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Environmental water quality management of glyphosate-based herbicides in South AfricaMensah, Paul Kojo January 2013 (has links)
Although the use of pesticides is necessary to meet the socio-economic needs of many developing countries, especially in Africa, side effects of these bio-active chemicals have contributed to contaminating aquatic and terrestrial ecosystems. Environmental water quality degradation by pesticides interferes with ecosystem health and poses numerous risks to aquatic life. In South Africa, glyphosate-based herbicides are frequently used to control weeds and invading alien plants, but ultimately end up in freshwater ecosystems. However, there are no South African-based environmental water quality management strategies to regulate these bio-active chemicals. Therefore, this study sought to provide a sound scientific background for the environmental water quality management of glyphosate-based herbicides in South Africa, by conducting both laboratory and field investigations. In the laboratory investigations, aquatic ecotoxicological methods were used to evaluate responses of the freshwater aquatic shrimp Caridina nilotica exposed to Roundup® at different biological system scales, and the responses of multiple South African aquatic species exposed to Roundup® through species sensitivity distribution (SSD). In the field investigations, the effect of Kilo Max WSG on the physicochemical and biological conditions of three selected sites in the Swartkops River before and after a spray episode by Working for Water were evaluated through biomonitoring, using the South African Scoring System version 5 (SASS5) as a sampling protocol. Both Roundup® and Kilo Max WSG are glyphosate-based herbicides. All the data were subjected to relevant statistical analyses. Findings of this study revealed that Roundup® elicited responses at different biological system scales in C. nilotica, while SSD estimates were used to derive proposed water quality guidelines for glyphosate-based herbicides in South Africa. The biomonitoring revealed that using glyphosate-based herbicides to control water hyacinth within the Swartkops River had a negligible impact on the physicochemical and biological conditions. Based on these findings, a conceptual framework that can be used for the integrated environmental water quality management of glyphosate-based herbicides in South Africa was developed as part of integrated water resource management (IWRM). The combined data sets contribute to a sound scientific basis for the environmental water quality management of glyphosate-based herbicides in South Africa.
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Evaluation of community water quality monitoring and management practices, and conceptualization of a participatory model : a case study of Luvuvhu Catchment, South AfricaNare, Lerato 11 February 2016 (has links)
Department of Hydrology and Water Resources / PhDH
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Investigation of trace components in autothermal gas reforming processesMuritala, Ibrahim Kolawole 10 January 2018 (has links) (PDF)
Trace component analysis in gasification processes are important part of elemental component balances in order to understand the fate of these participating compounds in the feedstock. Residual traces in the raw synthesis gas after quench could bring about the poisoning of catalysts and corrosion effects on plant facilities. The objective of this work is to investigate the effects of quenching operation on the trace components during test campaigns of the autothermal non-catalytic reforming of natural gas (Gas-POX) mode in the HP POX (high pressure partial oxidation) test plant. In order to achieve this, Aspen Plus simulation model of the quench chamber of the HP POX test plant was developed to re-calculate the quench chamber input amount of different trace compounds from their output amount measured during test points of the Gas-POX campaigns.
Variation in quench water temperatures from 130 °C to 220 °C and pH value of quench water as well as the resulting variation in Henry´s and Dissociation constant of the traces (CO2, H2S, NH3 and HCN) changed the distribution of traces calculated in the quench water. The formation of traces of organic acid (formic acid and acetic acid) and traces of BTEX, PAHs and soot in the quench water effluent were discussed. The discrepancies between equilibrium constant and reaction quotient (non-equilibrium or real) for the formation of NH3 and HCN at the exit of the gasifier were discussed. The assessment of the results in this work should lead to the improvement in the understanding of trace components and concepts that could be employed to influence their formation and reduction.
