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http://dx.doi.org/10.17137/korrae.2021.29.1.37

Analysis of the current status and implications of nitrogen recovery from livestock manure  

Im, Seongwon (Department of Civil Engineering, Inha University)
Kim, Sangmi (Department of Civil Engineering, Inha University)
Kim, Jimin (Department of Civil Engineering, Inha University)
Kim, Dong-Hoon (Department of Civil Engineering, Inha University)
Publication Information
Journal of the Korea Organic Resources Recycling Association / v.29, no.1, 2021 , pp. 37-46 More about this Journal
Abstract
Nitrogen and phosphorus in livestock manure are environmental pollutants, but also could be valuable industrial resources. In the present study, we (1) introduced various nitrogen removal technologies such as stripping, thermal method, membrane, and electrodialysis, (2) reviewed relevant studies reported in 2011-2020, in particular, full-scale experiences, and (3) assessed each technologies based on the above survey results. In addition, we provided the information on the appropriate range of the pH, temperature, gas and liquid ratio, and so on in ammonia stripping process, and expected mass balance when it is connected to biogasification process. We hope the content herein can be helpful for making policy and operating full-scale plant in Korea.
Keywords
Livestock manure; Nitrogen; Stripping; Mass balance; Full-scale plant;
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1 Marchetti, R., and Castelli, F., "Biochar from swine solids and digestate influence nutrient dynamics and carbon dioxide release in soil", Journal of environmental quality, 42(3), pp. 893-901. (2013).   DOI
2 Darestani, M., Haigh, V., Couperthwaite, S. J., Millar, G. J. and Nghiem, L. D., "Hollow fibre membrane contactors for ammonia recovery: Current status and future developments". Journal of environmental chemical engineering, 5(2), pp. 1349-1359. (2017).   DOI
3 Mandowara, A. and Bhattacharya, P. K., "Simulation studies of ammonia removal from water in a membrane contactor under liquid-liquid extraction mode", J. Environ. Manage., 92(1), pp. 121-130. (2011).   DOI
4 Tan, X., Tan, S. P., Teo, W. K. and Li, K., "Polyvinylidene fluoride (PVDF) hollow fibre membranes for ammonia removal from water", J. Membr. Sci., 271(1-2), pp. 59-68. (2006).   DOI
5 Ippersiel, D., Mondor, M., Lamarche, F., Tremblay, F., Dubreuil, J. and Masse, L., "Nitrogen potential recovery and concentration of ammonia from swine manure using electrodialysis coupled with air stripping", J. Environ. Manage., 95, pp. 165-169. (2012).
6 Liu, R., Wang, Y., Wu, G., Luo, J. and Wang, S., "Development of a selective electrodialysis for nutrient recovery and desalination during secondary effluent treatment", Chemical Engineering Journal, 322, pp. 224-233. (2017).   DOI
7 Mondor, M., Masse, L., Ippersiel, D., Lamarche, F. and Masse, D. I., "Use of electrodialysis and reverse osmosis for the recovery and concentration of ammonia from swine manure", Bioresource technology, 99(15), pp. 7363-7368. (2008).   DOI
8 EPS SOLUTION INC., "Advanced wastewater treatment system using membrane distilation and selective N,P Recovery Technology", (2017).
9 Kangwon National University, "Farm scale verification of developed technology for control and recovery of nitrogen and phosphorus from animal manure", (2012).
10 Korea University, "High-end solid fertilizer recovery using integrated zeolite-MAP process", (2017).
11 Ecodays, "Development of the removal and recovery system for high concentration ammonium nitrogen and phosphorus using ammonia stripping and magnetic Iron Oxide", (2017).
12 Laureni, M., Palatsi, J., Llovera, M. and Bonmati, A., "Influence of pig slurry characteristics on ammonia stripping efficiencies and quality of the recovered ammonium sulfate solution", J. Chem. Technol. Biot., 88, pp. 1654-1662. (2012).
