Modelling the biodegradation phases. The Activated Sludge Model N°^. 1 (ASM1) (HENZE et al., 1987) was chosen to simulate the biological process. Thirteen state variables described the fate of biodegradable and non-biodegradable, soluble and insoluble, carbon and nitrogen-based pollution as well as bacteria (heterotrophs and autotrophs): the biological processes are described by 19 kinetic and stoechiometric parameters. The values of the kinetic and stoechiometric parameters were the default values proposed by HENZE et al. (1987) at 20°C.

Except for oxygen, the general mass balance during non-settling phases was:

where Z was a state variable, V the working volume, r the reaction rate, t the time and q_in and q_out the feed and discharge rate respectively. During feeding:

During the discharge and wastage phases, which were assumed to be non-reactive:

and

Dissolved oxygen during aerated phases was controlled by a discrete PI controller by manipulation of the oxygen transfer coefficient.

For dissolved oxygen (S_O):

where S^*_O was the dissolved oxygen concentration at saturation and K_La the oxygen transfer coefficient.

During aerobic phases of the simulations, the oxygen concentration S₀ was maintained at 2 mg O₂•L^‑1 and was equal to 8 mg O₂•L^‑1. The oxygen transfer coefficient (K_La) was constant during aerobic phases and equal to 16 h^‑1 and was reduced to 0 during anoxic and anaerobic phases.

Modelling the settling phase: The double-exponential settling velocity model proposed by TAKACS et al. (1991) was selected to describe the behaviour of the sludge during the settling phase, which was not supposed to be reacting. The number of layers has been set to m and their thickness is adjusted for each cycle, with respect to the actual working volume. The first layer was at the bottom of the tank, where wastage was taking place. The partial discharge of a layer was taken into account to calculate the amount of sludge remaining in the reactor. Wastage and discharge were not supposed to disturb the layers.

Initialisation of the mathematical program: sludge and wastewater characteristics: The kinetic and settling parameters used to simulate the SBR behaviour were those given in the COST BSM1 (COPP, 2002; HENZE et al., 1987).

Reactor characteristics: The working volume of the lab scale reactor used for the simulations was 2 L. The incoming wastewater volume was equal to 0.9 L per cycle. The length of the phases, the control of dissolved oxygen concentration (2 mg/L) and the feeding and discharge of the reactor were controlled and monitored through the Bioexpert^© software. Feeding and discharge of the reactor were achieved using peristaltic pumps. The agitation rate was regulated at 80 rpm.

The working volume of the pilot scale SBR was 1320 litres. It was stirred at 40 rpm during the aerobic phase and at 30 rpm during the anoxic phase. The volume of incoming wastewater represented 50% of the working volume of the reactor. The reactor was monitored and controlled through the TSX Premium^© (Télémécanique) software.

Fractionation of the incoming wastewater: The incoming wastewater was a mixture of domestic (85% v/v) and industrial wastewater (15% v/v).

The ASM1 state variables for the incoming wastewater have been identified by different methods: a) coagulation-floculation followed by 0.45 µm pore size membrane filtration and b) biodegradation tests in closed reactors.

The fractionations were achieved under dry and rainy conditions.

1. The soluble fraction of COD (S_s0) was also identified by physico-chemical methods described by (MAMAIS et al., 1993; NAIDOO et al., 1998).The first step consisted in the elimination of suspended solids by using a coagulant flocculant. The supernatant was then filtered at 0.45 µm. S_s0 corresponds to the COD measured in the filtrate. Two coagulant flocculants were evaluated FeCl₃ (1 g•L^‑1) and ZnSO₄ (3 g•L^‑1).

