I need a labeled process flow chart and a DOF analysis for this problem: One way to make coal “cleaner” is to gasify the coal into “city gas”. In a proposed molten-iron coal gasification process pulverized coal of up to 3 mm size is blown into a molten iron bath and oxygen and steam are blown in from the bottom of the vessel. Materials such as lime for settling the slag, or steam for batch cooling and hydrogen generation can be injected at the same time. The sulfur in the coal reacts with lime to form calcium sulfide, which dissolves into the slag. The process operates at atmospheric pressure and 1400 to 1500°C. Under these conditions, coal volatiles escape immediately and are cracked. The carbon conversion rate is said to be above 98% and the gas is typically 65 to 70% CO, 25 to 35% hydrogen, and less than 2% carbon dioxide. Sulfur content of the gas is less than 20 ppm. Assume that the product gas is 68% Co, 30% H2, and 2% CO2. Calculate the enthalpy change that occurs on the cooling of 1000 m3 of the gas at 1475 °C and 1 atm to 25°C and 1 atm. (Hint, check appendix B from the book Elementary Principles of Chemical Process, 4th Edition). Use 273.15 for conversion to degrees K and 0.08206 for the gas constant and use Carbon monoxide form 1 ~ a. 28.95 b. 0.4110 c. 0.3548 d. -2.220 0-1500 Carbon dioxide CO, form 1 a. 36.11 b. 4.233 c. -2.887 d. 7.464 0-1500 and Hydrogen H, form 1 a. 28.84 b. 0.00765 c. 0.3288 d. -0,8698 0-1500 for heat capacities Form 1: C,[kJ/(mol-°C)] or [kJ/(mol-K)] = a + bT + cT^2 + dT^3
I need a labeled process flow chart and a DOF analysis for this problem: One way to make coal “cleaner” is to gasify the coal into “city gas”. In a proposed molten-iron coal gasification process pulverized coal of up to 3 mm size is blown into a molten iron bath and oxygen and steam are blown in from the bottom of the vessel. Materials such as lime for settling the slag, or steam for batch cooling and hydrogen generation can be injected at the same time. The sulfur in the coal reacts with lime to form calcium sulfide, which dissolves into the slag. The process operates at atmospheric pressure and 1400 to 1500°C. Under these conditions, coal volatiles escape immediately and are cracked. The carbon conversion rate is said to be above 98% and the gas is typically 65 to 70% CO, 25 to 35% hydrogen, and less than 2% carbon dioxide. Sulfur content of the gas is less than 20 ppm. Assume that the product gas is 68% Co, 30% H2, and 2% CO2. Calculate the enthalpy change that occurs on the cooling of 1000 m3 of the gas at 1475 °C and 1 atm to 25°C and 1 atm. (Hint, check appendix B from the book Elementary Principles of Chemical Process, 4th Edition). Use 273.15 for conversion to degrees K and 0.08206 for the gas constant and use Carbon monoxide form 1 ~ a. 28.95 b. 0.4110 c. 0.3548 d. -2.220 0-1500 Carbon dioxide CO, form 1 a. 36.11 b. 4.233 c. -2.887 d. 7.464 0-1500 and Hydrogen H, form 1 a. 28.84 b. 0.00765 c. 0.3288 d. -0,8698 0-1500 for heat capacities Form 1: C,[kJ/(mol-°C)] or [kJ/(mol-K)] = a + bT + cT^2 + dT^3
Step by step
Solved in 2 steps
