Design and Control of Reactive Distillation Process for the Production of Methyl Valerate

Chen, Cheng-Liang; Chung, Yi‐Chang; Lee, Hao‐Yeh

doi:10.1021/acs.iecr.5b03495

Cited by 20 publications

(10 citation statements)

References 15 publications

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“…In their control strategy, the feed ratio is manipulated by the sensitive tray temperature of the RD column; however, the reflux rate of the RD column is ratioed to the sum of the two feed flow rates (F L /SF) instead of the fixed β L . Their results demonstrate that the product purities can be controlled at their respective specifications with smaller offsets using both control schemes with fixed β L or F L /SF; however, relatively large transient deviations occur in the dynamic responses of the product purities for the control strategy proposed by Chen et al 49 By referring to the previous relevant works, 48,49 the sensitive tray temperature of the RD column of RDWC is used to manipulate the molar flow rate ratio of the n-propanol feed to acetic acid feed (F R ), while the sensitive tray temperature of the product column of RWDC is used to manipulate its reboiler duty (Q R-PC ). The open-loop sensitivity analysis is implemented to select the sensitive tray temperatures of the RD and product columns by introducing ±0.1% step change in each manipulated variable while keeping the others at their nominal steady-state values.…”

Section: Plant-wide Control Schemementioning

confidence: 99%

Section: Plant-wide Control Schemementioning

confidence: 99%

“…48 proposed a control structure for a thermally coupled RD process for the esterification of acetic acid and isopropanol, wherein the feed ratio is manipulated by the sensitive tray temperature of the RD column while β L is fixed. Chen et al 49 investigated the control performance of a thermally coupled RD process for producing methyl valerate. In their control strategy, the feed ratio is manipulated by the sensitive tray temperature of the RD column; however, the reflux rate of the RD column is ratioed to the sum of the two feed flow rates (F L /SF) instead of the fixed β L .…”

Section: Plant-wide Control Schemementioning

confidence: 99%

“…By referring to the previous relevant works, , the sensitive tray temperature of the RD column of RDWC is used to manipulate the molar flow rate ratio of the n -propanol feed to acetic acid feed ( F R ), while the sensitive tray temperature of the product column of RWDC is used to manipulate its reboiler duty ( Q R‑PC ). The open-loop sensitivity analysis is implemented to select the sensitive tray temperatures of the RD and product columns by introducing ±0.1% step change in each manipulated variable while keeping the others at their nominal steady-state values.…”

Section: Plant-wide Control Schemementioning

confidence: 99%

See 3 more Smart Citations

Process Development, Assessment, and Control of Reactive Dividing-Wall Column with Vapor Recompression for Producing n-Propyl Acetate

Feng

Shen

Rangaiah

et al. 2018

Ind. Eng. Chem. Res.

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As a combination of the conventional reactive distillation (RD) and diving-wall column, reactive diving-wall column (RDWC) is the highly thermally integrated process that has the advantages of higher thermodynamic efficiency, lower capital cost, and smaller equipment size. In this study, the conceptual design of four different RD processes, i.e., the conventional RD, RDWC, heat-integrated RDWC (HIRDWC), and vapor recompression heat-pump-assisted RDWC (VRHP-RDWC), was presented for the production of n-propyl acetate via the esterification of n-propanol with acetic acid. The results indicate that compared with that of conventional RD process the total annual cost of RDWC, HIRDWC, and VRHP-RDWC intensified processes is reduced by 10.44, 19.40, and 74.54%, respectively, while their thermodynamic efficiency is 9.96, 15.52, and 25.53%, respectively, which are also significantly higher than that of conventional RD process (9.25%). Subsequently, since the VRHP-RDWC process exhibits the most favorable performance for intensifying the conventional RD process, two alternative control strategies were developed and assessed for the operation of VRHP-RDWC. Control performances demonstrate that the challenging VRHP-RDWC process can be operated smoothly under large disturbances of feed flow rate, water impurity in acetic acid feed, and n-propanol feed as well as for set-point changes in temperature controllers.

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Section: Plant-wide Control Schemementioning

confidence: 99%

Section: Plant-wide Control Schemementioning

confidence: 99%

Section: Plant-wide Control Schemementioning

confidence: 99%

Section: Plant-wide Control Schemementioning

confidence: 99%

See 2 more Smart Citations

Process Development, Assessment, and Control of Reactive Dividing-Wall Column with Vapor Recompression for Producing n-Propyl Acetate

Feng

Shen

Rangaiah

et al. 2018

Ind. Eng. Chem. Res.

View full text Add to dashboard Cite

show abstract

“…In general, the higher degree of integration will make the process more challenging to control and will perhaps restrict the implementation of highly intensified processes in industry [7]. Many of the published works on control design for intensified processes deal with reactive distillation (see, e.g., [10,[13][14][15]), but reported work in the area of solids 1 http://ibd-project.eu/…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Process control in intensified continuous solids handling

Ohenoja

Boodhoo

Reay

et al. 2018

Chemical Engineering and Processing - Process Intensification

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Conceptual methods for synthesis of reactive distillation processes: recent developments and perspectives

Kiss,

Muthia,

Pazmiño‐Mayorga

et al. 2024

J of Chemical Tech & Biotech

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Reactive distillation (RD) is a process intensification technique that offers major advantages over conventional technologies by enabling the integration of reaction and separation into a single apparatus. This integration introduces and exploits complex interaction between mass transfer, chemical reaction and hydrodynamics within an RD column; however, these complexities can hinder the adoption of reactive distillation by industry.Many approaches were developed by the scientific community to advance understanding and to expedite the initialization of RD design at the conceptual level. This paper critically discusses recent developments in conceptual methods for synthesizing RD processes. This review paper is the first to consider the range of available approaches for assessing the technical feasibility, controllability, economic viability, and sustainability, of RD units by taking into account various configurations in which RD is treated as a new unit operation, and as part of process synthesis in a different way of designing processes based on functions. The review also addresses complex configurations, such as advanced RD technologies. Special attention is paid to process modeling and simulation as well as to education. Knowledge gaps to be filled by further research are indicated.This article is protected by copyright. All rights reserved.

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Design and Control of Reactive Distillation Process for the Production of Methyl Valerate

Cited by 20 publications

References 15 publications

Process Development, Assessment, and Control of Reactive Dividing-Wall Column with Vapor Recompression for Producing n-Propyl Acetate

Process Development, Assessment, and Control of Reactive Dividing-Wall Column with Vapor Recompression for Producing n-Propyl Acetate

Process control in intensified continuous solids handling

Conceptual methods for synthesis of reactive distillation processes: recent developments and perspectives

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