SU377030A1 - INSTALLATION FOR CULTIVATION OF ALGAE - Google Patents

Description

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The invention relates to devices for the reproduction of photosynthetic single-celled algae, namely, plants for the cultivation of algae.

Similar installations are known that contain an algae growing apparatus, gas exchange, pipelines, and a pump forming a liquid-circulating circuit, a gas flow booster, gas analyzers, and a device for removing oxygen from the gas mixture, forming a gas circulation circuit, and a pipeline for supplying carbon dioxide n automatic control system for controlling parameters.

The proposed installation polishes the reliability of work and reduces energy consumption.

This is achieved by the fact that the gas exchanger is made in the form of an em.kosti, divided by a gas-permeable film into two zones: gas and liquid, each of which is connected to a corresponding circulation circuit.

FIG. 1 shows a schematic diagram of an installation installation; in fig. 2 - gas exchanger, view in nlan; in fig. 3 is a section along A-A in FIG. 2; in fig. 4 is a sectional view: along BB in FIG. 2; in fig. 5 shows a device for removing oxygen from a gas mixture, a slit.

The plant for the cultivation of algae consists of apnarag 1 for the cultivation of algae, gas exchanger 2, pipelines 3, pump 4, forming a liquid circulation loop 5; Pelletizing discharger 6, gas analyzer 7 for carbon dioxide, gas analyzer 8 for oxygen, devices 9 for removing oxygen from the gas mixture forming a gas circulation loop 10. The installation also has a pipeline 11 for supplying carbon dioxide to the system for automatic control and regulation of parameters the carbon dioxide gas including the grandchild clan 12 regulating the zero - organ 13, the supply signal from the tachoanalizer 7 with the setting voltage of 14 percent carbon dioxide regulating the regulating zero - organ 15 signal is collated by the analyzer 8 from the voltage setter 16 the pro-percentage oxygen content.

The gas exchanger 2 is a tank consisting of two housings 17 and 18, separated by a gas-permeable film 19 - into two zones 20 and 21, respectively, a gas and a tank. Each zone is connected.

to the corresponding circulation circuit 5 n 10. The gas exchanger is equipped with fittings 22 and 23 for gas inlet n, with connector 24 for liquid outlet n by fitting (not shown in the drawings) for liquid inlet.

are located on the same axis with the clamp 23.

The case also contains lugs 25 and 26 for organizing the movement of liquid and gas along the ring between the respective fittings and collectors 27 and 28 with holes 29 and 30 through which gas and liquid are evenly fed into the working space of the body.

The device 9 for removing oxygen from the gas mixture is made in the form of a column 31 with a granule-absorber absorber 32, inside of which heating element 33 is placed. In the Column there are distributors 34 and 35, flanges 36 and 37, as well as a filter 38 installed at the outlet.

The installation works as follows.

When the concentration drops as a result of photosynthesis of carbon dioxide dissolved in a liquid (suspension), the driving force of diffusion through the gas-permeable film 19 of the gas-flooder 2 increases, which leads to the movement of carbon dioxide through the film from the gas circuit 10 to the liquid 5. The decrease in the concentration of carbon dioxide in the gas mixture, measured gas analyzer 7, below the set by the setting device 14, triggers the zero-body 13, which includes the primary valve 12. Under the action of the pulping valve, the dose of carbon dioxide through the valve 12 walk: a gas circuit 10, vvsstanavliva initial concentration therein. In this case, the zero-organ 13 is shut off, thus the compartment of the gas circuit from the carbon dioxide supply system.

Thus, the concentration of dissolved carbon dioxide is maintained in the suspension regardless of the rate of carbon dioxide extraction during the growth of algae. Simultaneously with the fall in the concentration of carbon dioxide, the concentration of dissolved oxygen increases, the driving force of diffusion through the film increases, which leads to the release of gaseous oxygen and its movement through the film from the suspension into the gas circuit.

An increase in the percentage of oxygen in the gas mixture, measured by the gas analyzer 8, higher than that specified for the sensors 16, causes the zero to be triggered by the organ 15, which turns on the heating element 33 of the device 9. Heating the absorber 32 creates an OPPORTUNITY for its oxidation reaction, which causes an excess oxygen from the air / gas mixture is removed to unit 9,

where and binds chemically.

Restoration of the percentage of oxygen leads to the zero-organ 15 disconnection and, subsequently, the heating element 33. Switching off the element 33 after some time stops the oxidation reaction.

Thus, both in suspension and in the gas mixture, predetermined concentrations of carbon dioxide and

oxygen, which ensures the stability of food and p and a n i.

Subject matter

An algae culture plant containing an algae culture apparatus, a gas exchanger, pipelines and a pump forming a liquid circulation loop, a gas flow booster, gas analyzers and a device for removing oxygen from the gas mixture forming the gas circulation loop, as well as a pipeline for supplying carbon dioxide and an automatic control and regulation system (parameters, characterized in that, in order to increase the reliability of the installation in operation and reduce the energy consumption, the gas exchanger is in the form of a container divided by a gas-permeable film into two zones: gas and

a liquid circuit, each of which is connected to a corresponding circulation circuit.

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