PL213473B1 - Photobioreactor system for microalgae culture - Google Patents

Description

The subject of the invention is a photobioreactor system for the cultivation of microalgae as a mineral feed additive.

A photobioreactor is known from US Patent No. 6,602,703, consisting of a cuboid containing a medium and several parallel-arranged light-emitting lines immersed in a medium solution, which is equipped with a device for cleaning the surface of the light source.

The photobioreactor for culturing photosynthetic microorganisms described in another US Patent No. 4,952,511 comprises a cylindrical reservoir in which is located at least one light chamber that extends into the interior of the reservoir and at least one high-intensity lamp whose light is introduced into the chambers. light chambers each having at least one transparent wall and a device for diffusing the lamp light evenly through the transparent wall.

A photobioreactor consisting of parallel trays arranged at different levels is known from the US patent application no. US 2007 0 155 006. The distance between the trays is much greater than their width. In order to reflect and disperse the sunlight, optical elements have been placed between the trays, thanks to which the growing microalgae benefit from the sunlight.

Another patent, US 5,151,347 describes a photobioreactor for culturing microalgae under controlled conditions with the possibility of circulating the isotope of ¹³ CO 2 or ¹⁴ CO 2, with the option of removing the photosynthesis product - oxygen from the reactor. In this photobioreactor, CO2 is introduced into the suspension and mixing is simultaneously ensured by bubbling. The light source is fluorescent lamps that can be placed in the mixture or above its surface.

A photobioreactor is known from the patent No. US 6 509 188 composed of many chambers connected with each other by means of pipes and wires. Each chamber has one wall made of a material transmitting sunlight, one or more walls are sinusoidal in shape, transverse walls are placed inside the chamber, and the entire reactor is equipped with a turbulent flow device. The rectangular shape and the small depth of the reactor result in a high surface area to volume ratio.

Also known from US patent 5,659,977 is an integrated microalgae production system at a power plant, where the heat generated in the electricity production process is used to dry the biomass, and the CO2 by-product is used as a substrate in microalgae biomass cultivation in the pond. In this embodiment includes reception of fresh biomass and thermal drying, and the breeding pond 22 can have an area ranging from 404.7 m ² to 8094 m ² and a depth of 15 cm to 38 cm, which gives a surface to volume ratio from 2.6 to 6, 7.

The essence of the invention is a photobioreactor system for the cultivation of microalgae with the use of mineral nutrients, which is characterized in that in a closed circuit it comprises a photoautotrophic culture module, made up of at least three light transmitting columns connected in series, and a separation module with a filtration device and a pump connected by a system tubing and valves to the first and last columns of the photoautotrophic culture module through the biomass reservoir. In addition, in the system, the inlet and outlet pipes of each module have their own shut-off valves, enabling the introduction of the medium stream to the first column and the circulation of the biomass being grown, its separation and cutting off the biomass tank during the cultivation of microalgae, while equipping the pipes with their own shut-off valves enables the creation of two independent closed circuits, photoautotrophic culture module circulation and separation module circulation. The first circuit comprises connecting the columns via the pump itself, and the second circuit comprises connecting the columns via a separation module containing a preferably mobile filter, and a biomass tank and pump.

The height-to-diameter ratio of the columns of the photoautotrophic culture module is 10: 1.

Preferably, the columns are made of acrylic glass and have vents in the upper parts, each of them has a port in the lower part and a CO2 inlet port in the upper part of the last column.

Preferably, the system is equipped with a heating system for heating the nutrient solution during the growth of algae, connected to a closed circuit.

In the system according to the invention, it is possible to carry out the separation process in parallel or sequentially with the culturing process carried out in the photoautotrophic culturing module.

PL 213 473 B1

The system according to the invention makes it possible to obtain an algae biomass concentrate that can be used for the production of mineral feed additives, as well as for the extraction of other valuable products.

The advantage of the system according to the invention is that, through a system of conduits and shut-off valves, it enables parallel or sequential cultivation of algae biomass and separation of the grown biomass from the post-cultivation solution for use as animal feed.

In the photobioreactor system, thanks to the combination of the photoautotrophic culture module with the separation module, it was possible to significantly reduce the size of the entire system, guaranteeing obtaining a large amount of biomass. The number of columns in the photoautotrophic culture module as well as their dimensions can be increased and freely adjusted depending on the demand for the type of microalgae. The system of connections and valves also guarantees, thanks to the possibility of dividing the stream of the circulating suspension into two streams, that the algae growth process is carried out with the use of one stream and that the process of separating algae biomass from the post-culture solution is carried out in the filtration device.

The advantage of the system is also the fact that with low financial outlays for its construction, energy is saved, because the algae biomass is cultivated in visible light.

The invention, in an exemplary embodiment, is shown on the drawing showing the photobioreactor system.

Example I ₃

The photobioreactor system for the cultivation of microalgae, with a capacity of 500 dm ³ , includes a photoautotrophic culture module made of five light transmitting columns 1 made of acrylic glass, each of which is equipped with a vent 2 to remove air from the system and a stub pipe 3 for for sampling, as well as for introducing clean water for nutrient preparation. The columns connected in series are situated vertically and parallel to each other, and the ratio of their height to diameter is 10: 1. Before the last column of the module, there is an inlet connection of the introduced carbon dioxide (CO2) as one of the substrates. In addition, the first and last columns are connected by a conduit and valve system that form two independent closed circuits, the circuit of the photoautotrophic culture module and the circuit of the separation module. The first circuit connects the columns via the pump 5 itself, and the second circuit connects the columns via a separation module containing a mobile vacuum filter 6 and a biomass tank 7 and pump 5. In the system, almost all lines have their own shut-off valves to introduce the medium stream into the first column and circulation of the cultivated biomass, its separation and cut-off of the biomass tank during the cultivation of microalgae, the inlet conduit 8 to the cultivation module has a cut-off valve 9, conduit 10 connecting directly the photoautotrophic cultivation module with pump 5, is equipped with a valve 11, conduit 12 connecting the cultivation module with a separation module and supplying the circulated biomass to the tank 7 is equipped with a valve 13, the conduit 14 connecting the tank 7 with the pump 5 has a valve 15, the tank 7 is equipped with a valve 16 draining excess solution and a pressure equalizing fuse 17. In addition, the system is equipped with a heating system for heating the nutrient solution during the growth of algae, connected to a closed circuit, equipped with an electric thermostatic heater 18. Additionally, the heating system includes a solar mat 19, connected to the system by pipes 20 equipped with valves 21. Alternatively, the tank 7, after removing the filter 6, acts as a mixer in the preparation of the medium with inorganic salts.

