KR20150085423A - Method for biomass recovery using acid mine wastewater - Google Patents

Abstract

The present invention relates to a method for collecting biomass in an efficient manner by using acid mine wastewater including iron, aluminum positive ion, negative ion such as sulfate or calcium and magnesium positive ion. The method is allowed to reduce costs required for collecting microalgae by using wastewater, while having an effect of purifying water by removing phosphorus, and enables wastewater to be re-used in a culture, thereby collecting condensed biomass and enabling the biomass to be used as a raw material for bio energy and as a soil reformer. Therefore, the method of the present invention has various effects and is an eco-friendly method of condensing and culturing.

Description

TECHNICAL FIELD The present invention relates to a biomass recovery method using acid mine drainage,

The present invention relates to a method for recovering biomass using acidic mine drainage, and more particularly, to a method for recovering biomass using acid mine drainage, and more particularly, to an anion such as iron, aluminum, The present invention relates to a method for efficiently recovering biomass using acid mine drainage containing magnesium cations.

With the depletion of fossil energy, unstable international oil prices, and the Climate Change Agreement, CO2 emissions are being reduced, and research and investment in low-carbon and environmentally friendly fuels and materials are actively being carried out globally. Especially in the United States, there are enormous corporate investments and national support policies on the use of microalgae as biomass, and investment and development are being actively carried out in almost all developed countries such as the EU, India and Israel. In Korea, the Ministry of Knowledge and Economy (MOIC) has finalized the 2012 Energy R & D Implementation Plan, which will inject 1.82 trillion won in March 2012, and outlined the project to demonstrate the process of converting CO2 into high value-added products using microalgae. As a mass, we are supporting microalgae as a national project, and large companies have recently started cultivation of microalgae or are considering it as a long-term project. Therefore, we are very interested in producing bio-energy and high-value-added materials using microalgae (Yoon, Sung-ho, 2012. Trends in biofuel production using microalgae, Bioin Special Webzine).

Microalgae Bioenergization process consists of microalgae cultivation, microalgae recovery, extraction of raw materials and fuel conversion. Many techniques for improving the efficiency of each unit process have been proposed. However, even if a bioreactor having a relatively high productivity is used, the biomass concentration is less than 5 g / L, which is costly and thus not economical.

Microbial cells including microalgae are characterized in that the functional groups such as a carboxyl group present on the cell surface are negatively charged and thus maintain a stable state in an aqueous solution. Therefore, by adding a cationic polymer such as alum or a cationic polymer such as chitosan to the microalgae culture solution, neutralization of the negative charge of the microalgae cells induces aggregation, and the aggregates are precipitated by gravity or supplied with fine bubbles A number of methods for lifting have been proposed. Although this flocculation-based method has advantages in that it has a simple process configuration and is suitable for a large-capacity process, it takes a long time for flocculation, pH adjustment in the culture fluid is needed separately in order to optimize the flocculation condition and since the flocculation agent can not be reused, There is a drawback that it is consumed. It is also pointed out that the coagulant present along with microalgae biomass acts as an impurity in the downstream lipid extraction or conversion process.

Various techniques such as flocculation, centrifugation, filtration, sedimentation, and flotation have been attempted to recover other particulate matter including microalgae. However, due to the efficiency and cost of coagulants depending on the characteristics of the target substances, many difficulties are encountered (Oh, Hee Mok, 2011. Current Status and Prospect of Fuelization of Microalgae Biomass, New & Information for Chemical Engineering, 29 (3), 355 -360).

In particular, in the production of biodiesel fuel using microalgae, the total cost of harvesting is about 20-30%, which means that optimal biomass recovery methods are required considering economic factors, efficiency and environmental friendliness (Brennan & Owende, 2010. Biofuels from microalgae- A review of technologies for production, processing and extractions of biofuels and co-products, Renewable and Sustainable Energy Reviews, 14 (2), 557-577).

Microalgae coagulants are generally known to use metal cations such as iron and aluminum as inorganic coagulants and increase efficiency by increasing the ionic strength with anion such as sulfuric acid. However, in most cases, it is a chemical coagulant with a possibility of secondary contamination. Although chemical coagulants are cheap, they are often harmful to the environment and the human body. Therefore, there is a need for harvesting technology that is environmentally friendly, economical and highly applicable and efficient in order to utilize microalgae as biomass.

