Method for alkaline flocculation harvesting and circulation culture of microalgae

A technology of circular culture and microalgae cultivation, applied in the direction of microorganism-based methods, biochemical equipment and methods, microorganisms, etc., can solve the problems of reducing microalgae revenue, microalgae cultivation reactor amplification, microalgae growth limitation, etc., to achieve Reduce the cost of microalgae cultivation, reduce the cost of carbon source supply, and avoid the effect of continuous infusion

Active Publication Date: 2018-12-28
DALIAN UNIV OF TECH
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Problems solved by technology

The traditional algae culture system continuously bubbles CO into the culture system 2 Although providing carbon source for algae can ensure high-efficiency gas-liquid mass transfer, there are still deficiencies in this technology: first, CO 2 The high transportation cost, high energy consumption and low utilization efficiency make the cost of algae culture remain high
It has been reported in the literature that CO in flue gas can be utilized 2 , but due to the high concentration of CO separated from the flue gas 2 Need to consume a huge amount of energy; secondly, the separated CO 2 It needs to be transported to the algae culture base through pipelines, and the cost of pipelines is relatively high; moreover, the flue gas contains a large amount of toxic substances, including substances rich in sulfur and nitrogen, which will seriously affect the normal growth of algae; The second is CO 2 Aeration makes microalgae culture reactor scale-up problematic, limiting its large-scale commercial production
These problems can be overcome by using bicarbonate, but the cost of bicarbonate itself is relatively high, so it needs to be recycled
In addition, the high pH generated by bicarbonate consumption not only inhibits the growth of microalgae, but also carbonate cannot be utilized by microalgae at high pH, ​​so that the growth of microalgae is limited by carbon sources.
In addition, if the microalgae culture medium cannot be reused and discharged directly, the large amount of nutrients it contains not only has a huge environmental damage effect, such as water pollution, but also becomes a waste of resources, reducing the income of microalgae will also cause
[0004] In addition, due to the characteristics of microalgae cells, harvesting is difficult and costly, and the cost of harvesting microalgae accounts for 20-30% of the entire industrial chain
The traditional microalgae biomass harvesting methods are mainly centrifugation, filtration, flocculation by adding inorganic or organic flocculants, etc. Among these harvesting methods, there are advantages and disadvantages: centrifugal harvesting has high efficiency and wide applicability but consumes energy Larger, it will damage the algae and is not suitable for large-scale application; filtration is more economical, but it is easy to cause membrane pollution and reduce the recovery efficiency; the effect of flocculant recovery is obvious, but adding flocculant to the water body will introduce foreign Compounds cause water pollution, affecting downstream operations and making it difficult to separate again
On the other hand, due to the high price of flocculants, the use of flocculants will increase production costs, and their use in large-scale commercial production of microalgae is limited.
[0005] In summary, the use of traditional microalgae cultivation methods and biomass harvesting methods still have disadvantages such as high energy consumption and high cost, which hinder the commercialization of large-scale production of microalgae.

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  • Method for alkaline flocculation harvesting and circulation culture of microalgae
  • Method for alkaline flocculation harvesting and circulation culture of microalgae
  • Method for alkaline flocculation harvesting and circulation culture of microalgae

Examples

Experimental program
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Effect test

Embodiment 1

[0048] Embodiment 1: the influence of different concentrations of sodium bicarbonate on the growth of oil-rich new green algae

[0049] First, explore the effects of different concentrations of sodium bicarbonate on the growth of oil-rich neochloroalgae. The concentration of sodium bicarbonate is set to 0, 0.1, 0.3, 0.5, 0.7 mol / L, and the composition and content of other nutrients remain the same. For details, see the formula in Table 1 , Table 2. The culture system is a 1L Erlenmeyer flask, the culture volume is 400mL, the inoculation density is 0.05g / L, and the light intensity is 141.5μmol / m 2 · s, the temperature is 25° C., and the culture time is 5 days.

[0050] Experimental results such as figure 1 As shown, after being cultured in medium containing different concentrations of sodium bicarbonate for 5 days, its biomass concentration reached 0.083g / L, 0.91±0.04, 1.64±0.03, 1.50±0.05 and 1.52±0.02g / L respectively, of which 0.3 The biomass of mol / L sodium bicarbonate ex...

