RU2497944C2 - Method of cultivation of microalgae for biofuel purpose - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: method of cultivation of microalgae for biofuel purpose comprises two stages of algolisation. At the first stage the algolisation is carried out by primary inoculum of the culture, preferably Chlorella vulgaris BIN, obtained in the photobioreactor synchronously or time-shifted, of multifunctional indoor pools with translucent railing. The total volume of the said pools is from 1/30 to 1/15 of the total amount of open water reservoirs. The secondary inoculum is grown with a bulk density of 10⁹-10¹¹ cells/l, at that the cultivation is started in spring with an average daily temperature of water in the pools in the range of 12-18°C. The second stage of cultivation the microalgae is started by selection from the pools of secondary inoculum at a temperature of water in the open water reservoirs of 12-18°C, and continue its supply to the open water reservoirs to reach in them of the bulk density of microalgae 2·10⁸-10⁹. The secondary inoculum is partially taken from the pool as a finished product in spring and autumn with the water temperature in them is in the range of 8-12°C, at that in multifunctional pools the equal amount of water with dissolved biogens is added. The resulting microalgae contain 33.9 % cellulose, 51.0 % proteins, 7.3% fats.

EFFECT: increased productivity of microalgae cultivation method.

3 cl, 1 dwg, 4 ex

Description

The invention relates to the field of energy microbiology, in particular to systems for the production of microalgae biomass (MB), used for the preparation of third-generation biofuels, and can be used in energy, fuel and chemical industries, in feed production technologies.

Currently, two methods of cultivating MB biomass are most widely used: cultivation in open water, which requires minimal capital and operating costs, and the cultivation method in the photobioreactor (FBI), a completely closed system that supports the specified optimal parameters of the cultivation medium for target strains of MB with minimal use of natural energy sources (in particular, solar radiation) or only under artificial conditions (see, for example, Ross M.Yu., Strebkov D.S. Bio diesel fuel from algae / Under the editorship of the doctor of chemical sciences, professor Yu.M. Shchekochikhina, M .: GNU VIESH. 2008, 252 p.).

The disadvantages of the FBI include the unreasonably high cost of MB biomass for fuel use, while the most significant drawbacks of open systems are the low average annual productivity in a temperate climate and the inability to effectively control the species composition and cultivation conditions.

A well-known compromise solution to the above problems is considered the cultivation method in greenhouses (see, for example, Ross M.Yu., Strebkov D.S. Biodiesel from algae / Under the editorship of Dr. of Chemical Sciences, Professor Yu.M. . Shchekochikhina, M .; GNU VIESH, 2008, 252 pp.), Which makes it possible to bring the thermal regime of the culture medium closer to optimal and increase the average annual productivity by extending the cultivation period at relatively low costs associated with the construction of building envelopes and the associated heat infrastructure s. However, they allow you to solve many problems that are typical for fully open systems. In particular, under these conditions, it is possible to maintain a dominant position and higher productivity of the target strains.

As a disadvantage of this technology, it should be noted the low utilization of the pond-greenhouse equipment, which is located in a short production cycle (no more than 4 ... 6 months for the middle zone of the Russian Federation). In addition, greenhouse ponds have, as a rule, a relatively small area, which is dictated, first of all, by economic considerations, and cannot fully satisfy the needs of the industrial production of biomass MB for biofuel purposes.

The closest to the claimed technical essence and the achieved result is a two-stage method of combating the "flowering" of water with blue-green algae in ponds ", which includes two stages, while the second stage is carried out in open ponds, by their algalization with the introduction of the primary inoculum of the target strain, Algolizant is applied twice in the spring when water temperature in the lower layers of the reservoir reaches 5-10 ° C and again after 2-3 weeks, while in winter, when ice is freezing, clearing the ice from snow from 1/3 to 50% of the reservoir area (RU No. 2350569, IPC C02F 3/32, December 3, 2007).

The main disadvantage of this method is the low efficiency of the first (winter) stage of introducing an algolysant in a temperate climate due to the unfavorable temperature background for the development of algaculture in the winter period of the most promising microalgae strains for this zone, such as Chlorella vulgaris and its derivatives.

