Reactor and manufacturing method thereof

What is claimed is: 1. A reactor, comprising: a coil including a hollow core-insertion part; and a core unit comprising a plurality of partial cores butted one another to form a closed magnetic path, and partially inserted and disposed in the hollow core-insertion part of the coil, the plurality of partial cores comprising a first partial core which forms a magnetic path passing through the hollow core-insertion part of the coil and has a pressed face surface pressed at a time of press-shaping; and a second partial core which forms a magnetic path passing through an exterior of the hollow core-insertion part of the coil and has a pressed face surface pressed at a time of press-shaping, the first partial core inserted and disposed in the hollow core-insertion part of the coil such that the pressed face surface of the first partial core is oriented orthogonal to a winding axis direction of the coil, the second partial core butted against the first partial core and disposed such that the pressed face surface of the second partial core is oriented orthogonal to the pressed face surface of the first partial core, and the pressed face surface of the second partial core being a substantially flat plane, wherein the first partial core comprises a first magnetic path end face orthogonal to the winding axis direction, the second partial core comprises a second magnetic path end face orthogonal to the winding axis direction, and the first magnetic path end face and the second magnetic path end face are disposed so as to face each other, and to have different area sizes between each other. 2. The reactor according to claim 1 , wherein the second magnetic path end face has a smaller area size than the area size of the first magnetic path end face, and has a smaller dimension than the first magnetic path end face in a direction orthogonal to the pressed face surface of the second partial core. 3. The reactor according to claim 1 , wherein the first magnetic path end face and the second magnetic path end face are disposed in the hollow core-insertion part of the coil so as to face with each other with a first gap therebetween. 4. The reactor according to claim 1 , wherein a cross-sectional shape of the first partial core orthogonal to the winding axis direction is substantially similar to a cross-sectional shape of the hollow core-insertion part of the coil orthogonal to the winding axis direction. 5. The reactor according to claim 1 , wherein the coil comprises a pair of coils disposed side by side in a parallel manner, the core unit comprises: at least a pair of I-shaped cores each inserted and disposed in the hollow core-insertion part of each of the pair of coils; and a pair of U-shaped cores each comprising a first leg portion and second leg portion disposed in parallel with each other, and being disposed in such a way that the respective first leg portions and the respective second leg portions face with each other, the respective first leg portions of the pair of U-shaped cores and the respective second leg portions thereof are disposed so as to be butted with each other through the I-shaped core inserted and disposed in the hollow core-insertion part of the coil to form a substantially annular closed magnetic path, the I-shaped core is the first partial core, and the U-shaped core is the second partial core. 6. The reactor according to claim 5 , wherein the I-shaped core comprises a plurality of I-shaped cores inserted in the hollow core-insertion part of each coil and disposed side by side in the winding axis direction. 7. The reactor according to claim 6 , further comprising second gaps each present between the adjoining I-shaped cores so as to form the closed magnetic path. 8. The reactor according to claim 7 , further comprising first gaps present between the respective first and second leg portions of the U-shaped core and the I-shaped cores, wherein all of the first and the second gaps are disposed in the hollow core-insertion part of the coil. 9. A reactor comprising: a coil including a hollow core-insertion part; and a core unit comprising a plurality of partial cores butted one another to form a closed magnetic path, and partially inserted and disposed in the hollow core-insertion part of the coil, the plurality of partial cores comprising a first partial core which forms a magnetic path passing through the hollow core-insertion part of the coil and has a pressed face surface pressed at a time of press-shaping; and a second partial core which forms a magnetic path passing through an exterior of the hollow core-insertion part of the coil and has a pressed face surface pressed at a time of press-shaping, the first partial core being inserted and disposed in the hollow core-insertion part of the coil with the pressed face surface of the first partial core being oriented orthogonal to a winding axis direction of the coil, the second partial core being butted against the first partial core and disposed such that the pressed surface face of the second partial core is oriented orthogonal to the pressed face surfaces of the first partial core, and the pressed face surface of the second partial core being a substantially flat plane wherein one of the pressed face surface of the plurality of partial cores and the pressed face surface of one of the pressed face surface of the first partial core and the second partial core has a burr extending outward from a substantially flat plane of the pressed face surface. 10. The reactor according to claim 1 , wherein the pressed face surface of the second partial core is provided with a step portion across a whole edge of the pressed face of which height is equal to or smaller than 1 mm. 11. The reactor according to claim 1 , wherein the pressed face surface of the second partial core is provided with a step portion with a height equal to or smaller than 5% relative to a thickness of the second partial core.