RU2770009C1 - Method and system for capturing and using co2 in the cultivation of unicellular algae on paddy fields - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: group of inventions relates to biotechnology. A method for capturing and using CO₂ and a system for implementing the claimed method are proposed. The method includes filling the paddy field with water, followed by seeding with unicellular Chlorella algae; feeding CO₂, previously isolated and cooled from the exhaust gases of production, through the openings of the gas pipeline into the paddy fields. When the optimal concentration is reached, unicellular algae are separated, concentrated and processed using anaerobic fermentation into vermicompost and methane. The system includes a module for cleaning and cooling waste CO₂ connected via gas pipelines to paddy fields, which is connected in series by a gas pipeline to a cleaning, drying unit and a container for anaerobic fermentation of a suspension of unicellular algae.

EFFECT: inventions provide an expansion of the arsenal of means and methods for capturing and using CO₂ in order to obtain products with economic value.

2 cl, 1 dwg

Description

Technical field

The invention relates to technologies for capturing, using and storing CO ₂ (CCUS).

State of the art

CCUS (Carbon Capture, Usage and Storage) technologies are currently receiving much attention around the world, as these technologies represent an important step towards reducing the impact of industrial production on the climate.

US 2007092962 describes an apparatus and method for removing CO ₂ using a photo bioreactor with light emitting diodes (LEDs). This apparatus and method is useful for removing unwanted CO ₂ from a water stream.

US 20140057321 describes a method comprising: capturing CO ₂ from a source of carbon dioxide; CO ₂ fixation; conversion of fixed CO ₂ into biomass; and obtaining high-value material. Trapping includes absorbing CO ₂ with a liquid absorbent selected from the group consisting of amine, potassium carbonate, ammonia water, and any combination thereof.

Document FR 3044935 describes a method for processing CO ₂ , including: recovery of gaseous CO ₂ ; converting gaseous CO ₂ into liquid CO ₂ ; storage of liquid CO ₂ ; converting the accumulated liquid CO ₂ into gaseous CO ₂ ; conversion of gaseous CO ₂ into hydrocarbon by photosynthesis; recovery of the formed hydrocarbon.

Technical problem

The United Nations Economic Commission for Europe (UNECE) strategic plans call for countries to reduce their dependence on fossil fuels from 80% to about 50% by 2050, and to achieve a significantly negative balance of CO ₂ emissions. It is estimated that in order to make progress towards this 2°C target, EU countries need to take action to reduce or capture at least 90 Gt of CO ₂ emissions by 2050.

Since fossil fuels will continue to play an important role in the short to medium term, achieving carbon neutrality will require the use of CCUS technologies to reduce CO ₂ emissions.

CO ₂ utilization is the use of captured hydrocarbon to create products of economic value. Use is divided into 3 main areas: mineralization, biological and chemical use.

One example of use in the field of mineralization is the incorporation of CO ₂ into concrete.

One result of chemical use is the production of urea fertilizers and some specialty polymers. In the future, CO ₂ together with H ₂ can be used to produce synthetic fuels, synthesis gas and methanol. Synthesis gas and methanol are the main chemical feedstock from which many chemicals and polymers can be produced.

In biological use, CO ₂ is used to stimulate plant growth.

Thus, the problem solved by the invention is to expand the areas of CO ₂ use, using technologies for capturing, using and storing CO ₂ (CCUS). Another objective is to obtain products of economic value, namely biohumus and/or biomethane.

Terms and Definitions

In this application, the following definition terms are used:

Biomethane is a gas produced by methane fermentation of biomass.

Biohumus is an organic fertilizer, a product of biomass processing.

Biomass - plant material from single-celled plants used for energy production or in various industrial processes as a raw material.

Rice check - a plot of arable land with rice crops, fenced off with earthen rollers to retain water.

Unicellular algae - a genus of unicellular green algae preferably with a planktonic, thermophilic strain, such as a planktonic strain of Chlorella.

The essence of the invention Rice fields, divided into rice fields, are a kind of reservoir, characterized by the following features: shallow depth; controlled flow, sharp fluctuations in temperature; alternation of seasons for planting and growing rice and seasons, the so-called "water fallow", when the field is not used, but flooded with water.

These features make it possible to consider rice fields divided into paddy fields as photobioreactors for growing unicellular algae.

To improve the performance of the photo bioreactor, the paddy field is equipped with CO ₂ forced enrichment, which stimulates the growth of unicellular algae. CO ₂ can be obtained by cleaning and cooling the exhaust gases of a thermal power plant or any other production, as well as by other methods. After cooling and purification, CO ₂ is fed into gas pipelines, the working part of which passes along the bottom of rice paddies and saturates the water through the holes, stimulating the growth of unicellular algae. The method for capturing, using and storing CO ₂ when growing unicellular algae on rice paddies includes the following steps:

- flooding the rice field with water and sowing with a strain of unicellular algae;

- separation and cooling of CO ₂ from waste gases obtained during the operation of the production source, delivery through gas pipelines, through holes, in gas pipelines, into rice fields, in order to saturate water and grow unicellular algae;

- draining the resulting suspension, upon reaching the optimal concentration of unicellular algae;

- the concentration of the suspension into a paste with a water content of 20-50%;

- separating excess water from the suspension and directing it back into the rice paddy;

- anaerobic fermentation of a suspension of unicellular algae and its processing into a paste of unicellular algae containing a solid component - biohumus and a gas component - biomethane;

- use of the resulting biohumus as a fertilizer for rice fields that are not under water vapor;

- compression and transportation to the consumer of the obtained biomethane.

