ES2909891A1 - Photobiorreactors for microalgae cultivation, aimed at different applications, related to the recovery of natural resources, within a cell economy model (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Set of photobioreactors, each of which is constituted by two flexible transparent semi -strokes, covered with a flexible concave upper cover of PVC glass, leaving an air chamber between the crop and the cover, which incorporates some co -sensors of co <sub sensors > 2 </p>, temperature, pH and conductivity, which are arranged longitudinally, and in parallel, to the base of each of the buckets in the middle zone of the crop, which allow to act before the conditions are unfavorable for The crop, allowing a better control of the operating conditions, as well as maintaining the optimal conditions of purification and growth of the algae continuously. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Photobioreactors for the cultivation of microalgae, intended for different applications, related to the recovery of natural resources, within a cellular economy model

Object of the invention

The present invention refers to a device that incorporates a microalgae cultivation system in a modular, scalable and low cost way, for the treatment of liquid effluents from agricultural-livestock or industrial establishments and the growth of microalgae with specific applications in treatments. and agricultural processes, or as a production system for agricultural biostimulants, soil regeneration systems, process water reuse, CO ² sink, aquifer recovery, always within a circular economy concept.

The invention is based on the use of a microalgae cultivation system for the production of microalgae biomass as a CO ² sink, as well as as a system for the production of agricultural biostimulants and soil regenerators while allowing cultivation through the use of liquid effluents from the production plants of agricultural products, livestock and all those related to the biotechnological and pharmacological industry through the use of microalgae as a tool.

The set uses an innovative design, photobioreactors, which are hemispherical growth trays made of flexible and transparent material for the passage of light. An adequate environment is established for the cultivation of microalgae and the treatment of water for its regeneration, while at the same time optimizing the photisynthetic processes.

The object of the invention is a modular and scalable microalgae cultivation system (using photobioreactors) to be used in applications related to agriculture, livestock farms, the agri-food industry, and all those dedicated directly or indirectly to the bio sector.

Background of the invention

Microalgae are plant microorganisms with the highest photosynthetic efficiency in nature and with a high capacity to absorb CO ² and also have the ability to absorb and/or adsorb contaminating substances present in the water, eliminating them from it. Microalgae are a natural purifier of the environment.

In cultivation, microalgae need nitrogen (N), phosphorus (P) and potassium (K), microelements and CO ² for their growth, and carry out photosynthesis releasing oxygen (O ² ), and producing from these inorganic elements , countless organic components such as sugars, lipids, carotenoids, xanthophylls, vitamins and their precursors, amino acids, hormones and their precursors, etc.

The cultivation of microalgae has a potential for application in the treatment of effluents from agricultural-livestock establishments and the food industry, rich in the aforementioned nutrients, sometimes in excess that turn them into pollutants but which can be consumed by the algae.

Through the treatment of effluents using the proposed device, for the cultivation of microalgae, a removal of the content of N and P greater than 90% is achieved. The property of microalgae to remove heavy metals from the aqueous medium is also important. Through this treatment process, non-polluting organic fertilizers are produced, favoring the reduction of CO ² emissions produced during the manufacture of inorganic fertilizers in petrochemical processes. And avoiding the escape of other greenhouse gases such as NOx and SOx.

There are various types of microalgae culture methods such as tube aces, cylindrical or large agitated culture ponds. The invention with the proposed device, based on scalable hemispherical photobioreactors, allows obtaining optimal crop performance with a low investment cost.

The object of the invention is the cultivation of microalgae, whose use is the use of residual water or water with excess nutrients, in such a way that it allows the entry of the same and also the exit as a biofertilizer, soil recuperator, with a great capacity of storage in little space, low cost, being able to operate manually and/or automated to facilitate its use. These are the characteristics that make the proposed design meet the needs of its users and improve the photobioreactors used to date.

The areas of work in this field involve fluid dynamic characterization, quantification of stress phenomena (pH, conductivity, light, etc.) and productivity.

The cultivation of microalgae needs an agitation system using blades, turbines, pumping, bubbling or aeration systems to prevent the settlement of the algae and to be able to be exposed to light with the same probability due to the turbulence caused and achieve homogeneous and intense photosynthesis. .

Taking into account the type of application, there are different types of microalgae cultivation systems, open systems where there is contact with the environment and closed or semi-closed systems where there is little contact with the environment.

Open systems include lagoons or ponds with rotating blades where light transfer is not ideal. These systems are more appropriate for the growth of algae and microalgae, since they are exposed to the atmosphere, they can become contaminated with unwanted organisms that can inhibit growth or displace the species in culture. They are very cheap systems, but they have the great disadvantage that they require large areas of land.

