Industrial water reuse with integrated membrane system increases the sustainability of the chemical manufacturing

Majamaa, Katariina; Aerts, P; Groot, Cornelis; Paping, Lambèr L. M. J.; Broek, Wilbert van den; Agtmaal, Sjack van

doi:10.5004/dwt.2010.1284

Cited by 20 publications

(8 citation statements)

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“…Van Paassen et al then showed that biofouling accumulated on feed spacers causes an exponential increase in the pressure drop across the membrane module containing the feed spacer [ 147 ]. To remedy the biofouling of feed spacers, various solutions have been proposed [ 148 , 149 ]. More recently, researchers have focused on the surface chemistry of the feed spacers.…”

Section: Anti-fouling Methods and Materialsmentioning

confidence: 99%

Emerging Anti-Fouling Methods: Towards Reusability of 3D-Printed Devices for Biomedical Applications

Lepowsky

2018

Micromachines

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Microfluidic devices are used in a myriad of biomedical applications such as cancer screening, drug testing, and point-of-care diagnostics. Three-dimensional (3D) printing offers a low-cost, rapid prototyping, efficient fabrication method, as compared to the costly—in terms of time, labor, and resources—traditional fabrication method of soft lithography of poly(dimethylsiloxane) (PDMS). Various 3D printing methods are applicable, including fused deposition modeling, stereolithography, and photopolymer inkjet printing. Additionally, several materials are available that have low-viscosity in their raw form and, after printing and curing, exhibit high material strength, optical transparency, and biocompatibility. These features make 3D-printed microfluidic chips ideal for biomedical applications. However, for developing devices capable of long-term use, fouling—by nonspecific protein absorption and bacterial adhesion due to the intrinsic hydrophobicity of most 3D-printed materials—presents a barrier to reusability. For this reason, there is a growing interest in anti-fouling methods and materials. Traditional and emerging approaches to anti-fouling are presented in regard to their applicability to microfluidic chips, with a particular interest in approaches compatible with 3D-printed chips.

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Section: Anti-fouling Methods and Materialsmentioning

confidence: 99%

Emerging Anti-Fouling Methods: Towards Reusability of 3D-Printed Devices for Biomedical Applications

Lepowsky

2018

Micromachines

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“…Compared to SW fodder, plant recovery increased by 20%, saving on 3 million m3 / a water intake. Reduced water intake helps reduce the use of active chemicals [36]. The fact that burnt clay sludge sludges absorb significantly more water than normal dense aggregates is mainly due to their cohesive cellular structure and the size of the pores.…”

Section: Water Reuse Treatmentmentioning

confidence: 99%

A Study on Various Implications on Reusing in Manufacturing

Amol

Venkateswaran

Ramachandran³

et al. 2021

JEMM

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Material recycling is the sustainable use of a substance, sustainable production, additive production, powder reuse, knowledge management, reuse of water, etc. Is the process of picking up old items and finding new ones? ... Sometimes items can be reused by others. Clothes can be donated frequently and given a second life. Recycling is better than recycling because it saves energy coming from disposing and recycling materials.This significantly reduces waste and pollution because it reduces the need for raw materials and saves both forest and water supply. When we do not recycle, reuse and reduce, we are destroying natural habitats. As it is, our planet cannot cope with the current rate of destruction. If we fail to reuse what we already have, we end up in a sticky situation of running out of resources. By reducing our waste, we are conserving our resources. Resources such as aluminum, petroleum and wood are all used to make new products such as cans, plastic bags and paper packaging. Less energy is used to recycle materials as opposed to creating new ones.

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“…Another advantage of membrane processes is that they can flexibly be scaled up with different unit operations and membrane types to add treatment capacity if necessary (Quist-Jensen et al 2015). Various full-scale studies have demonstrated that membrane-based advanced treatment processes (MATP) can be designed to reclaim WWTP effluents for all three water usage types: (i) (in)direct potable reuse for domestic consumption (Ortuño et al 2012;Chalmers & Patel 2013;Van Houtte & Verbauwhede 2013), (ii) demineralised process water for industrial reuse (Majamaa et al 2010;Shang et al 2011) and (iii) irrigation water for agricultural reuse (Hamoda et al 2015).…”

Section: Introductionmentioning

confidence: 99%

A techno-economic analysis of membrane-based advanced treatment processes for the reuse of municipal wastewater

Kehrein

Jafari

Slagt

et al. 2021

Journal of Water Reuse and Desalination

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The objective of this paper is to compare, under Dutch market conditions, the energy consumption and net costs of membrane-based advanced treatment processes for three water reuse types (i.e. potable, industrial, agricultural reuse). The water source is municipal wastewater treatment plant effluent. Results indicate that the application of reverse osmosis is needed to reclaim high quality water for industrial and potable reuse but not for irrigation water which offers significant energy savings but may not lead automatically to lower net costs. While a reclamation process for industrial reuse is economically most promising, irrigation water reclamation processes are not cost effective due to low water prices. Moreover, process operational expenditures may exceed capital expenditures which is important for tender procedures. A significant cost factor is waste management that may exceed energy costs. Water recovery rates could be significantly enhanced through the integration of a softener/biostabilizer unit prior to reverse osmosis. Moreover, the energy consumption of wastewater reclamation processes could be supplied on-site with solar energy. The possibility of designing a ‘fit for multi-purpose’ reclamation process is discussed briefly. This comparative analysis allows for better informed decision making about which reuse type is preferably targeted in a municipal wastewater reuse project from a process design perspective.

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Industrial water reuse with integrated membrane system increases the sustainability of the chemical manufacturing

Cited by 20 publications

References 1 publication

Emerging Anti-Fouling Methods: Towards Reusability of 3D-Printed Devices for Biomedical Applications

Emerging Anti-Fouling Methods: Towards Reusability of 3D-Printed Devices for Biomedical Applications

A Study on Various Implications on Reusing in Manufacturing

A techno-economic analysis of membrane-based advanced treatment processes for the reuse of municipal wastewater

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