Principles of Food and Bioprocess Engineering (FS 231) Solutions to Example Problems on Mass Balance

Principles of Food and Bioprocess Engineering (FS 231) Solutions to Example Problems on Mass Balance 1. The mass balance equation for the system is: 2 + 3 = m This yields, m = 5 kg 2. The mass balance equation for the system is: 2 + 3 = m This yields, m = 5 kg/s 3. We have 1 mass balance equation for each sub-system, yielding a total of 2 equations. First sub-system: 2 + 3 = m 1 + 4 Second sub-system: 4 + 4 = 2 + m 2 Solving, we get: m = 1 kg/s, m = 6 kg/s 4. In this system, we have 2 equations and 2 unknowns. However, the mass balance equation in the first sub-system does not give us any information except that the problem is well-posed. Thus, we are left with one mass balance equation for sub-system #2 and 2 unknowns in that equation. Thus, we can not solve for m 1 and m 2 in this problem. All that we can say is that: 4 + m = 2 + m. 5. The Overall Mass Balance (OMB) equation is: 2 + 1 = m The solids balance equation is: 0.3 (2) + x (1) = 0.4 (m) This yields, m = 3 kg/s, x = 0.6 6. OMB: 5 + 1 = m Sugar: 0.2 (5) + 0.3 (1) = x 1 (m) Starch: 0.6 (5) + 0.4 (1) = x 2 (m) Solving, we get: m = 6 kg/s, x = 0.22, x = 0.57 7. OMB for first sub-system: 10 + 2 = m 1 + 9 Solids balance for first sub-system: 0.6 (10) + 0.42 (2) = x 1 (m 1) + 0.7 (9) OMB for second sub-system: 9 = m 2 + 6 + 2 Solids balance for second sub-system: 0.7 (9) = x (m ) + 0.9 (6) + 0.42 (2) 2 2 Solving, we get: m 1 = 3 kg/s, x 1 = 0.18, m 2 = 1 kg/s, x 2 = 0.06 8. There are four components (sugar, starch, oil, and water) in each sub-system and hence there are four mass balance equations in each sub-system, yielding a total of 8 equations. OMB in first sub-system: 10 + 3 = 2 + 5 + m 1 Starch balance in first sub-system: 0.3 (10) = x 4 (2) + x 1 (m 1) + 0.4 (5) Sugar balance in first sub-system: 0.06 (10) + x 2 (3) = 0.4 (m 1) Oil balance in first sub-system: x (3) = 0.3 (2) 3

OMB in second sub-system: m 1 + 2 + m 2 = 3 + 9 Starch balance in second sub-system: x 1 (m 1) = 0 Sugar balance in second sub-system: 0.4 (m 1) + x 6 (m 2) + 0.7 (2) = x 2 (3) + 0.4 (9) Oil balance in second sub-system: x (m ) = x (3) 5 2 3 Solving, we get: m 1 = 6 kg/s, m 2 = 4 kg/s, x 1 = 0, x 2 = 0.6, x 3 = 0.2, x 4 = 0.5, x 5 = 0.15, x 6 = 0.4 9. There are four components (sugar, starch, oil, and water) in each sub-system and hence there are four mass balance equations in each sub-system, yielding a total of 8 equations. OMB in first sub-system: 10 + 2 = 8 + m 1 Starch balance in first sub-system: 0.4 (10) = x 1 (m 1) Sugar balance in first sub-system: 0.5 (10) + 0.3 (2) = 0.7 (8) Oil balance in first sub-system: 0 = x (m ) 2 1 OMB in second sub-system: m 1 + m 2 = 5 + 5 Starch balance in second sub-system: x 1 (m 1) + 0.1 (m 2) = x 5 (5) Sugar balance in second sub-system: 0 = x 3 (5) + x 6 (5) Oil balance in second sub-system: x (m ) + 0.5 (m ) = x (5) + 0.2 (5) 2 4 Solving, we get: m 1 = 4 kg/s, m 2 = 6 kg/s, x 1 = 1.0, x 2 = 0, x 3 = 0, x 4 = 0.4, x 5 = 0.92, x 6 = 0 10. Since there are 5 components in this system, there are 5 equations. OMB: 6 + 4 = 8 + m Sugar: 0.2 (6) = x 3 (8) Starch: x 1 (6) + 0.3 (4) = 0.3 (8) + 0.6 (m) Oil: x 6 (4) = 0.2 (m) Protein: 0 = x (8) + x (m) 2 5 In order to determine x 4, we note that the sum of the fractions of the individual components of the product exiting from the top of the system at 8 kg/s must add up to 1.0. i.e., 0.3 + x + x + x = 1.0 2 3 4 Solving, we get: m = 2 kg/s, x 1 = 0.4, x 2 = 0, x 3 = 0.15, x 4 = 0.55, x 5 = 0, x 6 = 0.1 11. Since there are 4 components in each of the 3 sub-systems, we have a total of 12 equations. Overall mass balance equation: 10 + m 1 = 3 + 5 + m2 Total Fat balance equation: 10 (x 2) + m 1 (x 3) = m 2 (0.8) Total Protein balance equation: 10 (x 1) + m 1 (0.25) = 3 (1.0) + m 2 (x 8) + 5 (0.02) Total Vitamin balance equation: 10 (0.35) = 5 (0.64) + m (x ) 2 9

