KR100723543B1 - Operation technique of single reactor for sporulation of genus bacillus - Google Patents

Abstract

A method for operating a single reactor for sporulation of Genus bacillus is provided to reduce the size of the reactor and perform the sporulation within short period of time by progressing the sporulation of the Genus bacillus in the single reactor. The method comprises the steps of: (a) after precipitating Genus bacillus flowing into a single reactor for about 10-12 hours, returning generated supernatant therefrom; and (b) applying heat to the precipitated Genus bacillus to a temperature of 80-90 deg.C for about less than 2 hours to sporulate it, and then returning it. The method further comprises a step of: agitating the precipitated Genus bacillus at a predetermined speed.

Description

Operation Technique of single reactor for Sporulation of Genus Bacillus

1 is a view showing the configuration of a single reactor for spores of the Bacillus community to which the present invention is applied.

Figure 2 shows the flow for the operation of a single reactor for spores of the Bacillus community according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: reactor 11: inlet valve

12 temperature controller 13 supernatant liquid return valve

14: stirrer 15: heating jacket

16: sludge return valve 17: supernatant return pump

18: sludge conveying pump

The present invention relates to the operation of a single reactor for the sporulation of Bacillus community for the treatment of sewage, manure, livestock waste and organic industrial wastewater, and more specifically, spores by heating the Bacillus community of nutrient cells in a single reactor It is about driving method to promote anger.

Generally, activated sludge method for wastewater treatment is to remove organic matter, so the efficiency of treating nitrogen and nutrients is very low. Therefore, nutrients of nitrogen and phosphorus, which are excessively released into the natural world, cause eutrophic lakes and red tide in lakes and coasts, causing enormous loss to the natural environment and human life.

Accordingly, advanced treatment technologies such as A / O, VIP, and SBR have been developed to remove nutrients contained in sewage and wastewater.

These methods are mainly to nitrify nitrogen and then denitrify in anoxic state to remove nitrogen, increase phosphorus release in anaerobic state, and then remove phosphorus by ingestion of microorganisms in aerobic state.

However, these methods inject a large amount of air to nitrify ammonia nitrogen and return it to a reactor that maintains anaerobic conditions for denitrification. Therefore, organic substances decay in the reactor in anaerobic conditions, causing odor or oxidizing ammonia nitrogen. It takes a lot of energy and requires a lot of maintenance costs, and it is sensitive to water quality and water temperature fluctuations, so it is not possible to obtain stable water quality, and it requires a lot of facility costs because it requires 10 to 20 times dilution water after anaerobic or aerobic digestion. Due to the complexity of the process, there was a difficulty in acquiring advanced driving skills.

In view of this point, a short rod shape, and subject to the positive gram in a non-ideal environment for growth to create a resistant spores resistant anaerobic bacteria Bacillus (Bacillus) Wu Burning, the organic material contained in the waste water, Bacillus for removing nitrogen and phosphorus Advanced sewage and wastewater treatment technology using clusters has been developed.

In other words, abandoning the reaction tank composed of a plurality of yarns in a tapered aeration method (gradually decreasing the air method) to finally form an anaerobic state, and by returning the spores of the Bacillus cluster in the anoxic state back to the reactor to spore-> By repeating the life cycle of the cells-> spores, it maintains more than a certain number of cells in the reactor to remove organic matter, nitrogen and phosphorus contained in the waste water.

However, spore culture in this Bacillus process requires low DO (Dissolved Oxygen) and organic-free conditions in order to proceed with spores, and at the same time requires sufficient residence time for spores. As a result, the size of the reactor increases and a problem that requires a lot of time occurs.

Accordingly, the present invention is to solve the above problems, by proceeding the spores of the Bacillus community in a single reactor, the appropriate operation of the spore culture tank of the Bacillus community to perform the spores in a short time while reducing the size of the reactor In providing a method.

