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On some thermodynamic and kinetic aspects of desorption from zeolites under microwave irradiation
Thermochimicu Acta, 152 (1989) 43-51 Elsevier Science Publishers B.V., Amsterdam
ON SOME THERMODYNAMIC MICROWAVE
43 -
AND KINETIC
Printed
in The Netherlands
ASPECTS
OF DESORPTION
FROM ZEOLITES
UNDER
IRRADIATION
M. BENCRANAAl, 1Laboratoire de Marrakech
M. LALLEMANT,
M.H. SIMONOT-GRANGE
de Chimie Physique, (Maroc).
Universite
et G. BERTRAND2
Caddi Ayyad,
Facultk
des Sciences
2Laboratoire de Recherches sur la Rdactivit4 des Solides C.N.R.S U.A.23, FacultC des Sciences Mirande - B.P 138 - 21004 DIJON CEDEX (France)
SUMMARY
The desorption of 13x xeolite is studied under controlled pressure and temperature conditions (T = 42OC) in an apparatus combining microthermogravimetry with a microwave guide ; the experimental study leads to the kinetic and thermodynamic characteristics of the zeolite in the microwave field. The lack of any modifications to the kinetic regime due to the field and some experimental results (evolution of the diffusion coefficient with the microwave power) tends to indicate that the irradiation effect may be reduced in this case to calorifit effect.
INTRODUCTION The first oil-crisis investigation
lead. If this solar of problems. capture
of 1973 has produced
for the use of renewable
First,
it is necessary
it. Finally,
reserve,
it is necessary
of
in the
its use faces a lot
to set up the techniques intermittent
a vast effort
with the solar energy
energy makes up an enormous
this dilute, uncertainand
for storing
in all the world
energies,
which allow
to
energy and then to transform
to be able to restore
this energy
it
in
order to use it. For all these problems, cal compounds chemical tricity
chemists
"(ref. 1)" which
heat pumps "(refs. the enormous
Their applications household
efficiency
1) The formation adsorbent.
conventional difficult
proceedings
heating
scale. But some problems
chemi-
in so-called
present
on elec-
energy
at
or solid adsorption.
and energy
storage
need to be solved
on a
for obtai-
:
problem
heating which
0040-6031/S9/$03.50
for cooling,
or more precisely
which
present
which always
0 1989 Elsevier
the hydration
stage of chemical
of regeneration
operation
storage
cycles of liquid absorption
It's an essential
2) The problem
They propose
of being able to store and restore
are designed
or industrial
ning a better
to offer.
can store and carry solar energy
2-3)". These
advantage
will. They use thermodynamic
have solution
requires
Science
cycling.
is often performed
a lot of major
by pumping
drawbacks.
high temperatures.
Publishers
of an anhydrous
B.V.
or by
It's a long and
44
In both cases, the knowledge
* A basic or fundamental mechanismsin applied
the hydration
to a material
** Or applied
the regeneration
of
research
of these systems. For example, cycle effects, pressure
(specific
of microwave
as the power of the field or
gas.
field effect applied
to only one of these points
to a material
on the microwave
action,
new and fruitful means of investigation
lyophilisation,
dissipating
thawing
or dehydration.
energy everywhere,
Indeed
in volume
because
"(refs.
:the
regeneration.
during
it's a means
at present,
4-10)"
they
such as drying,
of carrying
and
or at interfaces.
The aim of this study is to supply the relevant lowingquestions
of the real working
the dehydration-hydration
the mass effects,
We will focus our attention constitute
field effect
effect or heating).
on key parameters
In this paper, we will devote our attention research
:
either
of reaction
of microwave
the delay time or other parameters
of adsorbent
requires
the knowledge
case or the research
during
study
of the transformation
study, for example,
elements
to answer
the fol-
:
(i) Is microwave
interaction
a simple conventional
heat
or is there a spe-
cific action of the field ? (ii) How do of microwave
the kinetics
of the regeneration
stage evolve
in the presence
power ?
(iii) What are the working vi) of an affinity
parameters
thermal machine
using
(Pressure
P, temperature
13x zeolites
as adsorbent
T and power ?
EXPERIMENTAL The apparatus
is composed
of three essential
parts
:
. The microwave guide . The thermobalance . The reactor. Microwave The microwave at a frequency
part (Fig. la) is made up of a wave generator
of 2.450 MHz and protected
ted power is diverted
towards
by a wave circulator
an adapted water
plies a rectangular
wave guide
wave is propagated.
