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Clogging of HEPA fibrous filters by solid and liquid aerosol particles: An experimental study
A fibrous filter from industrial of the
is a common gas streams.
filter
cleaning device A fundamental
performance
under
aerosol
time. The purpose of this paper in presenting our experiments evolution
of pressure
drop
deposit
P. Penicot, LSGC-CNRS
load
and
is to illuminate of solid and
of HEPA
structure
often used to remove question concerns the
filters
is analysed
D. Thomas,
the
prediction
particles evolution of its life
some of the issues liquid particle filtration.
is described
iin both
as precisely
involved, The
cases
and
the
as possible.
F?Contal, D. Leclerc, J. Vendeb
/ Universitk Henri Poincark, 1 rue Grandville-BP *CE Saclay- DPEI-SERAC,
b&.393,
91191
451, 54001
NANCY
Gif-sur-Yvette,
Cedex, FfUNCE
FENCE
or several years, environmental purification p”‘“‘%4 !‘r ‘I requirements have become more and more stringent. 9, j, i Among all the devices designed to remove small i;*we*A-(2 ” 9 particles from gas streams, fibrous filters are
F
economically
.&%%h they are both
and quite
of an entanglement according
of thin
to several
inertia.
If clean
of many
is still not
completely
importance with
other
are relatively
solid
d eposit
particles
aspect
behaviours
well-known
the filtration
experiments
in both
(8)
during clogging is of major
of the filter.
and liquid drop
TC
or
and have been
the life time
of pressure
is analysed
I: !: 3: I: 5:
carried
particles
on the
in relation
Air production Dryer Aerosol generator Aerosol introductior, Upstream aerosol samplina system
7: 8:
Differential pressure transducer Downstream aerosol sampling system Mass flowmeter Exhaust filter Electropneumatic valve
9: IO: 11:
to the
cases and a comparison
of both
set-up
1 shows a dryer,
diagram
generator,
of the experimental
a filter
a mass flowmeter
and downstream is dried
system. captured
Aerosol particles penetrating by a back-up absolute filter. at different upstream
of aerosol
concentration
can be changed is kept drop
Filtration
using constant across
by passing
points
a by-pass using
results system.
a flow
the filter
& Separation
the test filter Temperature in order
pressure
acquisition
data.
is measured
Diluting
The
air velocity system with
from
concentration
systems
particle
air can velocity inside
a high accuracy
(1 Og/l
particles
Differential a Condensation
entails
aerosol
Particlee Mobility Nucleus
from
impactor
of both
Sizer
Counter
the nebulizer
then
oversized
of dried
compressed
the generator
enables
size and aerosol
size distribution Particle
to the
a nebulizer
to eliminate
from
particle
generated.
according
with
whose
of both
concentration
stream
in order
aerosol
solution
was used
is generated
aerosol
the
modification
by the introduction
the second
modification
concentration.
an uranine
from
generator
impactors
and solidifies
air. Removing
came
and the aerosol
The
two
enables
of a soda fluorescein
44-011
at 1.8 bars. The through
another the
particles
A computer
or 1 OOg/l)
NFX
process.
operated
the influence
and the
solid
size distribution
following passes
transducer.
the atomizing
A standardised
are perfectly and pressure
to test
obtained
the test
air to the
and the filtration
regulator
It
a refrigeration
in the system.
on our
sampling
compressed
it through
of the filter
set-up.
containing
aerosol
The
generator
are controlled
holder
and two
the filter.
aerosol
be introduced
differential
Th e generated
a schematic
of an aerosol
upstream
pressure
interception
up
is performed.
consists
filter
are collected
diffusion,
on one hand
evolution
Experimental
filter,
particles
‘x2z3,, their behaviour understood3. This aspect paper
since
are made
in which like
technology
to use. They
studies
in this
hand. The
Figure
fibres
as it determines
We describe
interesting simple
mechanisms
filters
the subject
out
the most
effective
was measured (DMPS
(CNC
TSI
3071)
TSI 3020)
March
using
a
in line with and was found
1999
59
to be log-normal 0.3 1 nm each
with
and 0.4nm
the following with
mean
a geometric
diameters:
standard
O.l8nm,
deviation
the characterization,
of 1.8 in
case. particles
generated
measured
using
an Impactor around
section
density
The liquid aerosol
filter
two
from
Personal
urn. Table
a di-octyl
Particle
techniques
Marple
0.6
came
at 1.1 bars.
(DOP) was
(DMPS
associated
Sampler
1 sums
phtalate
size distribution 290)
up the main
with
features
A HEPA
(High
Efficiency
for
all experiments.
of the
Air
Several
Filter)
techniques
glass fibre were
used
the
Packing
the following
equation
(1):
(1)
G and Z are respectively
filter
filter
the grammage
and pf is the fibre fibre
law’(see Particulate
using
observing
micrograph.
to be
The
was used
calculated
Pf z
the filter
characteristics
was measured
electron
G
and
particles.
Filter
thickness
a scanning
was then a=--
CNC
and was found
The
using
mean
diameter
equation whose
(2))
packing
for
was first
predicting density
AP -=16p Z
estimated
using
the pressure
is cx , fibre
of
Davies’
drop
radius
of a fibrous
rf and thickness
Z:
CX”~ (1 + 56~‘) z f
U,
dDavles
and the thickness
density.
