FI69407C - ANORDING FOR THE SEPARATION OF THE TV SINSEMELLAN ICKE BLANDBARA VAETSKEFASER MED OLIKA TAETHET - Google Patents

Description

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Patent No. 10 CC 103C

(51) Kv.lk. * / Lnt.CI. 'B 01 D 17/025 FINLAND — FINLAND (21) Patent application - Patentansöknlng 793 ^ 2 ^ (22) Application date - Ansökningsdag 01 .11.79 (F ») (23) Starting date - Giltighetsdag 01.11 .79 (41) Has become public - Blivit offentlig 1 8.05-80

National Board of Patents and Registration Date of publication and publication - 3i.IO.85

Patent and registration authorities Ansökan utlagd och utl.skriften publicerad (32) (33) (31) Privilege claimed - Begärd priority 17-11.78 France-France (FR) 7832 * t7 ** (71) Sofrance SA, 8, Cours Bugeaud, 87 Limoges, France-France (FR) (72) Roger Tardy, Nexon, France-France (FR) (7 * 0 Oy Koister Ab (5 * 0 Apparatus for separating two liquid mixtures which are immiscible and have different densities - Anordning för separation av tva sinsemellan icke blandbara vätskefaser med oi ikä täthet

The invention relates to an apparatus for separating two immiscible phases of different densities contained in a liquid to be treated, the apparatus comprising a decantation chamber having two opposite walls and provided with two successive inner deflectors, one deflector being connected obliquely to the other wall and the other deflector obliquely connected to a second wall, and which chamber is provided with an inlet for the supply of the liquid to be treated, the supply direction being oblique to said deflectors.

This type of separation device is described in U.S. Patent No. 1,920,468.

DE-A-2 330 405 describes a device in which the feed does not take place between the sloping plates but directly into the decantation chamber. For this reason, the phases to be separated do not move in a different direction as soon as they enter the separation device, as in the device according to the invention- _ - L · .. _____ 2 69407 sa. The difference is therefore better in the device according to the invention.

DE-A-2 706 642 relates to a device in which the inlet is in the vicinity of the bottom of a parallel, oblique plate vessel, while in the device according to the invention the inlet takes place in a decantation chamber consisting only of two oblique deflectors at the inlet. after entering the decantation chamber, which does not happen in the device according to DE patent publication 2 330 405.

The separation device according to the invention is particularly suitable for separating hydrocarbons from waste water, for example industrial waste water or ballast water, which meets the requirements of O.M.C.I.'s decision A 393 of 14 November 1977, according to which the concentration of hydrocarbons in machine and tank effluent must not exceed 100 ppm.

The device according to the invention, based on natural decantation due to different densities, is characterized in that the inlet is located opposite the lower deflector 6, the opposite walls 12, 13 and the deflectors 5, 6 together forming a passage 7 with a lower outlet 15 and an upper outlet 14. whereby the inlet opening 8 opens into the passage 7.

It is recommended that the deflectors each rest on opposite walls of the chamber, respectively, and together with them form a separator.

According to another preferred feature of the invention, the upper edge of the lower deflector is practically at the same level as the lower edge of the upper deflector.

Embodiments of the invention are described below. Other features of the separating device according to the invention will become apparent from the description and drawings.

Drawings: Figure 1 is a basic diagram of a separation device according to the invention, Figure 2 is a vertical section of an embodiment of a separation device according to the invention, Figure 3 is a horizontal section of the separation device shown in Figure 2 in plane III-III of Figure 2, and Figure 4 is a perspective view of the separation device of Figure 2.

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The separation device schematically shown in Figure 1 consists of a shell 1 inside which has an inlet chamber 2, a transfer chamber 3 and an outlet chamber 4.

The inlet chamber 2 is provided with two deflectors 5 and 6, which mutually delimit a space 7 into which an inlet opening 8 opens, through which the liquid to be treated is fed to the separation device.

The deflectors are walls inclined in opposite directions to the direction of fluid supply, forming sharp opposite angles a and b with this supply direction 9 (assumed to be horizontal here), which are equal or different and preferably between 45 and 20 °, more preferably between 35 and 25 °. °, with an optimal angle size of about 30 °.

The lower edge 10 of the upper deflector 5 is preferably approximately flush with the upper edge 11 of the lower deflector 6 and the feed opening 8 is located just below the lower edge 10.

The liquid to be treated is, for example, ballast water (heavy phase) containing hydrocarbons (light phase), which must be separated to such an extent that the concentration of hydrocarbons in the water drops to an acceptable level before the water is discharged into the sea.

Most of the separation takes place by decantation in the inlet chamber 2 due to the barrier plates.

The deflectors 5 and 6 and the chamber walls 12 and 13, to which they are respectively attached, form a diverting device with diverting walls, through the upper discharge sector 14 the separated light phase towards the top of the chamber and through the lower discharge sector 15 the heavy phase still emulsified light phase to the bottom of the chamber. The light phase accumulating at the top of the chamber 2 can be removed by any suitable means (indicated by arrow 16), while the heavy phase (represented by the arrow 17) is directed to the transfer chamber 3.

The chamber 3, located below the inlet chamber, is provided with devices to facilitate the aggregation of the light phase still contained in the heavy phase, which may consist, for example, of a flange system 18 alone, with the flange axes horizontal but the flanges themselves either horizontal or inclined (transverse). These flanges are very close to each other, for example less than 10 mm apart, but still far enough away for the liquid to flow properly. It should be noted that a distance of 7 mm is suitable at a flow rate of 500 1 / h.