The transmitted
Cl), operating (2). The reflec-
load (3). The generator
(4) (type RG 112/U) inside which power is absorbed
sup-
a progressive
by a second water
load
(5). Thermobalance The coupling
of both methods-microthermogravimetry
carried out in laboratory sure and temperature,
allows
to record continuously
the variations
and microwaves-(Fig. under controlled
of mass of irradiated
samples
using
la) pres-
45
Microoven
Wave
load
PS 50
w 4
i
Vacuum
Fig. la. Experimental a microbalance sensitivity
(6) of zero SETARAM
used through
its possibilities It is positioned
tor by a metallic
circuit.
type PS 50. It's a dissymetric
This apparatus
g-
mass
scoop
: microwave
Apparatus
is l/SO
sample.
or pressure
of maximum
of electromagnetic under
balance,
its
load 50 g is currently
taring
if we often vary the
the wave guide and connected
tube (7) in order to avoid overpressures
with
the reac-
at the level of the
(8).
Reactor The reactor mities
(Fig. lb) consists
by two teflon-plates
by means
(9) which
of a furnace ribbon
piloted
hole at the centre of its larger is made up of a quarts-stick beam branches
and allows
ness of the reactor The reactor
are 4 mm thick,
to position
from a heating to vacuum
tight crossing mounted in a cylindrical
its temperature
diameter the sample
by toric joints
and supported
(10). of a cylindrical
element with cold extremities
and to pressure
tube. This microoven
pass. This one by one of the
in a wave guide axle. The tight-
(11) consisting
is provided
on a brass block, which
is fixed
The guide has a
faces to let the sample-stand
of 2 mm
is provided
closed at its extre-
in power by a rheostat.
is topped by a microoven
ling (12) made The tightness
of a part of wave guide,
by the utilization
slides
is necessary
spoo-
type TRRRMOCOAX.
via
of
toric joints
for the previous
activa-
tion of 13X seolites. Procedure After activation cuum, conditions
of 13X seolite
during
point, a water vapour temperature
in temperature
24 hours, we rehydrate
pressure
corresponding
(T = 42°C). From this hydration
T = 35O'C and pressure
it by imposing
to the saturation
through
the cold
of seolite
state, the dehydration
= va-
at
is achieved
46
Thermolok
Microoven @) (thermocoax withyold
(1
Teflon-p] .ate
t13X
Sample-standand SCOOD
Fig. lb. Exphrimental for a given pressure
zeolite
I
@-n
Apparatus
IB
Microbalance
llr
: microwave-thermogravimetry
in a 0.1 - 4.5 kPa range in accordance
power "i. It must be noted ted again, always
0b
that after each dehydration,
in the same conditions
PS 50
coupling. with incidental
the sample
is rehydra-
(T = 42OC, P = 5.6 kPa and xi = OW).
RESULTS The desorption
curves
The action of the microwave shown
by the thermopravimetric
field on the dehydration curves
__-
5oow
-.--
7oow
______-
3sou
--w .--0-9-w-
Fig. 2. Example
of loss-mass
of 13X zeolite
(Fig. 2) representing
curves m versus
is
the evolution
190w 1oow ow
time, T = 42°C and variable
powers.
of the desorbed for different
water mass versus
1) At null field and whatever parabolic
shape. In the presence
of the shape of curves which (i) First,
time, at a constant
powers "i. From these curves,
an initial
the pressure, of microwave
then presents
pressure
observations
can be made.
the m(t)
two parts
and
curves have a quasian evolution
:
to a loss of mass with a
since the power is high. This first part lines up
expression
tl=KA
water vapour
field, we observe
fast rise, corresponding
speed all the more important with the following
different
: (Fig. 3a)
"(ref.
11)"
A
500
0 300 l 190 v 100
P= 3.16kPa
Fig. 3a. Linear time).
transform
of experimantal
ni conditions.