The objective of the invention is to increase the average annual productivity of the method of cultivating MB biofuel purposes open method in a temperate climate.

The use of the invention allows to extend the effective period of biomass collection in comparison with existing technologies of open cultivation with maximum use of material and technical resources available at a particular facility.

The technical result is achieved by the fact that in the method of cultivating microalgae for biofuel purposes, comprising two stages of algolization, of which the second stage is carried out in open reservoirs with the introduction of the primary inoculum of the culture, mainly Chlorella vulgaris BIN, according to the invention, the first stage is algolized with the primary inoculum obtained in the photobioreactor , synchronously or with a time shift of multifunctional indoor pools with translucent fences, the total volume of which is from 1/30 to 1/15 of the total volume of open water bodies; grow a secondary inoculum with a bulk density of 10 ⁹ -10 ¹¹ cells / l, while cultivation begins in the spring with an average daily temperature of water in the pools in the range of 12-18 ° C; the second stage of the cultivation of microalgae is started by selection of the secondary inoculum from the pools at a water temperature of 12-18 ° C in open water and its supply to open water is continued until the microalgae has a bulk density of 2 · 10 ⁸ -10 ⁹ ; the secondary inoculum is also partially taken from the pool as a finished product in the spring and autumn periods at a water temperature in the range of 8-12 ° C, while an equal amount of water with biogens dissolved in it is added to multifunctional pools.

As multifunctional indoor pools, tanks designed for winter storage of commercial fish products can be used, and sewage and / or waste water from heating systems are used as a heat carrier for heating the pools.

Schematically presented is a device for implementing the above two-stage method of cultivating biomass MB biofuel destination (Figure 1).

The device consists of open reservoirs 1, indoor pools 2, a source of thermal energy 3 for heating the culture fluid in the pools and may also include a photobioreactor (FBI) 4.

The cultivation of biomass MB using the proposed method (for example, a strain of Chlorella vulgaris BIN) is as follows.

In the spring season, when the water temperature in pools 2 heated by heat sources 3 rises to an average daily value of at least 12-18 ° C, they begin to synchronize (or with a time shift, depending on the performance of the FBI 4) the primary inoculum of the strain Chlorella vulgaris BIN in the calculation of at least 10 ⁹ cells / l of the pool volume and carry out the stage of growing the secondary inoculum. As heat sources 3 can be used sewage and / or water at the outlet of the heating system.

Example 1

In the spring, when the bulk density of the secondary inoculum Chlorella vulgaris BIN in the pool reaches 10 ¹¹ cells / l, at an average daily temperature of water in multifunctional pools of 8 ° C, the volume of which is 5000 m ² (1/30 of the total volume of open water bodies), the secondary inoculum Chlorella vulgaris BIN is partially continuously withdrawn from the pool as a finished product, replenishing the selected culture medium with an equal amount of water with the necessary biogens dissolved in it. The secondary inoculum was grown in a standard Tamiya nutrient medium (Vonshak A. Microalgae: technology for laboratory cultivation of biomass in outdoor plants. In the book: Photosynthesis and bio-productivity: determination methods. M: Agropromizdat, 1989, p. 310-328), containing biogenic components: KNO ₃ , MgSO ₄ + 7H ₂ O and KNRO ₄ in the calculation of 5.0 g / l, 2.5 g / l and 1.25 g / l, respectively. To heat the pools use the thermal energy of sewage.

Example 2

In the spring, when the water temperature reaches 18 ° C in open reservoirs 1, the secondary inoculum is sent to open reservoirs for their algolization with the cultivated strain of Chlorella vulgaris BIN. The selection of the secondary inoculum Chlorella vulgaris BIN from pools 2, the volume of which is 10,000 m ³ (1/15 of the total volume of open reservoirs), at a temperature of 12 ° C in open reservoirs 1 is continued until the bulk density of microalgae of the cultured strain in open ponds 1 does not reach a value of the order of 2 · 10 ⁸ cells / l, after which MB biomass is taken from pools 2 as a finished product, replenishing the selected culture medium with an equal amount of water with dissolved biogens. In this example, the standard Tamiya nutrient medium was used: KNO ₃ , MgSO ₄ + 7H ₂ O and KHPO ₄ in the calculation of 5.0 g / l, 2.5 g / l and 1.25 g / l, respectively. The secondary inoculum is partially taken from the pool as a finished product. To heat the pools use the waste heat of the heating system.