Among the closed or semi-closed systems, photobioreactors with different geometries and lighting sources have been used, as many vertical flat reactors with white light fluorescent lamps, reactors illuminated with diodes almost internally or internally with fiber optics, or flat inclined reactors with external solar illumination. Tubular systems, vertical or inclined tubular coils and also cylindrical. Tubular tubes can be made of glass, methacrylate, PVC or another type of transparent plastic material, but they have problems related to the physics of fluids and length limitation, due to the production of oxygen and the loss of photosynthetic efficiency until reaching the inhibition of photosynthesis from high concentrations of oxygen.

However, with the proposed invention, the photobioreactors are built with flexible and transparent material, and the optimal environment for the growth of algae is created.

This will involve a type of crop that will allow the development of a totally ecological alternative for the production of agricultural biostimulants, soil bioremediators and effluent treatment with great productive and environmental benefits.

The cultivation of microalgae is a very viable solution for treatment of agro-industrial and livestock effluents, with this treatment inorganic compounds such as P and N, which microalgae use for their growth, are eliminated. They reduce BOD and COD as well as being efficient in removing heavy metals and degrading complex compounds such as pesticides and certain drugs.

The liquids obtained from the cultivation of microalgae are colloidal and by using them for irrigation, the porosity of the soil is increased, favoring its oxygenation and the retained colloids increase the absorption of nutrients.

The increase in porosity favors the retention of rainwater, avoiding the dragging of nutrients and contamination.

The use of these liquids produced generates a phytoremediation of the soil favoring the growth of crops.

To optimize the culture conditions, and for the design of the present invention, the necessary conditions for microalgae and their development have been taken into account. For this, laboratory tests with different types of microalgae suitable for each application were necessary.

As an example we can mention the capacity of the microalgae Chioreila vuigaris that has been studied for the production of biomass and the elimination of nutrients from different wastewater. (Tam and Wong, 1989).

Using a standard culture medium. The medium was mixed with primary wastewater, secondary wastewater and oil effluent in different proportions. The biomass growth and the decrease of P and N compounds in the liquids obtained were measured in each solution.

After 13 days of culture, an increase in biomass of 1.6 g/lt was achieved, going from 2 to 5%. In the liquids obtained, a reduction of N compounds of 85% and of P compounds of 100% was achieved.

The experiments carried out showed that through the cultivation of microalgae, a very efficient purification of the effluents of mining production can be achieved. The microalgae Coeiastrum proboscideum absorbs 100% of metals such as Pb. Cd Cu and Zn have been removed by 60%. The green microalgae Dunaiiiia biocuiata have a high power to purify oil residues and insecticides such as Deltamethrin. (Cerniglia et al., 1980).

Soder et al. (1978) found that Coeiastrum proboscideum absorbs 100% of the lead from a 1.0 ppm solution within 20-23°C and approximately 90% after only 1.5 h at 30°C. Cd was slightly less efficiently absorbed, with about 60% of Cd absorbed from a 40 ppb solution after 24 h. The 'absorption' process appears to be largely passive, probably through ionic exchange in the polysaccharides of the cell wall (Soeder et al., 1978), although a slower, metabolically mediated uptake step also occurs (Khummongol et al., 1982).

The efficiency of the uptake step depends on the nature and charge of the cell wall polysaccharides. The studies by Kaplan et al. (1988) with Chlorella stigmaphora and C. salina showed that native highly charged uronic acid polysaccharides had a high Cu complex formation capacity compared to less charged C. salina polysaccharides. Mangi and Schumacher (Mangi and Schumacher, 1979) with Mesotaenium and Xue and Sigg (1990) with Chlamydomonas reinhardii obtained similar results. Maeda and Sakaguchi. (1990) have shown that Cd accumulates mainly by adsorption, while Zn is actively taken up by Chlorella vulgaris and C. homosphaera cells.

Experiments carried out for the purification and deodorization of liquid manure from livestock have given good results. The unpleasant odors of this type of fluids are due to the fact that they contain anaerobic bacteria that produce hydrogen sulfide and the medium in which they proliferate has a low amount of dissolved oxygen and an acidic pH. Tests carried out with the cultivation of Chlorella sp at temperatures of 34°C, produces an important generation of the oxygen necessary for purification and deodorization. (Oswald, 1988).

Experiments carried out in open photobioreactors for cultivation of Chlorella vulgaris in four open microalgae photobioreactors for 26 days, achieved a purification of 84% and removal of nitrates of 26%. (Lincoln and Wilkie, 1995; Lincoln et al., 1996; Olguin et al., 1997; Costa, 2006).

The production of microalgae with closed and axenic systems, such as those used in laboratories, requires a very high investment and maintenance cost, which can only be accessed by large companies, while production in low-cost open systems does not guarantee performance. nor the quality of the product.

The growth of microalgae through the consumption of nutrients such as P and N depends on many factors such as temperature, pH of the medium and lighting.

