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The rate of oxidation of hydrogen sulphide by oxygen to elemental sulphur over NaX and NaY zeolites and the adsorption of sulphur
Applied Elsevier
Catalysis, 14 (1985) 185-206 Science Publishers B.V., Amsterdam
THE RATE OF OXIDATION OVER
OF HYDROGEN
NaX AND NaY ZEOLITES
A.5. VERVER
Department
VAN SWAAIJ
of Chemical
Technology,
(Received
Enschede,
16 June
in The Netherlands
SULPHIOE
BY OXYGEN
AND THE ADSORPTION
and W.P.M.
217, 7500 AE
185 - Printed
Twente
TO ELEMENTAL
SULPHUR
OF SULPHUR.
University
of Technology,
P.O.
Box
The Netherlands.
1984, accepted
22 November
1984)
ABSTRACT The rate of oxidation of H S by O2 over synthetic sodium faujasite zeolites to produce elemental su? phur has been studied at partial sulphur load of the zeolite using a gravimetric method. The rate of sulphur accumulation on a sample exposed to an atmosphere of about 1.0 vol % H2S and 0.5 vol % O2 in nitrogen has been measured. The rate of oxidation of H2S to sulphur has been derived for three different NaY type zeolites, i.e. with an Si/Al ratio at temperatures from about 120 to 200 of 1.70, 2.07 and 2.40 respectively, "C. The activation energy of the rate constant appears to be the same for these zeolites and amounts to about 53 kJ mol-I. The reaction rate increases substantially with a decreasing Si/Al ratio of the zeolite. So the NaX type zeolite is clearly more active in the H2S oxidation than the NaY type. The frequency factor of the rate constant is found to increase linearly with the number of H2S adsorption sites described previously by Karge and Rasko. This suggests that these sites act as reactive sites in the oxidation of H2S over sodium faujasite zeolites. By the same micro-weighing technique the rate of desorption of sulphur from sulphur loaded zeolites has been determined at a temperature of about 300 "C. The sulphur vapour pressure close to the zeolite surface has been derived from the rate of weight loss by mass transfer calculations. It appears to be slightly lower for NaX zeolite than for NaY zeolite. In general, the relative sulphur vapour pressure is well below 10e2 for all zeolites we tested, unless the maximum adsorption capacity has been approached closely. Because of the high activity and the low relative sulphur pressures observed for NaX type zeolite, this zeolite is preferable as a catalyst in the oxidation of H2S with O2 if sulphur should be recovered in an adsorbed state.
INTRODUCTION The oxidation the overall process
of hydrogen
reaction
with molecular
in the production
[I]. The primary
0166-9834/85/$03.30
sulphide
reaction
0 1985
of elemental
involved
Elsevier Science
is:
Publishers
B.V.
oxygen sulphur
is known
to be
in the Claus
186 H2S +;
Below
02 = S + H20
about 500 "C this oxidation
improvement quently
of reaction
mentioned
rate. Active
as useful
lites such as NaX exhibit sulphur
reaction
carbons,
catalysts.
superior
requires
Among
activity
the use of catalysts
aluminas
and zeolites
these catalysts, and selectivity
for
are fre-
synthetic towards
zeo-
elemental
[2,3].
In the Claus metric
process,
combustion
catalysts,
H2S is converted
and by reaction
according
with
to sulphur
vapour
the SO2 produced,
by substoichio-
over alumina-based
to the reaction:
2H2S + SO2 = 3s + H20
In processes
such as CBA [4,5] and Sulfreen
low-H2S
gases
Sulphur
condenses
by reaction
however,
deals with
2 at temperatures
on the catalyst
We are currently based,
(2)
investigating
on reaction
a similar
of the H2S
desulphurization paper
oxidation
and desorption
work a study has been initiated
modified
to the application
enabled.
On this subject
we shall
As a part of a larger investigated effect
of the sulphur
observed
a most
orders
report
signal
From kinetic
of sulphur
measurements
Oxidation
elsewhere
of H2S over synthetic
zeolites,
but gave no data on the reaction
The adsorption Whiteman
[IO] and by Steijns
high adsorption respectively
sorption
capacities
at relative
pour pressures sulphur.
[9]. They reported
of sulphur
On the other
Steijns
Steijns
and Mars
exposed
to H2S and
activities
was studied
also
for NaX and NaY
was studied authors
reaction
rate were
rate or the activation
[II]. These
[7]
et al. [8]
X and Y zeolites
different
is
and found an autocatalytic
of the reaction
on NaX zeolite
and Mars
catalyst
energy.
by Barrer
reported
and
remarkably
of about 0.35 and 0.30 kg sulphur per kg zeolite -2 pressures as low as 10 , i.e. sulphur va-
sulphur
of a factor
of sulphur
vapour
In that way the devel-
for NaX zeolite
and Ziolek
such as
catalysts,
up to 200 'C, they determined
by Dudzik
is
and
[6].
catalysts,
a few values
which
Based on the
on zeolite
over a moving
In ESR experiments
of H2S and O2 [8], but only
presented.
bed systems.
of H2S over NaX zeolite
adsorbed.
strong
of sulphur.
process
study on different
the oxidation
O2 mixtures.
behaviour
in fluidized
process
over zeolites
of the present
desulphurization
by heating.
is part of this study
NaX, and the adsorption
of a continuous
from
of sulphur.
periodically
findings
opment
is recovered
the dew point
bed and is removed
1. The present
the rate of reaction
[5] sulphur below
100 lower
hand,
than the equilibrium
no data are available
on NaY zeolites.
pressure
in literature
of liquid
on the ad-
187 In this study, sulphur
we focused
over various
determined dation
an the reaction
the rate of deposition
of H2S, on a catalyst
and 0.5 vol % 02. We looked ed sulphur
behaviour
the different
the influence
both
the maximum
NaX and NaY zeolites
caused
by the adsorb-
ratio of the zeolite
the adsorption Using
we
the rate of the oxi-
phenomena
we studied
of H2S to
method,
of about 1.0 vol % H2S
of the Si/Al
from the H2S oxidation.
we investigated
and hence
in an atmosphere
for autocatalytic
rate. Furthermore,
of sulphur
apparatus,
Using a gravimetric
of sulphur,
sample
and shall discuss
on the reaction
rate of the oxidation
NaX and NaY zeolites.
and desorption
the same micro-weighing
sulphur
adsorption
and the desorption
capacity
behaviour
of
of the sul-
phur adsorbed.
EXPERIMENTAL Experimental Sulphur
set-up adsorbed
slowly,
because
sulphur
load close
volatility
the relative
sulphur,
by measuring
The experimental
set-up
of a Sartorius
inserted
diameter
sample
pan (diameter
30 mm).
[lI]. Due to this low
the rate of the H2S oxidation accumulation
can be studied of a catalyst
atmosphere.
provided
with a quartz
mounted
tubular
furnace
samples
were contained
10 mm) in the middle
of the microbalance
was connected
(heated
1. It con-
hangdown
length
0.30 m, in-
in a shallow
quartz
of the oven. The electronic to a recorder
and the temperature
tube
con-
for continuous
regis-
of the gas in the vicinity
pan.
Reaction gas ___I_ A gaseous reaction was made
mixture
by adding
H2S. The composition and checked
capacity
Catalyst
of the sample weight
mixture
evaporates very -2 is below 10 even at a
used in this study is shown in Figure
troller
nitrogen
pressure
the rate of weight
tration
of the sample
vapour
4406 microbalance
in a vertically
ternal
of e.g. NaX zeolite
adsorption
in a H2S and O2 containing
sisted
m3s-I
sulphur
to the maximum
of adsorbed
gravimetrically sample
in the micropores
of about
together
1.0 vol % H2S and 0.5 vol % O2 in
flows of dry air and nitrogen
of the gas mixture
by chromatographic
was fed to the bottom
was adjusted
analysis
for each experiment.
of the hangdown
(at 20 "C and atmospheric
containing
by calibrated
florrmeters
The reaction
tube at a flowrate
of 3.3*10s6
pressure).