Embodiment 2

[0055] Example 2: Self-flocculation of oil-rich Neochlorella under alkaline conditions

[0056] In the process of microalgae cultivation, the bicarbonate in the medium is consumed, resulting in a highly alkaline environment, which can efficiently recover microalgal biomass without adding any flocculants, and does not produce any Biomass pollution. Therefore, the oil-rich neogreen algae cultured at the optimum sodium bicarbonate concentration (0.3mol / L) were harvested by centrifugation first, and the algae were washed several times with 0.5mol / L NaCl solution, and redissolved in the initial fresh medium with pH 10.0 The resuspended algae solution with cell concentration of 0.5, 1.0 and 2.0 g / L was obtained, and transferred to a 50 mL pre-dried graduated cylinder, and allowed to settle for 24 hours. In addition, this example also explored the influence of different concentrations of sodium bicarbonate (0.1, 0.3, 0.5, 0.7 mol / L) on self-flocculation.

[0057] Such as figure 2...

Embodiment 3

[0059] Example 3: Alkaline flocculation of oil-rich neochloroalgae at different calcium ion concentrations

[0060] In order to investigate the effect of calcium ion concentration on the flocculation and sedimentation of oil-rich Neochlorella, the oil-rich Neochlorella in the logarithmic growth phase was harvested by centrifugation, washed with 0.5mol / L NaCl solution for several times, and redissolved in the initial fresh culture at pH 10.0. Base, and set the cell concentration to 0.5g / L. Add 40mL of resuspended algae solution into a 250mL conical flask, then place the conical flask on a stirrer, stir the algae solution at a speed of 1000rpm, and mix different concentrations of CaCl 2 (5, 10, 15 and 20mmol / L) were slowly added to the culture medium, stirred for 10 minutes, then stirred at a speed of 250rpm for 20 minutes, transferred to a 50mL pre-dried measuring cylinder, left to settle for 24 hours, and the absorbance value A was measured. 750 .

[0061] The result is as ...

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Abstract

The invention provides a method for alkaline flocculation harvesting and circulation culture of microalgae. According to the method, bicarbonate is utilized as a carbon source to culture the microalgae. During the cultivation process, as the microalgae biomass grows and hydrogencarbonate is consumed, the pH rises, to form a highly alkaline environment which can induce self-flocculation of the microalgae, and the harvesting of the microalgae biomass is achieved; low concentrations of flocculating ions such as calcium, magnesium and iron are added into a culture liquid in the highly alkaline environment, the occurrence of flocculation can be produced, the microalgae biomass is harvested efficiently and quickly, the use of a high-cost high-concentration flocculant is avoided, and the problemof biomass pollution is solved. After the flocculation is harvested, CO2 is absorbed by a high alkaline medium rich in carbonate, and bicarbonate is regenerated as a carbon source and reused for microalgae cultivation to re-use water and nutrients, reducing the cost of microalgae cultivation. Therefore, the method can reduce cultivation and harvesting costs of the microalgae simultaneously and have promotion and application prospects in the field of large-scale cultivation of the microalgae.

Description

technical field [0001] The invention relates to the field of microalgae biotechnology, in particular to a method for harvesting microalgae by means of cyclic cultivation of microalgae and alkaline flocculation. Background technique [0002] Microalgae are a type of photosynthetic autotrophic microorganisms, rich in protein, polyunsaturated fatty acids, pigments and other nutrients. At the same time, because of its strong environmental adaptability, fast growth, high carbon sequestration efficiency, and high biomass, it has important applications in the fields of pharmaceutical industry, food industry, animal feed, bioenergy, and environmental protection. But large-scale cultivation of microalgae is still limited by high costs, including the cost of carbon sources, the cost of water and nutrients, and the cost of harvesting microalgae. [0003] Among them, the cost of carbon source is the main factor limiting the large-scale cultivation of microalgae. The traditional algae ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C12N1/12C12R1/89
CPCC12N1/12
Inventor 迟占有翟晓嵌朱陈霸
Owner DALIAN UNIV OF TECH
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