Fuel processors for hydrogen - fuels, technology and recent

Transcription

Fuel processors for hydrogen - fuels, technology and recent
Professor De Chen
Institutt for kjemisk prosessteknologi, NTNU
Gruppe for katalyse og petrokjemi
Department of Chemical Engineering
Kjemiblokk V, rom 407
[email protected]
1 - 12/01/2017
Kjemisk reaksjonsteknikk
Chemical Reaction Engineering
H. Scott Fogler: Elements of Chemical Engineering
www.engin.umich.edu/~cre
University of Michigan, USA
Department of Chemical Engineering
Time plan:
Week 34-47, Tuesday: 08:15-10:00
Thursday: 11:15:13:00
Problem solving: Tuseday:16:15-17:00
2 - 12/01/2017
Department of Chemical Engineering
3 - 12/01/2017
Kjemisk reaksjonsteknikk
Chemical Reaction Engineering
 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.
Department of Chemical Engineering
4 - 12/01/2017
Lecture notes will be published on It’s
learning after the lecture
(Pensumliste ligger på It’s learning
Deles ut på de første forelesningene)
Department of Chemical Engineering
Øvingsopplegget ligger på It’s learning
Deles ut på de første forelesningene
5 - 12/01/2017
Felleslaboratorium
Faglærer: Professor Heinz Preisig
For information: It’s learning
Introduction lecture:
Department of Chemical Engineering
Place : in PFI-50001, the lecture room on the
top of the building
Date: Tuesday 21 of August
Time: 12:15 - 14:00
6 - 12/01/2017
TKP4110 Chemical Reaction Engineering
Øvingene starter onsdag 26 august kl 1615
i K5.
Lillebø, Andreas Helland: [email protected]
Stud.ass.:
Kristian Selvåg : [email protected]
Department of Chemical Engineering
Øyvind Juvkam Eraker: [email protected]
Emily Ann Melsæther: [email protected]
7 - 12/01/2017
Lecture 1
Kjemisk reaksjonsteknikk
Chemical Reaction Engineering
Department of Chemical Engineering
1.Industrial reactors
2.Reaction engineering
3.Mass balance
4.Ideal reactors
8 - 12/01/2017
Steam Cracking (Rafnes)
Department of Chemical Engineering
9 - 12/01/2017
Batch reactor
Department of Chemical Engineering
10 - 12/01/2017
Fixed bed reactor
Department of Chemical Engineering
11 - 12/01/2017
CSTR bioreactor
Department of Chemical Engineering
12 - 12/01/2017
Artificial leaf, photochemical reactor
Department of Chemical Engineering
13 - 12/01/2017
Chemical Engineering
Momentum
transfer
Department of Chemical Engineering
Reaction
engineering
Mass
transfer
Heat
transfer
14 - 12/01/2017
Department of Chemical Engineering
15 - 12/01/2017
Reaction Engineering
Mole Balance
Rate Laws
Stoichiometry
Department of Chemical Engineering
These topics build upon one another
16
16 - 12/01/2017
No-ideal flow
Heat Effects
Isothermal Design
Stoichiometry
Department of Chemical Engineering
Rate Laws
Mole Balance
17
17 - 12/01/2017
Chemical kinetics and reactor design
are at the heart of
producing almost all industrial chemicals
Department of Chemical Engineering
It is primary a knowledge of
chemical kinetics and reactor design that
distinguishes
the chemical engineer from other engineers
18 - 12/01/2017
Reaction Engineering
1. Week 34, Aug. 21, chapter 1, Introduction, mole balance, and ideal
Department of Chemical Engineering
reactors,
2. Week 34, Aug. 23, chapter2, Conversion and reactor size
3. Week 35, Aug. 28, chapter 3, Reaction rates
4. Week 35, Aug. 30, chapter 3, Stoichometric numbers
5. Week 36, Sept. 4, chapter 4, isothermal reactor design (1)
6. Week 36, Sept. 6, chapter 4, isothermal reactor design (2)
7. Week 37, Sept. 11, chapter 10, catalysis and kinetics (1)
8. Week 37, Sept. 13, chapter 10, catalysis and kinetics (2)
9. Week 38, Sept. 18, chapter 10, catalysis and kinetics (2)
10.Week 38, Sept. 20, chapter 5,7, kinetic modeling (1)
11.Week 39, Sept. 25, chapter 5,7, kinetic modeling (2)
12.Week 39, Sept. 28 chapter 6, multiple reactions (1)
13.Week 40, Oct. 2, chapter 6 multiple reactions (2)
14.Week 40, Oct. 4, summary of chapter 1-7, and 10
19 - 12/01/2017
Reaction Engineering
 41 (9/10, 11/10) 8.1 - 8.2 (JPA)
 42 (16/10, 18/10) 8.3 – 8.5 (JPA)
 43 (23/10, 25/10) 8.6 - 8.7 (JPA)