This one lines up with the following = K' + K"t
(Fig. 3b)
0
to a continuously
a stage in the chosen pressure
Ln(l-o)
30
: CL=K&
curves m(t)
(ii) The second part of the curves corresponds speed until reaching
7 0
P, temperature expression
"(ref.
law (short decreasing T and power
:
11)"
Time (pin)
Fig. 3b.Linear transform law (long time).
of experimental
curves m(t)
_ ln(l-cC) = K' + K"t
48 Then, we can notice terpreted
in this case, that the curves
obtained
in field are in-
with the same laws as those in null field. There are no alterations
of kinetic 2) For
system through
the application
higher
(ri > 500 W) and in particular
sure values,
powers
other curves are obtained
ter a first part which
for the weaker
pres-
as you can see in Fig. 2 (curve B). Af-
a stage which
than that previously
at slight pressure
field.
seems to be the same, the loss of mass reaches
mum, and then goes through tly smaller
of an electric
hoped
represents
for the given power, while
and high powers are obtained
a maxi-
a rate of hydration
a microwave
plasma
sligh-
such curves is produced
in the reactor. 3) The general sent~amaximum
shape of the curves, with continuously
speed of desorption
ches a decomposition
step cm,). We notice
(Vi = 500 W), the curves v.
The desorption
equilibrium
(“i)p
reaof
and me ('ITi)are linear.
under field
of the field over the desorption
, which represents
figure 4
slope, pre-
and it always
that as far as the limit value
the experiment
The influence
decreasing
(vo) at the time origin
the network
equilibrium
of the isotherm
is shown
in
curves M = f(P)T obtai1
0.2 M(%) :F
30
0.85
1.5 2.15 2.8 3.45 T, 42’C Z = anhydrous zeoiite mass -58 gm
4.1 P(kR
25 20 15 10
5 C Fig. 4. Network curves.
graph
"(refs.
and values
. It
isotherms
12-13)".
of the power
is experimentally
for Pl and nil values
20
15
of adsorption
ned by calculation pressures
10
5
0
30
"(refs.
The compositions
(isopower
checked
of pressure
oalc*
25
curves)
11-12)" and isopower
obtained
with various
can be plotted
that the equilibrium
and microwave
315
power
on the same
desorption
obtained
(point A in the figure 4)
49
is the same as the equilibrium rature T defined which
therm
obtained
by the junction goes through
The desorption
under
obtained
in field appears of the steady
of the latter. The quantity
the application
depends
isopower
Pl at a tempe-
curve and the iso-
point A.
equilibrium
ting of the zeolite by the field, because
equilibrium
the same pressure
of the considered
of adsorbed
on the power of the field through
as a result
of the hea-
temperature
obtained
water
by
at the desorption
the material
temperature
imposed by the field.
Evolution
of the diffusion
The appropriate diffusion
coefficients
transformation
coefficient
tion of the microwave
the power of the field
f(t) (Fig. 3) enable
a=
Their evolution
in the zeolite. power
with
in (figure 5a). This figure
l o.lEkPa
to reach the water
is represented invites
as a func-
two remarks
:
@
ro.WkPa o j.16kPo
Fig. 5a. Variation coefficients. (i) We notice
as function
of the incident
that De coefficient
in near conditions
which
to the thermodynamic
power of
: the diffusion
characterizes
equilibrium
the diffusion
varies
of water
little with
the power
of the field. (ii) We observe water
that Do, the coefficient
in conditions
field, at constant diffusion
far removed pressure.
coefficient
with
characterizing
the diffusion
from this same equilibrium,
increases
This result can lead to infer an evolution
the field and the opportunity
of a specific
of
with
the
of the action
of the field on the material. Infact,
the comparison
ned for the temperature
between
the curves of the figure Sa, and those obtai-
(Fig. 5b) shows that both offer
ding to three domains of power. (iii) A first part I, isatvi
< 30 W power
in which
three parts corresponthe effect
of the field
is negligible. (iv)
For 30 < vi < 100 (part II), the temperature
tion depending
on the power,
the slope depends
follows
on the pressure.
a linear varia-
50
0b
v 0.18kPa o 0.86kPa 0 1.93kPa A 3.16kPa m 4.24kPa
vi I
200
100
300
400
Fig. 5b. Variation as function of the incident ture at the desorption equilibrium. If "i > 100 W, the zeolite
(v)
power, but the slope keeps
“O
temperature
independent
(wa$
: the material
power of
varies
of the pressure
tempera-
proportionally
to the
(part III).
