WO2011101469A1

WO2011101469A1 - Method for purifying gases including co2 and corresponding device

Info

Publication number: WO2011101469A1
Application number: PCT/EP2011/052515
Authority: WO
Inventors: Christophe Boonaert; Sébastien MALCHAIRE; Louis Masset
Original assignee: Agc Glass Europe; Carmeuse Group
Priority date: 2010-02-22
Filing date: 2011-02-21
Publication date: 2011-08-25
Also published as: BE1019198A3

Abstract

The invention relates to a method for purifying gases including CO₂ by means of phototrophic organisms, and to the corresponding device. According to the invention, such a method includes the following steps: a) adding (801) water from a water source; b) capturing and washing (802) the gas in an absorber including at least a portion of the water so as to obtain an aqueous solution of CO₂; c) from at least a portion of the water, preparing (803) an aqueous solution containing nutrients; d) injecting (804) into a photobioreactor including the phototrophic organisms at least a portion of the aqueous solution of CO₂ and at least a portion of the aqueous solution containing the nutrients; e) illuminating (805) the contents of the photobioreactor with a beam of light; wherein steps (b) and (c) can be performed in reverse order or simultaneously.

Description

Process for purifying gas comprising CO ₂ and corresponding device

1. Field of the invention

The present invention relates to the treatment of gases comprising carbon dioxide, especially combustion gases containing a significant portion of carbon dioxide.

2. Solutions of the prior art

Regulations aimed at limiting greenhouse gas emissions are increasing. The regulations in question are most often accompanied by penalties for those who do not comply with the requirements. Significantly, the requirements are more and more restrictive. Industries in particular, which constitute an important source of emission of these gases, are led to find solutions that make it possible to achieve the conditions that satisfy these regulations.

By nature some industries that consume large quantities of fossil fuels also produce large quantities of flue gas containing these gases whose emission is regulated. All industries in whose productions the implementation of fusion calcination, heat treatment of any kind are concerned. Among these are thermal power plants, iron and steel, glass production, refining of petroleum products, cement plants, lime production ...

At present, research has focused on techniques to reduce gas emissions in two ways: by limiting the consumption of fossil fuels on the one hand, and by capturing and / or storing gases. issued on the other hand.

The first way (limiting consumption) has been to use energy sources that do not generate flue gas. These sources, however, are generally more expensive and often only move emissions to upstream industries. This is the case of electrical energy when it is produced in thermal power plants for example.

The second way is to have means to limit the release of gas into the atmosphere. Solutions consist in capturing and storing these gases insofar as this solution is industrially possible. This is practiced, for example, on certain sites producing natural gas or oil, or even mines. The gases are, for example, reintroduced into the underground pockets from which the extracted fuels originate. The removal of gases such as carbon dioxide can also be the subject of treatments that lead to fixing this gas in a chemical form without impacting the environment, for example in the form of calcium carbonate. The products of this transformation are not of significant value. The overall cost is therefore relatively large.

Other solutions consist of using photosynthetic algae in reactors called "photobioreactors". Such organisms synthesize their organic matter by exploiting light (from the Sun) and by fixing carbon dioxide (hereinafter referred to as C0 ₂ ). In addition to C0 ₂ , their needs are water and nutrients present for example in the soil. The products obtained are organic matter also called "biomass", and oxygen (hereinafter referred to as O ₂ ) also called "metabolic oxygen". The photosynthesis reaction can be summarized by the following chemical equation:

n C0 ₂ + n H ₂ 0 → (CH ₂ 0) _n + n 0 ₂ (Equation 1).

The traditional scheme of algae culture is then the following: water enriched with nutrients is introduced into the photobioreactor. In addition, C0 ₂ is introduced into the photobioreactor and the photobioreactor receives a light radiation, which provides the energy required for the reaction. In these systems, C0 ₂ comes either from atmospheric air or from gases rich in C0 ₂ (pure C0 ₂ , flue gas, synthetic air, etc.). In the case of gases rich in C0 ₂ , the injection of these gases is carried out in a compressed form. Indeed, this compression is necessary to overcome the back pressure of the culture water, but it represents an energy cost of the order of 10% or more of the energy produced by the algal biomass.

To avoid this energy-consuming compression, patent application No. US2008178739A1 proposes a solution according to which the algae are grown in a horizontal plane surmounted by a synthetic atmosphere enriched in C0 ₂ . However, this solution has two disadvantages. First, the temperature of the gases must be limited to avoid destroying the algae culture by heating the water beyond a critical value, which depends on the strain used. Moreover, in such a device, the gas / water contact surface must be sufficiently large to allow a good diffusion of C0 ₂ in the water. This last characteristic constitutes the major disadvantage of such a device. 3. Objectives of the invention

The invention particularly aims to overcome these disadvantages of the prior art.

