HU185439B - Device for separating dispersed materials of same phase in flowing medium - Google Patents

Abstract

A gravitational-counterflow separating apparatus in which a particulate mass is separated into fractions in a counter-flowing fluid seperating medium is formed of a number of interconnected hollow units 1 arranged one above the other. Each unit has an inlet opening a at one end and an outlet opening b at the other end for the separating medium and has at least one maximum cross sectional area c between the inlet opening a and the outlet opening b to provide an expanding space adjacent the inlet opening a and a contracting space adjacent the outlet opening b. The units are either directly connected to one another with the outlet opening b of one unit adjoining the inlet opening a of the next unit above, or they are interconnected through distance pieces. <IMAGE>

Description

The present invention relates to an apparatus for separating dispersed materials of the same phase in a flowable medium (for example, for separating solid particles in a countercurrent gaseous medium).

It is a common task in the mining, chemical and allied industries to separate a set of particles of the same phase but of different character (for example, a set of solid particles) based on the single property of the particles.

Among the various methods and devices of separation which are known in the literature and practice, the so-called vertical crankshaft. gravity-countercurrent decomposers (devices in which a fluid flowing against a subset that falls in gravity, entrains a fraction of the particles, the other flows downstream of the fluid, and a portion floats in the stream; the behavior of the particles is determined by the forces acting on them ) are the most common. At present, these devices, which operate on the principle of gravity, operate with the least amount of energy, since they do not need to move unnecessary masses (eg screen frame, drum).

However, they have the disadvantage of having large, especially vertical, space requirements, which are well characterized by the low specific load (kg feedstock to be separated / 'm ³ fluid flowing), which essentially determines the sharpness of the separation.

In the literature, Engel: Untersuchungen torr Tragfahig-Keit hoer Luft bei hoar Windsiehtung. - Diss. TH Aachen. (1957), for example, when using quartz sand and air, the maximum specific load is 1.5 kg / m ³ but its optimum is 1.0 kg / m ³ .

According to other measurements, the optimum load of the Chisel, vertical rectangular cross-section equipment is 0.5 kg / ³ .

The most effective of the widespread multi-stage equipment is the so-called. The specific load capacity of zigzag classifiers is also in the range of 0.5-1.5 kg / m ³ .

Lauer: Labor-Windsichter. Aufbereitungs Technik. 1. Teil 70 (1976/5, 224-231; 2. Teil (1976) 10, 620-525).

The specific load increase is limited by the fact that at a certain load, which is different for each material and material state, the separated particles will clump together. As a result, the particle distribution in space and time changes near the boundary load, and therefore part of the phase to be graded leaves the equipment unchanged.

It is an object of the present invention to provide a device in which re-adherence of the particles of the separable set is prevented or the particles that are clumped together during the screening are again disintegrated into particles, thereby significantly increasing the specific load and thereby reducing the size of the device.

The object of the present invention is to provide a device comprising units formed of interconnecting expanding and narrowing spaces (narrowing - Animals), which create swirls in the separating medium entering the expanding space through the entire length of the device, which prevents the separation of new clumping and clumping are broken down into particles due to centrifugal force due to spinning motion and collision or rubbing of the particles.

The device, which is made out of several expanding-narrow seating extensions (units), allows on the one hand to disperse unit-forming material at unit entry into the upward-flowing gaseous medium, and on the other to separate fractions one by one, Depending on the shape and number of the particles, a very small number of characteristic parameters, such as solid particles, having substantially the same geometric size, can be separated off.

The units of the device according to the invention, the loose / seat-shrink joints, are hollow bodies which are preferably formed of rotational and / or planar surfaces with at least two openings (for inlet and outlet of material), between which the hollow body has at least one maximum cross-section. The expanding-tapering extensions can be joined together along the openings or with an intermediate piece, but they can also be joined together seamlessly or in one piece with a continuous surface. The extensions may also have other auxiliary portions, such as secondary material inlets and outlets, but may be provided with a double wall or other hollow wall for heat transfer or heat removal. The expanding-narrowing extension may be formed from frustoconical or truncated pyramidal shells with apertures of circular or parallelogram section.

Units formed from expanding-narrowing extensions may be placed side by side, for example, each extending-narrowing extension may have a common wall for better utilization.

The function of the device according to the invention can be compared to that of a superimposed sieve system in that each constriction where the separation medium is accelerated corresponds to a sieve, the function of the silencer apertures being essentially taken over by the velocity of the flowing medium; increasing speeds are associated with increasingly narrow screen aperture sizes. It should be noted, however, that the design of the sieve system, exact hole size requires a demanding and expensive job, expensive operation due to repeated acceleration of the masses, high maintenance requirements due to moving mechanisms and significant wear. In contrast, the manufacture of the present invention does not require any special expertise and special construction materials, the moving parts are free of glaze, are subject to much less wear, and are consequently inexpensive to manufacture, operate and maintain.

Some embodiments of the invention are exemplified in Figures 1-5.

