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Method for determining optimal preservation temperature of biofilm in wastewater treatment

20200140301 ยท 2020-05-07

    Inventors

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    Abstract

    The present disclosure discloses a method for determining optimal preservation temperature of biofilm in wastewater treatment, and belongs to the technical field of environmental engineering. The method for determining the optimum preservation temperature of the wastewater treatment biofilm constructed by the present disclosure comprises measuring the cell activity state of the biofilm by flow cytometry, and taking the preservation temperature closest to the cell activity state before preservation as the optimum preservation temperature. The method of the present disclosure can determine the optimum preservation temperature within a few hours and performs correlation analysis on the characteristic indexes of the biofilm activity recovery process to verify the reliability of the data. By using the method of the present disclosure, the step of recovering the activity of the biofilm process can be omitted, the pollutants can be discharged under the standard, and at the same time, the starting time of engineering application of the biofilm process can be effectively shortened, the long-term stable operation of the biofilm process is maintained, and the method has high industrial feasibility.

    Claims

    1. A method for determining an optimum preservation temperature of a wastewater treatment biofilm, comprising: measuring a cell activity state of the wastewater treatment biofilm based on flow cytometry; comparing the measured results of the cell activity states of the biofilm preserved at different temperatures with those of the biofilm before preservation; and taking the preservation temperature closest to the cell activity state of the biofilm before preservation as the optimum preservation temperature, wherein the measuring the cell activity state comprises measuring the content of living cells, early apoptotic cells, late apoptotic cells and dead cells.

    2. The method according to claim 1, wherein the wastewater treatment biofilm comprises aerobic granular sludge and a nitrifying-denitrifying biofilm.

    3. The method according to claim 1, wherein the measuring the cell activity state of the wastewater treatment biofilm based on the flow cytometry comprises: (1) preparing a test sample solution of the wastewater treatment biofilm: diluting a biofilm sample with a buffer, shaking evenly, filtering, centrifuging, leaving a supernatant, purging the cells with a pre-cooled phosphate buffer, repeating centrifugation and wash twice, then taking the supernatant as a sample, and mixing well with an appropriate amount of 10 Annexin V Binding Buffer; and (2) placing in a flow cytometer for measuring the cell activity state of each sample solution.

    4. The method according to claim 3, wherein a nylon membrane having a pore size of 5-15 m is used for filtration when the biofilm is aerobic granular sludge.

    5. The method according to claim 3, wherein a nylon membrane having a pore size of 6-8 m is used for filtration when the biofilm is a nitrifying-denitrifying biofilm.

    6. The method according to claim 3, wherein when the biofilm is aerobic granular sludge, the test sample solution is prepared by diluting the aerobic granular sludge with a buffer of pH 7.0-8.0.

    7. The method according to claim 3, wherein when the biofilm is a nitrifying-denitrifying biofilm, the test sample solution is prepared by diluting the nitrifying-denitrifying biofilm with a buffer of pH 6.6-7.0.

    8. The method according to claim 3, wherein a dilution volume ratio of the buffer to the biofilm is 8-10:1.

    9. A method for rapidly initiating biofilm engineering, comprising: using the method according to claim 1 to determine an optimum preservation temperature of a biofilm; preliminarily culturing and maturing the biofilm; placing in a preservation medium and preserving at the optimum preservation temperature; recovering activity; and using for an engineering application.

    10. The method according to claim 9, wherein when the biofilm is aerobic granular sludge, the preservation medium has a COD of 250 to 350 mg/L, NH.sub.4.sup.+N of 55-65 mg/L, and PO.sub.4.sup.3P of 6-10 mg/L.

    11. The method according to claim 9, wherein when the biofilm is aerobic granular sludge, the recovering the activity comprises inoculating the aerobic granular sludge into a sequencing batch reactor with a water drainage ratio of 45-60%, a reaction period of 2.5-4 h, a static water inflow period of 1-1.5 h, an aeration reaction period of 1.5-2.5 h, a sludge settling period of 2-6 min, and a rapid drainage period of 2-6 min.

    12. The method according to claim 11, wherein the sequencing batch reactor controls air and nitrogen content and proportion to ensure an anaerobic state of a water inflow section and an aerobic state of a reaction section by a real-time control system.

    13. The method according to claim 9, wherein when the biofilm is a nitrifying-denitrifying biofilm, the preservation medium has a COD of 180-220 mg/L, NH.sub.4.sup.+N of 25-35 mg/L, NO.sub.3.sup.N of 18-25 mg/L and PO.sub.4.sup.3P of 6-10 mg/L.

    14. The method according to claim 9, wherein when the biofilm is a nitrifying-denitrifying biofilm, the recovering the activity comprises inoculating the nitrifying-denitrifying biofilm into a bioreactor on the basis of an anoxic-oxic process with a setting time of 10-15 h, a nitrifying-denitrifying biofilm filling ratio of 40%-60%, and a nitrifying liquid reflux ratio of 70%-85%.