More specifically, it is an object of the invention, in at least one of its embodiments, to provide a process for the purification of gases or fumes rich in C0 ₂ , for example a flue gas, by means of phototrophic organisms. in a photobioreactor, which is less expensive in energy than conventional methods. By "phototrophic", we mean thereafter any organism capable of photosynthesis.

Another object of the invention, in at least one of its embodiments, is to implement such a method for performing this C0 ₂ injection without gas compression.

Another objective of the invention, in at least one of its embodiments, is to implement such a method according to which the amount of CO ₂ injected into the photobioreactor can be controlled independently of the amount of CO ₂ present in the gas. Another object of the invention, in at least one of its embodiments, is to implement such a technique that allows to obtain a better purification performance and this for a lower cost than conventional solutions.

4. Presentation of the invention

The invention relates to a gas purification process comprising C0 ₂ using phototrophic organisms, comprising the following steps:

a) supply of water from a source of water;

b) capturing and washing the gas in an absorber comprising at least a portion of the water so as to obtain an aqueous solution of CO ₂ ;

c) from at least a portion of the water, preparing an aqueous solution comprising nutrients;

d) injecting into a photobioreactor comprising the phototrophic organisms of at least a portion of the aqueous CO ₂ solution and at least a portion of the aqueous solution comprising the nutrients;

e) illumination of the photobioreactor contents by light radiation.

Of course, steps (b) and (c) can be implemented in any order, they can be implemented simultaneously or be implemented in parallel. Moreover, the portion of the water used in step (b) and the portion of the water used in step (c) may be distinct, or totally or partially merged.

The term "photobioreactor" any type of container or lagoon, whether closed or open (a closed lagoon may be, for example, a lagoon covered with a greenhouse), which allows the cultivation of phototrophic organisms.

The general principle of the invention is based on the introduction into the photobioreactor of an aqueous solution of CO ₂ obtained from the gas comprising CO ₂ , and not on the direct introduction of the gas into the photobioreactor. Thus, thanks to the method according to the invention, it is not necessary to perform a gas compression, which allows substantial savings in energy.

Advantageously, according to this method, the uptake of C0 ₂ from the gas comprising C0 ₂ , carried out during step (b), is decoupled from the injection of the solution obtained into the culture medium during the step ( d). The expression "culture medium" designates the overall aqueous solution contained in the photobioreactor (comprising at least a portion of the aqueous nutrient solution and at least a portion of the aqueous CO ₂ solution) as well as the phototrophic organisms contained in the photobioreactor.

Thus, the invention is based on an approach quite new and inventive capture C0 ₂ and C0 ₂ contribution to fixing by phototrophic organisms. Preferably, the process may comprise a step of regulating the CO _{2 content} in the overall aqueous solution contained in the photobioreactor: the CO ₂ concentration in the photobioreactor can be adjusted independently of the production of the gas comprising CO ₂ . Thus, by following the needs of the phototrophic organisms, an optimal crop yield of the phototrophic organisms is obtained, so that the consumption of CO ₂ is maximal, which makes it possible to increase the efficiency of the purification process according to the invention.

Advantageously, the above-mentioned regulation step comprises a step of temporarily storing at least a portion of the aqueous C0 ₂ solution. Since the injection of C0 ₂ into the culture medium can be decoupled from its uptake from the gas comprising C0 ₂ , the instantaneous flow rate of C0 ₂ injected into the photobioreactor can be controlled independently of the C0 ₂ flow rate present in the gas comprising the C0 ₂ . Thus, the invention allows continuous gas treatment, even if the supply of CO ₂ to the culture medium is not continuous. According to a preferred embodiment of the invention, the gas comprising C0 ₂ can come from industrial processes. Thus, the invention may also relate to lime kilns or glass furnaces, and in particular to oxy-combustion furnaces.

According to an advantageous implementation of the invention, the water contained in the photobioreactor is recycled in order to generate at least a portion of said water source. Thus, the amount of water needed is minimal.

According to a variant of the invention, each of steps (b) and (c) can be divided into a sequence of substeps, said substeps of steps (b) and (c) being interposed.