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Investigation of trace components in autothermal gas reforming processesMuritala, Ibrahim Kolawole 07 April 2017 (has links)
Trace component analysis in gasification processes are important part of elemental component balances in order to understand the fate of these participating compounds in the feedstock. Residual traces in the raw synthesis gas after quench could bring about the poisoning of catalysts and corrosion effects on plant facilities. The objective of this work is to investigate the effects of quenching operation on the trace components during test campaigns of the autothermal non-catalytic reforming of natural gas (Gas-POX) mode in the HP POX (high pressure partial oxidation) test plant. In order to achieve this, Aspen Plus simulation model of the quench chamber of the HP POX test plant was developed to re-calculate the quench chamber input amount of different trace compounds from their output amount measured during test points of the Gas-POX campaigns.
Variation in quench water temperatures from 130 °C to 220 °C and pH value of quench water as well as the resulting variation in Henry´s and Dissociation constant of the traces (CO2, H2S, NH3 and HCN) changed the distribution of traces calculated in the quench water. The formation of traces of organic acid (formic acid and acetic acid) and traces of BTEX, PAHs and soot in the quench water effluent were discussed. The discrepancies between equilibrium constant and reaction quotient (non-equilibrium or real) for the formation of NH3 and HCN at the exit of the gasifier were discussed. The assessment of the results in this work should lead to the improvement in the understanding of trace components and concepts that could be employed to influence their formation and reduction.:List of Figures vii
List of Tables xii
List of Abbreviations and Symbols xiii
1 Introduction 1
1.1 Background 1
1.2 Objective of the Work 4
1.3 Overview of the Work 5
2 Process and test conditions 6
2.1 HP POX test plant 6
2.2 Test campaign procedure 8
2.2.1 Gas-POX operating parameter range 8
2.2.2 Gas-POX experiments 9
2.2.3 Net reactions of partial oxidation 9
2.3 Gaseous feedstock characterization 11
2.3.1 Natural gas feedstock composition 11
2.4 Analytical methods for gaseous products 12
2.4.1 Hot gas sampling 12
2.4.2 Raw synthesis gas analysis after quench 13
2.5 Aqueous phase product analysis 14
2.5.1 Molecularly dissolved trace compounds and their ions trace analysis 14
2.5.2 Other trace analysis 15
2.6 Limit of accuracy in measurement systems 15
2.7 Summary 17
3 Simulation and methods 18
3.1 Test points calculation of the HP POX test campaign 18
3.1.1 Aspen Plus model for HP POX quench water system 19
3.2 Gas-POX 201 VP1 quench water system model simulation by Aspen Plus 23
3.2.1 Measured and calculated input parameters 23
3.2.2 Calculated sensitivity studies of species and their distribution for test point (VP1) 24
3.3 Used calculation tools related to the work 25
3.3.1 VBA in Excel 25
3.3.2 Python as interface between Aspen Plus and Microsoft Excel 26
3.3.3 Aspen Simulation Workbook 27
3.4 Summary 29
4 Trace components in quench water system 30
4.1 Physico-chemical parameters of quench water 31
4.1.1 Quench water pH adjustment 32
4.1.2 Henry constant 34
4.1.3 Dissociation constant 35
4.1.4 Organic acids in quench water 38
4.2 Carbon dioxide (CO2) 39
4.2.1 Results of sensitivity study: quench water temperature variation effects on CO2 41
4.2.2 Results of sensitivity study: quench water pH variation influence on CO2 42
4.3 Nitrogen compounds 43
4.3.1 Ammonia (NH3) 44
4.3.2 Results of sensitivity study: quench water temperature variation effects on NH3 46
4.3.3 Results of sensitivity study: quench water pH variation influence on NH3 47
4.3.4 Hydrogen Cyanide (HCN) 48
4.3.5 Results of sensitivity study: quench water temperature variation effects on HCN 50