Recently, a coagulant effect of CaCl ₂ and FeCl ₃ by an organic substance produced by bacteria during simultaneous culture of microalgae and bacteria (Lee JM, et al. 2013. Microalgae-associated bacteria play a key role in the flocculation of Chlorella vulgaris, Bioresource Technology, 131, 195-201). Although bio-coagulants are environmentally friendly, they are not economical yet and have a problem in that they are not efficient in the field. In addition, micro-algae harvesting technology using amine-supported magnetic nanoparticles has been studied (Oh, Yoo-Kwan, 2013. Greenhouse, Simple utilization of biomass resources in simple removal, Future Environment, No. 44). This technology is economical because it can be reused, but it is necessary to study the efficiency of microalgae except green algae.

Korean Patent No. 1,200,323 describes a method for producing an amino clay for algae harvesting in which an aminosilane-gel reaction is fixed mainly on metal cations. It is a particulate flocculant having no residual toxicity and can recover flocculants more efficiently and can be mass- . Since the coagulant does not remain after recovery, the patent can reduce the unit cost because the wastewater can be reused as the culture liquid after coagulation, but the application range is limited because the coagulation target is limited to green algae.

U.S. Patent Application Publication No. 2009-0162919 provides a method for agglomerating microalgae of 20 탆 or less by using an organic polymer mainly as a metal cation or a metal cation as a microalgae flocculant. The patent discloses that microorganisms including microalgae can be agglutinated and its application range is very wide. However, in the microalgae agglomeration and cultivation method, there is no incidental effect other than agglutination, and the chemically produced inorganic agglutinating agent And there is no indication of the utilization of waste resources, so there may be problems in economic efficiency and secondary pollution in the case of large-scale harvesting.

Korean Patent No. 951,710 relates to a wastewater treatment system utilizing a flocculant containing iron ions, which can remove iron ions from the flocculant by precipitating phosphorus, thereby contributing to prevention of eutrophication and removal of organic matter including algae .

As can be seen from the above-mentioned documents, there are few techniques that can be obtained at a time from the bird-harvesting techniques described so far to the effects of cultivation and agglomeration of microalgae as much as possible while minimizing the unit cost and the effect of environmental and ancillary purification. It is difficult to find examples of utilizing waste resources as coagulants. Therefore, it uses iron, aluminum and other various ions such as calcium, magnesium, and sulfuric acid, which are present in acidic mine drainage that occurs in about 1,200 abandoned mines including domestic metal light and coal mining, While it is possible to reuse the ions in the wastewater after the flocculation, it is necessary to use eco - friendly technology which can obtain the effect of purification of water by removal of phosphorus while ensuring economic efficiency.

1. United States Patent Publication No. 2009-0162919 2. Korean Patent No. 1,200,323 3. Korean Patent No. 951,710 4. Korean Patent No. 1,349,713

 Yoon Sung-ho (2012). Trends of biofuel production using microalgae at home and abroad, Bioin Special Webzine  Oh Hee Mok (2011). Current Status and Prospect of Fuelization of Microalgae Biomass, Journal of Chemical Engineering, Vol. 29, No. 3, pp. 156 (June 2011), pp. 355-360  Brennan, L., & Owende, P. (2010). Biofuels from microalgae-A review of technologies for production, processing and extractions of biofuels and co-products, Renewable and Sustainable Energy Reviews, 14 (2), 557-577  Lee, J. M., Cho, D. H., Ramanan, R., Kim, H., Oh, H. M., and Kim, H. S. (2013). Microalgae-associated bacteria play a key role in the flocculation of Chlorella vulgaris, Bioresource Technology, 131, 195-201

In the present invention, in recovering microorganisms or particulate matter including microalgae cultured in wastewater or synthetic medium, acidic mine drainage is used to increase the utilization of waste resources and to improve the economical efficiency and efficiency The method comprising:

In the present invention, there is provided a method for producing microalgae, comprising the steps of (a) culturing microalgae strains in a photoreactor in the presence of wastewater or synthetic medium, and (b) agglomerating microalgae by mixing the culture solution with acidic mine drainage containing iron, And (c) culturing the microalgae using the filtrate obtained after the flocculating step. By using the acidic mine drainage in which iron, aluminum and sulfate exist at a high concentration, Thereby economically recovering the biomass and simultaneously removing and / or recovering the phosphorus.

The microalgae flocculation and culture method according to the present invention can aggregate fine algae using iron, aluminum, and sulfate in acidic mine drainage, and can remove and recover phosphorus causing eutrophication. After culturing, Remaining ions can be used again for culturing as microalgae growth promoting factor. Therefore, the present invention can not only reduce the cost of harvesting microalgae by utilizing waste resources as a flocculant, but also can purify the water by the removal of phosphorus and reuse the wastewater for cultivation, and the agglomerated biomass can be used as a bio- It is an environmentally friendly coagulation and cultivation method that can bring various effects simultaneously in that it can be used.

