Theses and Dissertations (Chemical Engineering)

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    Refractometry models for compositional analysis of binary and ternary mixtures
    (University of Pretoria, 2024-01-26) Focke, Walter Wilhelm; Du Toit, Elizbé; u15076238@tuks.co.za; Pretorius, Franco
    A review of existing compositional binary mixture models for refractive indices was undertaken and showed that they can be recast in forms that are linear in mole or volume fraction. Typically, mole fractions proved to be the better composition descriptor when analysing literature data and the molar refraction was shown to be virtually temperature independent. Depending on whether temperature, density or refractive index measurements of the mixture are available, different correlations were developed to predict the composition (as shown below). Furthermore, refractive index measurements on mixtures of n-alkanes with DEET were taken to determine phase equilibrium behaviour. With extrapolation to infinite molar mass, these alkanes approach polyethylene, which is the material from which DEET-containing mosquito-repellent devices were made. The results show that the microporous structure was likely formed by liquid-liquid phase separation. Lastly, it was shown that Padé approximants provide good representations of binary and ternary refractive index data. The temperature dependence of the pure components was elegantly subsumed in a pure component property, namely, the molar volume. Various constraints were applied to reduce the number of adjustable parameters even further and this proved to be successful.
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    Poly(lactic acid) filament filled with layered double hydroxide for fused deposition modelling; optimisation of additive fraction and material extrusion parameters
    (University of Pretoria, 2024-07-31) Labuschagne, F.J.W.J. (Frederick Johannes Willem Jacobus); Coetzer, R.L.J. (Roelof); u18017763@tuks.co.za; De Bruin, Philip
    The optimum layered double hydroxide (LDH) loading in poly(lactic acid) (PLA) filament, layer height, nozzle temperature and infill density levels were determined by statistically maximising the ultimate tensile stress of printed parts. Fused deposition modelling (FDM) is a material extrusion additive manufacturing (AM) method. It allows the printing of complex parts with simple and relatively cheap equipment. After stereolithography, it is the most popular AM method. FDM parameters that influence a printed artefact most are layer height, nozzle temperature and infill density. PLA is a compostable polymer which can be synthesised from renewable sources. It is the most used polymer in FDM and is projected to continue dominating the 3D printing landscape. LDH is an anionic clay with a brucite-like structure. It contains carbonate anions in its interlayer, which can be exchanged with other substances, making it extremely versatile for various applications. From a systematic literature review following preferred reporting items for systematic reviews and meta-analyses (PRISMA) guidelines it was shown that only one paper describes acrylonitrile butadiene styrene filament filled with LDH. This showed that filaments containing LDH for FDM purposes have scope for research. With PLA being the most popular FDM polymer, a second review using PRISMA guidelines were completed on PLA filled with LDH. No other review on LDH in PLA was found in the 87 articles considered. A 24−1 fractional factorial experiment was used to screen the four factors, and was augmented to fit quadratic models for the respective responses. These included ultimate tensile stress and load, elongation at break, Young’s modulus and impact energy. A central composite design was used to verify the optimum conditions predicted by the derived models. The statistical design of experiments (DoE) considered the following ranges for LDH loading, layer height, nozzle temperature and infill density: 0 % to 10 %, 0.18 mm to 0.42 mm, 190 ◦C to 220 ◦C and 10 % to 100 % respectively. Analysis of variance (ANOVA) was used to derive models and analyse the factors that affect the responses. For tensile properties the optimum combination of factors were at lower levels of layer height, nozzle temperature and LDH loadings at 0.18 mm, 190 ◦C and between 0 % and 4 % respectively. Infill densities between 80 % and 100 % also yielded the maximum tensile properties. Impact properties did not vary statistically in this region either. Inconclusive results were observed for Young’s modulus, and it is expected that another material extrusion parameter affects this response. Even though inferior in strength, parts could be printed with filament containing up to 10 % LDH. It was shown that LDH PLA filament can be made and that artefacts can be printed with FDM. Up to 4 % LDH can be printed without negatively affecting mechanical properties compared to pure PLA, and printing is still possible with LDH loadings as high as 10 %. Because substances can be intercalated into LDH for specific purposes, a legion of applications including medical, environmental and flame retardance applications are theoretically possible. The combination of the benefits of FDM and LDH can lead to tremendous advancements in a variety of fields. Since this is the first work reported on LDH PLA filaments, further research and work is recommended. Development should focus on limiting degradation of PLA when making filled filament, achieving the required strengths for specific applications and testing the efficacy of intercalated substances after printing. The proper use of statistics in research is highly recommended. It was shown that resources are wasted because statistics are not fully exploited, especially in the nature science and engineering establishments. Specifically, it is not necessary to have five or more replications for each experimental point in a statistically designed experimental programme, especially in the screening stage of a DoE. More research in the effect of slicing software on printed parts are also required. It was found that the fracture locations on printed tensile parts depended on the Ultimaker Cura slicer settings instead of the material.
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    Multispecies bacterial attachment to A106 GB industry-finished steel used in heat exchangers
    (University of Pretoria, 2024-06-19) Chirwa, Evans M.N.; Tichapondwa, Shepherd Masimba; alicia.prithiraj@gmail.com; Prithiraj, Alicia
    Multispecies bacterial attachment to industrial-finished alloys is not understood. It is not well understood as to why certain bacterial species selectively attach to differently finished steel surfaces. It is also a matter of curiosity as to why the attachment of certain bacteria influences corrosion. Bacterial attachment in heat exchangers leads to biofouling, corrosion, and downtime costs. This study evaluated the synergistic effect of bacterial attachment to smooth and rough (industrial standard) surfaces unique to the petrochemical industry. From the results there were no significant time-related differences in colonisation (p(perm)>0.05), and bacterial levels on the surfaces (p>0.05). However, quantification of surfaces using Atomic Force Microscopy (AFM) showed significant differences (p<0.05) in the root mean square surface roughness (RMS) of the differently finished surfaces, elucidating that bacterial colonisation was not proportional to surface roughness. It was observed that Clostridium sp. colonised the rough surfaces abundantly, and Pseudomonas sp. favoured the rough surface during early colonisation which influenced the corrosion rate. In bacterial presence, the corrosion rate on the rough alloy surface on day 3, exhibited corrosion resistance. This was owing to the synergistic behaviour of the bacteria which selectively attached to the rough surface and formed biofilm. Increased corrosion rates were then observed when compared to the smooth alloy. On the rough surface on day 6, the corrosion rate was observed to be the highest with 38.72 ± 0.15 mm/y. Smooth surfaces exhibited unusual corrosion rates on this day. On day 13 both surfaces exhibited a corrosion protection phenomenon. In light of the findings, it was i observed that there were significant differences observed on day 6, in the corrosion rate value between the rough and smooth surfaces (p<0.05). The growth model confirmed that exponential growth phase took place from day 6. Total Organic Carbon (TOC) results revealed that during bacterial growth, the bacteria utilised the carbon sources and produced acetic acid and lactic acid which played an important role in the corrosion process. Unlike sulfate-reducing bacteria (SRB), Clostridium sp. and Pseudomonas sp. described in this study are rarely reported in the petrochemical environment. These microorganisms are ubiquitous; however, their dominance in these systems showed that they play a significant role in steel corrosion. This study used next-generation sequencing with qPCR into microbial species colonising steel with AFM, which are rarely reported jointly in the literature. These bacteria can survive nutrient-depleted conditions for extended periods. The results provided a basis to explicate metabolic pathways. Long-term steel exposure to the bacterial consortia indicated steel protection rather than corrosion. Innovative insights on carbon-metal bonding were also determined, which could be a basis for future work. The synergistic behaviour of the bacteria provided a new dimension of thinking regarding the corrosion of carbon steel. In this study, the smooth-finished alloy performed best in this process system based on the corrosion evaluation.