4.3.6 Results of sensitivity study: quench water pH variation influence on HCN 50
4.4 Sulphur compounds: H2S 51
4.4.1 Results of sensitivity study: quench water temperature variation effects on H2S 53
4.4.2 Results of sensitivity study: quench water pH variation influence on H2S 54
4.5 Summary 55
5 Organic acids trace studies in quench water 57
5.1 Organic acids interaction with ammonia compounds in the quench water 57
5.2 Formic acid 62
5.2.1 Trace of formic acid in quench water 64
5.3 Acetic acid 67
5.3.1 Trace of acetic acid in quench water 69
5.4 Summary 72
6 Temperature approach studies for NH3 and HCN formation in gasifier 74
6.1 Nitrogen compounds: NH3 and HCN 74
6.2 Ammonia (NH3) formation in the gasifer 77
6.3 Hydrogen cyanide (HCN) formation in the gasifier 79
6.4 Discrepancies between back-calculated reaction quotients and equilibrium constants of the NH3 formation 81
6.4.1 Case 1: calculated equilibrium distribution between N2, NH3 and HCN 81
6.4.2 Case 2: calculated equilibrium distribution between NH3 and HCN 83
6.5 Summary 84
7 Traces of BTEX, PAHs and soot in quench water 86
7.1 Quench water behaviour 87
7.2 BTEX compounds 88
7.2.1 BTEX in quench water effluent 90
7.3 PAH compounds 93
7.3.1 PAHs in quench water effluent 95
7.4 Soot formation 99
7.4.1 Soots in quench water effluent 101
7.5 Summary 102
8 Summary and outlook 103
Bibliography 106
9 Appendix 135
List of Figures
Figure 2.1: HP POX test plant main facility components and material flow courtesy of [Lurgi GmbH, 2008] 6
Figure 2.2: Simplified scheme of HP POX plant (including quench system) [Lurgi GmbH, 2008] 7
Figure 2.3: Overview of reactions of methane 10
Figure 3.1: Simplified scheme for HP POX quench water system 18
Figure 3.2: Aspen Plus flow diagrams of simulated HP POX quench water system 19
Figure 3.3: Integration of information and functions in VBA via Microsoft Excel to Aspen Plus model 25
Figure 3.4: Integration of information and functions in Python via Microsoft Excel to Aspen Plus model 26
Figure 3.5: ASW enables Excel users to rapidly run scenarios using the underlying rigorous models to analyze plant data, monitor performance, and make better decisions. 27
Figure 4.1: Vapour-liquid equilibria system of CO2, H2S, NH3, HCN and organic acids in the quench water and extended mechanisms according to [Kamps et al., 2001], [Alvaro et al., 2000], [Kuranov et al., 1996], [Xia et al., 1999] and [Edwards et al., 1978]. 30
Figure 4.2: HP POX quench water system with pH regulator for sensitivity studies 34
Figure 4.3: Henry´s constant for CO2, H2S, NH3 and HCN derived from [Edwards et al., 1978] for CO2, [Alvaro et al., 2000] for NH3, [Kamps et al., 2001] for H2S, and [Rumpf et al., 1992] for HCN 35
Figure 4.4: Dissociation constants for CO2, H2S, NH3, HCN and H2O derived from [Alvaro et al., 2000], [Kamps et al., 2001], and [Edwards et al., 1978] 37
Figure 4.5: The flow of CO2 in the quench water cycle (test point VP1). 40
Figure 4.6: Calculated quench water temperature variation and effects on CO2 distribution 42
Figure 4.7: Calculated influence of pH regulation and effects on CO2 distribution 43
Figure 4.8: The flow of NH3 in the quench water cycle (test point VP1). 46
Figure 4.9: Calculated quench water temperature variation and effects on NH3 distribution 47
Figure 4.10: Calculated influence of pH regulation and effects on NH3 distribution 48
Figure 4.11: The flow of HCN in the quench water cycle (test point VP1). 49
Figure 4.12: Calculated quench water temperature variation and effects on HCN distribution 50
Figure 4.13: Calculated influence of pH regulation and effects on HCN distribution 51
Figure 4.14: The flow of H2S in the quench water cycle (test point VP1) 53
Figure 4.15: Calculated quench water temperature variation and effects on H2S distribution 54
Figure 4.16: Calculated influence of pH regulation and effects on H2S distribution 55
