(The pressure can be estimated from the Antoine equation and Raoult’s law to be164 mmHg.)

I need understanding how this pressure was calculated.  Be thorough to the fullest.  

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cal%20Processes,%204th%20Edition%20(%20PDFDrive%20).pdf Copilot Q168 The values of nout were determined from the known mole fractions of benzene and toluene in the outlet streams and the calculated values of ny and nL. We do not know the feed-stream pressure and so we assume that AH for the change from 1 atm to Pfeed is negligible, and since the process is not running at an unusually low temperature or high pressure, we neglect the effects of pressure on enthalpy in the calculations of H₁ through H4. (The pressure can be estimated from the Antoine equation and Raoult's law to be 164 mm Hg.) The heat capacity and latent heat data needed to calculate the outlet enthalpies are obtained from Tables B.1 and B.2. - Q Search The formulas (including the APEx formulas) and values of the unknown specific enthalpies are given below. Convince yourself that the formulas represent AH for the transitions from the reference states to the process states. H₁ = = (Cp)c,H₁1dT[=Enthalpy(“benzene”,10,50,“C”,“I”)] = 5.341 kJ/mol 50°C H₂ = √ (C₂)CHT [=Enthalpy ("toluene", 10,50,"C","1")] = 6.341 kJ/mol 10°C (Cp)C6H6(v)dT 50°C H4 = VITY EXERCISE 10°C -80.1°C H3 = √°C (Cp)C¡Há(1)ďT +(AĤv )C.H₂ (80.1°C) + + 10°C 451 110.62°C of 695 Q 10°℃ 80.1°C [=Enthalpy("benzene", 10,80.1,"C","1") + Hv("benzene") +Enthalpy("benzene",80.1,50,"C","g")] = 37.53 kJ/mol The energy balance is 50°C (C₂)CH(1)dT + (A‚)c‚µ‚(110.62°C) + fo 110.62°C 50°C [=Enthalpy("toluene", 10,110.62,"C","1") + Hv("toluene") +Enthalpy("toluene",110.62,50,"C","g")] = 42.94 kJ/mol Q Ση Q = AH = Σn₁A₁ - Σnit₁ = out C in (Cp)C₂H₂(v) dT Q=17.7 kJ A gas emerges from a stack at 1200°C. Rather than being released directly to the atmosphere, it can he nassed through one or several heat exchangers and the heat it loses can he nut to use in a variety D Ka € ENG

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*Elementary Principles of Chemic X + ples%20of%20Chemical%20Processes,%204th%20Edition%20(%20PDFDrive%20).pdf | loud a - 8.4-4 cyclopedia Solution Basis: 1 mol Feed rator Ask Copilot + 450 of 695 via capy changes for the unce stups. college/felder Partial Vaporization of a Mixture An equimolar liquid mixture of benzene (B) and toluene (T) at 10°C is fed continuously to a vessel in which the mixture is heated to 50°C. The liquid product is 40.0 mole% B, and the vapor product is 68.4 mole% B. How much heat must be transferred to the mixture per g-mole of feed? We start with a degree-of-freedom analysis: mol, 10°C 0.500 mol B/mol 0.500 mol T/mol Q Search A EVAPORATOR QD 0000 ny(mol), 50°C 0.684 mol B/mol 0.316 mol T/mol QU) (mol), 50°C 0.400 mol B/mol 0.600 mol T/mol 3 unknown variables (ny, nL, Q) -2 material balances −1 -1 energy balance = 0 degrees of freedom We could count each specific enthalpy to be determined as an unknown variable, but then we would also degrees of freedom unchanged. count the equations for each of them in terms of heat capacities and latent heats, leaving the number of Bal Q 16 ENG