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    Plasma-vernietiging van rubberskroot : teoretiese en eksperimentele onderbou
    (University of Pretoria, 2023-12) Crouse, Philippus L.; Van der Walt, Izak J.; aaj421216@gmail.com; Jansen, Arnold Alexander
    Afrikaans: Die oorhoofse doelwit van hierdie navorsing was die onwikkeling van ʼn reaktorkonsep en vloeidiagam vir ʼn vervoerbare plasma-gebaseerde eenheid vir die prosesering van skrootrubber. Die projek het voor die internasionale Covid-inperkings afgeskop. In daardie stadium het Necsa reeds oor ʼn ontwerp vir ʼn navorsings-plasma-eenheid beskik. Die konstruksie van die toerusting is eers in 2022 voltooi met `n beperkte begroting. Die inbedryfstelling van die toerusting het deel van hierdie studie gevorm. Die algemene teikenvoermateriaal vir die eenheid is egter munisipale afval. Daar is nie gepoog om enige aspek van die sisteem tydens die studie vir die voer van rubber te optimiseer nie. Die gedrag van die navorsingsisteem ‒ soos hy ontwerp, gebou, en in bedryf gestel is ‒ is dus ge-evalueer vir rubber as voermateriaal. Die uiteindelike uitsette is konsep-voorstelle vir ʼn toekomstige rubbervergassingsisteem ‒ ondersteun deur die nuwe kennis geskep tydens die afhandeling van hierdie projek. Kritieke data vir reaktorontwerp behels die kinetika en die termodinamika van die proses. Die kinetika bepaal die minimum vertoeftyd van die material in die reaktor, en die vertoeftyd pen die grootte van die reaktor vas. Kinetika verwys oor die algemeen na die snelheid van die reaksie, of reaksies, en kan chemiese of fisiese meganismes behels. Die termodinamika van die proses bepaal beide die opbrengs en die energie-vereistes. Die nodige termodinamise data kan grootliks teoreties gegenereer word. Eksperimentele werk is egter nodig om die kinetika te bepaal. Hoewel daar ʼn oorvloed van data oor die termiese gedrag en kinetika van rubber in die oop literatuur beskikbaar is, is dit uiters riskant om nie eksperimentele werk op eie materiaal uit te voer nie; en verder was die formulering van die kinetika nie in die vorm wat vir hierdie projek benodig is nie. Twee noukeurige eksperimentele programme is gevolglik aangepak om die kinetika op `n mikro- en makroskaal vas te pen. Die eerste was ʼn termogravimatriese studie op fyn-gemaalde rubberkrummels, ≤ 100 μm. Die tweede was ʼn videografiese studie van die termiese gedrag van rubberblokkies in ʼn buisoond. Onder inerte toestande piroliseer rubber in die temperatuurgebied 200‒500 °C, om koolstofmonoksied, metaan, en verskeie alkane, alkene, en sikliese organiese verbindings te vorm. Die massaverlies is ordelik 70 %. Indien die residu verder na hoër temperature verhit word, vind addisionele massaverlies plaas ‒ maar slegs van ʼn verdere paar persent. Verskeie opsies vir die benutting van die koolstofhoudende residue is beskikbaar. Die konsep wat in die navorsing getoets is, is die gebruik van die tru-Boudouard-reaksie; dit is die reaksie van koostofdioksied met vaste koolstof, om koolstofmonoksied te vorm. Die termogravimetriese studie het isotermiese sowel as dinamiese lopies oor ʼn wye stel temperatuurprogramme behels. Kinetiese triplette, d.w.s. modelle, aktiveringsenergieë, en pre-eksponesiële faktore, is uit die isotermiese termogramme bepaal. Hierdie data is daarna gebruik as beginwaardes vir direkte passing van die dinamiese krommes. Die hoofbevindinge was dat: die eerste pirolisestap deur ʼn 3D-diffusiemodel beskryf kan word; die hoë-temperatuurpirolise onder inerte toestande deur die Mampel-meganisme; en die tru-Boudouard-reaksie deur ʼn chemiesbeheerde krimpende-partikelmodel. Die buisoondeksperimente het belangrike insig oor die termiese gedrag van makroskopiese rubberblokkies verskaf. Die blokkies verkool rofweg binne die tye wat deur die TGA-kinetika voorspel word, by laer temperature, met ʼn sigbare verkolingsfront wat na binne beweeg. By nagenoeg 800 °C en hoër word die prosestempo egter deur die warmte-oordragtempo bepaal. Die totale pirolisetyd kan bereken word as die som van die inherente pirolisetyd en ʼn warmte-oordragkomponent. Verder word die proses so vinnig dat die druk wat binne die rubber opbou a.g.v. die piroliseprodukgasse, hoog genoeg om mikro-ontploffings en verpoeiering van die blokkies te veroorsaak ‒ in granules van 100 μm en kleiner. Die tru-Boudouard se reaksietempo is direk eweredig aan die koolstofdioksiedkonsentrasie; die diffusiesnelheid van die koolstofdioksied na die reaksieoppervlak bepaal eers die reakietempo bo ~1 200 °C. Die plasmavergassingsreeks het die ondersoek uitgebrei na die kg h-1 skaal. Die werk is uitgevoer m.b.v. ʼn nuut-opgerigte 15 kW(e) plasma-vergassingstelsel, ontwerp om organiese materiaal met lug, suurstof en stoom, of kombinasies daarvan, te vergas waar die reaksiekinetika vinnig is. In die geval van die tru-Boudouardreaksie is die kinetika egter relatief stadig en die vereiste vertoeftyd in die reaktor beduidend. Die uitmekaarspat van die monsters, soos tydens die buis-oondeksperimente waargeneem, is bevestig deur die voorkoms van rubberkooks oral op koue oppervlaktes in die toerusting en die versamelde materiaal in die filter. Die endotermiese reaksie by die aanvanklike blootstelling van monsters in die buisoond is bevestig deur die temperatuurskommelings in die plasmareaktor wat tydens pulserende rubbervoer waargeneem is. Onder eksperimentele kondisies en -gasvloeie was die reaktorvolume van 4.7 L onvoldoende vir die verlangde vertoeftyd en dit het duidelik geword dat reaktorontwerp van kardinale belang sal wees vir ’n praktiese vergassingaanleg. Ten slotte word ʼn prosesvloeidiagram vir plasmavergassing van skrootrubber deur die tru-Boudouardreaksie voorgestel en bespreek, wat ook bedryfsveiligheid, omgewingsveiligheid, statutêre vereistes, en verwysings na prosesmodellering en ʼn aantal tegno-ekonomiese studies uit die literatuur insluit.
