Mixing and stirring device, method, and method for manufacturing lightweight gypsum board, including chute with eccentric orifice passage

The invention claimed is: 1. A mixing and stirring device for gypsum slurry, which has a circular casing forming a mixing area for mixing of the gypsum slurry, a rotary disc positioned in the casing and rotated in a predetermined rotational direction, and a tubular passage for delivery of the gypsum slurry, which is provided outside of the casing in order to feed the slurry of the mixing area onto a sheet of paper for gypsum board liner, and which generates an intratubular swirling flow for mixing the gypsum slurry with foam or foaming agent for adjustment of a specific gravity, wherein said tubular passage includes a chute which receives the gypsum slurry effluent from the casing through a slurry outlet port provided on the casing and which allows the slurry to flow down gravitationally therein, and a discharge pipe portion connected with an outlet part of said chute for spouting the slurry onto said sheet of paper; wherein said chute has an orifice passage which locally constricts a cross section of an intratubular area of the chute for causing the gypsum slurry and the foam or foaming agent to revolve in the intratubular area; and wherein a centroid of a figure of a cross section of the orifice passage is located at a position eccentric with respect to a center axis of said intratubular area. 2. The device as defined in claim 1 , wherein an eccentricity ratio η=ΔE/r of said centroid is set to be equal to or greater than 0.06, and wherein ΔE is a distance between said centroid and said center axis of the intratubular area, and r is a radius of the intratubular area. 3. The device as defined in claim 1 , wherein a contour of the cross section of said orifice passage is a composite figure constituted from a plurality of figures partially superimposed with each other, and the centroid of the composite figure is eccentric with respect to the center axis of said intratubular area. 4. The device as defined in claim 3 , wherein said composite figure is constituted from a plurality of circles having different diameters and/or different center positions, the circles being superimposed with each other only partially. 5. The device as defined in claim 1 , wherein an eccentricity ratio η′=ΔE/Rmax is set to be equal to or greater than 0.1, and wherein ΔE is a distance between said centroid and the center axis of said intratubular area, and Rmax is a maximum value of a distance between said center axis and a contour of the figure. 6. The device as defined in claim 1 , wherein a foam feeding port, which feeds the foam or foaming agent to said slurry, is located on an annular wall of said casing so as to feed the foam or foaming agent to the slurry immediately before the slurry of said mixing area flows into said slurry outlet port, or is provided on a hollow connector part between the chute and the slurry outlet port so as to feed the foam or foaming agent to the slurry immediately after the slurry of the mixing area flows through the slurry outlet port. 7. The device as defined in claim 1 , wherein an orifice member having said orifice passage is positioned in said chute, and the orifice member is supported in the chute rotatably around said center axis of the intratubular area for adjusting or controlling an intensity of an axisymmetric vortex flow breakdown action of the orifice passage. 8. An apparatus for manufacturing lightweight gypsum boards, which has the mixing and stirring device as defined in claim 1 . 9. A method for mixing and stirring gypsum slurry, with use of a mixing and stirring device for the gypsum slurry having a circular casing forming a mixing area for mixing of the gypsum slurry, a rotary disc positioned in the casing and rotated in a predetermined rotational direction, and a chute for delivery of the gypsum slurry which is provided outside of the casing in order to feed the slurry of the mixing area to a sheet of paper for gypsum board liner and which generates an intratubular swirling flow for mixing the slurry with foam or foaming agent for adjustment of specific gravity, wherein the slurry effluent from the casing through a slurry outlet port positioned on said casing is caused to flow down gravitationally in an intratubular area of the chute, and the foam or foaming agent is mixed with the slurry by said intratubular swirling flow generated in the intratubular area, and the slurry is introduced from the chute into a discharge pipe portion through an orifice passage which locally constricts a cross section of the intratubular area, and wherein a centroid of a figure of a cross section of the orifice passage is located at a position eccentric with respect to a center axis of said intratubular area, so that an axisymmetric vortex flow in the intratubular area is at least partially broken down by the orifice passage, for restricting regeneration or generation of the intratubular swirling flow in said discharge pipe portion on a downstream side of the orifice passage. 10. The method as defined in claim 9 , wherein an eccentricity ratio η=ΔE/r of said centroid is set to be equal to or greater than 0.06, and wherein ΔE is a distance between the centroid and said center axis, and r is a radius of said intratubular area. 11. The method as defined in claim 9 , wherein a contour of the cross section of said orifice passage is a composite figure constituted from a plurality of figures partially superimposed with each other, and the centroid of the composite figure is eccentric with respect to the center axis of said intratubular area. 12. The method as defined in claim 11 , wherein said composite figure is constituted from a plurality of circles having different diameters and/or different center positions, the circles being superimposed with each other only partially. 13. The method as defined in claim 9 , wherein an eccentricity ratio η′=ΔE/Rmax is set to be equal to or greater than 0.1, and wherein ΔE is a distance between said centroid and the center axis of said intratubular area, and Rmax is a maximum value of a distance between said center axis and a contour of the figure. 14. The method as defined in claim 9 , wherein a supply amount of foam or foaming agent fed to said gypsum slurry is set to be the amount for making a gypsum core of the gypsum board having a specific gravity in a range from 0.4 to 0.7. 15. The method as defined in claim 9 , wherein intensity of an axisymmetric vortex flow breakdown action of said orifice passage is adjusted or controlled by change or lateralization of a position or configuration of the cross section of said orifice passage. 16. A method for manufacturing lightweight gypsum boards having a specific gravity equal to or less than 0.8, wherein gypsum slurry is produced with use of a mixing and stirring device for the gypsum slurry, which has a circular casing forming a mixing area for mixing of the gypsum slurry, a rotary disc positioned in the casing and rotated in a predetermined rotational direction, and a tubular passage for delivery of the gypsum slurry provided outside of the casing in order to feed the slurry of the mixing area to a sheet of paper for gypsum board liner, and wherein the slurry of the mixing area is spouted onto said sheet of paper through a chute which allows the slurry to flow down gravitationally, comprising steps of: introducing said gypsum slurry of the mixing area effluent from the casing through a slurry outlet port disposed on the casing, into a tubular passage of said chute together with foam or foaming agent for adjustment of a specific gravity, and generating an intratubular swirling flow in an intratubular area of the chute by turning th