Figure 5.1: Aspen Plus back-calculated (real) formic acid concentration, quench water temperature and the calculated equilibrium formic acid concentration against back-calculated (real) ammonia concentration for the 47 test points (using amongst others sampled HCOO- and NH4+ values according to Table 2.6). 59
Figure 5.2: Aspen plus back-calculated (real) formic acid concentration, back-calculated (real) ammonia concentration and the calculated equilibrium formic acid concentration against quench water temperature for the 47 test points (using amongst others sampled HCOO- and NH4+ values according to Table 2.6). 60
Figure 5.3: Aspen plus back-calculated (real) acetic acid concentration, quench water temperature and the calculated equilibrium acetic acid concentration against back-calculated (real) ammonia concentration for the 47 test points. 61
Figure 5.4: Aspen plus back-calculated (real) acetic acid concentration, back-calculated (real) ammonia concentration and the calculated equilibrium acetic acid concentration against quench water temperature for the 47 test points. 62
Figure 5.5: Concentration of formic acid (Aspen plus calculated m_eq and back-calculted m_real) formation in the quench and quench water temperature for the 47 test points. 64
Figure 5.6: Concentration of formic acid (Aspen plus calculated m_eq and back-calculted m_real) in the quench against quench water temperature for the 47 test points (as in Fig.5.2). 65
Figure 5.7: Comparison between formic acid equilibrium constant (Keq), reaction quotient (Kreal) and the quench water temperature for the 47 test points. 66
Figure 5.8: Comparison between formic acid equilibrium constant (Keq) and reaction quotient (Kreal) against quench water temperatures for the 47 test points. 67
Figure 5.9: Concentration of acetic acid (Aspen plus calculated m_eq and back-calculted m_real) in the quench and quench water temperature for the 47 test points. 69
Figure 5.10: Concentration of acetic acid (Aspen plus calculated m_eq and back-calculted m_real) in the quench against quench water temperature for the 47 test points (as in Fig.5.4). 70
Figure 5.11: Comparison between acetic acid equilibrium constant (Keq), reaction quotient (Kreal) and the quench water temperature for the 47 test points. 71
Figure 5.12: Comparison between acetic acid equilibrium constant (Keq) and reaction quotient (Kreal) against quench water temperatures for the 47 test points. 72
Figure 6.1: Mole fraction of gas compoents in the hot gas outlet out of gasifier against hot gas temperature for the 47 test points 76
Figure 6.2: Calculated reaction quotient (Q) and equlibrium constant (Keq) for NH3 against hot gas temperature for the 47 test points (see Fig. 9.10 in Appendix) 77
Figure 6.3: NH3 temperature approach against hot gas temperature for the 47 test points (see Fig. 9.11 in Appendix) 78
Figure 6.4: Calculated reaction quotient (Q) and equlibrium constant (Keq) for HCN against hot gas temperature for the 47 test points (see Fig. 9.13 in Appendix) 79
Figure 6.5: HCN temperature approach against hot gas temperature for the 47 test points (see Fig. 9.14 in Appendix) 80
Figure 6.6: Comparison between calculated real and equilibrium hot gas N2, NH3 and HCN mol fractions against their respective hot gas temperature (case 1). 82
Figure 6.7: Relations between back-calculated real and equilibrium hot gas N2, NH3 and HCN mol fractions (for chemical equilibrium according to equations (6.1) and (6.4)) against their respective hot gas temperature (see Case 1, Section 6.4.1, and Fig. 6.6) 82
Figure 6.8: Comparison between calculated real and equilibrium hot gas HCN mol fraction against their respective hot gas temperature (case 2). 83
Figure 6.9: Relations between back-calculated real and equilibrium hot gas HCN mol fractions, and change in NH3 mol fractions (for chemical equilibrium according to equation (6.4)), against their respective hot gas temperature (see. Case 2, Section 6.4.2 and Fig. 6.7) 84
