Environmental management options for pulverised fuel ash (PFA)

Ip, Mei-fong, Phyllis., 葉美芳.

January 1994

published_or_final_version / Environmental Management / Master / Master of Science in Environmental Management

Fly ash - Environmental aspects.

Performance of zeolite ZSM-5 synthesised from South African fly ash in the conversion of methanol to hydrocarbons

Folifac, Leo

January 2018

Thesis (Master of Engineering in Chemical Engineering)--Cape Peninsula University of Technology, 2018. / Zeolites have found applications as heterogeneous or solid catalyst in the petrochemical and refining industries. Zeolite ZSM-5 in particular is a highly siliceous solid catalyst with a porous network that consists of medium pore structure (pore openings 5-5.5 A). The solid catalyst (ZSM-5) is well known for its high temperature stability and strong acidity, which makes it an established catalyst used for different petrochemical processes such as Methanol-To-Gasoline (MTG), isomerisation, disproportionation, and cracking. Unlike in the past, the synthesis of zeolite ZSM-5 from other sources that contains silica (Si) and alumina (Al) with the addition of a template (TPBr) as a structure-directing agent is eminent. Its synthesis can be achievable from coal fly ash that is a waste material and a cheap source of Si and Al. Coal fly ash is a waste material that is produced during the combustion of coal to generate electricity. The elemental composition of coal fly ash consists of mostly SiO2 and Al2O3 together with other significant and trace elements. Zeolite ZSM-5 catalyst synthesised from coal fly ash by previous authors required an excessive amount of additional source of silica even though the XRD spectra still show the presence of quartz and mullite phase in the final products. These phases prevented the use of fly ash (solid) as a precursor to synthesise zeolite ZSM-5 products. However, the synthesis of high purity zeolite ZSM-5 products by extracting silica and alumina from South African fly ash and then using it with small amounts of fumed silica was investigated This aim was achieved by fusing fly ash (FA) with sodium hydroxide (NaOH) under hydrothermal condition set at 550 oC for 1 hour 30 minutes. The quartz and mullite phase observed by previous authors was digested by the fusion process. Thereafter, the treatment of fused fly ash filtrate (FFAF) with concentrated H2SO4 (98-99%), precipitated silica and removed Al that therefore increased the Si/Al ratio from 1.97 in fly ash (FA) to 9.5 in the silica extract (named fused fly ash extract). This route was designed to improve the quality of the final products and reduced the amount of fumed silica added to the synthesis mixture prior to hydrothermal synthesis. In this line of investigation, the process of adding fumed silica to the hydrothermal gel was optimised. H-FF1 with a Si/Al ratio of 9.5 was synthesised using the silica extract without the addition of fumed silica. Its XRD, SEM and relative crystallinity results proved that H-FF1 was inactive and hence was not further characterised and utilised in the conversion of methanol to hydrocarbons (MTH). Purer phase zeolite ZSM-5 products (H-FF2 and H-FF3) that were synthesised from silica extract with the addition of small amounts of fumed silica were characterised and successfully used in the methanol to hydrocarbons (MTH) reaction. The synthesised ZSM-5 products had different Si/Al ratio, different morphology, crystal size, BET surface area, and relative crystallinity as well as different trends in the MTH reaction. It was also observed that H-FF2 and H-FF3 (pure phase) solid catalyst deactivated faster than the commercial H-ZSM-5 in the MTH reaction. However, the MTH conversion over H-FF2 competed with that of the commercial H-ZSM-5 within 3 hours of time on stream (TOS) but later deactivated at a faster rate. This was caused by the large crystal size and reduced BET surface area of H-FF2 when compared to the commercial H-ZSM-5. However, H-FF2 performed better than H-FF3 on stream (MTH reaction) due to its smaller crystal size and higher BET. This study has successfully utilised a route that synthesised high purity zeolite ZSM-5 products from the South African fused fly ash extract (FFAE) with the addition of small amounts of fumed silica. The properties of the synthesised zeolite ZSM-5 products (H-FF2 and H-FF3) were similar to that of the commercial H-ZSM-5 as well as active in the MTH reaction. This promoted the utilisation of a waste material (coal fly ash) to synthesise highly siliceous zeolite ZSM-5 products that avoided the presence of mineral phases from fly ash in the final products.

