WO2013011448A1 - Photobioreactor for producing a concentrated algal solution and device for exposing the solution, in particular for such a photobioreactor - Google Patents

Abstract

The invention relates to a photobioreactor for the closed-circuit production of a concentrated algal solution, comprising: a container (3) containing the algal solution (2); at least one sleeve (5) which is made of a flexible, transparent material that is resistant to pulling and pressure, which is hung vertically from a bracket, and which is submerged in the algal solution, the sleeve (5) being filled with a liquid (L) capable of balancing the external pressure in order to maintain the cylindrical shape thereof, and of transmitting and diffusing light.

Description

 The invention relates to a photobioreactor for the production of a concentrated algal solution, kind of those that contain a container containing the algal solution.

 The development of algal culture, in particular micro-algal to obtain a photosynthetic biofuel or nutraceuticals derived from algal biomass, can be achieved on a large scale only by significantly reducing the cost of photo-bioreactors and their exploitation. In addition, algal production is not restricted to warm, sunny regions, and technical solutions to increase algal production in temperate latitudes should be considered.

 DE 103 15 750 shows a photo-bioreactor comprising rows of transparent vertical tubes, through which the algal solution subjected to the light radiation passes through the tubes, which allows photosynthesis.

 Other photo-bioreactors use compartments of different shapes, separated by rigid walls, in particular polycarbonate or other monomeric or polymeric materials. These materials are expensive and the manufacturing time is long for parts intended for industrial applications of photo-bioreactors that can cover several tens of hectares. In addition, these materials are flammable and their ecological footprint is significant for manufacturing and deconstruction.

 Aerial photo-bioreactors require a large land grab and a height that induces a windward grip that penalizes the construction. Due to their large surface area in contact with the outside air, aerial photo-bioreactors are very sensitive to climatic conditions, which affects their performance in cold, windy or hot regions.

 The purpose of the invention is, above all, to provide an economic photo-bioreactor both in terms of investments and operating costs and whose construction can be achieved in a reduced time. It is desirable that the photo-bioreactor ensures maximum production of algal biomass, regardless of the season and latitude of the site.

The invention also aims to propose a photo-bioreactor whose influence land and the height of the facilities are reduced. It is also desirable to ensure a reduction of the environmental footprint and the risks in the event of a storm and / or fire coming from inside or outside the site.

 According to the invention, a photo-bioreactor for the closed circuit production of a concentrated algal solution comprising a container containing the algal solution, is characterized in that at least one handle made of a flexible, transparent, resistant material traction and pressure, suspended vertically to a support, is immersed in the algal solution, the sleeve being filled with a liquid suitable for balancing the external pressure to maintain its cylindrical shape, and to transmit and diffuse the light.

 The term "transparent" as used in the specification and claims means a light-transmitting material, and this term is to be broadly understood to encompass a translucent material.

 Advantageously, the height of the liquid in the sleeves immersed in the algal solution is greater than that of the algal solution in order to ensure a differential hydrostatic pressure for maintaining the shape of the sleeve without stress on the flexible wall.

 The container containing the algal solution may consist of a basin, in particular covered, filled with algal solution, basin in which is immersed at least one transparent transparent flexible sleeve and filled with a liquid, in particular water + additive (antifreeze, fluorescent, anti-foam) transmitting and diffusing the light captured at the upper end of the sleeve, which is closed at its lower end. In practice, the basin comprises a plurality of transparent transparent flexible sleeves filled with a liquid, judiciously distributed, transmitting and diffusing the light captured throughout the volume of the basin.

 The basin may be cylindrical or rectangular; it can be aerial, buried or semi-buried.

 The basin may be made of concrete, or resin, or flexible material with external structure, or prefabricated elements assembled on site with implementation of an inner lining. The walls of the basin may also be made of a transparent membrane which is waterproof, in particular flexible.

The container containing the algal solution may be constituted by a flexible transparent sleeve. Fixing the sleeve to the support can be achieved by providing, in the support, for each sleeve a frustoconical opening, decreasing in section from top to bottom, and the upper edge of the The handle is wedged against the frustoconical wall of the opening by a plug itself frustoconical, conjugated with the opening, and made of transparent material.

 The algal solution is exposed to light passing through the wall of the sleeve. Further exposure can be provided by the light captured at the upper end of the sleeve and directed to the algal solution.