=2
J+lhereKis
We define the slope drop
0
0.5
WT 1 Collected
Mass
1.5 (g/m*)
2
numerical
0.056
and dDaVies=
the effect
the generated constant
was weighed
several
different
filtration
aspect 1 r
2500
0 .
tf=Zl mn tf=46 mn
filtration
0
Table
I ” 0
50
100 150 Mass Collected
200 (g/m*)
w CLOG 250 300
filtration
1999
pressure
drop,
the face velocity
the tested
filter
mass. This
the same
operating
so that we could electron
was
a linear
up all experiments
of the filtration
at various linking
carried
out.
evolution of liquid
Excellent
reproducibility
as can be seen from times
tf, are situated
both
of the
parameters.
of pressure loss or solid aerosol
that
on the same
Filtration
with
states against
of the experiments
the fact
was
the deposit
mass was plotted equation
the filter
process
conditions
observe
micrographs
the collected
to obtain
IX =
pm.
on the filter keeping
the collected
time
through urn,
At the end of the experiment,
under
scanning
0.14)
passes (f50)
In Figure 2 and 3, we can see the evolution of the pressure during clogging respectively in the case of liquid and solid attained
March
time 2 sums
(t
loss across
clogging.
Moreover,
Comparison during the particles
particles.
60
taking
are: Z = 575
1.14
was filtered
times
the pressure
Experiments
to determine
repeated
clogging. g -b
aerosol
during
Us)
of the loading
and the pressure
measured
AP is
values
of the
To describe
2.5
AP to
a flow
the medium.The (? 0.006)
Us.
of air (velocity
line linking when
Description
2
, ooo
of straight
of the filter
all plots
drop
was for different
curve.
& Separation
a
the evolution mass but
of pressure
suddenly
We can easily (for
both
solid
collected
particle
takes
place
chainlike
analysis
Plotting for
filtration
pressure
As illustrated of two
collected
becoming
quite
give rise
consists
a given
two
from
drop.
particles
The
expected processes
mass
a linear clogging
parts.
different
Filtration
steps
function
Nevertheless, from
by Figure
(here
by liquid
intuition
2, the clogging
wr),
the behaviour the solid
one.
& Separation
is firstly
it is more
of the loading particles
‘7 6. The
to the
appearing
as loading
increase
that
on the same of solid
firstly
drop
the filter
surface.
to form
are filled
in, corresponding
the filter
surface.
graph
(Figure aerosol,
entails
a far higher
We
on the bridges
at the
all to the
6), the increase we become
is
of this film.
deposited
together
and solid
particles
as droplets
At the end of clogging,
layer
covering
liquid
droplets
The
of pressure
on the thickness
and join fibres.
on the first of a film
covering
particles.
that in the early
are deposited
of a film
grow
show
of pressure
aware
pressure
that the drop
than
and previous
to an increase
: the increase called
particles
of several
both
This
work4,
out for the liquid
exponential
we can assume
interstices
of
4A).
attributed
5 clearly
any information
progressively
presence drop
The
by the presence
intersections
(Figure previous
thickness
in Figure
liquid
not obtain
fibres
firstly
the formation
can be easily
was carried
presented
the fibres.
However
that the filtration
other
are
of the
4B).
of filtration,
could
filtration
drop
curve
micrographs
with
dendrites with
(Figure
explained
have been
called
of a cake of increasing
around
both
show
increases
stage
particles
surfaces of the filter
of pressure
same
drop
electron
presence The
of the pressure
Scanning
filter
of the loading
to the way that
the filter.
loaded
observations
As might
each part
is in agreement
rise
function
exponential.
filtrations)
agglomerates
linear
studies,
attribute
in the depth
observation
is a linear
and liquid
inside
solid
drop
the rise becomes
in by solid
slow
and for
rapid,
mass.
(Figure
3) is also made
of the liquid In the early
stage
aerosol
up of is
of filtration,
March
1999
61
between
the transition
had also observed
z
6000
this
agreement
between
correlation
wy
particles
with
quickly
entailing
formation
point
and the particle
linear
relationship.
our
experimental
~3.975
results
dp. We may
a higher
specific
a greater
of the cake
Renaudin7
that
form
effect.
reached
8 shows smaller
dendrites
The
for
good
and a simple
suppose
area will
clogging
is then
size. Figure
more
point
a smaller
of amount
of
particles. In the case of liquid clogging
point
covering
the filter
the increase 100
150
Mass
200
Collected
250
300
The
(g/m”)
influence
tendency
is a smaller
suppose
better
that
collection
we want solid
DOP
WT
1 1.5 Mass Collected
particles.
In other
words,
h’ ig h er amount
of liquid
than
and then from
before
of uranine, new
dendrites
collecting
Points
of filter
particles
entailing
deposited
they
around
is greater.
velocity.
