Electric-resistance-welded pipe welding apparatus

The invention claimed is: 1. An electric-resistance-welded pipe welding apparatus, comprising: rolls bending a metal strip to have a circular cross section so that a pair of side edges of the metal strip face each other, the pair of side edges spaced from one another in a downstream direction of the rolls to form a gap; a heating device provided immediately near the metal strip so that heating is performed with respect to the pair of side edges, and the pair of side edges are welded while being pressed to and coming in contact with each other, the heating device having a center and a first end located upstream from the center of the heating device when viewed along a traveling direction of the metal strip and a second end located downstream from the center of the heating device; and a first ferromagnetic body disposed outside the heating device when viewed in a horizontal plane and having a center and a first end located upstream from the center of the first ferromagnetic body and a second end located downstream from the center of the first ferromagnetic body, the first end and second end of the first ferromagnetic body being located upstream from the first end of the heating device when viewed along a traveling direction of the metal strip, the first ferromagnetic body being movably inserted between the pair of side edges of the metal strip, wherein the first ferromagnetic body has a portion that extends along the length of the ferromagnetic body in the traveling direction that extends into the gap between the pair of side edges of the metal strip so as to face the pair of side edges of the metal strip, and in a plane view, the first ferromagnetic body is located upstream from the first end of the heating device so that a space exists between the first ferromagnetic body and the heating device. 2. The electric-resistance-welded pipe welding apparatus according to claim 1 , wherein a surface of the first ferromagnetic body is coated with a material which is non-magnetic and non-conductive. 3. The electric-resistance-welded pipe welding apparatus according to claim 1 , further comprising: a moving mechanism that moves the first ferromagnetic body so as to avoid damage thereof in the gap between the pair of side edges when the first ferromagnetic body comes in contact with the pair of side edges. 4. The electric-resistance-welded pipe welding apparatus according to claim 3 , wherein the moving mechanism is a wire material that hangs and supports the first ferromagnetic body. 5. The electric-resistance-welded pipe welding apparatus according to claim 3 , wherein a shape of the first ferromagnetic body when viewed in a cross-section perpendicular to the traveling direction of the metal strip is a T shape or an H shape which includes a horizontal portion which is disposed in an upper portion of the first ferromagnetic body and a vertical portion which is vertically extended downward from the horizontal portion, and wherein the moving mechanism is an installation plate which includes an opening portion into which the vertical portion is inserted so that the vertical portion is positioned between the pair of side edges, and a placement portion which is provided in a periphery of the opening portion and in which the horizontal portion is placed. 6. The electric-resistance-welded pipe welding apparatus according to claim 5 , further comprising: a member that discharges a cooling medium on the upper portion of the first ferromagnetic body, and a spacer that is interposed between the horizontal portion and the placement portion when the horizontal portion of the first ferromagnetic body is placed on the placement portion of the installation plate, wherein a space through which the cooling medium passes is provided in the spacer so that the cooling medium moves down to the vertical portion of the first ferromagnetic body when the cooling medium is discharged to the upper portion of the first ferromagnetic body. 7. The electric-resistance-welded pipe welding apparatus according to claim 5 , further comprising: a member that discharges a cooling medium to the upper portion of the first ferromagnetic body, wherein the first ferromagnetic body includes slits which pass the cooling medium, and the cooling medium passes through the slits and moves down to the vertical portion when the cooling medium is discharged to the upper portion of the first ferromagnetic body. 8. The electric-resistance-welded pipe welding apparatus according to claim 1 , further comprising a second ferromagnetic body, wherein the heating device is an induction coil, and wherein the second ferromagnetic body is ring shaped and disposed in an outer circumference of the induction coil. 9. The electric-resistance-welded pipe welding apparatus according to claim 8 , wherein the second ferromagnetic body is divided into a plurality of sections along a circumferential direction of the induction coil. 10. The electric-resistance-welded pipe welding apparatus according to claim 9 , wherein a cooling channel to which the cooling medium flows is provided between adjacent sections of the second ferromagnetic body. 11. The electric-resistance-welded pipe welding apparatus according to claim 1 , wherein the heating device is an induction coil, and a metallic shield plate which shields a magnetic flux generated by the induction coil is also provided further in a portion upstream than the first ferromagnetic body in the traveling direction. 12. The electric-resistance-welded pipe welding apparatus according to claim 1 , wherein the first ferromagnetic body is above the metal strip and extends in the gap. 13. The electric-resistance-welded pipe welding apparatus according to claim 1 , wherein the first ferromagnetic has a T shape, an inverted T shape, or an H shape cross-section. 14. The electric-resistance-welded pipe welding apparatus according to claim 1 , further comprising: an impeder installed in an inner portion of the bent metal strip, wherein the first ferromagnetic body is vertically separated from the impeder.