Formation of Aerobic Granular Sludge in a Continuous-Flow Reactor – Control Strategy for the Selection of Well-Settling Granular Sludge

ABSTRACT In this study, the formation characteristics of aerobic granular sludge in a continuous-flow reactor were investigated under several experimental conditions. Both surface loading rate (equal to liquid linear velocity at a sludge settling zone) and aeration rate strongly affected the selection of well-settling sludge in the same manner as sludge settling time in a sequencing batch reactor. By setting and controlling adequate surface loading and aeration rates, small particles were effectively washed out, and well-settling sludge selectively remained in the reactor. As a result, aerobic granular sludge was effectively formed. On the other hand, feeding pattern, i.e., continuous and intermittent feeding, did not affect the aerobic granulation when completely inorganic wastewater was fed. These findings will contribute to the dissemination of aerobic granular sludge technology because the information on the formation of aerobic granular sludge in a continuous-flow reactor is limited.

Journal of Water and Environment Technology, Vol 8, No.3, 2010

Address correspondence to Satoshi Tsuneda, Department of Life Science and Medical Bioscience,

Formation of Aerobic Granular Sludge in a Continuous-Flow Reactor – Control Strategy for the Selection of Well-Settling Granular Sludge -

Naohiro KISHIDA*, Atsushi KONO**, Yutaka YAMASHITA***, Satoshi TSUNEDA***

*Department of Water Supply Engineering, National Institute of Public Health, 2-3-6 Minami, Wako, Saitama 351-0197, Japan

**Department of Chemical Engineering, Waseda University, 3-4-1 Okubo, Shinjuku-ku, Tokyo 169-8555, Japan

***Department of Life Science and Medical Bioscience, Waseda University, 2-2 Wakamatsu-cho, Shinjuku-ku, Tokyo 162-8480, Japan

ABSTRACT

In this study, the formation characteristics of aerobic granular sludge in a continuous-flow reactor were investigated under several experimental conditions Both surface loading rate (equal

to liquid linear velocity at a sludge settling zone) and aeration rate strongly affected the selection

of well-settling sludge in the same manner as sludge settling time in a sequencing batch reactor

By setting and controlling adequate surface loading and aeration rates, small particles were effectively washed out, and well-settling sludge selectively remained in the reactor As a result, aerobic granular sludge was effectively formed On the other hand, feeding pattern, i.e., continuous and intermittent feeding, did not affect the aerobic granulation when completely inorganic wastewater was fed These findings will contribute to the dissemination of aerobic granular sludge technology because the information on the formation of aerobic granular sludge

in a continuous-flow reactor is limited

Keywords: aerobic granular sludge, continuous-flow reactor, nitrification

INTRODUCTION

In recent years, aerobic granular sludge technology has received much attention because

of its specific characteristics (de Kreuk et al., 2007) Aerobic granular sludge has some

advantages over conventional bioflocs, such as excellent settleability and high biomass

retention (Liu et al., 2004) Aerobic granular sludge technology is applicable to the removal of not only organic carbon but also nitrogen and phosphorus (Kishida et al.,

2006)

Aerobic granulation of suspended growth aggregates is a phenomenon that has been most frequently observed in systems applying the sequencing batch reactor (SBR) concept (Wilderer and McSwain, 2004), and most of the previous studies succeeded in

the formation of aerobic granular sludge using SBRs (Dulekgurgen et al., 2003; Mosquera-Corral et al., 2005; Kishida et al., 2008) However, in our previous studies,

aerobic granulation was observed in a continuous-flow aerobic upflow fluidized bed (AUFB) reactor when completely inorganic wastewater containing high concentration

of ammonia (hereinafter called “ammonia-rich wastewater”) was fed (Tsuneda et al., 2003) Campos et al (2000) has also reported aerobic granulation using a similar

continuous-flow reactor although they inoculated the sludge coming from the effluent of

a nitrifying biofilm airlift reactor using carrier materials This phenomenon is quite unique To disseminate aerobic granular sludge technology, establishment of a

formation method in a continuous-flow reactor is very important because continuous-flow reactors are more popular than SBRs all over the world However, there is very little information on factors influencing aerobic granulation in a continuous-flow reactor, and therefore, it takes a long time to start-up aerobic granular sludge processes using a continuous-flow reactor at present Actually, it took approximately 100 days to form granular sludge with a diameter of 200 m in our

previous study (Tsuneda et al., 2003), which makes practical application difficult

