Granulated body manufacturing apparatus and method

What is claimed is: 1. A granulated body manufacturing apparatus comprising: a housing that includes a cylindrical internal space, is disposed so that a center axis direction of the internal space is horizontal, and houses a raw material for a granulated body inside the internal space; an agitation blade that is provided along an inner circumferential surface of the internal space, and upon being rotated around the center axis, scoops up the raw material accumulated in a bottom portion of the internal space and makes the raw material fall down from an upper position inside the internal space; and a crossing blade including a wire having a wire diameter not exceeding 0.3 mm, the wire being provided at a position in a range, inside the internal space, in which the crossing blade does not come into contact with the agitation blade, and upon being rotated around the center axis, crossing a route of the fall of the raw material and fining the raw material, and being looped around a framework body that is provided at a position in a range, inside the internal space, in which the framework body does not come into contact with the agitation blade, and rotates around the center axis. 2. The manufacturing apparatus according to claim 1 , wherein: the framework body includes a hub portion that receives a rotational driving force from a rotation driving source, a first branch portion projecting outward from the hub portion, and a second branch portion projecting outward from the hub portion at a site that is different in an axis direction from that of the first branch portion; and the wire is looped around the first branch portion and the second branch portion. 3. The manufacturing apparatus according to claim 2 , wherein the first branch portion and the second branch portion are provided at respective positions that are different from each other also in a circumferential direction around the axis. 4. The manufacturing apparatus according to claim 1 , wherein a rotation speed of the framework body is higher than a rotation speed of the agitation blade. 5. The manufacturing apparatus according to claim 2 , wherein a rotation speed of the framework body is higher than a rotation speed of the agitation blade. 6. The manufacturing apparatus according to claim 3 , wherein a rotation speed of the framework body is higher than a rotation speed of the agitation blade. 7. A granulated body manufacturing method comprising: housing a raw material for a granulated body in a cylindrical internal space disposed so that a center axis direction of the cylindrical internal space is horizontal; rotating an agitation blade around the center axis, the agitation blade being provided along an inner circumferential surface of the internal space, and scooping up the raw material accumulated in a bottom portion of the internal space and making the raw material fall from an upper position inside the internal space; and rotating a crossing blade around the center axis, the crossing blade being provided at a position in a range, inside the internal space, in which the crossing blade does not come into contact with the agitation blade, making the crossing blade cross a route of the fall of the raw material and fining the raw material, a wire having a wire diameter not exceeding 0.3 mm being used for the crossing blade, the wire being looped around a framework body that is provided at a position in a range, inside the internal space, in which the framework body does not come into contact with the agitation blade, and rotates around the center axis. 8. A granulated body manufacturing method comprising: housing a raw material for a granulated body in a cylindrical internal space disposed so that a center axis direction of the cylindrical internal space is horizontal; rotating an agitation blade around the center axis, the agitation blade being provided along an inner circumferential surface of the internal space, scooping up the raw material accumulated in a bottom portion of the internal space, making the raw material fall from an upper position inside the internal space and fining the raw material; and injecting a foamed liquid containing a surfactant agent into the internal space while rotating the agitation blade, and mixing the raw material with the liquid.