Lecture 4 - umich.edu · Last Lecture Relative Rates of Reaction 4 . Last Lecture Rate Laws - Power...
Transcript of Lecture 4 - umich.edu · Last Lecture Relative Rates of Reaction 4 . Last Lecture Rate Laws - Power...
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Chemical Reaction Engineering (CRE) is the field that studies the rates and mechanisms of
chemical reactions and the design of the reactors in which they take place.
Lecture 4
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Today’s lecture Block 1
Mole Balances Size CSTRs and PFRs given –rA=f(X)
Block 2 Rate Laws Reaction Orders Arrhenius Equation
Block 3 Stoichiometry Stoichiometric Table Definitions of Concentration Calculate the Equilibrium Conversion, Xe
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Reactor Mole Balances in terms of conversion Reactor Differential Algebraic Integral
CSTR
PFR
Batch
X
t
PBR
X
W3
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Last Lecture Relative Rates of Reaction
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Last Lecture Rate Laws - Power Law Model
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A reactor follows an elementary rate law if the reaction orders just happens to agree with the stoichiometric coefficients for the reaction as written. e.g. If the above reaction follows an elementary rate law
2nd order in A, 1st order in B, overall third order
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Last Lecture Arrhenius Equation k is the specific reaction rate (constant) and is given by the Arrhenius Equation.
Where:
k
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These topics build upon one another
Mole Balance Rate Laws Stoichiometry
Reaction Engineering
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How to find
Step 1: Rate Law
Step 2: Stoichiometry
Step 3: Combine to get
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We shall set up Stoichiometry Tables using species A as our basis of calculation in the following reaction. We will use the stochiometric tables to express the concentration as a function of conversion. We will combine Ci = f(X) with the appropriate rate law to obtain -rA = f(X).
A is the limiting Reactant.
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For every mole of A that react, b/a moles of B react. Therefore moles of B remaining:
Let ΘB = NB0/NA0
Then:
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Species Symbol Initial Change Remaining
Batch System Stoichiometry Table
B B NB0=NA0ΘB -b/aNA0X NB=NA0(ΘB-b/aX)
A A NA0 -NA0X NA=NA0(1-X)
Inert I NI0=NA0ΘI ---------- NI=NA0ΘI
FT0 NT=NT0+δNA0X
Where: and
C C NC0=NA0ΘC +c/aNA0X NC=NA0(ΘC+c/aX)
D D ND0=NA0ΘD +d/aNA0X ND=NA0(ΘD+d/aX)
11 δ = change in total number of mol per mol A reacted
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Constant Volume Batch Note: If the reaction occurs in the liquid phase
or if a gas phase reaction occurs in a rigid (e.g. steel) batch reactor
Then
etc. 12
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Suppose
€
−rA = kACA2CB
Batch:
Stoichiometry
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−rA = kACA 02 1− X( )2 ΘB −
baX
⎛
⎝ ⎜
⎞
⎠ ⎟
Equimolar feed:
Stoichiometric feed:
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Constant Volume Batch Reactor (BR)
and we have
if then
Constant Volume Batch
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Consider the following elementary reaction with KC=20 dm3/mol and CA0=0.2 mol/dm3. Xe’ for both a batch reactor and a flow reactor.
Calculating the equilibrium conversion for gas phase reaction,Xe
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BR Example
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Step 1:
Step 2: rate law,
Calculate Xe
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BR Example
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Symbol Initial Change Remaining
B 0 ½ NA0X NA0 X/2
A NA0 -NA0X NA0(1-X)
Totals: NT0=NA0 NT=NA0 -NA0 X/2
@ equilibrium: -rA=0
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Calculate Xe BR Example
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Species Initial Change Remaining
A NA0 -NA0X NA=NA0(1-X)
B 0 +NA0X/2 NB=NA0X/2
NT0=NA0 NT=NA0-NA0X/2
Solution: At equilibrium
Stoichiometry Constant volume Batch
Calculating the equilibrium conversion for gas phase reaction
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BR Example
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€
Xeb = 0.703
BR Example Xeb
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A A FA0 -FA0X FA=FA0(1-X)
Species Symbol Reactor Feed Change Reactor Effluent
B B FB0=FA0ΘB -b/aFA0X FB=FA0(ΘB-b/aX)
Where:
Flow System Stochiometric Table
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Species Symbol Reactor Feed Change Reactor Effluent
Where:
Flow System Stochiometric Table
Inert I FI0=A0ΘI ---------- FI=FA0ΘI
FT0 FT=FT0+δFA0X
C C FC0=FA0ΘC +c/aFA0X FC=FA0(ΘC+c/aX)
D D FD0=FA0ΘD +d/aFA0X FD=FA0(ΘD+d/aX)
and
Concentration – Flow System 21
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Species Symbol Reactor Feed Change Reactor Effluent
A A FA0 -FA0X FA=FA0(1-X)
B B FB0=FA0ΘB -b/aFA0X FB=FA0(ΘB-b/aX)
C C FC0=FA0ΘC +c/aFA0X FC=FA0(ΘC+c/aX)
D D FD0=FA0ΘD +d/aFA0X FD=FA0(ΘD+d/aX)
Inert I FI0=FA0ΘI ---------- FI=FA0ΘI
FT0 FT=FT0+δFA0X
Where: and
Concentration – Flow System
Flow System Stochiometric Table
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Concentration Flow System:
Liquid Phase Flow System:
Flow Liquid Phase
etc.
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We will consider CA and CB for gas phase reactions in the next lecture
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Mole Balance
Rate Laws
Stoichiometry
Isothermal Design
Heat Effects
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End of Lecture 4
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