Catalysts Small catalyst
amounts
was a commercial powder
of pure zeolite
powder,
and these were carefully
spread
grade Linde molecular
was supplied
by P.A. Jacobs
i.e. 1 to
10 mg, were
on the bottom
sieve,
(Katholieke
used
of the sample
type 13X. NaY(1.70, Universiteit
as a pan. NaX
see below)
Leuven,
Belgium).
-
air
3% H2S Q_ in N2
N2
I
FI
FI
Q
a--
J
reaction mixture
Q
vent
nitroger
%
m
vent
PU
Figure
4
I
I
Experimental
set-up.
2
3
ml
r-4
:I I
N2
FI
Furnace
Sample 7.
valve
controller switch pan
Gas flow 6.
5. Temperature
4.
Balance Recorder
2. 3.
controller
Microbalance
1.
189
The other NaY catalysts Amsterdam). resulting
Chemical Si/Al
NaX(1.151,
Before
bv (Research
were added
in parentheses
and NaY(2.40)
Centre
was performed
to the zeolite
and the
names:
respectively.
procedure the catalyst
rate about 0.2 'C s-l) up to 400 "C. temperature,
attained,
experiments.
sample was dried in a nitrogen -6 m3s-1 N2; flow rate 3.3*10 STPI at increasing
> 99.98%
(heating
the measurement were
by Akzo Chemie
of the Si and Al content
NaY(2.07)
the experiments,
(high purity, rature
ratios
NaY(1.701,
Experimental
were provided
analysis
nitrogen
both isothermal
was replaced
Unless mentioned
When,
conditions
by the reaction
otherwise,
flow tempe-
after cooling
and a constant
mixture
only fresh catalyst
to
weight
to start the samples
have
been used.
RESULTS Accumulation When
of sulphur
the reaction
was introduced was formed
gas mixture
to the hangdown
from the oxidation
on the catalyst.
Formation
reaction
was also
In the microbalance, colour
recorded.
Figure
2. Accumulation
A typical
of the experiment time in the tubing
a level others
roughly
corresponding
[lO,ll].
As a matter
decreases
when the maximum
available
surface
may also become sulphur
vapour
pressure
and the desorption
sulphur
sulphur
On account
load,
sulphur
In the course
of the deposition
of sulphur
owing
reported
by
to the decreasing
of the zeolite
of sulphur
pores
[lo]. As
from the H2S
as is shown
in Figure
(Cl stops the formation
the weight
of the catalyst
pressure
becomes
stable weight
of sulphur
at
of the relative
of sulphur
vapour
tube.
holds
rate of the H2S oxidation
increase
of sulphur
and an apparently
of the catalyst
is established,
by nitrogen
of the lower
by the
to this, desorption
filling
of sulphur,
the rate of desorption
a few minutes
uptake
the formation
of sulphur
after the
is caused
increase
of the rapid
mixture
and, due to desorption
decreases.
within
the reaction
between
time plot is given in
zone of the hangdown
load is reached,
at the maximum
oxidation
versus
of the sample
about 45 seconds
to the maximum
In addition
was apparent
increase
delay period
the weight
because
an equilibrium
2. Replacing
of a weight
sulphur
a result,
from the
of fact, the reaction
area [7, 121.
important
(see [6],
and in the preheating
time of reaction
of the H2S-O2
of sulphur
is observed
(A), which
sulphur
and deposited
with fluid bed reactors
and the sustained
example
residence
a certain
the presence
of weight
elemental sample
as the main product
in our experiments
beginning
After
tube of the microbalance,
of the zeolite
weight
1 ~01% H2S and 0.5 ~01% 02 in N2
of H2S over the catalyst
of sulphur
p. 151). yellowish
shown
of about
at slightly
negligibly
is observed
also water,
produced
of slowly lower
small (D). by the
190
0,6-
T
1
0
I
1
2
I
I
3
4
time (KP s) Figure 2 zeolite,
Typical
weight
registration
of sulphur
accumulation
NaY(2.40)
1.65 mg, 188 "C.
T("C)
Figure
3
(al fresh.
Thermoanalysis (b) containing
of NaY(2.40) 0.34
(1.65 mg, heating
kg sulphur
rate 0.17
per kg dry zeolite.
'C s-l).
191
reaction,
might
have been adsorbed
zeolites
are known
analysis
of a fresh NaY(2.40)
cant weight gradually
to strongly
sample,
loss due to dehydration
decreasing
shows a marked catalyst
simultaneously
adsorb
weight
At temperatures
(Figure
as given
below
is observed.
loss of weight
occurred
Similarly,
above 200 "C a second weight
caused
about 100 and 200 "C all the sulphur
by the desorption
is not likely obtained
to adsorb
eventually
sulphur
adsorption
Maximum
sulphur
adsorption
At temperatures
while
loaded
sample
of the fresh
is slightly
is observed,
adsorbed.
lower.
which
is ob-
Consequently,
on the catalyst,
while
And so the net increase
2 can be considered
of
the maximum
values
of the maximum
have been determined.
sulphur
The results
capaci-
are present-
NaX(1.15) zeolite appears to adsorb less sulphur than the
The adsorption
temperature,
a signifi-
uo to 2011 "C a
capacity
above 100 "C several
4. The
NaY zeolites.
because
of the zeolite.
ty of the NaX and NaY zeolites ed in Figure
loss
remains
substantially.
at D in Figure
capacity
dehydration
loss
of the sulphur
3a, shows even
a sulphur
this weight
viously
water
in Figure
in the range where
3b), although
the sulphur,
[13]. Thermogravimetric
100 "C, while
between
weight
with
water molecules
capacity
for NaY zeolites
of NaX(1.15)
is clearly
a slight decrease
independent
at increasing
of
tempe-
rature can be seen. Adsorption
of sulphur
ture, because passage atoms
the apertures
of most molecules
adsorbed
capacity.
takes
for NaX11.15) whereas
Seff [14]
the supercages
of NaA zeolite.
of NaX zeolite
and about
the presence
for
are too narrow
the maximum
zeolite
has studied
sulphur
S5 rings
in each
sulphur
adsorption
of about 14 sulphur adsorb
up to 21 sul-
adsorption
complexes
similar
By an X-ray
diffraction
supercage
adsorption
the
of sulphur
has supercages
ratio.
struc-
to allow
number
from the maximum a value
Such a zeolite
From the maximum
of the zeolite
the NaY zeolites
the same Si/Al
of two parallel
has been proven.
Consequently
can be calculated
per supercage,
phur atoms per cavity.
in the supercages
to the other cages [13].
in a supercaqe
We determined
atoms adsorbed
place
in
to those study
of the NaA zeolite
capacity
we calculated
NaX(1.15) zeolite about the same number of sulphur atoms per supercage,
namely
14. For NaY zeolites
observed. above,
This might
or it might
tion because zeolites
a higher amount of sulphur atoms per cavity is
indicate
be caused
of a lower
the absence by a larger
cation
volume
concentration
as will be substantiated
Steijns
of the sulphur
and Mars [II] reported
available
complexes
mentioned
for sulphur
in the supercages
adsorp-
of the NaY
below. a maximum
NaX zeolite
of about 0.30 kg sulphur
what higher
than we have found
sulphur
per kg zeolite
for the NaX(1.15)
adsorption
capacity
at 260 "C, which
zeolite.
of
is some-
This can be ex-
192
-
0
NaX
(1.15)
A Nay
-I
(170)
0
Nay
(2.07)
l
Nay
(2.40)
I
2jo
2bo
160
100
T("C) Figure
4
Maximum
sulphur
adsorption
capacity
of NaX and NaY zeolites
versus
ratio of their zeolite
sample
temperature.
plained, might
however,
have
by suggesting
that the Si/Al
been slightly higher. Unfortunately
the Si/Al
ratio was not stated
by them.