    Description

    BRIEF DESCRIPTION OF FIGURES

    [0029] FIG. 1 shows the settling performance of aerobic granular sludge (sludge volume index SVI).

    [0030] FIG. 2 shows changes in the extracellular polymer (PN/PS) of aerobic granular sludge.

    [0031] FIG. 3 shows the removal rate of total nitrogen (TN) in aerobic granular sludge.

    [0032] FIG. 4 shows the removal rate of total phosphorus (TP) in aerobic granular sludge.

    [0033] FIG. 5 shows changes in the extracellular polymer PN/PS of nitrifying-denitrifying biofilm.

    [0034] FIG. 6 shows the removal rate of ammonia nitrogen (AN) in nitrifying-denitrifying biofilm.

    [0035] FIG. 7 shows the removal rate of total nitrogen (TN) in nitrifying-denitrifying biofilm.

    DETAILED DESCRIPTION

    [0036] The wastewater of the wastewater treatment plant of the present disclosure includes domestic water in residential areas and a small part of industrial wastewater in the upstream, and the annual average of inflow water is COD of 236 mg/L, ammonia nitrogen of 30.1 mg/L, total nitrogen of 37.8 mg/L, and total phosphorus of 4.5 mg/L. The nitrate nitrogen content is less than 1.0 mg/L.

    Example 1: Determination of the Optimum Preservation Temperature of Aerobic Granular Sludge

    [0037] Preservation Conditions of Aerobic Granular Sludge:

    [0038] The preservation temperature of the aerobic granular sludge was set to 20 C., 4 C. and 20 C. The 900 mL of the aerobic granular sludge and wastewater mixture in the aerobic granular sludge pilot plant was taken out, divided into three equal portions and placed in 1000 mL serum bottles containing 500 mL of preservation medium, respectively. The components of preservation medium were as follows: NaAc of 4200 mg/L, NH.sub.4Cl of 1100 mg/L, K.sub.2HPO.sub.4 of 370 mg/L, KH.sub.2PO.sub.4 of 140 mg/L, MgSO.sub.4 of 440 mg/L, KCl of 170 mg/L, and trace element solution of 1 ml/L; the components of trace element liquid composition were as follows: FeCl.sub.3.6H.sub.2O of 1.5 g/L, H.sub.3BO.sub.3 of 0.15 g/L, CuSO.sub.4.5H.sub.2O of 0.03 g/L, KI of 0.03 g/L, MnCl.sub.2.4H.sub.2O of 0.12 g/L, Na.sub.2MoO.sub.4.2H.sub.2O of 0.06 g/L, ZnSO.sub.4.7H.sub.2O of 0.12 g/L, and CoCl.sub.2.6H.sub.2O of 0.15 g/L. The preservation medium had a COD of 300 mg/L, NH.sub.4.sup.+N of 60 mg/L, and PO.sub.4.sup.3P of 8 mg/L. Serum bottles (3 parallel samples at each preservation temperature) were placed at 20 C., 4 C. and 20 C., and stored statically in the dark for 3 months.

    [0039] Cell State Characterization of Stored Aerobic Granular Sludge:

    [0040] Cell State Test Conditions by Flow Cytometry were as Follows:

    [0041] (1) A mixture of aerobic granular sludge stored in a 10 mL pilot system at each temperature for 3 months was taken, respectively, diluted to 100 mL with phosphate buffer of pH 7.2, and shaken for 2 min in a vortexer to break the sludge into flocs and ensure a uniform distribution;

    [0042] (2) The crushed sample was filtered through a nylon membrane having a pore size of 10 m, and 1.5 mL was placed in a 1.5 mL sharp-bottomed centrifuge tube;

    [0043] (3) The sample was centrifuged at 8000 rpm for 5 min;

    [0044] (4) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, the cells were purged with pre-cooled phosphate buffer, and the centrifugation and wash were repeated twice;

    [0045] (5) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, and mixed well with 0.3 mL of 10 Annexin V Binding Buffer;

    [0046] (6) 0.5 L of PI staining agent was added to the control FITC Annexin V group, 0.5 L of FITC Annexin V was added to the control PI group, 0.5 L of FITC Annexin V and 0.5 L of PI were added to the test group, which were mixed well and incubated for 15 min at room temperature in the dark, and then tested on a flow cytometer.

    [0047] The cell state results of aerobic granular sludge were shown in Table 1. The living cell proportion of aerobic granular sludge in the pilot system was higher, indicating that the pilot system works well. The aerobic granular sludge stored at 20 C. had the lowest living cell content and the highest dead cell content, indicating that it was not suitable to store aerobic granular sludge at 20 C. The aerobic granular sludge stored at 4 C. had a proportion of late apoptotic cells and dead cells of about 25.2%, indicating that the 4 C. condition can be used for the preservation of aerobic granular sludge. However, when the preservation temperature was 20 C., the living cell proportion of aerobic granular sludge was as high as 68.5%, which was only 20.0% lower than that of the aerobic granular sludge in the pilot system, indicating that the preservation condition at 20 C. was more suitable for storing aerobic granular sludge, at the same time, since it was necessary to consume more energy to control and maintain the low temperature condition of 4 C., it was preliminarily determined that 20 C. was the optimum temperature for storing aerobic granular sludge.