We
entails
of the filter.
a
Thus,
in the case of a
mass needed
Further
Figure
general
velocity
may be deeper
the collected
studied. The
a higher
layers
was velocity.
to form
experiments
a
would
be
this hypothesis.
to be able to predict
structure
is of major
the behaviour
importance
of the filters
if
under
loading.
explanation
can easily flow
a
its destruction comes
in the filter.
a higher
of the first
surface
wCLoG
3
can collect
before
A possible
are collected
are created:
fibres
case of droplets
In the case
be considered
resistance
than
as in the
I
0
0.1
0.2
0.3
0.4
0.5
the fibres.
of Interest
As described filter
particles
2.5
with
film
for which
of the filtration
of the filtration
of the deposit
and liquid
exponential.
air velocity.
point
the
(g/m*)
this kind solid
its replacement.
the way that
2
efficiency
to confirm
Characterization
0.5
clogging
an increase
and then
necessary
becomes
mass
size has not yet been
of the aerosol
on the filter
wCLOG of an entire
is the collected
of w CLOG with
smaller
velocity
studied
as a function
the penetration film
0
drop
of the particle
the evolution
may
wCLoG
determined
9 shows
we have
to the formation
surface.
of pressure
experimentally 50
particles,
corresponding
above,
in two
particular
steps. points
both
solid
It seems
and liquid
particles
to be interesting
corresponding
clog
to study
to a transition
the HEPA those
between
both
parts. In the case of solid transition which
point depth
begins, point
wr
found
filtration
comes
tangents
that
for
determined
the collected
to an end
studied
way whatever
62
the velocity
of fibres.
by the intersection 2. Let us firstly
particles
sizes,
of the filtration
March
at which
Let us also stress
1999
for
formation
by Figure velocity
particles the linear
wr was (on the range
3 < U, < 50 cm/s) as illustrated by Figure 7.This that (on the range studied), the aerosol is collected vicinity
wT the mass value
and cake
determined
as illustrated
the three
to be independent
we have
words,
was experimentally
of both
emphasize
particles,
or in other
result means in the same
are arriving
0
5
10 U, (cm/s)
15
in the
relationship
Filtration
& Separation
20
8000
z-
/
I
/
!
,
/
i ,
1-t
7000
F DOP filtration
6000
; : p
Clean air circulation I
3 a a e 75 E ? $ &
5000
both
‘1
I
. .
I I
.
stages
*
*
was reached.
The
step
between 1
cm/s).
the filter
second
.
(U,=l.8
experiment,
passing
of the experiment
varied
Each
(corresponding
velocity
As illustrated drop
until
As shown IO
0
20
30
40
Filtration
50
60
70
(small
time (mn1 (mn)
The
air velocity
(last
particles
We tried
to give
particle
a better
loading.
according
We first
to several
experimentally
observed
with
m/s
surface.
the linear pressure of a filter radius
Z,,
rp corresponding
Liquid
The
of the slope
be compared
value
an equilibrium
process phenomena:
Clean
air going
loading
effect
paper Both
collected that both
of such
through
or weak drop
during
loading).
is not due to a re-
in the filter. the film
formed
the fibres,
on the
had not initially
that an internal to be as minor
as
the air circulation. particles
loading,
the filter
and to bring
filter.
of particles
It also seems
during
filtration
This
the filter
no presence
for the resistance
opposed
phenomenon
for a higher
downstream
around
state.
of the liquid, place
as in the first
occur
omission
the effect
observed
be depicted
as
and relocation.
has enabled
to the fore
has also been
can then
drainage
of the
of relocation.
by Walsh
et al.“.
to the pressure
density for
of
that the drop
size. Then
a given
according
6000
process
up all results
we can also compare
was obtained previous
between
solid
the effect and liquid
of loading particles
with
corresponding
to values
issued
all methods
experimental
7
L
set of operating
of the filtration
3 sums
outlines
particles
were
on a HEPA
studied.
More
ap = 1 - E, and
E,.
Table
from
and all droplets
This
clearly
for a heavy
initially
several
cake
papers. values
(either
we can suppose
takes
Pa.
experiment
we can also see the
that the fall of pressure
of particles
possible,
of
4700
Zc the cake
We assumed
to the particle
that
agreement
with
area,
calculation curves.
simulations
of dendrites.
Good
with
estimate
to 0.3 1 urn particles other
of 10 %. The
of filter
of packing
we performed
formation
was
showed
Consequently,
relocation
cake thickness
an accuracy
drop
of the cake could
we could
Finally,
The
the aerosol
entrainement
attained was
around
of the experiment).
the filter
surface
to a decrease
if it is not so obvious especially
decrease
means
rise
density.
was made
law and the slope
conditions,
section
mass per unit
of thickness
to Davies’
of particles
the filter
by:
in the pressure
drop
amount
Then,
drop
result
filter
time
-1 PZC
estimate part
a sufficient
m/s
and the particle
A second
was
of the cake
a huge
with
calculated
E,
stage
through
That
this parameter
out during
microscope.
the deposited
thickness
and as
-z a g % E z t? 6
5000
1
4000
I ;
2000
L
/
1
Perte de charge
l
I
/
(Pa)
U. 0-M
. I li‘
’
1’
j
0.09
. . . . . . . . . *.,e
l ‘)** DOF’
l~
a9 * a..
0
Clean air circulation
j 0.04 0.03
studies.
particles
In this case, we tried stability
point
the loading coalescence
is much
of liquid
particles.
we carried to a high
in which a flow
was loaded (presence
Filtration
filter. until
field solid
more
variable
out two and a small
amount DOP
In the case of the first a pressure
of a film),
The
drop air velocity
& Separation
aerosol,
of 7000
from
0
its
20
40 60 Filtration time $I!?)
100
120
was suggested the nature
of
due to the possible
experiments
process
air (without
structure
of study
with
the filtration
of clean
the deposit
particular
behaviour
corresponding
the clogged
This
in comparison
Accordingly, particles)
to characterize
of view.
by the fact that,
where
was carried
passing
by solid
the cake porosity with,
the estimation
to be estimated
was then Ep =l-(
well
with
an electron
enough
porosity
from
To begin
to obtain
on the filter
fibre
to estimate
in order
deposited
with
tried
An experiment
of exposure
of the cake formed
techniques.
calculated
thickness.
great
description
phenomena
sampling
the pressure
of pressure
of deposited
to be attained
particles), even
and
15 min.