According to an embodiment according to the invention, step (d) comprises the following steps:

premixing said at least a portion of the aqueous CO ₂ solution with said at least a portion of the aqueous solution comprising the nutrients;

injection of the resulting solution of the premix into the photobioreactor. Thus, for example, the nutrient composition of the culture medium can be adjusted independently of its content of CO ₂ , the aqueous nutrient solution and the aqueous solution of CO ₂ being all the same prepared simultaneously. This preparation in parallel followed by a premixing allows a single injection of liquid into the photobioreactor, which can save time and reduce disturbances in the culture medium.

According to an advantageous variant of the invention, recovery by extraction of at least a portion of the metabolic oxygen produced by the phototrophic organisms in the photobioreactor can be envisaged. According to the invention, the term "phototrophic organisms" may designate by way of examples and in a nonlimiting manner algae, micro-algae, bacteria. The invention also relates to mixtures of one or more species of the aforementioned organisms.

According to the invention, the aqueous CO ₂ solution comprises CO ₂ which can be in three forms: dissolved CO ₂ , hydrogencarbonate (hereinafter referred to as HCO 3 ^- ), carbonate (hereinafter referred to as CO ^{3 -} ). According to the invention, the C0 ₂ provided in the photobioreactor during step (d) is in at least one of these three forms.

According to a particular embodiment, the invention also relates to a gas purification device comprising C0 ₂ by means of phototrophic organisms comprising:

a) means for supplying water from a source of water;

b) means for capturing and washing the gas in an absorber comprising at least a portion of the water so as to obtain an aqueous solution of CO ₂ ; c) means for preparing, from at least a portion of the water, an aqueous solution comprising nutrients;

d) photobioreactor injection means comprising the phototrophic organisms of at least a portion of the aqueous CO ₂ solution and at least a portion of the aqueous solution comprising the nutrients;

e) means for illuminating the content of the photobioreactor with light radiation.

The advantages of the devices are the same as those of the processes: they are not detailed further.

According to a preferred embodiment of the invention, the device comprises means for regulating the CO _{2 content} in the overall aqueous solution contained in the photobioreactor.

Advantageously, the regulating means comprise means for temporarily storing at least a portion of the aqueous C0 ₂ solution. According to an advantageous implementation of the device according to the invention, the gas comprising CO ₂ comes from an oxy-combustion furnace.

Advantageously, the device comprises means for recycling the water contained in the photobioreactor in order to generate at least a portion of said source of water.

According to a preferred embodiment, the means b) and c) are activated in a determined sequence according to which the activations of the means b) and c) are intercalated.

According to a variant of the invention, the means d) comprise:

means for premixing said at least one portion of the aqueous CO ₂ solution with said at least one portion of the aqueous solution comprising the nutrients;

means for injecting the resulting solution of the premix into the photobioreactor.

According to an advantageous implementation of the invention, the device comprises means for extracting at least a portion of the metabolic oxygen produced by the phototrophic organisms in the photobioreactor.

According to a variant of the invention, the phototrophic organisms comprise at least one of the following organisms:

- an algae;

a micro-algae;

a bacteria.

According to an embodiment according to the invention, the means d) comprise means for supplying the photobioreactor C0 ₂ in dissolved form.

5. List of figures

Other features and advantages of the invention will appear more clearly on reading the following description of preferred embodiments, given as simple illustrative and non-limiting examples, and the appended figures, among which: Figure 1 shows a synoptic of the traditional process of algae culture;

FIG. 2 illustrates an embodiment of the process according to the invention in which the preparation of the aqueous nutrient solution (step (c)) is carried out before obtaining the aqueous CO ₂ solution (step (b)); FIG. 3 illustrates an embodiment of the process according to the invention in which the obtaining of the aqueous solution of CO ₂ (step (b)) is carried out before the preparation of the aqueous solution of nutrients (step

(vs)) ;

FIG. 4 illustrates an embodiment of the method according to the invention in which the injection of C0 ₂ necessary to obtain an aqueous solution of C0 ₂ (step (b)) and the injection of the nutrients necessary for the production of an aqueous solution of nutrients are performed (step (d)) simultaneously or intercalated in the same portion of water; FIG. 5 illustrates an embodiment of the process according to the invention in which the obtaining of the aqueous CO ₂ solution (step (b)) and the preparation of the aqueous nutrient solution (step (c)) are carried out in parallel, and the injection of the aqueous CO ₂ solution and the injection of the aqueous nutrient solution into the photobioreactor during step (d) can be simultaneous, successive or intercalated;

FIG. 6 illustrates an embodiment of the process according to the invention for obtaining the aqueous CO ₂ solution (step (b)) and the preparation of the aqueous nutrient solution (step (c)) are carried out in parallel , and the solutions obtained are premixed so as to obtain a single solution comprising CO ₂ and nutrients, which is then injected into the photobioreactor;

FIG. 7 gives the variations of concentration of the different forms of CO ₂ present in the aqueous solution of CO ₂ as a function of the pH;

Figure 8 shows a block diagram of the claimed process.

