6 results on '"Kilmartin-Lynch, Shannon"'
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2. Transforming spent coffee grounds into a valuable resource for the enhancement of concrete strength.
- Author
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Roychand, Rajeev, Kilmartin-Lynch, Shannon, Saberian, Mohammad, Li, Jie, Zhang, Guomin, and Li, Chun Qing
- Subjects
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COFFEE grounds , *ORGANIC wastes , *LANDFILL gases , *REINFORCED concrete , *CONCRETE , *CONCRETE industry , *PORTLAND cement , *X-ray fluorescence , *EFFECT of temperature on concrete - Abstract
The decomposition of organic waste going to landfills produces methane gas, which is 21 times worse than CO 2 in its global warming potential. Spent coffee grounds (SCG) are one type of organic waste that makes up a significant proportion of the organic waste going to landfills. Therefore, it becomes imperative to look for a recycling solution to transform this waste into a valuable resource. The concrete industry has the potential to contribute significantly to increasing the recycling rate of this waste material. However, due to its high organic content, it is unsuitable to be used directly in structural concrete. Therefore, this experimental project looks at pyrolysing this waste at different temperatures (350 and 500 °C) to identify its suitability in improving the physicochemical and mechanical properties of concrete. The raw and pyrolysed forms of SCG were used as a replacement of fine aggregates (FA; sand) at 5, 10, 15 and 20% volume replacement levels. X-ray fluorescence (XRF), Carbon, Hydrogen, Nitrogen, and Sulfur (CHNS) analysis, laser diffraction particle size analysis, X-ray diffraction (XRD), scanning electron microscopy (SEM) and compressive strength tests were undertaken to investigate the properties of the raw material and their performance in the blended concrete composites. The results show that the leaching of organic compounds from the SCG hinders the hydration reaction of cement particles, thereby significantly hampering the compressive strength of SCG-blended concrete. However, pyrolysing the SCG at 350 °C led to a significant improvement in its material properties, which resulted in a 29.3% enhancement in the compressive strength of the composite concrete blended with coffee biochar. [Display omitted] • Spent coffee grounds (SCG) leach organic compounds that hinder the hydration reaction and compressive strength of concrete. • SCG pyrolysed at 350 and 500 °C show strong bond formation with the cement matrix. • 15 vol% replacement of sand with pyrolysed SCG at 350 °C provides ∼30% improvement in concrete strength. • 100% of 75,000 tonnes of waste SCG produced in Australia can be utilised in structural concrete. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
3. Application of COVID-19 single-use shredded nitrile gloves in structural concrete: Case study from Australia.
- Author
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Kilmartin-Lynch, Shannon, Roychand, Rajeev, Saberian, Mohammad, Li, Jie, and Zhang, Guomin
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- 2022
- Full Text
- View/download PDF
4. Preliminary evaluation of the feasibility of using polypropylene fibres from COVID-19 single-use face masks to improve the mechanical properties of concrete.
- Author
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Kilmartin-Lynch, Shannon, Saberian, Mohammad, Li, Jie, Roychand, Rajeev, and Zhang, Guomin
- Subjects
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MEDICAL masks , *COVID-19 , *PERSONAL protective equipment , *HIGH strength concrete , *POLYPROPYLENE , *CONCRETE - Abstract
With the ongoing global pandemic due to Coronavirus (COVID-19), the use of personal protective equipment (PPE), specifically single-use surgical masks, have been on a sharp incline. Currently, many countries are experiencing second and third waves of COVID-19 and as such have resorted to making face masks a mandatory requirement. The repercussions of this have resulted in millions of single-use face masks being discharged into the environment, washing up on beaches, floating beneath oceans and ending up in vulnerable places. The global pandemic has not only affected the economy and health of the world's population but now is seriously threatening the natural environment. The main plastic in single-use face masks is polypropylene which in landfill can take more than 25 years to break down. This paper explores an innovative way to use pandemic waste in concrete construction with the main focus on single-use face masks. Single-use masks have been cut-up by first removing the ear loops and inner nose wire to size and spread throughout five different mix designs to explore the possible benefits and uses within concrete. The masks were introduced by volume at 0% (control), 0.10%, 0.15%, 0.20% and 0.25% with testing focusing on compressive strength, indirect tensile strength, modulus of elasticity and ultrasonic pulse velocity to test the overall quality of the concrete. The introduction of the single-use face masks led to an increase in the strength properties of the concrete samples, as well as an increase in the overall quality of the concrete. However, beyond 0.20%, the trend of increasing strength began to decrease. • An innovative method is proposed to alleviate the waste generation issue associated with COVID-19. • The disposed surgical masks can be used to improve the strength of concrete. • The inclusion of 0.20% by volume of shredded surgical masks to concrete provided the highest strength properties. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
5. Carbon sequestration from waste and carbon dioxide mineralisation in concrete – A stronger, sustainable and eco-friendly solution to support circular economy.
