DOI QR코드

DOI QR Code

Analysis of Efficiency of Bacillus subtilis To Treat Bagasse Based Paper and Pulp Industry Wastewater-A Novel Approach

  • Received : 2013.12.06
  • Accepted : 2014.02.19
  • Published : 2014.04.20

Abstract

In this present study, bagasse based pulp and paper industry wastewater was treated under different operating conditions such as initial pH (6-8), temperature ($25-35^{\circ}C$) and contact time (3-7 days) by using Bacillus subtilis. Response surface methodology (RSM) coupled with Box-Behnken response surface design (BBD) was employed to investigate the effect of process variables on the responses such as turbidity, biological oxygen demand (BOD) and chemical oxygen demand (COD) removal. The experimental data were analyzed by Pareto analysis of variance (ANOVA) and the second order polynomial models were developed. Interactive effects of the process variables on the responses were studied using plotting 3D response surface contour graph and the optimum process conditions were found to be: initial pH of 7, temperature of $30^{\circ}C$ and contact time of 5 days. Under these conditions, removal efficiencies of turbidity, BOD and COD were found to be 85%, 93% and 80% respectively which are close agreement with real experiments. These results indicate that the treatment of bagasse based pulp and paper industry wastewater using Bacillus subtilis is an effective and novel technique.

Keywords

INTRODUCTION

Environmental safeguarding pains and developments in the technology have resulted in stringent discharge standards for discharge of industrial wastewaters to ecological system. Especially, discharge of paper and pulp industry wastewater into the ecological system pose a serious problem to the aquatic life. Moreover, this industry consumes a large amount of fresh water and hence increase the water scraity.1 In India, most of the pulp and paper industries use wood as the major raw material and bagasse as an alternative potential raw material for the production of paper. Bagasse is the fibrous mass, remaining after the extraction of juice from sugarcane from the sugar industry.2 Government of India encourages the use of bagasse as the raw material for the paper production inorder to minimize the deforestation. So that, many of the Indian paper industries uses a bagasse as an raw material now a days. Meanwhile, the bagasse based paper and pulp industry effluents have strong harmful characteristics such as biological oxygen demand (BOD), chemical oxygen demand (COD) and turbidity. To meet strict laws on environmental protection, pollutant loads discharged from the this industry wastewater should be first reduced to a significant extent, and a proper treatment step should be further applied to improve the quality of the final discharge in terms of residual pollutant contents. 3 Therefore, there is a critical need to adopt a cost effective treatment technology to treat heavily contaminated bagasse wastewater.

An extensive literature survey shows that, only a few information is available in the literature regarding the applicability of different treatment methods for the treatment of bagasse wastewater such as anaerobic sludge blanket (UASB) reactor4 and white rot fungus.5 Anaerobic treatment (UASB) of bagasse-based pulp and paper industry effluent shows that the overall COD removal was 80−85% and the biogas production factor of 520 l/(kg COD reduced) was achieved with 5.75 kgCOD m−3 d−1 of organic loading rate and 20 h HRT. Treatment of bagasse wastewater with white rot fungus shows the maximum colour removal efficiency of 82.5% at the optimal glucose and ammonium chloride concentrations of 15 g/l and 0.5 g/l, respectively, in a pH of 4.5. But these treatment processes has drawbacks such as long treatment time, start-up problem and low removal efficiency of COD and BOD. These characteristics makes it unfit to the large scale application and the discharge of wastewater after application of these treatment methods is still questionable due to the presence of considerable amount of pollutants. At present, biological treatment method of wastewaters using bacteria constitutes an alternative mode of treatment in aerobic conditions. Among various kinds of bacteria, the Bacillus subtilis bacteria have high biomass growth rate and substrate reduction, which was widely used in various wastewater treatment process.6 An extensive literature survey shows that, there is no research report is available on the treatment of bagasse based pulp and paper industry wastewater using bacterial strain of Bacillus subtilis. Hence, the main objective of the present study has been made to investigate and optimize the individual and interactive effect of process variables such as initial pH, temperature and contact time on the treatment of bagasse based pulp and paper industry wastewater using bacterial strain of Bacillus subtilis via response surface methodology (RSM). The treatment efficiency of present process was investigated based on the removal efficiencies of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater. The RSM is a statistical technique for designing experiments, building models, evaluating the effects of several factors, and searching optimum conditions for desirable responses. With RSM, the interactions of possible influencing parameters on treatment efficiency can be evaluated with a limited number of planned experiments with reduction of raw material and treatment time. Moreover, RSM has been widely used for optimization of various wastewater treatment processes.7 The results obtained from this study will useful to bagasse based paper and pulp industry wastewater treatment plants (WTP) for treating their effluents in a very effective manner with resanoable operating cost.

