NL2000649C2 - Method for concentrating microbiological organisms suspended in the liquid from a flowing liquid. - Google Patents

Abstract

The invention relates to a method for concentrating from a flowing liquid microbiological organisms suspended in the liquid, comprising the processing steps of : A) feeding the liquid with microbiological organisms suspended therein to a stationary cyclone (20), B) rotating the liquid with microbiological organisms suspended therein in a stationary housing of the cyclone, and.C) discharging at least two different fractions from the stationary cyclone; a first fraction having an increased concentration of suspended microbiological organisms relative to the supplied liquid and a second fraction having a decreased concentration of suspended microbiological organisms relative to the supplied liquid. The liquid is rotated in the stationary housing of the cyclone as a result of the presence of at least one guide element (43).

Description

Method for concentrating microbiological organisms suspended in the liquid from a flowing liquid

The invention relates to a method for concentrating microbiological organisms suspended in the liquid from a flowing liquid.

In the search for organic material as a raw material for, among other things, biofuel, but also other industrial applications such as use as food supplements, biological raw material for construction materials and so on, algae appear to have a number of advantageous properties. For example, there are algae species whose mass consists of up to 50% oil, while other beneficial substances such as colorants and the omega fatty acid EPA are also present in the algae, depending on the intended application. Another advantage is that the production capacity (the photosynthesis) in the production of algae can be particularly large. In practice, the production of algae per unit area appears to be 100 to 150 times more efficient than the cultivation of a number of agricultural crops such as, for example, maize and soy. The algae can also be used to purify waste water and CO2 from, for example, flue gases or fermentation waste gases can be bound. See for example the ECN report “Sustainable co-production of fine chemicals and energy from microalgae”, public final report E.E.T. project K99005 / 398510-1010 by J.H. Reith, April 2004. A disadvantage of the production of algae, however, is that as microbiological organisms they cannot easily be separated from the liquid in which they develop. Due to the generally very small dimensions of the microbiological organisms, separation is difficult and expensive. As possible separation techniques, reference is made to flotation, centrifugation, sand filtration and membrane technology. Chemical extraction is also recommended for the extraction of certain substances. All these separation techniques are only possible with high-quality application of the products to be separated. For relatively low-value application of the microbiological organisms (more particularly as a bio-fuel), these separation techniques are all too expensive and, moreover, they often do not even provide a positive (or only very limited advantageous) energy balance. For example, centrifugation is an energetically less favorable separation technique because centrifugation involves an energy-intensive operation.

2

The object of the present invention is to provide a more efficient method for concentrating microbiological organisms suspended in the liquid from a flowing liquid.

To this end, the invention provides a method for concentrating microbiological organisms suspended in the liquid from a flowing liquid, comprising the processing steps: A) supplying the liquid with microbiological organisms suspended therein to a stationary cyclone, B) feeding it into a stationary housing of rotating the cyclone of the liquid with microbiological organisms suspended therein, and C) discharging at least two different fractions from the stationary cyclone; a first fraction with a concentration of suspended microbiological organisms increased relative to the supplied liquid and a second fraction with a concentration of suspended microbiological organisms reduced relative to the supplied liquid. Due to the rotation of the liquid with microbiological organisms suspended therein in the stationary housing of the cyclone, a lighter fraction will migrate at least substantially to the inside of the cyclone and a heavier fraction will migrate to the outside of the cyclone. The heavier fraction and the lighter fraction are discharged from the cyclone at different positions.

20

A cyclone is a centrifugal separator in which a heavier fraction due to the larger mass is flung outwards by the centrifugal force. The different fractions usually leave the cyclone through different sides. One of the reasons why it is not obvious according to the prior art to separate microbiological organisms from a liquid by means of a cyclone is that microbiological organisms do not coagulate, or do not, at all. With coagulation, the merging of drips into a larger drop becomes. This property can be influenced by, for example, the composition of a mixture, the PH value, the presence of additives and so on. This means that a certain degree of separation in the cyclone does not lead to a stable separated situation, as is the case for example with oil / water separation, a separation technique in which the use of cyclones is popular. The non-coagulation of the microbiological organisms, in particular algae, will therefore immediately lead to mixing again with every small disturbance of a pure cyclone. This problem is all the more serious 3 if the differences in mass density between the liquid and the microbiological organisms are small, as is the case with a water / algae mixture. Here, the difference in mass density between the liquid and the microbiological organisms is typically less than 200,150,100, 50 or even 30 kg / m3. However, the present invention now provides the insight that despite the existing prejudices it is nevertheless possible to meaningfully concentrate microbiological organisms in a stationary cyclone. Concentration does not only mean complete separation but also pre-separation (increasing the concentration of microbiological organisms suspended in a liquid). First of all, a correct dimensioning of the vortex must be chosen, for example a diameter of less than 20 millimeters. The vortex must always develop a sufficient centrifugal force to concentrate the small non-coagulating microbiological organisms and, moreover, the flow pattern must be such that mixing is prevented. On the other hand, the insight is that a complete separation is not necessary, but that a substantial increase in the concentration of microbiological organisms in a first fraction of the liquid flow is also already very advantageous. A doubling of the concentration of, for example, a few hundred milligrams per liter already leads to a considerable increase in the efficiency of the total separation process, since the subsequent separation steps can now indeed be carried out more efficiently.

