KR20110029108A - The outdoor perfusion culture process of marine microalgae using thermal effluent of nuclear power plant - Google Patents

Abstract

PURPOSE: An outdoor perfusion culture method of marine microalgae using thermal effluent of nuclear power plant is provided to resolve environmental problem and obtain a large amount of microalgae. CONSTITUTION: A method for culturing marine microalgae using thermal effluent of nuclear power plant comprises: a step of continuously injecting nutrition materials and thermal effluent of nuclear power plant into a photo-bioreactor and discharging culture liquid from the photo-bioreactor at the same time; and a step of collecting remaining microalgae from the culture liquid by filtering and injecting the microalgae to the photo-bioreactor.

Description

The outdoor perfusion culture process of marine microalgae using thermal effluent of nuclear power plant}

The present invention relates to a perfusion culture process of marine microalgae, and more particularly, by utilizing a warm thermal effluent discharged from a nuclear power plant, culturing microalgae requires a warm temperature. The present invention relates to a technology capable of cultivating outdoor microalgae to meet the conditions necessary for cultivating marine microalgae, and at the same time, helping to solve environmental problems caused by warm drainage.

The present invention utilizes the thermal power of the nuclear power plant, which was used as a cooling water of a conventional nuclear power plant and flowed into the sea, causing various environmental problems in outdoor cultivation of marine microalgae, while efficiently utilizing thermal energy embedded in the nuclear power plant's thermal wastewater, and at the same time, environmental problems caused by the warm water. There is a characteristic in solving the problem.

High concentrations of culture are essential for the industrial use of marine microalgae as a biofuel.

Batch culture, fed-batch culture, etc. are known as a culture process of seawater microalgae.

First, in the case of batch culture, the strain does not grow to a certain concentration because nutrients are easily depleted and toxic by-products are accumulated by inserting a culture medium into the incubator.

It is a fed-batch culture that overcomes the shortcomings of batch culture as described above. This is a method of continuously supplying a new culture solution in accordance with the growth of cells. Can be. On the other hand, growth is reduced by the accumulation of waste products and severe imbalance of nutrients at the end of the culture.

Therefore, it is considered that the method of culturing strains using a perfusion culture process as in the present invention is effective. As described above, the conventional batch and fed-batch cultivation processes are easy to cultivate, but it is difficult to obtain high concentrations of cells in a batch cultivation, and the fed-batch cultivation can obtain high concentrations of cells, At the end of the cultivation it results in the accumulation of waste and severe imbalance of nutrients. In comparison, the perfusion culture has an advantage that high concentration culture is possible by continuously supplying fresh culture solution and continuously removing the used culture solution.

Meanwhile, Korea (South Korea) located in the mid-latitude has a low temperature due to cold winter northwest wind, so it is difficult to carry out outdoor culture of marine microalgae in warm regions. There are also similar difficulties in other countries where sea temperature is low.

In the present invention, in order to solve this problem, it was intended to utilize the hot water discharged from the nuclear power plant, this attempt was the first, nuclear power plant that was difficult to manage otherwise despite the bad impact on the ecosystem, such as destroying the sea ecosystem in the meantime By utilizing the present invention in the outdoor culture of marine microalgae, it is possible to contribute to energy utilization and environmental pollution solution. When a nuclear power plant is located on the coast, a huge amount of hot water is constantly discharged to the sea, and the high heat energy of the hot water has a variety of effects on the marine ecosystems around the nuclear power plant, which ultimately adversely affects fisheries. The characteristic of the warm water showing a high temperature of 7 to 8 ° C was used inversely. Conventionally, it was possible to cultivate marine microalgae outdoors only in a high temperature region, and according to the present invention, even if the region can be supplied with nuclear power plant, outdoor light cultivation is possible even in a low temperature region.

Detailed description of the invention

An object of the present invention is to provide a method for culturing a large amount of microalgae outdoors in a seawater environment.

The present invention having the above object as a method of culturing the marine microalgae in a perfusion type outdoors using a nuclear power plant,

While continuously injecting fresh nutrients necessary for the cultivation of microalgae into the photo-bioreactor along with nuclear wastewater, the medium is continuously pumped from the photo-bioreactor using a pump.

The microalgae contained in the cultured medium are filtered through a level filter and continuously fed back into the photo-bioreactor, the overflow is discarded, and the remaining culture is mixed with the nuclear wastewater. By circulating the outside of the optical-bioreactor to be discarded.

In addition, at this time, in the circulated outside of the optical-bioreactor by mixing a portion of the culture medium with the nuclear power plant waste water, the means for circulating to the outside of the optical-bioreactor is characterized in that the transparent tube.

The present invention is characterized by the above culture method or the culture system itself, and is not characterized in the kind of nutrients. Nutrients necessary for the cultivation of microalgae may be appropriately selected and used according to circumstances.