 A second transparent flexible sleeve, suspended on a support, can be immersed in the first sleeve, the second sleeve being filled with a liquid, in particular neutral with respect to the algal solution, suitable for balancing the external pressure and maintaining its cylindrical shape by the differential static pressure.

 Advantageously, the photo-bioreactor comprises, above the end of the flexible sleeves intended to diffuse the light in the algal solution, an optical concentrator, in particular a lens or a mirror, able to concentrate the light on the upper input of the sleeve associated with this concentrator. Advantageously, the optical concentrator, in particular the lens, is rotatably steerable at an angle of inclination and in azimuth in order to capture the maximum of solar radiation throughout the day, and whatever the season.

 The photo-bioreactor may comprise a passive internal device for transmitting light from the top to the bottom making it possible to filter the wavelengths of interest for the photosynthesis of microalgae and to limit the local heating due to the concentration of light. . The photobioreactor can have a light wavelength filter system (UV, IR) to limit local heating effects.

 The photo-bioreactor may include a removable sunshade, especially located above the lenses, or a mask incorporated on each of them to reduce light intensity during the most intense sunny periods.

 Flexible sleeves can be closed and weighted at the bottom. In the case where the sleeves do not comprise an algal solution but a different liquid, advantageously the composition of the liquid is neutral vis-à-vis the algal solution to avoid any risk in case of accidental breakage of the sleeve.

The photo-bioreactor advantageously comprises, for the replacement of the sleeves, a suction means of the internal liquid of the upper sleeve, which emptied sleeve flattens under the effect of the external pressure. A device for replacing the sleeves by winding on a drum, or unwinding from this drum, with automated cleaning of the sleeves, is advantageously provided.

 The photo-bioreactor may comprise a device for extracting the algal solution in the upper part of the container, in particular the basin, and a return to the container in the lower part of the water after extraction of the algae and filtration.

The photo-bioreactor may comprise, in the lower part of the container, in particular the basin, means for dispensing a gas under pressure, in particular carbon dioxide (CO ₂ ), mixed or not with water, also ensuring agitation of the algal solution.

 Means for capturing and recycling at least part of the gases that escape at the top of the container are advantageously provided. The container, in particular the basin, may be insulated and advantageously comprises a regulation of the temperature of the algal solution to the optimum growth value.

 The heating or cooling device of the basin may advantageously consist of a water / water tubular or plate heat exchanger located on the return of the algal solution after filtration or a circulation of temperate water circulating inside the sleeves water.

 Artificial lighting means, in particular at least one light emitting diode or LED, may be provided to illuminate the algal solution overnight, or during periods of low solar intensity to maintain minimal photosynthetic metabolism.

 The material of the sleeves is advantageously a monofilm of transparent plastic material of a thickness of a few tens of microns (micrometers), less than one hundred microns.

 The invention also relates to a device for exposure to light of an algal solution, in particular for a photo-bioreactor as defined above, characterized in that it comprises at least one handle made of a transparent flexible material , resistant to traction, this sleeve being designed to be suspended from a support and filled with a liquid which ensures a cylindrical shape, and to be immersed in the algal solution.

 The transparent flexible sleeve, filled with liquid, can be immersed in another transparent flexible sleeve filled with algal solution.

The invention also relates to a photobioreactor which results from the transformation of an open open pond into a closed photobioreactor having the characteristics described above. In this case, the devices described above are therefore applied to existing open ponds, which are transformed into closed photo-bioreactors.

 The invention consists, apart from the arrangements set out above, in a certain number of other arrangements which will be more explicitly discussed below with regard to embodiments described with reference to the accompanying drawings, but which are not in no way limiting. On these drawings:

 Fig. 1 is a schematic vertical section of a photo-bioreactor according to the invention, wherein the container containing the algal solution is formed by a basin.

 Fig. 2 is a horizontal section along line 11-11 of FIG. 1.

 Fig. 3 is a diagram, on a larger scale, of a flexible vertical sleeve with optical concentrator in the upper part.

 Figs. 4 and 5 are transverse vertical sections, on a smaller scale, of possible shapes for the basin of the photo-bioreactor.

 Fig. 6 is a schematic section, similar to FIG. 1, illustrating the replacement of a flexible sleeve.

 Fig. 7 is a top view of two cassettes respectively without the sleeves and with the flexible sleeves.

 Fig. 8 is a vertical section of a flexible sleeve forming a container for the algal solution, inside which is disposed a second flexible sleeve and

 Fig. 9 shows, similarly to FIG. 8, the whole of the two sleeves, while the one forming the container was partially emptied of algal solution.