Through the proposed invention, optimal conditions such as pH, temperature, conductivity and CO ² concentration for each type of purification are given to the environment.

As it is a plant with a closed photobioreactor system or photobioreactors, contamination of the crop is avoided or greatly reduced, increasing the quality of the product and the efficiency of wastewater decontamination. Due to its geometry, it allows the cultivation of high volumes of algae in a small space, taking advantage of the environmental conditions for cultivation over a long period without the need to consume other energies. These qualities allow it to be accessible to any type of company and to be able to adapt to any place, being able to be located in areas close to the application of the fertilizer. The parameter control system also allows the decontamination efficiency to be controlled in a reliable and scalable way.

Therefore, and compared to what was previously known, the application of the device that is presented with the present invention will bring improvements in the purification of polluting effluents and the production of totally ecological fertilizers, reduction of their costs, avoiding fines due to discharges, in addition to achieving improvement of the soil and crop yields.

The use of organic fertilizers reduces the use of inorganic fertilizers, the emission of CO ² generated in their manufacture and misuse due to overfertilization, as a consequence of the deterioration of the soil and its loss of capacity to retain carbon, and the contamination of the plants. watersheds. The photosynthesis and consumption of CO ² used by this photobioreactor contribute to the reduction of the greenhouse effect.

The productivity of the device is medium high, it does not require large investments or works, and its location can be changed as necessary, facilitating the use of effluents or raw materials obtained on the farm itself and which are a waste or source of contamination for it. , such as slurry, brine, process water, etc., and its approach to the area where the processed water will be applied through the cultivation of microalgae as biofertilizer.

In short, the invention presented solves the problem of continuous microalgae cultivation, without external contamination, as it is a non-hermetic closed system, with low maintenance cost, since its semi-cylindrical and flexible geometric shape allows light to enter from all directions, only rarely needing the use of artificial light.

Explanation of the invention

The photobioreactors for the cultivation of microalgae are constituted from a set of photobioreactors, each of which is constituted by two flexible transparent hemispherical buckets, covered with a concave flexible upper cover made of PVC glass, leaving an air chamber between the culture and the cover.

It also incorporates CO ² , temperature, pH and conductivity sensors, which are arranged longitudinally, and in parallel, at the base of each one of the buckets in the middle zone of the crop.

The CO ² , temperature, pH and conductivity sensors allow to act before the conditions are unfavorable for the crop, allowing a better control of the operating conditions, as well as maintaining the optimal conditions of purification and growth of the algae continuously. .

The pH and conductivity sensor makes it possible to know and monitor these parameters so that they can be modified so that they are optimal both for the cultivation of microalgae in the effluent to be decontaminated, and in the output of the product as biofertilizer, so that it meets the ideal conditions for cultivation. agriculture in which it is going to be applied.

In addition, it allows knowing the modification of these parameters due to the growth of microalgae and the use of the elements of the effluent by them.

Each bucket has an inlet for a liquid effluent and another inlet in which the sensors are incorporated, as well as an outlet for the biofertilizer generated from the effluent, through the growth of microalgae. In the set where the sensors are located, there is such a light for the growth of microalgae, in conditions of few hours of light or low intensity light outside.

The photobioreactors also incorporate an aeration circuit, which allows CO ² to be supplied and excess O ² to be removed from the culture chambers. This circuit is carried out by means of a bubble tube, which is connected to a temperature-controlled air chamber, which also allows air to be introduced at the right temperature for optimal growth of the cultivation, and minimal temperature regulation. Said aeration circuit also incorporates a compressor, which drives the external air towards the bottom of the cultivation chambers and towards the outside in the form of a bubble, through diffusers. The regulation of this aeration circuit is independent of the control of the programmer, which will be indicated later.

Through the closed system that the set incorporates, which is not hermetic, is low cost and scalable, it is possible to achieve a culture density (litres/m ² ) equal to or greater than the system of ponds with a lighting surface three times greater .

Finally, the support for the assembly consists of a metal structure with legs and a longitudinal bar in the middle, which supports the flexible PVC glass sheet and divides it, with a hemispherical cylindrical shape; being that each upper grouping unit from a photobioreactor is controlled by a programmer, which allows it to be scalable, through the modular grouping of photobioreactors. That is, the photobioreactors can be connected to each other, in series or in parallel, and grouped in sectors, so that each higher grouping unit from a photobioreactor is controlled by the indicated programmer.

Description of the drawings

To complement the description that will be made below and in order to help a better understanding of the characteristics of the invention, according to a preferred example of its practical embodiment, a set of drawings is attached as an integral part of said description. where, by way of illustration and not limitation, the following has been represented:

Figure 1.- Perspective view of the metal structure with legs and a longitudinal bar in the middle area.