In the perfusion type optical culture method of marine microalgae using the nuclear power plant of the present invention, the micro-algae are cultured outdoors in an optical bioreactor, and the used medium is extracted while removing the spent medium to the outside of the optical bioreactor. Add fresh medium to continue nutrient replenishment. When the spent algae are discharged out, the microalgae go out together with the culture medium, and the microalgae contained in the discharged medium are filtered through a level filter and brought back into the incubator. The level filter is not a special structure, but means a filter for filtering submerged microalgae. The filtering method by the level filter is performed by the difference in weight, and the overflow of the upper layer in which the heaviest microalgae in the spent medium does not go down and the remaining light impurities are discharged out.

In addition, the overflow (overflow) of the culture medium used in the above process is discarded and the remainder is mixed with the new nuclear power plant waste water to pass around the incubator. This is to utilize the warmth of the culture medium used to maintain the temperature of the photo-bioreactor. The mixing of the used culture solution with fresh nuclear power wastewater is because the temperature of the used culture solution is somewhat lowered.

In the present invention, it is preferable that the means for mixing some of the culture medium used with the nuclear wastewater to circulate outside of the photo-reactor is a transparent tube so as not to block sunlight from penetrating into the photo-reactor. .

Although not an essential feature of the present invention, it is clear that the temperature inside the photo-reactor or after the mixing of some of the used culture medium with the nuclear wastewater is controlled by using a separate thermometer to adjust the microalgal culture environment. Can be. The matters related to this may be selected by those of ordinary skill in the practice of the present invention, and thus detailed description thereof will be omitted.

According to the present invention, by culturing the marine microalgae utilizing the hot thermal effluent discharged from the nuclear power plant to meet the conditions necessary for the cultivation of microalgae that requires warm temperature, even in an environment where the sea water is not warm Outdoor mass cultivation of marine microalgae is possible without the use of energy.

In addition, it is possible to cultivate a high concentration of marine microalgae, which was difficult in the conventional fed-batch culture method.

In addition, the wastewater that has been a problem in the past is not only used directly for the cultivation of microalgae, but also collected without being discarded and recycled to a tube wrapped around the incubator to be used for maintaining the incubator's warmth. Not only can they be fully used, they can also help solve environmental problems caused by warm water.

1 illustrates an example of implementing the present invention, and shows an example of an outdoor perfusion culture process using thermal effluent of nuclear energy power plant.
① Input flow from into photo-bioreactor: Thermal Effluent with others nutrients
② Outflow: On-water drainage, used culture material and microalgae (Out flow from photo-bioreactor: Thermal Effluent with spent medium and microalgae)
③ Overflow of thermal effluent and spent medium
④ warm effluent and spent medium
⑤ filtered microalgae
⑥ Mix of constant temperature thermal effluent and spent medium
Embodiment for Invention
An embodiment of the present invention will be described with reference to FIG. 1.
In the present invention, the marine microalgae are cultured outdoors in the light-bioreactor. In the photo-bioreactor, a new medium containing nutrients necessary for microalgae cultivation (fresh medium) is continuously added to the inlet along with nuclear wastewater to replenish nutrients (①). Because of the use of nuclear power plant, outdoor cultivation is possible even in cold conditions.
On the other hand, the photo-bioreactor continuously discharges the culture solution, and may use a means such as a pump (②). The discharged culture may contain spent medium and microalgae.
The overflow of the discharged culture solution is discarded (③), and the microalgae contained therein are filtered through a level filter and sent back into the incubator (⑤). In addition, the remaining culture solution [4, which may contain a spent medium (spent medium)] is then mixed with a new nuclear power plant (6) and passed through a transparent tube wrapped around the incubator. The broth used thereby contributes to maintaining the temperature of the incubator until the end.
As described above, in the present invention, the new culture solution is introduced and the used culture solution is repeated to satisfy the optimum requirements for microalgae and at the same time prevents accumulation of waste products. The number of cells in the incubator continues to increase because it is filtered back to the incubator.
As described above, the present invention uses the same hot water drainage as the general seawater, but can utilize the advantages of the existing seawater culture technology as it is, while improving energy utilization and contributing to the problem of environmental pollution caused by warm water drainage.
Next, an experimental example of an outdoor perfusion light cultivation method using nuclear power plant wastewater is introduced.
[Step 1: Culture Sterilization Process]
The culture medium was 20 ml / L of Enrichment Solution 20 ml / L (Pasteurized thermal plume, NaNO ₃ 4.7g / 2L, Na _{2) in} 1L of nuclear power wastewater sterilized by autoclaving at 121 ° C. for 15 minutes using a high pressure sterilizer (manufactured by HK-AC120, Korea). glycerophosphate · 5H ₂ O 0.7g / 2L, ES Fe solution 325ml / 2L, P-IIMetal solution 325ml / 2L, HEPES buffer 6.5g / 2L, Vitamin B ₁₂ 3ml / 2L, Biotin Vitamin Solution 3ml / 2L, Thiamin Vitamin Solution 3ml / 2L) was used.
[Step 2: Inoculation and Stirring]
The incubator was also autoclaved at 121 ° C. for 15 minutes using a high pressure sterilizer, and then sprinkled with alcohol around the inlet to ignite the inlet, and then inoculated with the culture medium and microalgae Chlorella minutissima (UTEX, LB2341, USA) through the inlet. Stir at 150 rpm. And continue to add the same culture to replenish nutrients.
[3rd process: strain separation process through perfusion culture]
Simultaneously with the addition of the culture solution, the used culture solution is continuously taken out. At this time, the microalgae, like the used culture medium, go out, and the microalgae strain is separated and sent back into the incubator using the level filter contained in the discharged culture medium, while the overflow is discarded and the remaining culture medium is moved around the incubator. Circulate in a wrapped transparent tube.
[4th process: process using warm wastewater]
In the third process, the culture solution introduced into the transparent tube is mixed with the fresh nuclear wastewater and flowed into the tube to maintain the warmth of the incubator.
Experimental Example 1.
For this experiment, the experiment was conducted in January and February when the temperature was low near Uljin Nuclear Power Plant where the nuclear power plant drained water. A 14 L outdoor perfusion light-cultivation device (optical-bioreactor) was used, and experiments were performed using general seawater and nuclear power plant wastewater according to the process described in FIG. 1 and above. Graph 1 is a comparative analysis of the temperature change of the culture medium according to this.

