Compact triangular core transformer

The invention claimed is: 1. A three-phase stacked triangular transformer core with three legs and six yoke parts therebetween, wherein said legs include stacked laminations, characterized in that in a cross-sectional plane perpendicular to a central transformer core axis, said stacked laminations are oriented in substantially radial direction, wherein in the cross-sectional plane, each leg has two leg halves, wherein each leg half has a plurality of outer corners facing a corresponding leg half of a neighboring leg, wherein for each leg half, said plurality of outer corners lie on a respective straight line within a lateral tolerance ΔA, wherein for each leg half, the straight line defined by this leg half and the straight line defined by the corresponding leg half of the neighboring leg are parallel, and wherein said lateral tolerance ΔA is given by ΔA≦0.02*L, wherein L is a maximum length of a leg cross-section. 2. The transformer core according claim 1 , wherein in the cross-sectional plane an aspect ratio of a maximal width of said legs in radial direction to a maximal length of said legs in circumferential direction is greater than 0.6 and smaller than 0.9. 3. The transformer core according to claim 1 , wherein in the cross-sectional plane the legs are mirror symmetric with respect to a center line extending in circumferential direction. 4. The transformer core according to claim 1 , wherein in the cross-sectional plane the legs are asymmetric with respect to any center line extending in circumferential direction. 5. The transformer core according to claim 1 , wherein in the cross-sectional plane the legs are arranged such that a ratio between a footprint area of the legs and an area of a circle enveloping the legs is higher than 55%. 6. The transformer core according to claim 1 , wherein a ratio of the total mass of the yoke parts to the total mass of the legs is smaller than 65%. 7. The transformer core according to claim 1 , wherein an angle at an outer corner between the yoke parts and the corresponding legs is essentially 90°. 8. The transformer core according to claim 1 , wherein the yoke parts are bent. 9. The transformer core according to claim 1 , wherein ends of the legs and ends of the corresponding yoke parts are cut angularly. 10. The transformer core according to claim 1 , wherein each of the yoke part has a plurality of yoke laminations of different length. 11. The transformer core according to claim 10 , wherein an increase of the yoke lamination length between the successive yoke laminations within a given core step, is given by the equation ΔL=π/3*d s , wherein d s is the thickness of a sign lamination and ΔL is a length difference in the yoke lamination length. 12. The transformer core according to claim 1 , wherein low voltage windings and high voltage windings are wound directly on each of the legs. 13. Transformer having a transformer core according to claim 1 . 14. A method for manufacturing a stacked triangular transformer said method comprising: a) Providing at least three legs of stacked laminations, wherein in a cross-sectional plane, each leg has two leg halves, b) Winding coil windings on said at least three legs; c) Connecting said at least three legs with yoke parts whereby the legs are positioned such that in the cross-sectional plane, which is perpendicular to a central transformer core axis, for each leg said stacked laminations are oriented in substantially radial direction, wherein each leg half has a plurality of outer corners facing a corresponding leg half of a neighboring one of the legs, and wherein for each leg half, said plurality of outer corners lie on a straight line within a lateral tolerance ΔA, and wherein for each leg half, the straight line defined by this leg half and the straight line defined by the corresponding leg half of the neighboring one of the legs are parallel, and wherein said lateral tolerance ΔA is given by ΔA≦0.02*L, wherein L is a maximum length of a leg cross-section.