Characterization of organic particulates present in milk factory process waters used for reuse along with aerobically digested effluent wastewater
- Authors: Verheyen, Vincent , Cruickshank, Alicia , Wild, Karl , Heaven, M. , McGee, R. , Watkins, Mark , Nash, David
- Date: 2010
- Type: Text , Journal article
- Relation: Bioresource Technology Vol. 102, no. 2 (2010), p. 2118-2125
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- Description: Wastewater from a dairy processor is being reused and recycled both within the plant and for irrigation. Flash pyrolysis GC–MS was used to examine nitrogen and phenol containing compounds (M.W. = 35 to 450 g/mol) in the particulate fraction of the milk condensate, combined clean wastewater and aerobic bioreactor effluent. For comparison, the particulates were also prepared for standard GC–MS analyses using conventional solvent extraction methods. Compounds detected by pyrolysis GC–MS were found mostly in the bioreactor with the amino acid arginine (220 mg/kg) and the amino acid derivative 1-methyl-5-oxo-L-proline methyl ester (130 mg/kg) found at the highest concentrations. In comparison, sterols detected in the effluent were found at higher concentrations when using solvent extraction indicating some degradation with pyrolysis GC–MS. However, with few exceptions, particulates were generally found not to act as passive collectors capable of concentrating less water soluble chemicals.
Characterization of trace organic compounds in recycled water used for irrigation on turf and comparison with rain
- Authors: Heaven, M. , Verheyen, Vincent , Cruickshank, Alicia , Wild, Karl , Watkins, Mark , Nash, David
- Date: 2012
- Type: Text , Journal article
- Relation: Agricultural Water Management Vol. 103, no. (2012), p. 176-181
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- Description: Wastewaters are increasingly being reused in public spaces to supplant the use of potable water. In this study we investigated possible trace organic contaminants in wastewater from a dairy factory applied to a recreation reserve. Samples were taken of recycled dairy factory wastewater used to irrigate the reserve and from the subsurface drainage system after irrigation and after rainfall. Using gas chromatography–mass spectrometry, it was found that irrigation drainage mostly contained different compounds to those in rainfall drainage. This drainage water was found to contain residues of three agrochemicals (dicamba, 0.4 ± 0.07
Chemical characterization of MEA degradation in PCC pilot plants operating in Australia
- Authors: Cruickshank, Alicia , Verheyen, Vincent , Adeloju, Samuel , Meuleman, Erik , Chaffee, Alan , Cottrell, Aaron , Feron, Paul
- Date: 2013
- Type: Text , Journal article
- Relation: Energy Procedia Vol. 37, no. (2013), p. 877-882
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- Description: An important step towards commercial scale post-combustion CO2 capture from coal-fired power stations is understanding solvent degradation. Laboratory scale trials have identified three main solvent degradation pathways for 30% MEA: oxidative degradation, carbamate polymerization and formation of heat stable salts. This paper probes the semi-volatile organic compounds produced from a single batch of 30% MEA which was used to capture CO2 from a black coal-fired power station (Tarong, Queensland, Australia) for approximately 700 hours, followed by 500 hours at the brown coal-fired power station (Loy Yang, Victoria, Australia). Comparisons are made between the compounds identified in this aged solvent system with MEA degradation reactions described in literature. Most of semi-volatile compounds tentatively identified by GC/MS have previously been reported in laboratory scale degradation trials. Our preliminary results show low levels of degradation products were present in samples after its use in the pilot plant at Tarong (black coal) and consequent 13 months storage, but much higher concentrations were later found in the same solvent during its at use in the pilot plant at Loy Yang Power (brown coal). Further work includes identifying the cause of poor GC/MS repeatability and investigating the relative rates of reactions described in literature. The impact of inorganic anions and dissolved metals on MEA degradation will also be explored.
Soluble organic components of winery wastewater and implications for reuse
- Authors: Mosse, Kim , Verheyen, Vincent , Cruickshank, Alicia , Patti, Antonio , Cavagnaro, Timothy
- Date: 2013
- Type: Text , Journal article
- Relation: Agricultural Water Management Vol. 120, no. (2013), p. 5-10
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- Description: Sustainable reuse of winery wastewaters (WWW) via land application is of interest given the increasing industrialization of wine production. However, before WWW reuse can become widespread, its chemical composition and consequently its potential long-term impact need to be investigated. In this study, soluble materials in influent and effluent waters from different WWW treatment plants were analyzed at the molecular level using Solid Phase Micro Extraction Gas Chromatography/Mass Spectrometry (SPME GC–MS). The analytical focus was on key compound classes with potential for environmental harm, the majority of which were reduced by all treatments considered here. The effluents retained considerable quantities of recalcitrant phenolic compounds, which is of concern due to their potential phytotoxicity and proven resistance to aerobic degradation. This research highlights the importance of understanding the nature of organic material in WWW to ensure sustainable reuse.
Soluble, semivolatile phenol and nitrogen compounds in milk-processing wastewaters
- Authors: Verheyen, Vincent , Cruickshank, Alicia , Wild, Karl , Heaven, M. , McGee, R. , Watkins, Mark , Nash, David
- Date: 2009
- Type: Text , Journal article
- Relation: Journal of Dairy Science Vol. 92, no. 7 (2009), p.