    TABLE-US-00001 TABLE 1 Cell activity states (%) of aerobic granular sludge stored for 90 days Early Late Aerobic granular apoptotic apoptotic sludge Living cells cells cells Dead cells Pilot system 85.6 3.5 8.4 1.1 1.8 0.2 4.2 0.3 Stored at 20 C. 41.5 1.8 6.0 1.1 4.5 1.0 48.0 2.5 Stored at 4 C. 56.8 2.2 18.2 1.5 10.1 1.2 15.1 1.5 Stored at 20 C. 68.5 2.9 14.1 1.3 11.8 1.2 5.6 0.6

    Example 2: Verification of the Test Results of Aerobic Granular Sludge

    [0048] Activity Recovery Conditions of the Stored Aerobic Granular Sludge:

    [0049] The aerobic granular sludge derived from different serum bottles was inoculated into a sequencing batch reactor (SBR) for the activity recovery of aerobic granular sludge; the aerobic granular sludge stored at 20 C., 4 C. and 20 C. was placed in R1, R2 and R3, respectively. The SBR had an effective volume of 10.0 L, a water drainage ratio of 50%, a reaction period of 3 h, a static water inflow period of 60 min, an aeration reaction period of 112 min, a sludge settling period of 3 min, and a rapid drainage period of 5 min. The air and nitrogen content and proportion were controlled by a real-time control system to ensure the anaerobic state of the water inflow section and the aerobic state of the reaction section; and SRT was controlled to be 25 days.

    [0050] Characteristics of Aerobic Granular Sludge after Activity Recovery:

    [0051] After the activity recovery, all of the aerobic granular sludge in R1, R2 and R3 had good performance. As shown in Table 2, after recovering the aerobic granular sludge activity, the density and particle size of aerobic granular sludge at different preservation temperatures were close to those of aerobic granular sludge before preservation. Although the biomass of aerobic granular sludge (MLSS) at different preservation temperatures was only 91% of the biomass before preservation, on average, the biomass was 37.9% higher than the biomass of aerobic granular sludge after preservation, indicating that aerobic granular sludge re-adapted to the environment and the biomass was stably increased. Generally, the average denitrification rate and phosphorus release rate of activated sludge in the wastewater treatment plant were 3.0 mg/g MLSS.Math.h and 2.2 mg/g MLSS.Math.h, respectively. The domesticated aerobic granular sludge in the pilot plant will respectively take 25 d and 29 d to reach the same denitrification rate and phosphorus release rate. After the activity of the stored aerobic granular sludge was recovered, the aerobic granular sludge in R1 will respectively take 12 d and 13 d to reach the same denitrification rate and phosphorus release rate, the aerobic granular sludge in R2 will respectively take 10 d and 11 d to reach the same denitrification rate and phosphorus release rate, and the aerobic granular sludge in R3 will respectively take 8 d and 7 d to reach the same denitrification rate and phosphorus release rate, indicating that the aerobic granular sludge after the activity recovery all had better nitrogen and phosphorus removal effects, wherein the aerobic granular sludge stored at the temperature of 20 C. has the shortest activity recovery time and the condition at 20 C. was more suitable for storing the aerobic granular sludge.

    TABLE-US-00002 TABLE 2 Properties of aerobic granular sludge after preservation and activity recovery Time (d) Time (d) required for required for phosphorus Average denitrification release rate particle rate to be to be more size MLSS MLVSS more than 3.0 than 2.2 mg/g (g/cm.sup.3) (mm) (mg/L) (mg/L) mg/g MLSS .Math. h MLSS .Math. h Before sludge 1.025 1.6 8.7 7.7 25 29 preservation After aerobic granular sludge preservation After 1.020 1.3 5.6 4.3 preservation at 20 C. After 1.018 1.2 5.8 4.7 preservation at 4 C. After 1.018 1.2 6.2 5.3 preservation at 20 C. After activity recovery of the aerobic granular sludge Aerobic 1.024 1.5 8.0 7.0 12 13 granular sludge stored at 20 C. Aerobic 1.024 1.4 8.0 7.2 10 11 granular sludge stored at 4 C. Aerobic 1.024 1.4 8.0 7.2 8 7 granular sludge stored at 20 C.

