Solid-lubricated metal cutter and processing method thereof

We claim: 1. A solid-lubricated metal cutter having a cutting blade, comprising: a surface texture morphology formed on an outer surface of the metal cutter; a solid lubricant filled into the surface texture morphology; and a convex dam arranged on the cutter surface on which the surface texture morphology is located at a chip flow side of the surface texture morphology away from a cutting blade. 2. The metal cutter according to claim 1 , wherein, the surface texture morphology is a concave-convex complex morphology comprising an array of pits arranged at the center and annular bosses arranged around the pits. 3. The metal cutter according to claim 2 , wherein, the diameter of the pits is 50-500 μm and the depth of the pits is 10-100 μm. 4. The metal cutter according to claim 2 , wherein, the height of the annular bosses is 1-30 μm and the width of the annular bosses is 5-100 μm. 5. The metal cutter according to claim 2 , wherein, the surface texture morphology is at 50-200 μm distance from the cutting blade. 6. The metal cutter according to claim 2 , wherein, the solid lubricant is filled into the cutter surface with the concave-convex complex texture to a filling height that the solid lubricant is flush with the top of the annular bosses. 7. The metal cutter according to claim 6 , wherein, the convex dam is a band-shaped protrusion and has a height of 50-500 μm and a width of 100-1,000 μm. 8. The metal cutter according to claim 7 , wherein, the convex dam is perpendicular to a chip outflow direction. 9. The metal cutter according to claim 7 , further comprising at least one additional convex dam arranged parallel to the convex dam. 10. The metal cutter according to claim 1 , wherein, the surface texture morphology region comprises a portion where the cutter is in contact with chips and a portion where the cutter is in contact with a workpiece. 11. The metal cutter according to claim 10 , wherein, the area percentage of the surface texture morphology is 10%-40%. 12. The metal cutter according to claim 10 , wherein, the area percentage of the surface texture morphology is 15%-25%, and the workpiece is an aluminum alloy workpiece. 13. The metal cutter according to claim 10 , wherein, the area percentage of the surface texture morphology is 35%-45%, and the workpiece is a titanium alloy workpiece. 14. The metal cutter according to claim 1 , wherein, the solid lubricant is a composite material comprising one or two of molybdenum disulfide, graphite, tetraboron nitride, or silver solid lubricants. 15. A method of manufacturing a solid-lubricated metal cutter having a cutting blade, the method comprising: forming a surface texture morphology on the metal cutter; forming a convex dam on the cutter surface on which the surface texture morphology is located at a chip flow side; filling a solid lubricant into the surface texture morphology; and fixing the solid lubricant in the micro-texture morphology by a sintering process. 16. The method according to claim 15 , wherein, the surface texture morphology is processed with a laser beam to obtain a concave-convex complex morphology and a morphology of convex dam, wherein the laser is at least one of a CO 2 laser, lamp pumping YAG laser, diode pumping YAG laser, or optical fiber laser, and wherein the operating parameters of the laser comprise: 40-1,000 W output power; ±2 mm defocusing amount; and 0.01-500 ms pulse width. 17. The method according to claim 16 , wherein, the method for processing the concave-convex complex morphology further comprises: processing the cutter surface with a single laser pulse to obtain a morphology that has a pit at the center and an annular boss around the pit; changing the irradiation position of the laser on the cutter surface to an adjacent morphology point; processing with a single laser pulse; and repeating the operations to form an array of concave-convex complex morphologies. 18. The method according to claim 17 , wherein, the method for filling the solid lubricant into the surface texture morphology comprises: filling the solid lubricant into the pits of the concave-convex complex morphology until the final filling height of the solid lubricant is equal to the height of the annular bosses. 19. The method according to claim 17 , wherein, the method for filling the solid lubricant into the surface texture morphology comprises: filling the solid lubricant into the pits of the concave-convex complex morphology until the final filling height of the solid lubricant is greater than the height of the annular bosses; filling the spaces outside of the pits of the concave-convex complex morphology so that the solid lubricant covers all morphologies in the surface texture morphology region; and leveling the filled surface with a piece of abrasive paper, till the thickness of the solid lubricant layer is equal to the height of the annular bosses. 20. The method according to claim 16 , wherein, the convex dam is formed by continuous laser beam scanning. 21. The method according to claim 15 , wherein, a curing temperature of the sintering process is 200-600° C., and the curing time is 10-60 minutes. 22. The method according to claim 15 , wherein, after the sintering process, excessive solid lubricant on the surface is removed by sanding with a piece of abrasive paper until the height of the solid lubricant is equal to the height of the annular bosses. 23. The method according to claim 15 , wherein, the surface of the cutter is pre-processed before the surface texture is formed on the metal cutter and the surface of the metal cutter is polished so that the roughness Ra of the surface of the metal cutter is lower than 0.3 μm.