FI71500B - FOERFARANDE OCH ANORDNING FOER MATERIALSEPARERING MEDELST CENTRIFUGALKRAFT - Google Patents

Description

Ιν§ ** · 1 Γ Ί NOTICE 71 13 UTLÄGGN, NGSSKR, FT Μί) υυ (45) p -f? .- '':; : .l 1JP7 (51) Kv.lk. * / lnt.Cl. 'B 01 D ^ 5/12 FINLAND - FINLAND (21) Application for a patent - Patentansökning 792228 (22) Application date - Ansökningsdag 16.07-79 (23) Start date - Giltighetsdag 16.07.79 (41) Became iulkinen - Blivit offentlig 22.01.80

National Board of Patents and Registration .... „, ΜΛ. ......., „Λ.

* (44) Date of issue and date of issue. - 10 10 86

Patent and registration authorities in the field of public and private use (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed — Begärd priority 21.07-78

Germany 1i i tt Republic - Förbundsrepubliken Tyskland (DE) P 2832097.0 Proof samples ty-Styrkt (71) (72) Ernst-August Bielefeldt, Kieferngrund 20, Hollenstedt,

Federal Republic of Germany Förbundsrepubliken Tyskland (DE) (7 ^ 0 Oy Kolster Ab (5 ^) Method and apparatus for centrifugal separation of matter - Förfarande och anordning för materialseparering medelst centrifugal kraft

The invention relates to a method and apparatus for separating a heavier part of a suspended particle stream from a stream of suspended particles by centrifugal force, in which the vortex chamber is first guided curved and then in direct contact with the inner curvature region from the protruding immersion tube and removal of particles through openings arranged in the vortex chamber wall. Ao. the method is described and disclosed in DE-PS 2160415. In this method, the separated particles are discharged tangentially with the partial volume flow of the medium leaving the vortex chamber. Especially when the particles separated by such a device have to be collected, it is necessary to connect a direct separator.

2 71500 Accordingly, it is an object of the invention to provide a method and apparatus as mentioned above, in which the separated particles enter the collection tank directly from the vortex chamber without the aid of a flow. The method according to the invention is characterized in that the supplied medium flow (raw gas flow Qro) causes a constant circulating flow into the circulating channel surrounding the vortex chamber so that only part of the fed raw gas flow is absorbed through the immersion pipes. circulates and thereby increases the concentration of heavy particles it receives from the raw gas stream, and as a result the particles exit directly into the tank through slots placed in the boundary walls of the vortex chamber housing. The device according to the invention is characterized by a cylindrical vortex chamber housing with a central vortex chamber around which a constant circulation channel of almost equal height is arranged, into which the inlet opening opens tangentially. -these and / or the vortex chamber are provided with outlets. The device according to the invention is furthermore usable as a centrifuge, hydro-separator, etc. Said device can advantageously be connected to a dust silo. Using as a standalone device also often makes a lot of sense.

Other special features of the invention will become apparent from the subclaims and the description of the drawing.

The invention will now be described in more detail by means of exemplary embodiments with reference to the accompanying drawing, in which Figure 1 shows a vertical section of a separation device according to the invention (section AA from Figure 2), Figure 2 shows section BB from Figure 1, Figure 3 shows section 1 from section 1 from Fig. 4), Fig. 4 shows a section CC from Fig. 3, Fig. 5 shows a variation of the separating device of Fig. 4, Fig. 6 shows a detail Y from Fig. 5 and Fig. 7 shows a variation of Figs.

