Method for producing chemically treated alloy material, and chemical treatment solution regeneration apparatus used in method for producing chemically treated alloy material

The invention claimed is: 1. A method for producing a chemically treated alloy material, wherein the alloy material contains Fe, comprising: a chemical treatment step of immersing an alloy material in an oxalate treatment solution containing oxalate ions and fluorine ions to perform chemical treatment of the alloy material; and a treatment solution regeneration step of radiating light at the oxalate treatment solution during the chemical treatment and/or the oxalate treatment solution after the chemical treatment, wherein at least one part of a light source member is immersed in the oxalate treatment solution in a treatment solution regeneration bath. 2. The method for producing a chemically treated alloy material according to claim 1 , wherein: in the treatment solution regeneration step, light is radiated to the oxalate treatment solution while causing the oxalate treatment solution to flow. 3. The method for producing a chemically treated alloy material according to claim 1 , wherein: in the treatment solution regeneration step, wavelengths of the light include a wavelength in an ultraviolet range. 4. The method for producing a chemically treated alloy material according to claim 1 , further comprising: a step of adding oxalate ions to the oxalate treatment solution. 5. The method for producing a chemically treated alloy material according to claim 1 , wherein: the oxalate treatment solution further contains nitrate ions. 6. The method for producing a chemically treated alloy material according to claim 1 , wherein: the oxalate treatment solution further contains thiosulfate ions. 7. The method for producing a chemically treated alloy material according to claim 1 , wherein: the alloy material contains 10.5% or more of Cr. 8. A chemical treatment solution regeneration apparatus, comprising: a treatment solution regeneration bath capable of containing an oxalate treatment solution that contains oxalate ions and fluorine ions, during chemical treatment or after the chemical treatment of an alloy material containing Fe; and a light radiation apparatus that includes one or more light source members, with at least one part of the light source member being disposed inside the treatment solution regeneration bath or in a vicinity of an outer side of the treatment solution regeneration bath, the light radiation apparatus being capable of radiating light at the oxalate treatment solution during the chemical treatment or after the chemical treatment. 9. The chemical treatment solution regeneration apparatus according to claim 8 , wherein: at least one part of the light source member is immersible in the oxalate treatment solution in the treatment solution regeneration bath. 10. The chemical treatment solution regeneration apparatus according to claim 8 , further comprising: a flow mechanism that causes the oxalate treatment solution in the treatment solution regeneration bath to flow. 11. The chemical treatment solution regeneration apparatus according to claim 10 , further comprising: a chemical treatment bath capable of containing the oxalate treatment solution after being irradiated with the light by the light radiation apparatus in the treatment solution regeneration bath, the chemical treatment bath allowing the chemical treatment to be performed by immersing the alloy material in the oxalate treatment solution that is contained in the chemical treatment bath; wherein the flow mechanism comprises: a first liquid supply channel that conveys the oxalate treatment solution in the treatment solution regeneration bath to the chemical treatment bath, and a second liquid supply channel that conveys the oxalate treatment solution in the chemical treatment bath to the treatment solution regeneration bath. 12. The chemical treatment solution regeneration apparatus according to claim 11 , wherein: the chemical treatment bath includes: a first chemical treatment bath and a second chemical treatment bath; the first liquid supply channel including: a first liquid supply channel main body having two end portions on the chemical treatment bath side, a first chemical-treatment-bath-side discharge port that is formed at one of the end portions on the chemical treatment bath side of the first liquid supply channel main body and that discharges the oxalate treatment solution in the first liquid supply channel main body into the first chemical treatment bath, and a second chemical-treatment-bath-side discharge port that is formed at the other of the end portions on the chemical treatment bath side of the first liquid supply channel main body and that discharges the oxalate treatment solution in the first liquid supply channel main body into the second chemical treatment bath; the second liquid supply channel including: a second liquid supply channel main body having two end portions on the chemical treatment bath side, a first chemical-treatment-bath-side inflow port that is formed at one of the end portions on the chemical treatment bath side of the second liquid supply channel main body and that allows the oxalate treatment solution in the first chemical treatment bath to flow into the second liquid supply channel main body, and a second chemical-treatment-bath-side inflow port that is formed at the other of the end portions on the chemical treatment bath side of the second liquid supply channel main body and that allows the oxalate treatment solution in the second chemical treatment bath to flow into the second liquid supply channel; and the flow mechanism further comprises: a discharge port switching mechanism that switches whether to cause the oxalate treatment solution in the first liquid supply channel main body to be discharged from the first chemical-treatment-bath-side discharge port or from the second chemical-treatment-bath-side discharge port, and an inflow port switching mechanism that switches whether to cause the oxalate treatment solution to flow into the second liquid supply channel main body from the first chemical-treatment-bath-side inflow port or from the second chemical-treatment-bath-side inflow port. 13. The chemical treatment solution regeneration apparatus according to claim 10 , wherein: the flow mechanism comprises: an under-regeneration-treatment-solution circulation channel that causes the oxalate treatment solution in the treatment solution regeneration bath to circulate; the under-regeneration-treatment-solution circulation channel comprises: an under-regeneration-treatment-solution circulation channel main body having two end portions, the under-regeneration-treatment-solution circulation channel main body being capable of containing one part of the oxalate treatment solution in the treatment solution regeneration bath, an under-regeneration-treatment-solution inflow port that is formed at one of the end portions of the under-regeneration-treatment-solution circulation channel main body, and that allows the oxalate treatment solution in the treatment solution regeneration bath to flow into the under-regeneration-treatment-solution circulation channel main body, an under-regeneration-treatment-solution discharge port that is formed at the other end portion of the under-regeneration-treatment-solution circulation channel main body, and that discharges the oxalate treatment solution in the under-regeneration-treatment-solution circulation channel main body into the treatment solution regeneration bath, and an under-regeneration-treatment-solution circulation driving source that causes the oxalate treatment solution in the under-regeneration-treatment-solution circulation channel main body to move from t