    [0052] Settling Performance and Stability of Aerobic Granular Sludge after Activity Recovery:

    [0053] After the activity recovery, the aerobic granular sludge in R1, R2 and R3 had good settling performance, as shown in FIG. 1, and on the 10.sup.th day of activity recovery, all of the aerobic granular sludge at different preservation temperatures had a volume index SVI of less than 50.0 mL/g. Subsequently, the SVI of aerobic granular sludge decreased slightly and eventually stabilized between 46.1 mL/g and 47.8 mL/g. Extracellular polymer was an important factor in the formation of aerobic granular sludge, and the ratio (PN/PS) of protein (PN) substance to polysaccharide (PS) substance in extracellular polymer was an important index for measuring the structural stability of the aerobic granular sludge. The changes in the extracellular polymer PN/PS during activity recovery process of the aerobic granular sludge were shown in FIG. 2. Under different preservation temperatures, PN/PS difference was large, and the PN/PS of the aerobic granular sludge in R1 was in a reduction trend, indicating that the aerobic granular sludge stored at 20 C. had a poor stability and the temperature was not suitable for storing the aerobic granular sludge; the PN/PS of the aerobic granular sludge in the R2 was slightly increased, indicating that the aerobic granular sludge stored at 4 C. can maintain the stable state before preservation; the PN/PS ratio of the aerobic granular sludge in the R3 was obviously increased and tended to be stable, indicating that the aerobic granular sludge stored at 20 C. had a gradually increased stability after recovering the activity, and the temperature was suitable for being used as the preservation temperature of the aerobic granular sludge.

    [0054] Removal Efficiency of Pollutants by Aerobic Granular Sludge after Activity Recovery:

    [0055] After the activity recovery process, the removal rates of total nitrogen and total phosphorus by aerobic granular sludge at different preservation temperatures were gradually increased (FIG. 3 and FIG. 4), and the removal rates of total nitrogen (TN) and total phosphorus (TP) were over 70%. On the 10th day after the activity recovery, the aerobic granular sludge in R3 had the best removal effect on TN and TP, and the TN and TP removal rates showed a steady increase trend. This result also corresponded to the fastest recovery of the higher denitrification rate and phosphorus release rate by the aerobic granular sludge in R3 in Table 2, indicating that the condition at 20 C. was more suitable for storing aerobic granular sludge and was highly feasible in practical applications.

    [0056] Correlation Between Aerobic Granular Sludge Characteristics and Sludge Cell States after Activity Recovery:

    [0057] After 30 d of aerobic granular sludge activity recovery, flow cytometry was used to analyze the aerobic granular sludge cell states (as shown in Table 3). The living cell content in aerobic granular sludge at different preservation temperatures was basically the same as the content of living cells in the aerobic granular sludge of the pilot system, indicating that all of the aerobic granular sludge after the activity recovery can play the role of pollutant removal. Among them, the proportion of aerobic granular sludge living cells in R3 was the highest (86.5%3.5%), and the proportion of late apoptotic cells (3.8%1.0%) and the proportion of dead cells (3.3%0.3%) were the lowest, indicating the aerobic granular sludge cells stored at 20 C. had the highest cell activity and 20 C. was more suitable as a condition for storing aerobic granular sludge.

    TABLE-US-00003 TABLE 3 Cell activity states (%) of aerobic granular sludge cells after activity recovery (30 d) Early Late Aerobic granular apoptotic apoptotic sludge Living cells cells cells Dead cells Pilot system 86.5 3.9 6.7 1.4 5.8 0.8 1.0 0.2 Stored at 20 C. 82.3 3.8 6.5 1.5 6.2 1.3 5.0 0.2 Stored at 4 C. 83.1 3.2 6.5 1.3 6.3 1.2 4.1 0.3 Stored at 20 C. 86.5 3.5 6.4 1.3 3.8 1.0 3.3 0.3

    [0058] According to Correl correlation analysis, it was found that the denitrification rate and the phosphorus release rate of aerobic granular sludge had a very high correlation with the proportion of aerobic granular sludge live cells (as shown in Table 4), and the correlation coefficients were 0.9940 and 0.9954, respectively, indicating that the use of the proportion of aerobic granular sludge living cells as a method for evaluating the activity of aerobic granular sludge was extremely feasible. At the same time, in the stored aerobic granular sludge, the proportion of aerobic granular sludge live cells was the highest under the preservation condition of 20 C., which was consistent with results for the proportion of aerobic granular sludge living cells in R3 after activity recovery.

    TABLE-US-00004 TABLE 4 Correlation between aerobic granular sludge characteristics and cell activity sates after activity recovery Aerobic Aerobic Aerobic granular granular granular sludge stored sludge stored sludge stored at 20 C. at 4 C. at 20 C. Denitrification rate (mg/g 3.18 3.23 3.35 MLSS .Math. h) Phosphorus release rate 2.36 2.45 2.68 (mg/g MLSS .Math. h) Living cell proportion (%) 82.3 3.8 83.1 3.2 86.5 3.9 Correlation between 0.9940 denitrification rate and living cells Correlation between 0.9954 phosphorus release with living cells

    [0059] Therefore, it was determined that 20 C. was the most suitable condition for storing aerobic granular sludge, and flow cytometry can be used as the basis for determining the optimum preservation temperature of aerobic granular sludge. Flow cytometry is easy to operate, the data are fast and easy to obtain, accurate and reliable, and the aerobic granular sludge activity recovery process can be omitted, which is of great significance for the preservation and activity recovery of aerobic granular sludge.