Figure 2.- Perspective view of the assembly of the photobioreactors for microalgae cultivation. Figure 3.- Perspective view of the assembly of the photobioreactors for microalgae cultivation, with a frame in which the electrical system, CO ² , temperature, pH and conductivity sensors are inserted.

Figure 4.- Perspective view of the photobioreactors for microalgae cultivation.

In the aforementioned figures, the following constituent elements can be highlighted:

1. Buckets.

2. Panel in which CO ² , temperature, pH and conductivity sensors are inserted.

3. Bubble tube.

Preferred embodiment of the invention

As a preferred embodiment of the invention, the photobioreactors for growing microalgae are provided with a set of photobioreactors, each of which is made up of two flexible transparent hemispherical buckets (1), covered with a flexible concave top cover made of glass. 600 micron PVC, which leaves an air chamber between the crop and the lid.

Photobioreactors for microalgae cultivation also incorporate a frame in which CO ² , temperature, pH, and conductivity sensors (2) are inserted, which are arranged longitudinally, and in parallel, at the base of each of the buckets. in the middle zone of the crop.

Each bucket has an inlet for the culture medium and another where the CO ² , temperature, pH, and conductivity sensors are incorporated, as well as an outlet for the culture generated from the growth of microalgae. In the set where the CO ² , temperature, pH, and conductivity sensors are located, there is a light with such characteristics, which allows the growth of microalgae in conditions of few hours of light or low intensity light outside.

The water used in the crop (residual or fertilized) is poured directly into the photobioreactor, without the need for previous water storage tanks. At the optimal moment of the crop for its use as a fertilizer, an injection pump located inside the bucket will allow the output of the product at constant pressure.

Lastly, the photobioreactors for microalgae cultivation incorporate an aeration circuit, by means of a bubble tube (3), which is connected to a temperature-controlled air chamber, in addition to the CO ² input to the system and a minimum regulation of temperature, since an air intake is produced at a standard temperature for the culture, allowing the temperature of the culture liquid medium to be lowered in situations of high temperature and raised when it is very low, helping to maintain the ideal conditions for growth microalgae and favoring the decontamination of water from agribusiness. Said aeration circuit also incorporates a compressor, which drives the external air towards the bottom of the cultivation chambers and towards the outside in the form of a bubble, through diffusers. The regulation of this aeration circuit is independent of the control of the programmer, which will be indicated later.

The assembly support consists of a metal structure with legs and a longitudinal bar in the middle area that supports the flexible PVC glass sheet and divides it (as seen in Figure 2), acquiring a hemispherical cylindrical shape, providing great stability. To the system. The simplicity of the structure, both the metal support, as well as the flexible sheet and the lid, facilitates the transportability of the whole.

The photobioreactors can be connected to each other in series or in parallel, and grouped in sectors, so that each upper unit of grouping from a photobioreactor is controlled by a programmer.

It is not considered necessary to make this description more extensive so that any person skilled in the art understands the scope of the invention and the advantages derived from it in its different applications. The materials used in the manufacture of the different parts that make it up, including the fixing elements, their dimensions, shapes or designs, will be subject to variation as long as this does not imply an alteration in the essence of the invention. The terms in which the memory has been described are to be understood in a broad and non-limiting sense.

Claims (3)

1. Photobioreactors for the cultivation of microalgae characterized by being constituted from a set of photobioreactors, each of which is constituted by two flexible transparent hemispherical buckets (1), covered with a concave flexible upper cover made of PVC glass, leaving a chamber of air between the crop and the cover; CO ² , temperature, pH and conductivity sensors, and an aeration circuit; being that the support of the assembly consists of a metal structure with legs and a longitudinal bar in the middle area, which supports the flexible PVC glass sheet and divides it, with a hemispherical cylindrical shape; being that each upper unit of grouping from a photobioreactor is controlled by a programmer. 2. Photobioreactors for growing microalgae, according to claim 1, characterized in that each bucket has an inlet for a liquid medium and another inlet in which the CO ² , temperature, pH and conductivity sensors are incorporated, also arranged longitudinally, and in parallel, at the base of each of the buckets in the middle zone of the crop, in addition to an outlet for the biofertilizer generated from the effluent, through the growth of microalgae. In the set where the CO ² , temperature, pH and conductivity sensors (2) are located, there is such a light for the growth of microalgae, in conditions of few hours of light or low intensity light outside. 3. Photobioreactors for the cultivation of microalgae, according to claims 1 and 2, characterized in that it incorporates an aeration circuit, which is carried out by means of a bubble tube (3) that is connected to a temperature-controlled air chamber, to supply CO ² and remove excess O ² from the culture chambers, and for minimal temperature regulation; Said aeration circuit incorporates a compressor, which drives the external air towards the bottom of the cultivation chambers and towards the outside in the form of a bubble, through diffusers.