CS276119B6 - A method of large-scale cultivation of photoautotrophic algae and aninines and apparatus for carrying out this method - Google Patents

Abstract

A method of large-scale cultivation of photoautotrophic algae and cyanobacteria in the open air, whereby a carbon dioxide-saturated algae suspension, enriched with the necessary nutrients, flows down the gradient surfaces. The solution further relates to the relevant device. The essence of which lies in the fact that the gradient surfaces have a slope of 1 to 2% and are provided with means for ensuring flow turbulence.

Description

The invention relates to a method for large-scale cultivation of photoautotrophic algae and cyanobacteria in the open air, wherein a carbon dioxide-saturated suspension of algae enriched with the necessary nutrients flows down the slopes, as well as to an apparatus and a method for carrying out this method.

Ways of growing microscopic algae and cyanobacteria in the open air have been evolving around the world since the 1950s. Many workplaces deal with them, because a suitable cultivation technology is a basic condition for high yields and thus economically advantageous products of algal biomaay, which is of increasing interest in the world due to its biological value. Cultivation is carried out mainly on the basis of technologies developed in Japan, Germany, Czechoslovakia (Saver et al., 1970, Algolog. Stud. 1, 111-164; Goldman et al., 1979, Mater Res. 13, 119-136; Richmond 1980 , Interdiec, Sci. Rev. 1, 68-78; Soeder 1986, Microalgal Mase Culture, 25-41) or in devices based on these systems.

The most widely used West German outdoor cultivation devices are in the shape of elliptical pools, in which a 20 to 30 cm thick layer of algal suspension is most often set in motion with paddle stirrers.

The cultivation area of the equipment developed and used in Czechoslovakia is solved completely differently. An algae suspension with a layer thickness of 5 cm flows down a slightly inclined surface (slope 3%), which can be, for example, the roof of a greenhouse (then it consists of glass panes in a steel structure) or is placed at ground level (then it is usually made of concrete adjusted). The surface is divided in the direction of inclination into strips with a width of 1 to 2 m and in them, perpendicular to the direction of flow of the suspension, they are placed at an angle of 60 ° inclined partitions, 4 cm high and 3 to 5 mm away from the bottom. The suspension flows under and above the baffles, creating an intense vortex that mixes the suspension perfectly, prevents algae from settling and ensures even exposure of the algae to sunlight. In addition, a uniform thickness of the algal suspension is achieved over the entire cultivation area, which flows down the sloping roof of the greenhouse and is collected in a collecting trough at its lower end. From there, it is led to a return line opening into a circulating pump, which continuously pushes the suspension to the upper edge of the epic area. In the case of a cultivated surface placed on the ground, the suspension is extruded to its upper edge by a pipe by means of a pump placed below the lower edge of the slope.

The main disadvantages of pool-type cultivation units are: When using the depth of the algae layer (20 to 30 cm) it is necessary to work with very thin suspensions, in which the amount of dry mass of algae does not exceed 0.3 gl "'' ·. At higher densities, the limitation of growth is manifested by the lack of photosynthetically effective radiation, which does not penetrate into the deeper layers of suepension. The low concentration of suepension makes the separation of algae very expensive, the suspension agitated by the blades ee stirs little, which limits the growth by the lack of physically dissolved CO ₂ especially in the upper, most illuminated layer of algae, flow close to laminar causes uneven speed of movement of suspension in different layer depths. Slower movement of the lower layers and suspension near the side walls of the pool results in sedimentation of algae at the bottom and increased adhesion of algae on the walls of the pool, imperfect mixing and slow movement of the suspension result in insufficient removal of oxygen generated during photosynthesis. A higher concentration, especially in the upper layer of suepension, can reduce the rate of photosynthesis and algal growth.

The disadvantages of the said Czechoslovak cultivation system lie in particular in the fact that the five-centimeter layer of the suspension represents considerable demands on the energy input required for the operation of the circulation pump on the cultivation area with a 3% slope. At a production area of 1000 m, approx. 8000 l of slurry per minute pass through the pump; the large volume of suspension (for production Unit 1000 and It is 50,000 1) represents a considerable energy consumption for aeration of the suspension, which is carried out in the collecting tank during off-cultivation; depositing individual partitions on the cultivation area is very laborious, although the optimal density of the suspension when cultivating in a five-centimeter layer of algae is 5 times higher than when cultivating in swimming pools. Separation of algae mass in nutrient solution is expensive.