Zeolite catalysts

Zeolites -- Synthesis

Fly ash

Fly ash -- Recycling

Zeolites -- Industrial applications

Women's experiences, social support and adapting to the offshore lifestyle : my life, my house, my bed..., not my life, shared house, shared bed, shared..., to get yourself back into sharing, because it takes a bit to work out the two

watsone@iinet.net.au, Jacinth Ann Watson

January 2008

In the past two decades the growth of the offshore oil and gas industry of Western Australia has resulted in an increased number of families experiencing the intermittent absence of a partner/parent. The gendered nature of the offshore oil and gas industry means workers tend to be male and the partner left at home tends to be female. This was the case for the participants in this study. For two/three weeks the family experience the absence of the male 'breadwinner', creating a gap within the family as the women and children experiences the loss of the partner/parent. Two/three weeks later the male worker returns home for his rest period and he reengages in his roles and the family is reunited. When the worker is absent the partner at home takes on the worker's gendered roles, tasks and responsibilities; upon his return she surrenders (sometimes willingly) his gendered roles, tasks and responsibilities. Solheim (1988) state families of offshore oil and gas workers experience three social realities; his life at work, her 'single' life when he is at work, and their couple life when the worker arrives home. The families can develop a range of methods to adjust to the flux that occurs within families due to the work schedule (Forsyth and Gramling 1989). The repeated cyclical patterns of parting and reunion, weaving and balancing their three lives, and renegotiation of family work contribute to the stressors and strains the partners of offshore workers experience. This study investigated how the offshore lifestyle impacts the at home partner of offshore workers and in addition, how at home partners use their social networks as means to help adapt to the offshore work schedule, and makes two major findings. Firstly, the at home partners of offshore workers participate in exchanging, at various levels, social support with family, friends and neighbours, although the most important form of support which helps the at home partner adapt to the offshore lifestyle is the support they receive from the offshore worker. Secondly, adapting to the offshore lifestyle is highly influenced by a process consisting of four reactions. The reactions are: the beginning; normalising his presence; normalising his absence; and balancing two lives. The identification of the four reactions can provide a greater understanding of how the offshore oil and gas industry impacts on the daily lives of partners of offshore workers as it helps make visible the day-to-day lives of partners of offshore oil and gas workers.

Work and family

Job stress

Shift systems

Fly in/Fly out

families

adapting to FIFO lifestyle

social support

Effect of fly ash particles on the mechanical properties and microstructure of aluminium casting alloy A535

Gikunoo, Emmanuel

08 December 2004

Fly ash is a lightweight coal combustion by-product (CCB) separated from the exhaust gases of power generating plants using suspension-fired furnaces in which pulverized coal is used as the fuel. Its physical and chemical properties make it useful in construction and industrial materials, especially in cement manufacturing, concrete, liquid waste stabilization, and hydraulic mine backfill. The addition of fly ash into aluminum alloys has the potential to reduce the cost and density of aluminum castings while improving other physical and mechanical properties of the resulting metal matrix composites (MMCs). <p> This study investigated the effect of fly ash addition on the mechanical properties and microstructural behaviour of aluminum casting alloy A535. The unreinforced A535 alloy and its MMCs containing a mixture of 5 wt.% fly ash and 5 wt.% silicon carbide, 10 wt.% fly ash and 15 wt.% fly ash were investigated in the as-cast and solution heat treated conditions. Microhardness measurements, Charpy impact testing, tensile testing, optical microscopy, scanning electron microscopy (SEM), energy dispersive X-ray spectrometry (EDS), inductively coupled plasma/mass spectrometry (ICP/MS), X-ray diffractometry (XRD), and X-ray fluorescence spectroscopy (XRF) were used to evaluate these effects. <p> The results of this study show that increasing the fly ash content of the melt increased the porosity of the castings, which ultimately affected the density, tensile and impact properties of the MMCs. The density, microhardness, tensile strength and Charpy impact energy of the composites decreased with increasing fly ash content. The decline in density of the MMCs was due to extensive porosity developed with fly ash addition. Depletion of solid solution strengthening magnesium in the matrix was the reason observed for the decline in hardness. The loss in Charpy impact energy and tensile properties of the MMCs are also attributed partly to the depletion of solid solution strengthening magnesium atoms from the matrix and partly to porosity. <p> Microstructural studies revealed non-uniform distribution of reinforcement particles in the composites. The fly ash particles were found to congregate at the boundaries of a-aluminium dendrites in the castings. Mg content of A535 alloy decreased with increasing weight fraction of fly ash. Mg was found to be tied up in a complex network of Mg2Si thereby reducing its availability in the matrix for solid solution strengthening.