 44 (30/10, 1/11)

 45 (6/11, 8/11)
11 (JPA)
11 (JPA)
Department of Chemical Engineering
 46 (13/11, 15/11) 12.1-12.4 (JPA)
 47 (20/11,22/11) 12.5-12.8 (JPA)
 50 (Mandag 13/12)
Reaktorberegninger for ikke-isoterme systemer.
Energibalanser, stasjonær drift. Omsetning ved
likevekt. Optimal fødetemperatur.
CSTR med varmeeffekter og flere løsninger ved
stasjonær drift, ustabilitet.
Masseoverføring, ytre diffusjonseffekter i
heterogene systemer.
Fylte reaktorer (packed beds). Kjernemodellen
(shrinking core). Oppløsning av partikler og
regenerering av katalysator.
Diffusjon og reaksjon i katalysatorpartikler,
Thieles modul, effektivitetsfaktor.
Masseoverføring og reaksjon i flerfasereaktorer.
Oppsummering.
Eksamen, kl 0900-1300.
20 - 12/01/2017
Chemical Identity and reaction
 A chemical species is said to have reacted
when it has lost its chemical identity. There are
three ways for a species to loose its identity:
Department of Chemical Engineering
1. Decomposition
2. Combination
3. Isomerization
CH2=C(CH3)2
CH3CH3  H2 + H2C=CH2
N2 + O2  2 NO
C2H5CH=CH2 
21
21 - 12/01/2017
Reaction Rate
 The reaction rate is the rate at which a species
looses its chemical identity per unit volume.
 The rate of a reaction (mol/dm3/s) can be
expressed as either:
Department of Chemical Engineering
22
 The rate of Disappearance of reactant:
-rA
or as
 The rate of Formation (Generation) of product:
rP
22 - 12/01/2017
Reaction Rate
Department of Chemical Engineering
Consider the isomerization
AB
rA = the rate of formation of species A per unit
volume
-rA = the rate of a disappearance of species A per unit
volume
rB = the rate of formation of species B per unit
volume
23
23 - 12/01/2017
Reaction Rate
 For a catalytic reaction, we refer to -rA', which is
the rate of disappearance of species A on a per
mass of catalyst basis. (mol/gcat/s)
NOTE: dCA/dt is not the rate of reaction
Department of Chemical Engineering
24
24 - 12/01/2017
Reaction Rate
Department of Chemical Engineering
Consider species j:
1.rj is the rate of formation of species j per unit
volume [e.g. mol/dm3s]
2.rj is a function of concentration, temperature,
pressure, and the type of catalyst (if any)
3. rj is independent of the type of reaction system
(batch, plug flow, etc.)
4.rj is an algebraic equation, not a differential
equation
(e.g. = -rA = kCA or -rA = kCA2)
25
25 - 12/01/2017
General Mole Balance
System
Volume, V
Fj0
Department of Chemical Engineering
26
Gj
Fj
 Molar Flow  Molar Flow   Molar Rate   Molar Rate 
 Rate of
   Rate of
  Generation    Accumulation

 
 
 

 Species j in   Species j out  of Species j  of Species j 
dN j
Fj 0

Fj

Gj

dt
 mole 
 mole 
 mole 
 mole 











 time 
 time 
 time 
 time 
26 - 12/01/2017
General Mole Balance
If spatially uniform
G j  r jV
If NOT spatially uniform
Department of Chemical Engineering
27

