4. Two aqueous sulfuric solutions containing 20.0 wt% H2SO4 (SG = 1.139) and 60wt % HSO. (SG= 1.498) are mixed to form a 4.0 molar solution (SG= 1.213)
a. Calculate the mass fraction of sulfuric acid in the product solution
b. Taking 200 kg of the 20% feed solution as a basis, draw and label a flowchart of this process, labeling both masses and volumes.
c. Do degree of freedom analysis:
vili. How many unknowns?
ix. How many balances can be subtracted?
x. How many specific gravities can be subtracted?
xi. What is the result?
d. Calculate the feed ratio (liters 20% solution/liter 60% solution)
Two aqueous sulfuric solutions containing 20.0 wt% H2SO4 (SG = 1.139)
Taking 100 kg of the 20% feed solution as a basis, draw and label a flowchart of this process labeling both masses and volumes, and do the degree-of-freedom analysis.Calculate the feed ratio (liters 20% solution/liter 60% solution).
Two aqueous sulfuric acid (H2SO4) solutions containing 20.0 wt% H2SO4 (SG=1.139) and 80.0 wt% H2SO4 (SG=1.727) respectively, are mixed to form a 4.00 molar solution (mol/L) (SG=1.213). Calculate the mass fraction of sulfuric acid in the product stream. Atomic weight: H=1g/mol, O=16g/mol, S=32g/mol. Taking 100 kg of the 20 wt% feed solution as a basis, calculate the volumetric feed ratio of 20.0 wt% H2SO4 to 80.0 wt% H2SO4, to 2 decimal places.
Two aqueous hydrogen bromide solutions containing 12.0 wt% HBr (SG = 1.0867) and 65.0 wt% HBr (SG = 1.7613) are mixed to form a 3.90 molar HBr solution (SG = 1.1234)What feed rate of the 65.0 wt% HBr solution would be required to produce 1150 kg/hr of productWhat is the feed ratio of liters of 12.0 wt% HBr solution to liters of 65.0 wt% HBr solution?