Of great importance in the concentration of microbiological organisms suspended in the liquid is that the flow pattern in the vortex is very stable; this of course to prevent the mixing occurring very quickly. Stabilization of the flow pattern can be obtained in addition to a suitable dimensioning, for example by using guide elements and / or stabilization elements in the vortex. It is important to keep the local Reynolds number as low as possible everywhere, so that preferably no (heavy) turbulent flow occurs in the vortex. For a further stabilization of the liquid flow in the cyclone, it is also advantageous if the liquid is supplied to the device from several sides.

All these measures contribute to the flow of the medium mixture to be supplied to the cyclone during processing step A) having a substantially stable flow pattern.

4

The separation space in the vortex usually has an elongated shape which has a circular inner side in cross-section (i.e. in a cross-section perpendicular to the longitudinal or longitudinal axis of the cyclone). The separation space may or may not be tapered and may optionally be provided with a core around which the mixture is set into rotation as a vortex. It is noted that the liquid in the stationary housing of the cyclone can also go through a completely helical flow path (the structure need not be tapered but it can also be cylindrical). The rotating flow can be generated by a helical structure.

10

The liquid is, preferably due to economic and environmental considerations, preferably formed by water. Depending on the circumstances, this can be either fresh, brackish or salt water.

In yet another preferred variant, (free and / or dissolved) gas is added to the flowing liquid such that gas bubbles are formed in the liquid. These gas bubbles are preferably in the liquid during rotation of the liquid in stationary housing of the cyclone. The (micro) bubbles ((micro) bubbles) thus present attach themselves to the microbiological organisms, whereby the difference in mass density of the fractions to be separated can be changed, as a result of which a simpler separation becomes possible. Incidentally, this effect can also be obtained (or be enhanced) by causing the liquid with microbiological organisms suspended therein to expand at the inlet to the stationary housing of the cyclone. The expansion can take place both during the supply or at any time that the liquid is already in the stationary housing. Favorable results are further obtained when the liquid at the feed expands over the feed openings, for example preferably such that microbubbles arise. This principle works especially if the medium mixture is super-saturated (super-saturated with gas) when entering the cyclone.

30

The liquid with microbiological organisms suspended therein in the stationary housing of the cyclone is preferably rotated due to the presence of at least one guide element. Thus, the efficiency of concentrating can be increased relative to that of a tangential cyclone.

5

With the method described, it is difficult or even impossible to obtain a complete separation of liquid and microbiological organisms. However, this is not an objection. After all, the concentration of suspended microbiological organisms of the first fraction discharged from the stationary cyclone according to processing step C) with a concentration of suspended microbiological organisms already increased relative to the supplied liquid can be further increased. For example, by effecting a subsequent separation step after pre-separation by means of one or more of the operations: centrifuging, pressing, further concentrating, decanting and / or drying.

In yet another variant of the method according to the present invention, a flocculant for the microbiological organisms is supplied to the flowing liquid with suspended microbiological organisms. Such a flocculant leads to the small microbiological organisms joining together to form larger complexes (flakes) that are easier to concentrate (or even separable from the liquid. The flocculant can have a chemical composition, but is preferably this is formed by a natural flocculant, such as, for example, Chitosan, although it is noted here that microbiological organisms can also merge, bind or clot by other phenomena.

The present invention will be further elucidated with reference to the non-limitative exemplary embodiments shown in the following figures. Herein: figure 1 shows a cut-away perspective view of a device for performing the method according to the invention, and figure 2 a cut-away perspective view of an alternative embodiment variant of a device for performing the method according to the invention.

Figure 1 shows a vortex 20 with a core 1 and a jacket 2 between which guide fins 3 are positioned. The liquid with suspended microbiological organisms (e.g. algae) is supplied substantially axially in accordance with arrow Pi and obtains a rotating tangential component through the guide fins 3; see arrow P2 for this. The method of supplying the liquid is of secondary importance; the liquid can also have a radial component upstream of the guide fins 3 (see, for example, arrow Pr). In order to further stabilize the flow in the vortex 20, additional stabilizing fins 4 can also be provided between the guide fins 3. As a result of the guide fins 3 and the stabilization fins 4, the local Reynolds number will be lower, with the result that a stable flow will be present there more quickly. In the further description of this figure, it will be assumed that the microbiological organisms have a greater density than the liquid, but if this is precisely the reverse, then the following description should also be understood to be the reverse. For example, the highly oil-containing Botryococcus braunii has a mass density that is smaller than that of water, so that it can be separated as the lighter fraction, thus biofuel can be produced in a very efficient manner. Separating the lighter fraction is usually more advantageous in a cyclone than separating the heavier fraction.

