Transformer and Method of Engineering a Transformer to Incorporate a Leakage Inductance

The invention claimed is: 1 . A transformer comprising: a core formed of at least one MANC alloy, the at least one MANC alloy comprising a predefined permeability. 2 . The transformer of claim 1 , wherein the core comprises a first soft magnetic core and a second soft magnetic core each being ungapped, wherein the first core has a first predefined permeability and the second core has a second predefined permeability different than the first predefined permeability. 3 . The transformer of claim 2 , wherein the first core comprises an outer core of the transformer, wherein the second core comprises an inner core of the transformer, and wherein the second predefined permeability is less than the first predefined permeability. 4 . The transformer of claim 2 , wherein the first core comprises an outer core of the transformer, wherein the second core comprises an inner core of the transformer, and wherein the second predefined permeability is greater than the first predefined permeability. 5 . The transformer of claim 2 , wherein the transformer comprises a primary winding encompassing the first core and the second core, and a secondary winding encompassing the first core. 6 . The transformer of claim 5 , wherein, responsive to the secondary winding being open and current being applied to the primary winding, magnetizing flux in the transformer is primarily contained in the first core, with the second core being at least partially excited. 7 . The transformer of claim 5 , wherein, responsive to the primary winding being open and current being applied to the secondary winding, the first core is excited and the second core experiences substantially zero excitation. 8 . The transformer of claim 5 , wherein, responsive to the secondary winding being short circuited and current being applied to the primary winding, magnetizing flux within the first core is substantially eliminated, and leakage flux within the second core and associated with the primary winding are retained. 9 . The transformer of claim 2 , wherein the core further comprises a third soft magnetic core, wherein the first core is disposed internally within the second core, and wherein the second core is disposed internally within the third core. 10 . The transformer of claim 9 , wherein the third core is a magnetizing core, wherein the second core is an outer leakage core, and wherein the first core is an inner leakage core. 11 . The transformer of claim 9 , further comprising a primary winding, a secondary winding, and a tertiary winding, wherein the primary winding is disposed internal with respect to the first core, wherein the secondary winding is disposed between the first core and the second core, and wherein the tertiary winding is disposed between the second core and the third core. 12 . The transformer of claim 9 , wherein, responsive to power flowing between the primary winding and the secondary winding, an effective leakage inductance is dominated by the first core rather than the second core or the third core. 13 . The transformer of claim 9 , wherein, responsive to power flowing between the secondary winding and the tertiary winding, the second core provides a primary leakage inductance, while the first core and the third core contribute nominally to leakage inductance. 14 . The transformer of claim 9 , wherein, responsive to power flowing between the primary winding and the tertiary winding, leakage inductance exists due to both the first core and the second core. 15 . The transformer of claim 2 , wherein the core further comprises a third soft magnetic core, wherein the third core is disposed between the first core and the second core, wherein the first core is disposed on a first side of the third core and the second core is disposed on a second, opposite side of the third core. 16 . The transformer of claim 15 , wherein the first core comprises a first leakage core, wherein the second core comprises a second leakage core, and wherein the third core comprises a magnetizing core. 17 . The transformer of claim 2 , wherein the first core is formed of the at least one MANC alloy, and wherein the second core is formed of a non-MANC alloy. 18 . The transformer of claim 2 , wherein the first core is formed of a MANC alloy and the second core is formed of another MANC alloy. 19 . A method of engineering a transformer to incorporate a leakage inductance, the method comprising: forming a core of at least one MANC alloy, the at least one MANC alloy comprising a predefined permeability; and incorporating the core into the transformer. 20 . The method of claim 19 , further comprising forming the core with a first soft magnetic core having a first predefined permeability and a second soft magnetic core having a second predefined permeability different than the first predefined permeability. 21 . The method of claim 19 , wherein each of the first core and the second core are ungapped.