Aluminium Casting Alloy A535

Fly Ash-Reinforced Aluminium Composites

Fly Ash

Effect of fly ash particles on the mechanical properties and microstructure of aluminium casting alloy A535

Gikunoo, Emmanuel

08 December 2004

Fly ash is a lightweight coal combustion by-product (CCB) separated from the exhaust gases of power generating plants using suspension-fired furnaces in which pulverized coal is used as the fuel. Its physical and chemical properties make it useful in construction and industrial materials, especially in cement manufacturing, concrete, liquid waste stabilization, and hydraulic mine backfill. The addition of fly ash into aluminum alloys has the potential to reduce the cost and density of aluminum castings while improving other physical and mechanical properties of the resulting metal matrix composites (MMCs). <p> This study investigated the effect of fly ash addition on the mechanical properties and microstructural behaviour of aluminum casting alloy A535. The unreinforced A535 alloy and its MMCs containing a mixture of 5 wt.% fly ash and 5 wt.% silicon carbide, 10 wt.% fly ash and 15 wt.% fly ash were investigated in the as-cast and solution heat treated conditions. Microhardness measurements, Charpy impact testing, tensile testing, optical microscopy, scanning electron microscopy (SEM), energy dispersive X-ray spectrometry (EDS), inductively coupled plasma/mass spectrometry (ICP/MS), X-ray diffractometry (XRD), and X-ray fluorescence spectroscopy (XRF) were used to evaluate these effects. <p> The results of this study show that increasing the fly ash content of the melt increased the porosity of the castings, which ultimately affected the density, tensile and impact properties of the MMCs. The density, microhardness, tensile strength and Charpy impact energy of the composites decreased with increasing fly ash content. The decline in density of the MMCs was due to extensive porosity developed with fly ash addition. Depletion of solid solution strengthening magnesium in the matrix was the reason observed for the decline in hardness. The loss in Charpy impact energy and tensile properties of the MMCs are also attributed partly to the depletion of solid solution strengthening magnesium atoms from the matrix and partly to porosity. <p> Microstructural studies revealed non-uniform distribution of reinforcement particles in the composites. The fly ash particles were found to congregate at the boundaries of a-aluminium dendrites in the castings. Mg content of A535 alloy decreased with increasing weight fraction of fly ash. Mg was found to be tied up in a complex network of Mg2Si thereby reducing its availability in the matrix for solid solution strengthening.

Aluminium Casting Alloy A535

Fly Ash-Reinforced Aluminium Composites

Fly Ash

Soil genesis and vegetation growth in pulverized fuel ash and refuse landfills capped by decomposed granite /

Ngai, Yuen-yi, Helen.

January 1998

Thesis (M. Phil.)--University of Hong Kong, 1998. / Includes bibliographical references (leaves 222-238).