    Example 3: Determination of the Optimum Preservation Temperature of Nitrifying-Denitrifying Biofilm

    [0060] Preservation and Culture of Nitrifying-Denitrifying Biofilm:

    [0061] The preservation temperature of the nitrifying-denitrifying biofilm was set to 20 C., 4 C. and 20 C. 180 nitrifying-denitrifying biofilms in the biochemical reaction tank of the wastewater treatment plant were taken out, divided into three equal portions and placed in 1000 mL serum bottles containing 500 mL of preservation medium to maintain the nitrification and denitrification capacity of the biofilm, respectively. The components of preservation medium were as follows: NaAc of 240 mg/L, NH.sub.4Cl of 110 mg/L, KNO.sub.3 of 80 mg/L, K.sub.2HPO.sub.4 of 30 mg/L, KH.sub.2PO.sub.4 of 15 mg/L, MgSO.sub.4 of 40 mg/L, and KCl of 70 mg/L. The preservation medium had a COD of 200 mg/L, NH.sub.4.sup.+N of 30 mg/L, NO.sub.3.sup.N of 20 mg/L, and PO.sub.4.sup.3P of 8 mg/L. Serum bottles (3 parallel samples at each preservation temperature) were placed at 20 C., 4 C. and 20 C., and stored statically in the dark.

    [0062] Cell State Test of Stored Nitrifying-Denitrifying Biofilm:

    [0063] The nitrifying-denitrifying biofilms stored at 20 C., 4 C. and 20 C. for more than 120 d were used to determine the cell state of nitrifying-denitrifying biofilms. The cell state test conditions of flow cytometry were as follows:

    [0064] (1) 10 mL nitrifying-denitrifying biofilm was taken, diluted to 100 mL with phosphate buffer of pH 7.0, and shaken for 2 min in a vortexer to break the biofilm into flocs and ensure a uniform distribution;

    [0065] (2) The crushed sample was filtered through a nylon membrane having a pore size of 6 m, and 1.5 mL was placed in a 1.5 mL sharp-bottomed centrifuge tube;

    [0066] (3) The sample was centrifuged at 8000 rpm for 5 min;

    [0067] (4) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, the cells were purged with pre-cooled phosphate buffer, and the centrifugation and wash were repeated twice;

    [0068] (5) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, and mixed well with 0.3 mL of 10 Annexin V Binding Buffer;

    [0069] (6) 0.5 l of PI staining agent was added to the control FITC Annexin V group, 0.5 L of FITC Annexin V was added to the control PI group, 0.5 L of FITC Annexin V and 0.5 L of PI were added to the test group, which were mixed well and incubated for 15 min at room temperature in the dark, and then tested on a flow cytometer.

    [0070] The selection of the filtration pore size in the preparation of the sample was particularly important. If the pore size was too large, more biological flocs will be introduced, uneven dyeing will be produced, which will affect the final result; if the pore size was too small, the biological flocs cannot be effectively obtained.

    [0071] The cell state results of nitrifying-denitrifying biofilm were shown in Table 5. The living cells proportion of nitrifying-denitrifying biofilm in the biochemical reaction tank of the wastewater treatment plant was higher, indicating that the wastewater treatment plant works well. The nitrifying-denitrifying biofilm stored at 20 C. had the lowest living cell content and the highest dead cell content, indicating that it was not suitable to store nitrifying-denitrifying biofilm at 20 C. The nitrifying-denitrifying biofilm stored at 4 C. had the highest living cell proportion of 68.0% and a proportion of late apoptotic cells and dead cells of about 19.8%, indicating that the 4 C. condition can be used for the preservation of nitrifying-denitrifying biofilm. When the preservation temperature was 20 C., the living cell proportion of nitrifying-denitrifying biofilm was as high as 59.4%, which was only 12.6% lower than that of the nitrifying-denitrifying biofilm stored at 4 C., but the proportion of late apoptotic cells and dead cells for such nitrifying-denitrifying biofilm was about 31.6%, indicating that the preservation condition at 20 C. was not suitable for storing nitrifying-denitrifying biofilm, either. Therefore, it was preliminarily determined that 4 C. was the optimum temperature for storing nitrifying-denitrifying biofilm.

