Process intensification in catalytic wet air oxidation of phenol via coupling gas‐liquid microdispersion with trickle bed reactors

Tan, Jing; Nie, Miaomiao; Li, Zhikang; Ji, Yunpeng; Chen, Shijie; Deng, Wensheng; Chen, Lai; Lü, Yun; Su, Yuefeng

doi:10.1002/amp2.10029

J Adv Manuf & Process

2019

DOI: 10.1002/amp2.10029

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Process intensification in catalytic wet air oxidation of phenol via coupling gas‐liquid microdispersion with trickle bed reactors

Jing Tan

Miaomiao Nie

Zhikang Li

et al.

Abstract: Intensified trickle bed reactors were developed for catalytic wet air oxidation (CWAO) of phenol, by generating microbubbles before gas/liquid fluid flows along catalyst packed-beds. By coupling gas-liquid microdispersion module, phenol disappearance rate significantly increases under the same operating conditions and phenol conversion reaches 92% in 22 seconds at 160 C and 1000 kPa. Effects of operating conditions were studied systematically and results demonstrated characteristics of high-interaction regime … Show more

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Cited by 5 publications

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“…We look forward to more articles that connect process analysis with life cycle assessment using explicit process modeling and connecting advanced manufacturing with societal well-being. [2] Another important theme for the journal has been the design and study of modular and intensified processes, [10][11][12][13] and the technologies that can support them, such as 3D printing and other additive manufacturing techniques. [14] Neal et al [11] propose a modular ethane-to-liquids system based on using chemical looping oxidative dehydrogenation technology to convert ethane and natural gas liquids via cyclic redox reactions of highly effective redox catalyst particles.…”

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confidence: 99%

“…It provides a simplified process scheme and energy reduction. Tan et al [12] describe a method to improve the catalytic wet air oxidation of phenol in a trickle bed reactor by using a gas microdispersion unit. Maußner et al [10] propose a flexible chemical reactor design strategy to enable the use of multiple different bio-based feedstocks to produce a desired product.…”

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Welcome to the second year of the Journal of Advanced Manufacturing and Processing

Park

Lerou

Rinker

2019

J Adv Manuf & Process

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mentioning

confidence: 99%

mentioning

confidence: 99%

Welcome to the second year of the Journal of Advanced Manufacturing and Processing

Park

Lerou

Rinker

2019

J Adv Manuf & Process

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Process Intensification in Gas–Liquid Mass Transfer by Modification of Reactor Design: A Review

Zhang

Song

et al. 2023

Energy Tech

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Increasing greenhouse gas (GHG) emissions is a major issue facing the global environment and the public. This increase is due to accelerating industrial development and rising emissions of gases, including carbon dioxide (CO 2 ), methane (CH 4 ), and nitrogen oxides (NO x ). These gases are believed to be the source of global warming. [1] According to the Intergovernmental Panel on Climate Change (IPCC), total GHGs need to be reduced by 50-80% by 2050 to avoid extreme consequences. [2] Therefore, gas removal needs to be improved. In the late 1970s, a new method was developed, namely, carbon capture and storage (CCS), as an effective way to avoid CO 2 emissions into the atmosphere. In addition, H 2 absorption is required for microbial conversion to CH 4 . H 2 -liquid mass transfer limits the rate of biomethanation reactions due to the low H 2 distribution in solution that limits its solubility and, thus, its availability to methanogens. The development of biomethanation technology needs to focus on H 2 -liquid mass transfer to develop large biomethanation capacity. Therefore, an in-depth understanding of process design and operating conditions that affect H 2liquid mass transfer is necessary. In addition to, methane is the main component of natural gas and shale gas, accounting for 90% of the total abundance. [3,4] Thus, as one of the most widely used high-energy resources on earth, methane is considered as the next generation of carbon feedstock. Nevertheless, methane is a nonpolar gas, and its low solubility in solution hinders efficient mass transfer. Therefore, it is necessary to overcome these limitations to achieve high methane conversion. [5][6][7] To the best of our knowledge, as low-cost green oxidant, oxygen is widely used in microbial growth and product synthesis. [8] However, oxygen is less soluble in aqueous solution. At 294.15 K and 1 bar, the dissolved oxygen content of pure water is only 9.2 mg L À1 . [9] Therefore, it is a great challenge for reactor engineering to improve the oxygen transfer capacity of the equipment to meet the needs of the reaction.Ozonation is one of the most widely used advanced oxidation processes (AOPs), which has been applied to treat various types of organic wastewater. However, the equilibrium concentration and mass transfer efficiency of ozone in water are limited, leading to the poor ozone utilization. [10] Therefore, it is necessary to find effective methods to enhance ozone-liquid mass transfer.As deduced in the above finding, new approaches are needed to deal with the pointed out these limitations.Process reinforcement is an important part of the varied aspects of chemical science and engineering. [11] It allows for resource maximization and does more with less. [12] As shown in Table 1, the more and the less were summarized. [13] Mass transfer between gas and liquid is widely used in chemical engineering. It is closely correlated with reaction engineering, separation engineering, and many branches of chemical engineering. The rate and efficiency of mass transfer de...

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Microbubbles intensification and mechanism of wet air oxidation process of MDEA-containing wastewater

Zhao

Liu

Zhang

et al. 2021

Environmental Technology

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Process intensification in catalytic wet air oxidation of phenol via coupling gas‐liquid microdispersion with trickle bed reactors

Cited by 5 publications

References 47 publications

Welcome to the second year of the Journal of Advanced Manufacturing and Processing

Welcome to the second year of the Journal of Advanced Manufacturing and Processing

Process Intensification in Gas–Liquid Mass Transfer by Modification of Reactor Design: A Review

Microbubbles intensification and mechanism of wet air oxidation process of MDEA-containing wastewater

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