Method for manufacturing a metal workpiece limiting the appearance of recrystallized grains in said workpiece

The invention claimed is: 1. A method for manufacturing a metal workpiece by casting a metal alloy in a mold, wherein prior to said casting, a chart is determined providing a risk of appearance of recrystallized grains during the casting and/or solidification of the metal workpiece, depending on temperature and plastic deformation energy conditions undergone by said metal workpiece, said chart being obtained by implementing the following steps: mechanical test on a test piece so as to characterize a plastic deformation of said test piece according to different values of imposed stresses; thermal treatment of said test piece, then macrographic etching to determine an appearance of recrystallized grains in the test piece; and calculation, according to stress values measured during the mechanical test, of a plastic deformation energy in the test piece, the plastic deformation energy being plotted as a function of the temperature during the mechanical test, with information relating to a presence of recrystallized grains, so as to constitute the chart; the casting of the metal alloy in the mold is then carried out in order for the temperature and plastic deformation energy conditions undergone by said metal workpiece to be manufactured to be less than a given threshold for the risk of appearance of determined recrystallized grains according to the chart. 2. The method for manufacturing a metal workpiece according to claim 1 , wherein the mechanical test on the test piece is a traction test interrupted before rupture. 3. The method for manufacturing a metal workpiece according to claim 1 , wherein the mechanical test is carried out at an imposed temperature. 4. The method for manufacturing a metal workpiece according to claim 3 , wherein the calculation of the plastic deformation energy is determined from a total plastic deformation undergone by the test piece during a traction test. 5. The method for manufacturing a metal workpiece according to claim 1 , wherein the mechanical test is carried out at an imposed deformation rate and at an imposed cooling rate. 6. The method for manufacturing a metal workpiece according to claim 5 , wherein the calculation of the plastic deformation energy is determined from a total plastic deformation undergone by the test piece during the mechanical test, said total plastic deformation being determined from elastic deformation, and thermal expansion, undergone by the test piece during the mechanical test. 7. The method for manufacturing a metal workpiece according to claim 5 , wherein the deformation rate is comprised, in % of deformation, between around 10 −6 /s and around 10 −4 /s, and/or the cooling rate is comprised between around 10° C./min and around 40° C./min. 8. The method for manufacturing a metal workpiece according to claim 1 , wherein production of a chart includes, after the calculation of the plastic deformation energy, a step of verifying said calculation by digital simulation of the mechanical test including the following sub-steps: casting test of at least one simplified workpiece having a geometry representative of the geometry of the metal workpiece to be manufactured; thermal treatment of said at least one simplified workpiece, then macrographic etching to determine the presence of recrystallized grains in the at least one simplified workpiece; digital simulation of the casting of the at least one simplified workpiece and calculation of the plastic deformation energy in said at least one simplified workpiece during its cooling; plotting of the calculated values of plastic deformation energy to the chart and validation of the chart if the presence of recrystallized grains in the at least one simplified workpiece is consistent with the risk of appearance of recrystallized grains determined by the chart. 9. The method for manufacturing a metal workpiece according to claim 8 , wherein said metal workpiece is a turbine blade, and wherein the at least one simplified workpiece includes a geometry representative of the geometry of the turbine blade. 10. The method for manufacturing a metal workpiece according to claim 1 , wherein casting and solidification conditions include the following parameters: a susceptor setpoint temperature; a rate of pulling the casting mold from a hot zone to a cold zone of a furnace; and a use of a thermal insulator around the mold. 11. The method for manufacturing a metal workpiece according to claim 1 , wherein said metal workpiece is made of an AM1, DS200 or CMSX-4 alloy. 12. The method for manufacturing a metal workpiece according to claim 1 , wherein the thermal treatment step is carried out at a temperature above 1200° C.