Optimizing Crystal Size Distribution Based on Different Cooling Strategies in Batch Crystallization Process

  • Siti Zubaidah Adnan Faculty of Chemical & Process Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah, Lebuh Persiaran Tun Khalil Yaakob, 26300 Kuantan, Pahang, Malaysia
  • Noor Asma Fazli Abdul Samad Faculty of Chemical & Process Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah, Lebuh Persiaran Tun Khalil Yaakob, 26300 Kuantan, Pahang, Malaysia https://orcid.org/0000-0001-7331-0972
DOI: https://doi.org/10.22146/ajche.12190
Keywords: Cooling Profile, Crystallization, Crystal Size Distribution, Dissolution, Optimization Algorithm, Temperature Control

Abstract

Crystal size distribution (CSD) is an essential criterion for determining the production of high-quality crystals since it influences the efficiency of the crystallization process. Producing specified CSD in the crystallization process represents a main challenge as it depends on temperature control, which indirectly regulates the solution’s concentration and affects the crystal’s evolution. Different temperature profiles may influence the distribution of crystal products, and a suitable optimization algorithm is required to produce an optimum temperature trajectory that produces the desired CSD. Thus, this study aims to maximize the CSD of the grown seed crystals while minimizing the nucleus-grown crystals by employing the best optimization algorithm for the potash alum crystallization process. The crystallization process was developed and simulated in Matlab software using a potash alum in the water system. Four optimization algorithms were proposed with different objective functions, such as maximizing mean crystal size (I), minimizing coefficient of variation (II), minimizing nucleus-grown crystals (III), and maximizing CSD (IV). Based on the simulation results, optimization IV, which maximizes CSD, performs best with a large mean crystal size of 490 µm. Furthermore, the number of fine crystals was among the lowest at a volume distribution of 0.00071 m3/m compared to the linear profile at 0.00191 m3/m. Optimization IV employs a dissolution strategy, which manipulates two quality specifications in one algorithm (size of crystals and number of fines), which is considered the best optimal cooling profile for seeded batch crystallization by maximizing CSD and minimizing the generation of nucleus-grown crystals.

Author Biography

Noor Asma Fazli Abdul Samad, Faculty of Chemical & Process Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah, Lebuh Persiaran Tun Khalil Yaakob, 26300 Kuantan, Pahang, Malaysia

Faculty of Chemical & Process Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah, Lebuh Persiaran Tun Khalil Yaakob, 26300 Kuantan, Pahang, Malaysia

References

Aamir, E., 2010. “Population Balance Model-Based Optimal Control of Batch Crystallisation Processes for Systematic Crystal Size Distribution Design.” PhD thesis. Loughborough University, Leicestershire, England.

Adnan, S.Z., Saleh, S., and Samad, N.A.F.A., 2019. “Evaluation of controlled cooling for seeded batch crystallization incorporating dissolution,” in: AIP Conference Proceedings. AIP Publishing, pp. 020042–1–020042–8.

Adnan, S.Z., and Samad, N.A.F.A., 2022. “Effects of nucleation and crystal growth rates on crystal size distribution for seeded batch potash alum crystallization process.” ASEAN J. Chem. Eng. 22, 258-273.

Agrawal, S.G., and Paterson, A.H.J., 2015. “Secondary nucleation: mechanisms and models.” Chem. Eng. Commun. 202, 698–706.

Ashraf, A.B., and Rao, C.S., 2022. “Multiobjective temperature trajectory optimization for unseeded batch cooling crystallization of aspirin.” Comput. Chem. Eng. 160, 107704.

Hemalatha, K., Nagveni, P., Kumar, P.N., and Rani, K.Y., 2018. “Multiobjective optimization and experimental validation for batch cooling crystallization of citric acid anhydrate.” Comput. Chem. Eng. 112, 292–303.

