Demonstrate the calculations for enthalpies 1, 2, and 3.  

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||! PDF *Elementary Principles of Chemic X PDF *Elementary Principles of Chemic X + O 58°F Clear File | E:/Elementary%20Principles%20of%20Chemical%20Processes,%204th%20Edition%20(%20PDFDrive%20).pdf Draw T Read aloud 448 CHAPTER 8 Balances on Nonreactive Processes Example 8.5-2 468 of 695 CD Basis: 1 lbm solution (0.40 lbm H₂SO4 = 4.08 x 10-3 lb-mole, 0.60 lbm H₂O = 3.33 x 10-² lb-mole) 0.60 lbm H₂O(1, 32°F) → 0.60 lbm H₂O (1,77°F) Btu 047] (B) 77°F AH₁ (Btu) = (0.60 lbm H₂O) [/77 (C₂)14₂0 47] 32°F The heat capacity of liquid water is approximately 1 Btu/(lbm.°F). • 0.40 lbm H₂SO4(77°F) + 0.60 lbm H₂O (77°F) → 1.0 lbm H₂SO4 solution (aq, 77°F) lb-mole H₂O Btu lb-mole H₂SO4, lbm H₂SO4 AH₂(Btu) = (0.40 lbm H₂SO4) AĤ, 77°F, r = 8.2 Q Search The heat of mixing can be determined from the data in Table B.11 to be -279 Btu/lb H₂SO4. • 1.0 lbm H₂SO4 solution (aq, 77°F) → 1.0 lbm H₂SO4 solution (aq, 120°F) 120°F AH3(Btu) = (1.0 lbm) (Cp)40% H₂SO4 (aq) dT 77°F The heat capacity of the 40% sulfuric acid solution is roughly 0.67 Btu/(lbm.°F).¹5 (AH₁ +AH₂ + AH3)(Btu) • Ĥ(40% H₂SO4, 120°F) = 1.0 lbm solution (Verify that this is the value shown in Figure 8.5-1.) -56 Btu/lbm If any reference temperature but 77°F had been chosen for sulfuric acid, another step would have been included in which H₂SO4 was brought from Tref to 77°F prior to mixing. Once someone has gone to the trouble of preparing an enthalpy-concentration chart like that of Figure 8.5-1, energy balance calculations become relatively simple, as shown in Example 8.5-2. single liamid phase Concentration of an Aqueous H₂SO4 Solution {" Ⓡ J 63 50 D ENG Sign in (0) + O 3:59 AM 5/22/2023