The rate of oxidation The increase of oxidation influenced dation.
by simultaneous
According
within which served
might
concentration the catalyst causes
under
of water
analysis
curve
weight,
completely
might
be
also by the H2S oxi-
(cf. Figure
3) relatively
of the H2S oxidation, because
water
at B) that this amount
change
to be present
of the H2S - 02 feed,
adsorbed,
if the temperature
higher
a substantial
is likely
interruption
the weight
on the rate
increase
above 100 'C if the atmos-
on the catalyst,
of any possible
these conditions
almost
produced
from the H2S oxidation,
By intermediate
2, dotted
depends
the rate of weight
are to be expected
be present
layer.
2 obviously
But in the course
resulting
per cent of the catalyst
corresponds
water
the desorption
(cf. Figure
Therefore,
However,
adsorption
of nitrogen.
of water
in Figure
to the thermogravimetric
of adsorbed
phere consists amounts
observed
of H2S to sulphur.
low amounts
water
of Ii22
of weight
it could is less
is above
about
of the catalyst
to the rate of the deposition
be ob-
than one 120 'C. sample
of sulphur
and
193
hence to the rate of the oxidation the H2S oxidation plot according
From these
=>=dLp MS
x
results,
can be evaluated
only
to the known
data on the reaction
in the Appendix.
the mass
the concentration
zeolite.
was measured,
for the NaY zeolites
The rate of oxidation described typical
above,
example
I
gradientless
5
Reaction
(zeolite
I
versus
I
150
could
temperature
increase
transfer
rise of
for the ex-
was always
limitations.
be determined
in the that But
satisfactorily,
from the weight
the sulphur
1
1
I
0.3
(kgS/kgzeolite)
signal
load. Figure
to be poorly
0.2
“C)(a)
experi-
conditions.
rate of the oxidation
NaY(1.70),
mass
a). The rate data appear
0.1
as is de-
in this case an activity
of H2S was calculated
Xs
Figure
by serious
are
is at least 80 per
has to be made
the rate of the weight
and was plotted (curve
0
load
Although
the rate of reaction
approximately
in detail
and that the ultimate
are
effects
that in most
at the catalyst
bed is less than 4 "C. An exception
high that it has been influenced
i.e. under
phenomena
we have estimated
of both reactants
on the NaX(1.15)
at the catalyst
and if temperature
and heat transfer
Accordingly,
cent of the feed gas concentration
H2S oxidation
time
rate of the H2S oxidation
if the H2S and O2 concentration
We studied
periments
versus
(3)
feed gas concentrations
absent.
the catalyst
of fact, the rate of
to the weight
W,MS
useful
scribed ments
of H2S. As a matter
from the tangent
to:
'H2S = 2 * '02
close
then follows
as
5 shows a
reproducible
I
r
0.4
-
of H2S with
first experiment
O2 versus
the sulphur
(b) fourth experiment.
194 below
a sulphur
load of about 5 wt %, whereas
load are significant era1 cycles sequent
with
and, for example,
regeneration
accumulation
(see Figure
of the high activity
%, is not very clear.
We looked
on the fresh catalyst,
amounts,
load contributes
catalyst,
TABLE
but as is shown
considerably
more
to describe
Weight increase (wt %1
At high sulphur
load a maximum
to an NaX catalyst
peratures
between
phenomena
are generally
assumed kinetics
tained, from which -1 is derived.
an activation This
energy
of the reaction -1 about 55 kJ mol . Based
agrees
adsorbed
in H2S. energy
effect
-0.02 0.03 0.05 0.08
obtained
This
[7] with
regard effect
6.
Autocatalytic
are given
rate equation
and 13X molsieve
that the
lines
are ob-
of about 53 kJ
of the activation
reported
by Steijns,
viz.
adsorbed
on purified
active
mechanism [7,8].
in the
has been
are approximately
parallel
of the rate constant
of sulphur
tem-
at a sulphur
et al. [R] who have found
Reasonably
a general
in porous materials
at different
respectively
fairly well with values
et al. derived
Iron content, dry base (wt %l
in Figure
rate over a 13X catalyst
on the autocatalytic Steijns
over sulphur
on aluminas
in O2 and zero order
of the zeolites
and Mars
7. A first order
data of Steijns
of the H2S oxidation
mol
carbons,
with
2
rates observed
0.03 and 0.05 kg S per kg zeolite
in accordance
of the
extensively.
by them as the autocatalytic
The reaction
in Figure
activity
activity
of the catalyst.
120 and 200 "C, are summarized apparent.
the ini-
at higher
rate is observed.
by Steijns
rate of the H2S oxidation
plot presented
order
in the reaction
reported
in the micropores
on the reaction
explain
the activity
NaX(1.15) NaY(1.70) NaY(2.07) NaY(2.401
and has been described
adsorbed
load of 0.01,
been
about 5 wt
1, only small
cannot
Iron content -Catalyst
I:! 108 133
has previously
i.e. below
to the overall
Temperature ("Cl
1.0 0.4 0.4 0.3
of sulphur
again
temperature
H2S from an 02-free
in Table
the initial
data for H2S (1.0 vol.%)
phenomenon
Arrhenius
of
TABLE
NaX(1.151 NaY(1.70) NaY(2.071 NaY(2.401
Data
load,
Because
1
Catalyst
first
at low sulphur
for the adsorption
satisfactorily.
we did not attempt
Adsorption
to about 400 "C and sub-
reaction
i.e. less than 1.0 wt %, were found, which
tial peak in the activity sulphur
in nitrogen
at the original
of sev-
in the course
5, curve bl.
The nature
mixture
by heating
of sulphur
at a higher
the data obtained
also persistent
for the oxidation
They showed
of H2S
that the oxida-
0
-
load.
Reaction
0.4
01 x5 (kgS/
02 03 __
0.4
of H2S with O2 versus
kg NaY(207))
rate of the oxidation
0
1
(a) NaY(1.70).(b) NaY(2.07).(c) NaY(2.40).
Figure 6
03
02
01
X,(kgS/kgNaY(170))
006 004
the sulphur
OA Xs
(kgS/kgNaY
(240))
-
196
E=
53
kJ mol-'
NaY
(I.701
NaY
(2.071
NaY (240)
220 I I
I
100 I I
1
2.0
T("C)
140 I
I I
2.2
103 r
I
I
2.4
2.6
IO3 / T ( K-l> Figure
7
Arrhenius
plot of reaction
tion rate over an NaX zeolite [IZ], which
clearly
reflects
is related
with
sulphur
tial differences similarity
in the reaction
area are unlikely Q/Al
ratio
might
be causing
iron content
Obviously,
more
Dudzik
zeolite
active.
activity
is attended
parameters
which
surface
discussed comprises
We have found
differences adsorbed
Steijns
[7,12].
(see Table
by Steijns
an interaction
[9]. The chemisorption
in
of the
surface
with
a low
that iron impurities
analysis
of the zeolites
2) and, additionally, activity
in the oxidation
a mechanism
area
substan-
Because
in sulphur
on zeolites
suggested
Chemical
by a decreasing
are involved
than those considered
and Ziolek
NaY zeolites,
sulphur
shown low iron contents
increasing
NaY zeolites
large
surface
On the other
on a 13X zeolite,
catalyst.
rate over the NaY zeolites.
and, therefore,
a higher
sulphur
role of sulphur.
adsorbed
carbon
structure,
seems to be more
has, however,
of sulphur
on an active
of the zeolite
to the specific
the autocatalytic
hand, they found a high activity comparison
rate constants.
an
of the catalyst.
of H2S over NaX and
[15].
of the H2S oxidation of adsorbed
over NaX and
reactants
of H2S is suggested
and the
as an essential
197
step, at least during
the initial
on NaX and NaY zeolites spectroscopy
of zeolites
Rasko [17] determined na-rich
zeolites,
ally on unlocated tration
unit cell, inside
with
and suggested Na+ cations
remaining
cations
oxidation
of H2S is likely
cationic equal
n
near the walls depends
is equal
occupy
ratio.