In the system in the photoautotrophic culture phase, the solution of the previously inoculated and heated medium flows through lines 8 to the first column and then through the columns through line 10 to pump 5 with valve 11 open and valve 13 and closed closed. Then, with valve 21 open, the biomass suspension flows through pipe 20. to the solar mat 19 for supporting heating in order to cultivate at the optimal growth temperature for a given strain of microalgae. By carrying out such cultivation, 4 kg of fresh Spirulina maxima biomass are obtained for 50 days at 35 ° C. A sample of the suspension is taken daily from the holes 3 located at the bottom of each column 1 to determine the biomass concentration. After reaching the desired concentration in order to remove the self-shading effect, once a day for 15 minutes the microalgae biomass is sent to the separation module.

In the system in the separation phase, the filter 6 is placed in the tank 7, the biomass suspension is directed through the line 12 to the separation module, with valves 13 and 15 open. After disconnecting the filter device from the system, the valve 16 of the tank 7 is opened to remove excess solution. After the pressures have been equalized with the fuse 17, the filter 6 is removed together with the received biomass. The suspension is returned to the biomass separation module when the valve 16 and the fuse 17 of the tank 7 are closed.

PL 213 473 B1

The system may cultivate sequentially, alternating the photouatotrophic culture step described above, followed by a separation step. During the cultivation process, the biomass suspension is directed to the columns through conduit 8 with valve 9 open, and then with conduit 10 open with valve 11 to pump 5. The photoautotrophic culturing phase is carried out until the biomass concentration reaches the desired value. In the second stage of cultivation in the sequential system in the separation phase, the filter 6 is placed in the tank 7, the slurry is directed via line 12 to the separation module with valves 13 and 15 open and valve 11 closed. Then, when the biomass suspension reaches the desired transparency with closed valves 13 and 15 and open valve 11, the biomass slurry is again directed through line 10 to the photoautotrophic culture module. After disconnecting the filter device from the system, valve 16 of reservoir 7 is opened and excess solution is drained. After the pressures have been equalized with the fuse 17, the filter 6 is removed together with the received biomass. The suspension is returned to the biomass separation module when the valve 16 and the fuse 17 of the tank 7 are closed.

In the case of parallel cultivation, after the microalgae biomass has reached its maximum growth rate, the cultivation module and the separation module are started simultaneously. The suspension from the columns is directed simultaneously through lines 10 and 12 with open valves 11, 13 and 15.

List of symbols in Figure 1 - column

- column air vent 3 - column connection 4 - CO2 inlet connection 5 - pump

- vacuum filter 7 - biomass tank 8 - inlet pipe to the breeding module 9 - cut-off valve of the inlet pipe

- a cable connecting the photoautotrophic culture module with the pump

- valve of the inlet line to the pump

- cable connecting the photoautotrophic culture module with the separation module

- valve of the inlet line to the tank

- pipe connecting the tank with the pump

- valve of the pipe connecting the tank with the pump

- tank valve

- fuse

- thermostatic heater

- solar mat

- solar mat cables

- solar mat duct valves

Claims (7)

1. A photobioreactor system for the cultivation of microalgae, using mineral media, equipped with a photoautotrophic culture module, characterized in that in a closed circuit it comprises a photoautotrophic culture module formed by at least three light transmitting columns (1) connected in series and a separation module with filtration device (6) and pump (5), connected by a system of pipes and valves with the first and last column of the photoautotrophic culture module, through the biomass tank (7), the pipes are equipped with their own shut-off valves, enabling the creation of two independent closed circuits, circulation a photoautotrophic culture module and a separation module circuit, the first circuit of which includes the connection of columns (1) via the pump (5) itself, and the second circuit includes the connection of columns (1) via a separation module containing, preferably a mobile filter (6) and a biomass tank (7). ) and pump (5). 2. The system according to claim The method of claim 1, characterized in that the inlet and outlet conduits of each module have their own cut-off valves, enabling the introduction of the medium flow to the first column (1) and circulation of the cultivated biomass, its separation and cutting off the biomass tank (7) during the cultivation of microalgae . 3. The system according to p. The method of claim 1, wherein the height to diameter ratio in the columns (1) of the photoautotrophic culture module is 10: 1. 4. The system according to p. The column according to claim 1, characterized in that the columns (1) are made of acrylic glass and have vents (2) in their upper parts, and each of them has a stub pipe (3) in the lower part and an inlet connection (4) in the upper part of the last column. carbon dioxide. 5. The system according to p. A method according to claim 1, characterized in that it is equipped with a heating system for heating the nutrient solution during the growth of algae, connected in a closed circuit. 6. The system according to p. The method of claim 5, characterized in that the heating system is equipped with an electric thermostatic heater (18). 7. The system according to p. The method of claim 1 or 5, characterized in that the heating system comprises a solar mat (19).