Скачать книгу

designing and scaling of ultrasound reactors. Several authors previously reported multi-frequency ultrasound reactor for potential scale-up of ultrasound reactors [116–118]. In another study, Gogate and Pandit [118] reported design of large-scale sonochemical reactors using numerical model devolvement and experimental validation with different reactor types and reactions, including esterification and transesterification. They also recommended the use of multi-frequency reactors for large-scale commercial application.

      Nevertheless, an ongoing effort on the scale-up of the ultrasonic reactor in the future will be done by a numeric method and computer-based simulations method such as CFD [112] using tools such as COMSOL or ANSYS.

2.6 Application of Cavitational Reactors for Large-Scale Biodiesel Production

Sonochemistry induced by cavitational phenomena and its beneficial application for biodiesel production has attracted the interest of the research community and the industrial domain. Nevertheless, the complex design of the system and its effective implementation in a large-scale process still needs significant R&D efforts. The principal merit of cavitational reactors for biodiesel synthesis at a commercial scale is its reduced operational cost (in terms of energy requirement) and higher energy efficiencies and yields. In lab-scale studies, exergy analysis looks promising, but translating these ideas into commercial processing is still a challenge [119]. As discussed in the previous section, the two types of pilot-scale reactors have been designed, viz., multi-frequency sonochemical reactors and hydrodynamic cavitation reactors. The research group of Pandit and Gogate has demonstrated the successful application of pilot-scale hydrodynamic cavitational reactors for biodiesel synthesis in numerous studies [23, 97, 120]. These reactors achieve higher conversation rates in a shorter time and reduce solvent requirements compared to conventional mechanical mixing. However, these reactors are not compatible with the heterogeneous catalysts. This doesn’t improve the downstream processing of biodiesel, and thus becomes the main limitation in scale-up. The multi-frequency sonochemical reactors will be an ideal solution in such cases, but limited case studies have been carried out using such reactors. The main advantages of such reactors are their flexibility of operation in both batch and continuous model and the compatibility with heterogeneous catalysts. On the other hand, the high energy input of these reactors is the major limiting factor [79, 114, 121]. Murillo et al. [122] and others [86] have successfully demonstrated 3 L capacity ultrasonic reactor for biodiesel synthesis. Comprehensive work is still required to achieve the commercialization of biodiesel production.

2.7 Future Prospects and Challenges

      Biodiesel via transesterification is one of the emerging processes for meeting the increased demand for renewable fuels. Transesterification, being a heterogeneous reaction system, is a mass-transfer controlled process. Moreover, the selection of feedstock controls the economics of the overall process. In order to improve the overall economy of the process, the feedstock of non-edible oils and heterogeneous catalysts are the best feasible solutions. The use of heterogeneous catalysts further increases the mass transfer barriers and lowers the conversion rate. To improve the reaction kinetics and yield of the process, sonication is found to be a useful tool in lab-scale studies. Research on ultrasound-assisted or cavitation-assisted biodiesel processes is promising and demands further R&D efforts to develop large-scale operations. Significant research is also required on ultrasound-assisted heterogeneously catalyzed transesterification processes. Large-scale biodiesel production may require the use of a mixture of non-edible oils and third-generation feedstocks like microalgal lipids. Efficient processes need to be developed to convert these feedstocks into biodiesel in a cost-effective way that requires R&D in both chemistry and reactor design and engineering. Lab-scale research in academic institutions and universities and the pilot-scale trials in the industry should go hand-in-hand to develop an energy-efficient, sustainable, and economically attractive commercial biodiesel process.

References

      1. Moholkar, V.S., Choudhury, H.A., Singh, S., Khanna, S., Ranjan, A., Chakma, S., and Bhasarkar, J., Physical and chemical mechanisms of ultrasound in biofuel synthesis, in Production of Biofuels and Chemicals with Ultrasound (eds. Fang, Z., Smith, R.L.J., and Qi, X.), pp. 35–86. Springer, Dordrecht, 2015.