 Referring to Fig. 1 of the drawings, a photobioreactor 1, hereinafter abbreviated as PBR, can be seen for the production of a concentrated algal solution 2. The PBR comprises a container 3 containing the algal solution and a means 4 of exposure to light of this algal solution.

 According to the invention, the exposure means 4 comprises at least one vertical sleeve 5 made of a transparent flexible material, resistant to traction. This sleeve 5 is suspended from a support 6 and is filled with a liquid L which ensures a cylindrical shape to this sleeve.

The flexible sleeve 5 is advantageously made of an ultraviolet-resistant material, in particular polyethylene terephthalate, in particular a material known under the trademark Mylar ^® , or equivalent material. The sleeve can be obtained by winding a rectangular portion of sheet and assembling the two parallel edges by gluing or welding. The lower end of the sleeve is closed while the upper end remains open to be fixed on its periphery to the support 6.

 Fixing the sleeve 5 to the support 6 can be carried out as illustrated in FIG. 3 by providing, in the support 6, for each sleeve a frustoconical opening 7, decreasing in section from top to bottom. The upper edge of the sleeve 5 is wedged against the frustoconical wall of the opening 7 by a plug 8 itself frustoconical, conjugated with the opening 7, and made of transparent material.

 The attachment of the sleeves 5 on the top cover 10 of the reactors could be ensured in a different way, in particular by flanges instead of retaining by nested conical parts. It is not necessary to ensure complete sealing at this attachment because there is no contact between the algal solution and the water located inside the immersed sleeves 5.

 According to the embodiment of FIG. 1, the container 3 consists of a basin 9, filled with algal solution 2. A plurality of flexible transparent sleeves 5, filled with liquid L, are immersed in the algal solution 2 and are judiciously distributed to transmit and diffuse the light, captured at the upper end of the sleeves 5, throughout the basin 9 and the solution 2.

 The basin 9 is preferably closed at the top by a wall 10 acting as support 6 for the suspension of the sleeves 5.

 According to this embodiment, the liquid L which fills the sleeves 5 has the main function of transmitting and diffusing the light captured, and consists in particular of water + an additive (the additive may be antifreeze, or a product fluorescent or antiseptic, or an anti-foam product). The closed lower end of the sleeves 5 is preferably equipped with a ballast 11 (FIG 3). This ballast 1 1, when introducing empty sleeves into the algal solution 2, prevent them from floating, which would make it difficult to refill them later with water. The ballast may be formed of a rod or a ball of heavy material, metal or mineral.

 The sleeves 5 are in contact, by their outer wall, with the algal solution 2 which fills the basin.

The basin 9 may be of square or rectangular shape as illustrated in FIG. 2, or of cylindrical shape with circular cross section (not shown). The pelvis 9 may be aerial as illustrated in FIG. 1, in which case portholes 12 may be provided in the walls to complete the exposure to the light of the algal solution 2. The basin 9 can also be semi-buried or buried. The basin can also be made of prefabricated elements in the factory and assembled on site with a liner of the type used in swimming pools.

 The vertical cross section 13 of the basin may be rectangular as illustrated in FIG. 4, with a flat roof. Alternatively, as illustrated in FIG. 5, the section may have a trapezoidal bottom portion.

 In the case of an aerial or semi-buried basin, the walls can also be made of a transparent waterproof membrane, in particular flexible membrane, contributing to the exposure of the algal solution to light.

 The increase in brightness within the sleeves 5 can be achieved by providing an optical light concentrator over each sleeve or covering all or part of the reactor to focus the light on the upper input of the associated sleeve. . The concentrator 15 advantageously comprises a lens 16 placed above each sleeve 5. The lenses 16 concentrate and focus the light rays at the upper entrance of the handles 5. The lenses 16 can be fixed, inclined oriented like the solar panels preferably in the South, South West or South East, or can be steered in angle of inclination and azimuth in order to capture the maximum of solar radiation throughout the day.

 In the case where the walls of the pool 9 comprise portholes 12, or are transparent, it is possible to provide concentrators of light around the walls of the pool to concentrate the light on these transparent walls.

 Light concentrators can implement not only lenses but also mirrors, usually concave mirrors.

 A sunshade 17 (Fig. 3) can be provided to reduce the light intensity during the most intense periods.