 

EXPERIMENTAL

The wastewater used in this study was collected from bagasse based pulp and paper industry in Erode region, TamilNadu, India. The characteristics of wastewater were analyzed and the physico-chemical properties were shown in Table 1. All the chemicals used in this study were analytical grade. Initial pH of the wastewater was adjusted by using Hydrochloric acid or Sodium hydroxide (0.1 N).

The bacterial strain of Bacillus subtilis used in this study was obtained from Danisco Deutschland Gmbh, Germany and it was secluded by spread plate technique in nutrient agar media. Further it was identified by their morphological features and biochemical characterization.8 The morphological results confirm that, B. subtilis colonies were circular and shiny. Biochemical characterization of this culture showed that, Methyl red, Voges proskauer and Indole tests were negative. Nitrate reduction, starch hydrolysis, catalase, Gram’s reaction and oxidase tests showed positive results. Sub culturing was done on the nutrient agar and maintained the culture at 4 ℃ in nutrient agar slants prior to use. Nutrient broth media9 was used to prepare liquid culture of this bacterial strain.

Table 1.Characteristics of paper industry wastewater

Batch studies were carried out in 250 ml Erlenmeyer flasks containing 100 ml bagasse wastewater (pH of 6−8), which was inoculated with freshly prepared broth (5 ml) of Bacillus subtilis. Then this reaction mixture was shaken in an incubator cum shaker at 150 rpm for the time period of 7 days by varying the temperature between 25−35 ℃ under sterile conditions. Samples were withdrawn at particular time intervals (5−7 days) from the flasks and were analyzed to study the reduction of turbidity, BOD and COD.

The turbidity, BOD and COD analysis were carried out by methods described by American Public Health Association (APHA). The removal efficiency (RE) of turbidity, BOD and COD was calculated by using the following equation.10

where, c0 and ce is the initial and final concentrations of turbidity, BOD and COD respectively.

In this study, Box-Behnken response surface experimental design (BBD) with three factors at three levels was used to optimize and investigate the influence of process variables initial pH (6−8), temperature (25−35 ℃) and contact time (3−7 days) on the removal efficiencies of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater using bacterial strain of Bacillus subtilis. Process variables and their ranges were determined based on the single factor experimental analysis. After selection of process (independent) variables and their ranges, experiments were established based on a BBD and the complete design consists of 17 experiments with three centre points (used to estimate the experimental error). The total number of experiments was calculated from the following equation10

where, K is number of factors and C0 is the number of central point. For statistical calculations, the process variables were coded at three levels (−1, 0 and +1) and the coding was done by the following equation

where xi, is the dimensionless value of an independent variable; Xi, the real value of an independent variable; Xz, the real value of an independent variable at the centre point; and Xi, step change of the real value of the variable i. From the BBD experimental data, a second-order polynomial equation was fitted inorder to correlate the relationship between independent variables and responses. Generalized mathematical form of the second-order polynomial equation is given below11

where, Y is the response; Xi and Xj are variables (i and j range from 1 to k); β0 is the model intercept coefficient; βj, βjj and βij are interaction coefficients of linear, quadratic and the second-order terms, respectively; k is the number of independent parameters (k = 3 in this study); and ei is the error. Regression coefficients of linear, quadratic, and interaction involved in the second-order polynomial model and their effects were analyzed by Pareto analysis of variance (ANOVA) and all the terms in the model were tested by student’s F-test. All the statistical analyses were done with the help of Stat ease Design Expert 8.0.7.1 statistical software package (Stat-Ease Inc., Minneapolis, USA). After that, models were used for the construction of response surface contour plots to predict the relationships between independent and dependent variables.

