Your search keyword '"PAPER mill waste"' showing total 328 results

1. Intermetallic TiFe particles generation within porous monolithic carbon materials arising from paper mill waste and their cooperative hydrogen storage properties.

Author

Poupart, Romain, Cona, Christophe, Labrugère-Sarroste, Christine, Deleuze, Hervé, Backov, Rénal, and Bobet, Jean-Louis

Subjects

*PAPER mill waste, *SULFATE waste liquor, *CARBON-based materials, *HYDROGEN storage, *WASTE paper

Abstract

A new materials composed of TiFe particles stabilized onto a carbon support is described. The carbon support is derived from a waste from the paper industry called Kraft Black liquor. The particles are generated through an impregnation/reduction process of a mixture of titanium ethoxide and iron nitrate followed by a thermal treatment. The generated particles have been investigated through XPS, XRD and SEM analysis as well as tested for hydrogen storage. The hydrogen storage at 25 °C leads to a capacity of up to 0.5 wt% while at 150 °C, free of the carbon absorption, leads to a capacity of 0.2 wt% without any prior activation process. Novel TiF@carbo(HIPE) materials have been synthesized while employing Kraft black liquor as carbonaceous source. A specific carbo-reduction thermal treatment allows a synergetic TiFe particles external shell reduction concomitant with the surrounding carbonaceous backbone oxidation enhancing thereby the materials specific surface area and associated microporosity. Pre-activation free, TiFe@Carbo(HIPE) can achieve a capacity up to 0.5 wt% at 25 °C where TiFe particles and the carbonaceous host support are acting cooperatively. [Display omitted] • Generation and characterization of carbon from a waste from the paper industry. • Generation of TiFe nanoparticles on the carbon. • Characterization of the TiFe nanoparticles. • Use of the hybrid composite TiFe@Carbon for hydrogen storage. [ABSTRACT FROM AUTHOR]

Published

2024

2. Production of Lipid and Xylo-oligosaccharides from Cellulose and Hemicellulose in Reed Sawdust.

Author

Jiao, MeiZhen, Zhang, Xinran, Wang, Yiqin, Du, Jian, Tao, Yehan, Lv, Yanna, Chen, Ming, Lu, Jie, and Wang, Haisong

Subjects

*PAPER mill waste, *DOCOSAHEXAENOIC acid, *SPRAY drying, *WOOD waste, *FEED additives, *HEMICELLULOSE, *CELLULASE

Abstract

Reed sawdust is a kind of paper mill waste with high cellulose and hemicellulose content. To promote the rational use of resources, it is essential to make full use of waste resources and transform them into new values. In this work, reed sawdust was pretreated with liquid hot water (LHW) at 170 °C for 30 min. A total of 39.00 g/L glucose was obtained after enzymatic saccharification of cellulose at 50 °C, 20 FPU/g-reed sawdust cellulase, 25% (w/v) reed sawdust, in 5 replenishments. When the fermentation was performed 96 h, the medium contained xylo-oligosaccharides (XOS) 11.74 g/L and biomass 15.21 g/L, in which lipid was 4.14 g/L. After spray drying, feed additives containing 29.17% XOS and 10.29% docosahexaenoic acid (DHA) can be prepared. In particular, the hemicellulose and cellulose in reed sawdust are creatively used at the same time without separation, which greatly reduces the cost of purification in traditional processes and provides a new way for the high-value transformation of sawdust resources. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effects of bleached wastewater released from pulp and paper mills on the Genotoxicity of freshwater fish (Channa punctatus (Bloch, 1793)).

Author

Devi, Km poonam and Singh, Ajay

Subjects

PAPER mill waste, FRESHWATER fishes, GENETIC toxicology, WATER pollution, WATER quality

Abstract

Water resource pollution is a significant issue that is only becoming worse even with the appropriate laws in place. Because effluent contaminants tend to accumulate in aquatic species, genotoxic researches on these pollutants are crucial. Therefore, using aquatic organisms to measure Genotoxicity is a highly helpful environmental monitoring technique. River Ami is a significant body of water in Maghar Sant Kabir Nagar, Uttar Pradesh, India that was contaminated by many industrial sources' untreated effluents. The current study set out to assess the genotoxic effects of these effluents on Channa punctatus fish as well as their toxic impacts on water quality. The research of Genotoxicity (the impact of bleached effluent on fish micronuclei) was conducted using the micronuclei. Fish treated with bleached effluent showed a significant (p<0.05) increase in the quantity of micronuclei compared to fish that were directly collected from the Aami River. Temperature, pH, DO, BOD, COD, TSS, and TDS are among the physico-chemical characteristics of a body of water that are assessed seasonally. All of these metrics were significantly higher than the Central Pollution Control Board of India's suggested tolerance limit. [ABSTRACT FROM AUTHOR]

Published

2024

4. Mechanism of Working Fluid Circulation in the Multisource Organic Solid Waste Incinerator.

Author

Bie, Yifan, Cheng, Qiang, and Luo, Zixue

Subjects

*PAPER mill waste, *SOLID waste, *ORGANIC wastes, *AIR flow, *INCINERATORS

Abstract

AbstractGarbage incineration power generation is utilized to dispose of multi-source organic solid waste. This work constructed a mathematical model for a 750 t/d garbage incinerator to reveal the coupled response between the boiler and furnace sides. Field experiments validated the model, exploring various operating conditions including different loads, fuel blending ratios, primary air, and internal flue gas recirculation (IGR) air flow rates. Increasing the load by 9.1% raised furnace heat exchange by 4.0% but reduced economizer heat exchange by 19.0%. Introducing waste cloth strips and paper mill waste enhanced furnace water-cooled wall heat transfer but reduced economizer heat exchange. A 10.8% rise in primary air flow increased superheater heat exchange by 7.8%. Similarly, a 21.3% rise in IGR air flow increased economizer heat exchange by 9.0%. The temperature rise and enthalpy rise in the superheater were higher when the low calorific value of the fuel was higher. Increasing primary air velocity enhanced heat transfer, raising the outlet temperature of the medium-temperature superheater, necessitating an increase in secondary water spray to adjust the outlet temperature of the high-temperature superheater. This work provides guidance for the design and practical operation of multi-source solid waste incinerators. [ABSTRACT FROM AUTHOR]

Published

2024

5. Upcycling Waste Biomass–Production of Porous Carbonaceous Supports from Paper Mill Sludge and Application to CO2 Conversion.

Author

Ribeiro, Mónica Stanton, Lima, Maria M. R. A., Vilarigues, Márcia, Zanatta, Marcileia, and Corvo, Marta C.

Subjects

PAPER mill waste, CARBON-based materials, HYDROTHERMAL carbonization, POROUS materials, WASTE management, CARBONACEOUS aerosols

Abstract

The urgent need for sustainable waste management strategies has led to the exploration of innovative approaches for the valorization of waste. In this study, a method is proposed for carbonizing waste biomass materials, particularly paper mill waste sludges (primary and biological) and knots, to produce porous carbonaceous supports. Through an initial hydrothermal carbonization followed by carbonization with nitrogen flow, porous carbon materials are successfully generated. The findings of this investigation validate the successful generation of effective carbonaceous supports utilizing waste biomass materials. These materials are then evaluated for their effectiveness as porous supports in the ionic liquid‐catalyzed cycloaddition reaction of CO2 to styrene oxide, achieving a remarkable conversion rate of up to 98% and an impressive selectivity exceeding 99%. Additionally, the results underscore the significant impact of the selected IL on the overall conversion process. Overall, this study presents a promising pathway for the valorization of paper mill waste sludge through the production of porous carbon materials with potential applications in catalysis and beyond. [ABSTRACT FROM AUTHOR]

Published

2024

6. Utilizing de‐inked paper sludge for sustainable production of medium‐density fiberboard: A comprehensive study.

Author

Ashori, Alireza, Mahmoudi Najafi, Seyed Heydar, Heydari, Vahid, Besharatifar, Kamran, Sharifi Taskouh, Hamed, and Maghsoodi, Davood

Subjects

*SUSTAINABILITY, *PAPER mill waste, *FIBERBOARD, *CRYSTAL whiskers, *WASTE recycling, *ADHESION, *MOISTURE

Abstract

This study investigated converting abundant paper mill waste, de‐inked paper sludge (DPS), into value‐added medium‐density fiberboard (MDF) panels. The objective was to repurpose this solid waste into a valuable material that aligns with the principles of a circular economy. Previous research has examined the addition of paper sludge to wood composites, but there is limited information on the specific incorporation of DPS into MDF production. This investigation offers new insights into this application. MDF panels were manufactured using hardwood fibers, with varying levels of urea‐formaldehyde resin (10% and 12% by weight) and different loadings of DPS (ranging from 0% to 50% by weight). X‐ray diffraction analysis revealed the presence of defective DPS fiber crystals. Contact angle measurements confirmed that DPS had poor wettability, corresponding to increased water absorption. As more DPS was incorporated, the mechanical properties of the panels progressively weakened due to defective fibers and poor adhesion between the fibers and the matrix. This was evident in scanning electron microscopy micrographs, which showed an escalation in interfacial flaws. Increasing the resin dosage noticeably improved the internal bond strength and reduced moisture uptake across all levels of DPS. However, at a DPS loading of 50%, the properties of the panels deteriorated by 36%–57% compared to the control MDF. Additionally, thickness swelling and water absorption increased significantly with higher DPS content, primarily due to the hydrophilic nature of the fibers. Based on optimization, it was determined that a DPS loading of 20% with a resin content of 12% provided the best balance between performance, waste utilization, cost, and moisture resistance. The reuse of abundant paper sludge supports the goals of a circular economy. However, strategies are required to tailor the processing methods and enable higher levels of recycled material without excessively compromising the key attributes of the product. Further research should focus on enhancing the quality of DPS and its compatibility with wood fibers and resin to enhance the performance of the composite material. Highlights: DPS from recycled paper mill assessed for MDF production with wood fibers and resinIncreasing DPS loading caused reductions in strength and adhesion of panelsWater absorption and thickness swelling markedly rose with more DPS additionIt was attributed to hydrophilic fibers and disrupted fiber‐matrix bondingOptimal formulation was 20% DPS loading and 12% resin content, balancing performance, waste utilization, and cost. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effectiveness of wood ash and paper sludge as liming and nutrient sources for annual ryegrass grown in podzolic soils of Newfoundland.