The system for capturing and using and storing CO ₂ , when growing single-celled algae on rice paddies, includes:

source of waste CO ₂ , connected to the module for purification and cooling of waste CO ₂ , which is connected via gas pipelines to the rice field,

moreover, the gas pipelines contain holes for saturating the water in the rice fields with the resulting CO ₂ ,

moreover, rice checks are connected through drain channels to a unit for cleaning and drying single-celled algae, which is connected by feedback through filling channels to the rice check for supplying a suspension of single-celled algae,

moreover, the unit for cleaning and drying unicellular algae is connected to a tank for anaerobic fermentation of a suspension of unicellular algae and processing of unicellular algae into biohumus and / or biomethane, and the tank for anaerobic fermentation of a suspension of unicellular algae is connected to a block for compressing the obtained biomethane, for its transportation to the consumer.

Description of drawings

In FIG. 1 schematically shows a system for capturing and using and storing CO ₂ when growing single-celled algae on rice paddies.

The positions in FIG. one:

1 - source of CO _2,

2 - cleaning and cooling module,

3 - gas pipeline through which CO ₂ enters rice fields,

4 - filling channels through which water planted with unicellular algae enters rice paddies,

5 - drain channels through which the suspension obtained from unicellular algae is drained from rice paddies,

6 - module for cleaning and drying biomass obtained from unicellular algae,

7 - rice check,

8 - feedback through filling channels with rice paddy for supplying a suspension of unicellular algae to the paddy paddy,

9 - the resulting suspension concentrate in the form of a paste of unicellular algae with a water content of 20-50%,

10 - container for anaerobic fermentation of a suspension of unicellular algae, anaerobic bacteria process the paste of unicellular algae into biohumus (solid components) and biomethane (gas components),

11 - biomethane obtained as a result of the fermentation of a paste of unicellular algae,

12 - module for compression and transportation of the resulting biomethane,

13 - module for the use of the obtained biomethane by the consumer.

Implementation of the invention

The method can be carried out as follows. The rice paddy is filled with water to a depth of 20-30 cm. The water temperature should not exceed 35°C. In the event of an increase in temperature, additional water is poured into the check. CO ₂ cooled and separated in the unit (2) from the exhaust gases obtained during the operation of the unit (1) (CHP or other production) through gas pipelines (3) enters the rice fields and through the holes in the gas pipelines (3) saturates the water with CO ₂ .

The attendants sow the checks with a strain of unicellular algae (preferably a planktonic, thermophilic strain).

Under the action of sunlight in water saturated with CO ₂ , unicellular algae actively multiply. When their concentration has risen to the optimum, the resulting suspension is drained into a block (6).

In block (6) the suspension is concentrated into a paste with a water content of 20-50%. Excess water is separated and, as a circulating water, is sent (8) to the rice paddy.

Block (10) is a container for anaerobic fermentation of a suspension of unicellular algae. In this tank, anaerobic bacteria process the paste of unicellular algae into biohumus (solid components) and biomethane (gas components).

The resulting vermicompost is extremely fertile soil, so it is used to fertilize rice paddies that are not under water vapor.

The biomethane obtained as a result of the fermentation of the unicellular algae paste is compressed and transported in the block (12) and sent to the consumer (13).

Thus, the areas of use of CO ₂ are expanding, using technologies for capturing, using and storing CO ₂ (CCUS). The problem of obtaining products of economic value, namely biohumus and/or biomethane, is also being solved.

Claims (12)

1. A method for capturing and using CO ₂ in the cultivation of unicellular algae on rice paddies, which includes the following steps: - flooding the rice field with water and seeding with a strain of single-celled algae Chlorella; - separation and cooling of CO ₂ from the exhaust gases obtained during the operation of the production source, delivery of CO ₂ through gas pipelines and through holes in gas pipelines, into rice fields, in order to saturate water and grow unicellular algae; - draining the resulting suspension when the optimal concentration of unicellular algae is reached; - the concentration of the suspension into a paste with a water content of 20-50%; - separating excess water from the suspension and directing it back into the rice paddy; - anaerobic fermentation of a suspension of unicellular algae and its processing into a paste of unicellular algae containing a solid component - biohumus and a gas component - biomethane. 2. A system for capturing and using CO ₂ in the cultivation of unicellular algae on rice paddies, including: source of outgoing CO ₂ connected through gas pipelines to the module for purification and cooling of outgoing carbon dioxide, which is connected through gas pipelines to the rice field, moreover, gas pipelines contain holes for saturating water in rice fields with the resulting CO ₂ , moreover, rice checks are connected through drain channels to a unit for cleaning and drying single-celled algae, which is connected by feedback through filling channels to the rice check for supplying a suspension of single-celled algae, moreover, the unit for cleaning and drying unicellular algae is connected to a tank for anaerobic fermentation of a suspension of unicellular algae and processing of unicellular algae into biohumus and / or biomethane, and the tank for anaerobic fermentation of a suspension of unicellular algae is connected to a block for compressing the obtained biomethane, for its compression and transportation to the consumer.

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