2. The state variables of ASM1 (S_I0, S_S0, X_S0, X_I0, S_NI0, S_ND0, X_NI0, X_ND0) were measured by a method inspired by STRICKER (2000): two reactors were filled with wastewater: the first one (working volume of 4 L) was filled with untreated wastewater (collected after pre-treatment in the WWTP of Limoges) and the second was filled with 4 L of filtered wastewater (1.2 µm). According to STRICKER (2000) recommendations, the reactors were inoculated with activated sludge (1/1000 v/v). The biodegradation tests lasted 30 days and were conducted twice for rainy weather and three times during the dry weather period of time, in order to have an accurate identification. Soluble and insoluble COD and nitrogen species were monitored every day.

Performance criteria, removal efficiency, analytical methods: The exit concentration of soluble carbon and nitrogen was compared to French standards. The removal efficiency (RE) was calculated according to equation 11:

Input value corresponded to the values reported in table 1 and output values were given by the simulator after ten SBR cycles.

French standards methods were used to determine pollution parameters: chemical oxygen demand (COD) (NFT 90‑101), total Kjeldhal nitrogen (TKN) (ISO 5663-1984(F)), total suspended solids (TSS, VSS, MSS) (NFT 90-105-1), nitrate, nitrite and orthophosphate ions (NF EN 10304-2). Ammonium ions concentrations were measured by ionic chromatography (Dionex DX 100).

Modelling carbon and nitrogen removal during 12‑hour and 24‑hour cycles (Benchmark fractionation): In a first part the effectiveness of BSM1 fractionation for SBR sizing was assessed. The characterisation of the incoming wastewater was determined according to the fractionation given by the Benchmark (BSM1) (see in table 1). The results, in terms of removal efficiencies and composition of the treated wastewater, respectively for 12‑hour and 24‑hour cycles of a SBR are given in table 3.

Table 3 shows that it was possible with the 24-hour cycles to reach both the French standard and low level of exit concentration, especially for nitrogen (5.5 and 5.7 mg N•.L^‑1) - whatever the climatic conditions. On the contrary, the exit concentrations of the 12-hour SBR cycles reached the upper limit of the French standards especially for total nitrogen (15.3 and 12.7 mg N•.L^‑1). In a first approach, this result may lead to the rejection of 12‑hour cycles because of a possible lack of reliability of 12-hour SBR cycles.

The distribution of ASM1 state variables given by the benchmark (BSM1) can be a useful tool at first, but it might prove to be incomplete if one considers the high variability of wastewater, according to the kind of effluent it contains (presence of industrial wastewater, separated or combined sewer system). It is then necessary to achieve a specific identification of ASM1 state variables for local wastewater later used in a lab scale or pilot scale reactor.

Specific fractionation of the influent: The incoming wastewater was a combination of industrial and domestic wastewater. The wastewater characterization might differ significantly from standard municipal wastewater used in the Benchmark (BSM1), but was a good example of the interest of using modelling and fractionation.

The results obtained for the variables in relation with carbon and nitrogen species are reported in tables 5 and 6. It is assumed in this study that S_I0 and X_I0 were not produced during aerobic batch tests from biomass decay, as the sludge inoculum was very low.

An accurate identification of S_S0 is of interest, as the availability of readily biodegradable carbon substances is important for the successful achievement of denitrification. The results showed that the method of biodegradation tests in closed reactors led to an overestimation of the S_s0 fraction, compared to physico-chemical methods (see in Table 4). The estimation of S_S0 includes a part of colloidal matter. It is in agreement with LEVINE et al. (1985), who concluded that it was necessary to use a 1.0 µm pore-size membrane to separate correctly the true soluble and particulate forms. Nevertheless, 0.45 µm pore-size membranes are widely used.

The specific identification of carbon ASM1 state variables during rainy or dry weather presented good correlations with other results found in literature (Table 5). The largest part of COD is biodegradable (soluble or particulate). Especially during dry periods, the largest part of biodegradable COD is particulate.

The results of nitrogen ASM1 variables (Table 6) showed that the distribution for the incoming wastewater differs partly from literature data. The proportion of inert species was not negligible, hence the interest of a specific identification.

