RU2007227C1 - Wet screening trommel - Google Patents

Abstract

FIELD: screening technology. SUBSTANCE: trommel has horizontally rotatably mounted drum 1 with a cylindrical sieving surface and end walls 2 which form an overflow threshold. Overflow pocket 5 which communicates with an initial product reservoir is located under the threshold. Feed manifold 3 is located over the overflow threshold, and its nozzles 4 - perpendicularly to sieving surface 2 for material feed over the overflow threshold. Washing nozzles 4 are mounted over drum 1, and course fraction bleed chute 7 - inside the drum under it. EFFECT: improved structure. 2 cl, 1 dwg

Description

 The invention is intended for the wet classification of finely divided plate materials, for example, mica.

 Hydrocyclones, upstream classification systems and wet shale shakers (such as rotap) are currently used for hydraulic classification. The main disadvantage of such installations is the comparatively low classification efficiency (transfer of a large fraction into a small class or a large fraction residue in a large class). From this point of view, classification according to the area of particles on the sieves gives better results, but the process is not technologically advanced due to the difficulty of removing (large) mica from the surface of the mesh [1].

 Also known is a drum screen for wet screening, which is a horizontal mesh drum with a horizontal axis of rotation, located between two bearing bearings [2].

 The suspension to be classified is fed into the drum. The large product remaining on the grid is washed off by nozzles into the inside of the drum and when the drum is tilted, it moves along its generatrix to the end of the drum, where the hopper for collecting a large fraction is located. The disadvantage of this device is that the large product washed off during the regeneration of the mesh is again mixed with the source material located at the bottom of the drum. When sliding down the lower surface of the inclined drum of a large product, part of the finer product is inevitably carried away, reducing the efficiency of the apparatus.

 There is also known a drum screen for wet screening, including a horizontal screening sieve with a cylindrical surface, cantileverly fixed from one end to the shaft, and a pulp supply line located at the lower end of the drum along its length, respectively, in the lower part inside the drum, and heat in the upper part inside the drum for the removal of large fractions and in the upper part above the drum - nozzles for supplying drainage water.

 Closest to the proposed device is a drum screen for wet screening, including a horizontally rotatable drum with end walls forming a drain threshold, a supply line with nozzles located above the drain threshold. The disadvantage of this device is that a large (oversize) fraction contains a large number of small (oversize) fractions that do not have time to pass under the grid while the material was in the screen.

 The aim of the invention is to provide high efficiency classification of plate materials.

 This is achieved by the fact that the screen is equipped with an overflow pocket located under the overflow threshold and communicated with the capacity of the initial suspension, and the nozzles of the supply line are perpendicular to the screening surface with the possibility of feeding material over the overflow threshold. Moreover, the drum is mounted cantilever on the shaft by means of a blind end wall, and the supply line, estrus of the removal of a large fraction and an overflow pocket are located at the opposite end.

 The drawing shows a drum screen.

 It consists of a cantilevered drum 1 and two end walls 2, a supply line 3, equipped with nozzles 4, an overflow pocket 5, estrus fine fraction 6, estrus coarse fraction 7, flush nozzles 8.

 The operation of the device is as follows. The suspension requiring classification is fed under pressure along the supply line 3 through nozzles 4 into the drum 1 having a cylindrical mesh surface, into its lower part directly onto the mesh. In this case, the nozzle diameter is selected depending on the volumetric productivity of the apparatus so that the pressure at the outlet of the suspension from the nozzle is at least 1 atm. A thin product through the net enters the estrus of fine fraction 6, and large particles of mica, forming a dense layer on the surface of the net, are carried away by it upward. When the drum 1 rotates, the mica-covered surface of the mesh leaves the suspension layer and, reaching its upper position, gets under the stream of water from the flushing nozzles 8. A large fraction with flushing water enters the estrus of the coarse fraction 7.

 As the experience of sieve classification of mica suspension shows, the flow of the suspension, getting onto the grid, is distributed approximately proportionally to the content of coarse and fine fractions in the initial suspension, and thus the suspension gradually accumulates over the grid, which then enters pocket 5 through the overflow threshold on the end wall 2 and returns into the container with the original suspension. Nozzles for supplying the initial suspension are installed above the overflow level so that the suspension is supplied to the open part of the screening surface (above the level of the suspension).

 These measures allow us to ensure high efficiency in the classification of materials with high hiding power (for example, mica), since with a high pressure of feeding the suspension through the nozzles to the screening surface of the particle in the flowing stream it is oriented along it, contributing to better passage through the grid. In addition, the unclassified suspension that accumulates inside the drum enters through a overflow into a special pocket and returns to the container with the original product without mixing with a large fraction (as will inevitably occur with such a suspension in the prototype).

 The location of the supply nozzles above the overflow pocket makes it possible to classify the material on a clean grid, free suspension. (56) Handbook of ore dressing. -M. : T. 1, Nedra, 1972.

 Copyright certificate N 967588, cl. B 07 B 1/08.

 Copyright certificate N 1518027, cl. B 07 B 1/22.

 Copyright certificate N 1447626, cl. B 07 B 1/22.

Claims (2)

 1. Drum screen for wet screening, including a horizontally rotatable drum with a cylindrical screening surface and with end walls forming an overflow threshold, the capacity of the initial suspension, a supply line with nozzles located above the overflow threshold, flush nozzles mounted under the drum surface, coarse fraction removal heat located inside the drum under the flushing nozzles, characterized in that, in order to increase the efficiency of classification of plate materials On the other hand, the screen is equipped with an overflow pocket located under the overflow threshold and communicated with the capacity of the initial suspension, and the nozzles of the supply line are perpendicular to the screening surface with the possibility of feeding material over the overflow threshold.  2. The screen according to claim 1, characterized in that the drum is mounted cantilever on the shaft by means of a blind end wall, and the supply line, estrus of a large fraction outlet and an overflow pocket are located at the opposite end.