13 Qiu, B., Fan, S., Tang, X., Qi, B., Deng, L., Wang, W., Liu, J., Wang, Y. and Xiao, Z., "Simultaneous recovery of phosphorus and nitrogen from liquid digestate by vacuum membrane distillation with permeate fractional condensation", Chinese J. Chem. Eng., 28, pp. 1558-1565. (2020).   DOI
14 Liu, L., Pang, C., Wu, S. and Dong, R., "Optimization and evaluation of an air-recirculated stripping for ammonia removal from the anaerobic digestate of pig manure", Process Saf. Environ. Prot., 94, pp. 350-357. (2015).   DOI
15 Song, Y. H., Qiu, G. L., Yuan, P., Cui, X. Y., Peng, J. F., Zeng, P., Duan, L., Xiang, L. C. and Qian, F., "Nutrients removal and recovery from anaerobically digested swine wastewater by struvite crystallization without chemical additions", J. Hazard. Mater., 190, pp. 140-149. (2011).   DOI
16 Adam, G., Mottet, A., Lemaigre, S., Tsachidou, B., Trouve, E. and Delfosse, P., "Fractionation of anaerobic digestates by dynamic nanofiltration and reverse osmosis: An industrial pilot case evaluation for nutrient recovery", J. Environ. Chem. Eng., 6, pp. 6723-6732. (2018).   DOI
17 Bolzonella, D., Fatone, F., Gottardo, M. and Frison, N., "Nutrients recovery from anaerobic digestate of agro-waste: techno-economic assessment of full scale applications", J. Environ. Manage., 216, pp. 111-119. (2018).   DOI
18 Errico, M., Sotoft, L. F., Nielsen, A. K. and Norddahl, B., "Treatment costs of ammonia recovery from biogas digestate by air stripping analyzed by process simulation", Clean Technol. Environ. Policy, 20(7), pp. 1479-1489. (2018).   DOI
19 Kinidi, L., Tan, I. A. W., Abdul Wahab, N. B., Tamrin, K. F. B., Hipolito, C. N. and Salleh, S. F., "Recent development in ammonia stripping process for industrial wastewater treatment", International Journal of Chemical Engineering, 2018, pp. 1-14. (2018).
20 Nasir, I. M., Mohd Ghazi, T. I. and Omar, R., "Anaerobic digestion technology in livestock manure treatment for biogas production: A review", Eng. Life Sci., 12(3), pp. 258-269. (2012).   DOI
21 Ministry of Environment, "Livestock manure treatment statistics" (2019).
22 Daejeon Sejong Research Institute, "The study of the livestock manure characteristics analysis and utilization in Sejong City" (2017).
23 Montalvo, S., Huilinir, C., Castillo, A., Pages Diaz, J. and Guerrero, L., "Carbon, nitrogen and phosphorus recovery from liquid swine wastes: a review", J. Chem. Technol. Biotechnol, 95, pp. 2335-2347. (2020).   DOI
24 Korea Rural Economic Institute, "Directions for introducing total maximum nutrient loading system of cultivated land", (2015).
25 National Institute of Environmental, "The study on the status of resource recovery system of livestock manure", (2014).
26 Menkveld, H. W. H. and Broeders, E., "Recovery of ammonia from digestate as fertilizer", Water Pract. Technol, 13(2), pp. 382-387. (2018).   DOI
27 Cantrell, K. B., Hunt, P. G., Uchimiya, M., Novak, J. M. and Ro, K. S., "Impact of pyrolysis temperature and manure source on physicochemical characteristics of biochar", Bioresour. Technol, 107, pp. 419-428. (2012).   DOI
28 Lucian, M. and Fiori, L., "Hydrothermal carbonization of waste biomass: Process design, modeling, energy efficiency and cost analysis", Energies, 10(2), p. 211. (2017).   DOI
29 Degermenci, N., Ata, O. N. and Yildiz, E., "Ammonia removal by air stripping in a semi-batch jet loop reactor. J", Ind. Eng. Chem, 18(1), pp. 399-404. (2012).   DOI