INTFXPRETATION These results incident
can be interpreted
power is divided
by taking into account
(i) The power used for the heating se of the temperature
(iii) Finally,
of the zeolite which
which
of the zeolite. We notice
1 to 1000 ratio in accordance Thus, at a given pressure
Then, if we consider
1) At low power
maximum
this division curves
speeds
Of
is
surfaces.
a steady state of the irra-
leading
by the heating
of the incident
to a possible
cooling
term.
power, we will understand
(Fig. 5). the desorption,
the total power applied
increase with
the temperaof the reactor.
on the material
the power of the field
: speed
of energy and not by the pressure.
(part III), we notice
that the seolite
is then no longer the factor limiting
speed of desorption
consequence
the latter in a
the same as the temperature
uses nearly
by the bringing
2) At high powers of energy
if the processes
are compensated
is practically
phenomenon
Initial and instantaneous
bringing
power,
(part I of the curves) during
ture of the seolite The desorption
is regulated
and microwave
of the obtained
with
with that of the sample-guide
can be reached
down, chiefly desorption,
is a
that this power
below the incident power and adopts a linear variation
the variation
an increa-
for the losses after a heat transfer.
the power used for the desorption
of the temperature
diated material
justifies
of this material.
(ii) The power used to compensate
decrease
the fact that the
into three parts,
is then fixed by a chemical
gets heated.
the desorption restriction
The ; the
imposed
by
51
local conditions
of temperature
and pressure.
which has not been used by the desorption material
and then possibly
3) At intermediate
to initiate
powers,
the same participation
kinetics
The surplus
process,
secondary
energy,
is first used to heat the phenomena
of desorption
in the global desorption
of microwave
(Plasma).
and thermic
exchanges
have
process.
CONCLUSION From an experimental guide, we have carried
apparatus,
field, through a preliminary
activation
tigation
has allowed
pointing
out the characteristics
cerned
explainedby
the thermic
acting essentially
evolution
of the material
experimental
some precisions
of the desorption
could be used in parallel
The experimental
invesway,
in field. In the con-
are mostly
under a microwave
field,
energy.
study which
concerning
of 13X zeolite
connection
obtained
depends
thermodynamic
on pressure and kinetic
in field. This information
with that already
published
and used favou-
rably in the elaboration/implementation
of a microwave
mable
in a machine producing cooling
to the stage of seolite
an adsorbate-adsorbent
in a
the study does not seem to take out any spe-
with the supply of calorific
and power has provided
with a wave desorption
in a reproducible
of the field. The results
In this case, the systematic
characteristics
curves
of such transformation
domain,
mechanisms
the 13X seolite
of the zeolite.
to draw the progression
field and pressure
cific interaction
linking microthermogravimetry
out a study concerning
regeneration
applicator,
conforfrom
cycle.
REFERENCES 1 Proceeding from the "International on thermochemical Energy Storage", Stockholm, January 7-8, 1980, edited by G. WETTEMARX (1980). 2 E.A.Brumberg, Tepidus Storage System, German-Swedish workshop on thermochemical energy storage and absorption heat technology, Stockholm, 1980. 3 H. BjurstrGm and W. Raldow, Energy Res., 1981, 5, p. 43. 4 F. Henry and M. Devillard, Application des microondes aux mesures precises d'humiditk, Communication Journee de 1'Association Fran$aise des Thermiciens, Paris, Avril 1984. 5 P. Bailleul, Circulation de l'eau dans les milieux : application des microondes, Rapport interne 1984, Centre d'Etudes et de Recherches de 1'Industrie des liants Hydrauliques. 6 A.J. Berteaud, P. Leprince et A. Priou, Rapport de la mission au Japon de repr&entant du Club Microondes E.D.F., Avril 1985. 7 A. Germain, Sechage des encres heliogravures par microondes, Diplome d'IngCnieur C.N.A.M., Paris 1983. 8 P.E. Huble, Chem. Eng. 1982, 4, p. 125. 9 L. Quemeneur, J. Choisnet et B. Raveau, Mater. Chem. Phys., 1983, 8, p. 293. 10 H. Julien et H. Valot, Polymer, 1985, 26, p. 506. 11 R.M. Barrer, J. Cem. Sot., 1948, 49, p. 133. 12 F. Belhamidi-Elhannoui, These de 3&me cycle, Dijon, 1982. 13 M.H. Simonot-Grange, F. Belhamidi-Elhannoui, Thermochim. Acta., 1984, 77, p.311.
