IT202000029957A1 - METHOD FOR PURIFICATION OF THE AIR AND SIMULTANEOUS PRODUCTION OF O2 THROUGH ALGAL CULTURE - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION having the title

?Method for air purification and simultaneous production of O2 by algal culture?

FIELD OF THE INVENTION

The present invention is part of the field of air purification in internal and/or domestic environments and relates to a method for air purification and simultaneous photo-conversion of carbon dioxide to oxygen by exploiting a photosynthesis process of a algal culture.

STATE OF ART

Nowadays the conditions of livability? within a closed environment are becoming more and more? subject of research and technological development, especially in the light of an increasingly wide spread of modalities working conditions such as smart working (or agile work), which allows the worker to fulfill his job duties, for example through remote access from the company computer, without the need to to go to the office. Basically, the domestic environment increasingly assumes the connotation of a real work station. Therefore, the improvement of livability conditions? within these environments? become an essential parameter to ensure the health of the worker. In particular, the quality of the air breathed ? one of the fundamental parameters to determine the conditions of livability? of an environment. It is underlined, in fact, that the quality of the air breathed ? a recurring theme in the studies on the quality? of the life of the population. Several studies have shown that the level of pollutants that accumulate in an enclosed space can be equal, if not even greater, than that present in the external environment. This problem assumes particularly evident connotations not only in particularly industrialized urban conglomerates but also in the cities? in which the multitude of circulating vehicles leads to a?High quantity? of pollution, the well-known smog. It is estimated that more than 20,000 people die every day from urban pollution. The activities in fact, man-made substances release toxic substances into the air, responsible for a total of 12.5% of all deaths in the world.

So, the increasingly high attention to quality of living conditions, and the consequent interest in improving livability? of both domestic and work environments, have led to the development of methods increasingly? advanced to try to remove, or at least render harmless, the substances harmful to human health present in the air.

At present, methods and devices based on physical filtering, electronic filtering or gas phase filtering technologies are used in the domestic air purification sector. Examples of these technologies are, respectively, HEPA filters, air ionizers, and activated carbon filters. In addition, other domestic air purification strategies make use of the properties? photocatalytic titanium dioxide. In particular, titanium dioxide, in the presence of UV radiation, capable of photocatalytically destroying the polluting substances present in the air, degrading them to H2O and CO2.

Other solutions are instead based on the so-called ?water revitalizers?, i.e. tanks filled with water that take advantage of the generation of a slight wave motion in order to favor the water-air exchange surface and thus retain the water? the pollutants present in the latter. Finally, another technological solution used mainly on an industrial level is based on the use of an algal culture in a continuous system, in large tanks of water which exploits solar radiation in order to purify the air from pollutants.

One of the most common drawbacks of such methods of the known art? however the poor adaptability? to the different environments in which they can be used. In fact, the air filtering technologies mentioned above are based on devices that are specifically sized according to the volume of the environment in which they will be arranged.

This feature strongly limits the? adaptability? and the flexibility? efficiency of the air purification method since the use of an undersized system determines a poor purification efficiency and, conversely, the use of an oversized system leads to unjustified energy waste.

Disadvantageously, moreover, the? effectiveness of the elements with property? photocatalytic used for air purification degrades rapidly resulting in recurring maintenance costs.

Furthermore, the purification methods currently available in the current state of the art have onerous costs related to their operation as well as they often employ devices with intrinsically large dimensions (due, for example, to the presence of voluminous fans for the air intake or large culture tanks) which limit their use in confined domestic environments. In fact, these devices generally cause at least partial obstruction of the light sources present inside the room itself, limiting the diffusion of light. Furthermore, another disadvantage mainly linked to systems based on the use of an algal culture concerns the costs and operations linked to keeping alive and optimizing the conditions of photosynthesis of the algal culture itself.

