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Life Cycle Assessment of Biogas from Separated slurry Process F.19: Separation of the degassed biomass mixtureF.19 Separation of digested biomass AFTER the Biogas plantF.19.1 Separation indexesThe separation technology considered after the biogas plant is the same as in section F.4 (i.e. decanting centrifuge separation), except that no polymer is added. Therefore, the material consumption data and the electricity data are the same as in F.4. Separation efficiencies data are based on Frandsen (2009), except for the total mass, for the same reasons as explained in section F.4.2. As for the separation before the biogas plant, it was assumed that the DM of the solid fraction coming out of the separator would remain approximately constant independently of the water content of the degassed slurry. Based on this, the total mass of fibre fraction can be evaluated, and thereby the separation index for the total mass. Since the amount of DM in the resulting fibre fraction was measured (26.71 %, which means that there is 267.1 kg DM per 1000 kg of fibre fraction according to table 4 in Frandsen (2009)), and since the DM content of the input degassed biomass is known (105.98 kg DM per kg degassed biomass, table F.22), the mass of fibre fraction produced can be calculated. This amounts to 241.639 kg fibre fraction per 1000 kg degassed biomass[19], which means that 24.16 % of the initial mass is found in the solid fraction. The remaining mass is then going in the liquid fraction, corresponding to 75.84 % (i.e. 100 % - 24.16 %). The separation indexes considered for the post-biogas separation are presented in table F.25. It should be noted that since no data were available for Cu and Zn, the efficiencies presented in Møller et al. (2007b) were used as the best available data. Table F.25. Separation indexes for separation of pig slurry AFTER the biogas plant. (polymer is not added). Data from Frandsen (2009), unless otherwise specified.
a) This is a calculated value, see text. b)No data. Assumed to be the same as DM. c) From Møller et al. (2007b). F.19.2 Mass balancesThe mass balances of the degassed biomass mixture before and after the separation are presented in table F.26. It should be highlighted that no data as regarding the emissions occurring during the separation process has been found, as it was also the case with the separation before the biogas is produced (i.e. process F.4). This lack of data is particularly critical as regarding ammonia emissions, which are likely to occur given the volatile nature of ammonia. Yet, it appears reasonable to assume that all the emissions likely to occur during the separation are occurring in later stages anyway, so considering them at this stage or at later stages does not change the overall results. The life cycle data for the separation post biogas production are presented in table F.27. Table F.26. Mass balances for separation of the degassed biomass. Table F.27. Life cycle data for separation (decanter centrifuge) after the anaerobic digestion. Data per 1000 kg slurry (ex-digester).
[19] The input degassed slurry to separate contains 105.98 kg DM/1000 kg degassed biomass. Yet, 60.9% of the DM ends up in the fibre fraction with the separation indexes considered (see table F.24) i.e. 105.98 kg * 60.9% = 64.542 kg DM per 1000 kg degassed biomass. As the fibre fraction contains 267.1 kg DM per 1000 kg fibre fraction (due to measurements, see table 4 in Frandsen (2009)), the total amount of fibre fraction is: 64.542 kg DM / 1000 kg degassed biomass * 1000 kg fibre fraction/ 267.1 kg DM = 241.639 kg fibre fraction per 1000 kg degassed biomass.
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