11, in the case of the second drop
Pa the
stages
velocity)
the evolution
air gives
seems
of 1400 during
to several
every
amount
of clean value
of deposited
Moreover,
Solid
(large
of pressure
experiment.
was applied
10 showing
by Figure
amount
decrease
according
experiment
a stable
drop
the filter
to the filtration
stage
the circulation
pressure
a pressure through
by Figure
for the first
particles),
until
air velocity
1.8 cm/s
8.5 cm/s.
In the case of the second
was loaded
(respectively of deposited
was followed particles)
by a step passed
experiment,
through
the filter
. i(,..:_ . Previous
inveestigations
[8],
[9]
From
85 to 92
Pa was reached
was kept
constant
during
March
1999
63
particularly,
the evolution
described.
Solid particles
of the filter pressure
before
stage
a cake
a linear with
0.3 1 urn. The
value
collected
in the depth
surface:
the
of the deposited by several
previous
influence
was precisely
on the filter
function
the cake porosity
are all in agreement for
drop
forming
loss becomes
determined
of pressure are in a first
works
around
of the particle
Cake
porosity
CL
Fluid
viscosity
Fibre
density
Pf
mass. We
techniques
&P
which
the value
P (T
Aerosol
AP
Filter
C-1 (Pa.i) (kg/m3)
particles
Standard
density
(kg/m3)
deviation
C-1
of 85%
size has not yet been
pressure
drop
Pa)
analysed. Liquid
particles
to form
displayed
droplets
on, droplets
around
coalesce
intersections.
The
filter
which
surface
pressure
drop.
the liquid
inside
of the film
theoretical between process
of filtration
evaluation
for
situated
may take
in a film
on the
increase that
Davies,
of
relocation
Characterization
it would
be of a great
of the solid
interest
the transition
and liquid
particle
C. N. (1973)
of
New-York.
of the
Kuwabara,
S. (1959)
distributed
parallel
in progress.
of wT and wCLOG
stages
seem carries
at the fibre
shown
place.
they
loading
results
have
is currently study,
since
When
the exponential
experiments
the filter this
both
bridges
stage
accounts
thickness
behaviour
surface.
to build
final
Several
To complete
different
the filter
to give
flow
a
points
at small
filtration
Penicot,
Reynolds
Company
for
supply
to express
gratitude
to Bernard
DUMAS
diameter
df
diameter
dP G
Particle
m/s
Collected
Tf
Fibre
l-P
tf
wT
grammage mass per
unit
of area
radius
Particle
radius
Filtration
Uo wcLocClogging
with
diameter
Filter
Fluid
estimated
time
velocity
Transition filtration
point
for liquid
point
from
to surface
filtration
Davies’law
media
Hinds,
(kg/m*)
Loading
(kg/m*)
Aerosol
(ml
Renaudin,
(4
k-4
fibres. DEA de 1’INPG Schmidt, E., Loffler, F. (1991)
The Analysis
(m/s)
Structures.
System
(kg/m2)
109.
(kg/m*)
Experimental of fibrous
(4
10
Walsh, The
64
March
density
of deposited
1999
particles
Recent
Behaviour
Advances under
in the Understanding
Solid
Particle
N. P. (1997)
on Penetration
and Resistance
Science
and khnology
V (1991)
Particle D.A.,
C-1 C-1
27, Suppl.1,
and Particle
Stenhouse,
filters.
fibrous
filter
of
Filtration
journal
Stenhouse, of solid material
of Dust Filters.
J.I.T,
Liu,
of Dust
B.Y.H.
Scurrah,
K.L., particle
Journal
Cake 8, 105.
clogging
385-393.
Graef, loading ofAerosol
A. (1996) on Science
617-618.
Filtration
a
(I 994) particle
Science 25,
aerosol
performance.
de filtres
Characterization
monodisperse
ofAerosol
and liquid
effect
of Glass Fiber
du colmatage
J.I.T.,
of solid
The
162-173.
27,
Modklisation
results
D.C.,
Load.
33, 501-506.
W. C., Kadrichu,
effect
HEPA
Air Cleaning
782-798
and Separation
thickness
Packing
Nuclear
(ml
Cake
aP
San Diego,
I? G. (1990)
of a typical
Zlst DOE/NRC
material.
Japuntich,
density
characteristics
W
Zc
packing
loading
B., Abrahamson,
P R., Ellison,
(m)
64
and
of
Separation
P. J., Dierkschiede,
Filter
thickness
J.
of fibrous
: experiments
Symposium
Fibrous
Filter
Filter
particles
D. C. (I 996)
Z
a
clogging
Walsh,
depth filtration
Societf,
D.,Vendel,
during
European
W. B., Monson,
and mass
Conference
Fibre
in a viscous Physical
Gases, 243-255
C., Richardson, filter
ofthe
P, Leclerc, drop
aerosol
98,4th
J., Higgins,
Efficiency
dDavies Fibre
or solid
PARSEC
Novick,V.
of filters.
London,
by randomly
or spheres Journal
Contal,
of pressure
by liquid
Part~clesfrom
wish
experienced
cylinders
D.,
Evolution
models. authors
forces
Numbers.
P., Thomas,
(1998) filters
The
The circular
Press
14, 527-532.
ofJapan
respectively.
