner surface of the other of the first and second sleeves, a second side having a first flat surface, and a third side having a second flat surface perpendicular to an edge of the first flat surface; wherein each pillar has a first blind hole near a first end of the second side, a second blind hole near a first end of the third side, a third blind hole near a second end of the second side and a fourth blind hole near a second end of the third side; wherein the first and second pillars of each sleeve are received by the inner surface between the first and second pillars of the other sleeve such that the sleeves are rotatably interconnected about the sleeve axis; and a plurality of compression springs, each compression spring having a first spring end configured to fit into one of the blind holes of a pillar of the first sleeve and a second spring end configured to fit into a corresponding blind hole of an adjacent pillar of the second sleeve when the second sleeve is interconnected to the first sleeve. 2. The mechanical system of claim 1 , further comprising: a first end cap configured to hold the first spring end; and a second end cap configured to hold the second spring end. 3. The mechanical system of claim 2 , wherein a diameter of each end cap is equal to a diameter of the blind hole and a length of each end cap is equal to a depth of the blind hole. 4. The mechanical system of claim 1 , wherein each compression spring is a helical compression spring. 5. The mechanical system of claim 1 , wherein each compression spring has a length at least three times of a depth of the blind hole. 6. The mechanical system of claim 1 , wherein at least one of the first and second mechanical elements is coupled to a linear actuator. 7. The mechanical system of claim 1 , wherein at least one of the first and second mechanical elements includes an opening configured to engage with the outer surface of the first sleeve of the flexure bearing. 8. The mechanical system of claim 7 , wherein at least one of the first and second mechanical elements has a second opening configured to engage with the second sleeve of the flexure bearing. 9. The mechanical system of claim 1 , wherein the flexure bearing is engaged with at least one of the first and second mechanical elements by press fit or interference fit. 10. The mechanical system of claim 1 , wherein a rotational angle between the first and second mechanical elements about the flexure bearing is up to 60°.