Overall mass balance equation: 5 + 2 + 1 = m 1 + m3 Total Fat balance equation: 2 (x 5) = m 1 (x 3) Total Protein balance equation: 5 (0.02) + 2 (x 6) + 1 (0.3) = m 1 (0.25) Total Vitamin balance equation: 5 (0.64) + 2 (x ) + 1 (x ) = m (1.0) 7 4 3 For the third sub-system: Overall mass balance equation: m 2 = 4 + 2 Total Fat balance equation: m 2 (0.8) = 4 (1.0) + 2 (x 5) Total Protein balance equation: m 2 (x 8) = 2 (x 6) Total Vitamin balance equation: m (x ) = 2 (x ) 2 9 7 Solving, we get: m 1 = 4 kg/s, m 2 = 6 kg/s, m 3 = 4 kg/s, x 1 = 0.27, x 2 = 0.4, x 3 = 0.2, x 4 = 0.5, x 5 = 0.4, x = 0.3, x = 0.15, x = 0.1, x = 0.05 6 7 8 9 12. Since there are 3 components in each of the sub-systems, we have a total of 6 equations. Overall mass balance equation: 5 + 3 = 2 + m 1 Protein balance equation: 0.5 (5) = 0.3 (2) + x 1 (m 1) Fat balance equation: 0.3 (3) = 0.2 (2) + x (m ) Overall mass balance equation: m 1 = m 2 + 2 + 2 Protein balance equation: x 1 (m 1) = x 3 (2) Fat balance equation: x (m ) = x (m ) 2 1 4 2 2 1 Solving, we get: m 1 = 6 kg/s, m 2 = 2 kg/s, x 1 = 0.317, x 2 = 0.083, x 3 = 0.95, x 4 = 0.25 13. Since there are 3 components in each of the 3 sub-systems, we have a total of 9 equations. Overall mass balance equation: 10 + m 1 + 2 = 3 + 13 Total Sugar balance equation: 0.3 (10) + x 2 (m 1) + 0.6 (2) = 0.1 (3) + x 1 (13) Total Starch balance equation: x (m ) = 0 3 1 Overall mass balance equation: 13 + 2 = m 2 + 2 + 5 Total Sugar balance equation: x 5 (13) + 0.05 (2) = x 5 (m 2) + 0.6 (2) Total Starch balance equation: 0.05 (2) = 0.02 (5) + x (m ) 4 2 For the third sub-system: Overall mass balance equation: 5 = m 1 + m3 Total Sugar balance equation: 0 = x 7 (m 3) + x 2 (m 1) Total Starch balance equation: 0.02 (5) = x (m ) + x (m ) 6 3 3 1 Solving, we get: m = 4 kg/s, m = 8 kg/s, m = 1 kg/s, x = 0.3, x = 0, x = 0, x = 0, x = 0.35, x = 0.1, x = 0 3 3 4 5 6 7

14. The system diagram for the problem is as shown below: We have 5 equations and 5 unknowns in this problem. Overall mass balance in first sub-system: 20 = m 1 + m2 Sugar balance in first sub-system: 0.15 (20) = x 1 (m 2) Overall mass balance in second sub-system: m 2 + m 3 = m 4 + 5 Sugar balance in second sub-system: x 1 (m 2) = 0.3 (m 4) Starch balance in second sub-system: m = 0.4 (m ) 3 4 Solving, we get: m 1 = 9 kg/hr, m 2 = 11 kg/hr, m 3 = 4 kg/hr, m 4 = 10 kg/hr, x 1 = 0.27 15. The mass flow rate (m) and moisture content on wet basis (x) are the two unknowns in the system shown below: Mass balance: 20 = 15 + m Solids balance: 0.1 (20) = x (m) m = 5 kg/hr and x = 0.4 Thus, the product consists of 2 kg/hr of solids and 3 kg/hr of water. Thus, (mc) = 3/2 = 1.5 = 150 % db

16. First sub-system Overall mass balance: 5 + m 1 = 3 + m 2 => 2 + m 1 = m2 Protein balance: 0.2 (5) + 0.1 (m 1) = 0.4 (3) + x 2 (m 2) => 1 + 0.1 (m 1) = 1.2 + x 2 (m 2) Fat balance: 0.2 (5) + 0.1 (m 1) = x 1 (3) + x 3 (m 2) => 1 + 0.1 (m 1) = x 1 (3) + x 3 (m 2) Carbohydrates balance: 0.3 (m ) = 0.2 (3) + x (m ) => 0.3 (m ) = 0.6 + x (m ) 1 4 2 1 4 2 Second sub-system Overall mass balance: m 2 + 10 = 5 + m 3 => m 2 + 5 = m3 Protein balance: x 2 (m 2) + 0.2 (10) = 0.4 (5) => x 2 (m 2) = 0 Fat balance: x 3 (m 2) + 0.3 (10) = 0.6 (5) => x 3 (m 2) = 0 Carbohydrates balance: x (m ) + x (10) = 0.4 (m ) => x (m ) + 10 x = 0.4 (m ) 4 2 5 3 4 2 5 3 Substituting x 2 (m 2) = 0 into the protein balance equation for the first sub-system, we get: 1 + 0.1 (m 1) = 1.2 This yields: m = 2 kg/s 1 Substituting this value in the overall mass balance equation for the first sub-system, we get: m = 4 kg/s 2 Since m 2 0, and x 2 (m 2) = x 3 (m 2) = 0, we get: x 2 = x 3 = 0 Substituting these values of m 1 and m 2 in the fat balance equation for the first sub-system, and noting that x (m ) = 0, we get: x = 0.4 3 2 1 Solving for the remaining variables, we get: m 3 = 9 kg/s, x 4 = 0, x 5 = 0.36