Finally, the optimization of the process variables was carried out by Derringer’s desired function methodology. This numerical optimization technique will optimize any combination of one or more goals; these may be either process variables or responses. The possible goals are: maximize, minimize, target, within range, none (for responses only). In this study, goals of the process variables were selected as in a range and the response goals were selected as maximize. After optimization, adequacy of the model equation for predicting the optimum response values was validated under the optimal conditions. Triplicate verification experiments were performed under the optimal conditions and the average value of the experiments was compared with the predicted values of the developed model equations.12

 

RESULTS AND DISCUSSION

In this study, three factors with three levels BBD was used to evaluate the effect and optimize the process variables on the responses such as removal of turbidity, BOD and COD. A total number of 17 batch experiments including five centre points were carried out in triplicates using sta-tistically deigned experiments and the results are shown in Table 2. The BBD experimental data was analyzed by sequential model sum of squares (Table 3) in order to obtain regression models and the decide about the adequacy of various models such as linear, interactive, quadratic and cubic models.13 From the Table 3, it is found that, linear and interactive (2FI) models are exhibited lower F-values and also having high p-values, when compared with quadratic model. Cubic model is found to be aliased. Therefore the quadratic model is chosen to describe the effects of process variables on the removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater using Bacillus subtilis. An empirical relationship between the responses and independent variables is expressed by a second-order polynomial equation with interaction terms. Three empirical models were developed to understand the interactive correlation between the responses and process variables. The final models obtained in terms of coded factors are given below,

Where Y1, Y2 and Y3 are turbidity, BOD and COD removal respectively. The statistical significance of the response functions (Y1−Y3) was checked by F-test, and the ANOVA results for response surface quadratic model and model terms are summarized in Table 4. The model F values and very low probability value (0.0001) indicated that the developed mathematical model was statistically significant and model equation can adequately used to describe the continuous electrocoagulation treatment method under a wide range of operating conditions. The p values are used to estimate whether F value is large enough to indicate statistical significance and used to check the significance of each coefficient. p values lower than 0.05 indicate that the model and model terms are statistically significant.

Table 2.BBD experimental design and results

Table 3.Sequential model sum of squares for responses

Significance of the developed model equations was evaluated by Pareto analysis of variance (ANOVA) and it is shown in Table 4. The higher model F values and lower p values (p < 0.0001) demonstrated that, the developed model was highly significant. The fit of the model was also evaluated by the determination co-efficient (R2), adj-R2 and Pre-R2. The high R2 values revealed that, the developed models are statistically significant and only small variations are not explained by the models. The value of Pre-R2 is in reasonable agreement with the value of adj-R2 and also shows that the form of the model chosen to explain the relationship between the factors and the response is well-correlated.14 These results indicate that, the deviations between experimental and predicted values are low and also showed a high degree of precision and reliability of the conducted experiments.14 Moreover, the adequacy of models was evaluated by constructing diagnostic plots such as predicted versus actual for the experimental data and it is shown in Fig. 1a−c. From the Figures, it is observed that, the data points on this plot lie very close to the diagonal line, because residuals for the prediction of each response is minimum and it indicates a good adequate agreement between experimental data and the data predicted by the developed models. This can confirm the normal distribution of the observed data and adequacy of the developed models.

Table 4.ANOVA table for responses

Figure 1.Predicted versus actual plot for responses.

Effect of Process Variables on Responses

Response surface contour plots were plotted from the developed models in order to study the individual and interaction effect among process variables on the responses and also used to determine the optimal condition of each factor for the maximum removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater using Bacillus subtilis. In this study, the model has more than two factors. So, the contour plots are drawn by maintaining one factor at a constant level (in turn at its central level), whereas the other two factors were varied in their range.15

Figure 2.Effect of pH and temperature on responses.