Hojjati, H., and Rohani, S., 2005. “Cooling and seeding effect on supersaturation and final crystal size distribution (CSD) of ammonium sulphate in a batch crystallizer.” Chem. Eng. Process. Process Intensif. 44, 949–957.

Lee, A.Y., Erdemir, D., and Myerson, A.S., 2019. “Crystals and Crystal Growth,” in: Handbook of Industrial Crystallization. Cambridge University Press, pp. 32–75.

Nagy, Z.K., Fujiwara, M., and Braatz, R.D., 2019. “Monitoring and Advanced Control of Crystallization Processes,” in: Handbook of Industrial Crystallization. Cambridge University Press, pp. 313–345.

Samad, N.A.F.A., Singh, R., Sin, G., Gernaey, K. V., and Gani, R., 2010. “Control of process operations and monitoring of product qualities through generic model-based in batch cooling crystallization.” Comput. Aided Chem. Eng. 28, 613–618.

Sanzida, N., and Nagy, Z.K., 2019. “Strategic evaluation of different direct nucleation control approaches for controlling batch cooling crystallisation via simulation and experimental case studies.” Comput. Chem. Eng. 130, 106559.

Seki, H., and Su, Y., 2015. “Robust optimal temperature swing operations for size control of seeded batch cooling crystallization.” Chem. Eng. Sci. 133, 16–23.

Szilágyi, B., 2022. “External fine particle removal for crystallization processes: Introduction and systematic comparison with the temperature cycling-based fines removal.” Chem. Eng. Process. Process Intensif. 179, 109074.

Szilagyi, B., and Nagy, Z.K., 2019. “Model-based analysis and quality-by-design framework for high aspect ratio crystals in crystallizer-wet mill systems using GPU acceleration enabled optimization.” Comput. Chem. Eng. 126, 421–433.

Trampuž, M., Teslić, D., and Likozar, B., 2021. “Crystal-size distribution-based dynamic process modelling, optimization, and scaling for seeded batch cooling crystallization of Active Pharmaceutical Ingredients (API).” Chem. Eng. Res. Des. 165, 254–269.

Walla, B., Bischoff, D., Corona Viramontes, I., Montes Figueredo, S., and Weuster-Botz, D., 2023. “Recent advances in the monitoring of protein crystallization processes in downstream processing.” Crystals 13, 773.

Zhang, D., Liu, L., Xu, S., Du, S., Dong, W., and Gong, J., 2018. “Optimization of cooling strategy and seeding by FBRM analysis of batch crystallization.” J. Cryst. Growth 486, 1–9.

Zheng, Y., Wang, X., and Wu, Z., 2022. “Machine learning modeling and predictive control of the batch crystallization process.” Ind. Eng. Chem. Res. 61, 5578–5592.

Zong, S., Zhou, G., Li, M., and Wang, X., 2023. “Deep learning-based on-line image analysis for continuous industrial crystallization processes.” Particuology 74, 173–183.

Published
2024-12-31
How to Cite
Adnan, S. Z., & Abdul Samad, N. A. F. (2024). Optimizing Crystal Size Distribution Based on Different Cooling Strategies in Batch Crystallization Process. ASEAN Journal of Chemical Engineering, 24(3), 276-286. https://doi.org/10.22146/ajche.12190
Issue
Vol 24 No 3 (2024)
Section
Articles

Copyright (c) 2024 ASEAN Journal of Chemical Engineering

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

Copyright holder for articles is ASEAN Journal of Chemical Engineering. Articles published in ASEAN J. Chem. Eng. are distributed under a Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) license. 

Authors agree to transfer all copyright rights in and to the above work to the ASEAN Journal of Chemical Engineering Editorial Board so that the Editorial Board shall have the right to publish the work for non-profit use in any media or form. In return, authors retain: (1) all proprietary rights other than copyright; (2) re-use of all or part of the above paper in their other work; (3) right to reproduce or authorize others to reproduce the above paper for authors’ personal use or for company use if the source and the journal copyright notice is indicated, and if the reproduction is not made for the purpose of sale.