6. Description of at least one embodiment of the invention With Figure 1 is illustrated the traditional scheme of algae culture in photobioreactors. Water 103 enriched with nutrients 104 is introduced into the photobioreactor 105. Furthermore, C0 ₂ 101 is introduced into the photobioreactor 105. In addition, the photobioreactor 105 receives a light radiation 102, which provides the energy required for the photobioreactor 105. reaction. In this system, C0 ₂ 101 is introduced directly into the photobioreactor 105.

The general principle of the invention is based on the decoupling of the C0 ₂ uptake from the gas, absorbed during step (b), of its injection into the culture medium during step (d). This decoupling is illustrated in FIGS. 2 to 6, where it can be seen that, contrary to FIG. 1, the C0 ₂ 201; 301; 401; 501; 601 is not introduced directly into the photobioreactor 205; 305; 405; 505; 605.

FIG. 2 shows a purification method according to a first embodiment: nutrients 204 are introduced into a portion of water coming from a water source 203 so as to obtain an aqueous solution comprising nutrients . Then this aqueous nutrient solution is enriched in C0 ₂ 201 from gases comprising CO ₂ , and the resulting aqueous solution is introduced into the photobioreactor 205 which comprises phototrophic organisms.

In FIG. 3, CO ₂ 301 is introduced into a portion of water 303 so as to obtain an aqueous solution of CO ₂ . Then this aqueous C0 ₂ solution is enriched in nutrients 304, and the resulting aqueous solution is introduced into photobioreactor 305 which comprises phototrophic organisms.

The passage from FIG. 2 to FIG. 3 is obtained by reversing the steps for obtaining the aqueous CO ₂ solution (step (b)) and the step of preparing the aqueous nutrient solution (step (c)). )).

FIG. 4 is the limiting case between FIGS. 2 and 3. According to a variant of the embodiment illustrated in FIG. 4, the nutrients 404 and the CO ₂ 401 can be introduced simultaneously into the same portion of water 403, then the The resulting aqueous solution is introduced into photobioreactor 405. Steps (b) and (c) are then simultaneous and "fused". According to another variant of the mode of 4, the injection rate 409 of the nutrients in the water portion and the C0 ₂ injection flow rate 408 in the same portion of water can be jerky, so that in fact each of the steps of obtaining the aqueous solution of CO ₂ and of preparing the aqueous solution of nutrients are cut into substeps, said substeps thus being "interleaved".

According to an embodiment shown in FIG. 5, the step of obtaining the aqueous CO ₂ solution (step (b)) and the step of preparing the aqueous nutrient solution (step (c)) can be performed in parallel. There is shown a particular case where there is a water reserve 503 (for example a tank) between the water source 500 and the photobioreactor 505. In the embodiment shown, parallel to the capture of the gas and the preparation of the aqueous solution of CO ₂ 501 with a portion of water of the water reserve 503, an aqueous solution comprising nutrients 504 is prepared with a portion of water of the water reserve 503 different from the first portion of water. 'water. Each of the solutions is separately injected into photobioreactor 505 comprising the phototrophic organisms. Again, the injections may be successive (injection 508 of the aqueous solution of CO ₂ before injection 509 of the aqueous solution comprising nutrients, or injection 509 of the aqueous solution comprising nutrients before injection 508 of the aqueous solution of C0 ₂ ), or the injections can be simultaneous (508 and 509 are performed at the same time), or the injections can be interspersed (the arrows 508 and 509 representing jerky flow rates).

The embodiment illustrated in FIG. 6 can be considered as a special case of the embodiment shown in FIG. 5, in which the aqueous solution of CO ₂ 601 and the aqueous solution comprising nutrients 604 are prepared in parallel, then mixed and finally injected into the photobioreactor 605 comprising the phototrophic organisms.

In all cases, the content of the photobioreactor is illuminated by a light radiation 202; 302; 402; 502; 602 which provides the energy necessary for the photosynthesis reaction. The products obtained are organic matter called "biomass"206;306;406;506; 606 and oxygen 0 ₂ 207; 307; 407; 507; 607. Biomass and oxygen can be extracted from the culture medium and recovered.

After cultivation, the phototrophic organisms can be harvested continuously or by spot samples, for example by traditional methods such as flocculation followed by filtration and drying. The removal of at least a portion of the culture medium and its treatment to recover the biomass may be called "biomass extraction". These samples can lead to water losses which will be preferentially offset by the addition of make-up water.