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    Novel solid phase synthesis of a visible-light-active p-n heterojunction CuS/ZnS photocatalyst for wastewater treatment applications
    (University of Pretoria, 2023-12-21) Chirwa, Evans M.N.; Tichapondwa, Shepherd Masimba; rachel.mugumo@tuks.co.za; Mugumo, Rachel
    Water contamination by toxic organic chemicals is a major global environmental concern leading to photocatalytic technologies applied in wastewater treatment. The aim of this work was to investigate a new, simple one-pot combustion synthesis technique for creating sulphur- based CuS/ZnS p-n heterojunction nanocomposite photocatalysts. The study examined the photocatalytic activity and reusability of these nanocomposites in removing rhodamine B (RhB) dye from aqueous systems under visible light irradiation. Rhodamine B is an azo dye that is widely applied in processing operations such as the colouring process in textile industries which provides significant socioeconomic benefits; however, its minute traces in water antagonistically affect the environment and all life forms. In this study, a novel heterointerface strategy is proposed for synthesising p-n heterojunction nanoporous agglomerate nanocomposites. This approach involves a simple one-pot one-step combustion method to that attunes the morphology and band gap energy of visible-light-induced nanomaterials. Various characterisation techniques were employed to analyse the physicochemical properties of the synthesised nanocomposite materials. X-Ray Diffraction (XRD) was used to ascertain the crystallinity and purity of the synthesised materials, while X-Ray Fluorescence (XRF) was utilised to determine the composition of the photocatalyst. To confirm the morphology and elemental chemical composition of the synthesised materials, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), and Energy-Dispersive X-Ray Spectroscopy (EDS) were conducted. Braunauer-Emmett-Teller (BET) analysis was employed to measure the surface area and pore size distribution of the materials. Furthermore, the optical properties, including the photo absorption range and band gap energy of the synthesised nanocomposite materials, were determined using Ultraviolet-Visible spectroscopy (UV-vis). Several intrinsic reaction parameters affecting the photodegradation process were systematically varied to determine the optimal conditions, including the catalyst composition (CuS, ZnS, and CuS/ZnS), catalyst loading (ranging from 0 to 15 gL -1 ), initial solution pH (ranging from 1 to 13), and initial pollutant concentration (varying from 5 to 100 ppm). The experimental findings revealed that a binary CuS/ZnS catalyst, loaded at 10 gL -1 and with a pH of 5, achieved an impressive 97 % degradation of a 5 ppm RhB dye following 270 minutes of visible light exposure. These results highlighted the significant enhancement in photocatalytic degradation efficiency when pristine ZnS is coupled with highly photosensitive CuS. Specifically, the degradation efficiency improved from 67 % to 97 % within 4 hours of solar irradiation. Moreover, it is noteworthy that the Langmuir-Hinshelwood kinetic model demonstrated the best fit to the data when a loading of 10 gL -1 was employed, yielding an impressive R 2 value of 0.99 and a maximum rate constant (k max ) value of 0.0186 min -1 indicative of pseudo-first-order kinetics rates. Additionally, this composite catalyst exhibited remarkable chemical stability and reusability, as it achieved 83 % RhB dye removal after five recycling runs. Further investigations involving scavenger tests identified the photogenerated holes (h + ) and superoxide free radicals (•O 2 ) as the primary reactive species responsible for degradation process. This comprehensive study provides valuable insight into the design of highly efficient nanomaterials for removing organic pollutants from wastewater, and a possible reaction mechanism is proposed.
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    Microbial fuel cells : the effect of granular activated carbon and graphite as growth substrates on bioelectrogenesis by Geobacter sulfurreducens
    (University of Pretoria, 2019-12) Badenhorst, Heinrich; u29079498@tuks.co.za; Van Heerden, Xandra
    There is an increasing demand for environmentally sustainable alternative energy sources as the supply of fossil fuels dwindles and the concern about our carbon footprint continues to increase. Bioelectrogenesis is a process that directly converts biomass into electricity. Bioelectrochemical systems hold great potential to breach the gap into sustainable and green energy. Bioelectrochemical systems can be thought of as fuel cells with regenerative, living microbial catalysts. The aim of this investigation was to study the effect of the addition of carbon particles to the anodic chamber of a microbial fuel cell (MFC) containing Geobacter sulfurreducens in order to change the conditions of the MFC. The effect of the crystallinity of the carbon on the efficiency of the cell was evaluated. A crystalline carbon in the form of graphite particles was added to the initial growth media to increase the electrical conductivity of the anolyte. An amorphous carbon, granular activated carbon (GAC) particles, was added to the growth media to increase microbial growth. It was then decided which parameter needed to be prioritised if only one carbon substrate were to be added. A mixture of the two carbon substrates was added to the growth media to investigate what, if both the microbial growth and the conductivity in the MFC were increased, the effect would be on bioelectrogenesis. The effect of various growth periods of G. sulfurreducens prior to inoculation into the MFCs was also investigated. The experiments was thus limited to screening the effects of the bacteria growth media and growth time for the different carbon substrates and mixtures thereof. An increased growth period, 4 months, appeared to be more advantageous for bioelectrogenesis. The addition of GAC particles proved to be advantageous to the microbial growth as the growth was improved nearly 6 fold compared to the control MFC containing G. sulfurreducens only. FE-SEM imaging and BET analyses confirmed that a large and rough surface area is ideal due to the ample attachment sites available for microbes. The biofilm thickens after only 3 weeks of growth. It was evident that the addition of GAC particles to the system was beneficial for bioelectrogenesis. The maximum power density of the MFC containing GAC particles with a 4 months growth period was increased by 6 times compared to the MFC containing pure G. sulfurreducens. The average total energy generated by the MFC containing GAC particles was also 41 % higher than that of the pure G. sulfurreducens control MFC. The overall outputs were improved by the mere addition of GAC particles to the growth media. The addition of the graphite particles to the system had to the opposite effect. The microbial growth was inhibited, which directly caused the bioelectrogenesis to be extremely low. The average energy density of the graphite containing MFC is almost equal to the blank MFC, i.e., the MFC containing no microbial community. This suggests that growth must be prioritised over conductivity. Without microbial growth, increased conductivity does not help the system. The energy density of the MFC comprising the 1:1 mixture of graphite and GAC particles as growth substrate increased the average energy density of the control MFC by 134 %. The addition of the mixture of the two carbon substrates showed