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Preparation and structure of synthetic membranes
Desalination, 46 (1983) 303-312
303
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
PREPARATION
A.
AND
STRUCTURE
OF
SYNTHETIC
MEMBRANES
Walch
Kalle
Niederlassung
O-6200
der
Wiesbaden
1
Hoechst
AG,
P.O.B.
3540,
(Germany)
ABSTRACT Processing
via
differing
areas
phase.
The
tion
of
fied
into
synthetic of
mechanism
the
structure
of
various
a few
formation
are
has
in
the
separation
membrane
basic
on
membranes
some
accepted or
and
in
particular however,
largely
the
liquid
the may
forma-
be
classi-
are
exemplified
adequate
for
microfiltration,
gas
future
in
in
Details
hyperfiltrat,ion,
set
been gaseous
structures,
principles. of
ultrafiltration, Accents
membranes
application
in
the
separation.
research
and
development
activi-
ties.
INTRODUCTION Membranes the and to
continue
fields
of
physiology. the
fical
the
kidney)
and
application
means cially
nology.
water
the
milk on
The
metal
improved
and
finishing production
electroplating OOll-9164/83/$03.00
and
comes
of
In the
to
Membrane
separation and
and
for
impetus
for
and
similar
processes
recovery
0 1983 Elsevier Science Publishers B.V.
of
espewere
separation
encouraged
the
the by
processes
membrane
the
for
where
purified
industry,
exploit and
in (arti-
thin-film
segments, of
applied
therapeutic
biotechnolog
installations
efficiencies
being
Further
food
processing
industries
effluents
from
in
medicine,
problems
(multilayer,
concentrated
advantage
such
are
for
analysis).
are
research
biology,
separation
purposes
whey
take
intensive
membranes
medicine
clinical
membranes
to
success
problems.
in
membranes.
early
of
chemistry,
engineering
products
synthetic
in
modified
of
object
synthetic
process
for
and/or
of
the
polymer
diagnostic
assay
substrates
and
of
industry,
calorimetric
be
and
Moreover,
solution
pharmaceutical
to
physical
the
for
textile
technology
solution
rinse
tech-
for
waste
recycling waters
of con-
taining
water-soluble
lfsh.ed.
Additional
offered
to
latices,
the
by
from
the
for
via
the
preparation
and
tion
which
cess
of
The from
energy membrane
The
and
variety
1.
a.
are
with
of
of
combustion desalinato
practical
the
development for
the
pro-
experience of
example,
ecolocon-
1 summarizes
typi-
volume
future.
membrane
.differing
of
the
years.
market
following
selection
0,
and
for
widely
for
seawater
Table
in
the
industry,
are an
processes
calls
properties the
and
principal
appropriate
membrane
process:
separation
based the
and
The
the
essentially
Separation sizes
b.
past
applications
separation
mechanisms
There
the
of
guiding
a particular
The
in
of
Additional
twenty
estimated
the
and
include
past
which
of
separation)
contributed
to
were
polymer
concentration
of and
materials.
their
characteristics.
considerations
led
estab-
means
electronics
the
processes
and
membranes
the
research
raw
by
membranes
enrichment
has
protect
processes
by
(gas
decisively
applied
membrane
and
brackish
during
installations
synthetic
performance
for
of
increasing wide
and
technology
NaOH
of
(pervaporation).
for
least
fully
improvement
and
synthetic
gas,
not
now
cleaning
phase
phase
water
initially
Cl,
gas
of
natural but
beneficial
steadily
for
has
membrane
existing
serve cal
of last
combination
gically
vapor
ultrapure
deacidification process,
the
the
are
process the
process
from
application
of
by of
electrolysis
oils
for
industry
electrowinning
components
solution
fields
lubricating
possibilities
chemical
chloride-aTkali specified
and
three
on
permeants
mechanisms
large
Separation
based
on
to
separated
be
differences
(sieve
substances
of
differences
separation:
in
the
molecular
effect).
in
the
charges
(electrochemical
of
the
effect).
305 c.
Separation
depending
materials
in
chemical
The
to
dispersed
3.
Mechanical
4.
Compatibility
of
The
properties
ly,
1.
dissolved
substances).
chemical
of
the
of
of
by
dry
stability
membrane
deposits
be
the
of
physico-
separated
(e.g.
the
rejection
the
of
membrane.
materials
being
processed
predisposition
membrane
subgaseous,
fouling
to
and
the
scaling)).
MEMBRANES
by
a
and
towards
and
of
with
(e.g.
synthetic
characterized
rial,
solubilities
of
to
membrane
flux
adsorption,
SYNTHETIC
Formation
the
or
formation
be
of (volume
of
OF
in
because
substances
separated
(biocompatibility,
FORMATION
phase
the
be
and
formation
differences
H-bonding).
permeation
stance
the
membrane
features
polarity,
2.
the
on
the
polymer
following
film
spinning
polycondensation,
membranes
by
by
somewhat
three
by
of
in-situ
posttreatment
arbitrari-
mechanisms:
extrusion
process,
or
can,
the
polymer
mate-
polymerization
of
the
and
corresponding
films.
2.
Formation
3.