- Author
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Roychand, Rajeev, Li, Jie, Kilmartin-Lynch, Shannon, Saberian, Mohammad, Zhu, Jiasheng, Youssf, Osama, and Ngo, Tuan
- Subjects
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CIRCULAR economy , *CARBON dioxide , *RAW materials , *CONCRETE , *NATURAL resources , *ORGANIC wastes , *CARBON sequestration - Abstract
• Wood biochar was used as a replacement of fine aggregates at 10, 20 and 30% replacement levels. • Effect of CO 2 curing of biochar blended concrete was also investigated. • All three replacement levels provide compressive strength higher than the control mix. • CO 2 curing shows a positive influence on the compressive strength of the biochar concrete. The production of concrete is heavily reliant on the continuous mining of natural resources, with the majority component being the natural aggregates which make up about 70–75% of the concrete volume. As the emphasis shifts towards promoting sustainability through recycling all types of waste to create a closed-loop circular economy, it's vital to explore alternative waste materials that can replace traditional raw materials in concrete production. Biochar derived from different organic waste materials has shown to improve the strength properties of concrete. However, the majority of the research has focussed on using biochar as a cement replacement material with very low cement replacement levels. Therefore, this research focuses on significantly increasing the uptake of the pyrolysed form of organic waste (wood biochar) by using it as a replacement of fine aggregates at replacement levels of 10, 20 and 30 vol%. The biochar blended concrete showed an improvement of 63.9, and 45.6% and a reduction of 9.6% in the 7-day compressive strength results at 10, 20 and 30% replacement levels, respectively. At 28 days, the biochar blended concrete samples showed an improvement of 20.1, 22.6, and 16% in the compressive strength results at 10, 20 and 30% replacement levels, respectively. Separately, the 10% WBC blended concrete was also cured in a CO 2 environment for 7 and 28 days. The results showed an improvement of 24.7 and 37.3 in the 28-day compressive strength results with the respective CO 2 curing of 7 and 28 days, compared to the control mix. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
6. Repurposing of COVID-19 single-use face masks for pavements base/subbase.
- Author
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Saberian, Mohammad, Li, Jie, Kilmartin-Lynch, Shannon, and Boroujeni, Mahdi
- Abstract
The coronavirus (COVID-19) pandemic has not only created a global health crisis, but it is also now threatening the environment. A multidisciplinary collaborative approach is required to fight against the pandemic and reduce the environmental risks associated with the disposal of used personal protective equipment (PPE). This paper explores an innovative way to reduce pandemic-generated waste by recycling the used face masks with other waste materials in civil constructions. In this research, for the first time, a series of experiments, including modified compaction, unconfined compression strength and resilient modulus tests, were conducted on the blends of different percentages of the shredded face mask (SFM) added to the recycled concrete aggregate (RCA) for road base and subbase applications. The experimental results show that RCA mixed with three different percentages (i.e., 1%, 2% and 3%) of SFM satisfied the stiffness and strength requirements for pavements base/subbase. The introduction of the shredded face mask not only increased the strength and stiffness but also improved the ductility and flexibility of RCA/SFM blends. The inclusion of 1% SFM to RCA resulted in the highest values of unconfined compressive strength (216 kPa) and the highest resilient modulus (314.35 MP). However, beyond 2%, increasing the amount of SFM led to a decrease in strength and stiffness. Unlabelled Image • A new and low carbon strategy is proposed to reduce pandemic-generated waste. • The inclusion of shredded face mask can improve ductility, flexibility and strength. • The disposed face masks can be used for pavement base/subbase applications. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
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