 The composition of the liquid L that fills the sleeves 5 is neutral vis-à-vis the algal solution to avoid any risk in case of accidental breakage. The liquid L, in the case of the embodiment of FIG. 1 is essentially water with an optional additive, this additive may be antifreeze, or an antiseptic, or a fluorescent product.

The height h5 of the liquid in the sleeves 5 is slightly greater than that h2 (Fig. 1) of the algal solution in the basin, in order to ensure a differential hydrostatic pressure (h5 - h2) which keeps the cylindrical shape unconstrained on the flexible wall of the sleeves 5. Referring to Fig. 6, one can see a drain operation of a 5.1 sleeve for replacement and the establishment of another sleeve 5.2.

 The sleeve 5.1 that it is desired to remove is connected, by its upper end, to a pipe 18 connected to the inlet of a suction means 19 of the liquid located inside the sleeve 5.1. The suction means 19 is generally constituted by a pump. For connection of sleeve 5.1 to line 18, the plug 8 (Fig. 3) is removed and the sleeve is connected to and supported by the suction line 18. The external pressure exerted by the algal solution 2 compresses the sleeve 5.1 which flattens and which, after disconnection of the suction pipe 18, is removed from the basin 9.

 A device 20 for replacing the sleeves, by winding, is provided above the pelvis 9. This device 20 comprises a rotary winding drum 21 mounted to be movable in translation above the pelvis 9 while being supported by a rail 22. cleaning members, in particular rotating brushes 23, are provided to move in translation with the drum 21 and to determine a vertical clearance gap for the flattened handle 5.2 which is cleaned by these brushes 23 when it is removed from the algal solution . The device 20 allows, by unwinding, to set up a new flattened sleeve in the algal solution 2 to replace that which has been removed.

 The length of the sleeves 5 corresponds to the height of the basin 9. In the case of an air basin, the height of the basin could be of the same order as that of the digesters. However, there is an economic limit, and the ratio of the projected area to the volume of the algal solution must be respected to optimize biomass production. In addition, the geometry depends on the available floor space. There is therefore an economic optimum height-surface. Non-limitingly, it can be indicated that the height of the basin 9 can vary from 1 m to 8 m and more.

 The dimensions of the horizontal section are limited mainly for construction reasons. In general, for rectangular or circular basins, it is the span that limits the width or diameter, except for placing intermediate posts in the basin or partitioning it into sections.

Several runs on one or more rows may be attached to cassettes 24 (Fig. 7) and set up or removed in a single operation. In the embodiment illustrated in FIG. 7, ten sleeves 5 are fixed on the same cassette 24. In this same figure 7, another cassette 24.1 has been represented, without being equipped with sleeves.

 A pipe 25 (Fig.1) extraction of the algal solution is provided in the upper part of the basin, in order to benefit from the higher concentration of algae. After extraction and filtration, the return of water is ensured in the lower part by a pipe 26. The nutrients for the development of algae can be injected into the return water.

 The process of extracting the biomass in the algae solution of the photobioreactors is continuous and, since it does not require intermediate storage in reservoirs, it is not necessary to provide ultrafiltration with membranes for avoid the inadvertent development of algae in the tanks.

The PBR comprises, in the lower part of the basin 9, means 27 for dispensing a gas under pressure, in particular carbon dioxide (CO ₂ ) mixed or not with air favorable for the development of algae, and ensuring the agitation of the algal solution 2. The distribution means 27 are constituted by ramps for blowing the gas, as illustrated by arrows F, in the spaces between the sleeves 5. The distribution means 27 are connected to the output of a booster 28, rotary, piston or screw, by a pipe 29. The distribution of carbon dioxide (CO ₂ ) provides agitation and homogeneity of the algal solution in the basin 9.

It is possible to capture and recycle some of the gases that escape from the upper part of the basin to better deplete carbon dioxide (CO ₂ ). For this, the PBR further comprises gas capturing means 30 formed by a pipe opening in the upper part of the basin 9, above the algal solution, in the gaseous surface above this solution. These capture means are connected to the suction of a fan 31 which delivers the gases in a pipe 32, in particular to the atmosphere. A recycling of a portion of these gases can be provided through a tapping 33 on the pipe 32, this tapping being connected to the suction of the booster 28.

 Pond 9 is insulated to reduce heat loss. Regulation of the temperature of the algal solution is advantageously provided by means of a device for reheating and / or cooling (not shown) of the water introduced via line 26 into the basin after filtration, which makes it possible to maintain optimum growth conditions of algae and micro-algae. The closure cover 10 of the basin is also insulated.