The specific objective of this study is to reveal some factors greatly influencing aerobic granulation in a continuous-flow reactor We focused our attention on the controllable factors influencing the selection of well-settling sludge because the sludge selection is one of the most important operational strategies that are essential to successful formation of aerobic granular sludge in an SBR (Li and Li, 2009) Sludge settling time

is known as an important factor influencing the sludge selection in an SBR (McSwain et al., 2004a) Generally, surface loading rate (equal to liquid linear velocity at a sludge

settling zone) and aeration rate in continuous upflow reactors govern the washout of sludge from the reactor, and therefore, we investigated the effect of surface loading rate and aeration rate on the selection of well-settling sludge and the formation of aerobic granular sludge To effectively achieve our goal, sludge selection (washout and retention) characteristics under different surface loading and aeration rates were preliminarily investigated using aerobic granular sludge that had already been formed in our previous studies Based on the preliminary experimental results, we decided the control strategy for the selection of well-settling sludge Then, we applied the strategy

to the formation of aerobic granular sludge in a continuous experiment In addition, the effect of feeding pattern, i.e continuous flow and sequencing batch flow modes, on the formation of aerobic granular sludge was investigated

MATERIALS AND METHODS

Reactor Configuration

In this study, AUFB reactors with a working volume of 13.8 L (including a gas-solid separator), an internal diameter of 5 cm, and a height of 3.2 m, were used for all experiments The schematic illustration of the AUFB reactor is shown in Fig 1 Although the AUFB reactor was originally designed to operate as a continuous-flow reactor, the reactors were used not only as continuous-flow reactors but also as SBR to investigate the effect of feeding patterns on the formation of aerobic granular sludge

Preliminary Experiment for Characterizing Sludge Washout and Retention

Sludge selection characteristics (washout and retention) in the AUFB reactor were investigated under different surface loading and aeration rate conditions Firstly, aerobic granular sludge and suspended biomass were mixed Secondly, the particle distribution

of the mixture was measured using different sieves with opening sizes of 125, 250 and

420 m Mixed liquor samples were sieved with them, and dry weight of each fraction was measured in the same manner as suspended solids (SS) Thirdly, the mixture was poured into the AUFB reactor Then, feeding and aeration were done, and the effluent was continuously sampled Particle size distribution in the effluent solution was also measured Finally, sludge washout characteristics were evaluated using sludge washout index (SWI) defined by the following equation

SWI (%/d) = DWEF eff (g/d) / DWEF in (g) × 100 (1)

in which DWEF eff is the dry weight of each fraction separated by sieving the effluent

solution, DWEF in is the dry weight of each fraction of initial biomass filled to the AUFB reactor If biomass growth is ignored, multiplicative inverse of SWI multiplied by 100 ((1/SWI) × 100) is equal to sludge retention time of each sludge separated by sieving

Surface loading rates ranged from 0.6 to 3 m3/m2/d, while aeration rates ranged from 0.3

to 0.8 L/min The pH was set at 6.8 to 7.0 by adding NaHCO3, and the water temperature was maintained at 22 ± 2°C

Reactor Setup and Operation for the Formation of Aerobic Granular Sludge

Two AUFB reactors were used for the formation of aerobic granular sludge Air was introduced from the bottom of the reactor, and aeration rate was gradually increased from 0.3 to 0.8 L/min based on the results from the preliminary experiments for characterizing sludge washout and retention Dissolved oxygen concentration at the middle part of reactors (approximately 1.5 m from the bottom of reactors) was over 2 mg/L through the entire experiment The initial concentration of mixed-liquor volatile suspended solids (MLVSS) was set at 1000 mg/L and the volumetric nitrogen loading rate was increased from 0.15 to 0.23 kg N/m3/d on day 22 The pH was set at 6.8 to 7.0 by adding NaHCO3 and the water temperature was maintained at 22 ± 2°C

The difference between Runs 1 and 2 is influent feeding mode In Run 1, ammonia-rich wastewater was continuously fed from the bottom of the reactor, while the wastewater was intermittently fed (sequencing batch mode) in Run 2 Hydraulic retention time (HRT) in Run 1 was initially set at 2 d (surface loading rate: 1.2 m3/m2/d) and decreased

to 1.33 d (surface loading rate: 1.8 m3/m2/d) on day 22, while HRT in Run 2 was fixed

at 1.5 d In Run 2, time lengths of influent feeding, aeration, sludge settling and effluent

Fig 1 - Schematic diagram of the AUFB reactor

Gas flow

Influent feeding Air

Liquid flow

Granular biomass

Effluent discharge (Continuous flow mode) Effluent discharge (Sequencing batch operational mode) Gas-solid separator

Effluent

Sludge settling zone Vertical sectional view

Overhead view

5cm

20cm

4.7cm 13cm

25cm

Effective volume:

7.5L

Sludge settling zone

discharge phases were fixed at 10 min, 21.75 h, 2 h and 5 min (a total of 24 h), respectively Volumetric exchange ratio was fixed at 0.67

