Stranded conductor and method for manufacturing stranded conductor

The invention claimed is: 1. A stranded conductor, comprising: an inner layer portion; and an outermost layer disposed outside of and concentrically with the inner layer portion, wherein the inner layer portion and outermost layer comprise a plurality of filaments stranded together such that the plurality of filaments comprises a plurality of softened filaments made of an aluminum material and identical to one another and includes a filament disposed along a center of the stranded conductor and a predetermined number of filaments disposed around and concentrically with the center, the inner layer portion includes six filaments of the filaments disposed around and concentrically with the center, and twelve filaments of the filaments disposed around and concentrically with the center and the six filaments, and a lay length is from 8.6 times to 22.0 times a conductor diameter of the stranded conductor, the outermost layer is formed of eighteen filaments of the filaments, an outer layer lay length with which the outermost layer is stranded is from 6.8 times to 22.7 times the conductor diameter, and an inner layer lay length of the inner layer portion in a state in which the outermost layer is formed is a value determined by Equation (1), P ⁢ ⁢ 3 = P ⁢ ⁢ 1 × P ⁢ ⁢ 2 P ⁢ ⁢ 1 + P ⁢ ⁢ 2 , ( 1 ) where P 1 represents an inner layer lay length prior to formation of the outermost layer, P 2 represents the outer layer lay length, and P 3 represents the inner layer lay length in the state in which the outermost layer is formed. 2. The stranded conductor according to claim 1 , wherein the plurality of filaments includes the six filaments that constitute a first filament and the twelve filaments that constitute a second filament such that the first filament and the second filament have an equal lay length. 3. The stranded conductor according to claim 1 , wherein at least the six filaments and the twelve filaments have an equal lay length, or, the six filaments, the twelve filaments, and the eighteen filaments have an equal lay length. 4. The stranded conductor according to claim 1 , wherein at least the six filaments and the twelve filaments have an equal lay length. 5. The stranded conductor according to claim 1 , wherein the six filaments, the twelve filaments, and the eighteen filaments have an equal lay length. 6. A method for manufacturing a stranded conductor, the stranded conductor including filaments made of an aluminum material and identical to one another, the filaments including a filament disposed along a center of the stranded conductor, six filaments stranded around and concentrically with the center, twelve filaments stranded around and concentrically with the center and the six filaments, and eighteen filaments stranded around and concentrically with the center and the twelve filaments, the method comprising: softening the filaments; and stranding together the filaments after the softening, wherein, in the stranding, a lay length is set to from 6.2 times to 15.7 times a conductor diameter of the stranded conductor and a tension from 1.0 N to 4.5 N is applied to the filaments. 7. A method for manufacturing a stranded conductor, the stranded conductor including filaments made of an aluminum material and identical to one another, the filaments including a filament disposed along a center of the stranded conductor and a predetermined number of filaments stranded around and concentrically with the center, the method comprising: stranding six filaments of the plurality of filaments, disposed around and concentrically with the center, and twelve filaments of the plurality of filaments, disposed around and concentrically with the center and the six filaments, wherein, in the stranding of the six filaments and twelve filaments, a lay length is set to from 6.4 times to 22.0 times a conductor diameter of the stranded conductor and a tension from 1.0 N to 7.0 N is applied to the filaments. 8. The method for manufacturing a stranded conductor, according to claim 7 , wherein, in the stranding of the six filaments and twelve filaments, the lay length is set to from 6.4 times to 16.9 times the conductor diameter and a tension from 5.0 N to 7.0 N is applied to the filaments, and after the stranding of the six filaments and twelve filaments, softening the filaments is performed. 9. The method for manufacturing a stranded conductor, according to claim 8 , wherein, the stranding of the six filaments and twelve filaments is performed after the softening of the filaments, and in the stranding of the six filaments and twelve filaments, the lay length is set to from 8.6 times to 22.0 times the conductor diameter and a tension from 1.0 N to 4.5 N is applied to the filaments. 10. A method for manufacturing a stranded conductor according to claim 9 , wherein the stranded conductor produced by the method according to claim 9 serves as an inner layer portion, the stranding of the six filaments and twelve filaments includes stranding the inner layer portion, and stranding an outermost layer formed of eighteen of the filaments, disposed outside of and concentrically with the inner layer portion, and in the stranding of the outermost layer, an outer layer lay length with which the outermost layer is to be stranded is set to from 6.8 times to 22.7 times the conductor diameter and a tension from 1.0 N to 4.5 N is applied to the filaments and a tension from 20 N to 150 N is applied to the inner layer portion. 11. A method for manufacturing a stranded conductor, the stranded conductor including filaments stranded together, the filaments being made of an aluminum material and identical to one another, the filaments including a filament disposed along a center of the stranded conductor, six filaments disposed around and concentrically with the center, twelve filaments disposed around and concentrically with the center and the six filaments, and eighteen filam