Aalborg Sep. 230902 Sludge EPS Characterization

Abstract

The characterization of sludge is inevitably based on the conception of the dewatering physical chemistry. Some cherish the notion that sludge is a micro gel particle system. [LeGrand et al., Water Research 32(12) 1998]. The particles, being the sludge flocs, do primarily consist of a condensed EPS-phase, in which single cells and bacterial colonies are embedded. Hence, the process of deswelling of a charged gel mirrors the sludge structure and the dewatering of this.

The structure of a charged gel is partly defined by properties, which leads to swelling and subsequently dissolution of the gel. These properties are defined by the free charge of the gel components and of the ionic environment and of the molar weight distribution of the gel components. Further, cohesive effects, defined by hydrophobic properties and charge density effects, define the structure.

The present paper addresses the analytical techniques to assess these features of the charged gel. These techniques are: ^a) colloidal- and pH-titration for the determination of the free charge, ^b) measurements of contact angle and IR-spectrophotometry for a relative assessment of hydrophobic properties and ^c) size exclusion chromatography for the assessment of molecular size distribution.

The experience in applying these techniques reveal a picture of sludge EPS as having a free surface charge density of 1-3 meq/g, as having fairly uniform hydrophobic properties and as apparently having a relatively broad and varying size distribution. The suggestion from this study is thus that a key parameter for the condensation of sludge EPS into gel particles is the molecular size distribution of the EPS. This will be illustrated from the analysis of sludge from various aerobic and anaerobic treatments.

10
HOW TO REACH ZERO EXCESS SLUDGE PRODUCTION IN THE WASTEWATER TREATMENT LINE?

(2). CIRSEE, ONDEO Services, 38, Rue du Président Wilson, 78230 Le Pecq, France.

• 
  Tel: +33-561-559-772 ; Fax: +33561-559-776; e-mail: paul@insa-tlse.fr
  

In Europe, major ways of disposing of excess sludge are subject to more and more legal and social constraints, and disposal of excess biomass may account for up to 60% of total plant operating costs (Horan, 1990). Therefore, reducing excess sludge production instead of merely treating it appears to be a very appealing solution to this social and economic issue, because the problem would be treated at its roots.

However many questions arise when looking for applying a technology of reduction of Excess Sludge Production (ESP) on the treatment line. What is the strategy to follow? Which technology is the one to apply? What would be the consequences on the global process efficiency? …. This paper will answer to some of these questions.

1) What sludge material should be targeted?

Sludge production is a result of biomass growth on wastewater biodegradable fraction and refractory organic and inorganic material accumulation coming both from the wastewater and from biological and physical chemical process occurring in the reactor. So a first question is asked: among those phenomena, which one should be mainly targeted to reach a significant reduction of ESP while minimizing costs? Should biomass net growth be decreased by increasing decay rate or maintenance energy requirements? Would it be better to target the refractory solid material? In this study, these different strategies are assessed. Firstly, Activated Sludge Model 1 (ASM1) was successfully calibrated using results from lab scale pilot plants operated at different sludge retention times (SRT). Secondly, it was used to compare the maximum reduction of ESP reachable by increasing biomass decay or maintenance energy requirements or by increasing solubilisation and/or biodegradability of refractory materials. In the case of an activated sludge system operated at SRT of 15 days and fed with a primary settled wastewater containing a solid refractory COD fraction (X_I) of 20%, ASM1-based simulations demonstrated that:

• 
  a 20% maximum reduction of ESP could be achieved when doubling biomass decay rate
  
• 
  a 35% maximum reduction of ESP could be reached when increasing maintenance energy requirements simulated by decreasing the heterotrophic growth yield by 30%
  
• 
  increasing solubilisation and biodegradability for solid refractory materials, 100% reduction of ESP could be reached.
  

Based on these results, oxidation technologies appear to be promising candidates for high reduction of ESP. Chemical oxidation may act complementary to biological oxidation because of specific affinity with unsaturated complex molecules, which are important part of particulate refractory COD fraction. Using ozone as oxidant in discontinuous reactor (2 L), solubilisation of particulate COD and mineral was followed for sludges from different origins. The high potential of ozone for solubilising both organic and inorganic fractions was then confirmed. A lab scale (26 L) activated sludge reactor continuously fed with a real primary settled wastewater from Toulouse was coupled with reactor (2 L) discontinuously fed with the mixed liquor. This discontinuous reactor served as contactor between gaseous ozone and sludge. For ozone dosage of 0.02 g O3 . (g VSS)^-1 no excess sludge production was observed (figure 1). This result confirms previous results obtained at various scales by Kamiya and Hirotsuji (1998) or Déléris (2001). So far, and from our knowledge, no other technology (thermal, mechanical, chemical, physical associated treatments) have demonstrated such a potential on real wastewater. This may be due to inadequate solubilisation potential of these last techniques.

Nitrogen and phosphorus compounds are also solubilised during ozonation. In the continuous pilot 90%± 5% of nitrificable nitrogen is nitrified whatever reduction of ESP degree. Nitrification potential then increases proportionally to the nitrogen solubilisation. Moreover, aerobic and anaerobic respirometric measurements show that the COD released after ozonation is partly easily biodegradable and can be consumed for denitrification. But, remaining O₂ will compete with nitrates as final electrons acceptors.

Solubilisation of nutrients and decrease of sludge production set the problem of nutrient recovery mainly for P recovery. New strategies should be developed.

References:

Déléris S., Paul E., Debellefontaine H., Geaugey V. (1999) Sludge reduction in wastewater treatment plants. Mass balances for assessing the efficiency of a combined treatment system: activated sludge and ozonation. 2eme Congrès Européen de Génie des Procédés, Montpellier, 5-7 octobre 1999.

Kamiya T. and Hirotsuji, J. (1998) New combined system of biological process and intermittent ozonation for advanced wastewater treatment. Wat. Sci. Tech. 38 (8-9), 145-153.