Fig. 8 illustrates another possible embodiment of the PBR. The algal solution 2 is disposed inside the flexible sleeve 5 suspended and is exposed to light through the wall of the sleeve. In this case, the inner wall of the sleeve 5 is in contact with the algal solution, while the outer wall of the sleeve 5 is in contact with the air. The algal solution 2 is extracted from the sleeve 5 by pumping.

 A second flexible sleeve 5a, of smaller diameter than that of the sleeve 5, and suspended on a support not shown in FIG. 8, is immersed in the algal solution of the first sleeve. The second sleeve 5a is filled with neutral liquid L to balance the external pressure. The liquid level in the second sleeve 5a is greater than that of the algal solution in the sleeve 5 to maintain a differential hydrostatic pressure as discussed with reference to FIG. 1.

 For the extraction of algae, the solution is pumped from the chamber 5 substantially over half the height of this chamber as shown in Fig.9, and filtered. The water is returned in the sleeve 5 around the sleeve 5a.

 A thermal regulation of the algal solution can be implemented by a heat exchange with a circulation of the liquid in the chamber 5a with temperature regulation (hot or cold water). In this case, the lower end of the sleeve 5a is open and connected to a liquid circuit in which is installed a heating / cooling device (not shown) of the liquid which is returned to the upper portion of the second sleeve 5a.

 As discussed with the sleeves 5 of the pelvis 9, it is possible to provide a light concentrator device above the upper end of the second handle 5a, to increase the intensity of the light on this end. The collected light is transmitted and diffused by the liquid

L in the algal solution 2 from the inside, radially. This exposure is added to that obtained from the outside through the wall of the sleeve 5.

 The establishment and removal of the second membrane 5a can be done as explained in connection with FIG. 6.

 The operation of the PBR according to the invention results from the foregoing explanations. The algal solution 2 exposed to light:

 either from the inside according to the embodiment of FIGS. 1 -6 and also, if necessary, from the outside through portholes 12 or a transparent wall,

 either from the outside according to the embodiment of FIGS. 8 and 9 and also, if necessary, from the inside through a second sleeve 5a,

allows the growth and development of algae which are then recovered, especially for the production of biofuels.

A significant and competitive advantage of the invention is related essentially to the material of monofilm sleeves with a thickness of a few tens of microns (micrometers) compared to several mm for polycarbonate sleeves or other flexible materials that would have to withstand greater pressure or strength (buckling or bending).

 The invention also has the following advantages:

 - specific production per square meter of very large surface area of PBR;

 - Reduced groundholding, resulting in availability and purchase of land;

- relatively low investments compared to PBRs made of rigid polycarbonate or glass;

 - No need to provide ultrafiltration of return water after separation because it is not stored in tanks because of continuous extraction of biomass;

- simplicity and speed for replacing and cleaning sleeves;

 - continuous production independent of climatic conditions (very little static heat loss or evaporation);

 - little water consumption of the process, only the intracellular water contained in the biomass extracted,

- Artificial lighting during the night increases production by avoiding a return to a purely respiratory metabolism;

 no risk of inhibition or photosynthetic saturation;

 - simple manufacturing elements that are easy to implement;

 - no risk for an exceptional event (especially a storm) or a fire in the reactors;

 - carbon footprints during weak construction and deconstruction;

- maximum height of the ACB that can be reduced according to local planning rules;

 - speed of manufacture and construction;

- Possibilities to treat flue gases if necessary or to recycle them to optimize the consumption of carbon dioxide (CO ₂ ).

 The production of sleeves 5 according to the invention is much less expensive than the production of rigid transparent tubes made of plastic material.

Claims

1. Photo-bioreactor for the closed circuit production of a concentrated algal solution comprising a container (3) containing the algal solution (2), characterized in that at least one handle (5, 5a) made of a flexible, transparent material , tensile and pressure resistant, suspended vertically to a support, is immersed in the algal solution, the sleeve (5, 5a) being filled with a liquid (L) suitable for balancing the external pressure to maintain its cylindrical shape, and to transmit and diffuse the light.

2. Photo-bioreactor according to claim 1, characterized in that the liquid height (h5) in the sleeves (5,5a) immersed in the algal solution is greater than that (h2) of the algal solution to ensure a differential hydrostatic pressure for maintaining the shape of the sleeve without stress on the flexible wall.