These disadvantages are eliminated by the method according to the invention, the essence of which is the suepension of algae

CS 276 119 B6 flows down the slope surfaces with a slope of 1 to 2% in a turbulent flow regime, the thickness of the algal suspension layer being 5 to 30 mm.

The required flow regime in the flowing layer of the suspension was achieved by roughening (profiling) the slope surface or by means of transverse partitions.

The invention further relates to a corresponding device with slope surfaces forming a greenhouse or placed on the ground, a return pipe with a pump and a carbon dioxide choke, the essence of which consists in that the slope surfaces have a slope of 1 to 2% and are provided with means for ensuring flow turbulence.

Preferably, the slope area with its own circulation of the suspension does not exceed 500 m and the length of the cultivation strips is in the range of 30 to 60 m.

The advantages of the proposed technology resulting mainly from lower costs per unit of the product are:

in cheaper equipment design by using smaller tanks by reducing the volume of cultured algae suspension by up to 85 to 90% and by using a circulating pump with a power lower by up to 80% and lower equipment operating costs, consisting mainly of:

in reduced energy requirements for the circulation of the suspension and its aeration in the collection tanks and for the separation of biomass from the nutrient solution and the possibility of dividing the total area not exceeding 500 m, which simplifies plant operation and optimizes the cultivation regime.

A comparison of energy requirements for plant operation and flower separation is given in Table 1.

Table 1 ^{* 4}

original partition system modified bulkhead eyelet barrier-free eyetem cultivation area 1,000 m ² 2 2 x 500 m 2 2 x 500 m total volume of suspension 50 000 1 25 000 1 5 - 8,000 1 required pump power 7,500 l.min ¹ 1,600 l.min ¹ 1,600 l.min ¹ to separate 1,000 g of dry matter it is necessary to process 1,000 l of suspension 500 1 suspension 100 l of suspension

Figures 1 and 2 schematically show a device according to the invention.

The pump j. Pushes the algae suspension from the tank 6 into the distribution trough 2, from which ee is evenly distributed on the slope cultivation surface 3, along which it flows into the connecting trough

4, which transfers the euspension to the opposite slope 5. From that suspension, it flows into the tank 6 and the whole process ee is repeated continuously. The slope of the cultivation strips is either barrier-free (Fig. 1) or is equipped with transverse partitions (Fig. 2).

Example

The production strain of single-celled algae Chlorella vulgaris XYZ, used in tubes on agar media enriched with mineral nutrient solution at a temperature of 15 ° C and irradiation of 10 Wm ² FAR, is used for cultivation. FAR means photosynthetically effective radiation measured by a spectrally non-selective sensor, sensitive only in the range of 400 to 700 nm.

CS 276 119 86

The ββ culture from the agar is converted to a liquid nutrient solution of the following composition:

Compound: Concentration with mg.! ^ C0 (NH ₂ ) ₂ urea 600.00 kh ₂ after ₄ potassium dihydrogen phosphate 340.00 MgSO ₄ «7H _{; L} 0 magnesium sulphate 500.00 FeSO.aJH ^ O 4 2 ferrous sulfate 13.90 H-QO- boric acid 3.10 MnSO ₄ .4H ₂ 0 manganese sulphate 1.10 CuSO ₄ .7H ₂ 0 copper sulphate 1.25 ZnSO ₄ .7H ₂ O zinc sulphate 1.45 / NH _4/2 MO0 ₄ ammonium molybdate 1.00 CoS0 ₄ .7H ₂ O cobalt sulphate 1.40 CaCl ₂ 6H ₂ O calcium chloride 10.50

In said nutrient solution, the culture is grown in 60-liter tubular photoreactor tubes with artificial radiant energy sources at an irradiation of 80 Wm, a temperature of 28 to 30 ° C and a concentration of CO ₂ in a mixture with air corresponding to 1.5 to 2.5% of dissolved CO suspension of algae up to the density of the beginning of the stationary phase of the growth curve, i.e. 5 to 6 g < 1 “.