For carbonaceous species, it was possible to conclude to a good agreement with the literature values, but it was not the case for nitrogen variables, the distribution of which appearing to be really specific when compared to the references. These results might be due to the presence of industrial effluent in the wastewater.

It appeared from these experimental data that:

• The reliability of Ss determination depended on the applied pore-size of the membrane, which confirms the work of LEVINE et al. (1985);

• Parts of the soluble and settleable fraction might belong to Xs (SOLLFRANK et GUJER, 1991);

• It was not possible to identify the variable X_B,H. In her important work on calibration, identifiability and optimal experimental design of activated sludge models, PETERSEN (2000) reported that this variable was not negligible. SPERANDIO (1998) evaluated this fraction at 10% of the global COD, and HENZE (1992) at 15-20%.

Modelling carbon and nitrogen removal during 12‑hours and 24‑hour cycles with a specific influent fractionation: The modelling of the 12‑hour and 24‑hour cycles, using the specific distribution of ASM1 state variables of incoming wastewater, is presented at figure 2. The average values of COD and TN were measured during rainy and dry weathers over three months, in the Wastewater Treatment Plant of Limoges (see Table 7).

The exit concentrations taken into account for the carbon forms are Ss and S_I (soluble forms of COD) and the ones for nitrogen are S_NH, S_ND (soluble forms of nitrogen) as we assumed that particular species concentration were negligible in the effluent.

The results of the simulations for 12‑hour and 24‑hour cycles with incoming wastewater specific identification of ASM1 state variables are collected in table 3. The exit concentrations and removal efficiency of nitrogen and carbon of the simulations show that it was now possible to treat the incoming wastewater with 12‑hour cycles in a SBR (Figure 2). It was, especially during dry weather, possible to reach exit concentrations of the treated wastewater below the French standards (Figure 2).

In order to test the validity of the above strategy (fractionation and modelling), 12‑hour cycles have been carried out at lab scale and then at pilot scale for several months. The incoming organic loading rate had an average value of 0.05 kg BOD₅•kg TSS•cycle^‑1. The sludge retention time was equal to ten days. The results are presented in table 8.

The different tests completed for the 12-hour cycles defined above, both at a lab scale or pilot scale, led to satisfactory results, in terms of carbon (> 90%) and nitrogen (> 80%) removal. The model validation was then controlled during one cycle for carbon and nitrogen removal. The results are presented for the pilot scale validation (Figures 3 and 4).

The specific identification of ASM1 state variables for the incoming wastewater during rainy or dry weather makes it possible to describe the experimental data with sufficient accuracy:

• Soluble carbon removal was very well described by ASM1, as well as the nitrification process, the increase of the soluble COD between 10 h and 11 h was linked to the withdrawal of the reactor (increase of the relative concentration);

• It was considered in this study that the effluent was only made of soluble forms of carbon. Possible underestimation of soluble carbon and especially S_I by ASM1 could be possible as it was a part of biomass decay (PETERSEN, 2000). This phenomenon was observed for the lab scale simulation but not for the pilot scale. Some authors mentioned that for long solid and hydraulic retention times, ASM1 did not give a good description of carbon consumption (SPERANDIO, 2006).

• The modelling of nitrogen removal with ASM1 has been largely discussed in the literature. Some authors mentioned difficulties for ASM1 to correctly describe the nitrification and denitrification processes, especially when the nitrogen content of the influent was important. On the other hand, COELHO et al. (2000), SMETS et al. (2003) showed that it was possible, in the context of domestic wastewater, to describe correctly N removal through a simplification of ASM1. BOAVENTURA et al. (2001) stated that for better accuracy of simplified ASM1 model, it was necessary to use robust mathematical filters.

• In this study, ASM1 was used without any simplification. An overestimation of ammonium concentration could be observed, probably due to the fact that biological reactions have not been considered during the modelling of the settling phase. KELLER et YUAN (2002) proposed to remedy this problem by using a combination of a hydraulic and a biological (ASM2d) model during the settling phase; in particular when the influent was fed in the bottom of the reactor during this phase.