Effect of Initial pH

Experiments were carried out to study the effect of initial pH (6, 7 and 8) over the removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater. From the results, it was observed that, the removal efficiency of turbidity, BOD and COD was increased linearly with increasing pH from 6−7 (Fig. 2a−c). Thereafter, there is drastic decrease in removal efficiency of turbidity, BOD and COD. These results clearly show that at pH 7 (neutral) is best working condition for this study.16

Effect of Temperature

Experiments were carried out to study the effect of temperature (25, 30 and 35 ℃) over the removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater. From the results, it was observed that, the removal of turbidity, BOD and COD was increased linearly with increasing temperature from 25−30 ℃ (Fig. 2a−c). Increase in temperature up to 30 ℃ would increase the growth rate of bacterial species which accelerate the treatment efficiency. However, temperature beyond 30℃ resulted in lower removal efficiencies, due to the negative impact on bacterial growth rate by the higher temperature.17

Effect of Contact Time

Contact time is one of the important factors for the removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater and it is associated with efficiency of treatment process. From the results (Fig. 3a−c), it is found that, the removal of turbidity, BOD and COD was increased upto contact time of 5 days. Beyond that, there is a negligible effect in removal of turbidity, BOD and COD. This phenomenon is explained by that, after the optimum contact time, almost all the organic matters present in the wastewater were effectively degraded by bacterial species and shows the ignorable effect.18

Figure 3.Effect of temperature and contact time on responses.

Optimization

Optimization of the process variables was determined by Derringer’s desired function methodology19,20 as follows: initial pH of 7, temperature of 30 ℃ and contact time of 5 days. Under these conditions, predicted removal of turbidity, BOD and COD were found to be 85%, 93% and 80% respectively with a desirability value of 0.996. The suitability of optimum conditions for predicting optimum response values was tested under the same set of optimized conditions. Triplicate experiments were performed under the optimized conditions and the mean values obtained from real experiments, demonstrated the validation of the optimized conditions.21,22

 

CONCLUSION

In this study, BBD was employed to study and optimize the process variables such as initial pH, temperature and contact time on the removal of turbidity, BOD and COD from bagasse based pulp and paper industry wastewater using Bacillus subtilis. From the experimental results, the mathematical models were developed with high R2 value and it was used to investigate the interactive effects of process variables on responses. ANOVA showed that all the process variables have significant effect on removal efficiencies. Optimum set of the process variables was obtained by derringer’s desired function methodology and it were found to be: initial pH of 7, temperature of 30 ℃ and contact time of 5 days. Under these optimal conditions, the exper-imental removal efficiencies of turbidity, BOD and COD were found to be 85%, 93% and 80% respectively. These results indicates that effectiveness of Bacillus subtilisto treat bagasse based pulp and paper industry wastewater.

