Mold insert for use in a mold for the manufacture of a cushioning element for sports apparel

That which is claimed is: 1. A mold insert for use in a mold for the manufacture of a cushioning element for sports apparel, a. wherein the cushioning element is manufactured from particles of an expanded material, b. wherein an electromagnetic field is used as an energy carrier to fuse particle surfaces of the particles of an expanded material, c. wherein the mold insert is manufactured using an additive manufacturing method, d. wherein the mold insert is made of a material and wherein the material comprises air cavities; and e. wherein the mold insert is adapted to locally adjust field strength of the electromagnetic field inside a molding cavity of the mold, based at least in part on geometry of the cushioning element, to obtain consistent fusion of the particles of an expanded material. 2. The mold insert according to claim 1 , wherein the mold insert is adapted to increase homogeneity of the field strength throughout molding cavity during the manufacture of the cushioning element. 3. The mold insert according to claim 1 , wherein the local adjustment of the field strength inside the molding cavity is at least partially caused by a local variation in dielectric properties of the mold insert. 4. The mold insert according to claim 3 , wherein the local adjustment of the field strength inside the molding cavity is at least partially caused by a local variation in permittivity of the mold insert. 5. The mold insert according to claim 4 , wherein the local variation in the permittivity of the mold insert is at least partially caused by a local variation in the density of material of the mold insert. 6. The mold insert according to claim 5 , where a higher density of the material of the mold insert results in a higher permittivity of the mold insert. 7. The mold insert according to claim 5 , wherein the local density of material of the mold insert lies between 0.4 g/cm 3 and 1.7 g/cm 3 . 8. The mold insert according to claim 3 , wherein the local adjustment of the field strength inside the molding cavity is at least partially caused by a local variation in the dielectric loss factor of the mold insert. 9. The mold insert according to claim 8 , wherein the local dielectric loss factor of the mold insert lies between 0.01 and 0.10. 10. The mold insert according to claim 1 , wherein the mold insert is arranged adjacent to the molding cavity and influences the geometry of the molding cavity. 11. The mold insert according to claim 8 , wherein the mold insert is arranged adjacent to the molding cavity and influences the geometry of the molding cavity and wherein the local variation in the dielectric loss factor further influences the amount of surface heat-up of the surface of the mold insert which is adjacent to the molding cavity during the manufacture of the cushioning element. 12. The mold insert according to claim 1 , wherein the cushioning element is a sole for a shoe, in particular a midsole. 13. A mold for the manufacture of a cushioning element for sports apparel from particles of an expanded material, a. wherein an electromagnetic field is used as an energy carrier to fuse the particle surfaces, and b. wherein the mold comprises a mold insert according to claim 1 . 14. A method for the manufacture of a cushioning element for sports apparel from particles of an expanded material, a. wherein an electromagnetic field is used as an energy carrier to fuse the particle surfaces, and b. wherein the method uses a mold according to claim 13 . 15. A cushioning element manufactured with the method according to claim 14 . 16. The cushioning element of claim 15 , wherein the cushioning element is a sole. 17. The cushioning element of claim 15 , wherein the cushioning element is a midsole. 18. The mold insert of claim 1 , wherein the mold insert is made of a single material.