a synergistic effect since adding only pure GAC to the MFC increased the average energy density by 41 % compared to the control MFC, and by the addition of pure graphite particles to the MFC had the opposite effect of producing lower energy density than the control MFC. Therefore, mixing the two neat carbon sources and adding the mixture to the MFC, caused the synergistic effect of increasing the energy density of the MFC by more than triple than that of the MFC containing only pure GAC. With the mixture of GAC and graphite particles, both parameters were improved, i.e., microbial growth was improved compared with the control MFC and the conductivity in the system was increased, increasing the electron transfer efficiency and consequently the bioelectrogenesis. One of the industrial applications of MFC systems where the impact can be maximised, is in waste water treatment, since the outcomes include both power generation and the removal of organic compounds in waste streams. It is well documented that numerous microbial fuel cells generate power by oxidation of compounds in wastewater. One study predicts, assuming 100 % efficiency, that the wastewater from a town of 150 000 people could be used to generate approximately 2.3 MW of power; but realistically, a power of 0.5 MW can be expected. From this review it is mentioned that up to 80 % of the chemical oxygen demand (COD) of the wastewater can be removed by using an MFC and that the power generated could be used on site to power additional wastewater treatment. The second most promising application is the use of MFC systems in the biomedical industry as implantable devices. Currently most implanted biomedical devices are powered by batteries, which need to be recharged or replaced, necessitating additional surgeries for the patients. A method for continual electricity generation within the body would revolutionise biomedical devices. The use of MFCs as power sources for implantable devices in humans is a promising focus point. MFCs offer advantages over existing technologies such as lithium-ion batteries in implantable devices such as the heart pacemakers. The MFC would ideally use a biological metabolite fuel source (i.e. glucose or lactate) which is available in physiological fluids such as blood. It is unlikely that MFCs can replace the enzymatic glucose sensors that are currently used, but it was found that a well-designed MFC system, operating in a continuous flow regime, is implanted into the large intestines and utilises the natural flora of microbes within the intestines, could provide adequate power for cardiac pacing. This is one of the most promising future research areas. There are several variables that impact MFC power outputs, therefore extensive future research is still required. The one major problem that needs to be addressed is the longevity of many types of MFCs, most of which would currently be capable of meeting demands for biomedical devices implanted for short-term applications only.
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    Simultaneous pH and EC control in hydroponics through real-time manipulation of the ammonium-to-nitrate ratio in the nutrient solution
    (University of Pretoria, 2024-03) Nicol, Willem; Brink, Gideon Hendrik; u17306290@tuks.co.za; Bosman, Roger Clive
    A control algorithm was developed and tested on a hydroponic ebb-and-flow system to assess the efficacy of the proposed control scheme. Three experimental runs were conducted with the purpose of testing the proposed control system on Brassica oleracea var. acephala. The first was an ideal case under sterile conditions, the second was under non-sterile conditions where bacteria were allowed to colonise the plant roots, and the last was a baseline run where nitrate was applied as the only nitrogen source. The system was able to control pH to within 0.5 of the set point (in this case 6.1) while EC control was sufficient to ensure that a steady stream of nutrients were available to the plants at all times. Relative growth rates were fast at maximum average values of between 0.20 per day and 0.21 per day for all of the runs and the yield of organic leaf matter was essentially the same across all the runs at 83 % to 86 % of total plant mass. Finally, the plants grown under the proposed control system were observed to exhibit some improvement in protein and chlorophyll content while the other nutritional characteristics considered were essentially unchanged between treatments. This was all accomplished without having to add any additional toxic ions like Cl- and Na+ as is the case in conventionally controlled systems.
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    Inactivation of Critically Ranked Carbapenem Resistant Bacteria and Genes in a Batch Atmospheric Plasma Reactor.
    (University of Pretoria, 2023-12-31) Iwarere, Samuel A.; Daramola, Michael O.; Chedly, Tizaoui; Unuofin, John O.; u28094001@tuks.co.za; Mosaka, Thabang B.M.
    Wastewater treatment plants (WWTPs) have been observed to be direct key reservoir of both antibiotic resistant bacteria (ARBs) and antibiotic resistant genes (ARGs) associated with human infection as high concentrations of ARBs and ARGs have been detected in recycled hospital water. Among the ARBs, the carbapenem-resistant Acinetobacter baumannii and carbapenem-resistant Pseudomonas aeruginosa are ranked as priority 1 (critical) pathogens by the World Health Organisation (WHO) as they constitute a major threat to public health. Moreover, from the heuristic search of literature, it was observed that not only do conventional WWTPs fail to efficiently prevent the discharge of ARBs and ARGs into freshwater environments, but majority of extant advanced treatment technologies are also riddled with bottlenecks that oftentimes outweigh their proficiency. This has warranted the need for treatment technologies that have the capacity to completely obliterate pathogens (ARBs) as well as inactivate their resistance genes (ARGs). In this regard, this study investigated non-thermal plasma (NTP) technology as an alternative disinfection step to inactivate these bacteria and their ARGs. Culture based method and polymerase chain reaction (PCR) were employed in confirming the carbapenem resistance gene blaNDM-1 in Acinetobacter baumannii (BAA 1605) and Pseudomonas aeruginosa (27853). Suspensions of carbapenem-resistant Acinetobacter baumannii (24 h culture) and ATCC Pseudomonas aeruginosa (16 hr culture) were prepared from the confirmed isolates and were subjected to plasma treatment at varying time intervals (3 min, 6 min, 9 min, 12 min and 15 min) in triplicates. The plasma treated samples were evaluated for re-growth and the presence of the resistance gene. The treatment resulted in a 1.13 log reduction after 3 min and the highest ≥8 log reduction (i.e. 99.999999 %) after 15 min for Acinetobacter baumannii. For Pseudomonas aeruginosa, the treatment resulted in a 0.68 log reduction after 3 min and the highest ≥8 log reduction after 12 min. The concentration of the blaNDM-1 gene decreased with time, proving that NTP can inactivate ARGs. The log reduction and gel images suggest that plasma disinfection has a great potential to be an efficient tertiary treatment step for WWTPs. However, there are many factors that still need to be optimised, such as reaction time to completely inactivate the ARGs and removal of biofilms in the way of the treatment of ARBs such as Pseudomonas aeruginosa; before implementation is possible as this technology is yet gradually gaining commercial and industrial espousal.