Karge
of alumina
The concen-
tetrahedra
and hexagonal
per
where
the number
by Karge
of
positions
prisms.
of the supercages,
sites per unit cell has been proposed
and
on alumi-
The number
the well-coordinated
Consequently,
By IR
preferenti-
of the supercages.
cages
near the walls
to proceed.
ratios,
takes place
on the Si/Al
i.e. sodalite
are located
Si/Al
of H2S
[16,17,18].
of the H2S adsorption
to the number
preferentially
the small cages [lg],
varied
nature
Adsorption
authors
that this adsorption
strongly
per unit cell but cations
by many
systematically
the dissociative
of these cations
Na+ cations
stage of the reaction.
has been described
The the
of these
and Rasko
as being
to: 192 + Sl/Al - 56
=1 Na+
(4)
They have found a good correlation ly adsorbed equation sites
H2S molecules
above.
zeolite. calculated Figure
8 as a function
concentration
8
factor
from the reaction
4. The value
Figure
reaction,
in the supercages
The frequency
k. of the Arrhenius
to increase
Frequency
factors
equation, in Figure
concentration rather
of the Arrhenius
to the
sites act as reactive to the number
on the Si/Al ratio of the
with
equation
which
can be
7, is plotted
calculated
linearly
sites in accordance
in the supercages.
of dissociative-
sites according
rate is related
and thus depends
rate data presented
of H2S adsorption
Na+ concentration
the reaction
of the Na+ cation
of k. is found
the concentration
of cationic
if the H2S adsorption
Consequently,
in the oxidation
of Na+ cations
between
and the number
with
an increasing
the suggested
versus
in
by equation
reac-
the calculated
198
tive sites model.
Figure
Na+ cations,
would
However,
which
8 predicts
this can also be explained
56 in equation cations
Ziolek
ratio [ZO]. They suggested (A104-)
cations
is located
heating
H2S oxidation,
which
of
by other workers
the catalytic and the Si/Al
with the number
of alumina
the total number
of Na+ ca-
because
only a fraction
sites and are thus likely
to about 300 "C, sulphur
desorbs
this treatment.
slowly
of Na+
to participate
accumulated
during
in detail
Barrer of sulphur
in
at each
and Whiteman
desorbs
be removed
by
in subsequent
from the zeolite
some irreversibly
adsorbed
the main part of the sulphur
at moderate
in the Appendix,
heating.
the sulphur
bed can be determined
sulphur
vapour
pressure
at
from the rate of the weight
loss as a function
and as a result,
of the sulphur
data on the vapour
load were obtained.
[lo] have investigated
and phosphorus
on different
of sulphur
concentration
very small bed heights
These
pres-
data are presented
gradients
and Mars
ate-adsorbate
[ll],
interaction
pressure ratio,
vapour
pressure
inside
the catalyst
sorption
bed.
S-shaped
isotherms
on the adsorbing of sulphur
might
more
we used
be consider-
determined an adsorb-
The sulphur
material. rapidly,
sul-
load.
indicating
molecules.
no
fluxes
the minimum
on NaX zeolite
zeolite
proceeds
Moreover,
sulphur
are found
sulphur
expect
and the mass
at the interface
isotherms
a relativ-
we might
to reach
at the actual
of the adsorbed
also depends
the desorption
pressure
and desorption
and have mentioned Therefore,
two to six hours
of sulphur
with the sulphur
In agreement
zeolites
of less than half a millimeter,
phur load, So the sulphur ed the equilibrium
the adsorption
from NaX zeolite.
were very low, i.e. it took about
by Steijns
while
the
over 90 per
9.
ely rapid release important
are formed,
experiments
could
adsorbed
could be removed obviously,
during
Eventually
the H2S oxidation
the rate of the weight
load in the desorption
in Figure
species
of the catalyst
loss. We measured
sure of sulphur
cycles,
the H2S oxidation
As is described the surface
during
On the fresh zeolite,
sulphur
was accumulated bed.
is the fact that sulphur
accumulationdesorption
or chemisorbed
which
from the catalyst
accumulated
Noteworthy
about completely.
Si/Al
equals
number
process.
cent of the sulphur
vapour
between
correlation
of the constant
higher
suggested
of
sites.
desorption
After
sulphur
a relation
is not very likely,
on supercage
the H2S adsorption
Sulphur
a direct
This
lower value
over NaX and NaY zeolites
per unit cell,
tions per unit cell.
in the absence
of e.g. other
the apparently
H,S adsorption
have elaborated
of the H2S oxidation
tetrahedra
with
for dissociative
and Dudzik
activity
activity
activity
by a possibly
4, in correspondence
available
a residual
imply an additional
At increasing
which
might
be
202 gas velocity
Ills
V
volume
m3
W
weight
V
wO
weight
ng h
kg of dry catalyst
sulphur
xS a
sample
load
heat transfer viscosity thermal
-1
coefficient
of gas conductivity
of gas
kg kg Slkg zeolite)-1 W m-2 .C-1 -2 Nsm W m-1 .C_l
4;;
heat flux
kW m
4;
mass
molm
d
Thiele
pg P
flux
-2 -2
s
-1
modulus
density
of gas
density
of zeolite
kg m particle
-3
kg me3
Subscripts eff
effective
i
at the interface
REFERENCES
5 6 7 8 ?O
11 12 13 14 15 16 :‘B 19 20 21 22 23 24 25 2’;
B.W. Gamson and R.H. Elkins, Chem. Eng.Prog. 49, (1953) 203. G.T. Kerr and G.C. Johnson, J. Phys. Chem., 64 (1960) 381. M. Steijns and P. Mars, Ind. Eng. Chem. Prod. Res. Dev., 16 (1977) 35. J.E. Nobles, J.W. Palm and U.K. Knudtson, Hydrocarbon Process., 56 (1977) 7 143. A.L. Kohl and F.C. Riesenfeld, Gas Purification, Gulf Publishing Co., Houston, 1979. A.B. Verver, Thesis, Twente University of Technology, The Netherlands,1984. M. Steijns and P. Mars, J. Catal., 35 (1974) 11. M. Steijns, F. Derks, A. Verloop and P. Mars, J. Catal., 42 (1976) 96. Z. Dudzik and M. Ziolek, J. Catal., 51 (1978) 345. R.M. Barrer and J.L. Whiteman, J. Chem. Sot. A, (1967) 13. M. Steijns and P. Mars, J. Colloid Interface Sci., 57 (1967) 175. M. Steijns, A. Peppelenbos and P. Mars, J. Colloid Interface Sci., 57 (1967) 181. D.W. Breck, Zeolite Molecular Sieves, John Wiley & Sons, 1974. K. Seff, J. Phys. Chem., 76 (1972) 2601. M. Steijns, Thesis, Twente University of Technolagy, The Netherlands,1976. A.V. Deo, I.G. Dalla Lana and H.W. Habgood, J. Catal., 21 (1971) 270. H.G. Karge and G. Rasko, J. Colloid Interface Sci., 64 (1978) 522. R.W. Tower, Z.M. George and H.G. Karge, Preprints 6th Can. Symp. on Catalysis, August 19-21, 1979, Ottawa, Ontario. J.V. Smith, in: Zeolite Chemistry and Catalysis, Ed.: J.A. Rabo, ACS Monograph 171, 1976. M. Ziolek and Z. Dudzik, Zeolites, 1 (1981) 117. R.B. Bird, W.E. Stewart and E.N. Lightfoot, Transport Phenomena, John Wiley & Sons, 1960. W.E. Resnick and R.R. White, Chem. Eng. Progr., 45 (1949) 377. T. Wigmans, H. van Cranenburgh, R. Elfring and J.A. Moulijn, Carbon, 21 (1983) 23. C.N. Satterfield, Mass Transfer in Heterogeneous Catalysis, M.I.T. Press,1970. A. Meisen and H.A. Bennett, Hydrocarbon Process., 58 (1979), 12 131. International Critical Tables, McGraw-Hill, New York, 1929. A.B. Verver and W.P.M. van Swaaij, to be published.