Author

Javed, Bilal, Katanda, Yeukai, Nadeem, Muhammad, Wickremasinghe, Thilini, Farhain, Muhammad M., Thomas, Raymond, Galagedara, Lakshman, Guo, Xiaobin, and Cheema, Mumtaz

Subjects

*WOOD ash, *ITALIAN ryegrass, *RYEGRASSES, *PAPER mill waste, *LIMING of soils, *ACID soils

Abstract

The acidic soils of western Newfoundland require liming for successful production of most crops. Locally sourced paper mill waste wood ash (WA) and paper sludge (SL) have potential as cheaper alternatives to limestone (LIME). Two greenhouse experiments evaluated WA and SL as liming and soil conditioning amendments for annual ryegrass (Lolium multiflorum) production. At 55 days after seeding, soil pH in WA (6.2 and 6.3) and wood ash and paper sludge (WASL) (6.0 and 6.3) were not different from that in LIME (6.0 and 6.5) for Experiments 1 and 2, respectively. However, pH in SL was 0.4 and 0.3 points lower than in LIME. Compared to LIME, WA, SL, and WASL produced 31%–52% and 57%–74% greater biomass yield in Experiments 1 and 2, respectively. N uptake was greater in WA (60 and 129 kg N ha−1) and WASL (51 and 97 kg N ha−1) compared to LIME (40 and 85 kg N ha−1), in Experiments 1 and 2, respectively. SL did not differ from LIME in Experiment 1, but reduced N uptake by 57% in Experiment 2. The results show significant potential of WA as an alternative amendment for liming and yield improvement of annual ryegrass grown in NL podzolic soils. However, SL has limited potential due to the risk of increasing N immobilization and residual soil mineral N when growing conditions are limiting. Combining SL with WA or biochar seemed to alleviate these risks. Overall, the adoption of these amendments for field production systems warrants serious consideration, following supplemental field studies to determine optimal application rates and timing. Core Ideas: The podzolic soils of Newfoundland have low pH and fertility, hence require liming.Locally sourced wastes, such as paper mill wood ash (WA) and sludge (SL), could be used as liming and nutrient sources.WA was equivalent to limestone (LIME) in improving and sustaining optimal soil pH.WA produced 52% and 74% greater annual ryegrass yield than conventional LIME application in podzolic soils. [ABSTRACT FROM AUTHOR]

Published

2024

8. Fabrication of hydrophobic coatings on paper substrates using silicone oil impregnated silica: a promising sustainable packaging material.

Author

Francy, Angitha, Ragi, T. M., Mohamed, A. Peer, and Ananthakumar, S.

Subjects

PACKAGING materials, BIODEGRADABLE plastics, SILICONE rubber, SUBSTRATES (Materials science), PAPER mill waste, SINGLE-use plastics, CONTACT angle

Abstract

Paper substrates possessing features ranging from hydrophobic to oxygen-barrier functional properties are gaining great attention recently due to the global ban on single-use plastics as well as the compulsion to avoid nonbiodegradable polymer packing. In this work, hydrophobic silica carriers are processed first through a direct physical impregnation of silicone oil in various amounts into the 20-nm sized silica nanoparticles and subsequently analyzed for the progressive changes in the surface hydrophobicity by water contact angle measurements. The hydrophobic nano-silica was also systematically analyzed by XRD, TGA, FTIR, SEM, and TEM and the results are presented. It was found that the nano-silica with the bulk BET surface area of 157 m2/g can accommodate 2.5 g of silicone oil per gram of silica, finally resulting in hydrophobic silica with a maximum contact angle of 139°. Later, this hydrophobic nano-silica was dispersed in a polymethylmethacrylate (PMMA) matrix and a coating formulation was prepared to develop water-repellent self-cleaning functional coatings on eco-friendly paper substrates. While applied as topcoats on paper substrates, the hydrophobic silica-PMMA gets embedded into the porous fibrous cellulose network and converts it into an impressive water-repellent packaging material with a contact angle of about 142°. This facile inorganic–organic hybrid topcoat strategy was successfully applied on the fibrous cellulose sludge waste produced by the paper mills to produce lightweight, water/moisture resistance packing material for circular economy. [ABSTRACT FROM AUTHOR]

Published

2024

9. Application of an integrated pyrolysis and chemical leaching process for pulper waste conversion into coal, hydrogen and chemical flocculating agent.

Author

Salimbeni, Andrea, Di Bianca, Marta, Maria Rizzo, Andrea, and Chiaramonti, David

Subjects

*CHEMICAL processes, *CHAR, *COAL mine waste, *PAPER mill waste, *CHEMICAL testing, *PYROLYSIS

Abstract

[Display omitted] • By slow pyrolysis, pulper waste is converted into a stable, carbon-rich material. • Chemical leaching upgrades the carbon-rich solid to a fossil coal substitute. • The process enables to recover more than 90 % of Ca and Al from pulper waste. • By precipitation, a reusable Al-based flocculating agent is obtained. • Clean hydrogen is produced by the reaction between metallic Al and HCl. This work aims to investigate the potentials of integrating slow pyrolysis and chemical leaching to recycle pulper waste (PW), the waste generated by paper mills, and consists of plastics, metallic films, and biobased polymers. The concentration of chlorine and metals is a barrier against PW valorisation by combustion or high temperature thermochemical processes. In this study, PW was tested by slow pyrolysis at 400 °C and 500 °C. Chemical leaching tests were performed by processing both chars in a 1.4 M HCl solution, at 80 °C for 2 h, to remove inorganic compounds and upgrade the char to a coal-like material. Then, precipitation by NaOH was conducted on the leachate. Slow pyrolysis led to a char mass yield around 30 %. Due to the high inorganic matter concentration (almost 36 %, mainly including chlorine, calcium, and aluminium), the char retained only 25 % of the feedstock's chemical energy, while the remaining 75 % was recovered in the pyrogas. Leaching of the 500 °C pyrolysis char led to extract 93 % of aluminium, and almost 100 % of calcium and chlorine, resulting in an upgraded char containing 15.5 % ash, comparable to a fossil coal. By char leaching, the oxidation reaction of aluminium could produce 8 kg hydrogen per dry ton PW. The effectiveness of the precipitated compounds as flocculating agents was demonstrated, enabling a closed-loop recycling in the same paper mill. In conclusion, the proposed process demonstrated to be an effective solution to convert PW into high quality products. [ABSTRACT FROM AUTHOR]

Published

2024

10. Fuel properties and combustion performance of hydrochars prepared by hydrothermal carbonization of different recycling paper mill wastes.

Author

Assis, Englatina I. N. C. and Chirwa, Evans M. N.

Subjects

PAPER mill waste, HYDROTHERMAL carbonization, PAPER recycling, CARBONIZATION, COMBUSTION, COAL-fired power plants

Abstract

The incineration of high‐moisture solid residues generated at the recycling paper mills represents an energetically unfavourable method of resource utilization. Alternatively, hydrothermal pre‐treatment is considered. In this study, low‐value paper sludges from three different recycling streams were hydrothermally carbonized at 205, 225, and 245°C for 3 h. The raw feedstocks and derived hydrochars were analyzed for energy properties, chemical characteristics, surface morphology, functional groups, and combustion performance employing energy densification and mass yield quantification, scanning electron microscopy, elemental analyzer, Fourier‐transform infrared spectroscopy, and thermogravimetry. The increase in reaction temperature was reported to cause a decrease in mass yield and an increase in energy densification and calorific values corresponding to 5.98%–49.35% and 10.10%–58.51% for raw fibre rejects and final sludge‐derived hydrochar, respectively. Hydrothermal carbonization (HTC) had a non‐significant influence on the energy densification of primary clarifier sludge‐derived hydrochar. Higher reaction temperatures favoured the rate of dehydration and decarboxylation, leading to hydrochars with lower H/C and O/C ratios, thereby enhancing the overall fuel properties. The low‐nitrogen and low‐sulphur fuels obtained validated the effectiveness of HTC treatment to produce high‐quality cleaner solid fuel. The burnout temperature was mostly reduced with an increase in HTC temperature. At HTC‐205 and 225°C, the ignition temperature and the combustion performance increased as a result of the HTC reaction mechanisms. HTC effectively recovered hydrochar with increased carbon content, improved energy densification, and good combustion adequacy. Hydrochar derived from recycling mills may play a role in the energy sector as a substitute for coal or in co‐combustion at coal‐fired power plants. [ABSTRACT FROM AUTHOR]

Published

2023

11. Effluents and residues from industrial sites for carbon dioxide capture: a review.

Author

Baena-Moreno, Francisco M., Leventaki, Emmanouela, Riddell, Alexander, Wojtasz-Mucha, Joanna, and Bernin, Diana

Subjects

*MUNICIPAL solid waste incinerator residues, *CARBON sequestration, *CONSTRUCTION & demolition debris, *PAPER mill waste, *INDUSTRIAL wastes, *INDUSTRIAL sites, *SLAG, *CARBON dioxide

Abstract

The adverse effects of climate change calls for the rapid transformation of manufacturing processes to decrease the emissions of carbon dioxide. In particular, a lower carbon footprint can be achieved by capturing carbon dioxide at the site of emission. Here we review the use of industrial effluents, waste and residues to capture carbon dioxide. Waste include steelmaking slag, municipal solid waste incinerator ashes, combustion fly ash, black liquor, paper mill waste, mining waste, cement waste, construction and demolition waste, waste from the organic industry, and flue gas desulfurization gypsum waste. Capture capacities range from 2 to 800 kg of carbon dioxide per ton of waste, depending on processes, waste type and conditions. Cement waste and flue gas desulfurization gypsum waste show the highest capture capacity per ton of waste. [ABSTRACT FROM AUTHOR]

Published

2023

12. Mechanical properties and microscopic mechanism of paper mill sludge-magnesium oxychloride cement composites.

Author

Jian Gong, Qianqian Liu, Shuren Wang, Zhixiang Wang, and Chunliu Li

Subjects

PAPER mills, CEMENT composites, PAPER mill waste, SUSTAINABLE construction, SCANNING electron microscopes, INDUSTRIAL wastes, SOLID waste, CONSTRUCTION materials

Abstract

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Published

2023

13. Effect of ferrate pretreatment on anaerobic digestibility of primary sludge spiked with resin acids.

Author

Das, Sreejon, Manoli, Kyriakos, Sharma, Virender K., Dagnew, Martha, and Ray, Madhumita B.