Therefore remains in the sector the need? to make available a method for purifying the air which is adaptable to an internal and/or domestic environment and which has low maintenance costs and prolonged efficiency over time. The present invention solves the problems of the known art by making available a method for the purification of an internal and/or domestic environment and simultaneous reduction of CO2 which, thanks to the maintenance of the algal culture under conditions of constant growth, allows to obtain optimized performance and durable over time.

SUMMARY OF THE INVENTION

The present invention relates to a method for purifying the air of an internal and/or domestic environment which exploits a process of photosynthesis of an algal culture contained within an aqueous medium. The method according to the present invention therefore makes it possible to purify the air of an internal and/or domestic environment by reducing/solubilising pollutants in the aqueous medium and photo-conversion of CO2 into O2 thanks to the photosynthesis process of the algal culture included in said half watery. The method according to the present invention also comprises stages of illumination and aeration of said aqueous medium as well as a phase of periodic maintenance of said algal culture in a state of constant growth in order to optimize its photosynthesis.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 ? a first exploded perspective view of a device 1 in accordance with a possible embodiment of the present invention; Figure 2 ? a sectional view of the device of figure 1;

Figure 3 ? an exploded perspective view of the device of figure 1. DETAILED DESCRIPTION OF THE INVENTION

For the purposes of the present invention with ?indoor environment? means a closed environment, possibly without ventilation, such as for example a room in an apartment or house (i.e. a domestic environment), an office, a gym.

The present invention relates to a method for purifying the air of an internal environment comprising the steps:

i) providing an aqueous medium comprising an algal culture;

ii) illuminating said aqueous medium with a light source;

iii) to convey a flow of air inside said aqueous medium generating a plurality? of air bubbles;

said method comprising a step of maintaining said algal culture in a state of constant growth by:

iv) periodically replacing at least 60%, preferably at least 80%, of the volume of said aqueous medium comprising said algal culture with a corresponding volume of fresh aqueous medium.

Without wanting to be bound by a specific theory, the Applicant has found that the method according to the present invention allows to purify the air of an internal environment not only by reducing any polluting agents possibly present in said air but also by means of the photoconversion of the air. carbon dioxide present in said air to oxygen. The method according to the present invention, in fact, allows to retain and break down and/or solubilize polluting agents possibly present within the flow of air conveyed in the aqueous medium, said polluting agents being for example particular and/or fine powders, preferably PM10 , PM5 or PM 2.5, or harmful gases such as formaldehyde or nitrogen dioxide.

Without wanting to be bound to a specific theory, the Applicant has found that thanks to step iii) it is possible to convey a flow of air inside said aqueous medium, generating a plurality of of air bubbles, ? Is it possible to optimize the exchange surface between the air (including the aforementioned polluting agents) and the aqueous medium, thus resulting in? in a reduction and/or solubilization more? effective.

The method according to the present invention also allows the photoconversion of the carbon dioxide present in said air to oxygen following the photosynthetic process of the algal culture which effectively sequesters the above polluting agents (including also CO2) producing oxygen and biomass.

For the purposes of the present invention, with the expression ?purification of the air of an internal environment? therefore it means not only a purification from polluting agents such as particulates, fine dust, phosphates, formaldehyde or nitrogen dioxide but at the same time also a simultaneous production of O2 from CO2 resulting in the effective reduction of the concentration of the latter in an environment interior, even in the absence of ventilation in said environment.

According to a preferred embodiment of the invention, said algal culture comprises or ? consisting of microorganisms selected from the group consisting of: microalgae of the genus Chlorella, cyanobacteria of the genus Arthrospira, green algae, red algae, brown algae, or a combination thereof.

Said microalgae of the genus Chlorella are preferably selected from the species C.vulgaris, S.sorokiniana, C.pyrenoidosa, or a combination thereof. Preferably, said cyanobacteria of the genus Arthrospira are for example cyanobacteria belonging to the species A.platensis c.d. ?Spriulina?.

In the embodiment wherein said algal culture comprises or ? constituted by a combination of these microorganisms, called algal culture? a co-culture, i.e. an algal culture in which the aforementioned microorganisms are not grown individually but are co-cultivated.

