DE936741C - Method for classifying fine-grained magnetized particles - Google Patents

Description

Method for Classifying Fine Grain Magnetized Particles Die The invention relates to a method for classifying fine-grained, magnetized Particles, especially of magnetite. Classified magnetite is used inter alia. in Ore and coal washes, where separations are carried out with the help of a magnetite suspension will. The size of the magnetite particles in such suspensions must, in view on the required stability and viscosity of the suspension, within certain Boundaries lie, z; B. between 5 and zoo microns.

Fine-grained material is usually made by in a closed circuit, which, among other things, comprises a classifier, a coarse-grained one Base product ground wet. The particles that are too coarse after grinding are then separated in the classifying device and returned to the grinding plant.

For magnetite which is magnetized in general and similarly magnetized However, the above-mentioned method is not suitable because the finely ground Magnetite particles agglomerate and are therefore difficult to classify.

The ground magnetite is therefore in practice subjected to a demagnetization process before being classified. However, it has not yet been possible to carry out the demagnetization so completely that fine magnetite can be properly classified in a conventional classifying device. A satisfactory solution to the problem in question . is therefore not yet available. The same naturally also applies to other magnetized materials.

It has now been found, however, that a good classification has the effect when one has fine, magnetized particles suspended in a liquid continuously and under pressure a hydrocyclone or a vortex chamber, which the "Purpose _ have appropriate dimensions. A demagnetization is not necessary. In this description, the term hydrocyclone is a vessel closed understand its limitation of a closed and on the inside smooth surface of revolution and that in the vicinity of one end with a tangential supply line or with a number of equally directed tangential feed lines and with one central discharge opening is provided while in the other opposite At the end there is another discharge opening, at the top if the Hydrocyclone mainly conical, or on the periphery if the hydrocyclone is mainly cylindrical in shape. The supply line opens into the most spacious Part of the hydrocyclone which is preferably cylindrical. The central discharge opening, which is provided at the end located near the supply line preferably provided with an axially arranged pipe reaching into the cyclone.

A vortex chamber is to be understood as a vessel, its limitation. a closed surface of revolution that is smooth on the inside. corresponds to and that near one end with a tangential line or with a number is provided by similarly directed tangential feed lines, while in the other opposite end is a central discharge opening and in or in the vicinity of this end a further discharge opening or in the vicinity of the or is provided in the periphery. -The shape and dimensions of hydrocyclones and Vortex chambers determine the results of the processing carried out in the same, and it is therefore necessary to adapt the shape and dimensions to the type of treatment. In the following exemplary embodiment, suitable dimensions are given; other dimensions but are also possible.

When you get a liquid a hydrocyclone or a vortex chamber supplies continuously and under pressure, a flow occurs in them, wherein the liquid rotates around the axis of the hydrocyclone or vortex chamber; namely with a vortex velocity which is higher in the vicinity of the axis than on the periphery. The thrust forces thus excited prevent magnetization Particles agglomerate and disperse previously agglomerated particles. If the Hydrocyclone and the swirl chamber also have suitable dimensions for this the supplied mixture of magnetized particles can also be classified therein.

It should be noted that the use of hydrocyclones and vortex chambers is already known for classification in general; it is also known that the angular velocity near the axis of a hydrocyclone and a vortex comb is larger than at the periphery.

The operation of the present invention, however, has not been heretofore suggested although it provides a simple solution to a problem with which Solution one has been busy in the ore and coal washers for years.

In the figures (Fig. I Scheme of the plant, Fig. 2 cyclone), in which the invention is explained in more detail, represents a: coarse magnetite suspended in water which is fed to the ball mill 2 through the channel i. The ground product is collected in the collecting container 3 and then flows through the suction line q. to pump 5, which pumps the mixture through line 6 to hydrocyclone 7. The latter consists of a cylindrical part 8 and an adjoining conical part Part 9 together. The line 6 opens tangentially into the cylindrical part B. This is closed by a plate io, which in turn is penetrated by a tube ii will. The centrally and axially arranged tube i i extends into the most spacious Part of the hydro, cyclone into it.

The discharge opening i2 is located at the narrow end of the conical part 9. The fine particles leave the hydrocyclone through pipe ii, so that a suspension of fine magnetite is discharged at b. The coarse particles leave the hydrocyclone through the tip opening 12 and return to the ball mill 2 via the channel i. example The hydrocyclone for classifying magnetite had the following dimensions: Diameter of the cylindrical part 8 3.5o mm Height of the cylindrical part: 8 ....... 14o mm Point angle of the conical part 9. . 6o ° Diameter of the supply line 6. . . . . . . . . 70 mm Diameter of the discharge pipe ii. .. .. i5o mm Length of the discharge pipe ii within the Hydrocyclones. . . . . . . . ...... 70 mm Diameter of the discharge opening 12 ... 8o mm The feed pressure was 0.5 atm. Under these conditions the output of the hydrocyclone was 60 m3 per hour.

The supply to the ball mill amounted to 300 kg of fresh magnetite per hour, of which 50 o / o was coarser than 25o microns, and further to 1200 kg of recirculated magnetite per hour (= coarse fraction from the hydrocyclone). The fine fraction b from the hydrocyclone contained 0.6% material that was coarser than 60 microns. The amount of magnetite in fraction b, which was smaller than 5 microns, could not be determined because the magnetite clumped; however, this amount was relatively small as a result of the low viscosity of the suspension produced.

Claims (1)

PATENT CLAIM: Method for classifying fine-grain magnetized Particles, characterized in that those suspended in a liquid are magnetized Particles continuously and under pressure in a hydrocyclone or a vortex chamber, which have the appropriate dimensions for the purpose, are supplied. Dressed Publications: Austrian Patent No. 16q.583.