Method for producing slit separator, method for producing separator roll, and method for slitting separator

The invention claimed is: 1. A method for producing a slit separator, comprising: a conveying step of conveying a battery separator original sheet which is porous; and a slitting step of slitting the battery separator original sheet by causing a slitting blade to cut into the battery separator original sheet which is being conveyed, in the slitting step, a blade edge angle of the slitting blade being in a range of not less than 3° to not more than 35° in a tangent plane, which tangent plane is in contact with the battery separator original sheet at a slitting position, which slitting position is a position at which the battery separator original sheet is being slit by the slitting blade, which blade edge angle of the slitting blade in the tangent plane is an angle at which angle the slitting blade expands from the blade edge as a tip in a cross section of the slitting blade taken along the tangent plane. 2. The method as set forth in claim 1 , wherein the blade edge of the slitting blade in the tangent plane is not more than 28°. 3. The method as set forth in claim 1 , wherein the blade edge angle of the slitting blade in the tangent plane falls within a range of not less than 5° to not more than 21°. 4. The method as set forth in claim 1 , wherein a shape of the blade edge of the slitting blade is plane-symmetrical with respect to a plane, the plane being (i) perpendicular to the tangent plane and (ii) parallel to a direction in which the battery separator original sheet is conveyed. 5. A method for producing a separator roll, comprising: each of the steps recited in the method as set forth in claim 1 ; and a winding step of winding, around a core, a separator which has been slit. 6. The method as set forth in claim 1 , wherein: the blade edge of the slitting blade has a linear shape; and in the slitting step, the slitting blade cuts into the battery separator original sheet such that the following Formula (6) is satisfied: θ 3 =2·tan −1 (sin(θ 2 )·tan(θ 1 /2))  Formula (6) where (i) θ 1 is a cross-sectional angle of a cross section perpendicular to the blade edge of the slitting blade, (ii) θ 2 is an angle between the blade edge and the battery separator original sheet, and (iii) θ 3 is the blade edge angle of the slitting blade in the tangent plane, wherein in the Formula (6), the θ 1 and θ 2 correspond to θ 3 falling within the range. 7. The method as set forth in claim 1 , wherein: the blade edge of the slitting blade has a shape of a circular arc; and in the slitting step, the slitting blade cuts into the battery separator original sheet such that the following Formula (6)′ is satisfied: θ 3 =2·tan −1 (sin(90°−cos 1 ((½)/ rs ))·tan(θ 1 /2))  Formula (6)′ where (i) θ 1 is a cross-sectional angle of a cross section perpendicular to the blade edge of the slitting blade, (ii) rs is a radius of the circular arc, (iii) 1 is a length of a part of the slitting blade which part falls on the tangent plane, the length being measured in a direction in which the battery separator original sheet is conveyed, and (iv) θ 3 is the blade edge angle of the slitting blade in the tangent plane, wherein in the Formula(6)′, θ 1 , rs, and 1 correspond to the θ 3 falling within the range. 8. The method as set forth in claim 1 , wherein: the blade edge of the slitting blade has a linear shape; in the slitting step, the battery separator original sheet is conveyed on a roller which is provided with a groove in which part of the blade edge of the slitting blade can be inserted; and in the slitting step, the slitting blade cuts into the battery separator original sheet such that the following Formula (6)″ is satisfied: θ 3 =2·tan −1 (sin(cos −1 (( rr−z ))/ rr ))·tan(θ 1 /2))  Formula(6)″ where (i) θ 1 is a cross-sectional angle of a cross section perpendicular to the blade edge of the slitting blade, (ii) rr is a radius of the roller, (iii) z is a depth of the part of the blade edge, which part is inserted in the groove, and (iv) θ 3 is a blade edge angle of the slitting blade in the tangent plane, wherein in the Formula (6)″, θ 1 , rr, and z correspond to θ 3 falling within the range. 9. The method as set forth in claim 6 , wherein: the slitting blade is a single-beveled blade; and in the slitting step, the slitting blade cuts into the battery separator original sheet such that in the Formula (6), a variable including θ 1a corresponds to θ 3a falling within the range where (i) by substituting the following Formula (10a) into the Formula (6), θ 3 is represented by the variable including θ ia and (ii) by substituting, into the following Formula (11), θ 3 which is represented by the variable including θ 1a , θ 3a is represented by the variable including θ 1a : θ 1 =2θ 1a   Formula (10a) θ 3a =θ 3 /2  Formula (11) where (i) θ 1a is a cross-sectional angle of a cross section perpendicular to the blade edge of the single-beveled blade and (ii) θ 3a is a blade edge angle of the single-beveled blade in the tangent plane. 10. The method as set forth in claim 1 , wherein: the slitting blade includes (i) an upper blade whose blade edge has a shape of a circular arc and (ii) a lower blade which is incorporated in a roller and which has an outer diameter identical to that of the roller; in the slitting step, the battery separator original sheet is conveyed on the roller; and in the slitting step, the upper blade cuts into the battery separator original sheet such that in the following Formula (12),θ 1a , rc, rd, and z correspond to θ 3a falling within the range where (i) a variable θ 2cc is represented by rc, rd, and z by substituting the following Formula (16) into the following Formula (17), (ii) the variable θ 2cd is represented by rc, rd, and z by substituting the following Formula (16) into the following Formula (18), and (iii) θ 3a is represented by rc, rd, and z by substituting, into the following Formula (12), the variable θ 2cc and the variable θ 2cd each represented by rc, rd, and z: OcOd=rc+rd−z   Formula (16) θ 2cc =cos −1 (( rc 2 +OcOd 2 −rd 2 )/(2 ·rc·OcOd ))  Formula (17) θ 2cd =cos −1 (( rd 2 +OcOd 2 −rc 2 )/(2 ·rd·OcOd ))  Formula (18) θ 3a =tan −1 (sin(θ 2cc +θ 2cd )·tan(θ 1a ))  Formula (12) where (i) θ 1a is a cross-sectional angle of a cross section perpendicular to the blade edge of the upper blade, (ii) rc is a radius of the upper blade, (iii) rd is a radius of the lower blade, (iv) z is a depth by which the upper blade and the lower blade are in contact with each other, and (v) θ 3a is a blade edge angle of the upper blade in the tangent plane.