Subjects

WATER treatment plant residuals, PAPER mill waste, ANAEROBIC digestion, SUSPENDED solids, PAPER pulp, WATER treatment plants, DRUG dosage

Abstract

Resin acids are mixtures of high molecular weight carboxylic acids found in tree resins. Due to higher hydrophobicity and low solubility, they tend to adsorb on the suspended solids in pulp and paper (P&P) mill wastewater and accumulate in primary sludge through settling. Anaerobic digestion (AD) is a common practice stabilizing sludge; however, high concentration of resin acids affects the AD process. The aim of this research was mainly to determine the impact of ferrate (Fe (VI)) oxidation on selected resin acids and anaerobic digestibility of ferrate-treated primary sludge (PS) spiked with the resin acids. First, batch control oxidation of model resin acids with Fe (VI) was conducted to identify an optimum dosage, pH and contact time using a Box–Behnken design approach. Thereafter, anaerobic treatability studies of primary sludge spiked with resin acids both under control condition and optimum ferrate pretreatment were conducted. Up to 97% oxidation of resin acids occurred in pure water, while only 44%—62% oxidation of resin acids occurred in PS with an increasing Fe (VI) dosage from 0.034 to 0.137 mg Fe (VI)/mg tCODfed. The pretreatment did not affect the anaerobic biodegradability of resin acids; however, it lowered their negative influences on the PS digestibility. About 0.076 mg Fe (VI) dosage/mg tCODfed solubilized the sludge increasing the methane production by 40% compared to the untreated digester. The potential benefits of ferrate pretreatment of P&P primary sludge include resin acids oxidation and subsequent toxicity reduction, higher sludge solubilization enhancing methane production and enabling anaerobic digestion at higher COD loading. [ABSTRACT FROM AUTHOR]

Published

2022

14. Evaluation of Fly Ash from Co-Combustion of Paper Mill Wastes and Coal as Supplementary Cementitious Materials.

Author

Wu, Ming-Fu and Huang, Wei-Hsing

Subjects

*PAPER mill waste, *FLY ash, *COAL mine waste, *COAL ash, *CO-combustion, *COAL combustion, *INCINERATION, *SCANNING electron microscopes, *X-ray fluorescence

Abstract

The applications of waste-derived fuel from paper mills in industrial boilers benefit the reduction of carbon emissions. However, the co-combustion of waste-derived fuel and coal causes significant changes in the characteristics of the ash and brings about the need to find possible means of the utilization of the ash produced. In this work fly, ash samples were collected from circulating fluidized bed (CFB) boilers co-combusting paper mill wastes with coal and analyzed in detail. The chemical, physical, and thermal characteristics of two different co-combustion fly ashes (CCFA) were investigated using X-ray fluorescence (XRF), X-ray diffraction (XRD), thermogravimetry (TG), and scanning electron microscope (SEM). The chemical composition of CCFA is largely affected by the fuel source type. Thermal analyses of CCFA show that the type of desulfurization system used by the boiler influences the form of sulfate present in the fly ash. The presence of calcium sulfite hemihydrate can cause a high loss in the ignition of CCFA. By comparing the physical requirements specified in the ASTM standard for coal fly ash to be used in concrete, the CCFA produced from paper mill wastes was found to show good potential as supplementary cementitious materials. [ABSTRACT FROM AUTHOR]

Published

2022

15. Field Measurement and Dispersion Modelling of Hydrogen Sulphide for Recycled Paper Mill in Malaysia.

Author

Li Yee Lim, Bong, Cassendra, Wai Shin Ho, Hashim, Haslenda, Taib, Mohd Rozainee, Pang Soon Ng, and Keng Yinn Wong

Subjects

HYDROGEN sulfide, PAPER mill waste, RECYCLED paper, POLLUTANTS

Abstract

Hydrogen sulphide (H2S) is a well-known environmental pollutant from the industrial sector due to its unpleasant odour and high toxicity. It can post health threat at a low threshold exposure limit, with concentration as low as 0.01-1.5 ppm. In the pulp and paper mills, a significant amount of total reduced sulphur (TRS) is generated during the pulping and bleaching process. The TRS contains various pollutants such hydrogen sulphide (H2S), methyl mercaptan and dimethyl. For recycled paper mills, since the collected papers did not undergo the pulping and bleaching processes, the pollutant produced is mainly H2S. Due to its high toxicity and low threshold limit, early H2S detection and understanding its air dispersion pattern are important to reduce the potential health risk imposed by H2S to the local workers and residence of the surrounding areas. However, the commonly used odour unit might not be sufficient to represent the specific concentration of H2S. There has also been limited studies on the H2S dispersion modelling in Malaysia. Thus, in this study, a H2S dispersion modelling was performed at a recycled paper mill in Malaysia, with H2S concentration (µg/m3) as the odour indicator, to understand the changes in H2S concentration at different distances from source and identify potential health risk. Firstly, air samples were collected and analysed to identify the emission hotspots. The American Meteorological Society/Environmental Protection Agency Regulatory Model (AERMOD) was then used to determine the dispersion pattern of H2S and its concentration across the surrounding air. Wind data for 2 y was recorded and input for the modelling. Both the gas sampling study and dispersion modelling showed that the concentration of H2S was below the threshold limit at a distance of 50 m from the emission source, which was the effluent sludge holding tank. It is unlikely that the H2S emission from the recycled paper mill would lead to odour or health complaints to the surroundings. [ABSTRACT FROM AUTHOR]

Published

2022

16. Hazard reduction of heavy metals by co-pyrolysis of modified vermiculite with paper mill sludge/municipal solid waste: Characterization, risk and reaction mechanism study in pyrolytic environment.

Author

Yang, Yuxuan, Zhong, Zhaoping, Zhen, Zongao, Jin, Baosheng, Zhang, Bo, Du, Haoran, Li, Qian, Zheng, Xiang, Qi, Renzhi, Ye, Qihang, and Jia, You

Subjects

*PAPER mill waste, *COPPER, *SOLID waste, *VERMICULITE, *DOPING agents (Chemistry), *HEAVY metals

Abstract

The increasing volume of paper mill sludge (PM) and municipal solid waste (MW) poses environmental problems associated with heavy metals. Co-pyrolysis of PM/MW with additives effectively reduces the risk of heavy metal contamination. In this study, co-modified vermiculite (LMV) was prepared using the modification methods of intercalation-exfoliation, Mg2+ impregnation, and thermal activation. PM and MW were mixed at different doping ratios, and a non-doping experiment was performed to compare the pyrolysis processes and the retention rates for different heavy metals (Zn, Cr, Cu, Cd, and Pb), as well as the potential ecological risks, and the form distribution of the heavy metals. The addition of LMV reduced the risk posed by heavy metals. In the absence of doping, a higher pyrolysis temperature is conducive to an increase in the oxidizable and residual fractions of heavy metals without higher retention rates. Among these heavy metals, Zn, Cr, and Cu had higher retention rates and low risks, whereas Cd had a relatively high risk with low retention rates. Simulations showed that there was a transfer of the Mulliken charge after the reaction, indicating that all the heavy metals can interact with O, Al, and Si in the LMV; this reaction mainly occurs around the No. 17 O atom of the LMV. The monomers, oxides, and chlorides of Zn/Cr/Cu exhibited better adsorption on vermiculite compared to that of Pb/Cd. [Display omitted] • HMs can be controlled well in PM/MW pyrolysis in fluidized bed by LMV • The addition of LMV can reduce HMs risk and improve HMs forms. • Dopping of PM/MW is not beneficial to hazards reduction of HMs. • HMs react with LMV are mainly concentrated around the No. 17 O atom. • The reactivity of Cr/Zn/Cu with LMV is stronger than those of Cd/Pb. [ABSTRACT FROM AUTHOR]

Published

2024

17. Printability of bio-composite sheets made from paper mill and cardboard mill waste sludge.

Author

Yüce, Hüseyin, Genç, Garip, Sönmez, Sinan, Özden, Öznur, Akgül, Ahmet, and Çetiner, Burcu Nilgün

Subjects

*PAPER mill waste, *PAPER mills, *INDUSTRIAL wastes, *COMPOSITE plates, *WASTE paper, *WASTE recycling

Abstract

Purpose: The purpose of this study is to reveal the usability of waste paper sludge on the production of composite materials and the printability of their surfaces were investigated. Design/methodology/approach: First, composite plates were produced by using dried and milled waste sludge together with polyester resin and epoxy. Screen printing using water, solvent and UV-based inks were carried out. Findings: It was determined that UV and solvent-based inks in both resin groups were permanently attached to the surface of composite plates produced using paper mill waste sludge, while it was found that the adhesion was not achieved sufficiently in cardboard factory waste sludge. Originality/value: The unique aspect of this study is obtained the composite plates from paper mill and cardboard mill waste sludge and improved the printability of them. [ABSTRACT FROM AUTHOR]

Published

2022

18. Response Surface Methodology for Treatment of Paper Mill Wastewater by Using Inorganic Polymeric Coagulant.

Author

Ali, Mohammed Eid M., Abdel Moniem, Shimaa M., Abdelsalam, Hazem, Ammar, Nabila S., and Ibrahim, Hanan S.

Subjects

PAPER mill waste, WASTEWATER treatment, FERRIC chloride, CHEMICAL oxygen demand, RESPONSE surfaces (Statistics)

Abstract

Inorganic polymeric ferric chloride (POFC) coagulant with proposed structure of Fen (Cl2.2OH0.8)n is synthesized using waste materials and characterized by XRD. In the current work scrutinized efficiency of POFC for paper mill wastewater (PMW) treatment using response surface methodology (RSM) with central Composite Design (CCD) modeling. Different factors; dose, rapid mixing speed, and rapid mixing time are used for optimize the coagulation process using POFC for treating PMW. The turbidity and chemical oxygen demand (COD) removals are the indicators for assessing POFC efficiency. The obtained result for XRD confirms the production of new material of inorganic polymeric coagulants. Based on RSM modelling, there is a high correlation between the experimental and predicated removals of turbidity and COD. Subsequently, the model is significantly applied for predicating COD and turbidity removals at different operation condition. Conclusively, the obtained results proposed for practical application of POFC coagulant for treatment of paper mill wastewater for COD and turbidity elimination. Furthermore, the applied RSM with CCD is talented model for optimizing treatment of PMW. [ABSTRACT FROM AUTHOR]

Published

2022

19. Influence of the characteristics of paper mill sludges on their anaerobic digestion.

Author

Courtois, Noemie, Pochard, Isabelle, Remery, Marielle, Hihn, Jean-Yves, and Tourneret, Laurent

Subjects

SEWAGE sludge digestion, FOOD aroma, PAPER mills, PAPER mill waste, GAS chromatography/Mass spectrometry (GC-MS), SLUDGE conditioning, WASTE treatment, ANAEROBIC digestion

Abstract

The objective of this study was to characterise the anaerobic degradation of three paper mill waste water treatment residues in the shape of sludges and to correlate this anaerobic digestion to the physico-chemical characteristics of the paper sludges. After a deep characterisation of each paper sludge in their initial stage, several parameters were analysed on each paper sludge in mesophilic conditions for 40–50 days: pH, conductivity, chemical oxygen demand, total organic acids and organic fibres degradation. A special care was taken to identify and quantify the volatile fatty acids (VFAs) produced by the digestion using gas chromatography coupled with a mass spectrometer. The results showed that in paper sludges, cellulose mainly degrades over time while the degradation of the other fibres (hemicellulose and lignin) is limited. Consequently, the greater the cellulose content in a paper sludge, the greater the digestion and formation of VFAs. However, not all the cellulose degrades because of a shielding effect of lignin on cellulose, and a pH buffering effect of the calcium carbonate present in the paper sludges limits the hydrolysis-acidogenesis step of the anaerobic digestion. Finally, the gas chromatography–mass spectrometry (GC-MS) investigations showed that acetic acid is the main VFA produced by the anaerobic digestion of paper sludges. This work helps predicting paper mill sludge evolution in the purpose of using them in circular economy. [ABSTRACT FROM AUTHOR]

Published

2022

20. The Hyperproduction of Polyhydroxybutyrate Using Bacillus mycoides ICRI89 through Enzymatic Hydrolysis of Affordable Cardboard.