Academic
Airfiltration,
& Separation
is a common gas streams.
filter
cleaning device A fundamental
performance
under
aerosol
time. The purpose of this paper in presenting our experiments evolution
of pressure
drop
deposit
P. Penicot, LSGC-CNRS
load
and
is to illuminate of solid and
of HEPA
structure
often used to remove question concerns the
filters
is analysed
D. Thomas,
the
prediction
particles evolution of its life
some of the issues liquid particle filtration.
is described
iin both
as precisely
involved, The
cases
and
the
as possible.
F?Contal, D. Leclerc, J. Vendeb
/ Universitk Henri Poincark, 1 rue Grandville-BP *CE Saclay- DPEI-SERAC,
b&.393,
91191
451, 54001
NANCY
Gif-sur-Yvette,
Cedex, FfUNCE
FENCE
or several years, environmental purification p”‘“‘%4 !‘r ‘I requirements have become more and more stringent. 9, j, i Among all the devices designed to remove small i;*we*A-(2 ” 9 particles from gas streams, fibrous filters are
F
economically
.&%%h they are both
and quite
of an entanglement according
of thin
to several
inertia.
If clean
of many
is still not
completely
importance with
other
are relatively
solid
d eposit
particles
aspect
behaviours
well-known
the filtration
experiments
in both
(8)
during clogging is of major
of the filter.
and liquid drop
TC
or
and have been
the life time
of pressure
is analysed
I: !: 3: I: 5:
carried
particles
on the
in relation
Air production Dryer Aerosol generator Aerosol introductior, Upstream aerosol samplina system
7: 8:
Differential pressure transducer Downstream aerosol sampling system Mass flowmeter Exhaust filter Electropneumatic valve
9: IO: 11:
to the
cases and a comparison
of both
set-up
1 shows a dryer,
diagram
generator,
of the experimental
a filter
a mass flowmeter
and downstream is dried
system. captured
Aerosol particles penetrating by a back-up absolute filter. at different upstream
of aerosol
concentration
can be changed is kept drop
Filtration
using constant across
by passing
points
a by-pass using
results system.
a flow
the filter
& Separation
the test filter Temperature in order
pressure
acquisition
data.
is measured
Diluting
The
air velocity system with
from
concentration
systems
particle
air can velocity inside
a high accuracy
(1 Og/l
particles
Differential a Condensation
entails
aerosol
Particlee Mobility Nucleus
from
impactor
of both
Sizer
Counter
the nebulizer
then
oversized
of dried
compressed
the generator
enables
size and aerosol
size distribution Particle
to the
a nebulizer
to eliminate
from
particle
generated.
according
with
whose
of both
concentration
stream
in order
aerosol
solution
was used
is generated
aerosol
the
modification
by the introduction
the second
modification
concentration.
an uranine
from
generator
impactors
and solidifies
air. Removing
came
and the aerosol
The
two
enables
of a soda fluorescein
44-011
at 1.8 bars. The through
another the
particles
A computer
or 1 OOg/l)
NFX
process.
operated
the influence
and the
solid
size distribution
following passes
transducer.
the atomizing
A standardised
are perfectly and pressure
to test
obtained
the test
air to the
and the filtration
regulator
It
a refrigeration
in the system.
on our
sampling
compressed
it through
of the filter
set-up.
containing
aerosol
The
generator
are controlled
holder
and two
the filter.
aerosol
be introduced
differential
Th e generated
a schematic
of an aerosol
upstream
pressure
interception
up
is performed.
consists
filter
are collected
diffusion,
on one hand
evolution
Experimental
filter,
particles
‘x2z3,, their behaviour understood3. This aspect paper
since
are made
in which like
technology
to use. They
studies
in this
hand. The
Figure
fibres
as it determines
We describe
interesting simple
mechanisms
filters
the subject
out
the most
effective
was measured (DMPS
(CNC
TSI
3071)
TSI 3020)
March
using
a
in line with and was found
1999
59
to be log-normal 0.3 1 nm each
with
and 0.4nm
the following with
mean
a geometric
diameters:
standard
O.l8nm,
deviation
the characterization,
of 1.8 in
case. particles
generated
measured
using
an Impactor around
section
density
The liquid aerosol
filter
two
from
Personal
urn. Table
a di-octyl
Particle
techniques
Marple
0.6
came
at 1.1 bars.
(DOP) was
(DMPS
associated
Sampler
1 sums
phtalate
size distribution 290)
up the main
with
features
A HEPA
(High
Efficiency
for
all experiments.
of the
Air
Several
Filter)
techniques
glass fibre were
used
the
Packing
the following
equation
(1):
(1)
G and Z are respectively
filter
filter
the grammage
and pf is the fibre fibre
law’(see Particulate
using
observing
micrograph.
to be
The
was used
calculated
Pf z
the filter
characteristics
was measured
electron
G
and
particles.
Filter
thickness
a scanning
was then a=--
CNC
and was found
The
using
mean
diameter
equation whose
(2))
packing
for
was first
predicting density
AP -=16p Z
estimated
using
the pressure
is cx , fibre
of
Davies’
drop
radius
of a fibrous
rf and thickness
Z:
CX”~ (1 + 56~‘) z f
U,
dDavles
and the thickness
density.