Production (glass
In
the
of
of or
excluded
area
which
gel
surface
should
are
rally
this
shown
by
tool thetic
for
leads
examining
membranes.
sol-gel
modified
porous
be
more
electron the
inorganic
cover
treated
or
for
ion-exchange they
preferably to
transition.
capillaries),
today
not
a
membranes
instance.
membranes
such
less
gel
formation
asymmetric
micrographs
microstructure
and
and
for
gas
(method
membranes
which
provide
morphology
1)
increasing
Membranes
hyperfiltration by
(method
a wide,
superficially.
ultrafiltration,
prepared
scanning
by
contribution
because
microfiltration, ration
layer
ZrO,/carbon
following
are
a
sepa-
2). as
a of
Gene-
will
reliable syn-
be
306 MEMBRANE
FORMATION
For were
many
years,
commercially
nitrate,
hols
and
water.
humidity,
since
phase
asymmetry have
of
their
a
polyamide,
for
Porous
2).
diameter porosity.
active
materials
formation
pore
been a
1 yields membranes
by
of
heterogeneous
fillers;
@Accurel,
pores
an
as-cast
Fig.
4).
polymer
stretching
the
by
very
flow
exact
velocity
addition
of
surface also
"dead
end",
polysulfone (Fig. polymer
dense
using
membranes by
(e.g.
addition it
film
by
af.ter
film
(@Celgard,
this
is
the
open
3) solutions
produced
Moreover,
pore
recently
binary
systems
the
increasing
Most
element
be
with
respectively),
from
homogeneous can
by
solution.
composite
prepared
Porous
also,
chemi-
diameters
since
air
sup-
membranes
pore
achieved and
reas
to
composite
minimal
were
and,
from
chemical utilized
increases
humidity,
films
its
In addition of
with
films
prefiltration of
chloride, fluoride)
self-contradictory
casting
(or
of
layer
generally
the
method
biaxially
is
period
pores.
or
pm
extensively
initially
membranes.
porosity
adequate
to
had
in
with
micro-
0,4
polyvinyl
because
supporting
surface
asymmetric
as
use
weak
disintegrate
about
polymer
were
composite
evaporation
Porous
to
sol-
skin
electron
polyvinylidene
membranes
temperature,
microfilters
ing
(e.g.
additional
requirement
air
layer
only
Any
will
having
the
commercialized.
a gel-membrane
the
The
membrane
polymers
one
the
high
during
extremely
observed
exhibit
scanning
alco-
tempera-
of
membrane.
by
application PS
However, of
is
for
This
of
control
other
membrane
combine
of
carefully
surface
shown
for
esters,
evaporation
the
membrane
as
nitrate
(PS)
matrices
(Fig.
the
been
compatibility,
must
on
from
recently
sistivity.
cal
by
across
of
conditions be
cellulose
blends,
a mixture
must
esters
from
corresponding in
initiated
opened
cellulose
1).x
Polysulfone
porting
the
polytetrafluoroethylene,
just
produced
characteristically
cellulose
(Fig.
on
be
graduated
porosity
are
based can
circulation is
formed
Microfilters
studied
and
air
microfilters
pores
diameter
have
polymers
Definite
been
the
graphs
or
the
and
in
They
acetate
separation
Such
vents.
when
microfilters
dissolving
ture,
may
MICROFILTRATION
only
available.
cellulose
instance,
FOR
accord-
without method
of
only
extractable
possible
treatment,
to
create
i.e.
mono-
@'Goretex,
'Figures 1 - 20 are referred to in the text but not reproduced be shown as slides during the presentation of the Paper.
here. They will
307 @'Poreflon,
5)
Fig.
nuclear
fragments
nuclear
tracks
MEMBRANE The
of
They
are
for
means
of
Today
these
increasing
higher
by
In
properties
the
cellulose
xanthogenate
have
in
medical
In
may 8).
(with
technical
areas
as
no
guaranteed
from
hemo-
(mechanical be
obtained
However,
and
need
in for
by case
of
dif-
sufficient
(low
sufficient
an
applications
rates
(Fig.
got
membranes
specific
transport
be
tetra-
regeneration
membranes
transport
to
and
preferably
cut-off,
dialysis
as
asymmetric
membranes
have
gel-like
particular
too.
structures
MW
more
7).
of
case
convective
distinct
etching
coagulation
in
which
ultrafiltration
to
as
heteropous
convective
asymmetric
mechanical
neutron-induced
dissolved
symmetric
competitors
favored
permeability)
with
the
(Fig.
competition,
are
bar,
by
acid
polymers.
permeability)
or
followed
of
diafiltration
10
are
cellulose
homogeneous
a certain
"technical"
subsequently
6).
('s'Cuprophan)
more
synthetic
fusive
and
Fig.
from
represented
heteroporous
ions,
sulfuric
number
is
film
ultrafilters
instance,
dilute
applications
the
ULTRAFILTRATION
cast
complex
(@Nadir),
various
heavy
FOR
precursors
amminecopper
there
or
bombarding
("Nuclepore,
FORMATlON
membranes.
by
or
compaction
permeate
up
drainage
etc.). For is
preparation
cast
into
period sed
(period
into
water) with
a
a
other
of
is
not
take
coagulation
sible
place,
formation to
of
numerous
a continuous critical
the
for
casting
but
immer-
(usually is
miscible
Diverging
phase
the
phase)
liquid
solution.
solution
evaporation
gas
a
polymer
the
bafore
polymer
short
another
the
structural
influences
need
of
or
a
from
separation
as
- cast
does
film
enters
extremely
sen-
bath.