The separation device shown in Figures 1 and 2 consists mainly of a vortex chamber 1, which in turn is formed by a curved wall 2 and two axial boundary walls 15. From the outside, two immersion tubes 8 protrude symmetrically and coaxially into this chamber. If, for example, a gas stream containing e.g. suspended particles is introduced as a raw gas stream Qro /, e.g. through the channel 12, then a very rapidly rotating vertical vortex is generated inside the rotary chamber 1. This vortex is shown by arrows 17 in Figure 1. The vortex induces a secondary flow inside the vortex chamber, indicated by arrows 18 in Figure 2. Due to the centrifugal forces acting inside the vortex, the particles entrained by the device move to the wall 2. At this point the secondary flow 18 grips and transports them. towards the axial boundary walls 15. Upon entering the area between the edges of the wall 2 and the axial boundary walls 15, the flow 18 is turned 90 °. The particles then exit through the slots 14 from the vortex chamber 1. They then move approximately tangentially to the flow 18 through the outlets 14. Upon entering the vortex chamber 1, the particles fall into the tank 7. The purified gas exits the vortex chamber as a clean gas stream Qre through the immersion pipes 8. It has been found that even the finest particles are separated when, in the path provided by the secondary flow 18, they are subjected to a vortex in the expanding helical lines and thus guaranteed to the wall 2, so that they cannot enter the suction of the mouths of the immersion tubes. There is thus a very efficient fine separation zone around the submersible pipes.

Figure 3 shows a vortex chamber 1 'located inside a curved wall 2' and surrounded there for the most part by a circulating hub 3. The cross-sectional channel 3 is formed in cross-section by an arcuate part 4 which is arranged in the radial direction approximately equidistant from the wall 2 and is the width of the chamber.

As shown in Fig. 4, the axial boundary walls of the circulation channel have outlet slots 5 through which a separable part of the medium is removed during operation of the vortex chamber when it enters the tank 7. Similar outlet slots 14 'can also be arranged in the axial boundary walls 15 of the vortex chamber 1'.

4 71500 In this modification, a rather technically favorable separation mechanism for the dispersed particles is created because only a partial volume flow is sucked out of the center Z, e.g. according to Fig. 4. This results in, for example, a longer residence time of the fine dust particles in the vortex chamber 1 ', so that these can be more easily transported outwards and out of the fine separation zone around the immersion tubes 8. The flow in the circulation channel 3 is enriched due to the continuous supply of raw gas Qro to such an extent, e.g. with dust particles, that the limit concentration is exceeded and the particles are therefore continuously and easily removed through the outlet slots 5. This considerably improves the qualitatively absorbed proportion of pure gas Q · re

It can be seen from Figure 5 that outlet slots 5 'and 14' of special shape have been used. This shape takes into account the fact that the particles are removed approximately along the tangents of the secondary flow. A secondary flow 9 is generated in the circulating duct 3. It is clear from Fig. 6 that with the stepped arrangement of the boundary walls one more outlet gap 6 can be provided.

Figure 7 shows a cross-section of a vortex chamber with a peeling slot 10. This slot is formed so as to peel off dust particles from the wall flow 11.

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Claims (6)

A method of separating the heavier portion by specific weight from a stream of a medium containing suspended particles by centrifugal force, the stream in a vortex chamber (1) being first guided and then following a vortex separation by a sustained vortex in immediate contact with the inner cup region and central mirror-like, axially outward discharge of the tili specific weight, the lighter portion through the orifices in the vortex chamber housing (2) and the particles are discharged through openings arranged in the vortex chamber wall, Causes a persistent circulation flow in the circulation channel (3) surrounding the vortex chamber (1) so that only a portion of the fed shrimp stream is sucked away through the immersion tubes and the non-suctioned portion forms a persistent vortex in the vortex chamber (1), thereby circulating the circulation flow thereby enriching with heavier particles from the shrimp stream o ch whereby the particles are directly effected in a container (7) through slots arranged in the boundary walls of the vortex chamber housing (2). 2. A method according to claim 1, characterized in that the circulation flow passes through at least one scaling slot (10), through which particles of the shrimp stream (Qro) are also separated. Device for carrying out the method according to claims 1 and 2, characterized by a cylindrical swirl chamber housing (2) comprising a central swirl chamber (1), around which is arranged a circulation channel (3) which unchanged, in which the inlet channel (12) opens tangentially, the downstream of the orifice of the inlet channel being provided a through-open aperture (13) between the circulation channel and the vortex chamber, at the height of the vortex chamber and the vortex chamber (s) of the vortex chamber and 5.6; 5 ', 6'; 14). 4. Device according to claim 3, characterized in that at least one peeling slot (10) is arranged in the radial boundary wall of the swirl chamber housing (2). Device according to claims 3 and / or 4, characterized in that a dust container (7) surrounds the swirl chamber housing (2).