Studies on Flexural Behaviour of Fly Ash-Lime-Gypsum Brick Masonry

Gourav, K

January 2015

Varieties of masonry units such as burnt clay bricks, stones and concrete products are used for masonry construction. Even though these materials are durable, they are considered as unsustainable options because of the issues concerning energy, environment and conservation of natural resources. The walling materials are consumed in bulk quantities and hence large quantities of natural resources are depleted. There is a need for energy efficient and environment friendly alternative materials for masonry. Fly ash is an industrial by-product from the coal based thermal power plants which can be exploited for manufacturing of masonry units such as fly ash blocks/bricks, which are an alternative for conventional masonry units. Fly ash-Lime-Gypsum (FaL-G) bricks can be manufactured by compaction of a mixture of fly ash-lime-gypsum and water. The behaviour of FaL-G brick masonry is inadequately explored area and hence the thesis is focused on understanding the flexural behaviour of FaL-G brick masonry and bond development phenomenon at FaL-G brick-mortar interface. A brief introduction to the fly ash-based masonry units and literature review with respect to utilizing fly ash in manufacturing masonry units are presented. Characteristics of raw materials used and the procedure followed in casting of masonry units/compacts, mortar and their assemblages including testing methods have been discussed. Characteristics of FaL-G brick, mortars, FaL-G brick masonry are presented. Apart from determining the stress-strain relationships for these materials shear strength parameters of FaL-G compact, mortar and brick-mortar joint were determined. Mohr-Coulomb failure envelopes for FaL-G compact and mortar are presented. The mechanism of bond development in masonry is discussed. FaL-G brick masonry shows considerably higher bond strength when compared with the bond strength of conventional brick masonry. Results of micro-structure analysis (SEM, XRD and TGA) of the FaL-G brick-mortar interfaces confirm the formation of chemical bond in addition to mechanical interlocking of cement hydration products into brick pores. Flexural behaviour of FaL-G brick masonry wallettes in the two orthogonal directions was studied. The flexural strength, displacement profiles and load-displacement curves were determined, and moment-curvature relationships were established. Linear elastic analysis performed closely predicted the cracking flexural stress in FaL-G brick masonry. A brief introduction to the computational modelling of masonry using different approaches has been presented. Literature review with respect to simplified micro-modelling approach has been discussed. The flexural behaviour of FaL-G brick masonry panels under lateral loads was predicted using a non-linear 3D finite element analysis. The finite element model reasonably predicted the flexural behaviour of FaL-G brick masonry panels. The thesis ends with summary of research work with a note on scope for further research.

FaL-G Brick

Fly Ash

FaL-G Brick Masonry

Fly ash-lime-gypsum Bricks

Civil Engineering

Role of muscoid flies in the ecology of shiga toxin-producing Escherichia coli (STEC) in confined cattle environments

Puri Giri, Rukmini

January 1900

Master of Science / Entomology / Ludek Zurek / House flies (Musca domestica L.) and stable flies (Stomoxys calcitrans L.) are insects of medical and veterinary importance. House flies are recognized as mechanical vectors of human foodborne pathogens and stable files are known for their painful bites resulting in reduction of body weight gain and milk production in cattle. The larval development of both fly species takes place in decaying organic materials (primarily animal manure), resulting in large fly populations in confined cattle environments. Shiga toxin-producing Escherichia coli (STEC) are a major foodborne pathogen. Cattle are the asymptomatic reservoir of STEC with bacteria being released to the environment via their feces. STEC O157 is the main serogroup causing human illness. However, infections with non-O157 STEC are increasing: more than 70% of non-O157 infections are caused by six serogroups of non-O157, referred as "Big six" (O26, O45, O103, O111, O121, and O145). In addition, there was a large 2011 outbreak in Europe caused by STEC O104. The objectives of my thesis were: 1) To assess the prevalence of seven serogroups of non-O157 STEC (O26, O45, O103, O104, O111, O121, and O145) (STEC-7) in house flies and stable flies collected from confined cattle environments; 2) To investigate the vector competence of house flies for non-O157 STEC-7. A total of 463 house flies from feedlots and dairies from six states, and 180 stable flies collected from a feedlot in Nebraska were processed for the isolation and identification of STEC-7 using a culture-based approach followed by PCR for the confirmation of serogroups, and virulence genes. A total of 34.3% of house flies and 1.1% of stable flies tested positive for at least one serogroup of E. coli of interest, and 1.5% of house flies harbored STEC with the Shiga-toxin gene (stx1). No STEC were detected in stable flies. Vector competence bioassays for non-O157 STEC revealed that house flies can carry non-O157 STEC for at least six days with the exception STEC O145. Overall, the findings of this research demonstrate that house flies, but not stable flies, likely play an important role in the ecology and transmission of non-O157 STEC in confined cattle environments.

