Device For Dispersing Water-Soluble Polymers

1 . A device for dispersing a water-soluble polymer in powder form having a standard particle size of less than 1 mm, comprising: a wetting chamber, into which the polymer is dosed, comprising a cylindrical upper part with a vertical axis of revolution extended by a conical lower part, said wetting chamber being further provided with: at least one opening formed in a thickness of a wall of the upper and/or lower parts, said opening emerging laterally into a connection to a primary water supply circuit, a cover provided with an opening formed in a thickness of a wall of said cover, said opening emerging into a connection to a source of powdered polymer, a chamber for grinding and discharging the dispersed polymer with a horizontal axis of revolution, said grinding chamber comprising: a rotor driven by a motor and provided with blades, said blades possibly being inclined with respect to the horizontal plane of the stator, a fixed stator in the form of a cylinder, in the wall of which a single row of vertical slots is cut over part of a height of said wall, over all or part of a periphery of the chamber, a ring fed by a secondary water circuit, the ring communicating with the grinding chamber so as to spray pressurized water onto the stator, an L-shaped tube connecting the wetting chamber to the grinding chamber, one end of which connects to the lower end of the wetting chamber and another end of which connects to an inlet of the grinding chamber, characterized in that the upper and lower parts of the wetting chamber and the L-shaped tube have an internal surface with an identical surface tension (TS 1 ), and in that the cover of the wetting chamber has an internal surface with a surface tension (TS 2 ) higher than the surface tension (TS 1 ) of the internal surface of the upper and lower parts of the wetting chamber and the L-shaped tube. 2 . The device according to claim 1 , characterized in that a difference between the surface tension of the internal face of the cover (TS 2 ) and that of the lower face of the upper and lower parts of the wetting chamber and the L-shaped tube (TS 1 ) is at most 4 mN·m −1 . 3 . The device according to claim 1 , characterized in that a difference between the surface tension of the internal face of the cover (TS 2 ) and that of the lower face of the upper and lower parts of the wetting chamber and the L-shaped tube (TS 1 ) is 4 mN·m −1 . 4 . The device according to claim 1 , characterized in that the thickness of the wall in which the opening is formed emerging into the connection to the primary water supply circuit and the internal surface of said connection to the primary water supply circuit have a surface tension equal to (TS 1 ). 5 . The device according to claim 1 , characterized in that the wetting chamber has an opening formed in the thickness of the wall of its upper part emerging laterally into an overflow and in that the thickness of the wall and the internal surface of said overflow have a surface tension equal to (TS 1 ). 6 . The device according to claim 1 , characterized in that the thickness of the wall of the cover in which the opening is formed emerging into the connection to the source of powdered polymer and the internal surface of said connection to the source of powdered polymer have a surface tension equal to (TS 2 ). 7 . The device according to claim 1 , characterized in that a material constituting the internal surface of the wetting chamber, its cover, including the thickness of the wall in which the openings are formed, and the internal surface of the L-shaped tube, is metal which has undergone a mechanical treatment capable of imparting to said surface a surface tension (TS 1 ) or (TS 2 ) respectively. 8 . The device according to claim 1 , characterized in that the material constituting the internal surface of the wetting chamber, its cover, including the thickness of the wall in which the openings are formed, and the internal surface of the L-shaped tube, is metal, and the internal surface is chemically modified so as to impart to said surfaces a surface tension (TS 1 ) or (TS 2 ) respectively. 9 . The device according to claim 1 , characterized in that the surface tension (TS 1 ) is between 7.5 and 19.5 mN·m −1 and the surface tension (TS 2 ) is between 11.5 and 23.5 mN·m −1 . 10 . The device according to claim 7 , characterized in that the mechanical treatment is electropolishing. 11 . The device according to claim 8 , characterized in that the metal surface is chemically modified by a coating, the surface of said coating having a surface tension (TS 1 ) or (TS 2 ). 12 . The device according to claim 1 , characterized in that the blades of the rotor, at least in part, and the stator are made of stainless steel chosen from austenitic-ferritic or austenitic steels treated by vacuum nitriding or by carbon diffusion.