15

Due to a strong rotating flow at the distal end of the sheath 2, the microbiological organisms (for example algae) will move to the outside of the separation space 9 under the influence of the centrifugal action. The separation space 9 is bounded by the core 1 and the sheath 2. In order to obtain a stable flow (and to prevent boundary layer loosening), the circumference of the distal end of the core 1 flows smoothly by means of an end part 8 having a decreasing diameter off. To increase the residence time in the vortex 20, a tail section 5 is also provided. This tail section 5 has an elongated shape and is shown here conically, but may also be cylindrical, for example. A critical value in practice relates to the distal side of the tail section 5, which should preferably be smaller than 20 mm, more preferably even smaller than 15, 10 or 5 mm. The advantage of the presence of the tail section 5 is that by maintaining the momentum the centrifugal force increases further, which leads to an improved separation. In the axial direction, the liquid with an increased concentration of microbiological organisms will go via a wall 10 of the tail section 5 to an outlet 10 where the first fraction of liquid with the increased concentration of microbiological organisms leaves the vortex 20 in accordance with the arrow P3. The second fraction of the liquid with a reduced concentration of microbiological organisms will exit from the center of the tail section 5 through an opening 7 arranged in the core backwards out of the vortex 7 according to the arrow P4. The vortex 20 is also called a countercurrent device because of the fractions emerging in different directions in accordance with the arrows P3 and P4.

Figure 2 shows a vortex 30 whose parts corresponding to the parts as shown in the vortex 20 according to Figure 1 are designated with the same reference numerals. Again, guide fins 3 are positioned between a core 1 and a casing 2 and the liquid with suspended microbiological organisms is supplied substantially axially in accordance with arrow Pi such that it obtains a rotating tangential component through the guide fins 3 in accordance with arrow P2. To further stabilize the flow, stabilization fins 4 can again be provided. Again, it is assumed here by way of example that the microbiological organisms have a greater density than the liquid.

Due to a strong rotating flow at the distal end of the sheath 2, the microbiological organisms (for example algae) will collapse under the influence of the centrifugal action to the outside of the separation space 9 bounded by the core 1 and the sheath 2. Again the core 1 is provided with an end part 8 with a smoothly decreasing diameter and a tail section 5 is also provided. In an axial direction ring, the liquid with increased concentration of microbiological organisms will go via a wall 10 from the tail section 5 to an outlet 11 where the first fraction of liquid with the increased concentration of microbiological organisms leaves the vortex 30 according to the arrow P5. The second fraction of the liquid with a reduced concentration of microbiological organisms will also exit from the center of the tail section 5 through discharge element 12 according to the arrow Pe on the distal side of the vortex 30. The vortex 30 is also called a vortex of the co-current principle because of the fractions emerging in different directions in accordance with the arrows P5 and P6.

Claims (13)

A method for concentrating microbiological organisms suspended in the liquid from a flowing liquid, comprising the processing steps: Method according to claim 1, characterized in that the microbiological organisms do not coagulate. 3. Method as claimed in any of the foregoing claims, characterized in that the difference in mass density between the liquid and the microbiological organisms is less than 200, 150, 100, 50 or 30 kg / m3. Method according to one of the preceding claims, characterized in that the microbiological organisms are essentially algae. A method according to any one of the preceding claims, characterized in that the liquid is water. A) supplying the liquid with microbiological organisms suspended therein to a stationary cyclone, B) rotating the liquid with microbiological organisms suspended therein in a stationary housing of the cyclone, and C) discharging at least from the stationary cyclone at least two different fractions; 10 a first fraction with a concentration of suspended microbiological organisms increased relative to the supplied liquid and a second fraction with a concentration of suspended microbiological organisms reduced relative to the supplied liquid. 6. A method according to any one of the preceding claims, characterized in that gas is added to the flowing liquid such that gas bubbles are formed in the liquid. Method according to claim 6, characterized in that the gas bubbles are in the liquid during rotation of the liquid in stationary housing of the cyclone. 8. Method as claimed in any of the foregoing claims, characterized in that the liquid with microbiological organisms suspended therein is rotated in the stationary housing of the cyclone as a result of the presence of at least one guiding element. 9. Method as claimed in any of the foregoing claims, characterized in that the concentration of suspended microbiological organisms of the first fraction discharged from the stationary cyclone according to processing step C) is further increased with a concentration of suspended microbiological organisms already increased relative to the supplied liquid. . 10. Method as claimed in any of the foregoing claims, characterized in that the liquid with microbiological organisms suspended therein expands at the inlet to the stationary housing of the cyclone. A method according to any one of the preceding claims, characterized in that a flocculant for the microbiological organisms is supplied to the flowing liquid with suspended microbiological organisms. 20 A method according to any one of the preceding claims, characterized in that the liquid in the stationary housing of the cyclone traverses a helical flow path. A method according to any one of the preceding claims, characterized in that the flowing liquid consists essentially of water and the microbiological organisms are mainly formed by Botryococcus braunii.