Illumination by light radiation 202; 302; 402; 502; 602 can be provided by a source of natural light, that is to say by the Sun.

The lighting can also be artificial, for example with lamps comprising a halogen bulb or a bulb based on light emitting diodes ("LEDs").

Preferably, the water source is controlled to ensure that the amount of harmful elements (especially toxic) phototrophic organisms is below a predetermined threshold. For the alga Chlorella vulgaris, for example, values derived from "Tolerance of Chlorella vulgaris for metallic and non-metallic ions" by E. Den Dooren De Jong, Antonie van Leeuwenhoek, vol. 31, pp. 301-313 (1965), and repeated in the following table:

Salt tested Concentration the most Concentration

high tolerated in the lowest experimental conditions (g at / L)

in the article (g

atom / L)

Sodium NaF 0.048 0.072

NaCl 0.59 0.68

MgS0 Magnesium ₄ * 7H ₂ 0 0.98 1.23

Chrome CrCl ₃ 0.0032 0.0064

Iron FeCl ₃ aq 0.003 0.006 Nickel Ni (N0 ₃ ) ₂ * 6H ₂ 0 6.9 10-6 17 10-6

Zinc ZnS0 ₄ * 7H ₂ 0 0.0017 0.0035

Lead Pb (N0 ₃ ) ₂ 0.002 0.003

Aluminum A1C1 ₃ * 6H ₂ 0 0.002 0.004

Mercury HgCl ₂ 0.000018 0.000037

The water source may be city water, river or canal water, rainwater, demineralized water, or bubbled city water. of air for removing one or more toxic elements for certain strains of phototrophic organisms, such as for example chlorine.

It is possible to set up a water recycling system as illustrated in FIG. 5. During the extraction of at least a portion of the biomass 506 by taking a portion of the culture medium included in the photobioreactor 505, a portion of water 510 can be recovered. After cleaning, this portion of water can be returned to the water reserve 503. Indeed, it can implement to do this a pump 511 connected between the photobioreactor 505 and the water reserve 503. This recycling system saves water. Only the losses of water, due for example to evaporation, or to the extraction of biomass, can then be compensated by providing a portion of water called "make-up water" 512.

According to the invention, the CO ₂ necessary for photosynthesis is supplied to the culture medium in the form of an aqueous solution of CO ₂ .

The dissolution of C0 ₂ gas 201; 301; 401; 501; 601 in water 203; 303; 403; 503; 603 corresponds to Y equation 2:

C0 ₂ (g _az ) → C0 ₂ (dissolved) (equation 2)

It obeys Henry's law in Equation 3:

[C0 ₂ (dissolved)] = Pco ₂ (gas) / H 2 (equation 3)

where [C0 ₂ (dissolved)] denotes the concentration of C0 ₂ dissolved in water, H _C o ₂ the Henry's constant for C0 ₂ , and p _C o ₂ (gas) the partial pressure in C0 ₂ of the phase gas. Then the dissolved C0 ₂ reacts with H ₂ 0 water to form HC0 ₃ ^" and C0 ₃ ^{2 ~} and the dissolution responds to the equilibria given by the following equations (4) and (5):

C0 ₂ (dissolved) + H ₂ 0 → HCO ₃ + H ⁺ (equation 4)

HC0 ₃ → C0 ₃ ² + H ⁺ (Equation 5)

The aqueous solution of CO ₂ comprises CO ₂ which can be actually three forms:. Dissolved CO ₂ (703), hydrogen carbonate HC0 ₃ ^"(704), and carbonate C0 ₃ ^{2 ~} (705) the major form is This figure shows the concentration of the different forms of CO ₂ that may exist in the aqueous solution of CO ₂ as a function of the pH: the abscissa axis 701 gives the values of the pH value (as illustrated in FIG. pH, and the y-axis 702 gives the concentration (in μιηοΐ / kg) of each form of CO ₂ present in the solution.

The necessary CO ₂ 201; 301; 401; 501; 601 can come from industrial gases, such as flue gases from glass furnaces or lime kilns, which emit a lot of CO ₂ .

Oxy-combustion furnaces, which use pure oxygen as the oxidant (rather than just air), produce gases that are particularly rich in CO ₂ and depleted of by-products, which makes treatment easier. Indeed, having a concentrated CO ₂ can increase the yield of the process according to the invention, and this at least for two reasons:

On the one hand, if the CO ₂ partial pressure is high, then the dissolved CO ₂ concentration is high according to Equation 3 and the dissolution rate of CO ₂ gas in water ([dissolved C0 ₂ ] / [C0 ₂ gaseous supplied]) is going to be big.