Without wanting to be bound to a specific theory, the Applicant has found that, thanks to steps i)-iv) of the method according to the present invention, the algal culture takes the form of a semi-continuous system, i.e. a system in which the algal culture is maintained in a state of constant growth, in particular thanks to the combination of phases ii) and iii) of lighting and ventilation with the specific periodic replacement, described in phase iv). Said constant growth state in fact provides that once the microorganisms have passed from the latent phase (i.e. the period taken by the microorganisms to adapt to the environment, i.e. in the case of the present invention, to the aqueous medium) to the exponential growth phase ( where the microorganisms multiply rapidly, making the most of the resources present in the aqueous culture medium) to the growth decline phase (where the multiplication rate of the microorganisms gradually begins to decrease), a substantial part of the algal culture is eliminated and replaced with fresh aqueous medium in order to prevent the microorganisms from entering the subsequent stationary and declining phases, instead restarting the cycle from the initial lag phase. Advantageously, phase iv) of the method according to the present invention can be considered as a maintenance phase that allows you to keep the algal culture in the optimal state of growth ensuring maximum effectiveness in terms of air purification and photosynthetic process for the transformation of CO2 into oxygen.

Preferably, said phase iv) ? carried out by replacing, with a periodic frequency, at least l?80%, preferably at least 90%, more? preferably between 85 and 95% of the volume of said aqueous medium comprising said algal culture with a corresponding volume of fresh aqueous medium.

For purposes of the present invention for ?fresh aqueous medium? is meant an aqueous medium, preferably water, which does not include an algal culture.

According to a particularly preferred embodiment, said phase iv)? carried out with a periodic frequency between once every two weeks and once every 8 weeks, preferably once every three weeks and once every 6 weeks.

Preferably, the aforementioned periodic frequency ? chosen on the basis of the temperature conditions of the environment in which the aqueous medium comprising said algal culture is located; these temperature conditions vary according to the various seasons of the year.

Preferably said environment ? an internal environment, preferably a home or work environment such as, for example, a room in a house or apartment, a gym, an office.

According to an embodiment, called phase iv) ? carried out with a periodic frequency ranging from once every 2 weeks to once every 3 weeks if the temperature of said room is between 25 and 40°C, preferably between 25 and 35°C.

According to an embodiment, called phase iv) ? carried out with a periodic frequency ranging from once every 8 weeks to once every 6 weeks if the temperature of said environment is between 5 and 25°C, preferably between 10 and 20°C.

According to an embodiment of the present invention, the maintenance of said algal culture in a state of constant growth? carried out by keeping the aqueous medium comprising said algal culture at an average temperature between 15 and 27°C, preferably between 18 and 24°C.

Preferably, maintaining said algal culture in a state of constant growth is carried out by maintaining the aqueous medium comprising said algal culture at a homogeneous average temperature, i.e. said aqueous medium having a homogeneous temperature distribution.

Preferably the maintenance of said aqueous medium at said average temperature, preferably homogeneous in said aqueous medium, is carried out by thermal dissipation means of the excess heat possibly produced by the light source used in phase ii) of the method according to the present invention.

According to a preferred embodiment, the plurality? of air bubbles generated by the conveyance of an air flow inside the aqueous medium comprising the algal culture according to phase iii) ? characterized in that said air bubbles have an average diameter of less than 20 mm, preferably less than 5 mm, more preferably between 0.5 mm and 5 mm.

Preferably, said flow of? air? conveyed inside said aqueous medium comprising said algal culture with a flow rate between 5 L/h and 18000 L/h for a volume of aqueous medium between 0.5 and 300 L, preferably with a flow rate between 500 L/h and 1500 L/h for a volume of aqueous medium between 2 and 25 L.