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    Characterisation of fischer-tropsch wax/LLDPE blends
    (University of Pretoria, 2023-08-17) Focke, Walter Wilhelm; Ramjee, Shatish; u19409088@tuks.co.za; Mhlabeni, Thobile Lillian
    Wax is often used as a processing additive in polymer compounding, particularly in thermoplastic processing, due to its ability to improve processability. Wax acts as an external lubricant in the polymer melt, reducing the melt viscosity and increasing the melt flow rate. It’s addition, in masterbatching operations, facilitates improved dispersion of additives and fillers, as well as easier mixing and extrusion. Furthermore, the addition of wax to the polymer can reduce the processing temperature, leading to energy savings and reduced wear on processing equipment. However, the effectiveness of wax as a processing additive is strongly dependent on the type and amount of wax used, as well as the specific polymer being processed and its processing conditions. This study investigated the flow behaviour and compatibility characteristics of Fischer-Tropsch (F-T) wax blended with linear low-density polyethylene (LLDPE), for its possible application as a processing aid package for highly filled pigment masterbatches. The samples were prepared by melt blending using extrusion. The blends were prepared in predetermined quantities of the F-T wax and LLDPE in increments of 10 wt-%. This study provides a survey of characterisation methods and principles using rheology, differential scanning calorimetry (DSC), and hot stage polarised optical microscopy (POM). Both sample preparation and characterisation work were conducted in a temperature range of 120 – 180 °C. Rheological behaviour of the F-T wax/LLDPE blends were measured using the cone-and-plate configuration. The results showed that small additions of LLDPE to F-T wax increased the viscosity of the blend significantly. The composition dependence of the zero-shear melt-viscosity of the blends was adequately represented by the Friedman and Porter mixing rule with alpa = 3.4. This is equivalent to the expression in which the viscosity is calculated via the weight-average molecular mass of the mixture, i.e., ηo = KM^3.4. This implies that the zero-shear melt viscosity was dominated by polymer chain entanglement. The activation energy for viscous flow was found to be insensitive to blend composition. A linear relationship in all the Han plots, i.e., the plots of the logarithm of the storage modulus (G') against the logarithm of the loss modulus (G") was observed. Within the experimental uncertainty, they were essentially unaffected by variations in blend composition, temperature and the applied angular frequency. Additionally, the Cole-Cole plots supported the notion that the wax/LLDPE blends were miscible in the molten state. These results suggest full miscibility of the F-T wax/LLDPE blend system down to temperatures as low as 120 °C. The melting and crystallisation behaviour were studied using hot-stage optical microscopy and differential scanning calorimetry (DSC) in isothermal and dynamic modes. DSC results revealed significant LLDPE melting point depression increasing with increasing wax content. Optical microscopic monitoring of isothermal crystallisation, of the LLDPE phase, showed that adding wax decreased the size of the polymer spherulites. Beyond 50 wt-% wax, it was not possible to distinguish the spherulites at the magnification applied (25). Overall, it was found that increasing the wax content delayed the onset of crystallisation, decreased the overall crystallinity, and reduced the size of the crystallites of the LLDPE-rich phase. The results from both techniques were consistent with partial co-crystallisation of the two components. In summary, all the results indicate full miscibility of the wax and the LLDPE in the melt and partial co-crystallisation in the solid state. Furthermore, in the dynamic DSC scans, the near complete absence of a wax-like melting peak for the blend containing 10 wt-% wax suggests complete miscibility at that concentration.
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    Assessment of a continuous-flow atmospheric air dielectric barrier discharge in the degradation of tramadol, cefixime, and carbamazepine in aqueous solutions
    (University of Pretoria, 2024-02-26) Samuel, Iwarere; Michael, Daramola; samuelo.babalola@gmail.com; Babalola, Samuel Olatunde
    Active pharmaceutical contaminants which are constantly released into both surface and ground water through wastewater treatment plants (WWTP), run-off from agricultural fields, excretion, and disposal of unused or expired medicines into sewage, have become a global concern because of their effects on the aquatic ecosystem and human health. Several studies have examined the use of non-thermal plasma reactors like the dielectric barrier discharge (DBD) in the degradation of various pharmaceutical compounds with significant degradation and mineralization efficiencies. However, most studies are either conducted in batch mode with small solution volumes or in pure synthetic solutions. Also, the working gases have mostly been pure synthetic oxygen gases, which can increase the associated cost of treatment. In this study, the performance of a continuous-flow atmospheric air dielectric barrier discharge was assessed specifically for the degradation of tramadol, cefixime, and carbamazepine, which are among the commonly discovered pharmaceuticals in the water cycle. By selecting pharmaceutical contaminants from different drug classifications, this study aimed to show the efficacy of a DBD reactor in degrading a wide range of pharmaceutical residues, irrespective of their physicochemical properties. At alternating current (AC) voltage range of 6 – 8 kV and frequency of 20 kHz, 93% degradation of tramadol was observed in 60 min, >99% degradation of cefixime in 8 min, and 92% degradation of carbamazepine in 40 min. Also, the degradation efficiency of each pollutant was susceptible to the operation conditions of the DBD, including applied voltage, initial concentration of pollutant, pH, conductivity, water matrix, and water flow rate. The chemical species generated were investigated with a spectrometer while radical scavenging experiments were used to establish their respective roles in the degradation of the pollutants. Experiments conducted in real wastewater effluent confirmed that the presence of 𝐻����𝐶����𝑂����3− used as pH buffers played a scavenging role in the degradation of analgesic tramadol in the matrix as the ion reacted with hydroxyl radicals (•OH) thereby reducing its oxidizing power. Also, a toxicity test revealed that the plasma-treated tramadol solution was less toxic to Escherichia coli as opposed to the untreated solution. A new idea was investigated, which was to understand what happens when a metal ion catalyst (Fe2+) is mixed with •OH radical scavengers. In this case, the reactor was able to still achieve significant degradation of cefixime due to the increased production of H2O2 in the aqueous solution. The reactor’s performance was also compared with UV-systems for the degradation of carbamazepine at similar experimental conditions. The degradation results obtained in 40 mins were 6.5%, 17.8%, 89%, 91%, and 98% for UV-only, UV/Fe, UV/H2O2, UV/Fe/H2O2, and plasma systems, respectively. The plasma system also had the highest energy efficiency (75.24 kWh/m3) and the least required energy cost of treatment (13 USD/m3) compared to the UV-systems considered. Thus, an assessment of the laboratory-scale studies has demonstrated the feasibility of the novel continuous-flow atmospheric air dielectric barrier reactor in the degradation of tramadol, cefixime, and carbamazepine pollutants in mono-component solutions. This technology has shown potential for field-scale studies as it can be incorporated into existing wastewater treatment plants to degrade active pharmaceutical residues that escape the various treatment stages. However, considering that pharmaceutical pollutants always exist as mixtures and not as a single component in solution, future studies should consider the efficacy of the reactor in degrading a mixture of the pollutants in different water matrices, including real pharmaceutical waste samples.
