Sintered magnet, electrical machine, use of the sintered magnet for an electrical machine and manufacturing method of a sintered magnet

The invention claimed is: 1. A sintered magnet, the sintered magnet comprising a core portion, a shell portion arranged at an outer part of the sintered magnet, and a diffusion portion arranged at least partially between the core portion and the shell portion, wherein the shell portion has a coercivity which is at least 30 kA/m larger than the coercivity of the core portion, wherein, in the diffusion portion, the coercivity is not less than the coercivity of the core portion and not larger than the coercivity of the shell portion and the value of the coercivity gradually increases from the core portion towards the shell portion, and wherein the thickness of the core portion is not less than 1 mm and the total thickness of the shell portion and the diffusion portion is at least 5 mm. 2. The sintered magnet according to claim 1 , wherein the diffusion portion has a coercivity gradient |∇H c | of at least 5 (kA/m)/mm throughout the diffusion portion. 3. The sintered magnet according to claim 1 , wherein the average density of the sintered magnet is 4.0 g/cm 3 to 8.5 g/cm 3 . 4. The sintered magnet according to claim 1 , wherein the coercivity of the core portion is at least 300 kA/m and less than 5000 kA/m and the coercivity of the shell portion is not more than 5000 kA/m. 5. The sintered magnet according to claim 1 , wherein the core portion comprises an alloy comprising at least one composition of elements a) to 1) selected from group I group I: a) Al, Ni and Co; b) Sm and Co; c) Sm and Fe; d) Sm, Fe and N; e) Fe and N; f) Mn, Al and C; g) Mn and Bi; h) hard ferrite; i) Fe, B, and at least one rare earth element; j) Fe, C, and at least one rare earth element; k) Nd, Fe and B l) Nd, Fe, B, and at least one rare earth element. 6. The sintered magnet according to claim 5 , wherein the core portion comprises at least one one element selected from group II, group II: Al, Co, Cu, Ga, Nb, Ti, Zr, and at least one light rare earth element. 7. The sintered magnet according claim 6 , wherein the total amount of the at least one element of group II is 0.05 to 20.0 mass % in the core portion. 8. The sintered magnet according to claim 1 , wherein the shell portion comprises an alloy comprising at least one composition of elements a) to l) selected from group I group I: a) Al, Ni and Co; b) Sm and Co; c) Sm and Fe; d) Sm, Fe and N; e) Fe and N; f) Mn, Al and C; g) Mn and Bi; h) hard ferrite; i) Fe, B, and at least one rare earth element; j) Fe, C, and at least one rare earth element; k) Nd, Fe and B l) Nd, Fe, B, and at least one rare earth element. 9. The sintered magnet according to claim 8 , wherein the shell portion comprises at least one element selected from group II, Group II Al, Ce, Co, Cu, Ga, La, Nb, Pr, Ti and Zr, and at least one heavy rare earth element. 10. The sintered magnet according claim 9 , wherein the total amount of the at least one element of group II is 0.05 to 20.0 mass % in the shell portion. 11. The sintered magnet according to claim 1 , wherein the sintered magnet is producible by forming a green body by magnetically aligning a first magnetic powder and a second magnetic powder so that the second magnetic powder is provided on at least a portion of the first magnetic powder, sintering the green body in a sintering furnace to form the sintered magnet having the core portion, the shell portion and the diffusion portion between the core portion and the shell portion, wherein the sintering time is 0.1 to 20 hours and the sintering temperature is 400° C. to 1200° C. 12. The sintered magnet according to claim 11 , wherein the forming includes compressing, wherein said sintering includes annealing the sintered green body, wherein, the annealing is performed at a temperature of 300° C. to 700° C. for a duration of 1 to 10 hours, wherein the sintering is performed under an inert gas having a pressure of 133 to 1013 Pa, the inert gas preferably comprising at least one of N 2 , Ar, and He, and wherein the compression of the first magnetic powder and the second magnetic powder is performed under a pressure of 50 to 500 MPa before sintering, wherein the pressing force is one of a uniaxial pressing force, an isostatic pressing force or a uniaxial pressing force, followed by an isostatic pressing force. 13. The sintered magnet according to claim 1 , wherein the shell portion extends two-dimensionally covering at least one of at least 10% of the total surface of the magnet; at least half of the total surface of the magnet; at least 50% of at least one face of the magnet; at least one face of the magnet essentially entirely. 14. The electrical machine according to claim 13 , wherein the electrical machine comprises at least one of an electric motor, a generator, a power transformer, an instrument transformer, a linear motion device and a magnetically biased inductor, and a magnetic actuator. 15. An electrical machine comprising at least one sintered magnet according to claim 1 . 16. A manufacturing method of a sintered magnet, comprising forming a green body by magnetically aligning a first magnetic powder and a second magnetic powder so that the second magnetic powder is provided on at least a portion of the first magnetic powder, sintering the green body in a sintering furnace to form a sintered magnet having a core portion ( 3 ), a shell portion ( 2 ) and a diffusion portion ( 4 ) that is arranged at least partially between the core portion and the shell portion, wherein the shell portion has a coercivity which is at least 30 kA/m larger than the coercivity of the core portion, wherein, in the diffusion portion, the coercivity is not less than the coercivity of the core portion and not larger than the coercivity of the shell portion and the value of the coercivity gradually increases from the core portion towards the shell portion, and wherein the thickness of the core portion is not less than 1 mm and the total thickness of the shell portion and the diffusion portion is at least 5 mm. 17. The manufacturing method according to claim 16 , wherein the green body is formed by magnetically aligning a first magnetic powder, a second magnetic powder and a third magnetic powder so that the second magnetic powder is provided on at least a portion of the third magnetic powder and the third magnetic powder is provided on at least a portion of the first magnetic powder. 18. The manufacturing method according to claim 17 , wherein at least one of the first magnetic powder and the third magnetic powder comprises an alloy comprising at least one composition of elements a) to l) selected from group I, group I: a) Al, Ni and Co; b) Sm and Co; c) Sm and Fe; d) Sm, Fe and N; e) Fe and N; Mn, Al and C; g) Mn and Bi; h) hard ferrite; i) Fe, B, and at least one rare earth element; j) Fe, C, and at least one rare earth element; k) Nd, Fe and B l) Nd, Fe, B, and at least one rare earth element. 19. The manufacturing method according to claim 18 , wherein at least one of the first magnetic powder and the third magnetic powder comprises at least one element selected from group II, group II Al, Co, Cu, Ga, Nb, Ti, Zr, and at least one light rare earth element. 20. The manufacturing method according to claim 19 , wherein the total amount of the at least one element of group II is 0.05 to 20.0 mass % in the core portion. 21. The manufacturing method according to claim 17 , wherein at least one of the second