Advantageously, the aforementioned aeration conditions (in particular, the preferred size of the air bubbles and the flow rate of the air flow) make it possible to increase the interface surface between the air flow and the algal culture, increasing the efficiency of photosynthesis and, therefore, the purification of the air according to the method of the present invention. According to a particularly preferred embodiment, step ii) of illuminating said aqueous medium with a light source and/or said step iii) of conveying a flow of air inside said aqueous medium generating a plurality of? of air bubbles, ? carried out for a period of time between 12 and 22 hours, preferably between 14 and 20 hours, plus? preferably said period of time being a continuous period of time. Advantageously, said lighting conditions create a ?day-night? alternation? which is particularly preferred for the purposes of the present invention. Advantageously, said aeration conditions create convective motions within the aqueous medium which allow the algal culture to be distributed homogeneously by keeping it in suspension within said aqueous medium and avoiding its accumulation or sediment which would affect the development and growth conditions of the algal culture itself.

Preferably said light source ? choice between: sunlight, broad spectrum light, artificial light, preferably LED, plus? preferably a plurality? of LEDs, or a combination thereof. Preferably said light source ? choice of a white, yellow, red, blue light source or a combination thereof. According to a particular embodiment, the optimal lighting conditions are reached when ? employed a plurality? of LEDs, preferably called plurality? of LEDs having a total luminous flux of between 250 and 50,000 lumens, preferably 10,000 lumens. According to a particularly preferred embodiment, said light source ? a LED source, preferably a plurality? of LEDs, more preferably having a red light:blue light ratio between 1:1 and 4:1, preferably 3:1.

According to a preferred embodiment said light source, preferably said plurality? of LEDs, creates a density? of total luminous radiation inside the aqueous medium between 1000 lumen/m<2 > and 10000 lumen/m<2>, preferably between 2500 and 8000 lumen/m<2>. Without wanting to be bound to a specific theory, the Applicant has found that the steps of the method according to the present invention allow to optimize the growth and the quality of the product. of the state of life of the algal culture always keeping it in the optimal conditions of constant growth, thus resulting? in photo-conversion processes deriving from the photosynthesis of said algal culture which are also optimal.

In particular, the preferred ?day-night? alternation conditions? and the aforesaid aeration conditions, together with the temperature conditions described above and the phase iv) of periodic maintenance of the algal culture effectively allow to maintain said algal culture in the best possible conditions of constant growth and are therefore advantageous for the purposes of the present invention allowing to maximize the photosynthesis of the algal culture.

Without wanting to be bound by a specific theory, the Applicant has advantageously found that the method according to the present invention allows to accelerate the reduction of the CO2 concentration in a closed environment by 4-5 hours even in the case in which said environment is not ventilated.

The Applicant has also found that the method according to the present invention allows to convert and therefore eliminate, for each liter of aqueous medium comprising the algal culture, from 10 mg to 240 mg of CO2 every hour, for a total of 90 g? 2.1 kg of CO2 per year.

According to an embodiment of the present invention, said aqueous medium comprising said algal culture ? comprised within a container, preferably a tub, made at least partially of a transparent or translucent material, said material being preferably glass, borosilicate glass, or polymethyl methacrylate. Preferably, said container has a volume between 0.5 and 300 L, preferably between 2 and 200 L.

According to an embodiment of the present invention, step iii) ? carried out by aeration means, preferably a pneumatic pump, able to introduce an air flow comprising a predetermined quantity of air inside said aqueous medium and air diffusion means configured to receive said air flow and generate a plurality? of bubbles, preferably said diffusion means comprising an airstone or a porous body.

According to a particularly preferred embodiment, with reference to the attached drawings, the method according to the present invention ? realized by means of a device 1 comprising a light source 2 configured to generate a light signal. Furthermore, the device 1 comprises a diffuser body 3 coupled to the light source and configured to propagate the light signal.

In other words, the diffuser body 3 allows the diffusion of the light signal generated by the light source 2.

Preferably, the light source 2 ? arranged facing a base portion of the diffuser body 3.