Wastewater Composition and Seed Sludge

Ammonia-rich wastewater was synthesized based on the discharge from a semiconductor manufacturing plant Table 1 shows the chemical composition of this synthetic wastewater, which contains numerous ammonium ions (NH4-N: 230-341 mg/L) and other inorganic ions (Ca: 500 mg/L) peculiar to industrial wastewater The NH4-N concentration at the continuous flow operational mode including the preliminary experiment was constant (300 mg/L), while the concentration at the sequencing batch operational mode (Run 2) was changed from 230 to 341 mg/L on day 22 to increase the NH4-N loading rate Iron in the form of FeSO47H2O and phosphorus in the form of KH2PO4 were added to the influent as a trace metal and nutrient, respectively

Aerobic granular sludge used for characterization of sludge washout and retention was obtained from another AUFB reactor that had been operated using ammonia-rich wastewater Details of the granular sludge cultivation methods employed are described

in a previous paper (Tsuneda et al., 2003) Seed sludge (suspended biomass) to form

aerobic granular sludge for all the experiments was obtained from an aerobic basin of a municipal wastewater treatment plant (Tokyo, Japan)

Table 1 - Wastewater composition

Analytical Methods

MLVSS, SS and sludge volume index (SVI) were analyzed in accordance with standard methods (APHA, 1998) Ammonia-nitrogen (NH4-N) was determined using ion chromatography (DX 120, Dionex, Japan) Both NO2-N and NO3-N were measured by ion chromatography (IC 2001, Tosoh, Japan)

RESULTS AND DISCUSSION

Effect of Surface Loading and Aeration Rates on the Selection of Well-Settling Sludge

As we expected, the increase in both surface loading and aeration rates strongly enhanced washout of small particles (dispersed sludge), while these effects were hardly observed in well-settling large particles (granular sludge), as shown in Fig 2 Therefore,

it must be possible to select only well-settling sludge, which is essential for the formation of aerobic granular sludge when setting adequate surface loading and aeration rates in a sequencing batch mode Although selection of well-settling granular sludge could be carried out most effectively under the highest surface loading and aeration rates condition, if we set the highest conditions at the startup period, almost all the

Concentration (mg/L) Component

Continuous flow mode Sequencing batch mode

NH4Cl N: 300 N: 230 – 341

biomass might be washed out Hence, both parameters should be gradually increased for the promotion of aerobic granulation

Fig 2 - Sludge washout index under different surface loading and aeration rates

Formation of Aerobic Granular Sludge by Controlling Surface Loading and Aeration Rates

Surface loading and aeration rates were initially set at 1.2 m3/m2/d and 0.30 L/min, respectively, which is equivalent to 4.3%/d of SWI of small particles (<125 m) in accordance with the preliminary experiment (Fig 2) If SWI is below 5.0%/d, it is empirically known in our previous studies that nitrifying bacteria can be retained in the reactor Actually, biomass was not excessively washed out in this study, and therefore, nitrification performance was stable, as shown in Figs 3 and 4 The value of SVI gradually decreased due to aerobic granulation, as shown in Figs 5 and 6 As sludge settling ability increased, surface loading and aeration rates were gradually increased, and finally set at 1.8 m3/m2/d (HRT: 1.33 d) and 0.80 L/min, respectively, which is equivalent to 16.4%/d of SWI of small particles (<125 m) Under this experimental condition, small particles were effectively washed out, and well-settling granular sludge selectively remained in the reactor As a result, aerobic granulation successfully proceeded, and aerobic granular sludge with an average diameter of 226 m was observed on day 65 This formation period is much shorter than that employed in our previous study without control strategy for the selection of well-settling granular sludge

(Tsuneda et al., 2003) Because specific surface area of small particles is much greater

than that of well-settling large particles, large particles are normally outcompeted by small particles due to competition for substrate (ammonia) uptake Therefore, small particles should be preferentially washed out for the growth of large particles by controlling surface loading and aeration rates, which promotes the formation of aerobic granular sludge

0 5 10 15 20 25

0.3 0.4 0.5 0.6 0.7 0.8

Ａ eration rate (L/min)

0

5

10

15

20

25

0.3 0.4 0.5 0.6 0.7 0.8

Ａ eration rate (L/min)

0 5 10 15 20 25

0.3 0.4 0.5 0.6 0.7 0.8

Ａ eration rate (L/min)

0

5

10

15

20

25

0.3 0.4 0.5 0.6 0.7 0.8 Ａeration rate (L/min)

Effect of Feeding Pattern on the Formation of Aerobic Granular Sludge

As shown in Figs 3 and 4, nitrification performance and sludge washout characteristics

at continuous flow and sequencing batch modes (Runs 1 and 2) were almost the same Under this experimental condition, sludge settling and aerobic granulation

0

0.10

0.20

0.30

0 1 2 3

3 /da

Aeration rate [L/min]

