PL34449B1 - De Directie van de Staatsmijnen in Limburg *) (Heerlen, the Netherlands - Google Patents

Description

It is well known to separate solid particles from gases or to compress suspensions with a cyclone. It was found that cyclones suitable for separating solid particles from gases and for compressing slurries by the Driessen method showed insignificant efficiency when applied to the separation of solids of different grain size and specific gravity. The said type of cyclone has essentially the shape of an elongated truncated cone. The invention relates to an improved cyclone showing high efficiency when used for the separation of solid particles of different sizes and specific gravities. It has, generally speaking, the shape of a series of truncated cones, and its apex gradually increases as it approaches the apex, whereby the cyclone has a convex shape in its vertical section. The gradual increase in the apex angle can be obtained by making the cyclone in the form *). The owner of the patent stated that the inventor is Frederick John Fontein. of a series of adjoining truncated cones with ever greater apex angles, or the walls of this cyclone may have mild convex curves near the apex opening, similar to a canopy. An exemplary embodiment of the subject matter of the invention is shown in the drawing. 1 shows a vertical section of a cyclone formed from a series of truncated cones; 2 is a cross-section of a part of a convex-walled cyclone, and FIG. 3 is a cross-section of a part of another cyclone with a convex wall around the concave apex. The cyclone according to FIG. and a series of truncated cones 6, 7, 8. The cylindrical portion 5 has a cover 9 provided with a drainage opening 10 and a supply conduit 11 tangential to the cylindrical portion 5 and connected to the cyclone by means of an opening 12. Taper 6 has a vertex angle 200. Cone 7 has a vertex angle of 600, and cone 8 has an angle of 600-900 or more. The apex opening 13 is externally provided with a ring 14. The cylindrical part 5 of the cyclone may have e.g. 60 mm in diameter and the upper opening 10 and 12, 18 mm in diameter. The lower diameter of the cone 6 can be 40 mm and the height is 118 mm. The cone 7 may have a bottom diameter of 25 mm and a height of 19 mm, and finally the cone 8 may have a diameter of 7 mm at the outlet, with a height of 9 mm. The above dimensions are those of the more common cyclones of the invention. When using, for example, the above-mentioned Driessen method, it is desirable that the amount of the necessary addition of fine particles is kept to a minimum. The operation of the cyclone according to the invention of the above-mentioned dimensions was compared with a cyclone known in the form of a single taper, with a top angle of 200 and a diameter of the top outlet of 7 mm, the diameter of the upper drain opening of this cyclone being 18 mm, and of the top opening 18 mm, the largest diameter of the cyclone at the base of its cone was 60 mm. The feed rate of these cyclones was equal, but less and less fine particles were added, as a result of which the specific weight gradually decreased. When a known cyclone is used, the separation of the materials is interrupted as soon as the specific weight is reduced to 1.07. On the other hand, when the cyclone according to the invention was used, the specific gravity of the suspension at the inlet opening of 1.07 continued to occur, and the specific gravity in the cyclone was 1.42. In the tests described above, cyclones for coal sorting were used. After the specific weight of the suspension was significantly reduced by reducing the amount of relatively fine particles added to it, the action of the known cyclone was interrupted, while in the cyclone according to the invention the specific gravity was maintained in accordance with the separation conditions. As the added fine particles must later be recovered, it is therefore evident that the less need to be added to the slurry, the more advantageously it is. The cyclone according to the invention thus has a distinct advantage over the known cyclones when used for separation by the Driessen method. The cyclone according to Fig. 2 is similar to the cyclone in Fig. 1, except that its apex has walls with a mild curvature. The section 7a of the cyclone between the lines X and Y corresponds to the cone 7 of the cyclone in FIG. 1, and the section 8a corresponds to the cone 8 of this cyclone. The mean inclination angles of the walls of sections 7a and 8 correspond to the head angles of the cones 7 and 8. The operation of these cyclones is the same; the only difference is that the cones 7 and 8 are more advantageous from the point of view of their simpler production than the surfaces of the sections 7a and 8a. The apex of the cyclone may also have walls convex inwards, which further enhances its performance. In Fig. 3, the cyclone has a similar shape to that in Fig. 2, with the difference that the walls of its lower apex near the outlet opening are slightly convex to the center. PL

Claims (2)

Claims 1. A cone-shaped cyclone with a tangentially led supply line, characterized in that it consists of a cylindrical part (5) and a series of truncated cones (6, 7, 8) with increasing apical angles. 2. Cyclone according to claim A method according to claim 1, characterized in that its apex angle at the outlet opening (14) is greater than 60 °. 3. Cyclone according to claim According to any of the preceding claims. with the angle of its truncated upper cone (6) approximately 20 °. 4. Cyclone according to claims A method as claimed in claim 1, characterized in that its lower apex portion has convex-shaped walls. 5. Cyclone according to claims A method as claimed in claim 1, characterized in that it has walls slightly concave near the apex opening. De Di rect ic van de Staatsmijnen i n Li m bu r g of the College of Patent Attorneys Bltk. 1 - 150 order 2C82—18.6-51. T-3-12004—21.8-52. To Patent No. 34,449 FiG.and F IG.3 FIG. 2. PL