Catalysis, 14 (1985) 185-206 Science Publishers B.V., Amsterdam
THE RATE OF OXIDATION OVER
OF HYDROGEN
NaX AND NaY ZEOLITES
A.5. VERVER
Department
VAN SWAAIJ
of Chemical
Technology,
(Received
Enschede,
16 June
in The Netherlands
SULPHIOE
BY OXYGEN
AND THE ADSORPTION
and W.P.M.
217, 7500 AE
185 - Printed
Twente
TO ELEMENTAL
SULPHUR
OF SULPHUR.
University
of Technology,
P.O.
Box
The Netherlands.
1984, accepted
22 November
1984)
ABSTRACT The rate of oxidation of H S by O2 over synthetic sodium faujasite zeolites to produce elemental su? phur has been studied at partial sulphur load of the zeolite using a gravimetric method. The rate of sulphur accumulation on a sample exposed to an atmosphere of about 1.0 vol % H2S and 0.5 vol % O2 in nitrogen has been measured. The rate of oxidation of H2S to sulphur has been derived for three different NaY type zeolites, i.e. with an Si/Al ratio at temperatures from about 120 to 200 of 1.70, 2.07 and 2.40 respectively, "C. The activation energy of the rate constant appears to be the same for these zeolites and amounts to about 53 kJ mol-I. The reaction rate increases substantially with a decreasing Si/Al ratio of the zeolite. So the NaX type zeolite is clearly more active in the H2S oxidation than the NaY type. The frequency factor of the rate constant is found to increase linearly with the number of H2S adsorption sites described previously by Karge and Rasko. This suggests that these sites act as reactive sites in the oxidation of H2S over sodium faujasite zeolites. By the same micro-weighing technique the rate of desorption of sulphur from sulphur loaded zeolites has been determined at a temperature of about 300 "C. The sulphur vapour pressure close to the zeolite surface has been derived from the rate of weight loss by mass transfer calculations. It appears to be slightly lower for NaX zeolite than for NaY zeolite. In general, the relative sulphur vapour pressure is well below 10e2 for all zeolites we tested, unless the maximum adsorption capacity has been approached closely. Because of the high activity and the low relative sulphur pressures observed for NaX type zeolite, this zeolite is preferable as a catalyst in the oxidation of H2S with O2 if sulphur should be recovered in an adsorbed state.
INTRODUCTION The oxidation the overall process
of hydrogen
reaction
with molecular
in the production
[I]. The primary
0166-9834/85/$03.30
sulphide
reaction
0 1985
of elemental
involved
Elsevier Science
is:
Publishers
B.V.
oxygen sulphur
is known
to be
in the Claus
186 H2S +;
Below
02 = S + H20
about 500 "C this oxidation
improvement quently
of reaction
mentioned
rate. Active
as useful
lites such as NaX exhibit sulphur
reaction
carbons,
catalysts.
superior
requires
Among
activity
the use of catalysts
aluminas
and zeolites
these catalysts, and selectivity
for
are fre-
synthetic towards
zeo-
elemental
[2,3].
In the Claus metric
process,
combustion
catalysts,
H2S is converted
and by reaction
according
with
to sulphur
vapour
the SO2 produced,
by substoichio-
over alumina-based
to the reaction:
2H2S + SO2 = 3s + H20
In processes
such as CBA [4,5] and Sulfreen
low-H2S
gases
Sulphur
condenses
by reaction
however,
deals with
2 at temperatures
on the catalyst
We are currently based,
(2)
investigating
on reaction
a similar
of the H2S
desulphurization paper
oxidation
and desorption
work a study has been initiated
modified
to the application
enabled.
On this subject
we shall
As a part of a larger investigated effect
of the sulphur
observed
a most
orders
report
signal
From kinetic
of sulphur
measurements
Oxidation
elsewhere
of H2S over synthetic
zeolites,
but gave no data on the reaction
The adsorption Whiteman
[IO] and by Steijns
high adsorption respectively
sorption
capacities
at relative
pour pressures sulphur.
[9]. They reported
of sulphur
On the other
Steijns
Steijns
and Mars
exposed
to H2S and
activities
was studied
also
for NaX and NaY
was studied authors
reaction
rate were
rate or the activation
[II]. These
[7]
et al. [8]
X and Y zeolites
different
is
and found an autocatalytic
of the reaction
on NaX zeolite
and Mars
catalyst
energy.
by Barrer
reported
and
remarkably
of about 0.35 and 0.30 kg sulphur per kg zeolite -2 pressures as low as 10 , i.e. sulphur va-
sulphur
of a factor
of sulphur
vapour
In that way the devel-
for NaX zeolite
and Ziolek
such as
catalysts,
up to 200 'C, they determined
by Dudzik
is
and
[6].
catalysts,
a few values
which
Based on the
on zeolite
over a moving
In ESR experiments
of H2S and O2 [8], but only
presented.
bed systems.
of H2S over NaX zeolite
adsorbed.
strong
of sulphur.
process
study on different
the oxidation
O2 mixtures.
behaviour
in fluidized
process
over zeolites
of the present
desulphurization
by heating.
is part of this study
NaX, and the adsorption
of a continuous
from
of sulphur.
periodically
findings
opment
is recovered
the dew point
bed and is removed
1. The present
the rate of reaction
[5] sulphur below
100 lower
hand,
than the equilibrium
no data are available
on NaY zeolites.
pressure
in literature
of liquid
on the ad-
187 In this study, sulphur
we focused
over various
determined dation
an the reaction
the rate of deposition
of H2S, on a catalyst
and 0.5 vol % 02. We looked ed sulphur
behaviour
the different
the influence
both
the maximum
NaX and NaY zeolites
caused
by the adsorb-
ratio of the zeolite
the adsorption Using
we
the rate of the oxi-
phenomena
we studied
of H2S to
method,
of about 1.0 vol % H2S
of the Si/Al
from the H2S oxidation.
we investigated
and hence
in an atmosphere
for autocatalytic
rate. Furthermore,
of sulphur
apparatus,
Using a gravimetric
of sulphur,
sample
and shall discuss
on the reaction
rate of the oxidation
NaX and NaY zeolites.
and desorption
the same micro-weighing
sulphur
adsorption
and the desorption
capacity
behaviour
of
of the sul-
phur adsorbed.
EXPERIMENTAL Experimental Sulphur
set-up adsorbed
slowly,
because
sulphur
load close
volatility
the relative
sulphur,
by measuring
The experimental
set-up
of a Sartorius
inserted
diameter
sample
pan (diameter
30 mm).
[lI]. Due to this low
the rate of the H2S oxidation accumulation
can be studied of a catalyst
atmosphere.
provided
with a quartz
mounted
tubular
furnace
samples
were contained
10 mm) in the middle
of the microbalance
was connected
(heated
1. It con-
hangdown
length
0.30 m, in-
in a shallow
quartz
of the oven. The electronic to a recorder
and the temperature
tube
con-
for continuous
regis-
of the gas in the vicinity
pan.
Reaction gas ___I_ A gaseous reaction was made
mixture
by adding
H2S. The composition and checked
capacity
Catalyst
of the sample weight
mixture
evaporates very -2 is below 10 even at a
used in this study is shown in Figure
troller
nitrogen
pressure
the rate of weight
tration
of the sample
vapour
4406 microbalance
in a vertically
ternal
of e.g. NaX zeolite
adsorption
in a H2S and O2 containing
sisted
m3s-I
sulphur
to the maximum
of adsorbed
gravimetrically sample
in the micropores
of about
together
1.0 vol % H2S and 0.5 vol % O2 in
flows of dry air and nitrogen
of the gas mixture
by chromatographic
was fed to the bottom
was adjusted
analysis
for each experiment.
of the hangdown
(at 20 "C and atmospheric
containing
by calibrated
florrmeters
The reaction
tube at a flowrate
of 3.3*10s6
pressure).
