Novel mechanical vapor recompression‐assisted evaporation process for improving energy efficiency in pulp and paper industry

Kim, Yurim; Lim, Jonghun; Cho, Hyungtae; Kim, Junghwan

doi:10.1002/er.7390

Cited by 20 publications

(4 citation statements)

References 32 publications

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“…[181][182][183][184][185][186][187] As a result, developing a strategy to address these issues that is both efficient and affordable has been difficult. Therefore, compared to landfilling and incineration, recycling technology not only minimizes toxic elements and waste pollution on the environment, [188][189][190] but it can also produce novel products with good mechanical and physical features. Due to their processing-related blending with other plastics and additives, these materials are not simple to recycle.…”

Section: R E V I E W T H E C H E M I C a L R E C O R Dmentioning

confidence: 99%

Electrochemical C−H/C−C Bond Oxygenation: A Potential Technology for Plastic Depolymerization

Rani,

Aslam,

Lal

et al. 2023

The Chemical Record

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Herein, we provide eco‐friendly and safely operated electrocatalytic methods for the selective oxidation directly or with water, air, light, metal catalyst or other mediators serving as the only oxygen supply. Heavy metals, stoichiometric chemical oxidants, or harsh conditions were drawbacks of earlier oxidative cleavage techniques. It has recently come to light that a crucial stage in the deconstruction of plastic waste and the utilization of biomass is the selective activation of inert C(sp3)−C/H(sp3) bonds, which continues to be a significant obstacle in the chemical upcycling of resistant polyolefin waste. An appealing alternative to chemical oxidations using oxygen and catalysts is direct or indirect electrochemical conversion. An essential transition in the chemical and pharmaceutical industries is the electrochemical oxidation of C−H/C−C bonds. In this review, we discuss cutting‐edge approaches to chemically recycle commercial plastics and feasible C−C/C−H bonds oxygenation routes for industrial scale‐up.

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Section: R E V I E W T H E C H E M I C a L R E C O R Dmentioning

confidence: 99%

Electrochemical C−H/C−C Bond Oxygenation: A Potential Technology for Plastic Depolymerization

Rani,

Aslam,

Lal

et al. 2023

The Chemical Record

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“…18 It can be calculated by dividing the TCI by the net present value of the annuity factor (AF). 21 EAC…”

Section: Total Cost Of Electrostatic Precipitatormentioning

confidence: 99%

Novel waste heat and oil recovery system in the finishing treatment of the textile process for cleaner production with economic improvement

Lim

Lee

Cho

et al. 2022

Intl J of Energy Research

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Summary In the textile industry, reactive dyeing requires large volumes of hot water, which increases cost and energy consumption. Although the waste heat of the exhaust gas from the stentering process can be recovered to reduce cost and energy consumption, fiber dust and oil mist inside the exhaust gas cause problems such as fouling and clogged pores. Hence, a novel waste heat and oil recovery system in the finishing treatment of the textile process is proposed for cleaner production with economic improvement. The proposed system comprises the following steps: (a) The exhaust gas is split by the electrostatic precipitator (ESP) at a certain ratio through optimization as its exhaust gas throughput is a key deciding variable for cost and profit. (b) A mathematical model of the overall cost, including profits from oil recovery and energy savings attributed to waste heat recovery, total capital investment, and total product cost attributed to the additional ESP installation, is designed to identify an optimal split ratio. (c) Fiber dust and oil mist are removed from the exhaust gas split at the optimal ratio using the ESP and then recycled as regenerated oil. Waste heat is recovered from the treated gas after the fiber dust and oil mist are recovered as regenerated oil through the heat exchange in the air to water heat exchanger; this recovered heat is supplied to the dyeing process to minimize the energy required for heating the water. (d) Finally, VOCs and the remaining pollutants are removed by activated carbon adsorption from the low‐temperature‐treated gas after the waste heat is recovered. These processes recover waste heat and oil and achieve process stability and efficiency improvements because of the removal of oil mist, fiber dust, and VOCs. As a result, the overall cost can be reduced by 10.2% based on the recovered waste heat and oil, and the fiber dusts, odor, and VOCs are removed by 95%, 89.86%, and 96.28%, respectively.

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“…Such an arrangement is termed Mechanical Vapor Recompression (MVR); being a kind of heat pump, it is gradually being applied in distillation processes [10,11] and evaporators [12,13]. It can facilitate both evaporation operation cost decreases and unit capacity increases, both effects being desired in industrial conditions [14,15].…”

Section: Introductionmentioning

confidence: 99%

Enhancing the Energy Efficiency of a Black Liquor Evaporation Plant by Mechanical Vapor Recompression Integration

Variny

2023

Ecp 2023

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Novel mechanical vapor recompression‐assisted evaporation process for improving energy efficiency in pulp and paper industry

Cited by 20 publications

References 32 publications

Electrochemical C−H/C−C Bond Oxygenation: A Potential Technology for Plastic Depolymerization

Electrochemical C−H/C−C Bond Oxygenation: A Potential Technology for Plastic Depolymerization

Novel waste heat and oil recovery system in the finishing treatment of the textile process for cleaner production with economic improvement

Enhancing the Energy Efficiency of a Black Liquor Evaporation Plant by Mechanical Vapor Recompression Integration

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