On the other hand, with a high CO ₂ partial pressure, for a unit rate of CO ₂ (of 1 kg / h for example), the total flow of gas will be less important. So with CO ₂ -rich gases, the volume of gas to be treated will be lower than for gases that are low in CO ₂ . This may allow for example to reduce the volume of equipment, including the device for dissolving CO ₂ in water.

The gases comprising the CO ₂ can be cleaned before the step of dissolving C0 ₂ gas 201; 301; 401; 501; 601 in water 203; 303; 403; 503; 603. The absorber used to capture these gases may consist of two parts that may or may not be separate: a cleaning device and a device for dissolving CO ₂ gas in water. For example, the depollution methods traditionally employed in the glass or lime industry may be used: the gases comprising CO ₂ may pass through a bag filter, on an electro-filter which makes it possible to remove particles, by example of heavy metals (such as Hg, Cr, Ni, Zn, Pb), then on a DeSOx device (to remove sulfur oxides) and a DeNOx catalyst (to remove nitrogen oxides).

Finally, in the invention, the gas comprising CO ₂ is no longer in direct contact with the culture medium. However, the oxygen production by photosynthesis takes place only in this medium. If it is considered that an aqueous solution is injected into the culture medium comprising only pure C0 ₂ dissolved gas and that it is totally absorbed by the phototrophic organisms (according to equation 1) or that the C0 ₂ non consumed by the phototrophic organisms remains in solution, then the only gas leaving the photobioreactor will be Γ0 ₂ metabolic. If the photobioreactor is closed, we can consider recovering this 0 ₂ metabolic 207; 307; 407; 507; 607.

The temperature of the culture medium depends on the species of phototrophic organism used. For Chlorella vulgaris algae for example, it is around 28 ° C. It is then necessary to cool the gas comprising CO ₂ . As an indication, the temperature of the gases at the outlet of a glass furnace is of the order of 220 ° C and the temperature of the gases at the outlet of a lime kiln is of the order of 150 ° C.

This can be done by traditional techniques, for example by means of a heat exchanger, the cold source can be the source of water 500. The heat exchanger can also be the device 513 for dissolving C0 ₂ gas in the water itself. Conversely, the heat of the gases comprising CO ₂ can be used to heat the culture medium if it is too cold (for example in winter).

The dissolution of CO ₂ gas 502 in the water explained above can be carried out by means of various devices 513 for dissolving CO ₂ gas in water, among which mention may be made of a bubble column, a stirred tank (magnetic by example), a plate column (perforated or cap), a packed column (co- or countercurrent), a Venturi, a spraying column, a film column.

The use of a "Amazon" type film column (marketed by the company Toussaint-Nyssenne) makes it possible, in addition to the dissolution of C0 ₂ in water, the elimination of dust, and the exchange of heat.

After this step, an aqueous solution of C0 ₂ is thus obtained. Advantageously according to the invention, the photo trophic organisms are never in direct contact with the C0 ₂ gas. Thus phototrophic organisms are not subject to shocks from gas bubbles and are not stressed.

The decoupling of the capture of C0 ₂ from the gas, carried out during step (b), of its injection into the culture medium during step (d) also makes it possible to carry out a storage of the C0 ₂ reserve. present in the water in dissolved form, for example in a buffer tank 514 (shown in FIG. 5) inserted between the device 513 for dissolving C0 ₂ gas in water and the photobioreactor 505. Thus, the supply of C0 ₂ in the culture medium can be regulated according to the needs. For example, it is conceivable to insert, between the buffer tank 514 and the photobioreactor 505, a pump 515 whose flow rate is adjustable, which makes it possible to adjust the amount of C0 ₂ in the culture medium. It is also possible to dilute the culture medium by adding make-up water 512. The requirements for C0 ₂ can be estimated by measuring the concentrations of HCO ₃ ^" and CO ₃ ^2" , for example with an automatic titrator of Applikon '(marketed by Metro hm). Another advantage of storing C0 ₂ in the form of an aqueous solution lies in its routing to photobioreactors 205; 305; 405; 505; 605. It is indeed easier to transport liquids than gases (transport by simple gravity for example), especially since the distance to be traveled is large (especially in the case of a field of about photobioreactors of several hectares). This translates into substantial cost savings.