=2
J+lhereKis
We define the slope drop
0
0.5
WT 1 Collected
Mass
1.5 (g/m*)
2
numerical
0.056
and dDaVies=
the effect
the generated constant
was weighed
several
different
filtration
aspect 1 r
2500
0 .
tf=Zl mn tf=46 mn
filtration
0
Table
I ” 0
50
100 150 Mass Collected
200 (g/m*)
w CLOG 250 300
filtration
1999
pressure
drop,
the face velocity
the tested
filter
mass. This
the same
operating
so that we could electron
was
a linear
up all experiments
of the filtration
at various linking
carried
out.
evolution of liquid
Excellent
reproducibility
as can be seen from times
tf, are situated
both
of the
parameters.
of pressure loss or solid aerosol
that
on the same
Filtration
with
states against
of the experiments
the fact
was
the deposit
mass was plotted equation
the filter
process
conditions
observe
micrographs
the collected
to obtain
IX =
pm.
on the filter keeping
the collected
time
through urn,
At the end of the experiment,
under
scanning
0.14)
passes (f50)
In Figure 2 and 3, we can see the evolution of the pressure during clogging respectively in the case of liquid and solid attained
March
time 2 sums
(t
loss across
clogging.
Moreover,
Comparison during the particles
particles.
60
taking
are: Z = 575
1.14
was filtered
times
the pressure
Experiments
to determine
repeated
clogging. g -b
aerosol
during
Us)
of the loading
and the pressure
measured
AP is
values
of the
To describe
2.5
AP to
a flow
the medium.The (? 0.006)
Us.
of air (velocity
line linking when
Description
2
, ooo
of straight
of the filter
all plots
drop
was for different
curve.
& Separation
a
the evolution mass but
of pressure
suddenly
We can easily (for
both
solid
collected
particle
takes
place
chainlike
analysis
Plotting for
filtration
pressure
As illustrated of two
collected
becoming
quite
give rise
consists
a given
two
from
drop.
particles
The
expected processes
mass
a linear clogging
parts.
different
Filtration
steps
function
Nevertheless, from
by Figure
(here
by liquid
intuition
2, the clogging
wr),
the behaviour the solid
one.
& Separation
is firstly
it is more
of the loading particles
‘7 6. The
to the
appearing
as loading
increase
that
on the same of solid
firstly
drop
the filter
surface.
to form
are filled
in, corresponding
the filter
surface.
graph
(Figure aerosol,
entails
a far higher
We
on the bridges
at the
all to the
6), the increase we become
is
of this film.
deposited
together
and solid
particles
as droplets
At the end of clogging,
layer
covering
liquid
droplets
The
of pressure
on the thickness
and join fibres.
on the first of a film
covering
particles.
that in the early
are deposited
of a film
grow
show
of pressure
aware
pressure
that the drop
than
and previous
to an increase
: the increase called
particles
of several
both
This
work4,
out for the liquid
exponential
we can assume
interstices
of
4A).
attributed
5 clearly
any information
progressively
presence drop
The
by the presence
intersections
(Figure previous
thickness
in Figure
liquid
not obtain
fibres
firstly
the formation
can be easily
was carried
presented
the fibres.
However
that the filtration
other
are
of the
4B).
of filtration,
could
filtration
drop
curve
micrographs
with
dendrites with
(Figure
explained
have been
called
of a cake of increasing
around
both
show
increases
stage
particles
surfaces of the filter
of pressure
same
drop
electron
presence The
of the pressure
Scanning
filter
of the loading
to the way that
the filter.
loaded
observations
As might
each part
is in agreement
rise
function
exponential.
filtrations)
agglomerates
linear
studies,
attribute
in the depth
observation
is a linear
and liquid
inside
solid
drop
the rise becomes
in by solid
slow
and for
rapid,
mass.
(Figure
3) is also made
of the liquid In the early
stage
aerosol
up of is
of filtration,
March
1999
61
between
the transition
had also observed
z
6000
this
agreement
between
correlation
wy
particles
with
quickly
entailing
formation
point
and the particle
linear
relationship.
our
experimental
~3.975
results
dp. We may
a higher
specific
a greater
of the cake
Renaudin7
that
form
effect.
reached
8 shows smaller
dendrites
The
for
good
and a simple
suppose
area will
clogging
is then
size. Figure
more
point
a smaller
of amount
of
particles. In the case of liquid clogging
point
covering
the filter
the increase 100
150
Mass
200
Collected
250
300
The
(g/m”)
influence
tendency
is a smaller
suppose
better
that
collection
we want solid
DOP
WT
1 1.5 Mass Collected
particles.
In other
words,
h’ ig h er amount
of liquid
than
and then from
before
of uranine, new
dendrites
collecting
Points
of filter
particles
entailing
deposited
they
around
is greater.
velocity.
We
entails
of the filter.
a
Thus,
in the case of a
mass needed
Further
Figure
general
velocity
may be deeper
the collected
studied. The
a higher
layers
was velocity.
to form
experiments
a
would
be
this hypothesis.
to be able to predict
structure
is of major
the behaviour
importance
of the filters
if
under
loading.
explanation
can easily flow
a
its destruction comes
in the filter.
a higher
of the first
surface
wCLoG
3
can collect
before
A possible
are collected
are created:
fibres
case of droplets
In the case
be considered
resistance
than
as in the
I
0
0.1
0.2
0.3
0.4
0.5
the fibres.
of Interest
As described filter
particles
2.5
with
film
for which
of the filtration
of the filtration
of the deposit
and liquid
exponential.
air velocity.
point
the
(g/m*)
this kind solid
its replacement.
