Method for producing stabilizer and heating device

The invention claimed is: 1. A method for producing a stabilizer using a hollow member including a part at which a cross sectional area varies along a central axis from a part having a small cross sectional area to a part having a large cross sectional area as a starting material, the method comprising: a heating process in which the hollow member is heated up to a temperature necessary to perform heat treatment by performing an energization heating of the hollow member, the heating process comprising: a primary heating process in which energization heating is performed between primary electrodes arranged at a cross-section varying part of both ends of the part having the large cross sectional area; and a secondary heating process performed after the primary heating process, in which energization heating is performed between secondary electrodes arranged at both ends of the hollow member, wherein in the primary heating process, the electrodes arranged at the cross section varying part are arranged apart from an interface part of the part having the large cross sectional area and the cross section varying part, and a position along an axis direction of the contacting portion between the electrode and the cross section varying part of a side of the part having the large cross sectional area is aligned to a position along the axis direction at which a cross sectional area ratio with respect to the part having the large cross sectional area in the cross section varying part is 90%, and alternatively, is aligned to a position closer to a side of the part having a small cross sectional area than the position at which the cross sectional area ratio is 90%. 2. The method for producing a stabilizer according to claim 1 , wherein in the primary heating process, a temperature of the part having the large cross sectional area of the hollow member is set to be 350 to 400° C. 3. The method for producing a stabilizer according to claim 1 , wherein an amount of carbon contained in the hollow member is set to be 0.2 to 0.3 wt % by weight ratio, and a temperature of the hollow member is set to be 1100° C. during the secondary heating process. 4. The method for producing a stabilizer according to claim 1 , wherein in a case in which an outer circumferential part of the cross section varying part is formed in a tapered shape, an inner circumferential part of the primary electrode which is arranged on the outer circumferential part of the cross section varying part is formed in a tapered shape that corresponds to the tapered shape of the cross section varying part. 5. A method for producing a stabilizer using a hollow member including a part at which a cross sectional area varies along a central axis from a part having a small cross sectional area to a part having a large cross sectional area as a starting material, the method comprising: a heating process in which the hollow member is heated up to a temperature necessary to perform heat treatment by performing an energization heating of the hollow member, the heating process comprising: a primary heating process in which energization heating is performed between primary electrodes arranged at a cross-section varying part of both ends of the part having the large cross sectional area; and a secondary heating process performed after the primary heating process, in which energization heating is performed between secondary electrodes arranged at both ends of the hollow member, wherein the part having the large cross sectional area is set to have a uniform cross sectional area that is the same along the entirety thereof, and the part having small cross sectional area is set to have a uniform cross sectional area that is the same along the entirety thereof, wherein in the primary heating process, a temperature of the part having the large cross sectional area of the hollow member is set as temperature Th indicated by Formula 1: Th = ( C × Tr + D ) × ( A ⁢ ⁢ 2 A ⁢ ⁢ 1 ) × ( L ⁢ ⁢ 1 L ⁢ ⁢ 2 ) - D C in which C×Tr+D is electric resistivity ρ (μΩmm), C and D are constants, and Tr is room temperature, A1 is the cross sectional area of the part having the small cross sectional area in mm 2 , L1 is a sum of lengths of the parts having small cross sectional area along a central axis direction in mm, A2 is the cross sectional area of the part having a large cross sectional area in mm 2 , L2 is a sum of lengths of the parts having a large cross sectional area along the central axis direction in mm.