Development and Demonstration of Membrane to Control Potential Pathogen (Legionella sp.) Associated With Cooling Towers

Sharma, Neha; Lavania, Meeta; Lal, Banwari

doi:10.3389/fenvs.2020.570904

Cited by 5 publications

(3 citation statements)

References 42 publications

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“…Therefore, one of the most usual methods to control the bacteria is to keep cold water below 20°C and hot water stored at least at 60°C, combining with the use of biocides (Cloutman-Green et al , 2019; Iervolino et al , 2017). Additional methods include membranes for monitoring, maintenance and control in combination with sulfate and alkalinity (Sharma et al , 2020), and the continuous release of copper and silver ions into the water, showing positive results in the control of legionella at near 43°C (Cloutman-Green et al , 2019). However, “[i]t is important that the functioning of the system and associated equipment is considered as a whole and not in isolation (e.g.…”

Section: Resultsmentioning

confidence: 99%

Digital transformation of legionella-safe cooling towers: an ecosystem design approach

Ângelo

Barata

2021

JFM

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Purpose Legionnaires’ disease is a major threat to public health. Solutions to deal with this problem are usually siloed and not entirely effective. This paper aims to model the information requirements of legionella-safe cooling towers in the era of Industry 4.0. Design/methodology/approach A year-long design science research was conducted in a cooling tower producer for heavy industries. The project started with a bibliometric analysis and literature review of legionella in cooling towers. Goal modeling techniques are then used to identify the requirements for digital transformation. Findings The improvement of legionella prevention, detection and outbreak response in digitally enabled cooling tower should involve different stakeholders. Digital twins and blockchain are disruptive technologies that can transform the cooling tower industry. Originality/value For theory, this study revises the most recent advances in legionella protection. Legionella-safe systems must be prepared to anticipate, monitor and immediate alert in case of an outbreak. For practice, this paper presents a distributed and digital architecture for cooling tower safety. However, technology is only a part of outbreak management solutions, requiring trustworthy conditions and real-time communication among stakeholders.

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Section: Resultsmentioning

confidence: 99%

Digital transformation of legionella-safe cooling towers: an ecosystem design approach

Ângelo

Barata

2021

JFM

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“…The shoot and root dry weights were recorded, and the roots-to-shoot ratio was determined. The leaves on the plant were counted; leaf area was calculated, and the number of primary branches was also counted for both the first and second harvesting stages ( Sharma et al., 2020 ). The soil pH and electrical conductivity were analysed using a pH metre and a conductivity metre, respectively.…”

Section: Methodsmentioning

confidence: 99%

Unveiling the potential of cellulose nanofibre based nitrogen fertilizer and its transformative effect on Vigna radiata (Mung Bean): nanofibre for sustainable agriculture

Sharma,

Kochar,

Allardyce

et al. 2024

Front. Plant Sci.

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IntroductionFertilizer management is crucial to maintaining a balance between environmental health, plant health, and total crop yield. Farmers are overutilizing fertilizers with a mind set to enhance the productive capacity of the field, which adversely impacts soil fertility and causes serious environmental hazards. To mitigate the issues of over-utilization of fertilizers, controlled-release fertilizers were developed using nitrogen fertilizer (ammonium chloride) loaded on cellulose nanofibres (named CNF*N).MethodologyIn this study, the effects of CNF*N were compared with commercial nitrogen fertilizer (ammonium chloride) on Vigna radiata (Mung) under greenhouse conditions. The pot experiment was conducted using six treatments: first treatment was control, where the plant was cultivated (T1); second treatment was T2, where the plant was cultivated with CNF to determine the impact of CNF on the plant; third was T3 where commercial ammonium chloride (24 mg/ 2 kg soil) was added to the plant; fourth was T4, where the plant was loaded with CNF, viz. CNF*N contains 4.8 mg of nitrogen; fifth was T5 CNF*N pellet contains 12 mg of nitrogen, and the last sixth treatment (T6) where CNF*N pellet containing 24 mg of nitrogen.ResultsIt indicated that the growth parameters were best achieved in T6 treatment. Plant height was at its maximum in the T6 treatment (44.4 ±0.1cm) after the second harvest, whereas the minimum plant height was observed in T1, which was 39.1 ±0.1 cm. Root-to-shoot weight ratio was also maximum in T6 (0.183± 0.02) and minimum in T1 (0.07± 0.01) after second harvesting. The significant difference among the treatments was determined with Tukey’s honestly significant difference (HSD). The nitrogen content (available and total) was significantly higher in the T4, T5, and T6 treatments (0.22, 0.25, and 0.28%) as compared to the control treatments (T1 (0.12%), T2 (0.13%), and T3 (0.14%) during the second harvesting stage (90 days), as nitrogen plays a crucial role in the development of vegetative growth in Vigna radiata. The rate of controlled-release nitrogen-fertilizer was found to be optimal in terms of plant growth and soil nutrients; hence, it could potentially play a crucial role in improving soil health and the yield of the crop.