References

  1. Merzouk, B.; Gourich, B.; Sekki, A.; Madani, K.; Chibane, M. J. Hazard. Mater. 2009, 164, 215. https://doi.org/10.1016/j.jhazmat.2008.07.144
  2. Khalid, B.; Melhem, E. S. J. Chem Eng. 2012, 198,201.
  3. Manaswini, B.; Partha, S. J.; Tanaji, T. M.; Ghangrekar, M. M. Bioelectrochemistry 2010, 79, 228. https://doi.org/10.1016/j.bioelechem.2010.06.002
  4. Thirugnanasambandham, K.; Sivakumar, V.; Prakash Maran, J. Carbohyd. Polym. 2013, 97, 451. https://doi.org/10.1016/j.carbpol.2013.05.012
  5. Zouboulis, A.; Katsoyiannis, I. Sep. Sci. Tech. 2002, 37,2859. https://doi.org/10.1081/SS-120005470
  6. Lew, B.; Tarre, S.; Belavski, M.; Gree, M. Water Sci. Tech. 2004, 49, 295.
  7. Prakash Maran, J.; Sivakumar, V.; Thirugnanasambandham, K.; Sridhar, R. Prep. Biochem. Biotech. 2013. DOI:10.1080/10826068.2013.791629.
  8. Aghamohammadi, N.; Aziz, H. A; Isa, M. H.; Zinatizadeh, A. A. Bioresour. Tech. 2007, 98, 3570. https://doi.org/10.1016/j.biortech.2006.11.037
  9. Nordin, M. Y.; Venkatesh, V. C.; Sharif, S.; Elting, S.; Abdullah, A. J. Mater. Process Tech. 2004, 145, 46. https://doi.org/10.1016/S0924-0136(03)00861-6
  10. Sridhar, R.; Sivakumar, V.; Prince Immanuel, V.; Prakash Maran, J. J. Hazard. Mater. 2011, 186, 1495. https://doi.org/10.1016/j.jhazmat.2010.12.028
  11. Reungsang, A.; Pattra, S.; Sittijunda, S. Energies 2012, 5, 4746. https://doi.org/10.3390/en5114746
  12. APHA, WPCF, AWWA Standard Methods for the Examination of Water and Wastewater, 19th ed.; American Public Health Association (APHA): Washington, DC, 1992.
  13. Prakash Maran, J.; Manikandan, S.; Thirugnanasambandham, K.; Vigna Nivetha, C.; Dinesh, R. Carbohyd. Polym. 2013, 92, 604. https://doi.org/10.1016/j.carbpol.2012.09.020
  14. Bhatti, M. S.; Reddy, A. S.; Thukral, A. K. J. Hazard. Mater. 2009, 172, 839. https://doi.org/10.1016/j.jhazmat.2009.07.072
  15. Prakash Maran, J.; Manikandan, S.; Vigna Nivetha, C.; Dinesh, R. Ara. J. Chem. DOI: 10.1016/j.arabjc.2013.02.007
  16. Thirugnanasambandham, K.; Sivakumar, V.; Prakash Maran, J. J. Serb. Chem. Soc. 2013. DOI: 10.2298/JSC130201053T.
  17. Kabir, E.; Hussain, D.; Haque, A.; Kim, K. H. Int. J. Green Energy. 2009, 6(4), 381. https://doi.org/10.1080/15435070903107064
  18. Thirugnanasambandham, K.; Sivakumar, V.; Prakash Maran, J. J. Serb. Chem. Soc. 2013. DOI: 10.2298/JSC130408074T.
  19. Tak Hyun, K.; Chulhwan, P.; Eung Bai, Shin.; Sangyong, K. Desalination. 2002, 150, 165. https://doi.org/10.1016/S0011-9164(02)00941-4
  20. Thirugnanasambandham, K.; Sivakumar, V.; Prakash Maran, J. J. Serb. Chem. Soc. 2013. DOI: 10.2298/JSC130408074T.
  21. Prakash Maran, J.; Sivakumar, V.; Thirugnanasambandham, K. Food Sci. Biotechnol. DOI 10.1007/s10068-014-0.
  22. Thirugnanasambandham, K.; Sivakumar, V.; Prakash Maran, J. J. Serb. Chem. Soc. 2013. DOI: 10.2298/JSC130619153T.

Cited by

  1. Modeling of by-product recovery and performance evaluation of Electro-Fenton treatment technique to treat poultry wastewater vol.46, 2015, https://doi.org/10.1016/j.jtice.2014.09.004
  2. Pilot scale evaluation of feasibility of reuse of wine industry wastewater using reverse osmosis system: modeling and optimization vol.57, pp.53, 2016, https://doi.org/10.1080/19443994.2016.1154894
  3. Optimization of reverse osmosis treatment process to reuse the distillery wastewater using Taguchi design vol.57, pp.51, 2016, https://doi.org/10.1080/19443994.2016.1141323
  4. Evaluation of an electrocoagulation process for the treatment of bagasse-based pulp and paper industry wastewater vol.34, pp.2, 2015, https://doi.org/10.1002/ep.12001
  5. Response surface modelling and optimization of treatment of meat industry wastewater using electrochemical treatment method vol.46, 2015, https://doi.org/10.1016/j.jtice.2014.09.021
  6. Efficiency of electrocoagulation method to treat chicken processing industry wastewater—modeling and optimization vol.45, pp.5, 2014, https://doi.org/10.1016/j.jtice.2014.04.011