In the catalytic reaction CO + 3H2 -->CH4 +H2O, if 25% excess hydrogen was used and...

In a catalytic reaction CO + 3H2 ---> CH4 + H2O If 25% excess hydrogen was...

In a catalytic reaction CO + 3H2 ---> CH4 + H2O If 25% excess hydrogen was used and the conversion of CO is 70%. Calculate the mole fractions of the product steam components using a) Molecular balance b) Extent of reaction method c) Atomic balance

One process for the production of methanol is the catalytic reaction of carbon dioxide and hydrogen....

One process for the production of methanol is the catalytic reaction of carbon dioxide and hydrogen. The chemical reaction is given by: CO2  3H2  CH3OH  H2O It is desired to produce 1000 mol/hr of methanol. The single pass conversion of the reactor is 10% while the overall conversion is 80% (both in terms of hydrogen). Note, carbon dioxide in the fresh feed is in 20% excess and all of the product (methanol) and the byproduct (water) is...

The steam reforming reaction can be described by the following two reactions: CH4 +H2O ↔ CO+3H2...

The steam reforming reaction can be described by the following two reactions: CH4 +H2O ↔ CO+3H2 CH4 +2H2O ↔ CO2 +4H2 Assume that both these reactions achieve equilibrium at 600 K. The equilibrium constants at this temperature for the two reactions are 0.41 and 1.09 respectively. Calculate the equilibrium composition if the starting composition is 5 moles of steam and 1 mole of methane at a pressure of 2 atm.

Using average bond enthalpies, estimate the enthalpy change for the following reaction: CH4(g) + H2O(g)3H2(g) +...

Using average bond enthalpies, estimate the enthalpy change for the following reaction: CH4(g) + H2O(g)3H2(g) + CO(g) ____kJ

The most important commercial process for generating hydrogen gas is the water-gas shift reaction: CH4(g) +...

The most important commercial process for generating hydrogen gas is the water-gas shift reaction: CH4(g) + H2O(g) → CO(g) + 3H2(g) Use tabulated thermodynamic data to find ΔG° for this reaction at the standard temperature of 25°C. 1.423×102 kJ Calculate ΔG°1000 for this process when it occurs at 1000 K .

The reaction between ethylene and hydrogen bromide to form ethyl bromide is carried out in a...

The reaction between ethylene and hydrogen bromide to form ethyl bromide is carried out in a continuous reactor. The product stream is analyzed and found to contain 54.7 mole% C2H5Br and 19.3% HBr. The feed to the reactor contains only ethylene and hydrogen bromide. Calculate the fractional conversion of the limiting reactant and the percentage by which the other reactant is in excess. If the molar flow rate of the feed stream is 175 molls, what is the extent of...

Ammonia is produced by reacting nitrogen and hydrogen. A feed stream consisting of 2.400% argon (by...

Ammonia is produced by reacting nitrogen and hydrogen. A feed stream consisting of 2.400% argon (by mole) and stoichiometric proportion of the reactants (N2 and H2) is fed into the system at the rate of 100 mol/min. The components enter a reactor, and then all ammonia is separated from the other components and leaves the process. The other components are recycled back to the feed stream, with a portion being purged from the system. The mole percentage of argon in...

The reaction for synthesis of ammonia is CO + 3H2 → CH4 + H2O At 10...

The reaction for synthesis of ammonia is CO + 3H2 → CH4 + H2O At 10 atm and 400 oC, it was observed that 3.85% of the gas mixture was NH3, starting initially from pure NH3. What is the value of KP? The reaction for synthesis of ammonia is begin inline style 3 over 2 end style H subscript 2 left parenthesis g right parenthesis space plus space begin inline style 1 half end style N subscript 2 left parenthesis...

One method for the manufacture of “synthetic gas” is the catalytic reforming of methane with steam...

One method for the manufacture of “synthetic gas” is the catalytic reforming of methane with steam at high temperature and atmospheric pressure: CH4 (g)+ H2O(g)→ CO(g)+ 3H2 (g) The only other reaction to be considered is the water-gas-shift reaction: CO (g)+ H2O(g)→ CO2 (g)+ H2 (g) If the reactants (methane and steam) are supplied in the ratio 2 mol steam to 1 mol methane, and if heat is supplied to the reactor so that the products reach a temperature of...

The major industrial source of hydrogen gas is by the following reaction: CH4(g) + H2O(g) ------>...

The major industrial source of hydrogen gas is by the following reaction: CH4(g) + H2O(g) ------> CO(g) + 3 H2(g) Use bond energies to predict deltaH for this reaction. So I used bond energy chart: CH4(g): 4mol C-H= 4*413kJ/mol H2O(g): 2mol H-O = 2*467kJ/mol 3 H2(g): 3mol H-H = 3*432kJ/mol CO(g): 1mol C-O = 1*358kJ/mol And I got the answer as 1290kJ.... but it is wrong because apparently for CO(g) the bond has to be a triple bond...so the energy...