Author

Abdelmalek, Fady, Steinbüchel, Alexander, and Rofeal, Marian

Subjects

*POLYHYDROXYALKANOATES, *POLYHYDROXYBUTYRATE, *PAPER mill waste, *CARDBOARD, *WASTE paper, *BIODEGRADABLE plastics, *BACILLUS (Bacteria)

Abstract

Bioplastics are contemplated as remarkable substitutes for conventional plastics to accommodate green technological advancements. However, their industrial production has not been fully implemented owing to the cost of carbon resources. From another perspective, valorizing different paper mill wastes has become a prominent research topic. These materials may serve as an affording sustainable feedstock for bioplastic production. Adjustment of cardboard waste hydrolysate as suitable fermentation media for production of bacterial polyhydroxyalkanoates (PHAs) has been investigated. Cardboard samples were defibered and dried before enzymatic hydrolysis. The enzymatic degradation of commercial cellulase was monitored over 15 days. Interestingly, 18.2 ± 0.2 g/L glucose yield was obtained from 50 g cardboard samples using a 1.5% (v/v) enzyme concentration. The samples exhibited maximum weight loss values of 69–73%. Meanwhile, five soil samples were collected from local sites in Lodz, Poland. A total of 31 bacterial isolates were screened and cultured on Nile blue plates. Analysis of the 16S rRNA gene sequence of the most potent producer revealed 100% similarity to Bacillus mycoides. Cardboard hydrolysates whole medium, modified MSM with cardboard hydrolysate and nitrogen depleted MSM with cardboard hydrolysate were utilized for PHA production, followed by PHA productivity and cell dry weight (CDW) estimation compared to glucose as a standard carbon source. An impressive PHA accumulation of 56% CDW was attained when the waste hydrolysate was used as a carbon source. FTIR and NMR analysis of the isolated PHA indicated that functional groups of the polymer were related to PHB (polyhydroxybutyrate). Thermal analysis demonstrates that PHB and PHB-CB (PHB produced from cardboard hydrolysate) have degradation temperatures of 380 and 369 °C, respectively, which reflect the high thermal stability and heat resistance compared to the same properties for a standard polymer. This is the first demonstration of full saccharification of corrugated cardboard paper waste for high-level production of PHA. In addition, the attained PHB productivity is one of the highest levels achieved from a real lignocellulosic waste. [ABSTRACT FROM AUTHOR]

Published

2022

21. Cellulose, clay and sodium alginate composites for the removal of methylene blue dye: Experimental and DFT studies.

Author

Kausar, Abida, Rehman, Shafiq Ur, Khalid, Farwa, Bonilla-Petriciolet, Adrián, Mendoza-Castillo, Didilia Ileana, Bhatti, Haq Nawaz, Ibrahim, Sobhy M., and Iqbal, Munawar

Subjects

*SODIUM alginate, *METHYLENE blue, *PAPER mill waste, *CELLULOSE, *POLLUTION remediation, *INDUSTRIAL wastes

Abstract

Cellulose/clay/sodium alginate composites were prepared and employed for the removal of methylene blue (MB) dye. Cellulose was extracted from a paper mill waste and used for composite preparation with sodium alginate (Na-Alg) and clay. MB dye removal was analyzed at different operating conditions (pH, initial concentration, temperature, composite dose). The dye was adsorbed up to 90% for an equilibrium time of 60 min at optimum level of adsorbent dose (0.05 g), temperature (30 °C) and pH (i.e., 7 and 11 for cellulose-Na-Alg and cellulose-Na-Alg-clay, respectively). Kinetics and isotherms of MB adsorption were quantified and modeled. Results showed that MB dye adsorption data followed the pseudo-first order kinetics and a statistical physics model was used to analyze the adsorption mechanism. Thermodynamic calculation revealed that the MB dye adsorption on these composites was an exothermic, spontaneous and feasible process. The composites were regenerated with HCl thus contributing to their reutilization in subsequent adsorption cycles. The DFT (density functional theory) calculations were executed to explain the interactions responsible for the adsorption of MB dye on the composites. Results revealed that the Na-Alg-cellulose composites were effective for the MB dye removal. Therefore, these composites can be considered as low-cost alternative adsorbents for the pollution remediation caused by dyes in industrial effluents. [ABSTRACT FROM AUTHOR]

Published

2022

22. Sustainable Production of Thermostable Laccase from Agro-Residues Waste by Bacillus aquimaris AKRC02.

Author

Kumar, Adarsh, Singh, Ajay Kumar, Bilal, Muhammad, and Chandra, Ram

Subjects

*LACCASE, *PAPER mill waste, *BACILLUS (Bacteria), *POLLUTANTS, *RICE bran, *POTATO waste, *WHEAT bran

Abstract

Laccase is a versatile enzyme that plays a major role in the remediation of various environmental pollutants. In this work, a thermo-tolerant halophilic Bacillus aquimaris AKRC02 was isolated from pulp and paper mill waste sludge for efficient laccase production. Various agro-industrial waste residues, including potato peel, banana peel, sawdust, pea peel, wheat bran, orange peel, and rice bran, were screened to produce laccase using a submerged fermentation process. Among these, rice bran supported the maximum laccase production (4.58 U/mL). The optimized environmental conditions (incubation time 120 h; 4.58 U/mL), 35 0C; 6.624 U/mL) and pH 7.0; 10.142 U/mL) and nutritional sources (glucose 1.0%; 14.164 U/mL and peptone 0.5%; 18.124 U/mL) significantly enhanced the laccase production. Purified laccase showed a specific activity and purification fold of 228.34 U/mg and 38.08, respectively. The purified enzyme showed a molecular weight of 65 kDa and high thermal stability at 45 0C for 8 h. In conclusion, the remarkable properties of the newly isolated bacterium may provide a significant opportunity for degrading environmental contaminants, making it an attractive biocatalyst for industrial applications. [ABSTRACT FROM AUTHOR]

Published

2022

23. Fast pyrolysis of paper sludge in a continuous stirred-tank reactor and liquid-liquid extraction of benzenoid aromatics from fast pyrolysis bio-liquid.

Author

Zhang, Tiantian, Rivas, Álvaro González, Fernandez, Xavier Fragua, Li, Na, Gucho, Eyerusalem, Zhu, Lin, Bijl, Anton, Llacuna, Joan Llorens, and He, Songbo

Subjects

*PAPER mill waste, *X-ray powder diffraction, *FLUORESCENCE spectroscopy, *X-ray fluorescence, *FAST reactors, *LIGNOCELLULOSE, *LIQUID-liquid extraction

Abstract

Paper sludge is a solid waste in paper mills and is conventionally treated by, e.g., landfill, composting, and incineration. Paper sludge contains paper production fillers and lignocellulosic biomass, both of which can be recycled to recover circular minerals and produce bio-based fuels and chemicals by, e.g., thermochemical recycling technology namely fast pyrolysis, for circular bioeconomy. In this paper, three different paper sludge samples collected in The Netherlands and Spain were analyzed by thermogravimetric analysis, moisture analysis, ash analysis, CHNS elemental analysis, powder X-ray diffraction, and X-ray fluorescence spectrometry. Fast pyrolysis of paper sludge was carried out in a lab-scale continuous stirred tank reactor at 500 ± 10 °C with a paper sludge feeding rate of 1 kg h−1. The recovery of circular minerals, which are mainly calcium carbonate, is 87.1 ± 2.2 % (on mineral basis). The yields of fast pyrolysis bio-liquid and biochar are 49.2 ± 6.7 wt% (on biomass basis, equivalent to 23.7 ± 2.2 wt% on paper sludge basis) and 23.8 ± 8.3 wt% (on biomass basis). Fast pyrolysis bio-liquid is a diluted aqueous containing various oxygenates (major, including alcohols, acids, benzenoid aromatics, aldehydes, ketones, ethers, and esters) and hydrocarbons. Liquid-liquid extraction of the fast pyrolysis bio-liquid using CH 3 OH/H 2 O and SO 2 /H 2 O was further performed to obtain an improved bio-liquid with relatively high concentration of the desired bio-based chemicals (namely benzenoid aromatics with the concentration of 53.1–65.9 area%). Both SO 2 /H 2 O and CH 3 OH/H 2 O show high liquid-liquid extraction efficiency to concentrate the benzenoid aromatics for 3.4–11.0 times. This work shows the fast pyrolysis followed by liquid-liquid extraction for the valorization of paper sludge, of which the former has been recently demonstrated on a pilot-scale unit in industry. However, the latter still needs to be further developed by, e.g., focusing on the extraction solvent and continuous liquid-liquid extraction process integrated to fast pyrolysis. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

24. High-efficiency recycling of papermaking wastes for synthesizing carbon/calcium terephthalate composite anodes for potassium-ion batteries.

