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TABLE A-20 Ideal-gas properties of carbon dioxide, C kJ/kmol kJ/kmol 202.966 205.920 208.717 6,938 5,285 7,627 246.282 247.032 247.773 248.507 249.233 249.952 210.062 19,672 20,078 25,648 26,631 21,305 215.146 216.351 7,526 7,826 252.065 252.755 253.439 254.117 22,522 218.694 29,629 24,242 24,669 25,097 30,644 256.110 256.762 257.408 225.225 226.250 227.258 228.252 229.230 230.194 13,372 10,714 259.311 260.551 15,483 28,588 29,031 29,476 35,821 36,347 36,876 262.371 262.968 263.559 233.916 234.814 235.700 13,885 264.728 265.304 265.877 266.444 18,576 237.439 238.292 40,070 40,607 239.962 240.789 241.602 242.405 267.566 33,537 42,226
TABLE Ideal-gas properties of carbon dioxide, CO, (Concludec) A-20 kJ/kmol 1000 269.215 270.293 86,420 43,859 44,953 46,051 35,378 88,806 302.884 303.544 304.198 1080 274.445 275.444 92,394 93.593 94,793 49,369 50,484 305.487 306.122 277.403 278.361 80,031 97,197 98,401 99,606 53,848 82,105 1220 280.238 308.604 282.066 282.962 283.847 2050 103,835 106,864 109,898 112,939 115,984 86,791 89,404 1280 49,691 50,672 94,648 62,963 286.439 287.283 65,271 1420 2500 131.290 322.808 324.026 56,609 2650 140,533 143.620 146,713 326.396 327.549 292.888 123,849 152,908 129,212 131,898 62,630 296.632 333.037 162,226 335.114 336.126 298.781 299.482 300.177 300.863 168,456 145,385 339.069 85,231 70,764
938 PROPERTY TABLES AND CHARTS TABLE A-26 halpy of formation, Gibbs function of formation, and absolute entropy at 25°C, 1 atm 5° Substance Formula kJ/kmol kJ/kmol kJ/kmol.K Carbon 0 5.74 0 130.68 "О 191.61 05.04 -137,150 197.65 0 Hydrogen Nitrogen 0 Carbon monoxide Carbon dioxide CO2(g) 393,520-394,360 213.80 H200e) 285,830 -237,180 69.9 NH 188.8 Water Hydrogen peroxide H0,2)136,310 -105,600 232.6 Ammonia 16,590 192.33 186.16 -46,190 Acetylene Ethylene Ethane C2H2(8) +226,730 +2 C2H4(8 +52,280+68,120 219.83 -84,680 -32,890 229.49 Propylene Propane n-Butane n-Octane n-Octane n-Dodecane Benzene Methyl alcohol Methyl alcohol Ethyl alcohol Ethyl alcohol Oxygen Hydrogen Nitrogen C3H6(g) CaHag)-103,850 -23,490 269.91 CHiog) CgH18(g) CgHi8() C12H26g-291,010 +50,150 622.83 +20,410 +62,720 266 15,710 310.12 208,450+16,530466.73 +6,610360.79 249,95 +82,930 +129,660 269.20 CH,OH(g) -200,670 -162,000 239.70 CH OH(e) -238,660 -166,360 126.80 C2H,OH(g)-235,310-168,570 282.59 C2H,OH(e)-277,690-174,890 277,690-174,890 160.70 +249,190 +231,770 161.06 +218,000 +203,290 114.72 +472,650 +455,510 153.30 +39,460 +34,280 183.70 H(g) N(g) OH(g) Hydroxyl Source of Data: From JANAF, Thermochemical Tables (Midland, MI: Dow Chemical Co., 1971) Selected Values of Chemical Thermodynamic Properties, NBS Technical Note 270-3, 1968; and API Research Project 44 (Carnegie Press, 1953).