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“…Recently, due to its ease of technical applicability, sophisticated separation performance, and compact design, membrane technology has been massively performed for wastewater treatment purposes worldwide (Vinardell et al, 2020;Zolghadr et al, 2021). Some benefits from the implementation of membrane technology in wastewater treatment have been demonstrated, including, clean process, low energy consumption, compact design, less chemical consumption, versatility to be combined with other processes, tunable removal properties, and sludge-free (Hu et al, 2020;Sharma et al, 2020;Vinardell et al, 2020;Younis et al, 2020;Álvarez Bayona et al, 2022). Despite its superiority, the membrane filtration process is prone to fouling issues (Zhao et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Development of anti-foulant ultraviolet-assisted polyvinyl alcohol layer on the polysulfone-based nanohybrid membrane for industrial rubber wastewater decontamination

Kusworo

Kumoro

Aryanti

et al. 2023

Front. Environ. Sci.

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Introduction: Membrane fouling has been reported to be one of the bottlenecks of membrane technologies for wastewater treatment. To mitigate its negative impacts, we fabricated polysulfone membrane (PSf) composites made of silica (SiO2) and graphene oxide (GO) nanoparticles that modified with ultraviolet (UV)-assisted polyvinyl alcohol layer on the membrane surface.Methods: The membrane composite was synthesized using non-solvent induced phase separation (NIPS) method. The membrane was further treated by UV irradiation and cross-linked with PVA coating to cope with the fouling problem. The modified membrane was applied for industrial rubber wastewater decontamination.Results: The UV irradiation and cross-linked PVA coating to the PSf/GO-SiO2 membrane improved the pseudo-steady state permeate flux by 60.15% from 20.05 to 50.32 L/m2hr and maintained the permeate flux up to 82.33%. About 85% of total dissolved solids (TDS), 81% of chemical oxygen demand (COD), and 84% of ammonia compound (NH3) with initial concentrations of 335.76, 242.55, 175.19 mg/L, respectively, could be removed after 8 h of membrane treatment. The modified membrane also exhibited an excellent flux recovery ratio of up to 83%.Discussion: The modified membrane changed the fouling mechanism from pore blockage to cake filtration, which signifies the capability of the membrane to tackle severe fouling tendency. The cross-linked UV/PVA coating reduced fouling formation by reducing the adsorptive interactions between the foulant molecules and the membrane surface by enhancing membrane surface hydrophilicity. This implies that incorporating GO/SiO2 nanoparticles with UV irradiation and PVA coating substantially enhanced the physicochemical properties of the PSf membrane.

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Development and Demonstration of Membrane to Control Potential Pathogen (Legionella sp.) Associated With Cooling Towers

Cited by 5 publications

References 42 publications

Digital transformation of legionella-safe cooling towers: an ecosystem design approach

Digital transformation of legionella-safe cooling towers: an ecosystem design approach

Unveiling the potential of cellulose nanofibre based nitrogen fertilizer and its transformative effect on Vigna radiata (Mung Bean): nanofibre for sustainable agriculture

Development of anti-foulant ultraviolet-assisted polyvinyl alcohol layer on the polysulfone-based nanohybrid membrane for industrial rubber wastewater decontamination

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