Catalysts Small catalyst
amounts
was a commercial powder
of pure zeolite
powder,
and these were carefully
spread
grade Linde molecular
was supplied
by P.A. Jacobs
i.e. 1 to
10 mg, were
on the bottom
sieve,
(Katholieke
used
of the sample
type 13X. NaY(1.70, Universiteit
as a pan. NaX
see below)
Leuven,
Belgium).
-
air
3% H2S Q_ in N2
N2
I
FI
FI
Q
a--
J
reaction mixture
Q
vent
nitroger
%
m
vent
PU
Figure
4
I
I
Experimental
set-up.
2
3
ml
r-4
:I I
N2
FI
Furnace
Sample 7.
valve
controller switch pan
Gas flow 6.
5. Temperature
4.
Balance Recorder
2. 3.
controller
Microbalance
1.
189
The other NaY catalysts Amsterdam). resulting
Chemical Si/Al
NaX(1.151,
Before
bv (Research
were added
in parentheses
and NaY(2.40)
Centre
was performed
to the zeolite
and the
names:
respectively.
procedure the catalyst
rate about 0.2 'C s-l) up to 400 "C. temperature,
attained,
experiments.
sample was dried in a nitrogen -6 m3s-1 N2; flow rate 3.3*10 STPI at increasing
> 99.98%
(heating
the measurement were
by Akzo Chemie
of the Si and Al content
NaY(2.07)
the experiments,
(high purity, rature
ratios
NaY(1.701,
Experimental
were provided
analysis
nitrogen
both isothermal
was replaced
Unless mentioned
When,
conditions
by the reaction
otherwise,
flow tempe-
after cooling
and a constant
mixture
only fresh catalyst
to
weight
to start the samples
have
been used.
RESULTS Accumulation When
of sulphur
the reaction
was introduced was formed
gas mixture
to the hangdown
from the oxidation
on the catalyst.
Formation
reaction
was also
In the microbalance, colour
recorded.
Figure
2. Accumulation
A typical
of the experiment time in the tubing
a level others
roughly
corresponding
[lO,ll].
As a matter
decreases
when the maximum
available
surface
may also become sulphur
vapour
pressure
and the desorption
sulphur
sulphur
On account
load,
sulphur
In the course
of the deposition
of sulphur
owing
reported
by
to the decreasing
of the zeolite
of sulphur
pores
[lo]. As
from the H2S
as is shown
in Figure
(Cl stops the formation
the weight
of the catalyst
pressure
becomes
stable weight
of sulphur
at
of the relative
of sulphur
vapour
tube.
holds
rate of the H2S oxidation
increase
of sulphur
and an apparently
of the catalyst
is established,
by nitrogen
of the lower
by the
to this, desorption
filling
of sulphur,
the rate of desorption
a few minutes
uptake
the formation
of sulphur
after the
is caused
increase
of the rapid
mixture
and, due to desorption
decreases.
within
the reaction
between
time plot is given in
zone of the hangdown
load is reached,
at the maximum
oxidation
versus
of the sample
about 45 seconds
to the maximum
In addition
was apparent
increase
delay period
the weight
because
an equilibrium
2. Replacing
of a weight
sulphur
a result,
from the
of fact, the reaction
area [7, 121.
important
(see [6],
and in the preheating
time of reaction
of the H2S-O2
of sulphur
is observed
(A), which
sulphur
and deposited
with fluid bed reactors
and the sustained
example
residence
a certain
the presence
of weight
elemental sample
as the main product
in our experiments
beginning
After
tube of the microbalance,
of the zeolite
weight
1 ~01% H2S and 0.5 ~01% 02 in N2
of H2S over the catalyst
of sulphur
p. 151). yellowish
shown
of about
at slightly
negligibly
is observed
also water,
produced
of slowly lower
small (D). by the
190
0,6-
T
1
0
I
1
2
I
I
3
4
time (KP s) Figure 2 zeolite,
Typical
weight
registration
of sulphur
accumulation
NaY(2.40)
1.65 mg, 188 "C.
T("C)
Figure
3
(al fresh.
Thermoanalysis (b) containing
of NaY(2.40) 0.34
(1.65 mg, heating
kg sulphur
rate 0.17
per kg dry zeolite.
'C s-l).
191
reaction,
might
have been adsorbed
zeolites
are known
analysis
of a fresh NaY(2.40)
cant weight gradually
to strongly
sample,
loss due to dehydration
decreasing
shows a marked catalyst
simultaneously
adsorb
weight
At temperatures
(Figure
as given
below
is observed.
loss of weight
occurred
Similarly,
above 200 "C a second weight
caused
about 100 and 200 "C all the sulphur
by the desorption
is not likely obtained
to adsorb
eventually
sulphur
adsorption
Maximum
sulphur
adsorption
At temperatures
while
loaded
sample
of the fresh
is slightly
is observed,
adsorbed.
lower.
which
is ob-
Consequently,
on the catalyst,
while
And so the net increase
2 can be considered
of
the maximum
values
of the maximum
have been determined.
sulphur
The results
capaci-
are present-
NaX(1.15) zeolite appears to adsorb less sulphur than the
The adsorption
temperature,
a signifi-
uo to 2011 "C a
capacity
above 100 "C several
4. The
NaY zeolites.
because
of the zeolite.
ty of the NaX and NaY zeolites ed in Figure
loss
remains
substantially.
at D in Figure
capacity
dehydration
loss
of the sulphur
3a, shows even
a sulphur
this weight
viously
water
in Figure
in the range where
3b), although
the sulphur,
[13]. Thermogravimetric
100 "C, while
between
weight
with
water molecules
capacity
for NaY zeolites
of NaX(1.15)
is clearly
a slight decrease
independent
at increasing
of
tempe-
rature can be seen. Adsorption
of sulphur
ture, because passage atoms
the apertures
of most molecules
adsorbed
capacity.
takes
for NaX11.15) whereas
Seff [14]
the supercages
of NaA zeolite.
of NaX zeolite
and about
the presence
for
are too narrow
the maximum
zeolite
has studied
sulphur
S5 rings
in each
sulphur
adsorption
of about 14 sulphur adsorb
up to 21 sul-
adsorption
complexes
similar
By an X-ray
diffraction
supercage
adsorption
the
of sulphur
has supercages
ratio.
struc-
to allow
number
from the maximum a value
Such a zeolite
From the maximum
of the zeolite
the NaY zeolites
the same Si/Al
of two parallel
has been proven.
Consequently
can be calculated
per supercage,
phur atoms per cavity.
in the supercages
to the other cages [13].
in a supercaqe
We determined
atoms adsorbed
place
in
to those study
of the NaA zeolite
capacity
we calculated
NaX(1.15) zeolite about the same number of sulphur atoms per supercage,
namely
14. For NaY zeolites
observed. above,
This might
or it might
tion because zeolites
a higher amount of sulphur atoms per cavity is
indicate
be caused
of a lower
the absence by a larger
cation
volume
concentration
as will be substantiated
Steijns
of the sulphur
and Mars [II] reported
available
complexes
mentioned
for sulphur
in the supercages
adsorp-
of the NaY
below. a maximum
NaX zeolite
of about 0.30 kg sulphur
what higher
than we have found
sulphur
per kg zeolite
for the NaX(1.15)
adsorption
capacity
at 260 "C, which
zeolite.
of
is some-
This can be ex-
192
-
0
NaX
(1.15)
A Nay
-I
(170)
0
Nay
(2.07)
l
Nay
(2.40)
I
2jo
2bo
160
100
T("C) Figure
4
Maximum
sulphur
adsorption
capacity
of NaX and NaY zeolites
versus
ratio of their zeolite
sample
temperature.
plained, might
however,
have
by suggesting
that the Si/Al
been slightly higher. Unfortunately
the Si/Al
ratio was not stated
by them.