Fig. 1 shows the case where the flocculant is untreated (left side) and the case where the flocculant is injected (right side).
Fig. 2 is a graph showing the results obtained in Example 1, wherein the initial pH and the initial microalgae concentration of the microalgae strains, Scenedesmus obliquus , at 25 [deg.] C were different from each other, 2b shows an initial pH of 9, an initial microalgal concentration of 0.5 g / L, and an initial microbial concentration of 0.5 g / L. Fig. 2c shows the coagulation efficiency according to the initial pH 7 and the initial microalgae concentration 1.0 g / L, Fig. 2d shows the coagulation efficiency according to the initial pH 9 and the initial microalgae concentration 1.0 g / L, Respectively.
FIG. 3 shows the result of an energy-dispersive X-ray (EDX) analysis of a sediment sample depending on the presence or absence of acid mine drainage as a result of Example 3. FIG. 3B shows that 3% of acidic mine drainage is injected.

Hereinafter, the present invention will be described in more detail.

The present invention relates to a method for recovering biomass using acidic mine drainage, and more particularly, to a method for recovering biomass using acid mine drainage, and more particularly, to an anion such as iron, aluminum, The present invention relates to a method for efficiently recovering biomass using acid mine drainage containing magnesium cations.

The technical principle to which the present invention is applied is based on Schulz-Hardy's law (C α 1 / u ⁶ ), the coagulation factor (the electrolyte concentration at which the potential barrier becomes zero according to the approach of the two) . This implies that the charge neutralization degree of the dispersing factor is proportional to the sixth power of the counterion ion charge number, which means that the cohesive force of the dispersing agent rapidly increases as the valence of the ion increases. Therefore, the amount of ions required to achieve the same effect for three kinds of ions having 1, 2, and 3 charge will be 1: 1, ⁶ : 1/3 ⁶ = 100: 1.6: 0.13, The high cost of Fe ³⁺ and Al ³⁺ is the main coagulant and the other Ca ²⁺ and Mg ²⁺ are the auxiliary coagulant. Thereby maximizing the recovery efficiency of algae biomass by shrinking the shaft.

The present invention relates to a method for producing microalgae, comprising the steps of: (a) culturing microalgae strains in a photoreactor in the presence of wastewater or synthetic medium; and (b) agglomerating microalgae by mixing the culture solution with acidic mine drainage containing iron, And (c) culturing the microalgae using the filtrate obtained after the coagulation step.

Next, the process of each step mentioned above will be described in more detail.

In an embodiment according to the present invention, the microalgae strains used in step (a) may be single cell, multicellular and spiral algae species.

In one embodiment according to the present invention, the algae strains are used in step (a) is three or four des mousse O Bulletin kusu (Scenedesmus obliquus), Chlamydomonas Mexicana (Chlamydomonas mexicana) and Chlorella 1 including vulgaris (Chlorella vulgaris) species It can be more than a species.

In one embodiment according to the present invention, the culture in step (a) is carried out in a 50 L photobioreactor at a culture temperature of 25-29 DEG C, pH 7-9, light intensity 50-100 mol / , Or in a continuous reactor equipped with an LED (Light Emitting Diode), but the present invention is not limited thereto.

In one embodiment of the present invention, in step (b), the recovery efficiency may vary depending on the acid mine drainage injection amount, the flocculation time, and the concentration and pH of the initial microalgae.

In one embodiment according to the present invention, the acid mine drainage used in step (b) may be at least one of coal mines, metal mines and wastewater discharged from a refinery.

In one embodiment of the present invention, an acidic mine drainage having iron (Fe) of 100 mg / L or more, aluminum (Al) of 100 mg / L or more, and sulfate of 1,000 mg / L or more may be used . If the concentration is less than the above-mentioned concentration, there is a possibility that the desired coagulation effect is not properly manifested.

In one embodiment of the present invention, the amount of acid mine drainage required for the flocculation step is less than 10% of the total solution volume, and the flocculation temperature may be in the range of 15 to 30 캜.

In one embodiment according to the present invention, the initial pH condition may be in the range of pH 6 to pH 9, more preferably in the range of pH 7 to pH 9.

In one embodiment of the present invention, the microalgae concentration of the culture medium used may be in the range of 0.5 to 2 g / L. In step (b), generally a desirable recovery efficiency can be obtained when the initial pH is 9 and the microalgae concentration is 1 g / L.

In one embodiment according to the present invention, an organic polymer may be used as a coagulation aid to form larger aggregates (floc).

Also in an embodiment according to the present invention, the acidic mine drainage in step (b) may remove phosphorus during flocculation and may be used as an adjunct to a chemical flocculant.