0

20

40

60

80

100

Time [day]

0 0.10 0.20 0.30

0 1 2 3

3 /day

0.80 0.50

0 20 40 60 80 100

Time [day]

Aeration rate [L/min]

0.30

Fig 3 - Nitrification performance at two operational modes Red line shows time course of HRT

0

1000

2000

3000

4000

5000

6000

7000

8000

9000

Time [day]

Top Bottom

Aeration rate [L/min]

Aeration rate [L/min]

0 1000 2000 3000 4000 5000 6000 7000 8000 9000

Time [day]

Aeration rate [L/min]

Top Bottom

Fig 4 - Time courses of MLVSS at two operational modes

0 100 200 300 400 500

Time [day]

SVI [30 min]

Aeration rate [L/min]

0

100

200

300

400

500

Time [day]

SVI [30 min]

Aeration rate [L/min]

Fig 5 - Time courses of SVI at two operational modes

Inoculum day 27 day 65 Inoculum day 27 day 65

Fig 6 - Evolution of aerobic granular sludge at two operational modes (bar = 200 µm)

characteristics in Run 1 were not apparently different from those in Run 2, as shown in

Figs 5 and 6 These results contradicted the results in previous studies (McSwain et al.,

2004b) This is because the characteristics of the influent wastewater are different When organic wastewater is fed, reportedly, intermittent feeding in the SBR produces feast-famine conditions that suppress filamentous organisms which strongly decrease sludge settling ability (Wilderer and McSwain, 2004) However, when completely inorganic wastewater is fed in the same manner as this study, filamentous organisms are normally unable to survive regardless of the feeding pattern Therefore, the apparent effect of feeding pattern on the aerobic granulation was not observed in this study

CONCLUSIONS

This study primarily reveals factors influencing aerobic granulation in a continuous-flow reactor Both surface loading and aeration rates affect the selection of well-settling sludge and the formation of aerobic granular sludge By setting and controlling adequate surface loading and aeration rates, small particles were effectively washed out, and well-settling sludge selectively remained in the reactor As a result, quicker granulation was successfully attained On the other hand, feeding pattern is not

an important factor in aerobic granulation when completely inorganic wastewater is fed

REFERENCES

Campos J L., Mendez R and Lema J M (2000) Operation of a nitrifying activated sludge

airlift (NASA) reactor without biomass carrier, Water Sci Technol., 41(4-5), 113-120

De Kreuk M K., Kishida N and van Loosdrecht M C M (2007) Aerobic granular sludge

- State of the art, Water Sci Technol., 55(8-9), 75-81

Dulekgurgen E., Ovez S., Artan N and Orhon D (2003) Enhanced biological phosphate

removal by granular sludge in a sequencing batch reactor, Biotechnol Lett., 25(9),

687-693

Kishida N., Kim J H., Tsuneda S and Sudo R (2006) Anaerobic/oxic/anoxic granular sludge process as an effective nutrient removal process utilizing denitrifying

polyphosphate-accumulating organisms, Water Res., 40(12), 2303–2310

Kishida N., Tsuneda S., Sakakibara Y., Kim J H and Sudo R (2008) Real-time control strategy for simultaneous nitrogen and phosphorus removal using aerobic granular

sludge, Water Sci Technol., 58(2), 445–450

Li A J and Li X Y (2009) Selective sludge discharge as the determining factor in SBR

aerobic granulation: Numerical modelling and experimental verification, Water Res.,

43(14), 3387-3396

Liu Y., Yang S F and Tay J H (2004) Improved stability of aerobic granules by selecting

slow-growing nitrifying bacteria, J Biotechnol., 108(2), 161-169

McSwain B S., Irvine R L and Wilderer P A (2004a) The influence of-settling time on

the formation of aerobic granules, Water Sci Technol., 50(10), 195-202

McSwain B S., Irvine R L and Wilderer P A (2004b) The effect of intermittent feeding

on aerobic granule structure, Water Sci Technol., 49(11–12), 19–25

Mosquera-Corral A., de Kreuk M K., Heijnen J J and van Loosdrecht M C M (2005) Effects of oxygen concentration on N-removal in an aerobic granular sludge reactor,

Water Res., 39(12), 2676-2686

Standard Methods for the Examination of Water and Wastewater (1998) 20th edn,

American Public Health Association/American Water Works Association/Water Environment Federation, Washington DC, USA

Tsuneda S., Nagano T., Hoshino T., Ejiri Y., Noda N and Hirata A (2003) Characterization

of nitrifying granules produced in an aerobic upflow fluidized bed reactor, Water Res.,

37(20), 4965-4973

Wilderer P A and McSwain B S (2004) The SBR and its biofilm application potentials,

Water Sci Technol., 50(10), 1-10