casting
keep
the
the
after
containing
microfilters
significantly
polymer
to
air
bath
in of
or
with
a non-solvent
components
the
ultrafilters
directly
contact
preparations
The
common
and
"precipitation"
which
common
of
film
and
polymer (large
parameters
in
features particular
coagulation. scale) constant
is
during This
membrane (Fig.
the
results
production 9).
course in in
of
the order
308 The development more
hydrophilic
of asymmetric polymers
and progressively
bic polymers
for applications
aggressive
plants
must
agents
cellulose
of sufficient
in solutions bility
bridging
Today, offers
polysulfone
oxidizing
However,
requires
drophobic
again
ted by positive of which
to a blend
ethalpy
resemble
10).
used
pH range
since
it
and stability
or dispersed
hydrophilicity
were made
The most
followed
with
components
sweet
or sour
of "per se" hy-
to blend
ones,
of polysulfone
appropriate
however,
often
successful
limi-
examples
or polyvinylidene
by subsequent
hydrolysis
alcohol).
of membrane
for gas separation
asymmetric
esters
ciently
still
membranes
represent
working
resistivity ment
(Fig.
formation they
for hyperfiltration
formally
have to be in-
in the following.
Again mixed
of its varia-
FOR HYPERFILTRATION/GASSEPARATION
principles
those
prote-
and even to dense
electropaints,
of mixing.
of poly(viny1
polymer
with
12).
hydrophilic
acetate),
FORMATION
’ Because cluded
with
are the sulfonation
fluoride/poly(vinyl
MEMBRANE
Attempts
polymers
wide
macromolecular
a balanced
membranes.
hydrophobic
and because porous
is preferentially
or cataphoretic
and
membrane
of these 'membranes to processes
diversified
(e.g. anaphoretic
where
as a membrane
and hyperfiltration
11,
or celluhydropho-
and sanitized).
industry)
(Fig.
the
temperatures
(low adsorption)
resistivity,
agents
higher
remained
to finely
still
application
increasingly whey)
ultra-
high temperature
towards
employing
acetate
porous
complexes
in the food industry sterilized
(pharmaceutical
with
led to the use of more
compatibility
from coarsely
membranes
(e.g.
be periodically
Nevertheless because
began
as polyelectrolyte
lose acetate more
ultrafilters
the initially
membrane
against
based
species.
common
have protected
on cellulose applied
but still
Ease and costs
concentrations their
acetate
effi-
of manufacture,
of chlorine
application
or
within
pretreat-
certain
areas. However, because
CA membranes
of their
degradation.
are precluded
susceptability
The Du Pont
Company
from many
to hydrolysis
applications
and biological
and Monsanto-Chemstrand
309 first
prepared
amides. and of
The
polar
asymmetric
structural
heterocyclic
asymmetric are
rature
solution
same
prepared
that
are
by
the for
periods
(e.g.
asymmetric
for
the
in
exhibit
for
Figure
The
CA
is
Most
points
of
asymmetric
fundamentally
since
the
those
for
the
evapoused
dimethyl
than,
poly-
low-tempe-
However,
longer
polyamides
preparation
preparation
membranes. are
boiling
the 13.
N-methylpyrrolidone,
higher
polyof
(preferably
polyamides
solvents
aromatic units
used
compiled
corresponding
on
basic
polycondensation
dimethylacetamide,
oxide)
the
polycondensation).
from
as
ration
based
of
polycondensates
membranes
amides
membranes
membranes formulas
sulf-
example,
acetone-
formamide. Polyacrylonitrile the
preparation
layer in
in PAN
copolymers of
membranes
desalination
and
Recently,
however,
obtaining
a
the
porous As
always step by
considered
or
the
too
dense
ultrafiltration Industries
layer
by
for
active for
use
purposes. succeeded
in
plasma
treatment
of
every the
can
cast
an
thickness
permeability
controlled.
to
polymer
prepare
appropiate
of
Hence,
membranes
of
the it
the
was
a
into
active
membrane
similar
supporting
be
logical
to
layer
cannot next
asymmetric
matrix
with
a thin
either
refractory
ones
homogene-
film. The
supporting
solvents
in
protected layer.
the
the
to
of
is
gel-layer
by
the
can
pass
Thus
by
by
usually
protects
the If
porous
extracted the
into
solution.
active
or
is
membrane.
spraying. pores
formed
by
porous
support
will
of
Then
the of
support-
the
porous
a water-soluble
polymer the
be
Penetration
surface
support,
must
generally
the
the
the
intermediate
the
during layer
or
supporting
coating
to
soluble PS
dipping
solution
the
thin-film
stability,
gel-layer
casting
the
a water
fine-porous
prepared
progressively
membrane.
for
chemical
gel-layer
be
solvents
prevented
a thin
the
must
solution
casting ist
This of
is
its
fabricate
with
solvents
site
these
thin-film
polymer.
layer
casting
layer
framework
support
the
the
Because
active
ing
framework
against
employed
of
for
Moreover,
optimally
an
not
water
attempt
coating
ous
been However,
porous
Electric surface
mentioned,
membrane.
be
too
suited
Sumitomo
resultant
to
only
either
permselective
already
the
is
also
membranes.
surface.
asymmetric and
have
asymmetric
from
molecules
the of
intermediate
operation finally
of lie
the only
compoon
310 the
porous
can
be
support
linking
the
high
possible
as
active
can
is
the
be
with
brought
by
between
or
water
case
way
layer
active
a
layer by
the
surporous
polymer
organic
and
solution
of
iso-
improvement
supporting be
a
its
diisocyanate,
might
direct
as The
at
significant
and
be
cross-linking
fabrication
an
It
cross-
should
multifunctional with
of
resistance.