Author

Zhu, Yongfeng, Zheng, Zhifeng, Khurram, Muhammad Shahzad, Vladimirovich, Vasilevich Sergey, Oboirien, Bilainu, Zhang, Yaning, Mostafa, Ehab, Zhang, Wenli, and Xiong, Qingang

Subjects

PAPER mill waste, ANODES, COST effectiveness, AUTOCATALYSIS, CALCIUM, CALCIUM ions, POLYETHYLENE terephthalate

Abstract

Because of the large ion radius of potassium and sluggish kinetics, high-performance anodes are required to release the horsepower of potassium-ion batteries. Calcium terephthalate emerges as an outstanding anode for potassium-ion batteries, due to its impressive combination of high discharge capacity and cycle stability. However, challenges arise from its intrinsic low conductivity and the reported high cost of calcium terephthalate. To address these issues, this study introduces a novel approach where carbon/calcium terephthalate composite anodes were synthesized to elevate electrochemical performance of potassium-ion batteries, where carbon and calcium terephthalate were completely derived and synthesized from waste polyethylene terephthalate and deinking sludge from a waste paper mill. The composite anodes exhibit remarkable potential as superior materials for potassium-ion batteries, demonstrating comparable performance to lithium-ion batteries using similar anodes as reported in literature. Furthermore, economic analysis underscores cost effectiveness of the proposed synthesis method. Ultimately, this research not only addresses the challenges associated with calcium terephthalate but also opens up the gate to directly utilize papermaking wastes to develop high-performance anode materials for potassium-ion batteries. [Display omitted] • A novel and low-cost way to synthesize CaTPA from papermaking wastes was proposed. • TPA was directly prepared from PET plastics through a simple autocatalytic reaction. • Ca and carbon in C/CaTPA directly came from inorganic and organic components of DS. • C/CaTPA anodes for PIBs show comparable electrochemical performance with LIBs. • This study opens the door to directly utilize papermaking wastes for anodes of PIBs. [ABSTRACT FROM AUTHOR]

Published

2024

25. Bioproduction of Linalool From Paper Mill Waste

Author

Mauro A. Rinaldi, Shirley Tait, Helen S. Toogood, and Nigel S. Scrutton

Subjects

terpenoids, biomanufacturing, paper mill waste, cellulose, linalool, high-value chemicals, Biotechnology, TP248.13-248.65

Abstract

A key challenge in chemicals biomanufacturing is the maintenance of stable, highly productive microbial strains to enable cost-effective fermentation at scale. A “cookie-cutter” approach to microbial engineering is often used to optimize host stability and productivity. This can involve identifying potential limitations in strain characteristics followed by attempts to systematically optimize production strains by targeted engineering. Such targeted approaches however do not always lead to the desired traits. Here, we demonstrate both ‘hit and miss’ outcomes of targeted approaches in attempts to generate a stable Escherichia coli strain for the bioproduction of the monoterpenoid linalool, a fragrance molecule of industrial interest. First, we stabilized linalool production strains by eliminating repetitive sequences responsible for excision of pathway components in plasmid constructs that encode the pathway for linalool production. These optimized pathway constructs were then integrated within the genome of E. coli in three parts to eliminate a need for antibiotics to maintain linalool production. Additional strategies were also employed including: reduction in cytotoxicity of linalool by adaptive laboratory evolution and modification or homologous gene replacement of key bottleneck enzymes GPPS/LinS. Our study highlights that a major factor influencing linalool titres in E. coli is the stability of the genetic construct against excision or similar recombination events. Other factors, such as decreasing linalool cytotoxicity and changing pathway genes, did not lead to improvements in the stability or titres obtained. With the objective of reducing fermentation costs at scale, the use of minimal base medium containing paper mill wastewater secondary paper fiber as sole carbon source was also investigated. This involved simultaneous saccharification and fermentation using either supplemental cellulase blends or by co-expressing secretable cellulases in E. coli containing the stabilized linalool production pathway. Combined, this study has demonstrated a stable method for linalool production using an abundant and low-cost feedstock and improved production strains, providing an important proof-of-concept for chemicals production from paper mill waste streams. For scaled production, optimization will be required, using more holistic approaches that involve further rounds of microbial engineering and fermentation process development.

Published

2022

26. Effect of Environmental Stressors on the Distribution and Abundance of Macroinvertebrates in Upper Awash River at Chilimo Forest, West Shewa, Ethiopia.

Author

Dabessa, Misgana, Lakew, Aschalew, Devi, Prabha, and Teressa, Hirpasa

Subjects

*ANIMAL diversity, *PAPER mill waste, *INVERTEBRATES, *ENVIRONMENTAL indicators, *OXYGEN in water, *AQUATIC invertebrates, *ENVIRONMENTAL protection

Abstract

Ethiopia is experiencing deterioration in river quality resulting in adverse effects on human health and hydrobionts. This study aimed to analyse the effects of specific environmental stressors on the distribution and abundance of macroinvertebrates in the Upper Awash River. The study was conducted from January 2018 to March 2018. Macroinvertebrates were collected from five sites using standard handheld nets. Physicochemical parameters including electrical conductivity, dissolved oxygen, total phosphorous, nitrate-nitrogen, pH, dissolved oxygen and water temperature that can affect the distribution and abundance of macroinvertebrates were assessed. A total of 14,465 individuals belonging to 33 families of insects and 5 families of the noninsect group were identified. Among all recorded taxa, Diptera was the most abundant and diversified order. Macroinvertebrates among the five sites showed variation in species evenness, richness, and Shannon Diversity Index. Values obtained from biotic indices and environmental parameters indicated the presence of organic pollution at different levels. The impacted downstream site paper mill waste (Walgata) had the relatively highest H-FBI index followed by Osole (more agricultural activities) indicating that Walgata and Osole were poorer in benthic faunal diversity than other sites. In addition, as habitat and water quality degradation increased, the number and percentage of Plecoptera, Ephemeroptera, and Trichoptera (EPT) decreased. The selected metrics will be also useful for the monitoring and assessment of the riverine systems and to access the impact of different stressors. As perturbation increased, species diversity, ETHbios index, Average Score Per Taxon, and family richness decreased, while the percentage of Chironomidae, Diptera, Dominant Taxa, and Hilsenhoff Family-Level Biotic Index increased indicating that tolerant species become abundant in degraded river bodies. Environmental protection agencies of governmental and nongovernmental organizations should make awareness for the local people so that they reduce activities that affect the river. Paper factory should also monitor its effluent from directly discharging into the Upper Awash River. [ABSTRACT FROM AUTHOR]

Published

2021

27. The Pearl of Siberia: LAKE BAIKAL.

Author

Buchet, Jennifer

Subjects

LAKES, PAPER mill waste

Abstract

FEATURES One of the earth's most amazing natural wonders - Lake Baikal - lies in southeastern Siberia. It's also home to one of the world's three freshwater seal species, the Baikal seal, or nerpa. Lake Baikal is the oldest and deepest lake in the world. [Extracted from the article]

Published

2022

28. Evaluation of Fly Ash from Co-Combustion of Paper Mill Wastes and Coal as Supplementary Cementitious Materials

Author

Ming-Fu Wu and Wei-Hsing Huang

Subjects

co-combustion, fly ash, solid recovered fuel, paper mill waste, waste-derived fuel, supplementary cementitious materials, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The applications of waste-derived fuel from paper mills in industrial boilers benefit the reduction of carbon emissions. However, the co-combustion of waste-derived fuel and coal causes significant changes in the characteristics of the ash and brings about the need to find possible means of the utilization of the ash produced. In this work fly, ash samples were collected from circulating fluidized bed (CFB) boilers co-combusting paper mill wastes with coal and analyzed in detail. The chemical, physical, and thermal characteristics of two different co-combustion fly ashes (CCFA) were investigated using X-ray fluorescence (XRF), X-ray diffraction (XRD), thermogravimetry (TG), and scanning electron microscope (SEM). The chemical composition of CCFA is largely affected by the fuel source type. Thermal analyses of CCFA show that the type of desulfurization system used by the boiler influences the form of sulfate present in the fly ash. The presence of calcium sulfite hemihydrate can cause a high loss in the ignition of CCFA. By comparing the physical requirements specified in the ASTM standard for coal fly ash to be used in concrete, the CCFA produced from paper mill wastes was found to show good potential as supplementary cementitious materials.

Published

2022

29. Sulu çözeltilerden Cd(II) iyonlarının adsorpsiyonunda kağıt fabrikası çamur atığının karbonizasyonu ile elde edilen karbonun kullanımı.

Author

ER ÇALIŞKAN, Çiğdem and ÇİFTÇİ, Harun

Subjects

*PAPER mill waste, *ADSORPTION isotherms, *LANGMUIR isotherms, *CARBONIZATION, *AQUEOUS solutions, *WATER treatment plant residuals, *ADSORPTION kinetics

Abstract

In this study, in which the adsorption of Cd(II) ions from aqueous solutions with the carbonization product obtained from the carbonization of paper mill waste sludge at different temperatures for two hours, it was observed that the adsorption efficiency increased with the increase of the carbonization temperature. The adsorption efficiency of Cd(II) ions depends largely on the pH of the environment. By contacting the 100 mg/L solution of Cd(II) with the carbonization product at 300, 400 and 500 °C at a dose of 5 g/L for 240 min at pH 5.5, the current Cd(II) ions were 45.3%, 52.4% and 61% removed. These values increased to 56%, 65.3% and 73.4% when the initial concentration of Cd(II) ions was taken as 50 Mg/L. When the dose was applied as 20 g/L for the initial concentration of 100 mg/L, all of the existing Cd (II) ions (except the carbonization product at 300 °C) were adsorbed. The results obtained for each carbonization product were applied to the Langmuir and Freundlich isotherms. The cadmium adsorption kinetics were defined with a second order model and the cadmium adsorption isotherm was determined to fit the Langmuir model better. The applicability of the results to the isotherm equations and the changes in the value of the isotherm constants depending on the carbonization temperature were examined. [ABSTRACT FROM AUTHOR]

Published

2021

30. Paper mill-based integrated nutrition of garden pea in the Eastern Himalayas

Author

RAKESH KUMAR, A THIRUGNANAVEL, NARENDRA KUMAWAT, and BIDYUT C DEKA

Subjects

Economics, Integrated nutrition, Paper mill waste, Pea varieties, Soil health, Agriculture

Abstract

Field experiment was conducted during rabi 2013-14 and 2014-15 to study the effect of paper mill waste integrated nutrition on yield, economics and soil health of garden pea varieties at ICAR-Research Complex for NEH Region, Nagaland Centre, Jharnapani, Nagaland. The experiment was laid out in split plot design and replicated thrice. Maximum seed yields (905 kg/ha), green pod yields (3454 kg/ha), gross return (₹ 108372/ha), net return (₹ 60260/ha) and B: C ratio (2.25) had recorded with Azad pea. Application of paper mill waste @ 1.0 t/ha gave higher yield attributes of garden pea than to its lowers levels. Highest gross return (₹109189/ha) and net return (₹ 57977/ha) was obtained with paper mill waste @ 1.0 t/ha, however the maximum B: C ratio (2.20) was noted in 0.5 t/ha. Significantly higher seed yield (926 kg/ha) and green pod yield (3449 kg/ha) were recorded with application of 100% RDF+25% RDF (ON), which was 53, 13, and 45% higher, respectively over control. Among integrated nutrition, maximum seed yield (977 kg/ha), green pod yield (3646), gross return (₹ 115328/ha), net return (₹ 64616/ha) and B:C ratio (2.28) was noted with 100% RDF + 25% RDF (ON). Soil health attributes, i.e. pH, EC, soil organic carbon; available NPK had improved significantly due to integrated nutrition. Thus, Azad pea could be grown with application of paper mill waste @ 1.0 t/ha along with 100% RDF+25% RDF(ON) for better productivity, profitability and soil health in Eastern Himalayas.