TABLE A-27 Enthalpy of Specitic heating heating vaporization,2 heat, c value,value mass, Density, Fuel (phase) Formula 12.011 2.016 0.708 32,800 32,800 4.4 141,800 120,000 Carbon monoxide (g) Methane (g Methanol (e) CO 16.043 32.042 26.038 30.070 46.069 2.20 55.530 50,050 1168 172 335 0.790 2.53 22,660 19,920 1.69 49,97048,280 1.75 51,900 47,520 2.44 29,670 26,810 2.77 50,330 46,340 2.42 49,15045,370 2.20 47,760 44,630 2.32 48,570 44,910 Butane () 1-Pentene () Isopentane (e) Benzene () 58.123 0.579 0,641 0.626 0.877 0.673 0.660 0.867 72.150 78.114 84.161 86.177 92.141 100.204 114.231 142.285 100-110 170 1.72 41,800 40,100 1.84 47,500 44,400 2.27 48,310 44,740 1.71 42,40040,500 2.24 48,100 44,600 2.2347,890 44.430 2.2147,640 44,240 Heptane () 0.703 0.730 361 350 47,30044,000 072-078 0.78-0.84 CHỉ.87a 2.246,100 43,200 1.9 45,500 42,800 0.82-0.88 Heavy diesel (e) 50,000 45,000 CHNo.n 18 At 1 atm and 20C At 25*C for liquid fuels, and 1 atm and normal boiling temperature for gaseous fuels At 25*C. Multiply by molar mass to obtain heating values in kJrkmol.
940 TABLE A-28 Natural logarithms of the equilibrium constan e equilibrium constant K, for the reaction "A 8C+D is defined as K,-PR. Temp.. 298 -164.005 -186.975 -367.480 500-92.827 -105.630 -213.372 1000 -39.80345.150 -99.127 1200 -30.874-35.005 -80.011 1400 -24.463-27.742 -66.329 1600 -19.637-22.285 -56.055 1800 -15.866-18.030 -48.051 2000 -12.840-14.622 -41.645 2200 -10.353 -11.827-36.391 2400 -8.2769.497-32.011 2600 -6.517-7.521 28.304 2800 5.002-5.826-25.117 3000-3.685 -4.357-22.359 3200-2.534 -3.072 -19.937 3400 -1.516-1.935-17.800 3600-0.609 -0.926-15.898 3800 0.202-0.019-14.199 0.934 0.796 -12.660 2.513 -9.414 3.895 6.807 5.023 -4.666 -92.208 -106.208 -60.281 -103.762 57.616 23.529 17.871 -13.842 -10.830 -8.497 -6.635 -5.120 20.295 -14.609 16.099 -13.066 -10.657 -8.728 -11.921 8.145 -5.619 -3.433 3.019 -4.719 -2.801 2.937 2.212 -2.114 2.451 1.891 1.392 0.945 -0,542 0.701 -1.513 -0.501 4000 -0.921 -0.686 0.920 500 2.486 5000 3.725 5500 4.743 60005.590 3.197 4.245 5.963 Source of Data: Gordon J. Van Wylen and Richard E. Sonntag. Fundamentals of Classical Thermodymamics, English/SI Version, 3rd ed. New York John Wiley &Sons, 1986), p. 723, table A.14. Based on thermodynamic data given in JANAF, Thermachemical Tables (Midland, MI: Thermal Research Laboratory. The Dow Chemical Company, 1971).
Homework Answers
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Methane gas is burned with 30 percent excess air. This fuel enters a steady- flow combustor at 0.8 atm and 25oC and is mixed with the air. The products of combustion leave this reacto...
Methane gas is burned with 30 percent excess air. This fuel enters a steady-flow combustor at 0.9 atm and 25'C...
Methane gas is burned with 30 percent excess air. This fuel enters a steady-flow combustor at 0.9 atm and 25'C and is mixed with the air. The products of combustion leave this reactor at 0.9 atm and 1600 K. Determine the equilibrium composition of the products of combustion and the amount of heat released by this combustion in kJ/kmol methane. Use data from the tables. CH4 Combustion 25℃ CO, HO 1600 K 30%acess 25 C The amount of carbon dioxide...
Propane fuel (C3H8) is burned in a space heater with 65 percent excess air. The fuel and air enter this heater steadily at 1 atm and 17°C, while the combustion products leave at 1 atm and 97°C. Calcu...
Propane fuel (C3H8) is burned in a space heater with 65 percent excess air. The fuel and air enter this heater steadily at 1 atm and 17°C, while the combustion products leave at 1 atm and 97°C. Calculate the heat transferred in this heater, in kJ/kmol fuel. Use data from the tables The heat transfer in the heater iskJ/kmol.
Propane fuel (C3H8) is burned in a space heater with 65 percent excess air. The fuel and air enter this heater...