    TABLE-US-00005 TABLE 5 Cell activity states (%) of nitrifying- denitrifying biofilm stored for 120 days Nitrifying- Early late denitrifying apoptotic apoptotic biofilm Living cells cells cells Dead cells Biochemical 85.0 3.2 9.7 1.0 4.5 0.2 0.8 0.2 reaction tank Stored at 20 C. 40.7 2.0 24.6 1.8 23.4 1.5 11.3 1.5 Stored at 4 C. 68.0 2.9 12.2 1.2 12.4 0.9 7.4 1.2 Stored at 20 C. 59.4 2.5 13.9 1.1 17.7 1.0 9.0 1.6

    Example 4: Verification of the Test Results of Nitrifying-Denitrifying Biofilm

    [0072] Activity Recovery Conditions of the Stored Nitrifying-Denitrifying Biofilm:

    [0073] The operation mode of sequencing batch reactor was used: nitrifying-denitrifying biofilm derived from different serum bottles was inoculated into a bioreactor (effective volume 10.0 L) for the activity recovery of nitrifying-denitrifying biofilm. The nitrifying-denitrifying biofilm stored at 20 C., 4 C. and 20 C. were placed in R1, R2 and R3, respectively. Based on the anoxic-oxic (AO) process, the bioreactor achieved simultaneous nitrification and denitrification in the sequencing batch reaction. The HRT was set to 12 h, the nitrification and denitrification filling ratio was 50%, and the nitrification liquid reflux ratio was 80%.

    [0074] Characteristics of Nitrifying-Denitrifying Biofilm after Activity Recovery:

    [0075] After the activity recovery, all of the nitrifying-denitrifying biofilm in R1, R2 and R3 had good performance. As shown in Table 6, after recovering the nitrifying-denitrifying biofilm activity, the density and thickness of nitrifying-denitrifying biofilm stored at 4 C. and 20 C. were close to those of nitrifying-denitrifying biofilm before preservation, and only the density and thickness of nitrifying-denitrifying biofilm stored at 20 C. slightly decreased. The biomass of nitrifying-denitrifying biofilm at different preservation temperatures all decreased, but after activity recovery, the biomass of nitrifying-denitrifying biofilm stored at 4 C. and 20 C. has achieved the biomass level of nitrifying-denitrifying biofilm before preservation, indicating that nitrifying-denitrifying biofilm re-adapted to the environment and the biomass was stably increased. Generally, the average nitrification rate and denitrification rate of biofilm in the wastewater treatment were 4.5 g NO.sub.3.sup.N/m.sup.2.Math.d and 5.0 g NO.sub.3.sup.-N/m.sup.2.Math.d, respectively. The domesticated nitrifying-denitrifying biofilm in the wastewater treatment plant will respectively take 25 d and 21 d to reach the same nitrification rate and denitrification rate. After the activity of the stored nitrifying-denitrifying biofilm was recovered, the nitrifying-denitrifying biofilm in R1 will respectively take 19 d and 17 d to reach the same nitrification rate and denitrification rate, the nitrifying-denitrifying biofilm in R2 will respectively take 8 d and 6 d to reach the same nitrification rate and denitrification rate, and the nitrifying-denitrifying biofilm in R3 will respectively take 13 d and 10 d to reach the same nitrification rate and denitrification rate. The biofilm thickness L of R1 was significantly reduced before and after the activity recovery, but a higher thickness can be maintained in both R2 and R3, so that a concentration gradient of oxygen was produced in the biofilm, which was beneficial to denitrification. It is indicated that all of the nitrifying-denitrifying biofilms after activity recovery had good denitrification effect. The nitrifying-denitrifying biofilm stored at 4 C. had the shortest activity recovery time and the condition at 4 C. was suitable for storing nitrifying-denitrifying biofilm.

    TABLE-US-00006 TABLE 6 Properties of nitrifying-denitrifying biofilm after preservation and activity recovery Time Time required for required for nitrification denitrification rate to be rate to be more than more than 4.5 g NO.sub.3.sup.N/ 5.0 g NO.sub.3.sup.N/ L MLSS MLVSS m.sup.2 .Math. d m.sup.2 .Math. d (g/cm.sup.3) (m) (mg/L) (mg/L) (d) (d) Biochemical 0.031 202 12.9 6.3 25 21 reaction tank After the preservation of nitrifying-denitrifying biofilm After 0.029 171 11.1 5.0 preservation at 20 C. After 0.030 201 12.6 6.0 preservation at 4 C. After 0.029 200 12.3 5.8 preservation at 20 C. After the activity recovery of nitrifying-denitrifying biofilm Nitrifying- 0.028 189 12.0 5.3 19 17 denitrifying biofilm stored at 20 C. Nitrifying- 0.030 205 12.4 6.2 8 6 denitrifying biofilm stored at 4 C. Nitrifying- 0.029 207 12.5 6.0 13 10 denitrifying biofilm stored at 20 C.