In accordance with a possible embodiment and as illustrated in the attached figures, the light source 2 is arranged below the diffuser body 3 along a direction, preferably vertical, transversal to a support plane of the lighting device 1.

Preferably, moreover, the light source 2 can be arranged below the diffuser body 3 along a vertical direction.

Advantageously, the light source 2 can understand a plurality of LEDs ensuring the lighting device 1, besides? a greater duration of the operative life, a strong reduction of the absorbed power to parity? of luminous flux generated with respect to the other light sources forming part of the prior art.

In particular, the lighting device 1 can include a support base able to support the aforementioned plurality? of LEDs so that it faces the base portion of the diffuser body 3.

Preferably, the diffuser body 3 ? made at least partially of transparent or translucent material, for example glass, borosilicate glass or polymethyl methacrylate or the like, so as to allow effective diffusion of the light signal. In accordance with a possible embodiment and as shown in the attached figures, the diffuser body 3 has a tubular shape, extending along an axis ?Z?.

According to a purely descriptive and non-limiting form of the present invention, the diffuser body 3 can have a base diameter between 30 and 1000 mm, preferably 100, and a height between 50 and 2000 mm, preferably 370.

Preferably, during a configuration of use of the lighting device 1 the development axis ?Z? ? substantially parallel to a vertical direction so that the diffusing body 3 can guarantee a wide diffusion of the light signal. According to further possible embodiments not shown in the attached figures, the diffuser body can present a different shape, for example cubic, parallelepiped or substantially spherical, without altering the inventive concept underlying the present invention.

Furthermore, the diffuser body 3 has at least one inlet opening 4 and at least one outlet opening 5 which are operatively connected to allow the passage of an air flow.

In other words, the diffuser body 3 can? defining a containment volume 6 suitable for allowing the passage of the previously mentioned air flow.

Advantageously, the openings 4, 5 allow the circulation of a flow of air in such a way that it is purified by suitable air purification means 7 as it will be. described in detail below.

In accordance with a possible embodiment and as shown in the attached figures, the diffuser body 3 can present a tubular conformation having a first end? 8 and a second end? 9. In particular, at least one? input opening 4 can? be placed at the first end? 8 of the diffuser body 3 and at least one? outlet opening 5 can? be placed at a second end? 9 of the diffuser body 3 opposed to the first extremity? 8 and/or in correspondence with a lateral surface of the same diffuser body 3.

The device 1 also comprises air purification means 7 arranged at least partially inside the diffuser body 3 and configured to remove polluting agents present in the air flow entering inside the diffuser body 3.

Advantageously, the air purification means 7 can comprise a photobioreactor 10 able to photo-convert the carbon dioxide to oxygen and/or to purify the air flow through a process of photosynthesis of an algal culture, thus allowing advantageously the implementation of the method according to the present invention.

In particular, the diffuser body 3 can be configured to house the aforementioned algal culture within the containment volume 6. In other words, the photobioreactor 10 ? configured to purify the air flow entering the diffuser body 3 through at least one inlet opening 4. The air flow interacts with the algal culture housed inside the containment volume 10 allowing photosynthesis and is subsequently emitted, substantially free of pollutants, through at least one outlet opening 5.

Photosynthesis also contributes to the development of algal culture, which, with frequency depending on the speed of growth of the same culture, must be at least partially removed from the containment volume 6 to allow the continuation of the purification of the air.

Advantageously, said partial removal from the containment volume is equivalent to periodic maintenance of the algal culture which allows effective maintenance of the algal culture in its continuous growth phase, thus allowing a virtually unlimited life of the crop itself.

In accordance with a possible and non-limiting embodiment of the present invention, the algal culture can comprising or consisting of microalgae of the genus Chlorella, including but not limited to the species C.vulgaris, C.sorokiniana, and C.pyrenoidosa.