In addition, a filtration after the dissolution of CO ₂ gas in water decoupled from the injection into the culture medium, for example with a filter 516 (placed between the device 513 for dissolving CO ₂ gas in water and the photobioreactor 505, or, where appropriate, between the buffer tank 514 and the photobioreactor 505), makes it possible to recover insoluble salts (such as CaCO ₃ , MgCO ₃ , etc.) and thus prevent their contact with the phototrophic organisms. In a traditional process such as that shown in Figure 1, these salts would have precipitated in the culture medium and mixed with the phototrophic organisms.

In the same way that one can regulate the supply of C0 ₂ 501 in the culture medium, the supply of nutrients 504 can be controlled. Nitrates are traditionally used as an indicator of the average level of nutrients, this control can be done by means of a measurement of the amount of nitrates in the overall aqueous solution. The additional supply of nutrients can then be achieved using a metering pump 517 placed between the nutrient store 504 and the photobioreactor 505.

A particular example of a gas purification device comprising C0 ₂ by means of phototrophic organisms according to the invention is now described.

Culture tests were carried out with algae of the order Chlorococcales, family: Chlorellaceae, genus: Chlorella, species: vulgaris (hereinafter referred to as "Chlorella vulgaris") in an open photobioreactor in glass size 85 * 5 * 280 cm (ie a volume of 1 19L) made with 12mm thick glass sheets glued, the seal being provided by an O-ring. The photobioreactor is located in a greenhouse and is filled with 112L of nutrient-enriched demineralized water so as to obtain an M8 culture medium whose macro- and micronutrient composition is indicated in the following tables:

The temperature of the reactor is ideally maintained around 27.5 ° C (+/- 2.5 ° C), which is the optimum temperature for Chlorella vulgaris, by means of a thermally insulated greenhouse with air conditioning and heat exchanger. internal heat to the photobioreactor.

Illumination is provided by natural light (ie in Belgium: 125W / m ² / year on average by counting the hours of night). In this example, the addition of C0 ₂ to the culture medium is carried out in the form of an aqueous solution containing hydrogen carbonate ions HCO ₃ ^" , in this case for example with an aqueous solution of NaHCO ₃ . Such a solution makes it possible to simulate the dissolution of CO ₂ gas in water and results in an aqueous solution of CO ₂ which can be assimilated to that which would be obtained by the process according to the invention.

The step of dissolving CO ₂ gas in demineralised water was also carried out with a 513 bullant-pilot device made of glass, 10 cm in diameter and 54 cm in height; its volume of work is 4 L. The tests were conducted with a volume of work of 3 L. A flow of gas of 600 mL / min containing 33% of C0 ₂ in the air (which can be likened to the composition of gases from an oxy-fuel glass furnace) is introduced by 16 holes 1.5 mm in diameter. The velocity of the gas through a hole is about 0.35 m / s. A mixer with 4 vertical blades rotates at a speed of 12000 rpm to destroy coalescing bubbles and reduce their diameter.

The yield of the dissolution, obtained by calculating the ratio [dissolved CO2] / [C0 ₂ introduced] is of the order of 55%.

By neglecting the degassing of the dissolved CO ₂ (at the photobioreactor 505, and possibly at the buffer tank 514) and assuming that the phototrophic organisms are synchronized with the device 513 for dissolving CO ₂ gas in water, ie the all the C0 ₂ dissolved in water by the above-mentioned device is consumed by the phototrophic organisms, then the efficiency of the C0 ₂ absorption process by the phototrophic organisms is the yield of the dissolution of C0 ₂ gas in water.

Under the conditions described above, the concentration of algae stabilizes at 1 g / l. To extract biomass 506, a portion of the culture medium can be sampled (punctually or continuously) and then subjected to a treatment comprising filtration, flocculation and drying steps.

The volume of water can be kept constant by the addition of make-up water 512 in the photobioreactor 505 to compensate for the losses due to evaporation and samples of culture medium.

In summary, one can compare the composition of the combustion gas of a glass furnace after a traditional treatment currently used in the glass industry without purification process by phototrophic organisms, with the composition of this gas after treatment by the process purification according to the embodiment of the invention described above. Traditional treatment consists of a simple cleaning of the gas. First this gas passes electro-filters to remove dust and undergo a DeSOx treatment to remove sulfur oxides (for example by adding CaCO ₃ in an aqueous medium, depending on the reaction: CaCO ₃ + SO ₂ ^→ CaSO ₃ + CO ₂ ), and the resulting gas passes over a DeNOx catalyst to remove the nitrogen oxides (for example by injecting NH ₃ in the form of NH ₄ OH on a ceramic honeycomb matrix which catalyzes the oxidation degradation reaction. of nitrogen in H ₂ 0, 0 ₂ and N ₂ .