the way that
2
efficiency
to confirm
Characterization
0.5
clogging
an increase
and then
necessary
becomes
mass
size has not yet been
of the aerosol
on the filter
wCLOG of an entire
is the collected
of w CLOG with
smaller
velocity
studied
as a function
the penetration film
0
drop
of the particle
the evolution
may
wCLoG
determined
9 shows
we have
to the formation
surface.
of pressure
experimentally 50
particles,
corresponding
above,
in two
particular
steps. points
both
solid
It seems
and liquid
particles
to be interesting
corresponding
clog
to study
to a transition
the HEPA those
between
both
parts. In the case of solid transition which
point depth
begins, point
wr
found
filtration
comes
tangents
that
for
determined
the collected
to an end
studied
way whatever
62
the velocity
of fibres.
by the intersection 2. Let us firstly
particles
sizes,
of the filtration
March
at which
Let us also stress
1999
for
formation
by Figure velocity
particles the linear
wr was (on the range
3 < U, < 50 cm/s) as illustrated by Figure 7.This that (on the range studied), the aerosol is collected vicinity
wT the mass value
and cake
determined
as illustrated
the three
to be independent
we have
words,
was experimentally
of both
emphasize
particles,
or in other
result means in the same
are arriving
0
5
10 U, (cm/s)
15
in the
relationship
Filtration
& Separation
20
8000
z-
/
I
/
!
,
/
i ,
1-t
7000
F DOP filtration
6000
; : p
Clean air circulation I
3 a a e 75 E ? $ &
5000
both
‘1
I
. .
I I
.
stages
*
*
was reached.
The
step
between 1
cm/s).
the filter
second
.
(U,=l.8
experiment,
passing
of the experiment
varied
Each
(corresponding
velocity
As illustrated drop
until
As shown IO
0
20
30
40
Filtration
50
60
70
(small
time (mn1 (mn)
The
air velocity
(last
particles
We tried
to give
particle
a better
loading.
according
We first
to several
experimentally
observed
with
m/s
surface.
the linear pressure of a filter radius
Z,,
rp corresponding
Liquid
The
of the slope
be compared
value
an equilibrium
process phenomena:
Clean
air going
loading
effect
paper Both
collected that both
of such
through
or weak drop
during
loading).
is not due to a re-
in the filter. the film
formed
the fibres,
on the
had not initially
that an internal to be as minor
as
the air circulation. particles
loading,
the filter
and to bring
filter.
of particles
It also seems
during
filtration
This
the filter
no presence
for the resistance
opposed
phenomenon
for a higher
downstream
around
state.
of the liquid, place
as in the first
occur
omission
the effect
observed
be depicted
as
and relocation.
has enabled
to the fore
has also been
can then
drainage
of the
of relocation.
by Walsh
et al.“.
to the pressure
density for
of
that the drop
size. Then
a given
according
6000
process
up all results
we can also compare
was obtained previous
between
solid
the effect and liquid
of loading particles
with
corresponding
to values
issued
all methods
experimental
7
L
set of operating
of the filtration
3 sums
outlines
particles
were
on a HEPA
studied.
More
ap = 1 - E, and
E,.
Table
from
and all droplets
This
clearly
for a heavy
initially
several
cake
papers. values
(either
we can suppose
takes
Pa.
experiment
we can also see the
that the fall of pressure
of particles
possible,
of
4700
Zc the cake
We assumed
to the particle
that
agreement
with
area,
calculation curves.
simulations
of dendrites.
Good
with
estimate
to 0.3 1 urn particles other
of 10 %. The
of filter
of packing
we performed
formation
was
showed
Consequently,
relocation
cake thickness
an accuracy
drop
of the cake could
we could
Finally,
The
the aerosol
entrainement
attained was
around
of the experiment).
the filter
surface
to a decrease
if it is not so obvious especially
decrease
means
rise
density.
was made
law and the slope
conditions,
section
mass per unit
of thickness
to Davies’
of particles
the filter
by:
in the pressure
drop
amount
Then,
drop
result
filter
time
-1 PZC
estimate part
a sufficient
m/s
and the particle
A second
was
of the cake
a huge
with
calculated
E,
stage
through
That
this parameter
out during
microscope.
the deposited
thickness
and as
-z a g % E z t? 6
5000
1
4000
I ;
2000
L
/
1
Perte de charge
l
I
/
(Pa)
U. 0-M
. I li‘
’
1’
j
0.09
. . . . . . . . . *.,e
l ‘)** DOF’
l~
a9 * a..
0
Clean air circulation
j 0.04 0.03
studies.
particles
In this case, we tried stability
point
the loading coalescence
is much
of liquid
particles.
we carried to a high
in which a flow
was loaded (presence
Filtration
filter. until
field solid
more
variable
out two and a small
amount DOP
In the case of the first a pressure
of a film),
The
drop air velocity
& Separation
aerosol,
of 7000
from
0
its
20
40 60 Filtration time $I!?)
100
120
was suggested the nature
of
due to the possible
experiments
process
air (without
structure
of study
with
the filtration
of clean
the deposit
particular
behaviour
corresponding
the clogged
This
in comparison
Accordingly, particles)
to characterize
of view.
by the fact that,
where
was carried
passing
by solid
the cake porosity with,
the estimation
to be estimated
was then Ep =l-(
well
with
an electron
enough
porosity
from
To begin
to obtain
on the filter
fibre
to estimate
in order
deposited
with
tried
An experiment
of exposure
of the cake formed
techniques.
calculated
thickness.
great
description
phenomena
sampling
the pressure
of pressure
of deposited
to be attained
particles), even
and
15 min.