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    Promoting circular economy and sustainable construction practices : investigating the integration of waste upcycling for a greener future, with a focus on eggshell and eggshell membrane utilization
    (University of Pretoria, 2023-09-20) Brink, Deon; ainasam000@gmail.com; Aina, Samuel Tomi
    As climate change continues to take the centre stage among issues of global discuss, carbon heavy industries including construction and agriculture continue to discover possible ways to foster the implementation of cleaner production technology as well as non-hazardous and sustainable waste disposal solutions. While previous studies have made commendable progress in proposing solutions, much more is still desired. A hybrid approach involving the principles of circular economy and material fusion by adsorption was employed on eggshells. Waste eggshells were valorised and up cycled with its major constituents finding effective use along the chain. This study examined the efficient separation of eggshells from its membrane, the recovery of valuable biochemical compounds and the optimized calcination of the bare shell to produce calcium oxide which is a viable cement replacement material. In addition, the adsorption kinetics of the shell membrane with silver nanoparticles and the effectiveness of the nanocomposite as a cytotoxic additive in cement mortar was investigated. The results demonstrated that in seventeen minutes, acetic acid efficiently weakened the bond between the shell and its semipermeable membrane while minimizing the dissolution of calcium and maximizing the leaching of valuable compounds and proteins like collagen. The calcined, leached, and separated shell produced calcium oxide of comparable quality to that derived from limestone during cement production. Further up the value chain, the separated membrane was employed as an adsorbent for silver nanoparticles and the antimicrobial property of the nanocomposite was exemplified on Pseudomonas aeruginosa and Bacillus subtilis. Pseudo-first order, Pseudo-second order, Two-phase adsorption, Crank internal mass transfer model, and Weber and Morris (W&M) kinetic models were employed to further understand the adsorption process. All the models were adequately fitted with R2 values ranging from 0.922 to 0.990 for both AgNPs and AgNO3. Both Langmuir and Freundlich Isotherm models were also fitted. The adsorption process was optimum at a pH of 6, 25 ◦C, and after 48 h of agitation. Compared to previous studies, a remarkable antimicrobial activity against Pseudomonas aeruginosa and Bacillus subtilis was exhibited resulting in 27.77% and 15.34% cell death, respectively. Analysis of variance and Tukey multiple comparison statistical tests were carried out to highlight the significance of the cell inhibition results at P<0.05 and 95% confidence level. B. subtilis exhibited significant tolerance to metabolic inhibition while P. aeruginosa was significantly inhibited. Following this impressive outcome, the cytotoxic property of the nanocomposite was tested in concrete mortar. This is to combat the ever-increasing nfrastructure budget relating to the maintenance of concrete structures damaged by microbial attacks in moist environments. Waste activated sludge obtained from a local domestic wastewater treatment plant, Pseudomonas aeruginosa, and Bacillus subtilis were studied in both aerobic and anaerobic conditions. Waste activated sludge was most susceptible to the nanocomposite with up to 50% cell death recorded for a 2% cement replacement. In contrast, Pseudomonas aeruginosa and Bacillus subtilis experienced a maximum of 9% and 5% cell death, respectively. For the same cement replacement approximately 5% reduction in compressive strength and no significant change in Tensile strength were measured. This minimal loss in compressive strength is negligible compared to be antimicrobial benefits. Furthermore, considering that about 8.7 million metric tons of eggshell was produced globally in 2021, this alternative use of the shell and its membrane is of great importance to the environment. This include reduction in needed landfill, cost saving and reduction in the generation of GHGs. This study presents a multifaceted approach to the valorisation of waste eggshells, demonstrating their potential as a valuable resource in addressing environmental and industrial challenges. This research underscores the importance of exploring innovative solutions that not only reduce waste but also contribute to the development of cleaner and more sustainable practices in various industries. As we continue to grapple with the pressing issues of climate change and resource conservation, such initiatives pave the way for a more environmentally responsible and economically viable future. This specific upcycling of eggshell and its membrane is of particular economic importance. To start with, the cost associated with managing over 8 million tons of eggshell waste could be invested in more profiting ventures. Through the valorisation process, the shell membrane and other biochemical compounds recovered are valuable sources of income due to the high demand of some of these substances, e.g., collagen. Also, against the backdrop of escalating infrastructure budgets worldwide, employing eggshell membrane as an antimicrobial additive in concrete could result in up to 40% savings in maintenance cost. To achieve these benefits however, it is paramount for the construction and waste industry to start looking into the possible challenges. These include collection, logistics, large scale implementation and more. Likewise, new policies surrounding waste disposal and reusage need to be implemented. Finally, new standards and safety regulations need to be developed while critically exploring and understanding the limitations of waste composites in concrete. In conclusion, this research demonstrates novelty by proposing an optimised eggshell calcination process by ensuring the recovery of the shell membrane and valuable biochemical compounds such as collagen prior to calcination. This will not only ensure the production of high-grade calcium oxide but will also in turn upcycle the net worth of eggshells. Secondly, the study proposes a novel ESM/Nanosilver antimicrobial composite through adsorption. This research also aims to enhance the adsorption efficiency of chemically produced AgNPs and AgNO3 by utilizing the eggshell membrane optimally separated from the shells. Thirdly, this research incorporated the antimicrobial ESM/Ag nanocomposite into cement mortar with the aim of producing an antimicrobial mortar. Lastly, this study demonstrated innovative contribution to academia through 5 publications and 6 conference presentations.
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    Performance measures of an active, small scale solar basin still in terms of production cost an energy efficiency
    (University of Pretoria, 2024-01-31) Sonnendecker, Paul Walter; aduawukuek@gmail.com; Adu-Awuku, Emmanuel
    The research investigated the characterisation of a cost-effective active solar still by implementing active solar still recommendations suggested by Marais (2018) and external condenser design improvements identified in the research work. Marais’ (2018) still variation 3 was used to design a solar still to improve still productivity performance: • By using an external condenser that will reduce the available condensation area and drive condensation away from the cover surface. • By using active fluid flow to circulate humid air and, or water through the solar still. • By reducing energy losses of the cover surface and energy accumulation of the back wall.
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    Empirical modelling in non-linear predictive control : a coffee roaster application
    (University of Pretoria, 2023-12-12) de Vaal, Philip L.; u17031096@tuks.co.za; Bolt, Cameron E.
    This dissertation presents the development and implementation of a model predictive control (MPC) system for a coffee roasting process, to optimise roasting quality while minimising energy consumption. The study involved analysing historical temperature profile data and roaster inputs to develop a hybrid model, combining empirical and first principles techniques, which predicts the measured bean temperature as a function of the available roaster inputs. The combination of the first-principles model with empirical modelling techniques reduced validation data error by increasing measured temperature prediction accuracy. Subsequently, a nonlinear MPC was designed and tuned through a series of simulations, adjusting prediction and control horizons while limiting input changes relative to the real-time input value. The optimal configuration achieved a sig nificant reduction in the average usage of liquefied petroleum gas (LPG) while maintaining a wide input range. The impact of the intelligent modelling and control system on the reduction of raw material waste, the improvement of the quality of the final product, and the overall efficiency of the roasting process was evaluated, showing significant improvements in all three areas. The proposed system enables operators to perform simulations of roasts and reduce raw material wastage when developing roast profiles, providing a valuable contribution to the coffee roasting industry. Future work includes further investigation of hybrid modelling and nonlinear optimisation techniques.