The rate of oxidation The increase of oxidation influenced dation.
by simultaneous
According
within which served
might
concentration the catalyst causes
under
of water
analysis
curve
weight,
completely
might
be
also by the H2S oxi-
(cf. Figure
3) relatively
of the H2S oxidation, because
water
at B) that this amount
change
to be present
of the H2S - 02 feed,
adsorbed,
if the temperature
higher
a substantial
is likely
interruption
the weight
on the rate
increase
above 100 'C if the atmos-
on the catalyst,
of any possible
these conditions
almost
produced
from the H2S oxidation,
By intermediate
2, dotted
depends
the rate of weight
are to be expected
be present
layer.
2 obviously
But in the course
resulting
per cent of the catalyst
corresponds
water
the desorption
(cf. Figure
Therefore,
However,
adsorption
of nitrogen.
of water
in Figure
to the thermogravimetric
of adsorbed
phere consists amounts
observed
of H2S to sulphur.
low amounts
water
of Ii22
of weight
it could is less
is above
about
of the catalyst
to the rate of the deposition
be ob-
than one 120 'C. sample
of sulphur
and
193
hence to the rate of the oxidation the H2S oxidation plot according
From these
=>=dLp MS
x
results,
can be evaluated
only
to the known
data on the reaction
in the Appendix.
the mass
the concentration
zeolite.
was measured,
for the NaY zeolites
The rate of oxidation described typical
above,
example
I
gradientless
5
Reaction
(zeolite
I
versus
I
150
could
temperature
increase
transfer
rise of
for the ex-
was always
limitations.
be determined
in the that But
satisfactorily,
from the weight
the sulphur
1
1
I
0.3
(kgS/kgzeolite)
signal
load. Figure
to be poorly
0.2
“C)(a)
experi-
conditions.
rate of the oxidation
NaY(1.70),
mass
a). The rate data appear
0.1
as is de-
in this case an activity
of H2S was calculated
Xs
Figure
by serious
are
is at least 80 per
has to be made
the rate of the weight
and was plotted (curve
0
load
Although
the rate of reaction
approximately
in detail
and that the ultimate
are
effects
that in most
at the catalyst
bed is less than 4 "C. An exception
high that it has been influenced
i.e. under
phenomena
we have estimated
of both reactants
on the NaX(1.15)
at the catalyst
and if temperature
and heat transfer
Accordingly,
cent of the feed gas concentration
H2S oxidation
time
rate of the H2S oxidation
if the H2S and O2 concentration
We studied
periments
versus
(3)
feed gas concentrations
absent.
the catalyst
of fact, the rate of
to the weight
W,MS
useful
scribed ments
of H2S. As a matter
from the tangent
to:
'H2S = 2 * '02
close
then follows
as
5 shows a
reproducible
I
r
0.4
-
of H2S with
first experiment
O2 versus
the sulphur
(b) fourth experiment.
194 below
a sulphur
load of about 5 wt %, whereas
load are significant era1 cycles sequent
with
and, for example,
regeneration
accumulation
(see Figure
of the high activity
%, is not very clear.
We looked
on the fresh catalyst,
amounts,
load contributes
catalyst,
TABLE
but as is shown
considerably
more
to describe
Weight increase (wt %1
At high sulphur
load a maximum
to an NaX catalyst
peratures
between
phenomena
are generally
assumed kinetics
tained, from which -1 is derived.
an activation This
energy
of the reaction -1 about 55 kJ mol . Based
agrees
adsorbed
in H2S. energy
effect
-0.02 0.03 0.05 0.08
obtained
This
[7] with
regard effect
6.
Autocatalytic
are given
rate equation
and 13X molsieve
that the
lines
are ob-
of about 53 kJ
of the activation
reported
by Steijns,
viz.
adsorbed
on purified
active
mechanism [7,8].
in the
has been
are approximately
parallel
of the rate constant
of sulphur
tem-
at a sulphur
et al. [R] who have found
Reasonably
a general
in porous materials
at different
respectively
fairly well with values
et al. derived
Iron content, dry base (wt %l
in Figure
rate over a 13X catalyst
on the autocatalytic Steijns
over sulphur
on aluminas
in O2 and zero order
of the zeolites
and Mars
7. A first order
data of Steijns
of the H2S oxidation
mol
carbons,
with
2
rates observed
0.03 and 0.05 kg S per kg zeolite
in accordance
of the
extensively.
by them as the autocatalytic
The reaction
in Figure
activity
activity
of the catalyst.
120 and 200 "C, are summarized apparent.
the ini-
at higher
rate is observed.
by Steijns
rate of the H2S oxidation
plot presented
order
in the reaction
reported
in the micropores
on the reaction
explain
the activity
NaX(1.15) NaY(1.70) NaY(2.07) NaY(2.401
and has been described
adsorbed
load of 0.01,
been
about 5 wt
1, only small
cannot
Iron content -Catalyst
I:! 108 133
has previously
i.e. below
to the overall
Temperature ("Cl
1.0 0.4 0.4 0.3
of sulphur
again
temperature
H2S from an 02-free
in Table
the initial
data for H2S (1.0 vol.%)
phenomenon
Arrhenius
of
TABLE
NaX(1.151 NaY(1.70) NaY(2.071 NaY(2.401
Data
load,
Because
1
Catalyst
first
at low sulphur
for the adsorption
satisfactorily.
we did not attempt
Adsorption
to about 400 "C and sub-
reaction
i.e. less than 1.0 wt %, were found, which
tial peak in the activity sulphur
in nitrogen
at the original
of sev-
in the course
5, curve bl.
The nature
mixture
by heating
of sulphur
at a higher
the data obtained
also persistent
for the oxidation
They showed
of H2S
that the oxida-
0
-
load.
Reaction
0.4
01 x5 (kgS/
02 03 __
0.4
of H2S with O2 versus
kg NaY(207))
rate of the oxidation
0
1
(a) NaY(1.70).(b) NaY(2.07).(c) NaY(2.40).
Figure 6
03
02
01
X,(kgS/kgNaY(170))
006 004
the sulphur
OA Xs
(kgS/kgNaY
(240))
-
196
E=
53
kJ mol-'
NaY
(I.701
NaY
(2.071
NaY (240)
220 I I
I
100 I I
1
2.0
T("C)
140 I
I I
2.2
103 r
I
I
2.4
2.6
IO3 / T ( K-l> Figure
7
Arrhenius
plot of reaction
tion rate over an NaX zeolite [IZ], which
clearly
reflects
is related
with
sulphur
tial differences similarity
in the reaction
area are unlikely Q/Al
ratio
might
be causing
iron content
Obviously,
more
Dudzik
zeolite
active.
activity
is attended
parameters
which
surface
discussed comprises
We have found
differences adsorbed
Steijns
[7,12].
(see Table
by Steijns
an interaction
[9]. The chemisorption
in
of the
surface
with
a low
that iron impurities
analysis
of the zeolites
2) and, additionally, activity
in the oxidation
a mechanism
area
substan-
Because
in sulphur
on zeolites
suggested
Chemical
by a decreasing
are involved
than those considered
and Ziolek
NaY zeolites,
sulphur
shown low iron contents
increasing
NaY zeolites
large
surface
On the other
on a 13X zeolite,
catalyst.
rate over the NaY zeolites.
and, therefore,
a higher
sulphur
role of sulphur.
adsorbed
carbon
structure,
seems to be more
has, however,
of sulphur
on an active
of the zeolite
to the specific
the autocatalytic
hand, they found a high activity comparison
rate constants.
an
of the catalyst.
of H2S over NaX and
[15].
of the H2S oxidation of adsorbed
over NaX and
reactants
of H2S is suggested
and the
as an essential
197
step, at least during
the initial
on NaX and NaY zeolites spectroscopy
of zeolites
Rasko [17] determined na-rich
zeolites,
ally on unlocated tration
unit cell, inside
with
and suggested Na+ cations
remaining
cations
oxidation
of H2S is likely
cationic equal
n
near the walls depends
is equal
occupy
ratio.