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- Description: Potable water is an essential and major input in processing our food supplies, and the continued growth in food manufacturing is placing increased pressure on this limited resource. Recycling and reuse of factory wastewater can lessen potable water use but requires a detailed understanding of wastewater properties. This study uses solid-phase extraction techniques with gas chromatography-mass spectrometry analysis to investigate trace-level semivolatile organic species in various waste and reference waters associated with the Burra Foods milk-processing plant located in Southeastern Australia. Our focus was on contaminants containing phenolic and heterocyclic nitrogen functional groups, which, because of their toxicity and persistence, may limit options for water recycling and reuse. Effluent from the wastewater treatment plant of the factory showed both the highest soluble carbon burden (47 mg/kg) and concentrations of target compounds. The target species found in these effluents included methyl phenol (13 mg/kg), hydroxy indole (9.8 mg/kg), synthetic tolyltriazoles (5.1 mg/kg) and alkyl phenol ethoxylates (0.2 mg/kg). Given the environmental stability of the tolyltriazoles, they may act as chemical markers where these effluents are used for purposes such as irrigation. Milk evaporator condensate waters, in contrast to the effluent, contained very few target species, with only low levels of pyrrolidine and piperidine derivatives such as ethylglutarimide (450 mug/L) detected. Although there were fewer target microcontaminants overall in the potable and creek reference waters, these samples had characteristic profiles. The potable water analysis revealed hydroxy cineole (2.1 microg/L) and the creek analysis revealed dichlorohydroxyacetophenone (0.3 microg/L), which were not detected in other waters. The compounds found in the wastewaters are likely to have been derived from milk or synthetic chemicals used in factory operations. The presence of nitrogen compounds in all the different milk-processing waters suggest their likely source was milk, probably milk phosphoproteins subjected to thermal, chemical, or microbial degradation. Our benign results for the condensates suggest it may be possible to substitute condensate for potable water with minimal pretreatment, both within the plant and in other applications, such as irrigation of recreation turf.
Thermochemolysis of winery wastewater particulates-molecular structural implications for water reuse
- Authors: Mosse, Kim , Verheyen, Vincent , Cruickshank, Alicia , Patti, Antonio , Cavagnaro, Timothy
- Date: 2012
- Type: Text , Journal article
- Relation: Journal of Analytical and Applied Pyrolysis Vol. 97, no. 164-170 (2012), p.
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- Description: Environmental concerns have increased the interest in winery wastewater remediation and reuse. These practices require more detailed understanding of wastewater composition to ensure optimum usage, and to minimize the risk of long term soil degradation and grape contamination. Particulate organic matter is an important contributor to the carbon burden in winery wastewaters. This article investigates the molecular structure of particulates from the most common winery wastewater treatment processes via infrared spectroscopic and thermochemolysis-gas chromatography/mass spectrometry techniques. Study of the organic composition of both influent and effluent particles enabled further insight into which compounds could prove problematic during treatment and on discharge. The yield and molecular structure of desorbed or “guest” compounds were found to strongly correlate with those produced during pyrolytic cracking. These “guest” compounds and macromolecular fragments form a continuum whose separation is based on molecular size. Polyphenolic and lignin derived compounds tended to survive the water treatment processes within assemblages of microbial detritus. No evidence was found for particles adsorbing and concentrating other unrelated organics such as anthropogenic chemicals from winery wastewaters. Any release of particulates will require careful management to prevent localized accumulation of recalcitrant compounds to toxic levels.
Towards commercial scale postcombustion capture of CO2 with monoethanolamine solvent: key considerations for solvent management and environmental impacts
- Authors: Cruickshank, Alicia , Verheyen, Vincent , Adeloju, Samuel , Meuleman, Erik , Feron, Paul
- Date: 2012
- Type: Text , Journal article
- Relation: Environmental Science & Technology Vol. 46, no. 7 (2012), p. 3643-3654
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- Description: Chemical absorption with aqueous amine solvents is the most advanced technology for postcombustion capture (PCC) of CO2 from coal-fired power stations and a number of pilot scale programs are evaluating novel solvents, optimizing energy efficiency, and validating engineering models. This review demonstrates that the development of commercial scale PCC also requires effective solvent management guidelines to ensure minimization of potential technical and environmental risks. Furthermore, the review reveals that while solvent degradation has been identified as a key source of solvent consumption in laboratory scale studies, it has not been validated at pilot scale. Yet this is crucial as solvent degradation products, such as organic acids, can increase corrosivity and reduce the CO2 absorption capacity of the solvent. It also highlights the need for the development of corrosion and solvent reclamation technologies, as well as strategies to minimize emissions of solvent and degradation products, such as ammonia, aldehydes, nitrosamines and nitramines, to the atmosphere from commercial scale PCC. Inevitably, responsible management of aqueous and solid waste will require more serious consideration. This will ultimately require effective waste management practices validated at pilot scale to minimize the likelihood of adverse human and environmental impacts from commercial scale PCC.