Published

2021

31. Valorisation of toxic paper mill waste through vermicomposting: An insight towards cleaner engineering through alleviation of wastes

Author

Ram Kumar Ganguly and Susanta Kumar Chakraborty

Subjects

Vermicomposting, Enzyme activity, Heavy metals, Paper mill waste, Bioaccumulation, Renewable energy sources, TJ807-830, Environmental engineering, TA170-171

Abstract

Valorisation involves conversion of toxic compounds into value added products. The present study has tried to evaluate the potential of vermicomposting in management of different types of toxic paper mill wastes such as primary waste (VCP) and secondary waste (VCS) using Eisenia fetida for 60 days. The procedure was performed using sundried samples of paper mill wastes, cow dung and straw in different trial sets using different ratios. The study had revealed that the trial sets (VCP1 and VCS1) using ratio of paper mill waste: Cow dung: Straw (5:4:1) were effective in maintaining physiochemical parameters and different population attributes of earthworm. The present study had also demonstrated the enzymatic enrichment of vermicompost in terms of 19 enzymes such as α-Glucosidase, lipase, leucine aminopeptidase etc. in maintenance of C/N ratio of the compost. A significant reduction of heavy metals were noticed in vermicomposting of primary waste (VCP1) as Zn (40%) ​> ​Pb (36%) ​> ​Cr (28%) ​> ​Cu (25%) and secondary waste (VCS1) as Zn (44%) ​> ​Pb (41%) ​> ​Cu (19%) ​> ​Cr (13%). Such reduction of heavy metal was highly correlated with the reduction of C/N ratio of the vermicompost. The process of bioremediation was further manifested through the regular monitoring of bioaccumulation factor (BAF) among earthworm population in vermicomposting of primary waste (VCP1) as Zn (0.40) ​> ​Cu (0.23) ​> ​Cr (0.18) ​> ​Pb (0.11) and secondary waste (VCS1) as Zn (0.47) ​> ​Cu (0.25) ​> ​Cr (0.21) ​> ​Pb (0.14). Therefore, the study concludes that the ratio of paper mill waste, cow dung and straw (5:4:1) can be an efficient formulation in qualitative enrichment of different toxic organic paper mill wastes through vermicomposting.

Published

2021

32. From wastes to functions: A paper mill sludge-based calcium-containing porous biochar adsorbent for phosphorus removal.

Author

Wang, Zhijuan, Miao, Rongrong, Ning, Ping, He, Liang, and Guan, Qingqing

Subjects

*PAPER mill waste, *BIOCHAR, *CARBONIZATION, *SOLID waste, *SLUDGE conditioning, *PHOSPHORUS

Abstract

[Display omitted] • Paper mill sludge-based calcium-containing biochar was cleanly prepared. • The maximum phosphorus adsorption capacity of an as-prepared biochar could be up to 68.49 mg·g−1. • Phosphorus was immobilized onto the as-prepared biochar in the forms of CaHPO 4 and Ca 5 (PO 4) 3 (OH). With the increased awareness of reusing solid wastes for higher sustainability and the concern of water pollution associated with phosphorus over-emission, there are strong interests in developing solid waste based adsorbents for purifying phosphorus-containing wastewater. As a rich calcium resource, paper mill sludge (i.e., a major solid waste from pulping industry) can be used as phosphorus removal adsorbent after calcination. Thus, in this work, a simple and clean thermally treating route has been proposed for preparing calcium-containing biochar from paper mill sludge. The effect of the physicochemical properties of paper mill sludge and its carbonization condition on phosphorus adsorption has been analyzed. Moreover, the influence of some key adsorption parameters, e.g., biochar dosage, initial pH of solution, co-existing anions, initial phosphorus concentration and contact time has also been investigated. The results showed that the phosphorus adsorption data could be fitted well with pseudo-second-order kinetic and Langmuir isothermal models. The calculated maximum adsorption capacity of the as-prepared optimal calcium-containing biochar could reach to 68.49 mg·g−1 at 25 °C. Combined with the characterization results, it can be reasonably inferred that the adsorption process was chemisorption-dominated. Lastly, the application of this spent adsorbent in agriculture field has also been discussed. In brief, this work provided a feasible strategy for converting paper mill solid waste to an environmental functional material (i.e., calcium-rich biochar) for remediation of eutrophic water. [ABSTRACT FROM AUTHOR]

Published

2021

33. Physicochemical Characteristics of Different Pulp and Paper Mill Waste Streams for Hydrothermal Conversion.

Author

Assis, Englatina I. N. C. and Chirwa, Evans M. N.

Subjects

PAPER mill waste, SEWAGE disposal plants, HEALTH risk assessment, HYDROTHERMAL carbonization, BITUMINOUS coal, REFUSE as fuel

Abstract

The pulp and paper industry generates significant amounts of waste from various processes consisting of organic and inorganic matter. Due to its composition, the management of pulp and paper mill sludge presents an economic burden for wastewater treatment plants. In South Africa, paper mill sludge is mainly incinerated, landfilled or used for land application. These practices cause environmental and health hazards. In this study, a process of stabilization of paper mill sludge through hydrothermal carbonization is proposed. The quality of biochar produced and energy yield will depend on the elemental composition, calorific value and ash content of the sludge. Results revealed samples are composed of flat fibrous cellulosic morphology, with high volatile matter and little fixed carbon percentage. The main decomposition occurred between 220-400 °C. Sludge from primary clarifier contains the highest ash percentage, hence it was found to be unsuitable for energy recovery through hydrothermal carbonization. Sludge from kraft and recycling paper mills exhibited lower ash content and higher caloric values, thus more preferable for coal conversion through hydrothermal carbonization. The sludges have a sulfur composition (2.33%) compared to heavy fuel oils and bituminous coal. [ABSTRACT FROM AUTHOR]

Published

2021

34. 造纸固废填埋场的设计.

Author

姜红梅

Subjects

SLUDGE management, PAPER mill waste, SOLID waste, PAPERMAKING, MUD, PAPER mills

Abstract

Copyright of China Pulp & Paper Industry is the property of China Pulp & Paper Industry Publishing House and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

35. The effect of sludge from waste paper industry additon as a filler into composite panel based on polypropylene plastic waste and cocofiber.

Author

Hidayani, Tengku Rachmi, Wirjosentono, Basuki, Yunus, Darwin, Tamrin, Pelita, Elda, Rahmad, Dedy, Mirandaulia, Meutia, Rusmar, Irfan, Sembriring, Seri Bima, Kaban, Jamaran, Marpaung, Lamek, Gea, Saharman, Basyuni, Mohammad, and Mahmud, Taifo

Subjects

*PLASTIC scrap, *WASTE paper, *PAPER mill waste, *POLYPROPYLENE, *WALL panels

Abstract

The aim of this research was to manufacture composite panel that can be used as wall panel for earthquake resistantly building. First stage on wall panel production was done by preparing polypropylene plastic waste, coconut coir fiber, and waste sludge paper mill. The second stage was carried out by mixing polypropylene plastic waste with coconut coir fiber and sludge of paper mill waste. In this research, two mixing variations were carried out. First variation was done by mixing polypropylene plastic waste and coconut fiber in a ratio of 60:40 without adding sludge, while the other was done by mixing sludge, polypropylene plastic waste and coconut fiber with a ratio of 60:20:20. The mixing process was done using extruder and the drying process was done using hot press. Density, internal adhesion values, and thickness extension of resulted composite panels then was characterized. From two variations resulted wall panels were found that the wall panels with sludge addition has better density value of 0.9713 g/cm3 compare to composite panel without sludge addition where its density value of 1.093 g/cm3. In addition, the internal adhesive strength value of the wall panels without sludge addition of 0.59 N/mm2, whereas it improved to 0.61 N/mm2 on panel with sludge addition. Moreover, the thickness of the panel that was produced without sludge addition was 0.508 percent, while panel with sludge addition decreased to 0.104 percent. [ABSTRACT FROM AUTHOR]

Published

2020

36. Pulp and paper mill wastes: utilizations and prospects for high value-added biomaterials.

Author

Haile, Adane, Gelebo, Gemeda Gebino, Tesfaye, Tamrat, Mengie, Wassie, Mebrate, Million Ayele, Abuhay, Amare, and Limeneh, Derseh Yilie

Subjects

PAPER mill waste, PULP mills, PAPER pulp, WASTE recycling, PAPER mills, BIOMATERIALS, SMART materials

Abstract

A wide variety of biomass is available all around the world. Most of the biomass exists as a by-product from manufacturing industries. Pulp and paper mills contribute to a higher amount of these biomasses mostly discarded in the landfills creating an environmental burden. Biomasses from other sources have been used to produce different kinds and grades of biomaterials such as those used in industrial and medical applications. The present review aims to investigate the availability of biomass from pulp and paper mills and show sustainable routes for the production of high value-added biomaterials. The study reveals that using conventional and integrated biorefinery technology the ample variety and quantity of waste generated from pulp and paper mills can be converted into wealth. As per the findings of the current review, it is shown that high-performance carbon fiber and bioplastic can be manufactured from black liquor of pulping waste; the cellulosic waste from sawdust and sludge can be utilized for the synthesis of CNC and regenerated fibers such as viscose rayon and acetate; the mineral-based pulping wastes and fly ash can be used for manufacturing of different kinds of biocomposites. The different biomaterials obtained from the pulp and paper mill biomass can be used for versatile applications including conventional, high performance, and smart materials. Through customization and optimization of the conversion techniques and product manufacturing schemes, a variety of engineering materials can be obtained from pulp and paper mill wastes realizing the current global waste to wealth developmental approach. [ABSTRACT FROM AUTHOR]

Published

2021

37. Impact of Paper Mill effluent on Protein Metabolism of Snake headed fish, Channa punctatus.

Author

Verma, Ashok Kumar and Prakash, Sadguru

Subjects

*PAPER mill waste, *PROTEIN metabolism, *CHANNA, *AMINO acids, *PROTEOLYSIS

Abstract

The present investigation was designed to study the effect of sublethal concentration of paper mill effluent on the total protein and amino acid contents in muscles, liver and gill of Channa punctatus after exposure to 96 hours. A significant decrease in protein content with increase in amino acids content in muscles, liver and gill of effluent exposed fishes was observed. A reduction in the protein content and enhancement of free amino acids in the muscles, liver and gill of experimental fish suggests that the tissue protein might have undergone proteolysis, during the stressful situation. Thus, the present study concludes that the protein metabolism of fish Channa punctatus affected during effluent exposure and reduces the nutritive value of fish. [ABSTRACT FROM AUTHOR]

Published

2021

38. Policies for the Circular Economy: the Case of Paper Industry.

Author

Rizzi, Paolo and Danesi, Sandro

Subjects

PAPER industry, CELLULOSE fibers, WASTE salvage, SUSTAINABLE development, ECO-labeling, PAPER mill waste, MILLS & mill-work, PLANT fibers, COVID-19 pandemic

Published

2021

39. Techno‐economic analysis and a novel assessment technique of paper mill sludge conversion to bioethanol toward sustainable energy production.