covalently
toluylene
this
acids
In
content
During
(e.g.
active
the
amines
stability.
drop.
polyepichlorohydrin)
contact
In
mechanical
hydrodynamic
a dissolved
agent
Finally
functional
formed
into
dichloride).
achieved.
its
its
cross-linking).
soaked
adhesion
poor pressure
layer,
minimize
also
cross-linking
phthaloyl
have
a sudden
amine-modified
(interfacial
subsequently the
to
(e.g.
support
will
by
intermediate
layer
gel-layer face
and
delaminated
in
framework
formed
interfacial
from
is
multi-
polyconden-
sation. addition
In
to
CA,
several
mides,
poly(ether/amides),
zolone
(PBIL)
structural ration the
form
unit
of
gives some
thin-film
which
Improved streams
of
only
volume
installed
of
In for
tration
plants
refined
and
concentrate
this from
waste
Figure
accelerated
using
in
has
purpose
in
the
prepa-
demonstrates and
Figure
16
membranes,
only
aggressive
process
by
and
the
supplanting
hyperfiltration
Often,
of
water
processing,
than
1978-1981
purified
application
brackish
gradually
more
during
of
15
the
than
in whey is
USA
1972-1981.
more
other
example,
the
lists
commercialized.
purposes
permeate
were
final
products
hyperfiltration plants
were
ultrafil-
using
ultrafiltration
ultra-
plants
may
be
(e.g.
to chemi-
industry). or
membranes 17
composite
agents
For
14
employed
membranes
towards
streams
development
composite
and
polya-
polybenzimida-
Figure
Figure
composite
hyperfiltration
cal/pharmaceutical The
membranes.
been
for
fact,
the
films. polymers
resistance
desalination.
filtration.
including and
barrier
asymmetric
cleaning
polymers
typical
typical
have
membranes
seawater market
some
chemical
and
synthetic
of
composite
of
a overview of
suitable
formulas
morphology
other
poly(ether/urea),
evolution
during
the
hyperfiltration
of years
asymmetric,
homogeneous
1953-1979
membranes
as
is an
summarized
example.
and in
311 MEMBRANE
pathway
possible
shown
structure
molecular
we
be
more
defined a
low
packaging to
logy
ted
by
clearly
all
having
by
of
but
urgent
still
contradictory of
In
limits
membrane
sently
became
lead
of
in
the
come
by
tive
in
the
molecular
view
active
Difficulties
but
morphoand
supplemenIn
accents
in
(Figure
aqueous
be
solutions
proved
as
characterized, as
18).
an
old
by
accessibility
facilitating
selective
the
thickness
a few
significant.
polymers
of
hundred
composite
by
approaches
order
to
(ac-
Angstroms
Problems of
in
of
pre-
mechanical
to
increase
improve the
thick-
selectivity
have
been
gas
separation
approach'
an
additional
coating
by
partially to
being
over-
eliminate less
selec-
permeable.
properties,
roughly
structurized formation
also
expe-
layer.
attention
fouling
brane
are
but
the
new
in to
polymer
"renaissance"
of
"Monsanto
highly
to
more
a
molecular
pin-holes
Intensified
reducing down
and to
has
groups
good
instance.
in
more
may
solutes
membrane
film.
to
parameters.
applications
Difficulties the
acceptor
layers
permeability ness
for
membrane
or
lead
composite)
results
to
tube
flat-sheet)
processing
sanitation
on
proton
addition,
tive)
and
or
has
water
by
for
polymers
pervaporation
asymmetric,
fiber,
molecular
problem.
transport,
abrasion
low
may
expressed
experimental
chlorine
a film,
in
the
finally
against
used
(e.g.
current
demands
nucleophilic
water
of
of
instance,
of
membranes
of
"membrane"
is
(e.g.
engineering
separating
be
function
membrane
from
against
to
to
variety
properties
films
feed-back
stability
word
DEVELOPMENT
most
leading the
for
AND
includes
function
barrier
configuration
R & 0 originate case
the the
this
relevant
particular
In
by
by
polyethylene,
resulting
proper
IN RESEARCH
figure
principles
recognized
practice
of.the
last
Furthermore
separating
In
its
have
films
ACCENTS
the
formation
density
molecular
riments.
by
in
separation.
structures
Thus
- FUTURE
FORMATION
The
has for
to
focused
instance,
active
(Figure
be
19).
layers
on
on
the
membrane
may
promote
dependance topography, secondary
of where mem-
312 The availibility
of improved
way
aided
for computer
use of heavy Rising
ions,
separation
problems
understanding
of biological membrane
"transport-active"
activities Finally, cations
distinct
also
with a more
membranes
structures membranes.
will
paves
formation
the by
of structurizing signals,
profound
give future
ressembling Corresponding
impulses
in their
function
research
by the government.
take a look beyond
structures
used to achieve optical
combined
are subvented
shall
of membrane
Principles knowingly
already we also
equipment or .for pore
for instance.
to hierarchic to
physical
manufacturing
conventional
appli-
even to non-separation
membrane segmented
films
or fibers
catalytic
for instance
(Figure
processes may be
activity
or
20).
The author is very much obliged to Priv.-Doz. Dr. W. Pusch, Max-Plan&-Inetitut fiirBiophysik (D-6000 Frankfurt/Main), for stimulating discussions and significant contributions to the paper.