Example 3

In the autumn period, at an average daily water temperature of 12 ° C in open reservoirs 1, the culture medium with a bulk density of 10 ⁹ cells / l is continuously taken and, with the addition of the necessary nutrients, sent to pools 2, at a temperature of 8 ° C, to replenish an equal volume the finished product selected from them. When implementing the method, Tamiya nutrient medium was used: KNO ₃ , MgSO ₄ + 7H ₂ O and KNRO ₄ in the calculation of 5.0 g / l, 2.5 g / l and 1.25 g / l, respectively. As pools, containers are used that are designed for winter storage of marketable fish products.

Example 4

In the spring, at an average daily water temperature of 12 ° C in pools 2 for winter keeping, fish of the fish farm are alternately algolized by the primary inoculum of microalgae belonging to the Diatoma species obtained in the photobioreactor. The selection of the secondary inoculum from the pool to open reservoirs begins at a water temperature of 12 ° C; while the selected culture medium is replenished with an equal amount of water with the dissolved biogens. When implementing the method, a typical nutrient medium was used containing the following substrate biogenic components, the content of which is indicated in grams per 1 kg of dry phytomass per day: Ca (NO ₃ ) ₂ - 0.04, K ₂ NRA ₄ - 0.01, MgSO ₄ * 7H ₂ O - 0.025, N ₂ CO ₃ - 0.025, Na ₂ SiO ₃ * 9H ₂ O - 0.02, FeCl ₃ * 6H ₂ O - 0.0008.

Also, the secondary inoculum is partially taken from the pool as a finished product, replenishing the selected culture medium with an equal amount of water with dissolved biogens, the composition of the substrate biogenic components.

In the spring, when the water temperature in open reservoirs 1 is below 12 ° С, the Chlorella vulgaris BIN secondary inoculum is not populated due to low productivity, and at temperatures above 18 ° С MB begins to be taken.

When a secondary inoculum is grown with a density below 10 ⁹ cells / l, selection of the inoculum from multifunctional pools is not advisable, and at a density of 10 ¹¹ cells / l, the selection of the secondary inoculum begins.

At temperatures in multifunctional pools below 8 ° C, the productivity of MB is not high enough, and at a temperature of 12 ° C, multifunctional pools are populated with the primary inoculum Chlorella vulgaris BIN.

The increase in the average annual productivity of the method of cultivating microalgae for biofuel purposes is due to the fact that the selection of the finished product is not performed both from multifunctional pools and from open water bodies.

The resulting MB Chlorella vulgaris BIN contains more than 92.2% of organic substances, such as 33.9% fiber, 51.0% protein, 7.3% fat, which are suitable for processing into biofuels.

Claims (3)

1. A method of cultivating microalgae for biofuel purposes, comprising two stages of algolization, of which the second stage is carried out in open reservoirs with the introduction of the primary culture inoculum, mainly Chlorella vulgaris BIN, characterized in that in the first stage algolization is performed with the primary inoculum obtained in the photobioreactor, synchronously or with time shift of multifunctional indoor pools with translucent fences, the total volume of which is from 1/30 to 1/15 of the total volume of open water bodies at; grow a secondary inoculum with a bulk density of 10 ⁹ -10 ¹¹ cells / l, while cultivation begins in the spring with an average daily temperature of water in the pools in the range of 12-18 ° C; the second stage of the cultivation of microalgae is started by selection of the secondary inoculum from the pools at a water temperature of 12-18 ° C in open water and its supply to open water is continued until the microalgae has a bulk density of 2 · 10 ⁸ -10; the secondary inoculum is also partially taken from the pool as a finished product in the spring and autumn periods at a water temperature in the range of 8-12 ° C, while an equal amount of water with biogens dissolved in it is added to multifunctional pools. 2. The method according to claim 1, characterized in that as multifunctional indoor pools use containers designed for winter storage of marketable fish products. 3. The method according to claim 1, characterized in that for the heating of pools as a heat carrier use sewage and / or waste water heating systems.