Formul Question 2 (50 points): Propane gas and burns with 20% excess air entering (molar C, Hs) at 25 C.I atm enters a reactor operating at steady state at 25 C l atm of the carbon entering with...
Formul Question 2 (50 points): Propane gas and burns with 20% excess air entering (molar C, Hs) at 25 C.I atm enters a reactor operating at steady state at 25 C l atm of the carbon entering with the fuel, 94% s) appears in the products at CO2 and the rest as CO. Heat transfer from the reactor occurs te of 1.4 x 10° kJ per kmol or propane. Use your ideal gas tables to answer this question. ite the...
Week 4 Process 1: Consider the process below: Water in Combustor Steam Generator Gas In Gas...
Week 4 Process 1: Consider the process below: Water in Combustor Steam Generator Gas In Gas Out Combustor exit Steam Out A methane (CH) and air mixture is burnt in the combustor then the heat is recovered to produce steam. The CHa/air mixture comes in at 25°C and contains 10 kg/h of CH4 and 500 kg/h of air (assume 79% Nitrogen (N2) and 21 % Oxygen (O2)). The final outlet gas leaves at 100 °C. The combustion reaction follows the...
1. [Suggested time 20-30 minutes] The reverse water gas shift (WGS) reaction occurs during many high temperature processes involving hydrocarbons and typically reaches equilibrium: coag) + H2(g)...
1. [Suggested time 20-30 minutes] The reverse water gas shift (WGS) reaction occurs during many high temperature processes involving hydrocarbons and typically reaches equilibrium: coag) + H2(g) 근 COe) + H2O(g) AG 298K (kJ/mol) AH1298K (kJ/mol) -137.66 -229.25 -395.51 0.00 -110.84 -242.52 -394.64 0.00 H20 (g) CO2(8) o lin 2 [3 points] Determine the standard Gibbs energy change for this reaction at 25°C b) c) [10 points] Calculate the equilibrium composition (molar fractions) for an isothermal reaction carried out at...
The initial volume of a gas at a pressure of 3.2 atm is 2.9 L
GAS LAWS 1. The initial volume of a gas at a pressure of 3.2 atm is 2.9 L What will the volume be if the pressure is increased to 4.0 atm? 2. A balloon is filled with 35 O L of helium in the morning when the temperature is 20.00. By noon the temperature has risen to 45.00. What is the new volume of the balloon? 3. A helium balloon with an internal pressure of 1.00 atm and a volume of 4.50 L...
Question 4 Not changed since last attempt Marked out of 1.00 Calculate w (in kJ) when 189 g iron (III) oxide (MM =...
Question 4 Not changed since last attempt Marked out of 1.00 Calculate w (in kJ) when 189 g iron (III) oxide (MM = 159.7 g/mol) reacts with excess carbon to produce carbon dioxide gas at 451 K: 2Fe2O3(s) + 3C(s) + 4Fe(s) + 3CO2(g) P Flag question Answer: Question 5 Not yet answered Calculate the work (in kJ) when 2.20 moles of methane react with excess oxygen at 470 K: Marked out of 1.00 CH4(g) + 20 (g) + CO2(g)...
10. Nitric acid, required in the production of nitrate fertilizers, is produced from ammonia by the...
10. Nitric acid, required in the production of nitrate fertilizers, is produced from ammonia by the Ostwald process. Use standard enthalpies of formation to calculate the enthalpy changes in the following system. Use the chemistry data tables posted on the google classroom to obtain the standard enthalpy of formation values. Show your work! (4 marks K/U) a. 4 NH3(g) + 5 O2(8) ► 4 NO(g) + 6 H2O(€) TULUI IU Several Compounds Compound AH, (kJ/mol) -704.2 AICI,(s) AI,O3(s) Caso (s)...
Question 1 (1 point) Calculate the density of nitrogen gas in a 4.32 L container at...
Question 1 (1 point) Calculate the density of nitrogen gas in a 4.32 L container at 1.0 atm and 25°C. Question 1 options: 0.57 g/L 0.74 g/L 1.15 g/L 1.31 g/L 1.56 g/L Save Question 2 (1 point) What volume is occupied by 1.00 kg of nitrogen gas at 5.00?C at a pressure of 735 Torr? Question 2 options: 1686 L 1242 L 843 L 738 L 621 L Save Question 3 (1 point) The ideal gas law fails to...
#5 S. Determine the percent yield of the following reaction when 2.80 g of Preacts with...