Hereinafter, the present invention will be described in more detail with reference to the following examples and experimental examples. However, these embodiments are provided so as to facilitate understanding of the present invention, and the technical scope of the present invention is not limited thereto.

Example 1. Culture of microalgae in wastewater

In order to obtain the microalgae biomass to be used for the coagulation experiment, 40 L of sterilized wastewater or synthetic medium (BBM) was injected into a 50 L photobioreactor, microinvasive strains ( S. obliquus ) were inoculated, and cultured for 20 days by an aeration method. The experimental conditions were 27 ℃, initial pH 6.8, and a red LED light source. The physico-chemical properties of the sewage used for microalgae cultivation are shown in Table 1. Physico-chemical properties of sewage used for microalgae cultivation.

Example 2. Microalgae flocculation method using acid mine drainage

Coagulation experiments were carried out on the basis of initial concentrations of 0.5 and 1 g / L of cultured microalgae and were performed at 5: 95 and 10: 90 (v: v ) Acid mine drainage and algae solution [Table 2] Ion content in acid mine drainage used for microalgae agglomeration]. As a pretreatment before the agglomeration experiment, acidic mine drainage was injected into a 500 mL beaker containing algae solution, stirred at 500 rpm for 2 minutes and at 100 rpm for 15 minutes and then immediately transferred to a 100 mL measuring cylinder. As a result of the agitation test for 1 hour, the recovery efficiency of biomass of 82% or more was observed under all conditions (compare the micro-algae agglomeration efficiency according to initial pH change in FIGS. 2 and 3) High recovery efficiencies of 84% were measured within 20 minutes of the experiment under algae concentration and 10% mine drainage (Fig. 2).

Example 3. Removal of phosphorus from wastewater using acid mine drainage

The experiment was carried out in an incubator shaker for 15 days by injecting 200 mL of pretreated sewage sludge into a 500 mL reactor. The experimental conditions were a temperature of 27 ° C, a pH of 7.1, a light quantity of 45 μmol / ㎡-sec and a stirring speed of 170 rpm (Table 4. Component content of pretreated sewage sludge). Iron can be precipitated with ferric phosphate minerals (eg, FePO ₄ ) along with phosphorous present in the wastewater as well as microalgae aggregation, and phosphorus can be removed and the energy-dispersive X- X-ray, EDX) analysis showed higher phosphorus contents in the samples injected with acid mine drainage (Figure 3).

Claims (15)

(a) culturing microalgae strains in a photoreactor in the presence of wastewater or synthetic media;
(b) an agglomeration step of mixing the culture solution with an acidic mine drainage containing iron, aluminum and sulfate to coagulate the microalgae; And
(c) culturing the microalgae using the filtrate obtained after the coagulation step.
The method according to claim 1,
In the step (a), the microalgae are any one selected from the group consisting of single cell, multi-cell, and spiral algae species.
The method according to claim 1,
Micro-algae in the step (a) is fine, characterized in that three or four of Death mousse O Bulletin kusu (Scenedesmus obliquus), Chlamydomonas Mexicana any one selected from the group consisting of (Chlamydomonas mexicana) and Chlorella vulgaris (Chlorella vulgaris) Algae agglutination and culture method.
The method according to claim 1,
In step (b), the acidic mine drainage is an acidic mine drainage containing at least 100 mg / L of iron (Fe), at least 100 mg / L of aluminum (Al), and at least 1,000 mg / Wherein the microalgae are collected and cultured.
The method according to claim 1,
Wherein the acidic mine drainage further comprises calcium or magnesium in the step (b).
The method according to claim 1,
Wherein the phosphorus is coagulated and removed in the step (b).
The method according to claim 1,
Wherein the acidic mine drainage in step (b) is drained from a source selected from the group consisting of coal mines, metal mines, and refineries.
The method according to claim 1,
Wherein in step (b), the amount of acid mine drainage is less than 10% of the total volume of the solution.
The method according to claim 1,
Wherein said initial pH condition is in the range of pH 6 to pH 9 in said step (b).
The method according to claim 1,
Wherein said initial pH condition is in the range of pH 7 to pH 9 in said step (b).
The method according to claim 1,
Wherein the microalgae concentration of the culture medium is 0.5 to 2 g / L in the step (b).
The method according to claim 1,
Wherein the initial pH is 9 and the microalgae concentration is 1 g / L in the step (b).
The method according to claim 1,
Wherein the step (b) is performed at a temperature in the range of 15 to 30 占 폚.
14. Biomass comprising microalgae produced according to the method of any one of claims 1 to 13.
15. The method of claim 14,
Wherein the biomass is a raw material for bio-energy or soil conditioner.

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