11, in the case of the second drop
Pa the
stages
velocity)
the evolution
air gives
seems
of 1400 during
to several
every
amount
of clean value
of deposited
Moreover,
Solid
(large
of pressure
experiment.
was applied
10 showing
by Figure
amount
decrease
according
experiment
a stable
drop
the filter
to the filtration
stage
the circulation
pressure
a pressure through
by Figure
for the first
particles),
until
air velocity
1.8 cm/s
8.5 cm/s.
In the case of the second
was loaded
(respectively of deposited
was followed particles)
by a step passed
experiment,
through
the filter
. i(,..:_ . Previous
inveestigations
[8],
[9]
From
85 to 92
Pa was reached
was kept
constant
during
March
1999
63
particularly,
the evolution
described.
Solid particles
of the filter pressure
before
stage
a cake
a linear with
0.3 1 urn. The
value
collected
in the depth
surface:
the
of the deposited by several
previous
influence
was precisely
on the filter
function
the cake porosity
are all in agreement for
drop
forming
loss becomes
determined
of pressure are in a first
works
around
of the particle
Cake
porosity
CL
Fluid
viscosity
Fibre
density
Pf
mass. We
techniques
&P
which
the value
P (T
Aerosol
AP
Filter
C-1 (Pa.i) (kg/m3)
particles
Standard
density
(kg/m3)
deviation
C-1
of 85%
size has not yet been
pressure
drop
Pa)
analysed. Liquid
particles
to form
displayed
droplets
on, droplets
around
coalesce
intersections.
The
filter
which
surface
pressure
drop.
the liquid
inside
of the film
theoretical between process
of filtration
evaluation
for
situated
may take
in a film
on the
increase that
Davies,
of
relocation
Characterization
it would
be of a great
of the solid
interest
the transition
and liquid
particle
C. N. (1973)
of
New-York.
of the
Kuwabara,
S. (1959)
distributed
parallel
in progress.
of wT and wCLOG
stages
seem carries
at the fibre
shown
place.
they
loading
results
have
is currently study,
since
When
the exponential
experiments
the filter this
both
bridges
stage
accounts
thickness
behaviour
surface.
to build
final
Several
To complete
different
the filter
to give
flow
a
points
at small
filtration
Penicot,
Reynolds
Company
for
supply
to express
gratitude
to Bernard
DUMAS
diameter
df
diameter
dP G
Particle
m/s
Collected
Tf
Fibre
l-P
tf
wT
grammage mass per
unit
of area
radius
Particle
radius
Filtration
Uo wcLocClogging
with
diameter
Filter
Fluid
estimated
time
velocity
Transition filtration
point
for liquid
point
from
to surface
filtration
Davies’law
media
Hinds,
(kg/m*)
Loading
(kg/m*)
Aerosol
(ml
Renaudin,
(4
k-4
fibres. DEA de 1’INPG Schmidt, E., Loffler, F. (1991)
The Analysis
(m/s)
Structures.
System
(kg/m2)
109.
(kg/m*)
Experimental of fibrous
(4
10
Walsh, The
64
March
density
of deposited
1999
particles
Recent
Behaviour
Advances under
in the Understanding
Solid
Particle
N. P. (1997)
on Penetration
and Resistance
Science
and khnology
V (1991)
Particle D.A.,
C-1 C-1
27, Suppl.1,
and Particle
Stenhouse,
filters.
fibrous
filter
of
Filtration
journal
Stenhouse, of solid material
of Dust Filters.
J.I.T,
Liu,
of Dust
B.Y.H.
Scurrah,
K.L., particle
Journal
Cake 8, 105.
clogging
385-393.
Graef, loading ofAerosol
A. (1996) on Science
617-618.
Filtration
a
(I 994) particle
Science 25,
aerosol
performance.
de filtres
Characterization
monodisperse
ofAerosol
and liquid
effect
of Glass Fiber
du colmatage
J.I.T.,
of solid
The
162-173.
27,
Modklisation
results
D.C.,
Load.
33, 501-506.
W. C., Kadrichu,
effect
HEPA
Air Cleaning
782-798
and Separation
thickness
Packing
Nuclear
(ml
Cake
aP
San Diego,
I? G. (1990)
of a typical
Zlst DOE/NRC
material.
Japuntich,
density
characteristics
W
Zc
packing
loading
B., Abrahamson,
P R., Ellison,
(m)
64
and
of
Separation
P. J., Dierkschiede,
Filter
thickness
J.
of fibrous
: experiments
Symposium
Fibrous
Filter
Filter
particles
D. C. (I 996)
Z
a
clogging
Walsh,
depth filtration
Societf,
D.,Vendel,
during
European
W. B., Monson,
and mass
Conference
Fibre
in a viscous Physical
Gases, 243-255
C., Richardson, filter
ofthe
P, Leclerc, drop
aerosol
98,4th
J., Higgins,
Efficiency
dDavies Fibre
or solid
PARSEC
Novick,V.
of filters.
London,
by randomly
or spheres Journal
Contal,
of pressure
by liquid
Part~clesfrom
wish
experienced
cylinders
D.,
Evolution
models. authors
forces
Numbers.
P., Thomas,
(1998) filters
The
The circular
Press
14, 527-532.
ofJapan
respectively.
Academic
Airfiltration,
& Separation