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MASS & ENERGY BALANCE Case study: Production of Citric Acid by Aspergillus niger using Cane Molasses in a Bioreactor By: Mr Zulkarnain, Mr Huzairy & Mr Fahrurrazi A laboratory scale stirred fermentor of 15-L capacity having working volume of 9-L was used for cultivation process and nutritional analysis. The strain GCBT7 Aspergillus niger, was found to enhance citric acid production. • • • • • • • • • • • Volume of fermenter: 15 L Working volume: 9 L pH value = pH 6.0 Incubation temperature = 30⁰C Raw molasses sugar-mainly sucrose (Substrate): 150 g/L Fermentation hours: 144 hours. Ammonium nitrate (Nitrogen source) = 0.2%= 2g/L Maximum Production citric acid (Product) : 99.56% ± 3.5 g/L The dry cell mass, A.niger (Biomass): 18.5 g/L (Notes: Assume 100% consumption of sugar and N source). Yields: 1) Yx/s (Biomass yield from substrate) = 0.123 2) Yp/s (Product yield from substrate) = 0.664 MASS BALANCE 1) Develop the product stoichiometric equation -assume extracellular product (citric acid) Substrate (Carbon source-sucrose from molasses) CwHxOyNz + aO2 + bHgOhNi eH2O + fCjHkOlNm Product (citric acid) Biomass (A.niger) cCHαOβNδ + dCO2 + Nitrogen source (Ammonium nitrate) CwHxOyNz + aO2 + bHgOhNi cCHαOβNδ + dCO2 + eH2O + fCjHkOlNm Stoichiometric coefficient elemental balance: C balance: w = c + d + fj H balance: x + bg = cα + 2e + fk O balance: y + 2a + bh = cβ +2d +e + fl N balance: z + bi = cδ + fm C12H22O11 + aO2 + bNH4NO3 dCO2 + eH2O + fC6H8O7 cCH1.72O0.55N0.17 + 2) Calculate the stoichiometric coefficient balance C balance : 12 = c + d + 6f H balance: 22 + 4b = 1.72c + 2e + 8f O balance: 11 + 2a +3b = 0.55c + 2d + e + 7f N balance: 2b = 0.17c Y x/s = c (Mw cells) / (Mw substrate) ** where Yx/s = 0.123 Mw cells = 24.9 + ash (7.5%) = 24.9 / (1 – 0.075) = 26.92 g/mol Mw substrate (sucrose) = 342 g/mol 0.123 = c (26.92 / 342) c = 1.56 N balance: 2b = 0.17c b = (1.56 * 0.17) /2 b = 0.133 Yp/s = 0.664 Yp/s = f (Mw product) / (Mw substrate) ** Mw citric acid = 192 g/mol Mw sucrose = 342 g/mol f = 1.15 C balance : 12 = c + d + 6f d = 12 -1.56 – 6(1.15) d = 3.54 H balance: 22 + 4b = 1.72c + 2e + 8f 22 + 4(0.133) = 1.72(1.56) + 2e + 8(1.15) e = (22.944 – 15.58) / 2 e = 5.32 O balance: 11 + 2a +3b = 0.55c + 2d + e + 7f a = (16.899 - 11.708) / 2 a = 4.95 C12H22O11 + 4.95O2 + 0.133 NH4NO3 1.56 CH1.72O0.55N0.17 + 3.54CO2 + 5.32H2O + 1.15 C6H8O7 C12H22O11 + 4.95O2 + 0.133 NH4NO3 1.56CH1.72O0.55N0.17 + 3.54CO2 + 5.32H2O + 1.15 C6H8O7 1 mol C12H22O11 produces 1.15 mol C6H8O7 1 mol C12H22O11 produces 1.56 mol CH1.72O0.55N0.17 1 mol C12H22O11 produces 3.54 mol CO2 1 mol C12H22O11 produces 5.32 mol H2O Estimation of plant capacity: 100 tonnes citric acid/year Mol of 100 tonnes of citric acid = 1 x 108 g / Mw citric acid = 1 x 108 g / 192 g/mol = 520 833 moles Amount of sucrose consumed: = (mol sucrose / mol citric acid) * total no. of mol citric acid) * Mw sucrose = (1 / 1.15) * 520 833 moles * 342 g/mol = 154.89 tonnes sucrose/year Amount of O2 consumed: = (4.95/1.15) * 520 833 moles * 32 g/mol = 71.74 tonnes O2 /year Amount of biomass produced: = (1.56/1) * 452 895 moles * 26.92 g/mol = 19.02 tonnes biomass / year Since the biomass is also a product side, so, use sucrose as basis i.e., Mol of 154.89 tonnes of sucrose = 1.55 x 108 g / Mw sucrose = 1 x 108 g / 342 g/mol = 452895 moles) Amount of Ammonium nitrate consumed: Mw NH4NO3 = 80 g / mol = (0.133/1.15) * 520 833 moles * 80 g/mol = 4.82 tonnes NH4NO3 / year Amount of CO2 produced: Mw CO2 = 44 g / mol =(3.54/1) * 452 895 moles * 44 g/mol = 70.54 tonnes CO2 / year Amount of H2O produced: Mw H2O = 18 g / mol =(5.32/1) * 452 895 moles * 18 g/mol = 43.37 tonnes H2O/ year Mass Balance Estimation of plant capacity: 100 tonnes citric acid/year Off gas (340.42 tonnes/year): CO2= 70.54 tonnes/year N2= 269.88 tonnes/year Molasses (1032.60 tonnes/year): 15% sucrose=154.89 tonnes/year 85% H2O in=877.71 tonnes/year Biomass (A.niger): 19.02 tonnes/year Fermenter Ammonium nitrate: 0.2 % (2g/L) = 4.82 tonnes/year Air (341.62 tonnes/year): 21%O2= 71.74 tonnes/year 79% N2= 269.88 tonnes/year Citric acid: 100 tonnes/year H2O out (921.08 tonnes/year): H2O produced= 43.37 tonnes/year H2O in=877.71 tonnes/year Total Mass Balances (MASSin ≈ MASSout): Stream Mass In (tonnes/year) Mass Out (tonnes/year) Sucrose 154.89 0 Ammonium nitrate 4.82 0 O2 71.74 0 N2 269.88 269.88 Biomass, A.niger 0 19.02 Citric acid 0 100.00 CO2 0 70.54 877.71 921.08 1379.04 1380.52 * Water Total Note: * some portions of water lost due to evaporation ENERGY BALANCE Considering the various quantities of materials involved, their specific heats, and their changes in temperature or state. Heat Management in Bioreactors: Temperature control essential for optimisation of biomass production or product formation. Typical cultivation conditions include: • Small reactors – large surface area to unit volume ratio – generally require heat addition. • Large reactors – small surface area to unit volume ratio – generally require heat removal. General operating temperature of microbes Growth Temp. (0C) Species Min. Opt. Max. Plant cells --- 25 --- Animal cells --- 37 --- E. Coli 10 30-37 45 B. Subtilis 15 30-37 55 S. Cerevisiae 0-5 28-36 40-42 Heat Balancing General energy balance can be applied to a bioreactor. Qacc= Qmet + Qag + Qaer + Qsen - Qevap - Qhxcr - Qsurr Where… Qacc – is the accumulated energy in the system (can be positive or negative in the case of heat loss) Qmet – Energy generated by metabolism Qag – Energy generated by agitation (W) Qaer – Energy generated by aeration (W) Qsen – Energy generated by condensation (sensible heat) Qevap – Heat loss to evaporation Qhxcr – Heat loss to heat exchanger (can be negative or positive) Qsurr – Heat loss to surrounding environment We require steady state conditions in a fermenter, therefore, in fermentation we require Qacc=0. If we ignore heat loss to the surrounding environment (usually negligible) we can describe the heat exchanger duty as: Qhxcr = Qmet + Qag + Qaer + Qsen – Qevap Energy Balance (study case) Assumption: -no shaft work (impeller), Ws=0 (in this example) -no evaporation, Mv=0 -heat of reaction, ΔHc at 30 °C is -460 kJ gmol-1 O2 consumed (for aerobic-consider only O2 combustion, - for anaerobic, you have to find ΔHc for each of the reactants & products). Q accumulation, Qacc = 0 Negligible sensible Heat change, Qsen = 0 Energy balance equation: For cell metabolism, the modified energy balance equation is: –ΔHrxn – MvΔhv – Q – Ws = 0 In this case, since Ws= 0; Mv= 0, therefore: –ΔHrxn – Q = 0 ΔHrxn is related to the amount of oxygen consumed: ΔHrxn = (-460 kJ gmol-1) * (71740 kg) * (1000g /1kg) * (1 gmol/ 32 g) Data from mass balance = -1.03 x 1010 kJ Since; –ΔHrxn – Q = 0 Q = +1.03 x 1010 kJ / year (amount of heat that must be removed from the fermenter per 100 tonnes citric acid produced ) Energy Balance Estimation of plant capacity: 100 tonnes citric acid/year Off gas (340.42 tonnes/year): CO2= 70.54 tonnes/year N2= 269.88 tonnes/year Molasses (1032.60 tonnes/year): 15% sucrose=154.89 tonnes/year 85% H2O in=877.71 tonnes/year Q= +1.03 x 1010 kJ Biomass (A.niger): 19.02 tonnes/year Fermenter 30 °C Ammonium nitrate: 0.2 % = 4.82 tonnes/year Air (341.62 tonnes/year): 21%O2= 71.74 tonnes/year 79% N2= 269.88 tonnes/year Citric acid: 100 tonnes/year H2O out (921.08 tonnes/year): H2O produced= 43.37 tonnes/year H2O in=877.71 tonnes/year Reference 1) Pauline M. Doran. (1995). Bioprocess Engineering Principle. Sydney, Australia. Elsevier Science & Technology Books. ISBN: 0122208552. 2) Electronic Journal of Biotechnology, Vol.5 No.3, Issue of December 15, 2002. ISSN: 0717-3458 by Universidad Católica de Valparaíso ,Chile. THANK YOU