303
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
PREPARATION
A.
AND
STRUCTURE
OF
SYNTHETIC
MEMBRANES
Walch
Kalle
Niederlassung
O-6200
der
Wiesbaden
1
Hoechst
AG,
P.O.B.
3540,
(Germany)
ABSTRACT Processing
via
differing
areas
phase.
The
tion
of
fied
into
synthetic of
mechanism
the
structure
of
various
a few
formation
are
has
in
the
separation
membrane
basic
on
membranes
some
accepted or
and
in
particular however,
largely
the
liquid
the may
forma-
be
classi-
are
exemplified
adequate
for
microfiltration,
gas
future
in
in
Details
hyperfiltrat,ion,
set
been gaseous
structures,
principles. of
ultrafiltration, Accents
membranes
application
in
the
separation.
research
and
development
activi-
ties.
INTRODUCTION Membranes the and to
continue
fields
of
physiology. the
fical
the
kidney)
and
application
means cially
nology.
water
the
milk on
The
metal
improved
and
finishing production
electroplating OOll-9164/83/$03.00
and
comes
of
In the
to
Membrane
separation and
and
for
impetus
for
and
similar
processes
recovery
0 1983 Elsevier Science Publishers B.V.
of
espewere
separation
encouraged
the
the by
processes
membrane
the
for
where
purified
industry,
exploit and
in (arti-
thin-film
segments, of
applied
therapeutic
biotechnolog
installations
efficiencies
being
Further
food
processing
industries
effluents
from
in
medicine,
problems
(multilayer,
concentrated
advantage
such
are
for
analysis).
are
research
biology,
separation
purposes
whey
take
intensive
membranes
medicine
clinical
membranes
to
success
problems.
in
membranes.
early
of
chemistry,
engineering
products
synthetic
in
modified
of
object
synthetic
process
for
and/or
of
the
polymer
diagnostic
assay
substrates
and
of
industry,
calorimetric
be
and
Moreover,
solution
pharmaceutical
to
physical
the
for
textile
technology
solution
rinse
tech-
for
waste
recycling waters
of con-
taining
water-soluble
lfsh.ed.
Additional
offered
to
latices,
the
by
from
the
for
via
the
preparation
and
tion
which
cess
of
The from
energy membrane
The
and
variety
1.
a.
are
with
of
of
combustion desalinato
practical
the
development for
the
pro-
experience of
example,
ecolocon-
1 summarizes
typi-
volume
future.
membrane
.differing
of
the
years.
market
following
selection
0,
and
for
widely
for
seawater
Table
in
the
industry,
are an
processes
calls
properties the
and
principal
appropriate
membrane
process:
separation
based the
and
The
the
essentially
Separation sizes
b.
past
applications
separation
mechanisms
There
the
of
guiding
a particular
The
in
of
Additional
twenty
estimated
the
and
include
past
which
of
separation)
contributed
to
were
polymer
concentration
of and
materials.
their
characteristics.
considerations
led
estab-
means
electronics
the
processes
and
membranes
the
research
raw
by
membranes
enrichment
has
protect
processes
by
(gas
decisively
applied
membrane
and
brackish
during
installations
synthetic
performance
for
of
increasing wide
and
technology
NaOH
of
(pervaporation).
for
least
fully
improvement
and
synthetic
gas,
not
now
cleaning
phase
phase
water
initially
Cl,
gas
of
natural but
beneficial
steadily
for
has
membrane
existing
serve cal
of last
combination
gically
vapor
ultrapure
deacidification process,
the
the
are
process the
process
from
application
of
by of
electrolysis
oils
for
industry
electrowinning
components
solution
fields
lubricating
possibilities
chemical
chloride-aTkali specified
and
three
on
permeants
mechanisms
large
Separation
based
on
to
separated
be
differences
(sieve
substances
of
differences
separation:
in
the
molecular
effect).
in
the
charges
(electrochemical
of
the
effect).
305 c.
Separation
depending
materials
in
chemical
The
to
dispersed
3.
Mechanical
4.
Compatibility
of
The
properties
ly,
1.
dissolved
substances).
chemical
of
the
of
of
by
dry
stability
membrane
deposits
be
the
of
physico-
separated
(e.g.
the
rejection
the
of
membrane.
materials
being
processed
predisposition
membrane
subgaseous,
fouling
to
and
the
scaling)).
MEMBRANES
by
a
and
towards
and
of
with
(e.g.
synthetic
characterized
rial,
solubilities
of
to
membrane
flux
adsorption,
SYNTHETIC
Formation
the
or
formation
be
of (volume
of
OF
in
because
substances
separated
(biocompatibility,
FORMATION
phase
the
be
and
formation
differences
H-bonding).
permeation
stance
the
membrane
features
polarity,
2.
the
on
the
polymer
following
film
spinning
polycondensation,
membranes
by
by
somewhat
three
by
of
in-situ
posttreatment
arbitrari-
mechanisms:
extrusion
process,
or
can,
the
polymer
mate-
polymerization
of
the
and
corresponding
films.
2.
Formation
3.