The purpose of the flanges is to multiply the liquid contact surface and reduce the decantation distance of the light phase droplets. These rise naturally, standing against the surface of the flange just above. Drops of the light phase accumulate on the surface of the flange and when the accumulation has continued long enough, at the end of the flange, the light phase is released as large droplets which are easily decanted in the removal phase.

The discharge chamber 4 has a light phase outlet 19 at the top and a heavy phase outlet 20 at the bottom; it is recommended to place a barrier plate 21 between the accumulation chamber 3 and the outlet opening 20, which prevents the liquid from leaving directly from the flanges and deflects the horizontal flow so as to facilitate decantation.

Figure 1 is only a diagram illustrating the principle of operation, in which the device is assumed to be faceted and the chambers to be rectangular.

Figures 2 to 4 show a cylindrical device according to the invention with its features.

The device consists of two cylindrical vertical walls 22 and 23 which define an annular space with each other.

The inlet 26 of the liquid to be treated opens into the upper part of this space below the flange 24 resting on the cylindrical outer wall 22 just in front of the flange 25 resting on the cylindrical inner wall 23. These disc-shaped flanges of the truncated cone jacket (see Figure 4) function like the deflectors 5 and 6 of Figure 1.

The heavy phase descends to the lower part of the annular space along the partition 27 and travels horizontally towards the other side of this wall, bypassing a series of horizontal semicircular flanges which act like flanges 18 in the device of Figure 1. When the liquid arrives on the other side of the partition 27, it passes into a pipe 29 which opens to the lower part of the annular space. This flow of liquid from one side of the partition 27 to the other is illustrated by the curved line 30 in Figure 3.

The tubes 29 lead to a space 31 delimited by an inner wall 23, from which the heavy phase leaves the outlet 32 at the lower end, while the light phase leaves the outlet 33 at the top. The space 31 forms an outlet chamber.

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In addition, the light phase separated by the flanges 24 and 25 is discharged through an outlet 34 at the top of the annular space.

The light phase outlets 33 and 34 can be controlled by valves 35 and 36 controlled by level detectors 37 and 38.

Figure 4 shows only the walls 22 and 23, the flanges 24 and 25, part of the flanges 28, a vertical partition 27 and a second vertical partition 39 into which the flanges starting from the partition 27 end.

It should be noted that the collection chamber is very simple in construction and does not have the inconvenience of cartridge collection devices. This is possible because only the mixture containing the hydrocarbon residues has to be treated in the collection chamber, since most of the hydrocarbons have separated and in the decantation chamber.

For example, when an aqueous mixture containing 25% by weight of hydrocarbons is fed to the inlet of the device according to the invention, a heavy phase (water) containing less than 50 ppm of hydrocarbons (by weight) is separated by the device.

If this mixture had been led directly into the collection chamber, the operation of the chamber would be blocked.

Claims (15)

1. S 4 O 7 A device for separating two phases of different densities in a liquid to be treated, the device comprising a decantation chamber having two opposite walls and provided with two successive inner deflectors, one deflector being connected obliquely to the other wall and the other deflector connecting obliquely to the second wall, and which chamber is provided with an inlet for supplying the liquid to be treated, the feed direction being oblique to said deflectors, characterized in that the inlet is opposite the lower deflector (6) with opposite walls (12, 13) and deflectors ( 5, 6) together form a passageway (7) with a lower exit (15) and an upper exit (14), whereby the inlet opening (8) opens into the passageway (7). Device according to Claim 1, characterized in that the upper edge (11) of the lower deflector (6) is substantially flush with the lower edge (10) of the upper deflector (5). Device according to Claim 1, characterized in that the deflectors (5, 6) are inclined walls opposite to the liquid supply direction (9) and form sharp angles (a, b) equal to or different from the supply direction. Device according to Claim 3, characterized in that the acute angles (a, b) are in the range from 45 to 20 °. Device according to Claim 3, characterized in that the acute angles (a, b) are in the range from 35 to 25 °. Device according to Claim 3, characterized in that the acute angles (a, b) are each approximately 30 °. Device according to Claim 1, characterized in that the deflectors (5, 6) are substantially planar. Device according to Claim 1, characterized in that the deflectors are partitions (24, 25) of the truncated cone jacket. Device according to Claims 2 to 4, characterized in that the inlet opening (8) is arranged just below the lower edge (10) of the upper deflector (5). Device according to Claim 7 or 8, characterized in that the inlet opening (8, 26) is arranged just below the upper deflector (5, 24). Device according to one of Claims 1 to 3, characterized in that it comprises a collection chamber (3) which receives the heavy phase from the decantation chamber (2) and which contains collection means which provide the following with the heavy phase. light phase aggregation. Device according to claim 11, characterized in that the collecting means comprise a plurality of parallel plates (18) extending along a horizontal axis. Device according to claim 11, characterized in that the collecting means comprise a plurality of disc-shaped plates (28) arranged one above the other. Device according to claim 11, characterized in that it comprises an outlet chamber (4) which receives liquid from the collection chamber (3). Device according to claims 8, 13 and 14, characterized in that it comprises a space (31) bounded by a first vertical cylindrical wall (23) and a second vertical cylindrical wall (22) surrounding the first vertical cylindrical wall (23) forming an annular space (27) therebetween, the upper part of the annular space (27) being provided with an inlet (26) for supplying the liquid to be treated and two additional deflectors (24, 25), the upper part forming a decantation chamber, and the annular space (27) ) the lower part is provided with collecting means (28), the lower part forming a collecting chamber, and being provided with a pipe connecting from the lower part to the space (31), this space forming an outlet chamber. 69407