The 95% suspension is then transferred to a refrigerated and air tank and the growth cycle in the photoreactor is repeated. When 250 l of suspension are thus prepared, the module of the production outdoor equipment with a culture area of 500 m is inoculated by diluting the stock inoculum to a volume of 2,500 l and the density of the suspension to approximately 5 g of dry algae. m of cultivation area.

The actual photosynthetic production of algal organic matter takes place during the day so that the circulating algae suspension is exposed to sunlight on the slope.

When the amount of dry algae mass per unit volume reaches a specified value, which is a function of the thickness of the suspension layer and the intensity of the FAR incident on the surface of the cultivated algae layer (FAR absorption rate), part of the mass is separated. The separation ae is carried out as required so that the density of the suspension is in the range of Λ to 60 g.m, depending on the period of the growing season. Practically about 20 to 30% of the total volume of the suspension is separated daily. The supernatant, enriched with spent biogenic elements, is 80% returned to the culture process. Practically about 20 to 30% of the total volume of the suspension is separated daily. The separation ae is carried out at the time when the suspension is stored in the collecting tanks either in the evening or in the morning. Algal biomass loses about 10% of its mass during the night by ingestion, while its chemical composition also changes: it decreases the amount of stored polysaccharides and increases the relative amount of pigments and proteins.

During cultivation, the following parameters are monitored and optimized: suspension density, amount of physically dissolved carbon dioxide and oxygen in suspension, ion concentration of basic biogenic elements of nutrient solution, pH of suspension, culture temperature, health status and biological purity of cultivated culture.

The density of the suspension ae is monitored by determining the dry mass of algae per unit volume of suspension by weighing, which is most often performed at the beginning and end of daily cultivation, and by periodic photometric measurement of the optical density of the suspension. The photosynthetically active radiation that the layer of cultured algae suspension absorbs is also measured continuously.

During the growth of algae and the suspension is saturated with carbon dioxide, which is best supplied from the central

· The concentration of physically dissolved C0 ₂ is continuously monitored in the analytical loop by means of an infra-analyzer through which CO ₂ passes, the concentration of which is in equilibrium with the concentration of C0 ₂ dissolved in the suspension · Optimal partial pressure of C0 ₂ in suspension, 1 to 2 kPa, is maintained by means of a pressure regulator with adjustable gas flow. Part of the analytical loop is also a flow analyzer of gaseous oxygen, which is in equilibrium with physically dissolved oxygen in suspension at the end of the slope. In case the p0 ₂ in the suspension exceeds the critical value of 50 kPa, the suspension is sprayed before entering the pump suction so that the required release of oxygen is achieved by creating a large surface area.

Claims (7)

PATENT CLAIMS A method for the large-scale cultivation of photoautotrophic algae and cyanobacteria in the open air, wherein a carbon dioxide-saturated suspension of algae enriched with the necessary nutrients flows down the slopes, characterized in that the run-off takes place in a turbulent flow regime with a layer thickness in the range of 5 to 30 mm. 2. The method according to item 1, characterized in that the turbulent flow is achieved by roughening the surface of the slope surfaces. 3. The method according to item 1, characterized in that! in that the turbulent flow is achieved by transverse baffles in the direction of flow. 4. Apparatus for carrying out the method according to item 1, consisting of sloping surfaces of the greenhouse roof or placed on the ground, a pump and a carbon dioxide choke, characterized in that! provided that the slope surfaces have a slope of 1 to 2% and are provided with means for ensuring flow turbulence. 5. The device according to point 4, characterized in! in that the means for ensuring the turbulent flow are formed by transverse partitions with a height of 10 to 20 mm, located above the slope surfaces at a height of 3 to 5 mm, which are preferably inclined to the flow direction. 6. The device according to item 4, characterized in that the slope surfaces are roughened to a roughness / μm of 0.1 to 0.2. 7. Devices according to points 4 to 6, characterized by! provided that the surface of the slopes with their own 2 circulation of the suspension does not exceed 500 m and their length is in the range of 30 to 60 m.