According to further possible embodiments of the present invention, the aforementioned algal culture can comprise or consist of cyanobacteria of the genus Arthrospira, including but not limited to the species A.platensis c.d. ?Spirulina?. Likewise, further embodiments of the present invention may include other types of photosynthetic microorganisms, including, but not limited to, cyanobacteria, green algae, red algae, and brown algae, both singly and co-cultivated without being altered. the inventive concept underlying the present invention.

Preferably, said algal culture ? as previously described. Advantageously, the inlet opening 4 obtained in correspondence with the base portion of the diffuser body 3 facilitates the diffusion of the air flow inside the algal culture, promoting an effective carrying out of the photosynthesis reactions.

Device 1 can? furthermore comprise aeration means 11 adapted to introduce a predetermined quantity? of air inside the diffuser body 3 through at least one inlet opening 4.

Advantageously, the aeration means 11 can comprise a pneumatic pump 12 able to promote the air flow to the air purification means 7.

In this way, the device 1 promotes the entry of the air flow inside the containment volume 6 ensuring reduced dimensions and limited noise pollution with respect to the devices of the known art.

Also, device 1 can? include air diffusion means 13 facing the inlet opening 4.

The air diffusion means 13 are configured to receive the air flow passing through the inlet opening 4 and generate a plurality of air flows. of bubbles having an average diameter of less than 20 mm, preferably less than 5 mm, plus? preferably between 0.5 mm and 5 mm.

In particular, the air diffusion means 13 can comprise an airstone or a porous body and, being arranged in correspondence with the inlet opening 4, receive the air flow coming, preferably, from the aeration means 11 and break it down in a plurality? of bubbles.

In this way, the diffusion means allow to increase the interface surface between the air flow and the algal culture, increasing the efficiency of the photosynthesis and, therefore, of the air purification according to the method of the present invention.

Advantageously, the device 1 can it also comprises thermal dissipation means 14 configured to dissipate a quantity? of heat generated by the light source 2 in such a way as to guarantee an algal development in accordance with specific temperature conditions and to allow the desired constant growth conditions according to the method of the present invention.

Preferably, the thermal dissipation means 14 comprise one or more? between at least one ventilation opening, able to allow an effective flow of air towards the light source 2, and/or a fan, configured to promote removal of an amount? of hot air from the vicinity of the light source 2.

Advantageously, device 1 pu? also include a command and adjustment module configured to allow the modification of one or more? operating parameters of the lighting device 1 itself.

In accordance with a purely illustrative and non-limiting form of the present invention, the command and adjustment module can allow the regulation of? intensity? and/or the wavelength of the light signal and/or pu? allow the regulation of the flow of air entering the diffuser body 3 by means of the regulation, for example, of the aeration means 11. In other words, the control and regulation module can? allow the regulation of the light signal emitted by the LEDs and the regulation of the flow rate of the air moved by the pneumatic pump 12.

It should be emphasized that these adjustments allow an effective development of the photosynthesis reactions inside the containment volume 6, preferably by regulating the algal development in such a way as to optimize the removal of the polluting agents present in the flow of air entering the diffuser body 3.

Preferably, the command and regulation module can? allow adjustment of the aforementioned operating parameters in automatic and/or manual mode thanks to the intervention of a user.

In particular, the command and regulation module can? comprising wireless interface means, for example of the bluetooth or wifi type, suitable for allowing a user to make the previously described adjustment via a remote control and/or via an app for mobile devices (for example smartphones or tablets).

In accordance with a possible embodiment and as shown in the attached figures, the device 1 can comprising a containing body 15 defining a housing suitable for at least partially housing the diffuser body and/or the light source, giving the device 1 particular structural strength and aesthetic appeal.

In particular, the containment body 15 can comprising a support portion 16 suitable for housing a respective base portion of the diffuser body 3, the light source 2 and the aeration means 11.

Preferably, the support portion 16 defines a support portion suitable for resting on a support surface for the device 1 and can include a non-slip portion designed to increase stability? of device 1.

The containment body 15 can also comprise a top portion 17.