Author

Alkasrawi, Malek, Rajangam, Alex S., Tawalbeh, Muhammad, Kafiah, Feras, Al‐Othman, Amani, Al‐Asheh, Sameer, and Sun, Qiang

Subjects

*PAPER mills, *ETHANOL as fuel, *PAPER mill waste, *BIOMASS energy, *SURFACE morphology, *SCANNING electron microscopy, *CORN stover

Abstract

Summary: A novel bioprocess design to convert paper mill sludge (PMS) to biofuels is proposed in this work. The design utilizes cellulosic fiber recovered from the PMS via optimized de‐ashing (HCl washing) step. This work specifically provided a technical and economic analysis of paper mill sludge conversion into biofuel production using a novel protocol. The protocol is based on scanning electron microscopy (SEM) analysis to assess the quality of the contained cellulose prior to further processing. The results are crucially important to determine the suitability of the PMS feedstock to produce biofuels. SEM analysis was employed as a preliminary screening tool to evaluate sludge digestibility and conversion. The SEM characterization technique established a direct relationship between the fiber morphology, presence of crystals salts and sugar yield after enzymatic hydrolysis. Substantial structural changes were observed before and after de‐ashing the sludge samples, leading to a correlation between the surface morphology and the washing step. The results suggested that de‐ashing changes the surface morphology and upon analysis, increased the sugar yield up to about 86% as opposed to 2.2% in sludge sample A as an example. The PMS conversion into biofuel was simulated using Aspen PLUS and compared to a similar process using corn stover as feedstock. The simulation results showed it is 20% cheaper to produce bioethanol from PMS compared to corn stover. The simulation revealed less energy demand by around 13 320 MJ/h compared to that when corn stover was used. [ABSTRACT FROM AUTHOR]

Published

2020

40. Comparative analysis of residual organic pollutants from bleached and unbleached paper mill wastewater and their toxicity on Phaseolus aureus and Tubifex tubifex.

Author

Kumar, Adarsh, Singh, Ajay Kumar, and Chandra, Ram

Subjects

*MUNG bean, *PAPER mills, *PAPER mill waste, *POLLUTANTS, *SEWAGE, *CORAL bleaching

Abstract

The paper industry wastewater even after bio-treatment at industrial scale is a major source of aquatic and soil pollution due to various unknown compounds. Hence, the study has focused on the detection of residual organic pollutants from the bleached and unbleached paper mill wastewater and both sources showed endocrine-disrupting compounds. The toxicity test with Phaseolus aureus seed germination showed inhibition of seed germination and alpha-amylase activity >25% in bleached and unbleached paper mill wastewater. The LC50 of Tubifex tubifex was noted of >50% after 48 hours incubation test. This revealed that the wastewater discharged from bleached paper mill is more toxic than unbleached paper mill waste this might be due to the use of more chemicals during bleaching and pulping process. This study has revealed that there is need to treat both paper mill wastewaters adequately prior to discharge. [ABSTRACT FROM AUTHOR]

Published

2020

41. Shotgun metagenomics of indigenous bacteria collected from the banks of the San Jacinto River for biodegradation of aromatic waste.

Author

Iyer, Rupa and Damania, Ashish

Subjects

*METAGENOMICS, *PAPER mill waste, *SHOTGUN sequencing, *BIODEGRADATION, *RIVERS, *WASTE products, *POLYCHLORINATED biphenyls, COMPREHENSIVE Environmental Response, Compensation & Liability Act of 1980 (U.S.)

Abstract

Several Eastern Harris County communities lie near the now enclosed San Jacinto River (SJR) Waste Pit Superfund, a dumping ground for chlorinated dioxins and other paper mill waste products. Currently, no active monitoring of the SJR is conducted for these toxins with the exact concentration and health impact to the area unknown. As such, remediation and monitoring efforts outside of the Superfund itself could be necessary. To better understand the possible environmental fate of these aromatics, here we provide a shotgun metagenomic analysis of the structural and putative functional diversity of the SJR microbiome from two impacted Channelview, Texas communities bordering the Superfund. Results show that the underlying SJR microbiome possesses a core of metabolic enzymes related to the β-ketoadipate and benzoate degradation pathways. This suggests possible endpoints for many aromatics found deposited in the SJR including dioxin-like compounds. However, degradation biomarkers related to the priming and initial cleavage of chlorinated dioxin-like aromatics while present, are poorly concentrated across sampled sites. This may be due in part to decreased coverage of low abundance bacterial species, but also be a contributing factor leading to increased recalcitrance of these compounds in this environment compared to other aromatics. [ABSTRACT FROM AUTHOR]

Published

2020

42. The use of calcined paper mill sludge as a chemical precipitant in the simultaneous removal of ammonium and phosphate − paper mill waste recycling and reuse.

Author

Myllymäki, Pekka, Pesonen, Janne, Romar, Henrik, Tao Hu, Tynjälä, Pekka, and Lassi, Ulla

Subjects

PAPER recycling, WASTE recycling, PAPER mills, PAPER mill waste, AMMONIUM phosphates, AMMONIUM, PHOSPHATES, PHOSPHATE removal (Water purification)

Abstract

Currently, recycling and re-use of materials is extremely important due to the diminishing of natural resources. The objective of the European Union’s circular economy strategy is to increase recycling and the use of industrial waste materials and side streams as secondary raw materials. In this study, a chemical precipitation method to simultaneously remove ammonium nitrogen and phosphate from the liquid phase of anaerobic digestate using calcined paper mill sludge was studied. Papermill sludge is a waste material that forms in the paper-making process. In addition, commercial calcium oxide (CaO) was used as a reference precipitant. The suitability of the formed precipitate’s composition for recycled fertilizer use was also considered. The study results indicated that calcined paper mill sludge was as effective precipitant as commercial CaO in the removal of ammonium nitrogen and phosphate from the synthetic wastewater. In addition, the results indicated that calcined paper mill sludge removed efficiently phosphate from the liquid phase of anaerobic digestate, which led to the formation of hydroxyapatite, Ca5(PO4 )3 (OH). In this research we have shown, that calcined paper mill sludge can be used to produce recycled, slow-release, solid fertilizer. Another possible reaction, such as adsorption was also considered. [ABSTRACT FROM AUTHOR]

Published

2020

43. Environmental impacts and limitations of third‐generation biobutanol: Life cycle assessment of n‐butanol produced by genetically engineered cyanobacteria.

Author

Nilsson, Astrid, Shabestary, Kiyan, Brandão, Miguel, and Hudson, Elton P.

Subjects

*BUTANOL, *BIOBUTANOL, *CYANOBACTERIA, *FOSSIL fuels, *PAPER mill waste, *CLOSTRIDIUM acetobutylicum, *WASTE heat, *ETHANOL as fuel

Abstract

Photosynthetic cyanobacteria have attracted interest as production organisms for third‐generation biofuels, where sunlight and CO2 are used by microbes directly to synthesize fuel molecules. A particularly suitable biofuel is n‐butanol, and there have been several laboratory reports of genetically engineered photosynthetic cyanobacteria capable of synthesizing and secreting n‐butanol. This work evaluates the environmental impacts and cumulative energy demand (CED) of cyanobacteria‐produced n‐butanol through a cradle‐to‐grave consequential life cycle assessment (LCA). A hypothetical production plant in northern Sweden (area 1 ha, producing 5–85 m3n‐butanol per year) was considered, and a range of cultivation formats and cellular productivity scenarios assessed. Depending on the scenario, greenhouse gas emissions (GHGe) ranged from 16.9 to 58.6 gCO2eq/MJBuOH and the CED from 3.8 to 13 MJ/MJBuOH. Only with the assumption of a nearby paper mill to supply waste sources for heat and CO2 was the sustainability requirement of at least 60% GHGe savings compared to fossil fuels reached, though placement in northern Sweden reduced energy needed for reactor cooling. A high CED in all scenarios shows that significant metabolic engineering is necessary, such as a carbon partitioning of >90% to n‐butanol, as well as improved light utilization, to begin to displace fossil fuels or even first‐ and second‐generation bioethanol. [ABSTRACT FROM AUTHOR]

Published

2020

44. Impact of Eisenia fetida populations on bio-conversion of paper mill solid wastes.

Author

Mohapatra, Devjani, Sahoo, K. K., and Sannigrahi, A. K.

Subjects

VERMICOMPOSTING, PAPER mill waste, EISENIA, ORGANIC wastes, SOLID waste, PLANT nutrients

Abstract

Purpose: Huge quantity of paper mill wastes are dumped at the outskirt of factory as unwanted materials. Vermicomposting is an eco-friendly technique for beneficial conversion of different biodegradable/organic wastes into useful organic manure utilizing earthworms. Solid wastes generated in paper mills contain appreciable quantity of organic matter. Attempt was made for bio-conversion of Emami paper mill wastes with different numbers of Eisenia fetida (5–30 earthworms/2 kg substrate) for studying its influence on vermi-conversing time and quality of prepared vermicompost. Method: Vermicomposting was carried out in trays following heap method and quality of final product was determined following both chemical analysis and bioassay on wheat seedlings. Results: Application of more earthworms up to 20 numbers per 2 kg substrate made bio-conversion quicker but further addition of earthworm, however, delayed the process as some earthworms came out of beds and died probably due to competition for food among earthworms inside beds. Ten earthworms per kg paper mill wastes–saw dust–cow dung mixture (1:0.5:0.5 weight wise) was found as optimum earthworm population for preparing quality vermicompost having more major and secondary plant nutrients. Bioassay of this manure on wheat seedlings also confirmed the analytical findings. Conclusion: It is confirmed that earthworm population in vermibed played vital role in faster decomposition of paper mill wastes and releasing of more nutrients, which ultimately helped in better growth of wheat seedlings. Successful demonstration of vermicomposting technique will encourage local farmers for beneficial utilization of paper mill wastes in their agriculture. [ABSTRACT FROM AUTHOR]

Published

2019

45. Calcium peroxide induced mechanical disintegration in acidic environment for efficient biogas and biopolymer generation from paper mill sludge.

Author

Preethi, Rajesh Banu, J., Kumar, Gopalakrishnan, and Gunasekaran, M.