The operation method of the single reaction tank for spores of the Bacillus community using a single reaction tank according to an aspect of the present invention for achieving the above object is settled for a predetermined time after the water containing the Bacillus community flowing into the single reaction tank, the supernatant produced The step of conveying and warming the settled Bacillus community to a predetermined temperature for a period of time includes the step of promoting spores and conveying.

Preferably, the operation of a single reactor for sporulation of the Bacillus community according to an aspect of the present invention further comprises the step of stirring the precipitated Bacillus community at a set rate.

The return of the supernatant is preferably made up of 40 to 60% of the supernatant.

The predetermined time for staying in the Bacillus community is preferably 10 to 12 hours.

The temperature and a predetermined time set for heating the precipitated Bacillus community is preferably 80 ~ 90 ℃ and 2 hours or less, respectively.

The set speed for stirring the precipitated Bacillus community is preferably 20 ~ 30RPM.

According to another aspect of the present invention, a method of operating a single reaction tank for sporulation of a Bacillus community using a single reaction tank includes returning a supernatant generated by immersing a Bacillus community flowing into the single reaction tank for a predetermined time, and the precipitated Bacillus. While the cluster is stirred at a constant speed, a step of warming to a predetermined temperature for spores and conveying.

The operation method of the spore culture tank of the Bacillus community using a single reaction tank according to another aspect of the present invention is to return 40 to 60% of the supernatant generated by holding the Bacillus community flowing into the single reactor for 10 to 12 hours; , And the Bacillus colony was kept for 10 to 12 hours, and the precipitated Bacillus colony was heated at 80 to 90 ° C. for 2 to 3 hours while stirring at 20 to 30 RPM, followed by sporulation.

Hereinafter, a method of operating a spore culture tank of a Bacillus community according to the present invention will be described in detail with reference to the accompanying drawings.

In addition, it should be noted that the same reference numerals are given to the same elements, although belonging to different drawings for convenience of understanding.

1 is a view showing a configuration for a single reactor for spores of the Bacillus community to which the present invention is applied.

As shown in Figure 1, the single reactor for spores of the Bacillus community according to the present invention is a reaction vessel 10, inlet valve 11, temperature controller 12, supernatant return valve 13, agitator 14 And a heating jacket 15, a sludge conveying valve 16, a supernatant liquid conveying pump 17, and a sludge conveying pump 18.

Reactor 10 is a device for sporifying the Bacillus community by heating the Bacillus community of the feeder cells.

The inflow valve 11 is a valve for introducing a Bacillus community into the reaction tank 10, it is preferably installed on the upper end of the reaction tank (10).

The supernatant return valve 13 is a valve for returning the supernatant containing the organic material generated as the Bacillus community introduced into the reaction tank 10 through the inlet valve 11 stays for a predetermined time and is precipitated, and 40 to 60 of the supernatant It is preferable to be provided in the position of the reaction tank 10 so that% may be conveyed.

At this time, the predetermined time for staying in the Bacillus community is preferably 10 to 12 hours.

The supernatant liquid conveying pump 17 is connected to the supernatant liquid conveying valve 13 and is a pump for conveying the supernatant liquid in the reaction tank 10.

The heating jacket 15 is a device for warming the precipitated Bacillus community to a set temperature, and 40 to 60% of the supernatant is returned from the bottom of the reaction tank 10 to efficiently heat the remaining Bacillus community after the reaction tank (10) It is preferable to be attached to the position of).

At this time, the set temperature for heating the precipitated Bacillus community is preferably 80 ~ 90 ℃.

The stirrer 14 is an apparatus for stirring the precipitated Bacillus community at a constant speed in order to efficiently transfer heat upon heating of the precipitated Bacillus community.

At this time, the constant speed for stirring the precipitated Bacillus community is preferably 20 ~ 30RPM.

The sludge conveyance valve 16 is a valve for conveying the sporeed Bacillus community, and is preferably provided at the lower end of the reaction vessel 10.