    [0076] Stability of Nitrifying-Denitrifying Biofilm after Activity Recovery:

    [0077] Extracellular polymer was an important factor in the formation of nitrifying-denitrifying biofilm, and the ratio (PN/PS) of protein (PN) substance to polysaccharide (PS) substance in extracellular polymer was an important index for measuring the structural stability of the nitrifying-denitrifying biofilm. The changes in the extracellular polymer PN/PS during activity recovery process of the nitrifying-denitrifying biofilm were shown in FIG. 5. Under different preservation temperatures, PN/PS difference was large, and the PN/PS of the nitrifying-denitrifying biofilm in R1 was in a reduction trend, indicating that the nitrifying-denitrifying biofilm stored at 20 C. had a poor stability and the temperature was not suitable for storing the nitrifying-denitrifying biofilm; the PN/PS of the nitrifying-denitrifying biofilm in the R3 was slightly increased, indicating that the nitrifying-denitrifying biofilm stored at 20 C. can maintain the stable state before preservation; the PN/PS ratio of the nitrifying-denitrifying biofilm in the R2 was obviously increased up to 4.2 or more and tended to be steady, indicating that the nitrifying-denitrifying biofilm stored at 4 C. had a gradually increased stability after recovering the activity, and the condition at 4 C. was suitable for being used as the preservation temperature of the nitrifying-denitrifying biofilm.

    [0078] Removal Efficiency of Pollutants by Nitrifying-Denitrifying Biofilm after Activity Recovery:

    [0079] After the activity recovery process, the removal rates of ammonia nitrogen and total nitrogen by nitrifying-denitrifying biofilm at different preservation temperatures were gradually increased (FIG. 6 and FIG. 7), and the removal rates of ammonia nitrogen and total nitrogen were over 90% and 80%, respectively. On the 8.sup.th day after the activity recovery, the nitrifying-denitrifying biofilm in R2 had the best removal effects on ammonia nitrogen and total nitrogen, and the ammonia nitrogen and total nitrogen removal rates showed a steady increase trend. This result also corresponded to the fastest recovery of the higher nitrification rate and denitrification rate by the nitrifying-denitrifying biofilm in R2 in Table 6, indicating that the condition at 4 C. was more suitable for storing nitrifying-denitrifying biofilm and was highly feasible in practical applications.

    [0080] Correlation Between Nitrifying-Denitrifying Biofilm Characteristics and Sludge Cell States after Activity Recovery:

    [0081] After the nitrifying-denitrifying biofilm activity recovery, flow cytometry was used to analyze the nitrifying-denitrifying biofilm cell states as shown in Table 7. The living cell content in nitrifying-denitrifying biofilm at different preservation temperatures was basically the same as the content of living cells in the nitrifying-denitrifying biofilm of the wastewater treatment plant, indicating that all of the nitrifying-denitrifying biofilm after the activity recovery can play the role of pollutant removal. Among them, the proportion of nitrifying-denitrifying biofilm living cells in R2 was the highest (84.3%3.0%), and the proportion of late apoptotic cells (6.2%1.5%) and the proportion of dead cells (4.3%0.3%) were the lowest, indicating the nitrifying-denitrifying biofilm cells stored at 4 C. had the highest cell activity and 4 C. was more suitable as a condition for storing nitrifying-denitrifying biofilm.

    TABLE-US-00007 TABLE 7 Cell activity states (%) of nitrifying-denitrifying biofilm after activity recovery Nitrifying- Early Late denitrifying apoptotic apoptotic biofilm Living cells cells cells Dead cells Biochemical 85.1 3.0 8.9 0.7 5.0 0.2 1.0 0.1 reaction tank Stored at 20 C. 82.5 3.5 6.5 1.8 6.5 1.3 4.5 0.5 Stored at 4 C. 84.0 3.0 5.5 1.7 6.2 1.5 4.3 0.3 Stored at 20 C. 83.0 3.1 5.8 1.7 6.8 1.3 4.4 0.7

    [0082] According to Correl correlation analysis, as shown in table 8, the nitrification rate and the denitrification rate of nitrifying-denitrifying biofilm had a very high correlation with the proportion of nitrifying-denitrifying biofilm live cells, and the correlation coefficients were 0.9286 and 0.9819, respectively, indicating that the use of the proportion of nitrifying-denitrifying biofilm living cells as a method for evaluating the activity of nitrifying-denitrifying biofilm was extremely feasible. At the same time, in the stored nitrifying-denitrifying biofilm, the proportion of nitrifying-denitrifying biofilm live cells was the highest under the preservation condition of 4 C., which was consistent with results for the proportion of nitrifying-denitrifying biofilm living cells in R2 after activity recovery.