V1
r j1
G j1  rj1V1


V2
rj 2
G j 2  rj 2 V2
27 - 12/01/2017
General Mole Balance
W
G j   rjiVi
i1
Take limit
n
Department of Chemical Engineering
Gj  
rjiVi

 r dV
j
i1 lim V  0 n  
28
28 - 12/01/2017
General Mole Balance
System
Volume, V
FA0
FA
GA
Department of Chemical Engineering
General Mole Balance on System Volume V
In
 Out  Generation  Accumulation
FA 0  FA

 r dV
A
dN A

dt
29
29 - 12/01/2017
Batch Reactor Mole Balance
Batch
FA 0  FA 
Department of Chemical Engineering
30

dN A
rA dV 
dt
FA 0  FA  0
Well Mixed

r
A
dV  rAV
dN A
 rAV
dt
30 - 12/01/2017
Batch Reactor Mole Balance
dN A
dt 
rAV
Integrating
when t = 0 NA=NA0
t = t NA=NA

Department of Chemical Engineering
t
NA

N A0
dN A
 rAV
Time necessary to reduce number of moles of A from NA0 to NA.
31
31 - 12/01/2017
Batch Reactor Mole Balance
t
NA

N A0
Department of Chemical Engineering
32
dN A
 rAV
NA
t
32 - 12/01/2017
CSTR Mole Balance
CSTR
Department of Chemical Engineering
FA 0  FA 
Steady State


dN A
rA dV 
dt
dN A
0
dt
33
33 - 12/01/2017
CSTR Mole Balance
Well Mixed
 r dV  r V
A
A
FA 0  FA  rAV  0
Department of Chemical Engineering
34

FA 0  FA
V 
rA
CSTR volume necessary to reduce the molar flow rate from FA0 to
FA.
34 - 12/01/2017
Plug Flow Reactor Mole Balance
V
FA
FA


Department of Chemical Engineering
35
V

V  V
 In  Out
 Generation

0
at V   



 at V  V  in V

FA V  FA V  V
 rA V
0
35 - 12/01/2017
Plug Flow Reactor Mole Balance
Rearrange and take limit as ΔV0
lim
V  0
Department of Chemical Engineering
36

FA V V  FA V
V
 rA
dFA
 rA
dV
This is the volume necessary to reduce the entering molar flow rate
(mol/s) from FA0 to the exit molar flow rate of FA.
36 - 12/01/2017
Alternative Derivation –
Plug Flow Reactor Mole Balance
PFR
dN A
FA0  FA   rA dV 
dt
Department of Chemical Engineering
Steady State
dN A
0
dt
FA0  FA   rA dV  0
37
37 - 12/01/2017
Alternative Derivation –
Plug Flow Reactor Mole Balance
Differientiate with respect to V
dFA
0
 rA
dV

Department of Chemical Engineering
38
The integral form is:

dFA
 rA
dV
V 
FA

FA 0
dFA
rA
This is the volume necessary to reduce the entering molar flow rate
(mol/s) from FA0 to the exit molar flow rate of FA.
38 - 12/01/2017
Packed Bed Reactor Mole Balance
PBR
Department of Chemical Engineering
39
dN A
FA W   FA W  W   rA W 
dt
dN A
Steady State
0
dt
lim
W  0
FA W  W  FA W
W
 rA
39 - 12/01/2017
Packed Bed Reactor Mole Balance
Rearrange:
dFA
 rA
dW
The integral form to find the catalyst weight is:

Department of Chemical Engineering
40
W
FA

FA 0
dFA
rA
PBR catalyst weight necessary to reduce the entering molar flow
rate FA0 to molar flow rate FA.
40 - 12/01/2017
Reactor Mole Balance Summary
Reactor
Batch
Differential
Integral
t
dN A
 rAV
dt
NA

N A0
dN A
rAV
NA
t
Department of Chemical Engineering
FA 0  FA
V 
rA
CSTR
PFR
Algebraic
dFA
 
rA
dV
V
FA

FA 0
FA
dFA
drA
V
41
41 - 12/01/2017