Production (glass
In
the
of
of or
excluded
area
which
gel
surface
should
are
rally
this
shown
by
tool thetic
for
leads
examining
membranes.
sol-gel
modified
porous
be
more
electron the
inorganic
cover
treated
or
for
ion-exchange they
preferably to
transition.
capillaries),
today
not
a
membranes
instance.
membranes
such
less
gel
formation
asymmetric
micrographs
microstructure
and
and
for
gas
(method
membranes
which
provide
morphology
1)
increasing
Membranes
hyperfiltration by
(method
a wide,
superficially.
ultrafiltration,
prepared
scanning
by
contribution
because
microfiltration, ration
layer
ZrO,/carbon
following
are
a
sepa-
2). as
a of
Gene-
will
reliable syn-
be
306 MEMBRANE
FORMATION
For were
many
years,
commercially
nitrate,
hols
and
water.
humidity,
since
phase
asymmetry have
of
their
a
polyamide,
for
Porous
2).
diameter porosity.
active
materials
formation
pore
been a
1 yields membranes
by
of
heterogeneous
fillers;
@Accurel,
pores
an
as-cast
Fig.
4).
polymer
stretching
the
by
very
flow
exact
velocity
addition
of
surface also
"dead
end",
polysulfone (Fig. polymer
dense
using
membranes by
(e.g.
addition it
film
by
af.ter
film
(@Celgard,
this
is
the
open
3) solutions
produced
Moreover,
pore
recently
binary
systems
the
increasing
Most
element
be
with
respectively),
from
homogeneous can
by
solution.
composite
prepared
Porous
also,
chemi-
diameters
since
air
sup-
membranes
pore
achieved and
reas
to
composite
minimal
were
and,
from
chemical utilized
increases
humidity,
films
its
In addition of
with
films
prefiltration of
chloride, fluoride)
self-contradictory
casting
(or
of
layer
generally
the
method
biaxially
is
period
pores.
or
pm
extensively
initially
membranes.
porosity
adequate
to
had
in
with
micro-
0,4
polyvinyl
because
supporting
surface
asymmetric
as
use
weak
disintegrate
about
polymer
were
composite
evaporation
Porous
to
sol-
skin
electron
polyvinylidene
membranes
temperature,
microfilters
ing
(e.g.
additional
requirement
air
layer
only
Any
will
having
the
commercialized.
a gel-membrane
the
The
membrane
polymers
one
the
high
during
extremely
observed
exhibit
scanning
alco-
tempera-
of
membrane.
by
application PS
However, of
is
for
This
of
control
other
membrane
combine
of
carefully
surface
shown
for
esters,
evaporation
the
membrane
as
nitrate
(PS)
matrices
(Fig.
the
been
compatibility,
must
on
from
recently
sistivity.
cal
by
across
of
conditions be
cellulose
blends,
a mixture
must
esters
from
corresponding in
initiated
opened
cellulose
1).x
Polysulfone
porting
the
polytetrafluoroethylene,
just
produced
characteristically
cellulose
(Fig.
on
be
graduated
porosity
are
based can
circulation is
formed
Microfilters
studied
and
air
microfilters
pores
diameter
have
polymers
Definite
been
the
graphs
or
the
and
in
They
acetate
separation
Such
vents.
when
microfilters
dissolving
ture,
may
MICROFILTRATION
only
available.
cellulose
instance,
FOR
accord-
without method
of
only
extractable
possible
treatment,
to
create
i.e.
mono-
@'Goretex,
'Figures 1 - 20 are referred to in the text but not reproduced be shown as slides during the presentation of the Paper.
here. They will
307 @'Poreflon,
5)
Fig.
nuclear
fragments
nuclear
tracks
MEMBRANE The
of
They
are
for
means
of
Today
these
increasing
higher
by
In
properties
the
cellulose
xanthogenate
have
in
medical
In
may 8).
(with
technical
areas
as
no
guaranteed
from
hemo-
(mechanical be
obtained
However,
and
need
in for
by case
of
dif-
sufficient
(low
sufficient
an
applications
rates
(Fig.
got
membranes
specific
transport
be
tetra-
regeneration
membranes
transport
to
and
preferably
cut-off,
dialysis
as
asymmetric
membranes
have
gel-like
particular
too.
structures
MW
more
7).
of
case
convective
distinct
etching
coagulation
in
which
ultrafiltration
to
as
heteropous
convective
asymmetric
mechanical
neutron-induced
dissolved
symmetric
competitors
favored
permeability)
with
the
(Fig.
competition,
are
bar,
by
acid
polymers.
permeability)
or
followed
of
diafiltration
10
are
cellulose
homogeneous
a certain
"technical"
subsequently
6).
('s'Cuprophan)
more
synthetic
fusive
and
Fig.
from
represented
heteroporous
ions,
sulfuric
number
is
film
ultrafilters
instance,
dilute
applications
the
ULTRAFILTRATION
cast
complex
(@Nadir),
various
heavy
FOR
precursors
amminecopper
there
or
bombarding
("Nuclepore,
FORMATlON
membranes.
by
or
compaction
permeate
up
drainage
etc.). For is
preparation
cast
into
period sed
(period
into
water) with
a
a
other
of
is
not
take
coagulation
sible
place,
formation to
of
numerous
a continuous critical
the
for
casting
but
immer-
(usually is
miscible
Diverging
phase
the
phase)
liquid
solution.
solution
evaporation
gas
a
polymer
the
bafore
polymer
short
another
the
structural
influences
need
of
or
a
from
separation
as
- cast
does
film
enters
extremely
sen-
bath.
casting
keep
the
the
after
containing
microfilters
significantly
polymer
to
air
bath
in of
or
with
a non-solvent
components
the
ultrafilters
directly
contact
preparations
The
common
and
"precipitation"
which
common
of
film
and
polymer (large
parameters
in
features particular
coagulation. scale) constant
is
during This
membrane (Fig.