    TABLE-US-00008 TABLE 8 Correlation between nitrifying-denitrifying biofilm characteristics and cell activity sates after activity recovery Nitrifying- Nitrifying- Nitrifying- denitrifying biofilm denitrifying biofilm denitrifying biofilm stored at 20 C. stored at 4 C. stored at 20 C. Nitrification rate (g 4.7 5.0 4.9 NO3.sup.-N/m.sup.2 .Math. d) Denitrification rate (g 5.1 5.5 5.3 NO3.sup.-N/m.sup.2 .Math. d) Living cells proportion 82.5 3.5 84.0 3.0 83.0 3.1 (%) Correlation between 0.9286 nitrification rate and living cells Correlation between 0.9820 denitrification rate and living cells

    [0083] Therefore, it was determined that 4 C. was the most suitable condition for storing nitrifying-denitrifying biofilm, and flow cytometry can be used as the basis for determining the optimum preservation temperature of nitrifying-denitrifying biofilm. Flow cytometry is easy to operate, the data are fast and easy to obtain, accurate and reliable, and the nitrifying-denitrifying biofilm activity recovery process can be omitted, which is of great significance for the preservation and activity recovery of nitrifying-denitrifying biofilm.

    Example 5: Test for Optimum Preservation Temperature of Nitrifying-Denitrifying Biofilm in Different pH Environments

    [0084] Preservation and Culture of Nitrifying-Denitrifying Biofilm:

    [0085] The preservation temperature of the nitrifying-denitrifying biofilm was set to 20 C., 4 C. and 20 C. 180 nitrifying-denitrifying biofilms in the biochemical reaction tank of the wastewater treatment plant were taken out, divided into three equal portions and placed in 1000 mL serum bottles containing 500 mL of preservation medium, respectively. The components of preservation medium were as follows: NaAc of 240 mg/L, NH.sub.4Cl of 110 mg/L, KNO.sub.3 of 80 mg/L, K.sub.2HPO.sub.4 of 30 mg/L, KH.sub.2PO.sub.4 of 15 mg/L, MgSO.sub.4 of 40 mg/L, and KCl of 70 mg/L. The preservation medium had a COD of 200 mg/L, NH.sub.4.sup.+N of 30 mg/L, NO.sub.3N of 20 mg/L, and PO.sub.4.sup.3P of 8 mg/L. Serum bottles (3 parallel samples at each preservation temperature) were placed at 20 C., 4 C. and 20 C., and stored statically in the dark.

    [0086] Cell State Test of Stored Nitrifying-Denitrifying Biofilm:

    [0087] The nitrifying-denitrifying biofilms stored at 20 C., 4 C. and 20 C. for more than 120 d were used to determine the cell state of nitrifying-denitrifying biofilms. The cell state test conditions of flow cytometry were as follows:

    [0088] (1) 10 mL nitrifying-denitrifying biofilm was taken, diluted to 100 mL with phosphate buffer of pH 7.2, and shaken for 2 min in a vortexer to break the biofilm into flocs and ensure a uniform distribution;

    [0089] (2) The crushed sample was filtered through a nylon membrane having a pore size of 6 m, and 1.5 mL was placed in a 1.5 mL sharp-bottomed centrifuge tube;

    [0090] (3) The sample was centrifuged at 8000 rpm for 5 min;

    [0091] (4) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, the cells were purged with pre-cooled phosphate buffer, and the centrifugation and wash were repeated twice;

    [0092] (5) The supernatant of the sample after centrifugation was pipetted with leaving about 0.1 mL of sample, and mixed well with 0.3 mL of 10 Annexin V Binding Buffer;

    [0093] (6) 0.5 L of PI staining agent was added to the control FITC Annexin V group, 0.5 L of FITC Annexin V was added to the control PI group, 0.5 L of FITC Annexin V and 0.5 L of PI were added to the test group, which were mixed well and incubated for 15 min at room temperature in the dark, and then tested on a flow cytometer.

    [0094] The test results for cell state of nitrifying-denitrifying biofilm were shown in table 9.

    TABLE-US-00009 TABLE 9 Cell activity states (pH 7.2) of nitrifying- denitrifying biofilm stored for 120 days Nitrifying- Early Late denitrifying apoptotic apoptotic biofilm Living cells cells cells Dead cells Stored at 20 C. 47.0 2.0 14.6 1.5 22.5 1.9 15.9 1.7 Stored at 4 C. 48.0 2.4 15.1 1.1 23.5 2.0 13.4 1.8 Stored at 20 C. 49.1 2.1 14.9 1.1 21.7 2.1 14.3 1.1

    [0095] From the results of Table 9, it was found that the samples prepared by using the phosphate buffer of pH 7.2 were selected to be tested, the proportion of the cell state in the living condition at each preservation temperature was relatively close, the beneficial results could not be obtained for analysis, and the data reliability was poor.

    [0096] In addition, the inventors also investigated the effect of filter pore size on the sample test: the nitrifying-denitrifying biofilm samples were respectively prepared with pore sizes of 8 m and 10 m, and it was found that the analysis results of the sample prepared with pore size of 8 m were consistent with the verification experiment, and the data was reliable; the corresponding data with 10 m did not have analytical capacity and cannot be used to determine the optimum preservation temperature.