ON SOME THERMODYNAMIC MICROWAVE
43 -
AND KINETIC
Printed
in The Netherlands
ASPECTS
OF DESORPTION
FROM ZEOLITES
UNDER
IRRADIATION
M. BENCRANAAl, 1Laboratoire de Marrakech
M. LALLEMANT,
M.H. SIMONOT-GRANGE
de Chimie Physique, (Maroc).
Universite
et G. BERTRAND2
Caddi Ayyad,
Facultk
des Sciences
2Laboratoire de Recherches sur la Rdactivit4 des Solides C.N.R.S U.A.23, FacultC des Sciences Mirande - B.P 138 - 21004 DIJON CEDEX (France)
SUMMARY
The desorption of 13x xeolite is studied under controlled pressure and temperature conditions (T = 42OC) in an apparatus combining microthermogravimetry with a microwave guide ; the experimental study leads to the kinetic and thermodynamic characteristics of the zeolite in the microwave field. The lack of any modifications to the kinetic regime due to the field and some experimental results (evolution of the diffusion coefficient with the microwave power) tends to indicate that the irradiation effect may be reduced in this case to calorifit effect.
INTRODUCTION The first oil-crisis investigation
lead. If this solar of problems. capture
of 1973 has produced
for the use of renewable
First,
it is necessary
it. Finally,
reserve,
it is necessary
of
in the
its use faces a lot
to set up the techniques intermittent
a vast effort
with the solar energy
energy makes up an enormous
this dilute, uncertainand
for storing
in all the world
energies,
which allow
to
energy and then to transform
to be able to restore
this energy
it
in
order to use it. For all these problems, cal compounds chemical tricity
chemists
"(ref. 1)" which
heat pumps "(refs. the enormous
Their applications household
efficiency
1) The formation adsorbent.
conventional difficult
proceedings
heating
scale. But some problems
chemi-
in so-called
present
on elec-
energy
at
or solid adsorption.
and energy
storage
need to be solved
on a
for obtai-
:
problem
heating which
0040-6031/S9/$03.50
for cooling,
or more precisely
which
present
which always
0 1989 Elsevier
the hydration
stage of chemical
of regeneration
operation
storage
cycles of liquid absorption
It's an essential
2) The problem
They propose
of being able to store and restore
are designed
or industrial
ning a better
to offer.
can store and carry solar energy
2-3)". These
advantage
will. They use thermodynamic
have solution
requires
Science
cycling.
is often performed
a lot of major
by pumping
drawbacks.
high temperatures.
Publishers
of an anhydrous
B.V.
or by
It's a long and
44
In both cases, the knowledge
* A basic or fundamental mechanismsin applied
the hydration
to a material
** Or applied
the regeneration
of
research
of these systems. For example, cycle effects, pressure
(specific
of microwave
as the power of the field or
gas.
field effect applied
to only one of these points
to a material
on the microwave
action,
new and fruitful means of investigation
lyophilisation,
dissipating
thawing
or dehydration.
energy everywhere,
Indeed
in volume
because
"(refs.
:the
regeneration.
during
it's a means
at present,
4-10)"
they
such as drying,
of carrying
and
or at interfaces.
The aim of this study is to supply the relevant lowingquestions
of the real working
the dehydration-hydration
the mass effects,
We will focus our attention constitute
field effect
effect or heating).
on key parameters
In this paper, we will devote our attention research
:
either
of reaction
of microwave
the delay time or other parameters
of adsorbent
requires
the knowledge
case or the research
during
study
of the transformation
study, for example,
elements
to answer
the fol-
:
(i) Is microwave
interaction
a simple conventional
heat
or is there a spe-
cific action of the field ? (ii) How do of microwave
the kinetics
of the regeneration
stage evolve
in the presence
power ?
(iii) What are the working vi) of an affinity
parameters
thermal machine
using
(Pressure
P, temperature
13x zeolites
as adsorbent
T and power ?
EXPERIMENTAL The apparatus
is composed
of three essential
parts
:
. The microwave guide . The thermobalance . The reactor. Microwave The microwave at a frequency
part (Fig. la) is made up of a wave generator
of 2.450 MHz and protected
ted power is diverted
towards
by a wave circulator
an adapted water
plies a rectangular
wave guide
wave is propagated.