The sludge conveying pump 18 is connected to the sludge conveying valve 16 and is a pump for conveying sporeed Bacillus communities in the reaction tank 10.

The temperature controller 12 is a device for measuring the internal temperature in the reactor 10 to maintain the production temperature of the spores.

Figure 2 is a view showing the flow for the operation of a single reactor for spores of the Bacillus community according to the present invention.

As shown in Figure 2, the operation method of the spore culture tank of the Bacillus community according to the present invention can be applied to a single reactor for spores of the Bacillus community shown in FIG.

Therefore, the operation of a single reactor for sporulation of the Bacillus community according to the present invention will be described using the configuration of a single reactor for spore of the Bacillus community shown in FIG.

Bacillus colonies made of feeder cells are introduced into the reaction tank 10 through the inlet valve (11) (S20).

Thereafter, the Bacillus community introduced into the reaction tank 10 is maintained for a predetermined time (10 to 12 hours), thereby generating a Bacillus colony and a supernatant precipitated as a predetermined time passes (S21).

40 to 60% of the supernatant thus produced is conveyed through the supernatant return valve 13 and the supernatant return pump 17 (S22).

In order to increase the efficiency of deposition and heating of the precipitated Bacillus community using the stirrer 14, the stirring of the Bacillus community is maintained at a set speed (20-30 RPM) (S23), and stirring is performed through the heating jacket 15. The Bacillus community is heated to spores for a set temperature (80 ~ 90 ℃) and time (less than 2 hours) (S24).

The Bacillus community that has precipitated through the heating jacket 15 is heated to convey the sporulated Bacillus community through the sludge return valve 16 and the sludge return pump 18 (S25).

As described above, according to the operation method of the single reaction tank for sporulation of the Bacillus community according to the present invention, the supernatant generated by precipitating the Bacillus community flowing in the single reaction tank for a predetermined time, and the settled Bacillus community is set By heating at a temperature for a certain period of time and sporulating and conveying, spores can be carried out within a short time while reducing the size of the reactor.

Claims (7)

A method of operating a single reactor for sporulation of a Bacillus colony using a single reactor, the method comprising: returning a supernatant generated by precipitating the Bacillus community flowing into the single reactor for a predetermined time; The method of operation of a single reactor for sporulation of the Bacillus community comprising the step of spores and conveyed by heating the precipitated Bacillus community to a predetermined temperature for a predetermined time. The method of claim 1, A method of operating a single reactor for spores of the Bacillus community further comprising the step of stirring the precipitated Bacillus community at a set rate. The method of claim 1, The return of the supernatant is a method of operating a single reactor for sporulation of Bacillus community consisting of 40 ~ 60% of the supernatant. The method of claim 1, The method of operating a single reactor for sporulation of the Bacillus community is a predetermined time for staying in the Bacillus community is 10 to 12 hours. The method of claim 1, The set temperature and a predetermined time for heating the precipitated Bacillus community is 80 ~ 90 ℃ and 2 or less operation method of a single reactor for spores of Bacillus community. The method of claim 2, The set speed for stirring the precipitated Bacillus community is 20 ~ 30RPM operation method of a single reactor for spores of Bacillus community. In the operation method of a single reaction tank for sporulation of Bacillus community using a single reactor, the step of returning the supernatant generated by the residence of the Bacillus cluster flowing into the single reactor for a certain time and the Bacillus cluster is settled by a predetermined time While carrying out a step of heating and spores the Bacillus community at a predetermined temperature while stirring at a constant speed, and spores, Returning 40 to 60% of the supernatant generated by maintaining the Bacillus community flowing into the single reactor for 10 to 12 hours; Bacillus colony, characterized in that the Bacillus community comprising the step of holding for 10 to 12 hours and the precipitated Bacillus community by stirring at 20 ~ 30RPM heated to 80 ~ 90 ℃ or less and spores and conveyed Operation of a Single Reactor for Spores of Water.

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