It can be seen that the use of the perfusion light cultivation apparatus through the warm drainage as described above maintains a considerably high temperature compared to that of Uljin. Therefore, it can be seen that it is possible to cultivate outdoors in a low temperature region because constant heat retention is maintained through a perfusion photoculture method using warm water.
Experimental Example 2.
The cell weights of outdoor cultures using warm water and outdoor cultures using general seawater were compared. In order to measure the growth of cells, 30 ml of the culture medium and the cells were taken in a 14 L light-bioreactor at 5 days intervals, and then measured in a wavelength range of 540 nm using a UV / Visible spectrophotometer (Kontron Instruments). The sample collected for dry cell weight measurement was filtered with 0.45 μm filter paper, and then dried at 80 ° C. for 24 hours, and then dried to fix the weight.

As shown in Graph 2, the perfusion culture using the warm water drainage maintained the warmth showed a relatively high cell production compared to the outdoor perfusion culture without any action. As a result, it can be seen that the cultivation through the warm drainage does not adversely affect the culture solution using the seawater, but rather, the outdoor mass cultivation can be efficiently performed due to the high thermal energy of the warm drainage.
Experimental Example 3.
In order to examine the possibility of biodiesel as a raw material of cultivation using warm water and outdoor cultivation using general seawater, lipid production was compared. In order to measure the intracellular lipids, the dried cells were lyophilized and pulverized before pretreatment. Then, 20 g of solvent CHCl ₃ : methanol (2: 1 v / v) was added to 1 g of the pulverized sample using Folch method, and the temperature was 30 to 30 ° C. Stir for 90 minutes. Then, the mixture was centrifuged, the supernatant was taken, 0.9% NaCl solvent was added, vortexed for several seconds, the centrifuged again, the supernatant was discarded, and the extract containing lipids (lower layer) was dried and weighed to obtain a fat content.

As a result, it can be seen that the lipid content, which is a useful material of biodiesel, is greatly increased when using warm water as described above. As a result, the possibility of producing abundant biodiesel lipids was confirmed through a perfusion type light cultivation process using warm water to produce lipids for biodiesel during outdoor culture in an area affected by low temperature.
Industrial availability
According to the present invention, the marine microalgae can be cultured in a large amount outdoors even in a cold region by utilizing hot effluent discharged from a nuclear power plant. Thus it can be used directly for the utilization of biofuels.

Claims (2)

Fresh nutrients necessary for the cultivation of microalgae are continuously injected into the photo-bioreactor together with the nuclear power plant wastewater, and the pump is continuously pumped out of the photo-bioreactor, and the microalgae contained therein Is filtered through a level filter and continuously fed back into the photo-bioreactor,
Overflow is discarded, and the remaining culture solution is mixed with nuclear power and wastewater to circulate outside the optical-bioreactor, and then discarded.
Perfusion culture method of marine microalgae using nuclear wastewater from nuclear power plants. The method of claim 1,
In the circulating outside the optical-bioreactor, a portion of the culture broached mixed with the nuclear power wastewater,
The means for circulating outside of the photo-bioreactor is a transparent tube,
Perfusion culture method of marine microalgae using nuclear wastewater from nuclear power plants.

Images