Friction stir welding method and friction stir welding apparatus

The invention claimed is: 1. A friction stir welding method comprising: a first friction stir welding process of forming a first stirring region in a welded part of a metallic material, by moving a first rotary tool in a first advancing direction while rotating the first rotary tool, the first rotary tool being disposed on one side of the welded part in a thickness direction across the welded part; and a second friction stir welding process of forming a second stirring region in the welded part, by moving a second rotary tool in a second advancing direction while rotating the second rotary tool, simultaneously with the first friction stir welding process, the second rotary tool being disposed on the other side of the welded part in the thickness direction across the welded part, wherein: the first stirring region is a region which reaches an interior of the welded part from the one side of the welded part in the thickness direction, the second stirring region is a region which reaches an interior of the welded part from the other side of the welded part in the thickness direction, the first stirring region and the second stirring region overlap each other inside the welded part in the thickness direction, a first rotary axis of the first rotary tool and a second rotary axis of the second rotary tool are provided in parallel, and the first rotary tool and the second rotary tool are configured to he shifted left and right orthogonal to the thickness direction, wherein the first rotary tool includes: a first tool body having a first shoulder part which is in contact with one surface of the welded part, and a first probe protruding from the first tool body toward the second rotary tool, wherein the second rotary tool includes: a second tool body having a second shoulder part which is in contact with the other surface of the welded part, and a second probe protruding from the second tool body toward the first rotary tool, and wherein the first rotary tool and the second rotary tool are configured to be shifted in a range in which at least a part of the first shoulder part and the second shoulder part overlap each other in the thickness direction; wherein the first rotary tool is configured to rotate about the first rotary axis, the first shoulder part has an outer circumferential surface, the first probe has a circular first front end surface on a front end side that is a second rotary tool side, the second rotary tool is configured to rotate about the second rotary axis, the second shoulder part has an outer circumferential surface, the second probe has a circular second from end surface on a front end side that is a first rotary tool side, a distance between the first rotary axis and the second rotary axis is defined as L, a diameter of the first shoulder part is defined as D 1 , a diameter of the first front end surface is defined as d 1 , a diameter of the second shoulder part is defined as D 2 , and a diameter of the second front end surface is set defined as d 2 , in a case where (D 1 /2+d 2 /2)≤(D 2 /2+d 1 /2), the first rotary tool and the second rotary tool are configured to be shifted so that the distance L is in a range of (d 1 /2+d 2 /2)<L<(D 1 /2+d 2 /2), and in a case where (D 1 /2+d 2 /2)>(D 2 /2+d 1 /2), the first rotary tool and the second rotary tool are configured to be shifted so that the distance L is in a range, of(d 1 /2+d 2 /2)<L<(D 2 /2+d 1 /2). 2. The friction stir welding method according to claim 1 , wherein: the welded part is a beveled part formed by making a pair of metallic materials butt against each other, the beveled part forms a welding line extending from a welding start point toward a welding end point, and the first rotary tool and the second rotary tool are configured to move on the welding line. 3. The friction stir welding method according to claim 1 , wherein: the first advancing direction and the second advancing direction are in a same advancing direction, the first rotary tool is formed to have a length in the thickness direction which reaches the interior of the welded part from the one side of the welded part, the second rotary tool is formed to have a length in the thickness direction which reaches the interior of the welded part from the other side of the welded part, and the first rotary tool and the second rotary tool overlap each other inside the welded part in the thickness direction and are configured to be at least shifted front and rear in the same advancing direction. 4. The friction stir welding method according to claim 1 , wherein, when the first rotary tool and the second rotary tool are viewed from one side in the thickness direction, a rotary direction of the first rotary tool and a rotary direction of the second rotary tool are opposite to each other. 5. The friction stir welding method according to claim 1 , wherein the first rotary tool and the second rotary tool have a same shape. 6. A friction stir welding method comprising: a first friction stir welding process of forming a first stirring region in a welded part of a metallic material, by moving a first rotary tool in a first advancing direction while rotating the first rotary tool, the first rotary tool being disposed on one side of the welded part in a thickness direction across the welded part; and a second friction stir welding process of forming a second stirring region in the welded part, by moving a second rotary tool in a second advancing direction while rotating the second rotary tool, simultaneously with the first friction stir welding process or after performing the first friction stir welding process, the second rotary tool being disposed on the other side of the welded part in the thickness direction across the welded part, wherein: the first stirring region is a region which reaches an interior of the welded part from the one side of the welded part in the thickness direction, the second stirring region is a region which reaches the interior of the welded part from the other side of the welded part in the thickness direction, the first stirring region and the second stirring region overlap each other inside the welded part in the thickness direction, when performing the second friction stir welding process after performing the first friction stir welding process, in the first friction stir welding process, a first reaction force rotary tool is provided on an opposite side of the first rotary tool across the welded part, the first reaction force rotary tool having a first abutting surface which abuts against the other side of the welded part in the thickness direction, and imparting a reaction force to the first rotary tool, and in the second friction stir welding process, a second reaction force rotary tool is provided on the opposite side of the second rotary tool across the welded part, the second reaction force rotary tool having a second abutting surface which abuts against the one side of the welded part in the thickness direction, and imparting a reaction force to the second rotary tool, wherein the first rotary tool has: a first tool body having a first shoulder part which is in contact with one surface of the welded part, a first insertion hole formed to penetrate the first tool body along a first rotary axis of the first rotary tool, and a first probe pin which is inserted through the first insertion hole, is movable in an axial direction of the first rotary axis and protrudes toward the first reaction force rotary tool from the first tool body, wherein the first reaction force rotary tool has: a second tool body having a second shoulder part which is in contact with the other surface of the welded part, a second insertion hole formed to penetrate the second tool body along a second rotary axis of the first reaction force rotary tool