Figure 6.10 Comparison between NH3 and HCN formation (mole fraction) calculated equilibrium constant (Keq) and calculated reaction quotient (Q), N2 consumption and hot gas temperatures for the 47 test points (case 1 and case 2). 85
Figure 7.1: HP POX test plant quench water system 88
Figure 7.2: Traces of BTEX measured in the Gas-POX 203 – 207 quench water effluent sample. 91
Figure 7.3: Individual component of BTEX measured in the Gas-POX 203 – 207 quench water effluent sample. 92
Figure 7.4: (a) Alkyl radical decomposition and (b) C1 and C2 hydrocarbons oxidation mechanism [Warnatz et al., 2000] 93
Figure 7.5: Recombination of C3H3 to form benzene 94
Figure 7.6: The Diels - Alder reaction for the formation of PAHs 95
Figure 7.7: Amount of PAHs that were detected in Gas-POX 203 – 207 test points quench water effluent samples. 97
Figure 7.8: Distribution of PAH compounds in Gas-POX 203 – 207 quench water effluent samples. 98
Figure 7.9: Some steps in soot formation [McEnally et al., 2006]. 99
Figure 7.10: Illustration of soot formation path in homogenous mixture [Bockhorn et al., 1994] 100
Figure 9.1: Aspen flow sheet set up for HP POX quench system GasPOX 201 VP1 (simplified and extension of Fig. 3.2, organic acids not taken into account). Tabulated values are given in Table 9.11. 135
Figure 9.2: Comparison between the Henry´s constant profiles: Aspen Plus (markers) and Literatures (solid lines) ([Edwards et al., 1978] for CO2, [Alvaro et al., 2000] for NH3, [Kamps et al., 2001] for H2S, and [Rumpf et al., 1992] for HCN as it can be seen in Fig. 4.3) 137
Figure 9.3: Henry´s constant profiles derived from literatures ([Edwards et al., 1978] for CO2, [Alvaro Pérez-Salado et al., 2000] for NH3, [Kamps et al., 2001] for H2S, and [Rumpf et al., 1992] for HCN as it can be seen in Fig. 4.3) 137
Figure 9.4: Comparison between the dissociation constant profiles: Aspen Plus (markers) and Literatures (solid or dashed lines) [Alvaro et al., 2000], [Kamps et al., 2001], and [Edwards et al., 1978] as in Fig.4.4. 138
Figure 9.5: Dissociation constant profiles derived from literatures [Kamps et al., 2001], and [Edwards et al., 1978] as in Fig.4.4. 138
Figure 9.6: Calculated pH values, temperature range and species 139
Figure 9.7: Aspen Plus flow sheet setup for organic acid compounds calculations (GasPOX 201 VP1, see also Table 9.12) 142
Figure 9.8: Aspen Plus flow sheet setup for nitrogen compounds calculations (GasPOX 201 VP1, see also Table 9.12, organic acids are taken into account in the aqueous streams of the quench system) 145
Figure 9.9: Yield of ammonia in gasifier (calculated real) and hot gas temperature against the 47 test points 146
Figure 9.10: Kreal or reaction quotient for ammonia formation in the gasifier against the 47 test points. 146
Figure 9.11: Temperature approach studies for ammonia and the 47 test points 147
Figure 9.12: Yield of HCN from the gasifier (calculated real and equilibrium) and hot gas temperature and the 47 test points 147
Figure 9.13: Comparison between equilibrium constant and reaction quotient for HCN and 47 test points 148
Figure 9.14: Temperature approach studies for HCN and the 47 test points 148
Figure 9.15: Comparison among equilibrium constants of reactions against temperature, T [°C] 149
Figure 9.16: Comparison among equilibrium constants of reactions against temperature, 1/T [1/K] 150
List of Tables
Table 2.1: Outline of Gas-POX mode operating parameter range 8
Table 2.2: Outline of test runs operating mode and parameters of chosen test campaigns 9
Table 2.3: Natural gas feedstock compositions 12
Table 2.4: Product synthesis gas analysis method (hot gas before quench) [Brüggemann, 2010] 12
Table 2.5: Analysis methods for raw synthesis gas [Brüggemann, 2010] 13
Table 2.6: Analysis methods for aqueous phase products [Brüggemann, 2010] 14
