Manufacturing of a metal component or a metal matrix composite component involving contactless induction of high-frequency vibrations

The invention claimed is: 1. Method of manufacturing a metal matrix composite component that includes a non-metal by use of a system for contactless induction of high-frequency vibrations in a volume of molten metal during the manufacturing of a metal matrix composite component, the system including a moveably arranged electromagnetic primary coil, an adjustment means for adjusting the position of the primary coil, and a control unit for controlling the position of the primary coil to a predefined distance above and not in physical contact with an upper free surface of the molten metal during use of the system, the method comprising: providing a foundry crucible containing at least a molten metal of which the component is to be at least partly composed, arranging the electromagnetic primary coil movably above the molten metal, adjusting the vertical position of the primary coil to a predefined distance above and not in physical contact with an upper free surface of the molten metal, applying power to the primary coil so that an electromagnetic field is obtained, adjusting the vertical position of the primary coil to maintain the predefined distance, maintaining the electromagnetic field for a predefined period of time so that a desired microstructure is obtained in the component being manufactured, arranging a secondary low-frequency electromagnetic coil around an outer circumference of the foundry crucible containing the molten metal, and applying power to the secondary coil so that flow and/or vibrations are induced in the molten metal. 2. Method according to claim 1 , further comprising: adding material to the molten metal in the foundry crucible and adjusting the vertical position of the primary coil accordingly. 3. Method according to claim 2 , where in the material is added through a feed device being arranged so that it is surrounded by windings of the primary coil. 4. Method according to claim 1 , wherein the secondary coil is used to induce vibrations of approximately 50 Hz. 5. Method for manufacturing a metal component by additive manufacturing, the method comprising: providing a work surface on which the component is to be manufactured, providing at least one deposition material from which the component is to be composed, advancing the deposition material to a localized deposition area where it is added to the component being manufactured, providing heat to the deposition area so that a free-standing melt-pool at least comprising molten metal is provided, so that the deposition material is deposited for building up the component, arranging an electromagnetic primary coil movably above the molten metal, adjusting a vertical position of a primary coil to a predefined distance above and not in physical contact with an upper free surface of the molten metal, applying power to the primary coil so that an electromagnetic field is obtained, adjusting the vertical position of the primary coil to maintain the predefined distance, and maintaining the electromagnetic field for a predefined period of time so that a desired microstructure is obtained in the component being manufactured, and mutually moving the work surface and the deposition material in a way that results in the additive manufacturing of the component. 6. Method according to claim 1 , wherein the metal is selected from the group consisting of aluminium, magnesium, titanium, zirconium, beryllium, steel, copper, nickel and cobalt. 7. Method according to claim 1 , wherein the method produces a metal matrix composite comprising reinforcement made from one or more of the following: SiC, ZrO2, Y2O3, Al2O3, MgO, and AlN. 8. Method according to claim 7 , wherein a characteristic size of the reinforcement is 10-1000 nm. 9. Method of manufacturing a metal matrix composite component that includes a non-metal by use of a system for contactless induction of high-frequency vibrations in a volume of molten metal during the manufacturing of a metal matrix composite component, the system including a moveably arranged electromagnetic primary coil, an adjustment means for adjusting the position of the primary coil, and a control unit for controlling the position of the primary coil to a predefined distance above and not in physical contact with an upper free surface of the molten metal during use of the system, the method comprising: providing a foundry crucible containing at least a molten metal of which the component is to be at least partly composed, arranging the electromagnetic primary coil movably above the molten metal, adjusting the vertical position of the primary coil to a predefined distance above and not in physical contact with an upper free surface of the molten metal, applying power to the primary coil so that an electromagnetic field is obtained, adjusting the vertical position of the primary coil to maintain the predefined distance, maintaining the electromagnetic field for a predefined period of time so that a desired microstructure is obtained in the component being manufactured, and adding material to the molten metal in the foundry crucible and adjusting the vertical position of the primary coil accordingly, wherein the material is added through a feed device being arranged so that it is surrounded by windings of the primary coil. 10. The method of claim 9 , further comprising: arranging a secondary low-frequency electromagnetic coil around an outer circumference of the foundry crucible containing the molten metal, and applying power to the secondary coil so that flow and/or vibrations are induced in the molten metal. 11. Method according to claim 9 , wherein the secondary coil is used to induce vibrations of approximately 50 Hz. 12. Method according to claim 9 , wherein the metal is selected from the group consisting of aluminium, magnesium, titanium, zirconium, beryllium, steel, copper, nickel and cobalt. 13. Method according to claim 9 , the method being used to manufacture a metal matrix composite comprising reinforcement made from one or more of the following: SiC, ZrO2, Y2O3, Al2O3, MgO, and AlN. 14. Method according to claim 9 , wherein a characteristic size of the reinforcement is 10-1000 nm. 15. Method according to claim 1 , wherein the metal matrix composite comprises a metal and a non-metal. 16. Method according to claim 9 , wherein the metal matrix composite comprises a metal and a non-metal.