Karge
of alumina
The concen-
tetrahedra
and hexagonal
per
where
the number
by Karge
of
positions
prisms.
of the supercages,
sites per unit cell has been proposed
and
on alumi-
The number
the well-coordinated
Consequently,
By IR
preferenti-
of the supercages.
cages
near the walls
to proceed.
ratios,
takes place
on the Si/Al
i.e. sodalite
are located
Si/Al
of H2S
[16,17,18].
of the H2S adsorption
to the number
preferentially
the small cages [lg],
varied
nature
Adsorption
authors
that this adsorption
strongly
per unit cell but cations
by many
systematically
the dissociative
of these cations
Na+ cations
stage of the reaction.
has been described
The the
of these
and Rasko
as being
to: 192 + Sl/Al - 56
=1 Na+
(4)
They have found a good correlation ly adsorbed equation sites
H2S molecules
above.
zeolite. calculated Figure
8 as a function
concentration
8
factor
from the reaction
4. The value
Figure
reaction,
in the supercages
The frequency
k. of the Arrhenius
to increase
Frequency
factors
equation, in Figure
concentration rather
of the Arrhenius
to the
sites act as reactive to the number
on the Si/Al ratio of the
with
equation
which
can be
7, is plotted
calculated
linearly
sites in accordance
in the supercages.
of dissociative-
sites according
rate is related
and thus depends
rate data presented
of H2S adsorption
Na+ concentration
the reaction
of the Na+ cation
of k. is found
the concentration
of cationic
if the H2S adsorption
Consequently,
in the oxidation
of Na+ cations
between
and the number
with
an increasing
the suggested
versus
in
by equation
reac-
the calculated
198
tive sites model.
Figure
Na+ cations,
would
However,
which
8 predicts
this can also be explained
56 in equation cations
Ziolek
ratio [ZO]. They suggested (A104-)
cations
is located
heating
H2S oxidation,
which
of
by other workers
the catalytic and the Si/Al
with the number
of alumina
the total number
of Na+ ca-
because
only a fraction
sites and are thus likely
to about 300 "C, sulphur
desorbs
this treatment.
slowly
of Na+
to participate
accumulated
during
in detail
Barrer of sulphur
in
at each
and Whiteman
desorbs
be removed
by
in subsequent
from the zeolite
some irreversibly
adsorbed
the main part of the sulphur
at moderate
in the Appendix,
heating.
the sulphur
bed can be determined
sulphur
vapour
pressure
at
from the rate of the weight
loss as a function
and as a result,
of the sulphur
data on the vapour
load were obtained.
[lo] have investigated
and phosphorus
on different
of sulphur
concentration
very small bed heights
These
pres-
data are presented
gradients
and Mars
ate-adsorbate
[ll],
interaction
pressure ratio,
vapour
pressure
inside
the catalyst
sorption
bed.
S-shaped
isotherms
on the adsorbing of sulphur
might
more
we used
be consider-
determined an adsorb-
The sulphur
material. rapidly,
sul-
load.
indicating
molecules.
no
fluxes
the minimum
on NaX zeolite
zeolite
proceeds
Moreover,
sulphur
are found
sulphur
expect
and the mass
at the interface
isotherms
a relativ-
we might
to reach
at the actual
of the adsorbed
also depends
the desorption
pressure
and desorption
and have mentioned Therefore,
two to six hours
of sulphur
with the sulphur
In agreement
zeolites
of less than half a millimeter,
phur load, So the sulphur ed the equilibrium
the adsorption
from NaX zeolite.
were very low, i.e. it took about
by Steijns
while
the
over 90 per
9.
ely rapid release important
are formed,
experiments
could
adsorbed
could be removed obviously,
during
Eventually
the H2S oxidation
the rate of the weight
load in the desorption
in Figure
species
of the catalyst
loss. We measured
sure of sulphur
cycles,
the H2S oxidation
As is described the surface
during
On the fresh zeolite,
sulphur
was accumulated bed.
is the fact that sulphur
accumulationdesorption
or chemisorbed
which
from the catalyst
accumulated
Noteworthy
about completely.
Si/Al
equals
number
process.
cent of the sulphur
vapour
between
correlation
of the constant
higher
suggested
of
sites.
desorption
After
sulphur
a relation
is not very likely,
on supercage
the H2S adsorption
Sulphur
a direct
This
lower value
over NaX and NaY zeolites
per unit cell,
tions per unit cell.
in the absence
of e.g. other
the apparently
H,S adsorption
have elaborated
of the H2S oxidation
tetrahedra
with
for dissociative
and Dudzik
activity
activity
activity
by a possibly
4, in correspondence
available
a residual
imply an additional
At increasing
which
might
be
202 gas velocity
Ills
V
volume
m3
W
weight
V
wO
weight
ng h
kg of dry catalyst
sulphur
xS a
sample
load
heat transfer viscosity thermal
-1
coefficient
of gas conductivity
of gas
kg kg Slkg zeolite)-1 W m-2 .C-1 -2 Nsm W m-1 .C_l
4;;
heat flux
kW m
4;
mass
molm
d
Thiele
pg P
flux
-2 -2
s
-1
modulus
density
of gas
density
of zeolite
kg m particle
-3
kg me3
Subscripts eff
effective
i
at the interface
REFERENCES
5 6 7 8 ?O
11 12 13 14 15 16 :‘B 19 20 21 22 23 24 25 2’;
B.W. Gamson and R.H. Elkins, Chem. Eng.Prog. 49, (1953) 203. G.T. Kerr and G.C. Johnson, J. Phys. Chem., 64 (1960) 381. M. Steijns and P. Mars, Ind. Eng. Chem. Prod. Res. Dev., 16 (1977) 35. J.E. Nobles, J.W. Palm and U.K. Knudtson, Hydrocarbon Process., 56 (1977) 7 143. A.L. Kohl and F.C. Riesenfeld, Gas Purification, Gulf Publishing Co., Houston, 1979. A.B. Verver, Thesis, Twente University of Technology, The Netherlands,1984. M. Steijns and P. Mars, J. Catal., 35 (1974) 11. M. Steijns, F. Derks, A. Verloop and P. Mars, J. Catal., 42 (1976) 96. Z. Dudzik and M. Ziolek, J. Catal., 51 (1978) 345. R.M. Barrer and J.L. Whiteman, J. Chem. Sot. A, (1967) 13. M. Steijns and P. Mars, J. Colloid Interface Sci., 57 (1967) 175. M. Steijns, A. Peppelenbos and P. Mars, J. Colloid Interface Sci., 57 (1967) 181. D.W. Breck, Zeolite Molecular Sieves, John Wiley & Sons, 1974. K. Seff, J. Phys. Chem., 76 (1972) 2601. M. Steijns, Thesis, Twente University of Technolagy, The Netherlands,1976. A.V. Deo, I.G. Dalla Lana and H.W. Habgood, J. Catal., 21 (1971) 270. H.G. Karge and G. Rasko, J. Colloid Interface Sci., 64 (1978) 522. R.W. Tower, Z.M. George and H.G. Karge, Preprints 6th Can. Symp. on Catalysis, August 19-21, 1979, Ottawa, Ontario. J.V. Smith, in: Zeolite Chemistry and Catalysis, Ed.: J.A. Rabo, ACS Monograph 171, 1976. M. Ziolek and Z. Dudzik, Zeolites, 1 (1981) 117. R.B. Bird, W.E. Stewart and E.N. Lightfoot, Transport Phenomena, John Wiley & Sons, 1960. W.E. Resnick and R.R. White, Chem. Eng. Progr., 45 (1949) 377. T. Wigmans, H. van Cranenburgh, R. Elfring and J.A. Moulijn, Carbon, 21 (1983) 23. C.N. Satterfield, Mass Transfer in Heterogeneous Catalysis, M.I.T. Press,1970. A. Meisen and H.A. Bennett, Hydrocarbon Process., 58 (1979), 12 131. International Critical Tables, McGraw-Hill, New York, 1929. A.B. Verver and W.P.M. van Swaaij, to be published.