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    Dried Xanthan Gum/Nanocellulose for Thermoplastic Starch Reinforcement
    (University of Pretoria, 2024-02-05) Focke, Walter Wilhelm; du Toit, Elizabeth Louisa; u18076272@tuks.co.za; Hoek, Zian
    Nanocellulose fibres are known to enhance the mechanical properties of biopolymers by acting as a reinforcing additive. However, the formation of irreversible hydrogen bonds and subsequent agglomeration upon drying means that nanocellulose is commercially only available as an aqueous suspension containing in excess of 75 % water. This not only increases transportation costs, rendering its use financially unsustainable but also limits its applicability in hydrophobic polymers. Therefore, it is crucial to produce dried and redispersible nanocellulose that retains its properties as a polymer filler to fully realise its potential in this field. In this work, the hydrocolloid, xanthan gum, proved to effectively prevent nanocellulose hornification when added to aqueous suspensions at levels as low as 15 % — based on the mass of nanocellulose — prior to drying. This was confirmed by several complementary techniques including rheology, turbidimetry, SEM- and TEM-imaging, as well as colloidal stability analyses. When xanthan gum and nanocellulose were incorporated into thermoplastic starch, a synergistic effect between the two additive materials on the tensile strength of the resultant biopolymer films was evident. The addition of previously dried nanocellulose/xanthan, in a 4:1 ratio, to thermoplastic starch at a starch-cellulose ratio of 20:1, increased the tensile strength from 5.4 MPa to 23.0 MPa. This confirmed that xanthan gum as a nanocellulose capping agent has the potential to enhance its usefulness as a biopolymer additive.
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    Aerobic polishing of liquid digestate for the preparation of hydroponic fertiliser
    (University of Pretoria, 2024-01-29) Nicol, Willie; Brink, Hendrik Gideon; Mathe, Lebani Oarabile Joy
    Nitrogen and phosphorus form the backbone of most lifeforms on earth, however, improper management of these nutrients has devastating effects on the environment. These effects can be lessened by the use of the anaerobic digestion process, which provides methane-rich biogas and nitrogen-rich liquid biofertiliser. The use of liquid digestate (LD) in hydroponics can be problematic given that these systems are prone to microbial contamination. Thus, minimising the organic carbon present in the digestate before nitrification would make it ideal for hydroponic use. By investigating the effect of pH on the use of a biological aerobic polishing unit for the removal of organic carbon with the retention of nitrogen and, to some extent phosphorus, the repeat-batch experiments displayed high levels of organic carbon removal at all investigated pH values (6, 7, and 8). Although ammonium losses were observed at pH 6 and 7, at pH 8, approximately 27% of the ammonium was recovered. Comparatively, the continuous process, wherein different three hydraulic retention times were investigated, performed better than the repeat-batch experiments as the TOC in the effluent was <100 mg L−1 which accounts for 90% of TOC removal from the LD. In this process, approximately 53% of the ammonium was recovered with the ammonium concentration in the polished product being >220 mg L−1 with the continuous addition of digestate. Excluding the nitrate, the nitrogen content in the polished product surpasses that of a standard Hoagland medium (≈ 210 mg L−1). Findings from the metagenomic analysis of the biofilm indicate that a large fraction of the bacteria present in the biofilm are heterotrophic, hence the rapid decrease in TOC. The presence of other microorganisms responsible for the rapid uptake of phosphorus (Gemmatimonas spp.), nitrate assimilation (Aquamicrobium spp.) and nitrogen acquisition (Luteimonas spp.) are also documented in the findings. The combined effect of these microorganisms is the driving force behind the rapid carbon removal and nitrogen recovery seen in the findings. This study provides a novel approach to the preparation of liquid digestate for hydroponic systems, which is not only more efficient but also minimises the risk of contamination in downstream processes, which will ultimately improve crop yield and quality. Although phosphate losses were observed throughout all experiments, the phosphate levels can be supplemented prior to hydroponic use. The continuous process provides a greater deal of nutrient recovery, while simultaneously converting a large fraction of the organic carbon present in the liquid digestate and is the suitable method for the implementation of a circular economy.
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    Plantwide control of an SO2 abatement plant
    (University of Pretoria, 2023) De Vaal, Philip L.; Brooks, Kevin; minet.uys@tuks.co.za; Crafford, Minèt
    This study focused on an SO2 abatement plant for a platinum group metal (PGM) smelting electric furnace. A systematic approach, using a simulated model of the plant, was followed to investigate plantwide control measures and thereby refine the plant's control philosophy. A steady-state model of a Wet gas Sulfuric Acid plant was developed using Aspen HYSYS software. The model was converted to a dynamic model to enable the evaluation of interactions within the process. This dynamic model was used while implementing a top-down, bottom-up plantwide control procedure. The results produced a control structure by which the first converter’s inlet temperature controls the final SO2 concentration. The feed gas heater’s (second heater in the system) outlet temperature is controlled by varying the steam flow rate, which is used as a means of disturbance rejection. Furthermore, using a dynamic model to implement a systematic plantwide control procedure eliminates the need to develop complex mathematical models while providing the opportunity to continuously validate the decisions made and selected manipulated and controlled variable pairings. Additional benefits of using a dynamic simulation model to implement a plantwide control model are: • It provides a link between steady-state optimisation and process control. • Self-optimising control is considered. • Improved understanding of the process and interactions in the process. • Provides a base model with the possibility to apply the solution to similar plants with minimal adjustment. • The opportunity of implementing dynamic matric control or model predictive control models to live plants (software dependent). • Constant consideration of the control and operation of the plant as well as the overall (plantwide) control objective.
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    Nickel Ferrite/Polyaniline Nanocomposite doped with 2-Naphthalene sulfonic acid as aqueous chromium adsorbent
    (University of Pretoria, 2023) Brink, Hendrik Gideon; Madhumita, Bhaumik; u15288057@tuks.co.za; Kasavo, Ruth Nzisi
    Chromium is one of the most toxic heavy metals found in many industrial effluents due to its ability to easily enter the human body and cause serious health problems. In this study, the ability of a nanocomposite of nickel ferrite and polyaniline doped with 2-naphthalene sulfonic acid (PANINSA/NiFe2O4) to remove chromium (Cr (VI)) from synthetic wastewater was studied. The doping of the material with 2-NSA leads to the formation of tubular-shaped rods which increases the surface area of the material. Adsorption parameters such as solution pH, dosage of adsorbent, time of agitation, and initial concentration of pollutant were studied and optimized. The adsorption was highly dependent on solution pH with a maximum adsorption observed at pH 2. The results revealed a maximum removal of 99.9% from 50 mg/L Cr (VI) solution for a catalyst loading of 1 g/L. Freundlich, Langmuir and Two-Surface Langmuir non-linear isotherm models were fitted to the data. Kinetics studies revealed a fast adsorption process in the first 30 minutes followed by slower adsorption with maximum Cr (VI) removal achieved within 24 hours. The Two-Surface Langmuir model best described the isotherm data from the experiment. The effect of the temperature study revealed that the adsorption capacity for the Cr (VI) increased with an increase in temperature with the maximum adsorption capacity (420 mg/g) observed at 45 °C. The calculated thermodynamic parameters revealed endothermic and spontaneous adsorption process. The Cr (VI) removal mechanism was by electrostatic attraction, reduction, and surface complexation. The reusability studies showed that PANI-NSA/NiF𝑒��2O4 could be used for 5 cycles with a 99 % Cr (VI)removal from 50 mL solution containing 50 mg/L Cr (VI)in the first 2 cycles This study demonstrated that PANI-NSA/NiFe2O4 has a potential in the industrial application for removal of Cr (VI).
