Continuous twin-screw mixer and mixing method

The invention claimed is: 1. A continuous mixer for continuously mixing a material, comprising: a barrel with a hollow interior; a hopper positioned to feed a material to be mixed to the interior of the barrel; and a pair of mixing rotors which are housed in the barrel and rotate in mutually different directions, each of the mixing rotors including a feeding portion which is an upstream part in an axial direction, the feeding portion including a first screw flight shaped to feed the material supplied from the hopper to the downstream side through the barrel, a mixing portion which is an intermediate part in the axial direction, the mixing portion including a plurality of mixing flights shaped to mix the material fed from the feeding portion, the mixing flights being formed about an axial center of the mixing rotor and projecting radially outward, and a discharging portion which is a downstream part in the axial direction, the discharging portion including a second screw flight shaped to feed the material mixed by the mixing portion to the downstream side, wherein: each of the mixing flights is shaped differently from each of the first screw flight and the second screw flight; the mixing flights each have a tip, a spacing between the tip of one mixing flight of the pair of mixing rotors and the other mixing flight of the pair of mixing rotors comprising an inter-rotor clearance which is a smallest clearance between the mixing portions in a cross section perpendicular to axial directions of both of the mixing rotors at each rotation phase of the mixing rotors, the rotations of the pair of mixing rotors in the mutually different directions causing respective surfaces of the mixing rotors to move in the same direction on the both sides of the inter-rotor clearance; both of the mixing rotors are arranged so as to make a center distance therebetween smaller than a rotation outer diameter of each of the mixing flights; and the inter-rotor clearance at each rotation phase of the mixing portions of the mixing rotors has a size equal to or smaller than 0.16-fold of an inner diameter of the barrel over a rotation region of 85% or more of one rotation of each of the mixing rotors. 2. A continuous mixer according to claim 1 , wherein the inter-rotor clearance has a size equal to or smaller than 0.16-fold of the inner diameter of the barrel over an entire area of one rotation of each of the mixing rotors. 3. A continuous mixer according to claim 1 , wherein each of the mixing portions forms recesses, each recess being formed between the mixing flights adjacent to each other in a circumferential direction and the pair of mixing rotors are arranged so as to rotate in such a manner that the mixing flights of one mixing rotor are opposed to the respective recesses of the other mixing rotor. 4. A continuous mixer according to claim 1 , wherein the inter-rotor clearance is smaller than the largest one of clearances formed in directions normal to the inner surface of the barrel between the outer surfaces of the mixing portions and the barrel inner surface over an entire area of one rotation of each of the mixing rotors. 5. A continuous mixer according to claim 1 , wherein the inter-rotor clearance has a size between 0.02-fold and 0.16-fold of the inner diameter of the barrel over an entire area of one rotation of each of the mixing rotors. 6. A continuous mixer according to claim 1 , wherein the inner diameter of the barrel is equal to or greater than 1.1-fold of the center distance. 7. A continuous mixer according to claim 1 , wherein the mixing rotor includes at least one mixing portion having a diameter D and an axial length L which make a ratio L/D be 1 or larger than 1. 8. A continuous mixer according to claim 7 , wherein each of the mixing rotors has the mixing portion in only a single area and has a total length ratio Ln/L1 which satisfies a condition of 0.30≤Ln/L1≤0.53 where Ln denotes an axial length of the mixing portion and L1 denotes an axial length of the rotor other than a supported portion of the rotor. 9. A continuous mixer according to claim 7 , wherein each of the mixing rotors has the mixing portion in each of a plurality of areas spaced in the axial direction and has a total length ratio Ln/L1 which satisfies a condition of 0.30≤Ln/L1≤0.53 where Ln denotes a total sum of axial lengths of all of the mixing portions and L1 denotes an axial length of the rotor other than a supported portion of the rotor. 10. A continuous mixing method for continuously mixing a material, comprising: preparing a continuous mixer according to claim 1 ; and mixing the material by generating an extensional flow in the material passing through the inter-rotor clearance. 11. A continuous mixing method according to claim 10 , wherein each of the mixing portions in the prepared continuous mixer forms recesses, each recess being formed between the mixing flights adjacent to each other in a circumferential direction, and the mixing rotors are rotated in such a manner that the mixing flights of one of the pair of mixing rotors are opposed to the respective recesses of the other mixing rotor. 12. A continuous mixer for continuously mixing a material, comprising: a barrel with a hollow interior; a hopper positioned to feed a material to be mixed to the interior of the barrel; and a pair of mixing rotors which are housed in the barrel and rotate in mutually different directions, each of the mixing rotors including a feeding portion which is an upstream part in an axial direction, the feeding portion including a first screw flight shaped to feed the material supplied from the hopper to the downstream side through the barrel, a mixing portion which is an intermediate part in the axial direction, the mixing portion including a plurality of mixing flights shaped to mix the material fed from the feeding portion, the mixing flights being formed about an axial center of the mixing rotor and projecting radially outward, and a discharging portion which is a downstream part in the axial direction, the discharging portion including a second screw flight shaped to feed the material mixed by the mixing portion to the downstream side, wherein: each of the mixing flights is shaped differently from each of the first screw flight and the second screw flight; the mixing flights each have a tip, a spacing between the tip of one mixing flight of the pair of mixing rotors and the other mixing flight of the pair of mixing rotors comprising an inter-rotor clearance which is a smallest clearance between the mixing portions in a cross section perpendicular to axial directions of both of the mixing rotors at each rotation phase of the mixing rotors, the rotations of the pair of mixing rotors in the mutually different directions causing respective surfaces of the mixing rotors to move in the same direction on the both sides of the inter-rotor clearance; both of the mixing rotors are arranged so as to make a center distance therebetween smaller than a rotation outer diameter of each of the mixing flights; and the inter-rotor clearance at each rotation phase of the mixing portions of the mixing rotors has a size equal to or smaller than 0.1-fold of an inner diameter of the barrel over a rotation region of 59% or more of one rotation of each of the mixing rotors. 13. A continuous mixing method for continuously mixing a material, comprising: preparing a continuous mixer according to claim 12 ; and mixing the material by generating an extensional flow in the material passing through the inter-rotor clearance. 14. A continuous mixing method according to claim 13 , wherein each of the mixing porti