Subjects

*BIOGAS production, *PAPER mill waste, *BIOGAS, *CHEMICAL oxygen demand, *PAPER mills, *PEROXIDES, *BIOCHEMICAL oxygen demand

Abstract

[Display omitted] • Calcium peroxide mediated disperser disintegration is a novel approach. • Acidic-calcium peroxide mediated disperser method solubilizes organics efficiently. • Bacillus aryabhattai amasses 85% polyhydroxybutyrate using pretreated sample. • Pretreated settled sludge yields 167 mL/g chemical oxygen demand of biogas. The proposed research envisioned to improve the accessibility of organics and hydrolysis of paper mill waste activated sludge for polyhydroxybutyrate production and anaerobic digestion. In order to fill this research gap an exploration has been made by adding lower dosage of calcium peroxide at acidic pH for the removal of exopolymeric substances thereby improving the disintegration efficacy. The results indicate that the calcium peroxide dosage of 0.06 g/g SS at pH 5 was optimum for floc fragmentation. The influence of floc fragmented sludge on disintegration by disperser shows the solubilization and solid decrement of 18.8% and 12.4% at the specific energy input of 4729.24 kJ/kg total solid. The impact of pretreated supernatant on polyhydroxybutyrate accumulation shows the maximum polyhydroxybutyrate content of 85.03 % while utilizing 60% (v/v) of pretreated sludge supernatant as a carbon source at 42 h. Subsequently, the settled sludge was directed towards an anaerobic biodegradability assay and found about 167 mL/g of chemical oxygen demand of biogas generation, which is higher than the crude sample (52 mL/g of chemical oxygen demand). The higher solubilization in pretreated sample reveals the easier accessibility of substrate by the microorganisms, thereby enhances bioenergy and valued product generation. [ABSTRACT FROM AUTHOR]

Published

2024

46. Synthesis of magnetic biochar-supported Fe-Cu bimetallic catalyst from pulp and paper mill wastes for the Fenton-like removal of rhodamine B dye.

Author

Shen, Yuehao, Xiao, Yuxin, Zhang, Hongjie, Fan, Hongjie, Li, Yao, Yan, Zhongli, and Zhang, Wen-Hui

Subjects

*PAPER mill waste, *BIMETALLIC catalysts, *RHODAMINE B, *IRON oxides, *PAPER pulp, *PULP mills, *WATER treatment plant residuals

Abstract

[Display omitted] • FeCu@BC catalysts were synthesized using a simple one-step pyrolysis method. • FeCu@BC 600-2 exhibited good magnetic separation ability and excellent reusability. • The synergistic effect of Fe 3 O 4 , Cu0 and Biochar maintains high RhB removal. • Key ROS involves •OH at pH 3, and •OH and 1O 2 at pH 7, respectively. • sp2 C = C in biochar and Cu(I) from Cu0 facilitated the reduction of Fe(III) Treating the wastes generated from pulp and paper mills, such as black liquor and Fenton sludge is challenging. In this study, the biochar-supported Fe-Cu bimetallic catalysts were synthesized by a one-step pyrolysis method using Fenton sludge as iron source, acid-precipitated black liquor (APBL) as carbon source and copper nitrate as copper source. The catalysts were used to remove rhodamine B (RhB) dye from aqueous solution by Fenton-like reaction. The optimal catalyst (FeCu@BC 600-2) was pyrolyzed at 600 °C with an Fe/Cu mixing ratio of 2 and consisted of mesoporous biochar supported nanoscale Fe 3 O 4 and Cu0. It had a specific surface area of 104.6 m2·g−1 and a saturation magnetization of 33.3 emu·g−1. In the FeCu@BC 600-2 /H 2 O 2 system, RhB dye (10 mg·L-1) was completely removed within 60 min at acidic pH (initial pH 3, 0.2 g·L-1 catalyst, 1 mM H 2 O 2) or 6 h at neutral pH (initial pH 7, 0.25 g·L-1 catalyst, 25 mM H 2 O 2) at 30 °C. Moreover, the FeCu@BC 600-2 exhibited good magnetic separation ability, low metal leaching, excellent reusability and broad applicability to other synthetic dyes. The dye removal mechanism involved the synergistic effect of adsorption and catalytic oxidation (especially heterogeneous catalytic oxidation). At acidic pH, RhB degradation was due to •OH radical, which was generated from the activation of H 2 O 2 by ≡Cu(I) or Cu(I) oxidized from Cu0 and ≡Fe(II) in Fe 3 O 4. At neutral pH, RhB degradation was mainly due to •OH and 1O 2 with the former being produced by ≡Cu(I) and ≡Fe(II). Furthermore, Cu(I) oxidized from Cu0 and the active functional groups (such as sp2 C = C) in the biochar facilitated the reduction of Fe(III) to Fe(II), resulting in a high catalytic oxidation efficiency. [ABSTRACT FROM AUTHOR]

Published

2023

47. LAB SCALE STUDY ON CHARACTERIZATION AND IDENTIFICATION OF PHENOL DEGRADING BACTERIA ISOLATED FROM PULP AND PAPER MILL EFFLUENT.

Author

Sachan, Preeti, Madan, Sangeeta, Hussain, Athar, and Singh, Utkarsh

Subjects

PAPER mill waste, BACTERIAL typing, WATER quality, WASTEWATER treatment, RIBOSOMAL RNA

Abstract

The untreated effluents from paper mills discharged into water bodies, damages the water quality and living organisms. Due to several limitations in the physicochemical treatment methods for treating industrial wastewaters the biological methods are more favourable alternative for the removal of pollutants. In the present study, phenol degrading activity by bacterial isolates collected from industrial effluent has been investigated. The isolated strains were further characterized by morphological, physiological, biochemical and 16S rRNA gene analysis. Isolates as Staphylococcus sp. (MH935803) and Staphylococcus sciuri (MH938044), has been identified in the present study. These two isolates have been identified as novel and potential aerobic bacterial strains that showed maximum survival in the phenol concentration up to 1600 mg/L and 1800 mg/L respectively. Further these strains may be used for biodegradation of phenol containing pulp and paper mill effluent. The study focuses on the characterization of efficient phenol degrading bacteria found in pulp and paper mill effluent which can be considered for use in large scale biorefining. [ABSTRACT FROM AUTHOR]

Published

2019

48. POTENCY OF PAPER MILL WASTE AS RECYCLABLE POLYPROPYLENE FILLED WITH COCONUT FIBER COMPOSITE FOR MITIGATIONAL MATERIAL.

Author

Pelita, Elda, Hidayani, Tengku Rachmi, and Rahmad, Dedy

Subjects

*PAPER mill waste, *COMPOSITE materials, *FIBROUS composites, *WALL panels, *COCONUT

Abstract

Regarding its geographical location, West Sumatra is an area prone to earthquakes. The solution to this condition is by mitigating the effects through the construction of earthquake-resistant buildings. Earthquake-resistant buildings may be constructed by replacing polymeric materials with characteristics of light, durable and good flexibilities. One of which by replacing stone as common building structure with composite material. Composite wall panels that are expected to be utilized to construct a resistant building, are made by mixing polypropylene plastic waste with coconut fiber and primary sludge from paper mill waste. The mixing method was performed using an extruder (dry mixing with heat). Composition of coconut fiber, primary sludge, and paper mill waste were 20:20:60, respectively based on the previous study. Method for casting composite wall panels was performed using hot-press. The composite wall panels showed a flexural properties of 9.6 N/mm², modulus of elasticity of 2,640 N/mm², melt temperature at 161.21°C, combustion point at 463.55oC, decomposition point at 476.99°C, carbon residue of 15.1%, density of 1.093 g/cm³, thickness swelling of 0.104%, internal bond strength of 0.61 N/mm², a good morphochemical interaction and following EN 634-2-2007 standard. [ABSTRACT FROM AUTHOR]

Published

2019

49. Sustainable utilization of paper mill solid wastes via synthesis of nano silica for production of belite based clinker.

Author

Vashistha, Prabhat, Singh, S.K., Dutt, Dharm, and Kumar, Vivek

Subjects

*SOLID waste, *PAPER mill waste, *FLY ash, *INDUSTRIAL wastes, *SILICA, *RAW materials

Abstract

The industrial solid waste generation and its stockpile disposal have major environmental consequences. These consequences could be minimized through the solid waste application as a raw material in other industries. The current study focusses on the utilization of lime sludge with boiler ash synthesized nanosilica for production of belite based clinker at relatively lower temperature. Lime sludge was also used in combination with fly ash and boiler ash to check the synthesis of compounds at varying temperatures. Nanosilica was synthesized from pretreated boiler ash through alkali treatment and acid precipitation. The synthesized nanosilica has been characterized for specific surface area, crystallinity, surface functional groups and size. Three different mixtures, containing lime sludge with nanosilica, fly ash, and boiler ash are fired at temperatures ranging from 900 °C to 1200 °C and characterized for the synthesis of belite. Conventionally, belite is synthesized above 1200 °C, whereas the combined application of lime sludge and nanosilica reduces the temperature of belite synthesis to 900 °C without pre calcination or addition of any chemical stabilizer. In the case of lime sludge and boiler ash blend, belite formation takes place at the higher temperature (1100–1200 °C). Anorthite synthesis takes place in case of lime sludge and fly ash blend, due to high percentage of alumina present in fly ash. Lime sludge and nanosilica based belite clinker are used to develop newer cementitious binder. Hydration and strength properties of developed binder proved worthy as building materials. This study will present alternatives for sustainable utilization of lime sludge, fly ash and boiler ash in construction. Image 1079591 • Nano silica is synthesized from boiler ash. • Lime sludge and Nanosilica are utilized for belite based clinker synthesis at low temperature. • Blends of lime sludge with boiler ash and fly ash are also checked for clinker synthesis. • The binder is prepared for the product development from synthesized belite clinker. • This prepared binder is tested for hydration and strength properties and found sustainable. [ABSTRACT FROM AUTHOR]

Published

2019

50. Heavy metal uptake by water lettuce (Pistia stratiotes L.) from paper mill effluent (PME): experimental and prediction modeling studies.

Author

Kumar, Vinod, Singh, Jogendra, and Kumar, Pankaj

Subjects

WATER lettuce, PAPER mill waste, BIOACCUMULATION, HEAVY metal toxicology, HEAVY metals & the environment

Abstract

The present paper reports the heavy metal uptake by water lettuce (Pistia stratiotes L.) from paper mill effluent (PME) with its prediction modeling studies. Lab scale phytoremediation experiments were performed in glass aquariums to grow P. stratiotes in 0% (bore well water as a control), 25%, 50%, 75%, and 100% concentrations of PME. The influence of pH and heavy metal concentration in PME for the effective uptake and accumulation of heavy metal contents (∆Y: mg/kg) in plant tissues was modeled using two-factor multiple linear regression. The results showed that the selected input variables were supportive to develop prediction models with higher linear regression (R2 > 0.72), high model efficiency (ME: 0.92–0.99), low mean average normalizing error (MANE < 0.02), and statistically significant F > Prob values. Kruskal-Wallis one-way post hoc test indicated that the contents of Cd, Cu, Fe, Pb, and Zn in the roots, leaves, and whole plant were affected by PME concentration while the contents of Mn did not. The correlation studies showed that the bioaccumulation of heavy metals was found both element and PME concentration specific. This work represents an effective method to model heavy metal uptake by P. stratiotes from PME. Furthermore, this methodology can also be adopted for predicting effective metal uptake by plant species being used for the phytoremediation of heavy metals from industrial effluents. [ABSTRACT FROM AUTHOR]

Published

2019