DE102009039554A1 - A method of harvesting algae from an algal suspension, first, second and third algal suspension concentrates and first, second and third nutrient liquid filtrate - Google Patents

Abstract

Saltwater algae in particular have great potential for converting CO ₂ . To extract the algae from their natural aqueous environment, energy-intensive centrifuges are used for separation.
The present invention proposes a method for harvesting algae from an algal suspension in which a concentration of the algal suspension is effected by means of a membrane filter, so that a first filtrate of a first nutrient fluid and a first concentrate of an algal suspension are present.
Thus, an energy efficient harvesting process for the recovery of algae from an algal suspension, especially microalgae, in a microalgae suspension can be provided.

Description

The invention discloses a method for harvesting algae from an algal suspension, in particular from a microalgae suspension, whereby a special type of concentration of the algal suspension takes place.

Algae are considered to be one of the most promising microorganisms to bind or convert CO ₂ . In particular, such algae are converted into diesel fuel. In this conversion, the lipids are used, which are present in the algae. Further conversions, for example in animal feed or cosmetics, are known.

Since algae are grown or grown in aqueous solutions, the algae must be separated from the aqueous solution. In this context, algae are also referred to as biomass. For the separation of the biomass, according to the prior art, centrifuging is used as an established method. The liquid is separated from the solid components in a centrifuge.

The object of the invention is to improve the state of the art.

The object is achieved by a method for harvesting algae from an algal suspension, in particular from a microalgae suspension, wherein a concentration of the algal suspension is effected by means of a membrane filter, so that a first filtrate of a nutrient fluid and a first concentrate of an algal suspension is present. Thereby, a method can be provided in which the use of energy is reduced.

Conceptually, the following is explained:

Algae of the species described here include eukaryotic, plant-like organisms living in water or multiplying in an aqueous environment, which carry out photosynthesis but are not taxonomically part of the actual plants. Furthermore, both freshwater and marine algae are included. In particular, the following groups of algae or algae species are included: Haptophyta, molting (Cryptista), Dinozoa, Raphidophyceae, Chlorarachniophyta, gold algae (Chrysophyta), diatoms (Bacillariophyta, also diatoms), brown algae (Thaeophyta), red algae (Rhodophyta), green algae and Ticobiliphyta, the algae listed here are particularly preferably used in salt water. In particular, the marine algae Nannochloropsis, Isochrysis, Phaeodactylum, Tetraselmis, Dunaniella and / or Spirulina and the freshwater algae Chlorella can be used. The algae can be cultivated and / or cultivated in the temperature range of 0 ° C. to 40 ° C. and at pressures of above 0 bar to 5 bar and in particular at values of approximately 1 bar.

The term "filtrate" refers in particular to the liquid component of the algal suspension without algae after the filtration process. In particular, this filtrate also contains the nutrients that the algae used to grow. The nutrients and the aqueous components can form a nutrient fluid.

The term "concentrate" is understood to mean the concentrated algae suspension up to the pure dry matter content of the algae suspension. The concentrate may also have nutrient fluid.

In particular, filters are used as the "membrane filter" in which the mass transport takes place either via a solution diffusion model or via a hydrodynamic model, wherein both models can also occur in parallel. In the solution diffusion model, the transport essentially takes place by the diffusion, with the component to be transported being dissolved in the membrane. In the preferred hydrodynamic model, the mass transport is purely convective.

In one embodiment of the invention, the membrane filter may comprise a permeable membrane. In this case, the filtrate can pass through the permeable membrane and thus separate, wherein the concentrate does not overcome the membrane.

In particular, since microalgae up to a micron in size are used, the membrane filter may have a hollow fiber membrane to take advantage of capillary forces.

In a further embodiment of the method, the hollow-fiber membrane may comprise perforated hollow glass fiber rods. As a result, an adhesion of the algae to the filter can advantageously be reduced.

So that the algae do not penetrate into the hollow glass fiber rods, the perforated glass fiber hollow rods can have a pore width of approx. 0.05 μm.

