Stirrer

The invention claimed is: 1. A stirrer, comprising: a housing including a sucking chamber and a stirring chamber, the sucking chamber and the stirring chamber being comparted by a comparting wall defining an introduction opening in a middle of the comparting wall; a rotating rotor which includes a rotation axis extending through the sucking chamber and the stirring chamber via the introduction opening, and is equipped with plural blades; and a screen having plural slits which is arranged around the rotating rotor, each of the plural slits extending along substantially the entire length of the screen, wherein there is a matching region being an area of a direct overlap between the plural blades and the plural slits in a radial direction perpendicular to the rotation axis, wherein when a fluid to be processed is discharged as an intermittent jet flow through the plural slits from inside the screen to outside the screen by rotating the rotating rotor, a circumferential velocity V (m/sec) of rotation of the rotating rotor satisfies an equation (1) below: V=D×π×N   (1), where D (m) is maximum outer diameter of the rotating rotor in the matching region, N (revolutions/sec) is number of rotations of the rotating rotor over a unit of time, and a frequency Z (kHz) of the intermittent jet flow satisfies an equation (2) below: Z=N×X×Y÷ 1000  (2), where X is number of the plural blades, and Y is number of the plural slits, and wherein the circumferential velocity V is set so as to be larger than 23 m/sec and smaller than 37 m/sec, and the frequency Z is set so as to be more than 35 kHz. 2. The stirrer according to claim 1 , wherein the frequency Z is set at less than 92 kHz. 3. The stirrer according to claim 1 , wherein the screen does not rotate. 4. The stirrer according to claim 1 , wherein diameters of the blades and of the screen become smaller as departing from an introduction port through which the fluid to be processed is introduced into the screen toward outside in the axial direction. 5. The stirrer according to claim 2 , wherein the screen does not rotate. 6. The stirrer according to claim 2 , wherein diameters of the blades and of the screen become smaller as departing from an introduction port through which the fluid to be processed is introduced into the screen toward outside in the axial direction. 7. The stirrer according to claim 3 , wherein diameters of the blades and of the screen become smaller as departing from an introduction port through which the fluid to be processed is introduced into the screen toward outside in the axial direction. 8. The stirrer according to claim 1 , wherein a clearance between the screen and the blades is 0.2-2 mm. 9. The stirrer according to claim 1 , wherein a number of the plural blades is no less than 6, a number of the plural slits is 30-800, and a maximum outer diameter of the rotating rotor in the matching region is in a range from 30 mm to 500 mm. 10. A stirrer, comprising: a housing including a sucking chamber and a stirring chamber, the sucking chamber and the stirring chamber being comparted by a comparting wall defining an introduction opening in a middle of the comparting wall; a rotor which includes a rotation axis extending through the sucking chamber and the stirring chamber via the introduction opening, and is equipped with plural blades; and a screen having plural slits which is arranged around the rotating rotor, each of the plural slits extending along substantially the entire length of the screen, wherein there is a matching region being an area of a direct overlap between the plural blades and the plural slits in a radial direction perpendicular to the rotation axis, wherein when a fluid to be processed is ejected as an intermittent jet flow through the plural slits from inside the screen to outside the screen by rotating the rotating rotor and the screen in the opposite direction with each other, a circumferential velocity V (m/sec) of relative rotation of the rotating rotor to the screen satisfies an equation (1) below: V=D ×π×( N 1+ N 2)  (1), where D (m) is maximum outer diameter of the rotating rotor in the matching region, N 1 (revolutions/sec) is number of rotations of the rotating rotor over a unit of time, N 2 (revolutions/sec) is number of rotations of the screen over a unit of time, and a frequency Z (kHz) of the intermittent jet flow satisfies an equation (2) below: Z =( N 1+ N 2)× X×Y÷ 1000  (2), where X is number of the plural blades, and Y is number of the plural slits, and the circumferential velocity V is set so as to be larger than 48 msec and smaller than 85 m/sec, and the frequency Z is set so as to be more than 65 kHz. 11. The stirrer according to claim 10 , wherein the frequency Z is set at less than 185 kHz. 12. The stirrer according to claim 11 , wherein diameters of the blades and of the screen become smaller as departing from an introduction port through which the fluid to be processed is introduced into the screen toward outside in the axial direction. 13. The stirrer according to claim 10 , wherein diameters of the blades and of the screen become smaller as departing from an introduction port through which the fluid to be processed is introduced into the screen toward outside in the axial direction. 14. The stirrer according to claim 10 , wherein a clearance between the screen and the blades is 0.2-2 mm. 15. The stirrer according to claim 10 , wherein a number of the plural blades is no less than 6, a number of the plural slits is 30-150, and a maximum outer diameter of the rotating rotor in the matching region is in a range from 30 mm to 150 mm.