The transmitted
Cl), operating (2). The reflec-
load (3). The generator
(4) (type RG 112/U) inside which power is absorbed
sup-
a progressive
by a second water
load
(5). Thermobalance The coupling
of both methods-microthermogravimetry
carried out in laboratory sure and temperature,
allows
to record continuously
the variations
and microwaves-(Fig. under controlled
of mass of irradiated
samples
using
la) pres-
45
Microoven
Wave
load
PS 50
w 4
i
Vacuum
Fig. la. Experimental a microbalance sensitivity
(6) of zero SETARAM
used through
its possibilities It is positioned
tor by a metallic
circuit.
type PS 50. It's a dissymetric
This apparatus
g-
mass
scoop
: microwave
Apparatus
is l/SO
sample.
or pressure
of maximum
of electromagnetic under
balance,
its
load 50 g is currently
taring
if we often vary the
the wave guide and connected
tube (7) in order to avoid overpressures
with
the reac-
at the level of the
(8).
Reactor The reactor mities
(Fig. lb) consists
by two teflon-plates
by means
(9) which
of a furnace ribbon
piloted
hole at the centre of its larger is made up of a quarts-stick beam branches
and allows
ness of the reactor The reactor
are 4 mm thick,
to position
from a heating to vacuum
tight crossing mounted in a cylindrical
its temperature
diameter the sample
by toric joints
and supported
(10). of a cylindrical
element with cold extremities
and to pressure
tube. This microoven
pass. This one by one of the
in a wave guide axle. The tight-
(11) consisting
is provided
on a brass block, which
is fixed
The guide has a
faces to let the sample-stand
of 2 mm
is provided
closed at its extre-
in power by a rheostat.
is topped by a microoven
ling (12) made The tightness
of a part of wave guide,
by the utilization
slides
is necessary
spoo-
type TRRRMOCOAX.
via
of
toric joints
for the previous
activa-
tion of 13X seolites. Procedure After activation cuum, conditions
of 13X seolite
during
point, a water vapour temperature
in temperature
24 hours, we rehydrate
pressure
corresponding
(T = 42°C). From this hydration
T = 35O'C and pressure
it by imposing
to the saturation
through
the cold
of seolite
state, the dehydration
= va-
at
is achieved
46
Thermolok
Microoven @) (thermocoax withyold
(1
Teflon-p] .ate
t13X
Sample-standand SCOOD
Fig. lb. Exphrimental for a given pressure
zeolite
I
@-n
Apparatus
IB
Microbalance
llr
: microwave-thermogravimetry
in a 0.1 - 4.5 kPa range in accordance
power "i. It must be noted ted again, always
0b
that after each dehydration,
in the same conditions
PS 50
coupling. with incidental
the sample
is rehydra-
(T = 42OC, P = 5.6 kPa and xi = OW).
RESULTS The desorption
curves
The action of the microwave shown
by the thermopravimetric
field on the dehydration curves
__-
5oow
-.--
7oow
______-
3sou
--w .--0-9-w-
Fig. 2. Example
of loss-mass
of 13X zeolite
(Fig. 2) representing
curves m versus
is
the evolution
190w 1oow ow
time, T = 42°C and variable
powers.
of the desorbed for different
water mass versus
1) At null field and whatever parabolic
shape. In the presence
of the shape of curves which (i) First,
time, at a constant
powers "i. From these curves,
an initial
the pressure, of microwave
then presents
pressure
observations
can be made.
the m(t)
two parts
and
curves have a quasian evolution
:
to a loss of mass with a
since the power is high. This first part lines up
expression
tl=KA
water vapour
field, we observe
fast rise, corresponding
speed all the more important with the following
different
: (Fig. 3a)
"(ref.
11)"
A
500
0 300 l 190 v 100
P= 3.16kPa
Fig. 3a. Linear time).
transform
of experimantal
ni conditions.
