Cutting insert for high-efficient cutting

The invention claimed is: 1. A cutting insert for high-efficiency cutting, including an upper surface, a lower surface, side surfaces for connecting the upper surface and the lower surface to each other, and corner side surfaces for connecting the side surfaces to each other in rounded shapes, with a circular opening formed through central portions of the upper and lower surfaces, the cutting insert comprising: cutting edges formed by respective junctions between one of the upper and lower surfaces and the side surfaces and between one of the upper and lower surfaces and the corner side surfaces consisting of three corner side surfaces, the cutting edges comprising: corner side cutting edges consisting of three corner side cutting edges corresponding to the three corner side surfaces respectively, three major cutting edge pairs, each pair including major cutting edges extending from opposite ends of the corner side cutting edges towards neighboring corner side cutting edges, three minor cutting edges connecting the major cutting edges, wherein the major cutting edges are longer than the minor cutting edges, and six boundary cutting edges, each boundary cutting edge positioned between one of the three minor cutting edges and a respective one of the three major cutting edges at the junction between a boundary edge and one of the upper and lower surfaces, the boundary edge forming a junction between the upper and lower surfaces. 2. The cutting insert for high-efficiency cutting according to claim 1 , wherein the cutting edges are formed by respective junctions between the upper and lower surfaces and the side surfaces and between the upper and lower surfaces and the corner side surfaces, the cutting edges comprising: six corner cutting edges; twelve major cutting edges extending from opposite ends of the corner cutting edges towards the neighboring corner cutting edges; and six minor cutting edges connected between the major cutting edges. 3. The cutting insert for high-efficiency cutting according to claim 2 , wherein, when the corner cutting edges and the minor cutting edges are seen in a front view, each of the major cutting edges, which is formed in the upper surface, and the corresponding major cutting edge, which is formed in the lower surface, are oriented relative to each other at an angle (γ) ranging from about 0° to 20°. 4. The cutting insert for high-efficiency cutting according to claim 2 , wherein, when the corner cutting edges and the minor cutting edges are seen in a front view, the adjacent major cutting edges, which extend from respective opposite ends of each of the corner cutting edges or each of the minor cutting edges, have an included angle δ ranging from about 160° to 180°. 5. The cutting insert for high-efficiency cutting according to claim 1 , wherein the cutting edges, which comprise the corner side cutting edges, the major cutting edges and the minor cutting edges, further comprise the boundary edge having a predetermined curvature along the length of the junction between the upper and lower surfaces. 6. The cutting insert for high-efficiency cutting according to claim 5 , wherein the boundary cutting edge has a curvature radius ranging from about 0.3 mm to 3.0 mm. 7. The cutting insert for high-efficiency cutting according to claim 5 , wherein the corner side cutting edges, the major cutting edges, the boundary cutting edges and the minor cutting edges are flush with each other. 8. The cutting insert for high-efficiency cutting according to claim 5 , wherein, when seen in a plan view or a front view of the cutting insert, the boundary cutting edges and the corresponding minor cutting edge have a predetermined convex curvature. 9. The cutting insert for high-efficiency cutting according to claim 8 , wherein a radius of the convex curvature ranges from about 150 mm to 300 mm. 10. The cutting insert for high-efficiency cutting according to claim 5 , wherein the minor cutting edges are formed higher or lower than the corner side cutting edges, and each of the major cutting edges extends from the corresponding corner side cutting edge towards the corresponding minor cutting edge at an upward or downward incline. 11. The cutting insert for high-efficiency cutting according to claim 10 , wherein, when seen in a plan view of the cutting insert, each of the major cutting edges and the minor cutting edges is defined by a linear line. 12. The cutting insert for high-efficiency cutting according to claim 10 , wherein, when seen in a plan view or a front view of the cutting insert, each of the minor cutting edges is defined by a convex curved line. 13. The cutting insert for high-efficiency cutting according to claim 1 , wherein each of the corner side cutting edges has a curvature radius ranging from about 0.5 mm to 3.0 mm. 14. The cutting insert for high-efficiency cutting according to claim 1 , wherein a corner land surface, a major cutting edge land surface and a minor cutting, edge land surface respectively extend from each of the corner cutting edges, each of the major cutting edges and each of the minor cutting edges towards the upper surface or the lower surface at predetermined inclined angles, a corner chip breaker, a major cutting edge chip breaker and a minor cutting edge chip breaker are respectively provided between the upper surface or the lower surface and the corner land surface, the major cutting edge land surface and the minor cutting edge land surface, and each of the corner chip breaker, the major cutting edge chip breaker and the minor cutting edge chip, breaker has a chip breaker angle θ that is less than about 90° with respect to the corresponding corner side surface or the corresponding side surface. 15. The cutting insert for high-efficiency cutting according to claim 1 , wherein the major cutting edges extend from respective opposite ends of each of the corner cutting edges towards the corresponding neighbor corner cutting edges at an included angle (α) ranging from about 80° to 120°. 16. The cutting insert for high-efficiency cutting according to claim 1 , wherein an angle (β) between each of the minor cutting edges and the adjacent major cutting edge is less than about 30°. 17. The cutting insert for high-efficiency cutting according to claim 1 , wherein the minor cutting edges are arranged to have a 120° rotationally symmetrical structure based on the circular opening. 18. The cutting insert for high-efficiency cutting according to claim 1 , wherein the length of the junction between the upper and lower surfaces is greater at the boundary cutting edges than the length of the junction between the upper and lower surfaces at the corner side cutting edges.