Table 2.7: Relative accuracy for the measured value for temperature, pressure and flow of each feed and product stream [Meyer, 2007] and [Brüggemann, 2010] 17
Table 3.1: Description of blocks used in Aspen Plus simulation. 20
Table 3.2: HP POX test plant quench water cycle parameters Gas-POX 201 VP1* 23
Table 3.3: pH regulator parameters 24
Table 4.1: Organic acids distribution in streams for VP1 based on calculation from Aspen Plus. 38
Table 4.2: The distribution of CO2 and its ions in all the streams 40
Table 4.3: The distribution of NH3 and its ions in all the streams 45
Table 4.4: The distribution of HCN and its ions in all the streams 49
Table 4.5: The distribution of H2S and its ions in all the streams 52
Table 7.1: Relative sooting tendency [Tesner et al., 2010] 101
Table 9.1: Natural gas feed analysis method [Brüggemann, 2010] 135
Table 9.2: pH scale with examples of solution [NALCO 2008] 136
Table 9.3: Gas-POX test campaigns and with designated serial numbers 140
Table 9.4: Summary of correlation coefficient (r) from Figures in Chapter 5 144
Table 9.5: Comparison among reactions temperatures and heat of reactions 149
Table 9.6: Content of BTEX compounds in Gas-POX quench water samples 151
Table 9.7: BTEX in quench water effluent samples results 152
Table 9.8: Content of PAH compounds in Gas-POX quench water samples 157
Table 9.9: PAHs in quench water effluent samples results 160
Table 9.10: Soot in quench water effluent samples results 169
Table 9.11: Aspen Plus flow sheet setup stream details (GasPOX 201 VP1, according to Fig.3.2 and Fig.9.1, organic acids not taken into account) 170
Table 9.12: Aspen Plus flow sheet setup for organic acid and nitrogen compounds calculations for GasPOX 201 VP1 (according to Figures 9.7 and 9.8, organic acids are taken into account) 174
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Coupled biogeochemical cycles in riparian zones with contrasting hydrogeomorphic characteristics in the US MidwestLiu, Xiaoqiang 11 December 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Numerous studies have investigated the fate of pollutants in riparian buffers, but few studies have focused on the control of multiple contaminants simultaneously in riparian zones. To better understand what drives the biogeochemical cycles of multiple contaminants in riparian zones, a 19-month study was conducted in riparian buffers across a range of hydrogeomorphic (HGM) settings in the White River watershed in Indiana. Three research sites [Leary Webber Ditch (LWD), Scott Starling (SS) and White River (WR)] with contrasting hydro-geomorphology were selected. We monitored groundwater table depth, oxidation reduction potential (ORP), dissolved oxygen (DO), dissolved organic carbon (DOC), NO3-, NH4+, soluble reactive phosphorus (SRP), SO42- , total Hg and methylmercury (MeHg). Our results revealed that differences in HGM conditions translated into distinctive site hydrology, but significant differences in site hydrology did not lead to different biogeochemical conditions. Nitrate reduction and sulfate re-oxidation were likely associated with major hydrological events, while sulfate reduction, ammonia and methylmercury production were likely associated with seasonal changes in biogeochemical conditions. Results also suggest that the LWD site was a small sink for nitrate but a source for sulfate and MeHg, the SS site was a small sink for MeHg but had little effect on NO3-, SO42- and SRP, and the WR was an intermediate to a large sink for nitrate, an intermediate sink for SRP, and a small source for MeHg. Land use and point source appears to have played an important role in regulating solute concentrations (NO3-, SRP and THg). Thermodynamic theories probably oversimplify the complex patterns of solute dynamics which, at the sites monitored in the present study, were more strongly impacted by HGM settings, land use, and proximity to a point source.
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