#5
S. Determine the percent yield of the following reaction when 2.80 g of Preacts with excess oxygen. The actual yield of this reaction is determined to by 3.89 g of P,Os. One 4 P +502 +2P205 12.803 t Properties of Liquids and Solids Instructions: Answer the following questions using the following information: AH 6.02 ku/mol; AH 40.7 kJ/mol; specific heat of water is 4.184 J/g °C, specific heat of ice is 2.063/8'C specific heat of water vapor is 2.03...
Methane gas is burned with 30 percent excess air. This fuel enters a steady-flow combustor at 0.9 atm and 25'C and is mixed with the air. The products of combustion leave this reactor at 0.9 atm and 1600 K. Determine the equilibrium composition of the products of combustion and the amount of heat released by this combustion in kJ/kmol methane. Use data from the tables. CH4 Combustion 25℃ CO, HO 1600 K 30%acess 25 C The amount of carbon dioxide...
Propane fuel (C3H8) is burned in a space heater with 65 percent excess air. The fuel and air enter this heater steadily at 1 atm and 17°C, while the combustion products leave at 1 atm and 97°C. Calculate the heat transferred in this heater, in kJ/kmol fuel. Use data from the tables The heat transfer in the heater iskJ/kmol.
Propane fuel (C3H8) is burned in a space heater with 65 percent excess air. The fuel and air enter this heater...
Formul Question 2 (50 points): Propane gas and burns with 20% excess air entering (molar C, Hs) at 25 C.I atm enters a reactor operating at steady state at 25 C l atm of the carbon entering with the fuel, 94% s) appears in the products at CO2 and the rest as CO. Heat transfer from the reactor occurs te of 1.4 x 10° kJ per kmol or propane. Use your ideal gas tables to answer this question. ite the...
Week 4 Process 1: Consider the process below: Water in Combustor Steam Generator Gas In Gas Out Combustor exit Steam Out A methane (CH) and air mixture is burnt in the combustor then the heat is recovered to produce steam. The CHa/air mixture comes in at 25°C and contains 10 kg/h of CH4 and 500 kg/h of air (assume 79% Nitrogen (N2) and 21 % Oxygen (O2)). The final outlet gas leaves at 100 °C. The combustion reaction follows the...
1. [Suggested time 20-30 minutes] The reverse water gas shift (WGS) reaction occurs during many high temperature processes involving hydrocarbons and typically reaches equilibrium: coag) + H2(g) 근 COe) + H2O(g) AG 298K (kJ/mol) AH1298K (kJ/mol) -137.66 -229.25 -395.51 0.00 -110.84 -242.52 -394.64 0.00 H20 (g) CO2(8) o lin 2 [3 points] Determine the standard Gibbs energy change for this reaction at 25°C b) c) [10 points] Calculate the equilibrium composition (molar fractions) for an isothermal reaction carried out at...
Question 4 Not changed since last attempt Marked out of 1.00 Calculate w (in kJ) when 189 g iron (III) oxide (MM = 159.7 g/mol) reacts with excess carbon to produce carbon dioxide gas at 451 K: 2Fe2O3(s) + 3C(s) + 4Fe(s) + 3CO2(g) P Flag question Answer: Question 5 Not yet answered Calculate the work (in kJ) when 2.20 moles of methane react with excess oxygen at 470 K: Marked out of 1.00 CH4(g) + 20 (g) + CO2(g)...
10. Nitric acid, required in the production of nitrate fertilizers, is produced from ammonia by the Ostwald process. Use standard enthalpies of formation to calculate the enthalpy changes in the following system. Use the chemistry data tables posted on the google classroom to obtain the standard enthalpy of formation values. Show your work! (4 marks K/U) a. 4 NH3(g) + 5 O2(8) ► 4 NO(g) + 6 H2O(€) TULUI IU Several Compounds Compound AH, (kJ/mol) -704.2 AICI,(s) AI,O3(s) Caso (s)...
#5
S. Determine the percent yield of the following reaction when 2.80 g of Preacts with excess oxygen. The actual yield of this reaction is determined to by 3.89 g of P,Os. One 4 P +502 +2P205 12.803 t Properties of Liquids and Solids Instructions: Answer the following questions using the following information: AH 6.02 ku/mol; AH 40.7 kJ/mol; specific heat of water is 4.184 J/g °C, specific heat of ice is 2.063/8'C specific heat of water vapor is 2.03...
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