Figure 1 is a sectional view of the apparatus

-2185 439 the addition! and showing the points of collection and marking the material flow and the medium flow.

Figure 2 illustrates an expanding-narrow seating extension of the apparatus with a plurality of possible profile sections and shapes.

Figure 3 is a partially sectional and partly sectional view of the apparatus with fractions suitable for fraction removal.

Figure 4 shows a schematic of some of the extensions of the apparatus. with feedback stubs (wires).

Fig. 5 is a side elevational view of the apparatus in which the extensions are joined by interlocking pieces.

In Fig. 1, the expanding / narrowing extensions 1 are superimposed. The separable medium 6 entering through the fluid inlet 2 falls under the influence of the gravitational field. The medium inlet 3 enters the separating medium 9, which runs countercurrently to the material 6. The separating medium 9 captures particles of the fine fraction 8 of the mixture while hiding the particles forming the coarse fraction 7. The fine fraction 8 leaves the apparatus through the outlet 4 with the separation medium 9. The coarse fraction 7 leaves the apparatus through the outlet 6.

The upwardly separating medium 9 also partially entrains coarse fractions 7 which, however, precipitate in the expanding-shrinking extensions 1 and fall down. Likewise, the coarse fraction 7 also contains fine particles 8 which separate in the expanding / shrinking Tokyates 1 and exit with the separating medium 9 upwards.

The extensions beneath the inlet 2 form the exit of the unit, while the extensions above form the enrichment section of the unit. In the expanding-narrowing extensions, a distinction can be made between the inlet openings a and the inlet openings b and the maximum cross-section c of the hollow extension.

in the case of assembled, directly connected extensions, the openings a and b have the same cross-section and shape.

Fig. 2 shows some typical sections of an expanding-narrowing extension 1, such as the inlet a, the outlet b and the maximum cross-section c. As can be seen from the figure, the related sections can be in straight or curved areas in different variations, some of which are shown in the drawing.

In the embodiment shown in Fig. 3, fractions can be separated from each expanding-narrowing extension 1. Thus, for example, the leading stump at fractional 5 'leaves the coarse fraction 7', but may also leave the floating fraction of the set 6 to be separated.

The embodiment shown in Fig. 4 allows separation into increasingly fine fractions, since the fine fraction 8 leaving the lower expanding / shrinking extension 1 may also contain particles which should have been separated by this extension; the recirculation of part of the material stream allows this separation. Thus, for example, the coarse fraction 7 'may be traced back to the extension 1 via the lower position 5' at the higher position 5 '.

For example, in the embodiment shown in Fig. 5, both the inlet opening <and the maximum cross-sectional dimension c of the expansion narrowing extensions 1 are monotonically increasing, and consequently the velocity of the upstream separating medium 9 decreases in the corresponding cross-sections. Thus, according to each speed step, the separation separates different qualities for each expanding taper extension. In the embodiment shown in the figure, the fluid inlet a and the fluid inlet b are clearly distinguished due to the inserts 10 used.

The series of experiments carried out with the apparatus according to the invention has proved that it can be operated with a significantly higher specific load of 1-4 kg / m ³ and the most favorable load is in the range of 2-3 kg / m ^{3 with} the sharp separation optimum.

In addition to these advantages, the equipment is very advantageous because of its simple design and therefore low investment, operating and maintenance costs.

It is particularly effective in the following processes:

i. separating a solid by means of a fluid (gas or liquid);

7. The process of the preceding claim, further comprising heating or cooling the material to be wound (roasting, deep-freezing);

3. The process of claim 1, wherein the solid particles influence the chemical reaction between the components of the fluid stream (e.g., catalytic reactions). The parameters of this process may also be affected by heat transfer in the case of a double jacket of the sides of the apparatus;

4. a variant of the one-point process in which the solid particles are precipitated from the fluid phase, for example by crystallization);

5. A variant of the one-step process, wherein a material transfer process is performed between the solid phase and the fluid.

Claims (5)

Patent claims ;. Apparatus for separating dispersed materials of the same phase in a fluid medium, comprising at least two expandable-shrinkable extensions (1) having a hollow configuration, the extensions having at least one fluid inlet (a) and at least one fluid outlet (b) the cavity having at least one cross-sectional maximum (c) and the expanding-narrowing extensions (1) being directly connected to their fluid inlet (a) and fluid outlet (b) openings and to the connecting pieces (10) connecting them. 2. That !. An embodiment of the apparatus according to claim 1, characterized in that each expandable extension (I) has stubs for obtaining separate fractions (5 ') and recirculating (2'), optionally having a material flow connection. An embodiment of the device according to claim 1 or 2, characterized in that the lead-in 3 -3-85 439 (a) and drainage openings (b) and their respective cross-sectional maxima have different surfaces per extension (l) or within. An embodiment of the device according to any one of claims 1 to 3, characterized in that the wall of the tapering taper extensions (1) has other hollows and / or ribs for transferring heat. 5. A device according to any one of the preceding claims, characterized in that it is an expandable one 5 s> the protruding extension (i) has a common wall. 5 pieces of figure