The values are listed in the following table:

In this example, the gas purification process comprising CO ₂ according to the invention makes it possible to reject 50% less CO ₂ in the atmosphere than by the conventional method. In connection with FIG. 8, a gas purification process comprising C0 _{2 is described} using phototrophic organisms. This method comprises a step 801 for supplying water from a water source; a step 802 of collecting and washing the gas in an absorber comprising at least a portion of the water so as to obtain an aqueous solution of CO ₂ ; a step 803 of preparing, from at least a portion of the water, an aqueous solution comprising nutrients; a photobioreactor injection step 804 comprising the phototrophic organisms of at least a portion of the aqueous CO ₂ solution and at least a portion of the aqueous solution comprising the nutrients; a step 805 for illuminating the contents of the photobioreactor with light radiation. Of course, the invention is not limited to the embodiments mentioned above.

In particular, the skilled person may provide any variant in the choice of the species of algae or micro-algae or more generally phototrophic organism. In addition to the Chlorella vulgaris mentioned here, it is possible, for example and without limitation, to use Chlorella sorokiniana, Dunaliella tertiolecta, Dunaliella salina or Haematococcus pluvialis. A mixture of several species can also be used. The phototrophic organism may also be a bacterium, such as for example a cyanobacterium, such as Spirulina platensis.

The invention applies of course, also to closed reactors, and lagoons (open or closed).

Likewise, the invention is not limited to a batch culture and also applies to a continuous culture.

In addition, the invention does not apply solely to the treatment of flue gases from glass or lime furnaces, but also to any type of gas or fumes comprising C0 ₂ , such as air combustion gases or fumes, for example industrial.

Claims

A method of purifying gas comprising C0 ₂ using phototrophic organisms comprising the steps of:

a) supply (801) of water (203; 303; 403; 503; 603) from a water source

b) capturing and washing (802) the gas in an absorber comprising at least a portion of the water so as to obtain an aqueous solution of CO 2; c) from at least a portion of the water, preparing (803) an aqueous solution comprising nutrients (204; 304; 404; 504; 604);

d) injecting (804) into a photobioreactor (205; 305; 405; 505; 605) comprising the phototrophic organisms of at least a portion of the aqueous CO 2 solution and at least a portion of the aqueous solution comprising the nutrients ;

e) illuminating (805) the contents of the photobioreactor with light radiation (202; 302; 402; 502; 602);

steps (b) and (c) can be inverted or simultaneous.

2. Method according to claim 1, characterized in that it comprises a step of regulating the CO _{2 content} in the overall aqueous solution contained in the photobioreactor (205; 305; 405; 505; 605).

3. Method according to claim 2, characterized in that the regulating step comprises a step of temporary storage of at least a portion of the aqueous solution of C0 ₂ .

4. Process according to claim 1, wherein the gas comprising CO ₂ (201; - combustion.

5. Method according to any one of claims 1 to 4, characterized in that the water contained in the photobioreactor (205; 305; 405; 505; 605) is recycled to generate at least a portion of said water source.

6. Method according to any one of claims 1 to 5, characterized in that each of steps (b) and (c) is divided into a sequence of substeps, said substeps of steps (b) and (c) being interspersed.

7. Method according to any one of claims 1 to 6, characterized in that step (d) comprises the following steps:

injection of the resulting solution of the premix into the photobioreactor.

8. Process according to any one of claims 1 to 7, characterized in that it comprises a step of extracting at least a portion of the metabolic oxygen (207; 307; 407; 507; 607) produced by phototrophic organisms in the photobioreactor (205; 305; 405; 505; 605).

9. Process according to any one of claims 1 to 8, characterized in that the phototrophic organisms comprise at least one of the following organisms:

- an algae;

- a micro-algae;

- a bacteria.

The method of any one of claims 1 to 9, wherein the CO ₂ (201; 301; 401; 501; 601) is supplied to the photobioreactor (205; 305; 405; 505; 605) at step (d) in dissolved form.

11. A gas purification device comprising C0 ₂ by means of phototrophic organisms comprising:

a) means for supplying water (203; 303; 403; 503; 603) from a source of water; b) means for capturing and washing the gas in an absorber comprising at least a portion of the water so as to obtain an aqueous solution of CO 2;

c) means for preparing, from at least a portion of the water, an aqueous solution comprising nutrients (204; 304; 404; 504; 604); d) injection means in a photobioreactor (205; 305; 405; 505; 605) comprising the phototrophic organisms of at least a portion of the aqueous CO 2 solution and at least a portion of the aqueous solution comprising the nutrients;

e) means for illuminating the content of the photobioreactor with light radiation (202; 302; 402; 502; 602).