2. Abomohra, A.E.F., Elsayed, M., Esakkimuthu, S., El-Sheekh, M., and Hanelt, D., Potential of fat, oil and grease (FOG) for biodiesel production: A critical review on the recent progress and future perspectives. Prog. Energy Combust. Sci., 81, 100868, 2020.

      3. Chuah, L.F., Klemeš, J.J., Yusup, S., Bokhari, A., Akbar, M.M., A review of cleaner intensification technologies in biodiesel production. J. Clean. Prod., 146, 181–193, 2017.

      4. Elbashir, N.O., Ahmed, W. Choudhury, H.A., Nasr, N.M., et al., GTL Derived Synthetic Fuels: Potentials and Challenges in Global Market, in Water-Food-Energy Nexus: Processes, Technologies and Challenges, CRC Press Taylor & Francis Group, 2016.

      5. Basha, S.A., Gopal, K.R., Jebaraj, S., A review on biodiesel production, combustion, emissions and performance. Renew. Sustain. Energy Rev., 13 (6–7), 1628–1634, 2009.

      6. Mahlia, T.M.I., Syazmi, Z.A.H.S., Mofijur, M., Abas, A.P., Bilad, M.R., Ong, H.C., Silitonga, A.S., Patent landscape review on biodiesel production: Technology updates. Renew. Sustain. Energy Rev., 118, 109526, 2020.

      7. Damanik, N., Ong, H.C., Tong, C.W., Mahlia, T.M.I., Silitonga, A.S., A review on the engine performance and exhaust emission characteristics of diesel engines fueled with biodiesel blends. Environ. Sci. Pollut. Res., 25 (16), 15307–15325, 2018.

      8. Knothe, G., and Razon, L.F., Biodiesel fuel. Prog. Energy Combust. Sci., 58, 36–59, 2017.

      9. Malani, R.S., Sardar, H., Malviya, Y., Goyal, A., Moholkar, V.S., Ultrasound-Intensified Biodiesel Production from Mixed Nonedible Oil Feedstock Using Heterogeneous Acid Catalyst Supported on Rubber De-oiled Cake. Ind. Eng. Chem. Res., 57 (44), 14926–14938, 2018.

      10. Malani, R.S., Choudhury, H.A., Moholkar, V.S., Waste biorefinery based on waste carbon sources: case study of biodiesel production using carbon based catalysts and mixed feedstocks of nonedible and waste oils, in Waste Biorefinery Volume-II (eds. Bhaskar, T., Pandey, A., Rene, E.R., and Tsang, D.C.W.), Elsevier B.V., pp. 337–378, 2020.

      11. Badday, A.S., Abdullah, A.Z., Lee, K.T., Khayoon, M.S., Intensification of biodiesel production via ultrasonic-assisted process: A critical review on fundamentals and recent development. Renew. Sustain. Energy Rev., 16 (7), 4574–4587, 2012.

      12. Wang, T., Global biodiesel production by country 2018. https://www.statista.com/statistics/271472/biodiesel-production-in-selected-countries/, 2019.

      13. IEA, Biofuel Production Growth by Country. IEA Paris, https://www.iea.org/data-and-statistics/charts/bio, 2019.

      14. Renewable energy policy Network 21st Century steering committee. Renewables 2014: global status report. REN 21, https://www.ren21.net/wp-content/uploads/2019/05/, 2014.

      15. Abbaszaadeh, A., Ghobadian, B., Omidkhah, M.R., Najafi, G., Current biodiesel production technologies: A comparative review. Energy Convers. Manag., 63, 138–148, 2012.

16. Aransiola, E.F., Ojumu, T. V., Oyekola, O.O., Madzimbamuto, T.F., Ikhu–Omoregbe, D.I.O., A review of current technology for biodiesel production: State of the art. Biomass and Bioenergy, 61, 276–297, 2014.

      17. Tabatabaei, M., Aghbashlo, M., Dehhaghi, M., Panahi, H.K.S., Mollahosseini, A., Hosseini, M., Soufiyan, M.M., Reactor technologies for biodiesel production and processing: a review. Prog. Energy Combust. Sci., 74, 239–303, 2019.

      18.

Скачать книгу