This one lines up with the following = K' + K"t
(Fig. 3b)
0
to a continuously
a stage in the chosen pressure
Ln(l-o)
30
: CL=K&
curves m(t)
(ii) The second part of the curves corresponds speed until reaching
7 0
P, temperature expression
"(ref.
law (short decreasing T and power
:
11)"
Time (pin)
Fig. 3b.Linear transform law (long time).
of experimental
curves m(t)
_ ln(l-cC) = K' + K"t
48 Then, we can notice terpreted
in this case, that the curves
obtained
in field are in-
with the same laws as those in null field. There are no alterations
of kinetic 2) For
system through
the application
higher
(ri > 500 W) and in particular
sure values,
powers
other curves are obtained
ter a first part which
for the weaker
pres-
as you can see in Fig. 2 (curve B). Af-
a stage which
than that previously
at slight pressure
field.
seems to be the same, the loss of mass reaches
mum, and then goes through tly smaller
of an electric
hoped
represents
for the given power, while
and high powers are obtained
a maxi-
a rate of hydration
a microwave
plasma
sligh-
such curves is produced
in the reactor. 3) The general sent~amaximum
shape of the curves, with continuously
speed of desorption
ches a decomposition
step cm,). We notice
(Vi = 500 W), the curves v.
The desorption
equilibrium
(“i)p
reaof
and me ('ITi)are linear.
under field
of the field over the desorption
, which represents
figure 4
slope, pre-
and it always
that as far as the limit value
the experiment
The influence
decreasing
(vo) at the time origin
the network
equilibrium
of the isotherm
is shown
in
curves M = f(P)T obtai1
0.2 M(%) :F
30
0.85
1.5 2.15 2.8 3.45 T, 42’C Z = anhydrous zeoiite mass -58 gm
4.1 P(kR
25 20 15 10
5 C Fig. 4. Network curves.
graph
"(refs.
and values
. It
isotherms
12-13)".
of the power
is experimentally
for Pl and nil values
20
15
of adsorption
ned by calculation pressures
10
5
0
30
"(refs.
The compositions
(isopower
checked
of pressure
oalc*
25
curves)
11-12)" and isopower
obtained
with various
can be plotted
that the equilibrium
and microwave
315
power
on the same
desorption
obtained
(point A in the figure 4)
49
is the same as the equilibrium rature T defined which
therm
obtained
by the junction goes through
The desorption
under
obtained
in field appears of the steady
of the latter. The quantity
the application
depends
isopower
Pl at a tempe-
curve and the iso-
point A.
equilibrium
ting of the zeolite by the field, because
equilibrium
the same pressure
of the considered
of adsorbed
on the power of the field through
as a result
of the hea-
temperature
obtained
water
by
at the desorption
the material
temperature
imposed by the field.
Evolution
of the diffusion
The appropriate diffusion
coefficients
transformation
coefficient
tion of the microwave
the power of the field
f(t) (Fig. 3) enable
a=
Their evolution
in the zeolite. power
with
in (figure 5a). This figure
l o.lEkPa
to reach the water
is represented invites
as a func-
two remarks
:
@
ro.WkPa o j.16kPo
Fig. 5a. Variation coefficients. (i) We notice
as function
of the incident
that De coefficient
in near conditions
which
to the thermodynamic
power of
: the diffusion
characterizes
equilibrium
the diffusion
varies
of water
little with
the power
of the field. (ii) We observe water
that Do, the coefficient
in conditions
field, at constant diffusion
far removed pressure.
coefficient
with
characterizing
the diffusion
from this same equilibrium,
increases
This result can lead to infer an evolution
the field and the opportunity
of a specific
of
with
the
of the action
of the field on the material. Infact,
the comparison
ned for the temperature
between
the curves of the figure Sa, and those obtai-
(Fig. 5b) shows that both offer
ding to three domains of power. (iii) A first part I, isatvi
< 30 W power
in which
three parts corresponthe effect
of the field
is negligible. (iv)
For 30 < vi < 100 (part II), the temperature
tion depending
on the power,
the slope depends
follows
on the pressure.
a linear varia-
50
0b
v 0.18kPa o 0.86kPa 0 1.93kPa A 3.16kPa m 4.24kPa
vi I
200
100
300
400
Fig. 5b. Variation as function of the incident ture at the desorption equilibrium. If "i > 100 W, the zeolite
(v)
power, but the slope keeps
“O
temperature
independent
(wa$
: the material
power of
varies
of the pressure
tempera-
proportionally
to the
(part III).