House fly

Stable fly

Cattle

Shiga-toxigenic Escherichia coli

Manure

Entomology (0353)

The Quantitative Determination of Glass in Slag and Fly Ash by Infrared Spectroscopy

Eberendu, Alexis N. R.

12 1900

The present study was aimed at developing a new inexpensive and accurate analytical method for determining the glass content of slag and fly ash. Infrared absorption spectroscopy using an internal standard proved to be the method of choice. Both synthetic and commercial slags and fly ashes were investigated.

fly ash

slag

infrared spectroscopy

chemical compositions

Infrared spectroscopy.

Fly ash -- Analysis.

Slag -- Analysis.

Glass.

The role of aluminium content in the control of the morphology of fly ash based hierarchical zeolite X

Cornelius, Mero-Lee Ursula

January 2015

>Magister Scientiae - MSc / Coal is the main source of electricity in South Africa, the combustion of which produces a large amount of waste (coal fly ash) annually. The large-scale generation of coal fly ash places major strain on landfills and the material is toxic in nature. The high silicon and aluminium content in fly ash makes it a suitable starting material for zeolite synthesis. Utilisation of fly ash as a starting material for zeolite synthesis alleviates an environmental burden by converting a waste product to an industrially applicable material. In this study, hierarchical zeolite X was synthesised from coal fly ash via the fusion method. The clear fused fly ash (FFA) extract (with molar composition 0.12 Al·14.6 Na·1.00 Si·163 H₂O) served as the synthesis solution for hydrothermal treatment. The influence of synthesis parameters (such as Si/Al ratio, aluminium source, hydrothermal temperature and stirring) on hierarchical zeolite X formation was studied to determine the cause behind the formation of this material. Synthesised zeolites and starting materials (Arnot coal fly ash and fused fly ash) were characterised by various analytical techniques such as XRD and SEM-EDS to determine the phase purity, morphology and elemental composition (framework Si/Al ratio) of these materials. The synthesis of hierarchical zeolite X under hydrothermal conditions was found to be highly sensitive to the aluminium content of the synthesis solution. The hierarchical morphology of zeolite X was formed preferentially in relatively aluminium-deficient (i.e. high Si/Al ratio) synthesis environments under stirred hydrothermal conditions of 90 °C for 16 hours. In the case of sodium aluminate addition, octahedral shaped zeolite X crystals were formed in relatively low Si/Al ratio synthesis environments, which was attributed to the presence of excess sodium cation content in the synthesis solution. Selected hierarchical zeolites (D2 and E2) were characterised further to gain more insight into the properties of this material. HR-TEM and FTIR revealed that hierarchical zeolite D2 and E2 exhibited the typical structural features of zeolite X. Zeolite D2 and E2 contained both micropores and mesopores and had a high BET surface area of 338-362 m²/g. These zeolites also exhibited appreciable solid acidity (0.81-1.12 mmol H/g zeolite). These properties make hierarchical zeolite X a favourable material for application in catalysis or adsorption. Overall, the formation of zeolite X with hierarchical morphology was proposed to be linked to the presence of zeolite P1 structural units in the framework of the zeolite. / National Research Foundation

Coal fly ash

Zeolite synthesis

Zeolites

Hierarchical zeolite X

Fly ash