DE2047534B2 - Method and device for preventing agglomeration during the separation of fine-grained particles in a rotary flow vortex - Google Patents

Description

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The invention relates to a method for preventing agglomeration during the deposition of fine-grained particles in a rotary flow vortex and a rotary flow vortex for implementation this procedure. The rotating flow vortex consists of a cylindrical vortex chamber with a coaxial inlet pipe for the raw gas and an opposite axial clean gas outlet as well as with tangential, the inflowing raw gas diagonally opposite auxiliary gas inlets in the Vortex chamber jacket and has an outlet gap surrounding the inflow pipe for separated Particles.

Rotary flow vortices of this type are, for example, from DT-PS 1092 281 and DT-PS 220 240 known. The in such rotary flow vortices through the flowing in via the auxiliary gas inlets Rotary flow generated by auxiliary gas consists of an outer helical circulating flow and an inner helical, rotating in the same direction Rotational vortex flow together, the axial flow components of the rotational and direction of the potential vortex. The particles to be deposited are from the inner rotational flow in the direction of the vortex chamber jacket carried outwards and through an outlet gap surrounding the axial inflow pipe.

With such a rotating flow vortex !! and also With other mechanical dust extractors, the separation usually results in an agglomeration of the particles to be separated fine-grained particles, which in itself has a positive effect on the separation efficiency. That applies in particular to rotary flow vortices, which are particularly suitable for separating particles below 5 μ

In process engineering in the chemical industry, however, it is often important that the Particles are deposited safely, but not their size or shape during this deposition change, d. In these cases there are signs of agglomeration extremely undesirable.

The invention is therefore based on the object of creating a method with which such agglomerations can largely be prevented without affecting the degree of separation of the dust extractor and the structure of the particles is changed.

To solve this problem, the invention provides that in a method of the initially described type together with the auxiliary gas and / or the raw gas a powdery liquid or gaseous agglomeration-preventing medium introduced into the vortex chamber and with the to be separated Particles is brought into intimate contact.

The medium sprayed into the vortex chamber is deposited in the rotating flow due to the effect of the occurring forces on the particles and is created so that they stick together the particles safely prevented. Finely dispersed silicon compounds, Coal dust or liquids or gases, such as anti-wetting agents or anti-static agents blown or sprayed into the swirl chamber or sucked in with an injector effect will.

In the case of a rotary flow vortex to carry out this method, the auxiliary gas inlets are connected and / or the raw gas inflow pipe supply lines with devices for supplying the agglomeration-preventing Media connected.

A corresponding rotary flow vortex is described using a schematic drawing, on which the method according to the invention is explained in more detail.

The vortex chamber 1 of the rotary flow vortex; has at its lower end a coaxial inflow pipe 4 for the raw gas 20 with an axial flow body 5 and guide vanes 6 for distributing swirl for the raw gas in the vicinity of the mouth of the inflow pipeS. The axial clean gas outlet 7 is located on the opposite side. Auxiliary inlets 2 which are tangential to the vortex chamber mamel and the inflowing raw gas also open into the vortex chamber 1 in the upper area. The auxiliary medium, which flows in through the obliquely tangential inlets 2, stimulates and maintains a helically downward circulating flow 8 in the area of the vortex chamber 1 close to the wall. Due to the effect of the raw gas inlet 4, this circulating flow 8 merges via a vortex sink 10 into the likewise helically running rotational flow 9 . The central rotational vortex flow 9 then leaves the vortex chamber 1 through the outlet 7 as clean gas 11.

The supplied through the coaxial inflow pipe 4

Raw gas 20 is set in rotation by the flow course prevailing in the vortex chamber 1, in the eddy source that forms above the raw gas inlet 4, the Particles due to the effect of centrifugal forces and the drag forces that are directed in the same direction discharged to the vortex chamber jacket. The discharged particles are then directed from the downward Potential vortex flow 8 is detected and with a branch 12 of this circulating flow through the of a Bunkcrblende 14 and the vortex chamber wall 1 formed outlet gap 13 in a not closer shown bunker or a conveyor line.

According to the invention, an agglomeration should now occur within the vortex chamber during the deposition the particles are reduced. For this purpose, delivery lines 15 are connected to the inlets 2 for the auxiliary gas, by means of a fan or an injection pump 16 from a storage container 17 the agglomeration preventing media are introduced into the vortex chamber. However, it is too possible to suck in these media with the secondary air fan like an injector and without a pump or Introduce auxiliary fan into the vortex chamber. Fer-

ner can the delivery lines 15 in the auxiliary inlets2 built-in injection nozzles 20 end, whereby the auxiliary gas exerts an injector effect and thus the pump 16 can also be dispensed with. By the prevailing in the rotary flow vortex Forces attach these media to the particles to be separated, so that an agglomeration is safely prevented.

But it is also possible to use the agglomeration-preventing medium together with the raw gas stream

is to be supplied. For this purpose it opens axially at the inflow pipe 4 below the guide body 5 a delivery line 18, via which - as described above - the Media can be fed. But it is also possible to use these media both via the inlets 2 as

also to be supplied via the inflow pipe 4 at the same time.

1 sheet of drawings

Claims (2)

Patent claims: 1. Method of preventing agglomeration in the separation of fine-grained particles in a rotary flow vortex, which consists of a cylindrical vortex chamber with a coaxial inflow pipe for the raw gas and the opposite axial clean gas outlet as well as with tangential, the inflowing raw gas obliquely opposite auxiliary gas inlets in the swirl chamber jacket consists and has an outlet gap surrounding the inlet pipe for separated particles, characterized in that that together with the auxiliary gas and / or the raw gas a dusty, liquid or gaseous, agglomeration-preventing medium introduced into the vortex chamber and with the particles to be deposited are brought into intimate contact. 2. rotary flow vortex for performing the method according to claim 1, which consists of a cylindrical vortex chamber with a coaxial inlet pipe for the raw gas and the opposite Clean gas outlet as well as with tangential, the inflowing raw gas diagonally opposite There is auxiliary gas inlets in the swirl chamber jacket and one surrounding the inflow pipe Has outlet gap for separated particles, characterized in that to the Auxiliary gas inlets (2) and / or the raw gas inflow pipe (4) with feed lines (15, 18) Devices (16; 19; 20) for supplying the agglomeration-preventing media are connected are.