Preferably, the top portion 17 ? fitted to the second end? 9 of the diffuser body 3 and/or has at least one opening suitable for allowing the passage of the air flow from the diffuser body 3 to an environment external to the device 1.

The support portion 16 and the top portion 17 can be made in one piece, giving the containment body 15 a highly robust monolithic structure.

According to further possible embodiments, the support portion 16 and the top portion 17 can be made separately without altering the inventive concept underlying the present invention.

Advantageously, the containment body 15 can be realized in a plurality? of different materials, for example wood, metal and/or polymeric materials, guaranteeing the device a highly flexible and highly aesthetically pleasing design.

According to one embodiment, said device 1? a lighting device.

It can therefore be observed that the present invention achieves the aims proposed by making available a method for purifying the air of an internal environment preferably by means of the device as described above. The method according to the present invention advantageously allows to increase the livability conditions? inside an environment thanks to air purification configured to remove pollutants present in an air flow that passes through it.

Advantageously, the lighting device has limited dimensions and low noise. which give it high flexibility? operational and adaptability? to the environments of use.

Advantageously, moreover, the control and regulation module allows to regulate the temperature of the algal culture and the air flow to the containment volume and, therefore, the volume of the purified air, allowing efficient adaptation of the lighting device to the environment in question. which ? willing.

Claims (10)

1. Method for purifying the air of an internal environment including the phases: i) providing an aqueous medium comprising an algal culture; ii) illuminating said aqueous medium with a light source; iii) to convey a flow of air inside said aqueous medium generating a plurality? of air bubbles; iv) periodically replacing at least 60%, preferably at least 80%, of the volume of said aqueous medium comprising said algal culture with a corresponding volume of fresh aqueous medium. 2. A method according to claim 1 wherein said algal culture comprises or? consisting of microorganisms selected from the group consisting of: microalgae of the genus Chlorella, cyanobacteria of the genus Arthrospira, green algae, red algae, brown algae, or a combination thereof. 3. A method according to claim 1 or 2 wherein said step iv) ? carried out with a periodic frequency between once every two weeks and once every 8 weeks, preferably once every three weeks and once every 6 weeks. 4. A method according to any one of the preceding claims wherein the maintenance of said algal culture in a state of constant growth is? carried out by keeping the aqueous medium comprising said algal culture at an average temperature between 15 and 27°C, preferably between 18 and 24°C. 5. Method according to any one of the preceding claims in which said bubbles have an average diameter of less than 20 mm, preferably less than 5 mm, more? preferably between 0.5 mm and 5 mm. 6. A method according to any one of the preceding claims wherein said air flow is conveyed inside said aqueous medium with a flow rate between 5 L/h and 18000 L/h for a volume of aqueous medium between 0.5 and 300 L, preferably between 50 L/h and 1500 L/h for a volume of aqueous medium between 2 and 25 L. 7. Method according to any one of the preceding claims wherein said step ii) of illuminating said aqueous medium with a light source and/or said step iii) of conveying a flow of air inside said aqueous medium generating a plurality of of air bubbles, ? carried out for a period of time between 12 and 22 hours, preferably between 14 and 20 hours, plus? preferably said period of time being a continuous period of time. 8. A method according to any one of the preceding claims wherein said light source is choice between: sunlight, broad spectrum light, artificial light, preferably LED, plus? preferably a plurality? of LEDs, or a combination thereof. 9. A method according to any preceding claim wherein said aqueous medium comprising said algal culture comprised within a container, preferably a tub, made at least partially of a transparent or translucent material, said material being preferably glass, borosilicate glass, or polymethylmethacrylate. 10. Method according to any one of the preceding claims wherein said step iii) ? carried out by aeration means, preferably a pneumatic pump, able to introduce an air flow comprising a predetermined quantity of air inside said aqueous medium and air diffusion means configured to receive said air flow and generate a plurality? of bubbles, preferably said diffusion means comprising an airstone or a porous body.