3. Photo-bioreactor according to claim 1 or 2, characterized in that the container (3) containing the algal solution consists of a basin (9), in particular covered, filled with algal solution, basin in which are immersed a a plurality of watertight, transparent transparent sleeves (5) filled with liquid (L), judiciously distributed, transmitting and diffusing throughout the basin the light sensed at the upper ends of the sleeves, which are closed at their lower end.

4. Photo-bioreactor according to claim 3, characterized in that the basin is made of concrete, or resin, or flexible material with external structure or prefabricated elements assembled on site with implementation of an inner liner.

5. Photo-bioreactor according to claim 3, characterized in that the walls of the basin are made of a transparent membrane, in particular flexible.

6. Photo-bioreactor according to claim 1 or 2, characterized in that the container (3) containing the algal solution (2) is constituted by a flexible transparent sleeve (5).

Photo-bioreactor according to one of the preceding claims, characterized in that the fixing of the sleeve (5) to the support (6) is carried out in providing, in the support (6), for each sleeve a frustoconical opening (7), decreasing in section from top to bottom, and the upper edge of the sleeve (5) is wedged against the frustoconical wall of the opening (7) by a plug (8) itself frustoconical conjugate opening (7), and made of transparent material.

8. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises, above the end of the flexible sleeves (5, 5a) provided for diffusing light in the algal solution, an optical concentrator (15), in particular a lens (16) or a mirror, adapted to focus the light on the upper input of the sleeve associated with the concentrator.

Photo-bioreactor according to claim 8, characterized in that the optical concentrator (15), in particular the lens (16), is steerable at an angle of inclination and in azimuth so as to capture the maximum of solar radiation at long of the day and whatever the season

10. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises a filter system wavelengths of light (UV, IR) to limit local heating effects.

1 1. Photo-bioreactor according to claim 8 or 9, characterized in that it comprises a sunshade (17) for reducing the light intensity during the most intense sunny periods.

12. Photo-bioreactor according to any one of the preceding claims, characterized in that the flexible handles (5) are closed and weighted (1 1) in the lower part.

13. Photo-bioreactor according to any one of the preceding claims, characterized in that the liquid (L) contained by the sleeve or sleeves (5,5a) immersed in the algal solution, is neutral vis-à-vis the solution algale to avoid any risk in case of accidental breakage of the sleeve.

14. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises, for the replacement of the sleeves, a suction means (18,19) of the internal liquid of the sleeve in the upper part, which sleeve emptied flattens under the effect of external pressure, and a device (20) for replacing the sleeves by winding on a drum (21), or unwinding from this drum, with automated cleaning (23) of the sleeves.

15. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises a device (25) for extracting the algal solution in the upper part of the container (3), in particular the basin (9), and a return (26) in the container in the lower part of the water after extraction of algae and filtration.

16. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises, in the lower part of the container (3), means (27) for distributing a gas under pressure, in particular carbon dioxide. carbon (CO ₂ ) mixed or not with air, ensuring agitation of the algal solution.

17. Photo-bioreactor according to any one of the preceding claims, characterized in that it comprises means for capturing and recycling (30, 31, 33) at least part of the gases that escape at the top of the container (3).

18. Photo-bioreactor according to any one of the preceding claims, characterized in that the container (3) is insulated and advantageously comprises a temperature control of the algal solution (2).

19. Photo-bioreactor according to any one of the preceding claims, characterized in that artificial lighting means, in particular at least one light-emitting diode or LED, is provided for illuminating the algal solution during the night, or during periods of low solar intensity.

20. Photo-bioreactor according to any one of the preceding claims, characterized in that the sleeve material is a monofilm of transparent plastic material of a thickness of a few tens of microns (micrometers).

21. Device for exposure to light of an algal solution, in particular for a photo-bioreactor according to any one of the preceding claims, characterized in that it comprises at least one handle (5, 5a) made of a flexible material transparent, resistant to traction, this sleeve being planned to be suspended from a support and filled with a liquid (L) which ensures a cylindrical shape, and to be immersed in the algal solution.

22. Device according to claim 21, characterized in that the transparent flexible sleeve (5, 5a), filled with liquid (L), is immersed in another transparent flexible sleeve (5) filled with algal solution.

23. Photo-bioreactor characterized in that it results from the transformation of an existing open-bottom pool into a closed photo-bioreactor according to any one of claims 1 to 20.