Piston ring for improved lubrication oil consumption

What is claimed is: 1 . A piston assembly for an internal combustion engine, comprising: a cylinder bore having a central axis and a cylinder wall that is equidistant from the central axis, and forming a radial axis that is orthogonal to the central axis; a piston having a plurality of ring grooves; and a ring positioned within a ring groove, the ring having a cross-section comprising: a lower surface and an outer radial surface that form a scraping corner; an inner radial surface; and an upper surface; wherein: the upper surface and the lower surface are generally parallel with one another, and both upper and lower surfaces form a positive first angle with respect to the radial axis; and the outer radial surface forms a second positive angle with respect to the central axis; such that when the ring is installed on the piston within the cylinder bore, a constant twist occurs in the ring about a rotational center of the cross-section, the constant twist occurring at each cross-sectional location of the ring about the circumference of the ring and between adjacent free ends of the ring. 2 . The piston assembly of claim 1 , wherein the adjacent free ends extend 5° in either direction from a gap in the ring and extend about the circumference of the ring. 3 . The piston assembly of claim 1 , wherein the first angle is less than 1°. 4 . The piston assembly of claim 3 , wherein the first angle is 0.5°. 5 . The piston assembly of claim 1 , wherein the second angle is less than 2°. 6 . The piston assembly of claim 5 , wherein the second angle is 1°. 7 . The piston assembly of claim 1 , wherein the scraping corner includes a relief having a contour that is less than 0.2 mm from a hypothetical corner that is formed at an intersection of the lower surface and the outer radial surface. 8 . A method of fabricating a ring for a piston assembly for an internal combustion engine, the method comprising: machining a lower surface and an outer radial surface of the ring to form a scraping corner; and machining an upper surface to be parallel with the lower surface in a cross section of the ring; wherein the upper surface and the lower surface form a positive first angle with respect to a radial axis of the ring, the radial axis extending radially from a centroid of the ring; wherein a central axis is formed that passes through the centroid and is orthogonal to the radial axis, and the outer radial surface forms a positive second angle with respect to the central axis; wherein a cross-section of the ring includes a rotational center such that a constant force occurs in the ring about its circumference and between its adjacent free ends, causing a constant amount of twist about the rotational center of the ring, the axis of rotation defined at each cross-sectional location of the ring about its circumference and between the adjacent free ends. 9 . The method of claim 8 , wherein the adjacent free ends extend 5° in either direction from a gap in the ring and extend about the circumference of the ring. 10 . The method of claim 9 , wherein the first angle is less than 1°. 11 . The method of claim 11 , wherein the first angle is 0.5°. 12 . The method of claim 9 , wherein the second angle is less than 2°. 13 . The method of claim 12 , wherein the second angle is 1°. 14 . A ring for a piston assembly, the ring having a cross-section comprising: a lower surface and an outer radial surface that form a scraping corner; an inner radial surface; and an upper surface; wherein: the upper surface and the lower surface are parallel with one another, and the upper surface and lower surface form a positive first angle with respect to a radial axis, wherein the radial axis is defined as an axis that extends radially from a centroid of the ring; and the outer radial surface forms a second angle with respect to a central axis that is orthogonal to the radial axis; such that a force is imparted at the scraping corner in a direction that is opposite a direction of an axial motion, causing the ring to twist from a static state to a dynamic flexed state and against a groove of the piston assembly, wherein an amount of twist in the flexed state occurs the same amount at each cross-sectional location of the ring about its circumference and between adjacent free ends thereof. 15 . The ring of claim 14 , wherein the adjacent free ends extend 5° in either direction from a gap in the ring and extend about the circumference of the ring. 16 . The ring of claim 15 , wherein when the axial motion is in a downward direction within the piston assembly, the force imparted is in an upward direction causing the positive first angle to increase in magnitude, and when the axial motion is in an upward direction within the piston assembly, the force imparted is in a downward direction within the piston assembly, causing the positive second angle to decrease in magnitude. 17 . The ring of claim 15 , wherein the scraping corner includes a relief having a contour that is less than 0.2 mm from a hypothetical corner that is formed at an intersection of the lower surface and the outer radial surface. 18 . The ring of claim 15 , wherein the first angle is less than 1° and the second angle is less than 2°. 19 . The ring of claim 18 , wherein the first angle is 0.5°. 20 . The ring of claim 18 , wherein the second angle is 1°.