Method for determining characteristic stress of welding structure, method for designing welded structure, and method for manufacturing welded structure

The invention claimed is: 1. A method of designing a welded structure, the method comprising: a test piece preparation step of preparing a test piece including a welding structure in which a welding material formed of an austenitic alloy is welded to a member formed of low-alloy steel or low-carbon steel; a hydrogen supply step of supplying hydrogen to the test piece; a characteristic stress acquisition step of applying a load to the test piece to which hydrogen was supplied and acquiring the characteristic stress showing material mechanical properties of the test piece; and a design step of designing the welded structure so that maximum stress occurring in the welding structure is less than the characteristic stress determined in the method of determining the characteristic stress of the welding structure in welded structures including the welding structure, wherein the welded structure includes a first member formed of the low-alloy steel or the low-carbon steel, a first welding member formed of a first welding material serving as the welding material built-up welded to the surface of the first member, and a second member welded to the surface of the first welding member via a second welding material, wherein the first member has a concave portion formed in the member formed of the low-alloy steel or the low-carbon steel by cutting a surface of the member and a side surface of the concave portion is inclined gradually toward an outer side of the concave portion as the side surface of the concave portion approaches an uncut surface, wherein the surface of the first member for built-up welding the first welding material is a bottom surface and a side surface of the concave portion, and wherein, in the design step, a region in which there is a side surface of the concave portion in a first direction in which a surface around the concave portion is widened is separated from a position in the first direction in which a surface of a second welding member formed of the second welding material is in contact with a surface of the first welding member. 2. The method of designing the welded structure according to claim 1 , wherein the hydrogen supply step is executed while the characteristic stress acquisition step is executed. 3. The method of designing the welded structure according to claim 1 , wherein the hydrogen supply step is executed before the characteristic stress acquisition step is executed. 4. The method of designing the welded structure according to claim 1 , wherein the hydrogen supply step is continuously executed while the characteristic stress acquisition step is executed, from a time before the execution of the characteristic stress acquisition step. 5. The method of designing the welded structure according to claim 1 , wherein, in the hydrogen supply step, the hydrogen is supplied to the test piece by arranging the test piece in an aqueous solution including hydrogen ions and setting the test piece as a negative electrode. 6. The method of designing welded structure according to claim 1 , wherein, in the hydrogen supply step, the hydrogen is supplied to the test piece by arranging the test piece in an aqueous solution including hydrogen ions and setting the test piece as a negative electrode, and wherein, according to the execution of the hydrogen supply step, a hydrogen supply condition including an execution time of the hydrogen supply step to be executed before the characteristic stress acquisition step is determined so that a hydrogen concentration of a part formed of the low-alloy steel or the low-carbon steel in the test piece is greater than or equal to a maximum hydrogen concentration in a part of the first member, the part being on a boundary side with the first welding member. 7. The method of designing the welded structure according to claim 1 , wherein, after a test piece base material including the welding structure in which the welding material is welded to the member formed of low-alloy steel or low-carbon steel is prepared in the test piece preparation step, a part including a boundary between the low-alloy steel or the low-carbon steel and the welding material is acquired as the test piece from the test piece base material. 8. The method of designing the welded structure according to claim 1 , wherein the characteristic stress acquired in the characteristic stress acquisition step is fracture stress. 9. The method of designing the welded structure according to claim 1 , wherein the welded structure is a pressure vessel. 10. The method of designing the welded structure according to claim 9 , wherein the pressure vessel is a vessel in which coolant in a nuclear power plant is accumulated. 11. A method of manufacturing a welded structure, the method comprising: the method of designing the welded structure according to claim 1 ; and a manufacturing step of manufacturing the welded structure according to a result of executing the design method. 12. A method of designing a welded structure, the method comprising: a test piece preparation step of preparing a test piece including a welding structure in which a welding material formed of an austenitic alloy is welded to a member formed of low-alloy steel or low-carbon steel; a hydrogen supply step of supplying hydrogen to the test piece; a characteristic stress acquisition step of applying a load to the test piece to which hydrogen was supplied and acquiring the characteristic stress showing material mechanical properties of the test piece; and a design step of designing the welded structure so that maximum stress occurring in the welding structure is less than the characteristic stress determined in the method of determining the characteristic stress of the welding structure in welded structures including the welding structure, wherein the welded structure includes a first member formed of the low-alloy steel or the low-carbon steel, a first welding member formed of a first welding material serving as the welding material built-up welded to the surface of the first member, and a second member welded to the surface of the first welding member via a second welding material, wherein the first member has a concave portion formed in the member by cutting a surface of the member formed of the low-alloy steel or the low-carbon steel, a side surface of the concave portion is inclined gradually toward an outer side of the concave portion as the side surface of the concave portion approaches an uncut surface, and a bottom surface of the concave portion is widened in the first direction in which a surface around the concave portion is widened, wherein the surface of the first member for built-up welding the first welding material is the bottom surface and the side surface of the concave portion, and wherein an angle formed by the side surface inclined to the bottom surface of the concave portion is determined so that a maximum stress occurring in the welding structure of the welded structure is less than the characteristic stress in the design step. 13. The method of designing the welded structure according to claim 12 , wherein the hydrogen supply step is executed while the characteristic stress acquisition step is executed. 14. The method of designing the welded structure according to claim 12 , wherein the hydrogen supply step is executed before the characteristic stress acquisition step is executed. 15. The method of designing the welded structure according to claim 12 , wherein the hydrogen supply step is continuously executed while the characteristic stress acquisition step is executed, from a time before the execution of the characteristi