課程名稱︰化學反應工程
課程性質︰必修
課程教師︰吳紀聖
開課學院:工學院
開課系所︰化工系
考試日期(年月日)︰103.05.28
考試時限(分鐘):110
是否需發放獎勵金:是
(如未明確表示,則不予發放)
試題 :
The 2nd Midterm of Reaction Engineering (Class 2)
May 28, 2014 10:20~12:10 普301
1. The elemental gas-phase reaction, A → B + 2C, is carried out
isothermally in a flow reactor with no pressure drop. The specific
reaction rate constant at 50℃ is 10^-3 min^-1, and the activation
energy is 85 kJ/mol. Pure A enters the reactor at 10 atm and 127℃ and
a molar flow rate of 2.5 mol/min. Calculate the reactor volume and
space time to achieve 90% conversion in (a) a PFR (10%), (b) a CSTR
(10%).
2. The liquid-phase reaction of methanol and triphenyl takes place in a
batch reactor at 25℃.
CH3OH + (C6H5)3CCl → (C6H5)3COCH3 + HCl
For an equal molar feed, the following concentration-time data was
obtained for the methanol.
Cmethanol (mol/dm^3) 1.0 0.95 0.816 0.707 0.5 0.37
Time (h) 0 0.278 1.389 2.78 8.33 16.66
The following concentration-time data were obtained for an initial
methanol concentration 0.1 mol/dm^3 and an initial triphenyl of 1.0
mol/dm^3.
Cmethanol (mol/dm^3) 0.1 0.0847 0.0735 0.0526 0.0357
Time (h) 0 1 2 5 10
(a) Determine the order of reaction and rate constant of rate law
(15%). (b) If you were to take more data points, what would be the
resonable setting (e.g. Cmethanol, Ctriphenyl)? Why? (5%)
3. The gas-phase reaction, A + B → C + D, takes place isothermally at
300K in a packed-bed reactor in which the feed is equal molar in A and
B with CA0 = 0.1 mol/dm^3. The reaction is second order in A and zero
order in B. Currently, 50% conversion is achieved in a reactor with
100 kg of catalyst for a columetric flow rate 100 dm^3/min. The
pressure drop parameter, α = 0.0099 kg^-1. What is the rate constant?
4. The decomposition of ozone in an inert gas M is by the following
elementary steps. Derive the rate law of ozone decomposition by PSSH.
k1
M + O3 ←→ O2 + O + M
k2
O3 + O —→ 2O2 rate limiting step
5. Derive the rate law for the following enzymatic reaction, i.e., rate
of product rP =?
Where E: enzyne, S: substrate, C: cofactor
k1 k2
E + S ←→ E‧S —→ P + E
k3
E + C ←→ E‧C
k4
E‧C + S —→ P + E‧C