In a further embodiment of the method, the concentration of the algal suspension can be up to a density between 50 g dry matter per liter (g TS / l) and 400 g dry matter per liter, in particular between 100 g dry matter per liter and 250 g dry matter per liter. As a result, a large part of the filtrate can already be taken from the nutrient solution of the algal suspension.

In order to accelerate the harvesting process for the highly concentrated algae suspensions, this concentrated algae suspension can be centrifuged so that a second filtrate of a nutrient fluid and a second nutrient concentrate of an algal suspension are present. Thus, then there is a biomass from the algae for further processing.

In a further embodiment of the method, the concentration can be up to a density of between 5 g dry matter per liter and 50 g dry matter per liter. As a result, the size and / or the number of membrane filters for the amount of algae harvested per time can be reduced.

As has been shown by the experiments of the inventor, it is particularly advantageous if the concentration takes place to a density between 10 g dry matter per liter and 20 g dry matter per liter.

In order to reduce the use of nutrient fluid or to increase the environmental compatibility, the first or the second filtrate can be reused from the nutrient fluid.

In order to achieve a thickening of the algal suspension, a flocculant for thickening the concentrate of the algae suspension may be added to the first algae suspension concentrate.

First, the term "flocculation" is explained. By flocculation finest suspended and collodially loosened, disturbing water constituents such as plankton, iron sludge or algae present in the water can be removed from the water. The boundary between suspended and collodially dissolved particles is about 0.45 microns. If the density of the fine particles is equal to that of the water, then they can float and not sediment.

Another disturbance of the sedimentation is given by the mutual repulsion of the individual particles with each other. These particles are often negatively charged and repel each other and prevent mutual aggregation. This can also prevent sedimentation.

In flocculation, these small particles are aggregated into larger flakes, so-called macro flocs, so that they then receive a greater density, which then sedimentation can take place.

A flocculating agent destabilizes the fine parts so that they no longer repel each other. Such flocculants may be aluminum or ferric salts. After destabilization, the fine particles may agglomerate, this part is also called coagulation. At the same time, however, flakes are also formed, in which the already coagulated flakes are bound in, and thereby made separable. This part is called flocculation. Flocculation may therefore include coagulation and flocculation.

Also, the pH value for flocculation can be adjusted. For example, when iron salts are used, the pH may be between 5.5-7.5. In the case of aluminum salts, in particular a pH of between 5.5 and 7.2 is preferred. In the present case, in particular, organic flocculants such as chitosan or polyacrylates can be used.

Further procedures and applications of flocculation can be found in the writings Mutschmann, Stimmelmayr / Taschenbuch der Wasserversorgung / Frackh-Verlag and Damrath- Cord- Landwehr / Wasserversorgung / B. G. Teubner Verlag, whose content in terms of flocculation are part of this document.

In order to be able to further process the biomass from algae, screening may be carried out by means of a sieve or a fine-pored tissue, in particular a gauze, so that a third filtrate of a nutrient fluid and a third concentrate of an algal suspension are present.

In a further aspect of the invention of the method, the third filtrate described above can be reused and supplied to the algal suspension.

In a third aspect of the invention, the object is achieved by the first algae suspension concentrate, which is present after carrying out the method described above.

In a further aspect of the invention, the object is achieved by the first Nährflüssigkeitsfiltrat, which is present after performing the method described above.

In a fifth aspect of the invention, the object is achieved by the second algae suspension concentrate which is present after carrying out the method described above.

In a further aspect of the invention, the object is achieved by the second Nährflüssigkeitsfiltrat, which is present after performing the method described above.

In a sixth aspect of the invention, the object is achieved by the third algae suspension concentrate, which is present after carrying out the method described above.

In a further aspect of the invention, the object is achieved by the third Nährflüssigkeitsfiltrat, which is present after performing the method described above.

Furthermore, the invention will be explained by way of example with reference to the drawing. It puts

1 the sequence of the inventive method with associated steps.

At a beginning 1 a microalgae suspension is present in a photobioreactor in a concentration of 1 to 2 g dry matter per liter or in an algae pool with a microalgae suspension in a concentration between about 0.2 to 0.5 g dry matter per liter.