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    Comparative screening study on the adsorption of Aqueous Pb(II) using different metabolically inhibited bacterial cultures from industry
    (University of Pretoria, 2023) Brink, Hendrik Gideon; Chirwa, Evans M.N.; u21798894@tuks.co.za; Kpai, Yawo Patrick
    The current study aimed at investigating the bioremediation removal effectiveness of Pb(II) by metabolically inhibited microbial cultures: a) Waste activated sewage sludge obtained from a local wastewater treatment plant (SS), commercially sourced industrial bioremediation microbes b) bran-based filler with bacteria (BB), and c) salt-and-starch based filler with bacteria (S&S), d) an industrially obtained Pb(II) remediating consortium (Cons), and purified strains of e) Paraclostridium bifermentans (PB), and f) Klebsiella pneumoniae (KP) isolated from the consortium. The study’s focus was specifically targeted towards operational analysis. This study demonstrated that the metabolically inactive SS, BB, S&S, Cons, PB, and KP bacteria adsorbed 55.4 mg/g, 54.6 mg/g, 50.6 mg/g, 54.4 mg/g, 27.4 mg/g, and 23.1 mg/g of Pb(II) within 3 h, respectively. In addition, maximum adsorption capacities of 141.2 mg/g, 208.5 mg/g, 193.8 mg/g, 220.4 mg/g, 153.2 mg/g, and 217.7 mg/g were measured respectively. FTIR spectroscopy supported the chemisorption of Pb(II) onto functional groups as being responsible for this removal. Two-phase pseudo-first-order kinetics fits best described the adsorption kinetics of the adsorbents which might be as a result of the separation of fast and slow adsorption rates into separate compartments, thereby allowing for better representation of a heterogeneous surface. The Crank mass transfer model shows that external mass transfer is the main mechanism of Pb(II) removal due to the high molecular diffusivity of Pb(II) as compared to the effective diffusion coefficients of the metabolically inhibited adsorbents. The equilibrium isotherm was well described by two-surface Langmuir equilibrium isotherm model likely due to different adsorption sites with different adsorption energies which allows a comparably better description of the adsorption. The morphology of the adsorbents showed that the surface of the metabolically inhibited adsorbents was rough, coarse, with observable pores, and irregular iii crevices. The results from the EDS analyses indicated the presence of Pb on the surface of the metabolically inhibited adsorbents confirming the adsorbents were able to remove Pb(II) from the aqueous systems. Recovery of Pb(II) from the biosorbents were further tested and showed 72.4 %, 68.6 %, 69.7 %, 69.6 %, 61.0 %, and 72.4 % for the SS, BB, S&S, Cons, PB, and KP bacteria, respectively. The results demonstrate the remarkable potential of these low cost, self- generating biosorbents for the treatment of Pb(II) contaminated aqueous streams.
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    The effect of pH control on ammonium release in anaerobic digestion
    (University of Pretoria, 2023) Nicol, Willie; Brink, Hendrik Gideon; u17046832@tuks.co.za; Gonde, Lonestar
    Anaerobic digestion is a process whereby microorganisms break down waste material into simpler compounds, while simultaneously producing biogas that is generally high in methane and carbon dioxide content (60 –70 % and 30 –40 %, respectively) and a nutrient-rich by-product called the digestate. The energy potential of this process cannot be overstated; it is estimated that a feed of one ton of biowaste generally translates to an electricity yield of 250 kWh. However, the digestate is a typically overlooked by-product in anaerobic digestion studies due to a fixation on the energy-dense biogas product. The digestate can be in either liquid or solid form, this study focused on the liquid digestate. The liquid digestate is generally high in valuable nutrients like nitrogen, potassium, and phosphorus which are essential for plant growth. This indicates that the liquid digestate can be an effective fertiliser. Currently, farmers habitually apply digestate on farmlands because of its high macronutrient concentration. However, an underexplored avenue is the use of liquid digestate as an organic fertiliser for soilless agriculture. Although soilless agriculture provides a multitude of advantages over conventional agriculture, such as providing better nutrient distribution while also saving on both land and water, it is still dependant on harmful mineral fertilisers. Given the major growth occurring in the soilless agriculture sector and the need for more sustainable fertilisation strategies in food production processes, liquid digestate has been promoted to a more prominent stream in the circular production of human nutrition. In this regard, it is important to understand the rate and extent of fertiliser production in anaerobic digestion process. In this study, the pH of the anaerobic digestion process was controlled at three different set points (6, 7, and 8) for three different substrates (banana peels, cow dung, and red lentils) in order to determine the ammonium release characteristics at each set point. This was achieved by using two different set-ups; One system employed a daily pH adjustment (Daily dosing system or DDS) while the other system (Continuous Dosing Set-up or CDS) employed pH corrections every minute. The results indicated that a pH of 7 is the optimal set point for both ammonium release as well as the gas production rate. This pH value provided average percentage differences of 20 % and 22 % in terms of ammonium release and gas production when compared to the runs that were performed without pH control. In terms of a comparative analysis between precise pH control, that was performed every minute and pH control that was performed once a day, there were differences present i in the gas production profiles, with the CDS providing enhanced rates compared to the DDS. The CDS provided an average percentage increase of 50 % compared to the DDS in terms of gas production. However, there was a negligible difference in the ammonium release rate.
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    Combustion performance of self-assembly ternary pyrotechnic time-delay compositions
    (University of Pretoria, 2022-12) Focke, Walter Wilhelm; Tichapondwa, Shepherd Masimba; shashaguosara@gmail.com; Guo, Shasha
    Pyrotechnic compositions are usually employed in time delay detonators to facilitate controlled initiation of explosive charges in mining and quarrying operations. Traditional fast and slow-burning formulations are problematic, as they contain heavy metals which are bio-accumulative and toxic to the environment. Thermite and intermetallic reactions offer the possibility of greener alternatives. Unfortunately, the high reaction temperatures associated with conventional thermites cause operational failures due to melting of the metal housings. Similarly, it is difficult to achieve sustained burning with intermetallic systems alone. This study investigated the use of a combination thermite and intermetallic-type reactions, produced using environmentally benign materials to achieve both slow and fast-burning effects while overcoming the aforementioned limitations.