the
results
production 9).
course in in
of
the order
308 The development more
hydrophilic
of asymmetric polymers
and progressively
bic polymers
for applications
aggressive
plants
must
agents
cellulose
of sufficient
in solutions bility
bridging
Today, offers
polysulfone
oxidizing
However,
requires
drophobic
again
ted by positive of which
to a blend
ethalpy
resemble
10).
used
pH range
since
it
and stability
or dispersed
hydrophilicity
were made
The most
followed
with
components
sweet
or sour
of "per se" hy-
to blend
ones,
of polysulfone
appropriate
however,
often
successful
limi-
examples
or polyvinylidene
by subsequent
hydrolysis
alcohol).
of membrane
for gas separation
asymmetric
esters
ciently
still
membranes
represent
working
resistivity ment
(Fig.
formation they
for hyperfiltration
formally
have to be in-
in the following.
Again mixed
of its varia-
FOR HYPERFILTRATION/GASSEPARATION
principles
those
prote-
and even to dense
electropaints,
of mixing.
of poly(viny1
polymer
with
12).
hydrophilic
acetate),
FORMATION
’ Because cluded
with
are the sulfonation
fluoride/poly(vinyl
MEMBRANE
Attempts
polymers
wide
macromolecular
a balanced
membranes.
hydrophobic
and because porous
is preferentially
or cataphoretic
and
membrane
of these 'membranes to processes
diversified
(e.g. anaphoretic
where
as a membrane
and hyperfiltration
11,
or celluhydropho-
and sanitized).
industry)
(Fig.
the
temperatures
(low adsorption)
resistivity,
agents
higher
remained
to finely
still
application
increasingly whey)
ultra-
high temperature
towards
employing
acetate
porous
complexes
in the food industry sterilized
(pharmaceutical
with
led to the use of more
compatibility
from coarsely
membranes
(e.g.
be periodically
Nevertheless because
began
as polyelectrolyte
lose acetate more
ultrafilters
the initially
membrane
against
based
species.
common
have protected
on cellulose applied
but still
Ease and costs
concentrations their
acetate
effi-
of manufacture,
of chlorine
application
or
within
pretreat-
certain
areas. However, because
CA membranes
of their
degradation.
are precluded
susceptability
The Du Pont
Company
from many
to hydrolysis
applications
and biological
and Monsanto-Chemstrand
309 first
prepared
amides. and of
The
polar
asymmetric
structural
heterocyclic
asymmetric are
rature
solution
same
prepared
that
are
by
the for
periods
(e.g.
asymmetric
for
the
in
exhibit
for
Figure
The
CA
is
Most
points
of
asymmetric
fundamentally
since
the
those
for
the
evapoused
dimethyl
than,
poly-
low-tempe-
However,
longer
polyamides
preparation
preparation
membranes. are
boiling
the 13.
N-methylpyrrolidone,
higher
polyof
(preferably
polyamides
solvents
aromatic units
used
compiled
corresponding
on
basic
polycondensation
dimethylacetamide,
oxide)
the
polycondensation).
from
as
ration
based
of
polycondensates
membranes
amides
membranes
membranes formulas
sulf-
example,
acetone-
formamide. Polyacrylonitrile the
preparation
layer in
in PAN
copolymers of
membranes
desalination
and
Recently,
however,
obtaining
a
the
porous As
always step by
considered
or
the
too
dense
ultrafiltration Industries
layer
by
for
active for
use
purposes. succeeded
in
plasma
treatment
of
every the
can
cast
an
thickness
permeability
controlled.
to
polymer
prepare
appropiate
of
Hence,
membranes
of
the it
the
was
a
into
active
membrane
similar
supporting
be
logical
to
layer
cannot next
asymmetric
matrix
with
a thin
either
refractory
ones
homogene-
film. The
supporting
solvents
in
protected layer.
the
the
to
of
is
gel-layer
by
the
can
pass
Thus
by
by
usually
protects
the If
porous
extracted the
into
solution.
active
or
is
membrane.
spraying. pores
formed
by
porous
support
will
of
Then
the of
support-
the
porous
a water-soluble
polymer the
be
Penetration
surface
support,
must
generally
the
the
the
intermediate
the
during layer
or
supporting
coating
to
soluble PS
dipping
solution
the
thin-film
stability,
gel-layer
casting
the
a water
fine-porous
prepared
progressively
membrane.
for
chemical
gel-layer
be
solvents
prevented
a thin
the
must
solution
casting ist
This of
is
its
fabricate
with
solvents
site
these
thin-film
polymer.
layer
casting
layer
framework
support
the
the
Because
active
ing
framework
against
employed
of
for
Moreover,
optimally
an
not
water
attempt
coating
ous
been However,
porous
Electric surface
mentioned,
membrane.
be
too
suited
Sumitomo
resultant
to
only
either
permselective
already
the
is
also
membranes.
surface.
asymmetric and
have
asymmetric
from
molecules
the of
intermediate
operation finally
of lie
the only
compoon
310 the
porous
can
be
support
linking
the
high
possible
as
active
can
is
the
be
with
brought
by
between
or
water
case
way
layer
active
a
layer by
the
surporous
polymer
organic
and
solution
of
iso-
improvement
supporting be
a
its
diisocyanate,
might
direct
as The
at
significant
and
be
cross-linking
fabrication
an
It
cross-
should
multifunctional with
of
resistance.