This microalgae suspension is concentrated by means of a membrane filter to a concentration of between 10 g dry matter per liter and 20 g dry matter per liter 2 , The membrane filter of the type PURON ^{TM from} the company Kochmembran Systems (KMS) from Aachen is used. This PURON ^TM membrane filter consists of perforated fiberglass hollow rods with a pore size of 0.05 μm. The microalgae are retained and the water with salts and nutrients is permeable through the membrane filter. After concentration 2 is a first filtrate F1 from water, salts and nutrients and a first concentrate K1 from a concentrated microalgae suspension.

The first filtrate F1 is recycled to the photobioreactor or algae pool as reused filtrate R1. This is in 1 as a step 6 characterized.

The first concentrate K1 can either be centrifuged (not shown).

After centrifugation, a second filtrate of water, salts and nutrients and a second concentrate of a concentrated microalgae suspension is present. Depending on the intensity of centrifugation, the second concentrate is free of water, salts or nutrients.

The first concentrate K1 can be thickened with a flocculant 3 become.

When thickening comes as a flocculant preferably the flocculant of the brand NICASAL Sachtleben Wasserchemie GmbH used.

The thickened algae are sifted through a gauze, giving step 4. is marked. Such a gauze is in particular a fine-pored tissue. After sifting 4. there is a third filtrate F3. This third filtrate comprises water, with dissolved salts or nutrients and is used as nutrient liquid R3 to the photobioreactor 1 or the algae pool 1 recycled 7 ,

The final algae biomass 5 has a dry matter content between 10% and 30%. This algal biomass can then be used for the production of diesel fuel, cosmetics, animal food, dietary supplements, etc.

Claims (19)

Method for harvesting algae from an algal suspension, in particular from a microalgae suspension, characterized in that the algae suspension is concentrated by means of a membrane filter, so that a first filtrate of a nutrient fluid and a first concentrate of an algal suspension are present. A method according to claim 1, characterized in that the membrane filter comprises a permeable membrane. Method according to one of the preceding claims, characterized in that the membrane filter comprises a hollow fiber membrane. A method according to claim 3, characterized in that the hollow fiber membrane comprises perforated hollow glass fiber rods. A method according to claim 4, characterized in that the perforated hollow glass fiber rods have a pore size of about 0.05 microns. Method according to one of the preceding claims, characterized in that the concentration of the algal suspension up to a density between 50 g dry matter per liter and 400 g dry matter per liter, in particular between 100 g dry matter per liter and 250 g dry matter per liter occurs. A method according to claim 6, characterized in that the concentrated algae suspension is centrifuged so that a second filtrate of a nutrient fluid and a second concentrate of an algal suspension are present. Method according to one of claims 1 to 5, characterized in that the concentration takes place up to a density between 5 g dry matter per liter and 50 g dry matter per liter. Method according to one of claims 1 to 5, characterized in that the concentration takes place up to a density of between 10 g dry matter per liter and 20 g dry matter per liter. Method according to one of the preceding claims, characterized in that the first or the second filtrate are reused from the nutrient fluid. Method according to one of claims 6, 8 to 10, characterized in that the first concentrate from the algal suspension, a flocculant for covering the concentrate of the algal suspension is supplied. Method according to one of the preceding claims, characterized in that after the steps described above, a sieving by means of a sieve or a fine-pored tissue, in particular a gauze, takes place, so that a third filtrate of a nutrient fluid and a third concentrate of an algal suspension is present. A method according to claim 12, characterized in that the third filtrate is reused from the nutrient fluid and the algal suspension is supplied. First algae suspension concentrate, characterized in that the first algae suspension concentrate after carrying out a method according to any one of claims 1 to 6 is present. First nutrient fluid filtrate, characterized in that the first nutrient fluid filtrate is present after performing a method according to any one of claims 1 to 6. A second algae suspension concentrate, characterized in that the second algae suspension concentrate is present after performing the method of claim 7. A second nutrient liquid filtrate, characterized in that the second nutrient liquid filtrate is present after performing the method of claim 7. Third algae suspension concentrate, characterized in that the third algae suspension concentrate is present after carrying out the method according to claim 12. A third nutrient liquid filtrate, characterized in that the third nutrient liquid filtrate is present after performing the method of claim 12.

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