INTFXPRETATION These results incident
can be interpreted
power is divided
by taking into account
(i) The power used for the heating se of the temperature
(iii) Finally,
of the zeolite which
which
of the zeolite. We notice
1 to 1000 ratio in accordance Thus, at a given pressure
Then, if we consider
1) At low power
maximum
this division curves
speeds
Of
is
surfaces.
a steady state of the irra-
leading
by the heating
of the incident
to a possible
cooling
term.
power, we will understand
(Fig. 5). the desorption,
the total power applied
increase with
the temperaof the reactor.
on the material
the power of the field
: speed
of energy and not by the pressure.
(part III), we notice
that the seolite
is then no longer the factor limiting
speed of desorption
consequence
the latter in a
the same as the temperature
uses nearly
by the bringing
2) At high powers of energy
if the processes
are compensated
is practically
phenomenon
Initial and instantaneous
bringing
power,
(part I of the curves) during
ture of the seolite The desorption
is regulated
and microwave
of the obtained
with
with that of the sample-guide
can be reached
down, chiefly desorption,
is a
that this power
below the incident power and adopts a linear variation
the variation
an increa-
for the losses after a heat transfer.
the power used for the desorption
of the temperature
diated material
justifies
of this material.
(ii) The power used to compensate
decrease
the fact that the
into three parts,
is then fixed by a chemical
gets heated.
the desorption restriction
The ; the
imposed
by
51
local conditions
of temperature
and pressure.
which has not been used by the desorption material
and then possibly
3) At intermediate
to initiate
powers,
the same participation
kinetics
The surplus
process,
secondary
energy,
is first used to heat the phenomena
of desorption
in the global desorption
of microwave
(Plasma).
and thermic
exchanges
have
process.
CONCLUSION From an experimental guide, we have carried
apparatus,
field, through a preliminary
activation
tigation
has allowed
pointing
out the characteristics
cerned
explainedby
the thermic
acting essentially
evolution
of the material
experimental
some precisions
of the desorption
could be used in parallel
The experimental
invesway,
in field. In the con-
are mostly
under a microwave
field,
energy.
study which
concerning
of 13X zeolite
connection
obtained
depends
thermodynamic
on pressure and kinetic
in field. This information
with that already
published
and used favou-
rably in the elaboration/implementation
of a microwave
mable
in a machine producing cooling
to the stage of seolite
an adsorbate-adsorbent
in a
the study does not seem to take out any spe-
with the supply of calorific
and power has provided
with a wave desorption
in a reproducible
of the field. The results
In this case, the systematic
characteristics
curves
of such transformation
domain,
mechanisms
the 13X seolite
of the zeolite.
to draw the progression
field and pressure
cific interaction
linking microthermogravimetry
out a study concerning
regeneration
applicator,
conforfrom
cycle.
REFERENCES 1 Proceeding from the "International on thermochemical Energy Storage", Stockholm, January 7-8, 1980, edited by G. WETTEMARX (1980). 2 E.A.Brumberg, Tepidus Storage System, German-Swedish workshop on thermochemical energy storage and absorption heat technology, Stockholm, 1980. 3 H. BjurstrGm and W. Raldow, Energy Res., 1981, 5, p. 43. 4 F. Henry and M. Devillard, Application des microondes aux mesures precises d'humiditk, Communication Journee de 1'Association Fran$aise des Thermiciens, Paris, Avril 1984. 5 P. Bailleul, Circulation de l'eau dans les milieux : application des microondes, Rapport interne 1984, Centre d'Etudes et de Recherches de 1'Industrie des liants Hydrauliques. 6 A.J. Berteaud, P. Leprince et A. Priou, Rapport de la mission au Japon de repr&entant du Club Microondes E.D.F., Avril 1985. 7 A. Germain, Sechage des encres heliogravures par microondes, Diplome d'IngCnieur C.N.A.M., Paris 1983. 8 P.E. Huble, Chem. Eng. 1982, 4, p. 125. 9 L. Quemeneur, J. Choisnet et B. Raveau, Mater. Chem. Phys., 1983, 8, p. 293. 10 H. Julien et H. Valot, Polymer, 1985, 26, p. 506. 11 R.M. Barrer, J. Cem. Sot., 1948, 49, p. 133. 12 F. Belhamidi-Elhannoui, These de 3&me cycle, Dijon, 1982. 13 M.H. Simonot-Grange, F. Belhamidi-Elhannoui, Thermochim. Acta., 1984, 77, p.311.