covalently
toluylene
this
acids
In
content
During
(e.g.
active
the
amines
stability.
drop.
polyepichlorohydrin)
contact
In
mechanical
hydrodynamic
a dissolved
agent
Finally
functional
formed
into
dichloride).
achieved.
its
its
cross-linking).
soaked
adhesion
poor pressure
layer,
minimize
also
cross-linking
phthaloyl
have
a sudden
amine-modified
(interfacial
subsequently the
to
(e.g.
support
will
by
intermediate
layer
gel-layer face
and
delaminated
in
framework
formed
interfacial
from
is
multi-
polyconden-
sation. addition
In
to
CA,
several
mides,
poly(ether/amides),
zolone
(PBIL)
structural ration the
form
unit
of
gives some
thin-film
which
Improved streams
of
only
volume
installed
of
In for
tration
plants
refined
and
concentrate
this from
waste
Figure
accelerated
using
in
has
purpose
in
the
prepa-
demonstrates and
Figure
16
membranes,
only
aggressive
process
by
and
the
supplanting
hyperfiltration
Often,
of
water
processing,
than
1978-1981
purified
application
brackish
gradually
more
during
of
15
the
than
in whey is
USA
1972-1981.
more
other
example,
the
lists
commercialized.
purposes
permeate
were
final
products
hyperfiltration plants
were
ultrafil-
using
ultrafiltration
ultra-
plants
may
be
(e.g.
to chemi-
industry). or
membranes 17
composite
agents
For
14
employed
membranes
towards
streams
development
composite
and
polya-
polybenzimida-
Figure
Figure
composite
hyperfiltration
cal/pharmaceutical The
membranes.
been
for
fact,
the
films. polymers
resistance
desalination.
filtration.
including and
barrier
asymmetric
cleaning
polymers
typical
typical
have
membranes
seawater market
some
chemical
and
synthetic
of
composite
of
a overview of
suitable
formulas
morphology
other
poly(ether/urea),
evolution
during
the
hyperfiltration
of years
asymmetric,
homogeneous
1953-1979
membranes
as
is an
summarized
example.
and in
311 MEMBRANE
pathway
possible
shown
structure
molecular
we
be
more
defined a
low
packaging to
logy
ted
by
clearly
all
having
by
of
but
urgent
still
contradictory of
In
limits
membrane
sently
became
lead
of
in
the
come
by
tive
in
the
molecular
view
active
Difficulties
but
morphoand
supplemenIn
accents
in
(Figure
aqueous
be
solutions
proved
as
characterized, as
18).
an
old
by
accessibility
facilitating
selective
the
thickness
a few
significant.
polymers
of
hundred
composite
by
approaches
order
to
(ac-
Angstroms
Problems of
in
of
pre-
mechanical
to
increase
improve the
thick-
selectivity
have
been
gas
separation
approach'
an
additional
coating
by
partially to
being
over-
eliminate less
selec-
permeable.
properties,
roughly
structurized formation
also
expe-
layer.
attention
fouling
brane
are
but
the
new
in to
polymer
"renaissance"
of
"Monsanto
highly
to
more
a
molecular
pin-holes
Intensified
reducing down
and to
has
groups
good
instance.
in
more
may
solutes
membrane
film.
to
parameters.
applications
Difficulties the
acceptor
layers
permeability ness
for
membrane
or
lead
composite)
results
to
tube
flat-sheet)
processing
sanitation
on
proton
addition,
tive)
and
or
has
water
by
for
polymers
pervaporation
asymmetric,
fiber,
molecular
problem.
transport,
abrasion
low
may
expressed
experimental
chlorine
a film,
in
the
finally
against
used
(e.g.
current
demands
nucleophilic
water
of
of
instance,
of
membranes
of
"membrane"
is
(e.g.
engineering
separating
be
function
membrane
from
against
to
to
variety
properties
films
feed-back
stability
word
DEVELOPMENT
most
leading the
for
AND
includes
function
barrier
configuration
R & 0 originate case
the the
this
relevant
particular
In
by
by
polyethylene,
resulting
proper
IN RESEARCH
figure
principles
recognized
practice
of.the
last
Furthermore
separating
In
its
have
films
ACCENTS
the
formation
density
molecular
riments.
by
in
separation.
structures
Thus
- FUTURE
FORMATION
The
has for
to
focused
instance,
active
(Figure
be
19).
layers
on
on
the
membrane
may
promote
dependance topography, secondary
of where mem-
312 The availibility
of improved
way
aided
for computer
use of heavy Rising
ions,
separation
problems
understanding
of biological membrane
"transport-active"
activities Finally, cations
distinct
also
with a more
membranes
structures membranes.
will
paves
formation
the by
of structurizing signals,
profound
give future
ressembling Corresponding
impulses
in their
function
research
by the government.
take a look beyond
structures
used to achieve optical
combined
are subvented
shall
of membrane
Principles knowingly
already we also
equipment or .for pore
for instance.
to hierarchic to
physical
manufacturing
conventional
appli-
even to non-separation
membrane segmented
films
or fibers
catalytic
for instance
(Figure
processes may be
activity
or
20).
The author is very much obliged to Priv.-Doz. Dr. W. Pusch, Max-Plan&-Inetitut fiirBiophysik (D-6000 Frankfurt/Main), for stimulating discussions and significant contributions to the paper.